Set the base path if specified

Fix compilation errors related to paths
Compile all contracts for a test file
2026-04-22 17:17:58 +00:00 · 2025-07-16 00:55:53 +03:00 · 2025-07-16 00:54:17 +03:00 · 2025-07-15 19:49:22 +03:00 · 2025-07-15 11:19:17 +00:00
16 changed files with 422 additions and 281 deletions
@@ -4012,6 +4012,7 @@ version = "0.1.0"
 dependencies = [
 "alloy",
 "anyhow",
 "futures",
 "once_cell",
 "tokio",
 "tracing",
@@ -25,6 +25,7 @@ alloy-primitives = "1.2.1"
 alloy-sol-types = "1.2.1"
 anyhow = "1.0"
 clap = { version = "4", features = ["derive"] }
 futures = { version = "0.3.31" }
 hex = "0.4.3"
 reqwest = { version = "0.12.15", features = ["blocking", "json"] }
 once_cell = "1.21"
@@ -44,6 +44,8 @@ pub trait SolidityCompiler {
 pub struct CompilerInput<T: PartialEq + Eq + Hash> {
    pub extra_options: T,
    pub input: SolcStandardJsonInput,
    pub allow_paths: Vec<PathBuf>,
    pub base_path: Option<PathBuf>,
 }
 /// The generic compilation output configuration.
@@ -83,8 +85,8 @@ where
 pub struct Compiler<T: SolidityCompiler> {
    input: SolcStandardJsonInput,
    extra_options: T::Options,
-    allow_paths: Vec<String>,
+    allow_paths: Vec<PathBuf>,
-    base_path: Option<String>,
+    base_path: Option<PathBuf>,
 }
 impl Default for Compiler<solc::Solc> {
@@ -145,12 +147,12 @@ where
        self
    }
-    pub fn allow_path(mut self, path: String) -> Self {
+    pub fn allow_path(mut self, path: PathBuf) -> Self {
        self.allow_paths.push(path);
        self
    }
-    pub fn base_path(mut self, base_path: String) -> Self {
+    pub fn base_path(mut self, base_path: PathBuf) -> Self {
        self.base_path = Some(base_path);
        self
    }
@@ -159,6 +161,8 @@ where
        T::new(solc_path).build(CompilerInput {
            extra_options: self.extra_options,
            input: self.input,
            allow_paths: self.allow_paths,
            base_path: self.base_path,
        })
    }
@@ -23,13 +23,27 @@ impl SolidityCompiler for Resolc {
        &self,
        input: CompilerInput<Self::Options>,
    ) -> anyhow::Result<CompilerOutput<Self::Options>> {
-        let mut child = Command::new(&self.resolc_path)
+        let mut command = Command::new(&self.resolc_path);
-            .arg("--standard-json")
+        command
            .args(&input.extra_options)
            .stdin(Stdio::piped())
            .stdout(Stdio::piped())
            .stderr(Stdio::piped())
-            .spawn()?;
+            .arg("--standard-json");
        if let Some(ref base_path) = input.base_path {
            command.arg("--base-path").arg(base_path);
        }
        if !input.allow_paths.is_empty() {
            command.arg("--allow-paths").arg(
                input
                    .allow_paths
                    .iter()
                    .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)?;
@@ -55,13 +69,22 @@ impl SolidityCompiler for Resolc {
            });
        }
-        let parsed: SolcStandardJsonOutput = serde_json::from_slice(&stdout).map_err(|e| {
+        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)
            )
        })?;
        // 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}")
            }
        }
        Ok(CompilerOutput {
            input,
            output: parsed,
@@ -9,6 +9,7 @@ use std::{
 use crate::{CompilerInput, CompilerOutput, SolidityCompiler};
 use revive_dt_config::Arguments;
 use revive_dt_solc_binaries::download_solc;
 use revive_solc_json_interface::SolcStandardJsonOutput;
 pub struct Solc {
    solc_path: PathBuf,
@@ -21,12 +22,27 @@ impl SolidityCompiler for Solc {
        &self,
        input: CompilerInput<Self::Options>,
    ) -> anyhow::Result<CompilerOutput<Self::Options>> {
-        let mut child = Command::new(&self.solc_path)
+        let mut command = Command::new(&self.solc_path);
        command
            .stdin(Stdio::piped())
            .stdout(Stdio::piped())
            .stderr(Stdio::piped())
-            .arg("--standard-json")
+            .arg("--standard-json");
-            .spawn()?;
+
        if let Some(ref base_path) = input.base_path {
            command.arg("--base-path").arg(base_path);
        }
        if !input.allow_paths.is_empty() {
            command.arg("--allow-paths").arg(
                input
                    .allow_paths
                    .iter()
                    .map(|path| path.display().to_string())
                    .collect::<Vec<_>>()
                    .join(","),
            );
        }
        let mut child = command.spawn()?;
        let stdin = child.stdin.as_mut().expect("should be piped");
        serde_json::to_writer(stdin, &input.input)?;
@@ -42,9 +58,26 @@ impl SolidityCompiler for Solc {
            });
        }
        let parsed =
            serde_json::from_slice::<SolcStandardJsonOutput>(&output.stdout).map_err(|e| {
                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}")
            }
        }
        Ok(CompilerOutput {
            input,
-            output: serde_json::from_slice(&output.stdout)?,
+            output: parsed,
            error: None,
        })
    }
@@ -69,14 +69,13 @@ where
            anyhow::bail!("unsupported solc version: {:?}", &mode.solc_version);
        };
-        let mut compiler = Compiler::<T::Compiler>::new()
+        let compiler = Compiler::<T::Compiler>::new()
-            .base_path(metadata.directory()?.display().to_string())
+            .allow_path(metadata.directory()?)
            .solc_optimizer(mode.solc_optimize());
-        for (file, _contract) in metadata.contract_sources()?.values() {
+        let compiler = FilesWithExtensionIterator::new(metadata.directory()?)
-            tracing::debug!("contract source {}", file.display());
+            .with_allowed_extension("sol")
-            compiler = compiler.with_source(file)?;
+            .try_fold(compiler, |compiler, path| compiler.with_source(&path))?;
        }
        let mut task = CompilationTask {
            json_input: compiler.input(),
@@ -180,12 +179,15 @@ where
    }
    pub fn deploy_contracts(&mut self, input: &Input, node: &T::Blockchain) -> anyhow::Result<()> {
-        tracing::debug!(
+        let tracing_span = tracing::debug_span!(
-            "Deploying contracts {}, having address {} on node: {}",
+            "Deploying contracts",
-            &input.instance,
+            ?input,
-            &input.caller,
+            node = std::any::type_name::<T>()
            std::any::type_name::<T>()
        );
        let _guard = tracing_span.enter();
        tracing::debug!(number_of_contracts_to_deploy = self.contracts.len());
        for output in self.contracts.values() {
            let Some(contract_map) = &output.contracts else {
                tracing::debug!(
@@ -476,3 +478,77 @@ where
        Ok(())
    }
 }
 /// 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`
 struct FilesWithExtensionIterator {
    /// The set of allowed extensions that that match the requirement and that should be returned
    /// when found.
    allowed_extensions: std::collections::HashSet<std::borrow::Cow<'static, str>>,
    /// The set of directories to visit next. This iterator does BFS and so these directories will
    /// only be visited if we can't find any files in our state.
    directories_to_search: Vec<std::path::PathBuf>,
    /// The set of files matching the allowed extensions that were found. If there are entries in
    /// 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.
    ///
    /// [`Iterator`]: std::iter::Iterator
    files_matching_allowed_extensions: Vec<std::path::PathBuf>,
 }
 impl FilesWithExtensionIterator {
    fn new(root_directory: std::path::PathBuf) -> Self {
        Self {
            allowed_extensions: Default::default(),
            directories_to_search: vec![root_directory],
            files_matching_allowed_extensions: Default::default(),
        }
    }
    fn with_allowed_extension(
        mut self,
        allowed_extension: impl Into<std::borrow::Cow<'static, str>>,
    ) -> Self {
        self.allowed_extensions.insert(allowed_extension.into());
        self
    }
 }
 impl Iterator for FilesWithExtensionIterator {
    type Item = std::path::PathBuf;
    fn next(&mut self) -> Option<Self::Item> {
        if let Some(file_path) = self.files_matching_allowed_extensions.pop() {
            return Some(file_path);
        };
        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
        // elect to just ignore it and look in the next directory, we do that by calling the next
        // method again on the iterator, which is an intentional decision that we made here instead
        // of panicking.
        let Ok(dir_entries) = std::fs::read_dir(directory_to_search) else {
            return self.next();
        };
        for entry in dir_entries.flatten() {
            let entry_path = entry.path();
            if entry_path.is_dir() {
                self.directories_to_search.push(entry_path)
            } else if entry_path.is_file()
                && entry_path.extension().is_some_and(|ext| {
                    self.allowed_extensions
                        .iter()
                        .any(|allowed| ext.eq_ignore_ascii_case(allowed.as_ref()))
                })
            {
                self.files_matching_allowed_extensions.push(entry_path)
            }
        }
        self.next()
    }
 }
@@ -123,9 +123,14 @@ impl Input {
            return Ok(Bytes::default()); // fallback or deployer — no input
        };
-        let abi = deployed_abis
+        let Some(abi) = deployed_abis.get(&self.instance) else {
-            .get(&self.instance)
+            tracing::error!(
-            .ok_or_else(|| anyhow::anyhow!("ABI for instance '{}' not found", &self.instance))?;
+                contract_name = self.instance,
                available_abis = ?deployed_abis.keys().collect::<Vec<_>>(),
                "Attempted to lookup ABI of contract but it wasn't found"
            );
            anyhow::bail!("ABI for instance '{}' not found", &self.instance);
        };
        tracing::trace!("ABI found for instance: {}", &self.instance);
@@ -11,6 +11,7 @@ rust-version.workspace = true
 [dependencies]
 alloy = { workspace = true }
 anyhow = { workspace = true }
 futures = { workspace = true }
 tracing = { workspace = true }
 once_cell = { workspace = true }
 tokio = { workspace = true }
@@ -0,0 +1,221 @@
 //! 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)
    }
 }
@@ -3,12 +3,9 @@
 use alloy::primitives::Address;
 use alloy::rpc::types::trace::geth::{DiffMode, GethTrace};
 use alloy::rpc::types::{TransactionReceipt, TransactionRequest};
 use tokio_runtime::TO_TOKIO;
-pub mod nonce;
+mod blocking_executor;
-mod tokio_runtime;
+pub use blocking_executor::*;
 pub mod trace;
 pub mod transaction;
 /// An interface for all interactions with Ethereum compatible nodes.
 pub trait EthereumNode {
@@ -1,55 +0,0 @@
 use std::pin::Pin;
 use alloy::{
    primitives::Address,
    providers::{Provider, ProviderBuilder},
 };
 use tokio::sync::oneshot;
 use crate::{TO_TOKIO, tokio_runtime::AsyncNodeInteraction};
 pub type Task = Pin<Box<dyn Future<Output = anyhow::Result<u64>> + Send>>;
 pub(crate) struct Nonce {
    sender: oneshot::Sender<anyhow::Result<u64>>,
    task: Task,
 }
 impl AsyncNodeInteraction for Nonce {
    type Output = anyhow::Result<u64>;
    fn split(
        self,
    ) -> (
        std::pin::Pin<Box<dyn Future<Output = Self::Output> + Send>>,
        oneshot::Sender<Self::Output>,
    ) {
        (self.task, self.sender)
    }
 }
 /// This is like `trace_transaction`, just for nonces.
 pub fn fetch_onchain_nonce(
    connection: String,
    wallet: alloy::network::EthereumWallet,
    address: Address,
 ) -> anyhow::Result<u64> {
    let sender = TO_TOKIO.lock().unwrap().nonce_sender.clone();
    let (tx, rx) = oneshot::channel();
    let task: Task = Box::pin(async move {
        let provider = ProviderBuilder::new()
            .wallet(wallet)
            .connect(&connection)
            .await?;
        let onchain = provider.get_transaction_count(address).await?;
        Ok(onchain)
    });
    sender
        .blocking_send(Nonce { task, sender: tx })
        .expect("not in async context");
    rx.blocking_recv()
        .unwrap_or_else(|err| anyhow::bail!("nonce fetch failed: {err}"))
 }
@@ -1,87 +0,0 @@
 //! The alloy crate __requires__ a tokio runtime.
 //! We contain any async rust right here.
 use once_cell::sync::Lazy;
 use std::pin::Pin;
 use std::sync::Mutex;
 use std::thread;
 use tokio::runtime::Runtime;
 use tokio::spawn;
 use tokio::sync::{mpsc, oneshot};
 use tokio::task::JoinError;
 use crate::nonce::Nonce;
 use crate::trace::Trace;
 use crate::transaction::Transaction;
 pub(crate) static TO_TOKIO: Lazy<Mutex<TokioRuntime>> =
    Lazy::new(|| Mutex::new(TokioRuntime::spawn()));
 /// Common interface for executing async node interactions from a non-async context.
 #[allow(clippy::type_complexity)]
 pub(crate) trait AsyncNodeInteraction: Send + 'static {
    type Output: Send;
    //// Returns the task and the output sender.
    fn split(
        self,
    ) -> (
        Pin<Box<dyn Future<Output = Self::Output> + Send>>,
        oneshot::Sender<Self::Output>,
    );
 }
 pub(crate) struct TokioRuntime {
    pub(crate) transaction_sender: mpsc::Sender<Transaction>,
    pub(crate) trace_sender: mpsc::Sender<Trace>,
    pub(crate) nonce_sender: mpsc::Sender<Nonce>,
 }
 impl TokioRuntime {
    fn spawn() -> Self {
        let rt = Runtime::new().expect("should be able to create the tokio runtime");
        let (transaction_sender, transaction_receiver) = mpsc::channel::<Transaction>(1024);
        let (trace_sender, trace_receiver) = mpsc::channel::<Trace>(1024);
        let (nonce_sender, nonce_receiver) = mpsc::channel::<Nonce>(1024);
        thread::spawn(move || {
            rt.block_on(async move {
                let transaction_task = spawn(interaction::<Transaction>(transaction_receiver));
                let trace_task = spawn(interaction::<Trace>(trace_receiver));
                let nonce_task = spawn(interaction::<Nonce>(nonce_receiver));
                if let Err(error) = transaction_task.await {
                    tracing::error!("tokio transaction task failed: {error}");
                }
                if let Err(error) = trace_task.await {
                    tracing::error!("tokio trace transaction task failed: {error}");
                }
                if let Err(error) = nonce_task.await {
                    tracing::error!("tokio nonce task failed: {error}");
                }
            });
        });
        Self {
            transaction_sender,
            trace_sender,
            nonce_sender,
        }
    }
 }
 async fn interaction<T>(mut receiver: mpsc::Receiver<T>) -> Result<(), JoinError>
 where
    T: AsyncNodeInteraction,
 {
    while let Some(task) = receiver.recv().await {
        spawn(async move {
            let (task, sender) = task.split();
            sender
                .send(task.await)
                .unwrap_or_else(|_| panic!("failed to send task output"));
        });
    }
    Ok(())
 }
@@ -1,43 +0,0 @@
 //! Trace transactions in a sync context.
 use std::pin::Pin;
 use alloy::rpc::types::trace::geth::GethTrace;
 use tokio::sync::oneshot;
 use crate::TO_TOKIO;
 use crate::tokio_runtime::AsyncNodeInteraction;
 pub type Task = Pin<Box<dyn Future<Output = anyhow::Result<GethTrace>> + Send>>;
 pub(crate) struct Trace {
    sender: oneshot::Sender<anyhow::Result<GethTrace>>,
    task: Task,
 }
 impl AsyncNodeInteraction for Trace {
    type Output = anyhow::Result<GethTrace>;
    fn split(
        self,
    ) -> (
        std::pin::Pin<Box<dyn Future<Output = Self::Output> + Send>>,
        oneshot::Sender<Self::Output>,
    ) {
        (self.task, self.sender)
    }
 }
 /// Execute some [Task] that return a [GethTrace] result.
 pub fn trace_transaction(task: Task) -> anyhow::Result<GethTrace> {
    let task_sender = TO_TOKIO.lock().unwrap().trace_sender.clone();
    let (sender, receiver) = oneshot::channel();
    task_sender
        .blocking_send(Trace { task, sender })
        .expect("we are not calling this from an async context");
    receiver
        .blocking_recv()
        .unwrap_or_else(|error| anyhow::bail!("no trace received: {error}"))
 }
@@ -1,46 +0,0 @@
 //! Execute transactions in a sync context.
 use std::pin::Pin;
 use alloy::rpc::types::TransactionReceipt;
 use tokio::sync::oneshot;
 use crate::TO_TOKIO;
 use crate::tokio_runtime::AsyncNodeInteraction;
 pub type Task = Pin<Box<dyn Future<Output = anyhow::Result<TransactionReceipt>> + Send>>;
 pub(crate) struct Transaction {
    receipt_sender: oneshot::Sender<anyhow::Result<TransactionReceipt>>,
    task: Task,
 }
 impl AsyncNodeInteraction for Transaction {
    type Output = anyhow::Result<TransactionReceipt>;
    fn split(
        self,
    ) -> (
        Pin<Box<dyn Future<Output = Self::Output> + Send>>,
        oneshot::Sender<Self::Output>,
    ) {
        (self.task, self.receipt_sender)
    }
 }
 /// Execute some [Task] that returns a [TransactionReceipt].
 pub fn execute_transaction(task: Task) -> anyhow::Result<TransactionReceipt> {
    let request_sender = TO_TOKIO.lock().unwrap().transaction_sender.clone();
    let (receipt_sender, receipt_receiver) = oneshot::channel();
    request_sender
        .blocking_send(Transaction {
            receipt_sender,
            task,
        })
        .expect("we are not calling this from an async context");
    receipt_receiver
        .blocking_recv()
        .unwrap_or_else(|error| anyhow::bail!("no receipt received: {error}"))
 }
@@ -23,10 +23,7 @@ use alloy::{
    },
 };
 use revive_dt_config::Arguments;
-use revive_dt_node_interaction::{
+use revive_dt_node_interaction::{BlockingExecutor, EthereumNode};
    EthereumNode, nonce::fetch_onchain_nonce, trace::trace_transaction,
    transaction::execute_transaction,
 };
 use tracing::Level;
 use crate::Node;
@@ -205,7 +202,7 @@ impl EthereumNode for Instance {
        let connection_string = self.connection_string();
        let wallet = self.wallet.clone();
-        execute_transaction(Box::pin(async move {
+        BlockingExecutor::execute(async move {
            let outer_span = tracing::debug_span!("Submitting transaction", ?transaction,);
            let _outer_guard = outer_span.enter();
@@ -284,7 +281,7 @@ impl EthereumNode for Instance {
                    }
                }
            }
-        }))
+        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
@@ -300,14 +297,14 @@ impl EthereumNode for Instance {
        });
        let wallet = self.wallet.clone();
-        trace_transaction(Box::pin(async move {
+        BlockingExecutor::execute(async move {
            Ok(ProviderBuilder::new()
                .wallet(wallet)
                .connect(&connection_string)
                .await?
                .debug_trace_transaction(transaction.transaction_hash, trace_options)
                .await?)
-        }))
+        })?
    }
    #[tracing::instrument(skip_all, fields(geth_node_id = self.id))]
@@ -329,7 +326,15 @@ impl EthereumNode for Instance {
        let connection_string = self.connection_string.clone();
        let wallet = self.wallet.clone();
-        let onchain_nonce = fetch_onchain_nonce(connection_string, wallet, address)?;
+        let onchain_nonce = BlockingExecutor::execute::<anyhow::Result<_>>(async move {
            ProviderBuilder::new()
                .wallet(wallet)
                .connect(&connection_string)
                .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);
@@ -27,10 +27,7 @@ use sp_runtime::AccountId32;
 use tracing::Level;
 use revive_dt_config::Arguments;
-use revive_dt_node_interaction::{
+use revive_dt_node_interaction::{BlockingExecutor, EthereumNode};
    EthereumNode, nonce::fetch_onchain_nonce, trace::trace_transaction,
    transaction::execute_transaction,
 };
 use crate::Node;
@@ -340,7 +337,7 @@ impl EthereumNode for KitchensinkNode {
        tracing::debug!("Submitting transaction: {transaction:#?}");
        tracing::info!("Submitting tx to kitchensink");
-        let receipt = execute_transaction(Box::pin(async move {
+        let receipt = BlockingExecutor::execute(async move {
            Ok(ProviderBuilder::new()
                .wallet(wallet)
                .connect(&url)
@@ -349,7 +346,7 @@ impl EthereumNode for KitchensinkNode {
                .await?
                .get_receipt()
                .await?)
-        }));
+        })?;
        tracing::info!(?receipt, "Submitted tx to kitchensink");
        receipt
    }
@@ -368,14 +365,14 @@ impl EthereumNode for KitchensinkNode {
        let wallet = self.wallet.clone();
-        trace_transaction(Box::pin(async move {
+        BlockingExecutor::execute(async move {
            Ok(ProviderBuilder::new()
                .wallet(wallet)
                .connect(&url)
                .await?
                .debug_trace_transaction(transaction.transaction_hash, trace_options)
                .await?)
-        }))
+        })?
    }
    #[tracing::instrument(skip_all, fields(kitchensink_node_id = self.id))]
@@ -394,7 +391,15 @@ impl EthereumNode for KitchensinkNode {
        let url = self.rpc_url.clone();
        let wallet = self.wallet.clone();
-        let onchain_nonce = fetch_onchain_nonce(url, wallet, address)?;
+        let onchain_nonce = BlockingExecutor::execute::<anyhow::Result<_>>(async move {
            ProviderBuilder::new()
                .wallet(wallet)
                .connect(&url)
                .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);
Author	SHA1	Message	Date
Omar Abdulla	a0006cb9a8	Set the base path if specified	2025-07-16 00:55:53 +03:00
Omar Abdulla	fd2e004ee6	Fix compilation errors related to paths	2025-07-16 00:54:17 +03:00
Omar Abdulla	94cfa8cbcf	Compile all contracts for a test file	2025-07-15 19:49:22 +03:00
Omar	14888f9767	Update the async runtime (#42 ) * Update the async runtime with syntactic sugar. * Fix doc test * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Update crates/node-interaction/src/blocking_executor.rs Co-authored-by: xermicus <cyrill@parity.io> * Improve the comments * Update the release profile --------- Co-authored-by: xermicus <cyrill@parity.io>	2025-07-15 11:19:17 +00:00