196 lines
5.7 KiB
Go
196 lines
5.7 KiB
Go
// Copyright 2014 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 analysis
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// This file computes the "implements" relation over all pairs of
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// named types in the program. (The mark-up is done by typeinfo.go.)
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// TODO(adonovan): do we want to report implements(C, I) where C and I
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// belong to different packages and at least one is not exported?
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import (
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"go/types"
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"sort"
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"golang.org/x/tools/go/types/typeutil"
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)
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// computeImplements computes the "implements" relation over all pairs
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// of named types in allNamed.
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func computeImplements(cache *typeutil.MethodSetCache, allNamed []*types.Named) map[*types.Named]implementsFacts {
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// Information about a single type's method set.
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type msetInfo struct {
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typ types.Type
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mset *types.MethodSet
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mask1, mask2 uint64
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}
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initMsetInfo := func(info *msetInfo, typ types.Type) {
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info.typ = typ
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info.mset = cache.MethodSet(typ)
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for i := 0; i < info.mset.Len(); i++ {
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name := info.mset.At(i).Obj().Name()
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info.mask1 |= 1 << methodBit(name[0])
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info.mask2 |= 1 << methodBit(name[len(name)-1])
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}
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}
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// satisfies(T, U) reports whether type T satisfies type U.
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// U must be an interface.
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//
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// Since there are thousands of types (and thus millions of
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// pairs of types) and types.Assignable(T, U) is relatively
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// expensive, we compute assignability directly from the
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// method sets. (At least one of T and U must be an
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// interface.)
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//
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// We use a trick (thanks gri!) related to a Bloom filter to
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// quickly reject most tests, which are false. For each
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// method set, we precompute a mask, a set of bits, one per
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// distinct initial byte of each method name. Thus the mask
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// for io.ReadWriter would be {'R','W'}. AssignableTo(T, U)
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// cannot be true unless mask(T)&mask(U)==mask(U).
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//
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// As with a Bloom filter, we can improve precision by testing
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// additional hashes, e.g. using the last letter of each
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// method name, so long as the subset mask property holds.
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//
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// When analyzing the standard library, there are about 1e6
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// calls to satisfies(), of which 0.6% return true. With a
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// 1-hash filter, 95% of calls avoid the expensive check; with
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// a 2-hash filter, this grows to 98.2%.
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satisfies := func(T, U *msetInfo) bool {
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return T.mask1&U.mask1 == U.mask1 &&
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T.mask2&U.mask2 == U.mask2 &&
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containsAllIdsOf(T.mset, U.mset)
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}
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// Information about a named type N, and perhaps also *N.
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type namedInfo struct {
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isInterface bool
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base msetInfo // N
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ptr msetInfo // *N, iff N !isInterface
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}
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var infos []namedInfo
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// Precompute the method sets and their masks.
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for _, N := range allNamed {
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var info namedInfo
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initMsetInfo(&info.base, N)
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_, info.isInterface = N.Underlying().(*types.Interface)
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if !info.isInterface {
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initMsetInfo(&info.ptr, types.NewPointer(N))
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}
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if info.base.mask1|info.ptr.mask1 == 0 {
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continue // neither N nor *N has methods
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}
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infos = append(infos, info)
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}
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facts := make(map[*types.Named]implementsFacts)
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// Test all pairs of distinct named types (T, U).
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// TODO(adonovan): opt: compute (U, T) at the same time.
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for t := range infos {
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T := &infos[t]
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var to, from, fromPtr []types.Type
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for u := range infos {
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if t == u {
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continue
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}
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U := &infos[u]
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switch {
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case T.isInterface && U.isInterface:
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if satisfies(&U.base, &T.base) {
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to = append(to, U.base.typ)
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}
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if satisfies(&T.base, &U.base) {
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from = append(from, U.base.typ)
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}
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case T.isInterface: // U concrete
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if satisfies(&U.base, &T.base) {
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to = append(to, U.base.typ)
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} else if satisfies(&U.ptr, &T.base) {
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to = append(to, U.ptr.typ)
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}
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case U.isInterface: // T concrete
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if satisfies(&T.base, &U.base) {
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from = append(from, U.base.typ)
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} else if satisfies(&T.ptr, &U.base) {
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fromPtr = append(fromPtr, U.base.typ)
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}
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}
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}
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// Sort types (arbitrarily) to avoid nondeterminism.
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sort.Sort(typesByString(to))
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sort.Sort(typesByString(from))
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sort.Sort(typesByString(fromPtr))
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facts[T.base.typ.(*types.Named)] = implementsFacts{to, from, fromPtr}
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}
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return facts
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}
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type implementsFacts struct {
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to []types.Type // named or ptr-to-named types assignable to interface T
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from []types.Type // named interfaces assignable from T
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fromPtr []types.Type // named interfaces assignable only from *T
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}
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type typesByString []types.Type
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func (p typesByString) Len() int { return len(p) }
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func (p typesByString) Less(i, j int) bool { return p[i].String() < p[j].String() }
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func (p typesByString) Swap(i, j int) { p[i], p[j] = p[j], p[i] }
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// methodBit returns the index of x in [a-zA-Z], or 52 if not found.
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func methodBit(x byte) uint64 {
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switch {
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case 'a' <= x && x <= 'z':
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return uint64(x - 'a')
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case 'A' <= x && x <= 'Z':
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return uint64(26 + x - 'A')
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}
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return 52 // all other bytes
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}
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// containsAllIdsOf reports whether the method identifiers of T are a
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// superset of those in U. If U belongs to an interface type, the
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// result is equal to types.Assignable(T, U), but is cheaper to compute.
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//
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// TODO(gri): make this a method of *types.MethodSet.
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//
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func containsAllIdsOf(T, U *types.MethodSet) bool {
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t, tlen := 0, T.Len()
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u, ulen := 0, U.Len()
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for t < tlen && u < ulen {
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tMeth := T.At(t).Obj()
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uMeth := U.At(u).Obj()
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tId := tMeth.Id()
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uId := uMeth.Id()
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if tId > uId {
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// U has a method T lacks: fail.
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return false
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}
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if tId < uId {
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// T has a method U lacks: ignore it.
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t++
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continue
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}
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// U and T both have a method of this Id. Check types.
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if !types.Identical(tMeth.Type(), uMeth.Type()) {
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return false // type mismatch
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}
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u++
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t++
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}
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return u == ulen
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}
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