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530 lines
17 KiB
Go
530 lines
17 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 determines equality of values.
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//
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// This package is intended to be a more powerful and safer alternative to
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// reflect.DeepEqual for comparing whether two values are semantically equal.
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//
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// The primary features of cmp are:
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//
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// • When the default behavior of equality does not suit the needs of the test,
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// custom equality functions can override the equality operation.
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// For example, an equality function may report floats as equal so long as they
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// are within some tolerance of each other.
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//
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// • Types that have an Equal method may use that method to determine equality.
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// This allows package authors to determine the equality operation for the types
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// that they define.
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//
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// • If no custom equality functions are used and no Equal method is defined,
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// equality is determined by recursively comparing the primitive kinds on both
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// values, much like reflect.DeepEqual. Unlike reflect.DeepEqual, unexported
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// fields are not compared by default; they result in panics unless suppressed
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// by using an Ignore option (see cmpopts.IgnoreUnexported) or explictly compared
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// using the AllowUnexported option.
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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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"github.com/google/go-cmp/cmp/internal/diff"
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"github.com/google/go-cmp/cmp/internal/function"
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"github.com/google/go-cmp/cmp/internal/value"
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)
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// BUG: Maps with keys containing NaN values cannot be properly compared due to
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// the reflection package's inability to retrieve such entries. Equal will panic
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// anytime it comes across a NaN key, but this behavior may change.
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//
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// See https://golang.org/issue/11104 for more details.
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var nothing = reflect.Value{}
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// Equal reports whether x and y are equal by recursively applying the
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// following rules in the given order to x and y and all of their sub-values:
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//
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// • If two values are not of the same type, then they are never equal
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// and the overall result is false.
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//
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// • Let S be the set of all Ignore, Transformer, and Comparer options that
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// remain after applying all path filters, value filters, and type filters.
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// If at least one Ignore exists in S, then the comparison is ignored.
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// If the number of Transformer and Comparer options in S is greater than one,
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// then Equal panics because it is ambiguous which option to use.
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// If S contains a single Transformer, then use that to transform the current
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// values and recursively call Equal on the output values.
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// If S contains a single Comparer, then use that to compare the current values.
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// Otherwise, evaluation proceeds to the next rule.
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//
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// • If the values have an Equal method of the form "(T) Equal(T) bool" or
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// "(T) Equal(I) bool" where T is assignable to I, then use the result of
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// x.Equal(y). Otherwise, no such method exists and evaluation proceeds to
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// the next rule.
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//
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// • Lastly, try to compare x and y based on their basic kinds.
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// Simple kinds like booleans, integers, floats, complex numbers, strings, and
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// channels are compared using the equivalent of the == operator in Go.
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// Functions are only equal if they are both nil, otherwise they are unequal.
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// Pointers are equal if the underlying values they point to are also equal.
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// Interfaces are equal if their underlying concrete values are also equal.
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//
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// Structs are equal if all of their fields are equal. If a struct contains
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// unexported fields, Equal panics unless the AllowUnexported option is used or
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// an Ignore option (e.g., cmpopts.IgnoreUnexported) ignores that field.
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//
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// Arrays, slices, and maps are equal if they are both nil or both non-nil
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// with the same length and the elements at each index or key are equal.
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// Note that a non-nil empty slice and a nil slice are not equal.
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// To equate empty slices and maps, consider using cmpopts.EquateEmpty.
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// Map keys are equal according to the == operator.
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// To use custom comparisons for map keys, consider using cmpopts.SortMaps.
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func Equal(x, y interface{}, opts ...Option) bool {
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s := newState(opts)
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s.compareAny(reflect.ValueOf(x), reflect.ValueOf(y))
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return s.result.Equal()
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}
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// Diff returns a human-readable report of the differences between two values.
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// It returns an empty string if and only if Equal returns true for the same
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// input values and options. The output string will use the "-" symbol to
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// indicate elements removed from x, and the "+" symbol to indicate elements
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// added to y.
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//
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// Do not depend on this output being stable.
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func Diff(x, y interface{}, opts ...Option) string {
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r := new(defaultReporter)
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opts = Options{Options(opts), r}
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eq := Equal(x, y, opts...)
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d := r.String()
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if (d == "") != eq {
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panic("inconsistent difference and equality results")
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}
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return d
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}
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type state struct {
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// These fields represent the "comparison state".
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// Calling statelessCompare must not result in observable changes to these.
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result diff.Result // The current result of comparison
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curPath Path // The current path in the value tree
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reporter reporter // Optional reporter used for difference formatting
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// dynChecker triggers pseudo-random checks for option correctness.
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// It is safe for statelessCompare to mutate this value.
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dynChecker dynChecker
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// These fields, once set by processOption, will not change.
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exporters map[reflect.Type]bool // Set of structs with unexported field visibility
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opts Options // List of all fundamental and filter options
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}
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func newState(opts []Option) *state {
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s := new(state)
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for _, opt := range opts {
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s.processOption(opt)
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}
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return s
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}
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func (s *state) processOption(opt Option) {
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switch opt := opt.(type) {
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case nil:
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case Options:
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for _, o := range opt {
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s.processOption(o)
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}
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case coreOption:
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type filtered interface {
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isFiltered() bool
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}
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if fopt, ok := opt.(filtered); ok && !fopt.isFiltered() {
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panic(fmt.Sprintf("cannot use an unfiltered option: %v", opt))
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}
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s.opts = append(s.opts, opt)
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case visibleStructs:
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if s.exporters == nil {
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s.exporters = make(map[reflect.Type]bool)
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}
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for t := range opt {
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s.exporters[t] = true
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}
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case reporter:
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if s.reporter != nil {
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panic("difference reporter already registered")
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}
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s.reporter = opt
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default:
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panic(fmt.Sprintf("unknown option %T", opt))
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}
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}
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// statelessCompare compares two values and returns the result.
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// This function is stateless in that it does not alter the current result,
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// or output to any registered reporters.
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func (s *state) statelessCompare(vx, vy reflect.Value) diff.Result {
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// We do not save and restore the curPath because all of the compareX
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// methods should properly push and pop from the path.
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// It is an implementation bug if the contents of curPath differs from
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// when calling this function to when returning from it.
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oldResult, oldReporter := s.result, s.reporter
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s.result = diff.Result{} // Reset result
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s.reporter = nil // Remove reporter to avoid spurious printouts
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s.compareAny(vx, vy)
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res := s.result
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s.result, s.reporter = oldResult, oldReporter
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return res
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}
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func (s *state) compareAny(vx, vy reflect.Value) {
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// TODO: Support cyclic data structures.
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// Rule 0: Differing types are never equal.
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if !vx.IsValid() || !vy.IsValid() {
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s.report(vx.IsValid() == vy.IsValid(), vx, vy)
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return
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}
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if vx.Type() != vy.Type() {
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s.report(false, vx, vy) // Possible for path to be empty
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return
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}
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t := vx.Type()
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if len(s.curPath) == 0 {
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s.curPath.push(&pathStep{typ: t})
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defer s.curPath.pop()
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}
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vx, vy = s.tryExporting(vx, vy)
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// Rule 1: Check whether an option applies on this node in the value tree.
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if s.tryOptions(vx, vy, t) {
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return
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}
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// Rule 2: Check whether the type has a valid Equal method.
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if s.tryMethod(vx, vy, t) {
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return
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}
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// Rule 3: Recursively descend into each value's underlying kind.
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switch t.Kind() {
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case reflect.Bool:
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s.report(vx.Bool() == vy.Bool(), vx, vy)
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return
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case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
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s.report(vx.Int() == vy.Int(), vx, vy)
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return
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case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
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s.report(vx.Uint() == vy.Uint(), vx, vy)
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return
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case reflect.Float32, reflect.Float64:
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s.report(vx.Float() == vy.Float(), vx, vy)
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return
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case reflect.Complex64, reflect.Complex128:
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s.report(vx.Complex() == vy.Complex(), vx, vy)
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return
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case reflect.String:
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s.report(vx.String() == vy.String(), vx, vy)
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return
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case reflect.Chan, reflect.UnsafePointer:
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s.report(vx.Pointer() == vy.Pointer(), vx, vy)
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return
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case reflect.Func:
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s.report(vx.IsNil() && vy.IsNil(), vx, vy)
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return
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case reflect.Ptr:
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if vx.IsNil() || vy.IsNil() {
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s.report(vx.IsNil() && vy.IsNil(), vx, vy)
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return
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}
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s.curPath.push(&indirect{pathStep{t.Elem()}})
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defer s.curPath.pop()
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s.compareAny(vx.Elem(), vy.Elem())
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return
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case reflect.Interface:
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if vx.IsNil() || vy.IsNil() {
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s.report(vx.IsNil() && vy.IsNil(), vx, vy)
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return
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}
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if vx.Elem().Type() != vy.Elem().Type() {
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s.report(false, vx.Elem(), vy.Elem())
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return
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}
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s.curPath.push(&typeAssertion{pathStep{vx.Elem().Type()}})
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defer s.curPath.pop()
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s.compareAny(vx.Elem(), vy.Elem())
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return
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case reflect.Slice:
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if vx.IsNil() || vy.IsNil() {
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s.report(vx.IsNil() && vy.IsNil(), vx, vy)
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return
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}
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fallthrough
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case reflect.Array:
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s.compareArray(vx, vy, t)
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return
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case reflect.Map:
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s.compareMap(vx, vy, t)
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return
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case reflect.Struct:
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s.compareStruct(vx, vy, t)
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return
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default:
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panic(fmt.Sprintf("%v kind not handled", t.Kind()))
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}
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}
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func (s *state) tryExporting(vx, vy reflect.Value) (reflect.Value, reflect.Value) {
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if sf, ok := s.curPath[len(s.curPath)-1].(*structField); ok && sf.unexported {
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if sf.force {
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// Use unsafe pointer arithmetic to get read-write access to an
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// unexported field in the struct.
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vx = unsafeRetrieveField(sf.pvx, sf.field)
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vy = unsafeRetrieveField(sf.pvy, sf.field)
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} else {
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// We are not allowed to export the value, so invalidate them
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// so that tryOptions can panic later if not explicitly ignored.
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vx = nothing
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vy = nothing
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}
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}
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return vx, vy
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}
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func (s *state) tryOptions(vx, vy reflect.Value, t reflect.Type) bool {
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// If there were no FilterValues, we will not detect invalid inputs,
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// so manually check for them and append invalid if necessary.
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// We still evaluate the options since an ignore can override invalid.
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opts := s.opts
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if !vx.IsValid() || !vy.IsValid() {
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opts = Options{opts, invalid{}}
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}
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// Evaluate all filters and apply the remaining options.
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if opt := opts.filter(s, vx, vy, t); opt != nil {
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return opt.apply(s, vx, vy)
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}
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return false
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}
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func (s *state) tryMethod(vx, vy reflect.Value, t reflect.Type) bool {
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// Check if this type even has an Equal method.
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m, ok := t.MethodByName("Equal")
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if !ok || !function.IsType(m.Type, function.EqualAssignable) {
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return false
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}
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eq := s.callTTBFunc(m.Func, vx, vy)
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s.report(eq, vx, vy)
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return true
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}
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func (s *state) callTRFunc(f, v reflect.Value) reflect.Value {
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if !s.dynChecker.Next() {
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return f.Call([]reflect.Value{v})[0]
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}
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// Run the function twice and ensure that we get the same results back.
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// We run in goroutines so that the race detector (if enabled) can detect
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// unsafe mutations to the input.
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c := make(chan reflect.Value)
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go detectRaces(c, f, v)
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want := f.Call([]reflect.Value{v})[0]
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if got := <-c; !s.statelessCompare(got, want).Equal() {
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// To avoid false-positives with non-reflexive equality operations,
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// we sanity check whether a value is equal to itself.
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if !s.statelessCompare(want, want).Equal() {
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return want
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}
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fn := getFuncName(f.Pointer())
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panic(fmt.Sprintf("non-deterministic function detected: %s", fn))
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}
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return want
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}
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func (s *state) callTTBFunc(f, x, y reflect.Value) bool {
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if !s.dynChecker.Next() {
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return f.Call([]reflect.Value{x, y})[0].Bool()
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}
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// Swapping the input arguments is sufficient to check that
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// f is symmetric and deterministic.
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// We run in goroutines so that the race detector (if enabled) can detect
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// unsafe mutations to the input.
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c := make(chan reflect.Value)
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go detectRaces(c, f, y, x)
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want := f.Call([]reflect.Value{x, y})[0].Bool()
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if got := <-c; !got.IsValid() || got.Bool() != want {
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fn := getFuncName(f.Pointer())
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panic(fmt.Sprintf("non-deterministic or non-symmetric function detected: %s", fn))
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}
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return want
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}
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func detectRaces(c chan<- reflect.Value, f reflect.Value, vs ...reflect.Value) {
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var ret reflect.Value
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defer func() {
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recover() // Ignore panics, let the other call to f panic instead
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c <- ret
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}()
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ret = f.Call(vs)[0]
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}
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func (s *state) compareArray(vx, vy reflect.Value, t reflect.Type) {
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step := &sliceIndex{pathStep{t.Elem()}, 0, 0}
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s.curPath.push(step)
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// Compute an edit-script for slices vx and vy.
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eq, es := diff.Difference(vx.Len(), vy.Len(), func(ix, iy int) diff.Result {
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step.xkey, step.ykey = ix, iy
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return s.statelessCompare(vx.Index(ix), vy.Index(iy))
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})
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// Equal or no edit-script, so report entire slices as is.
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if eq || es == nil {
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s.curPath.pop() // Pop first since we are reporting the whole slice
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s.report(eq, vx, vy)
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return
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}
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// Replay the edit-script.
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var ix, iy int
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for _, e := range es {
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switch e {
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case diff.UniqueX:
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step.xkey, step.ykey = ix, -1
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s.report(false, vx.Index(ix), nothing)
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ix++
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case diff.UniqueY:
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step.xkey, step.ykey = -1, iy
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s.report(false, nothing, vy.Index(iy))
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iy++
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default:
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step.xkey, step.ykey = ix, iy
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if e == diff.Identity {
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s.report(true, vx.Index(ix), vy.Index(iy))
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} else {
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s.compareAny(vx.Index(ix), vy.Index(iy))
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}
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ix++
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iy++
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}
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}
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s.curPath.pop()
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return
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}
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func (s *state) compareMap(vx, vy reflect.Value, t reflect.Type) {
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if vx.IsNil() || vy.IsNil() {
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s.report(vx.IsNil() && vy.IsNil(), vx, vy)
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return
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}
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// We combine and sort the two map keys so that we can perform the
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// comparisons in a deterministic order.
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step := &mapIndex{pathStep: pathStep{t.Elem()}}
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s.curPath.push(step)
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defer s.curPath.pop()
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for _, k := range value.SortKeys(append(vx.MapKeys(), vy.MapKeys()...)) {
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step.key = k
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vvx := vx.MapIndex(k)
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vvy := vy.MapIndex(k)
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switch {
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case vvx.IsValid() && vvy.IsValid():
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s.compareAny(vvx, vvy)
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case vvx.IsValid() && !vvy.IsValid():
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s.report(false, vvx, nothing)
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case !vvx.IsValid() && vvy.IsValid():
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s.report(false, nothing, vvy)
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default:
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// It is possible for both vvx and vvy to be invalid if the
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// key contained a NaN value in it. There is no way in
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// reflection to be able to retrieve these values.
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// See https://golang.org/issue/11104
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panic(fmt.Sprintf("%#v has map key with NaNs", s.curPath))
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}
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}
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}
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func (s *state) compareStruct(vx, vy reflect.Value, t reflect.Type) {
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var vax, vay reflect.Value // Addressable versions of vx and vy
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step := &structField{}
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s.curPath.push(step)
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defer s.curPath.pop()
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for i := 0; i < t.NumField(); i++ {
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vvx := vx.Field(i)
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vvy := vy.Field(i)
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step.typ = t.Field(i).Type
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step.name = t.Field(i).Name
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step.idx = i
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step.unexported = !isExported(step.name)
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if step.unexported {
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// Defer checking of unexported fields until later to give an
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// Ignore a chance to ignore the field.
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if !vax.IsValid() || !vay.IsValid() {
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// For unsafeRetrieveField to work, the parent struct must
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// be addressable. Create a new copy of the values if
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// necessary to make them addressable.
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vax = makeAddressable(vx)
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vay = makeAddressable(vy)
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}
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step.force = s.exporters[t]
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step.pvx = vax
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step.pvy = vay
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step.field = t.Field(i)
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}
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s.compareAny(vvx, vvy)
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}
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}
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// report records the result of a single comparison.
|
|
// It also calls Report if any reporter is registered.
|
|
func (s *state) report(eq bool, vx, vy reflect.Value) {
|
|
if eq {
|
|
s.result.NSame++
|
|
} else {
|
|
s.result.NDiff++
|
|
}
|
|
if s.reporter != nil {
|
|
s.reporter.Report(vx, vy, eq, s.curPath)
|
|
}
|
|
}
|
|
|
|
// dynChecker tracks the state needed to periodically perform checks that
|
|
// user provided functions are symmetric and deterministic.
|
|
// The zero value is safe for immediate use.
|
|
type dynChecker struct{ curr, next int }
|
|
|
|
// Next increments the state and reports whether a check should be performed.
|
|
//
|
|
// Checks occur every Nth function call, where N is a triangular number:
|
|
// 0 1 3 6 10 15 21 28 36 45 55 66 78 91 105 120 136 153 171 190 ...
|
|
// See https://en.wikipedia.org/wiki/Triangular_number
|
|
//
|
|
// This sequence ensures that the cost of checks drops significantly as
|
|
// the number of functions calls grows larger.
|
|
func (dc *dynChecker) Next() bool {
|
|
ok := dc.curr == dc.next
|
|
if ok {
|
|
dc.curr = 0
|
|
dc.next++
|
|
}
|
|
dc.curr++
|
|
return ok
|
|
}
|
|
|
|
// makeAddressable returns a value that is always addressable.
|
|
// It returns the input verbatim if it is already addressable,
|
|
// otherwise it creates a new value and returns an addressable copy.
|
|
func makeAddressable(v reflect.Value) reflect.Value {
|
|
if v.CanAddr() {
|
|
return v
|
|
}
|
|
vc := reflect.New(v.Type()).Elem()
|
|
vc.Set(v)
|
|
return vc
|
|
}
|