mirror of
https://github.com/golang/go
synced 2024-11-18 16:04:44 -07:00
9e5445377b
This is copied unchanged from x/exp. Change-Id: I944b912212f7fd844a4bea81605433baf4bcc9a2 Reviewed-on: https://go-review.googlesource.com/c/tools/+/170862 Reviewed-by: Jay Conrod <jayconrod@google.com>
220 lines
6.7 KiB
Go
220 lines
6.7 KiB
Go
package apidiff
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import (
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"go/types"
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"sort"
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)
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// Two types are correspond if they are identical except for defined types,
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// which must correspond.
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//
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// Two defined types correspond if they can be interchanged in the old and new APIs,
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// possibly after a renaming.
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//
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// This is not a pure function. If we come across named types while traversing,
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// we establish correspondence.
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func (d *differ) correspond(old, new types.Type) bool {
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return d.corr(old, new, nil)
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}
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// corr determines whether old and new correspond. The argument p is a list of
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// known interface identities, to avoid infinite recursion.
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//
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// corr calls itself recursively as much as possible, to establish more
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// correspondences and so check more of the API. E.g. if the new function has more
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// parameters than the old, compare all the old ones before returning false.
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//
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// Compare this to the implementation of go/types.Identical.
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func (d *differ) corr(old, new types.Type, p *ifacePair) bool {
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// Structure copied from types.Identical.
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switch old := old.(type) {
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case *types.Basic:
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return types.Identical(old, new)
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case *types.Array:
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if new, ok := new.(*types.Array); ok {
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return d.corr(old.Elem(), new.Elem(), p) && old.Len() == new.Len()
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}
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case *types.Slice:
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if new, ok := new.(*types.Slice); ok {
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return d.corr(old.Elem(), new.Elem(), p)
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}
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case *types.Map:
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if new, ok := new.(*types.Map); ok {
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return d.corr(old.Key(), new.Key(), p) && d.corr(old.Elem(), new.Elem(), p)
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}
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case *types.Chan:
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if new, ok := new.(*types.Chan); ok {
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return d.corr(old.Elem(), new.Elem(), p) && old.Dir() == new.Dir()
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}
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case *types.Pointer:
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if new, ok := new.(*types.Pointer); ok {
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return d.corr(old.Elem(), new.Elem(), p)
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}
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case *types.Signature:
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if new, ok := new.(*types.Signature); ok {
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pe := d.corr(old.Params(), new.Params(), p)
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re := d.corr(old.Results(), new.Results(), p)
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return old.Variadic() == new.Variadic() && pe && re
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}
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case *types.Tuple:
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if new, ok := new.(*types.Tuple); ok {
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for i := 0; i < old.Len(); i++ {
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if i >= new.Len() || !d.corr(old.At(i).Type(), new.At(i).Type(), p) {
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return false
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}
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}
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return old.Len() == new.Len()
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}
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case *types.Struct:
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if new, ok := new.(*types.Struct); ok {
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for i := 0; i < old.NumFields(); i++ {
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if i >= new.NumFields() {
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return false
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}
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of := old.Field(i)
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nf := new.Field(i)
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if of.Anonymous() != nf.Anonymous() ||
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old.Tag(i) != new.Tag(i) ||
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!d.corr(of.Type(), nf.Type(), p) ||
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!d.corrFieldNames(of, nf) {
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return false
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}
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}
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return old.NumFields() == new.NumFields()
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}
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case *types.Interface:
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if new, ok := new.(*types.Interface); ok {
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// Deal with circularity. See the comment in types.Identical.
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q := &ifacePair{old, new, p}
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for p != nil {
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if p.identical(q) {
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return true // same pair was compared before
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}
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p = p.prev
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}
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oldms := d.sortedMethods(old)
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newms := d.sortedMethods(new)
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for i, om := range oldms {
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if i >= len(newms) {
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return false
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}
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nm := newms[i]
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if d.methodID(om) != d.methodID(nm) || !d.corr(om.Type(), nm.Type(), q) {
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return false
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}
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}
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return old.NumMethods() == new.NumMethods()
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}
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case *types.Named:
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if new, ok := new.(*types.Named); ok {
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return d.establishCorrespondence(old, new)
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}
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if new, ok := new.(*types.Basic); ok {
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// Basic types are defined types, too, so we have to support them.
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return d.establishCorrespondence(old, new)
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}
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default:
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panic("unknown type kind")
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}
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return false
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}
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// Compare old and new field names. We are determining correspondence across packages,
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// so just compare names, not packages. For an unexported, embedded field of named
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// type (non-named embedded fields are possible with aliases), we check that the type
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// names correspond. We check the types for correspondence before this is called, so
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// we've established correspondence.
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func (d *differ) corrFieldNames(of, nf *types.Var) bool {
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if of.Anonymous() && nf.Anonymous() && !of.Exported() && !nf.Exported() {
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if on, ok := of.Type().(*types.Named); ok {
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nn := nf.Type().(*types.Named)
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return d.establishCorrespondence(on, nn)
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}
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}
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return of.Name() == nf.Name()
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}
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// Establish that old corresponds with new if it does not already
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// correspond to something else.
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func (d *differ) establishCorrespondence(old *types.Named, new types.Type) bool {
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oldname := old.Obj()
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oldc := d.correspondMap[oldname]
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if oldc == nil {
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// For now, assume the types don't correspond unless they are from the old
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// and new packages, respectively.
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//
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// This is too conservative. For instance,
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// [old] type A = q.B; [new] type A q.C
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// could be OK if in package q, B is an alias for C.
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// Or, using p as the name of the current old/new packages:
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// [old] type A = q.B; [new] type A int
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// could be OK if in q,
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// [old] type B int; [new] type B = p.A
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// In this case, p.A and q.B name the same type in both old and new worlds.
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// Note that this case doesn't imply circular package imports: it's possible
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// that in the old world, p imports q, but in the new, q imports p.
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//
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// However, if we didn't do something here, then we'd incorrectly allow cases
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// like the first one above in which q.B is not an alias for q.C
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//
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// What we should do is check that the old type, in the new world's package
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// of the same path, doesn't correspond to something other than the new type.
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// That is a bit hard, because there is no easy way to find a new package
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// matching an old one.
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if newn, ok := new.(*types.Named); ok {
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if old.Obj().Pkg() != d.old || newn.Obj().Pkg() != d.new {
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return old.Obj().Id() == newn.Obj().Id()
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}
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}
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// If there is no correspondence, create one.
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d.correspondMap[oldname] = new
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// Check that the corresponding types are compatible.
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d.checkCompatibleDefined(oldname, old, new)
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return true
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}
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return types.Identical(oldc, new)
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}
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func (d *differ) sortedMethods(iface *types.Interface) []*types.Func {
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ms := make([]*types.Func, iface.NumMethods())
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for i := 0; i < iface.NumMethods(); i++ {
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ms[i] = iface.Method(i)
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}
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sort.Slice(ms, func(i, j int) bool { return d.methodID(ms[i]) < d.methodID(ms[j]) })
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return ms
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}
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func (d *differ) methodID(m *types.Func) string {
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// If the method belongs to one of the two packages being compared, use
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// just its name even if it's unexported. That lets us treat unexported names
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// from the old and new packages as equal.
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if m.Pkg() == d.old || m.Pkg() == d.new {
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return m.Name()
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}
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return m.Id()
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}
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// Copied from the go/types package:
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// An ifacePair is a node in a stack of interface type pairs compared for identity.
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type ifacePair struct {
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x, y *types.Interface
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prev *ifacePair
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}
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func (p *ifacePair) identical(q *ifacePair) bool {
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return p.x == q.x && p.y == q.y || p.x == q.y && p.y == q.x
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}
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