tailscale/util/deephash/deephash.go
Josh Bleecher Snyder 0868329936 all: use any instead of interface{}
My favorite part of generics.

Signed-off-by: Josh Bleecher Snyder <josh@tailscale.com>
2022-03-17 11:35:09 -07:00

392 lines
11 KiB
Go

// Copyright (c) 2020 Tailscale Inc & 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 deephash hashes a Go value recursively, in a predictable order,
// without looping. The hash is only valid within the lifetime of a program.
// Users should not store the hash on disk or send it over the network.
// The hash is sufficiently strong and unique such that
// Hash(x) == Hash(y) is an appropriate replacement for x == y.
//
// The definition of equality is identical to reflect.DeepEqual except:
// * Floating-point values are compared based on the raw bits,
// which means that NaNs (with the same bit pattern) are treated as equal.
// * Types which implement interface { AppendTo([]byte) []byte } use
// the AppendTo method to produce a textual representation of the value.
// Thus, two values are equal if AppendTo produces the same bytes.
//
// WARNING: This package, like most of the tailscale.com Go module,
// should be considered Tailscale-internal; we make no API promises.
package deephash
import (
"bufio"
"crypto/sha256"
"encoding/binary"
"encoding/hex"
"fmt"
"hash"
"math"
"reflect"
"sync"
"time"
"unsafe"
)
// There is much overlap between the theory of serialization and hashing.
// A hash (useful for determining equality) can be produced by printing a value
// and hashing the output. The format must:
// * be deterministic such that the same value hashes to the same output, and
// * be parsable such that the same value can be reproduced by the output.
//
// The logic below hashes a value by printing it to a hash.Hash.
// To be parsable, it assumes that we know the Go type of each value:
// * scalar types (e.g., bool or int32) are printed as fixed-width fields.
// * list types (e.g., strings, slices, and AppendTo buffers) are prefixed
// by a fixed-width length field, followed by the contents of the list.
// * slices, arrays, and structs print each element/field consecutively.
// * interfaces print with a 1-byte prefix indicating whether it is nil.
// If non-nil, it is followed by a fixed-width field of the type index,
// followed by the format of the underlying value.
// * pointers print with a 1-byte prefix indicating whether the pointer is
// 1) nil, 2) previously seen, or 3) newly seen. Previously seen pointers are
// followed by a fixed-width field with the index of the previous pointer.
// Newly seen pointers are followed by the format of the underlying value.
// * maps print with a 1-byte prefix indicating whether the map pointer is
// 1) nil, 2) previously seen, or 3) newly seen. Previously seen pointers
// are followed by a fixed-width field of the index of the previous pointer.
// Newly seen maps are printed as a fixed-width field with the XOR of the
// hash of every map entry. With a sufficiently strong hash, this value is
// theoretically "parsable" by looking up the hash in a magical map that
// returns the set of entries for that given hash.
const scratchSize = 128
// hasher is reusable state for hashing a value.
// Get one via hasherPool.
type hasher struct {
h hash.Hash
bw *bufio.Writer
scratch [scratchSize]byte
visitStack visitStack
}
func (h *hasher) reset() {
if h.h == nil {
h.h = sha256.New()
}
if h.bw == nil {
h.bw = bufio.NewWriterSize(h.h, h.h.BlockSize())
}
h.bw.Flush()
h.h.Reset()
}
// Sum is an opaque checksum type that is comparable.
type Sum struct {
sum [sha256.Size]byte
}
func (s1 *Sum) xor(s2 Sum) {
for i := 0; i < sha256.Size; i++ {
s1.sum[i] ^= s2.sum[i]
}
}
func (s Sum) String() string {
return hex.EncodeToString(s.sum[:])
}
var (
once sync.Once
seed uint64
)
func (h *hasher) sum() (s Sum) {
h.bw.Flush()
// Sum into scratch & copy out, as hash.Hash is an interface
// so the slice necessarily escapes, and there's no sha256
// concrete type exported and we don't want the 'hash' result
// parameter to escape to the heap:
copy(s.sum[:], h.h.Sum(h.scratch[:0]))
return s
}
var hasherPool = &sync.Pool{
New: func() any { return new(hasher) },
}
// Hash returns the hash of v.
func Hash(v any) (s Sum) {
h := hasherPool.Get().(*hasher)
defer hasherPool.Put(h)
h.reset()
once.Do(func() {
seed = uint64(time.Now().UnixNano())
})
h.hashUint64(seed)
h.hashValue(reflect.ValueOf(v))
return h.sum()
}
// Update sets last to the hash of v and reports whether its value changed.
func Update(last *Sum, v ...any) (changed bool) {
sum := Hash(v)
if sum == *last {
// unchanged.
return false
}
*last = sum
return true
}
var appenderToType = reflect.TypeOf((*appenderTo)(nil)).Elem()
type appenderTo interface {
AppendTo([]byte) []byte
}
func (h *hasher) hashUint8(i uint8) {
h.bw.WriteByte(i)
}
func (h *hasher) hashUint16(i uint16) {
binary.LittleEndian.PutUint16(h.scratch[:2], i)
h.bw.Write(h.scratch[:2])
}
func (h *hasher) hashUint32(i uint32) {
binary.LittleEndian.PutUint32(h.scratch[:4], i)
h.bw.Write(h.scratch[:4])
}
func (h *hasher) hashUint64(i uint64) {
binary.LittleEndian.PutUint64(h.scratch[:8], i)
h.bw.Write(h.scratch[:8])
}
var uint8Type = reflect.TypeOf(byte(0))
func (h *hasher) hashValue(v reflect.Value) {
if !v.IsValid() {
return
}
w := h.bw
if v.CanInterface() {
// Use AppendTo methods, if available and cheap.
if v.CanAddr() && v.Type().Implements(appenderToType) {
a := v.Addr().Interface().(appenderTo)
size := h.scratch[:8]
record := a.AppendTo(size)
binary.LittleEndian.PutUint64(record, uint64(len(record)-len(size)))
w.Write(record)
return
}
}
// TODO(dsnet): Avoid cycle detection for types that cannot have cycles.
// Generic handling.
switch v.Kind() {
default:
panic(fmt.Sprintf("unhandled kind %v for type %v", v.Kind(), v.Type()))
case reflect.Ptr:
if v.IsNil() {
h.hashUint8(0) // indicates nil
return
}
// Check for cycle.
ptr := pointerOf(v)
if idx, ok := h.visitStack.seen(ptr); ok {
h.hashUint8(2) // indicates cycle
h.hashUint64(uint64(idx))
return
}
h.visitStack.push(ptr)
defer h.visitStack.pop(ptr)
h.hashUint8(1) // indicates visiting a pointer
h.hashValue(v.Elem())
case reflect.Struct:
for i, n := 0, v.NumField(); i < n; i++ {
h.hashValue(v.Field(i))
}
case reflect.Slice, reflect.Array:
vLen := v.Len()
if v.Kind() == reflect.Slice {
h.hashUint64(uint64(vLen))
}
if v.Type().Elem() == uint8Type && v.CanInterface() {
if vLen > 0 && vLen <= scratchSize {
// If it fits in scratch, avoid the Interface allocation.
// It seems tempting to do this for all sizes, doing
// scratchSize bytes at a time, but reflect.Slice seems
// to allocate, so it's not a win.
n := reflect.Copy(reflect.ValueOf(&h.scratch).Elem(), v)
w.Write(h.scratch[:n])
return
}
fmt.Fprintf(w, "%s", v.Interface())
return
}
for i := 0; i < vLen; i++ {
// TODO(dsnet): Perform cycle detection for slices,
// which is functionally a list of pointers.
// See https://github.com/google/go-cmp/blob/402949e8139bb890c71a707b6faf6dd05c92f4e5/cmp/compare.go#L438-L450
h.hashValue(v.Index(i))
}
case reflect.Interface:
if v.IsNil() {
h.hashUint8(0) // indicates nil
return
}
v = v.Elem()
h.hashUint8(1) // indicates visiting interface value
h.hashType(v.Type())
h.hashValue(v)
case reflect.Map:
// Check for cycle.
ptr := pointerOf(v)
if idx, ok := h.visitStack.seen(ptr); ok {
h.hashUint8(2) // indicates cycle
h.hashUint64(uint64(idx))
return
}
h.visitStack.push(ptr)
defer h.visitStack.pop(ptr)
h.hashUint8(1) // indicates visiting a map
h.hashMap(v)
case reflect.String:
s := v.String()
h.hashUint64(uint64(len(s)))
w.WriteString(s)
case reflect.Bool:
if v.Bool() {
h.hashUint8(1)
} else {
h.hashUint8(0)
}
case reflect.Int8:
h.hashUint8(uint8(v.Int()))
case reflect.Int16:
h.hashUint16(uint16(v.Int()))
case reflect.Int32:
h.hashUint32(uint32(v.Int()))
case reflect.Int64, reflect.Int:
h.hashUint64(uint64(v.Int()))
case reflect.Uint8:
h.hashUint8(uint8(v.Uint()))
case reflect.Uint16:
h.hashUint16(uint16(v.Uint()))
case reflect.Uint32:
h.hashUint32(uint32(v.Uint()))
case reflect.Uint64, reflect.Uint, reflect.Uintptr:
h.hashUint64(uint64(v.Uint()))
case reflect.Float32:
h.hashUint32(math.Float32bits(float32(v.Float())))
case reflect.Float64:
h.hashUint64(math.Float64bits(float64(v.Float())))
case reflect.Complex64:
h.hashUint32(math.Float32bits(real(complex64(v.Complex()))))
h.hashUint32(math.Float32bits(imag(complex64(v.Complex()))))
case reflect.Complex128:
h.hashUint64(math.Float64bits(real(complex128(v.Complex()))))
h.hashUint64(math.Float64bits(imag(complex128(v.Complex()))))
}
}
type mapHasher struct {
h hasher
val valueCache // re-usable values for map iteration
iter reflect.MapIter // re-usable map iterator
}
var mapHasherPool = &sync.Pool{
New: func() any { return new(mapHasher) },
}
type valueCache map[reflect.Type]reflect.Value
func (c *valueCache) get(t reflect.Type) reflect.Value {
v, ok := (*c)[t]
if !ok {
v = reflect.New(t).Elem()
if *c == nil {
*c = make(valueCache)
}
(*c)[t] = v
}
return v
}
// hashMap hashes a map in a sort-free manner.
// It relies on a map being a functionally an unordered set of KV entries.
// So long as we hash each KV entry together, we can XOR all
// of the individual hashes to produce a unique hash for the entire map.
func (h *hasher) hashMap(v reflect.Value) {
mh := mapHasherPool.Get().(*mapHasher)
defer mapHasherPool.Put(mh)
iter := &mh.iter
iter.Reset(v)
defer iter.Reset(reflect.Value{}) // avoid pinning v from mh.iter when we return
var sum Sum
k := mh.val.get(v.Type().Key())
e := mh.val.get(v.Type().Elem())
mh.h.visitStack = h.visitStack // always use the parent's visit stack to avoid cycles
for iter.Next() {
k.SetIterKey(iter)
e.SetIterValue(iter)
mh.h.reset()
mh.h.hashValue(k)
mh.h.hashValue(v)
sum.xor(mh.h.sum())
}
h.bw.Write(append(h.scratch[:0], sum.sum[:]...)) // append into scratch to avoid heap allocation
}
// visitStack is a stack of pointers visited.
// Pointers are pushed onto the stack when visited, and popped when leaving.
// The integer value is the depth at which the pointer was visited.
// The length of this stack should be zero after every hashing operation.
type visitStack map[pointer]int
func (v visitStack) seen(p pointer) (int, bool) {
idx, ok := v[p]
return idx, ok
}
func (v *visitStack) push(p pointer) {
if *v == nil {
*v = make(map[pointer]int)
}
(*v)[p] = len(*v)
}
func (v visitStack) pop(p pointer) {
delete(v, p)
}
// pointer is a thin wrapper over unsafe.Pointer.
// We only rely on comparability of pointers; we cannot rely on uintptr since
// that would break if Go ever switched to a moving GC.
type pointer struct{ p unsafe.Pointer }
func pointerOf(v reflect.Value) pointer {
return pointer{unsafe.Pointer(v.Pointer())}
}
// hashType hashes a reflect.Type.
// The hash is only consistent within the lifetime of a program.
func (h *hasher) hashType(t reflect.Type) {
// This approach relies on reflect.Type always being backed by a unique
// *reflect.rtype pointer. A safer approach is to use a global sync.Map
// that maps reflect.Type to some arbitrary and unique index.
// While safer, it requires global state with memory that can never be GC'd.
rtypeAddr := reflect.ValueOf(t).Pointer() // address of *reflect.rtype
h.hashUint64(uint64(rtypeAddr))
}