ARO-RP/vendor/github.com/jinzhu/copier/copier.go

829 строки
21 KiB
Go
Исходник Постоянная ссылка Обычный вид История

package copier
import (
"database/sql"
"database/sql/driver"
"fmt"
"reflect"
"strings"
"sync"
"unicode"
)
// These flags define options for tag handling
const (
// Denotes that a destination field must be copied to. If copying fails then a panic will ensue.
tagMust uint8 = 1 << iota
// Denotes that the program should not panic when the must flag is on and
// value is not copied. The program will return an error instead.
tagNoPanic
// Ignore a destination field from being copied to.
tagIgnore
// Denotes that the value as been copied
hasCopied
// Some default converter types for a nicer syntax
String string = ""
Bool bool = false
Int int = 0
Float32 float32 = 0
Float64 float64 = 0
)
// Option sets copy options
type Option struct {
// setting this value to true will ignore copying zero values of all the fields, including bools, as well as a
// struct having all it's fields set to their zero values respectively (see IsZero() in reflect/value.go)
IgnoreEmpty bool
CaseSensitive bool
DeepCopy bool
Converters []TypeConverter
// Custom field name mappings to copy values with different names in `fromValue` and `toValue` types.
// Examples can be found in `copier_field_name_mapping_test.go`.
FieldNameMapping []FieldNameMapping
}
func (opt Option) converters() map[converterPair]TypeConverter {
var converters = map[converterPair]TypeConverter{}
// save converters into map for faster lookup
for i := range opt.Converters {
pair := converterPair{
SrcType: reflect.TypeOf(opt.Converters[i].SrcType),
DstType: reflect.TypeOf(opt.Converters[i].DstType),
}
converters[pair] = opt.Converters[i]
}
return converters
}
type TypeConverter struct {
SrcType interface{}
DstType interface{}
Fn func(src interface{}) (dst interface{}, err error)
}
type converterPair struct {
SrcType reflect.Type
DstType reflect.Type
}
func (opt Option) fieldNameMapping() map[converterPair]FieldNameMapping {
var mapping = map[converterPair]FieldNameMapping{}
for i := range opt.FieldNameMapping {
pair := converterPair{
SrcType: reflect.TypeOf(opt.FieldNameMapping[i].SrcType),
DstType: reflect.TypeOf(opt.FieldNameMapping[i].DstType),
}
mapping[pair] = opt.FieldNameMapping[i]
}
return mapping
}
type FieldNameMapping struct {
SrcType interface{}
DstType interface{}
Mapping map[string]string
}
// Tag Flags
type flags struct {
BitFlags map[string]uint8
SrcNames tagNameMapping
DestNames tagNameMapping
}
// Field Tag name mapping
type tagNameMapping struct {
FieldNameToTag map[string]string
TagToFieldName map[string]string
}
// Copy copy things
func Copy(toValue interface{}, fromValue interface{}) (err error) {
return copier(toValue, fromValue, Option{})
}
// CopyWithOption copy with option
func CopyWithOption(toValue interface{}, fromValue interface{}, opt Option) (err error) {
return copier(toValue, fromValue, opt)
}
func copier(toValue interface{}, fromValue interface{}, opt Option) (err error) {
var (
isSlice bool
amount = 1
from = indirect(reflect.ValueOf(fromValue))
to = indirect(reflect.ValueOf(toValue))
converters = opt.converters()
mappings = opt.fieldNameMapping()
)
if !to.CanAddr() {
return ErrInvalidCopyDestination
}
// Return is from value is invalid
if !from.IsValid() {
return ErrInvalidCopyFrom
}
fromType, isPtrFrom := indirectType(from.Type())
toType, _ := indirectType(to.Type())
if fromType.Kind() == reflect.Interface {
fromType = reflect.TypeOf(from.Interface())
}
if toType.Kind() == reflect.Interface {
toType, _ = indirectType(reflect.TypeOf(to.Interface()))
oldTo := to
to = reflect.New(reflect.TypeOf(to.Interface())).Elem()
defer func() {
oldTo.Set(to)
}()
}
// Just set it if possible to assign for normal types
if from.Kind() != reflect.Slice && from.Kind() != reflect.Struct && from.Kind() != reflect.Map && (from.Type().AssignableTo(to.Type()) || from.Type().ConvertibleTo(to.Type())) {
if !isPtrFrom || !opt.DeepCopy {
to.Set(from.Convert(to.Type()))
} else {
fromCopy := reflect.New(from.Type())
fromCopy.Set(from.Elem())
to.Set(fromCopy.Convert(to.Type()))
}
return
}
if from.Kind() != reflect.Slice && fromType.Kind() == reflect.Map && toType.Kind() == reflect.Map {
if !fromType.Key().ConvertibleTo(toType.Key()) {
return ErrMapKeyNotMatch
}
if to.IsNil() {
to.Set(reflect.MakeMapWithSize(toType, from.Len()))
}
for _, k := range from.MapKeys() {
toKey := indirect(reflect.New(toType.Key()))
isSet, err := set(toKey, k, opt.DeepCopy, converters)
if err != nil {
return err
}
if !isSet {
return fmt.Errorf("%w map, old key: %v, new key: %v", ErrNotSupported, k.Type(), toType.Key())
}
elemType := toType.Elem()
if elemType.Kind() != reflect.Slice {
elemType, _ = indirectType(elemType)
}
toValue := indirect(reflect.New(elemType))
isSet, err = set(toValue, from.MapIndex(k), opt.DeepCopy, converters)
if err != nil {
return err
}
if !isSet {
if err = copier(toValue.Addr().Interface(), from.MapIndex(k).Interface(), opt); err != nil {
return err
}
}
for {
if elemType == toType.Elem() {
to.SetMapIndex(toKey, toValue)
break
}
elemType = reflect.PtrTo(elemType)
toValue = toValue.Addr()
}
}
return
}
if from.Kind() == reflect.Slice && to.Kind() == reflect.Slice {
if to.IsNil() {
slice := reflect.MakeSlice(reflect.SliceOf(to.Type().Elem()), from.Len(), from.Cap())
to.Set(slice)
}
if fromType.ConvertibleTo(toType) {
for i := 0; i < from.Len(); i++ {
if to.Len() < i+1 {
to.Set(reflect.Append(to, reflect.New(to.Type().Elem()).Elem()))
}
isSet, err := set(to.Index(i), from.Index(i), opt.DeepCopy, converters)
if err != nil {
return err
}
if !isSet {
// ignore error while copy slice element
err = copier(to.Index(i).Addr().Interface(), from.Index(i).Interface(), opt)
if err != nil {
continue
}
}
}
return
}
}
if fromType.Kind() != reflect.Struct || toType.Kind() != reflect.Struct {
// skip not supported type
return
}
if len(converters) > 0 {
if ok, e := set(to, from, opt.DeepCopy, converters); e == nil && ok {
// converter supported
return
}
}
if from.Kind() == reflect.Slice || to.Kind() == reflect.Slice {
isSlice = true
if from.Kind() == reflect.Slice {
amount = from.Len()
}
}
for i := 0; i < amount; i++ {
var dest, source reflect.Value
if isSlice {
// source
if from.Kind() == reflect.Slice {
source = indirect(from.Index(i))
} else {
source = indirect(from)
}
// dest
dest = indirect(reflect.New(toType).Elem())
} else {
source = indirect(from)
dest = indirect(to)
}
if len(converters) > 0 {
if ok, e := set(dest, source, opt.DeepCopy, converters); e == nil && ok {
if isSlice {
// FIXME: maybe should check the other types?
if to.Type().Elem().Kind() == reflect.Ptr {
to.Index(i).Set(dest.Addr())
} else {
if to.Len() < i+1 {
reflect.Append(to, dest)
} else {
to.Index(i).Set(dest)
}
}
} else {
to.Set(dest)
}
continue
}
}
destKind := dest.Kind()
initDest := false
if destKind == reflect.Interface {
initDest = true
dest = indirect(reflect.New(toType))
}
// Get tag options
flgs, err := getFlags(dest, source, toType, fromType)
if err != nil {
return err
}
// check source
if source.IsValid() {
copyUnexportedStructFields(dest, source)
// Copy from source field to dest field or method
fromTypeFields := deepFields(fromType)
for _, field := range fromTypeFields {
name := field.Name
// Get bit flags for field
fieldFlags := flgs.BitFlags[name]
// Check if we should ignore copying
if (fieldFlags & tagIgnore) != 0 {
continue
}
fieldNamesMapping := getFieldNamesMapping(mappings, fromType, toType)
srcFieldName, destFieldName := getFieldName(name, flgs, fieldNamesMapping)
if fromField := fieldByNameOrZeroValue(source, srcFieldName); fromField.IsValid() && !shouldIgnore(fromField, opt.IgnoreEmpty) {
// process for nested anonymous field
destFieldNotSet := false
if f, ok := dest.Type().FieldByName(destFieldName); ok {
// only initialize parent embedded struct pointer in the path
for idx := range f.Index[:len(f.Index)-1] {
destField := dest.FieldByIndex(f.Index[:idx+1])
if destField.Kind() != reflect.Ptr {
continue
}
if !destField.IsNil() {
continue
}
if !destField.CanSet() {
destFieldNotSet = true
break
}
// destField is a nil pointer that can be set
newValue := reflect.New(destField.Type().Elem())
destField.Set(newValue)
}
}
if destFieldNotSet {
break
}
toField := fieldByName(dest, destFieldName, opt.CaseSensitive)
if toField.IsValid() {
if toField.CanSet() {
isSet, err := set(toField, fromField, opt.DeepCopy, converters)
if err != nil {
return err
}
if !isSet {
if err := copier(toField.Addr().Interface(), fromField.Interface(), opt); err != nil {
return err
}
}
if fieldFlags != 0 {
// Note that a copy was made
flgs.BitFlags[name] = fieldFlags | hasCopied
}
}
} else {
// try to set to method
var toMethod reflect.Value
if dest.CanAddr() {
toMethod = dest.Addr().MethodByName(destFieldName)
} else {
toMethod = dest.MethodByName(destFieldName)
}
if toMethod.IsValid() && toMethod.Type().NumIn() == 1 && fromField.Type().AssignableTo(toMethod.Type().In(0)) {
toMethod.Call([]reflect.Value{fromField})
}
}
}
}
// Copy from from method to dest field
for _, field := range deepFields(toType) {
name := field.Name
srcFieldName, destFieldName := getFieldName(name, flgs, getFieldNamesMapping(mappings, fromType, toType))
var fromMethod reflect.Value
if source.CanAddr() {
fromMethod = source.Addr().MethodByName(srcFieldName)
} else {
fromMethod = source.MethodByName(srcFieldName)
}
if fromMethod.IsValid() && fromMethod.Type().NumIn() == 0 && fromMethod.Type().NumOut() == 1 && !shouldIgnore(fromMethod, opt.IgnoreEmpty) {
if toField := fieldByName(dest, destFieldName, opt.CaseSensitive); toField.IsValid() && toField.CanSet() {
values := fromMethod.Call([]reflect.Value{})
if len(values) >= 1 {
set(toField, values[0], opt.DeepCopy, converters)
}
}
}
}
}
if isSlice && to.Kind() == reflect.Slice {
if dest.Addr().Type().AssignableTo(to.Type().Elem()) {
if to.Len() < i+1 {
to.Set(reflect.Append(to, dest.Addr()))
} else {
isSet, err := set(to.Index(i), dest.Addr(), opt.DeepCopy, converters)
if err != nil {
return err
}
if !isSet {
// ignore error while copy slice element
err = copier(to.Index(i).Addr().Interface(), dest.Addr().Interface(), opt)
if err != nil {
continue
}
}
}
} else if dest.Type().AssignableTo(to.Type().Elem()) {
if to.Len() < i+1 {
to.Set(reflect.Append(to, dest))
} else {
isSet, err := set(to.Index(i), dest, opt.DeepCopy, converters)
if err != nil {
return err
}
if !isSet {
// ignore error while copy slice element
err = copier(to.Index(i).Addr().Interface(), dest.Interface(), opt)
if err != nil {
continue
}
}
}
}
} else if initDest {
to.Set(dest)
}
err = checkBitFlags(flgs.BitFlags)
}
return
}
func getFieldNamesMapping(mappings map[converterPair]FieldNameMapping, fromType reflect.Type, toType reflect.Type) map[string]string {
var fieldNamesMapping map[string]string
if len(mappings) > 0 {
pair := converterPair{
SrcType: fromType,
DstType: toType,
}
if v, ok := mappings[pair]; ok {
fieldNamesMapping = v.Mapping
}
}
return fieldNamesMapping
}
func fieldByNameOrZeroValue(source reflect.Value, fieldName string) (value reflect.Value) {
defer func() {
if err := recover(); err != nil {
value = reflect.Value{}
}
}()
return source.FieldByName(fieldName)
}
func copyUnexportedStructFields(to, from reflect.Value) {
if from.Kind() != reflect.Struct || to.Kind() != reflect.Struct || !from.Type().AssignableTo(to.Type()) {
return
}
// create a shallow copy of 'to' to get all fields
tmp := indirect(reflect.New(to.Type()))
tmp.Set(from)
// revert exported fields
for i := 0; i < to.NumField(); i++ {
if tmp.Field(i).CanSet() {
tmp.Field(i).Set(to.Field(i))
}
}
to.Set(tmp)
}
func shouldIgnore(v reflect.Value, ignoreEmpty bool) bool {
return ignoreEmpty && v.IsZero()
}
var deepFieldsLock sync.RWMutex
var deepFieldsMap = make(map[reflect.Type][]reflect.StructField)
func deepFields(reflectType reflect.Type) []reflect.StructField {
deepFieldsLock.RLock()
cache, ok := deepFieldsMap[reflectType]
deepFieldsLock.RUnlock()
if ok {
return cache
}
var res []reflect.StructField
if reflectType, _ = indirectType(reflectType); reflectType.Kind() == reflect.Struct {
fields := make([]reflect.StructField, 0, reflectType.NumField())
for i := 0; i < reflectType.NumField(); i++ {
v := reflectType.Field(i)
// PkgPath is the package path that qualifies a lower case (unexported)
// field name. It is empty for upper case (exported) field names.
// See https://golang.org/ref/spec#Uniqueness_of_identifiers
if v.PkgPath == "" {
fields = append(fields, v)
if v.Anonymous {
// also consider fields of anonymous fields as fields of the root
fields = append(fields, deepFields(v.Type)...)
}
}
}
res = fields
}
deepFieldsLock.Lock()
deepFieldsMap[reflectType] = res
deepFieldsLock.Unlock()
return res
}
func indirect(reflectValue reflect.Value) reflect.Value {
for reflectValue.Kind() == reflect.Ptr {
reflectValue = reflectValue.Elem()
}
return reflectValue
}
func indirectType(reflectType reflect.Type) (_ reflect.Type, isPtr bool) {
for reflectType.Kind() == reflect.Ptr || reflectType.Kind() == reflect.Slice {
reflectType = reflectType.Elem()
isPtr = true
}
return reflectType, isPtr
}
func set(to, from reflect.Value, deepCopy bool, converters map[converterPair]TypeConverter) (bool, error) {
if !from.IsValid() {
return true, nil
}
if ok, err := lookupAndCopyWithConverter(to, from, converters); err != nil {
return false, err
} else if ok {
return true, nil
}
if to.Kind() == reflect.Ptr {
// set `to` to nil if from is nil
if from.Kind() == reflect.Ptr && from.IsNil() {
to.Set(reflect.Zero(to.Type()))
return true, nil
} else if to.IsNil() {
// `from` -> `to`
// sql.NullString -> *string
if fromValuer, ok := driverValuer(from); ok {
v, err := fromValuer.Value()
if err != nil {
return true, nil
}
// if `from` is not valid do nothing with `to`
if v == nil {
return true, nil
}
}
// allocate new `to` variable with default value (eg. *string -> new(string))
to.Set(reflect.New(to.Type().Elem()))
}
// depointer `to`
to = to.Elem()
}
if deepCopy {
toKind := to.Kind()
if toKind == reflect.Interface && to.IsNil() {
if reflect.TypeOf(from.Interface()) != nil {
to.Set(reflect.New(reflect.TypeOf(from.Interface())).Elem())
toKind = reflect.TypeOf(to.Interface()).Kind()
}
}
if from.Kind() == reflect.Ptr && from.IsNil() {
return true, nil
}
if _, ok := to.Addr().Interface().(sql.Scanner); !ok && (toKind == reflect.Struct || toKind == reflect.Map || toKind == reflect.Slice) {
return false, nil
}
}
if from.Type().ConvertibleTo(to.Type()) {
to.Set(from.Convert(to.Type()))
} else if toScanner, ok := to.Addr().Interface().(sql.Scanner); ok {
// `from` -> `to`
// *string -> sql.NullString
if from.Kind() == reflect.Ptr {
// if `from` is nil do nothing with `to`
if from.IsNil() {
return true, nil
}
// depointer `from`
from = indirect(from)
}
// `from` -> `to`
// string -> sql.NullString
// set `to` by invoking method Scan(`from`)
err := toScanner.Scan(from.Interface())
if err != nil {
return false, nil
}
} else if fromValuer, ok := driverValuer(from); ok {
// `from` -> `to`
// sql.NullString -> string
v, err := fromValuer.Value()
if err != nil {
return false, nil
}
// if `from` is not valid do nothing with `to`
if v == nil {
return true, nil
}
rv := reflect.ValueOf(v)
if rv.Type().AssignableTo(to.Type()) {
to.Set(rv)
} else if to.CanSet() && rv.Type().ConvertibleTo(to.Type()) {
to.Set(rv.Convert(to.Type()))
}
} else if from.Kind() == reflect.Ptr {
return set(to, from.Elem(), deepCopy, converters)
} else {
return false, nil
}
return true, nil
}
// lookupAndCopyWithConverter looks up the type pair, on success the TypeConverter Fn func is called to copy src to dst field.
func lookupAndCopyWithConverter(to, from reflect.Value, converters map[converterPair]TypeConverter) (copied bool, err error) {
pair := converterPair{
SrcType: from.Type(),
DstType: to.Type(),
}
if cnv, ok := converters[pair]; ok {
result, err := cnv.Fn(from.Interface())
if err != nil {
return false, err
}
if result != nil {
to.Set(reflect.ValueOf(result))
} else {
// in case we've got a nil value to copy
to.Set(reflect.Zero(to.Type()))
}
return true, nil
}
return false, nil
}
// parseTags Parses struct tags and returns uint8 bit flags.
func parseTags(tag string) (flg uint8, name string, err error) {
for _, t := range strings.Split(tag, ",") {
switch t {
case "-":
flg = tagIgnore
return
case "must":
flg = flg | tagMust
case "nopanic":
flg = flg | tagNoPanic
default:
if unicode.IsUpper([]rune(t)[0]) {
name = strings.TrimSpace(t)
} else {
err = ErrFieldNameTagStartNotUpperCase
}
}
}
return
}
// getTagFlags Parses struct tags for bit flags, field name.
func getFlags(dest, src reflect.Value, toType, fromType reflect.Type) (flags, error) {
flgs := flags{
BitFlags: map[string]uint8{},
SrcNames: tagNameMapping{
FieldNameToTag: map[string]string{},
TagToFieldName: map[string]string{},
},
DestNames: tagNameMapping{
FieldNameToTag: map[string]string{},
TagToFieldName: map[string]string{},
},
}
var toTypeFields, fromTypeFields []reflect.StructField
if dest.IsValid() {
toTypeFields = deepFields(toType)
}
if src.IsValid() {
fromTypeFields = deepFields(fromType)
}
// Get a list dest of tags
for _, field := range toTypeFields {
tags := field.Tag.Get("copier")
if tags != "" {
var name string
var err error
if flgs.BitFlags[field.Name], name, err = parseTags(tags); err != nil {
return flags{}, err
} else if name != "" {
flgs.DestNames.FieldNameToTag[field.Name] = name
flgs.DestNames.TagToFieldName[name] = field.Name
}
}
}
// Get a list source of tags
for _, field := range fromTypeFields {
tags := field.Tag.Get("copier")
if tags != "" {
var name string
var err error
if _, name, err = parseTags(tags); err != nil {
return flags{}, err
} else if name != "" {
flgs.SrcNames.FieldNameToTag[field.Name] = name
flgs.SrcNames.TagToFieldName[name] = field.Name
}
}
}
return flgs, nil
}
// checkBitFlags Checks flags for error or panic conditions.
func checkBitFlags(flagsList map[string]uint8) (err error) {
// Check flag conditions were met
for name, flgs := range flagsList {
if flgs&hasCopied == 0 {
switch {
case flgs&tagMust != 0 && flgs&tagNoPanic != 0:
err = fmt.Errorf("field %s has must tag but was not copied", name)
return
case flgs&(tagMust) != 0:
panic(fmt.Sprintf("Field %s has must tag but was not copied", name))
}
}
}
return
}
func getFieldName(fieldName string, flgs flags, fieldNameMapping map[string]string) (srcFieldName string, destFieldName string) {
// get dest field name
if name, ok := fieldNameMapping[fieldName]; ok {
srcFieldName = fieldName
destFieldName = name
return
}
if srcTagName, ok := flgs.SrcNames.FieldNameToTag[fieldName]; ok {
destFieldName = srcTagName
if destTagName, ok := flgs.DestNames.TagToFieldName[srcTagName]; ok {
destFieldName = destTagName
}
} else {
if destTagName, ok := flgs.DestNames.TagToFieldName[fieldName]; ok {
destFieldName = destTagName
}
}
if destFieldName == "" {
destFieldName = fieldName
}
// get source field name
if destTagName, ok := flgs.DestNames.FieldNameToTag[fieldName]; ok {
srcFieldName = destTagName
if srcField, ok := flgs.SrcNames.TagToFieldName[destTagName]; ok {
srcFieldName = srcField
}
} else {
if srcField, ok := flgs.SrcNames.TagToFieldName[fieldName]; ok {
srcFieldName = srcField
}
}
if srcFieldName == "" {
srcFieldName = fieldName
}
return
}
func driverValuer(v reflect.Value) (i driver.Valuer, ok bool) {
if !v.CanAddr() {
i, ok = v.Interface().(driver.Valuer)
return
}
i, ok = v.Addr().Interface().(driver.Valuer)
return
}
func fieldByName(v reflect.Value, name string, caseSensitive bool) reflect.Value {
if caseSensitive {
return v.FieldByName(name)
}
return v.FieldByNameFunc(func(n string) bool { return strings.EqualFold(n, name) })
}