Files
pezkuwi-subxt/cumulus
Niklas Adolfsson e16ef0861f rpc: backpressured RPC server (bump jsonrpsee 0.20) (#1313)
This is a rather big change in jsonrpsee, the major things in this bump
are:
- Server backpressure (the subscription impls are modified to deal with
that)
- Allow custom error types / return types (remove jsonrpsee::core::Error
and jsonrpee::core::CallError)
- Bug fixes (graceful shutdown in particular not used by substrate
anyway)
   - Less dependencies for the clients in particular
   - Return type requires Clone in method call responses
   - Moved to tokio channels
   - Async subscription API (not used in this PR)

Major changes in this PR:
- The subscriptions are now bounded and if subscription can't keep up
with the server it is dropped
- CLI: add parameter to configure the jsonrpc server bounded message
buffer (default is 64)
- Add our own subscription helper to deal with the unbounded streams in
substrate

The most important things in this PR to review is the added helpers
functions in `substrate/client/rpc/src/utils.rs` and the rest is pretty
much chore.

Regarding the "bounded buffer limit" it may cause the server to handle
the JSON-RPC calls
slower than before.

The message size limit is bounded by "--rpc-response-size" thus "by
default 10MB * 64 = 640MB"
but the subscription message size is not covered by this limit and could
be capped as well.

Hopefully the last release prior to 1.0, sorry in advance for a big PR

Previous attempt: https://github.com/paritytech/substrate/pull/13992

Resolves https://github.com/paritytech/polkadot-sdk/issues/748, resolves
https://github.com/paritytech/polkadot-sdk/issues/627
2024-01-23 08:55:13 +00:00
..
2024-01-16 18:18:04 +00:00
2020-05-18 17:17:34 +02:00

Cumulus ☁️

Doc

This repository contains both the Cumulus SDK and also specific chains implemented on top of this SDK.

If you only want to run a Polkadot Parachain Node, check out our container section.

Cumulus SDK

A set of tools for writing Substrate-based Polkadot parachains. Refer to the included overview for architectural details, and the Connect to a relay chain how-to guide for a guided walk-through of using these tools.

It's easy to write blockchains using Substrate, and the overhead of writing parachains' distribution, p2p, database, and synchronization layers should be just as low. This project aims to make it easy to write parachains for Polkadot by leveraging the power of Substrate.

Cumulus clouds are shaped sort of like dots; together they form a system that is intricate, beautiful and functional.

Consensus

parachain-consensus is a consensus engine for Substrate that follows a Polkadot relay chain. This will run a Polkadot node internally, and dictate to the client and synchronization algorithms which chain to follow, finalize, and treat as best.

Collator

A Polkadot collator for the parachain is implemented by the polkadot-parachain binary (previously called polkadot-collator).

You may run polkadot-parachain locally after building it or using one of the container option described here.

Relay Chain Interaction

To operate a parachain node, a connection to the corresponding relay chain is necessary. This can be achieved in one of three ways:

  1. Run a full relay chain node within the parachain node (default)
  2. Connect to an external relay chain node via WebSocket RPC
  3. Run a light client for the relay chain

In-process Relay Chain Node

If an external relay chain node is not specified (default behavior), then a full relay chain node is spawned within the same process.

This node has all of the typical components of a regular Polkadot node and will have to fully sync with the relay chain to work.

Example command
polkadot-parachain \
	--chain parachain-chainspec.json \
	--tmp \
	-- \
	--chain relaychain-chainspec.json

External Relay Chain Node

An external relay chain node is connected via WebsSocket RPC by using the --relay-chain-rpc-urls command line argument. This option accepts one or more space-separated WebSocket URLs to a full relay chain node. By default, only the first URL will be used, with the rest as a backup in case the connection to the first node is lost.

Parachain nodes using this feature won't have to fully sync with the relay chain to work, so in general they will use fewer system resources.

Note: At this time, any parachain nodes using this feature will still spawn a significantly cut-down relay chain node in-process. Even though they lack the majority of normal Polkadot subsystems, they will still need to connect directly to the relay chain network.

Example command
polkadot-parachain \
	--chain parachain-chainspec.json \
	--tmp \
	--relay-chain-rpc-urls \
		"ws://relaychain-rpc-endpoint:9944" \
		"ws://relaychain-rpc-endpoint-backup:9944" \
	-- \
	--chain relaychain-chainspec.json

Relay Chain Light Client

An internal relay chain light client provides a fast and lightweight approach for connecting to the relay chain network. It provides relay chain notifications and facilitates runtime calls.

To specify which chain the light client should connect to, users need to supply a relay chain chain-spec as part of the relay chain arguments.

Note: At this time, any parachain nodes using this feature will still spawn a significantly cut-down relay chain node in-process. Even though they lack the majority of normal Polkadot subsystems, they will still need to connect directly to the relay chain network.

Example command
polkadot-parachain \
	--chain parachain-chainspec.json \
	--tmp \
	--relay-chain-light-client \
	-- \
	--chain relaychain-chainspec.json

Installation and Setup

Before building Cumulus SDK based nodes / runtimes prepare your environment by following Substrate installation instructions.

To launch a local network, you can use zombienet for quick setup and experimentation or follow the manual setup.

Zombienet

We use Zombienet to spin up networks for integration tests and local networks. Follow these installation steps to set it up on your machine. A simple network specification with two relay chain nodes and one collator is located at zombienet/examples/small_network.toml.

Which provider should I use?

Zombienet offers multiple providers to run networks. Choose the one that best fits your needs:

  • Podman: Choose this if you want to spin up a network quick and easy.
  • Native: Choose this if you want to develop and deploy your changes. Requires compilation of the binaries.
  • Kubernetes: Choose this for advanced use-cases or running on cloud-infrastructure.

How to run

To run the example network, use the following commands:

# Podman provider
zombienet --provider podman spawn ./zombienet/examples/small_network.toml

# Native provider, assumes polkadot and polkadot-parachains binary in $PATH
zombienet --provider native spawn ./zombienet/examples/small_network.toml

Manual Setup

Launch the Relay Chain

# Clone
git clone https://github.com/paritytech/polkadot-sdk

# Compile Polkadot's required binaries
cargo build --release -p polkadot

# Generate a raw chain spec
./target/release/polkadot build-spec --chain rococo-local --disable-default-bootnode --raw > rococo-local-cfde.json

# Alice
./target/release/polkadot --chain rococo-local-cfde.json --alice --tmp

# Bob (In a separate terminal)
./target/release/polkadot --chain rococo-local-cfde.json --bob --tmp --port 30334

Launch the Parachain

# Compile
cargo build --release -p polkadot-parachain-bin

# Export genesis state
./target/release/polkadot-parachain export-genesis-state > genesis-state

# Export genesis wasm
./target/release/polkadot-parachain export-genesis-wasm > genesis-wasm

# Collator1
./target/release/polkadot-parachain --collator --alice --force-authoring \
  --tmp --port 40335 --rpc-port 9946 -- --chain rococo-local-cfde.json --port 30335

# Collator2
./target/release/polkadot-parachain --collator --bob --force-authoring \
  --tmp --port 40336 --rpc-port 9947 -- --chain rococo-local-cfde.json --port 30336

# Parachain Full Node 1
./target/release/polkadot-parachain --tmp --port 40337 --rpc-port 9948 -- \
  --chain rococo-local-cfde.json --port 30337

Register the parachain

image

Asset Hub 🪙

This repository also contains the Asset Hub runtimes. Asset Hub is a system parachain providing an asset store for the Polkadot ecosystem.

Build & Launch a Node

To run an Asset Hub node, you will need to compile the polkadot-parachain binary:

cargo build --release --locked --bin polkadot-parachain

Once the executable is built, launch the parachain node via:

CHAIN=asset-hub-westend # or asset-hub-kusama
./target/release/polkadot-parachain --chain $CHAIN

Refer to the setup instructions to run a local network for development.

Contracts 📝

See the contracts-rococo readme for details.

Bridge-hub 📝

See the bridge-hubs readme for details.

Rococo 👑

Rococo is becoming a Community Parachain Testbed for parachain teams in the Polkadot ecosystem. It supports multiple parachains with the differentiation of long-term connections and recurring short-term connections, to see which parachains are currently connected and how long they will be connected for see here.

Rococo is an elaborate style of design and the name describes the painstaking effort that has gone into this project.

Build & Launch Rococo Collators

Collators are similar to validators in the relay chain. These nodes build the blocks that will eventually be included by the relay chain for a parachain.

To run a Rococo collator you will need to compile the following binary:

cargo build --release --locked --bin polkadot-parachain

Once the executable is built, launch collators for each parachain (repeat once each for chain tick, trick, track):

./target/release/polkadot-parachain --chain $CHAIN --validator

You can also build using a container.

Parachains

The network uses horizontal message passing (HRMP) to enable communication between parachains and the relay chain and, in turn, between parachains. This means that every message is sent to the relay chain, and from the relay chain to its destination parachain.