// Copyright 2023 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 devirtualize import ( "cmd/compile/internal/base" "cmd/compile/internal/inline" "cmd/compile/internal/ir" "cmd/compile/internal/logopt" "cmd/compile/internal/pgo" "cmd/compile/internal/typecheck" "cmd/compile/internal/types" "cmd/internal/obj" "cmd/internal/src" "encoding/json" "fmt" "os" "strings" ) // CallStat summarizes a single call site. // // This is used only for debug logging. type CallStat struct { Pkg string // base.Ctxt.Pkgpath Pos string // file:line:col of call. Caller string // Linker symbol name of calling function. // Direct or indirect call. Direct bool // For indirect calls, interface call or other indirect function call. Interface bool // Total edge weight from this call site. Weight int64 // Hottest callee from this call site, regardless of type // compatibility. Hottest string HottestWeight int64 // Devirtualized callee if != "". // // Note that this may be different than Hottest because we apply // type-check restrictions, which helps distinguish multiple calls on // the same line. Devirtualized string DevirtualizedWeight int64 } // ProfileGuided performs call devirtualization of indirect calls based on // profile information. // // Specifically, it performs conditional devirtualization of interface calls or // function value calls for the hottest callee. // // That is, for interface calls it performs a transformation like: // // type Iface interface { // Foo() // } // // type Concrete struct{} // // func (Concrete) Foo() {} // // func foo(i Iface) { // i.Foo() // } // // to: // // func foo(i Iface) { // if c, ok := i.(Concrete); ok { // c.Foo() // } else { // i.Foo() // } // } // // For function value calls it performs a transformation like: // // func Concrete() {} // // func foo(fn func()) { // fn() // } // // to: // // func foo(fn func()) { // if internal/abi.FuncPCABIInternal(fn) == internal/abi.FuncPCABIInternal(Concrete) { // Concrete() // } else { // fn() // } // } // // The primary benefit of this transformation is enabling inlining of the // direct call. func ProfileGuided(fn *ir.Func, p *pgo.Profile) { ir.CurFunc = fn name := ir.LinkFuncName(fn) var jsonW *json.Encoder if base.Debug.PGODebug >= 3 { jsonW = json.NewEncoder(os.Stdout) } var edit func(n ir.Node) ir.Node edit = func(n ir.Node) ir.Node { if n == nil { return n } ir.EditChildren(n, edit) call, ok := n.(*ir.CallExpr) if !ok { return n } var stat *CallStat if base.Debug.PGODebug >= 3 { // Statistics about every single call. Handy for external data analysis. // // TODO(prattmic): Log via logopt? stat = constructCallStat(p, fn, name, call) if stat != nil { defer func() { jsonW.Encode(&stat) }() } } op := call.Op() if op != ir.OCALLFUNC && op != ir.OCALLINTER { return n } if base.Debug.PGODebug >= 2 { fmt.Printf("%v: PGO devirtualize considering call %v\n", ir.Line(call), call) } if call.GoDefer { if base.Debug.PGODebug >= 2 { fmt.Printf("%v: can't PGO devirtualize go/defer call %v\n", ir.Line(call), call) } return n } var newNode ir.Node var callee *ir.Func var weight int64 switch op { case ir.OCALLFUNC: newNode, callee, weight = maybeDevirtualizeFunctionCall(p, fn, call) case ir.OCALLINTER: newNode, callee, weight = maybeDevirtualizeInterfaceCall(p, fn, call) default: panic("unreachable") } if newNode == nil { return n } if stat != nil { stat.Devirtualized = ir.LinkFuncName(callee) stat.DevirtualizedWeight = weight } return newNode } ir.EditChildren(fn, edit) } // Devirtualize interface call if possible and eligible. Returns the new // ir.Node if call was devirtualized, and if so also the callee and weight of // the devirtualized edge. func maybeDevirtualizeInterfaceCall(p *pgo.Profile, fn *ir.Func, call *ir.CallExpr) (ir.Node, *ir.Func, int64) { if base.Debug.PGODevirtualize < 1 { return nil, nil, 0 } // Bail if we do not have a hot callee. callee, weight := findHotConcreteInterfaceCallee(p, fn, call) if callee == nil { return nil, nil, 0 } // Bail if we do not have a Type node for the hot callee. ctyp := methodRecvType(callee) if ctyp == nil { return nil, nil, 0 } // Bail if we know for sure it won't inline. if !shouldPGODevirt(callee) { return nil, nil, 0 } // Bail if de-selected by PGO Hash. if !base.PGOHash.MatchPosWithInfo(call.Pos(), "devirt", nil) { return nil, nil, 0 } return rewriteInterfaceCall(call, fn, callee, ctyp), callee, weight } // Devirtualize an indirect function call if possible and eligible. Returns the new // ir.Node if call was devirtualized, and if so also the callee and weight of // the devirtualized edge. func maybeDevirtualizeFunctionCall(p *pgo.Profile, fn *ir.Func, call *ir.CallExpr) (ir.Node, *ir.Func, int64) { if base.Debug.PGODevirtualize < 2 { return nil, nil, 0 } // Bail if this is a direct call; no devirtualization necessary. callee := pgo.DirectCallee(call.Fun) if callee != nil { return nil, nil, 0 } // Bail if we do not have a hot callee. callee, weight := findHotConcreteFunctionCallee(p, fn, call) if callee == nil { return nil, nil, 0 } // TODO(go.dev/issue/61577): Closures need the closure context passed // via the context register. That requires extra plumbing that we // haven't done yet. if callee.OClosure != nil { if base.Debug.PGODebug >= 3 { fmt.Printf("callee %s is a closure, skipping\n", ir.FuncName(callee)) } return nil, nil, 0 } // runtime.memhash_varlen does not look like a closure, but it uses // runtime.getclosureptr to access data encoded by callers, which are // are generated by cmd/compile/internal/reflectdata.genhash. if callee.Sym().Pkg.Path == "runtime" && callee.Sym().Name == "memhash_varlen" { if base.Debug.PGODebug >= 3 { fmt.Printf("callee %s is a closure (runtime.memhash_varlen), skipping\n", ir.FuncName(callee)) } return nil, nil, 0 } // TODO(prattmic): We don't properly handle methods as callees in two // different dimensions: // // 1. Method expressions. e.g., // // var fn func(*os.File, []byte) (int, error) = (*os.File).Read // // In this case, typ will report *os.File as the receiver while // ctyp reports it as the first argument. types.Identical ignores // receiver parameters, so it treats these as different, even though // they are still call compatible. // // 2. Method values. e.g., // // var f *os.File // var fn func([]byte) (int, error) = f.Read // // types.Identical will treat these as compatible (since receiver // parameters are ignored). However, in this case, we do not call // (*os.File).Read directly. Instead, f is stored in closure context // and we call the wrapper (*os.File).Read-fm. However, runtime/pprof // hides wrappers from profiles, making it appear that there is a call // directly to the method. We could recognize this pattern return the // wrapper rather than the method. // // N.B. perf profiles will report wrapper symbols directly, so // ideally we should support direct wrapper references as well. if callee.Type().Recv() != nil { if base.Debug.PGODebug >= 3 { fmt.Printf("callee %s is a method, skipping\n", ir.FuncName(callee)) } return nil, nil, 0 } // Bail if we know for sure it won't inline. if !shouldPGODevirt(callee) { return nil, nil, 0 } // Bail if de-selected by PGO Hash. if !base.PGOHash.MatchPosWithInfo(call.Pos(), "devirt", nil) { return nil, nil, 0 } return rewriteFunctionCall(call, fn, callee), callee, weight } // shouldPGODevirt checks if we should perform PGO devirtualization to the // target function. // // PGO devirtualization is most valuable when the callee is inlined, so if it // won't inline we can skip devirtualizing. func shouldPGODevirt(fn *ir.Func) bool { var reason string if base.Flag.LowerM > 1 || logopt.Enabled() { defer func() { if reason != "" { if base.Flag.LowerM > 1 { fmt.Printf("%v: should not PGO devirtualize %v: %s\n", ir.Line(fn), ir.FuncName(fn), reason) } if logopt.Enabled() { logopt.LogOpt(fn.Pos(), ": should not PGO devirtualize function", "pgo-devirtualize", ir.FuncName(fn), reason) } } }() } reason = inline.InlineImpossible(fn) if reason != "" { return false } // TODO(prattmic): checking only InlineImpossible is very conservative, // primarily excluding only functions with pragmas. We probably want to // move in either direction. Either: // // 1. Don't even bother to check InlineImpossible, as it affects so few // functions. // // 2. Or consider the function body (notably cost) to better determine // if the function will actually inline. return true } // constructCallStat builds an initial CallStat describing this call, for // logging. If the call is devirtualized, the devirtualization fields should be // updated. func constructCallStat(p *pgo.Profile, fn *ir.Func, name string, call *ir.CallExpr) *CallStat { switch call.Op() { case ir.OCALLFUNC, ir.OCALLINTER, ir.OCALLMETH: default: // We don't care about logging builtin functions. return nil } stat := CallStat{ Pkg: base.Ctxt.Pkgpath, Pos: ir.Line(call), Caller: name, } offset := pgo.NodeLineOffset(call, fn) hotter := func(e *pgo.IREdge) bool { if stat.Hottest == "" { return true } if e.Weight != stat.HottestWeight { return e.Weight > stat.HottestWeight } // If weight is the same, arbitrarily sort lexicographally, as // findHotConcreteCallee does. return e.Dst.Name() < stat.Hottest } // Sum of all edges from this callsite, regardless of callee. // For direct calls, this should be the same as the single edge // weight (except for multiple calls on one line, which we // can't distinguish). callerNode := p.WeightedCG.IRNodes[name] for _, edge := range callerNode.OutEdges { if edge.CallSiteOffset != offset { continue } stat.Weight += edge.Weight if hotter(edge) { stat.HottestWeight = edge.Weight stat.Hottest = edge.Dst.Name() } } switch call.Op() { case ir.OCALLFUNC: stat.Interface = false callee := pgo.DirectCallee(call.Fun) if callee != nil { stat.Direct = true if stat.Hottest == "" { stat.Hottest = ir.LinkFuncName(callee) } } else { stat.Direct = false } case ir.OCALLINTER: stat.Direct = false stat.Interface = true case ir.OCALLMETH: base.FatalfAt(call.Pos(), "OCALLMETH missed by typecheck") } return &stat } // copyInputs copies the inputs to a call: the receiver (for interface calls) // or function value (for function value calls) and the arguments. These // expressions are evaluated once and assigned to temporaries. // // The assignment statement is added to init and the copied receiver/fn // expression and copied arguments expressions are returned. func copyInputs(curfn *ir.Func, pos src.XPos, recvOrFn ir.Node, args []ir.Node, init *ir.Nodes) (ir.Node, []ir.Node) { // Evaluate receiver/fn and argument expressions. The receiver/fn is // used twice but we don't want to cause side effects twice. The // arguments are used in two different calls and we can't trivially // copy them. // // recvOrFn must be first in the assignment list as its side effects // must be ordered before argument side effects. var lhs, rhs []ir.Node newRecvOrFn := typecheck.TempAt(pos, curfn, recvOrFn.Type()) lhs = append(lhs, newRecvOrFn) rhs = append(rhs, recvOrFn) for _, arg := range args { argvar := typecheck.TempAt(pos, curfn, arg.Type()) lhs = append(lhs, argvar) rhs = append(rhs, arg) } asList := ir.NewAssignListStmt(pos, ir.OAS2, lhs, rhs) init.Append(typecheck.Stmt(asList)) return newRecvOrFn, lhs[1:] } // retTemps returns a slice of temporaries to be used for storing result values from call. func retTemps(curfn *ir.Func, pos src.XPos, call *ir.CallExpr) []ir.Node { sig := call.Fun.Type() var retvars []ir.Node for _, ret := range sig.Results() { retvars = append(retvars, typecheck.TempAt(pos, curfn, ret.Type)) } return retvars } // condCall returns an ir.InlinedCallExpr that performs a call to thenCall if // cond is true and elseCall if cond is false. The return variables of the // InlinedCallExpr evaluate to the return values from the call. func condCall(curfn *ir.Func, pos src.XPos, cond ir.Node, thenCall, elseCall *ir.CallExpr, init ir.Nodes) *ir.InlinedCallExpr { // Doesn't matter whether we use thenCall or elseCall, they must have // the same return types. retvars := retTemps(curfn, pos, thenCall) var thenBlock, elseBlock ir.Nodes if len(retvars) == 0 { thenBlock.Append(thenCall) elseBlock.Append(elseCall) } else { // Copy slice so edits in one location don't affect another. thenRet := append([]ir.Node(nil), retvars...) thenAsList := ir.NewAssignListStmt(pos, ir.OAS2, thenRet, []ir.Node{thenCall}) thenBlock.Append(typecheck.Stmt(thenAsList)) elseRet := append([]ir.Node(nil), retvars...) elseAsList := ir.NewAssignListStmt(pos, ir.OAS2, elseRet, []ir.Node{elseCall}) elseBlock.Append(typecheck.Stmt(elseAsList)) } nif := ir.NewIfStmt(pos, cond, thenBlock, elseBlock) nif.SetInit(init) nif.Likely = true body := []ir.Node{typecheck.Stmt(nif)} // This isn't really an inlined call of course, but InlinedCallExpr // makes handling reassignment of return values easier. res := ir.NewInlinedCallExpr(pos, body, retvars) res.SetType(thenCall.Type()) res.SetTypecheck(1) return res } // rewriteInterfaceCall devirtualizes the given interface call using a direct // method call to concretetyp. func rewriteInterfaceCall(call *ir.CallExpr, curfn, callee *ir.Func, concretetyp *types.Type) ir.Node { if base.Flag.LowerM != 0 { fmt.Printf("%v: PGO devirtualizing interface call %v to %v\n", ir.Line(call), call.Fun, callee) } // We generate an OINCALL of: // // var recv Iface // // var arg1 A1 // var argN AN // // var ret1 R1 // var retN RN // // recv, arg1, argN = recv expr, arg1 expr, argN expr // // t, ok := recv.(Concrete) // if ok { // ret1, retN = t.Method(arg1, ... argN) // } else { // ret1, retN = recv.Method(arg1, ... argN) // } // // OINCALL retvars: ret1, ... retN // // This isn't really an inlined call of course, but InlinedCallExpr // makes handling reassignment of return values easier. // // TODO(prattmic): This increases the size of the AST in the caller, // making it less like to inline. We may want to compensate for this // somehow. sel := call.Fun.(*ir.SelectorExpr) method := sel.Sel pos := call.Pos() init := ir.TakeInit(call) recv, args := copyInputs(curfn, pos, sel.X, call.Args.Take(), &init) // Copy slice so edits in one location don't affect another. argvars := append([]ir.Node(nil), args...) call.Args = argvars tmpnode := typecheck.TempAt(base.Pos, curfn, concretetyp) tmpok := typecheck.TempAt(base.Pos, curfn, types.Types[types.TBOOL]) assert := ir.NewTypeAssertExpr(pos, recv, concretetyp) assertAsList := ir.NewAssignListStmt(pos, ir.OAS2, []ir.Node{tmpnode, tmpok}, []ir.Node{typecheck.Expr(assert)}) init.Append(typecheck.Stmt(assertAsList)) concreteCallee := typecheck.XDotMethod(pos, tmpnode, method, true) // Copy slice so edits in one location don't affect another. argvars = append([]ir.Node(nil), argvars...) concreteCall := typecheck.Call(pos, concreteCallee, argvars, call.IsDDD).(*ir.CallExpr) res := condCall(curfn, pos, tmpok, concreteCall, call, init) if base.Debug.PGODebug >= 3 { fmt.Printf("PGO devirtualizing interface call to %+v. After: %+v\n", concretetyp, res) } return res } // rewriteFunctionCall devirtualizes the given OCALLFUNC using a direct // function call to callee. func rewriteFunctionCall(call *ir.CallExpr, curfn, callee *ir.Func) ir.Node { if base.Flag.LowerM != 0 { fmt.Printf("%v: PGO devirtualizing function call %v to %v\n", ir.Line(call), call.Fun, callee) } // We generate an OINCALL of: // // var fn FuncType // // var arg1 A1 // var argN AN // // var ret1 R1 // var retN RN // // fn, arg1, argN = fn expr, arg1 expr, argN expr // // fnPC := internal/abi.FuncPCABIInternal(fn) // concretePC := internal/abi.FuncPCABIInternal(concrete) // // if fnPC == concretePC { // ret1, retN = concrete(arg1, ... argN) // Same closure context passed (TODO) // } else { // ret1, retN = fn(arg1, ... argN) // } // // OINCALL retvars: ret1, ... retN // // This isn't really an inlined call of course, but InlinedCallExpr // makes handling reassignment of return values easier. pos := call.Pos() init := ir.TakeInit(call) fn, args := copyInputs(curfn, pos, call.Fun, call.Args.Take(), &init) // Copy slice so edits in one location don't affect another. argvars := append([]ir.Node(nil), args...) call.Args = argvars // FuncPCABIInternal takes an interface{}, emulate that. This is needed // for to ensure we get the MAKEFACE we need for SSA. fnIface := typecheck.Expr(ir.NewConvExpr(pos, ir.OCONV, types.Types[types.TINTER], fn)) calleeIface := typecheck.Expr(ir.NewConvExpr(pos, ir.OCONV, types.Types[types.TINTER], callee.Nname)) fnPC := ir.FuncPC(pos, fnIface, obj.ABIInternal) concretePC := ir.FuncPC(pos, calleeIface, obj.ABIInternal) pcEq := typecheck.Expr(ir.NewBinaryExpr(base.Pos, ir.OEQ, fnPC, concretePC)) // TODO(go.dev/issue/61577): Handle callees that a closures and need a // copy of the closure context from call. For now, we skip callees that // are closures in maybeDevirtualizeFunctionCall. if callee.OClosure != nil { base.Fatalf("Callee is a closure: %+v", callee) } // Copy slice so edits in one location don't affect another. argvars = append([]ir.Node(nil), argvars...) concreteCall := typecheck.Call(pos, callee.Nname, argvars, call.IsDDD).(*ir.CallExpr) res := condCall(curfn, pos, pcEq, concreteCall, call, init) if base.Debug.PGODebug >= 3 { fmt.Printf("PGO devirtualizing function call to %+v. After: %+v\n", ir.FuncName(callee), res) } return res } // methodRecvType returns the type containing method fn. Returns nil if fn // is not a method. func methodRecvType(fn *ir.Func) *types.Type { recv := fn.Nname.Type().Recv() if recv == nil { return nil } return recv.Type } // interfaceCallRecvTypeAndMethod returns the type and the method of the interface // used in an interface call. func interfaceCallRecvTypeAndMethod(call *ir.CallExpr) (*types.Type, *types.Sym) { if call.Op() != ir.OCALLINTER { base.Fatalf("Call isn't OCALLINTER: %+v", call) } sel, ok := call.Fun.(*ir.SelectorExpr) if !ok { base.Fatalf("OCALLINTER doesn't contain SelectorExpr: %+v", call) } return sel.X.Type(), sel.Sel } // findHotConcreteCallee returns the *ir.Func of the hottest callee of a call, // if available, and its edge weight. extraFn can perform additional // applicability checks on each candidate edge. If extraFn returns false, // candidate will not be considered a valid callee candidate. func findHotConcreteCallee(p *pgo.Profile, caller *ir.Func, call *ir.CallExpr, extraFn func(callerName string, callOffset int, candidate *pgo.IREdge) bool) (*ir.Func, int64) { callerName := ir.LinkFuncName(caller) callerNode := p.WeightedCG.IRNodes[callerName] callOffset := pgo.NodeLineOffset(call, caller) var hottest *pgo.IREdge // Returns true if e is hotter than hottest. // // Naively this is just e.Weight > hottest.Weight, but because OutEdges // has arbitrary iteration order, we need to apply additional sort // criteria when e.Weight == hottest.Weight to ensure we have stable // selection. hotter := func(e *pgo.IREdge) bool { if hottest == nil { return true } if e.Weight != hottest.Weight { return e.Weight > hottest.Weight } // Now e.Weight == hottest.Weight, we must select on other // criteria. // If only one edge has IR, prefer that one. if (hottest.Dst.AST == nil) != (e.Dst.AST == nil) { if e.Dst.AST != nil { return true } return false } // Arbitrary, but the callee names will always differ. Select // the lexicographically first callee. return e.Dst.Name() < hottest.Dst.Name() } for _, e := range callerNode.OutEdges { if e.CallSiteOffset != callOffset { continue } if !hotter(e) { // TODO(prattmic): consider total caller weight? i.e., // if the hottest callee is only 10% of the weight, // maybe don't devirtualize? Similarly, if this is call // is globally very cold, there is not much value in // devirtualizing. if base.Debug.PGODebug >= 2 { fmt.Printf("%v: edge %s:%d -> %s (weight %d): too cold (hottest %d)\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight, hottest.Weight) } continue } if e.Dst.AST == nil { // Destination isn't visible from this package // compilation. // // We must assume it implements the interface. // // We still record this as the hottest callee so far // because we only want to return the #1 hottest // callee. If we skip this then we'd return the #2 // hottest callee. if base.Debug.PGODebug >= 2 { fmt.Printf("%v: edge %s:%d -> %s (weight %d) (missing IR): hottest so far\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight) } hottest = e continue } if extraFn != nil && !extraFn(callerName, callOffset, e) { continue } if base.Debug.PGODebug >= 2 { fmt.Printf("%v: edge %s:%d -> %s (weight %d): hottest so far\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight) } hottest = e } if hottest == nil { if base.Debug.PGODebug >= 2 { fmt.Printf("%v: call %s:%d: no hot callee\n", ir.Line(call), callerName, callOffset) } return nil, 0 } if base.Debug.PGODebug >= 2 { fmt.Printf("%v call %s:%d: hottest callee %s (weight %d)\n", ir.Line(call), callerName, callOffset, hottest.Dst.Name(), hottest.Weight) } return hottest.Dst.AST, hottest.Weight } // findHotConcreteInterfaceCallee returns the *ir.Func of the hottest callee of an // interface call, if available, and its edge weight. func findHotConcreteInterfaceCallee(p *pgo.Profile, caller *ir.Func, call *ir.CallExpr) (*ir.Func, int64) { inter, method := interfaceCallRecvTypeAndMethod(call) return findHotConcreteCallee(p, caller, call, func(callerName string, callOffset int, e *pgo.IREdge) bool { ctyp := methodRecvType(e.Dst.AST) if ctyp == nil { // Not a method. // TODO(prattmic): Support non-interface indirect calls. if base.Debug.PGODebug >= 2 { fmt.Printf("%v: edge %s:%d -> %s (weight %d): callee not a method\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight) } return false } // If ctyp doesn't implement inter it is most likely from a // different call on the same line if !typecheck.Implements(ctyp, inter) { // TODO(prattmic): this is overly strict. Consider if // ctyp is a partial implementation of an interface // that gets embedded in types that complete the // interface. It would still be OK to devirtualize a // call to this method. // // What we'd need to do is check that the function // pointer in the itab matches the method we want, // rather than doing a full type assertion. if base.Debug.PGODebug >= 2 { why := typecheck.ImplementsExplain(ctyp, inter) fmt.Printf("%v: edge %s:%d -> %s (weight %d): %v doesn't implement %v (%s)\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight, ctyp, inter, why) } return false } // If the method name is different it is most likely from a // different call on the same line if !strings.HasSuffix(e.Dst.Name(), "."+method.Name) { if base.Debug.PGODebug >= 2 { fmt.Printf("%v: edge %s:%d -> %s (weight %d): callee is a different method\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight) } return false } return true }) } // findHotConcreteFunctionCallee returns the *ir.Func of the hottest callee of an // indirect function call, if available, and its edge weight. func findHotConcreteFunctionCallee(p *pgo.Profile, caller *ir.Func, call *ir.CallExpr) (*ir.Func, int64) { typ := call.Fun.Type().Underlying() return findHotConcreteCallee(p, caller, call, func(callerName string, callOffset int, e *pgo.IREdge) bool { ctyp := e.Dst.AST.Type().Underlying() // If ctyp doesn't match typ it is most likely from a different // call on the same line. // // Note that we are comparing underlying types, as different // defined types are OK. e.g., a call to a value of type // net/http.HandlerFunc can be devirtualized to a function with // the same underlying type. if !types.Identical(typ, ctyp) { if base.Debug.PGODebug >= 2 { fmt.Printf("%v: edge %s:%d -> %s (weight %d): %v doesn't match %v\n", ir.Line(call), callerName, callOffset, e.Dst.Name(), e.Weight, ctyp, typ) } return false } return true }) }