Echidna is a weird creature that eats bugs and is highly electrosensitive (with apologies to Jacob Stanley)
More seriously, Echidna is a Haskell program designed for fuzzing/property-based testing of Ethereum smart contracts. It uses sophisticated grammar-based fuzzing campaigns based on a contract ABI to falsify user-defined predicates or Solidity assertions. We designed Echidna with modularity in mind, so it can be easily extended to include new mutations or test specific contracts in specific cases.
- Generates inputs tailored to your actual code
- Optional corpus collection, mutation and coverage guidance to find deeper bugs
- Powered by Slither to extract useful information before the fuzzing campaign
- Source code integration to identify which lines are covered after the fuzzing campaign
- Interactive terminal UI, text-only or JSON output
- Automatic test case minimization for quick triage
- Seamless integration into the development workflow
- Maximum gas usage reporting of the fuzzing campaign
- Support for a complex contract initialization with Etheno and Truffle
.. and a beautiful high-resolution handcrafted logo.
The core Echidna functionality is an executable called echidna
, which takes a contract and a list
of invariants (properties that should always remain true) as input. For each invariant, it generates
random sequences of calls to the contract and checks if the invariant holds. If it can find some way
to falsify the invariant, it prints the call sequence that does so. If it can't, you have some
assurance the contract is safe.
Invariants are expressed as Solidity functions with names that begin with echidna_
, have no arguments, and return a boolean. For example, if you have some balance
variable that should never go below 20
, you can write an extra function in your contract like this one:
function echidna_check_balance() public returns (bool) {
return(balance >= 20);
}
To check these invariants, run:
$ echidna myContract.sol
An example contract with tests can be found tests/solidity/basic/flags.sol. To run it, you should execute:
$ echidna tests/solidity/basic/flags.sol
Echidna should find a call sequence that falsifies echidna_sometimesfalse
and should be unable to find a falsifying input for echidna_alwaystrue
.
After finishing a campaign, Echidna can save a coverage maximizing corpus in a special directory specified with the corpusDir
config option. This directory will contain two entries: (1) a directory named coverage
with JSON files that can be replayed by Echidna and (2) a plain-text file named covered.txt
, a copy of the source code with coverage annotations.
If you run tests/solidity/basic/flags.sol
example, Echidna will save a few files serialized transactions in the coverage
directory and a covered.$(date +%s).txt
file with the following lines:
*r | function set0(int val) public returns (bool){
* | if (val % 100 == 0)
* | flag0 = false;
}
*r | function set1(int val) public returns (bool){
* | if (val % 10 == 0 && !flag0)
* | flag1 = false;
}
Our tool signals each execution trace in the corpus with the following "line marker":
*
if an execution ended with a STOPr
if an execution ended with a REVERTo
if an execution ended with an out-of-gas errore
if an execution ended with any other error (zero division, assertion failure, etc)
Echidna can test contracts compiled with different smart contract build systems, including Truffle or hardhat using crytic-compile. To invoke echidna with the current compilation framework, use echidna .
.
On top of that, Echidna supports two modes of testing complex contracts. Firstly, one can describe an initialization procedure with Truffle and Etheno and use that as the base state for Echidna. Secondly, Echidna can call into any contract with a known ABI by passing in the corresponding Solidity source in the CLI. Use allContracts: true
in your config to turn this on.
Our Building Secure Smart Contracts repository contains a crash course on Echidna, including examples, lessons and exercises.
There is an Echidna action which can be used to run echidna
as part of a
GitHub Actions workflow. Please refer to the
crytic/echidna-action repository for
usage instructions and examples.
Echidna's CLI can be used to choose the contract to test and load a configuration file.
$ echidna contract.sol --contract TEST --config config.yaml
The configuration file allows users to choose EVM and test generation parameters. An example of a complete and annotated config file with the default options can be found at tests/solidity/basic/default.yaml. More detailed documentation on the configuration options is available in our wiki.
Echidna supports three different output drivers. There is the default text
driver, a json
driver, and a none
driver, which should suppress all
stdout
output. The JSON driver reports the overall campaign as follows.
Campaign = {
"success" : bool,
"error" : string?,
"tests" : [Test],
"seed" : number,
"coverage" : Coverage,
"gas_info" : [GasInfo]
}
Test = {
"contract" : string,
"name" : string,
"status" : string,
"error" : string?,
"testType" : string,
"transactions" : [Transaction]?
}
Transaction = {
"contract" : string,
"function" : string,
"arguments" : [string]?,
"gas" : number,
"gasprice" : number
}
Coverage
is a dict describing certain coverage-increasing calls.
Each GasInfo
entry is a tuple that describes how maximal
gas usage was achieved, and is also not too important. These interfaces are
subject to change to be slightly more user-friendly at a later date. testType
will either be property
or assertion
, and status
always takes on either
fuzzing
, shrinking
, solved
, passed
, or error
.
One way to diagnose Echidna's performance issues is to run echidna
with profiling on.
To run Echidna with basic profiling, add +RTS -p -s
to your original echidna
command:
$ nix develop # alternatively nix-shell
$ cabal --enable-profiling run echidna -- ... +RTS -p -s
$ less echidna.prof
This produces a report file (echidna.prof
), that shows which functions take up the most CPU and memory usage.
If the basic profiling doesn't help, you can use more advanced profiling techniques.
Common causes for performance issues that we observed:
- Costly functions called in hot paths
- Lazy data constructors that accumulate thunks
- Inefficient data structures used in hot paths
Checking for these is a good place to start. If you suspect some comuptation is too lazy and
leaks memory, you can use force
from Control.DeepSeq
to make sure it gets evaluated.
EVM emulation and testing are hard. Echidna has some limitations in the latest release. Some of these are inherited from hevm while some are results from design/performance decisions or simply bugs in our code. We list them here including their corresponding issue and the status ("wont fix", "on hold", "in review", "fixed"). Issues that are "fixed" are expected to be included in the next Echidna release.
Description | Issue | Status |
---|---|---|
Vyper support is limited | #652 | wont fix |
Limited library support for testing | #651 | wont fix |
Before starting, make sure Slither is installed (pip3 install slither-analyzer --user
).
If you want to quickly test Echidna in Linux or MacOS, we provide statically linked Linux binaries built on Ubuntu and mostly static MacOS binaries on our releases page. You can also grab the same type of binaries from our CI pipeline, just click the commit to find binaries for Linux or MacOS.
If you have Homebrew installed on your Mac or Linux machine, you can install Echidna and all of its dependencies (Slither, crytic-compile) by running brew install echidna
.
You can also compile and install the latest master
branch code by running brew install --HEAD echidna
You can get further information in the echidna
Homebrew Formula page. The formula itself is maintained as part of the homebrew-core repository
If you prefer to use a pre-built Docker container, check out our docker
package, which is
auto-built via GitHub Actions. The echidna
container is based on
ubuntu:focal
and it is meant to be a small yet flexible enough image to use
Echidna on. It provides a pre-built version of echidna
, as well as
slither
, crytic-compile
, solc-select
and nvm
under 200 MB.
Note that the container images currently only build on x86 systems. Running them on ARM devices, such as Mac M1 systems, is not recommended due to the performance loss incurred by the CPU emulation.
Different tags are available for the Docker container image:
Tag | Build in tag |
---|---|
vx.y.z |
Build corresponding to release vx.y.z |
latest |
Latest Echidna tagged release. |
edge |
Most recent commit on the default branch. |
testing-foo |
Testing build based on the foo branch. |
To run the container with the latest Echidna version interactively, you can use
something like the following command. It will map the current directory as
/src
inside the container, and give you a shell where you can use
echidna
:
$ docker run --rm -it -v `pwd`:/src ghcr.io/crytic/echidna/echidna
Otherwise, if you want to locally build the latest version of Echidna, we recommend using Docker. From within a clone of this repository, run the following command to build the Docker container image:
$ docker build -t echidna -f docker/Dockerfile --target final-ubuntu .
Then, you can run the echidna
image locally. For example, to install solc
0.5.7 and check tests/solidity/basic/flags.sol
, you can run:
$ docker run -it -v `pwd`:/src echidna bash -c "solc-select install 0.5.7 && solc-select use 0.5.7 && echidna /src/tests/solidity/basic/flags.sol"
If you'd prefer to build from source, use Stack. stack install
should build and compile echidna
in ~/.local/bin
. You will need to link against libreadline and libsecp256k1 (built with recovery enabled), which should be installed with the package manager of your choosing. You also need to install the latest release of libff. Refer to our CI tests for guidance.
Some Linux distributions do not ship static libraries for certain things that Haskell needs, e.g. Arch Linux, which will cause stack build
to fail with linking errors because we use the -static
flag. In that case, use --flag echidna:-static
to produce a dynamically linked binary.
If you're getting errors building related to linking, try tinkering with --extra-include-dirs
and --extra-lib-dirs
.
Nix users can install the latest Echidna with:
$ nix-env -i -f https://github.com/crytic/echidna/tarball/master
With flakes enabled, you can run Echidna straight from this repo:
$ nix run github:crytic/echidna # master
$ nix run github:crytic/echidna/v2.1.1 # specific ref (tag/branch/commit)
To build a standalone release for non-Nix macOS systems, the following will build Echidna in a mostly static binary. This can also be used on Linux systems to produce a fully static binary.
$ nix build .#echidna-redistributable
Nix will automatically install all the dependencies required for development
including crytic-compile
and solc
. A quick way to start developing Echidna:
$ git clone https://github.com/crytic/echidna
$ cd echidna
$ nix develop # alternatively nix-shell
[nix-shell]$ cabal run echidna
[nix-shell]$ cabal run tests
[nix-shell]$ cabal new-repl
This is a partial list of smart contracts projects that use Echidna for testing:
- Curvance
- Primitive
- Uniswap-v3
- Balancer
- MakerDAO vest
- Optimism DAI Bridge
- WETH10
- Yield
- Convexity Protocol
- Aragon Staking
- Centre Token
- Tokencard
- Minimalist USD Stablecoin
The following shows public security reviews that used Echidna to uncover vulnerabilities
- Advanced Blockchain
- Amp
- Ampleforth
- Atlendis
- Balancer
- Basis
- Dai
- Frax
- Liquity
- LooksRare
- Maple
- Optimism
- Opyn
- Origin Dollar
- Origin
- Paxos
- Primitive
- RocketPool
- Seaport
- Set Protocol
- Shell protocol
- Sherlock
- Pegasys Pantheon
- TokenCard
- Uniswap
- Yearn
- Yield
- 88mph
- 0x
The following security vulnerabilities were found by Echidna. If you found a security vulnerability using our tool, please submit a PR with the relevant information.
Project | Vulnerability | Date |
---|---|---|
0x Protocol | If an order cannot be filled, then it cannot be canceled | Oct 2019 |
0x Protocol | If an order can be partially filled with zero, then it can be partially filled with one token | Oct 2019 |
0x Protocol | The cobbdouglas function does not revert when valid input parameters are used | Oct 2019 |
Balancer Core | An attacker cannot steal assets from a public pool | Jan 2020 |
Balancer Core | An attacker cannot generate free pool tokens with joinPool | Jan 2020 |
Balancer Core | Calling joinPool-exitPool does not lead to free pool tokens | Jan 2020 |
Balancer Core | Calling exitswapExternAmountOut does not lead to free assets | Jan 2020 |
Liquity Dollar | Closing troves require to hold the full amount of LUSD minted | Dec 2020 |
Liquity Dollar | Troves can be improperly removed | Dec 2020 |
Liquity Dollar | Initial redeem can revert unexpectedly | Dec 2020 |
Liquity Dollar | Redeem without redemptions might still return success | Dec 2020 |
Origin Dollar | Users are allowed to transfer more tokens that they have | Nov 2020 |
Origin Dollar | User balances can be larger than total supply | Nov 2020 |
Yield Protocol | Arithmetic computation for buying and selling tokens is imprecise | Aug 2020 |
We can also use Echidna to reproduce research examples from smart contract fuzzing papers to show how quickly it can find the solution. All of these can be solved, in a few seconds to one or two minutes on a laptop computer.
Paper Title | Venue | Publication Date |
---|---|---|
echidna-parade: Diverse multicore smart contract fuzzing | ISSTA 2021 | July 2021 |
Echidna: Effective, usable, and fast fuzzing for smart contracts | ISSTA 2020 | July 2020 |
Echidna: A Practical Smart Contract Fuzzer | FC 2020 | Feb 2020 |
If you are using Echidna for academic work, consider applying to the Crytic $10k Research Prize.
Feel free to stop by our #ethereum slack channel in Empire Hacking for help using or extending Echidna.
-
Get started by reviewing these simple Echidna invariants
-
Considering emailing the Echidna development team directly for more detailed questions
Echidna is licensed and distributed under the AGPLv3 license.