// Copyright 2009 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 gc import ( "cmd/compile/internal/syntax" "cmd/compile/internal/types" "fmt" ) func (p *noder) funcLit(expr *syntax.FuncLit) *Node { xtype := p.typeExpr(expr.Type) ntype := p.typeExpr(expr.Type) xfunc := p.nod(expr, ODCLFUNC, nil, nil) xfunc.Func.SetIsHiddenClosure(Curfn != nil) xfunc.Func.Nname = newfuncnamel(p.pos(expr), nblank.Sym) // filled in by typecheckclosure xfunc.Func.Nname.Name.Param.Ntype = xtype xfunc.Func.Nname.Name.Defn = xfunc clo := p.nod(expr, OCLOSURE, nil, nil) clo.Func.Ntype = ntype xfunc.Func.Closure = clo clo.Func.Closure = xfunc p.funcBody(xfunc, expr.Body) // closure-specific variables are hanging off the // ordinary ones in the symbol table; see oldname. // unhook them. // make the list of pointers for the closure call. for _, v := range xfunc.Func.Cvars.Slice() { // Unlink from v1; see comment in syntax.go type Param for these fields. v1 := v.Name.Defn v1.Name.Param.Innermost = v.Name.Param.Outer // If the closure usage of v is not dense, // we need to make it dense; now that we're out // of the function in which v appeared, // look up v.Sym in the enclosing function // and keep it around for use in the compiled code. // // That is, suppose we just finished parsing the innermost // closure f4 in this code: // // func f() { // v := 1 // func() { // f2 // use(v) // func() { // f3 // func() { // f4 // use(v) // }() // }() // }() // } // // At this point v.Outer is f2's v; there is no f3's v. // To construct the closure f4 from within f3, // we need to use f3's v and in this case we need to create f3's v. // We are now in the context of f3, so calling oldname(v.Sym) // obtains f3's v, creating it if necessary (as it is in the example). // // capturevars will decide whether to use v directly or &v. v.Name.Param.Outer = oldname(v.Sym) } return clo } // typecheckclosure typechecks an OCLOSURE node. It also creates the named // function associated with the closure. // TODO: This creation of the named function should probably really be done in a // separate pass from type-checking. func typecheckclosure(clo *Node, top int) { xfunc := clo.Func.Closure // Set current associated iota value, so iota can be used inside // function in ConstSpec, see issue #22344 if x := getIotaValue(); x >= 0 { xfunc.SetIota(x) } clo.Func.Ntype = typecheck(clo.Func.Ntype, ctxType) clo.Type = clo.Func.Ntype.Type clo.Func.Top = top // Do not typecheck xfunc twice, otherwise, we will end up pushing // xfunc to xtop multiple times, causing initLSym called twice. // See #30709 if xfunc.Typecheck() == 1 { return } for _, ln := range xfunc.Func.Cvars.Slice() { n := ln.Name.Defn if !n.Name.Captured() { n.Name.SetCaptured(true) if n.Name.Decldepth == 0 { Fatalf("typecheckclosure: var %S does not have decldepth assigned", n) } // Ignore assignments to the variable in straightline code // preceding the first capturing by a closure. if n.Name.Decldepth == decldepth { n.Name.SetAssigned(false) } } } xfunc.Func.Nname.Sym = closurename(Curfn) setNodeNameFunc(xfunc.Func.Nname) xfunc = typecheck(xfunc, ctxStmt) // Type check the body now, but only if we're inside a function. // At top level (in a variable initialization: curfn==nil) we're not // ready to type check code yet; we'll check it later, because the // underlying closure function we create is added to xtop. if Curfn != nil && clo.Type != nil { oldfn := Curfn Curfn = xfunc olddd := decldepth decldepth = 1 typecheckslice(xfunc.Nbody.Slice(), ctxStmt) decldepth = olddd Curfn = oldfn } xtop = append(xtop, xfunc) } // globClosgen is like Func.Closgen, but for the global scope. var globClosgen int // closurename generates a new unique name for a closure within // outerfunc. func closurename(outerfunc *Node) *types.Sym { outer := "glob." prefix := "func" gen := &globClosgen if outerfunc != nil { if outerfunc.Func.Closure != nil { prefix = "" } outer = outerfunc.funcname() // There may be multiple functions named "_". In those // cases, we can't use their individual Closgens as it // would lead to name clashes. if !outerfunc.Func.Nname.isBlank() { gen = &outerfunc.Func.Closgen } } *gen++ return lookup(fmt.Sprintf("%s.%s%d", outer, prefix, *gen)) } // capturevarscomplete is set to true when the capturevars phase is done. var capturevarscomplete bool // capturevars is called in a separate phase after all typechecking is done. // It decides whether each variable captured by a closure should be captured // by value or by reference. // We use value capturing for values <= 128 bytes that are never reassigned // after capturing (effectively constant). func capturevars(xfunc *Node) { lno := lineno lineno = xfunc.Pos clo := xfunc.Func.Closure cvars := xfunc.Func.Cvars.Slice() out := cvars[:0] for _, v := range cvars { if v.Type == nil { // If v.Type is nil, it means v looked like it // was going to be used in the closure, but // isn't. This happens in struct literals like // s{f: x} where we can't distinguish whether // f is a field identifier or expression until // resolving s. continue } out = append(out, v) // type check the & of closed variables outside the closure, // so that the outer frame also grabs them and knows they escape. dowidth(v.Type) outer := v.Name.Param.Outer outermost := v.Name.Defn // out parameters will be assigned to implicitly upon return. if outermost.Class() != PPARAMOUT && !outermost.Name.Addrtaken() && !outermost.Name.Assigned() && v.Type.Width <= 128 { v.Name.SetByval(true) } else { outermost.Name.SetAddrtaken(true) outer = nod(OADDR, outer, nil) } if Debug.m > 1 { var name *types.Sym if v.Name.Curfn != nil && v.Name.Curfn.Func.Nname != nil { name = v.Name.Curfn.Func.Nname.Sym } how := "ref" if v.Name.Byval() { how = "value" } Warnl(v.Pos, "%v capturing by %s: %v (addr=%v assign=%v width=%d)", name, how, v.Sym, outermost.Name.Addrtaken(), outermost.Name.Assigned(), int32(v.Type.Width)) } outer = typecheck(outer, ctxExpr) clo.Func.Enter.Append(outer) } xfunc.Func.Cvars.Set(out) lineno = lno } // transformclosure is called in a separate phase after escape analysis. // It transform closure bodies to properly reference captured variables. func transformclosure(xfunc *Node) { lno := lineno lineno = xfunc.Pos clo := xfunc.Func.Closure if clo.Func.Top&ctxCallee != 0 { // If the closure is directly called, we transform it to a plain function call // with variables passed as args. This avoids allocation of a closure object. // Here we do only a part of the transformation. Walk of OCALLFUNC(OCLOSURE) // will complete the transformation later. // For illustration, the following closure: // func(a int) { // println(byval) // byref++ // }(42) // becomes: // func(byval int, &byref *int, a int) { // println(byval) // (*&byref)++ // }(byval, &byref, 42) // f is ONAME of the actual function. f := xfunc.Func.Nname // We are going to insert captured variables before input args. var params []*types.Field var decls []*Node for _, v := range xfunc.Func.Cvars.Slice() { if !v.Name.Byval() { // If v of type T is captured by reference, // we introduce function param &v *T // and v remains PAUTOHEAP with &v heapaddr // (accesses will implicitly deref &v). addr := newname(lookup("&" + v.Sym.Name)) addr.Type = types.NewPtr(v.Type) v.Name.Param.Heapaddr = addr v = addr } v.SetClass(PPARAM) decls = append(decls, v) fld := types.NewField() fld.Nname = asTypesNode(v) fld.Type = v.Type fld.Sym = v.Sym params = append(params, fld) } if len(params) > 0 { // Prepend params and decls. f.Type.Params().SetFields(append(params, f.Type.Params().FieldSlice()...)) xfunc.Func.Dcl = append(decls, xfunc.Func.Dcl...) } dowidth(f.Type) xfunc.Type = f.Type // update type of ODCLFUNC } else { // The closure is not called, so it is going to stay as closure. var body []*Node offset := int64(Widthptr) for _, v := range xfunc.Func.Cvars.Slice() { // cv refers to the field inside of closure OSTRUCTLIT. cv := nod(OCLOSUREVAR, nil, nil) cv.Type = v.Type if !v.Name.Byval() { cv.Type = types.NewPtr(v.Type) } offset = Rnd(offset, int64(cv.Type.Align)) cv.Xoffset = offset offset += cv.Type.Width if v.Name.Byval() && v.Type.Width <= int64(2*Widthptr) { // If it is a small variable captured by value, downgrade it to PAUTO. v.SetClass(PAUTO) xfunc.Func.Dcl = append(xfunc.Func.Dcl, v) body = append(body, nod(OAS, v, cv)) } else { // Declare variable holding addresses taken from closure // and initialize in entry prologue. addr := newname(lookup("&" + v.Sym.Name)) addr.Type = types.NewPtr(v.Type) addr.SetClass(PAUTO) addr.Name.SetUsed(true) addr.Name.Curfn = xfunc xfunc.Func.Dcl = append(xfunc.Func.Dcl, addr) v.Name.Param.Heapaddr = addr if v.Name.Byval() { cv = nod(OADDR, cv, nil) } body = append(body, nod(OAS, addr, cv)) } } if len(body) > 0 { typecheckslice(body, ctxStmt) xfunc.Func.Enter.Set(body) xfunc.Func.SetNeedctxt(true) } } lineno = lno } // hasemptycvars reports whether closure clo has an // empty list of captured vars. func hasemptycvars(clo *Node) bool { xfunc := clo.Func.Closure return xfunc.Func.Cvars.Len() == 0 } // closuredebugruntimecheck applies boilerplate checks for debug flags // and compiling runtime func closuredebugruntimecheck(clo *Node) { if Debug_closure > 0 { xfunc := clo.Func.Closure if clo.Esc == EscHeap { Warnl(clo.Pos, "heap closure, captured vars = %v", xfunc.Func.Cvars) } else { Warnl(clo.Pos, "stack closure, captured vars = %v", xfunc.Func.Cvars) } } if compiling_runtime && clo.Esc == EscHeap { yyerrorl(clo.Pos, "heap-allocated closure, not allowed in runtime") } } // closureType returns the struct type used to hold all the information // needed in the closure for clo (clo must be a OCLOSURE node). // The address of a variable of the returned type can be cast to a func. func closureType(clo *Node) *types.Type { // Create closure in the form of a composite literal. // supposing the closure captures an int i and a string s // and has one float64 argument and no results, // the generated code looks like: // // clos = &struct{.F uintptr; i *int; s *string}{func.1, &i, &s} // // The use of the struct provides type information to the garbage // collector so that it can walk the closure. We could use (in this case) // [3]unsafe.Pointer instead, but that would leave the gc in the dark. // The information appears in the binary in the form of type descriptors; // the struct is unnamed so that closures in multiple packages with the // same struct type can share the descriptor. fields := []*Node{ namedfield(".F", types.Types[TUINTPTR]), } for _, v := range clo.Func.Closure.Func.Cvars.Slice() { typ := v.Type if !v.Name.Byval() { typ = types.NewPtr(typ) } fields = append(fields, symfield(v.Sym, typ)) } typ := tostruct(fields) typ.SetNoalg(true) return typ } func walkclosure(clo *Node, init *Nodes) *Node { xfunc := clo.Func.Closure // If no closure vars, don't bother wrapping. if hasemptycvars(clo) { if Debug_closure > 0 { Warnl(clo.Pos, "closure converted to global") } return xfunc.Func.Nname } closuredebugruntimecheck(clo) typ := closureType(clo) clos := nod(OCOMPLIT, nil, typenod(typ)) clos.Esc = clo.Esc clos.List.Set(append([]*Node{nod(OCFUNC, xfunc.Func.Nname, nil)}, clo.Func.Enter.Slice()...)) clos = nod(OADDR, clos, nil) clos.Esc = clo.Esc // Force type conversion from *struct to the func type. clos = convnop(clos, clo.Type) // non-escaping temp to use, if any. if x := prealloc[clo]; x != nil { if !types.Identical(typ, x.Type) { panic("closure type does not match order's assigned type") } clos.Left.Right = x delete(prealloc, clo) } return walkexpr(clos, init) } func typecheckpartialcall(fn *Node, sym *types.Sym) { switch fn.Op { case ODOTINTER, ODOTMETH: break default: Fatalf("invalid typecheckpartialcall") } // Create top-level function. xfunc := makepartialcall(fn, fn.Type, sym) fn.Func = xfunc.Func fn.Func.SetWrapper(true) fn.Right = newname(sym) fn.Op = OCALLPART fn.Type = xfunc.Type } // makepartialcall returns a DCLFUNC node representing the wrapper function (*-fm) needed // for partial calls. func makepartialcall(fn *Node, t0 *types.Type, meth *types.Sym) *Node { rcvrtype := fn.Left.Type sym := methodSymSuffix(rcvrtype, meth, "-fm") if sym.Uniq() { return asNode(sym.Def) } sym.SetUniq(true) savecurfn := Curfn saveLineNo := lineno Curfn = nil // Set line number equal to the line number where the method is declared. var m *types.Field if lookdot0(meth, rcvrtype, &m, false) == 1 && m.Pos.IsKnown() { lineno = m.Pos } // Note: !m.Pos.IsKnown() happens for method expressions where // the method is implicitly declared. The Error method of the // built-in error type is one such method. We leave the line // number at the use of the method expression in this // case. See issue 29389. tfn := nod(OTFUNC, nil, nil) tfn.List.Set(structargs(t0.Params(), true)) tfn.Rlist.Set(structargs(t0.Results(), false)) xfunc := dclfunc(sym, tfn) xfunc.Func.SetDupok(true) xfunc.Func.SetNeedctxt(true) tfn.Type.SetPkg(t0.Pkg()) // Declare and initialize variable holding receiver. cv := nod(OCLOSUREVAR, nil, nil) cv.Type = rcvrtype cv.Xoffset = Rnd(int64(Widthptr), int64(cv.Type.Align)) ptr := newname(lookup(".this")) declare(ptr, PAUTO) ptr.Name.SetUsed(true) var body []*Node if rcvrtype.IsPtr() || rcvrtype.IsInterface() { ptr.Type = rcvrtype body = append(body, nod(OAS, ptr, cv)) } else { ptr.Type = types.NewPtr(rcvrtype) body = append(body, nod(OAS, ptr, nod(OADDR, cv, nil))) } call := nod(OCALL, nodSym(OXDOT, ptr, meth), nil) call.List.Set(paramNnames(tfn.Type)) call.SetIsDDD(tfn.Type.IsVariadic()) if t0.NumResults() != 0 { n := nod(ORETURN, nil, nil) n.List.Set1(call) call = n } body = append(body, call) xfunc.Nbody.Set(body) funcbody() xfunc = typecheck(xfunc, ctxStmt) // Need to typecheck the body of the just-generated wrapper. // typecheckslice() requires that Curfn is set when processing an ORETURN. Curfn = xfunc typecheckslice(xfunc.Nbody.Slice(), ctxStmt) sym.Def = asTypesNode(xfunc) xtop = append(xtop, xfunc) Curfn = savecurfn lineno = saveLineNo return xfunc } // partialCallType returns the struct type used to hold all the information // needed in the closure for n (n must be a OCALLPART node). // The address of a variable of the returned type can be cast to a func. func partialCallType(n *Node) *types.Type { t := tostruct([]*Node{ namedfield("F", types.Types[TUINTPTR]), namedfield("R", n.Left.Type), }) t.SetNoalg(true) return t } func walkpartialcall(n *Node, init *Nodes) *Node { // Create closure in the form of a composite literal. // For x.M with receiver (x) type T, the generated code looks like: // // clos = &struct{F uintptr; R T}{T.M·f, x} // // Like walkclosure above. if n.Left.Type.IsInterface() { // Trigger panic for method on nil interface now. // Otherwise it happens in the wrapper and is confusing. n.Left = cheapexpr(n.Left, init) n.Left = walkexpr(n.Left, nil) tab := nod(OITAB, n.Left, nil) tab = typecheck(tab, ctxExpr) c := nod(OCHECKNIL, tab, nil) c.SetTypecheck(1) init.Append(c) } typ := partialCallType(n) clos := nod(OCOMPLIT, nil, typenod(typ)) clos.Esc = n.Esc clos.List.Set2(nod(OCFUNC, n.Func.Nname, nil), n.Left) clos = nod(OADDR, clos, nil) clos.Esc = n.Esc // Force type conversion from *struct to the func type. clos = convnop(clos, n.Type) // non-escaping temp to use, if any. if x := prealloc[n]; x != nil { if !types.Identical(typ, x.Type) { panic("partial call type does not match order's assigned type") } clos.Left.Right = x delete(prealloc, n) } return walkexpr(clos, init) } // callpartMethod returns the *types.Field representing the method // referenced by method value n. func callpartMethod(n *Node) *types.Field { if n.Op != OCALLPART { Fatalf("expected OCALLPART, got %v", n) } // TODO(mdempsky): Optimize this. If necessary, // makepartialcall could save m for us somewhere. var m *types.Field if lookdot0(n.Right.Sym, n.Left.Type, &m, false) != 1 { Fatalf("failed to find field for OCALLPART") } return m }