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dapp

Dapp Chat

dapp is a tool for building, testing and deploying smart contracts from the comfort of the command line.

As opposed to other tools, it does not use rpc to execute transactions. Instead, it invokes the hevm cli directly. This is faster, and allows for a lot of flexibility that isn't available in rpc, such as fuzz testing, symbolic execution, or cheat codes to modify mainnet state.

Table of Contents

Installing

dapp is distributed as part of the Dapp tools suite.

Basic usage: a tutorial

Let's create a new dapp project. We make a new directory and initialize the dapp skeleton structure:

mkdir dapptutorial
cd dapptutorial
dapp init

This creates two contracts, Dapptutorial.sol and Dapptutorial.t.sol in the src subdirectory and installs our testing library ds-test in the lib subdirectory.

Dapptutorial.t.sol is a testing contract with two trivial tests, which we can run with dapp test.

Building

For the sake of this tutorial, let's change Dapptutorial.sol to a simple vault with an eth bounty that can be accessed by giving the password 42:

pragma solidity ^0.8.6;

contract Dapptutorial {
    receive() external payable {
    }

    function withdraw(uint password) public {
        require(password == 42, "Access denied!");
        payable(msg.sender).transfer(address(this).balance);
    }
}

Compile the contract by running dapp build. If you didn't make any mistakes, you should simply see:

+ dapp clean
+ rm -rf out

Unit testing

Let's write some tests for our vault. Change Dapptutorial.t.sol to the following. We'll go over whats going on in the next paragraph.

import {DSTest} from "ds-test/test.sol";
import {Dapptutorial} from "./Dapptutorial.sol";

contract DapptutorialTest is DSTest {
    Dapptutorial dapptutorial;

    function setUp() public {
        dapptutorial = new Dapptutorial();
    }

    function test_withdraw() public {
        payable(address(dapptutorial)).transfer(1 ether);
        uint preBalance = address(this).balance;
        dapptutorial.withdraw(42);
        uint postBalance = address(this).balance;
        assertEq(preBalance + 1 ether, postBalance);
    }

    function testFail_withdraw_wrong_pass() public {
        payable(address(dapptutorial)).transfer(1 ether);
        uint preBalance = address(this).balance;
        dapptutorial.withdraw(1);
        uint postBalance = address(this).balance;
        assertEq(preBalance + 1 ether, postBalance);
    }

    // allow sending eth to the test contract
    receive() external payable {}
}

In the setUp() function, we are deploying the Dapptutorial contract. All following tests are run against the poststate of the setUp() function. The test_withdraw function first deposits 1 eth and then withdraws it, by giving the correct password. We check that the call was successful by comparing the pre and post balance of the testing account using assertEq. You can try changing the right hand side to postBalance + 1 and see what happens. Finally, we are testing the case where the wrong password is given in testFail_withdraw_wrong_pass. Any function prefixed with testFail is expected to fail, either with a revert or by violating an assertion. Finally, since a successful call to withdraw sends eth to the testing contract, we have to remember to implement a receive function in it.

For more debugging information, run dapp test with the -v flag to print the calltrace for failing tests, or enter the interactive debugger by running dapp debug.

Property based testing

Now let's try something more interesting - property based testing and symbolically executed tests.

We can generailize our test_withdraw function to not use the hardcoded 1 ether, but instead take the value as a parameter:

function test_withdraw(uint amount) public {
    payable(address(dapptutorial)).transfer(amount);
    uint preBalance = address(this).balance;
    dapptutorial.withdraw(42);
    uint postBalance = address(this).balance;
    assertEq(preBalance + amount, postBalance);
}

A test that takes at least one parameters is interpreted as a "property based test", or "fuzz test", and will be run multiple times with different values given to the parameters. The number of times each test is run can be configured by the --fuzz-runs flag and defaults to 100.

Running this test with dapp test -v, we see that this test actually fails with error BalanceTooLow for very high values of amount.

By default, the testing contract is given a balance of 2**96 wei, so we have to restrict the type of amount to uint96 to make sure we don't try to transfer more than we have:

function test_withdraw(uint96 amount) public {
    payable(address(dapptutorial)).transfer(amount);
    uint preBalance = address(this).balance;
    dapptutorial.withdraw(42);
    uint postBalance = address(this).balance;
    assertEq(preBalance + amount, postBalance);
}

If a counterexample is found, it can be replayed or analyzed in the debugger using the --replay flag.

Symbolically executed tests

While property based testing runs each function repeatedly with new input values, symbolic execution leaves these values symbolic and tries to explore each possible execution path. This gives a stronger guarantee and is more powerful than property based testing, but is also more difficult, especially for complicated functions.

Continuing with our vault example, imagine that we forgot the password and did not have the source available. We can symbolically explore all possibilities to find the one that lets us withdraw by writing a proveFail test:

function proveFail_withdraw(uint guess) public {
    payable(address(dapptutorial)).transfer(1 ether);
    uint preBalance = address(this).balance;
    dapptutorial.withdraw(guess);
    uint postBalance = address(this).balance;
    assertEq(preBalance + 1 ether, postBalance);
}

When we run this with dapp test, we are given a counterexample:

Failure: proveFail_withdraw(uint256)

  Counterexample:

    result:   Successful execution
    calldata: proveFail_withdraw(42)

which demonstrates that if we give the password 42, it is possible to withdraw from the vault.

The symbolic execution engine is backed by an SMT solver. When symbolically executing more complex tests you may encounter test failures with an SMT Query Timeout message. In this case, consider increasing the smt timeout using the --smttimeout flag or DAPP_TEST_SMTTIMEOUT environment variable (the default timeout is 60000 ms). Note that this timeout is per smt query not per test, and that each test may execute multiple queries (at least one query for each potential path through the test method).

For more reading on property based testing and symbolic execution, see this tutorial on the Ethereum Foundation blog.

Invariant testing

While other forms of tests are always run against the post state of the setUp() function in the testing contract, it can be also be useful to check whether a property is satisfied at every possible contract state. This can be done with the invariant* testing type. When running an invariant test, hevm will invoke any state mutating function from all addresses returned by a call to targetContracts(), if such a function exists in the testing contracts. If no such method exists, it will invoke methods from any non-testing contract available after the setUp() function has been run, checking the invariant* after each run.

The --depth parameter determines how many transactions deep each test will run, while the --fuzz-runs parameter determines how many times the whole process is repeated.

Note that a revert in any of the randomly generated call will not trigger a test failure. The goal of invariant tests is to find a state change that results in a violation of the assertions defined in the body of the test method, and since reverts do not result in a state change, they can be safely ignored. Reverts within the body of the invariant* test method will however still cause a test failure.

Example:

function invariant_totalSupply() public {
    assertEq(token.totalSupply(), initialTotalSupply);
}

If a counterexample is found, it can be replayed or analyzed in the debugger using the --replay flag.

SMTChecker testing

If you are using the standard JSON input mode and its field settings.modelChecker.engine is all, bmc or chc, Solidity's SMTChecker will be invoked when you run dapp build. If you wish to use that mode, these steps are recommended:

  • Run the usual compilation
  • Generate a separate input JSON with the SMTChecker enabled: export DAPP_SMTCHECKER=1 && dapp mk-standard-json &> dapp_smtchecker.json
  • Modify settings.modelChecker in the new JSON input accordingly. It is recommended that you use the contracts field settings.modelChecker.contracts to specify the main contracts you want to verify.
  • Tell dapp to use the new JSON as input: export DAPP_STANDARD_JSON=./dapp_smtchecker.json
  • Run dapp build

You may also want to change the settings.modelChecker.timeout and/or other fields in different runs.

Testing against RPC state

You can test how your contract interacts with already deployed contracts by letting the testing state be fetched from rpc with the --rpc flag.

Running dapp test with the --rpc flag enabled will cause every state fetching operation (such as SLOAD, EXTCODESIZE, CALL*, etc.) to request the state from $ETH_RPC_URL.

For example, if you want to try out wrapping ETH you could define WETH in the setUp() function:

import "ds-test/test.sol";

interface WETH {
    function balanceOf(address) external returns (uint);
    function deposit() external payable;
}

contract WethTest is DSTest {
    WETH weth;
    function setUp() public {
        weth = WETH(0xC02aaA39b223FE8D0A0e5C4F27eAD9083C756Cc2);
    }

    function testWrap() public {
        assertEq(weth.balanceOf(address(this)), 0);
        weth.deposit{value :1 ether}();
        assertEq(weth.balanceOf(address(this)), 1 ether);
    }
}

With ETH_RPC_URL set, you can run dapp test --rpc on this test or dapp debug --rpc to step through the testWrap function in the interactive debugger.

It is often useful to modify the state for testing purposes, for example to grant the testing contract with a balance of a particular token. This can be done using hevm cheat codes.

Deployment

To deploy a contract, you can use dapp create:

dapp create Dapptutorial [<constructorArgs>] [<options>]

The --verify flag verifies the contract on etherscan (requires ETHERSCAN_API_KEY).

Configuration

The commands of dapp can be customized with environment variables or flags. These variables can be set at the prompt or in a .dapprc file.

Below is a list of the environment variables recognized by dapp. You can additionally control various block parameters when running unit tests by using the hevm specific environment variables.

Variable Default Synopsis
DAPP_SRC src Directory for the project's Solidity contracts
DAPP_LIB lib Directory for installed Dapp packages
DAPP_OUT out Directory for compilation artifacts
DAPP_ROOT . Root directory of compilation
DAPP_SOLC_VERSION 0.8.6 Solidity compiler version to use
DAPP_SOLC n/a solc binary to use
DAPP_LIBRARIES automatically deployed Library addresses to link to
DAPP_SKIP_BUILD n/a Avoid compiling this time
DAPP_COVERAGE n/a Print coverage data
DAPP_LINK_TEST_LIBRARIES 1 when testing; else 0 Compile with libraries
DAPP_VERIFY_CONTRACT yes Attempt Etherscan verification
DAPP_ASYNC n/a Set to yes to skip waiting for etherscan verification to succeed
DAPP_STANDARD_JSON $(dapp mk-standard-json) Solidity compilation options
DAPP_SMTCHECKER n/a Set to 1 to output the default model checker settings when using dapp mk-standard-json. Running dapp build will invoke the SMTChecker.
DAPP_REMAPPINGS $(dapp remappings) Solidity remappings
DAPP_BUILD_OPTIMIZE 0 Activate Solidity optimizer (0 or 1)
DAPP_BUILD_OPTIMIZE_RUNS 200 Set the optimizer runs
DAPP_VIA_IR 0 Change compilation pipeline to go through the Yul intermediate representation (0 or 1)
DAPP_TEST_MATCH n/a Only run test methods matching a regex
DAPP_TEST_VERBOSITY 0 Sets how much detail dapp test logs. Verbosity 1 shows traces for failing tests, 2 shows logs for all tests, 3 shows traces for all tests
DAPP_TEST_FFI 0 Allow use of the ffi cheatcode in tests (0 or 1)
DAPP_TEST_FUZZ_RUNS 200 How many iterations to use for each property test in your project
DAPP_TEST_DEPTH 20 Number of transactions to sequence per invariant cycle
DAPP_TEST_SMTTIMEOUT 60000 Timeout passed to the smt solver for symbolic tests (in ms, and per smt query)
DAPP_TEST_MAX_ITERATIONS n/a The number of times hevm will revisit a particular branching point when symbolically executing
DAPP_TEST_SOLVER z3 Solver to use for symbolic execution (cvc4 or z3)
DAPP_TEST_MATCH n/a Regex used to determine test methods to run
DAPP_TEST_COV_MATCH n/a Regex used to determine which files to print coverage reports for. Prints all imported files by default (excluding tests and libs).
DAPP_TEST_REPLAY n/a Calldata for a specific property test case to replay in the debugger
HEVM_RPC n/a Set to yes to have hevm fetch state from rpc when running unit tests
ETH_RPC_URL n/a The url of the rpc server that should be used for any rpc calls
DAPP_TESTNET_RPC_PORT 8545 Which port to expose the rpc server on when running dapp testnet
DAPP_TESTNET_RPC_ADDRESS 127.0.0.1 Which ip address to bind the rpc server to when running dapp testnet
DAPP_TESTNET_CHAINID 99 Which chain id to use when running dapp testnet
DAPP_TESTNET_PERIOD 0 Blocktime to use for dapp testnet. 0 means blocks are produced instantly as soon as a transaction is received
DAPP_TESTNET_ACCOUNTS 0 How many extra accounts to create when running dapp testnet (At least one is always created)
DAPP_TESTNET_gethdir $HOME/.dapp/testnet Root directory that should be used for dapp testnet data
DAPP_TESTNET_SAVE n/a Name of the subdirectory under ${DAPP_TESTNET_gethdir}/snapshots where the chain data from the current dapp testnet invocation should be saved
DAPP_TESTNET_LOAD n/a Name of the subdirectory under ${DAPP_TESTNET_gethdir}/snapshots from which dapp testnet chain data should be loaded
DAPP_BUILD_EXTRACT n/a Set to a non null value to output .abi, .bin and .bin-runtime when using dapp build. Uses legacy build mode
DAPP_BUILD_LEGACY n/a Set to a non null value to compile using the --combined-json flag. This is provided for compatibility with older workflows

A global (always loaded) config file is located in ~/.dapprc. A local .dapprc can also be defined in your project's root, which overrides variables in the global config.

Whenever you run a dapp command the .dapprc files are sourced in order (global first, then the one in the current working directory, if it exists). If you wish to set configuration variables, you must use export as below:

export DAPP_SOLC_VERSION=0.8.6
export DAPP_REMAPPINGS=$(cat remappings.txt)
export DAPP_BUILD_OPTIMIZE=1
export DAPP_BUILD_OPTIMIZE_RUNS=1000000000
export DAPP_TEST_VERBOSITY=1

Under the hood .dapprc is interpreted as a shell script, which means you can add additional scripting logic which will be run whenever you use dapp. For example if you wanted to fuzz for many iterations in CI and only a few locally you could add this to your .dapprc:

if [ "$CI" == "true" ]
then
  export DAPP_TEST_FUZZ_RUNS=1000000 # In CI we want to fuzz for a long time.
else
  export DAPP_TEST_FUZZ_RUNS=1000 # When developing locally we only want to fuzz briefly.
fi

Precedence

There are multiple places to specify configuration options. They are read with the following precedence:

  1. command line flags
  2. local .dapprc
  3. global .dapprc
  4. locally set environment variables

solc version

You can specify a custom solc version to run within dapp with dapp --use <arg>. If the argument is of the form solc:x.y.z, the appropriate solc version will temporarily installed. If the argument contains a /, it is interpreted as a path to a solc binary to be used.

You may also specify a solc version using the DAPP_SOLC_VERSION environment variable, which is equivalent to running dapp --use solc:${DAPP_SOLC_VERSION} manually.

You can install any supported solc "standalone" (i.e. add it to your $PATH) with:

nix-env -iA solc-static-versions.solc_x_y_z \
  -if https://github.com/dapphub/dapptools/tarball/master

For a list of the supported solc versions, check solc-static-versions.nix.

Commands

dapp init

dapp-init -- bootstrap a new dapp
Usage: dapp init

Initializes the current directory to the default dapp structure, installing ds-test and creating two boilerplate contracts in the src directory.

dapp build

dapp-build -- compile the source code
Usage: dapp build [--extract]

--extract:  After building, write the .abi, .bin and .bin-runtime. Implies `--legacy`
    files from the solc json into $DAPP_OUT. Beware of contract
    name collisions. This is provided for compatibility with older
    workflows.
--optimize: activate the solidity optimizer.
--via-ir: change compilation pipeline to go through the Yul intermediate representation
--legacy:   Compile using the `--combined-json` flag. Some options are
    missing from this format. This is provided for compatibility with older
    workflows.

Compiles the contracts in the src directory. The compiler options of the build are generated by the dapp mk-standard-json command, which infers most options from the project structure. For more customizability, you can define your own configuration json by setting the file to the environment variable DAPP_STANDARD_JSON.

By default, dapp build uses dapp remappings to resolve Solidity import paths.

You can override this with the DAPP_REMAPPINGS environment variable.

dapp test

Usage: dapp test [<options>]

Options:
    -v, --verbose             trace output for failing tests
    --coverage                print coverage data
    --verbosity <number>      sets the verbosity to <number>
    --depth=<number>          number of transactions to sequence per invariant cycle
    --fuzz-runs <number>      number of times to run fuzzing tests
    --replay <string>         rerun a particular test case
    -m, --match <string>      only run test methods matching regex
    --cov-match <string>      only print coverage for files matching regex

RPC options:
    --rpc                     fetch remote state via ETH_RPC_URL
    --rpc-url <url>           fetch remote state via <url>
    --rpc-block <number>      block number (latest if not specified)

SMT options:
    --smttimeout <number>     timeout passed to the smt solver in ms (default 60000)
    --solver <string>         name of the smt solver to use (either "z3" or "cvc4")
    --max-iterations <number> number of times we may revisit a particular branching point during symbolic execution

dapp tests are written in Solidity using the ds-test module. To install it, run

dapp install ds-test

Every contract which inherits from DSTest will be treated as a test contract, if it has a setUp() function, it will be run before every test.

Every function prefixed with test is expected to succeed, while functions prefixed by testFail are expected to fail.

Functions prefixed with prove are run symbolically, expecting success while functions prefixed proveFail are run symbolically expecting failure.

The -v flag prints call traces for failing tests, --verbosity 2 will show ds-test events for all tests, while --verbosity 3 will show call traces for all tests.

If you provide --rpc, state will be fetched via rpc. Local changes take priority.

You can configure the testing environment using hevm specific environment variables.

To modify local state even more, you can use hevm cheat codes.

If your test function takes arguments, they will be randomly instantiated and the function will be run multiple times.

The number of times run is configurable using --fuzz-runs.

To step through a test in hevm interactive debugger, use dapp debug.

dapp test --match <regex> will only run tests that match the given regular expression. This will be matched against the file path of the test file, followed by the contract name and the test method, in the form src/my_test_file.sol:TestContract.test_name(). For example, to only run tests from the contract ContractA:

dapp test --match ':ContractA\.'

To run all tests, from all contracts, that contain either foo or bar in the test name:

dapp test --match '(foo|bar)'

To only run tests called 'test_this()' from TheContract in the src/test/a.t.sol file:

dapp test --match 'src/test/a\.t\.sol:TheContract\.test_this\(\)'

By default, dapp test also recompiles your contracts. To skip this, you can set the environment variable DAPP_SKIP_BUILD=1.

If you have any libraries in DAPP_SRC or DAPP_LIB with nonzero bytecode, they will be deployed locally and linked to by any contracts referring to them. This can be skipped by setting DAPP_LINK_TEST_LIBRARIES=0.

dapp debug

dapp-debug -- run unit tests interactively (hevm)
Usage: dapp debug [<options>]

Options:
   --rpc                 fetch remote state via ETH_RPC_URL
   --rpc-url=<url>       fetch remote state via <url>
   --rpc-block=<number>  block number (latest if not specified)

Enters the interactive debugger. See the hevm README for key bindings for navigation.

dapp create

dapp-create -- deploy a compiled contract (--verify on Etherscan)
Usage: dapp create <contractname> or
    dapp create <path>:<contractname>
Add --verify and export your ETHERSCAN_API_KEY to auto-verify on Etherscan

dapp address

dapp-address -- determine address of newly generated contract
Usage: dapp address <sender> <nonce>

dapp install

dapp-install -- install a smart contract library
Usage: dapp install <lib>
<lib> may be:
- a Dapphub repo (ds-foo)
- the URL of a Dapphub repo (https://github.com/dapphub/ds-foo)
- a path to a repo in another Github org (org-name/repo-name)

You can also specify a version (or branch / commit hash) for the repository by suffixing the URL with @<version>. dapp install will then proceed to clone the repository and then git checkout --recurse-submodules $version.

If the project you want to install does not follow the typical dapp project structure, you may need to configure the DAPP_REMAPPINGS environment variable to be able to find it. For an example, see this repo.

dapp uninstall

dapp-uninstall -- remove a smart contract library
Usage: dapp uninstall <lib>

dapp update

dapp-update -- fetch all upstream lib changes
Usage: dapp update [<lib>]

Updates a project submodule in the lib subdirectory.

dapp snapshot

dapp-snapshot -- creates a snapshot of each test's gas usage
Usage: dapp snapshot

Saves a snapshot of each concrete test's gas usage in a .gas-snapshot file.

dapp check-snapshot

dapp-check-snapshot -- check snapshot is up to date
Usage: dapp check-snapshot

Runs dapp snapshot and exits with an error code if its output does not match the current .gas-snapshot file.

dapp upgrade

dapp-upgrade -- pull & commit all upstream lib changes
Usage: dapp upgrade [<lib>]

dapp testnet

Spins up a geth testnet.

dapp verify-contract

dapp-verify-contract -- verify contract source on etherscan
Usage: dapp verify-contract <path>:<contractname> <address> [constructorArgs]

Example: dapp verify-contract src/auth/authorities/RolesAuthority.sol:RolesAuthority 0x9ed0e..

Requires ETHERSCAN_API_KEY to be set.

seth chain will be used to determine on which network the contract is to be verified.

Automatically run when the --verify flag is passed to dapp create.

dapp mk-standard-json

Generates a Solidity settings input json using the structure of the current directory.

The following environment variables can be used to override settings:

  • DAPP_SRC
  • DAPP_REMAPPINGS
  • DAPP_BUILD_OPTIMIZE
  • DAPP_BUILD_OPTIMIZE_RUNS
  • DAPP_LIBRARIES
  • DAPP_SMTCHECKER