src/runtime/rand.go - go - Git at Google

 // 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.

 // Random number generation

 package runtime

 import (
 	"internal/chacha8rand"
 	"internal/goarch"
 	"runtime/internal/math"
 	"unsafe"
 	_ "unsafe" // for go:linkname
 )

 // OS-specific startup can set startupRand if the OS passes
 // random data to the process at startup time.
 // For example Linux passes 16 bytes in the auxv vector.
 var startupRand []byte

 // globalRand holds the global random state.
 // It is only used at startup and for creating new m's.
 // Otherwise the per-m random state should be used
 // by calling goodrand.
 var globalRand struct {
 	lock  mutex
 	seed  [32]byte
 	state chacha8rand.State
 	init  bool
 }

 var readRandomFailed bool

 // randinit initializes the global random state.
 // It must be called before any use of grand.
 func randinit() {
 	lock(&globalRand.lock)
 	if globalRand.init {
 		fatal("randinit twice")
 	}

 	seed := &globalRand.seed
 	if startupRand != nil {
 		for i, c := range startupRand {
 			seed[i%len(seed)] ^= c
 		}
 		clear(startupRand)
 		startupRand = nil
 	} else {
 		if readRandom(seed[:]) != len(seed) {
 			// readRandom should never fail, but if it does we'd rather
 			// not make Go binaries completely unusable, so make up
 			// some random data based on the current time.
 			readRandomFailed = true
 			readTimeRandom(seed[:])
 		}
 	}
 	globalRand.state.Init(*seed)
 	clear(seed[:])
 	globalRand.init = true
 	unlock(&globalRand.lock)
 }

 // readTimeRandom stretches any entropy in the current time
 // into entropy the length of r and XORs it into r.
 // This is a fallback for when readRandom does not read
 // the full requested amount.
 // Whatever entropy r already contained is preserved.
 func readTimeRandom(r []byte) {
 	// Inspired by wyrand.
 	// An earlier version of this code used getg().m.procid as well,
 	// but note that this is called so early in startup that procid
 	// is not initialized yet.
 	v := uint64(nanotime())
 	for len(r) > 0 {
 		v ^= 0xa0761d6478bd642f
 		v *= 0xe7037ed1a0b428db
 		size := 8
 		if len(r) < 8 {
 			size = len(r)
 		}
 		for i := 0; i < size; i++ {
 			r[i] ^= byte(v >> (8 * i))
 		}
 		r = r[size:]
 		v = v>>32 | v<<32
 	}
 }

 // bootstrapRand returns a random uint64 from the global random generator.
 func bootstrapRand() uint64 {
 	lock(&globalRand.lock)
 	if !globalRand.init {
 		fatal("randinit missed")
 	}
 	for {
 		if x, ok := globalRand.state.Next(); ok {
 			unlock(&globalRand.lock)
 			return x
 		}
 		globalRand.state.Refill()
 	}
 }

 // bootstrapRandReseed reseeds the bootstrap random number generator,
 // clearing from memory any trace of previously returned random numbers.
 func bootstrapRandReseed() {
 	lock(&globalRand.lock)
 	if !globalRand.init {
 		fatal("randinit missed")
 	}
 	globalRand.state.Reseed()
 	unlock(&globalRand.lock)
 }

 // rand32 is uint32(rand()), called from compiler-generated code.
 //
 //go:nosplit
 func rand32() uint32 {
 	return uint32(rand())
 }

 // rand returns a random uint64 from the per-m chacha8 state.
 // Do not change signature: used via linkname from other packages.
 //
 //go:nosplit
 //go:linkname rand
 func rand() uint64 {
 	// Note: We avoid acquirem here so that in the fast path
 	// there is just a getg, an inlined c.Next, and a return.
 	// The performance difference on a 16-core AMD is
 	// 3.7ns/call this way versus 4.3ns/call with acquirem (+16%).
 	mp := getg().m
 	c := &mp.chacha8
 	for {
 		// Note: c.Next is marked nosplit,
 		// so we don't need to use mp.locks
 		// on the fast path, which is that the
 		// first attempt succeeds.
 		x, ok := c.Next()
 		if ok {
 			return x
 		}
 		mp.locks++ // hold m even though c.Refill may do stack split checks
 		c.Refill()
 		mp.locks--
 	}
 }

 // mrandinit initializes the random state of an m.
 func mrandinit(mp *m) {
 	var seed [4]uint64
 	for i := range seed {
 		seed[i] = bootstrapRand()
 	}
 	bootstrapRandReseed() // erase key we just extracted
 	mp.chacha8.Init64(seed)
 	mp.cheaprand = rand()
 }

 // randn is like rand() % n but faster.
 // Do not change signature: used via linkname from other packages.
 //
 //go:nosplit
 //go:linkname randn
 func randn(n uint32) uint32 {
 	// See https://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
 	return uint32((uint64(uint32(rand())) * uint64(n)) >> 32)
 }

 // cheaprand is a non-cryptographic-quality 32-bit random generator
 // suitable for calling at very high frequency (such as during scheduling decisions)
 // and at sensitive moments in the runtime (such as during stack unwinding).
 // it is "cheap" in the sense of both expense and quality.
 //
 // cheaprand must not be exported to other packages:
 // the rule is that other packages using runtime-provided
 // randomness must always use rand.
 //
 //go:nosplit
 func cheaprand() uint32 {
 	mp := getg().m
 	// Implement wyrand: https://github.com/wangyi-fudan/wyhash
 	// Only the platform that math.Mul64 can be lowered
 	// by the compiler should be in this list.
 	if goarch.IsAmd64|goarch.IsArm64|goarch.IsPpc64|
 		goarch.IsPpc64le|goarch.IsMips64|goarch.IsMips64le|
 		goarch.IsS390x|goarch.IsRiscv64|goarch.IsLoong64 == 1 {
 		mp.cheaprand += 0xa0761d6478bd642f
 		hi, lo := math.Mul64(mp.cheaprand, mp.cheaprand^0xe7037ed1a0b428db)
 		return uint32(hi ^ lo)
 	}

 	// Implement xorshift64+: 2 32-bit xorshift sequences added together.
 	// Shift triplet [17,7,16] was calculated as indicated in Marsaglia's
 	// Xorshift paper: https://www.jstatsoft.org/article/view/v008i14/xorshift.pdf
 	// This generator passes the SmallCrush suite, part of TestU01 framework:
 	// http://simul.iro.umontreal.ca/testu01/tu01.html
 	t := (*[2]uint32)(unsafe.Pointer(&mp.cheaprand))
 	s1, s0 := t[0], t[1]
 	s1 ^= s1 << 17
 	s1 = s1 ^ s0 ^ s1>>7 ^ s0>>16
 	t[0], t[1] = s0, s1
 	return s0 + s1
 }

 // cheaprand64 is a non-cryptographic-quality 63-bit random generator
 // suitable for calling at very high frequency (such as during sampling decisions).
 // it is "cheap" in the sense of both expense and quality.
 //
 // cheaprand64 must not be exported to other packages:
 // the rule is that other packages using runtime-provided
 // randomness must always use rand.
 //
 //go:nosplit
 func cheaprand64() int64 {
 	return int64(cheaprand())<<31 ^ int64(cheaprand())
 }

 // cheaprandn is like cheaprand() % n but faster.
 //
 // cheaprandn must not be exported to other packages:
 // the rule is that other packages using runtime-provided
 // randomness must always use randn.
 //
 //go:nosplit
 func cheaprandn(n uint32) uint32 {
 	// See https://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
 	return uint32((uint64(cheaprand()) * uint64(n)) >> 32)
 }

 // Too much legacy code has go:linkname references
 // to runtime.fastrand and friends, so keep these around for now.
 // Code should migrate to math/rand/v2.Uint64,
 // which is just as fast, but that's only available in Go 1.22+.
 // It would be reasonable to remove these in Go 1.24.
 // Do not call these from package runtime.

 //go:linkname legacy_fastrand runtime.fastrand
 func legacy_fastrand() uint32 {
 	return uint32(rand())
 }

 //go:linkname legacy_fastrandn runtime.fastrandn
 func legacy_fastrandn(n uint32) uint32 {
 	return randn(n)
 }

 //go:linkname legacy_fastrand64 runtime.fastrand64
 func legacy_fastrand64() uint64 {
 	return rand()
 }
	// 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.

	// Random number generation

	package runtime

	import (
	"internal/chacha8rand"
	"internal/goarch"
	"runtime/internal/math"
	"unsafe"
	_ "unsafe" // for go:linkname
	)

	// OS-specific startup can set startupRand if the OS passes
	// random data to the process at startup time.
	// For example Linux passes 16 bytes in the auxv vector.
	var startupRand []byte

	// globalRand holds the global random state.
	// It is only used at startup and for creating new m's.
	// Otherwise the per-m random state should be used
	// by calling goodrand.
	var globalRand struct {
	lock mutex
	seed [32]byte
	state chacha8rand.State
	init bool
	}

	var readRandomFailed bool

	// randinit initializes the global random state.
	// It must be called before any use of grand.
	func randinit() {
	lock(&globalRand.lock)
	if globalRand.init {
	fatal("randinit twice")
	}

	seed := &globalRand.seed
	if startupRand != nil {
	for i, c := range startupRand {
	seed[i%len(seed)] ^= c
	}
	clear(startupRand)
	startupRand = nil
	} else {
	if readRandom(seed[:]) != len(seed) {
	// readRandom should never fail, but if it does we'd rather
	// not make Go binaries completely unusable, so make up
	// some random data based on the current time.
	readRandomFailed = true
	readTimeRandom(seed[:])
	}
	}
	globalRand.state.Init(*seed)
	clear(seed[:])
	globalRand.init = true
	unlock(&globalRand.lock)
	}

	// readTimeRandom stretches any entropy in the current time
	// into entropy the length of r and XORs it into r.
	// This is a fallback for when readRandom does not read
	// the full requested amount.
	// Whatever entropy r already contained is preserved.
	func readTimeRandom(r []byte) {
	// Inspired by wyrand.
	// An earlier version of this code used getg().m.procid as well,
	// but note that this is called so early in startup that procid
	// is not initialized yet.
	v := uint64(nanotime())
	for len(r) > 0 {
	v ^= 0xa0761d6478bd642f
	v *= 0xe7037ed1a0b428db
	size := 8
	if len(r) < 8 {
	size = len(r)
	}
	for i := 0; i < size; i++ {
	r[i] ^= byte(v >> (8 * i))
	}
	r = r[size:]
	v = v>>32 \| v<<32
	}
	}

	// bootstrapRand returns a random uint64 from the global random generator.
	func bootstrapRand() uint64 {
	lock(&globalRand.lock)
	if !globalRand.init {
	fatal("randinit missed")
	}
	for {
	if x, ok := globalRand.state.Next(); ok {
	unlock(&globalRand.lock)
	return x
	}
	globalRand.state.Refill()
	}
	}

	// bootstrapRandReseed reseeds the bootstrap random number generator,
	// clearing from memory any trace of previously returned random numbers.
	func bootstrapRandReseed() {
	lock(&globalRand.lock)
	if !globalRand.init {
	fatal("randinit missed")
	}
	globalRand.state.Reseed()
	unlock(&globalRand.lock)
	}

	// rand32 is uint32(rand()), called from compiler-generated code.
	//
	//go:nosplit
	func rand32() uint32 {
	return uint32(rand())
	}

	// rand returns a random uint64 from the per-m chacha8 state.
	// Do not change signature: used via linkname from other packages.
	//
	//go:nosplit
	//go:linkname rand
	func rand() uint64 {
	// Note: We avoid acquirem here so that in the fast path
	// there is just a getg, an inlined c.Next, and a return.
	// The performance difference on a 16-core AMD is
	// 3.7ns/call this way versus 4.3ns/call with acquirem (+16%).
	mp := getg().m
	c := &mp.chacha8
	for {
	// Note: c.Next is marked nosplit,
	// so we don't need to use mp.locks
	// on the fast path, which is that the
	// first attempt succeeds.
	x, ok := c.Next()
	if ok {
	return x
	}
	mp.locks++ // hold m even though c.Refill may do stack split checks
	c.Refill()
	mp.locks--
	}
	}

	// mrandinit initializes the random state of an m.
	func mrandinit(mp *m) {
	var seed [4]uint64
	for i := range seed {
	seed[i] = bootstrapRand()
	}
	bootstrapRandReseed() // erase key we just extracted
	mp.chacha8.Init64(seed)
	mp.cheaprand = rand()
	}

	// randn is like rand() % n but faster.
	// Do not change signature: used via linkname from other packages.
	//
	//go:nosplit
	//go:linkname randn
	func randn(n uint32) uint32 {
	// See https://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
	return uint32((uint64(uint32(rand())) * uint64(n)) >> 32)
	}

	// cheaprand is a non-cryptographic-quality 32-bit random generator
	// suitable for calling at very high frequency (such as during scheduling decisions)
	// and at sensitive moments in the runtime (such as during stack unwinding).
	// it is "cheap" in the sense of both expense and quality.
	//
	// cheaprand must not be exported to other packages:
	// the rule is that other packages using runtime-provided
	// randomness must always use rand.
	//
	//go:nosplit
	func cheaprand() uint32 {
	mp := getg().m
	// Implement wyrand: https://github.com/wangyi-fudan/wyhash
	// Only the platform that math.Mul64 can be lowered
	// by the compiler should be in this list.
	if goarch.IsAmd64\|goarch.IsArm64\|goarch.IsPpc64\|
	goarch.IsPpc64le\|goarch.IsMips64\|goarch.IsMips64le\|
	goarch.IsS390x\|goarch.IsRiscv64\|goarch.IsLoong64 == 1 {
	mp.cheaprand += 0xa0761d6478bd642f
	hi, lo := math.Mul64(mp.cheaprand, mp.cheaprand^0xe7037ed1a0b428db)
	return uint32(hi ^ lo)
	}

	// Implement xorshift64+: 2 32-bit xorshift sequences added together.
	// Shift triplet [17,7,16] was calculated as indicated in Marsaglia's
	// Xorshift paper: https://www.jstatsoft.org/article/view/v008i14/xorshift.pdf
	// This generator passes the SmallCrush suite, part of TestU01 framework:
	// http://simul.iro.umontreal.ca/testu01/tu01.html
	t := (*[2]uint32)(unsafe.Pointer(&mp.cheaprand))
	s1, s0 := t[0], t[1]
	s1 ^= s1 << 17
	s1 = s1 ^ s0 ^ s1>>7 ^ s0>>16
	t[0], t[1] = s0, s1
	return s0 + s1
	}

	// cheaprand64 is a non-cryptographic-quality 63-bit random generator
	// suitable for calling at very high frequency (such as during sampling decisions).
	// it is "cheap" in the sense of both expense and quality.
	//
	// cheaprand64 must not be exported to other packages:
	// the rule is that other packages using runtime-provided
	// randomness must always use rand.
	//
	//go:nosplit
	func cheaprand64() int64 {
	return int64(cheaprand())<<31 ^ int64(cheaprand())
	}

	// cheaprandn is like cheaprand() % n but faster.
	//
	// cheaprandn must not be exported to other packages:
	// the rule is that other packages using runtime-provided
	// randomness must always use randn.
	//
	//go:nosplit
	func cheaprandn(n uint32) uint32 {
	// See https://lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
	return uint32((uint64(cheaprand()) * uint64(n)) >> 32)
	}

	// Too much legacy code has go:linkname references
	// to runtime.fastrand and friends, so keep these around for now.
	// Code should migrate to math/rand/v2.Uint64,
	// which is just as fast, but that's only available in Go 1.22+.
	// It would be reasonable to remove these in Go 1.24.
	// Do not call these from package runtime.

	//go:linkname legacy_fastrand runtime.fastrand
	func legacy_fastrand() uint32 {
	return uint32(rand())
	}

	//go:linkname legacy_fastrandn runtime.fastrandn
	func legacy_fastrandn(n uint32) uint32 {
	return randn(n)
	}

	//go:linkname legacy_fastrand64 runtime.fastrand64
	func legacy_fastrand64() uint64 {
	return rand()
	}