This repository contains the set of Cairo (Cairo compiler version Zero) programs that implement the core EVM logic of Kakarot zkEVM.
Kakarot is an EVM implementation in Cairo. Cairo being a high-level zero-knowledge domain specific language (zkDSL), Kakarot is provable by design. This allows for proving the execution of EVM transactions, and makes Kakarot a de facto so-called zkEVM.
While some zkEVM implementations (see for example Scroll or Taiko) tries to prove existing EVM implementations (mainly Geth), Kakarot is like another new Geth, but provable by design, simply because it runs on the CairoVM.
We strongly believe the CairoVM will provide the best zero-knowledge toolbox in the coming years and that the Ethereum network effect will remain prevalent. We present to developers an abstraction layer they're familiar with: the EVM. Build and deploy as if you were working on Ethereum, be forward compatible with the future of zero-knowledge.
Kakarot is a work in progress, and it is not ready for production.
Kakarot presentations and talks around the world
Getting started β’ Build β’ Test β’ Report a bug
We support 100% of EVM opcodes and 6 out of 9 precompiles.
Here is a high-level architecture diagram of the entire Kakarot zkEVM system.
The set of Cairo programs in this repository are represented below:
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β Kakarot Core EVM is a set of Cairo programs
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β Kakarot can be packaged as a smart contract and deployed on any chain that runs the CairoVM (StarknetOS chains, Starknet Appchains, Starknet clients).
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β Kakarot is an EVM implementation.
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β οΈ Kakarot Core EVM (the Cairo programs in this repository) is not a blockchain by itself. Combined with an underlying CairoVM chain, an RPC layer, it forms an Ethereum-compatible L2 network. -
β Kakarot is not a compiler.
To contribute and setup your development environment, please check out the contribution guide.
The project uses uv to manage python dependencies and run commands. To install uv:
curl -LsSf https://astral.sh/uv/install.sh | shTo setup the project and install all dependencies:
make setupTo build the CairoZero files:
make buildTo build the test Solidity smart contracts:
# install foundry if you don't have it already
# curl -L https://foundry.paradigm.xyz | bash
# foundryup
make build-solThe project uses trunk.io to run a comprehensive list of linters.
To install Trunk, run:
curl https://get.trunk.io -fsSL | bashYou can also add Trunk to VSCode with this extension.
Then, don't forget to select Trunk as your default formatter in VSCode (command palette > Format Document With > Trunk).
Once Trunk is installed, you can install a pre-push hook to run the linters before each push:
trunk git-hooks syncKakarot tests uses pytest as test runner. Make sure to read the doc and get familiar with the tool to benefit from all of its features.
# Runs a local CairoVM client (or StarknetOS chain)
make run-nodes
# Run all tests. This requires a Katana instance and an Anvil instance running in the background: `make run-nodes`
make test
# Run only unit tests
make test-unit
# Run only e2e tests
make test-end-to-end
# Run a specific test file
pytest <PATH_TO_FILE>
# Run a specific test mark (markers in pyproject.toml)
pytest -m <MARK>Test architecture is the following:
- tests/src contains cairo tests for each cairo function in the kakarot codebase running either in plain cairo or with the starknet test runner;
- tests/end_to_end contains end-to-end tests running on an underlying Starknet-like network (using the Starknet RPC), currently Katana. These end-to-end tests contain both raw bytecode execution tests and test on real solidity contracts.
The difference between the starknet test runner (when using contracts) and the plain cairo one is that the former emulate a whole starknet network and is as such much slower (~10x).
Consequently, when writing tests, don't use contracts unless it's really required. Actually, for tests requiring a Starknet devnet, prefer end-to-end relying only on a RPC endpoint and currently running on Katana.
For an example of the cairo test runner, see for example the RLP library tests. Especially, the cairo runner uses hints to communicate values and return outputs:
kwargsofcairo_runare available in theprogram_inputvariable- values written in the
output_ptrsegment are returned, e.g.segments.write_arg(output_ptr, [ids.x])will return the list[x].
Both cairo and starknet tests can be used with the --profile-cairo flag to
generate a profiling file (see the --profile_output flag of the cairo-run
CLI). The file can then be used with pprof, for example:
go tool pprof --png <path_to_file.pb.gz>The project also contains a regular forge project (./solidity_contracts) to
generate real artifacts to be tested against. This project also contains some
forge tests (e.g. PlainOpcodes.t.sol) which purpose is to test easily the
solidity functions meant to be tested with kakarot, i.e. quickly making sure
that they return the expected output so that we know that we focus on kakarot
testing and not .sol testing. They are not part of the CI. Simply use
forge test to run them.
To run the Ethereum Foundation test suite, you need to pull locally the Kakarot ef-tests runner. To simplify the devX, you can create symlinks in the ef-tests repo pointing to your local changes. For example:
ln -s /Users/clementwalter/Documents/kkrt-labs/kakarot/blockchain-tests-skip.yml blockchain-tests-skip.yml
mkdir build && cd build
ln -s /Users/clementwalter/Documents/kkrt-labs/kakarot/build/ v0
ln -s /Users/clementwalter/Documents/kkrt-labs/kakarot/build/fixtures/ commonWith this setting, you can run a given EF test against your local Kakarot build by running (in the ef test directory):
cargo test <test_name> --features v0 -- --nocapture
# e.g. cargo test test_sha3_d7g0v0_Cancun --features v0 -- --nocaptureSee this doc to learn how to debug a cairo trace when the CairoVM reverts.
The following describes how to deploy the Kakarot as a Starknet smart contract on an underlying StarknetOS network.
It is not a description on how to deploy a solidity contract on the Kakarot EVM.
The deploy script relies on some env
variables defined in a .env file located at the root of the project and loaded
in the constant file. To get started, just
cp .env.example .envThe default file is self sufficient for using Kakarot with KATANA. If targeting other networks, make sure to fill the corresponding variables.
Furthermore, if you want to run the check-resources locally to check the steps usage of your local changes in the EF tests against main and other branches, you need to fill the following
GITHUB_TOKEN=your_github_token
You can learn how to create this token from here, we would suggest using a fine-grained token with only read access.
By default, everything will run on a local katana (started with
make run-katana). If you want to deploy to a given target, set the
STARKNET_NETWORK env variable, for example:
make deploy # localhost
STARKNET_NETWORK=testnet make deploy
STARKNET_NETWORK=mainnet make deployDeployed contract addresses will be stored in
./deployments/{networks}/deployments.json.
A step by step description of the individual components and how they are deployed/configured can be found here.
To run slither against provided Kakarot solidity contracts, you need to install slither and run:
forge build --build-info --force
slither . --foundry-out-directory solidity_contracts/build --ignore-compile --include-paths "DualVmToken.sol|L1KakarotMessaging.sol|L2KakarotMessaging.sol" --checklist > report.mdkakarot is released under the MIT.
Kakarot follows good practices of security, but 100% security cannot be assured. Kakarot is provided "as is" without any warranty. Use at your own risk.
For more information and to report security issues, please refer to our security documentation.
First off, thanks for taking the time to contribute! Contributions are what make the open-source community such an amazing place to learn, inspire, and create. Any contributions you make will benefit everybody else and are greatly appreciated.
Please read our contribution guidelines, and thank you for being involved!
