// Copyright 2025 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 bloop // This file contains support routines for keeping // statements alive // in such loops (example): // // for b.Loop() { // var a, b int // a = 5 // b = 6 // f(a, b) // } // // The results of a, b and f(a, b) will be kept alive. // // Formally, the lhs (if they are [ir.Name]-s) of // [ir.AssignStmt], [ir.AssignListStmt], // [ir.AssignOpStmt], and the results of [ir.CallExpr] // or its args if it doesn't return a value will be kept // alive. // // The keep alive logic is implemented with as wrapping a // runtime.KeepAlive around the Name. // // TODO: currently this is implemented with KeepAlive // because it will prevent DSE and DCE which is probably // what we want right now. And KeepAlive takes an ssa // value instead of a symbol, which is easier to manage. // But since KeepAlive's context was mainly in the runtime // and GC, should we implement a new intrinsic that lowers // to OpVarLive? Peeling out the symbols is a bit tricky // and also VarLive seems to assume that there exists a // VarDef on the same symbol that dominates it. import ( "cmd/compile/internal/base" "cmd/compile/internal/ir" "cmd/compile/internal/reflectdata" "cmd/compile/internal/typecheck" "cmd/compile/internal/types" "cmd/internal/src" ) // getNameFromNode tries to iteratively peel down the node to // get the name. func getNameFromNode(n ir.Node) *ir.Name { // Tries to iteratively peel down the node to get the names. for n != nil { switch n.Op() { case ir.ONAME: // Found the name, stop the loop. return n.(*ir.Name) case ir.OSLICE, ir.OSLICE3: n = n.(*ir.SliceExpr).X case ir.ODOT: n = n.(*ir.SelectorExpr).X case ir.OCONV, ir.OCONVIFACE, ir.OCONVNOP: n = n.(*ir.ConvExpr).X case ir.OADDR: n = n.(*ir.AddrExpr).X case ir.ODOTPTR: n = n.(*ir.SelectorExpr).X case ir.OINDEX, ir.OINDEXMAP: n = n.(*ir.IndexExpr).X default: n = nil } } return nil } // getAddressableNameFromNode is like getNameFromNode but returns nil if the node is not addressable. func getAddressableNameFromNode(n ir.Node) *ir.Name { if name := getNameFromNode(n); name != nil && ir.IsAddressable(name) { return name } return nil } // keepAliveAt returns a statement that is either curNode, or a // block containing curNode followed by a call to runtime.KeepAlive for each // node in ns. These calls ensure that nodes in ns will be live until // after curNode's execution. func keepAliveAt(ns []ir.Node, curNode ir.Node) ir.Node { if len(ns) == 0 { return curNode } pos := curNode.Pos() calls := []ir.Node{curNode} for _, n := range ns { if n == nil { continue } if n.Sym() == nil { continue } if n.Sym().IsBlank() { continue } if !ir.IsAddressable(n) { base.FatalfAt(n.Pos(), "keepAliveAt: node %v is not addressable", n) } arg := ir.NewConvExpr(pos, ir.OCONV, types.Types[types.TUNSAFEPTR], typecheck.NodAddr(n)) if !n.Type().IsInterface() { srcRType0 := reflectdata.TypePtrAt(pos, n.Type()) arg.TypeWord = srcRType0 arg.SrcRType = srcRType0 } callExpr := typecheck.Call(pos, typecheck.LookupRuntime("KeepAlive"), []ir.Node{arg}, false).(*ir.CallExpr) callExpr.IsCompilerVarLive = true callExpr.NoInline = true calls = append(calls, callExpr) } return ir.NewBlockStmt(pos, calls) } func debugName(name *ir.Name, pos src.XPos) { if base.Flag.LowerM > 1 { if name.Linksym() != nil { base.WarnfAt(pos, "%s will be kept alive", name.Linksym().Name) } else { base.WarnfAt(pos, "expr will be kept alive") } } } // preserveStmt transforms stmt so that any names defined/assigned within it // are used after stmt's execution, preventing their dead code elimination // and dead store elimination. The return value is the transformed statement. func preserveStmt(curFn *ir.Func, stmt ir.Node) (ret ir.Node) { ret = stmt switch n := stmt.(type) { case *ir.AssignStmt: // Peel down struct and slice indexing to get the names name := getAddressableNameFromNode(n.X) if name != nil { debugName(name, n.Pos()) ret = keepAliveAt([]ir.Node{name}, n) } else if deref := n.X.(*ir.StarExpr); deref != nil { ret = keepAliveAt([]ir.Node{deref}, n) if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "dereference will be kept alive") } } else if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "expr is unknown to bloop pass") } case *ir.AssignListStmt: ns := []ir.Node{} for _, lhs := range n.Lhs { name := getAddressableNameFromNode(lhs) if name != nil { debugName(name, n.Pos()) ns = append(ns, name) } else if deref := lhs.(*ir.StarExpr); deref != nil { ns = append(ns, deref) if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "dereference will be kept alive") } } else if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "expr is unknown to bloop pass") } } ret = keepAliveAt(ns, n) case *ir.AssignOpStmt: name := getAddressableNameFromNode(n.X) if name != nil { debugName(name, n.Pos()) ret = keepAliveAt([]ir.Node{name}, n) } else if deref := n.X.(*ir.StarExpr); deref != nil { ret = keepAliveAt([]ir.Node{deref}, n) if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "dereference will be kept alive") } } else if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "expr is unknown to bloop pass") } case *ir.CallExpr: curNode := stmt if n.Fun != nil && n.Fun.Type() != nil && n.Fun.Type().NumResults() != 0 { ns := []ir.Node{} // This function's results are not assigned, assign them to // auto tmps and then keepAliveAt these autos. // Note: markStmt assumes the context that it's called - this CallExpr is // not within another OAS2, which is guaranteed by the case above. results := n.Fun.Type().Results() lhs := make([]ir.Node, len(results)) for i, res := range results { tmp := typecheck.TempAt(n.Pos(), curFn, res.Type) lhs[i] = tmp ns = append(ns, tmp) } // Create an assignment statement. assign := typecheck.AssignExpr( ir.NewAssignListStmt(n.Pos(), ir.OAS2, lhs, []ir.Node{n})).(*ir.AssignListStmt) assign.Def = true for _, tmp := range lhs { // Place temp declarations in the loop body to help escape analysis. assign.PtrInit().Append(typecheck.Stmt(ir.NewDecl(assign.Pos(), ir.ODCL, tmp.(*ir.Name)))) } curNode = assign plural := "" if len(results) > 1 { plural = "s" } if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "function result%s will be kept alive", plural) } ret = keepAliveAt(ns, curNode) } else { // This function probably doesn't return anything, keep its args alive. argTmps := []ir.Node{} names := []ir.Node{} for i, a := range n.Args { if name := getAddressableNameFromNode(a); name != nil { // If they are name, keep them alive directly. debugName(name, n.Pos()) names = append(names, name) } else if a.Op() == ir.OSLICELIT { // variadic args are encoded as slice literal. s := a.(*ir.CompLitExpr) ns := []ir.Node{} for i, elem := range s.List { if name := getAddressableNameFromNode(elem); name != nil { debugName(name, n.Pos()) ns = append(ns, name) } else { // We need a temporary to save this arg. tmp := typecheck.TempAt(elem.Pos(), curFn, elem.Type()) assign := ir.NewAssignStmt(elem.Pos(), tmp, elem) assign.Def = true // Place temp declarations in the loop body to help escape analysis. assign.PtrInit().Append(typecheck.Stmt(ir.NewDecl(assign.Pos(), ir.ODCL, tmp))) argTmps = append(argTmps, typecheck.AssignExpr(assign)) names = append(names, tmp) s.List[i] = tmp if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "function arg will be kept alive") } } } names = append(names, ns...) } else { // expressions, we need to assign them to temps and change the original arg to reference // them. tmp := typecheck.TempAt(n.Pos(), curFn, a.Type()) assign := ir.NewAssignStmt(n.Pos(), tmp, a) assign.Def = true // Place temp declarations in the loop body to help escape analysis. assign.PtrInit().Append(typecheck.Stmt(ir.NewDecl(assign.Pos(), ir.ODCL, tmp))) argTmps = append(argTmps, typecheck.AssignExpr(assign)) names = append(names, tmp) n.Args[i] = tmp if base.Flag.LowerM > 1 { base.WarnfAt(n.Pos(), "function arg will be kept alive") } } } if len(argTmps) > 0 { argTmps = append(argTmps, n) curNode = ir.NewBlockStmt(n.Pos(), argTmps) } ret = keepAliveAt(names, curNode) } } return } func preserveStmts(curFn *ir.Func, list ir.Nodes) { for i := range list { list[i] = preserveStmt(curFn, list[i]) } } // isTestingBLoop returns true if it matches the node as a // testing.(*B).Loop. See issue #61515. func isTestingBLoop(t ir.Node) bool { if t.Op() != ir.OFOR { return false } nFor, ok := t.(*ir.ForStmt) if !ok || nFor.Cond == nil || nFor.Cond.Op() != ir.OCALLFUNC { return false } n, ok := nFor.Cond.(*ir.CallExpr) if !ok || n.Fun == nil || n.Fun.Op() != ir.OMETHEXPR { return false } name := ir.MethodExprName(n.Fun) if name == nil { return false } if fSym := name.Sym(); fSym != nil && name.Class == ir.PFUNC && fSym.Pkg != nil && fSym.Name == "(*B).Loop" && fSym.Pkg.Path == "testing" { // Attempting to match a function call to testing.(*B).Loop return true } return false } type editor struct { inBloop bool curFn *ir.Func } func (e editor) edit(n ir.Node) ir.Node { e.inBloop = isTestingBLoop(n) || e.inBloop // It's in bloop, mark the stmts with bodies. ir.EditChildren(n, e.edit) if e.inBloop { switch n := n.(type) { case *ir.ForStmt: preserveStmts(e.curFn, n.Body) case *ir.IfStmt: preserveStmts(e.curFn, n.Body) preserveStmts(e.curFn, n.Else) case *ir.BlockStmt: preserveStmts(e.curFn, n.List) case *ir.CaseClause: preserveStmts(e.curFn, n.List) preserveStmts(e.curFn, n.Body) case *ir.CommClause: preserveStmts(e.curFn, n.Body) case *ir.RangeStmt: preserveStmts(e.curFn, n.Body) } } return n } // BloopWalk performs a walk on all functions in the package // if it imports testing and wrap the results of all qualified // statements in a runtime.KeepAlive intrinsic call. See package // doc for more details. // // for b.Loop() {...} // // loop's body. func BloopWalk(pkg *ir.Package) { hasTesting := false for _, i := range pkg.Imports { if i.Path == "testing" { hasTesting = true break } } if !hasTesting { return } for _, fn := range pkg.Funcs { e := editor{false, fn} ir.EditChildren(fn, e.edit) } }