ReddRadar
Agent skill
rust-testing
Rust testing patterns including unit tests, integration tests, async testing, property-based testing, mocking, and coverage. Follows TDD methodology.
Stars
132,726
Forks
19,206
Install this agent skill to your Project
npx add-skill https://github.com/affaan-m/everything-claude-code/tree/main/skills/rust-testing
SKILL.md
Rust Testing Patterns
Comprehensive Rust testing patterns for writing reliable, maintainable tests following TDD methodology.
When to Use
- Writing new Rust functions, methods, or traits
- Adding test coverage to existing code
- Creating benchmarks for performance-critical code
- Implementing property-based tests for input validation
- Following TDD workflow in Rust projects
How It Works
- Identify target code — Find the function, trait, or module to test
- Write a test — Use
#[test]in a#[cfg(test)]module, rstest for parameterized tests, or proptest for property-based tests - Mock dependencies — Use mockall to isolate the unit under test
- Run tests (RED) — Verify the test fails with the expected error
- Implement (GREEN) — Write minimal code to pass
- Refactor — Improve while keeping tests green
- Check coverage — Use cargo-llvm-cov, target 80%+
TDD Workflow for Rust
The RED-GREEN-REFACTOR Cycle
RED → Write a failing test first
GREEN → Write minimal code to pass the test
REFACTOR → Improve code while keeping tests green
REPEAT → Continue with next requirement
Step-by-Step TDD in Rust
rust
// RED: Write test first, use todo!() as placeholder
pub fn add(a: i32, b: i32) -> i32 { todo!() }
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_add() { assert_eq!(add(2, 3), 5); }
}
// cargo test → panics at 'not yet implemented'
rust
// GREEN: Replace todo!() with minimal implementation
pub fn add(a: i32, b: i32) -> i32 { a + b }
// cargo test → PASS, then REFACTOR while keeping tests green
Unit Tests
Module-Level Test Organization
rust
// src/user.rs
pub struct User {
pub name: String,
pub email: String,
}
impl User {
pub fn new(name: impl Into<String>, email: impl Into<String>) -> Result<Self, String> {
let email = email.into();
if !email.contains('@') {
return Err(format!("invalid email: {email}"));
}
Ok(Self { name: name.into(), email })
}
pub fn display_name(&self) -> &str {
&self.name
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn creates_user_with_valid_email() {
let user = User::new("Alice", "alice@example.com").unwrap();
assert_eq!(user.display_name(), "Alice");
assert_eq!(user.email, "alice@example.com");
}
#[test]
fn rejects_invalid_email() {
let result = User::new("Bob", "not-an-email");
assert!(result.is_err());
assert!(result.unwrap_err().contains("invalid email"));
}
}
Assertion Macros
rust
assert_eq!(2 + 2, 4); // Equality
assert_ne!(2 + 2, 5); // Inequality
assert!(vec![1, 2, 3].contains(&2)); // Boolean
assert_eq!(value, 42, "expected 42 but got {value}"); // Custom message
assert!((0.1_f64 + 0.2 - 0.3).abs() < f64::EPSILON); // Float comparison
Error and Panic Testing
Testing Result Returns
rust
#[test]
fn parse_returns_error_for_invalid_input() {
let result = parse_config("}{invalid");
assert!(result.is_err());
// Assert specific error variant
let err = result.unwrap_err();
assert!(matches!(err, ConfigError::ParseError(_)));
}
#[test]
fn parse_succeeds_for_valid_input() -> Result<(), Box<dyn std::error::Error>> {
let config = parse_config(r#"{"port": 8080}"#)?;
assert_eq!(config.port, 8080);
Ok(()) // Test fails if any ? returns Err
}
Testing Panics
rust
#[test]
#[should_panic]
fn panics_on_empty_input() {
process(&[]);
}
#[test]
#[should_panic(expected = "index out of bounds")]
fn panics_with_specific_message() {
let v: Vec<i32> = vec![];
let _ = v[0];
}
Integration Tests
File Structure
text
my_crate/
├── src/
│ └── lib.rs
├── tests/ # Integration tests
│ ├── api_test.rs # Each file is a separate test binary
│ ├── db_test.rs
│ └── common/ # Shared test utilities
│ └── mod.rs
Writing Integration Tests
rust
// tests/api_test.rs
use my_crate::{App, Config};
#[test]
fn full_request_lifecycle() {
let config = Config::test_default();
let app = App::new(config);
let response = app.handle_request("/health");
assert_eq!(response.status, 200);
assert_eq!(response.body, "OK");
}
Async Tests
With Tokio
rust
#[tokio::test]
async fn fetches_data_successfully() {
let client = TestClient::new().await;
let result = client.get("/data").await;
assert!(result.is_ok());
assert_eq!(result.unwrap().items.len(), 3);
}
#[tokio::test]
async fn handles_timeout() {
use std::time::Duration;
let result = tokio::time::timeout(
Duration::from_millis(100),
slow_operation(),
).await;
assert!(result.is_err(), "should have timed out");
}
Test Organization Patterns
Parameterized Tests with rstest
rust
use rstest::{rstest, fixture};
#[rstest]
#[case("hello", 5)]
#[case("", 0)]
#[case("rust", 4)]
fn test_string_length(#[case] input: &str, #[case] expected: usize) {
assert_eq!(input.len(), expected);
}
// Fixtures
#[fixture]
fn test_db() -> TestDb {
TestDb::new_in_memory()
}
#[rstest]
fn test_insert(test_db: TestDb) {
test_db.insert("key", "value");
assert_eq!(test_db.get("key"), Some("value".into()));
}
Test Helpers
rust
#[cfg(test)]
mod tests {
use super::*;
/// Creates a test user with sensible defaults.
fn make_user(name: &str) -> User {
User::new(name, &format!("{name}@test.com")).unwrap()
}
#[test]
fn user_display() {
let user = make_user("alice");
assert_eq!(user.display_name(), "alice");
}
}
Property-Based Testing with proptest
Basic Property Tests
rust
use proptest::prelude::*;
proptest! {
#[test]
fn encode_decode_roundtrip(input in ".*") {
let encoded = encode(&input);
let decoded = decode(&encoded).unwrap();
assert_eq!(input, decoded);
}
#[test]
fn sort_preserves_length(mut vec in prop::collection::vec(any::<i32>(), 0..100)) {
let original_len = vec.len();
vec.sort();
assert_eq!(vec.len(), original_len);
}
#[test]
fn sort_produces_ordered_output(mut vec in prop::collection::vec(any::<i32>(), 0..100)) {
vec.sort();
for window in vec.windows(2) {
assert!(window[0] <= window[1]);
}
}
}
Custom Strategies
rust
use proptest::prelude::*;
fn valid_email() -> impl Strategy<Value = String> {
("[a-z]{1,10}", "[a-z]{1,5}")
.prop_map(|(user, domain)| format!("{user}@{domain}.com"))
}
proptest! {
#[test]
fn accepts_valid_emails(email in valid_email()) {
assert!(User::new("Test", &email).is_ok());
}
}
Mocking with mockall
Trait-Based Mocking
rust
use mockall::{automock, predicate::eq};
#[automock]
trait UserRepository {
fn find_by_id(&self, id: u64) -> Option<User>;
fn save(&self, user: &User) -> Result<(), StorageError>;
}
#[test]
fn service_returns_user_when_found() {
let mut mock = MockUserRepository::new();
mock.expect_find_by_id()
.with(eq(42))
.times(1)
.returning(|_| Some(User { id: 42, name: "Alice".into() }));
let service = UserService::new(Box::new(mock));
let user = service.get_user(42).unwrap();
assert_eq!(user.name, "Alice");
}
#[test]
fn service_returns_none_when_not_found() {
let mut mock = MockUserRepository::new();
mock.expect_find_by_id()
.returning(|_| None);
let service = UserService::new(Box::new(mock));
assert!(service.get_user(99).is_none());
}
Doc Tests
Executable Documentation
rust
/// Adds two numbers together.
///
/// # Examples
///
/// ```
/// use my_crate::add;
///
/// assert_eq!(add(2, 3), 5);
/// assert_eq!(add(-1, 1), 0);
/// ```
pub fn add(a: i32, b: i32) -> i32 {
a + b
}
/// Parses a config string.
///
/// # Errors
///
/// Returns `Err` if the input is not valid TOML.
///
/// ```no_run
/// use my_crate::parse_config;
///
/// let config = parse_config(r#"port = 8080"#).unwrap();
/// assert_eq!(config.port, 8080);
/// ```
///
/// ```no_run
/// use my_crate::parse_config;
///
/// assert!(parse_config("}{invalid").is_err());
/// ```
pub fn parse_config(input: &str) -> Result<Config, ParseError> {
todo!()
}
Benchmarking with Criterion
toml
# Cargo.toml
[dev-dependencies]
criterion = { version = "0.5", features = ["html_reports"] }
[[bench]]
name = "benchmark"
harness = false
rust
// benches/benchmark.rs
use criterion::{black_box, criterion_group, criterion_main, Criterion};
fn fibonacci(n: u64) -> u64 {
match n {
0 | 1 => n,
_ => fibonacci(n - 1) + fibonacci(n - 2),
}
}
fn bench_fibonacci(c: &mut Criterion) {
c.bench_function("fib 20", |b| b.iter(|| fibonacci(black_box(20))));
}
criterion_group!(benches, bench_fibonacci);
criterion_main!(benches);
Test Coverage
Running Coverage
bash
# Install: cargo install cargo-llvm-cov (or use taiki-e/install-action in CI)
cargo llvm-cov # Summary
cargo llvm-cov --html # HTML report
cargo llvm-cov --lcov > lcov.info # LCOV format for CI
cargo llvm-cov --fail-under-lines 80 # Fail if below threshold
Coverage Targets
| Code Type | Target |
|---|---|
| Critical business logic | 100% |
| Public API | 90%+ |
| General code | 80%+ |
| Generated / FFI bindings | Exclude |
Testing Commands
bash
cargo test # Run all tests
cargo test -- --nocapture # Show println output
cargo test test_name # Run tests matching pattern
cargo test --lib # Unit tests only
cargo test --test api_test # Integration tests only
cargo test --doc # Doc tests only
cargo test --no-fail-fast # Don't stop on first failure
cargo test -- --ignored # Run ignored tests
Best Practices
DO:
- Write tests FIRST (TDD)
- Use
#[cfg(test)]modules for unit tests - Test behavior, not implementation
- Use descriptive test names that explain the scenario
- Prefer
assert_eq!overassert!for better error messages - Use
?in tests that returnResultfor cleaner error output - Keep tests independent — no shared mutable state
DON'T:
- Use
#[should_panic]when you can testResult::is_err()instead - Mock everything — prefer integration tests when feasible
- Ignore flaky tests — fix or quarantine them
- Use
sleep()in tests — use channels, barriers, ortokio::time::pause() - Skip error path testing
CI Integration
yaml
# GitHub Actions
test:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v4
- uses: dtolnay/rust-toolchain@stable
with:
components: clippy, rustfmt
- name: Check formatting
run: cargo fmt --check
- name: Clippy
run: cargo clippy -- -D warnings
- name: Run tests
run: cargo test
- uses: taiki-e/install-action@cargo-llvm-cov
- name: Coverage
run: cargo llvm-cov --fail-under-lines 80
Remember: Tests are documentation. They show how your code is meant to be used. Write them clearly and keep them up to date.
Recommended Agent Skills
Expand your agent's capabilities with these related and highly-rated skills.
affaan-m/everything-claude-code
python-testing
Python testing best practices using pytest including fixtures, parametrization, mocking, coverage analysis, async testing, and test organization. Use when writing or improving Python tests.
132,726
19,206
Explore
affaan-m/everything-claude-code
golang-patterns
Go-specific design patterns and best practices including functional options, small interfaces, dependency injection, concurrency patterns, error handling, and package organization. Use when working with Go code to apply idiomatic Go patterns.
132,726
19,206
Explore
affaan-m/everything-claude-code
e2e-testing
Playwright E2E testing patterns, Page Object Model, configuration, CI/CD integration, artifact management, and flaky test strategies.
132,726
19,206
Explore
affaan-m/everything-claude-code
agentic-engineering
Operate as an agentic engineer using eval-first execution, decomposition, and cost-aware model routing. Use when AI agents perform most implementation work and humans enforce quality and risk controls.
132,726
19,206
Explore
affaan-m/everything-claude-code
api-design
REST API design patterns including resource naming, status codes, pagination, filtering, error responses, versioning, and rate limiting for production APIs.
132,726
19,206
Explore
affaan-m/everything-claude-code
python-patterns
Python-specific design patterns and best practices including protocols, dataclasses, context managers, decorators, async/await, type hints, and package organization. Use when working with Python code to apply Pythonic patterns.
132,726
19,206
Explore
Didn't find tool you were looking for?