Fix tests

Add default arguments for tests
2026-04-22 21:57:58 +00:00 · 2025-10-27 03:07:45 +03:00 · 2025-10-27 03:00:21 +03:00 · 2025-10-27 02:25:17 +03:00 · 2025-10-26 04:00:00 +03:00 · 2025-10-26 02:46:47 +03:00
100 changed files with 20879 additions and 5353 deletions
@@ -15,6 +15,7 @@ concurrency:
 env:
  CARGO_TERM_COLOR: always
  POLKADOT_VERSION: polkadot-stable2506-2
 jobs:
  cache-polkadot:
@@ -65,6 +66,37 @@ jobs:
        run: |
          cd polkadot-sdk
          cargo install --path substrate/frame/revive/rpc --bin eth-rpc
      - name: Cache downloaded Polkadot binaries
        id: cache-polkadot
        uses: actions/cache@v3
        with:
          path: |
            ~/polkadot-cache/polkadot
            ~/polkadot-cache/polkadot-execute-worker
            ~/polkadot-cache/polkadot-prepare-worker
            ~/polkadot-cache/polkadot-parachain
          key: polkadot-downloaded-${{ matrix.os }}-${{ env.POLKADOT_VERSION }}
      - name: Download Polkadot binaries on macOS
        if: matrix.os == 'macos-14' && steps.cache-polkadot.outputs.cache-hit != 'true'
        run: |
          mkdir -p ~/polkadot-cache
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-aarch64-apple-darwin -o ~/polkadot-cache/polkadot
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-execute-worker-aarch64-apple-darwin -o ~/polkadot-cache/polkadot-execute-worker
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-prepare-worker-aarch64-apple-darwin -o ~/polkadot-cache/polkadot-prepare-worker
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-parachain-aarch64-apple-darwin -o ~/polkadot-cache/polkadot-parachain
          chmod +x ~/polkadot-cache/*
      - name: Download Polkadot binaries on Ubuntu
        if: matrix.os == 'ubuntu-24.04' && steps.cache-polkadot.outputs.cache-hit != 'true'
        run: |
          mkdir -p ~/polkadot-cache
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot -o ~/polkadot-cache/polkadot
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-execute-worker -o ~/polkadot-cache/polkadot-execute-worker
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-prepare-worker -o ~/polkadot-cache/polkadot-prepare-worker
          curl -sL https://github.com/paritytech/polkadot-sdk/releases/download/${{ env.POLKADOT_VERSION }}/polkadot-parachain -o ~/polkadot-cache/polkadot-parachain
          chmod +x ~/polkadot-cache/*
  ci:
    name: CI on ${{ matrix.os }}
@@ -86,22 +118,43 @@ jobs:
            ~/.cargo/bin/eth-rpc
          key: polkadot-binaries-${{ matrix.os }}-${{ hashFiles('polkadot-sdk/.git') }}
      - name: Restore downloaded Polkadot binaries from cache
        uses: actions/cache@v3
        with:
          path: |
            ~/polkadot-cache/polkadot
            ~/polkadot-cache/polkadot-execute-worker
            ~/polkadot-cache/polkadot-prepare-worker
            ~/polkadot-cache/polkadot-parachain
          key: polkadot-downloaded-${{ matrix.os }}-${{ env.POLKADOT_VERSION }}
      - name: Install Polkadot binaries
        run: |
          sudo cp ~/polkadot-cache/polkadot /usr/local/bin/
          sudo cp ~/polkadot-cache/polkadot-execute-worker /usr/local/bin/
          sudo cp ~/polkadot-cache/polkadot-prepare-worker /usr/local/bin/
          sudo cp ~/polkadot-cache/polkadot-parachain /usr/local/bin/
          sudo chmod +x /usr/local/bin/polkadot*
      - name: Setup Rust toolchain
        uses: actions-rust-lang/setup-rust-toolchain@v1
        with:
          rustflags: ""
-      - name: Add wasm32 target
+      - name: Add wasm32 target and formatting
        run: |
          rustup target add wasm32-unknown-unknown
-          rustup component add rust-src
+          rustup component add rust-src rustfmt clippy
      - name: Install Geth on Ubuntu
        if: matrix.os == 'ubuntu-24.04'
        run: |
          sudo add-apt-repository -y ppa:ethereum/ethereum
          sudo apt-get update
          sudo apt-get install -y protobuf-compiler
          sudo apt-get install -y solc
          # We were facing some issues in CI with the 1.16.* versions of geth, and specifically on
          # Ubuntu. Eventually, we found out that the last version of geth that worked in our CI was
          # version 1.15.11. Thus, this is the version that we want to use in CI. The PPA sadly does
@@ -122,12 +175,33 @@ jobs:
          wget -qO- "$URL" | sudo tar xz -C /usr/local/bin --strip-components=1
          geth --version
          curl -sL https://github.com/paritytech/revive/releases/download/v0.3.0/resolc-x86_64-unknown-linux-musl -o resolc
          chmod +x resolc
          sudo mv resolc /usr/local/bin
      - name: Install Geth on macOS
        if: matrix.os == 'macos-14'
        run: |
          brew tap ethereum/ethereum
          brew install ethereum protobuf
          brew install solidity
          curl -sL https://github.com/paritytech/revive/releases/download/v0.3.0/resolc-universal-apple-darwin -o resolc
          chmod +x resolc
          sudo mv resolc /usr/local/bin
      - name: Install Kurtosis on macOS
        if: matrix.os == 'macos-14'
        run: brew install kurtosis-tech/tap/kurtosis-cli
      - name: Install Kurtosis on Ubuntu
        if: matrix.os == 'ubuntu-24.04'
        run: |
          echo "deb [trusted=yes] https://apt.fury.io/kurtosis-tech/ /" | sudo tee /etc/apt/sources.list.d/kurtosis.list
          sudo apt update
          sudo apt install kurtosis-cli
      - name: Machete
        uses: bnjbvr/cargo-machete@v0.7.1
@@ -143,5 +217,37 @@ jobs:
      - name: Check eth-rpc version
        run: eth-rpc --version
-      - name: Test cargo workspace
+      - name: Check resolc version
-        run: make test
+        run: resolc --version
      - name: Check polkadot version
        run: polkadot --version
      - name: Check polkadot-parachain version
        run: polkadot-parachain --version
      - name: Check polkadot-execute-worker version
        run: polkadot-execute-worker --version
      - name: Check polkadot-prepare-worker version
        run: polkadot-prepare-worker --version
      - name: Test Formatting
        run: make format
      - name: Test Clippy
        run: make clippy
      - name: Test Machete
        run: make machete
      - name: Unit Tests
        if: matrix.os == 'ubuntu-24.04'
        run: cargo test --workspace -- --nocapture
      # We can't install docker in the MacOS image used in CI and therefore we need to skip the
      # Kurtosis and lighthouse related tests when running the CI on MacOS.
      - name: Unit Tests
        if: matrix.os == 'macos-14'
        run: |
          cargo test --workspace -- --nocapture --skip lighthouse_geth::tests::
@@ -6,4 +6,10 @@ node_modules
 # We do not want to commit any log files that we produce from running the code locally so this is 
 # added to the .gitignore file.
-*.log
+*.log
 profile.json.gz
 workdir
 !/schema.json
 !/dev-genesis.json
@@ -1,3 +1,6 @@
 [submodule "polkadot-sdk"]
 	path = polkadot-sdk
 	url = https://github.com/paritytech/polkadot-sdk.git
 [submodule "resolc-compiler-tests"]
 	path = resolc-compiler-tests
 	url = https://github.com/paritytech/resolc-compiler-tests
@@ -8,9 +8,10 @@ authors = ["Parity Technologies <admin@parity.io>"]
 license = "MIT/Apache-2.0"
 edition = "2024"
 repository = "https://github.com/paritytech/revive-differential-testing.git"
-rust-version = "1.85.0"
+rust-version = "1.87.0"
 [workspace.dependencies]
 revive-dt-common = { version = "0.1.0", path = "crates/common" }
 revive-dt-compiler = { version = "0.1.0", path = "crates/compiler" }
 revive-dt-config = { version = "0.1.0", path = "crates/config" }
 revive-dt-core = { version = "0.1.0", path = "crates/core" }
@@ -21,50 +22,71 @@ revive-dt-node-pool = { version = "0.1.0", path = "crates/node-pool" }
 revive-dt-report = { version = "0.1.0", path = "crates/report" }
 revive-dt-solc-binaries = { version = "0.1.0", path = "crates/solc-binaries" }
-alloy-primitives = "1.2.1"
+ansi_term = "0.12.1"
 alloy-sol-types = "1.2.1"
 anyhow = "1.0"
-clap = { version = "4", features = ["derive"] }
+bson = { version = "2.15.0" }
 cacache = { version = "13.1.0" }
 clap = { version = "4", features = ["derive", "wrap_help"] }
 dashmap = { version = "6.1.0" }
 foundry-compilers-artifacts = { version = "0.18.0" }
 futures = { version = "0.3.31" }
 hex = "0.4.3"
-reqwest = { version = "0.12.15", features = ["blocking", "json"] }
+regex = "1"
 moka = "0.12.10"
 paste = "1.0.15"
 reqwest = { version = "0.12.15", features = ["json"] }
 once_cell = "1.21"
-rayon = { version = "1.10" }
+schemars = { version = "1.0.4", features = ["semver1"] }
 semver = { version = "1.0", features = ["serde"] }
 serde = { version = "1.0", default-features = false, features = ["derive"] }
 serde_json = { version = "1.0", default-features = false, features = [
    "arbitrary_precision",
    "std",
    "unbounded_depth",
 ] }
 serde_with = { version = "3.14.0", features = ["hex"] }
 serde_yaml_ng = { version = "0.10.0" }
 sha2 = { version = "0.10.9" }
 sp-core = "36.1.0"
 sp-runtime = "41.1.0"
 strum = { version = "0.27.2", features = ["derive"] }
 subxt = { version = "0.44.0" }
 temp-dir = { version = "0.1.16" }
 tempfile = "3.3"
-tokio = { version = "1", default-features = false, features = [
+thiserror = "2"
 tokio = { version = "1.47.0", default-features = false, features = [
    "rt-multi-thread",
    "process",
    "rt",
 ] }
 tower = { version = "0.5.2", features = ["limit"] }
 uuid = { version = "1.8", features = ["v4"] }
-tracing = "0.1.41"
+tracing = { version = "0.1.41" }
 tracing-appender = { version = "0.2.3" }
 tracing-subscriber = { version = "0.3.19", default-features = false, features = [
    "fmt",
    "json",
    "env-filter",
 ] }
 indexmap = { version = "2.10.0", default-features = false }
 itertools = { version = "0.14.0" }
 # revive compiler
 revive-solc-json-interface = { git = "https://github.com/paritytech/revive", rev = "3389865af7c3ff6f29a586d82157e8bc573c1a8e" }
 revive-common = { git = "https://github.com/paritytech/revive", rev = "3389865af7c3ff6f29a586d82157e8bc573c1a8e" }
 revive-differential = { git = "https://github.com/paritytech/revive", rev = "3389865af7c3ff6f29a586d82157e8bc573c1a8e" }
 zombienet-sdk = { git = "https://github.com/paritytech/zombienet-sdk.git", rev = "891f6554354ce466abd496366dbf8b4f82141241" }
 [workspace.dependencies.alloy]
-version = "1.0"
+version = "1.0.37"
 default-features = false
 features = [
    "json-abi",
    "providers",
    "provider-ws",
    "provider-ipc",
    "provider-http",
    "provider-debug-api",
    "reqwest",
    "rpc-types",
@@ -73,9 +95,13 @@ features = [
    "network",
    "serde",
    "rpc-types-eth",
    "genesis",
    "sol-types",
 ]
 [profile.bench]
 inherits = "release"
 lto = true
 codegen-units = 1
 [workspace.lints.clippy]
@@ -1,34 +1,120 @@
-# revive-differential-tests
+<div align="center">
  <h1><code>Revive Differential Tests</code></h1>
-The revive differential testing framework allows to define smart contract tests in a declarative manner in order to compile and execute them against different Ethereum-compatible blockchain implmentations. This is useful to:
+  <p>
- Analyze observable differences in contract compilation and execution across different blockchain implementations, including contract storage, account balances, transaction output and emitted events on a per-transaction base.
+    <strong>Differential testing for Ethereum-compatible smart contract stacks</strong>
- Collect and compare benchmark metrics such as code size, gas usage or transaction throughput per seconds (TPS) of different blockchain implementations.
+  </p>
- Ensure reproducible contract builds across multiple compiler implementations or multiple host platforms.
+</div>
 - Implement end-to-end regression tests for Ethereum-compatible smart contract stacks.
-# Declarative test format
+This project compiles and executes declarative smart-contract tests against multiple platforms, then compares behavior (status, return data, events, and state diffs). Today it supports:
-For now, the format used to write tests is the [matter-labs era compiler format](https://github.com/matter-labs/era-compiler-tests?tab=readme-ov-file#matter-labs-simplecomplex-format). This allows us to re-use many tests from their corpora.
+- Geth (EVM reference implementation)
 - Revive Kitchensink (Substrate-based PolkaVM + `eth-rpc` proxy)
-# The `retester` utility
+Use it to:
-The `retester` helper utilty is used to run the tests. To get an idea of what `retester` can do, please consults its command line help: 
+- Detect observable differences between platforms (execution success, logs, state changes)
 - Ensure reproducible builds across compilers/hosts
 - Run end-to-end regression suites
-```
+This framework uses the [MatterLabs tests format](https://github.com/matter-labs/era-compiler-tests/tree/main/solidity) for declarative tests which is composed of the following:
 cargo run -p revive-dt-core -- --help
 ```
-For example, to run the [complex Solidity tests](https://github.com/matter-labs/era-compiler-tests/tree/main/solidity/complex), define a corpus structure as follows:
+- Metadata files, this is akin to a module of tests in Rust.
 - Each metadata file contains multiple cases, a case is akin to a Rust test where a module can contain multiple tests.
 - Each case contains multiple steps and assertions, this is akin to any Rust test that contains multiple statements.
-```json
+Metadata files are JSON files, but Solidity files can also be metadata files if they include inline metadata provided as a comment at the top of the contract.
 {
    "name": "ML Solidity Complex",
    "path": "/path/to/era-compiler-tests/solidity/complex"
 }
 ```
-Assuming this to be saved in a `ml-solidity-complex.json` file, the following command will try to compile and execute the tests found inside the corpus:
+All of the steps contained within each test case are either:
 - Transactions that need to be submitted and assertions to run on the submitted transactions.
 - Assertions on the state of the chain (e.g., account balances, storage, etc...)
 All of the transactions submitted by the this tool to the test nodes follow a similar logic to what wallets do. We first use alloy to estimate the transaction fees, then we attach that to the transaction and submit it to the node and then await the transaction receipt.
 This repository contains none of the tests and only contains the testing framework or the test runner. The tests can be found in the [`resolc-compiler-tests`](https://github.com/paritytech/resolc-compiler-tests) repository which is a clone of [MatterLab's test suite](https://github.com/matter-labs/era-compiler-tests) with some modifications and adjustments made to suit our use case.
 ## Requirements
 This section describes the required dependencies that this framework requires to run. Compiling this framework is pretty straightforward and no additional dependencies beyond what's specified in the `Cargo.toml` file should be required.
 - Stable Rust
 - Geth - When doing differential testing against the PVM we submit transactions to a Geth node and to Kitchensink to compare them.
 - Kitchensink - When doing differential testing against the PVM we submit transactions to a Geth node and to Kitchensink to compare them.
 - ETH-RPC - All communication with Kitchensink is done through the ETH RPC.
 - Solc - This is actually a transitive dependency, while this tool doesn't require solc as it downloads the versions that it requires, resolc requires that Solc is installed and available in the path.
 - Resolc - This is required to compile the contracts to PolkaVM bytecode.
 - Kurtosis - The Kurtosis CLI tool is required for the production Ethereum mainnet-like node configuration with Geth as the execution layer and lighthouse as the consensus layer. Kurtosis also requires docker to be installed since it runs everything inside of docker containers.
 All of the above need to be installed and available in the path in order for the tool to work.
 ## Running The Tool
 This tool is being updated quite frequently. Therefore, it's recommended that you don't install the tool and then run it, but rather that you run it from the root of the directory using `cargo run --release`. The help command of the tool gives you all of the information you need to know about each of the options and flags that the tool offers.
 > [!NOTE]  
 > Note that the tests can be found in the [`resolc-compiler-tests`](https://github.com/paritytech/resolc-compiler-tests) repository.
 The simplest command to run this tool is the following:
 ```bash
-RUST_LOG=debug cargo r --release -p revive-dt-core  -- --corpus ml-solidity-complex.json 
+RUST_LOG="info" cargo run --release -- test \
    --test ./resolc-compiler-tests/fixtures/solidity \
    --platform geth-evm-solc \
    --working-directory workdir \
    > logs.log \
    2> output.log
 ```
 The above command will run the tool executing every one of the tests discovered in the path provided to the tool. All of the logs from the execution will be persisted in the `logs.log` file and all of the output of the tool will be persisted to the `output.log` file. If all that you're looking for is to run the tool and check which tests succeeded and failed, then the `output.log` file is what you need to be looking at. However, if you're contributing the to the tool then the `logs.log` file will be very valuable.
 <details>
 <summary>User Managed Nodes</summary>
 This section describes how the user can make use of nodes that they manage rather than allowing the tool to spawn and manage the nodes on the user's behalf.
 > ⚠️ This is an advanced feature of the tool and could lead test successes or failures to not be reproducible. Please use this feature with caution and only if you understand the implications of running your own node instead of having the framework manage your nodes. ⚠️
 If you're an advanced user and you'd like to manage your own nodes instead of having the tool initialize, spawn, and manage them, then you can choose to run your own nodes and then provide them to the tool to make use of just like the following:
 ```bash
 #!/usr/bin/env bash
 set -euo pipefail
 PLATFORM="revive-dev-node-revm-solc"
 retester export-genesis "$PLATFORM" > chainspec.json
 # Start revive-dev-node in a detached tmux session
 tmux new-session -d -s revive-dev-node \
  'RUST_LOG="error,evm=debug,sc_rpc_server=info,runtime::revive=debug" revive-dev-node \
    --dev \
    --chain chainspec.json \
    --force-authoring \
    --rpc-methods Unsafe \
    --rpc-cors all \
    --rpc-max-connections 4294967295 \
    --pool-limit 4294967295 \
    --pool-kbytes 4294967295'
 sleep 5
 # Start eth-rpc in a detached tmux session
 tmux new-session -d -s eth-rpc \
  'RUST_LOG="info,eth-rpc=debug" eth-rpc \
    --dev \
    --node-rpc-url ws://127.0.0.1:9944 \
    --rpc-max-connections 4294967295'
 sleep 5
 # Run the tests (logs to files as before)
 RUST_LOG="info" retester test \
  --platform "$PLATFORM" \
  --corpus ./revive-differential-tests/fixtures/solidity \
  --working-directory ./workdir \
  --concurrency.number-of-nodes 1 \
  --concurrency.number-of-concurrent-tasks 5 \
  --revive-dev-node.existing-rpc-url "http://localhost:8545" \
  > logs.log
 ```
 </details>
@@ -33,9 +33,5 @@
    "mixhash": "0x0000000000000000000000000000000000000000000000000000000000000000",
    "parentHash": "0x0000000000000000000000000000000000000000000000000000000000000000",
    "timestamp": "0x00",
-    "alloc": {
+    "alloc": {}
        "90F8bf6A479f320ead074411a4B0e7944Ea8c9C1": {
            "balance": "1000000000000000000"
        }
    }
 }
@@ -1,13 +1,24 @@
 {
    "modes": [
        "Y >=0.8.9",
-        "E",
+        "E"
        "I"
    ],
    "cases": [
        {
            "name": "first",
            "inputs": [
                {
                    "address": "0xdeadbeef00000000000000000000000000000042",
                    "expected_balance": "1233"
                },
                {
                    "address": "0xdeadbeef00000000000000000000000000000042",
                    "is_storage_empty": true
                },
                {
                    "address": "0xdeadbeef00000000000000000000000000000042",
                    "is_storage_empty": false
                },
                {
                    "instance": "WBTC_1",
                    "method": "#deployer",
@@ -0,0 +1 @@
@@ -0,0 +1,25 @@
 [package]
 name = "revive-dt-common"
 description = "A library containing common concepts that other crates in the workspace can rely on"
 version.workspace = true
 authors.workspace = true
 license.workspace = true
 edition.workspace = true
 repository.workspace = true
 rust-version.workspace = true
 [dependencies]
 alloy = { workspace = true }
 anyhow = { workspace = true }
 clap = { workspace = true }
 moka = { workspace = true, features = ["sync"] }
 once_cell = { workspace = true }
 regex = { workspace = true }
 semver = { workspace = true }
 serde = { workspace = true }
 schemars = { workspace = true }
 strum = { workspace = true }
 tokio = { workspace = true, default-features = false, features = ["time"] }
 [lints]
 workspace = true
@@ -0,0 +1,49 @@
 //! This module implements a cached file system allowing for results to be stored in-memory rather
 //! rather being queried from the file system again.
 use std::fs;
 use std::io::{Error, Result};
 use std::path::{Path, PathBuf};
 use moka::sync::Cache;
 use once_cell::sync::Lazy;
 pub fn read(path: impl AsRef<Path>) -> Result<Vec<u8>> {
    static READ_CACHE: Lazy<Cache<PathBuf, Vec<u8>>> = Lazy::new(|| Cache::new(10_000));
    let path = path.as_ref().canonicalize()?;
    match READ_CACHE.get(path.as_path()) {
        Some(content) => Ok(content),
        None => {
            let content = fs::read(path.as_path())?;
            READ_CACHE.insert(path, content.clone());
            Ok(content)
        }
    }
 }
 pub fn read_to_string(path: impl AsRef<Path>) -> Result<String> {
    let content = read(path)?;
    String::from_utf8(content).map_err(|_| {
        Error::new(
            std::io::ErrorKind::InvalidData,
            "The contents of the file are not valid UTF8",
        )
    })
 }
 pub fn read_dir(path: impl AsRef<Path>) -> Result<Box<dyn Iterator<Item = Result<PathBuf>>>> {
    static READ_DIR_CACHE: Lazy<Cache<PathBuf, Vec<PathBuf>>> = Lazy::new(|| Cache::new(10_000));
    let path = path.as_ref().canonicalize()?;
    match READ_DIR_CACHE.get(path.as_path()) {
        Some(entries) => Ok(Box::new(entries.into_iter().map(Ok)) as Box<_>),
        None => {
            let entries = fs::read_dir(path.as_path())?
                .flat_map(|maybe_entry| maybe_entry.map(|entry| entry.path()))
                .collect();
            READ_DIR_CACHE.insert(path.clone(), entries);
            Ok(read_dir(path).unwrap())
        }
    }
 }
@@ -0,0 +1,31 @@
 use std::{
    fs::{read_dir, remove_dir_all, remove_file},
    path::Path,
 };
 use anyhow::{Context, Result};
 /// This method clears the passed directory of all of the files and directories contained within
 /// without deleting the directory.
 pub fn clear_directory(path: impl AsRef<Path>) -> Result<()> {
    for entry in read_dir(path.as_ref())
        .with_context(|| format!("Failed to read directory: {}", path.as_ref().display()))?
    {
        let entry = entry.with_context(|| {
            format!(
                "Failed to read an entry in directory: {}",
                path.as_ref().display()
            )
        })?;
        let entry_path = entry.path();
        if entry_path.is_file() {
            remove_file(&entry_path)
                .with_context(|| format!("Failed to remove file: {}", entry_path.display()))?
        } else {
            remove_dir_all(&entry_path)
                .with_context(|| format!("Failed to remove directory: {}", entry_path.display()))?
        }
    }
    Ok(())
 }
@@ -0,0 +1,3 @@
 mod clear_dir;
 pub use clear_dir::*;
@@ -0,0 +1,3 @@
 mod poll;
 pub use poll::*;
@@ -0,0 +1,72 @@
 use std::ops::ControlFlow;
 use std::time::Duration;
 use anyhow::{Context as _, Result, anyhow};
 const EXPONENTIAL_BACKOFF_MAX_WAIT_DURATION: Duration = Duration::from_secs(60);
 /// A function that polls for a fallible future for some period of time and errors if it fails to
 /// get a result after polling.
 ///
 /// Given a future that returns a [`Result<ControlFlow<O, ()>>`], this function calls the future
 /// repeatedly (with some wait period) until the future returns a [`ControlFlow::Break`] or until it
 /// returns an [`Err`] in which case the function stops polling and returns the error.
 ///
 /// If the future keeps returning [`ControlFlow::Continue`] and fails to return a [`Break`] within
 /// the permitted polling duration then this function returns an [`Err`]
 ///
 /// [`Break`]: ControlFlow::Break
 /// [`Continue`]: ControlFlow::Continue
 pub async fn poll<F, O>(
    polling_duration: Duration,
    polling_wait_behavior: PollingWaitBehavior,
    mut future: impl FnMut() -> F,
 ) -> Result<O>
 where
    F: Future<Output = Result<ControlFlow<O, ()>>>,
 {
    let mut retries = 0;
    let mut total_wait_duration = Duration::ZERO;
    let max_allowed_wait_duration = polling_duration;
    loop {
        if total_wait_duration >= max_allowed_wait_duration {
            break Err(anyhow!(
                "Polling failed after {} retries and a total of {:?} of wait time",
                retries,
                total_wait_duration
            ));
        }
        match future()
            .await
            .context("Polled future returned an error during polling loop")?
        {
            ControlFlow::Continue(()) => {
                let next_wait_duration = match polling_wait_behavior {
                    PollingWaitBehavior::Constant(duration) => duration,
                    PollingWaitBehavior::ExponentialBackoff => {
                        Duration::from_secs(2u64.pow(retries))
                            .min(EXPONENTIAL_BACKOFF_MAX_WAIT_DURATION)
                    }
                };
                let next_wait_duration =
                    next_wait_duration.min(max_allowed_wait_duration - total_wait_duration);
                total_wait_duration += next_wait_duration;
                retries += 1;
                tokio::time::sleep(next_wait_duration).await;
            }
            ControlFlow::Break(output) => {
                break Ok(output);
            }
        }
    }
 }
 #[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, Default)]
 pub enum PollingWaitBehavior {
    Constant(Duration),
    #[default]
    ExponentialBackoff,
 }
@@ -0,0 +1,21 @@
 /// An iterator that could be either of two iterators.
 #[derive(Clone, Debug)]
 pub enum EitherIter<A, B> {
    A(A),
    B(B),
 }
 impl<A, B, T> Iterator for EitherIter<A, B>
 where
    A: Iterator<Item = T>,
    B: Iterator<Item = T>,
 {
    type Item = T;
    fn next(&mut self) -> Option<Self::Item> {
        match self {
            EitherIter::A(iter) => iter.next(),
            EitherIter::B(iter) => iter.next(),
        }
    }
 }
@@ -1,4 +1,8 @@
-use std::{borrow::Cow, collections::HashSet, path::PathBuf};
+use std::{
    borrow::Cow,
    collections::HashSet,
    path::{Path, PathBuf},
 };
 /// An iterator that finds files of a certain extension in the provided directory. You can think of
 /// this a glob pattern similar to: `${path}/**/*.md`
@@ -15,14 +19,20 @@ pub struct FilesWithExtensionIterator {
    /// this vector then they will be returned when the [`Iterator::next`] method is called. If not
    /// then we visit one of the next directories to visit.
    files_matching_allowed_extensions: Vec<PathBuf>,
    /// This option controls if the the cached file system should be used or not. This could be
    /// better for certain cases where the entries in the directories do not change and therefore
    /// caching can be used.
    use_cached_fs: bool,
 }
 impl FilesWithExtensionIterator {
-    pub fn new(root_directory: PathBuf) -> Self {
+    pub fn new(root_directory: impl AsRef<Path>) -> Self {
        Self {
            allowed_extensions: Default::default(),
-            directories_to_search: vec![root_directory],
+            directories_to_search: vec![root_directory.as_ref().to_path_buf()],
            files_matching_allowed_extensions: Default::default(),
            use_cached_fs: Default::default(),
        }
    }
@@ -33,6 +43,11 @@ impl FilesWithExtensionIterator {
        self.allowed_extensions.insert(allowed_extension.into());
        self
    }
    pub fn with_use_cached_fs(mut self, use_cached_fs: bool) -> Self {
        self.use_cached_fs = use_cached_fs;
        self
    }
 }
 impl Iterator for FilesWithExtensionIterator {
@@ -45,16 +60,19 @@ impl Iterator for FilesWithExtensionIterator {
        let directory_to_search = self.directories_to_search.pop()?;
-        // Read all of the entries in the directory. If we failed to read this dir's entires then we
+        let iterator = if self.use_cached_fs {
-        // elect to just ignore it and look in the next directory, we do that by calling the next
+            let Ok(dir_entries) = crate::cached_fs::read_dir(directory_to_search.as_path()) else {
-        // method again on the iterator, which is an intentional decision that we made here instead
+                return self.next();
-        // of panicking.
+            };
-        let Ok(dir_entries) = std::fs::read_dir(directory_to_search) else {
+            Box::new(dir_entries) as Box<dyn Iterator<Item = std::io::Result<PathBuf>>>
-            return self.next();
+        } else {
            let Ok(dir_entries) = std::fs::read_dir(directory_to_search) else {
                return self.next();
            };
            Box::new(dir_entries.map(|maybe_entry| maybe_entry.map(|entry| entry.path()))) as Box<_>
        };
-        for entry in dir_entries.flatten() {
+        for entry_path in iterator.flatten() {
            let entry_path = entry.path();
            if entry_path.is_dir() {
                self.directories_to_search.push(entry_path)
            } else if entry_path.is_file()
@@ -0,0 +1,5 @@
 mod either_iter;
 mod files_with_extension_iterator;
 pub use either_iter::*;
 pub use files_with_extension_iterator::*;
@@ -0,0 +1,9 @@
 //! This crate provides common concepts, functionality, types, macros, and more that other crates in
 //! the workspace can benefit from.
 pub mod cached_fs;
 pub mod fs;
 pub mod futures;
 pub mod iterators;
 pub mod macros;
 pub mod types;
@@ -1,3 +1,25 @@
 #[macro_export]
 macro_rules! impl_for_wrapper {
    (Display, $ident: ident) => {
        #[automatically_derived]
        impl std::fmt::Display for $ident {
            fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
                std::fmt::Display::fmt(&self.0, f)
            }
        }
    };
    (FromStr, $ident: ident) => {
        #[automatically_derived]
        impl std::str::FromStr for $ident {
            type Err = anyhow::Error;
            fn from_str(s: &str) -> anyhow::Result<Self> {
                s.parse().map(Self).map_err(Into::into)
            }
        }
    };
 }
 /// Defines wrappers around types.
 ///
 /// For example, the macro invocation seen below:
@@ -12,11 +34,9 @@
 /// pub struct CaseId(usize);
 /// ```
 ///
-/// And would also implement a number of methods on this type making it easier
+/// And would also implement a number of methods on this type making it easier to use.
 /// to use.
 ///
-/// These wrapper types become very useful as they make the code a lot easier
+/// These wrapper types become very useful as they make the code a lot easier to read.
 /// to read.
 ///
 /// Take the following as an example:
 ///
@@ -26,33 +46,37 @@
 /// }
 /// ```
 ///
-/// In the above code it's hard to understand what the various types refer to or
+/// In the above code it's hard to understand what the various types refer to or what to expect them
-/// what to expect them to contain.
+/// to contain.
 ///
-/// With these wrapper types we're able to create code that's self-documenting
+/// With these wrapper types we're able to create code that's self-documenting in that the types
-/// in that the types tell us what the code is referring to. The above code is
+/// tell us what the code is referring to. The above code is transformed into
 /// transformed into
 ///
 /// ```rust,ignore
 /// struct State {
 ///     contracts: HashMap<CaseId, HashMap<ContractName, ContractByteCode>>
 /// }
 /// ```
 ///
 /// Note that we follow the same syntax for defining wrapper structs but we do not permit the use of
 /// generics.
 #[macro_export]
 macro_rules! define_wrapper_type {
    (
        $(#[$meta: meta])*
-        $ident: ident($ty: ty) $(;)?
+        $vis:vis struct $ident: ident($ty: ty)
        $(
            impl $($trait_ident: ident),*
        )?
        ;
    ) => {
        $(#[$meta])*
-        pub struct $ident($ty);
+        $vis struct $ident($ty);
        impl $ident {
-            pub fn new(value: $ty) -> Self {
+            pub fn new(value: impl Into<$ty>) -> Self {
                Self(value)
            }
            pub fn new_from<T: Into<$ty>>(value: T) -> Self {
                Self(value.into())
            }
@@ -102,5 +126,15 @@ macro_rules! define_wrapper_type {
                value.0
            }
        }
        $(
            $(
                $crate::macros::impl_for_wrapper!($trait_ident, $ident);
            )*
        )?
    };
 }
 /// Technically not needed but this allows for the macro to be found in the `macros` module of the
 /// crate in addition to being found in the root of the crate.
 pub use {define_wrapper_type, impl_for_wrapper};
@@ -0,0 +1,3 @@
 mod define_wrapper_type;
 pub use define_wrapper_type::*;
@@ -0,0 +1,134 @@
 use clap::ValueEnum;
 use schemars::JsonSchema;
 use serde::{Deserialize, Serialize};
 use strum::{AsRefStr, Display, EnumString, IntoStaticStr};
 /// An enum of the platform identifiers of all of the platforms supported by this framework. This
 /// could be thought of like the target triple from Rust and LLVM where it specifies the platform
 /// completely starting with the node, the vm, and finally the compiler used for this combination.
 #[derive(
    Clone,
    Copy,
    Debug,
    PartialEq,
    Eq,
    PartialOrd,
    Ord,
    Hash,
    Serialize,
    Deserialize,
    ValueEnum,
    EnumString,
    Display,
    AsRefStr,
    IntoStaticStr,
    JsonSchema,
 )]
 #[serde(rename_all = "kebab-case")]
 #[strum(serialize_all = "kebab-case")]
 pub enum PlatformIdentifier {
    /// The Go-ethereum reference full node EVM implementation with the solc compiler.
    GethEvmSolc,
    /// The Lighthouse Go-ethereum reference full node EVM implementation with the solc compiler.
    LighthouseGethEvmSolc,
    /// The kitchensink node with the PolkaVM backend with the resolc compiler.
    KitchensinkPolkavmResolc,
    /// The kitchensink node with the REVM backend with the solc compiler.
    KitchensinkRevmSolc,
    /// The revive dev node with the PolkaVM backend with the resolc compiler.
    ReviveDevNodePolkavmResolc,
    /// The revive dev node with the REVM backend with the solc compiler.
    ReviveDevNodeRevmSolc,
    /// A zombienet based Substrate/Polkadot node with the PolkaVM backend with the resolc compiler.
    ZombienetPolkavmResolc,
    /// A zombienet based Substrate/Polkadot node with the REVM backend with the solc compiler.
    ZombienetRevmSolc,
 }
 /// An enum of the platform identifiers of all of the platforms supported by this framework.
 #[derive(
    Clone,
    Copy,
    Debug,
    PartialEq,
    Eq,
    PartialOrd,
    Ord,
    Hash,
    Serialize,
    Deserialize,
    ValueEnum,
    EnumString,
    Display,
    AsRefStr,
    IntoStaticStr,
    JsonSchema,
 )]
 pub enum CompilerIdentifier {
    /// The solc compiler.
    Solc,
    /// The resolc compiler.
    Resolc,
 }
 /// An enum representing the identifiers of the supported nodes.
 #[derive(
    Clone,
    Copy,
    Debug,
    PartialEq,
    Eq,
    PartialOrd,
    Ord,
    Hash,
    Serialize,
    Deserialize,
    ValueEnum,
    EnumString,
    Display,
    AsRefStr,
    IntoStaticStr,
    JsonSchema,
 )]
 pub enum NodeIdentifier {
    /// The go-ethereum node implementation.
    Geth,
    /// The go-ethereum node implementation.
    LighthouseGeth,
    /// The Kitchensink node implementation.
    Kitchensink,
    /// The revive dev node implementation.
    ReviveDevNode,
    /// A zombienet spawned nodes
    Zombienet,
 }
 /// An enum representing the identifiers of the supported VMs.
 #[derive(
    Clone,
    Copy,
    Debug,
    PartialEq,
    Eq,
    PartialOrd,
    Ord,
    Hash,
    Serialize,
    Deserialize,
    ValueEnum,
    EnumString,
    Display,
    AsRefStr,
    IntoStaticStr,
    JsonSchema,
 )]
 #[serde(rename_all = "lowercase")]
 #[strum(serialize_all = "lowercase")]
 pub enum VmIdentifier {
    /// The ethereum virtual machine.
    Evm,
    /// The EraVM virtual machine.
    EraVM,
    /// Polkadot's PolaVM Risc-v based virtual machine.
    PolkaVM,
 }
@@ -0,0 +1,13 @@
 mod identifiers;
 mod mode;
 mod parsed_test_specifier;
 mod private_key_allocator;
 mod round_robin_pool;
 mod version_or_requirement;
 pub use identifiers::*;
 pub use mode::*;
 pub use parsed_test_specifier::*;
 pub use private_key_allocator::*;
 pub use round_robin_pool::*;
 pub use version_or_requirement::*;
@@ -0,0 +1,438 @@
 use crate::iterators::EitherIter;
 use crate::types::VersionOrRequirement;
 use anyhow::{Context as _, bail};
 use regex::Regex;
 use schemars::JsonSchema;
 use semver::Version;
 use serde::{Deserialize, Serialize};
 use std::collections::HashSet;
 use std::fmt::Display;
 use std::str::FromStr;
 use std::sync::LazyLock;
 /// This represents a mode that a given test should be run with, if possible.
 ///
 /// We obtain this by taking a [`ParsedMode`], which may be looser or more strict
 /// in its requirements, and then expanding it out into a list of [`Mode`]s.
 ///
 /// Use [`ParsedMode::to_test_modes()`] to do this.
 #[derive(Clone, Debug, PartialEq, Eq, Hash, Serialize, Deserialize)]
 pub struct Mode {
    pub pipeline: ModePipeline,
    pub optimize_setting: ModeOptimizerSetting,
    pub version: Option<semver::VersionReq>,
 }
 impl Display for Mode {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        self.pipeline.fmt(f)?;
        f.write_str(" ")?;
        self.optimize_setting.fmt(f)?;
        if let Some(version) = &self.version {
            f.write_str(" ")?;
            version.fmt(f)?;
        }
        Ok(())
    }
 }
 impl FromStr for Mode {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
        let parsed_mode = ParsedMode::from_str(s)?;
        let mut iter = parsed_mode.to_modes();
        let (Some(mode), None) = (iter.next(), iter.next()) else {
            bail!("Failed to parse the mode")
        };
        Ok(mode)
    }
 }
 impl Mode {
    /// Return all of the available mode combinations.
    pub fn all() -> impl Iterator<Item = &'static Mode> {
        static ALL_MODES: LazyLock<Vec<Mode>> = LazyLock::new(|| {
            ModePipeline::test_cases()
                .flat_map(|pipeline| {
                    ModeOptimizerSetting::test_cases().map(move |optimize_setting| Mode {
                        pipeline,
                        optimize_setting,
                        version: None,
                    })
                })
                .collect::<Vec<_>>()
        });
        ALL_MODES.iter()
    }
    /// Resolves the [`Mode`]'s solidity version requirement into a [`VersionOrRequirement`] if
    /// the requirement is present on the object. Otherwise, the passed default version is used.
    pub fn compiler_version_to_use(&self, default: Version) -> VersionOrRequirement {
        match self.version {
            Some(ref requirement) => requirement.clone().into(),
            None => default.into(),
        }
    }
 }
 /// What do we want the compiler to do?
 #[derive(Clone, Copy, Debug, Eq, PartialEq, Ord, PartialOrd, Hash, Serialize, Deserialize)]
 pub enum ModePipeline {
    /// Compile Solidity code via Yul IR
    ViaYulIR,
    /// Compile Solidity direct to assembly
    ViaEVMAssembly,
 }
 impl FromStr for ModePipeline {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
        match s {
            // via Yul IR
            "Y" => Ok(ModePipeline::ViaYulIR),
            // Don't go via Yul IR
            "E" => Ok(ModePipeline::ViaEVMAssembly),
            // Anything else that we see isn't a mode at all
            _ => Err(anyhow::anyhow!(
                "Unsupported pipeline '{s}': expected 'Y' or 'E'"
            )),
        }
    }
 }
 impl Display for ModePipeline {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        match self {
            ModePipeline::ViaYulIR => f.write_str("Y"),
            ModePipeline::ViaEVMAssembly => f.write_str("E"),
        }
    }
 }
 impl ModePipeline {
    /// Should we go via Yul IR?
    pub fn via_yul_ir(&self) -> bool {
        matches!(self, ModePipeline::ViaYulIR)
    }
    /// An iterator over the available pipelines that we'd like to test,
    /// when an explicit pipeline was not specified.
    pub fn test_cases() -> impl Iterator<Item = ModePipeline> + Clone {
        [ModePipeline::ViaYulIR, ModePipeline::ViaEVMAssembly].into_iter()
    }
 }
 #[derive(Clone, Copy, Debug, Eq, PartialEq, Ord, PartialOrd, Hash, Serialize, Deserialize)]
 pub enum ModeOptimizerSetting {
    /// 0 / -: Don't apply any optimizations
    M0,
    /// 1: Apply less than default optimizations
    M1,
    /// 2: Apply the default optimizations
    M2,
    /// 3 / +: Apply aggressive optimizations
    M3,
    /// s: Optimize for size
    Ms,
    /// z: Aggressively optimize for size
    Mz,
 }
 impl FromStr for ModeOptimizerSetting {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
        match s {
            "M0" => Ok(ModeOptimizerSetting::M0),
            "M1" => Ok(ModeOptimizerSetting::M1),
            "M2" => Ok(ModeOptimizerSetting::M2),
            "M3" => Ok(ModeOptimizerSetting::M3),
            "Ms" => Ok(ModeOptimizerSetting::Ms),
            "Mz" => Ok(ModeOptimizerSetting::Mz),
            _ => Err(anyhow::anyhow!(
                "Unsupported optimizer setting '{s}': expected 'M0', 'M1', 'M2', 'M3', 'Ms' or 'Mz'"
            )),
        }
    }
 }
 impl Display for ModeOptimizerSetting {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        match self {
            ModeOptimizerSetting::M0 => f.write_str("M0"),
            ModeOptimizerSetting::M1 => f.write_str("M1"),
            ModeOptimizerSetting::M2 => f.write_str("M2"),
            ModeOptimizerSetting::M3 => f.write_str("M3"),
            ModeOptimizerSetting::Ms => f.write_str("Ms"),
            ModeOptimizerSetting::Mz => f.write_str("Mz"),
        }
    }
 }
 impl ModeOptimizerSetting {
    /// An iterator over the available optimizer settings that we'd like to test,
    /// when an explicit optimizer setting was not specified.
    pub fn test_cases() -> impl Iterator<Item = ModeOptimizerSetting> + Clone {
        [
            // No optimizations:
            ModeOptimizerSetting::M0,
            // Aggressive optimizations:
            ModeOptimizerSetting::M3,
        ]
        .into_iter()
    }
    /// Are any optimizations enabled?
    pub fn optimizations_enabled(&self) -> bool {
        !matches!(self, ModeOptimizerSetting::M0)
    }
 }
 /// This represents a mode that has been parsed from test metadata.
 ///
 /// Mode strings can take the following form (in pseudo-regex):
 ///
 /// ```text
 /// [YEILV][+-]? (M[0123sz])? <semver>?
 /// ```
 ///
 /// We can parse valid mode strings into [`ParsedMode`] using [`ParsedMode::from_str`].
 #[derive(Clone, Debug, PartialEq, Eq, Hash, Deserialize, Serialize, JsonSchema)]
 #[serde(try_from = "String", into = "String")]
 pub struct ParsedMode {
    pub pipeline: Option<ModePipeline>,
    pub optimize_flag: Option<bool>,
    pub optimize_setting: Option<ModeOptimizerSetting>,
    pub version: Option<semver::VersionReq>,
 }
 impl FromStr for ParsedMode {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
        static REGEX: LazyLock<Regex> = LazyLock::new(|| {
            Regex::new(r"(?x)
                ^
                (?:(?P<pipeline>[YEILV])(?P<optimize_flag>[+-])?)? # Pipeline to use eg Y, E+, E-
                \s*
                (?P<optimize_setting>M[a-zA-Z0-9])?                # Optimize setting eg M0, Ms, Mz
                \s*
                (?P<version>[>=<^]*\d+(?:\.\d+)*)?                  # Optional semver version eg >=0.8.0, 0.7, <0.8
                $
            ").unwrap()
        });
        let Some(caps) = REGEX.captures(s) else {
            anyhow::bail!("Cannot parse mode '{s}' from string");
        };
        let pipeline = match caps.name("pipeline") {
            Some(m) => Some(
                ModePipeline::from_str(m.as_str())
                    .context("Failed to parse mode pipeline from string")?,
            ),
            None => None,
        };
        let optimize_flag = caps.name("optimize_flag").map(|m| m.as_str() == "+");
        let optimize_setting = match caps.name("optimize_setting") {
            Some(m) => Some(
                ModeOptimizerSetting::from_str(m.as_str())
                    .context("Failed to parse optimizer setting from string")?,
            ),
            None => None,
        };
        let version = match caps.name("version") {
            Some(m) => Some(
                semver::VersionReq::parse(m.as_str())
                    .map_err(|e| {
                        anyhow::anyhow!(
                            "Cannot parse the version requirement '{}': {e}",
                            m.as_str()
                        )
                    })
                    .context("Failed to parse semver requirement from mode string")?,
            ),
            None => None,
        };
        Ok(ParsedMode {
            pipeline,
            optimize_flag,
            optimize_setting,
            version,
        })
    }
 }
 impl Display for ParsedMode {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        let mut has_written = false;
        if let Some(pipeline) = self.pipeline {
            pipeline.fmt(f)?;
            if let Some(optimize_flag) = self.optimize_flag {
                f.write_str(if optimize_flag { "+" } else { "-" })?;
            }
            has_written = true;
        }
        if let Some(optimize_setting) = self.optimize_setting {
            if has_written {
                f.write_str(" ")?;
            }
            optimize_setting.fmt(f)?;
            has_written = true;
        }
        if let Some(version) = &self.version {
            if has_written {
                f.write_str(" ")?;
            }
            version.fmt(f)?;
        }
        Ok(())
    }
 }
 impl From<ParsedMode> for String {
    fn from(parsed_mode: ParsedMode) -> Self {
        parsed_mode.to_string()
    }
 }
 impl TryFrom<String> for ParsedMode {
    type Error = anyhow::Error;
    fn try_from(value: String) -> Result<Self, Self::Error> {
        ParsedMode::from_str(&value)
    }
 }
 impl ParsedMode {
    /// This takes a [`ParsedMode`] and expands it into a list of [`Mode`]s that we should try.
    pub fn to_modes(&self) -> impl Iterator<Item = Mode> {
        let pipeline_iter = self.pipeline.as_ref().map_or_else(
            || EitherIter::A(ModePipeline::test_cases()),
            |p| EitherIter::B(std::iter::once(*p)),
        );
        let optimize_flag_setting = self.optimize_flag.map(|flag| {
            if flag {
                ModeOptimizerSetting::M3
            } else {
                ModeOptimizerSetting::M0
            }
        });
        let optimize_flag_iter = match optimize_flag_setting {
            Some(setting) => EitherIter::A(std::iter::once(setting)),
            None => EitherIter::B(ModeOptimizerSetting::test_cases()),
        };
        let optimize_settings_iter = self.optimize_setting.as_ref().map_or_else(
            || EitherIter::A(optimize_flag_iter),
            |s| EitherIter::B(std::iter::once(*s)),
        );
        pipeline_iter.flat_map(move |pipeline| {
            optimize_settings_iter
                .clone()
                .map(move |optimize_setting| Mode {
                    pipeline,
                    optimize_setting,
                    version: self.version.clone(),
                })
        })
    }
    /// Return a set of [`Mode`]s that correspond to the given [`ParsedMode`]s.
    /// This avoids any duplicate entries.
    pub fn many_to_modes<'a>(
        parsed: impl Iterator<Item = &'a ParsedMode>,
    ) -> impl Iterator<Item = Mode> {
        let modes: HashSet<_> = parsed.flat_map(|p| p.to_modes()).collect();
        modes.into_iter()
    }
 }
 #[cfg(test)]
 mod tests {
    use super::*;
    #[test]
    fn test_parsed_mode_from_str() {
        let strings = vec![
            ("Mz", "Mz"),
            ("Y", "Y"),
            ("Y+", "Y+"),
            ("Y-", "Y-"),
            ("E", "E"),
            ("E+", "E+"),
            ("E-", "E-"),
            ("Y M0", "Y M0"),
            ("Y M1", "Y M1"),
            ("Y M2", "Y M2"),
            ("Y M3", "Y M3"),
            ("Y Ms", "Y Ms"),
            ("Y Mz", "Y Mz"),
            ("E M0", "E M0"),
            ("E M1", "E M1"),
            ("E M2", "E M2"),
            ("E M3", "E M3"),
            ("E Ms", "E Ms"),
            ("E Mz", "E Mz"),
            // When stringifying semver again, 0.8.0 becomes ^0.8.0 (same meaning)
            ("Y 0.8.0", "Y ^0.8.0"),
            ("E+ 0.8.0", "E+ ^0.8.0"),
            ("Y M3 >=0.8.0", "Y M3 >=0.8.0"),
            ("E Mz <0.7.0", "E Mz <0.7.0"),
            // We can parse +- _and_ M1/M2 but the latter takes priority.
            ("Y+ M1 0.8.0", "Y+ M1 ^0.8.0"),
            ("E- M2 0.7.0", "E- M2 ^0.7.0"),
            // We don't see this in the wild but it is parsed.
            ("<=0.8", "<=0.8"),
        ];
        for (actual, expected) in strings {
            let parsed = ParsedMode::from_str(actual)
                .unwrap_or_else(|_| panic!("Failed to parse mode string '{actual}'"));
            assert_eq!(
                expected,
                parsed.to_string(),
                "Mode string '{actual}' did not parse to '{expected}': got '{parsed}'"
            );
        }
    }
    #[test]
    fn test_parsed_mode_to_test_modes() {
        let strings = vec![
            ("Mz", vec!["Y Mz", "E Mz"]),
            ("Y", vec!["Y M0", "Y M3"]),
            ("E", vec!["E M0", "E M3"]),
            ("Y+", vec!["Y M3"]),
            ("Y-", vec!["Y M0"]),
            ("Y <=0.8", vec!["Y M0 <=0.8", "Y M3 <=0.8"]),
            (
                "<=0.8",
                vec!["Y M0 <=0.8", "Y M3 <=0.8", "E M0 <=0.8", "E M3 <=0.8"],
            ),
        ];
        for (actual, expected) in strings {
            let parsed = ParsedMode::from_str(actual)
                .unwrap_or_else(|_| panic!("Failed to parse mode string '{actual}'"));
            let expected_set: HashSet<_> = expected.into_iter().map(|s| s.to_owned()).collect();
            let actual_set: HashSet<_> = parsed.to_modes().map(|m| m.to_string()).collect();
            assert_eq!(
                expected_set, actual_set,
                "Mode string '{actual}' did not expand to '{expected_set:?}': got '{actual_set:?}'"
            );
        }
    }
 }
@@ -0,0 +1,133 @@
 use std::{fmt::Display, path::PathBuf, str::FromStr};
 use anyhow::{Context as _, bail};
 use crate::types::Mode;
 #[derive(Clone, Debug, PartialEq, Eq, Hash)]
 pub enum ParsedTestSpecifier {
    /// All of the test cases in the file should be ran across all of the specified modes
    FileOrDirectory {
        /// The path of the metadata file containing the test cases.
        metadata_or_directory_file_path: PathBuf,
    },
    /// Only a specific case within the metadata file should be ran across all of the modes in the
    /// file.
    Case {
        /// The path of the metadata file containing the test cases.
        metadata_file_path: PathBuf,
        /// The index of the specific case to run.
        case_idx: usize,
    },
    /// A specific case and a specific mode should be ran. This is the most specific out of all of
    /// the specifier types.
    CaseWithMode {
        /// The path of the metadata file containing the test cases.
        metadata_file_path: PathBuf,
        /// The index of the specific case to run.
        case_idx: usize,
        /// The parsed mode that the test should be run in.
        mode: Mode,
    },
 }
 impl Display for ParsedTestSpecifier {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        match self {
            ParsedTestSpecifier::FileOrDirectory {
                metadata_or_directory_file_path,
            } => {
                write!(f, "{}", metadata_or_directory_file_path.display())
            }
            ParsedTestSpecifier::Case {
                metadata_file_path,
                case_idx,
            } => {
                write!(f, "{}::{}", metadata_file_path.display(), case_idx)
            }
            ParsedTestSpecifier::CaseWithMode {
                metadata_file_path,
                case_idx,
                mode,
            } => {
                write!(
                    f,
                    "{}::{}::{}",
                    metadata_file_path.display(),
                    case_idx,
                    mode
                )
            }
        }
    }
 }
 impl FromStr for ParsedTestSpecifier {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
        let mut split_iter = s.split("::");
        let Some(path_string) = split_iter.next() else {
            bail!("Could not find the path in the test specifier")
        };
        let path = PathBuf::from(path_string)
            .canonicalize()
            .context("Failed to canonicalize the path of the test")?;
        let Some(case_idx_string) = split_iter.next() else {
            return Ok(Self::FileOrDirectory {
                metadata_or_directory_file_path: path,
            });
        };
        let case_idx = usize::from_str(case_idx_string)
            .context("Failed to parse the case idx of the test specifier from string")?;
        // At this point the provided path must be a file.
        if !path.is_file() {
            bail!(
                "Test specifier with a path and case idx must point to a file and not a directory"
            )
        }
        let Some(mode_string) = split_iter.next() else {
            return Ok(Self::Case {
                metadata_file_path: path,
                case_idx,
            });
        };
        let mode = Mode::from_str(mode_string)
            .context("Failed to parse the mode string in the parsed test specifier")?;
        Ok(Self::CaseWithMode {
            metadata_file_path: path,
            case_idx,
            mode,
        })
    }
 }
 impl From<ParsedTestSpecifier> for String {
    fn from(value: ParsedTestSpecifier) -> Self {
        value.to_string()
    }
 }
 impl TryFrom<String> for ParsedTestSpecifier {
    type Error = anyhow::Error;
    fn try_from(value: String) -> Result<Self, Self::Error> {
        value.parse()
    }
 }
 impl TryFrom<&str> for ParsedTestSpecifier {
    type Error = anyhow::Error;
    fn try_from(value: &str) -> Result<Self, Self::Error> {
        value.parse()
    }
 }
@@ -0,0 +1,36 @@
 use alloy::primitives::U256;
 use alloy::signers::local::PrivateKeySigner;
 use anyhow::{Context, Result, bail};
 /// This is a sequential private key allocator. When instantiated, it allocated private keys in
 /// sequentially and in order until the maximum private key specified is reached.
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
 pub struct PrivateKeyAllocator {
    /// The next private key to be returned by the allocator when requested.
    next_private_key: U256,
    /// The highest private key (exclusive) that can be returned by this allocator.
    highest_private_key_inclusive: U256,
 }
 impl PrivateKeyAllocator {
    /// Creates a new instance of the private key allocator.
    pub fn new(highest_private_key_inclusive: U256) -> Self {
        Self {
            next_private_key: U256::ONE,
            highest_private_key_inclusive,
        }
    }
    /// Allocates a new private key and errors out if the maximum private key has been reached.
    pub fn allocate(&mut self) -> Result<PrivateKeySigner> {
        if self.next_private_key > self.highest_private_key_inclusive {
            bail!("Attempted to allocate a private key but failed since all have been allocated");
        };
        let private_key =
            PrivateKeySigner::from_slice(self.next_private_key.to_be_bytes::<32>().as_slice())
                .context("Failed to convert the private key digits into a private key")?;
        self.next_private_key += U256::ONE;
        Ok(private_key)
    }
 }
@@ -0,0 +1,24 @@
 use std::sync::atomic::{AtomicUsize, Ordering};
 pub struct RoundRobinPool<T> {
    next_index: AtomicUsize,
    items: Vec<T>,
 }
 impl<T> RoundRobinPool<T> {
    pub fn new(items: Vec<T>) -> Self {
        Self {
            next_index: Default::default(),
            items,
        }
    }
    pub fn round_robin(&self) -> &T {
        let current = self.next_index.fetch_add(1, Ordering::SeqCst) % self.items.len();
        self.items.get(current).unwrap()
    }
    pub fn iter(&self) -> impl Iterator<Item = &T> {
        self.items.iter()
    }
 }
@@ -0,0 +1,41 @@
 use semver::{Version, VersionReq};
 #[derive(Clone, Debug)]
 pub enum VersionOrRequirement {
    Version(Version),
    Requirement(VersionReq),
 }
 impl From<Version> for VersionOrRequirement {
    fn from(value: Version) -> Self {
        Self::Version(value)
    }
 }
 impl From<VersionReq> for VersionOrRequirement {
    fn from(value: VersionReq) -> Self {
        Self::Requirement(value)
    }
 }
 impl TryFrom<VersionOrRequirement> for Version {
    type Error = anyhow::Error;
    fn try_from(value: VersionOrRequirement) -> Result<Self, Self::Error> {
        let VersionOrRequirement::Version(version) = value else {
            anyhow::bail!("Version or requirement was not a version");
        };
        Ok(version)
    }
 }
 impl TryFrom<VersionOrRequirement> for VersionReq {
    type Error = anyhow::Error;
    fn try_from(value: VersionOrRequirement) -> Result<Self, Self::Error> {
        let VersionOrRequirement::Requirement(requirement) = value else {
            anyhow::bail!("Version or requirement was not a requirement");
        };
        Ok(requirement)
    }
 }
@@ -9,11 +9,21 @@ repository.workspace = true
 rust-version.workspace = true
 [dependencies]
 anyhow = { workspace = true }
 revive-solc-json-interface = { workspace = true }
 revive-dt-common = { workspace = true }
 revive-dt-config = { workspace = true }
 revive-dt-solc-binaries = { workspace = true }
 revive-common = { workspace = true }
 alloy = { workspace = true }
 anyhow = { workspace = true }
 dashmap = { workspace = true }
 foundry-compilers-artifacts = { workspace = true }
 semver = { workspace = true }
 serde = { workspace = true }
 serde_json = { workspace = true }
 tracing = { workspace = true }
 tokio = { workspace = true }
 [lints]
 workspace = true
@@ -4,20 +4,23 @@
 //! - Polkadot revive Wasm compiler
 use std::{
-    fs::read_to_string,
+    collections::HashMap,
    hash::Hash,
    path::{Path, PathBuf},
    pin::Pin,
 };
-use revive_dt_config::Arguments;
+use alloy::json_abi::JsonAbi;
 use alloy::primitives::Address;
 use anyhow::{Context as _, Result};
 use semver::Version;
 use serde::{Deserialize, Serialize};
 use revive_common::EVMVersion;
-use revive_solc_json_interface::{
+use revive_dt_common::cached_fs::read_to_string;
-    SolcStandardJsonInput, SolcStandardJsonInputLanguage, SolcStandardJsonInputSettings,
+
-    SolcStandardJsonInputSettingsOptimizer, SolcStandardJsonInputSettingsSelection,
+// Re-export this as it's a part of the compiler interface.
-    SolcStandardJsonOutput,
+pub use revive_dt_common::types::{Mode, ModeOptimizerSetting, ModePipeline};
 };
 use semver::Version;
 pub mod revive_js;
 pub mod revive_resolc;
@@ -25,150 +28,149 @@ pub mod solc;
 /// A common interface for all supported Solidity compilers.
 pub trait SolidityCompiler {
-    /// Extra options specific to the compiler.
+    /// Returns the version of the compiler.
-    type Options: Default + PartialEq + Eq + Hash;
+    fn version(&self) -> &Version;
    /// Returns the path of the compiler executable.
    fn path(&self) -> &Path;
    /// The low-level compiler interface.
    fn build(
        &self,
-        input: CompilerInput<Self::Options>,
+        input: CompilerInput,
-    ) -> anyhow::Result<CompilerOutput<Self::Options>>;
+    ) -> Pin<Box<dyn Future<Output = Result<CompilerOutput>> + '_>>;
-    fn new(solc_executable: PathBuf) -> Self;
+    /// Does the compiler support the provided mode and version settings.
-
+    fn supports_mode(
-    fn get_compiler_executable(config: &Arguments, version: Version) -> anyhow::Result<PathBuf>;
+        &self,
        optimizer_setting: ModeOptimizerSetting,
        pipeline: ModePipeline,
    ) -> bool;
 }
 /// The generic compilation input configuration.
-#[derive(Debug)]
+#[derive(Clone, Debug, Default, Serialize, Deserialize)]
-pub struct CompilerInput<T: PartialEq + Eq + Hash> {
+pub struct CompilerInput {
-    pub extra_options: T,
+    pub pipeline: Option<ModePipeline>,
-    pub input: SolcStandardJsonInput,
+    pub optimization: Option<ModeOptimizerSetting>,
    pub evm_version: Option<EVMVersion>,
    pub allow_paths: Vec<PathBuf>,
    pub base_path: Option<PathBuf>,
    pub sources: HashMap<PathBuf, String>,
    pub libraries: HashMap<PathBuf, HashMap<String, Address>>,
    pub revert_string_handling: Option<RevertString>,
 }
 /// The generic compilation output configuration.
-#[derive(Debug)]
+#[derive(Debug, Clone, Default, Serialize, Deserialize)]
-pub struct CompilerOutput<T: PartialEq + Eq + Hash> {
+pub struct CompilerOutput {
-    /// The solc standard JSON input.
+    /// The compiled contracts. The bytecode of the contract is kept as a string in case linking is
-    pub input: CompilerInput<T>,
+    /// required and the compiled source has placeholders.
-    /// The produced solc standard JSON output.
+    pub contracts: HashMap<PathBuf, HashMap<String, (String, JsonAbi)>>,
    pub output: SolcStandardJsonOutput,
    /// The error message in case the compiler returns abnormally.
    pub error: Option<String>,
 }
-impl<T> PartialEq for CompilerInput<T>
+/// A generic builder style interface for configuring the supported compiler options.
-where
+#[derive(Default)]
-    T: PartialEq + Eq + Hash,
+pub struct Compiler {
-{
+    input: CompilerInput,
    fn eq(&self, other: &Self) -> bool {
        let self_input = serde_json::to_vec(&self.input).unwrap_or_default();
        let other_input = serde_json::to_vec(&self.input).unwrap_or_default();
        self.extra_options.eq(&other.extra_options) && self_input == other_input
    }
 }
-impl<T> Eq for CompilerInput<T> where T: PartialEq + Eq + Hash {}
+impl Compiler {
 impl<T> Hash for CompilerInput<T>
 where
    T: PartialEq + Eq + Hash,
 {
    fn hash<H: std::hash::Hasher>(&self, state: &mut H) {
        self.extra_options.hash(state);
        state.write(&serde_json::to_vec(&self.input).unwrap_or_default());
    }
 }
 /// A generic builder style interface for configuring all compiler options.
 pub struct Compiler<T: SolidityCompiler> {
    input: SolcStandardJsonInput,
    extra_options: T::Options,
    allow_paths: Vec<PathBuf>,
    base_path: Option<PathBuf>,
 }
 impl Default for Compiler<solc::Solc> {
    fn default() -> Self {
        Self::new()
    }
 }
 impl<T> Compiler<T>
 where
    T: SolidityCompiler,
 {
    pub fn new() -> Self {
        Self {
-            input: SolcStandardJsonInput {
+            input: CompilerInput {
-                language: SolcStandardJsonInputLanguage::Solidity,
+                pipeline: Default::default(),
                optimization: Default::default(),
                evm_version: Default::default(),
                allow_paths: Default::default(),
                base_path: Default::default(),
                sources: Default::default(),
-                settings: SolcStandardJsonInputSettings::new(
+                libraries: Default::default(),
-                    None,
+                revert_string_handling: Default::default(),
                    Default::default(),
                    None,
                    SolcStandardJsonInputSettingsSelection::new_required(),
                    SolcStandardJsonInputSettingsOptimizer::new(
                        false,
                        None,
                        &Version::new(0, 0, 0),
                        false,
                    ),
                    None,
                    None,
                ),
            },
            extra_options: Default::default(),
            allow_paths: Default::default(),
            base_path: None,
        }
    }
-    pub fn solc_optimizer(mut self, enabled: bool) -> Self {
+    pub fn with_optimization(mut self, value: impl Into<Option<ModeOptimizerSetting>>) -> Self {
-        self.input.settings.optimizer.enabled = enabled;
+        self.input.optimization = value.into();
        self
    }
-    pub fn with_source(mut self, path: &Path) -> anyhow::Result<Self> {
+    pub fn with_pipeline(mut self, value: impl Into<Option<ModePipeline>>) -> Self {
-        self.input
+        self.input.pipeline = value.into();
-            .sources
+        self
-            .insert(path.display().to_string(), read_to_string(path)?.into());
+    }
    pub fn with_evm_version(mut self, version: impl Into<Option<EVMVersion>>) -> Self {
        self.input.evm_version = version.into();
        self
    }
    pub fn with_allow_path(mut self, path: impl AsRef<Path>) -> Self {
        self.input.allow_paths.push(path.as_ref().into());
        self
    }
    pub fn with_base_path(mut self, path: impl Into<Option<PathBuf>>) -> Self {
        self.input.base_path = path.into();
        self
    }
    pub fn with_source(mut self, path: impl AsRef<Path>) -> Result<Self> {
        self.input.sources.insert(
            path.as_ref().to_path_buf(),
            read_to_string(path.as_ref()).context("Failed to read the contract source")?,
        );
        Ok(self)
    }
-    pub fn evm_version(mut self, evm_version: EVMVersion) -> Self {
+    pub fn with_library(
-        self.input.settings.evm_version = Some(evm_version);
+        mut self,
        path: impl AsRef<Path>,
        name: impl AsRef<str>,
        address: Address,
    ) -> Self {
        self.input
            .libraries
            .entry(path.as_ref().to_path_buf())
            .or_default()
            .insert(name.as_ref().into(), address);
        self
    }
-    pub fn extra_options(mut self, extra_options: T::Options) -> Self {
+    pub fn with_revert_string_handling(
-        self.extra_options = extra_options;
+        mut self,
        revert_string_handling: impl Into<Option<RevertString>>,
    ) -> Self {
        self.input.revert_string_handling = revert_string_handling.into();
        self
    }
-    pub fn allow_path(mut self, path: PathBuf) -> Self {
+    pub fn then(self, callback: impl FnOnce(Self) -> Self) -> Self {
-        self.allow_paths.push(path);
+        callback(self)
        self
    }
-    pub fn base_path(mut self, base_path: PathBuf) -> Self {
+    pub fn try_then<E>(self, callback: impl FnOnce(Self) -> Result<Self, E>) -> Result<Self, E> {
-        self.base_path = Some(base_path);
+        callback(self)
        self
    }
-    pub fn try_build(self, solc_path: PathBuf) -> anyhow::Result<CompilerOutput<T::Options>> {
+    pub async fn try_build(self, compiler: &dyn SolidityCompiler) -> Result<CompilerOutput> {
-        T::new(solc_path).build(CompilerInput {
+        compiler.build(self.input).await
            extra_options: self.extra_options,
            input: self.input,
            allow_paths: self.allow_paths,
            base_path: self.base_path,
        })
    }
-    /// Returns the compiler JSON input.
+    pub fn input(&self) -> &CompilerInput {
-    pub fn input(&self) -> SolcStandardJsonInput {
+        &self.input
        self.input.clone()
    }
 }
 /// Defines how the compiler should handle revert strings.
 #[derive(
    Clone, Debug, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, Default, Serialize, Deserialize,
 )]
 pub enum RevertString {
    #[default]
    Default,
    Debug,
    Strip,
    VerboseDebug,
 }
@@ -3,152 +3,309 @@
 use std::{
    path::PathBuf,
-    process::{Command, Stdio},
+    pin::Pin,
    process::Stdio,
    sync::{Arc, LazyLock},
 };
-use crate::{CompilerInput, CompilerOutput, SolidityCompiler};
+use dashmap::DashMap;
-use revive_dt_config::Arguments;
+use revive_dt_common::types::VersionOrRequirement;
-use revive_solc_json_interface::SolcStandardJsonOutput;
+use revive_dt_config::{ResolcConfiguration, SolcConfiguration, WorkingDirectoryConfiguration};
 use revive_solc_json_interface::{
    SolcStandardJsonInput, SolcStandardJsonInputLanguage, SolcStandardJsonInputSettings,
    SolcStandardJsonInputSettingsOptimizer, SolcStandardJsonInputSettingsSelection,
    SolcStandardJsonOutput,
 };
 use tracing::{Span, field::display};
 use crate::{
    CompilerInput, CompilerOutput, ModeOptimizerSetting, ModePipeline, SolidityCompiler, solc::Solc,
 };
 use alloy::json_abi::JsonAbi;
 use anyhow::{Context as _, Result};
 use semver::Version;
 use tokio::{io::AsyncWriteExt, process::Command as AsyncCommand};
 /// A wrapper around the `resolc` binary, emitting PVM-compatible bytecode.
-#[derive(Debug)]
+#[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
-pub struct Resolc {
+pub struct Resolc(Arc<ResolcInner>);
 #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
 struct ResolcInner {
    /// The internal solc compiler that the resolc compiler uses as a compiler frontend.
    solc: Solc,
    /// Path to the `resolc` executable
    resolc_path: PathBuf,
 }
 impl Resolc {
    pub async fn new(
        context: impl AsRef<SolcConfiguration>
        + AsRef<ResolcConfiguration>
        + AsRef<WorkingDirectoryConfiguration>,
        version: impl Into<Option<VersionOrRequirement>>,
    ) -> Result<Self> {
        /// This is a cache of all of the resolc compiler objects. Since we do not currently support
        /// multiple resolc compiler versions, so our cache is just keyed by the solc compiler and
        /// its version to the resolc compiler.
        static COMPILERS_CACHE: LazyLock<DashMap<Solc, Resolc>> = LazyLock::new(Default::default);
        let resolc_configuration = AsRef::<ResolcConfiguration>::as_ref(&context);
        let solc = Solc::new(&context, version)
            .await
            .context("Failed to create the solc compiler frontend for resolc")?;
        Ok(COMPILERS_CACHE
            .entry(solc.clone())
            .or_insert_with(|| {
                Self(Arc::new(ResolcInner {
                    solc,
                    resolc_path: resolc_configuration.path.clone(),
                }))
            })
            .clone())
    }
 }
 impl SolidityCompiler for Resolc {
-    type Options = Vec<String>;
+    fn version(&self) -> &Version {
        // We currently return the solc compiler version since we do not support multiple resolc
        // compiler versions.
        SolidityCompiler::version(&self.0.solc)
    }
    fn path(&self) -> &std::path::Path {
        &self.0.resolc_path
    }
    #[tracing::instrument(level = "debug", ret)]
    #[tracing::instrument(
        level = "error",
        skip_all,
        fields(
            resolc_version = %self.version(),
            solc_version = %self.0.solc.version(),
            json_in = tracing::field::Empty
        ),
        err(Debug)
    )]
    fn build(
        &self,
-        input: CompilerInput<Self::Options>,
+        CompilerInput {
-    ) -> anyhow::Result<CompilerOutput<Self::Options>> {
+            pipeline,
-        let mut command = Command::new(&self.resolc_path);
+            optimization,
-        command
+            evm_version,
-            .stdin(Stdio::piped())
+            allow_paths,
-            .stdout(Stdio::piped())
+            base_path,
-            .stderr(Stdio::piped())
+            sources,
-            .arg("--standard-json");
+            libraries,
-
+            // TODO: this is currently not being handled since there is no way to pass it into
-        if let Some(ref base_path) = input.base_path {
+            // resolc. So, we need to go back to this later once it's supported.
-            command.arg("--base-path").arg(base_path);
+            revert_string_handling: _,
-        }
+        }: CompilerInput,
-        if !input.allow_paths.is_empty() {
+    ) -> Pin<Box<dyn Future<Output = Result<CompilerOutput>> + '_>> {
-            command.arg("--allow-paths").arg(
+        Box::pin(async move {
-                input
+            if !matches!(pipeline, None | Some(ModePipeline::ViaYulIR)) {
-                    .allow_paths
+                anyhow::bail!(
-                    .iter()
+                    "Resolc only supports the Y (via Yul IR) pipeline, but the provided pipeline is {pipeline:?}"
-                    .map(|path| path.display().to_string())
+                );
                    .collect::<Vec<_>>()
                    .join(","),
            );
        }
        let mut child = command.spawn()?;
        let stdin_pipe = child.stdin.as_mut().expect("stdin must be piped");
        serde_json::to_writer(stdin_pipe, &input.input)?;
        let json_in = serde_json::to_string_pretty(&input.input)?;
        let output = child.wait_with_output()?;
        let stdout = output.stdout;
        let stderr = output.stderr;
        if !output.status.success() {
            let message = String::from_utf8_lossy(&stderr);
            tracing::error!(
                "resolc failed exit={} stderr={} JSON-in={} ",
                output.status,
                &message,
                json_in,
            );
            return Ok(CompilerOutput {
                input,
                output: Default::default(),
                error: Some(message.into()),
            });
        }
        let mut parsed =
            serde_json::from_slice::<SolcStandardJsonOutput>(&stdout).map_err(|e| {
                anyhow::anyhow!(
                    "failed to parse resolc JSON output: {e}\nstderr: {}",
                    String::from_utf8_lossy(&stderr)
                )
            })?;
        // Detecting if the compiler output contained errors and reporting them through logs and
        // errors instead of returning the compiler output that might contain errors.
        for error in parsed.errors.iter().flatten() {
            if error.severity == "error" {
                tracing::error!(?error, ?input, "Encountered an error in the compilation");
                anyhow::bail!("Encountered an error in the compilation: {error}")
            }
        }
-        // We need to do some post processing on the output to make it in the same format that solc
+            let input = SolcStandardJsonInput {
-        // outputs. More specifically, for each contract, the `.metadata` field should be replaced
+                language: SolcStandardJsonInputLanguage::Solidity,
-        // with the `.metadata.solc_metadata` field which contains the ABI and other information
+                sources: sources
-        // about the compiled contracts. We do this because we do not want any downstream logic to
+                    .into_iter()
-        // need to differentiate between which compiler is being used when extracting the ABI of the
+                    .map(|(path, source)| (path.display().to_string(), source.into()))
-        // contracts.
+                    .collect(),
-        if let Some(ref mut contracts) = parsed.contracts {
+                settings: SolcStandardJsonInputSettings {
-            for (contract_path, contracts_map) in contracts.iter_mut() {
+                    evm_version,
-                for (contract_name, contract_info) in contracts_map.iter_mut() {
+                    libraries: Some(
-                    let Some(metadata) = contract_info.metadata.take() else {
+                        libraries
-                        continue;
+                            .into_iter()
-                    };
+                            .map(|(source_code, libraries_map)| {
                                (
                                    source_code.display().to_string(),
                                    libraries_map
                                        .into_iter()
                                        .map(|(library_ident, library_address)| {
                                            (library_ident, library_address.to_string())
                                        })
                                        .collect(),
                                )
                            })
                            .collect(),
                    ),
                    remappings: None,
                    output_selection: Some(SolcStandardJsonInputSettingsSelection::new_required()),
                    via_ir: Some(true),
                    optimizer: SolcStandardJsonInputSettingsOptimizer::new(
                        optimization
                            .unwrap_or(ModeOptimizerSetting::M0)
                            .optimizations_enabled(),
                        None,
                        &Version::new(0, 0, 0),
                        false,
                    ),
                    metadata: None,
                    polkavm: None,
                },
            };
            Span::current().record("json_in", display(serde_json::to_string(&input).unwrap()));
-                    // Get the `solc_metadata` in the metadata of the contract.
+            let path = &self.0.resolc_path;
-                    let Some(solc_metadata) = metadata
+            let mut command = AsyncCommand::new(path);
-                        .get("solc_metadata")
+            command
-                        .and_then(|metadata| metadata.as_str())
+                .stdin(Stdio::piped())
-                    else {
+                .stdout(Stdio::piped())
-                        tracing::error!(
+                .stderr(Stdio::piped())
-                            contract_path,
+                .arg("--solc")
-                            contract_name,
+                .arg(self.0.solc.path())
-                            metadata = serde_json::to_string(&metadata).unwrap(),
+                .arg("--standard-json");
                            "Encountered a contract compiled with resolc that has no solc_metadata"
                        );
                        anyhow::bail!(
                            "Contract {} compiled with resolc that has no solc_metadata",
                            contract_name
                        );
                    };
-                    // Replace the original metadata with the new solc_metadata.
+            if let Some(ref base_path) = base_path {
-                    contract_info.metadata =
+                command.arg("--base-path").arg(base_path);
-                        Some(serde_json::Value::String(solc_metadata.to_string()));
+            }
            if !allow_paths.is_empty() {
                command.arg("--allow-paths").arg(
                    allow_paths
                        .iter()
                        .map(|path| path.display().to_string())
                        .collect::<Vec<_>>()
                        .join(","),
                );
            }
            let mut child = command
                .spawn()
                .with_context(|| format!("Failed to spawn resolc at {}", path.display()))?;
            let stdin_pipe = child.stdin.as_mut().expect("stdin must be piped");
            let serialized_input = serde_json::to_vec(&input)
                .context("Failed to serialize Standard JSON input for resolc")?;
            stdin_pipe
                .write_all(&serialized_input)
                .await
                .context("Failed to write Standard JSON to resolc stdin")?;
            let output = child
                .wait_with_output()
                .await
                .context("Failed while waiting for resolc process to finish")?;
            let stdout = output.stdout;
            let stderr = output.stderr;
            if !output.status.success() {
                let json_in = serde_json::to_string_pretty(&input)
                    .context("Failed to pretty-print Standard JSON input for logging")?;
                let message = String::from_utf8_lossy(&stderr);
                tracing::error!(
                    status = %output.status,
                    message = %message,
                    json_input = json_in,
                    "Compilation using resolc failed"
                );
                anyhow::bail!("Compilation failed with an error: {message}");
            }
            let parsed = serde_json::from_slice::<SolcStandardJsonOutput>(&stdout)
                .map_err(|e| {
                    anyhow::anyhow!(
                        "failed to parse resolc JSON output: {e}\nstderr: {}",
                        String::from_utf8_lossy(&stderr)
                    )
                })
                .context("Failed to parse resolc standard JSON output")?;
            tracing::debug!(
                output = %serde_json::to_string(&parsed).unwrap(),
                "Compiled successfully"
            );
            // Detecting if the compiler output contained errors and reporting them through logs and
            // errors instead of returning the compiler output that might contain errors.
            for error in parsed.errors.iter().flatten() {
                if error.severity == "error" {
                    tracing::error!(
                        ?error,
                        ?input,
                        output = %serde_json::to_string(&parsed).unwrap(),
                        "Encountered an error in the compilation"
                    );
                    anyhow::bail!("Encountered an error in the compilation: {error}")
                }
            }
        }
-        tracing::debug!(
+            let Some(contracts) = parsed.contracts else {
-            output = %serde_json::to_string(&parsed).unwrap(),
+                anyhow::bail!("Unexpected error - resolc output doesn't have a contracts section");
-            "Compiled successfully"
+            };
        );
-        Ok(CompilerOutput {
+            let mut compiler_output = CompilerOutput::default();
-            input,
+            for (source_path, contracts) in contracts.into_iter() {
-            output: parsed,
+                let src_for_msg = source_path.clone();
-            error: None,
+                let source_path = PathBuf::from(source_path)
                    .canonicalize()
                    .with_context(|| format!("Failed to canonicalize path {src_for_msg}"))?;
                let map = compiler_output.contracts.entry(source_path).or_default();
                for (contract_name, contract_information) in contracts.into_iter() {
                    let bytecode = contract_information
                        .evm
                        .and_then(|evm| evm.bytecode.clone())
                        .context("Unexpected - Contract compiled with resolc has no bytecode")?;
                    let abi = {
                        let metadata = contract_information
                            .metadata
                            .as_ref()
                            .context("No metadata found for the contract")?;
                        let solc_metadata_str = match metadata {
                            serde_json::Value::String(solc_metadata_str) => {
                                solc_metadata_str.as_str()
                            }
                            serde_json::Value::Object(metadata_object) => {
                                let solc_metadata_value = metadata_object
                                    .get("solc_metadata")
                                    .context("Contract doesn't have a 'solc_metadata' field")?;
                                solc_metadata_value
                                    .as_str()
                                    .context("The 'solc_metadata' field is not a string")?
                            }
                            serde_json::Value::Null
                            | serde_json::Value::Bool(_)
                            | serde_json::Value::Number(_)
                            | serde_json::Value::Array(_) => {
                                anyhow::bail!("Unsupported type of metadata {metadata:?}")
                            }
                        };
                        let solc_metadata = serde_json::from_str::<serde_json::Value>(
                            solc_metadata_str,
                        )
                        .context(
                            "Failed to deserialize the solc_metadata as a serde_json generic value",
                        )?;
                        let output_value = solc_metadata
                            .get("output")
                            .context("solc_metadata doesn't have an output field")?;
                        let abi_value = output_value
                            .get("abi")
                            .context("solc_metadata output doesn't contain an abi field")?;
                        serde_json::from_value::<JsonAbi>(abi_value.clone())
                            .context("ABI found in solc_metadata output is not valid ABI")?
                    };
                    map.insert(contract_name, (bytecode.object, abi));
                }
            }
            Ok(compiler_output)
        })
    }
-    fn new(resolc_path: PathBuf) -> Self {
+    fn supports_mode(
-        Resolc { resolc_path }
+        &self,
-    }
+        optimize_setting: ModeOptimizerSetting,
-
+        pipeline: ModePipeline,
-    fn get_compiler_executable(
+    ) -> bool {
-        config: &Arguments,
+        pipeline == ModePipeline::ViaYulIR
-        _version: semver::Version,
+            && SolidityCompiler::supports_mode(&self.0.solc, optimize_setting, pipeline)
    ) -> anyhow::Result<PathBuf> {
        if !config.resolc.as_os_str().is_empty() {
            return Ok(config.resolc.clone());
        }
        Ok(PathBuf::from("resolc"))
    }
 }
@@ -3,101 +3,297 @@
 use std::{
    path::PathBuf,
-    process::{Command, Stdio},
+    pin::Pin,
    process::Stdio,
    sync::{Arc, LazyLock},
 };
-use crate::{CompilerInput, CompilerOutput, SolidityCompiler};
+use dashmap::DashMap;
-use revive_dt_config::Arguments;
+use revive_dt_common::types::VersionOrRequirement;
 use revive_dt_config::{SolcConfiguration, WorkingDirectoryConfiguration};
 use revive_dt_solc_binaries::download_solc;
-use revive_solc_json_interface::SolcStandardJsonOutput;
+use tracing::{Span, field::display, info};
-#[derive(Debug)]
+use crate::{CompilerInput, CompilerOutput, ModeOptimizerSetting, ModePipeline, SolidityCompiler};
-pub struct Solc {
+
 use anyhow::{Context as _, Result};
 use foundry_compilers_artifacts::{
    output_selection::{
        BytecodeOutputSelection, ContractOutputSelection, EvmOutputSelection, OutputSelection,
    },
    solc::CompilerOutput as SolcOutput,
    solc::*,
 };
 use semver::Version;
 use tokio::{io::AsyncWriteExt, process::Command as AsyncCommand};
 #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
 pub struct Solc(Arc<SolcInner>);
 #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
 struct SolcInner {
    /// The path of the solidity compiler executable that this object uses.
    solc_path: PathBuf,
    /// The version of the solidity compiler executable that this object uses.
    solc_version: Version,
 }
 impl Solc {
    pub async fn new(
        context: impl AsRef<SolcConfiguration> + AsRef<WorkingDirectoryConfiguration>,
        version: impl Into<Option<VersionOrRequirement>>,
    ) -> Result<Self> {
        // This is a cache for the compiler objects so that whenever the same compiler version is
        // requested the same object is returned. We do this as we do not want to keep cloning the
        // compiler around.
        static COMPILERS_CACHE: LazyLock<DashMap<(PathBuf, Version), Solc>> =
            LazyLock::new(Default::default);
        let working_directory_configuration =
            AsRef::<WorkingDirectoryConfiguration>::as_ref(&context);
        let solc_configuration = AsRef::<SolcConfiguration>::as_ref(&context);
        // We attempt to download the solc binary. Note the following: this call does the version
        // resolution for us. Therefore, even if the download didn't proceed, this function will
        // resolve the version requirement into a canonical version of the compiler. It's then up
        // to us to either use the provided path or not.
        let version = version
            .into()
            .unwrap_or_else(|| solc_configuration.version.clone().into());
        let (version, path) =
            download_solc(working_directory_configuration.as_path(), version, false)
                .await
                .context("Failed to download/get path to solc binary")?;
        Ok(COMPILERS_CACHE
            .entry((path.clone(), version.clone()))
            .or_insert_with(|| {
                info!(
                    solc_path = %path.display(),
                    solc_version = %version,
                    "Created a new solc compiler object"
                );
                Self(Arc::new(SolcInner {
                    solc_path: path,
                    solc_version: version,
                }))
            })
            .clone())
    }
 }
 impl SolidityCompiler for Solc {
-    type Options = ();
+    fn version(&self) -> &Version {
        &self.0.solc_version
    }
    fn path(&self) -> &std::path::Path {
        &self.0.solc_path
    }
    #[tracing::instrument(level = "debug", ret)]
    #[tracing::instrument(
        level = "error",
        skip_all,
        fields(json_in = tracing::field::Empty),
        err(Debug)
    )]
    fn build(
        &self,
-        input: CompilerInput<Self::Options>,
+        CompilerInput {
-    ) -> anyhow::Result<CompilerOutput<Self::Options>> {
+            pipeline,
-        let mut command = Command::new(&self.solc_path);
+            optimization,
-        command
+            evm_version,
-            .stdin(Stdio::piped())
+            allow_paths,
-            .stdout(Stdio::piped())
+            base_path,
-            .stderr(Stdio::piped())
+            sources,
-            .arg("--standard-json");
+            libraries,
            revert_string_handling,
        }: CompilerInput,
    ) -> Pin<Box<dyn Future<Output = Result<CompilerOutput>> + '_>> {
        Box::pin(async move {
            // Be careful to entirely omit the viaIR field if the compiler does not support it,
            // as it will error if you provide fields it does not know about. Because
            // `supports_mode` is called prior to instantiating a compiler, we should never
            // ask for something which is invalid.
            let via_ir = match (pipeline, self.compiler_supports_yul()) {
                (pipeline, true) => pipeline.map(|p| p.via_yul_ir()),
                (_pipeline, false) => None,
            };
-        if let Some(ref base_path) = input.base_path {
+            let input = SolcInput {
-            command.arg("--base-path").arg(base_path);
+                language: SolcLanguage::Solidity,
-        }
+                sources: Sources(
-        if !input.allow_paths.is_empty() {
+                    sources
-            command.arg("--allow-paths").arg(
+                        .into_iter()
-                input
+                        .map(|(source_path, source_code)| (source_path, Source::new(source_code)))
-                    .allow_paths
+                        .collect(),
-                    .iter()
+                ),
-                    .map(|path| path.display().to_string())
+                settings: Settings {
-                    .collect::<Vec<_>>()
+                    optimizer: Optimizer {
-                    .join(","),
+                        enabled: optimization.map(|o| o.optimizations_enabled()),
-            );
+                        details: Some(Default::default()),
-        }
+                        ..Default::default()
-        let mut child = command.spawn()?;
+                    },
                    output_selection: OutputSelection::common_output_selection(
                        [
                            ContractOutputSelection::Abi,
                            ContractOutputSelection::Evm(EvmOutputSelection::ByteCode(
                                BytecodeOutputSelection::Object,
                            )),
                        ]
                        .into_iter()
                        .map(|item| item.to_string()),
                    ),
                    evm_version: evm_version.map(|version| version.to_string().parse().unwrap()),
                    via_ir,
                    libraries: Libraries {
                        libs: libraries
                            .into_iter()
                            .map(|(file_path, libraries)| {
                                (
                                    file_path,
                                    libraries
                                        .into_iter()
                                        .map(|(library_name, library_address)| {
                                            (library_name, library_address.to_string())
                                        })
                                        .collect(),
                                )
                            })
                            .collect(),
                    },
                    debug: revert_string_handling.map(|revert_string_handling| DebuggingSettings {
                        revert_strings: match revert_string_handling {
                            crate::RevertString::Default => Some(RevertStrings::Default),
                            crate::RevertString::Debug => Some(RevertStrings::Debug),
                            crate::RevertString::Strip => Some(RevertStrings::Strip),
                            crate::RevertString::VerboseDebug => Some(RevertStrings::VerboseDebug),
                        },
                        debug_info: Default::default(),
                    }),
                    ..Default::default()
                },
            };
-        let stdin = child.stdin.as_mut().expect("should be piped");
+            Span::current().record("json_in", display(serde_json::to_string(&input).unwrap()));
        serde_json::to_writer(stdin, &input.input)?;
        let output = child.wait_with_output()?;
-        if !output.status.success() {
+            let path = &self.0.solc_path;
-            let message = String::from_utf8_lossy(&output.stderr);
+            let mut command = AsyncCommand::new(path);
-            tracing::error!("solc failed exit={} stderr={}", output.status, &message);
+            command
-            return Ok(CompilerOutput {
+                .stdin(Stdio::piped())
-                input,
+                .stdout(Stdio::piped())
-                output: Default::default(),
+                .stderr(Stdio::null())
-                error: Some(message.into()),
+                .arg("--standard-json");
            });
        }
-        let parsed =
+            if let Some(ref base_path) = base_path {
-            serde_json::from_slice::<SolcStandardJsonOutput>(&output.stdout).map_err(|e| {
+                command.arg("--base-path").arg(base_path);
                anyhow::anyhow!(
                    "failed to parse resolc JSON output: {e}\nstderr: {}",
                    String::from_utf8_lossy(&output.stdout)
                )
            })?;
        // Detecting if the compiler output contained errors and reporting them through logs and
        // errors instead of returning the compiler output that might contain errors.
        for error in parsed.errors.iter().flatten() {
            if error.severity == "error" {
                tracing::error!(?error, ?input, "Encountered an error in the compilation");
                anyhow::bail!("Encountered an error in the compilation: {error}")
            }
-        }
+            if !allow_paths.is_empty() {
                command.arg("--allow-paths").arg(
                    allow_paths
                        .iter()
                        .map(|path| path.display().to_string())
                        .collect::<Vec<_>>()
                        .join(","),
                );
            }
            let mut child = command
                .spawn()
                .with_context(|| format!("Failed to spawn solc at {}", path.display()))?;
-        tracing::debug!(
+            let stdin = child.stdin.as_mut().expect("should be piped");
-            output = %String::from_utf8_lossy(&output.stdout).to_string(),
+            let serialized_input = serde_json::to_vec(&input)
-            "Compiled successfully"
+                .context("Failed to serialize Standard JSON input for solc")?;
-        );
+            stdin
                .write_all(&serialized_input)
                .await
                .context("Failed to write Standard JSON to solc stdin")?;
            let output = child
                .wait_with_output()
                .await
                .context("Failed while waiting for solc process to finish")?;
-        Ok(CompilerOutput {
+            if !output.status.success() {
-            input,
+                let json_in = serde_json::to_string_pretty(&input)
-            output: parsed,
+                    .context("Failed to pretty-print Standard JSON input for logging")?;
-            error: None,
+                tracing::error!(
                    status = %output.status,
                    json_input = json_in,
                    "Compilation using solc failed"
                );
                anyhow::bail!("Compilation failed");
            }
            let parsed = serde_json::from_slice::<SolcOutput>(&output.stdout)
                .map_err(|e| {
                    anyhow::anyhow!(
                        "failed to parse resolc JSON output: {e}\nstdout: {}",
                        String::from_utf8_lossy(&output.stdout)
                    )
                })
                .context("Failed to parse solc standard JSON output")?;
            // Detecting if the compiler output contained errors and reporting them through logs and
            // errors instead of returning the compiler output that might contain errors.
            for error in parsed.errors.iter() {
                if error.severity == Severity::Error {
                    tracing::error!(?error, ?input, "Encountered an error in the compilation");
                    anyhow::bail!("Encountered an error in the compilation: {error}")
                }
            }
            tracing::debug!(
                output = %String::from_utf8_lossy(&output.stdout).to_string(),
                "Compiled successfully"
            );
            let mut compiler_output = CompilerOutput::default();
            for (contract_path, contracts) in parsed.contracts {
                let map = compiler_output
                    .contracts
                    .entry(contract_path.canonicalize().with_context(|| {
                        format!(
                            "Failed to canonicalize contract path {}",
                            contract_path.display()
                        )
                    })?)
                    .or_default();
                for (contract_name, contract_info) in contracts.into_iter() {
                    let source_code = contract_info
                        .evm
                        .and_then(|evm| evm.bytecode)
                        .map(|bytecode| match bytecode.object {
                            BytecodeObject::Bytecode(bytecode) => bytecode.to_string(),
                            BytecodeObject::Unlinked(unlinked) => unlinked,
                        })
                        .context("Unexpected - contract compiled with solc has no source code")?;
                    let abi = contract_info
                        .abi
                        .context("Unexpected - contract compiled with solc as no ABI")?;
                    map.insert(contract_name, (source_code, abi));
                }
            }
            Ok(compiler_output)
        })
    }
-    fn new(solc_path: PathBuf) -> Self {
+    fn supports_mode(
-        Self { solc_path }
+        &self,
-    }
+        _optimize_setting: ModeOptimizerSetting,
-
+        pipeline: ModePipeline,
-    fn get_compiler_executable(
+    ) -> bool {
-        config: &Arguments,
+        // solc 0.8.13 and above supports --via-ir, and less than that does not. Thus, we support mode E
-        version: semver::Version,
+        // (ie no Yul IR) in either case, but only support Y (via Yul IR) if the compiler is new enough.
-    ) -> anyhow::Result<PathBuf> {
+        pipeline == ModePipeline::ViaEVMAssembly
-        let path = download_solc(config.directory(), version, config.wasm)?;
+            || (pipeline == ModePipeline::ViaYulIR && self.compiler_supports_yul())
-        Ok(path)
+    }
 }
 impl Solc {
    fn compiler_supports_yul(&self) -> bool {
        const SOLC_VERSION_SUPPORTING_VIA_YUL_IR: Version = Version::new(0, 8, 13);
        SolidityCompiler::version(self) >= &SOLC_VERSION_SUPPORTING_VIA_YUL_IR
    }
 }
@@ -0,0 +1,9 @@
 // SPDX-License-Identifier: MIT
 pragma solidity >=0.6.9;
 contract Callable {
    function f(uint[1] memory p1) public pure returns(uint) {
        return p1[0];
    }
 }
@@ -0,0 +1,16 @@
 // SPDX-License-Identifier: MIT
 // Report https://linear.app/matterlabs/issue/CPR-269/call-with-calldata-variable-bug
 pragma solidity >=0.6.9;
 import "./callable.sol";
 contract Main {
    function main(
        uint[1] calldata p1,
        Callable callable
    ) public pure returns (uint) {
        return callable.f(p1);
    }
 }
@@ -0,0 +1,21 @@
 { "cases": [ {
    "name": "first",
    "inputs": [
        {
            "instance": "Main",
            "method": "main",
            "calldata": [
                "1",
                "Callable.address"
            ]
        }
    ],
    "expected": [
        "1"
    ]
 } ],
    "contracts": {
        "Main": "main.sol:Main",
        "Callable": "callable.sol:Callable"
    }
 }
@@ -0,0 +1,88 @@
 use std::path::PathBuf;
 use revive_dt_common::types::VersionOrRequirement;
 use revive_dt_compiler::{Compiler, revive_resolc::Resolc, solc::Solc};
 use revive_dt_config::TestExecutionContext;
 use semver::Version;
 #[tokio::test]
 async fn contracts_can_be_compiled_with_solc() {
    // Arrange
    let args = TestExecutionContext::default();
    let solc = Solc::new(&args, VersionOrRequirement::Version(Version::new(0, 8, 30)))
        .await
        .unwrap();
    // Act
    let output = Compiler::new()
        .with_source("./tests/assets/array_one_element/callable.sol")
        .unwrap()
        .with_source("./tests/assets/array_one_element/main.sol")
        .unwrap()
        .try_build(&solc)
        .await;
    // Assert
    let output = output.expect("Failed to compile");
    assert_eq!(output.contracts.len(), 2);
    let main_file_contracts = output
        .contracts
        .get(
            &PathBuf::from("./tests/assets/array_one_element/main.sol")
                .canonicalize()
                .unwrap(),
        )
        .unwrap();
    let callable_file_contracts = output
        .contracts
        .get(
            &PathBuf::from("./tests/assets/array_one_element/callable.sol")
                .canonicalize()
                .unwrap(),
        )
        .unwrap();
    assert!(main_file_contracts.contains_key("Main"));
    assert!(callable_file_contracts.contains_key("Callable"));
 }
 #[tokio::test]
 async fn contracts_can_be_compiled_with_resolc() {
    // Arrange
    let args = TestExecutionContext::default();
    let resolc = Resolc::new(&args, VersionOrRequirement::Version(Version::new(0, 8, 30)))
        .await
        .unwrap();
    // Act
    let output = Compiler::new()
        .with_source("./tests/assets/array_one_element/callable.sol")
        .unwrap()
        .with_source("./tests/assets/array_one_element/main.sol")
        .unwrap()
        .try_build(&resolc)
        .await;
    // Assert
    let output = output.expect("Failed to compile");
    assert_eq!(output.contracts.len(), 2);
    let main_file_contracts = output
        .contracts
        .get(
            &PathBuf::from("./tests/assets/array_one_element/main.sol")
                .canonicalize()
                .unwrap(),
        )
        .unwrap();
    let callable_file_contracts = output
        .contracts
        .get(
            &PathBuf::from("./tests/assets/array_one_element/callable.sol")
                .canonicalize()
                .unwrap(),
        )
        .unwrap();
    assert!(main_file_contracts.contains_key("Main"));
    assert!(callable_file_contracts.contains_key("Callable"));
 }
@@ -9,9 +9,17 @@ repository.workspace = true
 rust-version.workspace = true
 [dependencies]
 revive-dt-common = { workspace = true }
 alloy = { workspace = true }
 anyhow = { workspace = true }
 clap = { workspace = true }
 semver = { workspace = true }
 temp-dir = { workspace = true }
 serde = { workspace = true }
 serde_json = { workspace = true }
 serde_with = { workspace = true }
 strum = { workspace = true }
 [lints]
 workspace = true
@@ -13,6 +13,7 @@ name = "retester"
 path = "src/main.rs"
 [dependencies]
 revive-dt-common = { workspace = true }
 revive-dt-compiler = { workspace = true }
 revive-dt-config = { workspace = true }
 revive-dt-format = { workspace = true }
@@ -20,13 +21,22 @@ revive-dt-node = { workspace = true }
 revive-dt-node-interaction = { workspace = true }
 revive-dt-report = { workspace = true }
 ansi_term = { workspace = true }
 alloy = { workspace = true }
 anyhow = { workspace = true }
 bson = { workspace = true }
 cacache = { workspace = true }
 clap = { workspace = true }
 futures = { workspace = true }
 indexmap = { workspace = true }
 tokio = { workspace = true }
 tracing = { workspace = true }
 tracing-appender = { workspace = true }
 tracing-subscriber = { workspace = true }
-rayon = { workspace = true }
+schemars = { workspace = true }
-revive-solc-json-interface = { workspace = true }
+semver = { workspace = true }
 serde = { workspace = true }
 serde_json = { workspace = true }
-temp-dir = { workspace = true }
+
 [lints]
 workspace = true
@@ -0,0 +1,743 @@
 use std::{
    collections::HashMap,
    ops::ControlFlow,
    sync::{
        Arc,
        atomic::{AtomicUsize, Ordering},
    },
    time::Duration,
 };
 use alloy::{
    hex,
    json_abi::JsonAbi,
    network::{Ethereum, TransactionBuilder},
    primitives::{Address, TxHash, U256},
    rpc::types::{
        TransactionReceipt, TransactionRequest,
        trace::geth::{
            CallFrame, GethDebugBuiltInTracerType, GethDebugTracerConfig, GethDebugTracerType,
            GethDebugTracingOptions,
        },
    },
 };
 use anyhow::{Context as _, Result, bail};
 use futures::TryFutureExt;
 use indexmap::IndexMap;
 use revive_dt_common::{
    futures::{PollingWaitBehavior, poll},
    types::PrivateKeyAllocator,
 };
 use revive_dt_format::{
    metadata::{ContractInstance, ContractPathAndIdent},
    steps::{
        AllocateAccountStep, Calldata, EtherValue, FunctionCallStep, Method, RepeatStep, Step,
        StepIdx, StepPath,
    },
    traits::{ResolutionContext, ResolverApi},
 };
 use tokio::sync::{Mutex, OnceCell, mpsc::UnboundedSender};
 use tracing::{Instrument, Span, debug, error, field::display, info, info_span, instrument};
 use crate::{
    differential_benchmarks::{ExecutionState, WatcherEvent},
    helpers::{CachedCompiler, TestDefinition, TestPlatformInformation},
 };
 static DRIVER_COUNT: AtomicUsize = AtomicUsize::new(0);
 /// The differential tests driver for a single platform.
 pub struct Driver<'a, I> {
    /// The id of the driver.
    driver_id: usize,
    /// The information of the platform that this driver is for.
    platform_information: &'a TestPlatformInformation<'a>,
    /// The resolver of the platform.
    resolver: Arc<dyn ResolverApi + 'a>,
    /// The definition of the test that the driver is instructed to execute.
    test_definition: &'a TestDefinition<'a>,
    /// The private key allocator used by this driver and other drivers when account allocations are
    /// needed.
    private_key_allocator: Arc<Mutex<PrivateKeyAllocator>>,
    /// The execution state associated with the platform.
    execution_state: ExecutionState,
    /// The send side of the watcher's unbounded channel associated with this driver.
    watcher_tx: UnboundedSender<WatcherEvent>,
    /// The number of steps that were executed on the driver.
    steps_executed: usize,
    /// This is the queue of steps that are to be executed by the driver for this test case. Each
    /// time `execute_step` is called one of the steps is executed.
    steps_iterator: I,
 }
 impl<'a, I> Driver<'a, I>
 where
    I: Iterator<Item = (StepPath, Step)>,
 {
    // region:Constructors & Initialization
    pub async fn new(
        platform_information: &'a TestPlatformInformation<'a>,
        test_definition: &'a TestDefinition<'a>,
        private_key_allocator: Arc<Mutex<PrivateKeyAllocator>>,
        cached_compiler: &CachedCompiler<'a>,
        watcher_tx: UnboundedSender<WatcherEvent>,
        steps: I,
    ) -> Result<Self> {
        let mut this = Driver {
            driver_id: DRIVER_COUNT.fetch_add(1, Ordering::SeqCst),
            platform_information,
            resolver: platform_information
                .node
                .resolver()
                .await
                .context("Failed to create resolver")?,
            test_definition,
            private_key_allocator,
            execution_state: ExecutionState::empty(),
            steps_executed: 0,
            steps_iterator: steps,
            watcher_tx,
        };
        this.init_execution_state(cached_compiler)
            .await
            .context("Failed to initialize the execution state of the platform")?;
        Ok(this)
    }
    async fn init_execution_state(&mut self, cached_compiler: &CachedCompiler<'a>) -> Result<()> {
        let compiler_output = cached_compiler
            .compile_contracts(
                self.test_definition.metadata,
                self.test_definition.metadata_file_path,
                self.test_definition.mode.clone(),
                None,
                self.platform_information.compiler.as_ref(),
                self.platform_information.platform,
                &self.platform_information.reporter,
            )
            .await
            .inspect_err(|err| error!(?err, "Pre-linking compilation failed"))
            .context("Failed to produce the pre-linking compiled contracts")?;
        let mut deployed_libraries = None::<HashMap<_, _>>;
        let mut contract_sources = self
            .test_definition
            .metadata
            .contract_sources()
            .inspect_err(|err| error!(?err, "Failed to retrieve contract sources from metadata"))
            .context("Failed to get the contract instances from the metadata file")?;
        for library_instance in self
            .test_definition
            .metadata
            .libraries
            .iter()
            .flatten()
            .flat_map(|(_, map)| map.values())
        {
            debug!(%library_instance, "Deploying Library Instance");
            let ContractPathAndIdent {
                contract_source_path: library_source_path,
                contract_ident: library_ident,
            } = contract_sources
                .remove(library_instance)
                .context("Failed to get the contract sources of the contract instance")?;
            let (code, abi) = compiler_output
                .contracts
                .get(&library_source_path)
                .and_then(|contracts| contracts.get(library_ident.as_str()))
                .context("Failed to get the code and abi for the instance")?;
            let code = alloy::hex::decode(code)?;
            // Getting the deployer address from the cases themselves. This is to ensure
            // that we're doing the deployments from different accounts and therefore we're
            // not slowed down by the nonce.
            let deployer_address = self
                .test_definition
                .case
                .steps
                .iter()
                .filter_map(|step| match step {
                    Step::FunctionCall(input) => input.caller.as_address().copied(),
                    Step::BalanceAssertion(..) => None,
                    Step::StorageEmptyAssertion(..) => None,
                    Step::Repeat(..) => None,
                    Step::AllocateAccount(..) => None,
                })
                .next()
                .unwrap_or(FunctionCallStep::default_caller_address());
            let tx = TransactionBuilder::<Ethereum>::with_deploy_code(
                TransactionRequest::default().from(deployer_address),
                code,
            );
            let receipt = self
                .execute_transaction(tx, None)
                .and_then(|(_, receipt_fut)| receipt_fut)
                .await
                .inspect_err(|err| {
                    error!(
                        ?err,
                        %library_instance,
                        "Failed to deploy the library"
                    )
                })?;
            debug!(?library_instance, "Deployed library");
            let library_address = receipt
                .contract_address
                .expect("Failed to deploy the library");
            deployed_libraries.get_or_insert_default().insert(
                library_instance.clone(),
                (library_ident.clone(), library_address, abi.clone()),
            );
        }
        let compiler_output = cached_compiler
            .compile_contracts(
                self.test_definition.metadata,
                self.test_definition.metadata_file_path,
                self.test_definition.mode.clone(),
                deployed_libraries.as_ref(),
                self.platform_information.compiler.as_ref(),
                self.platform_information.platform,
                &self.platform_information.reporter,
            )
            .await
            .inspect_err(|err| error!(?err, "Post-linking compilation failed"))
            .context("Failed to compile the post-link contracts")?;
        for (contract_path, contract_name_to_info_mapping) in compiler_output.contracts.iter() {
            for (contract_name, (contract_bytecode, _)) in contract_name_to_info_mapping.iter() {
                let contract_bytecode = hex::decode(contract_bytecode)
                    .expect("Impossible for us to get an undecodable bytecode after linking");
                self.platform_information
                    .reporter
                    .report_contract_information_event(
                        contract_path.to_path_buf(),
                        contract_name.clone(),
                        contract_bytecode.len(),
                    )
                    .expect("Should not fail");
            }
        }
        self.execution_state = ExecutionState::new(
            compiler_output.contracts,
            deployed_libraries.unwrap_or_default(),
        );
        Ok(())
    }
    // endregion:Constructors & Initialization
    // region:Step Handling
    pub async fn execute_all(mut self) -> Result<usize> {
        while let Some(result) = self.execute_next_step().await {
            result?
        }
        Ok(self.steps_executed)
    }
    pub async fn execute_next_step(&mut self) -> Option<Result<()>> {
        let (step_path, step) = self.steps_iterator.next()?;
        info!(%step_path, "Executing Step");
        Some(
            self.execute_step(&step_path, &step)
                .await
                .inspect(|_| info!(%step_path, "Step execution succeeded"))
                .inspect_err(|err| error!(%step_path, ?err, "Step execution failed")),
        )
    }
    #[instrument(
        level = "info",
        skip_all,
        fields(
            driver_id = self.driver_id,
            %step_path,
        ),
        err(Debug),
    )]
    async fn execute_step(&mut self, step_path: &StepPath, step: &Step) -> Result<()> {
        let steps_executed = match step {
            Step::FunctionCall(step) => self
                .execute_function_call(step_path, step.as_ref())
                .await
                .context("Function call step Failed"),
            Step::Repeat(step) => self
                .execute_repeat_step(step_path, step.as_ref())
                .await
                .context("Repetition Step Failed"),
            Step::AllocateAccount(step) => self
                .execute_account_allocation(step_path, step.as_ref())
                .await
                .context("Account Allocation Step Failed"),
            // The following steps are disabled in the benchmarking driver.
            Step::BalanceAssertion(..) | Step::StorageEmptyAssertion(..) => Ok(0),
        }?;
        self.steps_executed += steps_executed;
        Ok(())
    }
    #[instrument(level = "info", skip_all, fields(driver_id = self.driver_id))]
    pub async fn execute_function_call(
        &mut self,
        step_path: &StepPath,
        step: &FunctionCallStep,
    ) -> Result<usize> {
        let deployment_receipts = self
            .handle_function_call_contract_deployment(step_path, step)
            .await
            .context("Failed to deploy contracts for the function call step")?;
        let transaction_hash = self
            .handle_function_call_execution(step_path, step, deployment_receipts)
            .await
            .context("Failed to handle the function call execution")?;
        self.handle_function_call_variable_assignment(step, transaction_hash)
            .await
            .context("Failed to handle function call variable assignment")?;
        Ok(1)
    }
    async fn handle_function_call_contract_deployment(
        &mut self,
        step_path: &StepPath,
        step: &FunctionCallStep,
    ) -> Result<HashMap<ContractInstance, TransactionReceipt>> {
        let mut instances_we_must_deploy = IndexMap::<ContractInstance, bool>::new();
        for instance in step.find_all_contract_instances().into_iter() {
            if !self
                .execution_state
                .deployed_contracts
                .contains_key(&instance)
            {
                instances_we_must_deploy.entry(instance).or_insert(false);
            }
        }
        if let Method::Deployer = step.method {
            instances_we_must_deploy.swap_remove(&step.instance);
            instances_we_must_deploy.insert(step.instance.clone(), true);
        }
        let mut receipts = HashMap::new();
        for (instance, deploy_with_constructor_arguments) in instances_we_must_deploy.into_iter() {
            let calldata = deploy_with_constructor_arguments.then_some(&step.calldata);
            let value = deploy_with_constructor_arguments
                .then_some(step.value)
                .flatten();
            let caller = {
                let context = self.default_resolution_context();
                step.caller
                    .resolve_address(self.resolver.as_ref(), context)
                    .await?
            };
            if let (_, _, Some(receipt)) = self
                .get_or_deploy_contract_instance(
                    &instance,
                    caller,
                    calldata,
                    value,
                    Some(step_path),
                )
                .await
                .context("Failed to get or deploy contract instance during input execution")?
            {
                receipts.insert(instance.clone(), receipt);
            }
        }
        Ok(receipts)
    }
    async fn handle_function_call_execution(
        &mut self,
        step_path: &StepPath,
        step: &FunctionCallStep,
        mut deployment_receipts: HashMap<ContractInstance, TransactionReceipt>,
    ) -> Result<TxHash> {
        match step.method {
            // This step was already executed when `handle_step` was called. We just need to
            // lookup the transaction receipt in this case and continue on.
            Method::Deployer => deployment_receipts
                .remove(&step.instance)
                .context("Failed to find deployment receipt for constructor call")
                .map(|receipt| receipt.transaction_hash),
            Method::Fallback | Method::FunctionName(_) => {
                let tx = step
                    .as_transaction(self.resolver.as_ref(), self.default_resolution_context())
                    .await?;
                Ok(self.execute_transaction(tx, Some(step_path)).await?.0)
            }
        }
    }
    async fn handle_function_call_call_frame_tracing(
        &mut self,
        tx_hash: TxHash,
    ) -> Result<CallFrame> {
        self.platform_information
            .node
            .trace_transaction(
                tx_hash,
                GethDebugTracingOptions {
                    tracer: Some(GethDebugTracerType::BuiltInTracer(
                        GethDebugBuiltInTracerType::CallTracer,
                    )),
                    tracer_config: GethDebugTracerConfig(serde_json::json! {{
                        "onlyTopCall": true,
                        "withLog": false,
                        "withStorage": false,
                        "withMemory": false,
                        "withStack": false,
                        "withReturnData": true
                    }}),
                    ..Default::default()
                },
            )
            .await
            .map(|trace| {
                trace
                    .try_into_call_frame()
                    .expect("Impossible - we requested a callframe trace so we must get it back")
            })
    }
    async fn handle_function_call_variable_assignment(
        &mut self,
        step: &FunctionCallStep,
        tx_hash: TxHash,
    ) -> Result<()> {
        let Some(ref assignments) = step.variable_assignments else {
            return Ok(());
        };
        // Handling the return data variable assignments.
        let callframe = OnceCell::new();
        for (variable_name, output_word) in assignments.return_data.iter().zip(
            callframe
                .get_or_try_init(|| self.handle_function_call_call_frame_tracing(tx_hash))
                .await
                .context("Failed to get the callframe trace for transaction")?
                .output
                .as_ref()
                .unwrap_or_default()
                .to_vec()
                .chunks(32),
        ) {
            let value = U256::from_be_slice(output_word);
            self.execution_state
                .variables
                .insert(variable_name.clone(), value);
            tracing::info!(
                variable_name,
                variable_value = hex::encode(value.to_be_bytes::<32>()),
                "Assigned variable"
            );
        }
        Ok(())
    }
    #[instrument(level = "info", skip_all, fields(driver_id = self.driver_id), err(Debug))]
    async fn execute_repeat_step(
        &mut self,
        step_path: &StepPath,
        step: &RepeatStep,
    ) -> Result<usize> {
        let tasks = (0..step.repeat)
            .map(|_| Driver {
                driver_id: DRIVER_COUNT.fetch_add(1, Ordering::SeqCst),
                platform_information: self.platform_information,
                resolver: self.resolver.clone(),
                test_definition: self.test_definition,
                private_key_allocator: self.private_key_allocator.clone(),
                execution_state: self.execution_state.clone(),
                steps_executed: 0,
                steps_iterator: {
                    let steps = step
                        .steps
                        .iter()
                        .cloned()
                        .enumerate()
                        .map(|(step_idx, step)| {
                            let step_idx = StepIdx::new(step_idx);
                            let step_path = step_path.append(step_idx);
                            (step_path, step)
                        })
                        .collect::<Vec<_>>();
                    steps.into_iter()
                },
                watcher_tx: self.watcher_tx.clone(),
            })
            .map(|driver| driver.execute_all());
        // TODO: Determine how we want to know the `ignore_block_before` and if it's through the
        // receipt and how this would impact the architecture and the possibility of us not waiting
        // for receipts in the future.
        self.watcher_tx
            .send(WatcherEvent::RepetitionStartEvent {
                ignore_block_before: 0,
            })
            .context("Failed to send message on the watcher's tx")?;
        let res = futures::future::try_join_all(tasks)
            .await
            .context("Repetition execution failed")?;
        Ok(res.into_iter().sum())
    }
    #[instrument(level = "info", fields(driver_id = self.driver_id), skip_all, err(Debug))]
    pub async fn execute_account_allocation(
        &mut self,
        _: &StepPath,
        step: &AllocateAccountStep,
    ) -> Result<usize> {
        let Some(variable_name) = step.variable_name.strip_prefix("$VARIABLE:") else {
            bail!("Account allocation must start with $VARIABLE:");
        };
        let private_key = self
            .private_key_allocator
            .lock()
            .await
            .allocate()
            .context("Account allocation through the private key allocator failed")?;
        let account = private_key.address();
        let variable = U256::from_be_slice(account.0.as_slice());
        self.execution_state
            .variables
            .insert(variable_name.to_string(), variable);
        Ok(1)
    }
    // endregion:Step Handling
    // region:Contract Deployment
    #[instrument(
        level = "info",
        skip_all,
        fields(
            driver_id = self.driver_id,
            %contract_instance,
            %deployer
        ),
        err(Debug),
    )]
    async fn get_or_deploy_contract_instance(
        &mut self,
        contract_instance: &ContractInstance,
        deployer: Address,
        calldata: Option<&Calldata>,
        value: Option<EtherValue>,
        step_path: Option<&StepPath>,
    ) -> Result<(Address, JsonAbi, Option<TransactionReceipt>)> {
        if let Some((_, address, abi)) = self
            .execution_state
            .deployed_contracts
            .get(contract_instance)
        {
            info!(
                %address,
                "Contract instance already deployed."
            );
            Ok((*address, abi.clone(), None))
        } else {
            info!("Contract instance requires deployment.");
            let (address, abi, receipt) = self
                .deploy_contract(contract_instance, deployer, calldata, value, step_path)
                .await
                .context("Failed to deploy contract")?;
            info!(
                %address,
                "Contract instance has been deployed."
            );
            Ok((address, abi, Some(receipt)))
        }
    }
    #[instrument(
    level = "info",
    skip_all,
        fields(
            driver_id = self.driver_id,
            %contract_instance,
            %deployer
        ),
        err(Debug),
    )]
    async fn deploy_contract(
        &mut self,
        contract_instance: &ContractInstance,
        deployer: Address,
        calldata: Option<&Calldata>,
        value: Option<EtherValue>,
        step_path: Option<&StepPath>,
    ) -> Result<(Address, JsonAbi, TransactionReceipt)> {
        let Some(ContractPathAndIdent {
            contract_source_path,
            contract_ident,
        }) = self
            .test_definition
            .metadata
            .contract_sources()?
            .remove(contract_instance)
        else {
            anyhow::bail!(
                "Contract source not found for instance {:?}",
                contract_instance
            )
        };
        let Some((code, abi)) = self
            .execution_state
            .compiled_contracts
            .get(&contract_source_path)
            .and_then(|source_file_contracts| source_file_contracts.get(contract_ident.as_ref()))
            .cloned()
        else {
            anyhow::bail!(
                "Failed to find information for contract {:?}",
                contract_instance
            )
        };
        let mut code = match alloy::hex::decode(&code) {
            Ok(code) => code,
            Err(error) => {
                tracing::error!(
                    ?error,
                    contract_source_path = contract_source_path.display().to_string(),
                    contract_ident = contract_ident.as_ref(),
                    "Failed to hex-decode byte code - This could possibly mean that the bytecode requires linking"
                );
                anyhow::bail!("Failed to hex-decode the byte code {}", error)
            }
        };
        if let Some(calldata) = calldata {
            let calldata = calldata
                .calldata(self.resolver.as_ref(), self.default_resolution_context())
                .await?;
            code.extend(calldata);
        }
        let tx = {
            let tx = TransactionRequest::default().from(deployer);
            let tx = match value {
                Some(ref value) => tx.value(value.into_inner()),
                _ => tx,
            };
            TransactionBuilder::<Ethereum>::with_deploy_code(tx, code)
        };
        let receipt = match self
            .execute_transaction(tx, step_path)
            .and_then(|(_, receipt_fut)| receipt_fut)
            .await
        {
            Ok(receipt) => receipt,
            Err(error) => {
                tracing::error!(?error, "Contract deployment transaction failed.");
                return Err(error);
            }
        };
        let Some(address) = receipt.contract_address else {
            anyhow::bail!("Contract deployment didn't return an address");
        };
        tracing::info!(
            instance_name = ?contract_instance,
            instance_address = ?address,
            "Deployed contract"
        );
        self.platform_information
            .reporter
            .report_contract_deployed_event(contract_instance.clone(), address)?;
        self.execution_state.deployed_contracts.insert(
            contract_instance.clone(),
            (contract_ident, address, abi.clone()),
        );
        Ok((address, abi, receipt))
    }
    // endregion:Contract Deployment
    // region:Resolution & Resolver
    fn default_resolution_context(&self) -> ResolutionContext<'_> {
        ResolutionContext::default()
            .with_deployed_contracts(&self.execution_state.deployed_contracts)
            .with_variables(&self.execution_state.variables)
    }
    // endregion:Resolution & Resolver
    // region:Transaction Execution
    /// Executes the transaction on the driver's node with some custom waiting logic for the receipt
    #[instrument(
        level = "info",
        skip_all,
        fields(driver_id = self.driver_id, transaction_hash = tracing::field::Empty)
    )]
    async fn execute_transaction(
        &self,
        transaction: TransactionRequest,
        step_path: Option<&StepPath>,
    ) -> anyhow::Result<(TxHash, impl Future<Output = Result<TransactionReceipt>>)> {
        let node = self.platform_information.node;
        let transaction_hash = node
            .submit_transaction(transaction)
            .await
            .context("Failed to submit transaction")?;
        Span::current().record("transaction_hash", display(transaction_hash));
        info!("Submitted transaction");
        if let Some(step_path) = step_path {
            self.watcher_tx
                .send(WatcherEvent::SubmittedTransaction {
                    transaction_hash,
                    step_path: step_path.clone(),
                })
                .context("Failed to send the transaction hash to the watcher")?;
        };
        Ok((transaction_hash, async move {
            info!("Starting to poll for transaction receipt");
            poll(
                Duration::from_secs(30 * 60),
                PollingWaitBehavior::Constant(Duration::from_secs(1)),
                || {
                    async move {
                        match node.get_receipt(transaction_hash).await {
                            Ok(receipt) => {
                                info!("Polling succeeded, receipt found");
                                Ok(ControlFlow::Break(receipt))
                            }
                            Err(_) => Ok(ControlFlow::Continue(())),
                        }
                    }
                    .instrument(info_span!("Polling for receipt"))
                },
            )
            .instrument(info_span!("Polling for receipt", %transaction_hash))
            .await
            .inspect(|_| info!("Found the transaction receipt"))
        }))
    }
    // endregion:Transaction Execution
 }
@@ -0,0 +1,194 @@
 //! The main entry point for differential benchmarking.
 use std::{collections::BTreeMap, sync::Arc};
 use anyhow::Context as _;
 use futures::{FutureExt, StreamExt};
 use revive_dt_common::types::PrivateKeyAllocator;
 use revive_dt_core::Platform;
 use revive_dt_format::{
    corpus::Corpus,
    steps::{Step, StepIdx, StepPath},
 };
 use tokio::sync::Mutex;
 use tracing::{Instrument, error, info, info_span, instrument, warn};
 use revive_dt_config::{BenchmarkingContext, Context};
 use revive_dt_report::Reporter;
 use crate::{
    differential_benchmarks::{Driver, Watcher, WatcherEvent},
    helpers::{CachedCompiler, NodePool, create_test_definitions_stream},
 };
 /// Handles the differential testing executing it according to the information defined in the
 /// context
 #[instrument(level = "info", err(Debug), skip_all)]
 pub async fn handle_differential_benchmarks(
    mut context: BenchmarkingContext,
    reporter: Reporter,
 ) -> anyhow::Result<()> {
    // A bit of a hack but we need to override the number of nodes specified through the CLI since
    // benchmarks can only be run on a single node. Perhaps in the future we'd have a cleaner way to
    // do this. But, for the time being, we need to override the cli arguments.
    if context.concurrency_configuration.number_of_nodes != 1 {
        warn!(
            specified_number_of_nodes = context.concurrency_configuration.number_of_nodes,
            updated_number_of_nodes = 1,
            "Invalid number of nodes specified through the CLI. Benchmarks can only be run on a single node. Updated the arguments."
        );
        context.concurrency_configuration.number_of_nodes = 1;
    };
    let full_context = Context::Benchmark(Box::new(context.clone()));
    // Discover all of the metadata files that are defined in the context.
    let corpus = context
        .corpus_configuration
        .test_specifiers
        .clone()
        .into_iter()
        .try_fold(Corpus::default(), Corpus::with_test_specifier)
        .context("Failed to parse the test corpus")?;
    info!(
        len = corpus.metadata_file_count(),
        "Discovered metadata files"
    );
    // Discover the list of platforms that the tests should run on based on the context.
    let platforms = context
        .platforms
        .iter()
        .copied()
        .map(Into::<&dyn Platform>::into)
        .collect::<Vec<_>>();
    // Starting the nodes of the various platforms specified in the context. Note that we use the
    // node pool since it contains all of the code needed to spawn nodes from A to Z and therefore
    // it's the preferred way for us to start nodes even when we're starting just a single node. The
    // added overhead from it is quite small (performance wise) since it's involved only when we're
    // creating the test definitions, but it might have other maintenance overhead as it obscures
    // the fact that only a single node is spawned.
    let platforms_and_nodes = {
        let mut map = BTreeMap::new();
        for platform in platforms.iter() {
            let platform_identifier = platform.platform_identifier();
            let node_pool = NodePool::new(full_context.clone(), *platform)
                .await
                .inspect_err(|err| {
                    error!(
                        ?err,
                        %platform_identifier,
                        "Failed to initialize the node pool for the platform."
                    )
                })
                .context("Failed to initialize the node pool")?;
            map.insert(platform_identifier, (*platform, node_pool));
        }
        map
    };
    info!("Spawned the platform nodes");
    // Preparing test definitions for the execution.
    let test_definitions = create_test_definitions_stream(
        &full_context,
        &corpus,
        &platforms_and_nodes,
        None,
        reporter.clone(),
    )
    .await
    .collect::<Vec<_>>()
    .await;
    info!(len = test_definitions.len(), "Created test definitions");
    // Creating the objects that will be shared between the various runs. The cached compiler is the
    // only one at the current moment of time that's safe to share between runs.
    let cached_compiler = CachedCompiler::new(
        context
            .working_directory
            .as_path()
            .join("compilation_cache"),
        context
            .compilation_configuration
            .invalidate_compilation_cache,
    )
    .await
    .map(Arc::new)
    .context("Failed to initialize cached compiler")?;
    // Note: we do not want to run all of the workloads concurrently on all platforms. Rather, we'd
    // like to run all of the workloads for one platform, and then the next sequentially as we'd
    // like for the effect of concurrency to be minimized when we're doing the benchmarking.
    for platform in platforms.iter() {
        let platform_identifier = platform.platform_identifier();
        let span = info_span!("Benchmarking for the platform", %platform_identifier);
        let _guard = span.enter();
        for test_definition in test_definitions.iter() {
            let platform_information = &test_definition.platforms[&platform_identifier];
            let span = info_span!(
                "Executing workload",
                metadata_file_path = %test_definition.metadata_file_path.display(),
                case_idx = %test_definition.case_idx,
                mode = %test_definition.mode,
            );
            let _guard = span.enter();
            // Initializing all of the components requires to execute this particular workload.
            let private_key_allocator = Arc::new(Mutex::new(PrivateKeyAllocator::new(
                context.wallet_configuration.highest_private_key_exclusive(),
            )));
            let (watcher, watcher_tx) = Watcher::new(
                platform_information
                    .node
                    .subscribe_to_full_blocks_information()
                    .await
                    .context("Failed to subscribe to full blocks information from the node")?,
                test_definition
                    .reporter
                    .execution_specific_reporter(0usize, platform_identifier),
            );
            let driver = Driver::new(
                platform_information,
                test_definition,
                private_key_allocator,
                cached_compiler.as_ref(),
                watcher_tx.clone(),
                test_definition
                    .case
                    .steps_iterator_for_benchmarks(context.default_repetition_count)
                    .enumerate()
                    .map(|(step_idx, step)| -> (StepPath, Step) {
                        (StepPath::new(vec![StepIdx::new(step_idx)]), step)
                    }),
            )
            .await
            .context("Failed to create the benchmarks driver")?;
            futures::future::try_join(
                watcher.run(),
                driver
                    .execute_all()
                    .instrument(info_span!("Executing Benchmarks", %platform_identifier))
                    .inspect(|_| {
                        info!("All transactions submitted - driver completed execution");
                        watcher_tx
                            .send(WatcherEvent::AllTransactionsSubmitted)
                            .unwrap()
                    }),
            )
            .await
            .context("Failed to run the driver and executor")
            .inspect(|(_, steps_executed)| info!(steps_executed, "Workload Execution Succeeded"))
            .inspect_err(|err| error!(?err, "Workload Execution Failed"))?;
        }
    }
    Ok(())
 }
@@ -0,0 +1,43 @@
 use std::{collections::HashMap, path::PathBuf};
 use alloy::{
    json_abi::JsonAbi,
    primitives::{Address, U256},
 };
 use revive_dt_format::metadata::{ContractIdent, ContractInstance};
 #[derive(Clone)]
 /// The state associated with the test execution of one of the workloads.
 pub struct ExecutionState {
    /// The compiled contracts, these contracts have been compiled and have had the libraries linked
    /// against them and therefore they're ready to be deployed on-demand.
    pub compiled_contracts: HashMap<PathBuf, HashMap<String, (String, JsonAbi)>>,
    /// A map of all of the deployed contracts and information about them.
    pub deployed_contracts: HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>,
    /// This map stores the variables used for each one of the cases contained in the metadata file.
    pub variables: HashMap<String, U256>,
 }
 impl ExecutionState {
    pub fn new(
        compiled_contracts: HashMap<PathBuf, HashMap<String, (String, JsonAbi)>>,
        deployed_contracts: HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>,
    ) -> Self {
        Self {
            compiled_contracts,
            deployed_contracts,
            variables: Default::default(),
        }
    }
    pub fn empty() -> Self {
        Self {
            compiled_contracts: Default::default(),
            deployed_contracts: Default::default(),
            variables: Default::default(),
        }
    }
 }
@@ -0,0 +1,9 @@
 mod driver;
 mod entry_point;
 mod execution_state;
 mod watcher;
 pub use driver::*;
 pub use entry_point::*;
 pub use execution_state::*;
 pub use watcher::*;
@@ -0,0 +1,206 @@
 use std::{
    collections::HashMap,
    pin::Pin,
    sync::Arc,
    time::{SystemTime, UNIX_EPOCH},
 };
 use alloy::primitives::{BlockNumber, TxHash};
 use anyhow::Result;
 use futures::{Stream, StreamExt};
 use revive_dt_format::steps::StepPath;
 use revive_dt_report::{ExecutionSpecificReporter, MinedBlockInformation, TransactionInformation};
 use tokio::sync::{
    RwLock,
    mpsc::{UnboundedReceiver, UnboundedSender, unbounded_channel},
 };
 use tracing::{info, instrument};
 /// This struct defines the watcher used in the benchmarks. A watcher is only valid for 1 workload
 /// and MUST NOT be re-used between workloads since it holds important internal state for a given
 /// workload and is not designed for reuse.
 pub struct Watcher {
    /// The receive side of the channel that all of the drivers and various other parts of the code
    /// send events to the watcher on.
    rx: UnboundedReceiver<WatcherEvent>,
    /// This is a stream of the blocks that were mined by the node. This is for a single platform
    /// and a single node from that platform.
    blocks_stream: Pin<Box<dyn Stream<Item = MinedBlockInformation>>>,
    /// The reporter used to send events to the report aggregator.
    reporter: ExecutionSpecificReporter,
 }
 impl Watcher {
    pub fn new(
        blocks_stream: Pin<Box<dyn Stream<Item = MinedBlockInformation>>>,
        reporter: ExecutionSpecificReporter,
    ) -> (Self, UnboundedSender<WatcherEvent>) {
        let (tx, rx) = unbounded_channel::<WatcherEvent>();
        (
            Self {
                rx,
                blocks_stream,
                reporter,
            },
            tx,
        )
    }
    #[instrument(level = "info", skip_all)]
    pub async fn run(mut self) -> Result<()> {
        // The first event that the watcher receives must be a `RepetitionStartEvent` that informs
        // the watcher of the last block number that it should ignore and what the block number is
        // for the first important block that it should look for.
        let ignore_block_before = loop {
            let Some(WatcherEvent::RepetitionStartEvent {
                ignore_block_before,
            }) = self.rx.recv().await
            else {
                continue;
            };
            break ignore_block_before;
        };
        // This is the set of the transaction hashes that the watcher should be looking for and
        // watch for them in the blocks. The watcher will keep watching for blocks until it sees
        // that all of the transactions that it was watching for has been seen in the mined blocks.
        let watch_for_transaction_hashes =
            Arc::new(RwLock::new(HashMap::<TxHash, (StepPath, SystemTime)>::new()));
        // A boolean that keeps track of whether all of the transactions were submitted or if more
        // txs are expected to come through the receive side of the channel. We do not want to rely
        // on the channel closing alone for the watcher to know that all of the transactions were
        // submitted and for there to be an explicit event sent by the core orchestrator that
        // informs the watcher that no further transactions are to be expected and that it can
        // safely ignore the channel.
        let all_transactions_submitted = Arc::new(RwLock::new(false));
        let watcher_event_watching_task = {
            let watch_for_transaction_hashes = watch_for_transaction_hashes.clone();
            let all_transactions_submitted = all_transactions_submitted.clone();
            async move {
                while let Some(watcher_event) = self.rx.recv().await {
                    match watcher_event {
                        // Subsequent repetition starts are ignored since certain workloads can
                        // contain nested repetitions and therefore there's no use in doing any
                        // action if the repetitions are nested.
                        WatcherEvent::RepetitionStartEvent { .. } => {}
                        WatcherEvent::SubmittedTransaction {
                            transaction_hash,
                            step_path,
                        } => {
                            watch_for_transaction_hashes
                                .write()
                                .await
                                .insert(transaction_hash, (step_path, SystemTime::now()));
                        }
                        WatcherEvent::AllTransactionsSubmitted => {
                            *all_transactions_submitted.write().await = true;
                            self.rx.close();
                            info!("Watcher's Events Watching Task Finished");
                            break;
                        }
                    }
                }
            }
        };
        let reporter = self.reporter.clone();
        let block_information_watching_task = {
            let watch_for_transaction_hashes = watch_for_transaction_hashes.clone();
            let all_transactions_submitted = all_transactions_submitted.clone();
            let mut blocks_information_stream = self.blocks_stream;
            async move {
                while let Some(block) = blocks_information_stream.next().await {
                    // If the block number is equal to or less than the last block before the
                    // repetition then we ignore it and continue on to the next block.
                    if block.ethereum_block_information.block_number <= ignore_block_before {
                        continue;
                    }
                    reporter
                        .report_block_mined_event(block.clone())
                        .expect("Can't fail");
                    if *all_transactions_submitted.read().await
                        && watch_for_transaction_hashes.read().await.is_empty()
                    {
                        break;
                    }
                    info!(
                        block_number = block.ethereum_block_information.block_number,
                        block_tx_count = block.ethereum_block_information.transaction_hashes.len(),
                        remaining_transactions = watch_for_transaction_hashes.read().await.len(),
                        "Observed a block"
                    );
                    // Remove all of the transaction hashes observed in this block from the txs we
                    // are currently watching for.
                    let mut watch_for_transaction_hashes =
                        watch_for_transaction_hashes.write().await;
                    for tx_hash in block.ethereum_block_information.transaction_hashes.iter() {
                        let Some((step_path, submission_time)) =
                            watch_for_transaction_hashes.remove(tx_hash)
                        else {
                            continue;
                        };
                        let transaction_information = TransactionInformation {
                            transaction_hash: *tx_hash,
                            submission_timestamp: submission_time
                                .duration_since(UNIX_EPOCH)
                                .expect("Can't fail")
                                .as_secs() as _,
                            block_timestamp: block.ethereum_block_information.block_timestamp,
                            block_number: block.ethereum_block_information.block_number,
                        };
                        reporter
                            .report_step_transaction_information_event(
                                step_path,
                                transaction_information,
                            )
                            .expect("Can't fail")
                    }
                }
                info!("Watcher's Block Watching Task Finished");
            }
        };
        let (_, _) =
            futures::future::join(watcher_event_watching_task, block_information_watching_task)
                .await;
        Ok(())
    }
 }
 #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
 pub enum WatcherEvent {
    /// Informs the watcher that it should begin watching for the blocks mined by the platforms.
    /// Before the watcher receives this event it will not be watching for the mined blocks. The
    /// reason behind this is that we do not want the initialization transactions (e.g., contract
    /// deployments) to be included in the overall TPS and GPS measurements since these blocks will
    /// most likely only contain a single transaction since they're just being used for
    /// initialization.
    RepetitionStartEvent {
        /// This is the block number of the last block seen before the repetition started. This is
        /// used to instruct the watcher to ignore all block prior to this block when it starts
        /// streaming the blocks.
        ignore_block_before: BlockNumber,
    },
    /// Informs the watcher that a transaction was submitted and that the watcher should watch for a
    /// transaction with this hash in the blocks that it watches.
    SubmittedTransaction {
        /// The hash of the submitted transaction.
        transaction_hash: TxHash,
        /// The step path of the step that the transaction belongs to.
        step_path: StepPath,
    },
    /// Informs the watcher that all of the transactions of this benchmark have been submitted and
    /// that it can expect to receive no further transaction hashes and not even watch the channel
    /// any longer.
    AllTransactionsSubmitted,
 }
@@ -0,0 +1,371 @@
 //! The main entry point into differential testing.
 use std::{
    collections::{BTreeMap, BTreeSet},
    io::{BufWriter, Write, stderr},
    sync::Arc,
    time::{Duration, Instant},
 };
 use ansi_term::{ANSIStrings, Color};
 use anyhow::Context as _;
 use futures::{FutureExt, StreamExt};
 use revive_dt_common::{cached_fs::read_to_string, types::PrivateKeyAllocator};
 use revive_dt_core::Platform;
 use revive_dt_format::corpus::Corpus;
 use tokio::sync::{Mutex, RwLock, Semaphore};
 use tracing::{Instrument, error, info, info_span, instrument};
 use revive_dt_config::{Context, OutputFormat, TestExecutionContext};
 use revive_dt_report::{Reporter, ReporterEvent, TestCaseStatus};
 use crate::{
    differential_tests::Driver,
    helpers::{CachedCompiler, NodePool, create_test_definitions_stream},
 };
 /// Handles the differential testing executing it according to the information defined in the
 /// context
 #[instrument(level = "info", err(Debug), skip_all)]
 pub async fn handle_differential_tests(
    context: TestExecutionContext,
    reporter: Reporter,
 ) -> anyhow::Result<()> {
    let reporter_clone = reporter.clone();
    // Discover all of the metadata files that are defined in the context.
    let corpus = context
        .corpus_configuration
        .test_specifiers
        .clone()
        .into_iter()
        .try_fold(Corpus::default(), Corpus::with_test_specifier)
        .context("Failed to parse the test corpus")?;
    info!(
        len = corpus.metadata_file_count(),
        "Discovered metadata files"
    );
    // Discover the list of platforms that the tests should run on based on the context.
    let platforms = context
        .platforms
        .iter()
        .copied()
        .map(Into::<&dyn Platform>::into)
        .collect::<Vec<_>>();
    // Starting the nodes of the various platforms specified in the context.
    let platforms_and_nodes = {
        let mut map = BTreeMap::new();
        for platform in platforms.iter() {
            let platform_identifier = platform.platform_identifier();
            let context = Context::Test(Box::new(context.clone()));
            let node_pool = NodePool::new(context, *platform)
                .await
                .inspect_err(|err| {
                    error!(
                        ?err,
                        %platform_identifier,
                        "Failed to initialize the node pool for the platform."
                    )
                })
                .context("Failed to initialize the node pool")?;
            map.insert(platform_identifier, (*platform, node_pool));
        }
        map
    };
    info!("Spawned the platform nodes");
    // Preparing test definitions.
    let only_execute_failed_tests = match context.ignore_success_configuration.path.as_ref() {
        Some(path) => {
            let report = read_to_string(path)
                .context("Failed to read the report file to ignore the succeeding test cases")?;
            Some(serde_json::from_str(&report).context("Failed to deserialize report")?)
        }
        None => None,
    };
    let full_context = Context::Test(Box::new(context.clone()));
    let test_definitions = create_test_definitions_stream(
        &full_context,
        &corpus,
        &platforms_and_nodes,
        only_execute_failed_tests.as_ref(),
        reporter.clone(),
    )
    .await
    .collect::<Vec<_>>()
    .await;
    info!(len = test_definitions.len(), "Created test definitions");
    // Creating everything else required for the driver to run.
    let cached_compiler = CachedCompiler::new(
        context
            .working_directory
            .as_path()
            .join("compilation_cache"),
        context
            .compilation_configuration
            .invalidate_compilation_cache,
    )
    .await
    .map(Arc::new)
    .context("Failed to initialize cached compiler")?;
    let private_key_allocator = Arc::new(Mutex::new(PrivateKeyAllocator::new(
        context.wallet_configuration.highest_private_key_exclusive(),
    )));
    // Creating the driver and executing all of the steps.
    let semaphore = context
        .concurrency_configuration
        .concurrency_limit()
        .map(Semaphore::new)
        .map(Arc::new);
    let running_task_list = Arc::new(RwLock::new(BTreeSet::<usize>::new()));
    let driver_task = futures::future::join_all(test_definitions.iter().enumerate().map(
        |(test_id, test_definition)| {
            let running_task_list = running_task_list.clone();
            let semaphore = semaphore.clone();
            let private_key_allocator = private_key_allocator.clone();
            let cached_compiler = cached_compiler.clone();
            let mode = test_definition.mode.clone();
            let span = info_span!(
                "Executing Test Case",
                test_id,
                metadata_file_path = %test_definition.metadata_file_path.display(),
                case_idx = %test_definition.case_idx,
                mode = %mode,
            );
            async move {
                let permit = match semaphore.as_ref() {
                    Some(semaphore) => Some(semaphore.acquire().await.expect("Can't fail")),
                    None => None,
                };
                running_task_list.write().await.insert(test_id);
                let driver = match Driver::new_root(
                    test_definition,
                    private_key_allocator,
                    &cached_compiler,
                )
                .await
                {
                    Ok(driver) => driver,
                    Err(error) => {
                        test_definition
                            .reporter
                            .report_test_failed_event(format!("{error:#}"))
                            .expect("Can't fail");
                        error!("Test Case Failed");
                        drop(permit);
                        running_task_list.write().await.remove(&test_id);
                        return;
                    }
                };
                info!("Created the driver for the test case");
                match driver.execute_all().await {
                    Ok(steps_executed) => test_definition
                        .reporter
                        .report_test_succeeded_event(steps_executed)
                        .expect("Can't fail"),
                    Err(error) => {
                        test_definition
                            .reporter
                            .report_test_failed_event(format!("{error:#}"))
                            .expect("Can't fail");
                        error!("Test Case Failed");
                    }
                };
                info!("Finished the execution of the test case");
                drop(permit);
                running_task_list.write().await.remove(&test_id);
            }
            .instrument(span)
        },
    ))
    .inspect(|_| {
        info!("Finished executing all test cases");
        reporter_clone
            .report_completion_event()
            .expect("Can't fail")
    });
    let cli_reporting_task = start_cli_reporting_task(context.output_format, reporter);
    tokio::task::spawn(async move {
        loop {
            let remaining_tasks = running_task_list.read().await;
            info!(
                count = remaining_tasks.len(),
                ?remaining_tasks,
                "Remaining Tests"
            );
            drop(remaining_tasks);
            tokio::time::sleep(Duration::from_secs(10)).await
        }
    });
    futures::future::join(driver_task, cli_reporting_task).await;
    Ok(())
 }
 #[allow(irrefutable_let_patterns, clippy::uninlined_format_args)]
 async fn start_cli_reporting_task(output_format: OutputFormat, reporter: Reporter) {
    let mut aggregator_events_rx = reporter.subscribe().await.expect("Can't fail");
    drop(reporter);
    let start = Instant::now();
    let mut global_success_count = 0;
    let mut global_failure_count = 0;
    let mut global_ignore_count = 0;
    let mut buf = BufWriter::new(stderr());
    while let Ok(event) = aggregator_events_rx.recv().await {
        let ReporterEvent::MetadataFileSolcModeCombinationExecutionCompleted {
            metadata_file_path,
            mode,
            case_status,
        } = event
        else {
            continue;
        };
        match output_format {
            OutputFormat::Legacy => {
                let _ = writeln!(buf, "{} - {}", mode, metadata_file_path.display());
                for (case_idx, case_status) in case_status.into_iter() {
                    let _ = write!(buf, "\tCase Index {case_idx:>3}: ");
                    let _ = match case_status {
                        TestCaseStatus::Succeeded { steps_executed } => {
                            global_success_count += 1;
                            writeln!(
                                buf,
                                "{}",
                                ANSIStrings(&[
                                    Color::Green.bold().paint("Case Succeeded"),
                                    Color::Green
                                        .paint(format!(" - Steps Executed: {steps_executed}")),
                                ])
                            )
                        }
                        TestCaseStatus::Failed { reason } => {
                            global_failure_count += 1;
                            writeln!(
                                buf,
                                "{}",
                                ANSIStrings(&[
                                    Color::Red.bold().paint("Case Failed"),
                                    Color::Red.paint(format!(" - Reason: {}", reason.trim())),
                                ])
                            )
                        }
                        TestCaseStatus::Ignored { reason, .. } => {
                            global_ignore_count += 1;
                            writeln!(
                                buf,
                                "{}",
                                ANSIStrings(&[
                                    Color::Yellow.bold().paint("Case Ignored"),
                                    Color::Yellow.paint(format!(" - Reason: {}", reason.trim())),
                                ])
                            )
                        }
                    };
                }
                let _ = writeln!(buf);
            }
            OutputFormat::CargoTestLike => {
                writeln!(
                    buf,
                    "\t{} {} - {}\n",
                    Color::Green.paint("Running"),
                    metadata_file_path.display(),
                    mode
                )
                .unwrap();
                let mut success_count = 0;
                let mut failure_count = 0;
                let mut ignored_count = 0;
                writeln!(buf, "running {} tests", case_status.len()).unwrap();
                for (case_idx, case_result) in case_status.iter() {
                    let status = match case_result {
                        TestCaseStatus::Succeeded { .. } => {
                            success_count += 1;
                            global_success_count += 1;
                            Color::Green.paint("ok")
                        }
                        TestCaseStatus::Failed { reason } => {
                            failure_count += 1;
                            global_failure_count += 1;
                            Color::Red.paint(format!("FAILED, {reason}"))
                        }
                        TestCaseStatus::Ignored { reason, .. } => {
                            ignored_count += 1;
                            global_ignore_count += 1;
                            Color::Yellow.paint(format!("ignored, {reason:?}"))
                        }
                    };
                    writeln!(buf, "test case_idx_{} ... {}", case_idx, status).unwrap();
                }
                writeln!(buf).unwrap();
                let status = if failure_count > 0 {
                    Color::Red.paint("FAILED")
                } else {
                    Color::Green.paint("ok")
                };
                writeln!(
                    buf,
                    "test result: {}. {} passed; {} failed; {} ignored",
                    status, success_count, failure_count, ignored_count,
                )
                .unwrap();
                writeln!(buf).unwrap();
                if aggregator_events_rx.is_empty() {
                    buf = tokio::task::spawn_blocking(move || {
                        buf.flush().unwrap();
                        buf
                    })
                    .await
                    .unwrap();
                }
            }
        }
    }
    info!("Aggregator Broadcast Channel Closed");
    // Summary at the end.
    match output_format {
        OutputFormat::Legacy => {
            writeln!(
                buf,
                "{} cases: {} cases succeeded, {} cases failed in {} seconds",
                global_success_count + global_failure_count + global_ignore_count,
                Color::Green.paint(global_success_count.to_string()),
                Color::Red.paint(global_failure_count.to_string()),
                start.elapsed().as_secs()
            )
            .unwrap();
        }
        OutputFormat::CargoTestLike => {
            writeln!(
                buf,
                "run finished. {} passed; {} failed; {} ignored; finished in {}s",
                global_success_count,
                global_failure_count,
                global_ignore_count,
                start.elapsed().as_secs()
            )
            .unwrap();
        }
    }
 }
@@ -0,0 +1,35 @@
 use std::{collections::HashMap, path::PathBuf};
 use alloy::{
    json_abi::JsonAbi,
    primitives::{Address, U256},
 };
 use revive_dt_format::metadata::{ContractIdent, ContractInstance};
 #[derive(Clone)]
 /// The state associated with the test execution of one of the tests.
 pub struct ExecutionState {
    /// The compiled contracts, these contracts have been compiled and have had the libraries linked
    /// against them and therefore they're ready to be deployed on-demand.
    pub compiled_contracts: HashMap<PathBuf, HashMap<String, (String, JsonAbi)>>,
    /// A map of all of the deployed contracts and information about them.
    pub deployed_contracts: HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>,
    /// This map stores the variables used for each one of the cases contained in the metadata file.
    pub variables: HashMap<String, U256>,
 }
 impl ExecutionState {
    pub fn new(
        compiled_contracts: HashMap<PathBuf, HashMap<String, (String, JsonAbi)>>,
        deployed_contracts: HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>,
    ) -> Self {
        Self {
            compiled_contracts,
            deployed_contracts,
            variables: Default::default(),
        }
    }
 }
@@ -0,0 +1,11 @@
 //! This module contains all of the code responsible for performing differential tests including the
 //! driver implementation, state implementation, and the core logic that allows for tests to be
 //! executed.
 mod driver;
 mod entry_point;
 mod execution_state;
 pub use driver::*;
 pub use entry_point::*;
 pub use execution_state::*;
@@ -1,834 +0,0 @@
 //! The test driver handles the compilation and execution of the test cases.
 use std::collections::HashMap;
 use std::marker::PhantomData;
 use alloy::json_abi::JsonAbi;
 use alloy::network::{Ethereum, TransactionBuilder};
 use alloy::rpc::types::TransactionReceipt;
 use alloy::rpc::types::trace::geth::GethTrace;
 use alloy::{
    primitives::Address,
    rpc::types::{
        TransactionRequest,
        trace::geth::{AccountState, DiffMode},
    },
 };
 use anyhow::Context;
 use indexmap::IndexMap;
 use revive_dt_compiler::{Compiler, SolidityCompiler};
 use revive_dt_config::Arguments;
 use revive_dt_format::case::CaseIdx;
 use revive_dt_format::input::Method;
 use revive_dt_format::metadata::{ContractInstance, ContractPathAndIdentifier};
 use revive_dt_format::{input::Input, metadata::Metadata, mode::SolcMode};
 use revive_dt_node_interaction::EthereumNode;
 use revive_dt_report::reporter::{CompilationTask, Report, Span};
 use revive_solc_json_interface::SolcStandardJsonOutput;
 use serde_json::Value;
 use std::fmt::Debug;
 use crate::Platform;
 use crate::common::*;
 pub struct State<'a, T: Platform> {
    /// The configuration that the framework was started with.
    ///
    /// This is currently used to get certain information from it such as the solc mode and other
    /// information used at runtime.
    config: &'a Arguments,
    /// The [`Span`] used in reporting.
    span: Span,
    /// A vector of all of the compiled contracts. Each call to [`build_contracts`] adds a new entry
    /// to this vector.
    ///
    /// [`build_contracts`]: State::build_contracts
    contracts: Vec<SolcStandardJsonOutput>,
    /// This map stores the contracts deployments that have been made for each case within a
    /// metadata file. Note, this means that the state can't be reused between different metadata
    /// files.
    deployed_contracts: HashMap<CaseIdx, HashMap<ContractInstance, (Address, JsonAbi)>>,
    phantom: PhantomData<T>,
 }
 impl<'a, T> State<'a, T>
 where
    T: Platform,
 {
    pub fn new(config: &'a Arguments, span: Span) -> Self {
        Self {
            config,
            span,
            contracts: Default::default(),
            deployed_contracts: Default::default(),
            phantom: Default::default(),
        }
    }
    /// Returns a copy of the current span.
    fn span(&self) -> Span {
        self.span
    }
    pub fn build_contracts(&mut self, mode: &SolcMode, metadata: &Metadata) -> anyhow::Result<()> {
        let mut span = self.span();
        span.next_metadata(
            metadata
                .file_path
                .as_ref()
                .expect("metadata should have been read from a file")
                .clone(),
        );
        let Some(version) = mode.last_patch_version(&self.config.solc) else {
            anyhow::bail!("unsupported solc version: {:?}", &mode.solc_version);
        };
        let compiler = Compiler::<T::Compiler>::new()
            .allow_path(metadata.directory()?)
            .solc_optimizer(mode.solc_optimize());
        let compiler = FilesWithExtensionIterator::new(metadata.directory()?)
            .with_allowed_extension("sol")
            .try_fold(compiler, |compiler, path| compiler.with_source(&path))?;
        let mut task = CompilationTask {
            json_input: compiler.input(),
            json_output: None,
            mode: mode.clone(),
            compiler_version: format!("{}", &version),
            error: None,
        };
        let compiler_path = T::Compiler::get_compiler_executable(self.config, version)?;
        match compiler.try_build(compiler_path) {
            Ok(output) => {
                task.json_output = Some(output.output.clone());
                task.error = output.error;
                self.contracts.push(output.output);
                if let Some(last_output) = self.contracts.last() {
                    if let Some(contracts) = &last_output.contracts {
                        for (file, contracts_map) in contracts {
                            for contract_name in contracts_map.keys() {
                                tracing::debug!(
                                    "Compiled contract: {contract_name} from file: {file}"
                                );
                            }
                        }
                    } else {
                        tracing::warn!("Compiled contracts field is None");
                    }
                }
                Report::compilation(span, T::config_id(), task);
                Ok(())
            }
            Err(error) => {
                tracing::error!("Failed to compile contract: {:?}", error.to_string());
                task.error = Some(error.to_string());
                Err(error)
            }
        }
    }
    pub fn handle_input(
        &mut self,
        metadata: &Metadata,
        case_idx: CaseIdx,
        input: &Input,
        node: &T::Blockchain,
    ) -> anyhow::Result<(TransactionReceipt, GethTrace, DiffMode)> {
        let deployment_receipts =
            self.handle_contract_deployment(metadata, case_idx, input, node)?;
        self.handle_input_execution(case_idx, input, deployment_receipts, node)
    }
    /// Handles the contract deployment for a given input performing it if it needs to be performed.
    fn handle_contract_deployment(
        &mut self,
        metadata: &Metadata,
        case_idx: CaseIdx,
        input: &Input,
        node: &T::Blockchain,
    ) -> anyhow::Result<HashMap<ContractInstance, TransactionReceipt>> {
        let span = tracing::debug_span!(
            "Handling contract deployment",
            ?case_idx,
            instance = ?input.instance
        );
        let _guard = span.enter();
        let mut instances_we_must_deploy = IndexMap::<ContractInstance, bool>::new();
        for instance in input.find_all_contract_instances().into_iter() {
            if !self
                .deployed_contracts
                .entry(case_idx)
                .or_default()
                .contains_key(&instance)
            {
                instances_we_must_deploy.entry(instance).or_insert(false);
            }
        }
        if let Method::Deployer = input.method {
            instances_we_must_deploy.swap_remove(&input.instance);
            instances_we_must_deploy.insert(input.instance.clone(), true);
        }
        tracing::debug!(
            instances_to_deploy = instances_we_must_deploy.len(),
            "Computed the number of required deployments for input"
        );
        let mut receipts = HashMap::new();
        for (instance, deploy_with_constructor_arguments) in instances_we_must_deploy.into_iter() {
            // What we have at this moment is just a contract instance which is kind of like a variable
            // name for an actual underlying contract. So, we need to resolve this instance to the info
            // of the contract that it belongs to.
            let Some(ContractPathAndIdentifier {
                contract_source_path,
                contract_ident,
            }) = metadata.contract_sources()?.remove(&instance)
            else {
                tracing::error!("Contract source not found for instance");
                anyhow::bail!("Contract source not found for instance {:?}", instance)
            };
            let compiled_contract = self.contracts.iter().find_map(|output| {
                output
                    .contracts
                    .as_ref()?
                    .get(&contract_source_path.display().to_string())
                    .and_then(|source_file_contracts| {
                        source_file_contracts.get(contract_ident.as_ref())
                    })
            });
            let Some(code) = compiled_contract
                .and_then(|contract| contract.evm.as_ref().and_then(|evm| evm.bytecode.as_ref()))
            else {
                tracing::error!(
                    contract_source_path = contract_source_path.display().to_string(),
                    contract_ident = contract_ident.as_ref(),
                    "Failed to find bytecode for contract"
                );
                anyhow::bail!("Failed to find bytecode for contract {:?}", instance)
            };
            // TODO: When we want to do linking it would be best to do it at this stage here. We have
            // the context from the metadata files and therefore know what needs to be linked and in
            // what order it needs to happen.
            let mut code = match alloy::hex::decode(&code.object) {
                Ok(code) => code,
                Err(error) => {
                    tracing::error!(
                        ?error,
                        contract_source_path = contract_source_path.display().to_string(),
                        contract_ident = contract_ident.as_ref(),
                        "Failed to hex-decode byte code - This could possibly mean that the bytecode requires linking"
                    );
                    anyhow::bail!("Failed to hex-decode the byte code {}", error)
                }
            };
            if deploy_with_constructor_arguments {
                let encoded_input = input
                    .encoded_input(self.deployed_contracts.entry(case_idx).or_default(), node)?;
                code.extend(encoded_input.to_vec());
            }
            let tx = {
                let tx = TransactionRequest::default().from(input.caller);
                TransactionBuilder::<Ethereum>::with_deploy_code(tx, code)
            };
            let receipt = match node.execute_transaction(tx) {
                Ok(receipt) => receipt,
                Err(error) => {
                    tracing::error!(
                        node = std::any::type_name::<T>(),
                        ?error,
                        "Contract deployment transaction failed."
                    );
                    return Err(error);
                }
            };
            let Some(address) = receipt.contract_address else {
                tracing::error!("Contract deployment transaction didn't return an address");
                anyhow::bail!("Contract deployment didn't return an address");
            };
            tracing::info!(
                instance_name = ?instance,
                instance_address = ?address,
                "Deployed contract"
            );
            let Some(Value::String(metadata)) =
                compiled_contract.and_then(|contract| contract.metadata.as_ref())
            else {
                tracing::error!("Contract does not have a metadata field");
                anyhow::bail!("Contract does not have a metadata field");
            };
            let Ok(metadata) = serde_json::from_str::<Value>(metadata) else {
                tracing::error!(%metadata, "Failed to parse solc metadata into a structured value");
                anyhow::bail!("Failed to parse solc metadata into a structured value {metadata}");
            };
            let Some(abi) = metadata.get("output").and_then(|value| value.get("abi")) else {
                tracing::error!(%metadata, "Failed to access the .output.abi field of the solc metadata");
                anyhow::bail!(
                    "Failed to access the .output.abi field of the solc metadata {metadata}"
                );
            };
            let Ok(abi) = serde_json::from_value::<JsonAbi>(abi.clone()) else {
                tracing::error!(%metadata, "Failed to deserialize ABI into a structured format");
                anyhow::bail!("Failed to deserialize ABI into a structured format {metadata}");
            };
            self.deployed_contracts
                .entry(case_idx)
                .or_default()
                .insert(instance.clone(), (address, abi));
            receipts.insert(instance.clone(), receipt);
        }
        Ok(receipts)
    }
    /// Handles the execution of the input in terms of the calls that need to be made.
    fn handle_input_execution(
        &mut self,
        case_idx: CaseIdx,
        input: &Input,
        deployment_receipts: HashMap<ContractInstance, TransactionReceipt>,
        node: &T::Blockchain,
    ) -> anyhow::Result<(TransactionReceipt, GethTrace, DiffMode)> {
        tracing::trace!("Calling execute_input for input: {input:?}");
        let receipt = match input.method {
            // This input was already executed when `handle_input` was called. We just need to
            // lookup the transaction receipt in this case and continue on.
            Method::Deployer => deployment_receipts
                .get(&input.instance)
                .context("Failed to find deployment receipt")?
                .clone(),
            Method::Fallback | Method::FunctionName(_) => {
                let tx = match input
                    .legacy_transaction(self.deployed_contracts.entry(case_idx).or_default(), node)
                {
                    Ok(tx) => {
                        tracing::debug!("Legacy transaction data: {tx:#?}");
                        tx
                    }
                    Err(err) => {
                        tracing::error!("Failed to construct legacy transaction: {err:?}");
                        return Err(err);
                    }
                };
                tracing::trace!("Executing transaction for input: {input:?}");
                match node.execute_transaction(tx) {
                    Ok(receipt) => receipt,
                    Err(err) => {
                        tracing::error!(
                            "Failed to execute transaction when executing the contract: {}, {:?}",
                            &*input.instance,
                            err
                        );
                        return Err(err);
                    }
                }
            }
        };
        tracing::trace!(
            "Transaction receipt for executed contract: {} - {:?}",
            &*input.instance,
            receipt,
        );
        let trace = node.trace_transaction(receipt.clone())?;
        tracing::trace!(
            "Trace result for contract: {} - {:?}",
            &*input.instance,
            trace
        );
        let diff = node.state_diff(receipt.clone())?;
        Ok((receipt, trace, diff))
    }
 }
 pub struct Driver<'a, Leader: Platform, Follower: Platform> {
    metadata: &'a Metadata,
    config: &'a Arguments,
    leader_node: &'a Leader::Blockchain,
    follower_node: &'a Follower::Blockchain,
 }
 impl<'a, L, F> Driver<'a, L, F>
 where
    L: Platform,
    F: Platform,
 {
    pub fn new(
        metadata: &'a Metadata,
        config: &'a Arguments,
        leader_node: &'a L::Blockchain,
        follower_node: &'a F::Blockchain,
    ) -> Driver<'a, L, F> {
        Self {
            metadata,
            config,
            leader_node,
            follower_node,
        }
    }
    pub fn trace_diff_mode(label: &str, diff: &DiffMode) {
        tracing::trace!("{label} - PRE STATE:");
        for (addr, state) in &diff.pre {
            Self::trace_account_state("  [pre]", addr, state);
        }
        tracing::trace!("{label} - POST STATE:");
        for (addr, state) in &diff.post {
            Self::trace_account_state("  [post]", addr, state);
        }
    }
    fn trace_account_state(prefix: &str, addr: &Address, state: &AccountState) {
        tracing::trace!("{prefix} 0x{addr:x}");
        if let Some(balance) = &state.balance {
            tracing::trace!("{prefix}   balance: {balance}");
        }
        if let Some(nonce) = &state.nonce {
            tracing::trace!("{prefix}   nonce: {nonce}");
        }
        if let Some(code) = &state.code {
            tracing::trace!("{prefix}   code: {code}");
        }
    }
    // A note on this function and the choice of how we handle errors that happen here. This is not
    // a doc comment since it's a comment for the maintainers of this code and not for the users of
    // this code.
    //
    // This function does a few things: it builds the contracts for the various SOLC modes needed.
    // It deploys the contracts to the chain, and it executes the various inputs that are specified
    // for the test cases.
    //
    // In most functions in the codebase, it's fine to just say "If we encounter an error just
    // bubble it up to the caller", but this isn't a good idea to do here and we need an elaborate
    // way to report errors all while being graceful and continuing execution where we can. For
    // example, if one of the inputs of one of the cases fail to execute, then we should not just
    // bubble that error up immediately. Instead, we should note it down and continue to the next
    // case as the next case might succeed.
    //
    // Therefore, this method returns an `ExecutionResult` object, and not just a normal `Result`.
    // This object is fully typed to contain information about what exactly in the execution was a
    // success and what failed.
    //
    // The above then allows us to have better logging and better information in the caller of this
    // function as we have a more detailed view of what worked and what didn't.
    pub fn execute(&mut self, span: Span) -> ExecutionResult {
        // This is the execution result object that all of the execution information will be
        // collected into and returned at the end of the execution.
        let mut execution_result = ExecutionResult::default();
        let tracing_span = tracing::info_span!("Handling metadata file");
        let _guard = tracing_span.enter();
        for mode in self.metadata.solc_modes() {
            let tracing_span = tracing::info_span!("With solc mode", solc_mode = ?mode);
            let _guard = tracing_span.enter();
            let mut leader_state = State::<L>::new(self.config, span);
            let mut follower_state = State::<F>::new(self.config, span);
            // We build the contracts. If building the contracts for the metadata file fails then we
            // have no other option but to keep note of this error and move on to the next solc mode
            // and NOT just bail out of the execution as a whole.
            let build_result = tracing::info_span!("Building contracts").in_scope(|| {
                match leader_state.build_contracts(&mode, self.metadata) {
                    Ok(_) => {
                        tracing::debug!(target = ?Target::Leader, "Contract building succeeded");
                        execution_result.add_successful_build(Target::Leader, mode.clone());
                    },
                    Err(error) => {
                        tracing::error!(target = ?Target::Leader, ?error, "Contract building failed");
                        execution_result.add_failed_build(Target::Leader, mode.clone(), error);
                        return Err(());
                    }
                }
                match follower_state.build_contracts(&mode, self.metadata) {
                    Ok(_) => {
                        tracing::debug!(target = ?Target::Follower, "Contract building succeeded");
                        execution_result.add_successful_build(Target::Follower, mode.clone());
                    },
                    Err(error) => {
                        tracing::error!(target = ?Target::Follower, ?error, "Contract building failed");
                        execution_result.add_failed_build(Target::Follower, mode.clone(), error);
                        return Err(());
                    }
                }
                Ok(())
            });
            if build_result.is_err() {
                // Note: We skip to the next solc mode as there's nothing that we can do at this
                // point, the building has failed. We do NOT bail out of the execution as a whole.
                continue;
            }
            // For cases if one of the inputs fail then we move on to the next case and we do NOT
            // bail out of the whole thing.
            'case_loop: for (case_idx, case) in self.metadata.cases.iter().enumerate() {
                let tracing_span = tracing::info_span!(
                    "Handling case",
                    case_name = case.name,
                    case_idx = case_idx
                );
                let _guard = tracing_span.enter();
                let case_idx = CaseIdx::new_from(case_idx);
                // For inputs if one of the inputs fail we move on to the next case (we do not move
                // on to the next input as it doesn't make sense. It depends on the previous one).
                for (input_idx, input) in case.inputs.iter().enumerate() {
                    let tracing_span = tracing::info_span!("Handling input", input_idx);
                    let _guard = tracing_span.enter();
                    let execution_result =
                        tracing::info_span!("Executing input", contract_name = ?input.instance)
                            .in_scope(|| {
                                let (leader_receipt, _, leader_diff) = match leader_state
                                    .handle_input(self.metadata, case_idx, input, self.leader_node)
                                {
                                    Ok(result) => result,
                                    Err(error) => {
                                        tracing::error!(
                                            target = ?Target::Leader,
                                            ?error,
                                            "Contract execution failed"
                                        );
                                        execution_result.add_failed_case(
                                            Target::Leader,
                                            mode.clone(),
                                            case.name
                                                .as_deref()
                                                .unwrap_or("no case name")
                                                .to_owned(),
                                            case_idx,
                                            input_idx,
                                            anyhow::Error::msg(format!("{error}")),
                                        );
                                        return Err(error);
                                    }
                                };
                                let (follower_receipt, _, follower_diff) = match follower_state
                                    .handle_input(
                                        self.metadata,
                                        case_idx,
                                        input,
                                        self.follower_node,
                                    ) {
                                    Ok(result) => result,
                                    Err(error) => {
                                        tracing::error!(
                                            target = ?Target::Follower,
                                            ?error,
                                            "Contract execution failed"
                                        );
                                        execution_result.add_failed_case(
                                            Target::Follower,
                                            mode.clone(),
                                            case.name
                                                .as_deref()
                                                .unwrap_or("no case name")
                                                .to_owned(),
                                            case_idx,
                                            input_idx,
                                            anyhow::Error::msg(format!("{error}")),
                                        );
                                        return Err(error);
                                    }
                                };
                                Ok((leader_receipt, leader_diff, follower_receipt, follower_diff))
                            });
                    let Ok((leader_receipt, leader_diff, follower_receipt, follower_diff)) =
                        execution_result
                    else {
                        // Noting it again here: if something in the input fails we do not move on
                        // to the next input, we move to the next case completely.
                        continue 'case_loop;
                    };
                    if leader_diff == follower_diff {
                        tracing::debug!("State diffs match between leader and follower.");
                    } else {
                        tracing::debug!("State diffs mismatch between leader and follower.");
                        Self::trace_diff_mode("Leader", &leader_diff);
                        Self::trace_diff_mode("Follower", &follower_diff);
                    }
                    if leader_receipt.logs() != follower_receipt.logs() {
                        tracing::debug!("Log/event mismatch between leader and follower.");
                        tracing::trace!("Leader logs: {:?}", leader_receipt.logs());
                        tracing::trace!("Follower logs: {:?}", follower_receipt.logs());
                    }
                    if leader_receipt.status() != follower_receipt.status() {
                        tracing::debug!(
                            "Mismatch in status: leader = {}, follower = {}",
                            leader_receipt.status(),
                            follower_receipt.status()
                        );
                    }
                }
                // Note: Only consider the case as having been successful after we have processed
                // all of the inputs and completed the entire loop over the input.
                execution_result.add_successful_case(
                    Target::Leader,
                    mode.clone(),
                    case.name.clone().unwrap_or("no case name".to_owned()),
                    case_idx,
                );
                execution_result.add_successful_case(
                    Target::Follower,
                    mode.clone(),
                    case.name.clone().unwrap_or("no case name".to_owned()),
                    case_idx,
                );
            }
        }
        execution_result
    }
 }
 #[derive(Debug, Default)]
 pub struct ExecutionResult {
    pub results: Vec<Box<dyn ExecutionResultItem>>,
    pub successful_cases_count: usize,
    pub failed_cases_count: usize,
 }
 impl ExecutionResult {
    pub fn new() -> Self {
        Self {
            results: Default::default(),
            successful_cases_count: Default::default(),
            failed_cases_count: Default::default(),
        }
    }
    pub fn add_successful_build(&mut self, target: Target, solc_mode: SolcMode) {
        self.results
            .push(Box::new(BuildResult::Success { target, solc_mode }));
    }
    pub fn add_failed_build(&mut self, target: Target, solc_mode: SolcMode, error: anyhow::Error) {
        self.results.push(Box::new(BuildResult::Failure {
            target,
            solc_mode,
            error,
        }));
    }
    pub fn add_successful_case(
        &mut self,
        target: Target,
        solc_mode: SolcMode,
        case_name: String,
        case_idx: CaseIdx,
    ) {
        self.successful_cases_count += 1;
        self.results.push(Box::new(CaseResult::Success {
            target,
            solc_mode,
            case_name,
            case_idx,
        }));
    }
    pub fn add_failed_case(
        &mut self,
        target: Target,
        solc_mode: SolcMode,
        case_name: String,
        case_idx: CaseIdx,
        input_idx: usize,
        error: anyhow::Error,
    ) {
        self.failed_cases_count += 1;
        self.results.push(Box::new(CaseResult::Failure {
            target,
            solc_mode,
            case_name,
            case_idx,
            error,
            input_idx,
        }));
    }
 }
 pub trait ExecutionResultItem: Debug {
    /// Converts this result item into an [`anyhow::Result`].
    fn as_result(&self) -> Result<(), &anyhow::Error>;
    /// Provides information on whether the provided result item is of a success or failure.
    fn is_success(&self) -> bool;
    /// Provides information of the target that this result is for.
    fn target(&self) -> &Target;
    /// Provides information on the [`SolcMode`] mode that we being used for this result item.
    fn solc_mode(&self) -> &SolcMode;
    /// Provides information on the case name and number that this result item pertains to. This is
    /// [`None`] if the error doesn't belong to any case (e.g., if it's a build error outside of any
    /// of the cases.).
    fn case_name_and_index(&self) -> Option<(&str, &CaseIdx)>;
    /// Provides information on the input number that this result item pertains to. This is [`None`]
    /// if the error doesn't belong to any input (e.g., if it's a build error outside of any of the
    /// inputs.).
    fn input_index(&self) -> Option<usize>;
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
 pub enum Target {
    Leader,
    Follower,
 }
 #[derive(Debug)]
 pub enum BuildResult {
    Success {
        target: Target,
        solc_mode: SolcMode,
    },
    Failure {
        target: Target,
        solc_mode: SolcMode,
        error: anyhow::Error,
    },
 }
 impl ExecutionResultItem for BuildResult {
    fn as_result(&self) -> Result<(), &anyhow::Error> {
        match self {
            Self::Success { .. } => Ok(()),
            Self::Failure { error, .. } => Err(error)?,
        }
    }
    fn is_success(&self) -> bool {
        match self {
            Self::Success { .. } => true,
            Self::Failure { .. } => false,
        }
    }
    fn target(&self) -> &Target {
        match self {
            Self::Success { target, .. } | Self::Failure { target, .. } => target,
        }
    }
    fn solc_mode(&self) -> &SolcMode {
        match self {
            Self::Success { solc_mode, .. } | Self::Failure { solc_mode, .. } => solc_mode,
        }
    }
    fn case_name_and_index(&self) -> Option<(&str, &CaseIdx)> {
        None
    }
    fn input_index(&self) -> Option<usize> {
        None
    }
 }
 #[derive(Debug)]
 pub enum CaseResult {
    Success {
        target: Target,
        solc_mode: SolcMode,
        case_name: String,
        case_idx: CaseIdx,
    },
    Failure {
        target: Target,
        solc_mode: SolcMode,
        case_name: String,
        case_idx: CaseIdx,
        input_idx: usize,
        error: anyhow::Error,
    },
 }
 impl ExecutionResultItem for CaseResult {
    fn as_result(&self) -> Result<(), &anyhow::Error> {
        match self {
            Self::Success { .. } => Ok(()),
            Self::Failure { error, .. } => Err(error)?,
        }
    }
    fn is_success(&self) -> bool {
        match self {
            Self::Success { .. } => true,
            Self::Failure { .. } => false,
        }
    }
    fn target(&self) -> &Target {
        match self {
            Self::Success { target, .. } | Self::Failure { target, .. } => target,
        }
    }
    fn solc_mode(&self) -> &SolcMode {
        match self {
            Self::Success { solc_mode, .. } | Self::Failure { solc_mode, .. } => solc_mode,
        }
    }
    fn case_name_and_index(&self) -> Option<(&str, &CaseIdx)> {
        match self {
            Self::Success {
                case_name,
                case_idx,
                ..
            }
            | Self::Failure {
                case_name,
                case_idx,
                ..
            } => Some((case_name, case_idx)),
        }
    }
    fn input_index(&self) -> Option<usize> {
        match self {
            CaseResult::Success { .. } => None,
            CaseResult::Failure { input_idx, .. } => Some(*input_idx),
        }
    }
 }
@@ -0,0 +1,355 @@
 //! A wrapper around the compiler which allows for caching of compilation artifacts so that they can
 //! be reused between runs.
 use std::{
    borrow::Cow,
    collections::HashMap,
    path::{Path, PathBuf},
    sync::{Arc, LazyLock},
 };
 use futures::FutureExt;
 use revive_dt_common::{iterators::FilesWithExtensionIterator, types::CompilerIdentifier};
 use revive_dt_compiler::{Compiler, CompilerOutput, Mode, SolidityCompiler};
 use revive_dt_core::Platform;
 use revive_dt_format::metadata::{ContractIdent, ContractInstance, Metadata};
 use alloy::{hex::ToHexExt, json_abi::JsonAbi, primitives::Address};
 use anyhow::{Context as _, Error, Result};
 use revive_dt_report::ExecutionSpecificReporter;
 use semver::Version;
 use serde::{Deserialize, Serialize};
 use tokio::sync::{Mutex, RwLock, Semaphore};
 use tracing::{Instrument, debug, debug_span, instrument};
 pub struct CachedCompiler<'a> {
    /// The cache that stores the compiled contracts.
    artifacts_cache: ArtifactsCache,
    /// This is a mechanism that the cached compiler uses so that if multiple compilation requests
    /// come in for the same contract we never compile all of them and only compile it once and all
    /// other tasks that request this same compilation concurrently get the cached version.
    cache_key_lock: RwLock<HashMap<CacheKey<'a>, Arc<Mutex<()>>>>,
 }
 impl<'a> CachedCompiler<'a> {
    pub async fn new(path: impl AsRef<Path>, invalidate_cache: bool) -> Result<Self> {
        let mut cache = ArtifactsCache::new(path);
        if invalidate_cache {
            cache = cache
                .with_invalidated_cache()
                .await
                .context("Failed to invalidate compilation cache directory")?;
        }
        Ok(Self {
            artifacts_cache: cache,
            cache_key_lock: Default::default(),
        })
    }
    /// Compiles or gets the compilation artifacts from the cache.
    #[allow(clippy::too_many_arguments)]
    #[instrument(
        level = "debug",
        skip_all,
        fields(
            metadata_file_path = %metadata_file_path.display(),
            %mode,
            platform = %platform.platform_identifier()
        ),
        err
    )]
    pub async fn compile_contracts(
        &self,
        metadata: &'a Metadata,
        metadata_file_path: &'a Path,
        mode: Cow<'a, Mode>,
        deployed_libraries: Option<&HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>>,
        compiler: &dyn SolidityCompiler,
        platform: &dyn Platform,
        reporter: &ExecutionSpecificReporter,
    ) -> Result<CompilerOutput> {
        let cache_key = CacheKey {
            compiler_identifier: platform.compiler_identifier(),
            compiler_version: compiler.version().clone(),
            metadata_file_path,
            solc_mode: mode.clone(),
        };
        let compilation_callback = || {
            async move {
                compile_contracts(
                    metadata
                        .directory()
                        .context("Failed to get metadata directory while preparing compilation")?,
                    metadata
                        .files_to_compile()
                        .context("Failed to enumerate files to compile from metadata")?,
                    &mode,
                    deployed_libraries,
                    compiler,
                    reporter,
                )
                .map(|compilation_result| compilation_result.map(CacheValue::new))
                .await
            }
            .instrument(debug_span!(
                "Running compilation for the cache key",
                cache_key.compiler_identifier = %cache_key.compiler_identifier,
                cache_key.compiler_version = %cache_key.compiler_version,
                cache_key.metadata_file_path = %cache_key.metadata_file_path.display(),
                cache_key.solc_mode = %cache_key.solc_mode,
            ))
        };
        let compiled_contracts = match deployed_libraries {
            // If deployed libraries have been specified then we will re-compile the contract as it
            // means that linking is required in this case.
            Some(_) => {
                debug!("Deployed libraries defined, recompilation must take place");
                debug!("Cache miss");
                compilation_callback()
                    .await
                    .context("Compilation callback for deployed libraries failed")?
                    .compiler_output
            }
            // If no deployed libraries are specified then we can follow the cached flow and attempt
            // to lookup the compilation artifacts in the cache.
            None => {
                debug!("Deployed libraries undefined, attempting to make use of cache");
                // Lock this specific cache key such that we do not get inconsistent state. We want
                // that when multiple cases come in asking for the compilation artifacts then they
                // don't all trigger a compilation if there's a cache miss. Hence, the lock here.
                let read_guard = self.cache_key_lock.read().await;
                let mutex = match read_guard.get(&cache_key).cloned() {
                    Some(value) => {
                        drop(read_guard);
                        value
                    }
                    None => {
                        drop(read_guard);
                        self.cache_key_lock
                            .write()
                            .await
                            .entry(cache_key.clone())
                            .or_default()
                            .clone()
                    }
                };
                let _guard = mutex.lock().await;
                match self.artifacts_cache.get(&cache_key).await {
                    Some(cache_value) => {
                        if deployed_libraries.is_some() {
                            reporter
                                .report_post_link_contracts_compilation_succeeded_event(
                                    compiler.version().clone(),
                                    compiler.path(),
                                    true,
                                    None,
                                    cache_value.compiler_output.clone(),
                                )
                                .expect("Can't happen");
                        } else {
                            reporter
                                .report_pre_link_contracts_compilation_succeeded_event(
                                    compiler.version().clone(),
                                    compiler.path(),
                                    true,
                                    None,
                                    cache_value.compiler_output.clone(),
                                )
                                .expect("Can't happen");
                        }
                        cache_value.compiler_output
                    }
                    None => {
                        let compiler_output = compilation_callback()
                            .await
                            .context("Compilation callback failed (cache miss path)")?
                            .compiler_output;
                        self.artifacts_cache
                            .insert(
                                &cache_key,
                                &CacheValue {
                                    compiler_output: compiler_output.clone(),
                                },
                            )
                            .await
                            .context(
                                "Failed to write the cached value of the compilation artifacts",
                            )?;
                        compiler_output
                    }
                }
            }
        };
        Ok(compiled_contracts)
    }
 }
 async fn compile_contracts(
    metadata_directory: impl AsRef<Path>,
    mut files_to_compile: impl Iterator<Item = PathBuf>,
    mode: &Mode,
    deployed_libraries: Option<&HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>>,
    compiler: &dyn SolidityCompiler,
    reporter: &ExecutionSpecificReporter,
 ) -> Result<CompilerOutput> {
    // Puts a limit on how many compilations we can perform at any given instance which helps us
    // with some of the errors we've been seeing with high concurrency on MacOS (we have not tried
    // it on Linux so we don't know if these issues also persist there or not.)
    static SPAWN_GATE: LazyLock<Semaphore> = LazyLock::new(|| Semaphore::new(5));
    let _permit = SPAWN_GATE.acquire().await?;
    let all_sources_in_dir = FilesWithExtensionIterator::new(metadata_directory.as_ref())
        .with_allowed_extension("sol")
        .with_use_cached_fs(true)
        .collect::<Vec<_>>();
    let compilation = Compiler::new()
        .with_allow_path(metadata_directory)
        // Handling the modes
        .with_optimization(mode.optimize_setting)
        .with_pipeline(mode.pipeline)
        // Adding the contract sources to the compiler.
        .try_then(|compiler| {
            files_to_compile.try_fold(compiler, |compiler, path| compiler.with_source(path))
        })?
        // Adding the deployed libraries to the compiler.
        .then(|compiler| {
            deployed_libraries
                .iter()
                .flat_map(|value| value.iter())
                .map(|(instance, (ident, address, abi))| (instance, ident, address, abi))
                .flat_map(|(_, ident, address, _)| {
                    all_sources_in_dir
                        .iter()
                        .map(move |path| (ident, address, path))
                })
                .fold(compiler, |compiler, (ident, address, path)| {
                    compiler.with_library(path, ident.as_str(), *address)
                })
        });
    let input = compilation.input().clone();
    let output = compilation.try_build(compiler).await;
    match (output.as_ref(), deployed_libraries.is_some()) {
        (Ok(output), true) => {
            reporter
                .report_post_link_contracts_compilation_succeeded_event(
                    compiler.version().clone(),
                    compiler.path(),
                    false,
                    input,
                    output.clone(),
                )
                .expect("Can't happen");
        }
        (Ok(output), false) => {
            reporter
                .report_pre_link_contracts_compilation_succeeded_event(
                    compiler.version().clone(),
                    compiler.path(),
                    false,
                    input,
                    output.clone(),
                )
                .expect("Can't happen");
        }
        (Err(err), true) => {
            reporter
                .report_post_link_contracts_compilation_failed_event(
                    compiler.version().clone(),
                    compiler.path().to_path_buf(),
                    input,
                    format!("{err:#}"),
                )
                .expect("Can't happen");
        }
        (Err(err), false) => {
            reporter
                .report_pre_link_contracts_compilation_failed_event(
                    compiler.version().clone(),
                    compiler.path().to_path_buf(),
                    input,
                    format!("{err:#}"),
                )
                .expect("Can't happen");
        }
    }
    output
 }
 struct ArtifactsCache {
    path: PathBuf,
 }
 impl ArtifactsCache {
    pub fn new(path: impl AsRef<Path>) -> Self {
        Self {
            path: path.as_ref().to_path_buf(),
        }
    }
    #[instrument(level = "debug", skip_all, err)]
    pub async fn with_invalidated_cache(self) -> Result<Self> {
        cacache::clear(self.path.as_path())
            .await
            .map_err(Into::<Error>::into)
            .with_context(|| format!("Failed to clear cache at {}", self.path.display()))?;
        Ok(self)
    }
    #[instrument(level = "debug", skip_all, err)]
    pub async fn insert(&self, key: &CacheKey<'_>, value: &CacheValue) -> Result<()> {
        let key = bson::to_vec(key).context("Failed to serialize cache key (bson)")?;
        let value = bson::to_vec(value).context("Failed to serialize cache value (bson)")?;
        cacache::write(self.path.as_path(), key.encode_hex(), value)
            .await
            .with_context(|| {
                format!("Failed to write cache entry under {}", self.path.display())
            })?;
        Ok(())
    }
    pub async fn get(&self, key: &CacheKey<'_>) -> Option<CacheValue> {
        let key = bson::to_vec(key).ok()?;
        let value = cacache::read(self.path.as_path(), key.encode_hex())
            .await
            .ok()?;
        let value = bson::from_slice::<CacheValue>(&value).ok()?;
        Some(value)
    }
 }
 #[derive(Clone, Debug, PartialEq, Eq, Hash, Serialize)]
 struct CacheKey<'a> {
    /// The identifier of the used compiler.
    compiler_identifier: CompilerIdentifier,
    /// The version of the compiler that was used to compile the artifacts.
    compiler_version: Version,
    /// The path of the metadata file that the compilation artifacts are for.
    metadata_file_path: &'a Path,
    /// The mode that the compilation artifacts where compiled with.
    solc_mode: Cow<'a, Mode>,
 }
 #[derive(Clone, Debug, Serialize, Deserialize)]
 struct CacheValue {
    /// The compiler output from the compilation run.
    compiler_output: CompilerOutput,
 }
 impl CacheValue {
    pub fn new(compiler_output: CompilerOutput) -> Self {
        Self { compiler_output }
    }
 }
@@ -0,0 +1,7 @@
 mod cached_compiler;
 mod pool;
 mod test;
 pub use cached_compiler::*;
 pub use pool::*;
 pub use test::*;
@@ -0,0 +1,59 @@
 //! This crate implements concurrent handling of testing node.
 use std::sync::atomic::{AtomicUsize, Ordering};
 use anyhow::Context as _;
 use revive_dt_config::*;
 use revive_dt_core::Platform;
 use revive_dt_node_interaction::EthereumNode;
 /// The node pool starts one or more [Node] which then can be accessed
 /// in a round robbin fashion.
 pub struct NodePool {
    next: AtomicUsize,
    nodes: Vec<Box<dyn EthereumNode + Send + Sync>>,
 }
 impl NodePool {
    /// Create a new Pool. This will start as many nodes as there are workers in `config`.
    pub async fn new(context: Context, platform: &dyn Platform) -> anyhow::Result<Self> {
        let concurrency_configuration = AsRef::<ConcurrencyConfiguration>::as_ref(&context);
        let nodes = concurrency_configuration.number_of_nodes;
        let mut handles = Vec::with_capacity(nodes);
        for _ in 0..nodes {
            let context = context.clone();
            handles.push(platform.new_node(context)?);
        }
        let mut nodes = Vec::with_capacity(nodes);
        for handle in handles {
            nodes.push(
                handle
                    .join()
                    .map_err(|error| anyhow::anyhow!("failed to spawn node: {:?}", error))
                    .context("Failed to join node spawn thread")?
                    .context("Node failed to spawn")?,
            );
        }
        let pre_transactions_tasks = nodes
            .iter_mut()
            .map(|node| node.pre_transactions())
            .collect::<Vec<_>>();
        futures::future::try_join_all(pre_transactions_tasks)
            .await
            .context("Failed to run the pre-transactions task")?;
        Ok(Self {
            nodes,
            next: Default::default(),
        })
    }
    /// Get a handle to the next node.
    pub fn round_robbin(&self) -> &dyn EthereumNode {
        let current = self.next.fetch_add(1, Ordering::SeqCst) % self.nodes.len();
        self.nodes.get(current).unwrap().as_ref()
    }
 }
@@ -0,0 +1,349 @@
 use std::collections::BTreeMap;
 use std::sync::Arc;
 use std::{borrow::Cow, path::Path};
 use futures::{Stream, StreamExt, stream};
 use indexmap::{IndexMap, indexmap};
 use revive_dt_common::types::PlatformIdentifier;
 use revive_dt_config::Context;
 use revive_dt_format::corpus::Corpus;
 use serde_json::{Value, json};
 use revive_dt_compiler::Mode;
 use revive_dt_compiler::SolidityCompiler;
 use revive_dt_format::{
    case::{Case, CaseIdx},
    metadata::MetadataFile,
 };
 use revive_dt_node_interaction::EthereumNode;
 use revive_dt_report::{ExecutionSpecificReporter, Report, Reporter, TestCaseStatus};
 use revive_dt_report::{TestSpecificReporter, TestSpecifier};
 use tracing::{debug, error, info};
 use crate::Platform;
 use crate::helpers::NodePool;
 pub async fn create_test_definitions_stream<'a>(
    // This is only required for creating the compiler objects and is not used anywhere else in the
    // function.
    context: &Context,
    corpus: &'a Corpus,
    platforms_and_nodes: &'a BTreeMap<PlatformIdentifier, (&dyn Platform, NodePool)>,
    only_execute_failed_tests: Option<&Report>,
    reporter: Reporter,
 ) -> impl Stream<Item = TestDefinition<'a>> {
    let cloned_reporter = reporter.clone();
    stream::iter(
        corpus
            .cases_iterator()
            .inspect(move |(metadata_file, ..)| {
                cloned_reporter
                    .report_metadata_file_discovery_event(
                        metadata_file.metadata_file_path.clone(),
                        metadata_file.content.clone(),
                    )
                    .unwrap();
            })
            .map(move |(metadata_file, case_idx, case, mode)| {
                let reporter = reporter.clone();
                (
                    metadata_file,
                    case_idx,
                    case,
                    mode.clone(),
                    reporter.test_specific_reporter(Arc::new(TestSpecifier {
                        solc_mode: mode.as_ref().clone(),
                        metadata_file_path: metadata_file.metadata_file_path.clone(),
                        case_idx: CaseIdx::new(case_idx),
                    })),
                )
            })
            // Inform the reporter of each one of the test cases that were discovered which we expect to
            // run.
            .inspect(|(_, _, _, _, reporter)| {
                reporter
                    .report_test_case_discovery_event()
                    .expect("Can't fail");
            }),
    )
    // Creating the Test Definition objects from all of the various objects we have and creating
    // their required dependencies (e.g., compiler).
    .filter_map(
        move |(metadata_file, case_idx, case, mode, reporter)| async move {
            let mut platforms = BTreeMap::new();
            for (platform, node_pool) in platforms_and_nodes.values() {
                let node = node_pool.round_robbin();
                let compiler = platform
                    .new_compiler(context.clone(), mode.version.clone().map(Into::into))
                    .await
                    .inspect_err(|err| {
                        error!(
                            ?err,
                            platform_identifier = %platform.platform_identifier(),
                            "Failed to instantiate the compiler"
                        )
                    })
                    .ok()?;
                reporter
                    .report_node_assigned_event(
                        node.id(),
                        platform.platform_identifier(),
                        node.connection_string(),
                    )
                    .expect("Can't fail");
                let reporter =
                    reporter.execution_specific_reporter(node.id(), platform.platform_identifier());
                platforms.insert(
                    platform.platform_identifier(),
                    TestPlatformInformation {
                        platform: *platform,
                        node,
                        compiler,
                        reporter,
                    },
                );
            }
            Some(TestDefinition {
                /* Metadata file information */
                metadata: metadata_file,
                metadata_file_path: metadata_file.metadata_file_path.as_path(),
                /* Mode Information */
                mode: mode.clone(),
                /* Case Information */
                case_idx: CaseIdx::new(case_idx),
                case,
                /* Platform and Node Assignment Information */
                platforms,
                /* Reporter */
                reporter,
            })
        },
    )
    // Filter out the test cases which are incompatible or that can't run in the current setup.
    .filter_map(move |test| async move {
        match test.check_compatibility(only_execute_failed_tests) {
            Ok(()) => Some(test),
            Err((reason, additional_information)) => {
                debug!(
                    metadata_file_path = %test.metadata.metadata_file_path.display(),
                    case_idx = %test.case_idx,
                    mode = %test.mode,
                    reason,
                    additional_information =
                        serde_json::to_string(&additional_information).unwrap(),
                    "Ignoring Test Case"
                );
                test.reporter
                    .report_test_ignored_event(
                        reason.to_string(),
                        additional_information
                            .into_iter()
                            .map(|(k, v)| (k.into(), v))
                            .collect::<IndexMap<_, _>>(),
                    )
                    .expect("Can't fail");
                None
            }
        }
    })
    .inspect(|test| {
        info!(
            metadata_file_path = %test.metadata_file_path.display(),
            case_idx = %test.case_idx,
            mode = %test.mode,
            "Created a test case definition"
        );
    })
 }
 /// This is a full description of a differential test to run alongside the full metadata file, the
 /// specific case to be tested, the platforms that the tests should run on, the specific nodes of
 /// these platforms that they should run on, the compilers to use, and everything else needed making
 /// it a complete description.
 pub struct TestDefinition<'a> {
    /* Metadata file information */
    pub metadata: &'a MetadataFile,
    pub metadata_file_path: &'a Path,
    /* Mode Information */
    pub mode: Cow<'a, Mode>,
    /* Case Information */
    pub case_idx: CaseIdx,
    pub case: &'a Case,
    /* Platform and Node Assignment Information */
    pub platforms: BTreeMap<PlatformIdentifier, TestPlatformInformation<'a>>,
    /* Reporter */
    pub reporter: TestSpecificReporter,
 }
 impl<'a> TestDefinition<'a> {
    /// Checks if this test can be ran with the current configuration.
    pub fn check_compatibility(
        &self,
        only_execute_failed_tests: Option<&Report>,
    ) -> TestCheckFunctionResult {
        self.check_metadata_file_ignored()?;
        self.check_case_file_ignored()?;
        self.check_target_compatibility()?;
        self.check_evm_version_compatibility()?;
        self.check_compiler_compatibility()?;
        self.check_ignore_succeeded(only_execute_failed_tests)?;
        Ok(())
    }
    /// Checks if the metadata file is ignored or not.
    fn check_metadata_file_ignored(&self) -> TestCheckFunctionResult {
        if self.metadata.ignore.is_some_and(|ignore| ignore) {
            Err(("Metadata file is ignored.", indexmap! {}))
        } else {
            Ok(())
        }
    }
    /// Checks if the case file is ignored or not.
    fn check_case_file_ignored(&self) -> TestCheckFunctionResult {
        if self.case.ignore.is_some_and(|ignore| ignore) {
            Err(("Case is ignored.", indexmap! {}))
        } else {
            Ok(())
        }
    }
    /// Checks if the platforms all support the desired targets in the metadata file.
    fn check_target_compatibility(&self) -> TestCheckFunctionResult {
        let mut error_map = indexmap! {
            "test_desired_targets" => json!(self.metadata.targets.as_ref()),
        };
        let mut is_allowed = true;
        for (_, platform_information) in self.platforms.iter() {
            let is_allowed_for_platform = match self.metadata.targets.as_ref() {
                None => true,
                Some(required_vm_identifiers) => {
                    required_vm_identifiers.contains(&platform_information.platform.vm_identifier())
                }
            };
            is_allowed &= is_allowed_for_platform;
            error_map.insert(
                platform_information.platform.platform_identifier().into(),
                json!(is_allowed_for_platform),
            );
        }
        if is_allowed {
            Ok(())
        } else {
            Err((
                "One of the platforms do do not support the targets allowed by the test.",
                error_map,
            ))
        }
    }
    // Checks for the compatibility of the EVM version with the platforms specified.
    fn check_evm_version_compatibility(&self) -> TestCheckFunctionResult {
        let Some(evm_version_requirement) = self.metadata.required_evm_version else {
            return Ok(());
        };
        let mut error_map = indexmap! {
            "test_desired_evm_version" => json!(self.metadata.required_evm_version),
        };
        let mut is_allowed = true;
        for (_, platform_information) in self.platforms.iter() {
            let is_allowed_for_platform =
                evm_version_requirement.matches(&platform_information.node.evm_version());
            is_allowed &= is_allowed_for_platform;
            error_map.insert(
                platform_information.platform.platform_identifier().into(),
                json!(is_allowed_for_platform),
            );
        }
        if is_allowed {
            Ok(())
        } else {
            Err((
                "EVM version is incompatible for the platforms specified",
                error_map,
            ))
        }
    }
    /// Checks if the platforms compilers support the mode that the test is for.
    fn check_compiler_compatibility(&self) -> TestCheckFunctionResult {
        let mut error_map = indexmap! {
            "test_desired_evm_version" => json!(self.metadata.required_evm_version),
        };
        let mut is_allowed = true;
        for (_, platform_information) in self.platforms.iter() {
            let is_allowed_for_platform = platform_information
                .compiler
                .supports_mode(self.mode.optimize_setting, self.mode.pipeline);
            is_allowed &= is_allowed_for_platform;
            error_map.insert(
                platform_information.platform.platform_identifier().into(),
                json!(is_allowed_for_platform),
            );
        }
        if is_allowed {
            Ok(())
        } else {
            Err((
                "Compilers do not support this mode either for the provided platforms.",
                error_map,
            ))
        }
    }
    /// Checks if the test case should be executed or not based on the passed report and whether the
    /// user has instructed the tool to ignore the already succeeding test cases.
    fn check_ignore_succeeded(
        &self,
        only_execute_failed_tests: Option<&Report>,
    ) -> TestCheckFunctionResult {
        let Some(report) = only_execute_failed_tests else {
            return Ok(());
        };
        let test_case_status = report
            .execution_information
            .get(&(self.metadata_file_path.to_path_buf().into()))
            .and_then(|obj| obj.case_reports.get(&self.case_idx))
            .and_then(|obj| obj.mode_execution_reports.get(&self.mode))
            .and_then(|obj| obj.status.as_ref());
        match test_case_status {
            Some(TestCaseStatus::Failed { .. }) => Ok(()),
            Some(TestCaseStatus::Ignored { .. }) => Err((
                "Ignored since it was ignored in a previous run",
                indexmap! {},
            )),
            Some(TestCaseStatus::Succeeded { .. }) => {
                Err(("Ignored since it succeeded in a prior run", indexmap! {}))
            }
            None => Ok(()),
        }
    }
 }
 pub struct TestPlatformInformation<'a> {
    pub platform: &'a dyn Platform,
    pub node: &'a dyn EthereumNode,
    pub compiler: Box<dyn SolidityCompiler>,
    pub reporter: ExecutionSpecificReporter,
 }
 type TestCheckFunctionResult = Result<(), (&'static str, IndexMap<&'static str, Value>)>;
@@ -3,45 +3,622 @@
 //! This crate defines the testing configuration and
 //! provides a helper utility to execute tests.
-use revive_dt_compiler::{SolidityCompiler, revive_resolc, solc};
+use std::{
-use revive_dt_config::TestingPlatform;
+    pin::Pin,
-use revive_dt_node::{geth, kitchensink::KitchensinkNode};
+    thread::{self, JoinHandle},
 };
 use alloy::genesis::Genesis;
 use anyhow::Context as _;
 use revive_dt_common::types::*;
 use revive_dt_compiler::{SolidityCompiler, revive_resolc::Resolc, solc::Solc};
 use revive_dt_config::*;
 use revive_dt_node::{
    Node, node_implementations::geth::GethNode,
    node_implementations::lighthouse_geth::LighthouseGethNode,
    node_implementations::substrate::SubstrateNode, node_implementations::zombienet::ZombienetNode,
 };
 use revive_dt_node_interaction::EthereumNode;
 use tracing::info;
-pub mod common;
+/// A trait that describes the interface for the platforms that are supported by the tool.
-pub mod driver;
+#[allow(clippy::type_complexity)]
 /// One platform can be tested differentially against another.
 ///
 /// For this we need a blockchain node implementation and a compiler.
 pub trait Platform {
-    type Blockchain: EthereumNode;
+    /// Returns the identifier of this platform. This is a combination of the node and the compiler
-    type Compiler: SolidityCompiler;
+    /// used.
    fn platform_identifier(&self) -> PlatformIdentifier;
-    /// Returns the matching [TestingPlatform] of the [revive_dt_config::Arguments].
+    /// Returns a full identifier for the platform.
-    fn config_id() -> TestingPlatform;
+    fn full_identifier(&self) -> (NodeIdentifier, VmIdentifier, CompilerIdentifier) {
        (
            self.node_identifier(),
            self.vm_identifier(),
            self.compiler_identifier(),
        )
    }
    /// Returns the identifier of the node used.
    fn node_identifier(&self) -> NodeIdentifier;
    /// Returns the identifier of the vm used.
    fn vm_identifier(&self) -> VmIdentifier;
    /// Returns the identifier of the compiler used.
    fn compiler_identifier(&self) -> CompilerIdentifier;
    /// Creates a new node for the platform by spawning a new thread, creating the node object,
    /// initializing it, spawning it, and waiting for it to start up.
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>>;
    /// Creates a new compiler for the provided platform
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>>;
    /// Exports the genesis/chainspec for the node.
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value>;
 }
-#[derive(Default)]
+#[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
-pub struct Geth;
+pub struct GethEvmSolcPlatform;
-impl Platform for Geth {
+impl Platform for GethEvmSolcPlatform {
-    type Blockchain = geth::Instance;
+    fn platform_identifier(&self) -> PlatformIdentifier {
-    type Compiler = solc::Solc;
+        PlatformIdentifier::GethEvmSolc
    }
-    fn config_id() -> TestingPlatform {
+    fn node_identifier(&self) -> NodeIdentifier {
-        TestingPlatform::Geth
+        NodeIdentifier::Geth
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::Evm
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Solc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = GethNode::new(context);
            let node = spawn_node::<GethNode>(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Solc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let genesis = AsRef::<GenesisConfiguration>::as_ref(&context).genesis()?;
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        let node_genesis = GethNode::node_genesis(genesis.clone(), &wallet);
        serde_json::to_value(node_genesis)
            .context("Failed to convert node genesis to a serde_value")
    }
 }
-#[derive(Default)]
+#[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
-pub struct Kitchensink;
+pub struct LighthouseGethEvmSolcPlatform;
-impl Platform for Kitchensink {
+impl Platform for LighthouseGethEvmSolcPlatform {
-    type Blockchain = KitchensinkNode;
+    fn platform_identifier(&self) -> PlatformIdentifier {
-    type Compiler = revive_resolc::Resolc;
+        PlatformIdentifier::LighthouseGethEvmSolc
    }
-    fn config_id() -> TestingPlatform {
+    fn node_identifier(&self) -> NodeIdentifier {
-        TestingPlatform::Kitchensink
+        NodeIdentifier::LighthouseGeth
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::Evm
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Solc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = LighthouseGethNode::new(context);
            let node = spawn_node::<LighthouseGethNode>(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Solc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let genesis = AsRef::<GenesisConfiguration>::as_ref(&context).genesis()?;
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        let node_genesis = LighthouseGethNode::node_genesis(genesis.clone(), &wallet);
        serde_json::to_value(node_genesis)
            .context("Failed to convert node genesis to a serde_value")
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
 pub struct KitchensinkPolkavmResolcPlatform;
 impl Platform for KitchensinkPolkavmResolcPlatform {
    fn platform_identifier(&self) -> PlatformIdentifier {
        PlatformIdentifier::KitchensinkPolkavmResolc
    }
    fn node_identifier(&self) -> NodeIdentifier {
        NodeIdentifier::Kitchensink
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::PolkaVM
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Resolc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let kitchensink_path = AsRef::<KitchensinkConfiguration>::as_ref(&context)
            .path
            .clone();
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = SubstrateNode::new(
                kitchensink_path,
                SubstrateNode::KITCHENSINK_EXPORT_CHAINSPEC_COMMAND,
                None,
                context,
                &[],
            );
            let node = spawn_node(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Resolc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let kitchensink_path = AsRef::<KitchensinkConfiguration>::as_ref(&context)
            .path
            .as_path();
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        let export_chainspec_command = SubstrateNode::KITCHENSINK_EXPORT_CHAINSPEC_COMMAND;
        SubstrateNode::node_genesis(kitchensink_path, export_chainspec_command, &wallet)
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
 pub struct KitchensinkRevmSolcPlatform;
 impl Platform for KitchensinkRevmSolcPlatform {
    fn platform_identifier(&self) -> PlatformIdentifier {
        PlatformIdentifier::KitchensinkRevmSolc
    }
    fn node_identifier(&self) -> NodeIdentifier {
        NodeIdentifier::Kitchensink
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::Evm
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Solc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let kitchensink_path = AsRef::<KitchensinkConfiguration>::as_ref(&context)
            .path
            .clone();
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = SubstrateNode::new(
                kitchensink_path,
                SubstrateNode::KITCHENSINK_EXPORT_CHAINSPEC_COMMAND,
                None,
                context,
                &[],
            );
            let node = spawn_node(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Solc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let kitchensink_path = AsRef::<KitchensinkConfiguration>::as_ref(&context)
            .path
            .as_path();
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        let export_chainspec_command = SubstrateNode::KITCHENSINK_EXPORT_CHAINSPEC_COMMAND;
        SubstrateNode::node_genesis(kitchensink_path, export_chainspec_command, &wallet)
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
 pub struct ReviveDevNodePolkavmResolcPlatform;
 impl Platform for ReviveDevNodePolkavmResolcPlatform {
    fn platform_identifier(&self) -> PlatformIdentifier {
        PlatformIdentifier::ReviveDevNodePolkavmResolc
    }
    fn node_identifier(&self) -> NodeIdentifier {
        NodeIdentifier::ReviveDevNode
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::PolkaVM
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Resolc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let revive_dev_node_configuration = AsRef::<ReviveDevNodeConfiguration>::as_ref(&context);
        let revive_dev_node_path = revive_dev_node_configuration.path.clone();
        let revive_dev_node_consensus = revive_dev_node_configuration.consensus.clone();
        let eth_rpc_connection_strings = revive_dev_node_configuration.existing_rpc_url.clone();
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = SubstrateNode::new(
                revive_dev_node_path,
                SubstrateNode::REVIVE_DEV_NODE_EXPORT_CHAINSPEC_COMMAND,
                Some(revive_dev_node_consensus),
                context,
                &eth_rpc_connection_strings,
            );
            let node = spawn_node(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Resolc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let revive_dev_node_path = AsRef::<ReviveDevNodeConfiguration>::as_ref(&context)
            .path
            .as_path();
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        let export_chainspec_command = SubstrateNode::REVIVE_DEV_NODE_EXPORT_CHAINSPEC_COMMAND;
        SubstrateNode::node_genesis(revive_dev_node_path, export_chainspec_command, &wallet)
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
 pub struct ReviveDevNodeRevmSolcPlatform;
 impl Platform for ReviveDevNodeRevmSolcPlatform {
    fn platform_identifier(&self) -> PlatformIdentifier {
        PlatformIdentifier::ReviveDevNodeRevmSolc
    }
    fn node_identifier(&self) -> NodeIdentifier {
        NodeIdentifier::ReviveDevNode
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::Evm
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Solc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let revive_dev_node_configuration = AsRef::<ReviveDevNodeConfiguration>::as_ref(&context);
        let revive_dev_node_path = revive_dev_node_configuration.path.clone();
        let revive_dev_node_consensus = revive_dev_node_configuration.consensus.clone();
        let eth_rpc_connection_strings = revive_dev_node_configuration.existing_rpc_url.clone();
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = SubstrateNode::new(
                revive_dev_node_path,
                SubstrateNode::REVIVE_DEV_NODE_EXPORT_CHAINSPEC_COMMAND,
                Some(revive_dev_node_consensus),
                context,
                &eth_rpc_connection_strings,
            );
            let node = spawn_node(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Solc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let revive_dev_node_path = AsRef::<ReviveDevNodeConfiguration>::as_ref(&context)
            .path
            .as_path();
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        let export_chainspec_command = SubstrateNode::REVIVE_DEV_NODE_EXPORT_CHAINSPEC_COMMAND;
        SubstrateNode::node_genesis(revive_dev_node_path, export_chainspec_command, &wallet)
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
 pub struct ZombienetPolkavmResolcPlatform;
 impl Platform for ZombienetPolkavmResolcPlatform {
    fn platform_identifier(&self) -> PlatformIdentifier {
        PlatformIdentifier::ZombienetPolkavmResolc
    }
    fn node_identifier(&self) -> NodeIdentifier {
        NodeIdentifier::Zombienet
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::PolkaVM
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Resolc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let polkadot_parachain_path = AsRef::<PolkadotParachainConfiguration>::as_ref(&context)
            .path
            .clone();
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = ZombienetNode::new(polkadot_parachain_path, context);
            let node = spawn_node(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Resolc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let polkadot_parachain_path = AsRef::<PolkadotParachainConfiguration>::as_ref(&context)
            .path
            .as_path();
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        ZombienetNode::node_genesis(polkadot_parachain_path, &wallet)
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Default, Hash)]
 pub struct ZombienetRevmSolcPlatform;
 impl Platform for ZombienetRevmSolcPlatform {
    fn platform_identifier(&self) -> PlatformIdentifier {
        PlatformIdentifier::ZombienetRevmSolc
    }
    fn node_identifier(&self) -> NodeIdentifier {
        NodeIdentifier::Zombienet
    }
    fn vm_identifier(&self) -> VmIdentifier {
        VmIdentifier::Evm
    }
    fn compiler_identifier(&self) -> CompilerIdentifier {
        CompilerIdentifier::Solc
    }
    fn new_node(
        &self,
        context: Context,
    ) -> anyhow::Result<JoinHandle<anyhow::Result<Box<dyn EthereumNode + Send + Sync>>>> {
        let genesis_configuration = AsRef::<GenesisConfiguration>::as_ref(&context);
        let polkadot_parachain_path = AsRef::<PolkadotParachainConfiguration>::as_ref(&context)
            .path
            .clone();
        let genesis = genesis_configuration.genesis()?.clone();
        Ok(thread::spawn(move || {
            let node = ZombienetNode::new(polkadot_parachain_path, context);
            let node = spawn_node(node, genesis)?;
            Ok(Box::new(node) as Box<_>)
        }))
    }
    fn new_compiler(
        &self,
        context: Context,
        version: Option<VersionOrRequirement>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Box<dyn SolidityCompiler>>>>> {
        Box::pin(async move {
            let compiler = Solc::new(context, version).await;
            compiler.map(|compiler| Box::new(compiler) as Box<dyn SolidityCompiler>)
        })
    }
    fn export_genesis(&self, context: Context) -> anyhow::Result<serde_json::Value> {
        let polkadot_parachain_path = AsRef::<PolkadotParachainConfiguration>::as_ref(&context)
            .path
            .as_path();
        let wallet = AsRef::<WalletConfiguration>::as_ref(&context).wallet();
        ZombienetNode::node_genesis(polkadot_parachain_path, &wallet)
    }
 }
 impl From<PlatformIdentifier> for Box<dyn Platform> {
    fn from(value: PlatformIdentifier) -> Self {
        match value {
            PlatformIdentifier::GethEvmSolc => Box::new(GethEvmSolcPlatform) as Box<_>,
            PlatformIdentifier::LighthouseGethEvmSolc => {
                Box::new(LighthouseGethEvmSolcPlatform) as Box<_>
            }
            PlatformIdentifier::KitchensinkPolkavmResolc => {
                Box::new(KitchensinkPolkavmResolcPlatform) as Box<_>
            }
            PlatformIdentifier::KitchensinkRevmSolc => {
                Box::new(KitchensinkRevmSolcPlatform) as Box<_>
            }
            PlatformIdentifier::ReviveDevNodePolkavmResolc => {
                Box::new(ReviveDevNodePolkavmResolcPlatform) as Box<_>
            }
            PlatformIdentifier::ReviveDevNodeRevmSolc => {
                Box::new(ReviveDevNodeRevmSolcPlatform) as Box<_>
            }
            PlatformIdentifier::ZombienetPolkavmResolc => {
                Box::new(ZombienetPolkavmResolcPlatform) as Box<_>
            }
            PlatformIdentifier::ZombienetRevmSolc => Box::new(ZombienetRevmSolcPlatform) as Box<_>,
        }
    }
 }
 impl From<PlatformIdentifier> for &dyn Platform {
    fn from(value: PlatformIdentifier) -> Self {
        match value {
            PlatformIdentifier::GethEvmSolc => &GethEvmSolcPlatform as &dyn Platform,
            PlatformIdentifier::LighthouseGethEvmSolc => {
                &LighthouseGethEvmSolcPlatform as &dyn Platform
            }
            PlatformIdentifier::KitchensinkPolkavmResolc => {
                &KitchensinkPolkavmResolcPlatform as &dyn Platform
            }
            PlatformIdentifier::KitchensinkRevmSolc => {
                &KitchensinkRevmSolcPlatform as &dyn Platform
            }
            PlatformIdentifier::ReviveDevNodePolkavmResolc => {
                &ReviveDevNodePolkavmResolcPlatform as &dyn Platform
            }
            PlatformIdentifier::ReviveDevNodeRevmSolc => {
                &ReviveDevNodeRevmSolcPlatform as &dyn Platform
            }
            PlatformIdentifier::ZombienetPolkavmResolc => {
                &ZombienetPolkavmResolcPlatform as &dyn Platform
            }
            PlatformIdentifier::ZombienetRevmSolc => &ZombienetRevmSolcPlatform as &dyn Platform,
        }
    }
 }
 fn spawn_node<T: Node + EthereumNode + Send + Sync>(
    mut node: T,
    genesis: Genesis,
 ) -> anyhow::Result<T> {
    info!(
        id = node.id(),
        connection_string = node.connection_string(),
        "Spawning node"
    );
    node.spawn(genesis)
        .context("Failed to spawn node process")?;
    info!(
        id = node.id(),
        connection_string = node.connection_string(),
        "Spawned node"
    );
    Ok(node)
 }
@@ -1,178 +1,96 @@
-use std::{collections::HashMap, sync::LazyLock};
+mod differential_benchmarks;
 mod differential_tests;
 mod helpers;
 use anyhow::Context as _;
 use clap::Parser;
-use rayon::{ThreadPoolBuilder, prelude::*};
+use revive_dt_report::ReportAggregator;
-
+use schemars::schema_for;
-use revive_dt_config::*;
+use tracing::{info, level_filters::LevelFilter};
 use revive_dt_core::{
    Geth, Kitchensink, Platform,
    driver::{Driver, State},
 };
 use revive_dt_format::{corpus::Corpus, metadata::MetadataFile};
 use revive_dt_node::pool::NodePool;
 use revive_dt_report::reporter::{Report, Span};
 use temp_dir::TempDir;
 use tracing::Level;
 use tracing_subscriber::{EnvFilter, FmtSubscriber};
-static TEMP_DIR: LazyLock<TempDir> = LazyLock::new(|| TempDir::new().unwrap());
+use revive_dt_config::Context;
 use revive_dt_core::Platform;
 use revive_dt_format::metadata::Metadata;
 use crate::{
    differential_benchmarks::handle_differential_benchmarks,
    differential_tests::handle_differential_tests,
 };
 fn main() -> anyhow::Result<()> {
-    let args = init_cli()?;
+    let (writer, _guard) = tracing_appender::non_blocking::NonBlockingBuilder::default()
        .lossy(false)
        // Assuming that each line contains 255 characters and that each character is one byte, then
        // this means that our buffer is about 4GBs large.
        .buffered_lines_limit(0x1000000)
        .thread_name("buffered writer")
        .finish(std::io::stdout());
    for (corpus, tests) in collect_corpora(&args)? {
        let span = Span::new(corpus, args.clone())?;
        match &args.compile_only {
            Some(platform) => compile_corpus(&args, &tests, platform, span),
            None => execute_corpus(&args, &tests, span)?,
        }
        Report::save()?;
    }
    Ok(())
 }
 fn init_cli() -> anyhow::Result<Arguments> {
    let subscriber = FmtSubscriber::builder()
-        .with_thread_ids(true)
+        .with_writer(writer)
-        .with_thread_names(true)
+        .with_thread_ids(false)
-        .with_env_filter(EnvFilter::from_default_env())
+        .with_thread_names(false)
        .with_env_filter(
            EnvFilter::builder()
                .with_default_directive(LevelFilter::OFF.into())
                .from_env_lossy(),
        )
        .with_ansi(false)
        .pretty()
        .finish();
    tracing::subscriber::set_global_default(subscriber)?;
    info!("Differential testing tool is starting");
-    let mut args = Arguments::parse();
+    let mut context = Context::try_parse()?;
    context.update_for_profile();
-    if args.corpus.is_empty() {
+    let (reporter, report_aggregator_task) = ReportAggregator::new(context.clone()).into_task();
        anyhow::bail!("no test corpus specified");
    }
-    match args.working_directory.as_ref() {
+    match context {
-        Some(dir) => {
+        Context::Test(context) => tokio::runtime::Builder::new_multi_thread()
-            if !dir.exists() {
+            .worker_threads(context.concurrency_configuration.number_of_threads)
-                anyhow::bail!("workdir {} does not exist", dir.display());
+            .enable_all()
-            }
+            .build()
            .expect("Failed building the Runtime")
            .block_on(async move {
                let differential_tests_handling_task =
                    handle_differential_tests(*context, reporter);
                futures::future::try_join(differential_tests_handling_task, report_aggregator_task)
                    .await?;
                Ok(())
            }),
        Context::Benchmark(context) => tokio::runtime::Builder::new_multi_thread()
            .worker_threads(context.concurrency_configuration.number_of_threads)
            .enable_all()
            .build()
            .expect("Failed building the Runtime")
            .block_on(async move {
                let differential_benchmarks_handling_task =
                    handle_differential_benchmarks(*context, reporter);
                futures::future::try_join(
                    differential_benchmarks_handling_task,
                    report_aggregator_task,
                )
                .await?;
                Ok(())
            }),
        Context::ExportGenesis(ref export_genesis_context) => {
            let platform = Into::<&dyn Platform>::into(export_genesis_context.platform);
            let genesis = platform.export_genesis(context)?;
            let genesis_json = serde_json::to_string_pretty(&genesis)
                .context("Failed to serialize the genesis to JSON")?;
            println!("{genesis_json}");
            Ok(())
        }
-        None => {
+        Context::ExportJsonSchema => {
-            args.temp_dir = Some(&TEMP_DIR);
+            let schema = schema_for!(Metadata);
            println!("{}", serde_json::to_string_pretty(&schema).unwrap());
            Ok(())
        }
    }
    tracing::info!("workdir: {}", args.directory().display());
    ThreadPoolBuilder::new()
        .num_threads(args.workers)
        .build_global()?;
    Ok(args)
 }
 fn collect_corpora(args: &Arguments) -> anyhow::Result<HashMap<Corpus, Vec<MetadataFile>>> {
    let mut corpora = HashMap::new();
    for path in &args.corpus {
        let corpus = Corpus::try_from_path(path)?;
        tracing::info!("found corpus: {}", path.display());
        let tests = corpus.enumerate_tests();
        tracing::info!("corpus '{}' contains {} tests", &corpus.name, tests.len());
        corpora.insert(corpus, tests);
    }
    Ok(corpora)
 }
 fn run_driver<L, F>(args: &Arguments, tests: &[MetadataFile], span: Span) -> anyhow::Result<()>
 where
    L: Platform,
    F: Platform,
    L::Blockchain: revive_dt_node::Node + Send + Sync + 'static,
    F::Blockchain: revive_dt_node::Node + Send + Sync + 'static,
 {
    let leader_nodes = NodePool::<L::Blockchain>::new(args)?;
    let follower_nodes = NodePool::<F::Blockchain>::new(args)?;
    tests.par_iter().for_each(
        |MetadataFile {
             content: metadata,
             path: metadata_file_path,
         }| {
            // Starting a new tracing span for this metadata file. This allows our logs to be clear
            // about which metadata file the logs belong to. We can add other information into this
            // as well to be able to associate the logs with the correct metadata file and case
            // that's being executed.
            let tracing_span = tracing::span!(
                Level::INFO,
                "Running driver",
                metadata_file_path = metadata_file_path.display().to_string(),
            );
            let _guard = tracing_span.enter();
            let mut driver = Driver::<L, F>::new(
                metadata,
                args,
                leader_nodes.round_robbin(),
                follower_nodes.round_robbin(),
            );
            let execution_result = driver.execute(span);
            tracing::info!(
                case_success_count = execution_result.successful_cases_count,
                case_failure_count = execution_result.failed_cases_count,
                "Execution completed"
            );
            let mut error_count = 0;
            for result in execution_result.results.iter() {
                if !result.is_success() {
                    tracing::error!(execution_error = ?result, "Encountered an error");
                    error_count += 1;
                }
            }
            if error_count == 0 {
                tracing::info!("Execution succeeded");
            } else {
                tracing::info!("Execution failed");
            }
        },
    );
    Ok(())
 }
 fn execute_corpus(args: &Arguments, tests: &[MetadataFile], span: Span) -> anyhow::Result<()> {
    match (&args.leader, &args.follower) {
        (TestingPlatform::Geth, TestingPlatform::Kitchensink) => {
            run_driver::<Geth, Kitchensink>(args, tests, span)?
        }
        (TestingPlatform::Geth, TestingPlatform::Geth) => {
            run_driver::<Geth, Geth>(args, tests, span)?
        }
        _ => unimplemented!(),
    }
    Ok(())
 }
 fn compile_corpus(
    config: &Arguments,
    tests: &[MetadataFile],
    platform: &TestingPlatform,
    span: Span,
 ) {
    tests.par_iter().for_each(|metadata| {
        for mode in &metadata.solc_modes() {
            match platform {
                TestingPlatform::Geth => {
                    let mut state = State::<Geth>::new(config, span);
                    let _ = state.build_contracts(mode, metadata);
                }
                TestingPlatform::Kitchensink => {
                    let mut state = State::<Kitchensink>::new(config, span);
                    let _ = state.build_contracts(mode, metadata);
                }
            };
        }
    });
 }
@@ -9,13 +9,22 @@ repository.workspace = true
 rust-version.workspace = true
 [dependencies]
-revive-dt-node-interaction = { workspace = true }
+revive-dt-common = { workspace = true }
 revive-common = { workspace = true }
 alloy = { workspace = true }
 alloy-primitives = { workspace = true }
 alloy-sol-types = { workspace = true }
 anyhow = { workspace = true }
 futures = { workspace = true }
 tracing = { workspace = true }
 schemars = { workspace = true }
 semver = { workspace = true }
 serde = { workspace = true, features = ["derive"] }
 serde_json = { workspace = true }
 itertools = { workspace = true }
 [dev-dependencies]
 tokio = { workspace = true }
 [lints]
 workspace = true
@@ -1,18 +1,117 @@
-use serde::Deserialize;
+use schemars::JsonSchema;
 use serde::{Deserialize, Serialize};
-use crate::{define_wrapper_type, input::Input, mode::Mode};
+use revive_dt_common::{
    macros::define_wrapper_type,
    types::{Mode, ParsedMode},
 };
-#[derive(Debug, Default, Deserialize, Clone, Eq, PartialEq)]
+use crate::steps::*;
 #[derive(Debug, Default, Serialize, Deserialize, Clone, Eq, PartialEq, JsonSchema)]
 pub struct Case {
    /// An optional name of the test case.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub name: Option<String>,
    /// An optional comment on the case which has no impact on the execution in any way.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub comment: Option<String>,
-    pub modes: Option<Vec<Mode>>,
+
-    pub inputs: Vec<Input>,
+    /// This represents a mode that has been parsed from test metadata.
    ///
    /// Mode strings can take the following form (in pseudo-regex):
    ///
    /// ```text
    /// [YEILV][+-]? (M[0123sz])? <semver>?
    /// ```
    ///
    /// If this is provided then it takes higher priority than the modes specified in the metadata
    /// file.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub modes: Option<Vec<ParsedMode>>,
    /// The set of steps to run as part of this test case.
    #[serde(rename = "inputs")]
    pub steps: Vec<Step>,
    /// An optional name of the group of tests that this test belongs to.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub group: Option<String>,
    /// An optional set of expectations and assertions to make about the transaction after it ran.
    ///
    /// If this is not specified then the only assertion that will be ran is that the transaction
    /// was successful.
    ///
    /// This expectation that's on the case itself will be attached to the final step of the case.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub expected: Option<Expected>,
    /// An optional boolean which defines if the case as a whole should be ignored. If null then the
    /// case will not be ignored.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub ignore: Option<bool>,
 }
 impl Case {
    pub fn steps_iterator(&self) -> impl Iterator<Item = Step> {
        let steps_len = self.steps.len();
        self.steps
            .clone()
            .into_iter()
            .enumerate()
            .map(move |(idx, mut step)| {
                let Step::FunctionCall(ref mut input) = step else {
                    return step;
                };
                if idx + 1 == steps_len {
                    if input.expected.is_none() {
                        input.expected = self.expected.clone();
                    }
                    // TODO: What does it mean for us to have an `expected` field on the case itself
                    // but the final input also has an expected field that doesn't match the one on
                    // the case? What are we supposed to do with that final expected field on the
                    // case?
                    step
                } else {
                    step
                }
            })
    }
    pub fn steps_iterator_for_benchmarks(
        &self,
        default_repeat_count: usize,
    ) -> Box<dyn Iterator<Item = Step> + '_> {
        let contains_repeat = self
            .steps_iterator()
            .any(|step| matches!(&step, Step::Repeat(..)));
        if contains_repeat {
            Box::new(self.steps_iterator()) as Box<_>
        } else {
            Box::new(std::iter::once(Step::Repeat(Box::new(RepeatStep {
                comment: None,
                repeat: default_repeat_count,
                steps: self.steps_iterator().collect(),
            })))) as Box<_>
        }
    }
    pub fn solc_modes(&self) -> Vec<Mode> {
        match &self.modes {
            Some(modes) => ParsedMode::many_to_modes(modes.iter()).collect(),
            None => Mode::all().cloned().collect(),
        }
    }
 }
 define_wrapper_type!(
    /// A wrapper type for the index of test cases found in metadata file.
-    #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
+    #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
-    CaseIdx(usize);
+    #[serde(transparent)]
    pub struct CaseIdx(usize) impl Display, FromStr;
 );
@@ -1,67 +1,200 @@
 use std::{
-    fs::File,
+    borrow::Cow,
    collections::HashMap,
    path::{Path, PathBuf},
 };
-use serde::{Deserialize, Serialize};
+use itertools::Itertools;
 use revive_dt_common::{
    iterators::{EitherIter, FilesWithExtensionIterator},
    types::{Mode, ParsedMode, ParsedTestSpecifier},
 };
 use tracing::{debug, warn};
-use crate::metadata::MetadataFile;
+use crate::{
    case::{Case, CaseIdx},
    metadata::{Metadata, MetadataFile},
 };
-#[derive(Clone, Debug, Default, Serialize, Deserialize, Eq, PartialEq, Hash)]
+#[derive(Default)]
 pub struct Corpus {
-    pub name: String,
+    test_specifiers: HashMap<ParsedTestSpecifier, Vec<PathBuf>>,
-    pub path: PathBuf,
+    metadata_files: HashMap<PathBuf, MetadataFile>,
 }
 impl Corpus {
-    /// Try to read and parse the corpus definition file at given `path`.
+    pub fn new() -> Self {
-    pub fn try_from_path(path: &Path) -> anyhow::Result<Self> {
+        Default::default()
        let file = File::open(path)?;
        Ok(serde_json::from_reader(file)?)
    }
-    /// Scan the corpus base directory and return all tests found.
+    pub fn with_test_specifier(
-    pub fn enumerate_tests(&self) -> Vec<MetadataFile> {
+        mut self,
-        let mut tests = Vec::new();
+        test_specifier: ParsedTestSpecifier,
-        collect_metadata(&self.path, &mut tests);
+    ) -> anyhow::Result<Self> {
-        tests
+        match &test_specifier {
-    }
+            ParsedTestSpecifier::FileOrDirectory {
-}
+                metadata_or_directory_file_path: metadata_file_path,
-
+            }
-/// Recursively walks `path` and parses any JSON or Solidity file into a test
+            | ParsedTestSpecifier::Case {
-/// definition [Metadata].
+                metadata_file_path, ..
-///
+            }
-/// Found tests are inserted into `tests`.
+            | ParsedTestSpecifier::CaseWithMode {
-///
+                metadata_file_path, ..
-/// `path` is expected to be a directory.
+            } => {
-pub fn collect_metadata(path: &Path, tests: &mut Vec<MetadataFile>) {
+                let metadata_files = enumerate_metadata_files(metadata_file_path);
-    let dir_entry = match std::fs::read_dir(path) {
+                self.test_specifiers.insert(
-        Ok(dir_entry) => dir_entry,
+                    test_specifier,
-        Err(error) => {
+                    metadata_files
-            tracing::error!("failed to read dir '{}': {error}", path.display());
+                        .iter()
-            return;
+                        .map(|metadata_file| metadata_file.metadata_file_path.clone())
-        }
+                        .collect(),
-    };
+                );
-
+                for metadata_file in metadata_files.into_iter() {
-    for entry in dir_entry {
+                    self.metadata_files
-        let entry = match entry {
+                        .insert(metadata_file.metadata_file_path.clone(), metadata_file);
-            Ok(entry) => entry,
+                }
            Err(error) => {
                tracing::error!("error reading dir entry: {error}");
                continue;
            }
        };
-        let path = entry.path();
+        Ok(self)
-        if path.is_dir() {
+    }
            collect_metadata(&path, tests);
            continue;
        }
-        if path.is_file() {
+    pub fn cases_iterator(
-            if let Some(metadata) = MetadataFile::try_from_file(&path) {
+        &self,
-                tests.push(metadata)
+    ) -> impl Iterator<Item = (&'_ MetadataFile, CaseIdx, &'_ Case, Cow<'_, Mode>)> + '_ {
        let mut iterator = Box::new(std::iter::empty())
            as Box<dyn Iterator<Item = (&'_ MetadataFile, CaseIdx, &'_ Case, Cow<'_, Mode>)> + '_>;
        for (test_specifier, metadata_file_paths) in self.test_specifiers.iter() {
            for metadata_file_path in metadata_file_paths {
                let metadata_file = self
                    .metadata_files
                    .get(metadata_file_path)
                    .expect("Must succeed");
                match test_specifier {
                    ParsedTestSpecifier::FileOrDirectory { .. } => {
                        for (case_idx, case) in metadata_file.cases.iter().enumerate() {
                            let case_idx = CaseIdx::new(case_idx);
                            let modes = case.modes.as_ref().or(metadata_file.modes.as_ref());
                            let modes = match modes {
                                Some(modes) => EitherIter::A(
                                    ParsedMode::many_to_modes(modes.iter())
                                        .map(Cow::<'static, _>::Owned),
                                ),
                                None => EitherIter::B(Mode::all().map(Cow::<'static, _>::Borrowed)),
                            };
                            iterator = Box::new(
                                iterator.chain(
                                    modes
                                        .into_iter()
                                        .map(move |mode| (metadata_file, case_idx, case, mode)),
                                ),
                            )
                        }
                    }
                    ParsedTestSpecifier::Case { case_idx, .. } => {
                        let Some(case) = metadata_file.cases.get(*case_idx) else {
                            warn!(
                                test_specifier = %test_specifier,
                                metadata_file_path = %metadata_file_path.display(),
                                case_idx = case_idx,
                                case_count = metadata_file.cases.len(),
                                "Specified case not found in metadata file"
                            );
                            continue;
                        };
                        let case_idx = CaseIdx::new(*case_idx);
                        let modes = case.modes.as_ref().or(metadata_file.modes.as_ref());
                        let modes = match modes {
                            Some(modes) => EitherIter::A(
                                ParsedMode::many_to_modes(modes.iter())
                                    .map(Cow::<'static, Mode>::Owned),
                            ),
                            None => EitherIter::B(Mode::all().map(Cow::<'static, _>::Borrowed)),
                        };
                        iterator = Box::new(
                            iterator.chain(
                                modes
                                    .into_iter()
                                    .map(move |mode| (metadata_file, case_idx, case, mode)),
                            ),
                        )
                    }
                    ParsedTestSpecifier::CaseWithMode { case_idx, mode, .. } => {
                        let Some(case) = metadata_file.cases.get(*case_idx) else {
                            warn!(
                                test_specifier = %test_specifier,
                                metadata_file_path = %metadata_file_path.display(),
                                case_idx = case_idx,
                                case_count = metadata_file.cases.len(),
                                "Specified case not found in metadata file"
                            );
                            continue;
                        };
                        let case_idx = CaseIdx::new(*case_idx);
                        let mode = Cow::Borrowed(mode);
                        iterator = Box::new(iterator.chain(std::iter::once((
                            metadata_file,
                            case_idx,
                            case,
                            mode,
                        ))))
                    }
                }
            }
        }
        iterator.unique_by(|item| (&item.0.metadata_file_path, item.1, item.3.clone()))
    }
    pub fn metadata_file_count(&self) -> usize {
        self.metadata_files.len()
    }
 }
 fn enumerate_metadata_files(path: impl AsRef<Path>) -> Vec<MetadataFile> {
    let root_path = path.as_ref();
    let mut tests = if !root_path.is_dir() {
        Box::new(std::iter::once(root_path.to_path_buf())) as Box<dyn Iterator<Item = _>>
    } else {
        Box::new(
            FilesWithExtensionIterator::new(root_path)
                .with_use_cached_fs(true)
                .with_allowed_extension("sol")
                .with_allowed_extension("json"),
        )
    }
    .map(move |metadata_file_path| (root_path, metadata_file_path))
    .filter_map(|(root_path, metadata_file_path)| {
        Metadata::try_from_file(&metadata_file_path)
            .or_else(|| {
                debug!(
                    discovered_from = %root_path.display(),
                    metadata_file_path = %metadata_file_path.display(),
                    "Skipping file since it doesn't contain valid metadata"
                );
                None
            })
            .map(|metadata| MetadataFile {
                metadata_file_path,
                corpus_file_path: root_path.to_path_buf(),
                content: metadata,
            })
            .inspect(|metadata_file| {
                debug!(
                    metadata_file_path = %metadata_file.relative_path().display(),
                    "Loaded metadata file"
                )
            })
    })
    .collect::<Vec<_>>();
    tests.sort_by(|a, b| a.metadata_file_path.cmp(&b.metadata_file_path));
    tests.dedup_by(|a, b| a.metadata_file_path == b.metadata_file_path);
    tests
 }
@@ -1,670 +0,0 @@
 use std::collections::HashMap;
 use alloy::{
    eips::BlockNumberOrTag,
    json_abi::JsonAbi,
    network::TransactionBuilder,
    primitives::{Address, Bytes, U256},
    rpc::types::TransactionRequest,
 };
 use semver::VersionReq;
 use serde::Deserialize;
 use serde_json::Value;
 use revive_dt_node_interaction::EthereumNode;
 use crate::metadata::ContractInstance;
 #[derive(Clone, Debug, Default, Deserialize, Eq, PartialEq)]
 pub struct Input {
    #[serde(default = "default_caller")]
    pub caller: Address,
    pub comment: Option<String>,
    #[serde(default = "default_instance")]
    pub instance: ContractInstance,
    pub method: Method,
    #[serde(default)]
    pub calldata: Calldata,
    pub expected: Option<Expected>,
    pub value: Option<String>,
    pub storage: Option<HashMap<String, Calldata>>,
 }
 #[derive(Clone, Debug, Deserialize, Eq, PartialEq)]
 #[serde(untagged)]
 pub enum Expected {
    Calldata(Calldata),
    Expected(ExpectedOutput),
    ExpectedMany(Vec<ExpectedOutput>),
 }
 #[derive(Clone, Debug, Default, Deserialize, Eq, PartialEq)]
 pub struct ExpectedOutput {
    compiler_version: Option<VersionReq>,
    return_data: Option<Calldata>,
    events: Option<Value>,
    exception: Option<bool>,
 }
 #[derive(Clone, Debug, Deserialize, Eq, PartialEq)]
 #[serde(untagged)]
 pub enum Calldata {
    Single(String),
    Compound(Vec<String>),
 }
 /// Specify how the contract is called.
 #[derive(Debug, Default, Deserialize, Clone, Eq, PartialEq)]
 pub enum Method {
    /// Initiate a deploy transaction, calling contracts constructor.
    ///
    /// Indicated by `#deployer`.
    #[serde(rename = "#deployer")]
    Deployer,
    /// Does not calculate and insert a function selector.
    ///
    /// Indicated by `#fallback`.
    #[default]
    #[serde(rename = "#fallback")]
    Fallback,
    /// Call the public function with the given name.
    #[serde(untagged)]
    FunctionName(String),
 }
 impl Default for Calldata {
    fn default() -> Self {
        Self::Compound(Default::default())
    }
 }
 impl Calldata {
    pub fn find_all_contract_instances(&self, vec: &mut Vec<ContractInstance>) {
        if let Calldata::Compound(compound) = self {
            for item in compound {
                if let Some(instance) = item.strip_suffix(".address") {
                    vec.push(ContractInstance::new_from(instance))
                }
            }
        }
    }
    pub fn construct_call_data(
        &self,
        buffer: &mut Vec<u8>,
        deployed_contracts: &HashMap<ContractInstance, (Address, JsonAbi)>,
        chain_state_provider: &impl EthereumNode,
    ) -> anyhow::Result<()> {
        match self {
            Calldata::Single(string) => {
                alloy::hex::decode_to_slice(string, buffer)?;
            }
            Calldata::Compound(items) => {
                for (arg_idx, arg) in items.iter().enumerate() {
                    match resolve_argument(arg, deployed_contracts, chain_state_provider) {
                        Ok(resolved) => {
                            buffer.extend(resolved.to_be_bytes::<32>());
                        }
                        Err(error) => {
                            tracing::error!(arg, arg_idx, ?error, "Failed to resolve argument");
                            return Err(error);
                        }
                    };
                }
            }
        };
        Ok(())
    }
    pub fn size_requirement(&self) -> usize {
        match self {
            Calldata::Single(single) => (single.len() - 2) / 2,
            Calldata::Compound(items) => items.len() * 32,
        }
    }
 }
 impl ExpectedOutput {
    pub fn find_all_contract_instances(&self, vec: &mut Vec<ContractInstance>) {
        if let Some(ref cd) = self.return_data {
            cd.find_all_contract_instances(vec);
        }
    }
 }
 impl Input {
    fn instance_to_address(
        &self,
        instance: &ContractInstance,
        deployed_contracts: &HashMap<ContractInstance, (Address, JsonAbi)>,
    ) -> anyhow::Result<Address> {
        deployed_contracts
            .get(instance)
            .map(|(a, _)| *a)
            .ok_or_else(|| anyhow::anyhow!("instance {instance:?} not deployed"))
    }
    pub fn encoded_input(
        &self,
        deployed_contracts: &HashMap<ContractInstance, (Address, JsonAbi)>,
        chain_state_provider: &impl EthereumNode,
    ) -> anyhow::Result<Bytes> {
        match self.method {
            Method::Deployer | Method::Fallback => {
                let mut calldata = Vec::<u8>::with_capacity(self.calldata.size_requirement());
                self.calldata.construct_call_data(
                    &mut calldata,
                    deployed_contracts,
                    chain_state_provider,
                )?;
                Ok(calldata.into())
            }
            Method::FunctionName(ref function_name) => {
                let Some(abi) = deployed_contracts.get(&self.instance).map(|(_, a)| a) else {
                    tracing::error!(
                        contract_name = self.instance.as_ref(),
                        available_abis = ?deployed_contracts.keys().collect::<Vec<_>>(),
                        "Attempted to lookup ABI of contract but it wasn't found"
                    );
                    anyhow::bail!("ABI for instance '{}' not found", self.instance.as_ref());
                };
                tracing::trace!("ABI found for instance: {}", &self.instance.as_ref());
                // We follow the same logic that's implemented in the matter-labs-tester where they resolve
                // the function name into a function selector and they assume that he function doesn't have
                // any existing overloads.
                // https://github.com/matter-labs/era-compiler-tester/blob/1dfa7d07cba0734ca97e24704f12dd57f6990c2c/compiler_tester/src/test/case/input/mod.rs#L158-L190
                let function = abi
                    .functions()
                    .find(|function| function.signature().starts_with(function_name))
                    .ok_or_else(|| {
                        anyhow::anyhow!(
                            "Function with name {:?} not found in ABI for the instance {:?}",
                            function_name,
                            &self.instance
                        )
                    })?;
                tracing::trace!("Functions found for instance: {}", self.instance.as_ref());
                tracing::trace!(
                    "Starting encoding ABI's parameters for instance: {}",
                    self.instance.as_ref()
                );
                // Allocating a vector that we will be using for the calldata. The vector size will be:
                // 4 bytes for the function selector.
                // function.inputs.len() * 32 bytes for the arguments (each argument is a U256).
                //
                // We're using indices in the following code in order to avoid the need for us to allocate
                // a new buffer for each one of the resolved arguments.
                let mut calldata = Vec::<u8>::with_capacity(4 + self.calldata.size_requirement());
                calldata.extend(function.selector().0);
                self.calldata.construct_call_data(
                    &mut calldata,
                    deployed_contracts,
                    chain_state_provider,
                )?;
                Ok(calldata.into())
            }
        }
    }
    /// Parse this input into a legacy transaction.
    pub fn legacy_transaction(
        &self,
        deployed_contracts: &HashMap<ContractInstance, (Address, JsonAbi)>,
        chain_state_provider: &impl EthereumNode,
    ) -> anyhow::Result<TransactionRequest> {
        let input_data = self.encoded_input(deployed_contracts, chain_state_provider)?;
        let transaction_request = TransactionRequest::default();
        match self.method {
            Method::Deployer => Ok(transaction_request.with_deploy_code(input_data)),
            _ => Ok(transaction_request
                .to(self.instance_to_address(&self.instance, deployed_contracts)?)
                .input(input_data.into())),
        }
    }
    pub fn find_all_contract_instances(&self) -> Vec<ContractInstance> {
        let mut vec = Vec::new();
        vec.push(self.instance.clone());
        self.calldata.find_all_contract_instances(&mut vec);
        match &self.expected {
            Some(Expected::Calldata(cd)) => {
                cd.find_all_contract_instances(&mut vec);
            }
            Some(Expected::Expected(expected)) => {
                expected.find_all_contract_instances(&mut vec);
            }
            Some(Expected::ExpectedMany(expected)) => {
                for expected in expected {
                    expected.find_all_contract_instances(&mut vec);
                }
            }
            None => {}
        }
        vec
    }
 }
 fn default_instance() -> ContractInstance {
    ContractInstance::new_from("Test")
 }
 fn default_caller() -> Address {
    "90F8bf6A479f320ead074411a4B0e7944Ea8c9C1".parse().unwrap()
 }
 /// This function takes in the string calldata argument provided in the JSON input and resolves it
 /// into a [`U256`] which is later used to construct the calldata.
 ///
 /// # Note
 ///
 /// This piece of code is taken from the matter-labs-tester repository which is licensed under MIT
 /// or Apache. The original source code can be found here:
 /// https://github.com/matter-labs/era-compiler-tester/blob/0ed598a27f6eceee7008deab3ff2311075a2ec69/compiler_tester/src/test/case/input/value.rs#L43-L146
 fn resolve_argument(
    value: &str,
    deployed_contracts: &HashMap<ContractInstance, (Address, JsonAbi)>,
    chain_state_provider: &impl EthereumNode,
 ) -> anyhow::Result<U256> {
    if let Some(instance) = value.strip_suffix(".address") {
        Ok(U256::from_be_slice(
            deployed_contracts
                .get(&ContractInstance::new_from(instance))
                .map(|(a, _)| *a)
                .ok_or_else(|| anyhow::anyhow!("Instance `{}` not found", instance))?
                .as_ref(),
        ))
    } else if let Some(value) = value.strip_prefix('-') {
        let value = U256::from_str_radix(value, 10)
            .map_err(|error| anyhow::anyhow!("Invalid decimal literal after `-`: {}", error))?;
        if value > U256::ONE << 255u8 {
            anyhow::bail!("Decimal literal after `-` is too big");
        }
        let value = value
            .checked_sub(U256::ONE)
            .ok_or_else(|| anyhow::anyhow!("`-0` is invalid literal"))?;
        Ok(U256::MAX.checked_sub(value).expect("Always valid"))
    } else if let Some(value) = value.strip_prefix("0x") {
        Ok(U256::from_str_radix(value, 16)
            .map_err(|error| anyhow::anyhow!("Invalid hexadecimal literal: {}", error))?)
    } else if value == "$CHAIN_ID" {
        let chain_id = chain_state_provider.chain_id()?;
        Ok(U256::from(chain_id))
    } else if value == "$GAS_LIMIT" {
        let gas_limit = chain_state_provider.block_gas_limit(BlockNumberOrTag::Latest)?;
        Ok(U256::from(gas_limit))
    } else if value == "$COINBASE" {
        let coinbase = chain_state_provider.block_coinbase(BlockNumberOrTag::Latest)?;
        Ok(U256::from_be_slice(coinbase.as_ref()))
    } else if value == "$DIFFICULTY" {
        let block_difficulty = chain_state_provider.block_difficulty(BlockNumberOrTag::Latest)?;
        Ok(block_difficulty)
    } else if value.starts_with("$BLOCK_HASH") {
        let offset: u64 = value
            .split(':')
            .next_back()
            .and_then(|value| value.parse().ok())
            .unwrap_or_default();
        let current_block_number = chain_state_provider.last_block_number()?;
        let desired_block_number = current_block_number - offset;
        let block_hash = chain_state_provider.block_hash(desired_block_number.into())?;
        Ok(U256::from_be_bytes(block_hash.0))
    } else if value == "$BLOCK_NUMBER" {
        let current_block_number = chain_state_provider.last_block_number()?;
        Ok(U256::from(current_block_number))
    } else if value == "$BLOCK_TIMESTAMP" {
        let timestamp = chain_state_provider.block_timestamp(BlockNumberOrTag::Latest)?;
        Ok(U256::from(timestamp))
    } else {
        Ok(U256::from_str_radix(value, 10)
            .map_err(|error| anyhow::anyhow!("Invalid decimal literal: {}", error))?)
    }
 }
 #[cfg(test)]
 mod tests {
    use super::*;
    use alloy::json_abi::JsonAbi;
    use alloy_primitives::address;
    use alloy_sol_types::SolValue;
    use std::collections::HashMap;
    struct DummyEthereumNode;
    impl EthereumNode for DummyEthereumNode {
        fn execute_transaction(
            &self,
            _: TransactionRequest,
        ) -> anyhow::Result<alloy::rpc::types::TransactionReceipt> {
            unimplemented!()
        }
        fn trace_transaction(
            &self,
            _: alloy::rpc::types::TransactionReceipt,
        ) -> anyhow::Result<alloy::rpc::types::trace::geth::GethTrace> {
            unimplemented!()
        }
        fn state_diff(
            &self,
            _: alloy::rpc::types::TransactionReceipt,
        ) -> anyhow::Result<alloy::rpc::types::trace::geth::DiffMode> {
            unimplemented!()
        }
        fn fetch_add_nonce(&self, _: Address) -> anyhow::Result<u64> {
            unimplemented!()
        }
        fn chain_id(&self) -> anyhow::Result<alloy_primitives::ChainId> {
            Ok(0x123)
        }
        fn block_gas_limit(&self, _: alloy::eips::BlockNumberOrTag) -> anyhow::Result<u128> {
            Ok(0x1234)
        }
        fn block_coinbase(&self, _: alloy::eips::BlockNumberOrTag) -> anyhow::Result<Address> {
            Ok(Address::ZERO)
        }
        fn block_difficulty(&self, _: alloy::eips::BlockNumberOrTag) -> anyhow::Result<U256> {
            Ok(U256::from(0x12345u128))
        }
        fn block_hash(
            &self,
            _: alloy::eips::BlockNumberOrTag,
        ) -> anyhow::Result<alloy_primitives::BlockHash> {
            Ok([0xEE; 32].into())
        }
        fn block_timestamp(
            &self,
            _: alloy::eips::BlockNumberOrTag,
        ) -> anyhow::Result<alloy_primitives::BlockTimestamp> {
            Ok(0x123456)
        }
        fn last_block_number(&self) -> anyhow::Result<alloy_primitives::BlockNumber> {
            Ok(0x1234567)
        }
    }
    #[test]
    fn test_encoded_input_uint256() {
        let raw_metadata = r#"
            [
                {
                    "inputs": [{"name": "value", "type": "uint256"}],
                    "name": "store",
                    "outputs": [],
                    "stateMutability": "nonpayable",
                    "type": "function"
                }
            ]
        "#;
        let parsed_abi: JsonAbi = serde_json::from_str(raw_metadata).unwrap();
        let selector = parsed_abi
            .function("store")
            .unwrap()
            .first()
            .unwrap()
            .selector()
            .0;
        let input = Input {
            instance: ContractInstance::new_from("Contract"),
            method: Method::FunctionName("store".to_owned()),
            calldata: Calldata::Compound(vec!["42".into()]),
            ..Default::default()
        };
        let mut contracts = HashMap::new();
        contracts.insert(
            ContractInstance::new_from("Contract"),
            (Address::ZERO, parsed_abi),
        );
        let encoded = input.encoded_input(&contracts, &DummyEthereumNode).unwrap();
        assert!(encoded.0.starts_with(&selector));
        type T = (u64,);
        let decoded: T = T::abi_decode(&encoded.0[4..]).unwrap();
        assert_eq!(decoded.0, 42);
    }
    #[test]
    fn test_encoded_input_address_with_signature() {
        let raw_abi = r#"[
        {
            "inputs": [{"name": "recipient", "type": "address"}],
            "name": "send",
            "outputs": [],
            "stateMutability": "nonpayable",
            "type": "function"
        }
        ]"#;
        let parsed_abi: JsonAbi = serde_json::from_str(raw_abi).unwrap();
        let selector = parsed_abi
            .function("send")
            .unwrap()
            .first()
            .unwrap()
            .selector()
            .0;
        let input: Input = Input {
            instance: "Contract".to_owned().into(),
            method: Method::FunctionName("send(address)".to_owned()),
            calldata: Calldata::Compound(vec![
                "0x1000000000000000000000000000000000000001".to_string(),
            ]),
            ..Default::default()
        };
        let mut contracts = HashMap::new();
        contracts.insert(
            ContractInstance::new_from("Contract"),
            (Address::ZERO, parsed_abi),
        );
        let encoded = input.encoded_input(&contracts, &DummyEthereumNode).unwrap();
        assert!(encoded.0.starts_with(&selector));
        type T = (alloy_primitives::Address,);
        let decoded: T = T::abi_decode(&encoded.0[4..]).unwrap();
        assert_eq!(
            decoded.0,
            address!("0x1000000000000000000000000000000000000001")
        );
    }
    #[test]
    fn test_encoded_input_address() {
        let raw_abi = r#"[
        {
            "inputs": [{"name": "recipient", "type": "address"}],
            "name": "send",
            "outputs": [],
            "stateMutability": "nonpayable",
            "type": "function"
        }
        ]"#;
        let parsed_abi: JsonAbi = serde_json::from_str(raw_abi).unwrap();
        let selector = parsed_abi
            .function("send")
            .unwrap()
            .first()
            .unwrap()
            .selector()
            .0;
        let input: Input = Input {
            instance: ContractInstance::new_from("Contract"),
            method: Method::FunctionName("send".to_owned()),
            calldata: Calldata::Compound(vec![
                "0x1000000000000000000000000000000000000001".to_string(),
            ]),
            ..Default::default()
        };
        let mut contracts = HashMap::new();
        contracts.insert(
            ContractInstance::new_from("Contract"),
            (Address::ZERO, parsed_abi),
        );
        let encoded = input.encoded_input(&contracts, &DummyEthereumNode).unwrap();
        assert!(encoded.0.starts_with(&selector));
        type T = (alloy_primitives::Address,);
        let decoded: T = T::abi_decode(&encoded.0[4..]).unwrap();
        assert_eq!(
            decoded.0,
            address!("0x1000000000000000000000000000000000000001")
        );
    }
    #[test]
    fn resolver_can_resolve_chain_id_variable() {
        // Arrange
        let input = "$CHAIN_ID";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(resolved, U256::from(DummyEthereumNode.chain_id().unwrap()))
    }
    #[test]
    fn resolver_can_resolve_gas_limit_variable() {
        // Arrange
        let input = "$GAS_LIMIT";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(
            resolved,
            U256::from(
                DummyEthereumNode
                    .block_gas_limit(Default::default())
                    .unwrap()
            )
        )
    }
    #[test]
    fn resolver_can_resolve_coinbase_variable() {
        // Arrange
        let input = "$COINBASE";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(
            resolved,
            U256::from_be_slice(
                DummyEthereumNode
                    .block_coinbase(Default::default())
                    .unwrap()
                    .as_ref()
            )
        )
    }
    #[test]
    fn resolver_can_resolve_block_difficulty_variable() {
        // Arrange
        let input = "$DIFFICULTY";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(
            resolved,
            DummyEthereumNode
                .block_difficulty(Default::default())
                .unwrap()
        )
    }
    #[test]
    fn resolver_can_resolve_block_hash_variable() {
        // Arrange
        let input = "$BLOCK_HASH";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(
            resolved,
            U256::from_be_bytes(DummyEthereumNode.block_hash(Default::default()).unwrap().0)
        )
    }
    #[test]
    fn resolver_can_resolve_block_number_variable() {
        // Arrange
        let input = "$BLOCK_NUMBER";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(
            resolved,
            U256::from(DummyEthereumNode.last_block_number().unwrap())
        )
    }
    #[test]
    fn resolver_can_resolve_block_timestamp_variable() {
        // Arrange
        let input = "$BLOCK_TIMESTAMP";
        // Act
        let resolved = resolve_argument(input, &Default::default(), &DummyEthereumNode);
        // Assert
        let resolved = resolved.expect("Failed to resolve argument");
        assert_eq!(
            resolved,
            U256::from(
                DummyEthereumNode
                    .block_timestamp(Default::default())
                    .unwrap()
            )
        )
    }
 }
@@ -2,7 +2,6 @@
 pub mod case;
 pub mod corpus;
 pub mod input;
 pub mod macros;
 pub mod metadata;
-pub mod mode;
+pub mod steps;
 pub mod traits;
@@ -1,19 +1,26 @@
 use std::{
    cmp::Ordering,
    collections::BTreeMap,
    fmt::Display,
-    fs::{File, read_to_string},
+    fs::File,
    ops::Deref,
    path::{Path, PathBuf},
    str::FromStr,
 };
 use schemars::JsonSchema;
 use serde::{Deserialize, Serialize};
-use crate::{
+use revive_common::EVMVersion;
-    case::Case,
+use revive_dt_common::{
-    define_wrapper_type,
+    cached_fs::read_to_string,
-    mode::{Mode, SolcMode},
+    iterators::FilesWithExtensionIterator,
    macros::define_wrapper_type,
    types::{Mode, ParsedMode, VmIdentifier},
 };
 use tracing::error;
 use crate::case::Case;
 pub const METADATA_FILE_EXTENSION: &str = "json";
 pub const SOLIDITY_CASE_FILE_EXTENSION: &str = "sol";
@@ -21,16 +28,26 @@ pub const SOLIDITY_CASE_COMMENT_MARKER: &str = "//!";
 #[derive(Debug, Default, Deserialize, Clone, Eq, PartialEq)]
 pub struct MetadataFile {
-    pub path: PathBuf,
+    /// The path of the metadata file. This will either be a JSON or solidity file.
    pub metadata_file_path: PathBuf,
    /// This is the path contained within the corpus file. This could either be the path of some dir
    /// or could be the actual metadata file path.
    pub corpus_file_path: PathBuf,
    /// The metadata contained within the file.
    pub content: Metadata,
 }
 impl MetadataFile {
-    pub fn try_from_file(path: &Path) -> Option<Self> {
+    pub fn relative_path(&self) -> &Path {
-        Metadata::try_from_file(path).map(|metadata| Self {
+        if self.corpus_file_path.is_file() {
-            path: path.to_owned(),
+            &self.corpus_file_path
-            content: metadata,
+        } else {
-        })
+            self.metadata_file_path
                .strip_prefix(&self.corpus_file_path)
                .unwrap()
        }
    }
 }
@@ -42,33 +59,83 @@ impl Deref for MetadataFile {
    }
 }
-#[derive(Debug, Default, Deserialize, Clone, Eq, PartialEq)]
+/// A MatterLabs metadata file.
 ///
 /// This defines the structure that the MatterLabs metadata files follow for defining the tests or
 /// the workloads.
 ///
 /// Each metadata file is composed of multiple test cases where each test case is isolated from the
 /// others and runs in a completely different address space. Each test case is composed of a number
 /// of steps and assertions that should be performed as part of the test case.
 #[derive(Debug, Default, Serialize, Deserialize, JsonSchema, Clone, Eq, PartialEq)]
 pub struct Metadata {
-    pub cases: Vec<Case>,
+    /// This is an optional comment on the metadata file which has no impact on the execution in any
-    pub contracts: Option<BTreeMap<ContractInstance, ContractPathAndIdentifier>>,
+    /// way.
-    // TODO: Convert into wrapper types for clarity.
+    #[serde(skip_serializing_if = "Option::is_none")]
-    pub libraries: Option<BTreeMap<String, BTreeMap<String, String>>>,
+    pub comment: Option<String>,
    /// An optional boolean which defines if the metadata file as a whole should be ignored. If null
    /// then the metadata file will not be ignored.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub ignore: Option<bool>,
-    pub modes: Option<Vec<Mode>>,
+
    /// An optional vector of targets that this Metadata file's cases can be executed on. As an
    /// example, if we wish for the metadata file's cases to only be run on PolkaVM then we'd
    /// specify a target of "PolkaVM" in here.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub targets: Option<Vec<VmIdentifier>>,
    /// A vector of the test cases and workloads contained within the metadata file. This is their
    /// primary description.
    pub cases: Vec<Case>,
    /// A map of all of the contracts that the test requires to run.
    ///
    /// This is a map where the key is the name of the contract instance and the value is the
    /// contract's path and ident in the file.
    ///
    /// If any contract is to be used by the test then it must be included in here first so that the
    /// framework is aware of its path, compiles it, and prepares it.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub contracts: Option<BTreeMap<ContractInstance, ContractPathAndIdent>>,
    /// The set of libraries that this metadata file requires.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub libraries: Option<BTreeMap<PathBuf, BTreeMap<ContractIdent, ContractInstance>>>,
    /// This represents a mode that has been parsed from test metadata.
    ///
    /// Mode strings can take the following form (in pseudo-regex):
    ///
    /// ```text
    /// [YEILV][+-]? (M[0123sz])? <semver>?
    /// ```
    #[serde(skip_serializing_if = "Option::is_none")]
    pub modes: Option<Vec<ParsedMode>>,
    #[serde(skip_serializing_if = "Option::is_none")]
    #[schemars(skip)]
    pub file_path: Option<PathBuf>,
    /// This field specifies an EVM version requirement that the test case has where the test might
    /// be run of the evm version of the nodes match the evm version specified here.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub required_evm_version: Option<EvmVersionRequirement>,
    /// A set of compilation directives that will be passed to the compiler whenever the contracts
    /// for the test are being compiled. Note that this differs from the [`Mode`]s in that a [`Mode`]
    /// is just a filter for when a test can run whereas this is an instruction to the compiler.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub compiler_directives: Option<CompilationDirectives>,
 }
 impl Metadata {
-    /// Returns the solc modes of this metadata, inserting a default mode if not present.
+    /// Returns the modes that we should test from this metadata.
-    pub fn solc_modes(&self) -> Vec<SolcMode> {
+    pub fn solc_modes(&self) -> Vec<Mode> {
-        self.modes
+        match &self.modes {
-            .to_owned()
+            Some(modes) => ParsedMode::many_to_modes(modes.iter()).collect(),
-            .unwrap_or_else(|| vec![Mode::Solidity(Default::default())])
+            None => Mode::all().cloned().collect(),
-            .iter()
+        }
            .filter_map(|mode| match mode {
                Mode::Solidity(solc_mode) => Some(solc_mode),
                Mode::Unknown(mode) => {
                    tracing::debug!("compiler: ignoring unknown mode '{mode}'");
                    None
                }
            })
            .cloned()
            .collect()
    }
    /// Returns the base directory of this metadata.
@@ -84,7 +151,7 @@ impl Metadata {
    /// Returns the contract sources with canonicalized paths for the files
    pub fn contract_sources(
        &self,
-    ) -> anyhow::Result<BTreeMap<ContractInstance, ContractPathAndIdentifier>> {
+    ) -> anyhow::Result<BTreeMap<ContractInstance, ContractPathAndIdent>> {
        let directory = self.directory()?;
        let mut sources = BTreeMap::new();
        let Some(contracts) = &self.contracts else {
@@ -93,19 +160,27 @@ impl Metadata {
        for (
            alias,
-            ContractPathAndIdentifier {
+            ContractPathAndIdent {
                contract_source_path,
                contract_ident,
            },
        ) in contracts
        {
            let alias = alias.clone();
-            let absolute_path = directory.join(contract_source_path).canonicalize()?;
+            let absolute_path = directory
                .join(contract_source_path)
                .canonicalize()
                .map_err(|error| {
                    anyhow::anyhow!(
                        "Failed to canonicalize contract source path '{}': {error}",
                        directory.join(contract_source_path).display()
                    )
                })?;
            let contract_ident = contract_ident.clone();
            sources.insert(
                alias,
-                ContractPathAndIdentifier {
+                ContractPathAndIdent {
                    contract_source_path: absolute_path,
                    contract_ident,
                },
@@ -124,10 +199,7 @@ impl Metadata {
    pub fn try_from_file(path: &Path) -> Option<Self> {
        assert!(path.is_file(), "not a file: {}", path.display());
-        let Some(file_extension) = path.extension() else {
+        let file_extension = path.extension()?;
            tracing::debug!("skipping corpus file: {}", path.display());
            return None;
        };
        if file_extension == METADATA_FILE_EXTENSION {
            return Self::try_from_json(path);
@@ -137,18 +209,12 @@ impl Metadata {
            return Self::try_from_solidity(path);
        }
        tracing::debug!("ignoring invalid corpus file: {}", path.display());
        None
    }
    fn try_from_json(path: &Path) -> Option<Self> {
        let file = File::open(path)
-            .inspect_err(|error| {
+            .inspect_err(|err| error!(path = %path.display(), %err, "Failed to open file"))
                tracing::error!(
                    "opening JSON test metadata file '{}' error: {error}",
                    path.display()
                );
            })
            .ok()?;
        match serde_json::from_reader::<_, Metadata>(file) {
@@ -156,11 +222,8 @@ impl Metadata {
                metadata.file_path = Some(path.to_path_buf());
                Some(metadata)
            }
-            Err(error) => {
+            Err(err) => {
-                tracing::error!(
+                error!(path = %path.display(), %err, "Deserialization of metadata failed");
                    "parsing JSON test metadata file '{}' error: {error}",
                    path.display()
                );
                None
            }
        }
@@ -168,12 +231,7 @@ impl Metadata {
    fn try_from_solidity(path: &Path) -> Option<Self> {
        let spec = read_to_string(path)
-            .inspect_err(|error| {
+            .inspect_err(|err| error!(path = %path.display(), %err, "Failed to read file content"))
                tracing::error!(
                    "opening JSON test metadata file '{}' error: {error}",
                    path.display()
                );
            })
            .ok()?
            .lines()
            .filter_map(|line| line.strip_prefix(SOLIDITY_CASE_COMMENT_MARKER))
@@ -191,43 +249,69 @@ impl Metadata {
                metadata.file_path = Some(path.to_path_buf());
                metadata.contracts = Some(
                    [(
-                        ContractInstance::new_from("test"),
+                        ContractInstance::new("Test"),
-                        ContractPathAndIdentifier {
+                        ContractPathAndIdent {
                            contract_source_path: path.to_path_buf(),
-                            contract_ident: ContractIdent::new_from("Test"),
+                            contract_ident: ContractIdent::new("Test"),
                        },
                    )]
                    .into(),
                );
                Some(metadata)
            }
-            Err(error) => {
+            Err(err) => {
-                tracing::error!(
+                error!(path = %path.display(), %err, "Failed to deserialize metadata");
                    "parsing Solidity test metadata file '{}' error: '{error}' from data: {spec}",
                    path.display()
                );
                None
            }
        }
    }
    /// Returns an iterator over all of the solidity files that needs to be compiled for this
    /// [`Metadata`] object
    ///
    /// Note: if the metadata is contained within a solidity file then this is the only file that
    /// we wish to compile since this is a self-contained test. Otherwise, if it's a JSON file
    /// then we need to compile all of the contracts that are in the directory since imports are
    /// allowed in there.
    pub fn files_to_compile(&self) -> anyhow::Result<Box<dyn Iterator<Item = PathBuf>>> {
        let Some(ref metadata_file_path) = self.file_path else {
            anyhow::bail!("The metadata file path is not defined");
        };
        if metadata_file_path
            .extension()
            .is_some_and(|extension| extension.eq_ignore_ascii_case("sol"))
        {
            Ok(Box::new(std::iter::once(metadata_file_path.clone())))
        } else {
            Ok(Box::new(
                FilesWithExtensionIterator::new(self.directory()?)
                    .with_allowed_extension("sol")
                    .with_use_cached_fs(true),
            ))
        }
    }
 }
 define_wrapper_type!(
    /// Represents a contract instance found a metadata file.
    ///
    /// Typically, this is used as the key to the "contracts" field of metadata files.
-    #[derive(Clone, Debug, Default, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
+    #[derive(
        Clone, Debug, Default, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize, JsonSchema
    )]
    #[serde(transparent)]
-    ContractInstance(String);
+    pub struct ContractInstance(String) impl Display;
 );
 define_wrapper_type!(
    /// Represents a contract identifier found a metadata file.
    ///
    /// A contract identifier is the name of the contract in the source code.
-    #[derive(Clone, Debug, Default, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
+    #[derive(
        Clone, Debug, Default, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize, JsonSchema
    )]
    #[serde(transparent)]
-    ContractIdent(String);
+    pub struct ContractIdent(String) impl Display;
 );
 /// Represents an identifier used for contracts.
@@ -237,9 +321,11 @@ define_wrapper_type!(
 /// ```text
 /// ${path}:${contract_ident}
 /// ```
-#[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
+#[derive(
    Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize, JsonSchema,
 )]
 #[serde(try_from = "String", into = "String")]
-pub struct ContractPathAndIdentifier {
+pub struct ContractPathAndIdent {
    /// The path of the contract source code relative to the directory containing the metadata file.
    pub contract_source_path: PathBuf,
@@ -247,7 +333,7 @@ pub struct ContractPathAndIdentifier {
    pub contract_ident: ContractIdent,
 }
-impl Display for ContractPathAndIdentifier {
+impl Display for ContractPathAndIdent {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        write!(
            f,
@@ -258,7 +344,7 @@ impl Display for ContractPathAndIdentifier {
    }
 }
-impl FromStr for ContractPathAndIdentifier {
+impl FromStr for ContractPathAndIdent {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
@@ -281,20 +367,26 @@ impl FromStr for ContractPathAndIdentifier {
                identifier = Some(next_item.to_owned())
            }
        }
-        let Some(path) = path else {
+        match (path, identifier) {
-            anyhow::bail!("Path is not defined");
+            (Some(path), Some(identifier)) => Ok(Self {
-        };
+                contract_source_path: PathBuf::from(path),
-        let Some(identifier) = identifier else {
+                contract_ident: ContractIdent::new(identifier),
-            anyhow::bail!("Contract identifier is not defined")
+            }),
-        };
+            (None, Some(path)) | (Some(path), None) => {
-        Ok(Self {
+                let Some(identifier) = path.split(".").next().map(ToOwned::to_owned) else {
-            contract_source_path: PathBuf::from(path),
+                    anyhow::bail!("Failed to find identifier");
-            contract_ident: ContractIdent::new(identifier),
+                };
-        })
+                Ok(Self {
                    contract_source_path: PathBuf::from(path),
                    contract_ident: ContractIdent::new(identifier),
                })
            }
            (None, None) => anyhow::bail!("Failed to find the path and identifier"),
        }
    }
 }
-impl TryFrom<String> for ContractPathAndIdentifier {
+impl TryFrom<String> for ContractPathAndIdent {
    type Error = anyhow::Error;
    fn try_from(value: String) -> Result<Self, Self::Error> {
@@ -302,12 +394,194 @@ impl TryFrom<String> for ContractPathAndIdentifier {
    }
 }
-impl From<ContractPathAndIdentifier> for String {
+impl From<ContractPathAndIdent> for String {
-    fn from(value: ContractPathAndIdentifier) -> Self {
+    fn from(value: ContractPathAndIdent) -> Self {
        value.to_string()
    }
 }
 /// An EVM version requirement that the test case has. This gets serialized and deserialized from
 /// and into [`String`]. This follows a simple format of (>=|<=|=|>|<) followed by a string of the
 /// EVM version.
 ///
 /// When specified, the framework will only run the test if the node's EVM version matches that
 /// required by the metadata file.
 #[derive(
    Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize, JsonSchema,
 )]
 #[serde(try_from = "String", into = "String")]
 pub struct EvmVersionRequirement {
    ordering: Ordering,
    or_equal: bool,
    evm_version: EVMVersion,
 }
 impl EvmVersionRequirement {
    pub fn new_greater_than_or_equals(version: EVMVersion) -> Self {
        Self {
            ordering: Ordering::Greater,
            or_equal: true,
            evm_version: version,
        }
    }
    pub fn new_greater_than(version: EVMVersion) -> Self {
        Self {
            ordering: Ordering::Greater,
            or_equal: false,
            evm_version: version,
        }
    }
    pub fn new_equals(version: EVMVersion) -> Self {
        Self {
            ordering: Ordering::Equal,
            or_equal: false,
            evm_version: version,
        }
    }
    pub fn new_less_than(version: EVMVersion) -> Self {
        Self {
            ordering: Ordering::Less,
            or_equal: false,
            evm_version: version,
        }
    }
    pub fn new_less_than_or_equals(version: EVMVersion) -> Self {
        Self {
            ordering: Ordering::Less,
            or_equal: true,
            evm_version: version,
        }
    }
    pub fn matches(&self, other: &EVMVersion) -> bool {
        let ordering = other.cmp(&self.evm_version);
        ordering == self.ordering || (self.or_equal && matches!(ordering, Ordering::Equal))
    }
 }
 impl Display for EvmVersionRequirement {
    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        let Self {
            ordering,
            or_equal,
            evm_version,
        } = self;
        match ordering {
            Ordering::Less => write!(f, "<")?,
            Ordering::Equal => write!(f, "=")?,
            Ordering::Greater => write!(f, ">")?,
        }
        if *or_equal && !matches!(ordering, Ordering::Equal) {
            write!(f, "=")?;
        }
        write!(f, "{evm_version}")
    }
 }
 impl FromStr for EvmVersionRequirement {
    type Err = anyhow::Error;
    fn from_str(s: &str) -> Result<Self, Self::Err> {
        match s.as_bytes() {
            [b'>', b'=', remaining @ ..] => Ok(Self {
                ordering: Ordering::Greater,
                or_equal: true,
                evm_version: str::from_utf8(remaining)?.try_into()?,
            }),
            [b'>', remaining @ ..] => Ok(Self {
                ordering: Ordering::Greater,
                or_equal: false,
                evm_version: str::from_utf8(remaining)?.try_into()?,
            }),
            [b'<', b'=', remaining @ ..] => Ok(Self {
                ordering: Ordering::Less,
                or_equal: true,
                evm_version: str::from_utf8(remaining)?.try_into()?,
            }),
            [b'<', remaining @ ..] => Ok(Self {
                ordering: Ordering::Less,
                or_equal: false,
                evm_version: str::from_utf8(remaining)?.try_into()?,
            }),
            [b'=', remaining @ ..] => Ok(Self {
                ordering: Ordering::Equal,
                or_equal: false,
                evm_version: str::from_utf8(remaining)?.try_into()?,
            }),
            _ => anyhow::bail!("Invalid EVM version requirement {s}"),
        }
    }
 }
 impl TryFrom<String> for EvmVersionRequirement {
    type Error = anyhow::Error;
    fn try_from(value: String) -> Result<Self, Self::Error> {
        value.parse()
    }
 }
 impl From<EvmVersionRequirement> for String {
    fn from(value: EvmVersionRequirement) -> Self {
        value.to_string()
    }
 }
 /// A set of compilation directives that will be passed to the compiler whenever the contracts for
 /// the test are being compiled. Note that this differs from the [`Mode`]s in that a [`Mode`] is
 /// just a filter for when a test can run whereas this is an instruction to the compiler.
 /// Defines how the compiler should handle revert strings.
 #[derive(
    Clone,
    Debug,
    Copy,
    PartialEq,
    Eq,
    PartialOrd,
    Ord,
    Hash,
    Default,
    Serialize,
    Deserialize,
    JsonSchema,
 )]
 pub struct CompilationDirectives {
    /// Defines how the revert strings should be handled.
    pub revert_string_handling: Option<RevertString>,
 }
 /// Defines how the compiler should handle revert strings.
 #[derive(
    Clone,
    Debug,
    Copy,
    PartialEq,
    Eq,
    PartialOrd,
    Ord,
    Hash,
    Default,
    Serialize,
    Deserialize,
    JsonSchema,
 )]
 #[serde(rename_all = "camelCase")]
 pub enum RevertString {
    /// The default handling of the revert strings.
    #[default]
    Default,
    /// The debug handling of the revert strings.
    Debug,
    /// Strip the revert strings.
    Strip,
    /// Provide verbose debug strings for the revert string.
    VerboseDebug,
 }
 #[cfg(test)]
 mod test {
    use super::*;
@@ -318,7 +592,7 @@ mod test {
        let string = "ERC20/ERC20.sol:ERC20";
        // Act
-        let identifier = ContractPathAndIdentifier::from_str(string);
+        let identifier = ContractPathAndIdent::from_str(string);
        // Assert
        let identifier = identifier.expect("Failed to parse");
@@ -1,96 +0,0 @@
 use semver::Version;
 use serde::de::Deserializer;
 use serde::{Deserialize, Serialize};
 /// Specifies the compilation mode of the test artifact.
 #[derive(Hash, Debug, Clone, Eq, PartialEq)]
 pub enum Mode {
    Solidity(SolcMode),
    Unknown(String),
 }
 /// Specify Solidity specific compiler options.
 #[derive(Hash, Debug, Default, Clone, Eq, PartialEq, Serialize, Deserialize)]
 pub struct SolcMode {
    pub solc_version: Option<semver::VersionReq>,
    solc_optimize: Option<bool>,
    pub llvm_optimizer_settings: Vec<String>,
 }
 impl SolcMode {
    /// Try to parse a mode string into a solc mode.
    /// Returns `None` if the string wasn't a solc YUL mode string.
    ///
    /// The mode string is expected to start with the `Y` ID (YUL ID),
    /// optionally followed by `+` or `-` for the solc optimizer settings.
    ///
    /// Options can be separated by a whitespace contain the following
    /// - A solc `SemVer version requirement` string
    /// - One or more `-OX` where X is a supposed to be an LLVM opt mode
    pub fn parse_from_mode_string(mode_string: &str) -> Option<Self> {
        let mut result = Self::default();
        let mut parts = mode_string.trim().split(" ");
        match parts.next()? {
            "Y" => {}
            "Y+" => result.solc_optimize = Some(true),
            "Y-" => result.solc_optimize = Some(false),
            _ => return None,
        }
        for part in parts {
            if let Ok(solc_version) = semver::VersionReq::parse(part) {
                result.solc_version = Some(solc_version);
                continue;
            }
            if let Some(level) = part.strip_prefix("-O") {
                result.llvm_optimizer_settings.push(level.to_string());
                continue;
            }
            panic!("the YUL mode string {mode_string} failed to parse, invalid part: {part}")
        }
        Some(result)
    }
    /// Returns whether to enable the solc optimizer.
    pub fn solc_optimize(&self) -> bool {
        self.solc_optimize.unwrap_or(true)
    }
    /// Calculate the latest matching solc patch version. Returns:
    /// - `latest_supported` if no version request was specified.
    /// - A matching version with the same minor version as `latest_supported`, if any.
    /// - `None` if no minor version of the `latest_supported` version matches.
    pub fn last_patch_version(&self, latest_supported: &Version) -> Option<Version> {
        let Some(version_req) = self.solc_version.as_ref() else {
            return Some(latest_supported.to_owned());
        };
        // lgtm
        for patch in (0..latest_supported.patch + 1).rev() {
            let version = Version::new(0, latest_supported.minor, patch);
            if version_req.matches(&version) {
                return Some(version);
            }
        }
        None
    }
 }
 impl<'de> Deserialize<'de> for Mode {
    fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
    where
        D: Deserializer<'de>,
    {
        let mode_string = String::deserialize(deserializer)?;
        if let Some(solc_mode) = SolcMode::parse_from_mode_string(&mode_string) {
            return Ok(Self::Solidity(solc_mode));
        }
        Ok(Self::Unknown(mode_string))
    }
 }
@@ -0,0 +1,176 @@
 use std::collections::HashMap;
 use std::pin::Pin;
 use alloy::eips::BlockNumberOrTag;
 use alloy::json_abi::JsonAbi;
 use alloy::primitives::TxHash;
 use alloy::primitives::{Address, BlockHash, BlockNumber, BlockTimestamp, ChainId, U256};
 use anyhow::Result;
 use crate::metadata::{ContractIdent, ContractInstance};
 /// A trait of the interface are required to implement to be used by the resolution logic that this
 /// crate implements to go from string calldata and into the bytes calldata.
 pub trait ResolverApi {
    /// Returns the ID of the chain that the node is on.
    fn chain_id(&self) -> Pin<Box<dyn Future<Output = Result<ChainId>> + '_>>;
    /// Returns the gas price for the specified transaction.
    fn transaction_gas_price(
        &self,
        tx_hash: TxHash,
    ) -> Pin<Box<dyn Future<Output = Result<u128>> + '_>>;
    // TODO: This is currently a u128 due to substrate needing more than 64 bits for its gas limit
    // when we implement the changes to the gas we need to adjust this to be a u64.
    /// Returns the gas limit of the specified block.
    fn block_gas_limit(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = Result<u128>> + '_>>;
    /// Returns the coinbase of the specified block.
    fn block_coinbase(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = Result<Address>> + '_>>;
    /// Returns the difficulty of the specified block.
    fn block_difficulty(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = Result<U256>> + '_>>;
    /// Returns the base fee of the specified block.
    fn block_base_fee(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = Result<u64>> + '_>>;
    /// Returns the hash of the specified block.
    fn block_hash(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = Result<BlockHash>> + '_>>;
    /// Returns the timestamp of the specified block,
    fn block_timestamp(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = Result<BlockTimestamp>> + '_>>;
    /// Returns the number of the last block.
    fn last_block_number(&self) -> Pin<Box<dyn Future<Output = Result<BlockNumber>> + '_>>;
 }
 #[derive(Clone, Copy, Debug, Default)]
 /// Contextual information required by the code that's performing the resolution.
 pub struct ResolutionContext<'a> {
    /// When provided the contracts provided here will be used for resolutions.
    deployed_contracts: Option<&'a HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>>,
    /// When provided the variables in here will be used for performing resolutions.
    variables: Option<&'a HashMap<String, U256>>,
    /// When provided this block number will be treated as the tip of the chain.
    block_number: Option<&'a BlockNumber>,
    /// When provided the resolver will use this transaction hash for all of its resolutions.
    transaction_hash: Option<&'a TxHash>,
 }
 impl<'a> ResolutionContext<'a> {
    pub fn new() -> Self {
        Default::default()
    }
    pub fn new_from_parts(
        deployed_contracts: impl Into<
            Option<&'a HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>>,
        >,
        variables: impl Into<Option<&'a HashMap<String, U256>>>,
        block_number: impl Into<Option<&'a BlockNumber>>,
        transaction_hash: impl Into<Option<&'a TxHash>>,
    ) -> Self {
        Self {
            deployed_contracts: deployed_contracts.into(),
            variables: variables.into(),
            block_number: block_number.into(),
            transaction_hash: transaction_hash.into(),
        }
    }
    pub fn with_deployed_contracts(
        mut self,
        deployed_contracts: impl Into<
            Option<&'a HashMap<ContractInstance, (ContractIdent, Address, JsonAbi)>>,
        >,
    ) -> Self {
        self.deployed_contracts = deployed_contracts.into();
        self
    }
    pub fn with_variables(
        mut self,
        variables: impl Into<Option<&'a HashMap<String, U256>>>,
    ) -> Self {
        self.variables = variables.into();
        self
    }
    pub fn with_block_number(mut self, block_number: impl Into<Option<&'a BlockNumber>>) -> Self {
        self.block_number = block_number.into();
        self
    }
    pub fn with_transaction_hash(
        mut self,
        transaction_hash: impl Into<Option<&'a TxHash>>,
    ) -> Self {
        self.transaction_hash = transaction_hash.into();
        self
    }
    pub fn resolve_block_number(&self, number: BlockNumberOrTag) -> BlockNumberOrTag {
        match self.block_number {
            Some(block_number) => match number {
                BlockNumberOrTag::Latest => BlockNumberOrTag::Number(*block_number),
                n @ (BlockNumberOrTag::Finalized
                | BlockNumberOrTag::Safe
                | BlockNumberOrTag::Earliest
                | BlockNumberOrTag::Pending
                | BlockNumberOrTag::Number(_)) => n,
            },
            None => number,
        }
    }
    pub fn deployed_contract(
        &self,
        instance: &ContractInstance,
    ) -> Option<&(ContractIdent, Address, JsonAbi)> {
        self.deployed_contracts
            .and_then(|deployed_contracts| deployed_contracts.get(instance))
    }
    pub fn deployed_contract_address(&self, instance: &ContractInstance) -> Option<&Address> {
        self.deployed_contract(instance).map(|(_, a, _)| a)
    }
    pub fn deployed_contract_abi(&self, instance: &ContractInstance) -> Option<&JsonAbi> {
        self.deployed_contract(instance).map(|(_, _, a)| a)
    }
    pub fn variable(&self, name: impl AsRef<str>) -> Option<&U256> {
        self.variables
            .and_then(|variables| variables.get(name.as_ref()))
    }
    pub fn tip_block_number(&self) -> Option<&'a BlockNumber> {
        self.block_number
    }
    pub fn transaction_hash(&self) -> Option<&'a TxHash> {
        self.transaction_hash
    }
 }
@@ -9,9 +9,14 @@ repository.workspace = true
 rust-version.workspace = true
 [dependencies]
 revive-common = { workspace = true }
 revive-dt-format = { workspace = true }
 revive-dt-report = { workspace = true }
 alloy = { workspace = true }
 anyhow = { workspace = true }
 futures = { workspace = true }
-tracing = { workspace = true }
+
-once_cell = { workspace = true }
+[lints]
-tokio = { workspace = true }
+workspace = true
@@ -1,220 +0,0 @@
 //! The alloy crate __requires__ a tokio runtime.
 //! We contain any async rust right here.
 use std::{any::Any, panic::AssertUnwindSafe, pin::Pin, thread};
 use futures::FutureExt;
 use once_cell::sync::Lazy;
 use tokio::{
    runtime::Builder,
    sync::{mpsc::UnboundedSender, oneshot},
 };
 /// A blocking async executor.
 ///
 /// This struct exposes the abstraction of a blocking async executor. It is a global and static
 /// executor which means that it doesn't require for new instances of it to be created, it's a
 /// singleton and can be accessed by any thread that wants to perform some async computation on the
 /// blocking executor thread.
 ///
 /// The API of the blocking executor is created in a way so that it's very natural, simple to use,
 /// and unbounded to specific tasks or return types. The following is an example of using this
 /// executor to drive an async computation:
 ///
 /// ```rust
 /// use revive_dt_node_interaction::*;
 ///
 /// fn blocking_function() {
 ///     let result = BlockingExecutor::execute(async move {
 ///         tokio::time::sleep(std::time::Duration::from_secs(1)).await;
 ///         0xFFu8
 ///     })
 ///     .expect("Computation failed");
 ///
 ///     assert_eq!(result, 0xFF);
 /// }
 /// ```
 ///
 /// Users get to pass in their async tasks without needing to worry about putting them in a [`Box`],
 /// [`Pin`], needing to perform down-casting, or the internal channel mechanism used by the runtime.
 /// To the user, it just looks like a function that converts some async code into sync code.
 ///
 /// This struct also handled panics that occur in the passed futures and converts them into errors
 /// that can be handled by the user. This is done to allow the executor to be robust.
 ///
 /// Internally, the executor communicates with the tokio runtime thread through channels which carry
 /// the [`TaskMessage`] and the results of the execution.
 pub struct BlockingExecutor;
 impl BlockingExecutor {
    pub fn execute<R>(future: impl Future<Output = R> + Send + 'static) -> Result<R, anyhow::Error>
    where
        R: Send + 'static,
    {
        // Note: The blocking executor is a singleton and therefore we store its state in a static
        // so that it's assigned only once. Additionally, when we set the state of the executor we
        // spawn the thread where the async runtime runs.
        static STATE: Lazy<ExecutorState> = Lazy::new(|| {
            tracing::trace!("Initializing the BlockingExecutor state");
            // All communication with the tokio runtime thread happens over mspc channels where the
            // producers here are the threads that want to run async tasks and the consumer here is
            // the tokio runtime thread.
            let (tx, mut rx) = tokio::sync::mpsc::unbounded_channel::<TaskMessage>();
            thread::spawn(move || {
                let runtime = Builder::new_current_thread()
                    .enable_all()
                    .build()
                    .expect("Failed to create the async runtime");
                runtime.block_on(async move {
                    while let Some(TaskMessage {
                        future: task,
                        response_tx: response_channel,
                    }) = rx.recv().await
                    {
                        tracing::trace!("Received a new future to execute");
                        tokio::spawn(async move {
                            // One of the things that the blocking executor does is that it allows
                            // us to catch panics if they occur. By wrapping the given future in an
                            // AssertUnwindSafe::catch_unwind we are able to catch all panic unwinds
                            // in the given future and convert them into errors.
                            let task = AssertUnwindSafe(task).catch_unwind();
                            let result = task.await;
                            let _ = response_channel.send(result);
                        });
                    }
                })
            });
            ExecutorState { tx }
        });
        // We need to perform blocking synchronous communication between the current thread and the
        // tokio runtime thread with the result of the async computation and the oneshot channels
        // from tokio allows us to do that. The sender side of the channel will be given to the
        // tokio runtime thread to send the result when the computation is completed and the receive
        // side of the channel will be kept with this thread to await for the response of the async
        // task to come back.
        let (response_tx, response_rx) =
            oneshot::channel::<Result<Box<dyn Any + Send>, Box<dyn Any + Send>>>();
        // The tokio runtime thread expects a Future<Output = Box<dyn Any + Send>> + Send to be
        // sent to it to execute. However, this function has a typed Future<Output = R> + Send and
        // therefore we need to change the type of the future to fit what the runtime thread expects
        // in the task message. In doing this conversion, we lose some of the type information since
        // we're converting R => dyn Any. However, we will perform down-casting on the result to
        // convert it back into R.
        let future = Box::pin(async move { Box::new(future.await) as Box<dyn Any + Send> });
        let task = TaskMessage::new(future, response_tx);
        if let Err(error) = STATE.tx.send(task) {
            tracing::error!(?error, "Failed to send the task to the blocking executor");
            anyhow::bail!("Failed to send the task to the blocking executor: {error:?}")
        }
        let result = match response_rx.blocking_recv() {
            Ok(result) => result,
            Err(error) => {
                tracing::error!(
                    ?error,
                    "Failed to get the response from the blocking executor"
                );
                anyhow::bail!("Failed to get the response from the blocking executor: {error:?}")
            }
        };
        match result.map(|result| {
            *result
                .downcast::<R>()
                .expect("Type mismatch in the downcast")
        }) {
            Ok(result) => Ok(result),
            Err(error) => {
                tracing::error!(
                    ?error,
                    "Failed to downcast the returned result into the expected type"
                );
                anyhow::bail!(
                    "Failed to downcast the returned result into the expected type: {error:?}"
                )
            }
        }
    }
 }
 /// Represents the state of the async runtime. This runtime is designed to be a singleton runtime
 /// which means that in the current running program there's just a single thread that has an async
 /// runtime.
 struct ExecutorState {
    /// The sending side of the task messages channel. This is used by all of the other threads to
    /// communicate with the async runtime thread.
    tx: UnboundedSender<TaskMessage>,
 }
 /// Represents a message that contains an asynchronous task that's to be executed by the runtime
 /// as well as a way for the runtime to report back on the result of the execution.
 struct TaskMessage {
    /// The task that's being requested to run. This is a future that returns an object that does
    /// implement [`Any`] and [`Send`] to allow it to be sent between the requesting thread and the
    /// async thread.
    future: Pin<Box<dyn Future<Output = Box<dyn Any + Send>> + Send>>,
    /// A one shot sender channel where the sender of the task is expecting to hear back on the
    /// result of the task.
    response_tx: oneshot::Sender<Result<Box<dyn Any + Send>, Box<dyn Any + Send>>>,
 }
 impl TaskMessage {
    pub fn new(
        future: Pin<Box<dyn Future<Output = Box<dyn Any + Send>> + Send>>,
        response_tx: oneshot::Sender<Result<Box<dyn Any + Send>, Box<dyn Any + Send>>>,
    ) -> Self {
        Self {
            future,
            response_tx,
        }
    }
 }
 #[cfg(test)]
 mod test {
    use super::*;
    #[test]
    fn simple_future_works() {
        // Act
        let result = BlockingExecutor::execute(async move {
            tokio::time::sleep(std::time::Duration::from_secs(1)).await;
            0xFFu8
        })
        .unwrap();
        // Assert
        assert_eq!(result, 0xFFu8);
    }
    #[test]
    #[allow(unreachable_code, clippy::unreachable)]
    fn panics_in_futures_are_caught() {
        // Act
        let result = BlockingExecutor::execute(async move {
            panic!("This is a panic!");
            0xFFu8
        });
        // Assert
        assert!(result.is_err());
        // Act
        let result = BlockingExecutor::execute(async move {
            tokio::time::sleep(std::time::Duration::from_secs(1)).await;
            0xFFu8
        })
        .unwrap();
        // Assert
        assert_eq!(result, 0xFFu8)
    }
 }
@@ -1,48 +1,83 @@
 //! This crate implements all node interactions.
-use alloy::eips::BlockNumberOrTag;
+use std::pin::Pin;
-use alloy::primitives::{Address, BlockHash, BlockNumber, BlockTimestamp, ChainId, U256};
+use std::sync::Arc;
-use alloy::rpc::types::trace::geth::{DiffMode, GethTrace};
+
-use alloy::rpc::types::{TransactionReceipt, TransactionRequest};
+use alloy::network::Ethereum;
 use alloy::primitives::{Address, StorageKey, TxHash, U256};
 use alloy::providers::DynProvider;
 use alloy::rpc::types::trace::geth::{DiffMode, GethDebugTracingOptions, GethTrace};
 use alloy::rpc::types::{EIP1186AccountProofResponse, TransactionReceipt, TransactionRequest};
 use anyhow::Result;
-mod blocking_executor;
+use futures::Stream;
-pub use blocking_executor::*;
+use revive_common::EVMVersion;
 use revive_dt_format::traits::ResolverApi;
 use revive_dt_report::MinedBlockInformation;
 /// An interface for all interactions with Ethereum compatible nodes.
 #[allow(clippy::type_complexity)]
 pub trait EthereumNode {
    /// A function to run post spawning the nodes and before any transactions are run on the node.
    fn pre_transactions(&mut self) -> Pin<Box<dyn Future<Output = anyhow::Result<()>> + '_>>;
    fn id(&self) -> usize;
    /// Returns the nodes connection string.
    fn connection_string(&self) -> &str;
    fn submit_transaction(
        &self,
        transaction: TransactionRequest,
    ) -> Pin<Box<dyn Future<Output = Result<TxHash>> + '_>>;
    fn get_receipt(
        &self,
        tx_hash: TxHash,
    ) -> Pin<Box<dyn Future<Output = Result<TransactionReceipt>> + '_>>;
    /// Execute the [TransactionRequest] and return a [TransactionReceipt].
-    fn execute_transaction(&self, transaction: TransactionRequest) -> Result<TransactionReceipt>;
+    fn execute_transaction(
        &self,
        transaction: TransactionRequest,
    ) -> Pin<Box<dyn Future<Output = Result<TransactionReceipt>> + '_>>;
    /// Trace the transaction in the [TransactionReceipt] and return a [GethTrace].
-    fn trace_transaction(&self, transaction: TransactionReceipt) -> Result<GethTrace>;
+    fn trace_transaction(
        &self,
        tx_hash: TxHash,
        trace_options: GethDebugTracingOptions,
    ) -> Pin<Box<dyn Future<Output = Result<GethTrace>> + '_>>;
    /// Returns the state diff of the transaction hash in the [TransactionReceipt].
-    fn state_diff(&self, transaction: TransactionReceipt) -> Result<DiffMode>;
+    fn state_diff(&self, tx_hash: TxHash) -> Pin<Box<dyn Future<Output = Result<DiffMode>> + '_>>;
-    /// Returns the next available nonce for the given [Address].
+    /// Returns the balance of the provided [`Address`] back.
-    fn fetch_add_nonce(&self, address: Address) -> Result<u64>;
+    fn balance_of(&self, address: Address) -> Pin<Box<dyn Future<Output = Result<U256>> + '_>>;
-    /// Returns the ID of the chain that the node is on.
+    /// Returns the latest storage proof of the provided [`Address`]
-    fn chain_id(&self) -> Result<ChainId>;
+    fn latest_state_proof(
        &self,
        address: Address,
        keys: Vec<StorageKey>,
    ) -> Pin<Box<dyn Future<Output = Result<EIP1186AccountProofResponse>> + '_>>;
-    // TODO: This is currently a u128 due to Kitchensink needing more than 64 bits for its gas limit
+    /// Returns the resolver that is to use with this ethereum node.
-    // when we implement the changes to the gas we need to adjust this to be a u64.
+    fn resolver(&self) -> Pin<Box<dyn Future<Output = Result<Arc<dyn ResolverApi + '_>>> + '_>>;
    /// Returns the gas limit of the specified block.
    fn block_gas_limit(&self, number: BlockNumberOrTag) -> Result<u128>;
-    /// Returns the coinbase of the specified block.
+    /// Returns the EVM version of the node.
-    fn block_coinbase(&self, number: BlockNumberOrTag) -> Result<Address>;
+    fn evm_version(&self) -> EVMVersion;
-    /// Returns the difficulty of the specified block.
+    /// Returns a stream of the blocks that were mined by the node.
-    fn block_difficulty(&self, number: BlockNumberOrTag) -> Result<U256>;
+    fn subscribe_to_full_blocks_information(
        &self,
    ) -> Pin<
        Box<
            dyn Future<Output = anyhow::Result<Pin<Box<dyn Stream<Item = MinedBlockInformation>>>>>
                + '_,
        >,
    >;
-    /// Returns the hash of the specified block.
+    fn provider(&self)
-    fn block_hash(&self, number: BlockNumberOrTag) -> Result<BlockHash>;
+    -> Pin<Box<dyn Future<Output = anyhow::Result<DynProvider<Ethereum>>> + '_>>;
    /// Returns the timestamp of the specified block,
    fn block_timestamp(&self, number: BlockNumberOrTag) -> Result<BlockTimestamp>;
    /// Returns the number of the last block.
    fn last_block_number(&self) -> Result<BlockNumber>;
 }
@@ -11,18 +11,31 @@ rust-version.workspace = true
 [dependencies]
 anyhow = { workspace = true }
 alloy = { workspace = true }
 futures = { workspace = true }
 tracing = { workspace = true }
 tower = { workspace = true }
 tokio = { workspace = true }
-revive-dt-node-interaction = { workspace = true }
+revive-common = { workspace = true }
 revive-dt-common = { workspace = true }
 revive-dt-config = { workspace = true }
 revive-dt-format = { workspace = true }
 revive-dt-node-interaction = { workspace = true }
 revive-dt-report = { workspace = true }
 serde = { workspace = true }
 serde_json = { workspace = true }
 serde_with = { workspace = true }
 serde_yaml_ng = { workspace = true }
 sp-core = { workspace = true }
 sp-runtime = { workspace = true }
 subxt = { workspace = true }
 zombienet-sdk = { workspace = true }
 [dev-dependencies]
 temp-dir = { workspace = true }
 tokio = { workspace = true }
 [lints]
 workspace = true
@@ -0,0 +1,10 @@
 use alloy::primitives::ChainId;
 /// This constant defines how much Wei accounts are pre-seeded with in genesis.
 ///
 /// Note: After changing this number, check that the tests for substrate work as we encountered
 /// some issues with different values of the initial balance on substrate.
 pub const INITIAL_BALANCE: u128 = 10u128.pow(37);
 /// The chain id used for all of the chains spawned by the framework.
 pub const CHAIN_ID: ChainId = 420420420;
@@ -1,655 +0,0 @@
 //! The go-ethereum node implementation.
 use std::{
    collections::HashMap,
    fs::{File, OpenOptions, create_dir_all, remove_dir_all},
    io::{BufRead, BufReader, Read, Write},
    path::PathBuf,
    process::{Child, Command, Stdio},
    sync::{
        Mutex,
        atomic::{AtomicU32, Ordering},
    },
    time::{Duration, Instant},
 };
 use alloy::{
    eips::BlockNumberOrTag,
    network::{Ethereum, EthereumWallet},
    primitives::{Address, BlockHash, BlockNumber, BlockTimestamp, U256},
    providers::{
        Provider, ProviderBuilder,
        ext::DebugApi,
        fillers::{FillProvider, TxFiller},
    },
    rpc::types::{
        TransactionReceipt, TransactionRequest,
        trace::geth::{DiffMode, GethDebugTracingOptions, PreStateConfig, PreStateFrame},
    },
 };
 use revive_dt_config::Arguments;
 use revive_dt_node_interaction::{BlockingExecutor, EthereumNode};
 use tracing::Level;
 use crate::Node;
 static NODE_COUNT: AtomicU32 = AtomicU32::new(0);
 /// The go-ethereum node instance implementation.
 ///
 /// Implements helpers to initialize, spawn and wait the node.
 ///
 /// Assumes dev mode and IPC only (`P2P`, `http`` etc. are kept disabled).
 ///
 /// Prunes the child process and the base directory on drop.
 #[derive(Debug)]
 pub struct Instance {
    connection_string: String,
    base_directory: PathBuf,
    data_directory: PathBuf,
    logs_directory: PathBuf,
    geth: PathBuf,
    id: u32,
    handle: Option<Child>,
    network_id: u64,
    start_timeout: u64,
    wallet: EthereumWallet,
    nonces: Mutex<HashMap<Address, u64>>,
    /// This vector stores [`File`] objects that we use for logging which we want to flush when the
    /// node object is dropped. We do not store them in a structured fashion at the moment (in
    /// separate fields) as the logic that we need to apply to them is all the same regardless of
    /// what it belongs to, we just want to flush them on [`Drop`] of the node.
    logs_file_to_flush: Vec<File>,
 }
 impl Instance {
    const BASE_DIRECTORY: &str = "geth";
    const DATA_DIRECTORY: &str = "data";
    const LOGS_DIRECTORY: &str = "logs";
    const IPC_FILE: &str = "geth.ipc";
    const GENESIS_JSON_FILE: &str = "genesis.json";
    const READY_MARKER: &str = "IPC endpoint opened";
    const ERROR_MARKER: &str = "Fatal:";
    const GETH_STDOUT_LOG_FILE_NAME: &str = "node_stdout.log";
    const GETH_STDERR_LOG_FILE_NAME: &str = "node_stderr.log";
    /// Create the node directory and call `geth init` to configure the genesis.
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn init(&mut self, genesis: String) -> anyhow::Result<&mut Self> {
        create_dir_all(&self.base_directory)?;
        create_dir_all(&self.logs_directory)?;
        let genesis_path = self.base_directory.join(Self::GENESIS_JSON_FILE);
        File::create(&genesis_path)?.write_all(genesis.as_bytes())?;
        let mut child = Command::new(&self.geth)
            .arg("init")
            .arg("--datadir")
            .arg(&self.data_directory)
            .arg(genesis_path)
            .stderr(Stdio::piped())
            .stdout(Stdio::null())
            .spawn()?;
        let mut stderr = String::new();
        child
            .stderr
            .take()
            .expect("should be piped")
            .read_to_string(&mut stderr)?;
        if !child.wait()?.success() {
            anyhow::bail!("failed to initialize geth node #{:?}: {stderr}", &self.id);
        }
        Ok(self)
    }
    /// Spawn the go-ethereum node child process.
    ///
    /// [Instance::init] must be called prior.
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn spawn_process(&mut self) -> anyhow::Result<&mut Self> {
        // This is the `OpenOptions` that we wish to use for all of the log files that we will be
        // opening in this method. We need to construct it in this way to:
        // 1. Be consistent
        // 2. Less verbose and more dry
        // 3. Because the builder pattern uses mutable references so we need to get around that.
        let open_options = {
            let mut options = OpenOptions::new();
            options.create(true).truncate(true).write(true);
            options
        };
        let stdout_logs_file = open_options
            .clone()
            .open(self.geth_stdout_log_file_path())?;
        let stderr_logs_file = open_options.open(self.geth_stderr_log_file_path())?;
        self.handle = Command::new(&self.geth)
            .arg("--dev")
            .arg("--datadir")
            .arg(&self.data_directory)
            .arg("--ipcpath")
            .arg(&self.connection_string)
            .arg("--networkid")
            .arg(self.network_id.to_string())
            .arg("--nodiscover")
            .arg("--maxpeers")
            .arg("0")
            .stderr(stderr_logs_file.try_clone()?)
            .stdout(stdout_logs_file.try_clone()?)
            .spawn()?
            .into();
        if let Err(error) = self.wait_ready() {
            tracing::error!(?error, "Failed to start geth, shutting down gracefully");
            self.shutdown()?;
            return Err(error);
        }
        self.logs_file_to_flush
            .extend([stderr_logs_file, stdout_logs_file]);
        Ok(self)
    }
    /// Wait for the g-ethereum node child process getting ready.
    ///
    /// [Instance::spawn_process] must be called priorly.
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn wait_ready(&mut self) -> anyhow::Result<&mut Self> {
        let start_time = Instant::now();
        let logs_file = OpenOptions::new()
            .read(true)
            .write(false)
            .append(false)
            .truncate(false)
            .open(self.geth_stderr_log_file_path())?;
        let maximum_wait_time = Duration::from_millis(self.start_timeout);
        let mut stderr = BufReader::new(logs_file).lines();
        loop {
            if let Some(Ok(line)) = stderr.next() {
                if line.contains(Self::ERROR_MARKER) {
                    anyhow::bail!("Failed to start geth {line}");
                }
                if line.contains(Self::READY_MARKER) {
                    return Ok(self);
                }
            }
            if Instant::now().duration_since(start_time) > maximum_wait_time {
                anyhow::bail!("Timeout in starting geth");
            }
        }
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id), level = Level::TRACE)]
    fn geth_stdout_log_file_path(&self) -> PathBuf {
        self.logs_directory.join(Self::GETH_STDOUT_LOG_FILE_NAME)
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id), level = Level::TRACE)]
    fn geth_stderr_log_file_path(&self) -> PathBuf {
        self.logs_directory.join(Self::GETH_STDERR_LOG_FILE_NAME)
    }
    fn provider(
        &self,
    ) -> impl Future<
        Output = anyhow::Result<
            FillProvider<impl TxFiller<Ethereum>, impl Provider<Ethereum>, Ethereum>,
        >,
    > + 'static {
        let connection_string = self.connection_string();
        let wallet = self.wallet.clone();
        Box::pin(async move {
            ProviderBuilder::new()
                .wallet(wallet)
                .connect(&connection_string)
                .await
                .map_err(Into::into)
        })
    }
 }
 impl EthereumNode for Instance {
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn execute_transaction(
        &self,
        transaction: TransactionRequest,
    ) -> anyhow::Result<alloy::rpc::types::TransactionReceipt> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            let outer_span = tracing::debug_span!("Submitting transaction", ?transaction,);
            let _outer_guard = outer_span.enter();
            let provider = provider.await?;
            let pending_transaction = provider.send_transaction(transaction).await?;
            let transaction_hash = pending_transaction.tx_hash();
            let span = tracing::info_span!("Awaiting transaction receipt", ?transaction_hash);
            let _guard = span.enter();
            // The following is a fix for the "transaction indexing is in progress" error that we
            // used to get. You can find more information on this in the following GH issue in geth
            // https://github.com/ethereum/go-ethereum/issues/28877. To summarize what's going on,
            // before we can get the receipt of the transaction it needs to have been indexed by the
            // node's indexer. Just because the transaction has been confirmed it doesn't mean that
            // it has been indexed. When we call alloy's `get_receipt` it checks if the transaction
            // was confirmed. If it has been, then it will call `eth_getTransactionReceipt` method
            // which _might_ return the above error if the tx has not yet been indexed yet. So, we
            // need to implement a retry mechanism for the receipt to keep retrying to get it until
            // it eventually works, but we only do that if the error we get back is the "transaction
            // indexing is in progress" error or if the receipt is None.
            //
            // At the moment we do not allow for the 60 seconds to be modified and we take it as
            // being an implementation detail that's invisible to anything outside of this module.
            //
            // We allow a total of 60 retries for getting the receipt with one second between each
            // retry and the next which means that we allow for a total of 60 seconds of waiting
            // before we consider that we're unable to get the transaction receipt.
            let mut retries = 0;
            loop {
                match provider.get_transaction_receipt(*transaction_hash).await {
                    Ok(Some(receipt)) => {
                        tracing::info!("Obtained the transaction receipt");
                        break Ok(receipt);
                    }
                    Ok(None) => {
                        if retries == 60 {
                            tracing::error!(
                                "Polled for transaction receipt for 60 seconds but failed to get it"
                            );
                            break Err(anyhow::anyhow!("Failed to get the transaction receipt"));
                        } else {
                            tracing::trace!(
                                retries,
                                "Sleeping for 1 second and trying to get the receipt again"
                            );
                            retries += 1;
                            tokio::time::sleep(std::time::Duration::from_secs(1)).await;
                            continue;
                        }
                    }
                    Err(error) => {
                        let error_string = error.to_string();
                        if error_string.contains("transaction indexing is in progress") {
                            if retries == 60 {
                                tracing::error!(
                                    "Polled for transaction receipt for 60 seconds but failed to get it"
                                );
                                break Err(error.into());
                            } else {
                                tracing::trace!(
                                    retries,
                                    "Sleeping for 1 second and trying to get the receipt again"
                                );
                                retries += 1;
                                tokio::time::sleep(std::time::Duration::from_secs(1)).await;
                                continue;
                            }
                        } else {
                            break Err(error.into());
                        }
                    }
                }
            }
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn trace_transaction(
        &self,
        transaction: TransactionReceipt,
    ) -> anyhow::Result<alloy::rpc::types::trace::geth::GethTrace> {
        let trace_options = GethDebugTracingOptions::prestate_tracer(PreStateConfig {
            diff_mode: Some(true),
            disable_code: None,
            disable_storage: None,
        });
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            Ok(provider
                .await?
                .debug_trace_transaction(transaction.transaction_hash, trace_options)
                .await?)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn state_diff(
        &self,
        transaction: alloy::rpc::types::TransactionReceipt,
    ) -> anyhow::Result<DiffMode> {
        match self
            .trace_transaction(transaction)?
            .try_into_pre_state_frame()?
        {
            PreStateFrame::Diff(diff) => Ok(diff),
            _ => anyhow::bail!("expected a diff mode trace"),
        }
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn fetch_add_nonce(&self, address: Address) -> anyhow::Result<u64> {
        let provider = self.provider();
        let onchain_nonce = BlockingExecutor::execute::<anyhow::Result<_>>(async move {
            provider
                .await?
                .get_transaction_count(address)
                .await
                .map_err(Into::into)
        })??;
        let mut nonces = self.nonces.lock().unwrap();
        let current = nonces.entry(address).or_insert(onchain_nonce);
        let value = *current;
        *current += 1;
        Ok(value)
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn chain_id(&self) -> anyhow::Result<alloy::primitives::ChainId> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider.await?.get_chain_id().await.map_err(Into::into)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn block_gas_limit(&self, number: BlockNumberOrTag) -> anyhow::Result<u128> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider
                .await?
                .get_block_by_number(number)
                .await?
                .ok_or(anyhow::Error::msg("Blockchain has no blocks"))
                .map(|block| block.header.gas_limit as _)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn block_coinbase(&self, number: BlockNumberOrTag) -> anyhow::Result<Address> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider
                .await?
                .get_block_by_number(number)
                .await?
                .ok_or(anyhow::Error::msg("Blockchain has no blocks"))
                .map(|block| block.header.beneficiary)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn block_difficulty(&self, number: BlockNumberOrTag) -> anyhow::Result<U256> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider
                .await?
                .get_block_by_number(number)
                .await?
                .ok_or(anyhow::Error::msg("Blockchain has no blocks"))
                .map(|block| block.header.difficulty)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn block_hash(&self, number: BlockNumberOrTag) -> anyhow::Result<BlockHash> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider
                .await?
                .get_block_by_number(number)
                .await?
                .ok_or(anyhow::Error::msg("Blockchain has no blocks"))
                .map(|block| block.header.hash)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn block_timestamp(&self, number: BlockNumberOrTag) -> anyhow::Result<BlockTimestamp> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider
                .await?
                .get_block_by_number(number)
                .await?
                .ok_or(anyhow::Error::msg("Blockchain has no blocks"))
                .map(|block| block.header.timestamp)
        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn last_block_number(&self) -> anyhow::Result<BlockNumber> {
        let provider = self.provider();
        BlockingExecutor::execute(async move {
            provider.await?.get_block_number().await.map_err(Into::into)
        })?
    }
 }
 impl Node for Instance {
    fn new(config: &Arguments) -> Self {
        let geth_directory = config.directory().join(Self::BASE_DIRECTORY);
        let id = NODE_COUNT.fetch_add(1, Ordering::SeqCst);
        let base_directory = geth_directory.join(id.to_string());
        Self {
            connection_string: base_directory.join(Self::IPC_FILE).display().to_string(),
            data_directory: base_directory.join(Self::DATA_DIRECTORY),
            logs_directory: base_directory.join(Self::LOGS_DIRECTORY),
            base_directory,
            geth: config.geth.clone(),
            id,
            handle: None,
            network_id: config.network_id,
            start_timeout: config.geth_start_timeout,
            wallet: config.wallet(),
            nonces: Mutex::new(HashMap::new()),
            // We know that we only need to be storing 2 files so we can specify that when creating
            // the vector. It's the stdout and stderr of the geth node.
            logs_file_to_flush: Vec::with_capacity(2),
        }
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn connection_string(&self) -> String {
        self.connection_string.clone()
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn shutdown(&mut self) -> anyhow::Result<()> {
        // Terminate the processes in a graceful manner to allow for the output to be flushed.
        if let Some(mut child) = self.handle.take() {
            child
                .kill()
                .map_err(|error| anyhow::anyhow!("Failed to kill the geth process: {error:?}"))?;
        }
        // Flushing the files that we're using for keeping the logs before shutdown.
        for file in self.logs_file_to_flush.iter_mut() {
            file.flush()?
        }
        // Remove the node's database so that subsequent runs do not run on the same database. We
        // ignore the error just in case the directory didn't exist in the first place and therefore
        // there's nothing to be deleted.
        let _ = remove_dir_all(self.base_directory.join(Self::DATA_DIRECTORY));
        Ok(())
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn spawn(&mut self, genesis: String) -> anyhow::Result<()> {
        self.init(genesis)?.spawn_process()?;
        Ok(())
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn version(&self) -> anyhow::Result<String> {
        let output = Command::new(&self.geth)
            .arg("--version")
            .stdin(Stdio::null())
            .stdout(Stdio::piped())
            .stderr(Stdio::null())
            .spawn()?
            .wait_with_output()?
            .stdout;
        Ok(String::from_utf8_lossy(&output).into())
    }
 }
 impl Drop for Instance {
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
    fn drop(&mut self) {
        self.shutdown().expect("Failed to shutdown")
    }
 }
 #[cfg(test)]
 mod tests {
    use revive_dt_config::Arguments;
    use temp_dir::TempDir;
    use crate::{GENESIS_JSON, Node};
    use super::*;
    fn test_config() -> (Arguments, TempDir) {
        let mut config = Arguments::default();
        let temp_dir = TempDir::new().unwrap();
        config.working_directory = temp_dir.path().to_path_buf().into();
        (config, temp_dir)
    }
    fn new_node() -> (Instance, TempDir) {
        let (args, temp_dir) = test_config();
        let mut node = Instance::new(&args);
        node.init(GENESIS_JSON.to_owned())
            .expect("Failed to initialize the node")
            .spawn_process()
            .expect("Failed to spawn the node process");
        (node, temp_dir)
    }
    #[test]
    fn init_works() {
        Instance::new(&test_config().0)
            .init(GENESIS_JSON.to_string())
            .unwrap();
    }
    #[test]
    fn spawn_works() {
        Instance::new(&test_config().0)
            .spawn(GENESIS_JSON.to_string())
            .unwrap();
    }
    #[test]
    fn version_works() {
        let version = Instance::new(&test_config().0).version().unwrap();
        assert!(
            version.starts_with("geth version"),
            "expected version string, got: '{version}'"
        );
    }
    #[test]
    fn can_get_chain_id_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let chain_id = node.chain_id();
        // Assert
        let chain_id = chain_id.expect("Failed to get the chain id");
        assert_eq!(chain_id, 420_420_420);
    }
    #[test]
    fn can_get_gas_limit_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let gas_limit = node.block_gas_limit(BlockNumberOrTag::Latest);
        // Assert
        let gas_limit = gas_limit.expect("Failed to get the gas limit");
        assert_eq!(gas_limit, u32::MAX as u128)
    }
    #[test]
    fn can_get_coinbase_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let coinbase = node.block_coinbase(BlockNumberOrTag::Latest);
        // Assert
        let coinbase = coinbase.expect("Failed to get the coinbase");
        assert_eq!(coinbase, Address::new([0xFF; 20]))
    }
    #[test]
    fn can_get_block_difficulty_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let block_difficulty = node.block_difficulty(BlockNumberOrTag::Latest);
        // Assert
        let block_difficulty = block_difficulty.expect("Failed to get the block difficulty");
        assert_eq!(block_difficulty, U256::ZERO)
    }
    #[test]
    fn can_get_block_hash_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let block_hash = node.block_hash(BlockNumberOrTag::Latest);
        // Assert
        let _ = block_hash.expect("Failed to get the block hash");
    }
    #[test]
    fn can_get_block_timestamp_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let block_timestamp = node.block_timestamp(BlockNumberOrTag::Latest);
        // Assert
        let _ = block_timestamp.expect("Failed to get the block timestamp");
    }
    #[test]
    fn can_get_block_number_from_node() {
        // Arrange
        let (node, _temp_dir) = new_node();
        // Act
        let block_number = node.last_block_number();
        // Assert
        let block_number = block_number.expect("Failed to get the block number");
        assert_eq!(block_number, 0)
    }
 }
@@ -0,0 +1,3 @@
 mod process;
 pub use process::*;
@@ -0,0 +1,191 @@
 use std::{
    fs::{File, OpenOptions},
    io::{BufRead, BufReader, Write},
    path::Path,
    process::{Child, Command},
    time::{Duration, Instant},
 };
 use anyhow::{Context, Result, bail};
 /// A wrapper around processes which allows for their stdout and stderr to be logged and flushed
 /// when the process is dropped.
 #[derive(Debug)]
 pub struct Process {
    /// The handle of the child process.
    child: Child,
    /// The file that stdout is being logged to.
    stdout_logs_file: File,
    /// The file that stderr is being logged to.
    stderr_logs_file: File,
 }
 impl Process {
    pub fn new(
        log_file_prefix: impl Into<Option<&'static str>>,
        logs_directory: impl AsRef<Path>,
        binary_path: impl AsRef<Path>,
        command_building_callback: impl FnOnce(&mut Command, File, File),
        process_readiness_wait_behavior: ProcessReadinessWaitBehavior,
    ) -> Result<Self> {
        let log_file_prefix = log_file_prefix.into();
        let (stdout_file_name, stderr_file_name) = match log_file_prefix {
            Some(prefix) => (
                format!("{prefix}_stdout.log"),
                format!("{prefix}_stderr.log"),
            ),
            None => ("stdout.log".to_string(), "stderr.log".to_string()),
        };
        let stdout_logs_file_path = logs_directory.as_ref().join(stdout_file_name);
        let stderr_logs_file_path = logs_directory.as_ref().join(stderr_file_name);
        let stdout_logs_file = OpenOptions::new()
            .write(true)
            .truncate(true)
            .create(true)
            .open(stdout_logs_file_path.as_path())
            .context("Failed to open the stdout logs file")?;
        let stderr_logs_file = OpenOptions::new()
            .write(true)
            .truncate(true)
            .create(true)
            .open(stderr_logs_file_path.as_path())
            .context("Failed to open the stderr logs file")?;
        let mut command = {
            let stdout_logs_file = stdout_logs_file
                .try_clone()
                .context("Failed to clone the stdout logs file")?;
            let stderr_logs_file = stderr_logs_file
                .try_clone()
                .context("Failed to clone the stderr logs file")?;
            let mut command = Command::new(binary_path.as_ref());
            command_building_callback(&mut command, stdout_logs_file, stderr_logs_file);
            command
        };
        let mut child = command
            .spawn()
            .context("Failed to spawn the built command")?;
        match process_readiness_wait_behavior {
            ProcessReadinessWaitBehavior::NoStartupWait => {}
            ProcessReadinessWaitBehavior::WaitDuration(duration) => std::thread::sleep(duration),
            ProcessReadinessWaitBehavior::TimeBoundedWaitFunction {
                max_wait_duration,
                mut check_function,
            } => {
                let spawn_time = Instant::now();
                let stdout_logs_file = OpenOptions::new()
                    .read(true)
                    .open(stdout_logs_file_path)
                    .context("Failed to open the stdout logs file")?;
                let stderr_logs_file = OpenOptions::new()
                    .read(true)
                    .open(stderr_logs_file_path)
                    .context("Failed to open the stderr logs file")?;
                let mut stdout_lines = BufReader::new(stdout_logs_file).lines();
                let mut stderr_lines = BufReader::new(stderr_logs_file).lines();
                let mut stdout = String::new();
                let mut stderr = String::new();
                loop {
                    let stdout_line = stdout_lines.next().and_then(Result::ok);
                    let stderr_line = stderr_lines.next().and_then(Result::ok);
                    if let Some(stdout_line) = stdout_line.as_ref() {
                        stdout.push_str(stdout_line);
                        stdout.push('\n');
                    }
                    if let Some(stderr_line) = stderr_line.as_ref() {
                        stderr.push_str(stderr_line);
                        stderr.push('\n');
                    }
                    let check_result =
                        check_function(stdout_line.as_deref(), stderr_line.as_deref()).context(
                            format!(
                                "Failed to wait for the process to be ready - {stdout} - {stderr}"
                            ),
                        )?;
                    if check_result {
                        break;
                    }
                    if Instant::now().duration_since(spawn_time) > max_wait_duration {
                        bail!(
                            "Waited for the process to start but it failed to start in time. stderr {stderr} - stdout {stdout}"
                        )
                    }
                }
            }
            ProcessReadinessWaitBehavior::WaitForCommandToExit => {
                if !child
                    .wait()
                    .context("Failed waiting for process to finish")?
                    .success()
                {
                    anyhow::bail!("Failed to spawn command");
                }
            }
        }
        Ok(Self {
            child,
            stdout_logs_file,
            stderr_logs_file,
        })
    }
 }
 impl Drop for Process {
    fn drop(&mut self) {
        self.child.kill().expect("Failed to kill the process");
        self.stdout_logs_file
            .flush()
            .expect("Failed to flush the stdout logs file");
        self.stderr_logs_file
            .flush()
            .expect("Failed to flush the stderr logs file");
    }
 }
 pub enum ProcessReadinessWaitBehavior {
    /// The process does not require any kind of wait after it's been spawned and can be used
    /// straight away.
    NoStartupWait,
    /// Waits for the command to exit.
    WaitForCommandToExit,
    /// The process does require some amount of wait duration after it's been started.
    WaitDuration(Duration),
    /// The process requires a time bounded wait function which is a function of the lines that
    /// appear in the log files.
    TimeBoundedWaitFunction {
        /// The maximum amount of time to wait for the check function to return true.
        max_wait_duration: Duration,
        /// The function to use to check if the process spawned is ready to use or not. This
        /// function should return the following in the following cases:
        ///
        /// - `Ok(true)`: Returned when the condition the process is waiting for has been fulfilled
        ///   and the wait is completed.
        /// - `Ok(false)`: The process is not ready yet but it might be ready in the future.
        /// - `Err`: The process is not ready yet and will not be ready in the future as it appears
        ///   that it has encountered an error when it was being spawned.
        ///
        /// The first argument is a line from stdout and the second argument is a line from stderr.
        #[allow(clippy::type_complexity)]
        check_function: Box<dyn FnMut(Option<&str>, Option<&str>) -> anyhow::Result<bool>>,
    },
 }
@@ -1,33 +1,25 @@
 //! This crate implements the testing nodes.
-use revive_dt_config::Arguments;
+use alloy::genesis::Genesis;
 use revive_dt_node_interaction::EthereumNode;
-pub mod geth;
+pub mod constants;
-pub mod kitchensink;
+pub mod helpers;
-pub mod pool;
+pub mod node_implementations;
-
+pub mod provider_utils;
 /// The default genesis configuration.
 pub const GENESIS_JSON: &str = include_str!("../../../genesis.json");
 /// An abstract interface for testing nodes.
 pub trait Node: EthereumNode {
    /// Create a new uninitialized instance.
    fn new(config: &Arguments) -> Self;
    /// Spawns a node configured according to the genesis json.
    ///
    /// Blocking until it's ready to accept transactions.
-    fn spawn(&mut self, genesis: String) -> anyhow::Result<()>;
+    fn spawn(&mut self, genesis: Genesis) -> anyhow::Result<()>;
    /// Prune the node instance and related data.
    ///
    /// Blocking until it's completely stopped.
    fn shutdown(&mut self) -> anyhow::Result<()>;
    /// Returns the nodes connection string.
    fn connection_string(&self) -> String;
    /// Returns the node version.
    fn version(&self) -> anyhow::Result<String>;
 }
@@ -0,0 +1,915 @@
 //! The go-ethereum node implementation.
 use std::{
    fs::{File, create_dir_all, remove_dir_all},
    io::Read,
    ops::ControlFlow,
    path::PathBuf,
    pin::Pin,
    process::{Command, Stdio},
    sync::{
        Arc,
        atomic::{AtomicU32, Ordering},
    },
    time::Duration,
 };
 use alloy::{
    eips::BlockNumberOrTag,
    genesis::{Genesis, GenesisAccount},
    network::{Ethereum, EthereumWallet, NetworkWallet},
    primitives::{Address, BlockHash, BlockNumber, BlockTimestamp, StorageKey, TxHash, U256},
    providers::{
        Provider,
        ext::DebugApi,
        fillers::{CachedNonceManager, ChainIdFiller, NonceFiller},
    },
    rpc::types::{
        EIP1186AccountProofResponse, TransactionReceipt, TransactionRequest,
        trace::geth::{
            DiffMode, GethDebugTracingOptions, GethTrace, PreStateConfig, PreStateFrame,
        },
    },
 };
 use anyhow::Context as _;
 use futures::{FutureExt, Stream, StreamExt};
 use revive_common::EVMVersion;
 use tokio::sync::OnceCell;
 use tracing::{Instrument, error, instrument};
 use revive_dt_common::{
    fs::clear_directory,
    futures::{PollingWaitBehavior, poll},
 };
 use revive_dt_config::*;
 use revive_dt_format::traits::ResolverApi;
 use revive_dt_node_interaction::EthereumNode;
 use revive_dt_report::{EthereumMinedBlockInformation, MinedBlockInformation};
 use crate::{
    Node,
    constants::{CHAIN_ID, INITIAL_BALANCE},
    helpers::{Process, ProcessReadinessWaitBehavior},
    provider_utils::{ConcreteProvider, FallbackGasFiller, construct_concurrency_limited_provider},
 };
 static NODE_COUNT: AtomicU32 = AtomicU32::new(0);
 /// The go-ethereum node instance implementation.
 ///
 /// Implements helpers to initialize, spawn and wait the node.
 ///
 /// Assumes dev mode and IPC only (`P2P`, `http`` etc. are kept disabled).
 ///
 /// Prunes the child process and the base directory on drop.
 #[derive(Debug)]
 #[allow(clippy::type_complexity)]
 pub struct GethNode {
    connection_string: String,
    base_directory: PathBuf,
    data_directory: PathBuf,
    logs_directory: PathBuf,
    geth: PathBuf,
    id: u32,
    handle: Option<Process>,
    start_timeout: Duration,
    wallet: Arc<EthereumWallet>,
    nonce_manager: CachedNonceManager,
    provider: OnceCell<ConcreteProvider<Ethereum, Arc<EthereumWallet>>>,
 }
 impl GethNode {
    const BASE_DIRECTORY: &str = "geth";
    const DATA_DIRECTORY: &str = "data";
    const LOGS_DIRECTORY: &str = "logs";
    const IPC_FILE: &str = "geth.ipc";
    const GENESIS_JSON_FILE: &str = "genesis.json";
    const READY_MARKER: &str = "IPC endpoint opened";
    const ERROR_MARKER: &str = "Fatal:";
    const TRANSACTION_INDEXING_ERROR: &str = "transaction indexing is in progress";
    const TRANSACTION_TRACING_ERROR: &str = "historical state not available in path scheme yet";
    const RECEIPT_POLLING_DURATION: Duration = Duration::from_secs(5 * 60);
    const TRACE_POLLING_DURATION: Duration = Duration::from_secs(60);
    pub fn new(
        context: impl AsRef<WorkingDirectoryConfiguration>
        + AsRef<WalletConfiguration>
        + AsRef<GethConfiguration>
        + Clone,
    ) -> Self {
        let working_directory_configuration =
            AsRef::<WorkingDirectoryConfiguration>::as_ref(&context);
        let wallet_configuration = AsRef::<WalletConfiguration>::as_ref(&context);
        let geth_configuration = AsRef::<GethConfiguration>::as_ref(&context);
        let geth_directory = working_directory_configuration
            .as_path()
            .join(Self::BASE_DIRECTORY);
        let id = NODE_COUNT.fetch_add(1, Ordering::SeqCst);
        let base_directory = geth_directory.join(id.to_string());
        let wallet = wallet_configuration.wallet();
        Self {
            connection_string: base_directory.join(Self::IPC_FILE).display().to_string(),
            data_directory: base_directory.join(Self::DATA_DIRECTORY),
            logs_directory: base_directory.join(Self::LOGS_DIRECTORY),
            base_directory,
            geth: geth_configuration.path.clone(),
            id,
            handle: None,
            start_timeout: geth_configuration.start_timeout_ms,
            wallet: wallet.clone(),
            nonce_manager: Default::default(),
            provider: Default::default(),
        }
    }
    /// Create the node directory and call `geth init` to configure the genesis.
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn init(&mut self, genesis: Genesis) -> anyhow::Result<&mut Self> {
        let _ = clear_directory(&self.base_directory);
        let _ = clear_directory(&self.logs_directory);
        create_dir_all(&self.base_directory)
            .context("Failed to create base directory for geth node")?;
        create_dir_all(&self.logs_directory)
            .context("Failed to create logs directory for geth node")?;
        let genesis = Self::node_genesis(genesis, self.wallet.as_ref());
        let genesis_path = self.base_directory.join(Self::GENESIS_JSON_FILE);
        serde_json::to_writer(
            File::create(&genesis_path).context("Failed to create geth genesis file")?,
            &genesis,
        )
        .context("Failed to serialize geth genesis JSON to file")?;
        let mut child = Command::new(&self.geth)
            .arg("--state.scheme")
            .arg("hash")
            .arg("init")
            .arg("--datadir")
            .arg(&self.data_directory)
            .arg(genesis_path)
            .stderr(Stdio::piped())
            .stdout(Stdio::null())
            .spawn()
            .context("Failed to spawn geth --init process")?;
        let mut stderr = String::new();
        child
            .stderr
            .take()
            .expect("should be piped")
            .read_to_string(&mut stderr)
            .context("Failed to read geth --init stderr")?;
        if !child
            .wait()
            .context("Failed waiting for geth --init process to finish")?
            .success()
        {
            anyhow::bail!("failed to initialize geth node #{:?}: {stderr}", &self.id);
        }
        Ok(self)
    }
    /// Spawn the go-ethereum node child process.
    ///
    /// [Instance::init] must be called prior.
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn spawn_process(&mut self) -> anyhow::Result<&mut Self> {
        let process = Process::new(
            None,
            self.logs_directory.as_path(),
            self.geth.as_path(),
            |command, stdout_file, stderr_file| {
                command
                    .arg("--dev")
                    .arg("--datadir")
                    .arg(&self.data_directory)
                    .arg("--ipcpath")
                    .arg(&self.connection_string)
                    .arg("--nodiscover")
                    .arg("--maxpeers")
                    .arg("0")
                    .arg("--txlookuplimit")
                    .arg("0")
                    .arg("--cache.blocklogs")
                    .arg("512")
                    .arg("--state.scheme")
                    .arg("hash")
                    .arg("--syncmode")
                    .arg("full")
                    .arg("--gcmode")
                    .arg("archive")
                    .stderr(stderr_file)
                    .stdout(stdout_file);
            },
            ProcessReadinessWaitBehavior::TimeBoundedWaitFunction {
                max_wait_duration: self.start_timeout,
                check_function: Box::new(|_, stderr_line| match stderr_line {
                    Some(line) => {
                        if line.contains(Self::ERROR_MARKER) {
                            anyhow::bail!("Failed to start geth {line}");
                        } else if line.contains(Self::READY_MARKER) {
                            Ok(true)
                        } else {
                            Ok(false)
                        }
                    }
                    None => Ok(false),
                }),
            },
        );
        match process {
            Ok(process) => self.handle = Some(process),
            Err(err) => {
                error!(?err, "Failed to start geth, shutting down gracefully");
                self.shutdown()
                    .context("Failed to gracefully shutdown after geth start error")?;
                return Err(err);
            }
        }
        Ok(self)
    }
    async fn provider(&self) -> anyhow::Result<ConcreteProvider<Ethereum, Arc<EthereumWallet>>> {
        self.provider
            .get_or_try_init(|| async move {
                construct_concurrency_limited_provider::<Ethereum, _>(
                    self.connection_string.as_str(),
                    FallbackGasFiller::default(),
                    ChainIdFiller::new(Some(CHAIN_ID)),
                    NonceFiller::new(self.nonce_manager.clone()),
                    self.wallet.clone(),
                )
                .await
                .context("Failed to construct the provider")
            })
            .await
            .cloned()
    }
    pub fn node_genesis(mut genesis: Genesis, wallet: &EthereumWallet) -> Genesis {
        for signer_address in NetworkWallet::<Ethereum>::signer_addresses(&wallet) {
            genesis
                .alloc
                .entry(signer_address)
                .or_insert(GenesisAccount::default().with_balance(U256::from(INITIAL_BALANCE)));
        }
        genesis
    }
 }
 impl EthereumNode for GethNode {
    fn pre_transactions(&mut self) -> Pin<Box<dyn Future<Output = anyhow::Result<()>> + '_>> {
        Box::pin(async move { Ok(()) })
    }
    fn id(&self) -> usize {
        self.id as _
    }
    fn connection_string(&self) -> &str {
        &self.connection_string
    }
    #[instrument(
        level = "info",
        skip_all,
        fields(geth_node_id = self.id, connection_string = self.connection_string),
        err,
    )]
    fn submit_transaction(
        &self,
        transaction: TransactionRequest,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<TxHash>> + '_>> {
        Box::pin(async move {
            let provider = self
                .provider()
                .await
                .context("Failed to create the provider for transaction submission")?;
            let pending_transaction = provider
                .send_transaction(transaction)
                .await
                .context("Failed to submit the transaction through the provider")?;
            Ok(*pending_transaction.tx_hash())
        })
    }
    #[instrument(
        level = "info",
        skip_all,
        fields(geth_node_id = self.id, connection_string = self.connection_string),
        err,
    )]
    fn get_receipt(
        &self,
        tx_hash: TxHash,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<TransactionReceipt>> + '_>> {
        Box::pin(async move {
            self.provider()
                .await
                .context("Failed to create provider for getting the receipt")?
                .get_transaction_receipt(tx_hash)
                .await
                .context("Failed to get the receipt of the transaction")?
                .context("Failed to get the receipt of the transaction")
        })
    }
    #[instrument(
        level = "info",
        skip_all,
        fields(geth_node_id = self.id, connection_string = self.connection_string),
        err,
    )]
    fn execute_transaction(
        &self,
        transaction: TransactionRequest,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<TransactionReceipt>> + '_>> {
        Box::pin(async move {
            let provider = self
                .provider()
                .await
                .context("Failed to create provider for transaction submission")?;
            let pending_transaction = provider
                .send_transaction(transaction)
                .await
                .inspect_err(
                    |err| error!(%err, "Encountered an error when submitting the transaction"),
                )
                .context("Failed to submit transaction to geth node")?;
            let transaction_hash = *pending_transaction.tx_hash();
            // The following is a fix for the "transaction indexing is in progress" error that we used
            // to get. You can find more information on this in the following GH issue in geth
            // https://github.com/ethereum/go-ethereum/issues/28877. To summarize what's going on,
            // before we can get the receipt of the transaction it needs to have been indexed by the
            // node's indexer. Just because the transaction has been confirmed it doesn't mean that it
            // has been indexed. When we call alloy's `get_receipt` it checks if the transaction was
            // confirmed. If it has been, then it will call `eth_getTransactionReceipt` method which
            // _might_ return the above error if the tx has not yet been indexed yet. So, we need to
            // implement a retry mechanism for the receipt to keep retrying to get it until it
            // eventually works, but we only do that if the error we get back is the "transaction
            // indexing is in progress" error or if the receipt is None.
            //
            // Getting the transaction indexed and taking a receipt can take a long time especially when
            // a lot of transactions are being submitted to the node. Thus, while initially we only
            // allowed for 60 seconds of waiting with a 1 second delay in polling, we need to allow for
            // a larger wait time. Therefore, in here we allow for 5 minutes of waiting with exponential
            // backoff each time we attempt to get the receipt and find that it's not available.
            poll(
                Self::RECEIPT_POLLING_DURATION,
                PollingWaitBehavior::Constant(Duration::from_millis(200)),
                move || {
                    let provider = provider.clone();
                    async move {
                        match provider.get_transaction_receipt(transaction_hash).await {
                            Ok(Some(receipt)) => Ok(ControlFlow::Break(receipt)),
                            Ok(None) => Ok(ControlFlow::Continue(())),
                            Err(error) => {
                                let error_string = error.to_string();
                                match error_string.contains(Self::TRANSACTION_INDEXING_ERROR) {
                                    true => Ok(ControlFlow::Continue(())),
                                    false => Err(error.into()),
                                }
                            }
                        }
                    }
                },
            )
            .instrument(tracing::info_span!(
                "Awaiting transaction receipt",
                ?transaction_hash
            ))
            .await
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn trace_transaction(
        &self,
        tx_hash: TxHash,
        trace_options: GethDebugTracingOptions,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<GethTrace>> + '_>> {
        Box::pin(async move {
            let provider = self
                .provider()
                .await
                .context("Failed to create provider for tracing")?;
            poll(
                Self::TRACE_POLLING_DURATION,
                PollingWaitBehavior::Constant(Duration::from_millis(200)),
                move || {
                    let provider = provider.clone();
                    let trace_options = trace_options.clone();
                    async move {
                        match provider
                            .debug_trace_transaction(tx_hash, trace_options)
                            .await
                        {
                            Ok(trace) => Ok(ControlFlow::Break(trace)),
                            Err(error) => {
                                let error_string = error.to_string();
                                match error_string.contains(Self::TRANSACTION_TRACING_ERROR) {
                                    true => Ok(ControlFlow::Continue(())),
                                    false => Err(error.into()),
                                }
                            }
                        }
                    }
                },
            )
            .await
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn state_diff(
        &self,
        tx_hash: TxHash,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<DiffMode>> + '_>> {
        Box::pin(async move {
            let trace_options = GethDebugTracingOptions::prestate_tracer(PreStateConfig {
                diff_mode: Some(true),
                disable_code: None,
                disable_storage: None,
            });
            match self
                .trace_transaction(tx_hash, trace_options)
                .await
                .context("Failed to trace transaction for prestate diff")?
                .try_into_pre_state_frame()
                .context("Failed to convert trace into pre-state frame")?
            {
                PreStateFrame::Diff(diff) => Ok(diff),
                _ => anyhow::bail!("expected a diff mode trace"),
            }
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn balance_of(
        &self,
        address: Address,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<U256>> + '_>> {
        Box::pin(async move {
            self.provider()
                .await
                .context("Failed to get the Geth provider")?
                .get_balance(address)
                .await
                .map_err(Into::into)
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn latest_state_proof(
        &self,
        address: Address,
        keys: Vec<StorageKey>,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<EIP1186AccountProofResponse>> + '_>> {
        Box::pin(async move {
            self.provider()
                .await
                .context("Failed to get the Geth provider")?
                .get_proof(address, keys)
                .latest()
                .await
                .map_err(Into::into)
        })
    }
    // #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn resolver(
        &self,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Arc<dyn ResolverApi + '_>>> + '_>> {
        Box::pin(async move {
            let id = self.id;
            let provider = self.provider().await?;
            Ok(Arc::new(GethNodeResolver { id, provider }) as Arc<dyn ResolverApi>)
        })
    }
    fn evm_version(&self) -> EVMVersion {
        EVMVersion::Cancun
    }
    fn subscribe_to_full_blocks_information(
        &self,
    ) -> Pin<
        Box<
            dyn Future<Output = anyhow::Result<Pin<Box<dyn Stream<Item = MinedBlockInformation>>>>>
                + '_,
        >,
    > {
        Box::pin(async move {
            let provider = self
                .provider()
                .await
                .context("Failed to create the provider for block subscription")?;
            let block_subscription = provider.subscribe_full_blocks();
            let block_stream = block_subscription
                .into_stream()
                .await
                .context("Failed to create the block stream")?;
            let mined_block_information_stream = block_stream.filter_map(|block| async {
                let block = block.ok()?;
                Some(MinedBlockInformation {
                    ethereum_block_information: EthereumMinedBlockInformation {
                        block_number: block.number(),
                        block_timestamp: block.header.timestamp,
                        mined_gas: block.header.gas_used as _,
                        block_gas_limit: block.header.gas_limit as _,
                        transaction_hashes: block
                            .transactions
                            .into_hashes()
                            .as_hashes()
                            .expect("Must be hashes")
                            .to_vec(),
                    },
                    substrate_block_information: None,
                })
            });
            Ok(Box::pin(mined_block_information_stream)
                as Pin<Box<dyn Stream<Item = MinedBlockInformation>>>)
        })
    }
    fn provider(
        &self,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<alloy::providers::DynProvider<Ethereum>>> + '_>>
    {
        Box::pin(
            self.provider()
                .map(|provider| provider.map(|provider| provider.erased())),
        )
    }
 }
 pub struct GethNodeResolver {
    id: u32,
    provider: ConcreteProvider<Ethereum, Arc<EthereumWallet>>,
 }
 impl ResolverApi for GethNodeResolver {
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn chain_id(
        &self,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<alloy::primitives::ChainId>> + '_>> {
        Box::pin(async move { self.provider.get_chain_id().await.map_err(Into::into) })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn transaction_gas_price(
        &self,
        tx_hash: TxHash,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<u128>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_transaction_receipt(tx_hash)
                .await?
                .context("Failed to get the transaction receipt")
                .map(|receipt| receipt.effective_gas_price)
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn block_gas_limit(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<u128>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_block_by_number(number)
                .await
                .context("Failed to get the geth block")?
                .context("Failed to get the Geth block, perhaps there are no blocks?")
                .map(|block| block.header.gas_limit as _)
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn block_coinbase(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<Address>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_block_by_number(number)
                .await
                .context("Failed to get the geth block")?
                .context("Failed to get the Geth block, perhaps there are no blocks?")
                .map(|block| block.header.beneficiary)
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn block_difficulty(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<U256>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_block_by_number(number)
                .await
                .context("Failed to get the geth block")?
                .context("Failed to get the Geth block, perhaps there are no blocks?")
                .map(|block| U256::from_be_bytes(block.header.mix_hash.0))
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn block_base_fee(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<u64>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_block_by_number(number)
                .await
                .context("Failed to get the geth block")?
                .context("Failed to get the Geth block, perhaps there are no blocks?")
                .and_then(|block| {
                    block
                        .header
                        .base_fee_per_gas
                        .context("Failed to get the base fee per gas")
                })
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn block_hash(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<BlockHash>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_block_by_number(number)
                .await
                .context("Failed to get the geth block")?
                .context("Failed to get the Geth block, perhaps there are no blocks?")
                .map(|block| block.header.hash)
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn block_timestamp(
        &self,
        number: BlockNumberOrTag,
    ) -> Pin<Box<dyn Future<Output = anyhow::Result<BlockTimestamp>> + '_>> {
        Box::pin(async move {
            self.provider
                .get_block_by_number(number)
                .await
                .context("Failed to get the geth block")?
                .context("Failed to get the Geth block, perhaps there are no blocks?")
                .map(|block| block.header.timestamp)
        })
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn last_block_number(&self) -> Pin<Box<dyn Future<Output = anyhow::Result<BlockNumber>> + '_>> {
        Box::pin(async move { self.provider.get_block_number().await.map_err(Into::into) })
    }
 }
 impl Node for GethNode {
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn shutdown(&mut self) -> anyhow::Result<()> {
        drop(self.handle.take());
        // Remove the node's database so that subsequent runs do not run on the same database. We
        // ignore the error just in case the directory didn't exist in the first place and therefore
        // there's nothing to be deleted.
        let _ = remove_dir_all(self.base_directory.join(Self::DATA_DIRECTORY));
        Ok(())
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn spawn(&mut self, genesis: Genesis) -> anyhow::Result<()> {
        self.init(genesis)?.spawn_process()?;
        Ok(())
    }
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn version(&self) -> anyhow::Result<String> {
        let output = Command::new(&self.geth)
            .arg("--version")
            .stdin(Stdio::null())
            .stdout(Stdio::piped())
            .stderr(Stdio::null())
            .spawn()
            .context("Failed to spawn geth --version process")?
            .wait_with_output()
            .context("Failed to wait for geth --version output")?
            .stdout;
        Ok(String::from_utf8_lossy(&output).into())
    }
 }
 impl Drop for GethNode {
    #[instrument(level = "info", skip_all, fields(geth_node_id = self.id))]
    fn drop(&mut self) {
        self.shutdown().expect("Failed to shutdown")
    }
 }
 #[cfg(test)]
 mod tests {
    use std::sync::LazyLock;
    use super::*;
    fn test_config() -> TestExecutionContext {
        TestExecutionContext::default()
    }
    fn new_node() -> (TestExecutionContext, GethNode) {
        let context = test_config();
        let mut node = GethNode::new(&context);
        node.init(context.genesis_configuration.genesis().unwrap().clone())
            .expect("Failed to initialize the node")
            .spawn_process()
            .expect("Failed to spawn the node process");
        (context, node)
    }
    fn shared_state() -> &'static (TestExecutionContext, GethNode) {
        static STATE: LazyLock<(TestExecutionContext, GethNode)> = LazyLock::new(new_node);
        &STATE
    }
    fn shared_node() -> &'static GethNode {
        &shared_state().1
    }
    #[tokio::test]
    async fn node_mines_simple_transfer_transaction_and_returns_receipt() {
        // Arrange
        let (context, node) = shared_state();
        let account_address = context
            .wallet_configuration
            .wallet()
            .default_signer()
            .address();
        let transaction = TransactionRequest::default()
            .to(account_address)
            .value(U256::from(100_000_000_000_000u128));
        // Act
        let receipt = node.execute_transaction(transaction).await;
        // Assert
        let _ = receipt.expect("Failed to get the receipt for the transfer");
    }
    #[test]
    #[ignore = "Ignored since they take a long time to run"]
    fn version_works() {
        // Arrange
        let node = shared_node();
        // Act
        let version = node.version();
        // Assert
        let version = version.expect("Failed to get the version");
        assert!(
            version.starts_with("geth version"),
            "expected version string, got: '{version}'"
        );
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_chain_id_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let chain_id = node.resolver().await.unwrap().chain_id().await;
        // Assert
        let chain_id = chain_id.expect("Failed to get the chain id");
        assert_eq!(chain_id, 420_420_420);
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_gas_limit_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let gas_limit = node
            .resolver()
            .await
            .unwrap()
            .block_gas_limit(BlockNumberOrTag::Latest)
            .await;
        // Assert
        let _ = gas_limit.expect("Failed to get the gas limit");
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_coinbase_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let coinbase = node
            .resolver()
            .await
            .unwrap()
            .block_coinbase(BlockNumberOrTag::Latest)
            .await;
        // Assert
        let _ = coinbase.expect("Failed to get the coinbase");
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_block_difficulty_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let block_difficulty = node
            .resolver()
            .await
            .unwrap()
            .block_difficulty(BlockNumberOrTag::Latest)
            .await;
        // Assert
        let _ = block_difficulty.expect("Failed to get the block difficulty");
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_block_hash_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let block_hash = node
            .resolver()
            .await
            .unwrap()
            .block_hash(BlockNumberOrTag::Latest)
            .await;
        // Assert
        let _ = block_hash.expect("Failed to get the block hash");
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_block_timestamp_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let block_timestamp = node
            .resolver()
            .await
            .unwrap()
            .block_timestamp(BlockNumberOrTag::Latest)
            .await;
        // Assert
        let _ = block_timestamp.expect("Failed to get the block timestamp");
    }
    #[tokio::test]
    #[ignore = "Ignored since they take a long time to run"]
    async fn can_get_block_number_from_node() {
        // Arrange
        let node = shared_node();
        // Act
        let block_number = node.resolver().await.unwrap().last_block_number().await;
        // Assert
        let _ = block_number.expect("Failed to get the block number");
    }
 }
@@ -0,0 +1,4 @@
 pub mod geth;
 pub mod lighthouse_geth;
 pub mod substrate;
 pub mod zombienet;
@@ -1,68 +0,0 @@
 //! This crate implements concurrent handling of testing node.
 use std::{
    fs::read_to_string,
    sync::atomic::{AtomicUsize, Ordering},
    thread,
 };
 use anyhow::Context;
 use revive_dt_config::Arguments;
 use crate::Node;
 /// The node pool starts one or more [Node] which then can be accessed
 /// in a round robbin fasion.
 pub struct NodePool<T> {
    next: AtomicUsize,
    nodes: Vec<T>,
 }
 impl<T> NodePool<T>
 where
    T: Node + Send + 'static,
 {
    /// Create a new Pool. This will start as many nodes as there are workers in `config`.
    pub fn new(config: &Arguments) -> anyhow::Result<Self> {
        let nodes = config.workers;
        let genesis = read_to_string(&config.genesis_file).context(format!(
            "can not read genesis file: {}",
            config.genesis_file.display()
        ))?;
        let mut handles = Vec::with_capacity(nodes);
        for _ in 0..nodes {
            let config = config.clone();
            let genesis = genesis.clone();
            handles.push(thread::spawn(move || spawn_node::<T>(&config, genesis)));
        }
        let mut nodes = Vec::with_capacity(nodes);
        for handle in handles {
            nodes.push(
                handle
                    .join()
                    .map_err(|error| anyhow::anyhow!("failed to spawn node: {:?}", error))?
                    .map_err(|error| anyhow::anyhow!("node failed to spawn: {error}"))?,
            );
        }
        Ok(Self {
            nodes,
            next: Default::default(),
        })
    }
    /// Get a handle to the next node.
    pub fn round_robbin(&self) -> &T {
        let current = self.next.fetch_add(1, Ordering::SeqCst) % self.nodes.len();
        self.nodes.get(current).unwrap()
    }
 }
 fn spawn_node<T: Node + Send>(args: &Arguments, genesis: String) -> anyhow::Result<T> {
    let mut node = T::new(args);
    tracing::info!("starting node: {}", node.connection_string());
    node.spawn(genesis)?;
    Ok(node)
 }
@@ -0,0 +1,69 @@
 use std::sync::Arc;
 use alloy::transports::BoxFuture;
 use tokio::sync::Semaphore;
 use tower::{Layer, Service};
 #[derive(Clone, Debug)]
 pub struct ConcurrencyLimiterLayer {
    semaphore: Arc<Semaphore>,
 }
 impl ConcurrencyLimiterLayer {
    pub fn new(permit_count: usize) -> Self {
        Self {
            semaphore: Arc::new(Semaphore::new(permit_count)),
        }
    }
 }
 impl<S> Layer<S> for ConcurrencyLimiterLayer {
    type Service = ConcurrencyLimiterService<S>;
    fn layer(&self, inner: S) -> Self::Service {
        ConcurrencyLimiterService {
            service: inner,
            semaphore: self.semaphore.clone(),
        }
    }
 }
 #[derive(Clone)]
 pub struct ConcurrencyLimiterService<S> {
    service: S,
    semaphore: Arc<Semaphore>,
 }
 impl<S, Request> Service<Request> for ConcurrencyLimiterService<S>
 where
    S: Service<Request> + Send,
    S::Future: Send + 'static,
 {
    type Response = S::Response;
    type Error = S::Error;
    type Future = BoxFuture<'static, Result<Self::Response, Self::Error>>;
    fn poll_ready(
        &mut self,
        cx: &mut std::task::Context<'_>,
    ) -> std::task::Poll<Result<(), Self::Error>> {
        self.service.poll_ready(cx)
    }
    fn call(&mut self, req: Request) -> Self::Future {
        let semaphore = self.semaphore.clone();
        let future = self.service.call(req);
        Box::pin(async move {
            let _permit = semaphore
                .acquire()
                .await
                .expect("Semaphore has been closed");
            tracing::debug!(
                available_permits = semaphore.available_permits(),
                "Acquired Semaphore Permit"
            );
            future.await
        })
    }
 }
@@ -0,0 +1,95 @@
 use alloy::{
    network::{Network, TransactionBuilder},
    providers::{
        Provider, SendableTx,
        fillers::{GasFiller, TxFiller},
    },
    transports::TransportResult,
 };
 // Percentage padding applied to estimated gas (e.g. 120 = 20% padding)
 const GAS_ESTIMATE_PADDING_NUMERATOR: u64 = 120;
 const GAS_ESTIMATE_PADDING_DENOMINATOR: u64 = 100;
 #[derive(Clone, Debug)]
 pub struct FallbackGasFiller {
    inner: GasFiller,
    default_gas_limit: u64,
    default_max_fee_per_gas: u128,
    default_priority_fee: u128,
 }
 impl FallbackGasFiller {
    pub fn new(
        default_gas_limit: u64,
        default_max_fee_per_gas: u128,
        default_priority_fee: u128,
    ) -> Self {
        Self {
            inner: GasFiller,
            default_gas_limit,
            default_max_fee_per_gas,
            default_priority_fee,
        }
    }
 }
 impl Default for FallbackGasFiller {
    fn default() -> Self {
        FallbackGasFiller::new(25_000_000, 1_000_000_000, 1_000_000_000)
    }
 }
 impl<N> TxFiller<N> for FallbackGasFiller
 where
    N: Network,
 {
    type Fillable = Option<<GasFiller as TxFiller<N>>::Fillable>;
    fn status(
        &self,
        tx: &<N as Network>::TransactionRequest,
    ) -> alloy::providers::fillers::FillerControlFlow {
        <GasFiller as TxFiller<N>>::status(&self.inner, tx)
    }
    fn fill_sync(&self, _: &mut alloy::providers::SendableTx<N>) {}
    async fn prepare<P: Provider<N>>(
        &self,
        provider: &P,
        tx: &<N as Network>::TransactionRequest,
    ) -> TransportResult<Self::Fillable> {
        match self.inner.prepare(provider, tx).await {
            Ok(fill) => Ok(Some(fill)),
            Err(_) => Ok(None),
        }
    }
    async fn fill(
        &self,
        fillable: Self::Fillable,
        mut tx: alloy::providers::SendableTx<N>,
    ) -> TransportResult<SendableTx<N>> {
        if let Some(fill) = fillable {
            let mut tx = self.inner.fill(fill, tx).await?;
            if let Some(builder) = tx.as_mut_builder() {
                if let Some(estimated) = builder.gas_limit() {
                    let padded = estimated
                        .checked_mul(GAS_ESTIMATE_PADDING_NUMERATOR)
                        .and_then(|v| v.checked_div(GAS_ESTIMATE_PADDING_DENOMINATOR))
                        .unwrap_or(u64::MAX);
                    builder.set_gas_limit(padded);
                }
            }
            Ok(tx)
        } else {
            if let Some(builder) = tx.as_mut_builder() {
                builder.set_gas_limit(self.default_gas_limit);
                builder.set_max_fee_per_gas(self.default_max_fee_per_gas);
                builder.set_max_priority_fee_per_gas(self.default_priority_fee);
            }
            Ok(tx)
        }
    }
 }
@@ -0,0 +1,7 @@
 mod concurrency_limiter;
 mod fallback_gas_filler;
 mod provider;
 pub use concurrency_limiter::*;
 pub use fallback_gas_filler::*;
 pub use provider::*;
@@ -0,0 +1,132 @@
 use std::{ops::ControlFlow, sync::LazyLock, time::Duration};
 use alloy::{
    network::{Ethereum, Network, NetworkWallet, TransactionBuilder4844},
    providers::{
        Identity, PendingTransactionBuilder, Provider, ProviderBuilder, RootProvider,
        fillers::{ChainIdFiller, FillProvider, JoinFill, NonceFiller, TxFiller, WalletFiller},
    },
    rpc::client::ClientBuilder,
 };
 use anyhow::{Context, Result};
 use revive_dt_common::futures::{PollingWaitBehavior, poll};
 use tracing::{Instrument, debug, info, info_span};
 use crate::provider_utils::{ConcurrencyLimiterLayer, FallbackGasFiller};
 pub type ConcreteProvider<N, W> = FillProvider<
    JoinFill<
        JoinFill<JoinFill<JoinFill<Identity, FallbackGasFiller>, ChainIdFiller>, NonceFiller>,
        WalletFiller<W>,
    >,
    RootProvider<N>,
    N,
 >;
 pub async fn construct_concurrency_limited_provider<N, W>(
    rpc_url: &str,
    fallback_gas_filler: FallbackGasFiller,
    chain_id_filler: ChainIdFiller,
    nonce_filler: NonceFiller,
    wallet: W,
 ) -> Result<ConcreteProvider<N, W>>
 where
    N: Network<TransactionRequest: TransactionBuilder4844>,
    W: NetworkWallet<N>,
    Identity: TxFiller<N>,
    FallbackGasFiller: TxFiller<N>,
    ChainIdFiller: TxFiller<N>,
    NonceFiller: TxFiller<N>,
    WalletFiller<W>: TxFiller<N>,
 {
    // This is a global limit on the RPC concurrency that applies to all of the providers created
    // by the framework. With this limit, it means that we can have a maximum of N concurrent
    // requests at any point of time and no more than that. This is done in an effort to stabilize
    // the framework from some of the interment issues that we've been seeing related to RPC calls.
    static GLOBAL_CONCURRENCY_LIMITER_LAYER: LazyLock<ConcurrencyLimiterLayer> =
        LazyLock::new(|| ConcurrencyLimiterLayer::new(500));
    let client = ClientBuilder::default()
        .layer(GLOBAL_CONCURRENCY_LIMITER_LAYER.clone())
        .connect(rpc_url)
        .await
        .context("Failed to construct the RPC client")?;
    let provider = ProviderBuilder::new()
        .disable_recommended_fillers()
        .network::<N>()
        .filler(fallback_gas_filler)
        .filler(chain_id_filler)
        .filler(nonce_filler)
        .wallet(wallet)
        .connect_client(client);
    Ok(provider)
 }
 pub async fn execute_transaction<N, W>(
    provider: ConcreteProvider<N, W>,
    transaction: N::TransactionRequest,
 ) -> Result<N::ReceiptResponse>
 where
    N: Network<
            TransactionRequest: TransactionBuilder4844,
            TxEnvelope = <Ethereum as Network>::TxEnvelope,
        >,
    W: NetworkWallet<N>,
    Identity: TxFiller<N>,
    FallbackGasFiller: TxFiller<N>,
    ChainIdFiller: TxFiller<N>,
    NonceFiller: TxFiller<N>,
    WalletFiller<W>: TxFiller<N>,
 {
    let sendable_transaction = provider
        .fill(transaction)
        .await
        .context("Failed to fill transaction")?;
    let transaction_envelope = sendable_transaction
        .try_into_envelope()
        .context("Failed to convert transaction into an envelope")?;
    let tx_hash = *transaction_envelope.tx_hash();
    let mut pending_transaction = match provider.send_tx_envelope(transaction_envelope).await {
        Ok(pending_transaction) => pending_transaction,
        Err(error) => {
            let error_string = error.to_string();
            if error_string.contains("Transaction Already Imported") {
                PendingTransactionBuilder::<N>::new(provider.root().clone(), tx_hash)
            } else {
                return Err(error).context(format!("Failed to submit transaction {tx_hash}"));
            }
        }
    };
    debug!(%tx_hash, "Submitted Transaction");
    pending_transaction.set_timeout(Some(Duration::from_secs(240)));
    let tx_hash = pending_transaction.watch().await.context(format!(
        "Transaction inclusion watching timeout for {tx_hash}"
    ))?;
    poll(
        Duration::from_secs(60),
        PollingWaitBehavior::Constant(Duration::from_secs(3)),
        || {
            let provider = provider.clone();
            async move {
                match provider.get_transaction_receipt(tx_hash).await {
                    Ok(Some(receipt)) => {
                        info!("Found the transaction receipt");
                        Ok(ControlFlow::Break(receipt))
                    }
                    _ => Ok(ControlFlow::Continue(())),
                }
            }
        },
    )
    .instrument(info_span!("Polling for receipt", %tx_hash))
    .await
    .context(format!("Polling for receipt failed for {tx_hash}"))
 }
@@ -8,11 +8,22 @@ repository.workspace = true
 rust-version.workspace = true
 [dependencies]
 revive-dt-common = { workspace = true }
 revive-dt-config = { workspace = true }
 revive-dt-format = { workspace = true }
 revive-dt-compiler = { workspace = true }
 alloy = { workspace = true }
 anyhow = { workspace = true }
-tracing = { workspace = true }
+paste = { workspace = true }
 indexmap = { workspace = true, features = ["serde"] }
 itertools = { workspace = true }
 semver = { workspace = true }
 serde = { workspace = true }
 serde_json = { workspace = true }
-revive-solc-json-interface = { workspace = true }
+serde_with = { workspace = true }
 tokio = { workspace = true }
 tracing = { workspace = true }
 [lints]
 workspace = true
@@ -0,0 +1,957 @@
 //! Implementation of the report aggregator task which consumes the events sent by the various
 //! reporters and combines them into a single unified report.
 use std::{
    collections::{BTreeMap, BTreeSet, HashMap, HashSet},
    fs::OpenOptions,
    ops::{Add, Div},
    path::PathBuf,
    time::{SystemTime, UNIX_EPOCH},
 };
 use alloy::primitives::{Address, BlockNumber, BlockTimestamp, TxHash};
 use anyhow::{Context as _, Result};
 use indexmap::IndexMap;
 use itertools::Itertools;
 use revive_dt_common::types::PlatformIdentifier;
 use revive_dt_compiler::{CompilerInput, CompilerOutput, Mode};
 use revive_dt_config::Context;
 use revive_dt_format::{case::CaseIdx, metadata::ContractInstance, steps::StepPath};
 use semver::Version;
 use serde::{Deserialize, Serialize};
 use serde_with::{DisplayFromStr, serde_as};
 use tokio::sync::{
    broadcast::{Sender, channel},
    mpsc::{UnboundedReceiver, UnboundedSender, unbounded_channel},
 };
 use tracing::debug;
 use crate::*;
 pub struct ReportAggregator {
    /* Internal Report State */
    report: Report,
    remaining_cases: HashMap<MetadataFilePath, HashMap<Mode, HashSet<CaseIdx>>>,
    /* Channels */
    runner_tx: Option<UnboundedSender<RunnerEvent>>,
    runner_rx: UnboundedReceiver<RunnerEvent>,
    listener_tx: Sender<ReporterEvent>,
 }
 impl ReportAggregator {
    pub fn new(context: Context) -> Self {
        let (runner_tx, runner_rx) = unbounded_channel::<RunnerEvent>();
        let (listener_tx, _) = channel::<ReporterEvent>(0xFFFF);
        Self {
            report: Report::new(context),
            remaining_cases: Default::default(),
            runner_tx: Some(runner_tx),
            runner_rx,
            listener_tx,
        }
    }
    pub fn into_task(mut self) -> (Reporter, impl Future<Output = Result<()>>) {
        let reporter = self
            .runner_tx
            .take()
            .map(Into::into)
            .expect("Can't fail since this can only be called once");
        (reporter, async move { self.aggregate().await })
    }
    async fn aggregate(mut self) -> Result<()> {
        debug!("Starting to aggregate report");
        while let Some(event) = self.runner_rx.recv().await {
            debug!(event = event.variant_name(), "Received Event");
            match event {
                RunnerEvent::SubscribeToEvents(event) => {
                    self.handle_subscribe_to_events_event(*event);
                }
                RunnerEvent::MetadataFileDiscovery(event) => {
                    self.handle_metadata_file_discovery_event(*event);
                }
                RunnerEvent::TestCaseDiscovery(event) => {
                    self.handle_test_case_discovery(*event);
                }
                RunnerEvent::TestSucceeded(event) => {
                    self.handle_test_succeeded_event(*event);
                }
                RunnerEvent::TestFailed(event) => {
                    self.handle_test_failed_event(*event);
                }
                RunnerEvent::TestIgnored(event) => {
                    self.handle_test_ignored_event(*event);
                }
                RunnerEvent::NodeAssigned(event) => {
                    self.handle_node_assigned_event(*event);
                }
                RunnerEvent::PreLinkContractsCompilationSucceeded(event) => {
                    self.handle_pre_link_contracts_compilation_succeeded_event(*event)
                }
                RunnerEvent::PostLinkContractsCompilationSucceeded(event) => {
                    self.handle_post_link_contracts_compilation_succeeded_event(*event)
                }
                RunnerEvent::PreLinkContractsCompilationFailed(event) => {
                    self.handle_pre_link_contracts_compilation_failed_event(*event)
                }
                RunnerEvent::PostLinkContractsCompilationFailed(event) => {
                    self.handle_post_link_contracts_compilation_failed_event(*event)
                }
                RunnerEvent::LibrariesDeployed(event) => {
                    self.handle_libraries_deployed_event(*event);
                }
                RunnerEvent::ContractDeployed(event) => {
                    self.handle_contract_deployed_event(*event);
                }
                RunnerEvent::Completion(_) => {
                    break;
                }
                /* Benchmarks Events */
                RunnerEvent::StepTransactionInformation(event) => {
                    self.handle_step_transaction_information(*event)
                }
                RunnerEvent::ContractInformation(event) => {
                    self.handle_contract_information(*event);
                }
                RunnerEvent::BlockMined(event) => self.handle_block_mined(*event),
            }
        }
        self.handle_completion(CompletionEvent {});
        debug!("Report aggregation completed");
        let file_name = {
            let current_timestamp = SystemTime::now()
                .duration_since(UNIX_EPOCH)
                .context("System clock is before UNIX_EPOCH; cannot compute report timestamp")?
                .as_secs();
            let mut file_name = current_timestamp.to_string();
            file_name.push_str(".json");
            file_name
        };
        let file_path = self
            .report
            .context
            .working_directory_configuration()
            .as_path()
            .join(file_name);
        let file = OpenOptions::new()
            .create(true)
            .write(true)
            .truncate(true)
            .read(false)
            .open(&file_path)
            .with_context(|| {
                format!(
                    "Failed to open report file for writing: {}",
                    file_path.display()
                )
            })?;
        serde_json::to_writer_pretty(&file, &self.report).with_context(|| {
            format!("Failed to serialize report JSON to {}", file_path.display())
        })?;
        Ok(())
    }
    fn handle_subscribe_to_events_event(&self, event: SubscribeToEventsEvent) {
        let _ = event.tx.send(self.listener_tx.subscribe());
    }
    fn handle_metadata_file_discovery_event(&mut self, event: MetadataFileDiscoveryEvent) {
        self.report.metadata_files.insert(event.path.clone());
    }
    fn handle_test_case_discovery(&mut self, event: TestCaseDiscoveryEvent) {
        self.remaining_cases
            .entry(event.test_specifier.metadata_file_path.clone().into())
            .or_default()
            .entry(event.test_specifier.solc_mode.clone())
            .or_default()
            .insert(event.test_specifier.case_idx);
    }
    fn handle_test_succeeded_event(&mut self, event: TestSucceededEvent) {
        // Remove this from the set of cases we're tracking since it has completed.
        self.remaining_cases
            .entry(event.test_specifier.metadata_file_path.clone().into())
            .or_default()
            .entry(event.test_specifier.solc_mode.clone())
            .or_default()
            .remove(&event.test_specifier.case_idx);
        // Add information on the fact that the case was ignored to the report.
        let test_case_report = self.test_case_report(&event.test_specifier);
        test_case_report.status = Some(TestCaseStatus::Succeeded {
            steps_executed: event.steps_executed,
        });
        self.handle_post_test_case_status_update(&event.test_specifier);
    }
    fn handle_test_failed_event(&mut self, event: TestFailedEvent) {
        // Remove this from the set of cases we're tracking since it has completed.
        self.remaining_cases
            .entry(event.test_specifier.metadata_file_path.clone().into())
            .or_default()
            .entry(event.test_specifier.solc_mode.clone())
            .or_default()
            .remove(&event.test_specifier.case_idx);
        // Add information on the fact that the case was ignored to the report.
        let test_case_report = self.test_case_report(&event.test_specifier);
        test_case_report.status = Some(TestCaseStatus::Failed {
            reason: event.reason,
        });
        self.handle_post_test_case_status_update(&event.test_specifier);
    }
    fn handle_test_ignored_event(&mut self, event: TestIgnoredEvent) {
        // Remove this from the set of cases we're tracking since it has completed.
        self.remaining_cases
            .entry(event.test_specifier.metadata_file_path.clone().into())
            .or_default()
            .entry(event.test_specifier.solc_mode.clone())
            .or_default()
            .remove(&event.test_specifier.case_idx);
        // Add information on the fact that the case was ignored to the report.
        let test_case_report = self.test_case_report(&event.test_specifier);
        test_case_report.status = Some(TestCaseStatus::Ignored {
            reason: event.reason,
            additional_fields: event.additional_fields,
        });
        self.handle_post_test_case_status_update(&event.test_specifier);
    }
    fn handle_post_test_case_status_update(&mut self, specifier: &TestSpecifier) {
        let remaining_cases = self
            .remaining_cases
            .entry(specifier.metadata_file_path.clone().into())
            .or_default()
            .entry(specifier.solc_mode.clone())
            .or_default();
        if !remaining_cases.is_empty() {
            return;
        }
        let case_status = self
            .report
            .execution_information
            .entry(specifier.metadata_file_path.clone().into())
            .or_default()
            .case_reports
            .iter()
            .flat_map(|(case_idx, mode_to_execution_map)| {
                let case_status = mode_to_execution_map
                    .mode_execution_reports
                    .get(&specifier.solc_mode)?
                    .status
                    .clone()
                    .expect("Can't be uninitialized");
                Some((*case_idx, case_status))
            })
            .collect::<BTreeMap<_, _>>();
        let event = ReporterEvent::MetadataFileSolcModeCombinationExecutionCompleted {
            metadata_file_path: specifier.metadata_file_path.clone().into(),
            mode: specifier.solc_mode.clone(),
            case_status,
        };
        // According to the documentation on send, the sending fails if there are no more receiver
        // handles. Therefore, this isn't an error that we want to bubble up or anything. If we fail
        // to send then we ignore the error.
        let _ = self.listener_tx.send(event);
    }
    fn handle_node_assigned_event(&mut self, event: NodeAssignedEvent) {
        let execution_information = self.execution_information(&ExecutionSpecifier {
            test_specifier: event.test_specifier,
            node_id: event.id,
            platform_identifier: event.platform_identifier,
        });
        execution_information.node = Some(TestCaseNodeInformation {
            id: event.id,
            platform_identifier: event.platform_identifier,
            connection_string: event.connection_string,
        });
    }
    fn handle_pre_link_contracts_compilation_succeeded_event(
        &mut self,
        event: PreLinkContractsCompilationSucceededEvent,
    ) {
        let include_input = self
            .report
            .context
            .report_configuration()
            .include_compiler_input;
        let include_output = self
            .report
            .context
            .report_configuration()
            .include_compiler_output;
        let execution_information = self.execution_information(&event.execution_specifier);
        let compiler_input = if include_input {
            event.compiler_input
        } else {
            None
        };
        let compiler_output = if include_output {
            Some(event.compiler_output)
        } else {
            None
        };
        execution_information.pre_link_compilation_status = Some(CompilationStatus::Success {
            is_cached: event.is_cached,
            compiler_version: event.compiler_version,
            compiler_path: event.compiler_path,
            compiler_input,
            compiler_output,
        });
    }
    fn handle_post_link_contracts_compilation_succeeded_event(
        &mut self,
        event: PostLinkContractsCompilationSucceededEvent,
    ) {
        let include_input = self
            .report
            .context
            .report_configuration()
            .include_compiler_input;
        let include_output = self
            .report
            .context
            .report_configuration()
            .include_compiler_output;
        let execution_information = self.execution_information(&event.execution_specifier);
        let compiler_input = if include_input {
            event.compiler_input
        } else {
            None
        };
        let compiler_output = if include_output {
            Some(event.compiler_output)
        } else {
            None
        };
        execution_information.post_link_compilation_status = Some(CompilationStatus::Success {
            is_cached: event.is_cached,
            compiler_version: event.compiler_version,
            compiler_path: event.compiler_path,
            compiler_input,
            compiler_output,
        });
    }
    fn handle_pre_link_contracts_compilation_failed_event(
        &mut self,
        event: PreLinkContractsCompilationFailedEvent,
    ) {
        let execution_information = self.execution_information(&event.execution_specifier);
        execution_information.pre_link_compilation_status = Some(CompilationStatus::Failure {
            reason: event.reason,
            compiler_version: event.compiler_version,
            compiler_path: event.compiler_path,
            compiler_input: event.compiler_input,
        });
    }
    fn handle_post_link_contracts_compilation_failed_event(
        &mut self,
        event: PostLinkContractsCompilationFailedEvent,
    ) {
        let execution_information = self.execution_information(&event.execution_specifier);
        execution_information.post_link_compilation_status = Some(CompilationStatus::Failure {
            reason: event.reason,
            compiler_version: event.compiler_version,
            compiler_path: event.compiler_path,
            compiler_input: event.compiler_input,
        });
    }
    fn handle_libraries_deployed_event(&mut self, event: LibrariesDeployedEvent) {
        self.execution_information(&event.execution_specifier)
            .deployed_libraries = Some(event.libraries);
    }
    fn handle_contract_deployed_event(&mut self, event: ContractDeployedEvent) {
        self.execution_information(&event.execution_specifier)
            .deployed_contracts
            .get_or_insert_default()
            .insert(event.contract_instance.clone(), event.address);
        self.test_case_report(&event.execution_specifier.test_specifier)
            .contract_addresses
            .entry(event.contract_instance)
            .or_default()
            .entry(event.execution_specifier.platform_identifier)
            .or_default()
            .push(event.address);
    }
    fn handle_completion(&mut self, _: CompletionEvent) {
        self.runner_rx.close();
        self.handle_metrics_computation();
    }
    fn handle_metrics_computation(&mut self) {
        for report in self.report.execution_information.values_mut() {
            for report in report.case_reports.values_mut() {
                for report in report.mode_execution_reports.values_mut() {
                    for (platform_identifier, block_information) in
                        report.mined_block_information.iter_mut()
                    {
                        block_information.sort_by(|a, b| {
                            a.ethereum_block_information
                                .block_timestamp
                                .cmp(&b.ethereum_block_information.block_timestamp)
                        });
                        // Computing the TPS.
                        let tps = block_information
                            .iter()
                            .tuple_windows::<(_, _)>()
                            .map(|(block1, block2)| {
                                block2.ethereum_block_information.transaction_hashes.len() as u64
                                    / (block2.ethereum_block_information.block_timestamp
                                        - block1.ethereum_block_information.block_timestamp)
                            })
                            .collect::<Vec<_>>();
                        report
                            .metrics
                            .get_or_insert_default()
                            .transaction_per_second
                            .with_list(*platform_identifier, tps);
                        // Computing the GPS.
                        let gps = block_information
                            .iter()
                            .tuple_windows::<(_, _)>()
                            .map(|(block1, block2)| {
                                block2.ethereum_block_information.mined_gas as u64
                                    / (block2.ethereum_block_information.block_timestamp
                                        - block1.ethereum_block_information.block_timestamp)
                            })
                            .collect::<Vec<_>>();
                        report
                            .metrics
                            .get_or_insert_default()
                            .gas_per_second
                            .with_list(*platform_identifier, gps);
                        // Computing the gas block fullness
                        let gas_block_fullness = block_information
                            .iter()
                            .map(|block| block.gas_block_fullness_percentage())
                            .map(|v| v as u64)
                            .collect::<Vec<_>>();
                        report
                            .metrics
                            .get_or_insert_default()
                            .gas_block_fullness
                            .with_list(*platform_identifier, gas_block_fullness);
                        // Computing the ref-time block fullness
                        let reftime_block_fullness = block_information
                            .iter()
                            .filter_map(|block| block.ref_time_block_fullness_percentage())
                            .map(|v| v as u64)
                            .collect::<Vec<_>>();
                        dbg!(&reftime_block_fullness);
                        if !reftime_block_fullness.is_empty() {
                            report
                                .metrics
                                .get_or_insert_default()
                                .ref_time_block_fullness
                                .get_or_insert_default()
                                .with_list(*platform_identifier, reftime_block_fullness);
                        }
                        // Computing the proof size block fullness
                        let proof_size_block_fullness = block_information
                            .iter()
                            .filter_map(|block| block.proof_size_block_fullness_percentage())
                            .map(|v| v as u64)
                            .collect::<Vec<_>>();
                        dbg!(&proof_size_block_fullness);
                        if !proof_size_block_fullness.is_empty() {
                            report
                                .metrics
                                .get_or_insert_default()
                                .proof_size_block_fullness
                                .get_or_insert_default()
                                .with_list(*platform_identifier, proof_size_block_fullness);
                        }
                    }
                }
            }
        }
    }
    fn handle_step_transaction_information(&mut self, event: StepTransactionInformationEvent) {
        self.test_case_report(&event.execution_specifier.test_specifier)
            .steps
            .entry(event.step_path)
            .or_default()
            .transactions
            .entry(event.execution_specifier.platform_identifier)
            .or_default()
            .push(event.transaction_information);
    }
    fn handle_contract_information(&mut self, event: ContractInformationEvent) {
        self.test_case_report(&event.execution_specifier.test_specifier)
            .compiled_contracts
            .entry(event.source_code_path)
            .or_default()
            .entry(event.contract_name)
            .or_default()
            .contract_size
            .insert(
                event.execution_specifier.platform_identifier,
                event.contract_size,
            );
    }
    fn handle_block_mined(&mut self, event: BlockMinedEvent) {
        self.test_case_report(&event.execution_specifier.test_specifier)
            .mined_block_information
            .entry(event.execution_specifier.platform_identifier)
            .or_default()
            .push(event.mined_block_information);
    }
    fn test_case_report(&mut self, specifier: &TestSpecifier) -> &mut ExecutionReport {
        self.report
            .execution_information
            .entry(specifier.metadata_file_path.clone().into())
            .or_default()
            .case_reports
            .entry(specifier.case_idx)
            .or_default()
            .mode_execution_reports
            .entry(specifier.solc_mode.clone())
            .or_default()
    }
    fn execution_information(
        &mut self,
        specifier: &ExecutionSpecifier,
    ) -> &mut ExecutionInformation {
        let test_case_report = self.test_case_report(&specifier.test_specifier);
        test_case_report
            .platform_execution
            .entry(specifier.platform_identifier)
            .or_default()
            .get_or_insert_default()
    }
 }
 #[serde_as]
 #[derive(Clone, Debug, Serialize, Deserialize)]
 pub struct Report {
    /// The context that the tool was started up with.
    pub context: Context,
    /// The list of metadata files that were found by the tool.
    pub metadata_files: BTreeSet<MetadataFilePath>,
    /// Metrics from the execution.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub metrics: Option<Metrics>,
    /// Information relating to each test case.
    pub execution_information: BTreeMap<MetadataFilePath, MetadataFileReport>,
 }
 impl Report {
    pub fn new(context: Context) -> Self {
        Self {
            context,
            metrics: Default::default(),
            metadata_files: Default::default(),
            execution_information: Default::default(),
        }
    }
 }
 #[derive(Clone, Debug, Serialize, Deserialize, Default)]
 pub struct MetadataFileReport {
    /// Metrics from the execution.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub metrics: Option<Metrics>,
    /// The report of each case keyed by the case idx.
    pub case_reports: BTreeMap<CaseIdx, CaseReport>,
 }
 #[serde_as]
 #[derive(Clone, Debug, Serialize, Deserialize, Default)]
 pub struct CaseReport {
    /// Metrics from the execution.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub metrics: Option<Metrics>,
    /// The [`ExecutionReport`] for each one of the [`Mode`]s.
    #[serde_as(as = "HashMap<DisplayFromStr, _>")]
    pub mode_execution_reports: HashMap<Mode, ExecutionReport>,
 }
 #[derive(Clone, Debug, Serialize, Deserialize, Default)]
 pub struct ExecutionReport {
    /// Information on the status of the test case and whether it succeeded, failed, or was ignored.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub status: Option<TestCaseStatus>,
    /// Metrics from the execution.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub metrics: Option<Metrics>,
    /// Information related to the execution on one of the platforms.
    #[serde(skip_serializing_if = "BTreeMap::is_empty")]
    pub platform_execution: PlatformKeyedInformation<Option<ExecutionInformation>>,
    /// Information on the compiled contracts.
    #[serde(skip_serializing_if = "BTreeMap::is_empty")]
    pub compiled_contracts: BTreeMap<PathBuf, BTreeMap<String, ContractInformation>>,
    /// The addresses of the deployed contracts
    #[serde(skip_serializing_if = "BTreeMap::is_empty")]
    pub contract_addresses: BTreeMap<ContractInstance, PlatformKeyedInformation<Vec<Address>>>,
    /// Information on the mined blocks as part of this execution.
    #[serde(skip_serializing_if = "BTreeMap::is_empty")]
    pub mined_block_information: PlatformKeyedInformation<Vec<MinedBlockInformation>>,
    /// Information tracked for each step that was executed.
    #[serde(skip_serializing_if = "BTreeMap::is_empty")]
    pub steps: BTreeMap<StepPath, StepReport>,
 }
 /// Information related to the status of the test. Could be that the test succeeded, failed, or that
 /// it was ignored.
 #[derive(Clone, Debug, Serialize, Deserialize)]
 #[serde(tag = "status")]
 pub enum TestCaseStatus {
    /// The test case succeeded.
    Succeeded {
        /// The number of steps of the case that were executed.
        steps_executed: usize,
    },
    /// The test case failed.
    Failed {
        /// The reason for the failure of the test case.
        reason: String,
    },
    /// The test case was ignored. This variant carries information related to why it was ignored.
    Ignored {
        /// The reason behind the test case being ignored.
        reason: String,
        /// Additional fields that describe more information on why the test case is ignored.
        #[serde(flatten)]
        additional_fields: IndexMap<String, serde_json::Value>,
    },
 }
 /// Information related to the platform node that's being used to execute the step.
 #[derive(Clone, Debug, Serialize, Deserialize)]
 pub struct TestCaseNodeInformation {
    /// The ID of the node that this case is being executed on.
    pub id: usize,
    /// The platform of the node.
    pub platform_identifier: PlatformIdentifier,
    /// The connection string of the node.
    pub connection_string: String,
 }
 /// Execution information tied to the platform.
 #[derive(Clone, Debug, Default, Serialize, Deserialize)]
 pub struct ExecutionInformation {
    /// Information related to the node assigned to this test case.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub node: Option<TestCaseNodeInformation>,
    /// Information on the pre-link compiled contracts.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub pre_link_compilation_status: Option<CompilationStatus>,
    /// Information on the post-link compiled contracts.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub post_link_compilation_status: Option<CompilationStatus>,
    /// Information on the deployed libraries.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub deployed_libraries: Option<BTreeMap<ContractInstance, Address>>,
    /// Information on the deployed contracts.
    #[serde(skip_serializing_if = "Option::is_none")]
    pub deployed_contracts: Option<BTreeMap<ContractInstance, Address>>,
 }
 /// Information related to compilation
 #[derive(Clone, Debug, Serialize, Deserialize)]
 #[serde(tag = "status")]
 pub enum CompilationStatus {
    /// The compilation was successful.
    Success {
        /// A flag with information on whether the compilation artifacts were cached or not.
        is_cached: bool,
        /// The version of the compiler used to compile the contracts.
        compiler_version: Version,
        /// The path of the compiler used to compile the contracts.
        compiler_path: PathBuf,
        /// The input provided to the compiler to compile the contracts. This is only included if
        /// the appropriate flag is set in the CLI context and if the contracts were not cached and
        /// the compiler was invoked.
        #[serde(skip_serializing_if = "Option::is_none")]
        compiler_input: Option<CompilerInput>,
        /// The output of the compiler. This is only included if the appropriate flag is set in the
        /// CLI contexts.
        #[serde(skip_serializing_if = "Option::is_none")]
        compiler_output: Option<CompilerOutput>,
    },
    /// The compilation failed.
    Failure {
        /// The failure reason.
        reason: String,
        /// The version of the compiler used to compile the contracts.
        #[serde(skip_serializing_if = "Option::is_none")]
        compiler_version: Option<Version>,
        /// The path of the compiler used to compile the contracts.
        #[serde(skip_serializing_if = "Option::is_none")]
        compiler_path: Option<PathBuf>,
        /// The input provided to the compiler to compile the contracts. This is only included if
        /// the appropriate flag is set in the CLI context and if the contracts were not cached and
        /// the compiler was invoked.
        #[serde(skip_serializing_if = "Option::is_none")]
        compiler_input: Option<CompilerInput>,
    },
 }
 /// Information on each step in the execution.
 #[derive(Clone, Debug, Default, Serialize, Deserialize)]
 pub struct StepReport {
    /// Information on the transactions submitted as part of this step.
    transactions: PlatformKeyedInformation<Vec<TransactionInformation>>,
 }
 #[derive(Clone, Debug, Serialize, Deserialize)]
 pub struct TransactionInformation {
    /// The hash of the transaction
    pub transaction_hash: TxHash,
    pub submission_timestamp: u64,
    pub block_timestamp: u64,
    pub block_number: BlockNumber,
 }
 /// The metrics we collect for our benchmarks.
 #[derive(Clone, Debug, Default, Serialize, Deserialize)]
 pub struct Metrics {
    pub transaction_per_second: Metric<u64>,
    pub gas_per_second: Metric<u64>,
    /* Block Fullness */
    pub gas_block_fullness: Metric<u64>,
    #[serde(skip_serializing_if = "Option::is_none")]
    pub ref_time_block_fullness: Option<Metric<u64>>,
    #[serde(skip_serializing_if = "Option::is_none")]
    pub proof_size_block_fullness: Option<Metric<u64>>,
 }
 /// The data that we store for a given metric (e.g., TPS).
 #[derive(Clone, Debug, Default, Serialize, Deserialize)]
 pub struct Metric<T> {
    #[serde(skip_serializing_if = "Option::is_none")]
    pub minimum: Option<PlatformKeyedInformation<T>>,
    #[serde(skip_serializing_if = "Option::is_none")]
    pub maximum: Option<PlatformKeyedInformation<T>>,
    #[serde(skip_serializing_if = "Option::is_none")]
    pub mean: Option<PlatformKeyedInformation<T>>,
    #[serde(skip_serializing_if = "Option::is_none")]
    pub median: Option<PlatformKeyedInformation<T>>,
    #[serde(skip_serializing_if = "Option::is_none")]
    pub raw: Option<PlatformKeyedInformation<Vec<T>>>,
 }
 impl<T> Metric<T>
 where
    T: Default
        + Copy
        + Ord
        + PartialOrd
        + Add<Output = T>
        + Div<Output = T>
        + TryFrom<usize, Error: std::fmt::Debug>,
 {
    pub fn new() -> Self {
        Default::default()
    }
    pub fn platform_identifiers(&self) -> BTreeSet<PlatformIdentifier> {
        self.minimum
            .as_ref()
            .map(|m| m.keys())
            .into_iter()
            .flatten()
            .chain(
                self.maximum
                    .as_ref()
                    .map(|m| m.keys())
                    .into_iter()
                    .flatten(),
            )
            .chain(self.mean.as_ref().map(|m| m.keys()).into_iter().flatten())
            .chain(self.median.as_ref().map(|m| m.keys()).into_iter().flatten())
            .chain(self.raw.as_ref().map(|m| m.keys()).into_iter().flatten())
            .copied()
            .collect()
    }
    pub fn with_list(
        &mut self,
        platform_identifier: PlatformIdentifier,
        mut list: Vec<T>,
    ) -> &mut Self {
        list.sort();
        let Some(min) = list.first().copied() else {
            return self;
        };
        let Some(max) = list.last().copied() else {
            return self;
        };
        let sum = list.iter().fold(T::default(), |acc, num| acc + *num);
        let mean = sum / TryInto::<T>::try_into(list.len()).unwrap();
        let median = match list.len().is_multiple_of(2) {
            true => {
                let idx = list.len() / 2;
                let val1 = *list.get(idx - 1).unwrap();
                let val2 = *list.get(idx).unwrap();
                (val1 + val2) / TryInto::<T>::try_into(2usize).unwrap()
            }
            false => {
                let idx = list.len() / 2;
                *list.get(idx).unwrap()
            }
        };
        self.minimum
            .get_or_insert_default()
            .insert(platform_identifier, min);
        self.maximum
            .get_or_insert_default()
            .insert(platform_identifier, max);
        self.mean
            .get_or_insert_default()
            .insert(platform_identifier, mean);
        self.median
            .get_or_insert_default()
            .insert(platform_identifier, median);
        self.raw
            .get_or_insert_default()
            .insert(platform_identifier, list);
        self
    }
    pub fn combine(&self, other: &Self) -> Self {
        let mut platform_identifiers = self.platform_identifiers();
        platform_identifiers.extend(other.platform_identifiers());
        let mut this = Self::new();
        for platform_identifier in platform_identifiers {
            let mut l1 = self
                .raw
                .as_ref()
                .and_then(|m| m.get(&platform_identifier))
                .cloned()
                .unwrap_or_default();
            let l2 = other
                .raw
                .as_ref()
                .and_then(|m| m.get(&platform_identifier))
                .cloned()
                .unwrap_or_default();
            l1.extend(l2);
            this.with_list(platform_identifier, l1);
        }
        this
    }
 }
 #[derive(Clone, Debug, Serialize, Deserialize, Default)]
 pub struct ContractInformation {
    /// The size of the contract on the various platforms.
    pub contract_size: PlatformKeyedInformation<usize>,
 }
 #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
 pub struct MinedBlockInformation {
    pub ethereum_block_information: EthereumMinedBlockInformation,
    pub substrate_block_information: Option<SubstrateMinedBlockInformation>,
 }
 impl MinedBlockInformation {
    pub fn gas_block_fullness_percentage(&self) -> u8 {
        self.ethereum_block_information
            .gas_block_fullness_percentage()
    }
    pub fn ref_time_block_fullness_percentage(&self) -> Option<u8> {
        self.substrate_block_information
            .as_ref()
            .map(|block| block.ref_time_block_fullness_percentage())
    }
    pub fn proof_size_block_fullness_percentage(&self) -> Option<u8> {
        self.substrate_block_information
            .as_ref()
            .map(|block| block.proof_size_block_fullness_percentage())
    }
 }
 #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
 pub struct EthereumMinedBlockInformation {
    /// The block number.
    pub block_number: BlockNumber,
    /// The block timestamp.
    pub block_timestamp: BlockTimestamp,
    /// The amount of gas mined in the block.
    pub mined_gas: u128,
    /// The gas limit of the block.
    pub block_gas_limit: u128,
    /// The hashes of the transactions that were mined as part of the block.
    pub transaction_hashes: Vec<TxHash>,
 }
 impl EthereumMinedBlockInformation {
    pub fn gas_block_fullness_percentage(&self) -> u8 {
        (self.mined_gas * 100 / self.block_gas_limit) as u8
    }
 }
 #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
 pub struct SubstrateMinedBlockInformation {
    /// The ref time for substrate based chains.
    pub ref_time: u128,
    /// The max ref time for substrate based chains.
    pub max_ref_time: u64,
    /// The proof size for substrate based chains.
    pub proof_size: u128,
    /// The max proof size for substrate based chains.
    pub max_proof_size: u64,
 }
 impl SubstrateMinedBlockInformation {
    pub fn ref_time_block_fullness_percentage(&self) -> u8 {
        (self.ref_time * 100 / self.max_ref_time as u128) as u8
    }
    pub fn proof_size_block_fullness_percentage(&self) -> u8 {
        (self.proof_size * 100 / self.max_proof_size as u128) as u8
    }
 }
 /// Information keyed by the platform identifier.
 pub type PlatformKeyedInformation<T> = BTreeMap<PlatformIdentifier, T>;
@@ -1,94 +0,0 @@
 //! The report analyzer enriches the raw report data.
 use serde::{Deserialize, Serialize};
 use crate::reporter::CompilationTask;
 /// Provides insights into how well the compilers perform.
 #[derive(Clone, Default, Debug, Serialize, Deserialize, PartialEq, PartialOrd)]
 pub struct CompilerStatistics {
    /// The sum of contracts observed.
    pub n_contracts: usize,
    /// The mean size of compiled contracts.
    pub mean_code_size: usize,
    /// The mean size of the optimized YUL IR.
    pub mean_yul_size: usize,
    /// Is a proxy because the YUL also containes a lot of comments.
    pub yul_to_bytecode_size_ratio: f32,
 }
 impl CompilerStatistics {
    /// Cumulatively update the statistics with the next compiler task.
    pub fn sample(&mut self, compilation_task: &CompilationTask) {
        let Some(output) = &compilation_task.json_output else {
            return;
        };
        let Some(contracts) = &output.contracts else {
            return;
        };
        for (_solidity, contracts) in contracts.iter() {
            for (_name, contract) in contracts.iter() {
                let Some(evm) = &contract.evm else {
                    continue;
                };
                let Some(deploy_code) = &evm.deployed_bytecode else {
                    continue;
                };
                // The EVM bytecode can be unlinked and thus is not necessarily a decodable hex
                // string; for our statistics this is a good enough approximation.
                let bytecode_size = deploy_code.object.len() / 2;
                let yul_size = contract
                    .ir_optimized
                    .as_ref()
                    .expect("if the contract has a deploy code it should also have the opimized IR")
                    .len();
                self.update_sizes(bytecode_size, yul_size);
            }
        }
    }
    /// Updates the size statistics cumulatively.
    fn update_sizes(&mut self, bytecode_size: usize, yul_size: usize) {
        let n_previous = self.n_contracts;
        let n_current = self.n_contracts + 1;
        self.n_contracts = n_current;
        self.mean_code_size = (n_previous * self.mean_code_size + bytecode_size) / n_current;
        self.mean_yul_size = (n_previous * self.mean_yul_size + yul_size) / n_current;
        if self.mean_code_size > 0 {
            self.yul_to_bytecode_size_ratio =
                self.mean_yul_size as f32 / self.mean_code_size as f32;
        }
    }
 }
 #[cfg(test)]
 mod tests {
    use super::CompilerStatistics;
    #[test]
    fn compiler_statistics() {
        let mut received = CompilerStatistics::default();
        received.update_sizes(0, 0);
        received.update_sizes(3, 37);
        received.update_sizes(123, 456);
        let mean_code_size = 41; // rounding error from integer truncation
        let mean_yul_size = 164;
        let expected = CompilerStatistics {
            n_contracts: 3,
            mean_code_size,
            mean_yul_size,
            yul_to_bytecode_size_ratio: mean_yul_size as f32 / mean_code_size as f32,
        };
        assert_eq!(received, expected);
    }
 }
@@ -0,0 +1,37 @@
 //! Common types and functions used throughout the crate.
 use std::{path::PathBuf, sync::Arc};
 use revive_dt_common::{define_wrapper_type, types::PlatformIdentifier};
 use revive_dt_compiler::Mode;
 use revive_dt_format::{case::CaseIdx, steps::StepPath};
 use serde::{Deserialize, Serialize};
 define_wrapper_type!(
    #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
    #[serde(transparent)]
    pub struct MetadataFilePath(PathBuf);
 );
 /// An absolute specifier for a test.
 #[derive(Clone, Debug, PartialEq, Eq, Hash)]
 pub struct TestSpecifier {
    pub solc_mode: Mode,
    pub metadata_file_path: PathBuf,
    pub case_idx: CaseIdx,
 }
 /// An absolute path for a test that also includes information about the node that it's assigned to
 /// and what platform it belongs to.
 #[derive(Clone, Debug, PartialEq, Eq, Hash)]
 pub struct ExecutionSpecifier {
    pub test_specifier: Arc<TestSpecifier>,
    pub node_id: usize,
    pub platform_identifier: PlatformIdentifier,
 }
 #[derive(Clone, Debug, PartialEq, Eq, Hash)]
 pub struct StepExecutionSpecifier {
    pub execution_specifier: Arc<ExecutionSpecifier>,
    pub step_idx: StepPath,
 }
@@ -1,4 +1,11 @@
-//! The revive differential tests reporting facility.
+//! This crate implements the reporting infrastructure for the differential testing tool.
-pub mod analyzer;
+mod aggregator;
-pub mod reporter;
+mod common;
 mod reporter_event;
 mod runner_event;
 pub use aggregator::*;
 pub use common::*;
 pub use reporter_event::*;
 pub use runner_event::*;
@@ -1,243 +0,0 @@
 //! The reporter is the central place observing test execution by collecting data.
 //!
 //! The data collected gives useful insights into the outcome of the test run
 //! and helps identifying and reproducing failing cases.
 use std::{
    collections::HashMap,
    fs::{self, File, create_dir_all},
    path::PathBuf,
    sync::{Mutex, OnceLock},
    time::{SystemTime, UNIX_EPOCH},
 };
 use anyhow::Context;
 use serde::{Deserialize, Serialize};
 use revive_dt_config::{Arguments, TestingPlatform};
 use revive_dt_format::{corpus::Corpus, mode::SolcMode};
 use revive_solc_json_interface::{SolcStandardJsonInput, SolcStandardJsonOutput};
 use crate::analyzer::CompilerStatistics;
 pub(crate) static REPORTER: OnceLock<Mutex<Report>> = OnceLock::new();
 /// The `Report` datastructure stores all relevant inforamtion required for generating reports.
 #[derive(Clone, Debug, Default, Serialize, Deserialize)]
 pub struct Report {
    /// The configuration used during the test.
    pub config: Arguments,
    /// The observed test corpora.
    pub corpora: Vec<Corpus>,
    /// The observed test definitions.
    pub metadata_files: Vec<PathBuf>,
    /// The observed compilation results.
    pub compiler_results: HashMap<TestingPlatform, Vec<CompilationResult>>,
    /// The observed compilation statistics.
    pub compiler_statistics: HashMap<TestingPlatform, CompilerStatistics>,
    /// The file name this is serialized to.
    #[serde(skip)]
    directory: PathBuf,
 }
 /// Contains a compiled contract.
 #[derive(Clone, Debug, Serialize, Deserialize)]
 pub struct CompilationTask {
    /// The observed compiler input.
    pub json_input: SolcStandardJsonInput,
    /// The observed compiler output.
    pub json_output: Option<SolcStandardJsonOutput>,
    /// The observed compiler mode.
    pub mode: SolcMode,
    /// The observed compiler version.
    pub compiler_version: String,
    /// The observed error, if any.
    pub error: Option<String>,
 }
 /// Represents a report about a compilation task.
 #[derive(Clone, Debug, Serialize, Deserialize)]
 pub struct CompilationResult {
    /// The observed compilation task.
    pub compilation_task: CompilationTask,
    /// The linked span.
    pub span: Span,
 }
 /// The [Span] struct indicates the context of what is being reported.
 #[derive(Clone, Copy, Debug, Serialize, Deserialize)]
 pub struct Span {
    /// The corpus index this belongs to.
    corpus: usize,
    /// The metadata file this belongs to.
    metadata_file: usize,
    /// The index of the case definition this belongs to.
    case: usize,
    /// The index of the case input this belongs to.
    input: usize,
 }
 impl Report {
    /// The file name where this report will be written to.
    pub const FILE_NAME: &str = "report.json";
    /// The [Span] is expected to initialize the reporter by providing the config.
    const INITIALIZED_VIA_SPAN: &str = "requires a Span which initializes the reporter";
    /// Create a new [Report].
    fn new(config: Arguments) -> anyhow::Result<Self> {
        let now = SystemTime::now()
            .duration_since(UNIX_EPOCH)
            .unwrap()
            .as_millis();
        let directory = config.directory().join("report").join(format!("{now}"));
        if !directory.exists() {
            create_dir_all(&directory)?;
        }
        Ok(Self {
            config,
            directory,
            ..Default::default()
        })
    }
    /// Add a compilation task to the report.
    pub fn compilation(span: Span, platform: TestingPlatform, compilation_task: CompilationTask) {
        let mut report = REPORTER
            .get()
            .expect(Report::INITIALIZED_VIA_SPAN)
            .lock()
            .unwrap();
        report
            .compiler_statistics
            .entry(platform)
            .or_default()
            .sample(&compilation_task);
        report
            .compiler_results
            .entry(platform)
            .or_default()
            .push(CompilationResult {
                compilation_task,
                span,
            });
    }
    /// Write the report to disk.
    pub fn save() -> anyhow::Result<()> {
        let Some(reporter) = REPORTER.get() else {
            return Ok(());
        };
        let report = reporter.lock().unwrap();
        if let Err(error) = report.write_to_file() {
            anyhow::bail!("can not write report: {error}");
        }
        if report.config.extract_problems {
            if let Err(error) = report.save_compiler_problems() {
                anyhow::bail!("can not write compiler problems: {error}");
            }
        }
        Ok(())
    }
    /// Write compiler problems to disk for later debugging.
    pub fn save_compiler_problems(&self) -> anyhow::Result<()> {
        for (platform, results) in self.compiler_results.iter() {
            for result in results {
                // ignore if there were no errors
                if result.compilation_task.error.is_none()
                    && result
                        .compilation_task
                        .json_output
                        .as_ref()
                        .and_then(|output| output.errors.as_ref())
                        .map(|errors| errors.is_empty())
                        .unwrap_or(true)
                {
                    continue;
                }
                let path = &self.metadata_files[result.span.metadata_file]
                    .parent()
                    .unwrap()
                    .join(format!("{platform}_errors"));
                if !path.exists() {
                    create_dir_all(path)?;
                }
                if let Some(error) = result.compilation_task.error.as_ref() {
                    fs::write(path.join("compiler_error.txt"), error)?;
                }
                if let Some(errors) = result.compilation_task.json_output.as_ref() {
                    let file = File::create(path.join("compiler_output.txt"))?;
                    serde_json::to_writer_pretty(file, &errors)?;
                }
            }
        }
        Ok(())
    }
    fn write_to_file(&self) -> anyhow::Result<()> {
        let path = self.directory.join(Self::FILE_NAME);
        let file = File::create(&path).context(path.display().to_string())?;
        serde_json::to_writer_pretty(file, &self)?;
        tracing::info!("report written to: {}", path.display());
        Ok(())
    }
 }
 impl Span {
    /// Create a new [Span] with case and input index at 0.
    ///
    /// Initializes the reporting facility on the first call.
    pub fn new(corpus: Corpus, config: Arguments) -> anyhow::Result<Self> {
        let report = Mutex::new(Report::new(config)?);
        let mut reporter = REPORTER.get_or_init(|| report).lock().unwrap();
        reporter.corpora.push(corpus);
        Ok(Self {
            corpus: reporter.corpora.len() - 1,
            metadata_file: 0,
            case: 0,
            input: 0,
        })
    }
    /// Advance to the next metadata file: Resets the case input index to 0.
    pub fn next_metadata(&mut self, metadata_file: PathBuf) {
        let mut reporter = REPORTER
            .get()
            .expect(Report::INITIALIZED_VIA_SPAN)
            .lock()
            .unwrap();
        reporter.metadata_files.push(metadata_file);
        self.metadata_file = reporter.metadata_files.len() - 1;
        self.case = 0;
        self.input = 0;
    }
    /// Advance to the next case: Increas the case index by one and resets the input index to 0.
    pub fn next_case(&mut self) {
        self.case += 1;
        self.input = 0;
    }
    /// Advance to the next input.
    pub fn next_input(&mut self) {
        self.input += 1;
    }
 }
@@ -0,0 +1,22 @@
 //! A reporter event sent by the report aggregator to the various listeners.
 use std::collections::BTreeMap;
 use revive_dt_compiler::Mode;
 use revive_dt_format::case::CaseIdx;
 use crate::{MetadataFilePath, TestCaseStatus};
 #[derive(Clone, Debug)]
 pub enum ReporterEvent {
    /// An event sent by the reporter once an entire metadata file and solc mode combination has
    /// finished execution.
    MetadataFileSolcModeCombinationExecutionCompleted {
        /// The path of the metadata file.
        metadata_file_path: MetadataFilePath,
        /// The Solc mode that this metadata file was executed in.
        mode: Mode,
        /// The status of each one of the cases.
        case_status: BTreeMap<CaseIdx, TestCaseStatus>,
    },
 }
@@ -0,0 +1,669 @@
 //! The types associated with the events sent by the runner to the reporter.
 #![allow(dead_code)]
 use std::{collections::BTreeMap, path::PathBuf, sync::Arc};
 use alloy::primitives::Address;
 use anyhow::Context as _;
 use indexmap::IndexMap;
 use revive_dt_common::types::PlatformIdentifier;
 use revive_dt_compiler::{CompilerInput, CompilerOutput};
 use revive_dt_format::metadata::ContractInstance;
 use revive_dt_format::metadata::Metadata;
 use revive_dt_format::steps::StepPath;
 use semver::Version;
 use tokio::sync::{broadcast, oneshot};
 use crate::MinedBlockInformation;
 use crate::TransactionInformation;
 use crate::{ExecutionSpecifier, ReporterEvent, TestSpecifier, common::MetadataFilePath};
 macro_rules! __report_gen_emit_test_specific {
    (
        $ident:ident,
        $variant_ident:ident,
        $skip_field:ident;
        $( $bname:ident : $bty:ty, )*
        ;
        $( $aname:ident : $aty:ty, )*
    ) => {
        paste::paste! {
            pub fn [< report_ $variant_ident:snake _event >](
                &self
                $(, $bname: impl Into<$bty> )*
                $(, $aname: impl Into<$aty> )*
            ) -> anyhow::Result<()> {
                self.report([< $variant_ident Event >] {
                    $skip_field: self.test_specifier.clone()
                    $(, $bname: $bname.into() )*
                    $(, $aname: $aname.into() )*
                })
            }
        }
    };
 }
 macro_rules! __report_gen_emit_test_specific_by_parse {
    (
        $ident:ident,
        $variant_ident:ident,
        $skip_field:ident;
        $( $bname:ident : $bty:ty, )* ; $( $aname:ident : $aty:ty, )*
    ) => {
        __report_gen_emit_test_specific!(
            $ident, $variant_ident, $skip_field;
            $( $bname : $bty, )* ; $( $aname : $aty, )*
        );
    };
 }
 macro_rules! __report_gen_scan_before {
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        test_specifier : $skip_ty:ty,
        $( $after:ident : $aty:ty, )*
        ;
    ) => {
        __report_gen_emit_test_specific_by_parse!(
            $ident, $variant_ident, test_specifier;
            $( $before : $bty, )* ; $( $after : $aty, )*
        );
    };
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        $name:ident : $ty:ty, $( $after:ident : $aty:ty, )*
        ;
    ) => {
        __report_gen_scan_before!(
            $ident, $variant_ident;
            $( $before : $bty, )* $name : $ty,
            ;
            $( $after : $aty, )*
            ;
        );
    };
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        ;
    ) => {};
 }
 macro_rules! __report_gen_for_variant {
    (
        $ident:ident,
        $variant_ident:ident;
    ) => {};
    (
        $ident:ident,
        $variant_ident:ident;
        $( $field_ident:ident : $field_ty:ty ),+ $(,)?
    ) => {
        __report_gen_scan_before!(
            $ident, $variant_ident;
            ;
            $( $field_ident : $field_ty, )*
            ;
        );
    };
 }
 macro_rules! __report_gen_emit_execution_specific {
    (
        $ident:ident,
        $variant_ident:ident,
        $skip_field:ident;
        $( $bname:ident : $bty:ty, )*
        ;
        $( $aname:ident : $aty:ty, )*
    ) => {
        paste::paste! {
            pub fn [< report_ $variant_ident:snake _event >](
                &self
                $(, $bname: impl Into<$bty> )*
                $(, $aname: impl Into<$aty> )*
            ) -> anyhow::Result<()> {
                self.report([< $variant_ident Event >] {
                    $skip_field: self.execution_specifier.clone()
                    $(, $bname: $bname.into() )*
                    $(, $aname: $aname.into() )*
                })
            }
        }
    };
 }
 macro_rules! __report_gen_emit_execution_specific_by_parse {
    (
        $ident:ident,
        $variant_ident:ident,
        $skip_field:ident;
        $( $bname:ident : $bty:ty, )* ; $( $aname:ident : $aty:ty, )*
    ) => {
        __report_gen_emit_execution_specific!(
            $ident, $variant_ident, $skip_field;
            $( $bname : $bty, )* ; $( $aname : $aty, )*
        );
    };
 }
 macro_rules! __report_gen_scan_before_exec {
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        execution_specifier : $skip_ty:ty,
        $( $after:ident : $aty:ty, )*
        ;
    ) => {
        __report_gen_emit_execution_specific_by_parse!(
            $ident, $variant_ident, execution_specifier;
            $( $before : $bty, )* ; $( $after : $aty, )*
        );
    };
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        $name:ident : $ty:ty, $( $after:ident : $aty:ty, )*
        ;
    ) => {
        __report_gen_scan_before_exec!(
            $ident, $variant_ident;
            $( $before : $bty, )* $name : $ty,
            ;
            $( $after : $aty, )*
            ;
        );
    };
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        ;
    ) => {};
 }
 macro_rules! __report_gen_for_variant_exec {
    (
        $ident:ident,
        $variant_ident:ident;
    ) => {};
    (
        $ident:ident,
        $variant_ident:ident;
        $( $field_ident:ident : $field_ty:ty ),+ $(,)?
    ) => {
        __report_gen_scan_before_exec!(
            $ident, $variant_ident;
            ;
            $( $field_ident : $field_ty, )*
            ;
        );
    };
 }
 macro_rules! __report_gen_emit_step_execution_specific {
    (
        $ident:ident,
        $variant_ident:ident,
        $skip_field:ident;
        $( $bname:ident : $bty:ty, )*
        ;
        $( $aname:ident : $aty:ty, )*
    ) => {
        paste::paste! {
            pub fn [< report_ $variant_ident:snake _event >](
                &self
                $(, $bname: impl Into<$bty> )*
                $(, $aname: impl Into<$aty> )*
            ) -> anyhow::Result<()> {
                self.report([< $variant_ident Event >] {
                    $skip_field: self.step_specifier.clone()
                    $(, $bname: $bname.into() )*
                    $(, $aname: $aname.into() )*
                })
            }
        }
    };
 }
 macro_rules! __report_gen_emit_step_execution_specific_by_parse {
    (
        $ident:ident,
        $variant_ident:ident,
        $skip_field:ident;
        $( $bname:ident : $bty:ty, )* ; $( $aname:ident : $aty:ty, )*
    ) => {
        __report_gen_emit_step_execution_specific!(
            $ident, $variant_ident, $skip_field;
            $( $bname : $bty, )* ; $( $aname : $aty, )*
        );
    };
 }
 macro_rules! __report_gen_scan_before_step {
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        step_specifier : $skip_ty:ty,
        $( $after:ident : $aty:ty, )*
        ;
    ) => {
        __report_gen_emit_step_execution_specific_by_parse!(
            $ident, $variant_ident, step_specifier;
            $( $before : $bty, )* ; $( $after : $aty, )*
        );
    };
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        $name:ident : $ty:ty, $( $after:ident : $aty:ty, )*
        ;
    ) => {
        __report_gen_scan_before_step!(
            $ident, $variant_ident;
            $( $before : $bty, )* $name : $ty,
            ;
            $( $after : $aty, )*
            ;
        );
    };
    (
        $ident:ident, $variant_ident:ident;
        $( $before:ident : $bty:ty, )*
        ;
        ;
    ) => {};
 }
 macro_rules! __report_gen_for_variant_step {
    (
        $ident:ident,
        $variant_ident:ident;
    ) => {};
    (
        $ident:ident,
        $variant_ident:ident;
        $( $field_ident:ident : $field_ty:ty ),+ $(,)?
    ) => {
        __report_gen_scan_before_step!(
            $ident, $variant_ident;
            ;
            $( $field_ident : $field_ty, )*
            ;
        );
    };
 }
 /// Defines the runner-event which is sent from the test runners to the report aggregator.
 ///
 /// This macro defines a number of things related to the reporting infrastructure and the interface
 /// used. First of all, it defines the enum of all of the possible events that the runners can send
 /// to the aggregator. For each one of the variants it defines a separate struct for it to allow the
 /// variant field in the enum to be put in a [`Box`].
 ///
 /// In addition to the above, it defines [`From`] implementations for the various event types for
 /// the [`RunnerEvent`] enum essentially allowing for events such as [`CorpusFileDiscoveryEvent`] to
 /// be converted into a [`RunnerEvent`].
 ///
 /// In addition to the above, it also defines the [`RunnerEventReporter`] which is a wrapper around
 /// an [`UnboundedSender`] allowing for events to be sent to the report aggregator.
 ///
 /// With the above description, we can see that this macro defines almost all of the interface of
 /// the reporting infrastructure, from the enum itself, to its associated types, and also to the
 /// reporter that's used to report events to the aggregator.
 ///
 /// [`UnboundedSender`]: tokio::sync::mpsc::UnboundedSender
 macro_rules! define_event {
    (
        $(#[$enum_meta: meta])*
        $vis: vis enum $ident: ident {
            $(
                $(#[$variant_meta: meta])*
                $variant_ident: ident {
                    $(
                        $(#[$field_meta: meta])*
                        $field_ident: ident: $field_ty: ty
                    ),* $(,)?
                }
            ),* $(,)?
        }
    ) => {
        paste::paste! {
            $(#[$enum_meta])*
            #[derive(Debug)]
            $vis enum $ident {
                $(
                    $(#[$variant_meta])*
                    $variant_ident(Box<[<$variant_ident Event>]>)
                ),*
            }
            impl $ident {
                pub fn variant_name(&self) -> &'static str {
                    match self {
                        $(
                            Self::$variant_ident { .. } => stringify!($variant_ident)
                        ),*
                    }
                }
            }
            $(
                #[derive(Debug)]
                $(#[$variant_meta])*
                $vis struct [<$variant_ident Event>] {
                    $(
                        $(#[$field_meta])*
                        $vis $field_ident: $field_ty
                    ),*
                }
            )*
            $(
                impl From<[<$variant_ident Event>]> for $ident {
                    fn from(value: [<$variant_ident Event>]) -> Self {
                        Self::$variant_ident(Box::new(value))
                    }
                }
            )*
            /// Provides a way to report events to the aggregator.
            ///
            /// Under the hood, this is a wrapper around an [`UnboundedSender`] which abstracts away
            /// the fact that channels are used and that implements high-level methods for reporting
            /// various events to the aggregator.
            #[derive(Clone, Debug)]
            pub struct [< $ident Reporter >]($vis tokio::sync::mpsc::UnboundedSender<$ident>);
            impl From<tokio::sync::mpsc::UnboundedSender<$ident>> for [< $ident Reporter >] {
                fn from(value: tokio::sync::mpsc::UnboundedSender<$ident>) -> Self {
                    Self(value)
                }
            }
            impl [< $ident Reporter >] {
                pub fn test_specific_reporter(
                    &self,
                    test_specifier: impl Into<std::sync::Arc<crate::common::TestSpecifier>>
                ) -> [< $ident TestSpecificReporter >] {
                    [< $ident TestSpecificReporter >] {
                        reporter: self.clone(),
                        test_specifier: test_specifier.into(),
                    }
                }
                fn report(&self, event: impl Into<$ident>) -> anyhow::Result<()> {
                    self.0.send(event.into()).map_err(Into::into)
                }
                $(
                    pub fn [< report_ $variant_ident:snake _event >](&self, $($field_ident: impl Into<$field_ty>),*) -> anyhow::Result<()> {
                        self.report([< $variant_ident Event >] {
                            $($field_ident: $field_ident.into()),*
                        })
                    }
                )*
            }
            /// A reporter that's tied to a specific test case.
            #[derive(Clone, Debug)]
            pub struct [< $ident TestSpecificReporter >] {
                $vis reporter: [< $ident Reporter >],
                $vis test_specifier: std::sync::Arc<crate::common::TestSpecifier>,
            }
            impl [< $ident TestSpecificReporter >] {
                pub fn execution_specific_reporter(
                    &self,
                    node_id: impl Into<usize>,
                    platform_identifier: impl Into<PlatformIdentifier>
                ) -> [< $ident ExecutionSpecificReporter >] {
                    [< $ident ExecutionSpecificReporter >] {
                        reporter: self.reporter.clone(),
                        execution_specifier: Arc::new($crate::common::ExecutionSpecifier {
                            test_specifier: self.test_specifier.clone(),
                            node_id: node_id.into(),
                            platform_identifier: platform_identifier.into(),
                        })
                    }
                }
                fn report(&self, event: impl Into<$ident>) -> anyhow::Result<()> {
                    self.reporter.report(event)
                }
                $(
                    __report_gen_for_variant! { $ident, $variant_ident; $( $field_ident : $field_ty ),* }
                )*
            }
            /// A reporter that's tied to a specific execution of the test case such as execution on
            /// a specific node from a specific platform.
            #[derive(Clone, Debug)]
            pub struct [< $ident ExecutionSpecificReporter >] {
                $vis reporter: [< $ident Reporter >],
                $vis execution_specifier: std::sync::Arc<$crate::common::ExecutionSpecifier>,
            }
            impl [< $ident ExecutionSpecificReporter >] {
                fn report(&self, event: impl Into<$ident>) -> anyhow::Result<()> {
                    self.reporter.report(event)
                }
                $(
                    __report_gen_for_variant_exec! { $ident, $variant_ident; $( $field_ident : $field_ty ),* }
                )*
            }
            /// A reporter that's tied to a specific step execution
            #[derive(Clone, Debug)]
            pub struct [< $ident StepExecutionSpecificReporter >] {
                $vis reporter: [< $ident Reporter >],
                $vis step_specifier: std::sync::Arc<$crate::common::StepExecutionSpecifier>,
            }
            impl [< $ident StepExecutionSpecificReporter >] {
                fn report(&self, event: impl Into<$ident>) -> anyhow::Result<()> {
                    self.reporter.report(event)
                }
                $(
                    __report_gen_for_variant_step! { $ident, $variant_ident; $( $field_ident : $field_ty ),* }
                )*
            }
        }
    };
 }
 define_event! {
    /// An event type that's sent by the test runners/drivers to the report aggregator.
    pub(crate) enum RunnerEvent {
        /// An event emitted by the reporter when it wishes to listen to events emitted by the
        /// aggregator.
        SubscribeToEvents {
            /// The channel that the aggregator is to send the receive side of the channel on.
            tx: oneshot::Sender<broadcast::Receiver<ReporterEvent>>
        },
        /// An event emitted by runners when they've discovered a metadata file.
        MetadataFileDiscovery {
            /// The path of the metadata file discovered.
            path: MetadataFilePath,
            /// The content of the metadata file.
            metadata: Metadata
        },
        /// An event emitted by the runners when they discover a test case.
        TestCaseDiscovery {
            /// A specifier for the test that was discovered.
            test_specifier: Arc<TestSpecifier>,
        },
        /// An event emitted by the runners when a test case is ignored.
        TestIgnored {
            /// A specifier for the test that's been ignored.
            test_specifier: Arc<TestSpecifier>,
            /// A reason for the test to be ignored.
            reason: String,
            /// Additional fields that describe more information on why the test was ignored.
            additional_fields: IndexMap<String, serde_json::Value>
        },
        /// An event emitted by the runners when a test case has succeeded.
        TestSucceeded {
            /// A specifier for the test that succeeded.
            test_specifier: Arc<TestSpecifier>,
            /// The number of steps of the case that were executed by the driver.
            steps_executed: usize,
        },
        /// An event emitted by the runners when a test case has failed.
        TestFailed {
            /// A specifier for the test that succeeded.
            test_specifier: Arc<TestSpecifier>,
            /// A reason for the failure of the test.
            reason: String,
        },
        /// An event emitted when the test case is assigned a platform node.
        NodeAssigned {
            /// A specifier for the test that the assignment is for.
            test_specifier: Arc<TestSpecifier>,
            /// The ID of the node that this case is being executed on.
            id: usize,
            /// The identifier of the platform used.
            platform_identifier: PlatformIdentifier,
            /// The connection string of the node.
            connection_string: String,
        },
        /// An event emitted by the runners when the compilation of the contracts has succeeded
        /// on the pre-link contracts.
        PreLinkContractsCompilationSucceeded {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The version of the compiler used to compile the contracts.
            compiler_version: Version,
            /// The path of the compiler used to compile the contracts.
            compiler_path: PathBuf,
            /// A flag of whether the contract bytecode and ABI were cached or if they were compiled
            /// anew.
            is_cached: bool,
            /// The input provided to the compiler - this is optional and not provided if the
            /// contracts were obtained from the cache.
            compiler_input: Option<CompilerInput>,
            /// The output of the compiler.
            compiler_output: CompilerOutput
        },
        /// An event emitted by the runners when the compilation of the contracts has succeeded
        /// on the post-link contracts.
        PostLinkContractsCompilationSucceeded {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The version of the compiler used to compile the contracts.
            compiler_version: Version,
            /// The path of the compiler used to compile the contracts.
            compiler_path: PathBuf,
            /// A flag of whether the contract bytecode and ABI were cached or if they were compiled
            /// anew.
            is_cached: bool,
            /// The input provided to the compiler - this is optional and not provided if the
            /// contracts were obtained from the cache.
            compiler_input: Option<CompilerInput>,
            /// The output of the compiler.
            compiler_output: CompilerOutput
        },
        /// An event emitted by the runners when the compilation of the pre-link contract has
        /// failed.
        PreLinkContractsCompilationFailed {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The version of the compiler used to compile the contracts.
            compiler_version: Option<Version>,
            /// The path of the compiler used to compile the contracts.
            compiler_path: Option<PathBuf>,
            /// The input provided to the compiler - this is optional and not provided if the
            /// contracts were obtained from the cache.
            compiler_input: Option<CompilerInput>,
            /// The failure reason.
            reason: String,
        },
        /// An event emitted by the runners when the compilation of the post-link contract has
        /// failed.
        PostLinkContractsCompilationFailed {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The version of the compiler used to compile the contracts.
            compiler_version: Option<Version>,
            /// The path of the compiler used to compile the contracts.
            compiler_path: Option<PathBuf>,
            /// The input provided to the compiler - this is optional and not provided if the
            /// contracts were obtained from the cache.
            compiler_input: Option<CompilerInput>,
            /// The failure reason.
            reason: String,
        },
        /// An event emitted by the runners when a library has been deployed.
        LibrariesDeployed {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The addresses of the libraries that were deployed.
            libraries: BTreeMap<ContractInstance, Address>
        },
        /// An event emitted by the runners when they've deployed a new contract.
        ContractDeployed {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The instance name of the contract.
            contract_instance: ContractInstance,
            /// The address of the contract.
            address: Address
        },
        /// Reports the completion of the run.
        Completion {},
        /* Benchmarks Events */
        /// An event emitted with information on a transaction that was submitted for a certain step
        /// of the execution.
        StepTransactionInformation {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The path of the step that this transaction belongs to.
            step_path: StepPath,
            /// Information about the transaction
            transaction_information: TransactionInformation
        },
        ContractInformation {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// The path of the solidity source code that contains the contract.
            source_code_path: PathBuf,
            /// The name of the contract
            contract_name: String,
            /// The size of the contract
            contract_size: usize
        },
        BlockMined {
            /// A specifier for the execution that's taking place.
            execution_specifier: Arc<ExecutionSpecifier>,
            /// Information on the mined block,
            mined_block_information: MinedBlockInformation
        }
    }
 }
 /// An extension to the [`Reporter`] implemented by the macro.
 impl RunnerEventReporter {
    pub async fn subscribe(&self) -> anyhow::Result<broadcast::Receiver<ReporterEvent>> {
        let (tx, rx) = oneshot::channel::<broadcast::Receiver<ReporterEvent>>();
        self.report_subscribe_to_events_event(tx)
            .context("Failed to send subscribe request to reporter task")?;
        rx.await.map_err(Into::into)
    }
 }
 pub type Reporter = RunnerEventReporter;
 pub type TestSpecificReporter = RunnerEventTestSpecificReporter;
 pub type ExecutionSpecificReporter = RunnerEventExecutionSpecificReporter;
@@ -9,10 +9,16 @@ repository.workspace = true
 rust-version.workspace = true
 [dependencies]
 revive-dt-common = { workspace = true }
 anyhow = { workspace = true }
 hex = { workspace = true }
 tracing = { workspace = true }
 tokio = { workspace = true }
 reqwest = { workspace = true }
 semver = { workspace = true }
 serde = { workspace = true }
 sha2 = { workspace = true }
 [lints]
 workspace = true
@@ -6,54 +6,79 @@ use std::{
    io::{BufWriter, Write},
    os::unix::fs::PermissionsExt,
    path::{Path, PathBuf},
-    sync::{LazyLock, Mutex},
+    sync::LazyLock,
 };
-use crate::download::GHDownloader;
+use semver::Version;
 use tokio::sync::Mutex;
 use crate::download::SolcDownloader;
 use anyhow::Context as _;
 pub const SOLC_CACHE_DIRECTORY: &str = "solc";
 pub(crate) static SOLC_CACHER: LazyLock<Mutex<HashSet<PathBuf>>> = LazyLock::new(Default::default);
-pub(crate) fn get_or_download(
+pub(crate) async fn get_or_download(
    working_directory: &Path,
-    downloader: &GHDownloader,
+    downloader: &SolcDownloader,
-) -> anyhow::Result<PathBuf> {
+) -> anyhow::Result<(Version, PathBuf)> {
    let target_directory = working_directory
        .join(SOLC_CACHE_DIRECTORY)
        .join(downloader.version.to_string());
    let target_file = target_directory.join(downloader.target);
-    let mut cache = SOLC_CACHER.lock().unwrap();
+    let mut cache = SOLC_CACHER.lock().await;
    if cache.contains(&target_file) {
        tracing::debug!("using cached solc: {}", target_file.display());
-        return Ok(target_file);
+        return Ok((downloader.version.clone(), target_file));
    }
-    create_dir_all(target_directory)?;
+    create_dir_all(&target_directory).with_context(|| {
-    download_to_file(&target_file, downloader)?;
+        format!(
            "Failed to create solc cache directory: {}",
            target_directory.display()
        )
    })?;
    download_to_file(&target_file, downloader)
        .await
        .with_context(|| {
            format!(
                "Failed to write downloaded solc to {}",
                target_file.display()
            )
        })?;
    cache.insert(target_file.clone());
-    Ok(target_file)
+    Ok((downloader.version.clone(), target_file))
 }
-fn download_to_file(path: &Path, downloader: &GHDownloader) -> anyhow::Result<()> {
+async fn download_to_file(path: &Path, downloader: &SolcDownloader) -> anyhow::Result<()> {
    tracing::info!("caching file: {}", path.display());
    let Ok(file) = File::create_new(path) else {
        tracing::debug!("cache file already exists: {}", path.display());
        return Ok(());
    };
    #[cfg(unix)]
    {
-        let mut permissions = file.metadata()?.permissions();
+        let mut permissions = file
            .metadata()
            .with_context(|| format!("Failed to read metadata for {}", path.display()))?
            .permissions();
        permissions.set_mode(permissions.mode() | 0o111);
-        file.set_permissions(permissions)?;
+        file.set_permissions(permissions).with_context(|| {
            format!("Failed to set executable permissions on {}", path.display())
        })?;
    }
    let mut file = BufWriter::new(file);
-    file.write_all(&downloader.download()?)?;
+    file.write_all(
-    file.flush()?;
+        &downloader
            .download()
            .await
            .context("Failed to download solc binary bytes")?,
    )
    .with_context(|| format!("Failed to write solc binary to {}", path.display()))?;
    file.flush()
        .with_context(|| format!("Failed to flush file {}", path.display()))?;
    drop(file);
    #[cfg(target_os = "macos")]
@@ -64,8 +89,20 @@ fn download_to_file(path: &Path, downloader: &GHDownloader) -> anyhow::Result<()
        .stderr(std::process::Stdio::null())
        .stdout(std::process::Stdio::null())
        .stdout(std::process::Stdio::null())
-        .spawn()?
+        .spawn()
-        .wait()?;
+        .with_context(|| {
            format!(
                "Failed to spawn xattr to remove quarantine attribute on {}",
                path.display()
            )
        })?
        .wait()
        .with_context(|| {
            format!(
                "Failed waiting for xattr operation to complete on {}",
                path.display()
            )
        })?;
    Ok(())
 }
@@ -5,10 +5,13 @@ use std::{
    sync::{LazyLock, Mutex},
 };
 use revive_dt_common::types::VersionOrRequirement;
 use semver::Version;
 use sha2::{Digest, Sha256};
 use crate::list::List;
 use anyhow::Context as _;
 pub static LIST_CACHE: LazyLock<Mutex<HashMap<&'static str, List>>> =
    LazyLock::new(Default::default);
@@ -23,12 +26,17 @@ impl List {
    ///
    /// Caches the list retrieved from the `url` into [LIST_CACHE],
    /// subsequent calls with the same `url` will return the cached list.
-    pub fn download(url: &'static str) -> anyhow::Result<Self> {
+    pub async fn download(url: &'static str) -> anyhow::Result<Self> {
        if let Some(list) = LIST_CACHE.lock().unwrap().get(url) {
            return Ok(list.clone());
        }
-        let body: List = reqwest::blocking::get(url)?.json()?;
+        let body: List = reqwest::get(url)
            .await
            .with_context(|| format!("Failed to GET solc list from {url}"))?
            .json()
            .await
            .with_context(|| format!("Failed to deserialize solc list JSON from {url}"))?;
        LIST_CACHE.lock().unwrap().insert(url, body.clone());
@@ -36,65 +44,106 @@ impl List {
    }
 }
-/// Download solc binaries from GitHub releases (IPFS links aren't reliable).
+/// Download solc binaries from the official SolidityLang site
 #[derive(Clone, Debug)]
-pub struct GHDownloader {
+pub struct SolcDownloader {
    pub version: Version,
    pub target: &'static str,
    pub list: &'static str,
 }
-impl GHDownloader {
+impl SolcDownloader {
-    pub const BASE_URL: &str = "https://github.com/ethereum/solidity/releases/download";
+    pub const BASE_URL: &str = "https://binaries.soliditylang.org";
-    pub const LINUX_NAME: &str = "solc-static-linux";
+    pub const LINUX_NAME: &str = "linux-amd64";
-    pub const MACOSX_NAME: &str = "solc-macos";
+    pub const MACOSX_NAME: &str = "macosx-amd64";
-    pub const WINDOWS_NAME: &str = "solc-windows.exe";
+    pub const WINDOWS_NAME: &str = "windows-amd64";
-    pub const WASM_NAME: &str = "soljson.js";
+    pub const WASM_NAME: &str = "wasm";
-    fn new(version: Version, target: &'static str, list: &'static str) -> Self {
+    async fn new(
-        Self {
+        version: impl Into<VersionOrRequirement>,
-            version,
+        target: &'static str,
-            target,
+        list: &'static str,
-            list,
+    ) -> anyhow::Result<Self> {
        let version_or_requirement = version.into();
        match version_or_requirement {
            VersionOrRequirement::Version(version) => Ok(Self {
                version,
                target,
                list,
            }),
            VersionOrRequirement::Requirement(requirement) => {
                let Some(version) = List::download(list)
                    .await
                    .with_context(|| format!("Failed to download solc builds list from {list}"))?
                    .builds
                    .into_iter()
                    .map(|build| build.version)
                    .filter(|version| requirement.matches(version))
                    .max()
                else {
                    anyhow::bail!("Failed to find a version that satisfies {requirement:?}");
                };
                Ok(Self {
                    version,
                    target,
                    list,
                })
            }
        }
    }
-    pub fn linux(version: Version) -> Self {
+    pub async fn linux(version: impl Into<VersionOrRequirement>) -> anyhow::Result<Self> {
-        Self::new(version, Self::LINUX_NAME, List::LINUX_URL)
+        Self::new(version, Self::LINUX_NAME, List::LINUX_URL).await
    }
-    pub fn macosx(version: Version) -> Self {
+    pub async fn macosx(version: impl Into<VersionOrRequirement>) -> anyhow::Result<Self> {
-        Self::new(version, Self::MACOSX_NAME, List::MACOSX_URL)
+        Self::new(version, Self::MACOSX_NAME, List::MACOSX_URL).await
    }
-    pub fn windows(version: Version) -> Self {
+    pub async fn windows(version: impl Into<VersionOrRequirement>) -> anyhow::Result<Self> {
-        Self::new(version, Self::WINDOWS_NAME, List::WINDOWS_URL)
+        Self::new(version, Self::WINDOWS_NAME, List::WINDOWS_URL).await
    }
-    pub fn wasm(version: Version) -> Self {
+    pub async fn wasm(version: impl Into<VersionOrRequirement>) -> anyhow::Result<Self> {
-        Self::new(version, Self::WASM_NAME, List::WASM_URL)
+        Self::new(version, Self::WASM_NAME, List::WASM_URL).await
    }
    /// Returns the download link.
    pub fn url(&self) -> String {
        format!("{}/v{}/{}", Self::BASE_URL, &self.version, &self.target)
    }
    /// Download the solc binary.
    ///
    /// Errors out if the download fails or the digest of the downloaded file
    /// mismatches the expected digest from the release [List].
-    pub fn download(&self) -> anyhow::Result<Vec<u8>> {
+    pub async fn download(&self) -> anyhow::Result<Vec<u8>> {
-        tracing::info!("downloading solc: {self:?}");
+        let builds = List::download(self.list)
-        let expected_digest = List::download(self.list)?
+            .await
-            .builds
+            .with_context(|| format!("Failed to download solc builds list from {}", self.list))?
            .builds;
        let build = builds
            .iter()
            .find(|build| build.version == self.version)
            .ok_or_else(|| anyhow::anyhow!("solc v{} not found builds", self.version))
-            .map(|b| b.sha256.strip_prefix("0x").unwrap_or(&b.sha256).to_string())?;
+            .with_context(|| {
                format!(
                    "Requested solc version {} was not found in builds list fetched from {}",
                    self.version, self.list
                )
            })?;
-        let file = reqwest::blocking::get(self.url())?.bytes()?.to_vec();
+        let path = build.path.clone();
        let expected_digest = build
            .sha256
            .strip_prefix("0x")
            .unwrap_or(&build.sha256)
            .to_string();
        let url = format!("{}/{}/{}", Self::BASE_URL, self.target, path.display());
        let file = reqwest::get(&url)
            .await
            .with_context(|| format!("Failed to GET solc binary from {url}"))?
            .bytes()
            .await
            .with_context(|| format!("Failed to read solc binary bytes from {url}"))?
            .to_vec();
        if hex::encode(Sha256::digest(&file)) != expected_digest {
            anyhow::bail!("sha256 mismatch for solc version {}", self.version);
@@ -106,29 +155,58 @@ impl GHDownloader {
 #[cfg(test)]
 mod tests {
-    use crate::{download::GHDownloader, list::List};
+    use crate::{download::SolcDownloader, list::List};
-    #[test]
+    #[tokio::test]
-    fn try_get_windows() {
+    async fn try_get_windows() {
-        let version = List::download(List::WINDOWS_URL).unwrap().latest_release;
+        let version = List::download(List::WINDOWS_URL)
-        GHDownloader::windows(version).download().unwrap();
+            .await
            .unwrap()
            .latest_release;
        SolcDownloader::windows(version)
            .await
            .unwrap()
            .download()
            .await
            .unwrap();
    }
-    #[test]
+    #[tokio::test]
-    fn try_get_macosx() {
+    async fn try_get_macosx() {
-        let version = List::download(List::MACOSX_URL).unwrap().latest_release;
+        let version = List::download(List::MACOSX_URL)
-        GHDownloader::macosx(version).download().unwrap();
+            .await
            .unwrap()
            .latest_release;
        SolcDownloader::macosx(version)
            .await
            .unwrap()
            .download()
            .await
            .unwrap();
    }
-    #[test]
+    #[tokio::test]
-    fn try_get_linux() {
+    async fn try_get_linux() {
-        let version = List::download(List::LINUX_URL).unwrap().latest_release;
+        let version = List::download(List::LINUX_URL)
-        GHDownloader::linux(version).download().unwrap();
+            .await
            .unwrap()
            .latest_release;
        SolcDownloader::linux(version)
            .await
            .unwrap()
            .download()
            .await
            .unwrap();
    }
-    #[test]
+    #[tokio::test]
-    fn try_get_wasm() {
+    async fn try_get_wasm() {
-        let version = List::download(List::WASM_URL).unwrap().latest_release;
+        let version = List::download(List::WASM_URL).await.unwrap().latest_release;
-        GHDownloader::wasm(version).download().unwrap();
+        SolcDownloader::wasm(version)
            .await
            .unwrap()
            .download()
            .await
            .unwrap();
    }
 }
@@ -5,8 +5,11 @@
 use std::path::{Path, PathBuf};
 use anyhow::Context as _;
 use cache::get_or_download;
-use download::GHDownloader;
+use download::SolcDownloader;
 use revive_dt_common::types::VersionOrRequirement;
 use semver::Version;
 pub mod cache;
@@ -18,22 +21,23 @@ pub mod list;
 ///
 /// Subsequent calls for the same version will use a cached artifact
 /// and not download it again.
-pub fn download_solc(
+pub async fn download_solc(
    cache_directory: &Path,
-    version: Version,
+    version: impl Into<VersionOrRequirement>,
    wasm: bool,
-) -> anyhow::Result<PathBuf> {
+) -> anyhow::Result<(Version, PathBuf)> {
    let downloader = if wasm {
-        GHDownloader::wasm(version)
+        SolcDownloader::wasm(version).await
    } else if cfg!(target_os = "linux") {
-        GHDownloader::linux(version)
+        SolcDownloader::linux(version).await
    } else if cfg!(target_os = "macos") {
-        GHDownloader::macosx(version)
+        SolcDownloader::macosx(version).await
    } else if cfg!(target_os = "windows") {
-        GHDownloader::windows(version)
+        SolcDownloader::windows(version).await
    } else {
        unimplemented!()
-    };
+    }
    .context("Failed to initialize the Solc Downloader")?;
-    get_or_download(cache_directory, &downloader)
+    get_or_download(cache_directory, &downloader).await
 }
@@ -0,0 +1,93 @@
 #!/bin/bash
 # Revive Differential Tests - Quick Start Script
 # This script clones the test repository, and runs the tool
 set -e  # Exit on any error
 # Colors for output
 RED='\033[0;31m'
 GREEN='\033[0;32m'
 YELLOW='\033[1;33m'
 NC='\033[0m' # No Color
 # Configuration
 TEST_REPO_URL="https://github.com/paritytech/resolc-compiler-tests"
 TEST_REPO_DIR="resolc-compiler-tests"
 WORKDIR="workdir"
 # Optional positional argument: path to polkadot-sdk directory
 POLKADOT_SDK_DIR="${1:-}"
 # Binary paths (default to names in $PATH)
 REVIVE_DEV_NODE_BIN="revive-dev-node"
 ETH_RPC_BIN="eth-rpc"
 SUBSTRATE_NODE_BIN="substrate-node"
 echo -e "${GREEN}=== Revive Differential Tests Quick Start ===${NC}"
 echo ""
 # Check if test repo already exists
 if [ -d "$TEST_REPO_DIR" ]; then
    echo -e "${YELLOW}Test repository already exists. Pulling latest changes...${NC}"
    cd "$TEST_REPO_DIR"
    git pull
    cd ..
 else
    echo -e "${GREEN}Cloning test repository...${NC}"
    git clone "$TEST_REPO_URL"
 fi
 # If polkadot-sdk path is provided, verify and use binaries from there; build if needed
 if [ -n "$POLKADOT_SDK_DIR" ]; then
    if [ ! -d "$POLKADOT_SDK_DIR" ]; then
        echo -e "${RED}Provided polkadot-sdk directory does not exist: $POLKADOT_SDK_DIR${NC}"
        exit 1
    fi
    POLKADOT_SDK_DIR=$(realpath "$POLKADOT_SDK_DIR")
    echo -e "${GREEN}Using polkadot-sdk at: $POLKADOT_SDK_DIR${NC}"
    REVIVE_DEV_NODE_BIN="$POLKADOT_SDK_DIR/target/release/revive-dev-node"
    ETH_RPC_BIN="$POLKADOT_SDK_DIR/target/release/eth-rpc"
    SUBSTRATE_NODE_BIN="$POLKADOT_SDK_DIR/target/release/substrate-node"
    if [ ! -x "$REVIVE_DEV_NODE_BIN" ] || [ ! -x "$ETH_RPC_BIN" ] || [ ! -x "$SUBSTRATE_NODE_BIN" ]; then
        echo -e "${YELLOW}Required binaries not found in release target. Building...${NC}"
        (cd "$POLKADOT_SDK_DIR" && cargo build --release --package staging-node-cli --package pallet-revive-eth-rpc --package revive-dev-node)
    fi
    for bin in "$REVIVE_DEV_NODE_BIN" "$ETH_RPC_BIN" "$SUBSTRATE_NODE_BIN"; do
        if [ ! -x "$bin" ]; then
            echo -e "${RED}Expected binary not found after build: $bin${NC}"
            exit 1
        fi
    done
 else
    echo -e "${YELLOW}No polkadot-sdk path provided. Using binaries from $PATH.${NC}"
 fi
 # Create workdir if it doesn't exist
 mkdir -p "$WORKDIR"
 echo -e "${GREEN}Starting differential tests...${NC}"
 echo "This may take a while..."
 echo ""
 # Run the tool
 cargo build --release;
 RUST_LOG="info,alloy_pubsub::service=error" ./target/release/retester test \
    --platform revive-dev-node-polkavm-resolc \
    --test $(realpath "$TEST_REPO_DIR/fixtures/solidity") \
    --working-directory "$WORKDIR" \
    --concurrency.number-of-nodes 10 \
    --concurrency.number-of-threads 5 \
    --concurrency.number-of-concurrent-tasks 500 \
    --wallet.additional-keys 100000 \
    --kitchensink.path "$SUBSTRATE_NODE_BIN" \
    --revive-dev-node.path "$REVIVE_DEV_NODE_BIN" \
    --eth-rpc.path "$ETH_RPC_BIN" \
    > logs.log \
    2> output.log 
 echo -e "${GREEN}=== Test run completed! ===${NC}"
@@ -0,0 +1,583 @@
 {
  "$schema": "https://json-schema.org/draft/2020-12/schema",
  "title": "Metadata",
  "description": "A MatterLabs metadata file.\n\nThis defines the structure that the MatterLabs metadata files follow for defining the tests or\nthe workloads.\n\nEach metadata file is composed of multiple test cases where each test case is isolated from the\nothers and runs in a completely different address space. Each test case is composed of a number\nof steps and assertions that should be performed as part of the test case.",
  "type": "object",
  "properties": {
    "comment": {
      "description": "This is an optional comment on the metadata file which has no impact on the execution in any\nway.",
      "type": [
        "string",
        "null"
      ]
    },
    "ignore": {
      "description": "An optional boolean which defines if the metadata file as a whole should be ignored. If null\nthen the metadata file will not be ignored.",
      "type": [
        "boolean",
        "null"
      ]
    },
    "targets": {
      "description": "An optional vector of targets that this Metadata file's cases can be executed on. As an\nexample, if we wish for the metadata file's cases to only be run on PolkaVM then we'd\nspecify a target of \"PolkaVM\" in here.",
      "type": [
        "array",
        "null"
      ],
      "items": {
        "$ref": "#/$defs/VmIdentifier"
      }
    },
    "cases": {
      "description": "A vector of the test cases and workloads contained within the metadata file. This is their\nprimary description.",
      "type": "array",
      "items": {
        "$ref": "#/$defs/Case"
      }
    },
    "contracts": {
      "description": "A map of all of the contracts that the test requires to run.\n\nThis is a map where the key is the name of the contract instance and the value is the\ncontract's path and ident in the file.\n\nIf any contract is to be used by the test then it must be included in here first so that the\nframework is aware of its path, compiles it, and prepares it.",
      "type": [
        "object",
        "null"
      ],
      "additionalProperties": {
        "$ref": "#/$defs/ContractPathAndIdent"
      }
    },
    "libraries": {
      "description": "The set of libraries that this metadata file requires.",
      "type": [
        "object",
        "null"
      ],
      "additionalProperties": {
        "type": "object",
        "additionalProperties": {
          "$ref": "#/$defs/ContractInstance"
        }
      }
    },
    "modes": {
      "description": "This represents a mode that has been parsed from test metadata.\n\nMode strings can take the following form (in pseudo-regex):\n\n```text\n[YEILV][+-]? (M[0123sz])? <semver>?\n```",
      "type": [
        "array",
        "null"
      ],
      "items": {
        "$ref": "#/$defs/ParsedMode"
      }
    },
    "required_evm_version": {
      "description": "This field specifies an EVM version requirement that the test case has where the test might\nbe run of the evm version of the nodes match the evm version specified here.",
      "anyOf": [
        {
          "$ref": "#/$defs/EvmVersionRequirement"
        },
        {
          "type": "null"
        }
      ]
    },
    "compiler_directives": {
      "description": "A set of compilation directives that will be passed to the compiler whenever the contracts\nfor the test are being compiled. Note that this differs from the [`Mode`]s in that a [`Mode`]\nis just a filter for when a test can run whereas this is an instruction to the compiler.",
      "anyOf": [
        {
          "$ref": "#/$defs/CompilationDirectives"
        },
        {
          "type": "null"
        }
      ]
    }
  },
  "required": [
    "cases"
  ],
  "$defs": {
    "VmIdentifier": {
      "description": "An enum representing the identifiers of the supported VMs.",
      "oneOf": [
        {
          "description": "The ethereum virtual machine.",
          "type": "string",
          "const": "evm"
        },
        {
          "description": "The EraVM virtual machine.",
          "type": "string",
          "const": "eravm"
        },
        {
          "description": "Polkadot's PolaVM Risc-v based virtual machine.",
          "type": "string",
          "const": "polkavm"
        }
      ]
    },
    "Case": {
      "type": "object",
      "properties": {
        "name": {
          "description": "An optional name of the test case.",
          "type": [
            "string",
            "null"
          ]
        },
        "comment": {
          "description": "An optional comment on the case which has no impact on the execution in any way.",
          "type": [
            "string",
            "null"
          ]
        },
        "modes": {
          "description": "This represents a mode that has been parsed from test metadata.\n\nMode strings can take the following form (in pseudo-regex):\n\n```text\n[YEILV][+-]? (M[0123sz])? <semver>?\n```\n\nIf this is provided then it takes higher priority than the modes specified in the metadata\nfile.",
          "type": [
            "array",
            "null"
          ],
          "items": {
            "$ref": "#/$defs/ParsedMode"
          }
        },
        "inputs": {
          "description": "The set of steps to run as part of this test case.",
          "type": "array",
          "items": {
            "$ref": "#/$defs/Step"
          }
        },
        "group": {
          "description": "An optional name of the group of tests that this test belongs to.",
          "type": [
            "string",
            "null"
          ]
        },
        "expected": {
          "description": "An optional set of expectations and assertions to make about the transaction after it ran.\n\nIf this is not specified then the only assertion that will be ran is that the transaction\nwas successful.\n\nThis expectation that's on the case itself will be attached to the final step of the case.",
          "anyOf": [
            {
              "$ref": "#/$defs/Expected"
            },
            {
              "type": "null"
            }
          ]
        },
        "ignore": {
          "description": "An optional boolean which defines if the case as a whole should be ignored. If null then the\ncase will not be ignored.",
          "type": [
            "boolean",
            "null"
          ]
        }
      },
      "required": [
        "inputs"
      ]
    },
    "ParsedMode": {
      "description": "This represents a mode that has been parsed from test metadata.\n\nMode strings can take the following form (in pseudo-regex):\n\n```text\n[YEILV][+-]? (M[0123sz])? <semver>?\n```\n\nWe can parse valid mode strings into [`ParsedMode`] using [`ParsedMode::from_str`].",
      "type": "string"
    },
    "Step": {
      "description": "A test step.\n\nA test step can be anything. It could be an invocation to a function, an assertion, or any other\naction that needs to be run or executed on the nodes used in the tests.",
      "anyOf": [
        {
          "description": "A function call or an invocation to some function on some smart contract.",
          "$ref": "#/$defs/FunctionCallStep"
        },
        {
          "description": "A step for performing a balance assertion on some account or contract.",
          "$ref": "#/$defs/BalanceAssertionStep"
        },
        {
          "description": "A step for asserting that the storage of some contract or account is empty.",
          "$ref": "#/$defs/StorageEmptyAssertionStep"
        },
        {
          "description": "A special step for repeating a bunch of steps a certain number of times.",
          "$ref": "#/$defs/RepeatStep"
        },
        {
          "description": "A step type that allows for a new account address to be allocated and to later on be used\nas the caller in another step.",
          "$ref": "#/$defs/AllocateAccountStep"
        }
      ]
    },
    "FunctionCallStep": {
      "description": "This is an input step which is a transaction description that the framework translates into a\ntransaction and executes on the nodes.",
      "type": "object",
      "properties": {
        "caller": {
          "description": "The address of the account performing the call and paying the fees for it.",
          "type": "string",
          "default": "0x90f8bf6a479f320ead074411a4b0e7944ea8c9c1"
        },
        "comment": {
          "description": "An optional comment on the step which has no impact on the execution in any way.",
          "type": [
            "string",
            "null"
          ]
        },
        "instance": {
          "description": "The contract instance that's being called in this transaction step.",
          "$ref": "#/$defs/ContractInstance",
          "default": "Test"
        },
        "method": {
          "description": "The method that's being called in this step.",
          "$ref": "#/$defs/Method"
        },
        "calldata": {
          "description": "The calldata that the function should be invoked with.",
          "$ref": "#/$defs/Calldata",
          "default": []
        },
        "expected": {
          "description": "A set of assertions and expectations to have for the transaction.",
          "anyOf": [
            {
              "$ref": "#/$defs/Expected"
            },
            {
              "type": "null"
            }
          ]
        },
        "value": {
          "description": "An optional value to provide as part of the transaction.",
          "anyOf": [
            {
              "$ref": "#/$defs/EtherValue"
            },
            {
              "type": "null"
            }
          ]
        },
        "variable_assignments": {
          "description": "Variable assignment to perform in the framework allowing us to reference them again later on\nduring the execution.",
          "anyOf": [
            {
              "$ref": "#/$defs/VariableAssignments"
            },
            {
              "type": "null"
            }
          ]
        }
      },
      "required": [
        "method"
      ]
    },
    "ContractInstance": {
      "description": "Represents a contract instance found a metadata file.\n\nTypically, this is used as the key to the \"contracts\" field of metadata files.",
      "type": "string"
    },
    "Method": {
      "description": "Specify how the contract is called.",
      "anyOf": [
        {
          "description": "Initiate a deploy transaction, calling contracts constructor.\n\nIndicated by `#deployer`.",
          "type": "string",
          "const": "#deployer"
        },
        {
          "description": "Does not calculate and insert a function selector.\n\nIndicated by `#fallback`.",
          "type": "string",
          "const": "#fallback"
        },
        {
          "description": "Call the public function with the given name.",
          "type": "string"
        }
      ]
    },
    "Calldata": {
      "description": "A type definition for the calldata supported by the testing framework.\n\nWe choose to document all of the types used in [`Calldata`] in this one doc comment to elaborate\non why they exist and consolidate all of the documentation for calldata in a single place where\nit can be viewed and understood.\n\nThe [`Single`] variant of this enum is quite simple and straightforward: it's a hex-encoded byte\narray of the calldata.\n\nThe [`Compound`] type is more intricate and allows for capabilities such as resolution and some\nsimple arithmetic operations. It houses a vector of [`CalldataItem`]s which is just a wrapper\naround an owned string.\n\nA [`CalldataItem`] could be a simple hex string of a single calldata argument, but it could also\nbe something that requires resolution such as `MyContract.address` which is a variable that is\nunderstood by the resolution logic to mean \"Lookup the address of this particular contract\ninstance\".\n\nIn addition to the above, the format supports some simple arithmetic operations like add, sub,\ndivide, multiply, bitwise AND, bitwise OR, and bitwise XOR. Our parser understands the [reverse\npolish notation] simply because it's easy to write a calculator for that notation and since we\ndo not have plans to use arithmetic too often in tests. In reverse polish notation a typical\n`2 + 4` would be written as `2 4 +` which makes this notation very simple to implement through\na stack.\n\nCombining the above, a single [`CalldataItem`] could employ both resolution and arithmetic at\nthe same time. For example, a [`CalldataItem`] of `$BLOCK_NUMBER $BLOCK_NUMBER +` means that\nthe block number should be retrieved and then it should be added to itself.\n\nInternally, we split the [`CalldataItem`] by spaces. Therefore, `$BLOCK_NUMBER $BLOCK_NUMBER+`\nis invalid but `$BLOCK_NUMBER $BLOCK_NUMBER +` is valid and can be understood by the parser and\ncalculator. After the split is done, each token is parsed into a [`CalldataToken<&str>`] forming\nan [`Iterator`] over [`CalldataToken<&str>`]. A [`CalldataToken<&str>`] can then be resolved\ninto a [`CalldataToken<U256>`] through the resolution logic. Finally, after resolution is done,\nthis iterator of [`CalldataToken<U256>`] is collapsed into the final result by applying the\narithmetic operations requested.\n\nFor example, supplying a [`Compound`] calldata of `0xdeadbeef` produces an iterator of a single\n[`CalldataToken<&str>`] items of the value [`CalldataToken::Item`] of the string value 12 which\nwe can then resolve into the appropriate [`U256`] value and convert into calldata.\n\nIn summary, the various types used in [`Calldata`] represent the following:\n- [`CalldataItem`]: A calldata string from the metadata files.\n- [`CalldataToken<&str>`]: Typically used in an iterator of items from the space splitted\n  [`CalldataItem`] and represents a token that has not yet been resolved into its value.\n- [`CalldataToken<U256>`]: Represents a token that's been resolved from being a string and into\n  the word-size calldata argument on which we can perform arithmetic.\n\n[`Single`]: Calldata::Single\n[`Compound`]: Calldata::Compound\n[reverse polish notation]: https://en.wikipedia.org/wiki/Reverse_Polish_notation",
      "anyOf": [
        {
          "type": "string"
        },
        {
          "type": "array",
          "items": {
            "$ref": "#/$defs/CalldataItem"
          }
        }
      ]
    },
    "CalldataItem": {
      "description": "This represents an item in the [`Calldata::Compound`] variant. Each item will be resolved\naccording to the resolution rules of the tool.",
      "type": "string"
    },
    "Expected": {
      "description": "A set of expectations and assertions to make about the transaction after it ran.\n\nIf this is not specified then the only assertion that will be ran is that the transaction\nwas successful.",
      "anyOf": [
        {
          "description": "An assertion that the transaction succeeded and returned the provided set of data.",
          "$ref": "#/$defs/Calldata"
        },
        {
          "description": "A more complex assertion.",
          "$ref": "#/$defs/ExpectedOutput"
        },
        {
          "description": "A set of assertions.",
          "type": "array",
          "items": {
            "$ref": "#/$defs/ExpectedOutput"
          }
        }
      ]
    },
    "ExpectedOutput": {
      "description": "A set of assertions to run on the transaction.",
      "type": "object",
      "properties": {
        "compiler_version": {
          "description": "An optional compiler version that's required in order for this assertion to run.",
          "type": [
            "string",
            "null"
          ]
        },
        "return_data": {
          "description": "An optional field of the expected returns from the invocation.",
          "anyOf": [
            {
              "$ref": "#/$defs/Calldata"
            },
            {
              "type": "null"
            }
          ]
        },
        "events": {
          "description": "An optional set of assertions to run on the emitted events from the transaction.",
          "type": [
            "array",
            "null"
          ],
          "items": {
            "$ref": "#/$defs/Event"
          }
        },
        "exception": {
          "description": "A boolean which defines whether we expect the transaction to succeed or fail.",
          "type": "boolean",
          "default": false
        }
      }
    },
    "Event": {
      "type": "object",
      "properties": {
        "address": {
          "description": "An optional field of the address of the emitter of the event.",
          "anyOf": [
            {
              "$ref": "#/$defs/StepAddress"
            },
            {
              "type": "null"
            }
          ]
        },
        "topics": {
          "description": "The set of topics to expect the event to have.",
          "type": "array",
          "items": {
            "type": "string"
          }
        },
        "values": {
          "description": "The set of values to expect the event to have.",
          "$ref": "#/$defs/Calldata"
        }
      },
      "required": [
        "topics",
        "values"
      ]
    },
    "StepAddress": {
      "description": "An address type that might either be an address literal or a resolvable address.",
      "type": "string"
    },
    "EtherValue": {
      "description": "Defines an Ether value.\n\nThis is an unsigned 256 bit integer that's followed by some denomination which can either be\neth, ether, gwei, or wei.",
      "type": "string"
    },
    "VariableAssignments": {
      "type": "object",
      "properties": {
        "return_data": {
          "description": "A vector of the variable names to assign to the return data.\n\nExample: `UniswapV3PoolAddress`",
          "type": "array",
          "items": {
            "type": "string"
          }
        }
      },
      "required": [
        "return_data"
      ]
    },
    "BalanceAssertionStep": {
      "description": "This represents a balance assertion step where the framework needs to query the balance of some\naccount or contract and assert that it's some amount.",
      "type": "object",
      "properties": {
        "comment": {
          "description": "An optional comment on the balance assertion.",
          "type": [
            "string",
            "null"
          ]
        },
        "address": {
          "description": "The address that the balance assertion should be done on.\n\nThis is a string which will be resolved into an address when being processed. Therefore,\nthis could be a normal hex address, a variable such as `Test.address`, or perhaps even a\nfull on variable like `$VARIABLE:Uniswap`. It follows the same resolution rules that are\nfollowed in the calldata.",
          "$ref": "#/$defs/StepAddress"
        },
        "expected_balance": {
          "description": "The amount of balance to assert that the account or contract has. This is a 256 bit string\nthat's serialized and deserialized into a decimal string.",
          "type": "string"
        }
      },
      "required": [
        "address",
        "expected_balance"
      ]
    },
    "StorageEmptyAssertionStep": {
      "description": "This represents an assertion for the storage of some contract or account and whether it's empty\nor not.",
      "type": "object",
      "properties": {
        "comment": {
          "description": "An optional comment on the storage empty assertion.",
          "type": [
            "string",
            "null"
          ]
        },
        "address": {
          "description": "The address that the balance assertion should be done on.\n\nThis is a string which will be resolved into an address when being processed. Therefore,\nthis could be a normal hex address, a variable such as `Test.address`, or perhaps even a\nfull on variable like `$VARIABLE:Uniswap`. It follows the same resolution rules that are\nfollowed in the calldata.",
          "$ref": "#/$defs/StepAddress"
        },
        "is_storage_empty": {
          "description": "A boolean of whether the storage of the address is empty or not.",
          "type": "boolean"
        }
      },
      "required": [
        "address",
        "is_storage_empty"
      ]
    },
    "RepeatStep": {
      "description": "This represents a repetition step which is a special step type that allows for a sequence of\nsteps to be repeated (on different drivers) a certain number of times.",
      "type": "object",
      "properties": {
        "comment": {
          "description": "An optional comment on the repetition step.",
          "type": [
            "string",
            "null"
          ]
        },
        "repeat": {
          "description": "The number of repetitions that the steps should be repeated for.",
          "type": "integer",
          "format": "uint",
          "minimum": 0
        },
        "steps": {
          "description": "The sequence of steps to repeat for the above defined number of repetitions.",
          "type": "array",
          "items": {
            "$ref": "#/$defs/Step"
          }
        }
      },
      "required": [
        "repeat",
        "steps"
      ]
    },
    "AllocateAccountStep": {
      "type": "object",
      "properties": {
        "comment": {
          "description": "An optional comment on the account allocation step.",
          "type": [
            "string",
            "null"
          ]
        },
        "allocate_account": {
          "description": "An instruction to allocate a new account with the value being the variable name of that\naccount. This must start with `$VARIABLE:` and then be followed by the variable name of the\naccount.",
          "type": "string"
        }
      },
      "required": [
        "allocate_account"
      ]
    },
    "ContractPathAndIdent": {
      "description": "Represents an identifier used for contracts.\n\nThe type supports serialization from and into the following string format:\n\n```text\n${path}:${contract_ident}\n```",
      "type": "string"
    },
    "EvmVersionRequirement": {
      "description": "An EVM version requirement that the test case has. This gets serialized and deserialized from\nand into [`String`]. This follows a simple format of (>=|<=|=|>|<) followed by a string of the\nEVM version.\n\nWhen specified, the framework will only run the test if the node's EVM version matches that\nrequired by the metadata file.",
      "type": "string"
    },
    "CompilationDirectives": {
      "description": "A set of compilation directives that will be passed to the compiler whenever the contracts for\nthe test are being compiled. Note that this differs from the [`Mode`]s in that a [`Mode`] is\njust a filter for when a test can run whereas this is an instruction to the compiler.\nDefines how the compiler should handle revert strings.",
      "type": "object",
      "properties": {
        "revert_string_handling": {
          "description": "Defines how the revert strings should be handled.",
          "anyOf": [
            {
              "$ref": "#/$defs/RevertString"
            },
            {
              "type": "null"
            }
          ]
        }
      }
    },
    "RevertString": {
      "description": "Defines how the compiler should handle revert strings.",
      "oneOf": [
        {
          "description": "The default handling of the revert strings.",
          "type": "string",
          "const": "default"
        },
        {
          "description": "The debug handling of the revert strings.",
          "type": "string",
          "const": "debug"
        },
        {
          "description": "Strip the revert strings.",
          "type": "string",
          "const": "strip"
        },
        {
          "description": "Provide verbose debug strings for the revert string.",
          "type": "string",
          "const": "verboseDebug"
        }
      ]
    }
  }
 }
		`@@ -0,0 +1,3 @@`
							`mod define_wrapper_type;`

							`pub use define_wrapper_type::*;`