libgo: update to Go1.14beta1

Reviewed-on: https://go-review.googlesource.com/c/gofrontend/+/214297

5 files changed, 777 insertions, 40 deletions

diff --git a/libgo/go/hash/crc32/crc32_amd64p32.go b/libgo/go/hash/crc32/crc32_amd64p32.go
deleted file mode 100644
index f61b801..0000000
--- a/libgo/go/hash/crc32/crc32_amd64p32.go
+++ /dev/null
@@ -1,39 +0,0 @@
-// Copyright 2011 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.
-
-// +build ignore
-
-package crc32
-
-import "internal/cpu"
-
-// This file contains the code to call the SSE 4.2 version of the Castagnoli
-// CRC.
-
-// castagnoliSSE42 is defined in crc32_amd64p32.s and uses the SSE4.2 CRC32
-// instruction.
-//go:noescape
-func castagnoliSSE42(crc uint32, p []byte) uint32
-
-func archAvailableCastagnoli() bool {
-	return cpu.X86.HasSSE42
-}
-
-func archInitCastagnoli() {
-	if !cpu.X86.HasSSE42 {
-		panic("not available")
-	}
-	// No initialization necessary.
-}
-
-func archUpdateCastagnoli(crc uint32, p []byte) uint32 {
-	if !cpu.X86.HasSSE42 {
-		panic("not available")
-	}
-	return castagnoliSSE42(crc, p)
-}
-
-func archAvailableIEEE() bool                    { return false }
-func archInitIEEE()                              { panic("not available") }
-func archUpdateIEEE(crc uint32, p []byte) uint32 { panic("not available") }
diff --git a/libgo/go/hash/crc32/crc32_otherarch.go b/libgo/go/hash/crc32/crc32_otherarch.go
index c3acd25..86f9fd9 100644
--- a/libgo/go/hash/crc32/crc32_otherarch.go
+++ b/libgo/go/hash/crc32/crc32_otherarch.go
@@ -2,7 +2,7 @@
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.
 
-// -build !amd64,!amd64p32,!s390x,!ppc64le,!arm64
+// -build !amd64,!s390x,!ppc64le,!arm64
 
 package crc32
 
diff --git a/libgo/go/hash/maphash/maphash.go b/libgo/go/hash/maphash/maphash.go
new file mode 100644
index 0000000..3f406e9
--- /dev/null
+++ b/libgo/go/hash/maphash/maphash.go
@@ -0,0 +1,219 @@
+// Copyright 2019 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 maphash provides hash functions on byte sequences.
+// These hash functions are intended to be used to implement hash tables or
+// other data structures that need to map arbitrary strings or byte
+// sequences to a uniform distribution of integers.
+//
+// The hash functions are collision-resistant but not cryptographically secure.
+// (See crypto/sha256 and crypto/sha512 for cryptographic use.)
+package maphash
+
+import "unsafe"
+
+// A Seed is a random value that selects the specific hash function
+// computed by a Hash. If two Hashes use the same Seeds, they
+// will compute the same hash values for any given input.
+// If two Hashes use different Seeds, they are very likely to compute
+// distinct hash values for any given input.
+//
+// A Seed must be initialized by calling MakeSeed.
+// The zero seed is uninitialized and not valid for use with Hash's SetSeed method.
+//
+// Each Seed value is local to a single process and cannot be serialized
+// or otherwise recreated in a different process.
+type Seed struct {
+	s uint64
+}
+
+// A Hash computes a seeded hash of a byte sequence.
+//
+// The zero Hash is a valid Hash ready to use.
+// A zero Hash chooses a random seed for itself during
+// the first call to a Reset, Write, Seed, Sum64, or Seed method.
+// For control over the seed, use SetSeed.
+//
+// The computed hash values depend only on the initial seed and
+// the sequence of bytes provided to the Hash object, not on the way
+// in which the bytes are provided. For example, the three sequences
+//
+//     h.Write([]byte{'f','o','o'})
+//     h.WriteByte('f'); h.WriteByte('o'); h.WriteByte('o')
+//     h.WriteString("foo")
+//
+// all have the same effect.
+//
+// Hashes are intended to be collision-resistant, even for situations
+// where an adversary controls the byte sequences being hashed.
+//
+// A Hash is not safe for concurrent use by multiple goroutines, but a Seed is.
+// If multiple goroutines must compute the same seeded hash,
+// each can declare its own Hash and call SetSeed with a common Seed.
+type Hash struct {
+	_     [0]func() // not comparable
+	seed  Seed      // initial seed used for this hash
+	state Seed      // current hash of all flushed bytes
+	buf   [64]byte  // unflushed byte buffer
+	n     int       // number of unflushed bytes
+}
+
+// initSeed seeds the hash if necessary.
+// initSeed is called lazily before any operation that actually uses h.seed/h.state.
+// Note that this does not include Write/WriteByte/WriteString in the case
+// where they only add to h.buf. (If they write too much, they call h.flush,
+// which does call h.initSeed.)
+func (h *Hash) initSeed() {
+	if h.seed.s == 0 {
+		h.SetSeed(MakeSeed())
+	}
+}
+
+// WriteByte adds b to the sequence of bytes hashed by h.
+// It never fails; the error result is for implementing io.ByteWriter.
+func (h *Hash) WriteByte(b byte) error {
+	if h.n == len(h.buf) {
+		h.flush()
+	}
+	h.buf[h.n] = b
+	h.n++
+	return nil
+}
+
+// Write adds b to the sequence of bytes hashed by h.
+// It always writes all of b and never fails; the count and error result are for implementing io.Writer.
+func (h *Hash) Write(b []byte) (int, error) {
+	size := len(b)
+	for h.n+len(b) > len(h.buf) {
+		k := copy(h.buf[h.n:], b)
+		h.n = len(h.buf)
+		b = b[k:]
+		h.flush()
+	}
+	h.n += copy(h.buf[h.n:], b)
+	return size, nil
+}
+
+// WriteString adds the bytes of s to the sequence of bytes hashed by h.
+// It always writes all of s and never fails; the count and error result are for implementing io.StringWriter.
+func (h *Hash) WriteString(s string) (int, error) {
+	size := len(s)
+	for h.n+len(s) > len(h.buf) {
+		k := copy(h.buf[h.n:], s)
+		h.n = len(h.buf)
+		s = s[k:]
+		h.flush()
+	}
+	h.n += copy(h.buf[h.n:], s)
+	return size, nil
+}
+
+// Seed returns h's seed value.
+func (h *Hash) Seed() Seed {
+	h.initSeed()
+	return h.seed
+}
+
+// SetSeed sets h to use seed, which must have been returned by MakeSeed
+// or by another Hash's Seed method.
+// Two Hash objects with the same seed behave identically.
+// Two Hash objects with different seeds will very likely behave differently.
+// Any bytes added to h before this call will be discarded.
+func (h *Hash) SetSeed(seed Seed) {
+	if seed.s == 0 {
+		panic("maphash: use of uninitialized Seed")
+	}
+	h.seed = seed
+	h.state = seed
+	h.n = 0
+}
+
+// Reset discards all bytes added to h.
+// (The seed remains the same.)
+func (h *Hash) Reset() {
+	h.initSeed()
+	h.state = h.seed
+	h.n = 0
+}
+
+// precondition: buffer is full.
+func (h *Hash) flush() {
+	if h.n != len(h.buf) {
+		panic("maphash: flush of partially full buffer")
+	}
+	h.initSeed()
+	h.state.s = rthash(h.buf[:], h.state.s)
+	h.n = 0
+}
+
+// Sum64 returns h's current 64-bit value, which depends on
+// h's seed and the sequence of bytes added to h since the
+// last call to Reset or SetSeed.
+//
+// All bits of the Sum64 result are close to uniformly and
+// independently distributed, so it can be safely reduced
+// by using bit masking, shifting, or modular arithmetic.
+func (h *Hash) Sum64() uint64 {
+	h.initSeed()
+	return rthash(h.buf[:h.n], h.state.s)
+}
+
+// MakeSeed returns a new random seed.
+func MakeSeed() Seed {
+	var s1, s2 uint64
+	for {
+		s1 = uint64(runtime_fastrand())
+		s2 = uint64(runtime_fastrand())
+		// We use seed 0 to indicate an uninitialized seed/hash,
+		// so keep trying until we get a non-zero seed.
+		if s1|s2 != 0 {
+			break
+		}
+	}
+	return Seed{s: s1<<32 + s2}
+}
+
+//go:linkname runtime_fastrand runtime.fastrand
+func runtime_fastrand() uint32
+
+func rthash(b []byte, seed uint64) uint64 {
+	if len(b) == 0 {
+		return seed
+	}
+	// The runtime hasher only works on uintptr. For 64-bit
+	// architectures, we use the hasher directly. Otherwise,
+	// we use two parallel hashers on the lower and upper 32 bits.
+	if unsafe.Sizeof(uintptr(0)) == 8 {
+		return uint64(runtime_memhash(unsafe.Pointer(&b[0]), uintptr(seed), uintptr(len(b))))
+	}
+	lo := runtime_memhash(unsafe.Pointer(&b[0]), uintptr(seed), uintptr(len(b)))
+	hi := runtime_memhash(unsafe.Pointer(&b[0]), uintptr(seed>>32), uintptr(len(b)))
+	return uint64(hi)<<32 | uint64(lo)
+}
+
+//go:linkname runtime_memhash runtime.memhash
+//go:noescape
+func runtime_memhash(p unsafe.Pointer, seed, s uintptr) uintptr
+
+// Sum appends the hash's current 64-bit value to b.
+// It exists for implementing hash.Hash.
+// For direct calls, it is more efficient to use Sum64.
+func (h *Hash) Sum(b []byte) []byte {
+	x := h.Sum64()
+	return append(b,
+		byte(x>>0),
+		byte(x>>8),
+		byte(x>>16),
+		byte(x>>24),
+		byte(x>>32),
+		byte(x>>40),
+		byte(x>>48),
+		byte(x>>56))
+}
+
+// Size returns h's hash value size, 8 bytes.
+func (h *Hash) Size() int { return 8 }
+
+// BlockSize returns h's block size.
+func (h *Hash) BlockSize() int { return len(h.buf) }
diff --git a/libgo/go/hash/maphash/maphash_test.go b/libgo/go/hash/maphash/maphash_test.go
new file mode 100644
index 0000000..31d84a3
--- /dev/null
+++ b/libgo/go/hash/maphash/maphash_test.go
@@ -0,0 +1,88 @@
+// Copyright 2019 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 maphash
+
+import (
+	"hash"
+	"testing"
+)
+
+func TestUnseededHash(t *testing.T) {
+	m := map[uint64]struct{}{}
+	for i := 0; i < 1000; i++ {
+		h := new(Hash)
+		m[h.Sum64()] = struct{}{}
+	}
+	if len(m) < 900 {
+		t.Errorf("empty hash not sufficiently random: got %d, want 1000", len(m))
+	}
+}
+
+func TestSeededHash(t *testing.T) {
+	s := MakeSeed()
+	m := map[uint64]struct{}{}
+	for i := 0; i < 1000; i++ {
+		h := new(Hash)
+		h.SetSeed(s)
+		m[h.Sum64()] = struct{}{}
+	}
+	if len(m) != 1 {
+		t.Errorf("seeded hash is random: got %d, want 1", len(m))
+	}
+}
+
+func TestHashGrouping(t *testing.T) {
+	b := []byte("foo")
+	h1 := new(Hash)
+	h2 := new(Hash)
+	h2.SetSeed(h1.Seed())
+	h1.Write(b)
+	for _, x := range b {
+		err := h2.WriteByte(x)
+		if err != nil {
+			t.Fatalf("WriteByte: %v", err)
+		}
+	}
+	if h1.Sum64() != h2.Sum64() {
+		t.Errorf("hash of \"foo\" and \"f\",\"o\",\"o\" not identical")
+	}
+}
+
+func TestHashBytesVsString(t *testing.T) {
+	s := "foo"
+	b := []byte(s)
+	h1 := new(Hash)
+	h2 := new(Hash)
+	h2.SetSeed(h1.Seed())
+	n1, err1 := h1.WriteString(s)
+	if n1 != len(s) || err1 != nil {
+		t.Fatalf("WriteString(s) = %d, %v, want %d, nil", n1, err1, len(s))
+	}
+	n2, err2 := h2.Write(b)
+	if n2 != len(b) || err2 != nil {
+		t.Fatalf("Write(b) = %d, %v, want %d, nil", n2, err2, len(b))
+	}
+	if h1.Sum64() != h2.Sum64() {
+		t.Errorf("hash of string and bytes not identical")
+	}
+}
+
+func TestHashHighBytes(t *testing.T) {
+	// See issue 34925.
+	const N = 10
+	m := map[uint64]struct{}{}
+	for i := 0; i < N; i++ {
+		h := new(Hash)
+		h.WriteString("foo")
+		m[h.Sum64()>>32] = struct{}{}
+	}
+	if len(m) < N/2 {
+		t.Errorf("from %d seeds, wanted at least %d different hashes; got %d", N, N/2, len(m))
+	}
+}
+
+// Make sure a Hash implements the hash.Hash and hash.Hash64 interfaces.
+var _ hash.Hash = &Hash{}
+var _ hash.Hash64 = &Hash{}
diff --git a/libgo/go/hash/maphash/smhasher_test.go b/libgo/go/hash/maphash/smhasher_test.go
new file mode 100644
index 0000000..6e6f298
--- /dev/null
+++ b/libgo/go/hash/maphash/smhasher_test.go
@@ -0,0 +1,469 @@
+// Copyright 2019 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 maphash
+
+import (
+	"fmt"
+	"math"
+	"math/rand"
+	"runtime"
+	"strings"
+	"testing"
+	"unsafe"
+)
+
+// Smhasher is a torture test for hash functions.
+// https://code.google.com/p/smhasher/
+// This code is a port of some of the Smhasher tests to Go.
+
+var fixedSeed = MakeSeed()
+
+// Sanity checks.
+// hash should not depend on values outside key.
+// hash should not depend on alignment.
+func TestSmhasherSanity(t *testing.T) {
+	r := rand.New(rand.NewSource(1234))
+	const REP = 10
+	const KEYMAX = 128
+	const PAD = 16
+	const OFFMAX = 16
+	for k := 0; k < REP; k++ {
+		for n := 0; n < KEYMAX; n++ {
+			for i := 0; i < OFFMAX; i++ {
+				var b [KEYMAX + OFFMAX + 2*PAD]byte
+				var c [KEYMAX + OFFMAX + 2*PAD]byte
+				randBytes(r, b[:])
+				randBytes(r, c[:])
+				copy(c[PAD+i:PAD+i+n], b[PAD:PAD+n])
+				if bytesHash(b[PAD:PAD+n]) != bytesHash(c[PAD+i:PAD+i+n]) {
+					t.Errorf("hash depends on bytes outside key")
+				}
+			}
+		}
+	}
+}
+
+func bytesHash(b []byte) uint64 {
+	var h Hash
+	h.SetSeed(fixedSeed)
+	h.Write(b)
+	return h.Sum64()
+}
+func stringHash(s string) uint64 {
+	var h Hash
+	h.SetSeed(fixedSeed)
+	h.WriteString(s)
+	return h.Sum64()
+}
+
+const hashSize = 64
+
+func randBytes(r *rand.Rand, b []byte) {
+	r.Read(b) // can't fail
+}
+
+// A hashSet measures the frequency of hash collisions.
+type hashSet struct {
+	m map[uint64]struct{} // set of hashes added
+	n int                 // number of hashes added
+}
+
+func newHashSet() *hashSet {
+	return &hashSet{make(map[uint64]struct{}), 0}
+}
+func (s *hashSet) add(h uint64) {
+	s.m[h] = struct{}{}
+	s.n++
+}
+func (s *hashSet) addS(x string) {
+	s.add(stringHash(x))
+}
+func (s *hashSet) addB(x []byte) {
+	s.add(bytesHash(x))
+}
+func (s *hashSet) addS_seed(x string, seed Seed) {
+	var h Hash
+	h.SetSeed(seed)
+	h.WriteString(x)
+	s.add(h.Sum64())
+}
+func (s *hashSet) check(t *testing.T) {
+	const SLOP = 10.0
+	collisions := s.n - len(s.m)
+	pairs := int64(s.n) * int64(s.n-1) / 2
+	expected := float64(pairs) / math.Pow(2.0, float64(hashSize))
+	stddev := math.Sqrt(expected)
+	if float64(collisions) > expected+SLOP*(3*stddev+1) {
+		t.Errorf("unexpected number of collisions: got=%d mean=%f stddev=%f", collisions, expected, stddev)
+	}
+}
+
+// a string plus adding zeros must make distinct hashes
+func TestSmhasherAppendedZeros(t *testing.T) {
+	s := "hello" + strings.Repeat("\x00", 256)
+	h := newHashSet()
+	for i := 0; i <= len(s); i++ {
+		h.addS(s[:i])
+	}
+	h.check(t)
+}
+
+// All 0-3 byte strings have distinct hashes.
+func TestSmhasherSmallKeys(t *testing.T) {
+	h := newHashSet()
+	var b [3]byte
+	for i := 0; i < 256; i++ {
+		b[0] = byte(i)
+		h.addB(b[:1])
+		for j := 0; j < 256; j++ {
+			b[1] = byte(j)
+			h.addB(b[:2])
+			if !testing.Short() {
+				for k := 0; k < 256; k++ {
+					b[2] = byte(k)
+					h.addB(b[:3])
+				}
+			}
+		}
+	}
+	h.check(t)
+}
+
+// Different length strings of all zeros have distinct hashes.
+func TestSmhasherZeros(t *testing.T) {
+	N := 256 * 1024
+	if testing.Short() {
+		N = 1024
+	}
+	h := newHashSet()
+	b := make([]byte, N)
+	for i := 0; i <= N; i++ {
+		h.addB(b[:i])
+	}
+	h.check(t)
+}
+
+// Strings with up to two nonzero bytes all have distinct hashes.
+func TestSmhasherTwoNonzero(t *testing.T) {
+	if runtime.GOARCH == "wasm" {
+		t.Skip("Too slow on wasm")
+	}
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	h := newHashSet()
+	for n := 2; n <= 16; n++ {
+		twoNonZero(h, n)
+	}
+	h.check(t)
+}
+func twoNonZero(h *hashSet, n int) {
+	b := make([]byte, n)
+
+	// all zero
+	h.addB(b)
+
+	// one non-zero byte
+	for i := 0; i < n; i++ {
+		for x := 1; x < 256; x++ {
+			b[i] = byte(x)
+			h.addB(b)
+			b[i] = 0
+		}
+	}
+
+	// two non-zero bytes
+	for i := 0; i < n; i++ {
+		for x := 1; x < 256; x++ {
+			b[i] = byte(x)
+			for j := i + 1; j < n; j++ {
+				for y := 1; y < 256; y++ {
+					b[j] = byte(y)
+					h.addB(b)
+					b[j] = 0
+				}
+			}
+			b[i] = 0
+		}
+	}
+}
+
+// Test strings with repeats, like "abcdabcdabcdabcd..."
+func TestSmhasherCyclic(t *testing.T) {
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	r := rand.New(rand.NewSource(1234))
+	const REPEAT = 8
+	const N = 1000000
+	for n := 4; n <= 12; n++ {
+		h := newHashSet()
+		b := make([]byte, REPEAT*n)
+		for i := 0; i < N; i++ {
+			b[0] = byte(i * 79 % 97)
+			b[1] = byte(i * 43 % 137)
+			b[2] = byte(i * 151 % 197)
+			b[3] = byte(i * 199 % 251)
+			randBytes(r, b[4:n])
+			for j := n; j < n*REPEAT; j++ {
+				b[j] = b[j-n]
+			}
+			h.addB(b)
+		}
+		h.check(t)
+	}
+}
+
+// Test strings with only a few bits set
+func TestSmhasherSparse(t *testing.T) {
+	if runtime.GOARCH == "wasm" {
+		t.Skip("Too slow on wasm")
+	}
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	sparse(t, 32, 6)
+	sparse(t, 40, 6)
+	sparse(t, 48, 5)
+	sparse(t, 56, 5)
+	sparse(t, 64, 5)
+	sparse(t, 96, 4)
+	sparse(t, 256, 3)
+	sparse(t, 2048, 2)
+}
+func sparse(t *testing.T, n int, k int) {
+	b := make([]byte, n/8)
+	h := newHashSet()
+	setbits(h, b, 0, k)
+	h.check(t)
+}
+
+// set up to k bits at index i and greater
+func setbits(h *hashSet, b []byte, i int, k int) {
+	h.addB(b)
+	if k == 0 {
+		return
+	}
+	for j := i; j < len(b)*8; j++ {
+		b[j/8] |= byte(1 << uint(j&7))
+		setbits(h, b, j+1, k-1)
+		b[j/8] &= byte(^(1 << uint(j&7)))
+	}
+}
+
+// Test all possible combinations of n blocks from the set s.
+// "permutation" is a bad name here, but it is what Smhasher uses.
+func TestSmhasherPermutation(t *testing.T) {
+	if runtime.GOARCH == "wasm" {
+		t.Skip("Too slow on wasm")
+	}
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	permutation(t, []uint32{0, 1, 2, 3, 4, 5, 6, 7}, 8)
+	permutation(t, []uint32{0, 1 << 29, 2 << 29, 3 << 29, 4 << 29, 5 << 29, 6 << 29, 7 << 29}, 8)
+	permutation(t, []uint32{0, 1}, 20)
+	permutation(t, []uint32{0, 1 << 31}, 20)
+	permutation(t, []uint32{0, 1, 2, 3, 4, 5, 6, 7, 1 << 29, 2 << 29, 3 << 29, 4 << 29, 5 << 29, 6 << 29, 7 << 29}, 6)
+}
+func permutation(t *testing.T, s []uint32, n int) {
+	b := make([]byte, n*4)
+	h := newHashSet()
+	genPerm(h, b, s, 0)
+	h.check(t)
+}
+func genPerm(h *hashSet, b []byte, s []uint32, n int) {
+	h.addB(b[:n])
+	if n == len(b) {
+		return
+	}
+	for _, v := range s {
+		b[n] = byte(v)
+		b[n+1] = byte(v >> 8)
+		b[n+2] = byte(v >> 16)
+		b[n+3] = byte(v >> 24)
+		genPerm(h, b, s, n+4)
+	}
+}
+
+type key interface {
+	clear()              // set bits all to 0
+	random(r *rand.Rand) // set key to something random
+	bits() int           // how many bits key has
+	flipBit(i int)       // flip bit i of the key
+	hash() uint64        // hash the key
+	name() string        // for error reporting
+}
+
+type bytesKey struct {
+	b []byte
+}
+
+func (k *bytesKey) clear() {
+	for i := range k.b {
+		k.b[i] = 0
+	}
+}
+func (k *bytesKey) random(r *rand.Rand) {
+	randBytes(r, k.b)
+}
+func (k *bytesKey) bits() int {
+	return len(k.b) * 8
+}
+func (k *bytesKey) flipBit(i int) {
+	k.b[i>>3] ^= byte(1 << uint(i&7))
+}
+func (k *bytesKey) hash() uint64 {
+	return bytesHash(k.b)
+}
+func (k *bytesKey) name() string {
+	return fmt.Sprintf("bytes%d", len(k.b))
+}
+
+// Flipping a single bit of a key should flip each output bit with 50% probability.
+func TestSmhasherAvalanche(t *testing.T) {
+	if runtime.GOARCH == "wasm" {
+		t.Skip("Too slow on wasm")
+	}
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	avalancheTest1(t, &bytesKey{make([]byte, 2)})
+	avalancheTest1(t, &bytesKey{make([]byte, 4)})
+	avalancheTest1(t, &bytesKey{make([]byte, 8)})
+	avalancheTest1(t, &bytesKey{make([]byte, 16)})
+	avalancheTest1(t, &bytesKey{make([]byte, 32)})
+	avalancheTest1(t, &bytesKey{make([]byte, 200)})
+}
+func avalancheTest1(t *testing.T, k key) {
+	const REP = 100000
+	r := rand.New(rand.NewSource(1234))
+	n := k.bits()
+
+	// grid[i][j] is a count of whether flipping
+	// input bit i affects output bit j.
+	grid := make([][hashSize]int, n)
+
+	for z := 0; z < REP; z++ {
+		// pick a random key, hash it
+		k.random(r)
+		h := k.hash()
+
+		// flip each bit, hash & compare the results
+		for i := 0; i < n; i++ {
+			k.flipBit(i)
+			d := h ^ k.hash()
+			k.flipBit(i)
+
+			// record the effects of that bit flip
+			g := &grid[i]
+			for j := 0; j < hashSize; j++ {
+				g[j] += int(d & 1)
+				d >>= 1
+			}
+		}
+	}
+
+	// Each entry in the grid should be about REP/2.
+	// More precisely, we did N = k.bits() * hashSize experiments where
+	// each is the sum of REP coin flips. We want to find bounds on the
+	// sum of coin flips such that a truly random experiment would have
+	// all sums inside those bounds with 99% probability.
+	N := n * hashSize
+	var c float64
+	// find c such that Prob(mean-c*stddev < x < mean+c*stddev)^N > .9999
+	for c = 0.0; math.Pow(math.Erf(c/math.Sqrt(2)), float64(N)) < .9999; c += .1 {
+	}
+	c *= 4.0 // allowed slack - we don't need to be perfectly random
+	mean := .5 * REP
+	stddev := .5 * math.Sqrt(REP)
+	low := int(mean - c*stddev)
+	high := int(mean + c*stddev)
+	for i := 0; i < n; i++ {
+		for j := 0; j < hashSize; j++ {
+			x := grid[i][j]
+			if x < low || x > high {
+				t.Errorf("bad bias for %s bit %d -> bit %d: %d/%d\n", k.name(), i, j, x, REP)
+			}
+		}
+	}
+}
+
+// All bit rotations of a set of distinct keys
+func TestSmhasherWindowed(t *testing.T) {
+	windowed(t, &bytesKey{make([]byte, 128)})
+}
+func windowed(t *testing.T, k key) {
+	if runtime.GOARCH == "wasm" {
+		t.Skip("Too slow on wasm")
+	}
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	const BITS = 16
+
+	for r := 0; r < k.bits(); r++ {
+		h := newHashSet()
+		for i := 0; i < 1<<BITS; i++ {
+			k.clear()
+			for j := 0; j < BITS; j++ {
+				if i>>uint(j)&1 != 0 {
+					k.flipBit((j + r) % k.bits())
+				}
+			}
+			h.add(k.hash())
+		}
+		h.check(t)
+	}
+}
+
+// All keys of the form prefix + [A-Za-z0-9]*N + suffix.
+func TestSmhasherText(t *testing.T) {
+	if testing.Short() {
+		t.Skip("Skipping in short mode")
+	}
+	text(t, "Foo", "Bar")
+	text(t, "FooBar", "")
+	text(t, "", "FooBar")
+}
+func text(t *testing.T, prefix, suffix string) {
+	const N = 4
+	const S = "ABCDEFGHIJKLMNOPQRSTabcdefghijklmnopqrst0123456789"
+	const L = len(S)
+	b := make([]byte, len(prefix)+N+len(suffix))
+	copy(b, prefix)
+	copy(b[len(prefix)+N:], suffix)
+	h := newHashSet()
+	c := b[len(prefix):]
+	for i := 0; i < L; i++ {
+		c[0] = S[i]
+		for j := 0; j < L; j++ {
+			c[1] = S[j]
+			for k := 0; k < L; k++ {
+				c[2] = S[k]
+				for x := 0; x < L; x++ {
+					c[3] = S[x]
+					h.addB(b)
+				}
+			}
+		}
+	}
+	h.check(t)
+}
+
+// Make sure different seed values generate different hashes.
+func TestSmhasherSeed(t *testing.T) {
+	if unsafe.Sizeof(uintptr(0)) == 4 {
+		t.Skip("32-bit platforms don't have ideal seed-input distributions (see issue 33988)")
+	}
+	h := newHashSet()
+	const N = 100000
+	s := "hello"
+	for i := 0; i < N; i++ {
+		h.addS_seed(s, Seed{s: uint64(i + 1)})
+		h.addS_seed(s, Seed{s: uint64(i+1) << 32}) // make sure high bits are used
+	}
+	h.check(t)
+}