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go/pointer/analysis.go
Alan Donovan d2cdbefbfc go.tools/oracle: add option to output results in JSON syntax.
See json.go for interface specification.

Example usage:
% oracle -format=json -mode=callgraph code.google.com/p/go.tools/cmd/oracle

+ Tests, based on (small) golden files.

Overview:
  Each <query>Result structure has been "lowered" so that all
  but the most trivial logic in each display() function has
  been moved to the main query.

  Each one now has a toJSON method that populates a json.Result
  struct.  Though the <query>Result structs are similar to the
  correponding JSON protocol, they're not close enough to be
  used directly; for example, the former contain richer
  semantic entities (token.Pos, ast.Expr, ssa.Value,
  pointer.Pointer, etc) whereas JSON contains only their
  printed forms using Go basic types.

  The choices of what levels of abstractions the two sets of
  structs should have is somewhat arbitrary.  We may want
  richer information in the JSON output in future.

Details:
- oracle.Main has been split into oracle.Query() and the
  printing of the oracle.Result.
- the display() method no longer needs an *oracle param, only
  a print function.
- callees: sort the result for determinism.
- callees: compute the union across all contexts.
- callers: sort the results for determinism.
- describe(package): fixed a bug in the predicate for method
  accessibility: an unexported method defined in pkg A may
  belong to a type defined in package B (via
  embedding/promotion) and may thus be accessible to A.  New
  accessibleMethods() utility fixes this.
- describe(type): filter methods by accessibility.
- added tests of 'callgraph'.
- pointer: eliminated the 'caller CallGraphNode' parameter from
  pointer.Context.Call callback since it was redundant w.r.t
  site.Caller().
- added warning if CGO_ENABLED is unset.

R=crawshaw
CC=golang-dev
https://golang.org/cl/13270045
2013-09-03 15:29:02 -04:00

260 lines
7.8 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
// This file defines the entry points into the pointer analysis.
import (
"fmt"
"go/token"
"io"
"os"
"code.google.com/p/go.tools/go/types"
"code.google.com/p/go.tools/ssa"
)
// nodeid denotes a node.
// It is an index within analysis.nodes.
// We use small integers, not *node pointers, for many reasons:
// - they are smaller on 64-bit systems.
// - sets of them can be represented compactly in bitvectors or BDDs.
// - order matters; a field offset can be computed by simple addition.
type nodeid uint32
// node.flags bitmask values.
const (
ntObject = 1 << iota // start of an object (addressable memory location)
ntInterface // conctype node of interface object (=> ntObject)
ntFunction // identity node of function object (=> ntObject)
)
// A node is an equivalence class of memory locations.
// Nodes may be pointers, pointed-to locations, neither, or both.
type node struct {
// flags is a bitset of the node type (nt*) flags defined above.
flags uint32
// Number of following words belonging to the same "object" allocation.
// (Set by endObject.) Zero for all other nodes.
size uint32
// The type of the field denoted by this node. Non-aggregate,
// unless this is an iface.conctype node (i.e. the thing
// pointed to by an interface) in which case typ is that type.
typ types.Type
// data holds additional attributes of this node, depending on
// its flags.
//
// If ntObject is set, data is the ssa.Value of the
// instruction that allocated this memory, or nil if it was
// implicit.
//
// Special cases:
// - If ntInterface is also set, data will be a *ssa.MakeInterface.
// - If ntFunction is also set, this node is the first word of a
// function block, and data is a *cgnode (not an ssa.Value)
// representing this function.
data interface{}
// subelement indicates which directly embedded subelement of
// an object of aggregate type (struct, tuple, array) this is.
subelement *fieldInfo // e.g. ".a.b[*].c"
// Points-to sets.
pts nodeset // points-to set of this node
prevPts nodeset // pts(n) in previous iteration (for difference propagation)
// Graph edges
copyTo nodeset // simple copy constraint edges
// Complex constraints attached to this node (x).
// - *loadConstraint y=*x
// - *offsetAddrConstraint y=&x.f or y=&x[0]
// - *storeConstraint *x=z
// - *typeAssertConstraint y=x.(T)
// - *invokeConstraint y=x.f(params...)
complex constraintset
}
type constraint interface {
String() string
// Called by solver to prepare a constraint, e.g. to
// - initialize a points-to set (addrConstraint).
// - attach it to a pointer node (complex constraints).
init(a *analysis)
// solve is called for complex constraints when the pts for
// the node to which they are attached has changed.
solve(a *analysis, n *node, delta nodeset)
}
// dst = &src
// pts(dst) ⊇ {src}
// A base constraint used to initialize the solver's pt sets
type addrConstraint struct {
dst nodeid
src nodeid
}
// dst = src
// A simple constraint represented directly as a copyTo graph edge.
type copyConstraint struct {
dst nodeid
src nodeid
}
// dst = src[offset]
// A complex constraint attached to src (the pointer)
type loadConstraint struct {
offset uint32
dst nodeid
src nodeid
}
// dst[offset] = src
// A complex constraint attached to dst (the pointer)
type storeConstraint struct {
offset uint32
dst nodeid
src nodeid
}
// dst = &src.f or dst = &src[0]
// A complex constraint attached to dst (the pointer)
type offsetAddrConstraint struct {
offset uint32
dst nodeid
src nodeid
}
// dst = src.(typ)
// A complex constraint attached to src (the interface).
type typeAssertConstraint struct {
typ types.Type
dst nodeid
src nodeid
}
// src.method(params...)
// A complex constraint attached to iface.
type invokeConstraint struct {
method *types.Func // the abstract method
iface nodeid // the interface
params nodeid // the first parameter in the params/results block
}
// An analysis instance holds the state of a single pointer analysis problem.
type analysis struct {
config *Config // the client's control/observer interface
prog *ssa.Program // the program being analyzed
log io.Writer // log stream; nil to disable
panicNode nodeid // sink for panic, source for recover
nodes []*node // indexed by nodeid
flattenMemo map[types.Type][]*fieldInfo // memoization of flatten()
constraints []constraint // set of constraints
callsites []*callsite // all callsites
genq []*cgnode // queue of functions to generate constraints for
intrinsics map[*ssa.Function]intrinsic // non-nil values are summaries for intrinsic fns
reflectValueObj types.Object // type symbol for reflect.Value (if present)
reflectRtypeObj types.Object // type symbol for reflect.rtype (if present)
reflectRtype *types.Pointer // *reflect.rtype
funcObj map[*ssa.Function]nodeid // default function object for each func
probes map[*ssa.CallCommon]nodeid // maps call to print() to argument variable
valNode map[ssa.Value]nodeid // node for each ssa.Value
work worklist // solver's worklist
}
func (a *analysis) warnf(pos token.Pos, format string, args ...interface{}) {
if Warn := a.config.Warn; Warn != nil {
Warn(pos, format, args...)
} else {
fmt.Fprintf(os.Stderr, "%s: warning: ", a.prog.Fset.Position(pos))
fmt.Fprintf(os.Stderr, format, args...)
fmt.Fprintln(os.Stderr)
}
}
// Analyze runs the pointer analysis with the scope and options
// specified by config, and returns the (synthetic) root of the callgraph.
//
func Analyze(config *Config) CallGraphNode {
a := &analysis{
config: config,
log: config.Log,
prog: config.prog(),
valNode: make(map[ssa.Value]nodeid),
flattenMemo: make(map[types.Type][]*fieldInfo),
intrinsics: make(map[*ssa.Function]intrinsic),
funcObj: make(map[*ssa.Function]nodeid),
probes: make(map[*ssa.CallCommon]nodeid),
work: makeMapWorklist(),
}
if reflect := a.prog.PackagesByPath["reflect"]; reflect != nil {
a.reflectValueObj = reflect.Object.Scope().Lookup("Value")
a.reflectRtypeObj = reflect.Object.Scope().Lookup("rtype")
a.reflectRtype = types.NewPointer(a.reflectRtypeObj.Type())
}
if false {
a.log = os.Stderr // for debugging crashes; extremely verbose
}
if a.log != nil {
fmt.Fprintln(a.log, "======== NEW ANALYSIS ========")
}
root := a.generate()
// ---------- Presolver ----------
// TODO(adonovan): opt: presolver optimisations.
// ---------- Solver ----------
a.solve()
if a.log != nil {
// Dump solution.
for i, n := range a.nodes {
if n.pts != nil {
fmt.Fprintf(a.log, "pts(n%d) = %s : %s\n", i, n.pts, n.typ)
}
}
}
// Notify the client of the callsites if they're interested.
if CallSite := a.config.CallSite; CallSite != nil {
for _, site := range a.callsites {
CallSite(site)
}
}
Call := a.config.Call
for _, site := range a.callsites {
for nid := range a.nodes[site.targets].pts {
cgn := a.nodes[nid].data.(*cgnode)
// Notify the client of the call graph, if
// they're interested.
if Call != nil {
Call(site, cgn)
}
// Warn about calls to non-intrinsic external functions.
if fn := cgn.fn; fn.Blocks == nil && a.findIntrinsic(fn) == nil {
a.warnf(site.Pos(), "unsound call to unknown intrinsic: %s", fn)
a.warnf(fn.Pos(), " (declared here)")
}
}
}
return root
}