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go/ssa/builder_test.go
Alan Donovan 87ced824bd go.tools/ssa: fix computation of set of types requiring method sets.
Motivation:

Previously, we assumed that the set of types for which a
complete method set (containing all synthesized wrapper
functions) is required at runtime was the set of types
used as operands to some *ssa.MakeInterface instruction.

In fact, this is an underapproximation because types can
be derived from other ones via reflection, and some of
these may need methods.  The reflect.Type API allows *T to
be derived from T, and these may have different method
sets.  Reflection also allows almost any subcomponent of a
type to be accessed (with one exception: given T, defined
'type T struct{S}', you can reach S but not struct{S}).

As a result, the pointer analysis was unable to generate
all necessary constraints before running the solver,
causing a crash when reflection derives types whose
methods are unavailable.  (A similar problem would afflict
an ahead-of-time compiler based on ssa.  The ssa/interp
interpreter was immune only because it does not require
all wrapper methods to be created before execution
begins.)

Description:

This change causes the SSA builder to record, for each
package, the set of all types with non-empty method sets that
are referenced within that package.  This set is accessed via
Packages.TypesWithMethodSets().  Program.TypesWithMethodSets()
returns its union across all packages.

The set of references that matter are:
- types of operands to some MakeInterface instruction (as before)
- types of all exported package members
- all subcomponents of the above, recursively.
This is a conservative approximation to the set of types
whose methods may be called dynamically.

We define the owning package of a type as follows:
- the owner of a named type is the package in which it is defined;
- the owner of a pointer-to-named type is the owner of that named type;
- the owner of all other types is nil.

A package must include the method sets for all types that it
owns, and all subcomponents of that type that are not owned by
another package, recursively.  Types with an owner appear in
exactly one package; types with no owner (such as struct{T})
may appear within multiple packages.
(A typical Go compiler would emit multiple copies of these
methods as weak symbols; a typical linker would eliminate
duplicates.)

Also:
- go/types/typemap: implement hash function for *Tuple.
- pointer: generate nodes/constraints for all of
  ssa.Program.TypesWithMethodSets().
  Add rtti.go regression test.
- Add API test of Package.TypesWithMethodSets().
- Set Function.Pkg to nil (again) for wrapper functions,
  since these may be shared by many packages.
- Remove a redundant logging statement.
- Document that ssa CREATE phase is in fact sequential.

Fixes golang/go#6605

R=gri
CC=golang-dev
https://golang.org/cl/14920056
2013-10-23 17:07:52 -04:00

229 lines
6.6 KiB
Go

// Copyright 2013 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 file.
package ssa_test
import (
"go/parser"
"reflect"
"sort"
"strings"
"testing"
"code.google.com/p/go.tools/go/types"
"code.google.com/p/go.tools/importer"
"code.google.com/p/go.tools/ssa"
)
func isEmpty(f *ssa.Function) bool { return f.Blocks == nil }
// Tests that programs partially loaded from gc object files contain
// functions with no code for the external portions, but are otherwise ok.
func TestExternalPackages(t *testing.T) {
test := `
package main
import (
"bytes"
"io"
"testing"
)
func main() {
var t testing.T
t.Parallel() // static call to external declared method
t.Fail() // static call to promoted external declared method
testing.Short() // static call to external package-level function
var w io.Writer = new(bytes.Buffer)
w.Write(nil) // interface invoke of external declared method
}
`
imp := importer.New(new(importer.Config)) // no go/build.Context; uses GC importer
f, err := parser.ParseFile(imp.Fset, "<input>", test, 0)
if err != nil {
t.Error(err)
return
}
mainInfo := imp.CreatePackage("main", f)
prog := ssa.NewProgram(imp.Fset, ssa.SanityCheckFunctions)
if err := prog.CreatePackages(imp); err != nil {
t.Error(err)
return
}
mainPkg := prog.Package(mainInfo.Pkg)
mainPkg.Build()
// Only the main package and its immediate dependencies are loaded.
deps := []string{"bytes", "io", "testing"}
all := prog.AllPackages()
if len(all) != 1+len(deps) {
t.Errorf("unexpected set of loaded packages: %q", all)
}
for _, path := range deps {
pkg := prog.ImportedPackage(path)
if pkg == nil {
t.Errorf("package not loaded: %q", path)
continue
}
// External packages should have no function bodies (except for wrappers).
isExt := pkg != mainPkg
// init()
if isExt && !isEmpty(pkg.Func("init")) {
t.Errorf("external package %s has non-empty init", pkg)
} else if !isExt && isEmpty(pkg.Func("init")) {
t.Errorf("main package %s has empty init", pkg)
}
for _, mem := range pkg.Members {
switch mem := mem.(type) {
case *ssa.Function:
// Functions at package level.
if isExt && !isEmpty(mem) {
t.Errorf("external function %s is non-empty", mem)
} else if !isExt && isEmpty(mem) {
t.Errorf("function %s is empty", mem)
}
case *ssa.Type:
// Methods of named types T.
// (In this test, all exported methods belong to *T not T.)
if !isExt {
t.Fatalf("unexpected name type in main package: %s", mem)
}
mset := types.NewPointer(mem.Type()).MethodSet()
for i, n := 0, mset.Len(); i < n; i++ {
m := prog.Method(mset.At(i))
// For external types, only synthetic wrappers have code.
expExt := !strings.Contains(m.Synthetic, "wrapper")
if expExt && !isEmpty(m) {
t.Errorf("external method %s is non-empty: %s",
m, m.Synthetic)
} else if !expExt && isEmpty(m) {
t.Errorf("method function %s is empty: %s",
m, m.Synthetic)
}
}
}
}
}
expectedCallee := []string{
"(*testing.T).Parallel",
"(*testing.common).Fail",
"testing.Short",
"N/A",
}
callNum := 0
for _, b := range mainPkg.Func("main").Blocks {
for _, instr := range b.Instrs {
switch instr := instr.(type) {
case ssa.CallInstruction:
call := instr.Common()
if want := expectedCallee[callNum]; want != "N/A" {
got := call.StaticCallee().String()
if want != got {
t.Errorf("call #%d from main.main: got callee %s, want %s",
callNum, got, want)
}
}
callNum++
}
}
}
if callNum != 4 {
t.Errorf("in main.main: got %d calls, want %d", callNum, 4)
}
}
// TestMethodSets tests that Package.TypesWithMethodSets includes all necessary types.
func TestTypesWithMethodSets(t *testing.T) {
tests := []struct {
input string
want []string
}{
// An exported package-level type is needed.
{`package p; type T struct{}; func (T) f() {}`,
[]string{"*p.T", "p.T"},
},
// An unexported package-level type is not needed.
{`package p; type t struct{}; func (t) f() {}`,
nil,
},
// Subcomponents of type of exported package-level var are needed.
{`package p; import "bytes"; var V struct {*bytes.Buffer}`,
[]string{"struct{*bytes.Buffer}"},
},
// Subcomponents of type of unexported package-level var are not needed.
{`package p; import "bytes"; var v struct {*bytes.Buffer}`,
nil,
},
// Subcomponents of type of exported package-level function are needed.
{`package p; import "bytes"; func F(struct {*bytes.Buffer}) {}`,
[]string{"struct{*bytes.Buffer}"},
},
// Subcomponents of type of unexported package-level function are not needed.
{`package p; import "bytes"; func f(struct {*bytes.Buffer}) {}`,
nil,
},
// Subcomponents of type of exported method are needed.
{`package p; import "bytes"; type x struct{}; func (x) G(struct {*bytes.Buffer}) {}`,
[]string{"*p.x", "p.x", "struct{*bytes.Buffer}"},
},
// Subcomponents of type of unexported method are not needed.
{`package p; import "bytes"; type X struct{}; func (X) G(struct {*bytes.Buffer}) {}`,
[]string{"*p.X", "p.X", "struct{*bytes.Buffer}"},
},
// Local types aren't needed.
{`package p; import "bytes"; func f() { type T struct {*bytes.Buffer}; var t T; _ = t }`,
nil,
},
// ...unless used by MakeInterface.
{`package p; import "bytes"; func f() { type T struct {*bytes.Buffer}; _ = interface{}(T{}) }`,
[]string{"*p.T", "p.T"},
},
// Types used as operand of MakeInterface are needed.
{`package p; import "bytes"; func f() { _ = interface{}(struct{*bytes.Buffer}{}) }`,
[]string{"struct{*bytes.Buffer}"},
},
// MakeInterface is optimized away when storing to a blank.
{`package p; import "bytes"; var _ interface{} = struct{*bytes.Buffer}{}`,
nil,
},
}
for i, test := range tests {
imp := importer.New(new(importer.Config)) // no go/build.Context; uses GC importer
f, err := parser.ParseFile(imp.Fset, "<input>", test.input, 0)
if err != nil {
t.Errorf("test %d: %s", i, err)
continue
}
mainInfo := imp.CreatePackage("p", f)
prog := ssa.NewProgram(imp.Fset, ssa.SanityCheckFunctions)
if err := prog.CreatePackages(imp); err != nil {
t.Errorf("test %d: %s", i, err)
continue
}
mainPkg := prog.Package(mainInfo.Pkg)
prog.BuildAll()
var typstrs []string
for _, T := range mainPkg.TypesWithMethodSets() {
typstrs = append(typstrs, T.String())
}
sort.Strings(typstrs)
if !reflect.DeepEqual(typstrs, test.want) {
t.Errorf("test %d: got %q, want %q", i, typstrs, test.want)
}
}
}