vendor/github.com/mitchellh/hashstructure/hashstructure.go - third_party/github.com/docker/docker - Git at Google

 package hashstructure

 import (
 	"encoding/binary"
 	"fmt"
 	"hash"
 	"hash/fnv"
 	"reflect"
 )

 // ErrNotStringer is returned when there's an error with hash:"string"
 type ErrNotStringer struct {
 	Field string
 }

 // Error implements error for ErrNotStringer
 func (ens *ErrNotStringer) Error() string {
 	return fmt.Sprintf("hashstructure: %s has hash:\"string\" set, but does not implement fmt.Stringer", ens.Field)
 }

 // HashOptions are options that are available for hashing.
 type HashOptions struct {
 	// Hasher is the hash function to use. If this isn't set, it will
 	// default to FNV.
 	Hasher hash.Hash64

 	// TagName is the struct tag to look at when hashing the structure.
 	// By default this is "hash".
 	TagName string

 	// ZeroNil is flag determining if nil pointer should be treated equal
 	// to a zero value of pointed type. By default this is false.
 	ZeroNil bool
 }

 // Hash returns the hash value of an arbitrary value.
 //
 // If opts is nil, then default options will be used. See HashOptions
 // for the default values. The same *HashOptions value cannot be used
 // concurrently. None of the values within a *HashOptions struct are
 // safe to read/write while hashing is being done.
 //
 // Notes on the value:
 //
 //   * Unexported fields on structs are ignored and do not affect the
 //     hash value.
 //
 //   * Adding an exported field to a struct with the zero value will change
 //     the hash value.
 //
 // For structs, the hashing can be controlled using tags. For example:
 //
 //    struct {
 //        Name string
 //        UUID string `hash:"ignore"`
 //    }
 //
 // The available tag values are:
 //
 //   * "ignore" or "-" - The field will be ignored and not affect the hash code.
 //
 //   * "set" - The field will be treated as a set, where ordering doesn't
 //             affect the hash code. This only works for slices.
 //
 //   * "string" - The field will be hashed as a string, only works when the
 //                field implements fmt.Stringer
 //
 func Hash(v interface{}, opts *HashOptions) (uint64, error) {
 	// Create default options
 	if opts == nil {
 		opts = &HashOptions{}
 	}
 	if opts.Hasher == nil {
 		opts.Hasher = fnv.New64()
 	}
 	if opts.TagName == "" {
 		opts.TagName = "hash"
 	}

 	// Reset the hash
 	opts.Hasher.Reset()

 	// Create our walker and walk the structure
 	w := &walker{
 		h:       opts.Hasher,
 		tag:     opts.TagName,
 		zeronil: opts.ZeroNil,
 	}
 	return w.visit(reflect.ValueOf(v), nil)
 }

 type walker struct {
 	h       hash.Hash64
 	tag     string
 	zeronil bool
 }

 type visitOpts struct {
 	// Flags are a bitmask of flags to affect behavior of this visit
 	Flags visitFlag

 	// Information about the struct containing this field
 	Struct      interface{}
 	StructField string
 }

 func (w *walker) visit(v reflect.Value, opts *visitOpts) (uint64, error) {
 	t := reflect.TypeOf(0)

 	// Loop since these can be wrapped in multiple layers of pointers
 	// and interfaces.
 	for {
 		// If we have an interface, dereference it. We have to do this up
 		// here because it might be a nil in there and the check below must
 		// catch that.
 		if v.Kind() == reflect.Interface {
 			v = v.Elem()
 			continue
 		}

 		if v.Kind() == reflect.Ptr {
 			if w.zeronil {
 				t = v.Type().Elem()
 			}
 			v = reflect.Indirect(v)
 			continue
 		}

 		break
 	}

 	// If it is nil, treat it like a zero.
 	if !v.IsValid() {
 		v = reflect.Zero(t)
 	}

 	// Binary writing can use raw ints, we have to convert to
 	// a sized-int, we'll choose the largest...
 	switch v.Kind() {
 	case reflect.Int:
 		v = reflect.ValueOf(int64(v.Int()))
 	case reflect.Uint:
 		v = reflect.ValueOf(uint64(v.Uint()))
 	case reflect.Bool:
 		var tmp int8
 		if v.Bool() {
 			tmp = 1
 		}
 		v = reflect.ValueOf(tmp)
 	}

 	k := v.Kind()

 	// We can shortcut numeric values by directly binary writing them
 	if k >= reflect.Int && k <= reflect.Complex64 {
 		// A direct hash calculation
 		w.h.Reset()
 		err := binary.Write(w.h, binary.LittleEndian, v.Interface())
 		return w.h.Sum64(), err
 	}

 	switch k {
 	case reflect.Array:
 		var h uint64
 		l := v.Len()
 		for i := 0; i < l; i++ {
 			current, err := w.visit(v.Index(i), nil)
 			if err != nil {
 				return 0, err
 			}

 			h = hashUpdateOrdered(w.h, h, current)
 		}

 		return h, nil

 	case reflect.Map:
 		var includeMap IncludableMap
 		if opts != nil && opts.Struct != nil {
 			if v, ok := opts.Struct.(IncludableMap); ok {
 				includeMap = v
 			}
 		}

 		// Build the hash for the map. We do this by XOR-ing all the key
 		// and value hashes. This makes it deterministic despite ordering.
 		var h uint64
 		for _, k := range v.MapKeys() {
 			v := v.MapIndex(k)
 			if includeMap != nil {
 				incl, err := includeMap.HashIncludeMap(
 					opts.StructField, k.Interface(), v.Interface())
 				if err != nil {
 					return 0, err
 				}
 				if !incl {
 					continue
 				}
 			}

 			kh, err := w.visit(k, nil)
 			if err != nil {
 				return 0, err
 			}
 			vh, err := w.visit(v, nil)
 			if err != nil {
 				return 0, err
 			}

 			fieldHash := hashUpdateOrdered(w.h, kh, vh)
 			h = hashUpdateUnordered(h, fieldHash)
 		}

 		return h, nil

 	case reflect.Struct:
 		parent := v.Interface()
 		var include Includable
 		if impl, ok := parent.(Includable); ok {
 			include = impl
 		}

 		t := v.Type()
 		h, err := w.visit(reflect.ValueOf(t.Name()), nil)
 		if err != nil {
 			return 0, err
 		}

 		l := v.NumField()
 		for i := 0; i < l; i++ {
 			if innerV := v.Field(i); v.CanSet() || t.Field(i).Name != "_" {
 				var f visitFlag
 				fieldType := t.Field(i)
 				if fieldType.PkgPath != "" {
 					// Unexported
 					continue
 				}

 				tag := fieldType.Tag.Get(w.tag)
 				if tag == "ignore" || tag == "-" {
 					// Ignore this field
 					continue
 				}

 				// if string is set, use the string value
 				if tag == "string" {
 					if impl, ok := innerV.Interface().(fmt.Stringer); ok {
 						innerV = reflect.ValueOf(impl.String())
 					} else {
 						return 0, &ErrNotStringer{
 							Field: v.Type().Field(i).Name,
 						}
 					}
 				}

 				// Check if we implement includable and check it
 				if include != nil {
 					incl, err := include.HashInclude(fieldType.Name, innerV)
 					if err != nil {
 						return 0, err
 					}
 					if !incl {
 						continue
 					}
 				}

 				switch tag {
 				case "set":
 					f |= visitFlagSet
 				}

 				kh, err := w.visit(reflect.ValueOf(fieldType.Name), nil)
 				if err != nil {
 					return 0, err
 				}

 				vh, err := w.visit(innerV, &visitOpts{
 					Flags:       f,
 					Struct:      parent,
 					StructField: fieldType.Name,
 				})
 				if err != nil {
 					return 0, err
 				}

 				fieldHash := hashUpdateOrdered(w.h, kh, vh)
 				h = hashUpdateUnordered(h, fieldHash)
 			}
 		}

 		return h, nil

 	case reflect.Slice:
 		// We have two behaviors here. If it isn't a set, then we just
 		// visit all the elements. If it is a set, then we do a deterministic
 		// hash code.
 		var h uint64
 		var set bool
 		if opts != nil {
 			set = (opts.Flags & visitFlagSet) != 0
 		}
 		l := v.Len()
 		for i := 0; i < l; i++ {
 			current, err := w.visit(v.Index(i), nil)
 			if err != nil {
 				return 0, err
 			}

 			if set {
 				h = hashUpdateUnordered(h, current)
 			} else {
 				h = hashUpdateOrdered(w.h, h, current)
 			}
 		}

 		return h, nil

 	case reflect.String:
 		// Directly hash
 		w.h.Reset()
 		_, err := w.h.Write([]byte(v.String()))
 		return w.h.Sum64(), err

 	default:
 		return 0, fmt.Errorf("unknown kind to hash: %s", k)
 	}

 }

 func hashUpdateOrdered(h hash.Hash64, a, b uint64) uint64 {
 	// For ordered updates, use a real hash function
 	h.Reset()

 	// We just panic if the binary writes fail because we are writing
 	// an int64 which should never be fail-able.
 	e1 := binary.Write(h, binary.LittleEndian, a)
 	e2 := binary.Write(h, binary.LittleEndian, b)
 	if e1 != nil {
 		panic(e1)
 	}
 	if e2 != nil {
 		panic(e2)
 	}

 	return h.Sum64()
 }

 func hashUpdateUnordered(a, b uint64) uint64 {
 	return a ^ b
 }

 // visitFlag is used as a bitmask for affecting visit behavior
 type visitFlag uint

 const (
 	visitFlagInvalid visitFlag = iota
 	visitFlagSet               = iota << 1
 )
	package hashstructure

	import (
	"encoding/binary"
	"fmt"
	"hash"
	"hash/fnv"
	"reflect"
	)

	// ErrNotStringer is returned when there's an error with hash:"string"
	type ErrNotStringer struct {
	Field string
	}

	// Error implements error for ErrNotStringer
	func (ens *ErrNotStringer) Error() string {
	return fmt.Sprintf("hashstructure: %s has hash:\"string\" set, but does not implement fmt.Stringer", ens.Field)
	}

	// HashOptions are options that are available for hashing.
	type HashOptions struct {
	// Hasher is the hash function to use. If this isn't set, it will
	// default to FNV.
	Hasher hash.Hash64

	// TagName is the struct tag to look at when hashing the structure.
	// By default this is "hash".
	TagName string

	// ZeroNil is flag determining if nil pointer should be treated equal
	// to a zero value of pointed type. By default this is false.
	ZeroNil bool
	}

	// Hash returns the hash value of an arbitrary value.
	//
	// If opts is nil, then default options will be used. See HashOptions
	// for the default values. The same *HashOptions value cannot be used
	// concurrently. None of the values within a *HashOptions struct are
	// safe to read/write while hashing is being done.
	//
	// Notes on the value:
	//
	// * Unexported fields on structs are ignored and do not affect the
	// hash value.
	//
	// * Adding an exported field to a struct with the zero value will change
	// the hash value.
	//
	// For structs, the hashing can be controlled using tags. For example:
	//
	// struct {
	// Name string
	// UUID string `hash:"ignore"`
	// }
	//
	// The available tag values are:
	//
	// * "ignore" or "-" - The field will be ignored and not affect the hash code.
	//
	// * "set" - The field will be treated as a set, where ordering doesn't
	// affect the hash code. This only works for slices.
	//
	// * "string" - The field will be hashed as a string, only works when the
	// field implements fmt.Stringer
	//
	func Hash(v interface{}, opts *HashOptions) (uint64, error) {
	// Create default options
	if opts == nil {
	opts = &HashOptions{}
	}
	if opts.Hasher == nil {
	opts.Hasher = fnv.New64()
	}
	if opts.TagName == "" {
	opts.TagName = "hash"
	}

	// Reset the hash
	opts.Hasher.Reset()

	// Create our walker and walk the structure
	w := &walker{
	h: opts.Hasher,
	tag: opts.TagName,
	zeronil: opts.ZeroNil,
	}
	return w.visit(reflect.ValueOf(v), nil)
	}

	type walker struct {
	h hash.Hash64
	tag string
	zeronil bool
	}

	type visitOpts struct {
	// Flags are a bitmask of flags to affect behavior of this visit
	Flags visitFlag

	// Information about the struct containing this field
	Struct interface{}
	StructField string
	}

	func (w walker) visit(v reflect.Value, opts visitOpts) (uint64, error) {
	t := reflect.TypeOf(0)

	// Loop since these can be wrapped in multiple layers of pointers
	// and interfaces.
	for {
	// If we have an interface, dereference it. We have to do this up
	// here because it might be a nil in there and the check below must
	// catch that.
	if v.Kind() == reflect.Interface {
	v = v.Elem()
	continue
	}

	if v.Kind() == reflect.Ptr {
	if w.zeronil {
	t = v.Type().Elem()
	}
	v = reflect.Indirect(v)
	continue
	}

	break
	}

	// If it is nil, treat it like a zero.
	if !v.IsValid() {
	v = reflect.Zero(t)
	}

	// Binary writing can use raw ints, we have to convert to
	// a sized-int, we'll choose the largest...
	switch v.Kind() {
	case reflect.Int:
	v = reflect.ValueOf(int64(v.Int()))
	case reflect.Uint:
	v = reflect.ValueOf(uint64(v.Uint()))
	case reflect.Bool:
	var tmp int8
	if v.Bool() {
	tmp = 1
	}
	v = reflect.ValueOf(tmp)
	}

	k := v.Kind()

	// We can shortcut numeric values by directly binary writing them
	if k >= reflect.Int && k <= reflect.Complex64 {
	// A direct hash calculation
	w.h.Reset()
	err := binary.Write(w.h, binary.LittleEndian, v.Interface())
	return w.h.Sum64(), err
	}

	switch k {
	case reflect.Array:
	var h uint64
	l := v.Len()
	for i := 0; i < l; i++ {
	current, err := w.visit(v.Index(i), nil)
	if err != nil {
	return 0, err
	}

	h = hashUpdateOrdered(w.h, h, current)
	}

	return h, nil

	case reflect.Map:
	var includeMap IncludableMap
	if opts != nil && opts.Struct != nil {
	if v, ok := opts.Struct.(IncludableMap); ok {
	includeMap = v
	}
	}

	// Build the hash for the map. We do this by XOR-ing all the key
	// and value hashes. This makes it deterministic despite ordering.
	var h uint64
	for _, k := range v.MapKeys() {
	v := v.MapIndex(k)
	if includeMap != nil {
	incl, err := includeMap.HashIncludeMap(
	opts.StructField, k.Interface(), v.Interface())
	if err != nil {
	return 0, err
	}
	if !incl {
	continue
	}
	}

	kh, err := w.visit(k, nil)
	if err != nil {
	return 0, err
	}
	vh, err := w.visit(v, nil)
	if err != nil {
	return 0, err
	}

	fieldHash := hashUpdateOrdered(w.h, kh, vh)
	h = hashUpdateUnordered(h, fieldHash)
	}

	return h, nil

	case reflect.Struct:
	parent := v.Interface()
	var include Includable
	if impl, ok := parent.(Includable); ok {
	include = impl
	}

	t := v.Type()
	h, err := w.visit(reflect.ValueOf(t.Name()), nil)
	if err != nil {
	return 0, err
	}

	l := v.NumField()
	for i := 0; i < l; i++ {
	if innerV := v.Field(i); v.CanSet() \|\| t.Field(i).Name != "_" {
	var f visitFlag
	fieldType := t.Field(i)
	if fieldType.PkgPath != "" {
	// Unexported
	continue
	}

	tag := fieldType.Tag.Get(w.tag)
	if tag == "ignore" \|\| tag == "-" {
	// Ignore this field
	continue
	}

	// if string is set, use the string value
	if tag == "string" {
	if impl, ok := innerV.Interface().(fmt.Stringer); ok {
	innerV = reflect.ValueOf(impl.String())
	} else {
	return 0, &ErrNotStringer{
	Field: v.Type().Field(i).Name,
	}
	}
	}

	// Check if we implement includable and check it
	if include != nil {
	incl, err := include.HashInclude(fieldType.Name, innerV)
	if err != nil {
	return 0, err
	}
	if !incl {
	continue
	}
	}

	switch tag {
	case "set":
	f \|= visitFlagSet
	}

	kh, err := w.visit(reflect.ValueOf(fieldType.Name), nil)
	if err != nil {
	return 0, err
	}

	vh, err := w.visit(innerV, &visitOpts{
	Flags: f,
	Struct: parent,
	StructField: fieldType.Name,
	})
	if err != nil {
	return 0, err
	}

	fieldHash := hashUpdateOrdered(w.h, kh, vh)
	h = hashUpdateUnordered(h, fieldHash)
	}
	}

	return h, nil

	case reflect.Slice:
	// We have two behaviors here. If it isn't a set, then we just
	// visit all the elements. If it is a set, then we do a deterministic
	// hash code.
	var h uint64
	var set bool
	if opts != nil {
	set = (opts.Flags & visitFlagSet) != 0
	}
	l := v.Len()
	for i := 0; i < l; i++ {
	current, err := w.visit(v.Index(i), nil)
	if err != nil {
	return 0, err
	}

	if set {
	h = hashUpdateUnordered(h, current)
	} else {
	h = hashUpdateOrdered(w.h, h, current)
	}
	}

	return h, nil

	case reflect.String:
	// Directly hash
	w.h.Reset()
	_, err := w.h.Write([]byte(v.String()))
	return w.h.Sum64(), err

	default:
	return 0, fmt.Errorf("unknown kind to hash: %s", k)
	}

	}

	func hashUpdateOrdered(h hash.Hash64, a, b uint64) uint64 {
	// For ordered updates, use a real hash function
	h.Reset()

	// We just panic if the binary writes fail because we are writing
	// an int64 which should never be fail-able.
	e1 := binary.Write(h, binary.LittleEndian, a)
	e2 := binary.Write(h, binary.LittleEndian, b)
	if e1 != nil {
	panic(e1)
	}
	if e2 != nil {
	panic(e2)
	}

	return h.Sum64()
	}

	func hashUpdateUnordered(a, b uint64) uint64 {
	return a ^ b
	}

	// visitFlag is used as a bitmask for affecting visit behavior
	type visitFlag uint

	const (
	visitFlagInvalid visitFlag = iota
	visitFlagSet = iota << 1
	)