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go/pointer/api.go

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// 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
import (
"fmt"
"go/token"
"io"
"code.google.com/p/go.tools/go/types/typemap"
"code.google.com/p/go.tools/ssa"
)
type Config struct {
// -------- Scope of the analysis --------
// Clients must provide the analysis with at least one package defining a main() function.
Mains []*ssa.Package // set of 'main' packages to analyze
root *ssa.Function // synthetic analysis root
// -------- Optional callbacks invoked by the analysis --------
// Call is invoked for each discovered call-graph edge. The
// call-graph is a multigraph over CallGraphNodes with edges
// labelled by the CallSite that gives rise to the edge.
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 13:29:02 -06:00
// (The caller node is available as site.Caller())
//
// Clients that wish to construct a call graph may provide
// CallGraph.AddEdge here.
//
// The callgraph may be context-sensitive, i.e. it may
// distinguish separate calls to the same function depending
// on the context.
//
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 13:29:02 -06:00
Call func(site CallSite, callee CallGraphNode)
// CallSite is invoked for each call-site encountered in the
// program.
//
// The callgraph may be context-sensitive, i.e. it may
// distinguish separate calls to the same function depending
// on the context.
//
CallSite func(site CallSite)
// Warn is invoked for each warning encountered by the analysis,
// e.g. unknown external function, unsound use of unsafe.Pointer.
// pos may be zero if the position is not known.
Warn func(pos token.Pos, format string, args ...interface{})
// Print is invoked during the analysis for each discovered
// call to the built-in print(x).
//
// Pointer p may be saved until the analysis is complete, at
// which point its methods provide access to the analysis
// (The result of callings its methods within the Print
// callback is undefined.) p is nil if x is non-pointerlike.
//
// TODO(adonovan): this was a stop-gap measure for identifing
// arbitrary expressions of interest in the tests. Now that
// ssa.ValueForExpr exists, we should use that instead.
//
Print func(site *ssa.CallCommon, p Pointer)
// The client populates QueryValues[v] for each ssa.Value v
// of interest.
//
// The boolean (Indirect) indicates whether to compute the
// points-to set for v (false) or *v (true): the latter is
// typically wanted for Values corresponding to source-level
// lvalues, e.g. an *ssa.Global.
//
// The pointer analysis will populate the corresponding
// QueryResults value when it creates the pointer variable
// for v or *v. Upon completion the client can inspect the
// map for the results.
//
// If a Value belongs to a function that the analysis treats
// context-sensitively, the corresponding QueryResults slice
// may have multiple Pointers, one per distinct context. Use
// PointsToCombined to merge them.
//
// TODO(adonovan): refactor the API: separate all results of
// Analyze() into a dedicated Result struct.
//
QueryValues map[ssa.Value]Indirect
QueryResults map[ssa.Value][]Pointer
// -------- Other configuration options --------
// If Log is non-nil, a log messages are written to it.
// Logging is extremely verbose.
Log io.Writer
}
type Indirect bool // map[ssa.Value]Indirect is not a set
func (c *Config) prog() *ssa.Program {
for _, main := range c.Mains {
return main.Prog
}
panic("empty scope")
}
// A Pointer is an equivalence class of pointerlike values.
//
// TODO(adonovan): add a method
// Context() CallGraphNode
// for pointers corresponding to local variables,
//
type Pointer interface {
// PointsTo returns the points-to set of this pointer.
PointsTo() PointsToSet
// MayAlias reports whether the receiver pointer may alias
// the argument pointer.
MayAlias(Pointer) bool
String() string
}
// A PointsToSet is a set of labels (locations or allocations).
//
type PointsToSet interface {
// PointsTo returns the set of labels that this points-to set
// contains.
Labels() []*Label
// Intersects reports whether this points-to set and the
// argument points-to set contain common members.
Intersects(PointsToSet) bool
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 07:49:10 -06:00
// If this PointsToSet came from a Pointer of interface kind
// or a reflect.Value, DynamicTypes returns the set of dynamic
// types that it may contain. (For an interface, they will
// always be concrete types.)
//
// The result is a mapping whose keys are the dynamic types to
// which it may point. For each pointer-like key type, the
// corresponding map value is a set of pointer abstractions of
// that dynamic type, represented as a []Pointer slice. Use
// PointsToCombined to merge them.
//
// The result is empty unless CanHaveDynamicTypes(T).
//
DynamicTypes() *typemap.M
}
// Union returns the set containing all the elements of each set in sets.
func Union(sets ...PointsToSet) PointsToSet {
var union ptset
for _, set := range sets {
set := set.(ptset)
union.a = set.a
union.pts.addAll(set.pts)
}
return union
}
// PointsToCombined returns the combined points-to set of all the
// specified pointers.
func PointsToCombined(ptrs []Pointer) PointsToSet {
var ptsets []PointsToSet
for _, ptr := range ptrs {
ptsets = append(ptsets, ptr.PointsTo())
}
return Union(ptsets...)
}
// ---- PointsToSet public interface
type ptset struct {
a *analysis // may be nil if pts is nil
pts nodeset
}
func (s ptset) Labels() []*Label {
var labels []*Label
for l := range s.pts {
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 07:49:10 -06:00
labels = append(labels, s.a.labelFor(l))
}
return labels
}
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 07:49:10 -06:00
func (s ptset) DynamicTypes() *typemap.M {
var tmap typemap.M
tmap.SetHasher(s.a.hasher)
for ifaceObjId := range s.pts {
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 07:49:10 -06:00
tDyn, v, indirect := s.a.taggedValue(ifaceObjId)
if tDyn == nil {
continue // !CanHaveDynamicTypes(tDyn)
}
if indirect {
panic("indirect tagged object") // implement later
}
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 07:49:10 -06:00
prev, _ := tmap.At(tDyn).([]Pointer)
tmap.Set(tDyn, append(prev, ptr{s.a, v}))
}
return &tmap
}
func (x ptset) Intersects(y_ PointsToSet) bool {
y := y_.(ptset)
for l := range x.pts {
if _, ok := y.pts[l]; ok {
return true
}
}
return false
}
// ---- Pointer public interface
// ptr adapts a node to the Pointer interface.
type ptr struct {
a *analysis
n nodeid // non-zero
}
func (p ptr) String() string {
return fmt.Sprintf("n%d", p.n)
}
func (p ptr) PointsTo() PointsToSet {
return ptset{p.a, p.a.nodes[p.n].pts}
}
func (p ptr) MayAlias(q Pointer) bool {
return p.PointsTo().Intersects(q.PointsTo())
}
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 07:49:10 -06:00
func (p ptr) DynamicTypes() *typemap.M {
return p.PointsTo().DynamicTypes()
}