mirror of
https://github.com/restic/restic.git
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444 lines
14 KiB
Go
444 lines
14 KiB
Go
// Copyright 2016 Google Inc. All Rights Reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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// Package fields provides a view of the fields of a struct that follows the Go
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// rules, amended to consider tags and case insensitivity.
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//
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// Usage
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//
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// First define a function that interprets tags:
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//
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// func parseTag(st reflect.StructTag) (name string, keep bool, other interface{}, err error) { ... }
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//
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// The function's return values describe whether to ignore the field
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// completely or provide an alternate name, as well as other data from the
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// parse that is stored to avoid re-parsing.
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//
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// Then define a function to validate the type:
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//
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// func validate(t reflect.Type) error { ... }
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//
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// Then, if necessary, define a function to specify leaf types - types
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// which should be considered one field and not be recursed into:
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//
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// func isLeafType(t reflect.Type) bool { ... }
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//
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// eg:
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//
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// func isLeafType(t reflect.Type) bool {
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// return t == reflect.TypeOf(time.Time{})
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// }
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//
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// Next, construct a Cache, passing your functions. As its name suggests, a
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// Cache remembers validation and field information for a type, so subsequent
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// calls with the same type are very fast.
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//
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// cache := fields.NewCache(parseTag, validate, isLeafType)
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//
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// To get the fields of a struct type as determined by the above rules, call
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// the Fields method:
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//
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// fields, err := cache.Fields(reflect.TypeOf(MyStruct{}))
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//
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// The return value can be treated as a slice of Fields.
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//
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// Given a string, such as a key or column name obtained during unmarshalling,
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// call Match on the list of fields to find a field whose name is the best
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// match:
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//
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// field := fields.Match(name)
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//
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// Match looks for an exact match first, then falls back to a case-insensitive
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// comparison.
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package fields
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import (
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"bytes"
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"reflect"
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"sort"
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"cloud.google.com/go/internal/atomiccache"
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)
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// A Field records information about a struct field.
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type Field struct {
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Name string // effective field name
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NameFromTag bool // did Name come from a tag?
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Type reflect.Type // field type
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Index []int // index sequence, for reflect.Value.FieldByIndex
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ParsedTag interface{} // third return value of the parseTag function
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nameBytes []byte
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equalFold func(s, t []byte) bool
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}
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type ParseTagFunc func(reflect.StructTag) (name string, keep bool, other interface{}, err error)
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type ValidateFunc func(reflect.Type) error
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type LeafTypesFunc func(reflect.Type) bool
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// A Cache records information about the fields of struct types.
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//
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// A Cache is safe for use by multiple goroutines.
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type Cache struct {
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parseTag ParseTagFunc
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validate ValidateFunc
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leafTypes LeafTypesFunc
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cache atomiccache.Cache // from reflect.Type to cacheValue
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}
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// NewCache constructs a Cache.
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//
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// Its first argument should be a function that accepts
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// a struct tag and returns four values: an alternative name for the field
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// extracted from the tag, a boolean saying whether to keep the field or ignore
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// it, additional data that is stored with the field information to avoid
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// having to parse the tag again, and an error.
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//
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// Its second argument should be a function that accepts a reflect.Type and
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// returns an error if the struct type is invalid in any way. For example, it
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// may check that all of the struct field tags are valid, or that all fields
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// are of an appropriate type.
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func NewCache(parseTag ParseTagFunc, validate ValidateFunc, leafTypes LeafTypesFunc) *Cache {
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if parseTag == nil {
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parseTag = func(reflect.StructTag) (string, bool, interface{}, error) {
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return "", true, nil, nil
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}
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}
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if validate == nil {
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validate = func(reflect.Type) error {
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return nil
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}
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}
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if leafTypes == nil {
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leafTypes = func(reflect.Type) bool {
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return false
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}
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}
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return &Cache{
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parseTag: parseTag,
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validate: validate,
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leafTypes: leafTypes,
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}
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}
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// A fieldScan represents an item on the fieldByNameFunc scan work list.
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type fieldScan struct {
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typ reflect.Type
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index []int
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}
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// Fields returns all the exported fields of t, which must be a struct type. It
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// follows the standard Go rules for embedded fields, modified by the presence
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// of tags. The result is sorted lexicographically by index.
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//
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// These rules apply in the absence of tags:
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// Anonymous struct fields are treated as if their inner exported fields were
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// fields in the outer struct (embedding). The result includes all fields that
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// aren't shadowed by fields at higher level of embedding. If more than one
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// field with the same name exists at the same level of embedding, it is
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// excluded. An anonymous field that is not of struct type is treated as having
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// its type as its name.
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//
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// Tags modify these rules as follows:
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// A field's tag is used as its name.
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// An anonymous struct field with a name given in its tag is treated as
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// a field having that name, rather than an embedded struct (the struct's
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// fields will not be returned).
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// If more than one field with the same name exists at the same level of embedding,
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// but exactly one of them is tagged, then the tagged field is reported and the others
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// are ignored.
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func (c *Cache) Fields(t reflect.Type) (List, error) {
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if t.Kind() != reflect.Struct {
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panic("fields: Fields of non-struct type")
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}
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return c.cachedTypeFields(t)
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}
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// A List is a list of Fields.
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type List []Field
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// Match returns the field in the list whose name best matches the supplied
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// name, nor nil if no field does. If there is a field with the exact name, it
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// is returned. Otherwise the first field (sorted by index) whose name matches
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// case-insensitively is returned.
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func (l List) Match(name string) *Field {
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return l.MatchBytes([]byte(name))
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}
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// MatchBytes is identical to Match, except that the argument is a byte slice.
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func (l List) MatchBytes(name []byte) *Field {
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var f *Field
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for i := range l {
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ff := &l[i]
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if bytes.Equal(ff.nameBytes, name) {
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return ff
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}
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if f == nil && ff.equalFold(ff.nameBytes, name) {
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f = ff
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}
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}
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return f
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}
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type cacheValue struct {
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fields List
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err error
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}
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// cachedTypeFields is like typeFields but uses a cache to avoid repeated work.
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// This code has been copied and modified from
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// https://go.googlesource.com/go/+/go1.7.3/src/encoding/json/encode.go.
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func (c *Cache) cachedTypeFields(t reflect.Type) (List, error) {
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cv := c.cache.Get(t, func() interface{} {
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if err := c.validate(t); err != nil {
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return cacheValue{nil, err}
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}
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f, err := c.typeFields(t)
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return cacheValue{List(f), err}
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}).(cacheValue)
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return cv.fields, cv.err
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}
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func (c *Cache) typeFields(t reflect.Type) ([]Field, error) {
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fields, err := c.listFields(t)
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if err != nil {
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return nil, err
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}
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sort.Sort(byName(fields))
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// Delete all fields that are hidden by the Go rules for embedded fields.
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// The fields are sorted in primary order of name, secondary order of field
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// index length. So the first field with a given name is the dominant one.
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var out []Field
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for advance, i := 0, 0; i < len(fields); i += advance {
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// One iteration per name.
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// Find the sequence of fields with the name of this first field.
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fi := fields[i]
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name := fi.Name
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for advance = 1; i+advance < len(fields); advance++ {
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fj := fields[i+advance]
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if fj.Name != name {
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break
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}
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}
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// Find the dominant field, if any, out of all fields that have the same name.
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dominant, ok := dominantField(fields[i : i+advance])
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if ok {
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out = append(out, dominant)
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}
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}
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sort.Sort(byIndex(out))
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return out, nil
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}
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func (c *Cache) listFields(t reflect.Type) ([]Field, error) {
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// This uses the same condition that the Go language does: there must be a unique instance
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// of the match at a given depth level. If there are multiple instances of a match at the
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// same depth, they annihilate each other and inhibit any possible match at a lower level.
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// The algorithm is breadth first search, one depth level at a time.
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// The current and next slices are work queues:
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// current lists the fields to visit on this depth level,
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// and next lists the fields on the next lower level.
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current := []fieldScan{}
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next := []fieldScan{{typ: t}}
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// nextCount records the number of times an embedded type has been
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// encountered and considered for queueing in the 'next' slice.
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// We only queue the first one, but we increment the count on each.
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// If a struct type T can be reached more than once at a given depth level,
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// then it annihilates itself and need not be considered at all when we
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// process that next depth level.
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var nextCount map[reflect.Type]int
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// visited records the structs that have been considered already.
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// Embedded pointer fields can create cycles in the graph of
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// reachable embedded types; visited avoids following those cycles.
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// It also avoids duplicated effort: if we didn't find the field in an
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// embedded type T at level 2, we won't find it in one at level 4 either.
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visited := map[reflect.Type]bool{}
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var fields []Field // Fields found.
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for len(next) > 0 {
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current, next = next, current[:0]
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count := nextCount
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nextCount = nil
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// Process all the fields at this depth, now listed in 'current'.
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// The loop queues embedded fields found in 'next', for processing during the next
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// iteration. The multiplicity of the 'current' field counts is recorded
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// in 'count'; the multiplicity of the 'next' field counts is recorded in 'nextCount'.
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for _, scan := range current {
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t := scan.typ
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if visited[t] {
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// We've looked through this type before, at a higher level.
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// That higher level would shadow the lower level we're now at,
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// so this one can't be useful to us. Ignore it.
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continue
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}
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visited[t] = true
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for i := 0; i < t.NumField(); i++ {
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f := t.Field(i)
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exported := (f.PkgPath == "")
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// If a named field is unexported, ignore it. An anonymous
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// unexported field is processed, because it may contain
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// exported fields, which are visible.
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if !exported && !f.Anonymous {
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continue
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}
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// Examine the tag.
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tagName, keep, other, err := c.parseTag(f.Tag)
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if err != nil {
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return nil, err
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}
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if !keep {
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continue
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}
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if c.leafTypes(f.Type) {
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fields = append(fields, newField(f, tagName, other, scan.index, i))
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continue
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}
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var ntyp reflect.Type
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if f.Anonymous {
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// Anonymous field of type T or *T.
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ntyp = f.Type
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if ntyp.Kind() == reflect.Ptr {
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ntyp = ntyp.Elem()
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}
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}
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// Record fields with a tag name, non-anonymous fields, or
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// anonymous non-struct fields.
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if tagName != "" || ntyp == nil || ntyp.Kind() != reflect.Struct {
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if !exported {
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continue
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}
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fields = append(fields, newField(f, tagName, other, scan.index, i))
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if count[t] > 1 {
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// If there were multiple instances, add a second,
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// so that the annihilation code will see a duplicate.
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fields = append(fields, fields[len(fields)-1])
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}
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continue
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}
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// Queue embedded struct fields for processing with next level,
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// but only if the embedded types haven't already been queued.
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if nextCount[ntyp] > 0 {
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nextCount[ntyp] = 2 // exact multiple doesn't matter
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continue
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}
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if nextCount == nil {
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nextCount = map[reflect.Type]int{}
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}
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nextCount[ntyp] = 1
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if count[t] > 1 {
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nextCount[ntyp] = 2 // exact multiple doesn't matter
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}
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var index []int
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index = append(index, scan.index...)
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index = append(index, i)
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next = append(next, fieldScan{ntyp, index})
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}
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}
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}
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return fields, nil
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}
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func newField(f reflect.StructField, tagName string, other interface{}, index []int, i int) Field {
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name := tagName
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if name == "" {
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name = f.Name
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}
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sf := Field{
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Name: name,
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NameFromTag: tagName != "",
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Type: f.Type,
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ParsedTag: other,
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nameBytes: []byte(name),
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}
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sf.equalFold = foldFunc(sf.nameBytes)
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sf.Index = append(sf.Index, index...)
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sf.Index = append(sf.Index, i)
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return sf
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}
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// byName sorts fields using the following criteria, in order:
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// 1. name
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// 2. embedding depth
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// 3. tag presence (preferring a tagged field)
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// 4. index sequence.
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type byName []Field
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func (x byName) Len() int { return len(x) }
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func (x byName) Swap(i, j int) { x[i], x[j] = x[j], x[i] }
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func (x byName) Less(i, j int) bool {
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if x[i].Name != x[j].Name {
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return x[i].Name < x[j].Name
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}
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if len(x[i].Index) != len(x[j].Index) {
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return len(x[i].Index) < len(x[j].Index)
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}
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if x[i].NameFromTag != x[j].NameFromTag {
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return x[i].NameFromTag
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}
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return byIndex(x).Less(i, j)
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}
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// byIndex sorts field by index sequence.
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type byIndex []Field
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func (x byIndex) Len() int { return len(x) }
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func (x byIndex) Swap(i, j int) { x[i], x[j] = x[j], x[i] }
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func (x byIndex) Less(i, j int) bool {
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xi := x[i].Index
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xj := x[j].Index
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ln := len(xi)
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if l := len(xj); l < ln {
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ln = l
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}
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for k := 0; k < ln; k++ {
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if xi[k] != xj[k] {
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return xi[k] < xj[k]
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}
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}
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return len(xi) < len(xj)
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}
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// dominantField looks through the fields, all of which are known to have the
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// same name, to find the single field that dominates the others using Go's
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// embedding rules, modified by the presence of tags. If there are multiple
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// top-level fields, the boolean will be false: This condition is an error in
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// Go and we skip all the fields.
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func dominantField(fs []Field) (Field, bool) {
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// The fields are sorted in increasing index-length order, then by presence of tag.
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// That means that the first field is the dominant one. We need only check
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// for error cases: two fields at top level, either both tagged or neither tagged.
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if len(fs) > 1 && len(fs[0].Index) == len(fs[1].Index) && fs[0].NameFromTag == fs[1].NameFromTag {
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return Field{}, false
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}
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return fs[0], true
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}
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