// Copyright 2017, The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE.md file. package cmp import ( "fmt" "reflect" "regexp" "strings" "github.com/google/go-cmp/cmp/internal/function" ) // Option configures for specific behavior of Equal and Diff. In particular, // the fundamental Option functions (Ignore, Transformer, and Comparer), // configure how equality is determined. // // The fundamental options may be composed with filters (FilterPath and // FilterValues) to control the scope over which they are applied. // // The cmp/cmpopts package provides helper functions for creating options that // may be used with Equal and Diff. type Option interface { // filter applies all filters and returns the option that remains. // Each option may only read s.curPath and call s.callTTBFunc. // // An Options is returned only if multiple comparers or transformers // can apply simultaneously and will only contain values of those types // or sub-Options containing values of those types. filter(s *state, t reflect.Type, vx, vy reflect.Value) applicableOption } // applicableOption represents the following types: // Fundamental: ignore | validator | *comparer | *transformer // Grouping: Options type applicableOption interface { Option // apply executes the option, which may mutate s or panic. apply(s *state, vx, vy reflect.Value) } // coreOption represents the following types: // Fundamental: ignore | validator | *comparer | *transformer // Filters: *pathFilter | *valuesFilter type coreOption interface { Option isCore() } type core struct{} func (core) isCore() {} // Options is a list of Option values that also satisfies the Option interface. // Helper comparison packages may return an Options value when packing multiple // Option values into a single Option. When this package processes an Options, // it will be implicitly expanded into a flat list. // // Applying a filter on an Options is equivalent to applying that same filter // on all individual options held within. type Options []Option func (opts Options) filter(s *state, t reflect.Type, vx, vy reflect.Value) (out applicableOption) { for _, opt := range opts { switch opt := opt.filter(s, t, vx, vy); opt.(type) { case ignore: return ignore{} // Only ignore can short-circuit evaluation case validator: out = validator{} // Takes precedence over comparer or transformer case *comparer, *transformer, Options: switch out.(type) { case nil: out = opt case validator: // Keep validator case *comparer, *transformer, Options: out = Options{out, opt} // Conflicting comparers or transformers } } } return out } func (opts Options) apply(s *state, _, _ reflect.Value) { const warning = "ambiguous set of applicable options" const help = "consider using filters to ensure at most one Comparer or Transformer may apply" var ss []string for _, opt := range flattenOptions(nil, opts) { ss = append(ss, fmt.Sprint(opt)) } set := strings.Join(ss, "\n\t") panic(fmt.Sprintf("%s at %#v:\n\t%s\n%s", warning, s.curPath, set, help)) } func (opts Options) String() string { var ss []string for _, opt := range opts { ss = append(ss, fmt.Sprint(opt)) } return fmt.Sprintf("Options{%s}", strings.Join(ss, ", ")) } // FilterPath returns a new Option where opt is only evaluated if filter f // returns true for the current Path in the value tree. // // This filter is called even if a slice element or map entry is missing and // provides an opportunity to ignore such cases. The filter function must be // symmetric such that the filter result is identical regardless of whether the // missing value is from x or y. // // The option passed in may be an Ignore, Transformer, Comparer, Options, or // a previously filtered Option. func FilterPath(f func(Path) bool, opt Option) Option { if f == nil { panic("invalid path filter function") } if opt := normalizeOption(opt); opt != nil { return &pathFilter{fnc: f, opt: opt} } return nil } type pathFilter struct { core fnc func(Path) bool opt Option } func (f pathFilter) filter(s *state, t reflect.Type, vx, vy reflect.Value) applicableOption { if f.fnc(s.curPath) { return f.opt.filter(s, t, vx, vy) } return nil } func (f pathFilter) String() string { return fmt.Sprintf("FilterPath(%s, %v)", function.NameOf(reflect.ValueOf(f.fnc)), f.opt) } // FilterValues returns a new Option where opt is only evaluated if filter f, // which is a function of the form "func(T, T) bool", returns true for the // current pair of values being compared. If either value is invalid or // the type of the values is not assignable to T, then this filter implicitly // returns false. // // The filter function must be // symmetric (i.e., agnostic to the order of the inputs) and // deterministic (i.e., produces the same result when given the same inputs). // If T is an interface, it is possible that f is called with two values with // different concrete types that both implement T. // // The option passed in may be an Ignore, Transformer, Comparer, Options, or // a previously filtered Option. func FilterValues(f interface{}, opt Option) Option { v := reflect.ValueOf(f) if !function.IsType(v.Type(), function.ValueFilter) || v.IsNil() { panic(fmt.Sprintf("invalid values filter function: %T", f)) } if opt := normalizeOption(opt); opt != nil { vf := &valuesFilter{fnc: v, opt: opt} if ti := v.Type().In(0); ti.Kind() != reflect.Interface || ti.NumMethod() > 0 { vf.typ = ti } return vf } return nil } type valuesFilter struct { core typ reflect.Type // T fnc reflect.Value // func(T, T) bool opt Option } func (f valuesFilter) filter(s *state, t reflect.Type, vx, vy reflect.Value) applicableOption { if !vx.IsValid() || !vx.CanInterface() || !vy.IsValid() || !vy.CanInterface() { return nil } if (f.typ == nil || t.AssignableTo(f.typ)) && s.callTTBFunc(f.fnc, vx, vy) { return f.opt.filter(s, t, vx, vy) } return nil } func (f valuesFilter) String() string { return fmt.Sprintf("FilterValues(%s, %v)", function.NameOf(f.fnc), f.opt) } // Ignore is an Option that causes all comparisons to be ignored. // This value is intended to be combined with FilterPath or FilterValues. // It is an error to pass an unfiltered Ignore option to Equal. func Ignore() Option { return ignore{} } type ignore struct{ core } func (ignore) isFiltered() bool { return false } func (ignore) filter(_ *state, _ reflect.Type, _, _ reflect.Value) applicableOption { return ignore{} } func (ignore) apply(s *state, _, _ reflect.Value) { s.report(true, reportByIgnore) } func (ignore) String() string { return "Ignore()" } // validator is a sentinel Option type to indicate that some options could not // be evaluated due to unexported fields, missing slice elements, or // missing map entries. Both values are validator only for unexported fields. type validator struct{ core } func (validator) filter(_ *state, _ reflect.Type, vx, vy reflect.Value) applicableOption { if !vx.IsValid() || !vy.IsValid() { return validator{} } if !vx.CanInterface() || !vy.CanInterface() { return validator{} } return nil } func (validator) apply(s *state, vx, vy reflect.Value) { // Implies missing slice element or map entry. if !vx.IsValid() || !vy.IsValid() { s.report(vx.IsValid() == vy.IsValid(), 0) return } // Unable to Interface implies unexported field without visibility access. if !vx.CanInterface() || !vy.CanInterface() { const help = "consider using a custom Comparer; if you control the implementation of type, you can also consider using an Exporter, AllowUnexported, or cmpopts.IgnoreUnexported" var name string if t := s.curPath.Index(-2).Type(); t.Name() != "" { // Named type with unexported fields. name = fmt.Sprintf("%q.%v", t.PkgPath(), t.Name()) // e.g., "path/to/package".MyType } else { // Unnamed type with unexported fields. Derive PkgPath from field. var pkgPath string for i := 0; i < t.NumField() && pkgPath == ""; i++ { pkgPath = t.Field(i).PkgPath } name = fmt.Sprintf("%q.(%v)", pkgPath, t.String()) // e.g., "path/to/package".(struct { a int }) } panic(fmt.Sprintf("cannot handle unexported field at %#v:\n\t%v\n%s", s.curPath, name, help)) } panic("not reachable") } // identRx represents a valid identifier according to the Go specification. const identRx = `[_\p{L}][_\p{L}\p{N}]*` var identsRx = regexp.MustCompile(`^` + identRx + `(\.` + identRx + `)*$`) // Transformer returns an Option that applies a transformation function that // converts values of a certain type into that of another. // // The transformer f must be a function "func(T) R" that converts values of // type T to those of type R and is implicitly filtered to input values // assignable to T. The transformer must not mutate T in any way. // // To help prevent some cases of infinite recursive cycles applying the // same transform to the output of itself (e.g., in the case where the // input and output types are the same), an implicit filter is added such that // a transformer is applicable only if that exact transformer is not already // in the tail of the Path since the last non-Transform step. // For situations where the implicit filter is still insufficient, // consider using cmpopts.AcyclicTransformer, which adds a filter // to prevent the transformer from being recursively applied upon itself. // // The name is a user provided label that is used as the Transform.Name in the // transformation PathStep (and eventually shown in the Diff output). // The name must be a valid identifier or qualified identifier in Go syntax. // If empty, an arbitrary name is used. func Transformer(name string, f interface{}) Option { v := reflect.ValueOf(f) if !function.IsType(v.Type(), function.Transformer) || v.IsNil() { panic(fmt.Sprintf("invalid transformer function: %T", f)) } if name == "" { name = function.NameOf(v) if !identsRx.MatchString(name) { name = "λ" // Lambda-symbol as placeholder name } } else if !identsRx.MatchString(name) { panic(fmt.Sprintf("invalid name: %q", name)) } tr := &transformer{name: name, fnc: reflect.ValueOf(f)} if ti := v.Type().In(0); ti.Kind() != reflect.Interface || ti.NumMethod() > 0 { tr.typ = ti } return tr } type transformer struct { core name string typ reflect.Type // T fnc reflect.Value // func(T) R } func (tr *transformer) isFiltered() bool { return tr.typ != nil } func (tr *transformer) filter(s *state, t reflect.Type, _, _ reflect.Value) applicableOption { for i := len(s.curPath) - 1; i >= 0; i-- { if t, ok := s.curPath[i].(Transform); !ok { break // Hit most recent non-Transform step } else if tr == t.trans { return nil // Cannot directly use same Transform } } if tr.typ == nil || t.AssignableTo(tr.typ) { return tr } return nil } func (tr *transformer) apply(s *state, vx, vy reflect.Value) { step := Transform{&transform{pathStep{typ: tr.fnc.Type().Out(0)}, tr}} vvx := s.callTRFunc(tr.fnc, vx, step) vvy := s.callTRFunc(tr.fnc, vy, step) step.vx, step.vy = vvx, vvy s.compareAny(step) } func (tr transformer) String() string { return fmt.Sprintf("Transformer(%s, %s)", tr.name, function.NameOf(tr.fnc)) } // Comparer returns an Option that determines whether two values are equal // to each other. // // The comparer f must be a function "func(T, T) bool" and is implicitly // filtered to input values assignable to T. If T is an interface, it is // possible that f is called with two values of different concrete types that // both implement T. // // The equality function must be: // • Symmetric: equal(x, y) == equal(y, x) // • Deterministic: equal(x, y) == equal(x, y) // • Pure: equal(x, y) does not modify x or y func Comparer(f interface{}) Option { v := reflect.ValueOf(f) if !function.IsType(v.Type(), function.Equal) || v.IsNil() { panic(fmt.Sprintf("invalid comparer function: %T", f)) } cm := &comparer{fnc: v} if ti := v.Type().In(0); ti.Kind() != reflect.Interface || ti.NumMethod() > 0 { cm.typ = ti } return cm } type comparer struct { core typ reflect.Type // T fnc reflect.Value // func(T, T) bool } func (cm *comparer) isFiltered() bool { return cm.typ != nil } func (cm *comparer) filter(_ *state, t reflect.Type, _, _ reflect.Value) applicableOption { if cm.typ == nil || t.AssignableTo(cm.typ) { return cm } return nil } func (cm *comparer) apply(s *state, vx, vy reflect.Value) { eq := s.callTTBFunc(cm.fnc, vx, vy) s.report(eq, reportByFunc) } func (cm comparer) String() string { return fmt.Sprintf("Comparer(%s)", function.NameOf(cm.fnc)) } // Exporter returns an Option that specifies whether Equal is allowed to // introspect into the unexported fields of certain struct types. // // Users of this option must understand that comparing on unexported fields // from external packages is not safe since changes in the internal // implementation of some external package may cause the result of Equal // to unexpectedly change. However, it may be valid to use this option on types // defined in an internal package where the semantic meaning of an unexported // field is in the control of the user. // // In many cases, a custom Comparer should be used instead that defines // equality as a function of the public API of a type rather than the underlying // unexported implementation. // // For example, the reflect.Type documentation defines equality to be determined // by the == operator on the interface (essentially performing a shallow pointer // comparison) and most attempts to compare *regexp.Regexp types are interested // in only checking that the regular expression strings are equal. // Both of these are accomplished using Comparers: // // Comparer(func(x, y reflect.Type) bool { return x == y }) // Comparer(func(x, y *regexp.Regexp) bool { return x.String() == y.String() }) // // In other cases, the cmpopts.IgnoreUnexported option can be used to ignore // all unexported fields on specified struct types. func Exporter(f func(reflect.Type) bool) Option { if !supportExporters { panic("Exporter is not supported on purego builds") } return exporter(f) } type exporter func(reflect.Type) bool func (exporter) filter(_ *state, _ reflect.Type, _, _ reflect.Value) applicableOption { panic("not implemented") } // AllowUnexported returns an Options that allows Equal to forcibly introspect // unexported fields of the specified struct types. // // See Exporter for the proper use of this option. func AllowUnexported(types ...interface{}) Option { m := make(map[reflect.Type]bool) for _, typ := range types { t := reflect.TypeOf(typ) if t.Kind() != reflect.Struct { panic(fmt.Sprintf("invalid struct type: %T", typ)) } m[t] = true } return exporter(func(t reflect.Type) bool { return m[t] }) } // Result represents the comparison result for a single node and // is provided by cmp when calling Result (see Reporter). type Result struct { _ [0]func() // Make Result incomparable flags resultFlags } // Equal reports whether the node was determined to be equal or not. // As a special case, ignored nodes are considered equal. func (r Result) Equal() bool { return r.flags&(reportEqual|reportByIgnore) != 0 } // ByIgnore reports whether the node is equal because it was ignored. // This never reports true if Equal reports false. func (r Result) ByIgnore() bool { return r.flags&reportByIgnore != 0 } // ByMethod reports whether the Equal method determined equality. func (r Result) ByMethod() bool { return r.flags&reportByMethod != 0 } // ByFunc reports whether a Comparer function determined equality. func (r Result) ByFunc() bool { return r.flags&reportByFunc != 0 } // ByCycle reports whether a reference cycle was detected. func (r Result) ByCycle() bool { return r.flags&reportByCycle != 0 } type resultFlags uint const ( _ resultFlags = (1 << iota) / 2 reportEqual reportUnequal reportByIgnore reportByMethod reportByFunc reportByCycle ) // Reporter is an Option that can be passed to Equal. When Equal traverses // the value trees, it calls PushStep as it descends into each node in the // tree and PopStep as it ascend out of the node. The leaves of the tree are // either compared (determined to be equal or not equal) or ignored and reported // as such by calling the Report method. func Reporter(r interface { // PushStep is called when a tree-traversal operation is performed. // The PathStep itself is only valid until the step is popped. // The PathStep.Values are valid for the duration of the entire traversal // and must not be mutated. // // Equal always calls PushStep at the start to provide an operation-less // PathStep used to report the root values. // // Within a slice, the exact set of inserted, removed, or modified elements // is unspecified and may change in future implementations. // The entries of a map are iterated through in an unspecified order. PushStep(PathStep) // Report is called exactly once on leaf nodes to report whether the // comparison identified the node as equal, unequal, or ignored. // A leaf node is one that is immediately preceded by and followed by // a pair of PushStep and PopStep calls. Report(Result) // PopStep ascends back up the value tree. // There is always a matching pop call for every push call. PopStep() }) Option { return reporter{r} } type reporter struct{ reporterIface } type reporterIface interface { PushStep(PathStep) Report(Result) PopStep() } func (reporter) filter(_ *state, _ reflect.Type, _, _ reflect.Value) applicableOption { panic("not implemented") } // normalizeOption normalizes the input options such that all Options groups // are flattened and groups with a single element are reduced to that element. // Only coreOptions and Options containing coreOptions are allowed. func normalizeOption(src Option) Option { switch opts := flattenOptions(nil, Options{src}); len(opts) { case 0: return nil case 1: return opts[0] default: return opts } } // flattenOptions copies all options in src to dst as a flat list. // Only coreOptions and Options containing coreOptions are allowed. func flattenOptions(dst, src Options) Options { for _, opt := range src { switch opt := opt.(type) { case nil: continue case Options: dst = flattenOptions(dst, opt) case coreOption: dst = append(dst, opt) default: panic(fmt.Sprintf("invalid option type: %T", opt)) } } return dst }