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Aave StarkNet Bridge

Tests Check License: MIT

This codebase has been audited by three teams, whose reports are available in the repository: Nethermind, Peckshield and Certora.

Table of contents

Introduction

This bridge project is the first step of Aave in StarkNet ecosystem. The bridge allows users to deposit or withdraw their aTokens, and only aTokens, on Ethereum side, then mints or burns them wrapped aTokens named static_a_tokens on StarkNet side. static_a_tokens are equivalent to aTokens except that the former grow in value when the latter grow in balance.

Holding L1 aTokens lets you earn more tokens via two different mechanisms: (i) the amount of aTokens you hold increases over time and (ii) holding aTokens allows you to claim an accruing amount of Aave reward tokens. This bridge offers both mechanisms thanks to static_a_tokens on L2, and the equivalent of L1 Aave reward token on L2.

The bridge is also shaped for liquidity providers who are able to assume the Ethereum gas cost of deposits and withdrawals as they transact large enough amounts. They will deposit on Aave Ethereum, bridge the static_a_tokens to StarkNet and make them available for users there to buy and hold, thus accruing yield from L1.

We assume that L1 tokens approved by the bridge are pre-validated tokens, and that they are not deflationary.

Architecture

aave_bridge

Contracts

Overview

L1

  • Bridge - handles deposit of aTokens on L1, withdrawal of static_a_tokens from L2, and update of L2 rewards index. L1 deposits and withdrawals can be done with aToken or with their underlying asset.

L2

  • static_a_token - exchange-rate-increasing wrapper of aTokens on L2.
  • incentivized_erc20 - ERC20-compliant token, tracks claimable rewards and stores the last updated rewards index for each static_a_token holder.
  • rewAAVE - ERC20 representing Aave reward token on L2.
  • bridge - bridge responsible for:
    • minting and burning static_a_tokens on message from L1.
    • bridging rewAAVE tokens back to L1.
    • updating rewards_index for each static_a_token on message from L1.
  • proxy - generic implementation of a proxy in cairo.

More about static_a_token on L2

These static_a_tokens are a starting point for almost any cross-chain liquidity development to minimize “active” communication between chains. By design, a holder of those tokens - on Ethereum or after bridging somewhere else - will be passively accumulating yield from Aave on Ethereum.

More precisely, static_a_tokens are wrapped aTokens that grow in value while aTokens grow in balance. Such behavior is possible because static_a_tokens are backed by increasing amounts of aTokens locked in the L1 part of the bridge. static_a_tokens living on L2 can be bridged back to aTokens.

Proxies

Each of the following contracts is deployed behind a proxy:

  • bridge on L2
  • static_a_token on L2
  • rewAAVE token on L2
  • Bridge on L1

Governance

Control

  • static_a_token deployed contracts are controlled by L2 bridge.
  • rewAAVE token is controlled by L2 bridge.

Governance relayers

  • We rely on L1 -> L2 governance relayers to execute on L2 actions that have been decided on L1. In practice, we use two L1 contracts from Aave and one L2 contract from StarkNet DAI Bridge:
    • contracts/l1/governance/Executor.sol: It corresponds to Aave Short Executor whose goal is to execute payload that have been previously accepted by the DAO after a vote. One first need to queue the transaction to execute, and execute it after waiting enough time. Its code has been taken from Etherscan: link.
    • contracts/l1/governance/CrosschainForwarderStarknet.sol: It contains a single function named execute that sends a message to execute a function relay of the contract l2_governance_relay with an input address. It has been adapted from the one used for Polygon.
    • contracts/l2/governance/l2_governance_relay.cairo: It contains a single L1 handler named relay as well that takes an address as argument, checks the origin of the call and executes the function delegate_execute of the contract that correspond to the input address.

Deployed Contracts

Mainnet

Ethereum

StarkNet

Goerli

Ethereum

StarkNet

How it works

Bridging aTokens from L1 to L2

Approve bridge tokens

L1 aTokens and their corresponding L2 static_a_tokens are approved on L1 bridge in initialize function. The function _approveBridgeTokens is called internally to approve an array of aTokens with their corresponding static_a_tokens on L2.

Transfer from L1 to L2

Users can either deposit their aTokens (let's say aDai) or deposit the corresponding underlying asset (i.e Dai). Users first have to approve the bridge to spend the tokens - aTokens or the underlying asset. Calling deposit function, the following actions happen:

  • If the user deposits underlying asset:

    1. asset tokens will be transferred from the user account to L1 bridge.
    2. The bridge will convert asset tokens to aTokens - by depositing in Aave's lending pool.
    3. A message will be sent to L2 bridge with the amount of static_a_token to be minted, L1 token address, L2 recipient address, L1 block number and L1 rewards index.
    4. L2 bridge will mint to L2 recipient the given amount of corresponding static_a_tokens.  
  • If the user deposits aToken:

    1. aTokens will be transferred from the user account to L1 bridge.
    2. A message will be sent to L2 bridge with the amount of static_a_token to be minted, L1 token address, L2 recipient address, L1 block number and L1 rewards index.
    3. L2 bridge will mint to L2 recipient the given amount of corresponding static_a_tokens.

Transfer from L2 to L1

To bridge their static_a_tokens back to L1, users should first initiate a withdrawal on the L2 bridge. Calling initiate_withdraw results in the following:

  1. The amount of static_a_tokens to withdraw will be burned by L2 bridge.
  2. A message will be sent to L1 with L1 aToken address, L1 recipient, L2 rewards index and the amount.

Once the withdrawal is initiated on the L2 bridge, one can call the function withdraw on L1 bridge. Calling this function results in the following:

  1. The message previously sent will be consumed: if function parameters and parameters sent in the message are not the same, the withdrawal fails, otherwise the rest follows.
  2. L1 bridge will then transfer aTokens to the L1 recipient.
  3. L1 bridge will also check for any difference in the L1/L2 rewards index and transfer any unclaimed rewards to L1 recipient.

Synchronisation of rewards index on L1 and L2

StarkNet users will keep enjoying the same rewards as on L1 after bridging their assets. To do so, L1 rewards index is stored in the state of static_a_tokens. The index is updated every time a user deposits or withdraw the corresponding aToken, and can also be updated in a permissionless manner by calling the function updateL2State in L1 bridge. Rewards on L1 are sent to L1 recipient either when withdrawing static_a_tokens from L2 or when calling and then bridging rewards on L2 as described below.

Claiming rewards on L2

To claim rewards, an L2 user should call claim_rewards on static_a_token contract which calls L2 bridge in return. L2 bridge then mints due rewAAVE tokens to the L2 user.

Bridging rewards from L2 to L1

Calling bridge_rewards on L2 token bridge results in:

  1. The bridged amount of rewAAVE tokens will be burned.
  2. L1 bridge receives the bridging message and claims the rewards amount to self by calling claimRewards on Aave IncentivesController contract.
  3. Rewards are then transferred to L1 recipient.

ATokens deposit cancellation

If L1 -> L2 message consumption is unsuccessful, the user would lose custody over his aTokens forever.

That's why we have added support for the L1->L2 message cancellation on our L1 bridge contract, where users can cancel deposits of their aTokens by following the steps below:

  1. The user calls startDepositCancellation on L1 bridge by providing the message payload and nonce of the deposit message.

  2. After the messageCancellationDelay period has passed (defined on StarknetMessaging contract), the user can finalize the aTokens deposit cancellation by calling cancelDeposit on L1 bridge.

Bridge Ceiling

The amount of bridged aTokens is restricted to a certain amount set at the moment of deployment. We provide an array ceilings with a ceiling for each aToken to be approved on the L1 bridge, and we make sure that the bridge will only hold a scaled balance (without taking into account the interest growth) inferior or equal to the decided ceiling for each aToken.

How to bridge without coding

This section explains how to bridge Ethereum aTokens to StarkNet staticATokens using Etherscan UI and wallets on both networks.

1. Hold tokens that can be bridged

The first step is to have an Ethereum-compatible wallet funded with one of the six following tokens: DAI, aDAI, USDC, aUSDC, USDT or aUSDT.

2. Get tokens' balance

You should now select the amount you would like to bridge. Note that the tokens above do not have the same number of decimals. For this, go on the Etherscan page corresponding to your tokens, say DAI for instance, click on the tab "Read Contract" or "Read as Proxy" and call the function balanceOf with your wallet address.

If you hold $50 of DAI / aDAI, the output of balanceOf should be approximately 50000000000000000000, and if you hold $50 of USDC / aUSDC / USDT / aUSDT, it should be about 50000000.

3. Let the bridge transfer your tokens

Before depositing your tokens to the bridge, you should allow the bridge to spend your tokens. To do so, go on the token's Etherscan page, click on the tab "Write Contract" or "Write as Proxy", and then on "Connect to Web3" to connect your Ethereum wallet to Etherscan. Now, click on the function approve, and fill in the bridge's address (0x25c0667E46a704AfCF5305B0A586CC24c171E94D) as spender and the amount you would like to bridge as amount. Finally, click "Write" and accept the transaction on your wallet.

4. Deposit your tokens to the bridge

To deposit tokens to the bridge, go on the bridge contract Etherscan page here. If your wallet is disconnected, click on "Connect to Web3" again, and click on the deposit function to display its arguments. You should then enter the following inputs:

  • l1AToken: Fill in the address of the token you would like to bridge. For DAI, write 0x6B175474E89094C44Da98b954EedeAC495271d0F.
  • l2Recipient: Fill in your StarkNet wallet address, converted to decimal. For that, you can use this website, or use BigInt function in JavaScript. For instance, if the StarkNet wallet address is 0x01270059Ea5843794F1130830800EcEF60B7D1AFd195f1847a884223a5B94f4A, you should fill in 521222308224262530654458833061745344984501837223744122628617462097842360138.
  • amount: Fill in the amount you would like to bridge. This amount should be lower or equal to the amount you have approved in the previous step.
  • referralCode: Fill in 0. This argument is proper to identify future integrators.
  • fromUnderlyingAsset: Fill in false if the token you bridge is an aToken (aDAI, aUSDC, aUSDT); otherwise, fill in true.

Finally, click on "Write", accept the transaction and wait for Ethereum and StarkNet transactions to finish.

5. Import token to your StarkNet wallet

On your StarkNet wallet, click on "+ New token" for Argent X or "+ Add token" for Braavos, and fill in staticAToken's address that corresponds to tokens you have deposited on the Ethereum side - see this section for deployed contracts' addresses.

Installation

Environment

Install Node 16

Our codebase relies on Node 16. To install it, you can first install nvm and then run the following commands:

nvm install 16
nvm use 16

Install Python 3.9.0

Our codebase relies on Python 3.9.0. To install it, you can first install pyenv and then run the following commands:

pyenv install 3.9.0
pyenv local 3.9.0

Install GMP (needed for Cairo)

Before installing Cairo you need to install GMP. Run one of the following command depending on your OS.

sudo apt install -y libgmp3-dev # linux
brew install gmp # mac

Install Node dependencies

Let's install all our project dependencies:

yarn install

Install Python dependencies

Let’s create a virtual environment to isolate your project’s requirements from your global Python environment.

python -m venv .venv
source .venv/bin/activate

Install poetry for dependencies management

python -m pip install --upgrade pip
pip install poetry
poetry install

Build Cairo files

Solidity files are automatically compiled before running the tests, but Cairo files are not. To compile them, run:

yarn compile:l2

Start testnets

We recommend to run L1 and L2 testnets in different terminals.

Start L2 testnet

In a terminal where venv is activated, run:

yarn testnet:l2

Start L1 testnet

Create a .env file from the sample (cp .env.sample .env), and fill a value for the variable ALCHEMY KEY - you can get one here. Then, load all the environment variables.

source .env

And start L1 testnet in the same terminal by running:

yarn testnet:l1

Run tests

The project is tested using hardhat, the starknet hardhat plugin and starknet-devnet. We created a Docker Compose file to run tests easily: we start L1 and L2 test networks in two separate containers and run the tests from a third one. To run all tests, simply run the following commands:

docker compose up --build
docker exec -ti $(docker ps -f name=test-runner -q) bash
yarn test

Deployment

First make sure to set the aTokens addresses to be approved on the bridge as well as the metadata related to the staticATokens to be deployed on l2 in ./scripts/allowlistedTokens.ts.

yarn deploy-bridge:testnet #deploys bridge on l1 & l2 testnets

Contributors