// 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 implements the generation and resolution rules for // constraints arising from the use of reflection in the target // program. See doc.go for explanation of the representation. // // For consistency, the names of all parameters match those of the // actual functions in the "reflect" package. // // To avoid proliferation of equivalent labels, intrinsics should // memoize as much as possible, like TypeOf and Zero do for their // tagged objects. // // TODO(adonovan): this file is rather subtle. Explain how we derive // the implementation of each reflect operator from its spec, // including the subtleties of reflect.flag{Addr,RO,Indir}. // [Hint: our implementation is as if reflect.flagIndir was always // true, i.e. reflect.Values are pointers to tagged objects, there is // no inline allocation optimization; and indirect tagged objects (not // yet implemented) correspond to reflect.Values with // reflect.flagAddr.] // A picture would help too. // // TODO(adonovan): try factoring up the common parts of the majority of // these constraints that are single input, single output. import ( "fmt" exact "go/constant" "go/types" "reflect" "golang.org/x/tools/go/ssa" ) func init() { for name, fn := range map[string]intrinsic{ // reflect.Value methods. "(reflect.Value).Addr": ext۰reflect۰Value۰Addr, "(reflect.Value).Bool": ext۰NoEffect, "(reflect.Value).Bytes": ext۰reflect۰Value۰Bytes, "(reflect.Value).Call": ext۰reflect۰Value۰Call, "(reflect.Value).CallSlice": ext۰reflect۰Value۰CallSlice, "(reflect.Value).CanAddr": ext۰NoEffect, "(reflect.Value).CanInterface": ext۰NoEffect, "(reflect.Value).CanSet": ext۰NoEffect, "(reflect.Value).Cap": ext۰NoEffect, "(reflect.Value).Close": ext۰NoEffect, "(reflect.Value).Complex": ext۰NoEffect, "(reflect.Value).Convert": ext۰reflect۰Value۰Convert, "(reflect.Value).Elem": ext۰reflect۰Value۰Elem, "(reflect.Value).Field": ext۰reflect۰Value۰Field, "(reflect.Value).FieldByIndex": ext۰reflect۰Value۰FieldByIndex, "(reflect.Value).FieldByName": ext۰reflect۰Value۰FieldByName, "(reflect.Value).FieldByNameFunc": ext۰reflect۰Value۰FieldByNameFunc, "(reflect.Value).Float": ext۰NoEffect, "(reflect.Value).Index": ext۰reflect۰Value۰Index, "(reflect.Value).Int": ext۰NoEffect, "(reflect.Value).Interface": ext۰reflect۰Value۰Interface, "(reflect.Value).InterfaceData": ext۰NoEffect, "(reflect.Value).IsNil": ext۰NoEffect, "(reflect.Value).IsValid": ext۰NoEffect, "(reflect.Value).Kind": ext۰NoEffect, "(reflect.Value).Len": ext۰NoEffect, "(reflect.Value).MapIndex": ext۰reflect۰Value۰MapIndex, "(reflect.Value).MapKeys": ext۰reflect۰Value۰MapKeys, "(reflect.Value).Method": ext۰reflect۰Value۰Method, "(reflect.Value).MethodByName": ext۰reflect۰Value۰MethodByName, "(reflect.Value).NumField": ext۰NoEffect, "(reflect.Value).NumMethod": ext۰NoEffect, "(reflect.Value).OverflowComplex": ext۰NoEffect, "(reflect.Value).OverflowFloat": ext۰NoEffect, "(reflect.Value).OverflowInt": ext۰NoEffect, "(reflect.Value).OverflowUint": ext۰NoEffect, "(reflect.Value).Pointer": ext۰NoEffect, "(reflect.Value).Recv": ext۰reflect۰Value۰Recv, "(reflect.Value).Send": ext۰reflect۰Value۰Send, "(reflect.Value).Set": ext۰reflect۰Value۰Set, "(reflect.Value).SetBool": ext۰NoEffect, "(reflect.Value).SetBytes": ext۰reflect۰Value۰SetBytes, "(reflect.Value).SetComplex": ext۰NoEffect, "(reflect.Value).SetFloat": ext۰NoEffect, "(reflect.Value).SetInt": ext۰NoEffect, "(reflect.Value).SetLen": ext۰NoEffect, "(reflect.Value).SetMapIndex": ext۰reflect۰Value۰SetMapIndex, "(reflect.Value).SetPointer": ext۰reflect۰Value۰SetPointer, "(reflect.Value).SetString": ext۰NoEffect, "(reflect.Value).SetUint": ext۰NoEffect, "(reflect.Value).Slice": ext۰reflect۰Value۰Slice, "(reflect.Value).String": ext۰NoEffect, "(reflect.Value).TryRecv": ext۰reflect۰Value۰Recv, "(reflect.Value).TrySend": ext۰reflect۰Value۰Send, "(reflect.Value).Type": ext۰NoEffect, "(reflect.Value).Uint": ext۰NoEffect, "(reflect.Value).UnsafeAddr": ext۰NoEffect, // Standalone reflect.* functions. "reflect.Append": ext۰reflect۰Append, "reflect.AppendSlice": ext۰reflect۰AppendSlice, "reflect.Copy": ext۰reflect۰Copy, "reflect.ChanOf": ext۰reflect۰ChanOf, "reflect.DeepEqual": ext۰NoEffect, "reflect.Indirect": ext۰reflect۰Indirect, "reflect.MakeChan": ext۰reflect۰MakeChan, "reflect.MakeFunc": ext۰reflect۰MakeFunc, "reflect.MakeMap": ext۰reflect۰MakeMap, "reflect.MakeSlice": ext۰reflect۰MakeSlice, "reflect.MapOf": ext۰reflect۰MapOf, "reflect.New": ext۰reflect۰New, "reflect.NewAt": ext۰reflect۰NewAt, "reflect.PtrTo": ext۰reflect۰PtrTo, "reflect.Select": ext۰reflect۰Select, "reflect.SliceOf": ext۰reflect۰SliceOf, "reflect.TypeOf": ext۰reflect۰TypeOf, "reflect.ValueOf": ext۰reflect۰ValueOf, "reflect.Zero": ext۰reflect۰Zero, "reflect.init": ext۰NoEffect, // *reflect.rtype methods "(*reflect.rtype).Align": ext۰NoEffect, "(*reflect.rtype).AssignableTo": ext۰NoEffect, "(*reflect.rtype).Bits": ext۰NoEffect, "(*reflect.rtype).ChanDir": ext۰NoEffect, "(*reflect.rtype).ConvertibleTo": ext۰NoEffect, "(*reflect.rtype).Elem": ext۰reflect۰rtype۰Elem, "(*reflect.rtype).Field": ext۰reflect۰rtype۰Field, "(*reflect.rtype).FieldAlign": ext۰NoEffect, "(*reflect.rtype).FieldByIndex": ext۰reflect۰rtype۰FieldByIndex, "(*reflect.rtype).FieldByName": ext۰reflect۰rtype۰FieldByName, "(*reflect.rtype).FieldByNameFunc": ext۰reflect۰rtype۰FieldByNameFunc, "(*reflect.rtype).Implements": ext۰NoEffect, "(*reflect.rtype).In": ext۰reflect۰rtype۰In, "(*reflect.rtype).IsVariadic": ext۰NoEffect, "(*reflect.rtype).Key": ext۰reflect۰rtype۰Key, "(*reflect.rtype).Kind": ext۰NoEffect, "(*reflect.rtype).Len": ext۰NoEffect, "(*reflect.rtype).Method": ext۰reflect۰rtype۰Method, "(*reflect.rtype).MethodByName": ext۰reflect۰rtype۰MethodByName, "(*reflect.rtype).Name": ext۰NoEffect, "(*reflect.rtype).NumField": ext۰NoEffect, "(*reflect.rtype).NumIn": ext۰NoEffect, "(*reflect.rtype).NumMethod": ext۰NoEffect, "(*reflect.rtype).NumOut": ext۰NoEffect, "(*reflect.rtype).Out": ext۰reflect۰rtype۰Out, "(*reflect.rtype).PkgPath": ext۰NoEffect, "(*reflect.rtype).Size": ext۰NoEffect, "(*reflect.rtype).String": ext۰NoEffect, } { intrinsicsByName[name] = fn } } // -------------------- (reflect.Value) -------------------- func ext۰reflect۰Value۰Addr(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (Value).Bytes() Value ---------- // result = v.Bytes() type rVBytesConstraint struct { v nodeid // (ptr) result nodeid // (indirect) } func (c *rVBytesConstraint) ptr() nodeid { return c.v } func (c *rVBytesConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVBytes.result") } func (c *rVBytesConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVBytesConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Bytes()", c.result, c.v) } func (c *rVBytesConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, slice, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } tSlice, ok := tDyn.Underlying().(*types.Slice) if ok && types.Identical(tSlice.Elem(), types.Typ[types.Uint8]) { if a.onlineCopy(c.result, slice) { changed = true } } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰Bytes(a *analysis, cgn *cgnode) { a.addConstraint(&rVBytesConstraint{ v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (Value).Call(in []Value) []Value ---------- // result = v.Call(in) type rVCallConstraint struct { cgn *cgnode targets nodeid // (indirect) v nodeid // (ptr) arg nodeid // = in[*] result nodeid // (indirect) dotdotdot bool // interpret last arg as a "..." slice } func (c *rVCallConstraint) ptr() nodeid { return c.v } func (c *rVCallConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.targets), "rVCall.targets") h.markIndirect(onodeid(c.result), "rVCall.result") } func (c *rVCallConstraint) renumber(mapping []nodeid) { c.targets = mapping[c.targets] c.v = mapping[c.v] c.arg = mapping[c.arg] c.result = mapping[c.result] } func (c *rVCallConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Call(n%d)", c.result, c.v, c.arg) } func (c *rVCallConstraint) solve(a *analysis, delta *nodeset) { if c.targets == 0 { panic("no targets") } changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, fn, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } tSig, ok := tDyn.Underlying().(*types.Signature) if !ok { continue // not a function } if tSig.Recv() != nil { panic(tSig) // TODO(adonovan): rethink when we implement Method() } // Add dynamic call target. if a.onlineCopy(c.targets, fn) { a.addWork(c.targets) // TODO(adonovan): is 'else continue' a sound optimisation here? } // Allocate a P/R block. tParams := tSig.Params() tResults := tSig.Results() params := a.addNodes(tParams, "rVCall.params") results := a.addNodes(tResults, "rVCall.results") // Make a dynamic call to 'fn'. a.store(fn, params, 1, a.sizeof(tParams)) a.load(results, fn, 1+a.sizeof(tParams), a.sizeof(tResults)) // Populate P by type-asserting each actual arg (all merged in c.arg). for i, n := 0, tParams.Len(); i < n; i++ { T := tParams.At(i).Type() a.typeAssert(T, params, c.arg, false) params += nodeid(a.sizeof(T)) } // Use R by tagging and copying each actual result to c.result. for i, n := 0, tResults.Len(); i < n; i++ { T := tResults.At(i).Type() // Convert from an arbitrary type to a reflect.Value // (like MakeInterface followed by reflect.ValueOf). if isInterface(T) { // (don't tag) if a.onlineCopy(c.result, results) { changed = true } } else { obj := a.makeTagged(T, c.cgn, nil) a.onlineCopyN(obj+1, results, a.sizeof(T)) if a.addLabel(c.result, obj) { // (true) changed = true } } results += nodeid(a.sizeof(T)) } } if changed { a.addWork(c.result) } } // Common code for direct (inlined) and indirect calls to (reflect.Value).Call. func reflectCallImpl(a *analysis, cgn *cgnode, site *callsite, recv, arg nodeid, dotdotdot bool) nodeid { // Allocate []reflect.Value array for the result. ret := a.nextNode() a.addNodes(types.NewArray(a.reflectValueObj.Type(), 1), "rVCall.ret") a.endObject(ret, cgn, nil) // pts(targets) will be the set of possible call targets. site.targets = a.addOneNode(tInvalid, "rvCall.targets", nil) // All arguments are merged since they arrive in a slice. argelts := a.addOneNode(a.reflectValueObj.Type(), "rVCall.args", nil) a.load(argelts, arg, 1, 1) // slice elements a.addConstraint(&rVCallConstraint{ cgn: cgn, targets: site.targets, v: recv, arg: argelts, result: ret + 1, // results go into elements of ret dotdotdot: dotdotdot, }) return ret } func reflectCall(a *analysis, cgn *cgnode, dotdotdot bool) { // This is the shared contour implementation of (reflect.Value).Call // and CallSlice, as used by indirect calls (rare). // Direct calls are inlined in gen.go, eliding the // intermediate cgnode for Call. site := new(callsite) cgn.sites = append(cgn.sites, site) recv := a.funcParams(cgn.obj) arg := recv + 1 ret := reflectCallImpl(a, cgn, site, recv, arg, dotdotdot) a.addressOf(cgn.fn.Signature.Results().At(0).Type(), a.funcResults(cgn.obj), ret) } func ext۰reflect۰Value۰Call(a *analysis, cgn *cgnode) { reflectCall(a, cgn, false) } func ext۰reflect۰Value۰CallSlice(a *analysis, cgn *cgnode) { // TODO(adonovan): implement. Also, inline direct calls in gen.go too. if false { reflectCall(a, cgn, true) } } func ext۰reflect۰Value۰Convert(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (Value).Elem() Value ---------- // result = v.Elem() type rVElemConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *rVElemConstraint) ptr() nodeid { return c.v } func (c *rVElemConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVElem.result") } func (c *rVElemConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVElemConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Elem()", c.result, c.v) } func (c *rVElemConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, payload, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } switch t := tDyn.Underlying().(type) { case *types.Interface: if a.onlineCopy(c.result, payload) { changed = true } case *types.Pointer: obj := a.makeTagged(t.Elem(), c.cgn, nil) a.load(obj+1, payload, 0, a.sizeof(t.Elem())) if a.addLabel(c.result, obj) { changed = true } } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰Elem(a *analysis, cgn *cgnode) { a.addConstraint(&rVElemConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰Value۰Field(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰Value۰FieldByIndex(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰Value۰FieldByName(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰Value۰FieldByNameFunc(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (Value).Index() Value ---------- // result = v.Index() type rVIndexConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *rVIndexConstraint) ptr() nodeid { return c.v } func (c *rVIndexConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVIndex.result") } func (c *rVIndexConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVIndexConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Index()", c.result, c.v) } func (c *rVIndexConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, payload, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } var res nodeid switch t := tDyn.Underlying().(type) { case *types.Array: res = a.makeTagged(t.Elem(), c.cgn, nil) a.onlineCopyN(res+1, payload+1, a.sizeof(t.Elem())) case *types.Slice: res = a.makeTagged(t.Elem(), c.cgn, nil) a.load(res+1, payload, 1, a.sizeof(t.Elem())) case *types.Basic: if t.Kind() == types.String { res = a.makeTagged(types.Typ[types.Rune], c.cgn, nil) } } if res != 0 && a.addLabel(c.result, res) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰Index(a *analysis, cgn *cgnode) { a.addConstraint(&rVIndexConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (Value).Interface() Value ---------- // result = v.Interface() type rVInterfaceConstraint struct { v nodeid // (ptr) result nodeid // (indirect) } func (c *rVInterfaceConstraint) ptr() nodeid { return c.v } func (c *rVInterfaceConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVInterface.result") } func (c *rVInterfaceConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVInterfaceConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Interface()", c.result, c.v) } func (c *rVInterfaceConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, payload, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } if isInterface(tDyn) { if a.onlineCopy(c.result, payload) { a.addWork(c.result) } } else { if a.addLabel(c.result, vObj) { changed = true } } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰Interface(a *analysis, cgn *cgnode) { a.addConstraint(&rVInterfaceConstraint{ v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (Value).MapIndex(Value) Value ---------- // result = v.MapIndex(_) type rVMapIndexConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *rVMapIndexConstraint) ptr() nodeid { return c.v } func (c *rVMapIndexConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVMapIndex.result") } func (c *rVMapIndexConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVMapIndexConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.MapIndex(_)", c.result, c.v) } func (c *rVMapIndexConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, m, indirect := a.taggedValue(vObj) tMap, _ := tDyn.Underlying().(*types.Map) if tMap == nil { continue // not a map } if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } obj := a.makeTagged(tMap.Elem(), c.cgn, nil) a.load(obj+1, m, a.sizeof(tMap.Key()), a.sizeof(tMap.Elem())) if a.addLabel(c.result, obj) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰MapIndex(a *analysis, cgn *cgnode) { a.addConstraint(&rVMapIndexConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (Value).MapKeys() []Value ---------- // result = v.MapKeys() type rVMapKeysConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *rVMapKeysConstraint) ptr() nodeid { return c.v } func (c *rVMapKeysConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVMapKeys.result") } func (c *rVMapKeysConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVMapKeysConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.MapKeys()", c.result, c.v) } func (c *rVMapKeysConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, m, indirect := a.taggedValue(vObj) tMap, _ := tDyn.Underlying().(*types.Map) if tMap == nil { continue // not a map } if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } kObj := a.makeTagged(tMap.Key(), c.cgn, nil) a.load(kObj+1, m, 0, a.sizeof(tMap.Key())) if a.addLabel(c.result, kObj) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰MapKeys(a *analysis, cgn *cgnode) { // Allocate an array for the result. obj := a.nextNode() T := types.NewSlice(a.reflectValueObj.Type()) a.addNodes(sliceToArray(T), "reflect.MapKeys result") a.endObject(obj, cgn, nil) a.addressOf(T, a.funcResults(cgn.obj), obj) a.addConstraint(&rVMapKeysConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: obj + 1, // result is stored in array elems }) } func ext۰reflect۰Value۰Method(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰Value۰MethodByName(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (Value).Recv(Value) Value ---------- // result, _ = v.Recv() type rVRecvConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *rVRecvConstraint) ptr() nodeid { return c.v } func (c *rVRecvConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVRecv.result") } func (c *rVRecvConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVRecvConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Recv()", c.result, c.v) } func (c *rVRecvConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, ch, indirect := a.taggedValue(vObj) tChan, _ := tDyn.Underlying().(*types.Chan) if tChan == nil { continue // not a channel } if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } tElem := tChan.Elem() elemObj := a.makeTagged(tElem, c.cgn, nil) a.load(elemObj+1, ch, 0, a.sizeof(tElem)) if a.addLabel(c.result, elemObj) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰Recv(a *analysis, cgn *cgnode) { a.addConstraint(&rVRecvConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (Value).Send(Value) ---------- // v.Send(x) type rVSendConstraint struct { cgn *cgnode v nodeid // (ptr) x nodeid } func (c *rVSendConstraint) ptr() nodeid { return c.v } func (c *rVSendConstraint) presolve(*hvn) {} func (c *rVSendConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.x = mapping[c.x] } func (c *rVSendConstraint) String() string { return fmt.Sprintf("reflect n%d.Send(n%d)", c.v, c.x) } func (c *rVSendConstraint) solve(a *analysis, delta *nodeset) { for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, ch, indirect := a.taggedValue(vObj) tChan, _ := tDyn.Underlying().(*types.Chan) if tChan == nil { continue // not a channel } if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } // Extract x's payload to xtmp, then store to channel. tElem := tChan.Elem() xtmp := a.addNodes(tElem, "Send.xtmp") a.typeAssert(tElem, xtmp, c.x, false) a.store(ch, xtmp, 0, a.sizeof(tElem)) } } func ext۰reflect۰Value۰Send(a *analysis, cgn *cgnode) { params := a.funcParams(cgn.obj) a.addConstraint(&rVSendConstraint{ cgn: cgn, v: params, x: params + 1, }) } func ext۰reflect۰Value۰Set(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (Value).SetBytes(x []byte) ---------- // v.SetBytes(x) type rVSetBytesConstraint struct { cgn *cgnode v nodeid // (ptr) x nodeid } func (c *rVSetBytesConstraint) ptr() nodeid { return c.v } func (c *rVSetBytesConstraint) presolve(*hvn) {} func (c *rVSetBytesConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.x = mapping[c.x] } func (c *rVSetBytesConstraint) String() string { return fmt.Sprintf("reflect n%d.SetBytes(n%d)", c.v, c.x) } func (c *rVSetBytesConstraint) solve(a *analysis, delta *nodeset) { for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, slice, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } tSlice, ok := tDyn.Underlying().(*types.Slice) if ok && types.Identical(tSlice.Elem(), types.Typ[types.Uint8]) { if a.onlineCopy(slice, c.x) { a.addWork(slice) } } } } func ext۰reflect۰Value۰SetBytes(a *analysis, cgn *cgnode) { params := a.funcParams(cgn.obj) a.addConstraint(&rVSetBytesConstraint{ cgn: cgn, v: params, x: params + 1, }) } // ---------- func (Value).SetMapIndex(k Value, v Value) ---------- // v.SetMapIndex(key, val) type rVSetMapIndexConstraint struct { cgn *cgnode v nodeid // (ptr) key nodeid val nodeid } func (c *rVSetMapIndexConstraint) ptr() nodeid { return c.v } func (c *rVSetMapIndexConstraint) presolve(*hvn) {} func (c *rVSetMapIndexConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.key = mapping[c.key] c.val = mapping[c.val] } func (c *rVSetMapIndexConstraint) String() string { return fmt.Sprintf("reflect n%d.SetMapIndex(n%d, n%d)", c.v, c.key, c.val) } func (c *rVSetMapIndexConstraint) solve(a *analysis, delta *nodeset) { for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, m, indirect := a.taggedValue(vObj) tMap, _ := tDyn.Underlying().(*types.Map) if tMap == nil { continue // not a map } if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } keysize := a.sizeof(tMap.Key()) // Extract key's payload to keytmp, then store to map key. keytmp := a.addNodes(tMap.Key(), "SetMapIndex.keytmp") a.typeAssert(tMap.Key(), keytmp, c.key, false) a.store(m, keytmp, 0, keysize) // Extract val's payload to vtmp, then store to map value. valtmp := a.addNodes(tMap.Elem(), "SetMapIndex.valtmp") a.typeAssert(tMap.Elem(), valtmp, c.val, false) a.store(m, valtmp, keysize, a.sizeof(tMap.Elem())) } } func ext۰reflect۰Value۰SetMapIndex(a *analysis, cgn *cgnode) { params := a.funcParams(cgn.obj) a.addConstraint(&rVSetMapIndexConstraint{ cgn: cgn, v: params, key: params + 1, val: params + 2, }) } func ext۰reflect۰Value۰SetPointer(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (Value).Slice(v Value, i, j int) Value ---------- // result = v.Slice(_, _) type rVSliceConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *rVSliceConstraint) ptr() nodeid { return c.v } func (c *rVSliceConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rVSlice.result") } func (c *rVSliceConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *rVSliceConstraint) String() string { return fmt.Sprintf("n%d = reflect n%d.Slice(_, _)", c.result, c.v) } func (c *rVSliceConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, payload, indirect := a.taggedValue(vObj) if indirect { // TODO(adonovan): we'll need to implement this // when we start creating indirect tagged objects. panic("indirect tagged object") } var res nodeid switch t := tDyn.Underlying().(type) { case *types.Pointer: if tArr, ok := t.Elem().Underlying().(*types.Array); ok { // pointer to array res = a.makeTagged(types.NewSlice(tArr.Elem()), c.cgn, nil) if a.onlineCopy(res+1, payload) { a.addWork(res + 1) } } case *types.Array: // TODO(adonovan): implement addressable // arrays when we do indirect tagged objects. case *types.Slice: res = vObj case *types.Basic: if t == types.Typ[types.String] { res = vObj } } if res != 0 && a.addLabel(c.result, res) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Value۰Slice(a *analysis, cgn *cgnode) { a.addConstraint(&rVSliceConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // -------------------- Standalone reflect functions -------------------- func ext۰reflect۰Append(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰AppendSlice(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰Copy(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func ChanOf(ChanDir, Type) Type ---------- // result = ChanOf(dir, t) type reflectChanOfConstraint struct { cgn *cgnode t nodeid // (ptr) result nodeid // (indirect) dirs []types.ChanDir } func (c *reflectChanOfConstraint) ptr() nodeid { return c.t } func (c *reflectChanOfConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectChanOf.result") } func (c *reflectChanOfConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *reflectChanOfConstraint) String() string { return fmt.Sprintf("n%d = reflect.ChanOf(n%d)", c.result, c.t) } func (c *reflectChanOfConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.rtypeTaggedValue(tObj) if typeTooHigh(T) { continue } for _, dir := range c.dirs { if a.addLabel(c.result, a.makeRtype(types.NewChan(dir, T))) { changed = true } } } if changed { a.addWork(c.result) } } // dirMap maps reflect.ChanDir to the set of channel types generated by ChanOf. var dirMap = [...][]types.ChanDir{ 0: {types.SendOnly, types.RecvOnly, types.SendRecv}, // unknown reflect.RecvDir: {types.RecvOnly}, reflect.SendDir: {types.SendOnly}, reflect.BothDir: {types.SendRecv}, } func ext۰reflect۰ChanOf(a *analysis, cgn *cgnode) { // If we have access to the callsite, // and the channel argument is a constant (as is usual), // only generate the requested direction. var dir reflect.ChanDir // unknown if site := cgn.callersite; site != nil { if c, ok := site.instr.Common().Args[0].(*ssa.Const); ok { v, _ := exact.Int64Val(c.Value) if 0 <= v && v <= int64(reflect.BothDir) { dir = reflect.ChanDir(v) } } } params := a.funcParams(cgn.obj) a.addConstraint(&reflectChanOfConstraint{ cgn: cgn, t: params + 1, result: a.funcResults(cgn.obj), dirs: dirMap[dir], }) } // ---------- func Indirect(v Value) Value ---------- // result = Indirect(v) type reflectIndirectConstraint struct { cgn *cgnode v nodeid // (ptr) result nodeid // (indirect) } func (c *reflectIndirectConstraint) ptr() nodeid { return c.v } func (c *reflectIndirectConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectIndirect.result") } func (c *reflectIndirectConstraint) renumber(mapping []nodeid) { c.v = mapping[c.v] c.result = mapping[c.result] } func (c *reflectIndirectConstraint) String() string { return fmt.Sprintf("n%d = reflect.Indirect(n%d)", c.result, c.v) } func (c *reflectIndirectConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { vObj := nodeid(x) tDyn, _, _ := a.taggedValue(vObj) var res nodeid if tPtr, ok := tDyn.Underlying().(*types.Pointer); ok { // load the payload of the pointer's tagged object // into a new tagged object res = a.makeTagged(tPtr.Elem(), c.cgn, nil) a.load(res+1, vObj+1, 0, a.sizeof(tPtr.Elem())) } else { res = vObj } if a.addLabel(c.result, res) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Indirect(a *analysis, cgn *cgnode) { a.addConstraint(&reflectIndirectConstraint{ cgn: cgn, v: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func MakeChan(Type) Value ---------- // result = MakeChan(typ) type reflectMakeChanConstraint struct { cgn *cgnode typ nodeid // (ptr) result nodeid // (indirect) } func (c *reflectMakeChanConstraint) ptr() nodeid { return c.typ } func (c *reflectMakeChanConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectMakeChan.result") } func (c *reflectMakeChanConstraint) renumber(mapping []nodeid) { c.typ = mapping[c.typ] c.result = mapping[c.result] } func (c *reflectMakeChanConstraint) String() string { return fmt.Sprintf("n%d = reflect.MakeChan(n%d)", c.result, c.typ) } func (c *reflectMakeChanConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { typObj := nodeid(x) T := a.rtypeTaggedValue(typObj) tChan, ok := T.Underlying().(*types.Chan) if !ok || tChan.Dir() != types.SendRecv { continue // not a bidirectional channel type } obj := a.nextNode() a.addNodes(tChan.Elem(), "reflect.MakeChan.value") a.endObject(obj, c.cgn, nil) // put its address in a new T-tagged object id := a.makeTagged(T, c.cgn, nil) a.addLabel(id+1, obj) // flow the T-tagged object to the result if a.addLabel(c.result, id) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰MakeChan(a *analysis, cgn *cgnode) { a.addConstraint(&reflectMakeChanConstraint{ cgn: cgn, typ: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰MakeFunc(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func MakeMap(Type) Value ---------- // result = MakeMap(typ) type reflectMakeMapConstraint struct { cgn *cgnode typ nodeid // (ptr) result nodeid // (indirect) } func (c *reflectMakeMapConstraint) ptr() nodeid { return c.typ } func (c *reflectMakeMapConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectMakeMap.result") } func (c *reflectMakeMapConstraint) renumber(mapping []nodeid) { c.typ = mapping[c.typ] c.result = mapping[c.result] } func (c *reflectMakeMapConstraint) String() string { return fmt.Sprintf("n%d = reflect.MakeMap(n%d)", c.result, c.typ) } func (c *reflectMakeMapConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { typObj := nodeid(x) T := a.rtypeTaggedValue(typObj) tMap, ok := T.Underlying().(*types.Map) if !ok { continue // not a map type } mapObj := a.nextNode() a.addNodes(tMap.Key(), "reflect.MakeMap.key") a.addNodes(tMap.Elem(), "reflect.MakeMap.value") a.endObject(mapObj, c.cgn, nil) // put its address in a new T-tagged object id := a.makeTagged(T, c.cgn, nil) a.addLabel(id+1, mapObj) // flow the T-tagged object to the result if a.addLabel(c.result, id) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰MakeMap(a *analysis, cgn *cgnode) { a.addConstraint(&reflectMakeMapConstraint{ cgn: cgn, typ: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func MakeSlice(Type) Value ---------- // result = MakeSlice(typ) type reflectMakeSliceConstraint struct { cgn *cgnode typ nodeid // (ptr) result nodeid // (indirect) } func (c *reflectMakeSliceConstraint) ptr() nodeid { return c.typ } func (c *reflectMakeSliceConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectMakeSlice.result") } func (c *reflectMakeSliceConstraint) renumber(mapping []nodeid) { c.typ = mapping[c.typ] c.result = mapping[c.result] } func (c *reflectMakeSliceConstraint) String() string { return fmt.Sprintf("n%d = reflect.MakeSlice(n%d)", c.result, c.typ) } func (c *reflectMakeSliceConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { typObj := nodeid(x) T := a.rtypeTaggedValue(typObj) if _, ok := T.Underlying().(*types.Slice); !ok { continue // not a slice type } obj := a.nextNode() a.addNodes(sliceToArray(T), "reflect.MakeSlice") a.endObject(obj, c.cgn, nil) // put its address in a new T-tagged object id := a.makeTagged(T, c.cgn, nil) a.addLabel(id+1, obj) // flow the T-tagged object to the result if a.addLabel(c.result, id) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰MakeSlice(a *analysis, cgn *cgnode) { a.addConstraint(&reflectMakeSliceConstraint{ cgn: cgn, typ: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰MapOf(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func New(Type) Value ---------- // result = New(typ) type reflectNewConstraint struct { cgn *cgnode typ nodeid // (ptr) result nodeid // (indirect) } func (c *reflectNewConstraint) ptr() nodeid { return c.typ } func (c *reflectNewConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectNew.result") } func (c *reflectNewConstraint) renumber(mapping []nodeid) { c.typ = mapping[c.typ] c.result = mapping[c.result] } func (c *reflectNewConstraint) String() string { return fmt.Sprintf("n%d = reflect.New(n%d)", c.result, c.typ) } func (c *reflectNewConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { typObj := nodeid(x) T := a.rtypeTaggedValue(typObj) // allocate new T object newObj := a.nextNode() a.addNodes(T, "reflect.New") a.endObject(newObj, c.cgn, nil) // put its address in a new *T-tagged object id := a.makeTagged(types.NewPointer(T), c.cgn, nil) a.addLabel(id+1, newObj) // flow the pointer to the result if a.addLabel(c.result, id) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰New(a *analysis, cgn *cgnode) { a.addConstraint(&reflectNewConstraint{ cgn: cgn, typ: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰NewAt(a *analysis, cgn *cgnode) { ext۰reflect۰New(a, cgn) // TODO(adonovan): also report dynamic calls to unsound intrinsics. if site := cgn.callersite; site != nil { a.warnf(site.pos(), "unsound: %s contains a reflect.NewAt() call", site.instr.Parent()) } } // ---------- func PtrTo(Type) Type ---------- // result = PtrTo(t) type reflectPtrToConstraint struct { cgn *cgnode t nodeid // (ptr) result nodeid // (indirect) } func (c *reflectPtrToConstraint) ptr() nodeid { return c.t } func (c *reflectPtrToConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectPtrTo.result") } func (c *reflectPtrToConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *reflectPtrToConstraint) String() string { return fmt.Sprintf("n%d = reflect.PtrTo(n%d)", c.result, c.t) } func (c *reflectPtrToConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.rtypeTaggedValue(tObj) if typeTooHigh(T) { continue } if a.addLabel(c.result, a.makeRtype(types.NewPointer(T))) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰PtrTo(a *analysis, cgn *cgnode) { a.addConstraint(&reflectPtrToConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰Select(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func SliceOf(Type) Type ---------- // result = SliceOf(t) type reflectSliceOfConstraint struct { cgn *cgnode t nodeid // (ptr) result nodeid // (indirect) } func (c *reflectSliceOfConstraint) ptr() nodeid { return c.t } func (c *reflectSliceOfConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectSliceOf.result") } func (c *reflectSliceOfConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *reflectSliceOfConstraint) String() string { return fmt.Sprintf("n%d = reflect.SliceOf(n%d)", c.result, c.t) } func (c *reflectSliceOfConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.rtypeTaggedValue(tObj) if typeTooHigh(T) { continue } if a.addLabel(c.result, a.makeRtype(types.NewSlice(T))) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰SliceOf(a *analysis, cgn *cgnode) { a.addConstraint(&reflectSliceOfConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func TypeOf(v Value) Type ---------- // result = TypeOf(i) type reflectTypeOfConstraint struct { cgn *cgnode i nodeid // (ptr) result nodeid // (indirect) } func (c *reflectTypeOfConstraint) ptr() nodeid { return c.i } func (c *reflectTypeOfConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectTypeOf.result") } func (c *reflectTypeOfConstraint) renumber(mapping []nodeid) { c.i = mapping[c.i] c.result = mapping[c.result] } func (c *reflectTypeOfConstraint) String() string { return fmt.Sprintf("n%d = reflect.TypeOf(n%d)", c.result, c.i) } func (c *reflectTypeOfConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { iObj := nodeid(x) tDyn, _, _ := a.taggedValue(iObj) if a.addLabel(c.result, a.makeRtype(tDyn)) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰TypeOf(a *analysis, cgn *cgnode) { a.addConstraint(&reflectTypeOfConstraint{ cgn: cgn, i: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func ValueOf(interface{}) Value ---------- func ext۰reflect۰ValueOf(a *analysis, cgn *cgnode) { // TODO(adonovan): when we start creating indirect tagged // objects, we'll need to handle them specially here since // they must never appear in the PTS of an interface{}. a.copy(a.funcResults(cgn.obj), a.funcParams(cgn.obj), 1) } // ---------- func Zero(Type) Value ---------- // result = Zero(typ) type reflectZeroConstraint struct { cgn *cgnode typ nodeid // (ptr) result nodeid // (indirect) } func (c *reflectZeroConstraint) ptr() nodeid { return c.typ } func (c *reflectZeroConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "reflectZero.result") } func (c *reflectZeroConstraint) renumber(mapping []nodeid) { c.typ = mapping[c.typ] c.result = mapping[c.result] } func (c *reflectZeroConstraint) String() string { return fmt.Sprintf("n%d = reflect.Zero(n%d)", c.result, c.typ) } func (c *reflectZeroConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { typObj := nodeid(x) T := a.rtypeTaggedValue(typObj) // TODO(adonovan): if T is an interface type, we need // to create an indirect tagged object containing // new(T). To avoid updates of such shared values, // we'll need another flag on indirect tagged objects // that marks whether they are addressable or // readonly, just like the reflect package does. // memoize using a.reflectZeros[T] var id nodeid if z := a.reflectZeros.At(T); false && z != nil { id = z.(nodeid) } else { id = a.makeTagged(T, c.cgn, nil) a.reflectZeros.Set(T, id) } if a.addLabel(c.result, id) { changed = true } } if changed { a.addWork(c.result) } } func ext۰reflect۰Zero(a *analysis, cgn *cgnode) { a.addConstraint(&reflectZeroConstraint{ cgn: cgn, typ: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // -------------------- (*reflect.rtype) methods -------------------- // ---------- func (*rtype) Elem() Type ---------- // result = Elem(t) type rtypeElemConstraint struct { cgn *cgnode t nodeid // (ptr) result nodeid // (indirect) } func (c *rtypeElemConstraint) ptr() nodeid { return c.t } func (c *rtypeElemConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rtypeElem.result") } func (c *rtypeElemConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *rtypeElemConstraint) String() string { return fmt.Sprintf("n%d = (*reflect.rtype).Elem(n%d)", c.result, c.t) } func (c *rtypeElemConstraint) solve(a *analysis, delta *nodeset) { // Implemented by *types.{Map,Chan,Array,Slice,Pointer}. type hasElem interface { Elem() types.Type } changed := false for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.nodes[tObj].obj.data.(types.Type) if tHasElem, ok := T.Underlying().(hasElem); ok { if a.addLabel(c.result, a.makeRtype(tHasElem.Elem())) { changed = true } } } if changed { a.addWork(c.result) } } func ext۰reflect۰rtype۰Elem(a *analysis, cgn *cgnode) { a.addConstraint(&rtypeElemConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (*rtype) Field(int) StructField ---------- // ---------- func (*rtype) FieldByName(string) (StructField, bool) ---------- // result = FieldByName(t, name) // result = Field(t, _) type rtypeFieldByNameConstraint struct { cgn *cgnode name string // name of field; "" for unknown t nodeid // (ptr) result nodeid // (indirect) } func (c *rtypeFieldByNameConstraint) ptr() nodeid { return c.t } func (c *rtypeFieldByNameConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result+3), "rtypeFieldByName.result.Type") } func (c *rtypeFieldByNameConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *rtypeFieldByNameConstraint) String() string { return fmt.Sprintf("n%d = (*reflect.rtype).FieldByName(n%d, %q)", c.result, c.t, c.name) } func (c *rtypeFieldByNameConstraint) solve(a *analysis, delta *nodeset) { // type StructField struct { // 0 __identity__ // 1 Name string // 2 PkgPath string // 3 Type Type // 4 Tag StructTag // 5 Offset uintptr // 6 Index []int // 7 Anonymous bool // } for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.nodes[tObj].obj.data.(types.Type) tStruct, ok := T.Underlying().(*types.Struct) if !ok { continue // not a struct type } n := tStruct.NumFields() for i := 0; i < n; i++ { f := tStruct.Field(i) if c.name == "" || c.name == f.Name() { // a.offsetOf(Type) is 3. if id := c.result + 3; a.addLabel(id, a.makeRtype(f.Type())) { a.addWork(id) } // TODO(adonovan): StructField.Index should be non-nil. } } } } func ext۰reflect۰rtype۰FieldByName(a *analysis, cgn *cgnode) { // If we have access to the callsite, // and the argument is a string constant, // return only that field. var name string if site := cgn.callersite; site != nil { if c, ok := site.instr.Common().Args[0].(*ssa.Const); ok { name = exact.StringVal(c.Value) } } a.addConstraint(&rtypeFieldByNameConstraint{ cgn: cgn, name: name, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰rtype۰Field(a *analysis, cgn *cgnode) { // No-one ever calls Field with a constant argument, // so we don't specialize that case. a.addConstraint(&rtypeFieldByNameConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰rtype۰FieldByIndex(a *analysis, cgn *cgnode) {} // TODO(adonovan) func ext۰reflect۰rtype۰FieldByNameFunc(a *analysis, cgn *cgnode) {} // TODO(adonovan) // ---------- func (*rtype) In/Out(i int) Type ---------- // result = In/Out(t, i) type rtypeInOutConstraint struct { cgn *cgnode t nodeid // (ptr) result nodeid // (indirect) out bool i int // -ve if not a constant } func (c *rtypeInOutConstraint) ptr() nodeid { return c.t } func (c *rtypeInOutConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rtypeInOut.result") } func (c *rtypeInOutConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *rtypeInOutConstraint) String() string { return fmt.Sprintf("n%d = (*reflect.rtype).InOut(n%d, %d)", c.result, c.t, c.i) } func (c *rtypeInOutConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.nodes[tObj].obj.data.(types.Type) sig, ok := T.Underlying().(*types.Signature) if !ok { continue // not a func type } tuple := sig.Params() if c.out { tuple = sig.Results() } for i, n := 0, tuple.Len(); i < n; i++ { if c.i < 0 || c.i == i { if a.addLabel(c.result, a.makeRtype(tuple.At(i).Type())) { changed = true } } } } if changed { a.addWork(c.result) } } func ext۰reflect۰rtype۰InOut(a *analysis, cgn *cgnode, out bool) { // If we have access to the callsite, // and the argument is an int constant, // return only that parameter. index := -1 if site := cgn.callersite; site != nil { if c, ok := site.instr.Common().Args[0].(*ssa.Const); ok { v, _ := exact.Int64Val(c.Value) index = int(v) } } a.addConstraint(&rtypeInOutConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), out: out, i: index, }) } func ext۰reflect۰rtype۰In(a *analysis, cgn *cgnode) { ext۰reflect۰rtype۰InOut(a, cgn, false) } func ext۰reflect۰rtype۰Out(a *analysis, cgn *cgnode) { ext۰reflect۰rtype۰InOut(a, cgn, true) } // ---------- func (*rtype) Key() Type ---------- // result = Key(t) type rtypeKeyConstraint struct { cgn *cgnode t nodeid // (ptr) result nodeid // (indirect) } func (c *rtypeKeyConstraint) ptr() nodeid { return c.t } func (c *rtypeKeyConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result), "rtypeKey.result") } func (c *rtypeKeyConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *rtypeKeyConstraint) String() string { return fmt.Sprintf("n%d = (*reflect.rtype).Key(n%d)", c.result, c.t) } func (c *rtypeKeyConstraint) solve(a *analysis, delta *nodeset) { changed := false for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.nodes[tObj].obj.data.(types.Type) if tMap, ok := T.Underlying().(*types.Map); ok { if a.addLabel(c.result, a.makeRtype(tMap.Key())) { changed = true } } } if changed { a.addWork(c.result) } } func ext۰reflect۰rtype۰Key(a *analysis, cgn *cgnode) { a.addConstraint(&rtypeKeyConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // ---------- func (*rtype) Method(int) (Method, bool) ---------- // ---------- func (*rtype) MethodByName(string) (Method, bool) ---------- // result = MethodByName(t, name) // result = Method(t, _) type rtypeMethodByNameConstraint struct { cgn *cgnode name string // name of method; "" for unknown t nodeid // (ptr) result nodeid // (indirect) } func (c *rtypeMethodByNameConstraint) ptr() nodeid { return c.t } func (c *rtypeMethodByNameConstraint) presolve(h *hvn) { h.markIndirect(onodeid(c.result+3), "rtypeMethodByName.result.Type") h.markIndirect(onodeid(c.result+4), "rtypeMethodByName.result.Func") } func (c *rtypeMethodByNameConstraint) renumber(mapping []nodeid) { c.t = mapping[c.t] c.result = mapping[c.result] } func (c *rtypeMethodByNameConstraint) String() string { return fmt.Sprintf("n%d = (*reflect.rtype).MethodByName(n%d, %q)", c.result, c.t, c.name) } // changeRecv returns sig with Recv prepended to Params(). func changeRecv(sig *types.Signature) *types.Signature { params := sig.Params() n := params.Len() p2 := make([]*types.Var, n+1) p2[0] = sig.Recv() for i := 0; i < n; i++ { p2[i+1] = params.At(i) } return types.NewSignature(nil, types.NewTuple(p2...), sig.Results(), sig.Variadic()) } func (c *rtypeMethodByNameConstraint) solve(a *analysis, delta *nodeset) { for _, x := range delta.AppendTo(a.deltaSpace) { tObj := nodeid(x) T := a.nodes[tObj].obj.data.(types.Type) isIface := isInterface(T) // We don't use Lookup(c.name) when c.name != "" to avoid // ambiguity: >1 unexported methods could match. mset := a.prog.MethodSets.MethodSet(T) for i, n := 0, mset.Len(); i < n; i++ { sel := mset.At(i) if c.name == "" || c.name == sel.Obj().Name() { // type Method struct { // 0 __identity__ // 1 Name string // 2 PkgPath string // 3 Type Type // 4 Func Value // 5 Index int // } var sig *types.Signature var fn *ssa.Function if isIface { sig = sel.Type().(*types.Signature) } else { fn = a.prog.MethodValue(sel) // move receiver to params[0] sig = changeRecv(fn.Signature) } // a.offsetOf(Type) is 3. if id := c.result + 3; a.addLabel(id, a.makeRtype(sig)) { a.addWork(id) } if fn != nil { // a.offsetOf(Func) is 4. if id := c.result + 4; a.addLabel(id, a.objectNode(nil, fn)) { a.addWork(id) } } } } } } func ext۰reflect۰rtype۰MethodByName(a *analysis, cgn *cgnode) { // If we have access to the callsite, // and the argument is a string constant, // return only that method. var name string if site := cgn.callersite; site != nil { if c, ok := site.instr.Common().Args[0].(*ssa.Const); ok { name = exact.StringVal(c.Value) } } a.addConstraint(&rtypeMethodByNameConstraint{ cgn: cgn, name: name, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } func ext۰reflect۰rtype۰Method(a *analysis, cgn *cgnode) { // No-one ever calls Method with a constant argument, // so we don't specialize that case. a.addConstraint(&rtypeMethodByNameConstraint{ cgn: cgn, t: a.funcParams(cgn.obj), result: a.funcResults(cgn.obj), }) } // typeHeight returns the "height" of the type, which is roughly // speaking the number of chan, map, pointer and slice type constructors // at the root of T; these are the four type kinds that can be created // via reflection. Chan and map constructors are counted as double the // height of slice and pointer constructors since they are less often // deeply nested. // // The solver rules for type constructors must somehow bound the set of // types they create to ensure termination of the algorithm in cases // where the output of a type constructor flows to its input, e.g. // // func f(t reflect.Type) { // f(reflect.PtrTo(t)) // } // // It does this by limiting the type height to k, but this still leaves // a potentially exponential (4^k) number of of types that may be // enumerated in pathological cases. // func typeHeight(T types.Type) int { switch T := T.(type) { case *types.Chan: return 2 + typeHeight(T.Elem()) case *types.Map: k := typeHeight(T.Key()) v := typeHeight(T.Elem()) if v > k { k = v // max(k, v) } return 2 + k case *types.Slice: return 1 + typeHeight(T.Elem()) case *types.Pointer: return 1 + typeHeight(T.Elem()) } return 0 } func typeTooHigh(T types.Type) bool { return typeHeight(T) > 3 }