Skills Guide

Web3 Smart Contract Testing

VerifiedSafe

Comprehensively test smart contracts using Hardhat and Foundry with unit tests, integration tests, and mainnet forking. Helps when writing Solidity contract tests, setting up blockchain test suites, or automating coverage reporting and gas optimization.

Sby Skills Guide Bot
TestingIntermediate
806/2/2026
Claude CodeCursorCopilot
#smart-contracts#hardhat#foundry#ethereum#solidity

Recommended for

Claude CodeCursorTest generationCopilotQA / test engineer

Our review

This skill provides a comprehensive guide for testing Solidity smart contracts with Hardhat and Foundry, including unit tests, integration tests, mainnet forking, and gas optimization.

Strengths

  • Covers both Hardhat and Foundry, two popular frameworks
  • Includes advanced testing patterns like forking and fuzzing
  • Provides ready-to-use configurations and code examples
  • Addresses practical aspects like coverage and verification

Limitations

  • Primarily focused on Ethereum, less suitable for other blockchains
  • Requires prior knowledge of Solidity and web3 environment
  • Examples are based on specific tool versions that may change
When to use it

Use this skill when you need to set up robust test suites for Solidity smart contracts, especially using tools like Hardhat and Foundry.

When not to use it

Do not use it for testing traditional web applications, APIs, or other non-blockchain domains.

Security analysis

Safe
Quality score85/100

The skill provides educational guidance and code snippets for smart contract testing. It does not instruct destructive actions, data exfiltration, or obfuscated payloads. While example configuration references environment variables, it does not direct users to expose secrets, and the risk of misuse is inherent to any development template.

No concerns found

Examples

Set up Hardhat testing for ERC-20
I need to write comprehensive unit tests for an ERC-20 token contract using Hardhat. Include fixture setup, transfer tests, and event emission checks.
Fork mainnet for DeFi integration test
Help me set up a Hardhat fork of Ethereum mainnet to test my lending contract against real Uniswap pools. I want to simulate a flash loan attack scenario.
Gas optimization fuzzing with Foundry
Write a Foundry test that fuzzes the parameters of my swap function to identify gas-inefficient edge cases and report gas usage.

name: web3-testing description: "Test smart contracts comprehensively using Hardhat and Foundry with unit tests, integration tests, and mainnet forking. Use when testing Solidity contracts, setting up blockchain test suites, or va..." metadata: author: ncdevshiv version: "1.0" category: other updated: 2026-02-25 risk: unknown source: community

Web3 Smart Contract Testing

Master comprehensive testing strategies for smart contracts using Hardhat, Foundry, and advanced testing patterns.

Do not use this skill when

  • The task is unrelated to web3 smart contract testing
  • You need a different domain or tool outside this scope

Instructions

  • Clarify goals, constraints, and required inputs.
  • Apply relevant best practices and validate outcomes.
  • Provide actionable steps and verification.
  • If detailed examples are required, open resources/implementation-playbook.md.

Use this skill when

  • Writing unit tests for smart contracts
  • Setting up integration test suites
  • Performing gas optimization testing
  • Fuzzing for edge cases
  • Forking mainnet for realistic testing
  • Automating test coverage reporting
  • Verifying contracts on Etherscan

Hardhat Testing Setup

// hardhat.config.js
require("@nomicfoundation/hardhat-toolbox");
require("@nomiclabs/hardhat-etherscan");
require("hardhat-gas-reporter");
require("solidity-coverage");

module.exports = {
  solidity: {
    version: "0.8.19",
    settings: {
      optimizer: {
        enabled: true,
        runs: 200,
      },
    },
  },
  networks: {
    hardhat: {
      forking: {
        url: process.env.MAINNET_RPC_URL,
        blockNumber: 15000000,
      },
    },
    goerli: {
      url: process.env.GOERLI_RPC_URL,
      accounts: [process.env.PRIVATE_KEY],
    },
  },
  gasReporter: {
    enabled: true,
    currency: "USD",
    coinmarketcap: process.env.COINMARKETCAP_API_KEY,
  },
  etherscan: {
    apiKey: process.env.ETHERSCAN_API_KEY,
  },
};

Unit Testing Patterns

const { expect } = require("chai");
const { ethers } = require("hardhat");
const {
  loadFixture,
  time,
} = require("@nomicfoundation/hardhat-network-helpers");

describe("Token Contract", function () {
  // Fixture for test setup
  async function deployTokenFixture() {
    const [owner, addr1, addr2] = await ethers.getSigners();

    const Token = await ethers.getContractFactory("Token");
    const token = await Token.deploy();

    return { token, owner, addr1, addr2 };
  }

  describe("Deployment", function () {
    it("Should set the right owner", async function () {
      const { token, owner } = await loadFixture(deployTokenFixture);
      expect(await token.owner()).to.equal(owner.address);
    });

    it("Should assign total supply to owner", async function () {
      const { token, owner } = await loadFixture(deployTokenFixture);
      const ownerBalance = await token.balanceOf(owner.address);
      expect(await token.totalSupply()).to.equal(ownerBalance);
    });
  });

  describe("Transactions", function () {
    it("Should transfer tokens between accounts", async function () {
      const { token, owner, addr1 } = await loadFixture(deployTokenFixture);

      await expect(token.transfer(addr1.address, 50)).to.changeTokenBalances(
        token,
        [owner, addr1],
        [-50, 50],
      );
    });

    it("Should fail if sender doesn't have enough tokens", async function () {
      const { token, addr1 } = await loadFixture(deployTokenFixture);
      const initialBalance = await token.balanceOf(addr1.address);

      await expect(
        token.connect(addr1).transfer(owner.address, 1),
      ).to.be.revertedWith("Insufficient balance");
    });

    it("Should emit Transfer event", async function () {
      const { token, owner, addr1 } = await loadFixture(deployTokenFixture);

      await expect(token.transfer(addr1.address, 50))
        .to.emit(token, "Transfer")
        .withArgs(owner.address, addr1.address, 50);
    });
  });

  describe("Time-based tests", function () {
    it("Should handle time-locked operations", async function () {
      const { token } = await loadFixture(deployTokenFixture);

      // Increase time by 1 day
      await time.increase(86400);

      // Test time-dependent functionality
    });
  });

  describe("Gas optimization", function () {
    it("Should use gas efficiently", async function () {
      const { token } = await loadFixture(deployTokenFixture);

      const tx = await token.transfer(addr1.address, 100);
      const receipt = await tx.wait();

      expect(receipt.gasUsed).to.be.lessThan(50000);
    });
  });
});

Foundry Testing (Forge)

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

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

contract TokenTest is Test {
    Token token;
    address owner = address(1);
    address user1 = address(2);
    address user2 = address(3);

    function setUp() public {
        vm.prank(owner);
        token = new Token();
    }

    function testInitialSupply() public {
        assertEq(token.totalSupply(), 1000000 * 10**18);
    }

    function testTransfer() public {
        vm.prank(owner);
        token.transfer(user1, 100);

        assertEq(token.balanceOf(user1), 100);
        assertEq(token.balanceOf(owner), token.totalSupply() - 100);
    }

    function testFailTransferInsufficientBalance() public {
        vm.prank(user1);
        token.transfer(user2, 100); // Should fail
    }

    function testCannotTransferToZeroAddress() public {
        vm.prank(owner);
        vm.expectRevert("Invalid recipient");
        token.transfer(address(0), 100);
    }

    // Fuzzing test
    function testFuzzTransfer(uint256 amount) public {
        vm.assume(amount > 0 && amount <= token.totalSupply());

        vm.prank(owner);
        token.transfer(user1, amount);

        assertEq(token.balanceOf(user1), amount);
    }

    // Test with cheatcodes
    function testDealAndPrank() public {
        // Give ETH to address
        vm.deal(user1, 10 ether);

        // Impersonate address
        vm.prank(user1);

        // Test functionality
        assertEq(user1.balance, 10 ether);
    }

    // Mainnet fork test
    function testForkMainnet() public {
        vm.createSelectFork("https://eth-mainnet.alchemyapi.io/v2/...");

        // Interact with mainnet contracts
        address dai = 0x6B175474E89094C44Da98b954EedeAC495271d0F;
        assertEq(IERC20(dai).symbol(), "DAI");
    }
}

Advanced Testing Patterns

Snapshot and Revert

describe("Complex State Changes", function () {
  let snapshotId;

  beforeEach(async function () {
    snapshotId = await network.provider.send("evm_snapshot");
  });

  afterEach(async function () {
    await network.provider.send("evm_revert", [snapshotId]);
  });

  it("Test 1", async function () {
    // Make state changes
  });

  it("Test 2", async function () {
    // State reverted, clean slate
  });
});

Mainnet Forking

describe("Mainnet Fork Tests", function () {
  let uniswapRouter, dai, usdc;

  before(async function () {
    await network.provider.request({
      method: "hardhat_reset",
      params: [
        {
          forking: {
            jsonRpcUrl: process.env.MAINNET_RPC_URL,
            blockNumber: 15000000,
          },
        },
      ],
    });

    // Connect to existing mainnet contracts
    uniswapRouter = await ethers.getContractAt(
      "IUniswapV2Router",
      "0x7a250d5630B4cF539739dF2C5dAcb4c659F2488D",
    );

    dai = await ethers.getContractAt(
      "IERC20",
      "0x6B175474E89094C44Da98b954EedeAC495271d0F",
    );
  });

  it("Should swap on Uniswap", async function () {
    // Test with real Uniswap contracts
  });
});

Impersonating Accounts

it("Should impersonate whale account", async function () {
  const whaleAddress = "0x...";

  await network.provider.request({
    method: "hardhat_impersonateAccount",
    params: [whaleAddress],
  });

  const whale = await ethers.getSigner(whaleAddress);

  // Use whale's tokens
  await dai
    .connect(whale)
    .transfer(addr1.address, ethers.utils.parseEther("1000"));
});

Gas Optimization Testing

const { expect } = require("chai");

describe("Gas Optimization", function () {
  it("Compare gas usage between implementations", async function () {
    const Implementation1 =
      await ethers.getContractFactory("OptimizedContract");
    const Implementation2 = await ethers.getContractFactory(
      "UnoptimizedContract",
    );

    const contract1 = await Implementation1.deploy();
    const contract2 = await Implementation2.deploy();

    const tx1 = await contract1.doSomething();
    const receipt1 = await tx1.wait();

    const tx2 = await contract2.doSomething();
    const receipt2 = await tx2.wait();

    console.log("Optimized gas:", receipt1.gasUsed.toString());
    console.log("Unoptimized gas:", receipt2.gasUsed.toString());

    expect(receipt1.gasUsed).to.be.lessThan(receipt2.gasUsed);
  });
});

Coverage Reporting

# Generate coverage report
npx hardhat coverage

# Output shows:
# File                | % Stmts | % Branch | % Funcs | % Lines |
# -------------------|---------|----------|---------|---------|
# contracts/Token.sol |   100   |   90     |   100   |   95    |

Contract Verification

// Verify on Etherscan
await hre.run("verify:verify", {
  address: contractAddress,
  constructorArguments: [arg1, arg2],
});

# Or via CLI
npx hardhat verify --network mainnet CONTRACT_ADDRESS "Constructor arg1" "arg2"

CI/CD Integration

# .github/workflows/test.yml
name: Tests

on: [push, pull_request]

jobs:
  test:
    runs-on: ubuntu-latest

    steps:
      - uses: actions/checkout@v2
      - uses: actions/setup-node@v2
        with:
          node-version: "16"

      - run: npm install
      - run: npx hardhat compile
      - run: npx hardhat test
      - run: npx hardhat coverage

      - name: Upload coverage to Codecov
        uses: codecov/codecov-action@v2

Resources

  • references/hardhat-setup.md: Hardhat configuration guide
  • references/foundry-setup.md: Foundry testing framework
  • references/test-patterns.md: Testing best practices
  • references/mainnet-forking.md: Fork testing strategies
  • references/contract-verification.md: Etherscan verification
  • assets/hardhat-config.js: Complete Hardhat configuration
  • assets/test-suite.js: Comprehensive test examples
  • assets/foundry.toml: Foundry configuration
  • scripts/test-contract.sh: Automated testing script

Best Practices

  1. Test Coverage: Aim for >90% coverage
  2. Edge Cases: Test boundary conditions
  3. Gas Limits: Verify functions don't hit block gas limit
  4. Reentrancy: Test for reentrancy vulnerabilities
  5. Access Control: Test unauthorized access attempts
  6. Events: Verify event emissions
  7. Fixtures: Use fixtures to avoid code duplication
  8. Mainnet Fork: Test with real contracts
  9. Fuzzing: Use property-based testing
  10. CI/CD: Automate testing on every commit
Related skills

TDD Red-Green-Refactor

Testing

Skill that guides Claude through the complete TDD cycle.

Claude CodeWindsurfintermediate
650
189
2,063
Admin

Web Accessibility Audit

Testing

Performs a comprehensive web accessibility audit following WCAG standards.

claudeCursorWindsurfintermediate
129
37
441
Admin

UAT Test Case Generator

Testing

Generates structured and comprehensive user acceptance test cases.

claudechatgptintermediate
87
24
360
Admin