// 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. // “Abstract” syntax representation. package ir import ( "fmt" "go/constant" "cmd/compile/internal/base" "cmd/compile/internal/types" "cmd/internal/src" ) // A Node is the abstract interface to an IR node. type Node interface { // Formatting Format(s fmt.State, verb rune) // Source position. Pos() src.XPos SetPos(x src.XPos) // For making copies. For Copy and SepCopy. copy() Node doChildren(func(Node) bool) bool doChildrenWithHidden(func(Node) bool) bool editChildren(func(Node) Node) editChildrenWithHidden(func(Node) Node) // Abstract graph structure, for generic traversals. Op() Op Init() Nodes // Fields specific to certain Ops only. Type() *types.Type SetType(t *types.Type) Name() *Name Sym() *types.Sym Val() constant.Value SetVal(v constant.Value) // Storage for analysis passes. Esc() uint16 SetEsc(x uint16) // Typecheck values: // 0 means the node is not typechecked // 1 means the node is completely typechecked // 2 means typechecking of the node is in progress Typecheck() uint8 SetTypecheck(x uint8) NonNil() bool MarkNonNil() } // Line returns n's position as a string. If n has been inlined, // it uses the outermost position where n has been inlined. func Line(n Node) string { return base.FmtPos(n.Pos()) } func IsSynthetic(n Node) bool { name := n.Sym().Name return name[0] == '.' || name[0] == '~' } // IsAutoTmp indicates if n was created by the compiler as a temporary, // based on the setting of the .AutoTemp flag in n's Name. func IsAutoTmp(n Node) bool { if n == nil || n.Op() != ONAME { return false } return n.Name().AutoTemp() } // MayBeShared reports whether n may occur in multiple places in the AST. // Extra care must be taken when mutating such a node. func MayBeShared(n Node) bool { switch n.Op() { case ONAME, OLITERAL, ONIL, OTYPE: return true } return false } type InitNode interface { Node PtrInit() *Nodes SetInit(x Nodes) } func TakeInit(n Node) Nodes { init := n.Init() if len(init) != 0 { n.(InitNode).SetInit(nil) } return init } //go:generate stringer -type=Op -trimprefix=O node.go type Op uint8 // Node ops. const ( OXXX Op = iota // names ONAME // var or func name // Unnamed arg or return value: f(int, string) (int, error) { etc } // Also used for a qualified package identifier that hasn't been resolved yet. ONONAME OTYPE // type name OLITERAL // literal ONIL // nil // expressions OADD // X + Y OSUB // X - Y OOR // X | Y OXOR // X ^ Y OADDSTR // +{List} (string addition, list elements are strings) OADDR // &X OANDAND // X && Y OAPPEND // append(Args); after walk, X may contain elem type descriptor OBYTES2STR // Type(X) (Type is string, X is a []byte) OBYTES2STRTMP // Type(X) (Type is string, X is a []byte, ephemeral) ORUNES2STR // Type(X) (Type is string, X is a []rune) OSTR2BYTES // Type(X) (Type is []byte, X is a string) OSTR2BYTESTMP // Type(X) (Type is []byte, X is a string, ephemeral) OSTR2RUNES // Type(X) (Type is []rune, X is a string) OSLICE2ARR // Type(X) (Type is [N]T, X is a []T) OSLICE2ARRPTR // Type(X) (Type is *[N]T, X is a []T) // X = Y or (if Def=true) X := Y // If Def, then Init includes a DCL node for X. OAS // Lhs = Rhs (x, y, z = a, b, c) or (if Def=true) Lhs := Rhs // If Def, then Init includes DCL nodes for Lhs OAS2 OAS2DOTTYPE // Lhs = Rhs (x, ok = I.(int)) OAS2FUNC // Lhs = Rhs (x, y = f()) OAS2MAPR // Lhs = Rhs (x, ok = m["foo"]) OAS2RECV // Lhs = Rhs (x, ok = <-c) OASOP // X AsOp= Y (x += y) OCALL // X(Args) (function call, method call or type conversion) // OCALLFUNC, OCALLMETH, and OCALLINTER have the same structure. // Prior to walk, they are: X(Args), where Args is all regular arguments. // After walk, if any argument whose evaluation might requires temporary variable, // that temporary variable will be pushed to Init, Args will contain an updated // set of arguments. OCALLFUNC // X(Args) (function call f(args)) OCALLMETH // X(Args) (direct method call x.Method(args)) OCALLINTER // X(Args) (interface method call x.Method(args)) OCAP // cap(X) OCLEAR // clear(X) OCLOSE // close(X) OCLOSURE // func Type { Func.Closure.Body } (func literal) OCOMPLIT // Type{List} (composite literal, not yet lowered to specific form) OMAPLIT // Type{List} (composite literal, Type is map) OSTRUCTLIT // Type{List} (composite literal, Type is struct) OARRAYLIT // Type{List} (composite literal, Type is array) OSLICELIT // Type{List} (composite literal, Type is slice), Len is slice length. OPTRLIT // &X (X is composite literal) OCONV // Type(X) (type conversion) OCONVIFACE // Type(X) (type conversion, to interface) OCONVNOP // Type(X) (type conversion, no effect) OCOPY // copy(X, Y) ODCL // var X (declares X of type X.Type) // Used during parsing but don't last. ODCLFUNC // func f() or func (r) f() ODELETE // delete(Args) ODOT // X.Sel (X is of struct type) ODOTPTR // X.Sel (X is of pointer to struct type) ODOTMETH // X.Sel (X is non-interface, Sel is method name) ODOTINTER // X.Sel (X is interface, Sel is method name) OXDOT // X.Sel (before rewrite to one of the preceding) ODOTTYPE // X.Ntype or X.Type (.Ntype during parsing, .Type once resolved); after walk, Itab contains address of interface type descriptor and Itab.X contains address of concrete type descriptor ODOTTYPE2 // X.Ntype or X.Type (.Ntype during parsing, .Type once resolved; on rhs of OAS2DOTTYPE); after walk, Itab contains address of interface type descriptor OEQ // X == Y ONE // X != Y OLT // X < Y OLE // X <= Y OGE // X >= Y OGT // X > Y ODEREF // *X OINDEX // X[Index] (index of array or slice) OINDEXMAP // X[Index] (index of map) OKEY // Key:Value (key:value in struct/array/map literal) OSTRUCTKEY // Field:Value (key:value in struct literal, after type checking) OLEN // len(X) OMAKE // make(Args) (before type checking converts to one of the following) OMAKECHAN // make(Type[, Len]) (type is chan) OMAKEMAP // make(Type[, Len]) (type is map) OMAKESLICE // make(Type[, Len[, Cap]]) (type is slice) OMAKESLICECOPY // makeslicecopy(Type, Len, Cap) (type is slice; Len is length and Cap is the copied from slice) // OMAKESLICECOPY is created by the order pass and corresponds to: // s = make(Type, Len); copy(s, Cap) // // Bounded can be set on the node when Len == len(Cap) is known at compile time. // // This node is created so the walk pass can optimize this pattern which would // otherwise be hard to detect after the order pass. OMUL // X * Y ODIV // X / Y OMOD // X % Y OLSH // X << Y ORSH // X >> Y OAND // X & Y OANDNOT // X &^ Y ONEW // new(X); corresponds to calls to new in source code ONOT // !X OBITNOT // ^X OPLUS // +X ONEG // -X OOROR // X || Y OPANIC // panic(X) OPRINT // print(List) OPRINTLN // println(List) OPAREN // (X) OSEND // Chan <- Value OSLICE // X[Low : High] (X is untypechecked or slice) OSLICEARR // X[Low : High] (X is pointer to array) OSLICESTR // X[Low : High] (X is string) OSLICE3 // X[Low : High : Max] (X is untypedchecked or slice) OSLICE3ARR // X[Low : High : Max] (X is pointer to array) OSLICEHEADER // sliceheader{Ptr, Len, Cap} (Ptr is unsafe.Pointer, Len is length, Cap is capacity) OSTRINGHEADER // stringheader{Ptr, Len} (Ptr is unsafe.Pointer, Len is length) ORECOVER // recover() ORECOVERFP // recover(Args) w/ explicit FP argument ORECV // <-X ORUNESTR // Type(X) (Type is string, X is rune) OSELRECV2 // like OAS2: Lhs = Rhs where len(Lhs)=2, len(Rhs)=1, Rhs[0].Op = ORECV (appears as .Var of OCASE) OMIN // min(List) OMAX // max(List) OREAL // real(X) OIMAG // imag(X) OCOMPLEX // complex(X, Y) OUNSAFEADD // unsafe.Add(X, Y) OUNSAFESLICE // unsafe.Slice(X, Y) OUNSAFESLICEDATA // unsafe.SliceData(X) OUNSAFESTRING // unsafe.String(X, Y) OUNSAFESTRINGDATA // unsafe.StringData(X) OMETHEXPR // X(Args) (method expression T.Method(args), first argument is the method receiver) OMETHVALUE // X.Sel (method expression t.Method, not called) // statements OBLOCK // { List } (block of code) OBREAK // break [Label] // OCASE: case List: Body (List==nil means default) // For OTYPESW, List is a OTYPE node for the specified type (or OLITERAL // for nil) or an ODYNAMICTYPE indicating a runtime type for generics. // If a type-switch variable is specified, Var is an // ONAME for the version of the type-switch variable with the specified // type. OCASE OCONTINUE // continue [Label] ODEFER // defer Call OFALL // fallthrough OFOR // for Init; Cond; Post { Body } OGOTO // goto Label OIF // if Init; Cond { Then } else { Else } OLABEL // Label: OGO // go Call ORANGE // for Key, Value = range X { Body } ORETURN // return Results OSELECT // select { Cases } OSWITCH // switch Init; Expr { Cases } // OTYPESW: X := Y.(type) (appears as .Tag of OSWITCH) // X is nil if there is no type-switch variable OTYPESW // misc // intermediate representation of an inlined call. Uses Init (assignments // for the captured variables, parameters, retvars, & INLMARK op), // Body (body of the inlined function), and ReturnVars (list of // return values) OINLCALL // intermediary representation of an inlined call. OMAKEFACE // construct an interface value from rtype/itab and data pointers OITAB // rtype/itab pointer of an interface value OIDATA // data pointer of an interface value OSPTR // base pointer of a slice or string. Bounded==1 means known non-nil. OCFUNC // reference to c function pointer (not go func value) OCHECKNIL // emit code to ensure pointer/interface not nil ORESULT // result of a function call; Xoffset is stack offset OINLMARK // start of an inlined body, with file/line of caller. Xoffset is an index into the inline tree. OLINKSYMOFFSET // offset within a name OJUMPTABLE // A jump table structure for implementing dense expression switches OINTERFACESWITCH // A type switch with interface cases // opcodes for generics ODYNAMICDOTTYPE // x = i.(T) where T is a type parameter (or derived from a type parameter) ODYNAMICDOTTYPE2 // x, ok = i.(T) where T is a type parameter (or derived from a type parameter) ODYNAMICTYPE // a type node for type switches (represents a dynamic target type for a type switch) // arch-specific opcodes OTAILCALL // tail call to another function OGETG // runtime.getg() (read g pointer) OGETCALLERSP // internal/runtime/sys.GetCallerSP() (stack pointer in caller frame) OEND ) // IsCmp reports whether op is a comparison operation (==, !=, <, <=, // >, or >=). func (op Op) IsCmp() bool { switch op { case OEQ, ONE, OLT, OLE, OGT, OGE: return true } return false } // Nodes is a slice of Node. type Nodes []Node // ToNodes returns s as a slice of Nodes. func ToNodes[T Node](s []T) Nodes { res := make(Nodes, len(s)) for i, n := range s { res[i] = n } return res } // Append appends entries to Nodes. func (n *Nodes) Append(a ...Node) { if len(a) == 0 { return } *n = append(*n, a...) } // Prepend prepends entries to Nodes. // If a slice is passed in, this will take ownership of it. func (n *Nodes) Prepend(a ...Node) { if len(a) == 0 { return } *n = append(a, *n...) } // Take clears n, returning its former contents. func (n *Nodes) Take() []Node { ret := *n *n = nil return ret } // Copy returns a copy of the content of the slice. func (n Nodes) Copy() Nodes { if n == nil { return nil } c := make(Nodes, len(n)) copy(c, n) return c } // NameQueue is a FIFO queue of *Name. The zero value of NameQueue is // a ready-to-use empty queue. type NameQueue struct { ring []*Name head, tail int } // Empty reports whether q contains no Names. func (q *NameQueue) Empty() bool { return q.head == q.tail } // PushRight appends n to the right of the queue. func (q *NameQueue) PushRight(n *Name) { if len(q.ring) == 0 { q.ring = make([]*Name, 16) } else if q.head+len(q.ring) == q.tail { // Grow the ring. nring := make([]*Name, len(q.ring)*2) // Copy the old elements. part := q.ring[q.head%len(q.ring):] if q.tail-q.head <= len(part) { part = part[:q.tail-q.head] copy(nring, part) } else { pos := copy(nring, part) copy(nring[pos:], q.ring[:q.tail%len(q.ring)]) } q.ring, q.head, q.tail = nring, 0, q.tail-q.head } q.ring[q.tail%len(q.ring)] = n q.tail++ } // PopLeft pops a Name from the left of the queue. It panics if q is // empty. func (q *NameQueue) PopLeft() *Name { if q.Empty() { panic("dequeue empty") } n := q.ring[q.head%len(q.ring)] q.head++ return n } // NameSet is a set of Names. type NameSet map[*Name]struct{} // Has reports whether s contains n. func (s NameSet) Has(n *Name) bool { _, isPresent := s[n] return isPresent } // Add adds n to s. func (s *NameSet) Add(n *Name) { if *s == nil { *s = make(map[*Name]struct{}) } (*s)[n] = struct{}{} } type PragmaFlag uint16 const ( // Func pragmas. Nointerface PragmaFlag = 1 << iota Noescape // func parameters don't escape Norace // func must not have race detector annotations Nosplit // func should not execute on separate stack Noinline // func should not be inlined NoCheckPtr // func should not be instrumented by checkptr CgoUnsafeArgs // treat a pointer to one arg as a pointer to them all UintptrKeepAlive // pointers converted to uintptr must be kept alive UintptrEscapes // pointers converted to uintptr escape // Runtime-only func pragmas. // See ../../../../runtime/HACKING.md for detailed descriptions. Systemstack // func must run on system stack Nowritebarrier // emit compiler error instead of write barrier Nowritebarrierrec // error on write barrier in this or recursive callees Yeswritebarrierrec // cancels Nowritebarrierrec in this function and callees // Go command pragmas GoBuildPragma RegisterParams // TODO(register args) remove after register abi is working ) var BlankNode *Name func IsConst(n Node, ct constant.Kind) bool { return ConstType(n) == ct } // IsNil reports whether n represents the universal untyped zero value "nil". func IsNil(n Node) bool { return n != nil && n.Op() == ONIL } func IsBlank(n Node) bool { if n == nil { return false } return n.Sym().IsBlank() } // IsMethod reports whether n is a method. // n must be a function or a method. func IsMethod(n Node) bool { return n.Type().Recv() != nil } // HasUniquePos reports whether n has a unique position that can be // used for reporting error messages. // // It's primarily used to distinguish references to named objects, // whose Pos will point back to their declaration position rather than // their usage position. func HasUniquePos(n Node) bool { switch n.Op() { case ONAME: return false case OLITERAL, ONIL, OTYPE: if n.Sym() != nil { return false } } if !n.Pos().IsKnown() { if base.Flag.K != 0 { base.Warn("setlineno: unknown position (line 0)") } return false } return true } func SetPos(n Node) src.XPos { lno := base.Pos if n != nil && HasUniquePos(n) { base.Pos = n.Pos() } return lno } // The result of InitExpr MUST be assigned back to n, e.g. // // n.X = InitExpr(init, n.X) func InitExpr(init []Node, expr Node) Node { if len(init) == 0 { return expr } n, ok := expr.(InitNode) if !ok || MayBeShared(n) { // Introduce OCONVNOP to hold init list. n = NewConvExpr(base.Pos, OCONVNOP, nil, expr) n.SetType(expr.Type()) n.SetTypecheck(1) } n.PtrInit().Prepend(init...) return n } // what's the outer value that a write to n affects? // outer value means containing struct or array. func OuterValue(n Node) Node { for { switch nn := n; nn.Op() { case OXDOT: base.FatalfAt(n.Pos(), "OXDOT in OuterValue: %v", n) case ODOT: nn := nn.(*SelectorExpr) n = nn.X continue case OPAREN: nn := nn.(*ParenExpr) n = nn.X continue case OCONVNOP: nn := nn.(*ConvExpr) n = nn.X continue case OINDEX: nn := nn.(*IndexExpr) if nn.X.Type() == nil { base.Fatalf("OuterValue needs type for %v", nn.X) } if nn.X.Type().IsArray() { n = nn.X continue } } return n } } const ( EscUnknown = iota EscNone // Does not escape to heap, result, or parameters. EscHeap // Reachable from the heap EscNever // By construction will not escape. )