go-testing

Go testing conventions

The standard testing package is the whole toolkit: table-driven tests, hand-written fakes, httptest for handlers, and native fuzzing. No assertion libraries, no mock generators.

1. Table-driven tests with subtests

One slice of cases, one t.Run per case named for the behavior it pins down:

func TestParse(t *testing.T) {
	cases := []struct {
		name    string
		in      string
		wantKey string
		wantErr bool
	}{
		{"simple pair", "a=b", "a", false},
		{"missing separator", "ab", "", true},
		{"empty key", "=b", "", true},
		{"empty value ok", "a=", "a", false},
	}
	for _, c := range cases {
		t.Run(c.name, func(t *testing.T) {
			key, _, err := Parse(c.in)
			if (err != nil) != c.wantErr {
				t.Fatalf("Parse(%q) error = %v, wantErr %v", c.in, err, c.wantErr)
			}
			if key != c.wantKey {
				t.Errorf("Parse(%q) key = %q, want %q", c.in, key, c.wantKey)
			}
		})
	}
}

Adding a behavior means adding a row, not a function.

2. Plain stdlib assertions

if got != want { t.Errorf(...) } — no testify, gomega, or other assertion DSLs. Failure messages follow f(input) = got, want want so the log reads as the broken contract. Use t.Fatalf when continuing is pointless (setup failed, wrong status code); t.Errorf to keep collecting independent mismatches.

3. Fakes over mocks

Tests substitute a hand-written fake for the small consumer-defined interface (see the go-style skill) — a struct with canned returns, not a generated mock with expectations:

type fakeMinter struct {
	token     string
	expiresIn int64
	err       error
}

func (f *fakeMinter) Mint(_ context.Context, _ string, _ []string) (string, int64, error) {
	return f.token, f.expiresIn, f.err
}

Assert on observable behavior (responses, state), not on which methods were called.

4. Helpers take t and call t.Helper()

Shared setup is a function taking t *testing.T, calling t.Helper() first so failures point at the caller, and using t.Cleanup for teardown. Helpers fail the test themselves (t.Fatalf) rather than returning errors.

5. Test HTTP handlers with httptest

No network, no test server — build a request, record the response:

req := httptest.NewRequest(http.MethodPost, "/token", strings.NewReader(form.Encode()))
req.Header.Set("Content-Type", "application/x-www-form-urlencoded")
rr := httptest.NewRecorder()
broker.Handler().ServeHTTP(rr, req)
if rr.Code != http.StatusUnauthorized {
	t.Fatalf("status = %d, want %d (body: %s)", rr.Code, http.StatusUnauthorized, rr.Body.String())
}

6. Fuzz targets assert properties, with seed corpora

Every parser or validator handling untrusted input gets a Fuzz* target. Seed the interesting shapes with f.Add, then assert the properties that must hold for any input — no panics, and the security-critical invariants:

func FuzzParse(f *testing.F) {
	f.Add("a=b")
	f.Add("")
	f.Add("=value")
	f.Fuzz(func(t *testing.T, s string) {
		key, _, err := Parse(s) // must not panic on any input
		if err == nil && key == "" {
			t.Errorf("Parse(%q) accepted an empty key", s)
		}
	})
}

go test ./... replays the seed corpus on every run, so fuzz targets double as regression tests.

7. Invocations

go test ./...                                              # unit tests + fuzz seed corpora
go test -race ./...                                        # CI always runs with the race detector
go test -run '^$' -fuzz '^FuzzParse$' -fuzztime 20s ./internal/keyval   # fuzz one target

Only one fuzz target can run per package invocation, so the Makefile parameterizes it (make fuzz FUZZ=FuzzParse FUZZTIME=20s) — see the go-project skill for the Makefile and the go-release skill for the CI wiring.