@ -24,7 +24,6 @@ import (
"crypto/sha256"
"crypto/sha256"
"encoding/binary"
"encoding/binary"
"encoding/hex"
"encoding/hex"
"fmt"
"math"
"math"
"net/netip"
"net/netip"
"reflect"
"reflect"
@ -151,7 +150,8 @@ func Hash(v any) (s Sum) {
// the initial reflect.ValueOf from an interface value effectively strips
// the initial reflect.ValueOf from an interface value effectively strips
// the interface box off so we have to do it at the top level by hand.
// the interface box off so we have to do it at the top level by hand.
h . hashType ( va . Type ( ) )
h . hashType ( va . Type ( ) )
h . hashValue ( va , false )
ti := getTypeInfo ( va . Type ( ) )
ti . hasher ( ) ( h , va )
}
}
return h . sum ( )
return h . sum ( )
}
}
@ -180,12 +180,12 @@ func HasherForType[T any]() func(T) Sum {
if rv . Kind ( ) == reflect . Pointer && ! rv . IsNil ( ) {
if rv . Kind ( ) == reflect . Pointer && ! rv . IsNil ( ) {
va := addressableValue { rv . Elem ( ) } // dereferenced pointer is always addressable
va := addressableValue { rv . Elem ( ) } // dereferenced pointer is always addressable
h . hashType ( va . Type ( ) )
h . hashType ( va . Type ( ) )
h. hashValueWithType ( va , tiElem , false )
tiElem. hasher ( ) ( h , va )
} else {
} else {
va := newAddressableValue ( rv . Type ( ) )
va := newAddressableValue ( rv . Type ( ) )
va . Set ( rv )
va . Set ( rv )
h . hashType ( va . Type ( ) )
h . hashType ( va . Type ( ) )
h. hashValueWithType ( va , ti , false )
ti. hasher ( ) ( h , va )
}
}
}
}
return h . sum ( )
return h . sum ( )
@ -202,14 +202,6 @@ func Update(last *Sum, v any) (changed bool) {
return changed
return changed
}
}
var appenderToType = reflect . TypeOf ( ( * appenderTo ) ( nil ) ) . Elem ( )
type appenderTo interface {
AppendTo ( [ ] byte ) [ ] byte
}
var uint8Type = reflect . TypeOf ( byte ( 0 ) )
// typeInfo describes properties of a type.
// typeInfo describes properties of a type.
//
//
// A non-nil typeInfo is populated into the typeHasher map
// A non-nil typeInfo is populated into the typeHasher map
@ -218,7 +210,6 @@ var uint8Type = reflect.TypeOf(byte(0))
// This is used for recursive types.
// This is used for recursive types.
type typeInfo struct {
type typeInfo struct {
rtype reflect . Type
rtype reflect . Type
canMemHash bool
isRecursive bool
isRecursive bool
// elemTypeInfo is the element type's typeInfo.
// elemTypeInfo is the element type's typeInfo.
@ -233,8 +224,7 @@ type typeInfo struct {
hashFuncLazy typeHasherFunc // nil until created
hashFuncLazy typeHasherFunc // nil until created
}
}
// returns ok if it was handled; else slow path runs
type typeHasherFunc func ( h * hasher , v addressableValue )
type typeHasherFunc func ( h * hasher , v addressableValue ) ( ok bool )
var typeInfoMap sync . Map // map[reflect.Type]*typeInfo
var typeInfoMap sync . Map // map[reflect.Type]*typeInfo
var typeInfoMapPopulate sync . Mutex // just for adding to typeInfoMap
var typeInfoMapPopulate sync . Mutex // just for adding to typeInfoMap
@ -248,53 +238,44 @@ func (ti *typeInfo) buildHashFuncOnce() {
ti . hashFuncLazy = genTypeHasher ( ti )
ti . hashFuncLazy = genTypeHasher ( ti )
}
}
func ( h * hasher ) hashBoolv ( v addressableValue ) bool {
func ( h * hasher ) hashBoolv ( v addressableValue ) {
var b byte
var b byte
if v . Bool ( ) {
if v . Bool ( ) {
b = 1
b = 1
}
}
h . HashUint8 ( b )
h . HashUint8 ( b )
return true
}
}
func ( h * hasher ) hashUint8v ( v addressableValue ) bool {
func ( h * hasher ) hashUint8v ( v addressableValue ) {
h . HashUint8 ( uint8 ( v . Uint ( ) ) )
h . HashUint8 ( uint8 ( v . Uint ( ) ) )
return true
}
}
func ( h * hasher ) hashInt8v ( v addressableValue ) bool {
func ( h * hasher ) hashInt8v ( v addressableValue ) {
h . HashUint8 ( uint8 ( v . Int ( ) ) )
h . HashUint8 ( uint8 ( v . Int ( ) ) )
return true
}
}
func ( h * hasher ) hashUint16v ( v addressableValue ) bool {
func ( h * hasher ) hashUint16v ( v addressableValue ) {
h . HashUint16 ( uint16 ( v . Uint ( ) ) )
h . HashUint16 ( uint16 ( v . Uint ( ) ) )
return true
}
}
func ( h * hasher ) hashInt16v ( v addressableValue ) bool {
func ( h * hasher ) hashInt16v ( v addressableValue ) {
h . HashUint16 ( uint16 ( v . Int ( ) ) )
h . HashUint16 ( uint16 ( v . Int ( ) ) )
return true
}
}
func ( h * hasher ) hashUint32v ( v addressableValue ) bool {
func ( h * hasher ) hashUint32v ( v addressableValue ) {
h . HashUint32 ( uint32 ( v . Uint ( ) ) )
h . HashUint32 ( uint32 ( v . Uint ( ) ) )
return true
}
}
func ( h * hasher ) hashInt32v ( v addressableValue ) bool {
func ( h * hasher ) hashInt32v ( v addressableValue ) {
h . HashUint32 ( uint32 ( v . Int ( ) ) )
h . HashUint32 ( uint32 ( v . Int ( ) ) )
return true
}
}
func ( h * hasher ) hashUint64v ( v addressableValue ) bool {
func ( h * hasher ) hashUint64v ( v addressableValue ) {
h . HashUint64 ( v . Uint ( ) )
h . HashUint64 ( v . Uint ( ) )
return true
}
}
func ( h * hasher ) hashInt64v ( v addressableValue ) bool {
func ( h * hasher ) hashInt64v ( v addressableValue ) {
h . HashUint64 ( uint64 ( v . Int ( ) ) )
h . HashUint64 ( uint64 ( v . Int ( ) ) )
return true
}
}
// fieldInfo describes a struct field.
// fieldInfo describes a struct field.
@ -349,7 +330,7 @@ type structHasher struct {
fields [ ] fieldInfo
fields [ ] fieldInfo
}
}
func ( sh structHasher ) hash ( h * hasher , v addressableValue ) bool {
func ( sh structHasher ) hash ( h * hasher , v addressableValue ) {
base := v . Addr ( ) . UnsafePointer ( )
base := v . Addr ( ) . UnsafePointer ( )
for _ , f := range sh . fields {
for _ , f := range sh . fields {
if f . canMemHash {
if f . canMemHash {
@ -357,25 +338,21 @@ func (sh structHasher) hash(h *hasher, v addressableValue) bool {
continue
continue
}
}
va := addressableValue { v . Field ( f . index ) } // field is addressable if parent struct is addressable
va := addressableValue { v . Field ( f . index ) } // field is addressable if parent struct is addressable
if ! f . typeInfo . hasher ( ) ( h , va ) {
f . typeInfo . hasher ( ) ( h , va )
return false
}
}
}
return true
}
}
// genHashPtrToMemoryRange returns a hasher where the reflect.Value is a Ptr to
// genHashPtrToMemoryRange returns a hasher where the reflect.Value is a Ptr to
// the provided eleType.
// the provided eleType.
func genHashPtrToMemoryRange ( eleType reflect . Type ) typeHasherFunc {
func genHashPtrToMemoryRange ( eleType reflect . Type ) typeHasherFunc {
size := eleType . Size ( )
size := eleType . Size ( )
return func ( h * hasher , v addressableValue ) bool {
return func ( h * hasher , v addressableValue ) {
if v . IsNil ( ) {
if v . IsNil ( ) {
h . HashUint8 ( 0 ) // indicates nil
h . HashUint8 ( 0 ) // indicates nil
} else {
} else {
h . HashUint8 ( 1 ) // indicates visiting a pointer
h . HashUint8 ( 1 ) // indicates visiting a pointer
h . HashBytes ( unsafe . Slice ( ( * byte ) ( v . UnsafePointer ( ) ) , size ) )
h . HashBytes ( unsafe . Slice ( ( * byte ) ( v . UnsafePointer ( ) ) , size ) )
}
}
return true
}
}
}
}
@ -431,24 +408,23 @@ func genTypeHasher(ti *typeInfo) typeHasherFunc {
return genHashStructFields ( t )
return genHashStructFields ( t )
}
}
case reflect . Map :
case reflect . Map :
return func ( h * hasher , v addressableValue ) bool {
return func ( h * hasher , v addressableValue ) {
if v . IsNil ( ) {
if v . IsNil ( ) {
h . HashUint8 ( 0 ) // indicates nil
h . HashUint8 ( 0 ) // indicates nil
return true
return
}
}
if ti . isRecursive {
if ti . isRecursive {
ptr := pointerOf ( v )
ptr := pointerOf ( v )
if idx , ok := h . visitStack . seen ( ptr ) ; ok {
if idx , ok := h . visitStack . seen ( ptr ) ; ok {
h . HashUint8 ( 2 ) // indicates cycle
h . HashUint8 ( 2 ) // indicates cycle
h . HashUint64 ( uint64 ( idx ) )
h . HashUint64 ( uint64 ( idx ) )
return true
return
}
}
h . visitStack . push ( ptr )
h . visitStack . push ( ptr )
defer h . visitStack . pop ( ptr )
defer h . visitStack . pop ( ptr )
}
}
h . HashUint8 ( 1 ) // indicates visiting a map
h . HashUint8 ( 1 ) // indicates visiting a map
h . hashMap ( v , ti , ti . isRecursive )
h . hashMap ( v , ti , ti . isRecursive )
return true
}
}
case reflect . Pointer :
case reflect . Pointer :
et := t . Elem ( )
et := t . Elem ( )
@ -456,78 +432,72 @@ func genTypeHasher(ti *typeInfo) typeHasherFunc {
return genHashPtrToMemoryRange ( et )
return genHashPtrToMemoryRange ( et )
}
}
eti := getTypeInfo ( et )
eti := getTypeInfo ( et )
return func ( h * hasher , v addressableValue ) bool {
return func ( h * hasher , v addressableValue ) {
if v . IsNil ( ) {
if v . IsNil ( ) {
h . HashUint8 ( 0 ) // indicates nil
h . HashUint8 ( 0 ) // indicates nil
return true
return
}
}
if ti . isRecursive {
if ti . isRecursive {
ptr := pointerOf ( v )
ptr := pointerOf ( v )
if idx , ok := h . visitStack . seen ( ptr ) ; ok {
if idx , ok := h . visitStack . seen ( ptr ) ; ok {
h . HashUint8 ( 2 ) // indicates cycle
h . HashUint8 ( 2 ) // indicates cycle
h . HashUint64 ( uint64 ( idx ) )
h . HashUint64 ( uint64 ( idx ) )
return true
return
}
}
h . visitStack . push ( ptr )
h . visitStack . push ( ptr )
defer h . visitStack . pop ( ptr )
defer h . visitStack . pop ( ptr )
}
}
h . HashUint8 ( 1 ) // indicates visiting a pointer
h . HashUint8 ( 1 ) // indicates visiting a pointer
va := addressableValue { v . Elem ( ) } // dereferenced pointer is always addressable
va := addressableValue { v . Elem ( ) } // dereferenced pointer is always addressable
return eti . hasher ( ) ( h , va )
eti . hasher ( ) ( h , va )
}
}
case reflect . Interface :
case reflect . Interface :
return func ( h * hasher , v addressableValue ) bool {
return func ( h * hasher , v addressableValue ) {
if v . IsNil ( ) {
if v . IsNil ( ) {
h . HashUint8 ( 0 ) // indicates nil
h . HashUint8 ( 0 ) // indicates nil
return true
return
}
}
va := newAddressableValue ( v . Elem ( ) . Type ( ) )
va := newAddressableValue ( v . Elem ( ) . Type ( ) )
va . Set ( v . Elem ( ) )
va . Set ( v . Elem ( ) )
h . HashUint8 ( 1 ) // indicates visiting interface value
h . HashUint8 ( 1 ) // indicates visiting interface value
h . hashType ( va . Type ( ) )
h . hashType ( va . Type ( ) )
h. hashValue ( va , true )
ti := getTypeInfo ( va . Type ( ) )
return true
ti . hasher ( ) ( h , va )
}
}
default : // Func, Chan, UnsafePointer
default : // Func, Chan, UnsafePointer
return noopHasherFunc
return noopHasherFunc
}
}
}
}
// hashString hashes v, of kind String.
func ( h * hasher ) hashString ( v addressableValue ) {
func ( h * hasher ) hashString ( v addressableValue ) bool {
s := v . String ( )
s := v . String ( )
h . HashUint64 ( uint64 ( len ( s ) ) )
h . HashUint64 ( uint64 ( len ( s ) ) )
h . HashString ( s )
h . HashString ( s )
return true
}
}
func ( h * hasher ) hashFloat32v ( v addressableValue ) bool {
func ( h * hasher ) hashFloat32v ( v addressableValue ) {
h . HashUint32 ( math . Float32bits ( float32 ( v . Float ( ) ) ) )
h . HashUint32 ( math . Float32bits ( float32 ( v . Float ( ) ) ) )
return true
}
}
func ( h * hasher ) hashFloat64v ( v addressableValue ) bool {
func ( h * hasher ) hashFloat64v ( v addressableValue ) {
h . HashUint64 ( math . Float64bits ( v . Float ( ) ) )
h . HashUint64 ( math . Float64bits ( v . Float ( ) ) )
return true
}
}
func ( h * hasher ) hashComplex64v ( v addressableValue ) bool {
func ( h * hasher ) hashComplex64v ( v addressableValue ) {
c := complex64 ( v . Complex ( ) )
c := complex64 ( v . Complex ( ) )
h . HashUint32 ( math . Float32bits ( real ( c ) ) )
h . HashUint32 ( math . Float32bits ( real ( c ) ) )
h . HashUint32 ( math . Float32bits ( imag ( c ) ) )
h . HashUint32 ( math . Float32bits ( imag ( c ) ) )
return true
}
}
func ( h * hasher ) hashComplex128v ( v addressableValue ) bool {
func ( h * hasher ) hashComplex128v ( v addressableValue ) {
c := v . Complex ( )
c := v . Complex ( )
h . HashUint64 ( math . Float64bits ( real ( c ) ) )
h . HashUint64 ( math . Float64bits ( real ( c ) ) )
h . HashUint64 ( math . Float64bits ( imag ( c ) ) )
h . HashUint64 ( math . Float64bits ( imag ( c ) ) )
return true
}
}
// hashTimev hashes v, of kind time.Time.
// hashTimev hashes v, of kind time.Time.
func ( h * hasher ) hashTimev ( v addressableValue ) bool {
func ( h * hasher ) hashTimev ( v addressableValue ) {
// Include the zone offset (but not the name) to keep
// Include the zone offset (but not the name) to keep
// Hash(t1) == Hash(t2) being semantically equivalent to
// Hash(t1) == Hash(t2) being semantically equivalent to
// t1.Format(time.RFC3339Nano) == t2.Format(time.RFC3339Nano).
// t1.Format(time.RFC3339Nano) == t2.Format(time.RFC3339Nano).
@ -536,11 +506,10 @@ func (h *hasher) hashTimev(v addressableValue) bool {
h . HashUint64 ( uint64 ( t . Unix ( ) ) )
h . HashUint64 ( uint64 ( t . Unix ( ) ) )
h . HashUint32 ( uint32 ( t . Nanosecond ( ) ) )
h . HashUint32 ( uint32 ( t . Nanosecond ( ) ) )
h . HashUint32 ( uint32 ( offset ) )
h . HashUint32 ( uint32 ( offset ) )
return true
}
}
// hashAddrv hashes v, of type netip.Addr.
// hashAddrv hashes v, of type netip.Addr.
func ( h * hasher ) hashAddrv ( v addressableValue ) bool {
func ( h * hasher ) hashAddrv ( v addressableValue ) {
// The formatting of netip.Addr covers the
// The formatting of netip.Addr covers the
// IP version, the address, and the optional zone name (for v6).
// IP version, the address, and the optional zone name (for v6).
// This is equivalent to a1.MarshalBinary() == a2.MarshalBinary().
// This is equivalent to a1.MarshalBinary() == a2.MarshalBinary().
@ -560,40 +529,34 @@ func (h *hasher) hashAddrv(v addressableValue) bool {
h . HashUint64 ( binary . LittleEndian . Uint64 ( b [ 8 : ] ) )
h . HashUint64 ( binary . LittleEndian . Uint64 ( b [ 8 : ] ) )
h . HashString ( z )
h . HashString ( z )
}
}
return true
}
}
// hashSliceMem hashes v, of kind Slice, with a memhash-able element type.
// hashSliceMem hashes v, of kind Slice, with a memhash-able element type.
func ( h * hasher ) hashSliceMem ( v addressableValue ) bool {
func ( h * hasher ) hashSliceMem ( v addressableValue ) {
vLen := v . Len ( )
vLen := v . Len ( )
h . HashUint64 ( uint64 ( vLen ) )
h . HashUint64 ( uint64 ( vLen ) )
if vLen == 0 {
if vLen == 0 {
return true
return
}
}
h . HashBytes ( unsafe . Slice ( ( * byte ) ( v . UnsafePointer ( ) ) , v . Type ( ) . Elem ( ) . Size ( ) * uintptr ( vLen ) ) )
h . HashBytes ( unsafe . Slice ( ( * byte ) ( v . UnsafePointer ( ) ) , v . Type ( ) . Elem ( ) . Size ( ) * uintptr ( vLen ) ) )
return true
}
}
func genHashArrayMem ( n int , arraySize uintptr , efu * typeInfo ) typeHasherFunc {
func genHashArrayMem ( n int , arraySize uintptr , efu * typeInfo ) typeHasherFunc {
return func ( h * hasher , v addressableValue ) bool {
return func ( h * hasher , v addressableValue ) {
h . HashBytes ( unsafe . Slice ( ( * byte ) ( v . Addr ( ) . UnsafePointer ( ) ) , arraySize ) )
h . HashBytes ( unsafe . Slice ( ( * byte ) ( v . Addr ( ) . UnsafePointer ( ) ) , arraySize ) )
return true
}
}
}
}
func genHashArrayElements ( n int , eti * typeInfo ) typeHasherFunc {
func genHashArrayElements ( n int , eti * typeInfo ) typeHasherFunc {
return func ( h * hasher , v addressableValue ) bool {
return func ( h * hasher , v addressableValue ) {
for i := 0 ; i < n ; i ++ {
for i := 0 ; i < n ; i ++ {
va := addressableValue { v . Index ( i ) } // element is addressable if parent array is addressable
va := addressableValue { v . Index ( i ) } // element is addressable if parent array is addressable
if ! eti . hasher ( ) ( h , va ) {
eti . hasher ( ) ( h , va )
return false
}
}
}
return true
}
}
}
}
func noopHasherFunc ( h * hasher , v addressableValue ) bool { return true }
func noopHasherFunc ( h * hasher , v addressableValue ) { }
func genHashArray ( t reflect . Type , eti * typeInfo ) typeHasherFunc {
func genHashArray ( t reflect . Type , eti * typeInfo ) typeHasherFunc {
if t . Size ( ) == 0 {
if t . Size ( ) == 0 {
@ -615,17 +578,14 @@ type sliceElementHasher struct {
eti * typeInfo
eti * typeInfo
}
}
func ( seh sliceElementHasher ) hash ( h * hasher , v addressableValue ) bool {
func ( seh sliceElementHasher ) hash ( h * hasher , v addressableValue ) {
vLen := v . Len ( )
vLen := v . Len ( )
h . HashUint64 ( uint64 ( vLen ) )
h . HashUint64 ( uint64 ( vLen ) )
for i := 0 ; i < vLen ; i ++ {
for i := 0 ; i < vLen ; i ++ {
va := addressableValue { v . Index ( i ) } // slice elements are always addressable
va := addressableValue { v . Index ( i ) } // slice elements are always addressable
if ! seh . eti . hasher ( ) ( h , va ) {
seh . eti . hasher ( ) ( h , va )
return false
}
}
}
}
return true
}
func getTypeInfo ( t reflect . Type ) * typeInfo {
func getTypeInfo ( t reflect . Type ) * typeInfo {
if f , ok := typeInfoMap . Load ( t ) ; ok {
if f , ok := typeInfoMap . Load ( t ) ; ok {
@ -651,7 +611,6 @@ func getTypeInfoLocked(t reflect.Type, incomplete map[reflect.Type]*typeInfo) *t
ti := & typeInfo {
ti := & typeInfo {
rtype : t ,
rtype : t ,
isRecursive : typeIsRecursive ( t ) ,
isRecursive : typeIsRecursive ( t ) ,
canMemHash : typeIsMemHashable ( t ) ,
}
}
incomplete [ t ] = ti
incomplete [ t ] = ti
@ -666,140 +625,6 @@ func getTypeInfoLocked(t reflect.Type, incomplete map[reflect.Type]*typeInfo) *t
return ti
return ti
}
}
func ( h * hasher ) hashValue ( v addressableValue , forceCycleChecking bool ) {
if ! v . IsValid ( ) {
return
}
ti := getTypeInfo ( v . Type ( ) )
h . hashValueWithType ( v , ti , forceCycleChecking )
}
func ( h * hasher ) hashValueWithType ( v addressableValue , ti * typeInfo , forceCycleChecking bool ) {
doCheckCycles := forceCycleChecking || ti . isRecursive
if ti . hasher ( ) ( h , v ) {
return
}
// 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
}
if doCheckCycles {
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
va := addressableValue { v . Elem ( ) } // dereferenced pointer is always addressable
h . hashValueWithType ( va , ti . elemTypeInfo , doCheckCycles )
case reflect . Struct :
for i , n := 0 , v . NumField ( ) ; i < n ; i ++ {
va := addressableValue { v . Field ( i ) } // field is addressable if parent struct is addressable
h . hashValue ( va , doCheckCycles )
}
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 . Value )
h . HashBytes ( h . scratch [ : n ] )
return
}
fmt . Fprintf ( h , "%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
va := addressableValue { v . Index ( i ) } // slice elements are always addressable
h . hashValueWithType ( va , ti . elemTypeInfo , doCheckCycles )
}
case reflect . Interface :
if v . IsNil ( ) {
h . HashUint8 ( 0 ) // indicates nil
return
}
// TODO: Use a valueCache here?
va := newAddressableValue ( v . Elem ( ) . Type ( ) )
va . Set ( v . Elem ( ) )
h . HashUint8 ( 1 ) // indicates visiting interface value
h . hashType ( va . Type ( ) )
h . hashValue ( va , doCheckCycles )
case reflect . Map :
// Check for cycle.
if doCheckCycles {
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 , ti , doCheckCycles )
case reflect . String :
s := v . String ( )
h . HashUint64 ( uint64 ( len ( s ) ) )
h . HashString ( 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 {
type mapHasher struct {
h hasher
h hasher
valKey , valElem valueCache // re-usable values for map iteration
valKey , valElem valueCache // re-usable values for map iteration
@ -843,8 +668,8 @@ func (h *hasher) hashMap(v addressableValue, ti *typeInfo, checkCycles bool) {
k . SetIterKey ( iter )
k . SetIterKey ( iter )
e . SetIterValue ( iter )
e . SetIterValue ( iter )
mh . h . Reset ( )
mh . h . Reset ( )
mh. h . hashValueWithType ( k , ti . keyTypeInfo , checkCycles )
ti. keyTypeInfo . hasher ( ) ( & mh . h , k )
mh. h . hashValueWithType ( e , ti . elemTypeInfo , checkCycles )
ti. elemTypeInfo . hasher ( ) ( & mh . h , e )
sum . xor ( mh . h . sum ( ) )
sum . xor ( mh . h . sum ( ) )
}
}
h . HashBytes ( append ( h . scratch [ : 0 ] , sum . sum [ : ] ... ) ) // append into scratch to avoid heap allocation
h . HashBytes ( append ( h . scratch [ : 0 ] , sum . sum [ : ] ... ) ) // append into scratch to avoid heap allocation