An interest-bearing stablecoin bridge between all DeFi chains.
Gateway is built on Substrate.
Follow these steps to prepare a local Substrate development environment 🛠️
Install all the required dependencies with a single command (be patient, this can take up to 30 minutes).
curl https://getsubstrate.io -sSf | bash -s -- --fastFind manual setup instructions at the Substrate Developer Hub.
Once the development environment is set up, build Gateway. This command will build the Wasm and native code:
cargo build --releaseNote: that we require the rust nightly toolchain as we rely on unstable features (notably const_generics). You should make nightly your default rust toolchain.
To test, run:
cargo test -- -Z unstable-options --test-threads 1Purge any existing dev chain state:
./target/release/gateway purge-chain --devIf all else fails the chain state can be purged (on Mac OS X) like:
rm -rf ~/Library/Application\ Support/gateway/chains/devStart a dev chain:
./target/release/gateway --devOr, start a dev chain with detailed logging:
RUST_LOG=debug RUST_BACKTRACE=1 ./target/release/gateway -lruntime=debug --devTo see the multi-node consensus algorithm in action, run a local testnet with two validator nodes,
Alice and Bob, that have been configured as the initial
authorities of the local testnet chain and endowed with testnet units.
Note: this will require two terminal sessions (one for each node).
Start Alice's node first. The command below uses the default TCP port (30333) and specifies
/tmp/alice as the chain database location. Alice's node ID will be
12D3KooWEyoppNCUx8Yx66oV9fJnriXwCcXwDDUA2kj6vnc6iDEp (legacy representation:
QmRpheLN4JWdAnY7HGJfWFNbfkQCb6tFf4vvA6hgjMZKrR); this is determined by the node-key.
cargo +nightly run -- \
--db=ParityDB \
--base-path /tmp/alice \
--chain=local \
--alice \
--node-key 0000000000000000000000000000000000000000000000000000000000000001 \
--telemetry-url 'ws://telemetry.polkadot.io:1024 0' \
--validatorIn another terminal, use the following command to start Bob's node on a different TCP port (30334)
and with a chain database location of /tmp/bob. The --bootnodes option will connect his node to
Alice's on TCP port 30333:
cargo +nightly run -- \
--db=ParityDB \
--base-path /tmp/bob \
--bootnodes /ip4/127.0.0.1/tcp/30333/p2p/12D3KooWEyoppNCUx8Yx66oV9fJnriXwCcXwDDUA2kj6vnc6iDEp \
--chain=local \
--bob \
--port 30334 \
--ws-port 9945 \
--telemetry-url 'ws://telemetry.polkadot.io:1024 0' \
--validatorExecute cargo +nightly run -- --help to learn more about the Gateway's CLI options.
A Substrate project such as this consists of a number of components that are spread across a few directories.
A blockchain node is an application that allows users to participate in a blockchain network. Substrate-based blockchain nodes expose a number of capabilities:
- Networking: Substrate nodes use the
libp2pnetworking stack to allow the nodes in the network to communicate with one another. - Consensus: Blockchains must have a way to come to consensus on the state of the network. Substrate makes it possible to supply custom consensus engines and also ships with several consensus mechanisms that have been built on top of Web3 Foundation research.
- RPC Server: A remote procedure call (RPC) server is used to interact with Substrate nodes.
There are several files in the node directory - take special note of the following:
chain_spec.rs: A chain specification is a source code file that defines a Substrate chain's initial (genesis) state. Chain specifications are useful for development and testing, and critical when architecting the launch of a production chain. Take note of thedevelopment_configandtestnet_genesisfunctions, which are used to define the genesis state for the local development chain configuration. These functions identify some well-known accounts and use them to configure the blockchain's initial state.service.rs: This file defines the node implementation. Take note of the libraries that this file imports and the names of the functions it invokes. In particular, there are references to consensus-related topics, such as the longest chain rule, the Aura block authoring mechanism and the GRANDPA finality gadget.
After the node has been built, refer to the embedded documentation to learn more about the capabilities and configuration parameters that it exposes:
./target/release/gateway --helpIn Substrate, the terms "runtime" and "state transition function" are analogous - they refer to the core logic of the blockchain that is responsible for validating blocks and executing the state changes they define. The Substrate project in this repository uses the FRAME framework to construct a blockchain runtime. FRAME allows runtime developers to declare domain-specific logic in modules called "pallets". At the heart of FRAME is a helpful macro language that makes it easy to create pallets and flexibly compose them to create blockchains that can address a variety of needs.
Review the FRAME runtime implementation included in Gateway and note the following:
- This file configures several pallets to include in the runtime. Each pallet configuration is
defined by a code block that begins with
impl $PALLET_NAME::Config for Runtime. - The pallets are composed into a single runtime by way of the
construct_runtime!macro, which is part of the core FRAME Support library.
The runtime in this project is constructed using many FRAME pallets that ship with the
core Substrate repository and a
CASH pallet that is defined in the pallets directory.
A FRAME pallet is compromised of a number of blockchain primitives:
- Storage: FRAME defines a rich set of powerful storage abstractions that makes it easy to use Substrate's efficient key-value database to manage the evolving state of a blockchain.
- Dispatchables: FRAME pallets define special types of functions that can be invoked (dispatched) from outside of the runtime in order to update its state.
- Events: Substrate uses events to notify users of important changes in the runtime.
- Errors: When a dispatchable fails, it returns an error.
- Config: The
Configconfiguration interface is used to define the types and parameters upon which a FRAME pallet depends.
First, install Docker.
Then build the Dockerfile:
docker build -t gateway .Next, start your chain:
docker run --rm -it gateway -- /bin/shAll upgrades to Gateway should happen via the release process. We need to track which features were included in the release, usually including a changelog that covers each PR that was merged.
Proper release management is important here, especially since releases include many varieties of breaking changes. A scenario test should be written to show that things work as expected after the upgrade takes place. The goal is to not break things on release.
Releases should be cut from the develop (default) branch on Github.
First increment the spec version in runtime/src/lib.rs.
scripts/build_release.sh m88 # replace with your milestone versionReplace the release in the Dockerfile, using your tag (e.g. here m88):
- RUN scripts/pull_release.sh m16
- RUN chmod +x releases/m16/gateway-linux-x86
+ RUN scripts/pull_release.sh m88
+ RUN chmod +x releases/m88/gateway-linux-x86Note: this is only necessary if you are deploying a new chain, the chain spec is defined at genesis.
$ gateway> chains/build_spec.js -r m88 -c stablenet # replace m88 with your version
Github actions have been created to respond to git tags that are pushed to the repo that begin with m, followed by the spec version, e.g. m88.
This process will create a draft / pre-release that can be modified and published on github once ready.
Create a tag and push to this repo:
$ git tag -a m88 # use your milestone tag
$ git push origin m88Contributors are welcome, and will be held to a high standard. Please consider making an issue to discuss larger changes before making pull requests. All contributions will fall under the license on this repo, which currently does not grant open permission of use. Additionally, you agree that your code will be subject to any license which is later attached to this repository as if it had been initially licensed thusly.