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mirror of https://github.com/golang/go synced 2024-11-18 18:44:42 -07:00
go/pointer/pointer_test.go
Alan Donovan 3b5de067a1 go.tools/pointer: reflection, part 1: maps, and some core features.
Core:
        reflect.TypeOf
        reflect.ValueOf
        reflect.Zero
        reflect.Value.Interface
Maps:
        (reflect.Value).MapIndex
        (reflect.Value).MapKeys
        (reflect.Value).SetMapIndex
        (*reflect.rtype).Elem
        (*reflect.rtype).Key

+ tests:
  pointer/testdata/mapreflect.go.
  oracle/testdata/src/main/reflection.go.

Interface objects (T, V...) have been renamed "tagged objects".

Abstraction: we model reflect.Value similar to
interface{}---as a pointer that points only to tagged
objects---but a reflect.Value may also point to an "indirect
tagged object", one in which the payload V is of type *T not T.
These are required because reflect.Values can hold lvalues,
e.g. when derived via Field() or Elem(), though we won't use
them till we get to structs and pointers.

Solving: each reflection intrinsic defines a new constraint
and resolution rule.  Because of the nature of reflection,
generalizing across types, the resolution rules dynamically
create additional complex constraints during solving, where
previously only simple (copy) constraints were created.
This requires some solver changes:

  The work done before the main solver loop (to attach new
  constraints to the graph) is now done before each iteration,
  in processNewConstraints.

  Its loop over constraints is broken into two passes:
  the first handles base (addr-of) constraints,
  the second handles simple and complex constraints.

  constraint.init() has been inlined.  The only behaviour that
  varies across constraints is ptr()

Sadly this will pessimize presolver optimisations, when we get
there; such is the price of reflection.

Objects: reflection intrinsics create objects (i.e. cause
memory allocations) with no SSA operation.  We will represent
them as the cgnode of the instrinsic (e.g. reflect.New), so we
extend Labels and node.data to represent objects as a product
(not sum) of ssa.Value and cgnode and pull this out into its
own type, struct object.  This simplifies a number of
invariants and saves space.  The ntObject flag is now
represented by obj!=nil; the other flags are moved into
object.

cgnodes are now always recorded in objects/Labels for which it
is appropriate (all but those for globals, constants and the
shared contours for functions).

Also:
- Prepopulate the flattenMemo cache to consider reflect.Value
  a fake pointer, not a struct.
- Improve accessors and documentation on type Label.
- @conctypes assertions renamed @types (since dyn. types needn't be concrete).
- add oracle 'describe' test on an interface (missing, an oversight).

R=crawshaw
CC=golang-dev
https://golang.org/cl/13418048
2013-09-16 09:49:10 -04:00

570 lines
15 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 pointer_test
// This test uses 'expectation' comments embedded within testdata/*.go
// files to specify the expected pointer analysis behaviour.
// See below for grammar.
import (
"bytes"
"fmt"
"go/build"
"go/parser"
"go/token"
"io/ioutil"
"os"
"regexp"
"strconv"
"strings"
"testing"
"code.google.com/p/go.tools/go/types"
"code.google.com/p/go.tools/go/types/typemap"
"code.google.com/p/go.tools/importer"
"code.google.com/p/go.tools/pointer"
"code.google.com/p/go.tools/ssa"
)
var inputs = []string{
// Currently debugging:
// "testdata/tmp.go",
// Working:
"testdata/another.go",
"testdata/arrays.go",
"testdata/channels.go",
"testdata/context.go",
"testdata/conv.go",
"testdata/flow.go",
"testdata/fmtexcerpt.go",
"testdata/func.go",
"testdata/hello.go",
"testdata/interfaces.go",
"testdata/maps.go",
"testdata/panic.go",
"testdata/recur.go",
"testdata/structs.go",
"testdata/a_test.go",
"testdata/mapreflect.go",
// TODO(adonovan): get these tests (of reflection) passing.
// (The tests are mostly sound since they were used for a
// previous implementation.)
// "testdata/funcreflect.go",
// "testdata/arrayreflect.go",
// "testdata/chanreflect.go",
// "testdata/finalizer.go",
// "testdata/reflect.go",
// "testdata/structreflect.go",
}
// Expectation grammar:
//
// @calls f -> g
//
// A 'calls' expectation asserts that edge (f, g) appears in the
// callgraph. f and g are notated as per Function.String(), which
// may contain spaces (e.g. promoted method in anon struct).
//
// @pointsto a | b | c
//
// A 'pointsto' expectation asserts that the points-to set of its
// operand contains exactly the set of labels {a,b,c} notated as per
// labelString.
//
// A 'pointsto' expectation must appear on the same line as a
// print(x) statement; the expectation's operand is x.
//
// If one of the strings is "...", the expectation asserts that the
// points-to set at least the other labels.
//
// We use '|' because label names may contain spaces, e.g. methods
// of anonymous structs.
//
// From a theoretical perspective, concrete types in interfaces are
// labels too, but they are represented differently and so have a
// different expectation, @types, below.
//
// @types t | u | v
//
// A 'types' expectation asserts that the set of possible dynamic
// types of its interface operand is exactly {t,u,v}, notated per
// go/types.Type.String(). In other words, it asserts that the type
// component of the interface may point to that set of concrete type
// literals. It also works for reflect.Value, though the types
// needn't be concrete in that case.
//
// A 'types' expectation must appear on the same line as a
// print(x) statement; the expectation's operand is x.
//
// If one of the strings is "...", the expectation asserts that the
// interface's type may point to at least the other types.
//
// We use '|' because type names may contain spaces.
//
// @warning "regexp"
//
// A 'warning' expectation asserts that the analysis issues a
// warning that matches the regular expression within the string
// literal.
//
// @line id
//
// A line directive associates the name "id" with the current
// file:line. The string form of labels will use this id instead of
// a file:line, making @pointsto expectations more robust against
// perturbations in the source file.
// (NB, anon functions still include line numbers.)
//
type expectation struct {
kind string // "pointsto" | "types" | "calls" | "warning"
filename string
linenum int // source line number, 1-based
args []string
types []types.Type // for types
}
func (e *expectation) String() string {
return fmt.Sprintf("@%s[%s]", e.kind, strings.Join(e.args, " | "))
}
func (e *expectation) errorf(format string, args ...interface{}) {
fmt.Printf("%s:%d: ", e.filename, e.linenum)
fmt.Printf(format, args...)
fmt.Println()
}
func (e *expectation) needsProbe() bool {
return e.kind == "pointsto" || e.kind == "types"
}
// A record of a call to the built-in print() function. Used for testing.
type probe struct {
instr *ssa.CallCommon
arg0 pointer.Pointer // first argument to print
}
// Find probe (call to print(x)) of same source
// file/line as expectation.
func findProbe(prog *ssa.Program, probes []probe, e *expectation) *probe {
for _, p := range probes {
pos := prog.Fset.Position(p.instr.Pos())
if pos.Line == e.linenum && pos.Filename == e.filename {
// TODO(adonovan): send this to test log (display only on failure).
// fmt.Printf("%s:%d: info: found probe for %s: %s\n",
// e.filename, e.linenum, e, p.arg0) // debugging
return &p
}
}
return nil // e.g. analysis didn't reach this call
}
func doOneInput(input, filename string) bool {
impctx := &importer.Config{Build: &build.Default}
imp := importer.New(impctx)
// Parsing.
f, err := parser.ParseFile(imp.Fset, filename, input, parser.DeclarationErrors)
if err != nil {
// TODO(adonovan): err is a scanner error list;
// display all errors not just first?
fmt.Println(err)
return false
}
// Load main package and its dependencies.
info := imp.LoadMainPackage(f)
// SSA creation + building.
prog := ssa.NewProgram(imp.Fset, ssa.SanityCheckFunctions)
if err := prog.CreatePackages(imp); err != nil {
fmt.Println(err)
return false
}
prog.BuildAll()
mainpkg := prog.Package(info.Pkg)
ptrmain := mainpkg // main package for the pointer analysis
if mainpkg.Func("main") == nil {
// No main function; assume it's a test.
mainpkg.CreateTestMainFunction()
fmt.Printf("%s: synthesized testmain package for test.\n", imp.Fset.Position(f.Package))
}
ok := true
lineMapping := make(map[string]string) // maps "file:line" to @line tag
// Parse expectations in this input.
var exps []*expectation
re := regexp.MustCompile("// *@([a-z]*) *(.*)$")
lines := strings.Split(input, "\n")
for linenum, line := range lines {
linenum++ // make it 1-based
if matches := re.FindAllStringSubmatch(line, -1); matches != nil {
match := matches[0]
kind, rest := match[1], match[2]
e := &expectation{kind: kind, filename: filename, linenum: linenum}
if kind == "line" {
if rest == "" {
ok = false
e.errorf("@%s expectation requires identifier", kind)
} else {
lineMapping[fmt.Sprintf("%s:%d", filename, linenum)] = rest
}
continue
}
if e.needsProbe() && !strings.Contains(line, "print(") {
ok = false
e.errorf("@%s expectation must follow call to print(x)", kind)
continue
}
switch kind {
case "pointsto":
e.args = split(rest, "|")
case "types":
for _, typstr := range split(rest, "|") {
var t types.Type = types.Typ[types.Invalid] // means "..."
if typstr != "..." {
texpr, err := parser.ParseExpr(typstr)
if err != nil {
ok = false
// Don't print err since its location is bad.
e.errorf("'%s' is not a valid type", typstr)
continue
}
mainFileScope := mainpkg.Object.Scope().Child(0)
t, _, err = types.EvalNode(imp.Fset, texpr, mainpkg.Object, mainFileScope)
if err != nil {
ok = false
// Don't print err since its location is bad.
e.errorf("'%s' is not a valid type: %s", typstr, err)
continue
}
}
e.types = append(e.types, t)
}
case "calls":
e.args = split(rest, "->")
// TODO(adonovan): eagerly reject the
// expectation if fn doesn't denote
// existing function, rather than fail
// the expectation after analysis.
if len(e.args) != 2 {
ok = false
e.errorf("@calls expectation wants 'caller -> callee' arguments")
continue
}
case "warning":
lit, err := strconv.Unquote(strings.TrimSpace(rest))
if err != nil {
ok = false
e.errorf("couldn't parse @warning operand: %s", err.Error())
continue
}
e.args = append(e.args, lit)
default:
ok = false
e.errorf("unknown expectation kind: %s", e)
continue
}
exps = append(exps, e)
}
}
var probes []probe
var warnings []string
var log bytes.Buffer
callgraph := make(pointer.CallGraph)
// Run the analysis.
config := &pointer.Config{
Mains: []*ssa.Package{ptrmain},
Log: &log,
Print: func(site *ssa.CallCommon, p pointer.Pointer) {
probes = append(probes, probe{site, p})
},
Call: callgraph.AddEdge,
Warn: func(pos token.Pos, format string, args ...interface{}) {
msg := fmt.Sprintf(format, args...)
fmt.Printf("%s: warning: %s\n", prog.Fset.Position(pos), msg)
warnings = append(warnings, msg)
},
}
pointer.Analyze(config)
// Print the log is there was an error or a panic.
complete := false
defer func() {
if !complete || !ok {
log.WriteTo(os.Stderr)
}
}()
// Check the expectations.
for _, e := range exps {
var pr *probe
if e.needsProbe() {
if pr = findProbe(prog, probes, e); pr == nil {
ok = false
e.errorf("unreachable print() statement has expectation %s", e)
continue
}
if pr.arg0 == nil {
ok = false
e.errorf("expectation on non-pointerlike operand: %s", pr.instr.Args[0].Type())
continue
}
}
switch e.kind {
case "pointsto":
if !checkPointsToExpectation(e, pr, lineMapping, prog) {
ok = false
}
case "types":
if !checkTypesExpectation(e, pr) {
ok = false
}
case "calls":
if !checkCallsExpectation(prog, e, callgraph) {
ok = false
}
case "warning":
if !checkWarningExpectation(prog, e, warnings) {
ok = false
}
}
}
complete = true
// ok = false // debugging: uncomment to always see log
return ok
}
func labelString(l *pointer.Label, lineMapping map[string]string, prog *ssa.Program) string {
// Functions and Globals need no pos suffix,
// nor do allocations in intrinsic operations
// (for which we'll print the function name).
switch l.Value().(type) {
case nil, *ssa.Function, *ssa.Global:
return l.String()
}
str := l.String()
if pos := l.Pos(); pos != token.NoPos {
// Append the position, using a @line tag instead of a line number, if defined.
posn := prog.Fset.Position(pos)
s := fmt.Sprintf("%s:%d", posn.Filename, posn.Line)
if tag, ok := lineMapping[s]; ok {
return fmt.Sprintf("%s@%s:%d", str, tag, posn.Column)
}
str = fmt.Sprintf("%s@%s", str, posn)
}
return str
}
func checkPointsToExpectation(e *expectation, pr *probe, lineMapping map[string]string, prog *ssa.Program) bool {
expected := make(map[string]struct{})
surplus := make(map[string]struct{})
exact := true
for _, g := range e.args {
if g == "..." {
exact = false
continue
}
expected[g] = struct{}{}
}
// Find the set of labels that the probe's
// argument (x in print(x)) may point to.
for _, label := range pr.arg0.PointsTo().Labels() {
name := labelString(label, lineMapping, prog)
if _, ok := expected[name]; ok {
delete(expected, name)
} else if exact {
surplus[name] = struct{}{}
}
}
// Report set difference:
ok := true
if len(expected) > 0 {
ok = false
e.errorf("value does not alias these expected labels: %s", join(expected))
}
if len(surplus) > 0 {
ok = false
e.errorf("value may additionally alias these labels: %s", join(surplus))
}
return ok
}
// underlying returns the underlying type of typ. Copied from go/types.
func underlyingType(typ types.Type) types.Type {
if typ, ok := typ.(*types.Named); ok {
return typ.Underlying() // underlying types are never NamedTypes
}
if typ == nil {
panic("underlying(nil)")
}
return typ
}
func checkTypesExpectation(e *expectation, pr *probe) bool {
var expected typemap.M
var surplus typemap.M
exact := true
for _, g := range e.types {
if g == types.Typ[types.Invalid] {
exact = false
continue
}
expected.Set(g, struct{}{})
}
if t := pr.instr.Args[0].Type(); !pointer.CanHaveDynamicTypes(t) {
e.errorf("@types expectation requires an interface- or reflect.Value-typed operand, got %s", t)
return false
}
// Find the set of types that the probe's
// argument (x in print(x)) may contain.
for _, T := range pr.arg0.PointsTo().DynamicTypes().Keys() {
if expected.At(T) != nil {
expected.Delete(T)
} else if exact {
surplus.Set(T, struct{}{})
}
}
// Report set difference:
ok := true
if expected.Len() > 0 {
ok = false
e.errorf("interface cannot contain these types: %s", expected.KeysString())
}
if surplus.Len() > 0 {
ok = false
e.errorf("interface may additionally contain these types: %s", surplus.KeysString())
}
return ok
return false
}
func checkCallsExpectation(prog *ssa.Program, e *expectation, callgraph pointer.CallGraph) bool {
// TODO(adonovan): this is inefficient and not robust against
// typos. Better to convert strings to *Functions during
// expectation parsing (somehow).
for caller, callees := range callgraph {
if caller.Func().String() == e.args[0] {
found := make(map[string]struct{})
for callee := range callees {
s := callee.Func().String()
found[s] = struct{}{}
if s == e.args[1] {
return true // expectation satisfied
}
}
e.errorf("found no call from %s to %s, but only to %s",
e.args[0], e.args[1], join(found))
return false
}
}
e.errorf("didn't find any calls from %s", e.args[0])
return false
}
func checkWarningExpectation(prog *ssa.Program, e *expectation, warnings []string) bool {
// TODO(adonovan): check the position part of the warning too?
re, err := regexp.Compile(e.args[0])
if err != nil {
e.errorf("invalid regular expression in @warning expectation: %s", err.Error())
return false
}
if len(warnings) == 0 {
e.errorf("@warning %s expectation, but no warnings", strconv.Quote(e.args[0]))
return false
}
for _, warning := range warnings {
if re.MatchString(warning) {
return true
}
}
e.errorf("@warning %s expectation not satised; found these warnings though:", strconv.Quote(e.args[0]))
for _, warning := range warnings {
fmt.Println("\t", warning)
}
return false
}
func TestInput(t *testing.T) {
ok := true
wd, err := os.Getwd()
if err != nil {
t.Errorf("os.Getwd: %s", err)
return
}
// 'go test' does a chdir so that relative paths in
// diagnostics no longer make sense relative to the invoking
// shell's cwd. We print a special marker so that Emacs can
// make sense of them.
fmt.Fprintf(os.Stderr, "Entering directory `%s'\n", wd)
for _, filename := range inputs {
content, err := ioutil.ReadFile(filename)
if err != nil {
t.Errorf("couldn't read file '%s': %s", filename, err)
continue
}
if !doOneInput(string(content), filename) {
ok = false
}
}
if !ok {
t.Fail()
}
}
// join joins the elements of set with " | "s.
func join(set map[string]struct{}) string {
var buf bytes.Buffer
sep := ""
for name := range set {
buf.WriteString(sep)
sep = " | "
buf.WriteString(name)
}
return buf.String()
}
// split returns the list of sep-delimited non-empty strings in s.
func split(s, sep string) (r []string) {
for _, elem := range strings.Split(s, sep) {
elem = strings.TrimSpace(elem)
if elem != "" {
r = append(r, elem)
}
}
return
}