mirror of https://github.com/docker/cli.git
186 lines
6.2 KiB
Go
186 lines
6.2 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 file.
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// Package cmpopts provides common options for the cmp package.
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package cmpopts
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import (
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"errors"
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"fmt"
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"math"
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"reflect"
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"time"
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"github.com/google/go-cmp/cmp"
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)
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func equateAlways(_, _ interface{}) bool { return true }
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// EquateEmpty returns a [cmp.Comparer] option that determines all maps and slices
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// with a length of zero to be equal, regardless of whether they are nil.
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//
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// EquateEmpty can be used in conjunction with [SortSlices] and [SortMaps].
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func EquateEmpty() cmp.Option {
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return cmp.FilterValues(isEmpty, cmp.Comparer(equateAlways))
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}
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func isEmpty(x, y interface{}) bool {
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vx, vy := reflect.ValueOf(x), reflect.ValueOf(y)
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return (x != nil && y != nil && vx.Type() == vy.Type()) &&
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(vx.Kind() == reflect.Slice || vx.Kind() == reflect.Map) &&
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(vx.Len() == 0 && vy.Len() == 0)
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}
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// EquateApprox returns a [cmp.Comparer] option that determines float32 or float64
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// values to be equal if they are within a relative fraction or absolute margin.
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// This option is not used when either x or y is NaN or infinite.
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//
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// The fraction determines that the difference of two values must be within the
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// smaller fraction of the two values, while the margin determines that the two
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// values must be within some absolute margin.
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// To express only a fraction or only a margin, use 0 for the other parameter.
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// The fraction and margin must be non-negative.
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//
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// The mathematical expression used is equivalent to:
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//
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// |x-y| ≤ max(fraction*min(|x|, |y|), margin)
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//
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// EquateApprox can be used in conjunction with [EquateNaNs].
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func EquateApprox(fraction, margin float64) cmp.Option {
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if margin < 0 || fraction < 0 || math.IsNaN(margin) || math.IsNaN(fraction) {
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panic("margin or fraction must be a non-negative number")
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}
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a := approximator{fraction, margin}
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return cmp.Options{
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cmp.FilterValues(areRealF64s, cmp.Comparer(a.compareF64)),
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cmp.FilterValues(areRealF32s, cmp.Comparer(a.compareF32)),
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}
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}
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type approximator struct{ frac, marg float64 }
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func areRealF64s(x, y float64) bool {
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return !math.IsNaN(x) && !math.IsNaN(y) && !math.IsInf(x, 0) && !math.IsInf(y, 0)
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}
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func areRealF32s(x, y float32) bool {
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return areRealF64s(float64(x), float64(y))
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}
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func (a approximator) compareF64(x, y float64) bool {
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relMarg := a.frac * math.Min(math.Abs(x), math.Abs(y))
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return math.Abs(x-y) <= math.Max(a.marg, relMarg)
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}
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func (a approximator) compareF32(x, y float32) bool {
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return a.compareF64(float64(x), float64(y))
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}
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// EquateNaNs returns a [cmp.Comparer] option that determines float32 and float64
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// NaN values to be equal.
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//
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// EquateNaNs can be used in conjunction with [EquateApprox].
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func EquateNaNs() cmp.Option {
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return cmp.Options{
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cmp.FilterValues(areNaNsF64s, cmp.Comparer(equateAlways)),
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cmp.FilterValues(areNaNsF32s, cmp.Comparer(equateAlways)),
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}
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}
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func areNaNsF64s(x, y float64) bool {
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return math.IsNaN(x) && math.IsNaN(y)
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}
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func areNaNsF32s(x, y float32) bool {
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return areNaNsF64s(float64(x), float64(y))
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}
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// EquateApproxTime returns a [cmp.Comparer] option that determines two non-zero
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// [time.Time] values to be equal if they are within some margin of one another.
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// If both times have a monotonic clock reading, then the monotonic time
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// difference will be used. The margin must be non-negative.
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func EquateApproxTime(margin time.Duration) cmp.Option {
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if margin < 0 {
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panic("margin must be a non-negative number")
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}
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a := timeApproximator{margin}
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return cmp.FilterValues(areNonZeroTimes, cmp.Comparer(a.compare))
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}
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func areNonZeroTimes(x, y time.Time) bool {
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return !x.IsZero() && !y.IsZero()
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}
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type timeApproximator struct {
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margin time.Duration
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}
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func (a timeApproximator) compare(x, y time.Time) bool {
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// Avoid subtracting times to avoid overflow when the
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// difference is larger than the largest representable duration.
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if x.After(y) {
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// Ensure x is always before y
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x, y = y, x
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}
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// We're within the margin if x+margin >= y.
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// Note: time.Time doesn't have AfterOrEqual method hence the negation.
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return !x.Add(a.margin).Before(y)
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}
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// AnyError is an error that matches any non-nil error.
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var AnyError anyError
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type anyError struct{}
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func (anyError) Error() string { return "any error" }
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func (anyError) Is(err error) bool { return err != nil }
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// EquateErrors returns a [cmp.Comparer] option that determines errors to be equal
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// if [errors.Is] reports them to match. The [AnyError] error can be used to
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// match any non-nil error.
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func EquateErrors() cmp.Option {
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return cmp.FilterValues(areConcreteErrors, cmp.Comparer(compareErrors))
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}
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// areConcreteErrors reports whether x and y are types that implement error.
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// The input types are deliberately of the interface{} type rather than the
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// error type so that we can handle situations where the current type is an
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// interface{}, but the underlying concrete types both happen to implement
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// the error interface.
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func areConcreteErrors(x, y interface{}) bool {
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_, ok1 := x.(error)
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_, ok2 := y.(error)
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return ok1 && ok2
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}
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func compareErrors(x, y interface{}) bool {
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xe := x.(error)
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ye := y.(error)
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return errors.Is(xe, ye) || errors.Is(ye, xe)
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}
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// EquateComparable returns a [cmp.Option] that determines equality
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// of comparable types by directly comparing them using the == operator in Go.
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// The types to compare are specified by passing a value of that type.
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// This option should only be used on types that are documented as being
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// safe for direct == comparison. For example, [net/netip.Addr] is documented
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// as being semantically safe to use with ==, while [time.Time] is documented
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// to discourage the use of == on time values.
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func EquateComparable(typs ...interface{}) cmp.Option {
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types := make(typesFilter)
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for _, typ := range typs {
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switch t := reflect.TypeOf(typ); {
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case !t.Comparable():
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panic(fmt.Sprintf("%T is not a comparable Go type", typ))
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case types[t]:
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panic(fmt.Sprintf("%T is already specified", typ))
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default:
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types[t] = true
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}
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}
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return cmp.FilterPath(types.filter, cmp.Comparer(equateAny))
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}
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type typesFilter map[reflect.Type]bool
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func (tf typesFilter) filter(p cmp.Path) bool { return tf[p.Last().Type()] }
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func equateAny(x, y interface{}) bool { return x == y }
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