math/rand: use fastrand64 if possible

Now that the top-level math/rand functions are auto-seeded by default (issue #54880), use the runtime fastrand64 function when 1) Seed has not been called; 2) the GODEBUG randautoseed=0 is not used. The benchmarks run quickly and are relatively noisy, but they show significant improvements for parallel calls to the top-level functions. goos: linux goarch: amd64 pkg: math/rand cpu: 11th Gen Intel(R) Core(TM) i7-11850H @ 2.50GHz │ /tmp/foo.1 │ /tmp/foo.2 │ │ sec/op │ sec/op vs base │ Int63Threadsafe-16 11.605n ± 1% 3.094n ± 1% -73.34% (p=0.000 n=10) Int63ThreadsafeParallel-16 67.8350n ± 2% 0.4000n ± 1% -99.41% (p=0.000 n=10) Int63Unthreadsafe-16 1.947n ± 3% 1.924n ± 2% ~ (p=0.189 n=10) Intn1000-16 4.295n ± 2% 4.287n ± 3% ~ (p=0.517 n=10) Int63n1000-16 4.379n ± 0% 4.192n ± 2% -4.27% (p=0.000 n=10) Int31n1000-16 3.641n ± 3% 3.506n ± 0% -3.69% (p=0.000 n=10) Float32-16 3.330n ± 7% 3.250n ± 2% -2.40% (p=0.017 n=10) Float64-16 2.194n ± 6% 2.056n ± 4% -6.31% (p=0.004 n=10) Perm3-16 43.39n ± 9% 38.28n ± 12% -11.77% (p=0.015 n=10) Perm30-16 324.4n ± 6% 315.9n ± 19% ~ (p=0.315 n=10) Perm30ViaShuffle-16 175.4n ± 1% 143.6n ± 2% -18.15% (p=0.000 n=10) ShuffleOverhead-16 223.4n ± 2% 215.8n ± 1% -3.38% (p=0.000 n=10) Read3-16 5.428n ± 3% 5.406n ± 2% ~ (p=0.780 n=10) Read64-16 41.55n ± 5% 40.14n ± 3% -3.38% (p=0.000 n=10) Read1000-16 622.9n ± 4% 594.9n ± 2% -4.50% (p=0.000 n=10) Concurrent-16 136.300n ± 2% 4.647n ± 26% -96.59% (p=0.000 n=10) geomean 23.40n 12.15n -48.08% Fixes #49892 Change-Id: Iba75b326145512ab0b7ece233b98ac3d4e1fb504 Reviewed-on: https://go-review.googlesource.com/c/go/+/465037 Run-TryBot: Ian Lance Taylor <iant@golang.org> TryBot-Result: Gopher Robot <gobot@golang.org> Reviewed-by: Ian Lance Taylor <iant@google.com> Reviewed-by: Brad Fitzpatrick <bradfitz@golang.org> Reviewed-by: Russ Cox <rsc@golang.org> Auto-Submit: Ian Lance Taylor <iant@google.com>
2024-11-17 04:34:46 -07:00 · 2023-02-02 22:13:18 -08:00 · 2023-02-02 22:13:18 -08:00 · 0b9974d3f0
commit 0b9974d3f0
parent f63ee8b2c7
3 changed files with 284 additions and 44 deletions
--- a/src/math/rand/default_test.go
+++ b/src/math/rand/default_test.go
@ -0,0 +1,148 @@
 // Copyright 2023 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 rand_test
 import (
 	"fmt"
 	"internal/race"
 	"internal/testenv"
 	. "math/rand"
 	"os"
 	"runtime"
 	"strconv"
 	"sync"
 	"testing"
 )
 // Test that racy access to the default functions behaves reasonably.
 func TestDefaultRace(t *testing.T) {
 	// Skip the test in short mode, but even in short mode run
 	// the test if we are using the race detector, because part
 	// of this is to see whether the race detector reports any problems.
 	if testing.Short() && !race.Enabled {
 		t.Skip("skipping starting another executable in short mode")
 	}
 	const env = "GO_RAND_TEST_HELPER_CODE"
 	if v := os.Getenv(env); v != "" {
 		doDefaultTest(t, v)
 		return
 	}
 	t.Parallel()
 	for i := 0; i < 6; i++ {
 		i := i
 		t.Run(strconv.Itoa(i), func(t *testing.T) {
 			t.Parallel()
 			exe, err := os.Executable()
 			if err != nil {
 				exe = os.Args[0]
 			}
 			cmd := testenv.Command(t, exe, "-test.run=TestDefaultRace")
 			cmd = testenv.CleanCmdEnv(cmd)
 			cmd.Env = append(cmd.Env, fmt.Sprintf("GO_RAND_TEST_HELPER_CODE=%d", i/2))
 			if i%2 != 0 {
 				cmd.Env = append(cmd.Env, "GODEBUG=randautoseed=0")
 			}
 			out, err := cmd.CombinedOutput()
 			if len(out) > 0 {
 				t.Logf("%s", out)
 			}
 			if err != nil {
 				t.Error(err)
 			}
 		})
 	}
 }
 // doDefaultTest should be run before there have been any calls to the
 // top-level math/rand functions. Make sure that we can make concurrent
 // calls to top-level functions and to Seed without any duplicate values.
 // This will also give the race detector a change to report any problems.
 func doDefaultTest(t *testing.T, v string) {
 	code, err := strconv.Atoi(v)
 	if err != nil {
 		t.Fatalf("internal error: unrecognized code %q", v)
 	}
 	goroutines := runtime.GOMAXPROCS(0)
 	if goroutines < 4 {
 		goroutines = 4
 	}
 	ch := make(chan uint64, goroutines*3)
 	var wg sync.WaitGroup
 	// The various tests below should not cause race detector reports
 	// and should not produce duplicate results.
 	//
 	// Note: these tests can theoretically fail when using fastrand64
 	// in that it is possible to coincidentally get the same random
 	// number twice. That could happen something like 1 / 2**64 times,
 	// which is rare enough that it may never happen. We don't worry
 	// about that case.
 	switch code {
 	case 0:
 		// Call Seed and Uint64 concurrently.
 		wg.Add(goroutines)
 		for i := 0; i < goroutines; i++ {
 			go func(s int64) {
 				defer wg.Done()
 				Seed(s)
 			}(int64(i) + 100)
 		}
 		wg.Add(goroutines)
 		for i := 0; i < goroutines; i++ {
 			go func() {
 				defer wg.Done()
 				ch <- Uint64()
 			}()
 		}
 	case 1:
 		// Call Uint64 concurrently with no Seed.
 		wg.Add(goroutines)
 		for i := 0; i < goroutines; i++ {
 			go func() {
 				defer wg.Done()
 				ch <- Uint64()
 			}()
 		}
 	case 2:
 		// Start with Uint64 to pick the fast source, then call
 		// Seed and Uint64 concurrently.
 		ch <- Uint64()
 		wg.Add(goroutines)
 		for i := 0; i < goroutines; i++ {
 			go func(s int64) {
 				defer wg.Done()
 				Seed(s)
 			}(int64(i) + 100)
 		}
 		wg.Add(goroutines)
 		for i := 0; i < goroutines; i++ {
 			go func() {
 				defer wg.Done()
 				ch <- Uint64()
 			}()
 		}
 	default:
 		t.Fatalf("internal error: unrecognized code %d", code)
 	}
 	go func() {
 		wg.Wait()
 		close(ch)
 	}()
 	m := make(map[uint64]bool)
 	for i := range ch {
 		if m[i] {
 			t.Errorf("saw %d twice", i)
 		}
 		m[i] = true
 	}
 }
--- a/src/math/rand/rand.go
+++ b/src/math/rand/rand.go
@ -20,6 +20,7 @@ package rand
 import (
 	"internal/godebug"
 	"sync"
 	"sync/atomic"
 	_ "unsafe" // for go:linkname
 )
@ -269,8 +270,11 @@ func (r *Rand) Shuffle(n int, swap func(i, j int)) {
 // always returns len(p) and a nil error.
 // Read should not be called concurrently with any other Rand method.
 func (r *Rand) Read(p []byte) (n int, err error) {
-	if lk, ok := r.src.(*lockedSource); ok {
+	switch src := r.src.(type) {
-		return lk.read(p, &r.readVal, &r.readPos)
+	case *lockedSource:
 		return src.read(p, &r.readVal, &r.readPos)
 	case *fastSource:
 		return src.read(p, &r.readVal, &r.readPos)
 	}
 	return read(p, r.src, &r.readVal, &r.readPos)
 }
@ -301,7 +305,75 @@ func read(p []byte, src Source, readVal *int64, readPos *int8) (n int, err error
 * Top-level convenience functions
 */
-var globalRand = New(new(lockedSource))
+// globalRandGenerator is the source of random numbers for the top-level
 // convenience functions. When possible it uses the runtime fastrand64
 // function to avoid locking. This is not possible if the user called Seed,
 // either explicitly or implicitly via GODEBUG=randautoseed=0.
 var globalRandGenerator atomic.Pointer[Rand]
 var randautoseed = godebug.New("randautoseed")
 // globalRand returns the generator to use for the top-level convenience
 // functions.
 func globalRand() *Rand {
 	if r := globalRandGenerator.Load(); r != nil {
 		return r
 	}
 	// This is the first call. Initialize based on GODEBUG.
 	var r *Rand
 	if randautoseed.Value() == "0" {
 		randautoseed.IncNonDefault()
 		r = New(new(lockedSource))
 		r.Seed(1)
 	} else {
 		r = &Rand{
 			src: &fastSource{},
 			s64: &fastSource{},
 		}
 	}
 	if !globalRandGenerator.CompareAndSwap(nil, r) {
 		// Two different goroutines called some top-level
 		// function at the same time. While the results in
 		// that case are unpredictable, if we just use r here,
 		// and we are using a seed, we will most likely return
 		// the same value for both calls. That doesn't seem ideal.
 		// Just use the first one to get in.
 		return globalRandGenerator.Load()
 	}
 	return r
 }
 //go:linkname fastrand64
 func fastrand64() uint64
 // fastSource is an implementation of Source64 that uses the runtime
 // fastrand functions.
 type fastSource struct {
 	// The mutex is used to avoid race conditions in Read.
 	mu sync.Mutex
 }
 func (*fastSource) Int63() int64 {
 	return int64(fastrand64() & rngMask)
 }
 func (*fastSource) Seed(int64) {
 	panic("internal error: call to fastSource.Seed")
 }
 func (*fastSource) Uint64() uint64 {
 	return fastrand64()
 }
 func (fs *fastSource) read(p []byte, readVal *int64, readPos *int8) (n int, err error) {
 	fs.mu.Lock()
 	n, err = read(p, fs, readVal, readPos)
 	fs.mu.Unlock()
 	return
 }
 // Seed uses the provided seed value to initialize the default Source to a
 // deterministic state. Seed values that have the same remainder when
@ -321,65 +393,90 @@ var globalRand = New(new(lockedSource))
 // from the global random source. To avoid such breakages, programs
 // that need a specific result sequence should use NewRand(NewSource(seed))
 // to obtain a random generator that other packages cannot access.
-func Seed(seed int64) { globalRand.Seed(seed) }
+func Seed(seed int64) {
 	orig := globalRandGenerator.Load()
 	// If we are already using a lockedSource, we can just re-seed it.
 	if orig != nil {
 		if _, ok := orig.src.(*lockedSource); ok {
 			orig.Seed(seed)
 			return
 		}
 	}
 	// Otherwise either
 	// 1) orig == nil, which is the normal case when Seed is the first
 	// top-level function to be called, or
 	// 2) orig is already a fastSource, in which case we need to change
 	// to a lockedSource.
 	// Either way we do the same thing.
 	r := New(new(lockedSource))
 	r.Seed(seed)
 	if !globalRandGenerator.CompareAndSwap(orig, r) {
 		// Something changed underfoot. Retry to be safe.
 		Seed(seed)
 	}
 }
 // Int63 returns a non-negative pseudo-random 63-bit integer as an int64
 // from the default Source.
-func Int63() int64 { return globalRand.Int63() }
+func Int63() int64 { return globalRand().Int63() }
 // Uint32 returns a pseudo-random 32-bit value as a uint32
 // from the default Source.
-func Uint32() uint32 { return globalRand.Uint32() }
+func Uint32() uint32 { return globalRand().Uint32() }
 // Uint64 returns a pseudo-random 64-bit value as a uint64
 // from the default Source.
-func Uint64() uint64 { return globalRand.Uint64() }
+func Uint64() uint64 { return globalRand().Uint64() }
 // Int31 returns a non-negative pseudo-random 31-bit integer as an int32
 // from the default Source.
-func Int31() int32 { return globalRand.Int31() }
+func Int31() int32 { return globalRand().Int31() }
 // Int returns a non-negative pseudo-random int from the default Source.
-func Int() int { return globalRand.Int() }
+func Int() int { return globalRand().Int() }
 // Int63n returns, as an int64, a non-negative pseudo-random number in the half-open interval [0,n)
 // from the default Source.
 // It panics if n <= 0.
-func Int63n(n int64) int64 { return globalRand.Int63n(n) }
+func Int63n(n int64) int64 { return globalRand().Int63n(n) }
 // Int31n returns, as an int32, a non-negative pseudo-random number in the half-open interval [0,n)
 // from the default Source.
 // It panics if n <= 0.
-func Int31n(n int32) int32 { return globalRand.Int31n(n) }
+func Int31n(n int32) int32 { return globalRand().Int31n(n) }
 // Intn returns, as an int, a non-negative pseudo-random number in the half-open interval [0,n)
 // from the default Source.
 // It panics if n <= 0.
-func Intn(n int) int { return globalRand.Intn(n) }
+func Intn(n int) int { return globalRand().Intn(n) }
 // Float64 returns, as a float64, a pseudo-random number in the half-open interval [0.0,1.0)
 // from the default Source.
-func Float64() float64 { return globalRand.Float64() }
+func Float64() float64 { return globalRand().Float64() }
 // Float32 returns, as a float32, a pseudo-random number in the half-open interval [0.0,1.0)
 // from the default Source.
-func Float32() float32 { return globalRand.Float32() }
+func Float32() float32 { return globalRand().Float32() }
 // Perm returns, as a slice of n ints, a pseudo-random permutation of the integers
 // in the half-open interval [0,n) from the default Source.
-func Perm(n int) []int { return globalRand.Perm(n) }
+func Perm(n int) []int { return globalRand().Perm(n) }
 // Shuffle pseudo-randomizes the order of elements using the default Source.
 // n is the number of elements. Shuffle panics if n < 0.
 // swap swaps the elements with indexes i and j.
-func Shuffle(n int, swap func(i, j int)) { globalRand.Shuffle(n, swap) }
+func Shuffle(n int, swap func(i, j int)) { globalRand().Shuffle(n, swap) }
 // Read generates len(p) random bytes from the default Source and
 // writes them into p. It always returns len(p) and a nil error.
 // Read, unlike the Rand.Read method, is safe for concurrent use.
 //
 // Deprecated: For almost all use cases, crypto/rand.Read is more appropriate.
-func Read(p []byte) (n int, err error) { return globalRand.Read(p) }
+func Read(p []byte) (n int, err error) { return globalRand().Read(p) }
 // NormFloat64 returns a normally distributed float64 in the range
 // [-math.MaxFloat64, +math.MaxFloat64] with
@ -389,7 +486,7 @@ func Read(p []byte) (n int, err error) { return globalRand.Read(p) }
 // adjust the output using:
 //
 //	sample = NormFloat64() * desiredStdDev + desiredMean
-func NormFloat64() float64 { return globalRand.NormFloat64() }
+func NormFloat64() float64 { return globalRand().NormFloat64() }
 // ExpFloat64 returns an exponentially distributed float64 in the range
 // (0, +math.MaxFloat64] with an exponential distribution whose rate parameter
@ -398,44 +495,23 @@ func NormFloat64() float64 { return globalRand.NormFloat64() }
 // callers can adjust the output using:
 //
 //	sample = ExpFloat64() / desiredRateParameter
-func ExpFloat64() float64 { return globalRand.ExpFloat64() }
+func ExpFloat64() float64 { return globalRand().ExpFloat64() }
 type lockedSource struct {
 	lk sync.Mutex
-	s  *rngSource // nil if not yet allocated
+	s  *rngSource
 }
 //go:linkname fastrand64
 func fastrand64() uint64
 var randautoseed = godebug.New("randautoseed")
 // source returns r.s, allocating and seeding it if needed.
 // The caller must have locked r.
 func (r *lockedSource) source() *rngSource {
 	if r.s == nil {
 		var seed int64
 		if randautoseed.Value() == "0" {
 			randautoseed.IncNonDefault()
 			seed = 1
 		} else {
 			seed = int64(fastrand64())
 		}
 		r.s = newSource(seed)
 	}
 	return r.s
 }
 func (r *lockedSource) Int63() (n int64) {
 	r.lk.Lock()
-	n = r.source().Int63()
+	n = r.s.Int63()
 	r.lk.Unlock()
 	return
 }
 func (r *lockedSource) Uint64() (n uint64) {
 	r.lk.Lock()
-	n = r.source().Uint64()
+	n = r.s.Uint64()
 	r.lk.Unlock()
 	return
 }
@ -467,7 +543,7 @@ func (r *lockedSource) seed(seed int64) {
 // read implements Read for a lockedSource without a race condition.
 func (r *lockedSource) read(p []byte, readVal *int64, readPos *int8) (n int, err error) {
 	r.lk.Lock()
-	n, err = read(p, r.source(), readVal, readPos)
+	n, err = read(p, r.s, readVal, readPos)
 	r.lk.Unlock()
 	return
 }
--- a/src/math/rand/rand_test.go
+++ b/src/math/rand/rand_test.go
@ -14,6 +14,7 @@ import (
 	. "math/rand"
 	"os"
 	"runtime"
 	"sync"
 	"testing"
 	"testing/iotest"
 )
@ -683,3 +684,18 @@ func BenchmarkRead1000(b *testing.B) {
 		r.Read(buf)
 	}
 }
 func BenchmarkConcurrent(b *testing.B) {
 	const goroutines = 4
 	var wg sync.WaitGroup
 	wg.Add(goroutines)
 	for i := 0; i < goroutines; i++ {
 		go func() {
 			defer wg.Done()
 			for n := b.N; n > 0; n-- {
 				Int63()
 			}
 		}()
 	}
 	wg.Wait()
 }