mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-11-10 08:20:23 +00:00
91774fc936
Uses github.com/libopenstorage/secrets to communicate with Vault. This removes the need for maintaining our own limited Vault APIs. By adding the new dependency, several other packages got updated in the process. Unused indirect dependencies have been removed from go.mod. Signed-off-by: Niels de Vos <ndevos@redhat.com>
379 lines
13 KiB
Go
379 lines
13 KiB
Go
// Copyright 2017, The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE.md file.
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package cmp
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import (
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"fmt"
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"reflect"
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"strings"
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"unicode"
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"unicode/utf8"
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"github.com/google/go-cmp/cmp/internal/value"
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)
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// Path is a list of PathSteps describing the sequence of operations to get
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// from some root type to the current position in the value tree.
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// The first Path element is always an operation-less PathStep that exists
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// simply to identify the initial type.
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//
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// When traversing structs with embedded structs, the embedded struct will
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// always be accessed as a field before traversing the fields of the
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// embedded struct themselves. That is, an exported field from the
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// embedded struct will never be accessed directly from the parent struct.
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type Path []PathStep
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// PathStep is a union-type for specific operations to traverse
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// a value's tree structure. Users of this package never need to implement
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// these types as values of this type will be returned by this package.
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//
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// Implementations of this interface are
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// StructField, SliceIndex, MapIndex, Indirect, TypeAssertion, and Transform.
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type PathStep interface {
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String() string
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// Type is the resulting type after performing the path step.
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Type() reflect.Type
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// Values is the resulting values after performing the path step.
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// The type of each valid value is guaranteed to be identical to Type.
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//
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// In some cases, one or both may be invalid or have restrictions:
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// • For StructField, both are not interface-able if the current field
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// is unexported and the struct type is not explicitly permitted by
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// an Exporter to traverse unexported fields.
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// • For SliceIndex, one may be invalid if an element is missing from
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// either the x or y slice.
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// • For MapIndex, one may be invalid if an entry is missing from
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// either the x or y map.
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//
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// The provided values must not be mutated.
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Values() (vx, vy reflect.Value)
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}
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var (
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_ PathStep = StructField{}
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_ PathStep = SliceIndex{}
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_ PathStep = MapIndex{}
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_ PathStep = Indirect{}
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_ PathStep = TypeAssertion{}
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_ PathStep = Transform{}
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)
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func (pa *Path) push(s PathStep) {
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*pa = append(*pa, s)
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}
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func (pa *Path) pop() {
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*pa = (*pa)[:len(*pa)-1]
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}
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// Last returns the last PathStep in the Path.
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// If the path is empty, this returns a non-nil PathStep that reports a nil Type.
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func (pa Path) Last() PathStep {
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return pa.Index(-1)
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}
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// Index returns the ith step in the Path and supports negative indexing.
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// A negative index starts counting from the tail of the Path such that -1
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// refers to the last step, -2 refers to the second-to-last step, and so on.
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// If index is invalid, this returns a non-nil PathStep that reports a nil Type.
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func (pa Path) Index(i int) PathStep {
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if i < 0 {
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i = len(pa) + i
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}
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if i < 0 || i >= len(pa) {
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return pathStep{}
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}
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return pa[i]
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}
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// String returns the simplified path to a node.
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// The simplified path only contains struct field accesses.
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//
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// For example:
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// MyMap.MySlices.MyField
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func (pa Path) String() string {
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var ss []string
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for _, s := range pa {
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if _, ok := s.(StructField); ok {
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ss = append(ss, s.String())
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}
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}
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return strings.TrimPrefix(strings.Join(ss, ""), ".")
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}
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// GoString returns the path to a specific node using Go syntax.
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//
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// For example:
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// (*root.MyMap["key"].(*mypkg.MyStruct).MySlices)[2][3].MyField
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func (pa Path) GoString() string {
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var ssPre, ssPost []string
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var numIndirect int
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for i, s := range pa {
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var nextStep PathStep
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if i+1 < len(pa) {
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nextStep = pa[i+1]
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}
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switch s := s.(type) {
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case Indirect:
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numIndirect++
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pPre, pPost := "(", ")"
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switch nextStep.(type) {
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case Indirect:
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continue // Next step is indirection, so let them batch up
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case StructField:
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numIndirect-- // Automatic indirection on struct fields
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case nil:
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pPre, pPost = "", "" // Last step; no need for parenthesis
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}
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if numIndirect > 0 {
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ssPre = append(ssPre, pPre+strings.Repeat("*", numIndirect))
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ssPost = append(ssPost, pPost)
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}
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numIndirect = 0
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continue
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case Transform:
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ssPre = append(ssPre, s.trans.name+"(")
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ssPost = append(ssPost, ")")
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continue
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}
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ssPost = append(ssPost, s.String())
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}
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for i, j := 0, len(ssPre)-1; i < j; i, j = i+1, j-1 {
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ssPre[i], ssPre[j] = ssPre[j], ssPre[i]
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}
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return strings.Join(ssPre, "") + strings.Join(ssPost, "")
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}
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type pathStep struct {
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typ reflect.Type
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vx, vy reflect.Value
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}
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func (ps pathStep) Type() reflect.Type { return ps.typ }
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func (ps pathStep) Values() (vx, vy reflect.Value) { return ps.vx, ps.vy }
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func (ps pathStep) String() string {
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if ps.typ == nil {
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return "<nil>"
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}
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s := ps.typ.String()
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if s == "" || strings.ContainsAny(s, "{}\n") {
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return "root" // Type too simple or complex to print
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}
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return fmt.Sprintf("{%s}", s)
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}
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// StructField represents a struct field access on a field called Name.
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type StructField struct{ *structField }
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type structField struct {
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pathStep
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name string
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idx int
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// These fields are used for forcibly accessing an unexported field.
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// pvx, pvy, and field are only valid if unexported is true.
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unexported bool
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mayForce bool // Forcibly allow visibility
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paddr bool // Was parent addressable?
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pvx, pvy reflect.Value // Parent values (always addressible)
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field reflect.StructField // Field information
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}
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func (sf StructField) Type() reflect.Type { return sf.typ }
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func (sf StructField) Values() (vx, vy reflect.Value) {
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if !sf.unexported {
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return sf.vx, sf.vy // CanInterface reports true
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}
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// Forcibly obtain read-write access to an unexported struct field.
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if sf.mayForce {
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vx = retrieveUnexportedField(sf.pvx, sf.field, sf.paddr)
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vy = retrieveUnexportedField(sf.pvy, sf.field, sf.paddr)
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return vx, vy // CanInterface reports true
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}
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return sf.vx, sf.vy // CanInterface reports false
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}
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func (sf StructField) String() string { return fmt.Sprintf(".%s", sf.name) }
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// Name is the field name.
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func (sf StructField) Name() string { return sf.name }
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// Index is the index of the field in the parent struct type.
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// See reflect.Type.Field.
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func (sf StructField) Index() int { return sf.idx }
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// SliceIndex is an index operation on a slice or array at some index Key.
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type SliceIndex struct{ *sliceIndex }
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type sliceIndex struct {
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pathStep
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xkey, ykey int
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isSlice bool // False for reflect.Array
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}
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func (si SliceIndex) Type() reflect.Type { return si.typ }
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func (si SliceIndex) Values() (vx, vy reflect.Value) { return si.vx, si.vy }
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func (si SliceIndex) String() string {
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switch {
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case si.xkey == si.ykey:
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return fmt.Sprintf("[%d]", si.xkey)
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case si.ykey == -1:
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// [5->?] means "I don't know where X[5] went"
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return fmt.Sprintf("[%d->?]", si.xkey)
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case si.xkey == -1:
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// [?->3] means "I don't know where Y[3] came from"
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return fmt.Sprintf("[?->%d]", si.ykey)
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default:
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// [5->3] means "X[5] moved to Y[3]"
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return fmt.Sprintf("[%d->%d]", si.xkey, si.ykey)
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}
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}
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// Key is the index key; it may return -1 if in a split state
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func (si SliceIndex) Key() int {
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if si.xkey != si.ykey {
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return -1
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}
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return si.xkey
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}
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// SplitKeys are the indexes for indexing into slices in the
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// x and y values, respectively. These indexes may differ due to the
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// insertion or removal of an element in one of the slices, causing
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// all of the indexes to be shifted. If an index is -1, then that
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// indicates that the element does not exist in the associated slice.
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//
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// Key is guaranteed to return -1 if and only if the indexes returned
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// by SplitKeys are not the same. SplitKeys will never return -1 for
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// both indexes.
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func (si SliceIndex) SplitKeys() (ix, iy int) { return si.xkey, si.ykey }
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// MapIndex is an index operation on a map at some index Key.
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type MapIndex struct{ *mapIndex }
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type mapIndex struct {
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pathStep
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key reflect.Value
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}
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func (mi MapIndex) Type() reflect.Type { return mi.typ }
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func (mi MapIndex) Values() (vx, vy reflect.Value) { return mi.vx, mi.vy }
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func (mi MapIndex) String() string { return fmt.Sprintf("[%#v]", mi.key) }
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// Key is the value of the map key.
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func (mi MapIndex) Key() reflect.Value { return mi.key }
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// Indirect represents pointer indirection on the parent type.
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type Indirect struct{ *indirect }
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type indirect struct {
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pathStep
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}
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func (in Indirect) Type() reflect.Type { return in.typ }
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func (in Indirect) Values() (vx, vy reflect.Value) { return in.vx, in.vy }
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func (in Indirect) String() string { return "*" }
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// TypeAssertion represents a type assertion on an interface.
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type TypeAssertion struct{ *typeAssertion }
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type typeAssertion struct {
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pathStep
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}
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func (ta TypeAssertion) Type() reflect.Type { return ta.typ }
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func (ta TypeAssertion) Values() (vx, vy reflect.Value) { return ta.vx, ta.vy }
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func (ta TypeAssertion) String() string { return fmt.Sprintf(".(%v)", ta.typ) }
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// Transform is a transformation from the parent type to the current type.
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type Transform struct{ *transform }
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type transform struct {
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pathStep
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trans *transformer
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}
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func (tf Transform) Type() reflect.Type { return tf.typ }
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func (tf Transform) Values() (vx, vy reflect.Value) { return tf.vx, tf.vy }
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func (tf Transform) String() string { return fmt.Sprintf("%s()", tf.trans.name) }
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// Name is the name of the Transformer.
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func (tf Transform) Name() string { return tf.trans.name }
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// Func is the function pointer to the transformer function.
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func (tf Transform) Func() reflect.Value { return tf.trans.fnc }
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// Option returns the originally constructed Transformer option.
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// The == operator can be used to detect the exact option used.
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func (tf Transform) Option() Option { return tf.trans }
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// pointerPath represents a dual-stack of pointers encountered when
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// recursively traversing the x and y values. This data structure supports
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// detection of cycles and determining whether the cycles are equal.
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// In Go, cycles can occur via pointers, slices, and maps.
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//
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// The pointerPath uses a map to represent a stack; where descension into a
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// pointer pushes the address onto the stack, and ascension from a pointer
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// pops the address from the stack. Thus, when traversing into a pointer from
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// reflect.Ptr, reflect.Slice element, or reflect.Map, we can detect cycles
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// by checking whether the pointer has already been visited. The cycle detection
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// uses a seperate stack for the x and y values.
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//
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// If a cycle is detected we need to determine whether the two pointers
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// should be considered equal. The definition of equality chosen by Equal
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// requires two graphs to have the same structure. To determine this, both the
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// x and y values must have a cycle where the previous pointers were also
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// encountered together as a pair.
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//
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// Semantically, this is equivalent to augmenting Indirect, SliceIndex, and
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// MapIndex with pointer information for the x and y values.
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// Suppose px and py are two pointers to compare, we then search the
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// Path for whether px was ever encountered in the Path history of x, and
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// similarly so with py. If either side has a cycle, the comparison is only
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// equal if both px and py have a cycle resulting from the same PathStep.
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//
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// Using a map as a stack is more performant as we can perform cycle detection
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// in O(1) instead of O(N) where N is len(Path).
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type pointerPath struct {
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// mx is keyed by x pointers, where the value is the associated y pointer.
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mx map[value.Pointer]value.Pointer
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// my is keyed by y pointers, where the value is the associated x pointer.
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my map[value.Pointer]value.Pointer
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}
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func (p *pointerPath) Init() {
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p.mx = make(map[value.Pointer]value.Pointer)
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p.my = make(map[value.Pointer]value.Pointer)
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}
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// Push indicates intent to descend into pointers vx and vy where
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// visited reports whether either has been seen before. If visited before,
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// equal reports whether both pointers were encountered together.
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// Pop must be called if and only if the pointers were never visited.
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//
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// The pointers vx and vy must be a reflect.Ptr, reflect.Slice, or reflect.Map
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// and be non-nil.
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func (p pointerPath) Push(vx, vy reflect.Value) (equal, visited bool) {
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px := value.PointerOf(vx)
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py := value.PointerOf(vy)
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_, ok1 := p.mx[px]
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_, ok2 := p.my[py]
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if ok1 || ok2 {
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equal = p.mx[px] == py && p.my[py] == px // Pointers paired together
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return equal, true
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}
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p.mx[px] = py
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p.my[py] = px
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return false, false
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}
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// Pop ascends from pointers vx and vy.
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func (p pointerPath) Pop(vx, vy reflect.Value) {
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delete(p.mx, value.PointerOf(vx))
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delete(p.my, value.PointerOf(vy))
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}
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// isExported reports whether the identifier is exported.
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func isExported(id string) bool {
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r, _ := utf8.DecodeRuneInString(id)
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return unicode.IsUpper(r)
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}
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