Using Foundry Start to End with Phron

Introduction

Foundry has become an increasingly popular development environment for smart contracts because it requires only one language: Solidity. Phron offers introductory documentation on using Foundry with Phron networks, which is recommended to read to get an introduction to using Foundry. In this tutorial, we will dip our toes deeper into the library to get a more cohesive look at properly developing, testing, and deploying with Foundry.

In this demonstration, we will deploy two smart contracts. One is a token, and the other will depend on that token. We will also write unit tests to ensure the contracts work as expected. To deploy them, we will write a script that Foundry will use to determine the deployment logic. Finally, we will verify the smart contracts on Phron's blockchain explorer.

Checking Prerequisites

To get started, you will need the following:

  • Have an account with funds. You can get DEV tokens for testing on Phron once every 24 hours from the Phron Faucet

  • To test out the examples in this guide on Phron, you will need to have your own endpoint and API key, which you can get from one of the supported Endpoint Providers

  • Have a Phron API Key

Create a Foundry Project

The first step to start a Foundry project is, of course, to create it. If you have Foundry installed, you can run:

forge init foundry && cd foundry

This will have the forge utility initialize a new folder named foundry with a Foundry project initialized within it. The script, src, and test folders may have files in them already. Be sure to delete them, because we will be writing our own soon.

From here, there are a few things to do first before writing any code. First, we want to add a dependency to OpenZeppelin's smart contracts, because they include helpful contracts to use when writing token smart contracts. To do so, add them using their GitHub repository name:

forge install OpenZeppelin/openzeppelin-contracts

This will add the OpenZeppelin git submodule to your lib folder. To be sure that this dependency is mapped, you can override the mappings in a special file, remappings.txt:

forge remappings > remappings.txt

Every line in this file is one of the dependencies that can be referenced in the project's smart contracts. Dependencies can be edited and renamed so that it's easier to reference different folders and files when working on smart contracts. It should look similar to this with OpenZeppelin installed properly:

ds-test/=lib/forge-std/lib/ds-test/src/
forge-std/=lib/forge-std/src/
openzeppelin-contracts/=lib/openzeppelin-contracts/

Finally, let's open up the foundry.toml file. In preparation for Etherscan verification and deployment, add this to the file:

[profile.default]
src = 'src'
out = 'out'
libs = ['lib']
solc_version = '0.8.20'

[rpc_endpoints]
phronbase = "https://testnet.phron.ai"
phronapi = "INSERT_RPC_API_ENDPOINT"

[etherscan]
phronbase = { key = "${PHRONSCAN_API_KEY}" }
phronapi = { key = "${PHRONSCAN_API_KEY}" }

The first addition is a specification of the solc_version, underneath profile.default. The rpc_endpoints tag allows you to define which RPC endpoints to use when deploying to a named network, in this case, Phron. The etherscan tag allows you to add Etherscan API keys for smart contract verification, which we will review later.

Add Smart Contracts

Smart contracts in Foundry destined for deployment by default belong in the src folder. In this tutorial, we'll write two smart contracts. Starting with the token:

touch MyToken.sol

Open the file and add the following to it:

// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;

// Import OpenZeppelin Contract
import {ERC20} from "@openzeppelin/contracts/token/ERC20/ERC20.sol";

// This ERC-20 contract mints the specified amount of tokens to the contract creator
contract MyToken is ERC20 {
    constructor(uint256 initialSupply) ERC20("MyToken", "MYTOK") {
        _mint(msg.sender, initialSupply);
    }

    // An external minting function allows anyone to mint as many tokens as they want
    function mint(uint256 toMint, address to) external {
        require(toMint <= 1 ether);
        _mint(to, toMint);
    }
}

As you can see, the OpenZeppelin ERC20 smart contract is imported by the mapping defined in remappings.txt.

The second smart contract, which we'll name Container.sol, will depend on this token contract. It is a simple contract that holds the ERC-20 token we'll deploy. You can create the file by executing:

touch Container.sol

Open the file and add the following to it:

// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;

// Import OpenZeppelin Contract
import {MyToken} from "./MyToken.sol";

enum ContainerStatus {
    Unsatisfied,
    Full,
    Overflowing
}

contract Container {
    MyToken token;
    uint256 capacity;
    ContainerStatus public status;

    constructor(MyToken _token, uint256 _capacity) {
        token = _token;
        capacity = _capacity;
        status = ContainerStatus.Unsatisfied;
    }

    // Updates the status value based on the number of tokens that this contract has
    function updateStatus() public {
        address container = address(this);
        uint256 balance = token.balanceOf(container);
        if (balance < capacity) {
            status = ContainerStatus.Unsatisfied;
        } else if (balance == capacity) {
            status = ContainerStatus.Full;
        } else if (_isOverflowing(balance)) {
            status = ContainerStatus.Overflowing;
        }
    }

    // Returns true if the contract should be in an overflowing state, false if otherwise
    function _isOverflowing(uint256 balance) internal view returns (bool) {
        return balance > capacity;
    }
}

The Container smart contract can have its status updated based on how many tokens it holds and what its initial capacity value was set to. If the number of tokens it holds is above its capacity, its status can be updated to Overflowing. If it holds tokens equal to capacity, its status can be updated to Full. Otherwise, the contract will start and stay in the Unsatisfied state.

Container requires a MyToken smart contract instance to function, so when we deploy it, we will need logic to ensure that it is deployed with a MyToken smart contract.

Write Tests

Before we deploy anything to a TestNet or MainNet, however, it's good to test your smart contracts. There are many types of tests:

  • Unit tests — allow you to test specific parts of a smart contract's functionality. When writing your own smart contracts, it can be a good idea to break functionality into different sections so that it is easier to unit test

  • Fuzz tests — allow you to test a smart contract with a wide variety of inputs to check for edge cases

  • Integration tests — allow you to test a smart contract when it works in conjunction with other smart contracts, so that you know it works as expected in a deployed environment

    • Forking tests - integration tests that allows you to make a fork (a carbon copy of a network), so that you can simulate a series of transactions on a preexisting network

Unit Tests in Foundry

To get started with writing tests for this tutorial, make a new file in the test folder:

cd test
touch MyToken.t.sol

By convention, all of your tests should end with .t.sol and start with the name of the smart contract that it is testing. In practice, the test can be stored anywhere and is considered a test if it has a function that starts with the word "test".

Let's start by writing a test for the token smart contract. Open up MyToken.t.sol and add:

pragma solidity ^0.8.0;

import "forge-std/Test.sol";
import "../src/MyToken.sol";

contract MyTokenTest is Test {
    MyToken public token;

    // Runs before each test
    function setUp() public {
        token = new MyToken(100);
    }

    // Tests if minting during the constructor happens properly
    function testConstructorMint() public {
        assertEq(token.balanceOf(address(this)), 100);
    }
}

Let's break down what's happening here. The first line is typical for a Solidity file: setting the Solidity version. The next two lines are imports. forge-std/Test.sol is the standard library that Forge (and thus Foundry) includes to help with testing. This includes the Test smart contract, certain assertions, and forge cheatcodes.

If you take a look at the MyTokenTest smart contract, you'll see two functions. The first is setUp, which is run before each test. So in this test contract, a new instance of MyToken is deployed every time a test function is run. You know if a function is a test function if it starts with the word "test", so the second function, testConstructorMint is a test function.

Great! Let's write some more tests, but for Container.

touch Container.t.sol

And add the following:

// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.0;

import "forge-std/Test.sol";
import {MyToken} from "../src/MyToken.sol";
import {Container, ContainerStatus} from "../src/Container.sol";

contract ContainerTest is Test {
    MyToken public token;
    Container public container;

    uint256 constant CAPACITY = 100;

    // Runs before each test
    function setUp() public {
        token = new MyToken(1000);
        container = new Container(token, CAPACITY);
    }

    // Tests if the container is unsatisfied right after constructing
    function testInitialUnsatisfied() public {
        assertEq(token.balanceOf(address(container)), 0);
        assertTrue(container.status() == ContainerStatus.Unsatisfied);
    }

    // Tests if the container will be "full" once it reaches its capacity
    function testContainerFull() public {
        token.transfer(address(container), CAPACITY);
        container.updateStatus();

        assertEq(token.balanceOf(address(container)), CAPACITY);
        assertTrue(container.status() == ContainerStatus.Full);
    }
}

This test smart contract has two tests, so when running the tests, there will be two deployments of both MyToken and Container, for four smart contracts. You can run the following command to see the result of the test:

forge test

When testing, you should see the following output:

forge test[⠊] Compiling...No files changed, compilation skipped
Ran 1 test for test/MyToken.t.sol:MyTokenTest[PASS] testConstructorMint() (gas: 10651)Suite result: ok. 1 passed; 0 failed; 0 skipped; finished in 361.83µs (39.46µs CPU time)
Ran 2 tests for test/Container.t.sol:ContainerTest[PASS] testContainerFull() (gas: 73204)[PASS] testInitialUnsatisfied() (gas: 18476)Suite result: ok. 2 passed; 0 failed; 0 skipped; finished in 422.00µs (128.67µs CPU time)Ran 2 test suites in 138.17ms (783.83µs CPU time): 3 tests passed, 0 failed, 0 skipped (3 total tests)

Test Harnesses in Foundry

Sometimes you'll want to unit test an internal function in a smart contract. To do so, you'll have to write a test harness smart contract, which inherits from the smart contract and exposes the internal function as a public one.

For example, in Container, there is an internal function named _isOverflowing, which checks to see if the smart contract has more tokens than its capacity. To test this, add the following test harness smart contract to the Container.t.sol file:

contract ContainerHarness is Container {
    constructor(MyToken _token, uint256 _capacity) Container(_token, _capacity) {}

    function exposed_isOverflowing(uint256 balance) external view returns(bool) {
        return _isOverflowing(balance);
    }
}

Now, inside of the ContainerTest smart contract, you can add a new test that tests the previously unreachable _isOverflowing contract:

// Tests for negative cases of the internal _isOverflowing function
function testIsOverflowingFalse() public {
    ContainerHarness harness = new ContainerHarness(token , CAPACITY);
    assertFalse(harness.exposed_isOverflowing(CAPACITY - 1));
    assertFalse(harness.exposed_isOverflowing(CAPACITY));
    assertFalse(harness.exposed_isOverflowing(0));
}

Now, when you run the test with forge test, you should see that testIsOverflowingFalse passes!

forge test[⠊] Compiling...[⠒] Compiling 1 files with 0.8.20[⠢] Solc 0.8.20 finished in 1.06sCompiler run successful
Ran 1 test for test/MyToken.t.sol:MyTokenTest[PASS] testConstructorMint() (gas: 10651)Suite result: ok. 1 passed; 0 failed; 0 skipped; finished in 498.00µs (48.96µs CPU time)
Ran 3 tests for test/Container.t.sol:ContainerTest[PASS] testContainerFull() (gas: 73238)[PASS] testInitialUnsatisfied() (gas: 18510)[PASS] testIsOverflowingFalse() (gas: 192130)Suite result: ok. 3 passed; 0 failed; 0 skipped; finished in 606.17µs (183.54µs CPU time)Ran 2 test suites in 138.29ms (1.10ms CPU time): 4 tests passed, 0 failed, 0 skipped (4 total tests)

Fuzzing Tests in Foundry

When you write a unit test, you can only use so many inputs to test. You can test edge cases, a few select values, and perhaps one or two random ones. But when working with inputs, there are nearly an infinite amount of different ones to test! How can you be sure that they work for every value? Wouldn't you feel safer if you could test 10000 different inputs instead of less than 10?

One of the best ways that developers can test many inputs is through fuzzing, or fuzz tests. Foundry automatically fuzz tests when an input in a test function is included. To illustrate this, add the following test to the MyTokenTest contract in MyToken.t.sol.

// Fuzz tests for success upon minting tokens one ether or below
function testMintOneEtherOrBelow(uint256 amountToMint) public {
    vm.assume(amountToMint <= 1 ether);

    token.mint(amountToMint, msg.sender);
    assertEq(token.balanceOf(msg.sender), amountToMint);
}

This test includes uint256 amountToMint as input, which tells Foundry to fuzz with uint256 inputs! By default, Foundry will input 256 different inputs, but this can be configured with the FOUNDRY_FUZZ_RUNS environment variable.

Additionally, the first line in the function uses vm.assume to only use inputs that are less than or equal to one ether since the mint function reverts if someone tries to mint more than one ether at a time. This cheatcode helps you direct the fuzzing into the right range.

Let's look at another fuzzing test to put in the MyTokenTest contract, but this time where we expect to fail:

// Fuzz tests for failure upon minting tokens above one ether
function testFailMintAboveOneEther(uint256 amountToMint) public {
    vm.assume(amountToMint > 1 ether);

    token.mint(amountToMint, msg.sender);
}

In Foundry, when you want to test for a failure, instead of just starting your test function with the world "test", you start it with "testFail". In this test, we assume that the amountToMint is above one ether, which should fail!

Now run the tests:

forge test

You should see something similar to the following in the console:

forge test[⠊] Compiling...[⠊] Compiling 1 files with 0.8.20[⠒] Solc 0.8.20 finished in 982.65msCompiler run successful
Ran 3 tests for test/Container.t.sol:ContainerTest[PASS] testContainerFull() (gas: 73238)[PASS] testInitialUnsatisfied() (gas: 18510)[PASS] testIsOverflowingFalse() (gas: 192130)Suite result: ok. 3 passed; 0 failed; 0 skipped; finished in 446.25µs (223.67µs CPU time)
Ran 3 tests for test/MyToken.t.sol:MyTokenTest[PASS] testConstructorMint() (gas: 10651)[PASS] testFailMintAboveOneEther(uint256) (runs: 256, μ: 8462, ~: 8462)[PASS] testMintOneEtherOrBelow(uint256) (runs: 256, μ: 37939, ~: 39270)Suite result: ok. 3 passed; 0 failed; 0 skipped; finished in 10.78ms (18.32ms CPU time)Ran 2 test suites in 138.88ms (11.23ms CPU time): 6 tests passed, 0 failed, 0 skipped (6 total tests)

Forking Tests in Foundry

In Foundry, you can locally fork a network so that you can test out how the contracts would work in an environment with already deployed smart contracts. For example, if someone deployed smart contract A on Phron that required a token smart contract, you could fork the Phron network and deploy your own token to test how smart contract A would react to it.

Note

Phron's custom precompile smart contracts currently do not work in Foundry forks because precompiles are Substrate-based whereas typical smart contracts are completely based on the EVM. Learn more about forking on Phron and the differences between Phron and Ethereum.

In this tutorial, you will test how your Container smart contract interacts with an already deployed MyToken contract on Phron

Let's add a new test function to the ContainerTest smart contract in Container.t.sol called testAlternateTokenOnPhronFork:

// Fork tests in the Phron environment
function testAlternateTokenOnPhronFork() public {
    // Creates and selects a fork, returns a fork ID
    uint256 phronFork = vm.createFork("phron");
    vm.selectFork(phronFork);
    assertEq(vm.activeFork(), phronFork);

    // Get token that's already deployed & deploys a container instance
    token = MyToken(0x359436610E917e477D73d8946C2A2505765ACe90);
    container = new Container(token, CAPACITY);

    // Mint tokens to the container & update container status
    token.mint(CAPACITY, address(container));
    container.updateStatus();

    // Assert that the capacity is full, just like the rest of the time
    assertEq(token.balanceOf(address(container)), CAPACITY);
    assertTrue(container.status() == ContainerStatus.Full);
}

The first step (and thus first line) in this function is to have the test function fork a network with vm.createFork. Recall that vm is a cheat code provided by the Forge standard library. All that's necessary to create a fork is an RPC URL, or an alias for an RPC URL that's stored in the foundry.toml file. In this case, we added an RPC URL for "phron" in the setup step, so in the test function we will just pass the word "phronbase". This cheat code function returns an ID for the fork created, which is stored in an uint256 and is necessary for activating the fork.

On the second line, after the fork has been created, the environment will select and use the fork in the test environment with vm.selectFork. The third line just demonstrates that the current fork, retrieved with vm.activeFork, is the same as the Phron fork.

The fourth line of code retrieves an already deployed instance of MyToken, which is what's so useful about forking: you can use contracts that are already deployed.

The rest of the code tests capacity like you would expect a local test to. If you run the tests (with the -vvvv tag for extra logging), you'll see that it passes:

forge test -vvvv
forge test[PASS] testIsOverflowingFalse() (gas: 192130)Traces: [192130] ContainerTest::testIsOverflowingFalse() ├─ [151256] → new ContainerHarness@0xF62849F9A0B5Bf2913b396098F7c7019b51A820a │ └─ ← [Return] 522 bytes of code ├─ [421] ContainerHarness::exposed_isOverflowing(99) [staticcall] │ └─ ← [Return] false ├─ [0] VM::assertFalse(false) [staticcall] │ └─ ← [Return] ├─ [421] ContainerHarness::exposed_isOverflowing(100) [staticcall] │ └─ ← [Return] false ├─ [0] VM::assertFalse(false) [staticcall] │ └─ ← [Return] ├─ [421] ContainerHarness::exposed_isOverflowing(0) [staticcall] │ └─ ← [Return] false ├─ [0] VM::assertFalse(false) [staticcall] │ └─ ← [Return] └─ ← [Stop]Suite result: ok. 4 passed; 0 failed; 0 skipped; finished in 2.07s (2.07s CPU time)Ran 2 test suites in 2.44s (2.08s CPU time): 7 tests passed, 0 failed, 0 skipped (7 total tests)

That's it for testing! You can find the complete Container.t.sol and MyToken.t.sol files below:

Container.t.sol
// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.0;

import "forge-std/Test.sol";
import {MyToken} from "../src/MyToken.sol";
import {Container, ContainerStatus} from "../src/Container.sol";

contract ContainerTest is Test {
    MyToken public token;
    Container public container;

    uint256 constant CAPACITY = 100;

    function setUp() public {
        token = new MyToken(1000);
        container = new Container(token, CAPACITY);
    }

    function testInitialUnsatisfied() public {
        assertEq(token.balanceOf(address(container)), 0);
        assertTrue(container.status() == ContainerStatus.Unsatisfied);
    }

    function testContainerFull() public {
        token.transfer(address(container), CAPACITY);
        container.updateStatus();

        assertEq(token.balanceOf(address(container)), CAPACITY);
        assertTrue(container.status() == ContainerStatus.Full);
    }

    function testIsOverflowingFalse() public {
        ContainerHarness harness = new ContainerHarness(token , CAPACITY);
        assertFalse(harness.exposed_isOverflowing(CAPACITY - 1));
        assertFalse(harness.exposed_isOverflowing(CAPACITY));
        assertFalse(harness.exposed_isOverflowing(0));
    }

    function testAlternateTokenOnPhronFork() public {
        // Creates and selects a fork
        uint256 phronFork = vm.createFork("phron");
        vm.selectFork(phronFork);
        assertEq(vm.activeFork(), phronFork);

        // Get token that's already deployed & deploys a container instance
        token = MyToken(0x93e1e9EC6c1A8736266A595EFe97B5673ea0fEAc);
        container = new Container(token, CAPACITY);

        // Mint tokens to the container & update container status
        token.mint(CAPACITY, address(container));
        container.updateStatus();

        // Assert that the capacity is full
        assertEq(token.balanceOf(address(container)), CAPACITY);
        assertTrue(container.status() == ContainerStatus.Full);
    }
}

contract ContainerHarness is Container {
    constructor(MyToken _token, uint256 _capacity) Container(_token, _capacity) {}

    function exposed_isOverflowing(uint256 balance) external view returns(bool) {
        return _isOverflowing(balance);
    }
}
MyToken.t.sol
// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.0;

import "forge-std/Test.sol";
import "../src/MyToken.sol";

contract MyTokenTest is Test {
    MyToken public token;

    function setUp() public {
        token = new MyToken(100);
    }

    function testConstructorMint() public {
        assertEq(token.balanceOf(address(this)), 100);
    }

    function testMintOneEtherOrBelow(uint256 amountToMint) public {
        vm.assume(amountToMint <= 1 ether);

        token.mint(amountToMint, msg.sender);
        assertEq(token.balanceOf(msg.sender), amountToMint);
    }

    function testFailMintAboveOneEther(uint256 amountToMint) public {
        vm.assume(amountToMint > 1 ether);

        token.mint(amountToMint, msg.sender);
    }
}

Deploy in Foundry with Solidity Scripts

Not only are tests in Foundry written in Solidity, the scripts are too! Like other developer environments, scripts can be written to help interact with deployed smart contracts or can help along a complex deployment process that would be difficult to do manually. Even though scripts are written in Solidity, they are never deployed to a chain. Instead, much of the logic is actually run off-chain, so don't worry about any additional gas costs for using Foundry instead of a JavaScript environment like Hardhat.

Deploy on Phron

In this tutorial, we will use Foundry's scripts to deploy the MyToken and Container smart contracts. To create the deployment scripts, create a new file in the script folder:

cd script
touch Container.s.sol

By convention, scripts should end with s.sol and have a name similar to the script they relate to. In this case, we are deploying the Container smart contract, so we have named the script Container.s.sol, though it's not the end of the world if you use a more suitable or descriptive name.

In this script, add:

pragma solidity ^0.8.0;

import "forge-std/Script.sol";
import {MyToken} from "../src/MyToken.sol";
import {Container} from "../src/Container.sol";

contract ContainerDeployScript is Script {
    // Runs the script; deploys MyToken and Container
    function run() public {
        // Get the private key from the .env
        uint256 deployerPrivateKey = vm.envUint("PRIVATE_KEY");
        vm.startBroadcast(deployerPrivateKey);

        // Make a new token
        MyToken token = new MyToken(1000);

        // Make a new container
        new Container(token, 500);

        vm.stopBroadcast();
    }
}

Let's break this script down. The first line is standard: declaring the solidity version. The imports include the two smart contracts you previously added, which will be deployed. This includes additional functionality to use in a script, including the Script contract.

Now let's look at the logic in the contract. There is a single function, run, which is where the script logic is hosted. In this run function, the vm object is used often. This is where all of the Forge cheatcodes are stored, which determines the state of the virtual machine that the solidity is run in.

In the first line within the run function, vm.envUint is used to get a private key from the system's environment variables (we will do this soon). In the second line, vm.startBroadcast starts a broadcast, which indicates that the following logic should take place on-chain. So when the MyToken and the Container contracts are instantiated with the new keyword, they are instantiated on-chain. The final line, vm.stopBroadcast ends the broadcast.

Before we run this script, let's set up some of our environment variables. Create a new .env file:

touch .env

And within this file, add the following:

PRIVATE_KEY=YOUR_PRIVATE_KEY
PHRONSCAN_API_KEY=YOUR_PHRONSCAN_API_KEY

Note

Foundry provides additional options for handling your private key. It is up to you to decide whether or not you would rather use it in the console, have it stored in your device's environment, using a hardware wallet, or using a keystore.

To add these environment variables, run the following command:

source .env

Now your script and project should be ready for deployment! Use the following command to do so:

forge script Container.s.sol:ContainerDeployScript --broadcast --verify -vvvv --legacy --rpc-url phron

This command runs the ContainerDeployScript contract as a script. The --broadcast option tells Forge to allow broadcasting of transactions, the --verify option tells Forge to verify to Phronscan when deploying, -vvvv makes the command output verbose, and --rpc-url phronbase sets the network to what phronbase was set to in foundry.toml. The --legacy flag instructs Foundry to bypass EIP-1559. While all Phron networks support EIP-1559, Foundry will refuse to submit the transaction to phronbase and revert to a local simulation if you omit the --legacy flag.

You should see something like this as output:

Script ran successfully.Setting up 1 EVM.Simulated On-chain Traces: [488164] → new MyToken@0xAEe1a769b10d03a6CeB4D9DFd3aBB2EF807ee6aa ├─ emit Transfer(from: 0x0000000000000000000000000000000000000000, to: 0x3B939FeaD1557C741Ff06492FD0127bd287A421e, value: 1000) └─ ← [Return] 1980 bytes of code [133238] → new Container@0xeb1Ff38A645Eae4E64dFb93772D8129F88E11Ab1 └─ ← [Return] 432 bytes of codeChain 1287Estimated gas price: 0.125 gweiEstimated total gas used for script: 1670737Estimated amount required: 0.000208842125 ETHSending transactions [0 - 0].⠁ [00:00:00] [#############################################################>-------------------------------------------------------------] 1/2 txes (0.7s)Waiting for receipts.⠉ [00:00:22] [#######################################################################################################################] 1/1 receipts (0.0s)phron✅ [Success]Hash: 0x2ad8994c12af74bdcb04873e13d97dc543a2fa7390c1e194732ab43ec828cb3bContract Address: 0xAEe1a769b10d03a6CeB4D9DFd3aBB2EF807ee6aaBlock: 6717135Paid: 0.000116937 ETH (935496 gas * 0.125 gwei)Sending transactions [1 - 1].⠉ [00:00:23] [###########################################################################################################################] 2/2 txes (0.0s)Waiting for receipts.⠉ [00:00:21] [#######################################################################################################################] 1/1 receipts (0.0s)phron✅ [Success]Hash: 0x3bfb4cee2be4269badc57e0053d8b4d94d9d57d7936ecaa1e13ac1e2199f3b12Contract Address: 0xeb1Ff38A645Eae4E64dFb93772D8129F88E11Ab1Block: 6717137Paid: 0.000035502 ETH (284016 gas * 0.125 gwei)ONCHAIN EXECUTION COMPLETE & SUCCESSFUL.Total Paid: 0.000152439 ETH (1219512 gas * avg 0.125 gwei)

You should be able to see that your contracts were deployed, and are verified on Phronscan! For example, this is where my Container.sol contract was deployed.

The entire deployment script is available below:

Container.s.sol
// SPDX-License-Identifier: UNLICENSED
pragma solidity ^0.8.0;

import "forge-std/Script.sol";
import {MyToken} from "../src/MyToken.sol";
import {Container} from "../src/Container.sol";

contract ContainerDeployScript is Script {
    function run() public {
        // Get the private key from the .env
        uint256 deployerPrivateKey = vm.envUint("PRIVATE_KEY");
        vm.startBroadcast(deployerPrivateKey);

        // Make a new token
        MyToken token = new MyToken(1000);

        // Make a new container
        new Container(token, 500);

        vm.stopBroadcast();
    }
}

Deploy on Phron MainNet

Let's say that you're comfortable with your smart contracts and you want to deploy on the Phron MainNet! The process isn't too different from what was just done, you just have to change the command's rpc-url from phronbase to phron, since you've already added Phron MainNet's information in the foundry.toml file:

forge script Container.s.sol:ContainerDeployScript --broadcast --verify -vvvv --legacy --rpc-url phron

It's important to note that there are additional, albeit more complex, ways of handling private keys in Foundry. Some of these methods can be considered safer than storing a production private key in environment variables.

That's it! You've gone from nothing to a fully tested, deployed, and verified Foundry project. You can now adapt this so that you can use Foundry in your own projects!

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