1
0
mirror of https://github.com/golang/go synced 2024-11-19 11:24:51 -07:00
go/src/testing/sub_test.go

423 lines
10 KiB
Go
Raw Normal View History

// Copyright 2016 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package testing
import (
"io/ioutil"
"sync/atomic"
"time"
)
func TestTestContext(t *T) {
const (
add1 = 0
done = 1
)
// After each of the calls are applied to the context, the
type call struct {
typ int // run or done
// result from applying the call
running int
waiting int
started bool
}
testCases := []struct {
max int
run []call
}{{
max: 1,
run: []call{
{typ: add1, running: 1, waiting: 0, started: true},
{typ: done, running: 0, waiting: 0, started: false},
},
}, {
max: 1,
run: []call{
{typ: add1, running: 1, waiting: 0, started: true},
{typ: add1, running: 1, waiting: 1, started: false},
{typ: done, running: 1, waiting: 0, started: true},
{typ: done, running: 0, waiting: 0, started: false},
{typ: add1, running: 1, waiting: 0, started: true},
},
}, {
max: 3,
run: []call{
{typ: add1, running: 1, waiting: 0, started: true},
{typ: add1, running: 2, waiting: 0, started: true},
{typ: add1, running: 3, waiting: 0, started: true},
{typ: add1, running: 3, waiting: 1, started: false},
{typ: add1, running: 3, waiting: 2, started: false},
{typ: add1, running: 3, waiting: 3, started: false},
{typ: done, running: 3, waiting: 2, started: true},
{typ: add1, running: 3, waiting: 3, started: false},
{typ: done, running: 3, waiting: 2, started: true},
{typ: done, running: 3, waiting: 1, started: true},
{typ: done, running: 3, waiting: 0, started: true},
{typ: done, running: 2, waiting: 0, started: false},
{typ: done, running: 1, waiting: 0, started: false},
{typ: done, running: 0, waiting: 0, started: false},
},
}}
for i, tc := range testCases {
ctx := &testContext{
startParallel: make(chan bool),
maxParallel: tc.max,
}
for j, call := range tc.run {
doCall := func(f func()) chan bool {
done := make(chan bool)
go func() {
f()
done <- true
}()
return done
}
started := false
switch call.typ {
case add1:
signal := doCall(ctx.waitParallel)
select {
case <-signal:
started = true
case ctx.startParallel <- true:
<-signal
}
case done:
signal := doCall(ctx.release)
select {
case <-signal:
case <-ctx.startParallel:
started = true
<-signal
}
}
if started != call.started {
t.Errorf("%d:%d:started: got %v; want %v", i, j, started, call.started)
}
if ctx.running != call.running {
t.Errorf("%d:%d:running: got %v; want %v", i, j, ctx.running, call.running)
}
if ctx.numWaiting != call.waiting {
t.Errorf("%d:%d:waiting: got %v; want %v", i, j, ctx.numWaiting, call.waiting)
}
}
}
}
// TODO: remove this stub when API is exposed
func (t *T) Run(name string, f func(t *T)) bool { return t.run(name, f) }
func TestTRun(t *T) {
realTest := t
testCases := []struct {
desc string
ok bool
maxPar int
f func(*T)
}{{
desc: "failnow skips future sequential and parallel tests at same level",
ok: false,
maxPar: 1,
f: func(t *T) {
ranSeq := false
ranPar := false
t.Run("", func(t *T) {
t.Run("par", func(t *T) {
t.Parallel()
ranPar = true
})
t.Run("seq", func(t *T) {
ranSeq = true
})
t.FailNow()
t.Run("seq", func(t *T) {
realTest.Error("test must be skipped")
})
t.Run("par", func(t *T) {
t.Parallel()
realTest.Error("test must be skipped.")
})
})
if !ranPar {
realTest.Error("parallel test was not run")
}
if !ranSeq {
realTest.Error("sequential test was not run")
}
},
}, {
desc: "failure in parallel test propagates upwards",
ok: false,
maxPar: 1,
f: func(t *T) {
t.Run("", func(t *T) {
t.Parallel()
t.Run("par", func(t *T) {
t.Parallel()
t.Fail()
})
})
},
}, {
desc: "use Run to locally synchronize parallelism",
ok: true,
maxPar: 1,
f: func(t *T) {
var count uint32
t.Run("waitGroup", func(t *T) {
for i := 0; i < 4; i++ {
t.Run("par", func(t *T) {
t.Parallel()
atomic.AddUint32(&count, 1)
})
}
})
if count != 4 {
t.Errorf("count was %d; want 4", count)
}
},
}, {
desc: "run no more than *parallel tests concurrently",
ok: true,
maxPar: 4,
f: func(t *T) {
max := 0
in := make(chan int)
out := make(chan int)
ctx := t.context
t.Run("wait", func(t *T) {
t.Run("controller", func(t *T) {
// Verify sequential tests don't skew counts.
t.Run("seq1", func(t *T) {})
t.Run("seq2", func(t *T) {})
t.Run("seq3", func(t *T) {})
t.Parallel()
for i := 0; i < 80; i++ {
ctx.mu.Lock()
if ctx.running > max {
max = ctx.running
}
ctx.mu.Unlock()
<-in
// force a minimum to avoid a race, although it works
// without it.
if i >= ctx.maxParallel-2 { // max - this - 1
out <- i
}
}
close(out)
})
// Ensure we don't exceed the maximum even with nested parallelism.
for i := 0; i < 2; i++ {
t.Run("", func(t *T) {
t.Parallel()
for j := 0; j < 40; j++ {
t.Run("", func(t *T) {
t.Run("seq1", func(t *T) {})
t.Run("seq2", func(t *T) {})
t.Parallel()
in <- j
<-out
})
}
})
}
})
if max != ctx.maxParallel {
realTest.Errorf("max: got %d; want: %d", max, ctx.maxParallel)
}
},
}, {
desc: "alternate sequential and parallel",
// Sequential tests should partake in the counting of running threads.
// Otherwise, if one runs parallel subtests in sequential tests that are
// itself subtests of parallel tests, the counts can get askew.
ok: true,
maxPar: 1,
f: func(t *T) {
t.Run("a", func(t *T) {
t.Parallel()
t.Run("b", func(t *T) {
// Sequential: ensure running count is decremented.
t.Run("c", func(t *T) {
t.Parallel()
})
})
})
},
}, {
desc: "alternate sequential and parallel 2",
// Sequential tests should partake in the counting of running threads.
// Otherwise, if one runs parallel subtests in sequential tests that are
// itself subtests of parallel tests, the counts can get askew.
ok: true,
maxPar: 2,
f: func(t *T) {
for i := 0; i < 2; i++ {
t.Run("a", func(t *T) {
t.Parallel()
time.Sleep(time.Nanosecond)
for i := 0; i < 2; i++ {
t.Run("b", func(t *T) {
time.Sleep(time.Nanosecond)
for i := 0; i < 2; i++ {
t.Run("c", func(t *T) {
t.Parallel()
time.Sleep(time.Nanosecond)
})
}
})
}
})
}
},
}, {
desc: "stress test",
ok: true,
maxPar: 4,
f: func(t *T) {
t.Parallel()
for i := 0; i < 12; i++ {
t.Run("a", func(t *T) {
t.Parallel()
time.Sleep(time.Nanosecond)
for i := 0; i < 12; i++ {
t.Run("b", func(t *T) {
time.Sleep(time.Nanosecond)
for i := 0; i < 12; i++ {
t.Run("c", func(t *T) {
t.Parallel()
time.Sleep(time.Nanosecond)
t.Run("d1", func(t *T) {})
t.Run("d2", func(t *T) {})
t.Run("d3", func(t *T) {})
t.Run("d4", func(t *T) {})
})
}
})
}
})
}
},
}}
for _, tc := range testCases {
ctx := newTestContext(tc.maxPar)
root := &T{
common: common{
barrier: make(chan bool),
w: ioutil.Discard,
},
context: ctx,
}
ok := root.Run(tc.desc, tc.f)
ctx.release()
if ok != tc.ok {
t.Errorf("%s:ok: got %v; want %v", tc.desc, ok, tc.ok)
}
if ok != !root.Failed() {
t.Errorf("%s:root failed: got %v; want %v", tc.desc, !ok, root.Failed())
}
if ctx.running != 0 || ctx.numWaiting != 0 {
t.Errorf("%s:running and waiting non-zero: got %d and %d", tc.desc, ctx.running, ctx.numWaiting)
}
}
}
// TODO: remove this stub when API is exposed
func (b *B) Run(name string, f func(b *B)) bool { return b.runBench(name, f) }
func TestBRun(t *T) {
work := func(b *B) {
for i := 0; i < b.N; i++ {
time.Sleep(time.Nanosecond)
}
}
testCases := []struct {
desc string
failed bool
f func(*B)
}{{
desc: "simulate sequential run of subbenchmarks.",
f: func(b *B) {
b.Run("", func(b *B) { work(b) })
time1 := b.result.NsPerOp()
b.Run("", func(b *B) { work(b) })
time2 := b.result.NsPerOp()
if time1 >= time2 {
t.Errorf("no time spent in benchmark t1 >= t2 (%d >= %d)", time1, time2)
}
},
}, {
desc: "bytes set by all benchmarks",
f: func(b *B) {
b.Run("", func(b *B) { b.SetBytes(10); work(b) })
b.Run("", func(b *B) { b.SetBytes(10); work(b) })
if b.result.Bytes != 20 {
t.Errorf("bytes: got: %d; want 20", b.result.Bytes)
}
},
}, {
desc: "bytes set by some benchmarks",
// In this case the bytes result is meaningless, so it must be 0.
f: func(b *B) {
b.Run("", func(b *B) { b.SetBytes(10); work(b) })
b.Run("", func(b *B) { work(b) })
b.Run("", func(b *B) { b.SetBytes(10); work(b) })
if b.result.Bytes != 0 {
t.Errorf("bytes: got: %d; want 0", b.result.Bytes)
}
},
}, {
desc: "failure carried over to root",
failed: true,
f: func(b *B) { b.Fail() },
}, {
desc: "memory allocation",
f: func(b *B) {
const bufSize = 256
alloc := func(b *B) {
var buf [bufSize]byte
for i := 0; i < b.N; i++ {
_ = append([]byte(nil), buf[:]...)
}
}
b.Run("", func(b *B) { alloc(b) })
b.Run("", func(b *B) { alloc(b) })
if got := b.result.MemAllocs; got != 2 {
t.Errorf("MemAllocs was %v; want 2", got)
}
if got := b.result.MemBytes; got != 2*bufSize {
t.Errorf("MemBytes was %v; want %v", got, 2*bufSize)
}
},
}}
for _, tc := range testCases {
var ok bool
// This is almost like the Benchmark function, except that we override
// the benchtime and catch the failure result of the subbenchmark.
root := &B{
common: common{
signal: make(chan bool),
},
benchFunc: func(b *B) { ok = b.Run("test", tc.f) }, // Use Run to catch failure.
benchTime: time.Microsecond,
}
root.run()
if ok != !tc.failed {
t.Errorf("%s:ok: got %v; want %v", tc.desc, ok, !tc.failed)
}
if !ok != root.Failed() {
t.Errorf("%s:root failed: got %v; want %v", tc.desc, !ok, root.Failed())
}
// All tests are run as subtests
if root.result.N != 1 {
t.Errorf("%s: N for parent benchmark was %d; want 1", tc.desc, root.result.N)
}
}
}