| name | testing |
| description | Use when creating leaf types, after refactoring, during implementation, or when testing advice is needed.
Automatically invoked to write tests for new types, or use as testing expert advisor.
Covers unit, integration, and system tests with emphasis on in-memory dependencies.
Ensures 100% coverage on leaf types with public API testing.
|
Principles and patterns for writing effective Go tests.
Writes tests autonomously based on code structure and type design, and serves as testing expert advisor.
Reference: See reference.md for comprehensive testutils patterns and DSL examples.
<quick_start>
- Identify test level needed (unit/integration/system)
- Choose structure: table-driven (simple) or testify suites (complex setup)
- Write in pkg_test package - test public API only
- Use in-memory implementations from testutils
- Avoid pitfalls: No time.Sleep, no conditionals in test cases
Ready after tests? Run linter: task lintwithfix
</quick_start>
<when_to_use>
<automatic_invocation>
- Automatically invoked by @linter-driven-development during Phase 1 (Implementation Foundation)
- Automatically invoked by @refactoring when new isolated types are created
- Automatically invoked by @code-designing after designing new types
- After creating new leaf types - Types that should have 100% unit test coverage
- After extracting functions during refactoring that create testable units
</automatic_invocation>
<manual_invocation>
- User explicitly requests tests to be written
- User asks for testing advice, recommendations, or "what to do"
- When testing strategy is unclear (table-driven vs testify suites)
- When choosing between dependency levels (in-memory vs binary vs test-containers)
- When adding tests to existing untested code
- When user needs testing expert guidance or consultation
</manual_invocation>
</when_to_use>
**Test only the public API**
- Use `pkg_test` package name
- Test types through their constructors
- No testing private methods/functions
Prefer real implementations over mocks
- Use in-memory implementations (fastest, no external deps)
- Use HTTP test servers (httptest)
- Use temp files/directories
- Test with actual dependencies when beneficial
Coverage targets
- Leaf types: 100% unit test coverage
- Orchestrating types: Integration tests
- Critical workflows: System tests
<test_pyramid>
Three levels of testing, each serving a specific purpose:
<unit_tests level="base">
- Test leaf types in isolation
- Fast, focused, no external dependencies
- 100% coverage target for leaf types
- Use
pkg_test package, test public API only
</unit_tests>
<integration_tests level="middle">
- Test seams between components
- Test workflows across package boundaries
- Use real or in-memory implementations
- Verify components work together correctly
</integration_tests>
<system_tests level="top">
- Black box testing from
tests/ folder
- Test entire system via CLI/API
- Test critical end-to-end workflows
- Dependency options: in-memory mocks, binaries (exec.Command), or test-containers
- Prefer in-memory when possible, but use appropriate level for the test
</system_tests>
</test_pyramid>
<reusable_infrastructure>
Build shared test infrastructure in internal/testutils/:
- In-memory mock servers with DSL (HTTP, DB, file system)
- Reusable across all test levels
- Test the infrastructure itself!
- Can expose as CLI tools for manual testing
Dependency Priority (choose appropriate level):
- In-memory (fastest): Pure Go, httptest, in-memory DB - use when testing your code's logic
- Binary (isolated): Standalone executable via exec.Command - use when testing against real service
- Test-containers (realistic): Programmatic Docker from Go - use when you need real external services
- Docker-compose (full stack): For complex multi-service scenarios
Choose based on what you're testing, not dogmatically. In-memory is fastest but sometimes you need real services.
See reference.md for comprehensive testutils patterns and DSL examples.
</reusable_infrastructure>
<unit_tests_workflow>
Purpose: Test leaf types in isolation, 100% coverage target
- Identify leaf types - Self-contained types with logic
- Choose structure - Table-driven (simple) or testify suites (complex setup)
- Write in pkg_test package - Test public API only
- Use in-memory implementations - From testutils or local implementations
- Avoid pitfalls - No time.Sleep, no conditionals in cases, no private method tests
Test structure:
- Table-driven: Separate success/error test functions (complexity = 1)
- Testify suites: Only for complex infrastructure setup (HTTP servers, DBs)
- Always use named struct fields (linter reorders fields)
See reference.md for detailed patterns and examples.
</unit_tests_workflow>
<integration_tests_workflow>
Purpose: Test seams between components, verify they work together
- Identify integration points - Where packages/components interact
- Choose dependencies - Prefer: in-memory > binary > test-containers
- Write tests - In
pkg_test or integration_test.go with build tags
- Test workflows - Cover happy path and error scenarios across boundaries
- Use real or testutils implementations - Avoid heavy mocking
File organization:
package user_test
See reference.md for integration test patterns with dependencies.
</integration_tests_workflow>
<system_tests_workflow>
Purpose: Black box test entire system, critical end-to-end workflows
- Place in tests/ folder - At project root, separate from packages
- Test via CLI/API - exec.Command for CLI, HTTP client for APIs
- Choose dependency level based on what you're testing:
- In-memory: Fastest, use when testing your code's behavior
- Binary: exec.Command to run real executables in separate process
- Test-containers: When you need real external services (DB, message queue)
- Test critical workflows - User journeys, not every edge case
Example with in-memory mock:
func TestCLI_UserWorkflow(t *testing.T) {
mockAPI := testutils.NewMockServer().
OnGET("/users/1").RespondJSON(200, user).
Build()
defer mockAPI.Close()
cmd := exec.Command("./myapp", "get-user", "1",
"--api-url", mockAPI.URL())
output, err := cmd.CombinedOutput()
}
Example with binary executable:
func TestSystem_WithRealService(t *testing.T) {
svc := exec.Command("./myservice", "--port", "8080")
svc.Start()
defer svc.Process.Kill()
waitForHealthy(t, "http://localhost:8080/health")
resp, err := http.Get("http://localhost:8080/api/users")
}
See reference.md for comprehensive system test patterns including test-containers.
</system_tests_workflow>
<key_patterns>
Table-Driven Tests (Cyclomatic Complexity = 1):
- NEVER use wantErr bool - Splits test logic, adds conditionals
- Max complexity = 1 inside t.Run() - No if/else, no switch, no conditionals
- Separate success and error test functions (TestFoo_Success, TestFoo_Error)
- Always use named struct fields (linter reorders fields)
tests := []struct {
input string
want string
wantErr bool
}{...}
for _, tt := range tests {
t.Run(tt.name, func(t *testing.T) {
got, err := Parse(tt.input)
if tt.wantErr {
require.Error(t, err)
} else {
require.NoError(t, err)
require.Equal(t, tt.want, got)
}
})
}
func TestParse_Success(t *testing.T) {
tests := []struct {
name string
input string
want string
}{...}
for _, tt := range tests {
t.Run(tt.name, func(t *testing.T) {
got, err := Parse(tt.input)
require.NoError(t, err)
require.Equal(t, tt.want, got)
})
}
}
func TestParse_Error(t *testing.T) {
tests := []struct {
name string
input string
}{...}
for _, tt := range tests {
t.Run(tt.name, func(t *testing.T) {
_, err := Parse(tt.input)
require.Error(t, err)
})
}
}
Testify Suites:
- Only for complex infrastructure (HTTP servers, DBs, OpenTelemetry)
- SetupSuite/TearDownSuite for expensive shared setup
- SetupTest/TearDownTest for per-test isolation
Synchronization:
- Never use time.Sleep (flaky, slow)
- Use channels with select/timeout for async operations
- Use sync.WaitGroup for concurrent operations
See reference.md for complete patterns with code examples.
</key_patterns>
<output_format>
After writing tests:
TESTING COMPLETE
Unit Tests:
- user/user_id_test.go: 100% (4 test cases)
- user/email_test.go: 100% (6 test cases)
- user/service_test.go: 100% (8 test cases)
Integration Tests:
- user/integration_test.go: 3 workflows tested
- Dependencies: In-memory DB, httptest mock server
System Tests:
- tests/cli_test.go: 2 end-to-end workflows (in-memory mocks)
- tests/api_test.go: 1 full API workflow (binary executable)
- tests/db_test.go: 1 database workflow (test-containers)
Test Infrastructure:
- internal/testutils/httpserver: In-memory mock API with DSL
- internal/testutils/mockdb: In-memory database mock
- internal/testutils/containers: Test-container helpers
Test Execution:
$ go test ./... # All tests (in-memory only)
$ go test -tags=integration ./... # Include integration tests
$ go test ./tests/... # System tests (may need containers)
All tests pass
100% coverage on leaf types
Next Steps:
1. Run linter: task lintwithfix
2. If linter fails → use @refactoring skill
3. If linter passes → use @pre-commit-review skill
</output_format>
<testing_checklist>
<unit_tests_checklist>
<integration_tests_checklist>
<system_tests_checklist>
<test_infrastructure_checklist>
See reference.md for complete testing guidelines and examples.
</testing_checklist>
<success_criteria>
Testing is complete when ALL of the following are true:
