blob: 1e6d913ae644324ec56269d89380a962e4871c07 [file] [log] [blame]
// 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/types"
"cmd/internal/objabi"
"cmd/internal/sys"
"encoding/binary"
"fmt"
"strings"
)
// The constant is known to runtime.
const tmpstringbufsize = 32
const zeroValSize = 1024 // must match value of runtime/map.go:maxZero
func walk(fn *Node) {
Curfn = fn
if Debug['W'] != 0 {
s := fmt.Sprintf("\nbefore walk %v", Curfn.Func.Nname.Sym)
dumplist(s, Curfn.Nbody)
}
lno := lineno
// Final typecheck for any unused variables.
for i, ln := range fn.Func.Dcl {
if ln.Op == ONAME && (ln.Class() == PAUTO || ln.Class() == PAUTOHEAP) {
ln = typecheck(ln, ctxExpr|ctxAssign)
fn.Func.Dcl[i] = ln
}
}
// Propagate the used flag for typeswitch variables up to the NONAME in its definition.
for _, ln := range fn.Func.Dcl {
if ln.Op == ONAME && (ln.Class() == PAUTO || ln.Class() == PAUTOHEAP) && ln.Name.Defn != nil && ln.Name.Defn.Op == OTYPESW && ln.Name.Used() {
ln.Name.Defn.Left.Name.SetUsed(true)
}
}
for _, ln := range fn.Func.Dcl {
if ln.Op != ONAME || (ln.Class() != PAUTO && ln.Class() != PAUTOHEAP) || ln.Sym.Name[0] == '&' || ln.Name.Used() {
continue
}
if defn := ln.Name.Defn; defn != nil && defn.Op == OTYPESW {
if defn.Left.Name.Used() {
continue
}
yyerrorl(defn.Left.Pos, "%v declared but not used", ln.Sym)
defn.Left.Name.SetUsed(true) // suppress repeats
} else {
yyerrorl(ln.Pos, "%v declared but not used", ln.Sym)
}
}
lineno = lno
if nerrors != 0 {
return
}
walkstmtlist(Curfn.Nbody.Slice())
if Debug['W'] != 0 {
s := fmt.Sprintf("after walk %v", Curfn.Func.Nname.Sym)
dumplist(s, Curfn.Nbody)
}
zeroResults()
heapmoves()
if Debug['W'] != 0 && Curfn.Func.Enter.Len() > 0 {
s := fmt.Sprintf("enter %v", Curfn.Func.Nname.Sym)
dumplist(s, Curfn.Func.Enter)
}
}
func walkstmtlist(s []*Node) {
for i := range s {
s[i] = walkstmt(s[i])
}
}
func paramoutheap(fn *Node) bool {
for _, ln := range fn.Func.Dcl {
switch ln.Class() {
case PPARAMOUT:
if ln.isParamStackCopy() || ln.Name.Addrtaken() {
return true
}
case PAUTO:
// stop early - parameters are over
return false
}
}
return false
}
// The result of walkstmt MUST be assigned back to n, e.g.
// n.Left = walkstmt(n.Left)
func walkstmt(n *Node) *Node {
if n == nil {
return n
}
setlineno(n)
walkstmtlist(n.Ninit.Slice())
switch n.Op {
default:
if n.Op == ONAME {
yyerror("%v is not a top level statement", n.Sym)
} else {
yyerror("%v is not a top level statement", n.Op)
}
Dump("nottop", n)
case OAS,
OASOP,
OAS2,
OAS2DOTTYPE,
OAS2RECV,
OAS2FUNC,
OAS2MAPR,
OCLOSE,
OCOPY,
OCALLMETH,
OCALLINTER,
OCALL,
OCALLFUNC,
ODELETE,
OSEND,
OPRINT,
OPRINTN,
OPANIC,
OEMPTY,
ORECOVER,
OGETG:
if n.Typecheck() == 0 {
Fatalf("missing typecheck: %+v", n)
}
wascopy := n.Op == OCOPY
init := n.Ninit
n.Ninit.Set(nil)
n = walkexpr(n, &init)
n = addinit(n, init.Slice())
if wascopy && n.Op == OCONVNOP {
n.Op = OEMPTY // don't leave plain values as statements.
}
// special case for a receive where we throw away
// the value received.
case ORECV:
if n.Typecheck() == 0 {
Fatalf("missing typecheck: %+v", n)
}
init := n.Ninit
n.Ninit.Set(nil)
n.Left = walkexpr(n.Left, &init)
n = mkcall1(chanfn("chanrecv1", 2, n.Left.Type), nil, &init, n.Left, nodnil())
n = walkexpr(n, &init)
n = addinit(n, init.Slice())
case OBREAK,
OCONTINUE,
OFALL,
OGOTO,
OLABEL,
ODCLCONST,
ODCLTYPE,
OCHECKNIL,
OVARDEF,
OVARKILL,
OVARLIVE:
break
case ODCL:
v := n.Left
if v.Class() == PAUTOHEAP {
if compiling_runtime {
yyerror("%v escapes to heap, not allowed in runtime", v)
}
if prealloc[v] == nil {
prealloc[v] = callnew(v.Type)
}
nn := nod(OAS, v.Name.Param.Heapaddr, prealloc[v])
nn.SetColas(true)
nn = typecheck(nn, ctxStmt)
return walkstmt(nn)
}
case OBLOCK:
walkstmtlist(n.List.Slice())
case OCASE:
yyerror("case statement out of place")
case ODEFER:
Curfn.Func.SetHasDefer(true)
Curfn.Func.numDefers++
if Curfn.Func.numDefers > maxOpenDefers {
// Don't allow open-coded defers if there are more than
// 8 defers in the function, since we use a single
// byte to record active defers.
Curfn.Func.SetOpenCodedDeferDisallowed(true)
}
if n.Esc != EscNever {
// If n.Esc is not EscNever, then this defer occurs in a loop,
// so open-coded defers cannot be used in this function.
Curfn.Func.SetOpenCodedDeferDisallowed(true)
}
fallthrough
case OGO:
switch n.Left.Op {
case OPRINT, OPRINTN:
n.Left = wrapCall(n.Left, &n.Ninit)
case ODELETE:
if mapfast(n.Left.List.First().Type) == mapslow {
n.Left = wrapCall(n.Left, &n.Ninit)
} else {
n.Left = walkexpr(n.Left, &n.Ninit)
}
case OCOPY:
n.Left = copyany(n.Left, &n.Ninit, true)
default:
n.Left = walkexpr(n.Left, &n.Ninit)
}
case OFOR, OFORUNTIL:
if n.Left != nil {
walkstmtlist(n.Left.Ninit.Slice())
init := n.Left.Ninit
n.Left.Ninit.Set(nil)
n.Left = walkexpr(n.Left, &init)
n.Left = addinit(n.Left, init.Slice())
}
n.Right = walkstmt(n.Right)
if n.Op == OFORUNTIL {
walkstmtlist(n.List.Slice())
}
walkstmtlist(n.Nbody.Slice())
case OIF:
n.Left = walkexpr(n.Left, &n.Ninit)
walkstmtlist(n.Nbody.Slice())
walkstmtlist(n.Rlist.Slice())
case ORETURN:
Curfn.Func.numReturns++
if n.List.Len() == 0 {
break
}
if (Curfn.Type.FuncType().Outnamed && n.List.Len() > 1) || paramoutheap(Curfn) {
// assign to the function out parameters,
// so that reorder3 can fix up conflicts
var rl []*Node
for _, ln := range Curfn.Func.Dcl {
cl := ln.Class()
if cl == PAUTO || cl == PAUTOHEAP {
break
}
if cl == PPARAMOUT {
if ln.isParamStackCopy() {
ln = walkexpr(typecheck(nod(ODEREF, ln.Name.Param.Heapaddr, nil), ctxExpr), nil)
}
rl = append(rl, ln)
}
}
if got, want := n.List.Len(), len(rl); got != want {
// order should have rewritten multi-value function calls
// with explicit OAS2FUNC nodes.
Fatalf("expected %v return arguments, have %v", want, got)
}
// move function calls out, to make reorder3's job easier.
walkexprlistsafe(n.List.Slice(), &n.Ninit)
ll := ascompatee(n.Op, rl, n.List.Slice(), &n.Ninit)
n.List.Set(reorder3(ll))
break
}
walkexprlist(n.List.Slice(), &n.Ninit)
// For each return parameter (lhs), assign the corresponding result (rhs).
lhs := Curfn.Type.Results()
rhs := n.List.Slice()
res := make([]*Node, lhs.NumFields())
for i, nl := range lhs.FieldSlice() {
nname := asNode(nl.Nname)
if nname.isParamHeapCopy() {
nname = nname.Name.Param.Stackcopy
}
a := nod(OAS, nname, rhs[i])
res[i] = convas(a, &n.Ninit)
}
n.List.Set(res)
case ORETJMP:
break
case OINLMARK:
break
case OSELECT:
walkselect(n)
case OSWITCH:
walkswitch(n)
case ORANGE:
n = walkrange(n)
}
if n.Op == ONAME {
Fatalf("walkstmt ended up with name: %+v", n)
}
return n
}
func isSmallMakeSlice(n *Node) bool {
if n.Op != OMAKESLICE {
return false
}
r := n.Right
if r == nil {
r = n.Left
}
t := n.Type
return smallintconst(r) && (t.Elem().Width == 0 || r.Int64() < maxImplicitStackVarSize/t.Elem().Width)
}
// walk the whole tree of the body of an
// expression or simple statement.
// the types expressions are calculated.
// compile-time constants are evaluated.
// complex side effects like statements are appended to init
func walkexprlist(s []*Node, init *Nodes) {
for i := range s {
s[i] = walkexpr(s[i], init)
}
}
func walkexprlistsafe(s []*Node, init *Nodes) {
for i, n := range s {
s[i] = safeexpr(n, init)
s[i] = walkexpr(s[i], init)
}
}
func walkexprlistcheap(s []*Node, init *Nodes) {
for i, n := range s {
s[i] = cheapexpr(n, init)
s[i] = walkexpr(s[i], init)
}
}
// convFuncName builds the runtime function name for interface conversion.
// It also reports whether the function expects the data by address.
// Not all names are possible. For example, we never generate convE2E or convE2I.
func convFuncName(from, to *types.Type) (fnname string, needsaddr bool) {
tkind := to.Tie()
switch from.Tie() {
case 'I':
if tkind == 'I' {
return "convI2I", false
}
case 'T':
switch {
case from.Size() == 2 && from.Align == 2:
return "convT16", false
case from.Size() == 4 && from.Align == 4 && !types.Haspointers(from):
return "convT32", false
case from.Size() == 8 && from.Align == types.Types[TUINT64].Align && !types.Haspointers(from):
return "convT64", false
}
if sc := from.SoleComponent(); sc != nil {
switch {
case sc.IsString():
return "convTstring", false
case sc.IsSlice():
return "convTslice", false
}
}
switch tkind {
case 'E':
if !types.Haspointers(from) {
return "convT2Enoptr", true
}
return "convT2E", true
case 'I':
if !types.Haspointers(from) {
return "convT2Inoptr", true
}
return "convT2I", true
}
}
Fatalf("unknown conv func %c2%c", from.Tie(), to.Tie())
panic("unreachable")
}
// The result of walkexpr MUST be assigned back to n, e.g.
// n.Left = walkexpr(n.Left, init)
func walkexpr(n *Node, init *Nodes) *Node {
if n == nil {
return n
}
// Eagerly checkwidth all expressions for the back end.
if n.Type != nil && !n.Type.WidthCalculated() {
switch n.Type.Etype {
case TBLANK, TNIL, TIDEAL:
default:
checkwidth(n.Type)
}
}
if init == &n.Ninit {
// not okay to use n->ninit when walking n,
// because we might replace n with some other node
// and would lose the init list.
Fatalf("walkexpr init == &n->ninit")
}
if n.Ninit.Len() != 0 {
walkstmtlist(n.Ninit.Slice())
init.AppendNodes(&n.Ninit)
}
lno := setlineno(n)
if Debug['w'] > 1 {
Dump("before walk expr", n)
}
if n.Typecheck() != 1 {
Fatalf("missed typecheck: %+v", n)
}
if n.Type.IsUntyped() {
Fatalf("expression has untyped type: %+v", n)
}
if n.Op == ONAME && n.Class() == PAUTOHEAP {
nn := nod(ODEREF, n.Name.Param.Heapaddr, nil)
nn = typecheck(nn, ctxExpr)
nn = walkexpr(nn, init)
nn.Left.MarkNonNil()
return nn
}
opswitch:
switch n.Op {
default:
Dump("walk", n)
Fatalf("walkexpr: switch 1 unknown op %+S", n)
case ONONAME, OEMPTY, OGETG, ONEWOBJ:
case OTYPE, ONAME, OLITERAL:
// TODO(mdempsky): Just return n; see discussion on CL 38655.
// Perhaps refactor to use Node.mayBeShared for these instead.
// If these return early, make sure to still call
// stringsym for constant strings.
case ONOT, ONEG, OPLUS, OBITNOT, OREAL, OIMAG, ODOTMETH, ODOTINTER,
ODEREF, OSPTR, OITAB, OIDATA, OADDR:
n.Left = walkexpr(n.Left, init)
case OEFACE, OAND, OSUB, OMUL, OADD, OOR, OXOR, OLSH, ORSH:
n.Left = walkexpr(n.Left, init)
n.Right = walkexpr(n.Right, init)
case ODOT, ODOTPTR:
usefield(n)
n.Left = walkexpr(n.Left, init)
case ODOTTYPE, ODOTTYPE2:
n.Left = walkexpr(n.Left, init)
// Set up interface type addresses for back end.
n.Right = typename(n.Type)
if n.Op == ODOTTYPE {
n.Right.Right = typename(n.Left.Type)
}
if !n.Type.IsInterface() && !n.Left.Type.IsEmptyInterface() {
n.List.Set1(itabname(n.Type, n.Left.Type))
}
case OLEN, OCAP:
if isRuneCount(n) {
// Replace len([]rune(string)) with runtime.countrunes(string).
n = mkcall("countrunes", n.Type, init, conv(n.Left.Left, types.Types[TSTRING]))
break
}
n.Left = walkexpr(n.Left, init)
// replace len(*[10]int) with 10.
// delayed until now to preserve side effects.
t := n.Left.Type
if t.IsPtr() {
t = t.Elem()
}
if t.IsArray() {
safeexpr(n.Left, init)
setintconst(n, t.NumElem())
n.SetTypecheck(1)
}
case OCOMPLEX:
// Use results from call expression as arguments for complex.
if n.Left == nil && n.Right == nil {
n.Left = n.List.First()
n.Right = n.List.Second()
}
n.Left = walkexpr(n.Left, init)
n.Right = walkexpr(n.Right, init)
case OEQ, ONE, OLT, OLE, OGT, OGE:
n = walkcompare(n, init)
case OANDAND, OOROR:
n.Left = walkexpr(n.Left, init)
// cannot put side effects from n.Right on init,
// because they cannot run before n.Left is checked.
// save elsewhere and store on the eventual n.Right.
var ll Nodes
n.Right = walkexpr(n.Right, &ll)
n.Right = addinit(n.Right, ll.Slice())
case OPRINT, OPRINTN:
n = walkprint(n, init)
case OPANIC:
n = mkcall("gopanic", nil, init, n.Left)
case ORECOVER:
n = mkcall("gorecover", n.Type, init, nod(OADDR, nodfp, nil))
case OCLOSUREVAR, OCFUNC:
case OCALLINTER, OCALLFUNC, OCALLMETH:
if n.Op == OCALLINTER {
usemethod(n)
}
if n.Op == OCALLFUNC && n.Left.Op == OCLOSURE {
// Transform direct call of a closure to call of a normal function.
// transformclosure already did all preparation work.
// Prepend captured variables to argument list.
n.List.Prepend(n.Left.Func.Enter.Slice()...)
n.Left.Func.Enter.Set(nil)
// Replace OCLOSURE with ONAME/PFUNC.
n.Left = n.Left.Func.Closure.Func.Nname
// Update type of OCALLFUNC node.
// Output arguments had not changed, but their offsets could.
if n.Left.Type.NumResults() == 1 {
n.Type = n.Left.Type.Results().Field(0).Type
} else {
n.Type = n.Left.Type.Results()
}
}
walkCall(n, init)
case OAS, OASOP:
init.AppendNodes(&n.Ninit)
// Recognize m[k] = append(m[k], ...) so we can reuse
// the mapassign call.
mapAppend := n.Left.Op == OINDEXMAP && n.Right.Op == OAPPEND
if mapAppend && !samesafeexpr(n.Left, n.Right.List.First()) {
Fatalf("not same expressions: %v != %v", n.Left, n.Right.List.First())
}
n.Left = walkexpr(n.Left, init)
n.Left = safeexpr(n.Left, init)
if mapAppend {
n.Right.List.SetFirst(n.Left)
}
if n.Op == OASOP {
// Rewrite x op= y into x = x op y.
n.Right = nod(n.SubOp(), n.Left, n.Right)
n.Right = typecheck(n.Right, ctxExpr)
n.Op = OAS
n.ResetAux()
}
if oaslit(n, init) {
break
}
if n.Right == nil {
// TODO(austin): Check all "implicit zeroing"
break
}
if !instrumenting && isZero(n.Right) {
break
}
switch n.Right.Op {
default:
n.Right = walkexpr(n.Right, init)
case ORECV:
// x = <-c; n.Left is x, n.Right.Left is c.
// order.stmt made sure x is addressable.
n.Right.Left = walkexpr(n.Right.Left, init)
n1 := nod(OADDR, n.Left, nil)
r := n.Right.Left // the channel
n = mkcall1(chanfn("chanrecv1", 2, r.Type), nil, init, r, n1)
n = walkexpr(n, init)
break opswitch
case OAPPEND:
// x = append(...)
r := n.Right
if r.Type.Elem().NotInHeap() {
yyerror("%v is go:notinheap; heap allocation disallowed", r.Type.Elem())
}
switch {
case isAppendOfMake(r):
// x = append(y, make([]T, y)...)
r = extendslice(r, init)
case r.IsDDD():
r = appendslice(r, init) // also works for append(slice, string).
default:
r = walkappend(r, init, n)
}
n.Right = r
if r.Op == OAPPEND {
// Left in place for back end.
// Do not add a new write barrier.
// Set up address of type for back end.
r.Left = typename(r.Type.Elem())
break opswitch
}
// Otherwise, lowered for race detector.
// Treat as ordinary assignment.
}
if n.Left != nil && n.Right != nil {
n = convas(n, init)
}
case OAS2:
init.AppendNodes(&n.Ninit)
walkexprlistsafe(n.List.Slice(), init)
walkexprlistsafe(n.Rlist.Slice(), init)
ll := ascompatee(OAS, n.List.Slice(), n.Rlist.Slice(), init)
ll = reorder3(ll)
n = liststmt(ll)
// a,b,... = fn()
case OAS2FUNC:
init.AppendNodes(&n.Ninit)
r := n.Right
walkexprlistsafe(n.List.Slice(), init)
r = walkexpr(r, init)
if isIntrinsicCall(r) {
n.Right = r
break
}
init.Append(r)
ll := ascompatet(n.List, r.Type)
n = liststmt(ll)
// x, y = <-c
// order.stmt made sure x is addressable or blank.
case OAS2RECV:
init.AppendNodes(&n.Ninit)
r := n.Right
walkexprlistsafe(n.List.Slice(), init)
r.Left = walkexpr(r.Left, init)
var n1 *Node
if n.List.First().isBlank() {
n1 = nodnil()
} else {
n1 = nod(OADDR, n.List.First(), nil)
}
fn := chanfn("chanrecv2", 2, r.Left.Type)
ok := n.List.Second()
call := mkcall1(fn, types.Types[TBOOL], init, r.Left, n1)
n = nod(OAS, ok, call)
n = typecheck(n, ctxStmt)
// a,b = m[i]
case OAS2MAPR:
init.AppendNodes(&n.Ninit)
r := n.Right
walkexprlistsafe(n.List.Slice(), init)
r.Left = walkexpr(r.Left, init)
r.Right = walkexpr(r.Right, init)
t := r.Left.Type
fast := mapfast(t)
var key *Node
if fast != mapslow {
// fast versions take key by value
key = r.Right
} else {
// standard version takes key by reference
// order.expr made sure key is addressable.
key = nod(OADDR, r.Right, nil)
}
// from:
// a,b = m[i]
// to:
// var,b = mapaccess2*(t, m, i)
// a = *var
a := n.List.First()
if w := t.Elem().Width; w <= zeroValSize {
fn := mapfn(mapaccess2[fast], t)
r = mkcall1(fn, fn.Type.Results(), init, typename(t), r.Left, key)
} else {
fn := mapfn("mapaccess2_fat", t)
z := zeroaddr(w)
r = mkcall1(fn, fn.Type.Results(), init, typename(t), r.Left, key, z)
}
// mapaccess2* returns a typed bool, but due to spec changes,
// the boolean result of i.(T) is now untyped so we make it the
// same type as the variable on the lhs.
if ok := n.List.Second(); !ok.isBlank() && ok.Type.IsBoolean() {
r.Type.Field(1).Type = ok.Type
}
n.Right = r
n.Op = OAS2FUNC
// don't generate a = *var if a is _
if !a.isBlank() {
var_ := temp(types.NewPtr(t.Elem()))
var_.SetTypecheck(1)
var_.MarkNonNil() // mapaccess always returns a non-nil pointer
n.List.SetFirst(var_)
n = walkexpr(n, init)
init.Append(n)
n = nod(OAS, a, nod(ODEREF, var_, nil))
}
n = typecheck(n, ctxStmt)
n = walkexpr(n, init)
case ODELETE:
init.AppendNodes(&n.Ninit)
map_ := n.List.First()
key := n.List.Second()
map_ = walkexpr(map_, init)
key = walkexpr(key, init)
t := map_.Type
fast := mapfast(t)
if fast == mapslow {
// order.stmt made sure key is addressable.
key = nod(OADDR, key, nil)
}
n = mkcall1(mapfndel(mapdelete[fast], t), nil, init, typename(t), map_, key)
case OAS2DOTTYPE:
walkexprlistsafe(n.List.Slice(), init)
n.Right = walkexpr(n.Right, init)
case OCONVIFACE:
n.Left = walkexpr(n.Left, init)
fromType := n.Left.Type
toType := n.Type
// typeword generates the type word of the interface value.
typeword := func() *Node {
if toType.IsEmptyInterface() {
return typename(fromType)
}
return itabname(fromType, toType)
}
// Optimize convT2E or convT2I as a two-word copy when T is pointer-shaped.
if isdirectiface(fromType) {
l := nod(OEFACE, typeword(), n.Left)
l.Type = toType
l.SetTypecheck(n.Typecheck())
n = l
break
}
if staticuint64s == nil {
staticuint64s = newname(Runtimepkg.Lookup("staticuint64s"))
staticuint64s.SetClass(PEXTERN)
// The actual type is [256]uint64, but we use [256*8]uint8 so we can address
// individual bytes.
staticuint64s.Type = types.NewArray(types.Types[TUINT8], 256*8)
zerobase = newname(Runtimepkg.Lookup("zerobase"))
zerobase.SetClass(PEXTERN)
zerobase.Type = types.Types[TUINTPTR]
}
// Optimize convT2{E,I} for many cases in which T is not pointer-shaped,
// by using an existing addressable value identical to n.Left
// or creating one on the stack.
var value *Node
switch {
case fromType.Size() == 0:
// n.Left is zero-sized. Use zerobase.
cheapexpr(n.Left, init) // Evaluate n.Left for side-effects. See issue 19246.
value = zerobase
case fromType.IsBoolean() || (fromType.Size() == 1 && fromType.IsInteger()):
// n.Left is a bool/byte. Use staticuint64s[n.Left * 8] on little-endian
// and staticuint64s[n.Left * 8 + 7] on big-endian.
n.Left = cheapexpr(n.Left, init)
// byteindex widens n.Left so that the multiplication doesn't overflow.
index := nod(OLSH, byteindex(n.Left), nodintconst(3))
if thearch.LinkArch.ByteOrder == binary.BigEndian {
index = nod(OADD, index, nodintconst(7))
}
value = nod(OINDEX, staticuint64s, index)
value.SetBounded(true)
case n.Left.Class() == PEXTERN && n.Left.Name != nil && n.Left.Name.Readonly():
// n.Left is a readonly global; use it directly.
value = n.Left
case !fromType.IsInterface() && n.Esc == EscNone && fromType.Width <= 1024:
// n.Left does not escape. Use a stack temporary initialized to n.Left.
value = temp(fromType)
init.Append(typecheck(nod(OAS, value, n.Left), ctxStmt))
}
if value != nil {
// Value is identical to n.Left.
// Construct the interface directly: {type/itab, &value}.
l := nod(OEFACE, typeword(), typecheck(nod(OADDR, value, nil), ctxExpr))
l.Type = toType
l.SetTypecheck(n.Typecheck())
n = l
break
}
// Implement interface to empty interface conversion.
// tmp = i.itab
// if tmp != nil {
// tmp = tmp.type
// }
// e = iface{tmp, i.data}
if toType.IsEmptyInterface() && fromType.IsInterface() && !fromType.IsEmptyInterface() {
// Evaluate the input interface.
c := temp(fromType)
init.Append(nod(OAS, c, n.Left))
// Get the itab out of the interface.
tmp := temp(types.NewPtr(types.Types[TUINT8]))
init.Append(nod(OAS, tmp, typecheck(nod(OITAB, c, nil), ctxExpr)))
// Get the type out of the itab.
nif := nod(OIF, typecheck(nod(ONE, tmp, nodnil()), ctxExpr), nil)
nif.Nbody.Set1(nod(OAS, tmp, itabType(tmp)))
init.Append(nif)
// Build the result.
e := nod(OEFACE, tmp, ifaceData(n.Pos, c, types.NewPtr(types.Types[TUINT8])))
e.Type = toType // assign type manually, typecheck doesn't understand OEFACE.
e.SetTypecheck(1)
n = e
break
}
fnname, needsaddr := convFuncName(fromType, toType)
if !needsaddr && !fromType.IsInterface() {
// Use a specialized conversion routine that only returns a data pointer.
// ptr = convT2X(val)
// e = iface{typ/tab, ptr}
fn := syslook(fnname)
dowidth(fromType)
fn = substArgTypes(fn, fromType)
dowidth(fn.Type)
call := nod(OCALL, fn, nil)
call.List.Set1(n.Left)
call = typecheck(call, ctxExpr)
call = walkexpr(call, init)
call = safeexpr(call, init)
e := nod(OEFACE, typeword(), call)
e.Type = toType
e.SetTypecheck(1)
n = e
break
}
var tab *Node
if fromType.IsInterface() {
// convI2I
tab = typename(toType)
} else {
// convT2x
tab = typeword()
}
v := n.Left
if needsaddr {
// Types of large or unknown size are passed by reference.
// Orderexpr arranged for n.Left to be a temporary for all
// the conversions it could see. Comparison of an interface
// with a non-interface, especially in a switch on interface value
// with non-interface cases, is not visible to order.stmt, so we
// have to fall back on allocating a temp here.
if !islvalue(v) {
v = copyexpr(v, v.Type, init)
}
v = nod(OADDR, v, nil)
}
dowidth(fromType)
fn := syslook(fnname)
fn = substArgTypes(fn, fromType, toType)
dowidth(fn.Type)
n = nod(OCALL, fn, nil)
n.List.Set2(tab, v)
n = typecheck(n, ctxExpr)
n = walkexpr(n, init)
case OCONV, OCONVNOP:
n.Left = walkexpr(n.Left, init)
if n.Op == OCONVNOP && checkPtr(Curfn, 1) {
if n.Type.IsPtr() && n.Left.Type.Etype == TUNSAFEPTR { // unsafe.Pointer to *T
n = walkCheckPtrAlignment(n, init, nil)
break
}
if n.Type.Etype == TUNSAFEPTR && n.Left.Type.Etype == TUINTPTR { // uintptr to unsafe.Pointer
n = walkCheckPtrArithmetic(n, init)
break
}
}
param, result := rtconvfn(n.Left.Type, n.Type)
if param == Txxx {
break
}
fn := basicnames[param] + "to" + basicnames[result]
n = conv(mkcall(fn, types.Types[result], init, conv(n.Left, types.Types[param])), n.Type)
case OANDNOT:
n.Left = walkexpr(n.Left, init)
n.Op = OAND
n.Right = nod(OBITNOT, n.Right, nil)
n.Right = typecheck(n.Right, ctxExpr)
n.Right = walkexpr(n.Right, init)
case ODIV, OMOD:
n.Left = walkexpr(n.Left, init)
n.Right = walkexpr(n.Right, init)
// rewrite complex div into function call.
et := n.Left.Type.Etype
if isComplex[et] && n.Op == ODIV {
t := n.Type
n = mkcall("complex128div", types.Types[TCOMPLEX128], init, conv(n.Left, types.Types[TCOMPLEX128]), conv(n.Right, types.Types[TCOMPLEX128]))
n = conv(n, t)
break
}
// Nothing to do for float divisions.
if isFloat[et] {
break
}
// rewrite 64-bit div and mod on 32-bit architectures.
// TODO: Remove this code once we can introduce
// runtime calls late in SSA processing.
if Widthreg < 8 && (et == TINT64 || et == TUINT64) {
if n.Right.Op == OLITERAL {
// Leave div/mod by constant powers of 2.
// The SSA backend will handle those.
switch et {
case TINT64:
c := n.Right.Int64()
if c < 0 {
c = -c
}
if c != 0 && c&(c-1) == 0 {
break opswitch
}
case TUINT64:
c := uint64(n.Right.Int64())
if c != 0 && c&(c-1) == 0 {
break opswitch
}
}
}
var fn string
if et == TINT64 {
fn = "int64"
} else {
fn = "uint64"
}
if n.Op == ODIV {
fn += "div"
} else {
fn += "mod"
}
n = mkcall(fn, n.Type, init, conv(n.Left, types.Types[et]), conv(n.Right, types.Types[et]))
}
case OINDEX:
n.Left = walkexpr(n.Left, init)
// save the original node for bounds checking elision.
// If it was a ODIV/OMOD walk might rewrite it.
r := n.Right
n.Right = walkexpr(n.Right, init)
// if range of type cannot exceed static array bound,
// disable bounds check.
if n.Bounded() {
break
}
t := n.Left.Type
if t != nil && t.IsPtr() {
t = t.Elem()
}
if t.IsArray() {
n.SetBounded(bounded(r, t.NumElem()))
if Debug['m'] != 0 && n.Bounded() && !Isconst(n.Right, CTINT) {
Warn("index bounds check elided")
}
if smallintconst(n.Right) && !n.Bounded() {
yyerror("index out of bounds")
}
} else if Isconst(n.Left, CTSTR) {
n.SetBounded(bounded(r, int64(len(strlit(n.Left)))))
if Debug['m'] != 0 && n.Bounded() && !Isconst(n.Right, CTINT) {
Warn("index bounds check elided")
}
if smallintconst(n.Right) && !n.Bounded() {
yyerror("index out of bounds")
}
}
if Isconst(n.Right, CTINT) {
if n.Right.Val().U.(*Mpint).CmpInt64(0) < 0 || n.Right.Val().U.(*Mpint).Cmp(maxintval[TINT]) > 0 {
yyerror("index out of bounds")
}
}
case OINDEXMAP:
// Replace m[k] with *map{access1,assign}(maptype, m, &k)
n.Left = walkexpr(n.Left, init)
n.Right = walkexpr(n.Right, init)
map_ := n.Left
key := n.Right
t := map_.Type
if n.IndexMapLValue() {
// This m[k] expression is on the left-hand side of an assignment.
fast := mapfast(t)
if fast == mapslow {
// standard version takes key by reference.
// order.expr made sure key is addressable.
key = nod(OADDR, key, nil)
}
n = mkcall1(mapfn(mapassign[fast], t), nil, init, typename(t), map_, key)
} else {
// m[k] is not the target of an assignment.
fast := mapfast(t)
if fast == mapslow {
// standard version takes key by reference.
// order.expr made sure key is addressable.
key = nod(OADDR, key, nil)
}
if w := t.Elem().Width; w <= zeroValSize {
n = mkcall1(mapfn(mapaccess1[fast], t), types.NewPtr(t.Elem()), init, typename(t), map_, key)
} else {
z := zeroaddr(w)
n = mkcall1(mapfn("mapaccess1_fat", t), types.NewPtr(t.Elem()), init, typename(t), map_, key, z)
}
}
n.Type = types.NewPtr(t.Elem())
n.MarkNonNil() // mapaccess1* and mapassign always return non-nil pointers.
n = nod(ODEREF, n, nil)
n.Type = t.Elem()
n.SetTypecheck(1)
case ORECV:
Fatalf("walkexpr ORECV") // should see inside OAS only
case OSLICEHEADER:
n.Left = walkexpr(n.Left, init)
n.List.SetFirst(walkexpr(n.List.First(), init))
n.List.SetSecond(walkexpr(n.List.Second(), init))
case OSLICE, OSLICEARR, OSLICESTR, OSLICE3, OSLICE3ARR:
checkSlice := checkPtr(Curfn, 1) && n.Op == OSLICE3ARR && n.Left.Op == OCONVNOP && n.Left.Left.Type.Etype == TUNSAFEPTR
if checkSlice {
n.Left.Left = walkexpr(n.Left.Left, init)
} else {
n.Left = walkexpr(n.Left, init)
}
low, high, max := n.SliceBounds()
low = walkexpr(low, init)
if low != nil && isZero(low) {
// Reduce x[0:j] to x[:j] and x[0:j:k] to x[:j:k].
low = nil
}
high = walkexpr(high, init)
max = walkexpr(max, init)
n.SetSliceBounds(low, high, max)
if checkSlice {
n.Left = walkCheckPtrAlignment(n.Left, init, max)
}
if n.Op.IsSlice3() {
if max != nil && max.Op == OCAP && samesafeexpr(n.Left, max.Left) {
// Reduce x[i:j:cap(x)] to x[i:j].
if n.Op == OSLICE3 {
n.Op = OSLICE
} else {
n.Op = OSLICEARR
}
n = reduceSlice(n)
}
} else {
n = reduceSlice(n)
}
case ONEW:
if n.Esc == EscNone {
if n.Type.Elem().Width >= maxImplicitStackVarSize {
Fatalf("large ONEW with EscNone: %v", n)
}
r := temp(n.Type.Elem())
r = nod(OAS, r, nil) // zero temp
r = typecheck(r, ctxStmt)
init.Append(r)
r = nod(OADDR, r.Left, nil)
r = typecheck(r, ctxExpr)
n = r
} else {
n = callnew(n.Type.Elem())
}
case OADDSTR:
n = addstr(n, init)
case OAPPEND:
// order should make sure we only see OAS(node, OAPPEND), which we handle above.
Fatalf("append outside assignment")
case OCOPY:
n = copyany(n, init, instrumenting && !compiling_runtime)
// cannot use chanfn - closechan takes any, not chan any
case OCLOSE:
fn := syslook("closechan")
fn = substArgTypes(fn, n.Left.Type)
n = mkcall1(fn, nil, init, n.Left)
case OMAKECHAN:
// When size fits into int, use makechan instead of
// makechan64, which is faster and shorter on 32 bit platforms.
size := n.Left
fnname := "makechan64"
argtype := types.Types[TINT64]
// Type checking guarantees that TIDEAL size is positive and fits in an int.
// The case of size overflow when converting TUINT or TUINTPTR to TINT
// will be handled by the negative range checks in makechan during runtime.
if size.Type.IsKind(TIDEAL) || maxintval[size.Type.Etype].Cmp(maxintval[TUINT]) <= 0 {
fnname = "makechan"
argtype = types.Types[TINT]
}
n = mkcall1(chanfn(fnname, 1, n.Type), n.Type, init, typename(n.Type), conv(size, argtype))
case OMAKEMAP:
t := n.Type
hmapType := hmap(t)
hint := n.Left
// var h *hmap
var h *Node
if n.Esc == EscNone {
// Allocate hmap on stack.
// var hv hmap
hv := temp(hmapType)
zero := nod(OAS, hv, nil)
zero = typecheck(zero, ctxStmt)
init.Append(zero)
// h = &hv
h = nod(OADDR, hv, nil)
// Allocate one bucket pointed to by hmap.buckets on stack if hint
// is not larger than BUCKETSIZE. In case hint is larger than
// BUCKETSIZE runtime.makemap will allocate the buckets on the heap.
// Maximum key and elem size is 128 bytes, larger objects
// are stored with an indirection. So max bucket size is 2048+eps.
if !Isconst(hint, CTINT) ||
hint.Val().U.(*Mpint).CmpInt64(BUCKETSIZE) <= 0 {
// In case hint is larger than BUCKETSIZE runtime.makemap
// will allocate the buckets on the heap, see #20184
//
// if hint <= BUCKETSIZE {
// var bv bmap
// b = &bv
// h.buckets = b
// }
nif := nod(OIF, nod(OLE, hint, nodintconst(BUCKETSIZE)), nil)
nif.SetLikely(true)
// var bv bmap
bv := temp(bmap(t))
zero = nod(OAS, bv, nil)
nif.Nbody.Append(zero)
// b = &bv
b := nod(OADDR, bv, nil)
// h.buckets = b
bsym := hmapType.Field(5).Sym // hmap.buckets see reflect.go:hmap
na := nod(OAS, nodSym(ODOT, h, bsym), b)
nif.Nbody.Append(na)
nif = typecheck(nif, ctxStmt)
nif = walkstmt(nif)
init.Append(nif)
}
}
if Isconst(hint, CTINT) && hint.Val().U.(*Mpint).CmpInt64(BUCKETSIZE) <= 0 {
// Handling make(map[any]any) and
// make(map[any]any, hint) where hint <= BUCKETSIZE
// special allows for faster map initialization and
// improves binary size by using calls with fewer arguments.
// For hint <= BUCKETSIZE overLoadFactor(hint, 0) is false
// and no buckets will be allocated by makemap. Therefore,
// no buckets need to be allocated in this code path.
if n.Esc == EscNone {
// Only need to initialize h.hash0 since
// hmap h has been allocated on the stack already.
// h.hash0 = fastrand()
rand := mkcall("fastrand", types.Types[TUINT32], init)
hashsym := hmapType.Field(4).Sym // hmap.hash0 see reflect.go:hmap
a := nod(OAS, nodSym(ODOT, h, hashsym), rand)
a = typecheck(a, ctxStmt)
a = walkexpr(a, init)
init.Append(a)
n = convnop(h, t)
} else {
// Call runtime.makehmap to allocate an
// hmap on the heap and initialize hmap's hash0 field.
fn := syslook("makemap_small")
fn = substArgTypes(fn, t.Key(), t.Elem())
n = mkcall1(fn, n.Type, init)
}
} else {
if n.Esc != EscNone {
h = nodnil()
}
// Map initialization with a variable or large hint is
// more complicated. We therefore generate a call to
// runtime.makemap to initialize hmap and allocate the
// map buckets.
// When hint fits into int, use makemap instead of
// makemap64, which is faster and shorter on 32 bit platforms.
fnname := "makemap64"
argtype := types.Types[TINT64]
// Type checking guarantees that TIDEAL hint is positive and fits in an int.
// See checkmake call in TMAP case of OMAKE case in OpSwitch in typecheck1 function.
// The case of hint overflow when converting TUINT or TUINTPTR to TINT
// will be handled by the negative range checks in makemap during runtime.
if hint.Type.IsKind(TIDEAL) || maxintval[hint.Type.Etype].Cmp(maxintval[TUINT]) <= 0 {
fnname = "makemap"
argtype = types.Types[TINT]
}
fn := syslook(fnname)
fn = substArgTypes(fn, hmapType, t.Key(), t.Elem())
n = mkcall1(fn, n.Type, init, typename(n.Type), conv(hint, argtype), h)
}
case OMAKESLICE:
l := n.Left
r := n.Right
if r == nil {
r = safeexpr(l, init)
l = r
}
t := n.Type
if n.Esc == EscNone {
if !isSmallMakeSlice(n) {
Fatalf("non-small OMAKESLICE with EscNone: %v", n)
}
// var arr [r]T
// n = arr[:l]
i := indexconst(r)
if i < 0 {
Fatalf("walkexpr: invalid index %v", r)
}
// cap is constrained to [0,2^31) or [0,2^63) depending on whether
// we're in 32-bit or 64-bit systems. So it's safe to do:
//
// if uint64(len) > cap {
// if len < 0 { panicmakeslicelen() }
// panicmakeslicecap()
// }
nif := nod(OIF, nod(OGT, conv(l, types.Types[TUINT64]), nodintconst(i)), nil)
niflen := nod(OIF, nod(OLT, l, nodintconst(0)), nil)
niflen.Nbody.Set1(mkcall("panicmakeslicelen", nil, init))
nif.Nbody.Append(niflen, mkcall("panicmakeslicecap", nil, init))
nif = typecheck(nif, ctxStmt)
init.Append(nif)
t = types.NewArray(t.Elem(), i) // [r]T
var_ := temp(t)
a := nod(OAS, var_, nil) // zero temp
a = typecheck(a, ctxStmt)
init.Append(a)
r := nod(OSLICE, var_, nil) // arr[:l]
r.SetSliceBounds(nil, l, nil)
r = conv(r, n.Type) // in case n.Type is named.
r = typecheck(r, ctxExpr)
r = walkexpr(r, init)
n = r
} else {
// n escapes; set up a call to makeslice.
// When len and cap can fit into int, use makeslice instead of
// makeslice64, which is faster and shorter on 32 bit platforms.
if t.Elem().NotInHeap() {
yyerror("%v is go:notinheap; heap allocation disallowed", t.Elem())
}
len, cap := l, r
fnname := "makeslice64"
argtype := types.Types[TINT64]
// Type checking guarantees that TIDEAL len/cap are positive and fit in an int.
// The case of len or cap overflow when converting TUINT or TUINTPTR to TINT
// will be handled by the negative range checks in makeslice during runtime.
if (len.Type.IsKind(TIDEAL) || maxintval[len.Type.Etype].Cmp(maxintval[TUINT]) <= 0) &&
(cap.Type.IsKind(TIDEAL) || maxintval[cap.Type.Etype].Cmp(maxintval[TUINT]) <= 0) {
fnname = "makeslice"
argtype = types.Types[TINT]
}
m := nod(OSLICEHEADER, nil, nil)
m.Type = t
fn := syslook(fnname)
m.Left = mkcall1(fn, types.Types[TUNSAFEPTR], init, typename(t.Elem()), conv(len, argtype), conv(cap, argtype))
m.Left.MarkNonNil()
m.List.Set2(conv(len, types.Types[TINT]), conv(cap, types.Types[TINT]))
m = typecheck(m, ctxExpr)
m = walkexpr(m, init)
n = m
}
case OMAKESLICECOPY:
if n.Esc == EscNone {
Fatalf("OMAKESLICECOPY with EscNone: %v", n)
}
t := n.Type
if t.Elem().NotInHeap() {
Fatalf("%v is go:notinheap; heap allocation disallowed", t.Elem())
}
length := conv(n.Left, types.Types[TINT])
copylen := nod(OLEN, n.Right, nil)
copyptr := nod(OSPTR, n.Right, nil)
if !types.Haspointers(t.Elem()) && n.Bounded() {
// When len(to)==len(from) and elements have no pointers:
// replace make+copy with runtime.mallocgc+runtime.memmove.
// We do not check for overflow of len(to)*elem.Width here
// since len(from) is an existing checked slice capacity
// with same elem.Width for the from slice.
size := nod(OMUL, conv(length, types.Types[TUINTPTR]), conv(nodintconst(t.Elem().Width), types.Types[TUINTPTR]))
// instantiate mallocgc(size uintptr, typ *byte, needszero bool) unsafe.Pointer
fn := syslook("mallocgc")
sh := nod(OSLICEHEADER, nil, nil)
sh.Left = mkcall1(fn, types.Types[TUNSAFEPTR], init, size, nodnil(), nodbool(false))
sh.Left.MarkNonNil()
sh.List.Set2(length, length)
sh.Type = t
s := temp(t)
r := typecheck(nod(OAS, s, sh), ctxStmt)
r = walkexpr(r, init)
init.Append(r)
// instantiate memmove(to *any, frm *any, size uintptr)
fn = syslook("memmove")
fn = substArgTypes(fn, t.Elem(), t.Elem())
ncopy := mkcall1(fn, nil, init, nod(OSPTR, s, nil), copyptr, size)
ncopy = typecheck(ncopy, ctxStmt)
ncopy = walkexpr(ncopy, init)
init.Append(ncopy)
n = s
} else { // Replace make+copy with runtime.makeslicecopy.
// instantiate makeslicecopy(typ *byte, tolen int, fromlen int, from unsafe.Pointer) unsafe.Pointer
fn := syslook("makeslicecopy")
s := nod(OSLICEHEADER, nil, nil)
s.Left = mkcall1(fn, types.Types[TUNSAFEPTR], init, typename(t.Elem()), length, copylen, conv(copyptr, types.Types[TUNSAFEPTR]))
s.Left.MarkNonNil()
s.List.Set2(length, length)
s.Type = t
n = typecheck(s, ctxExpr)
n = walkexpr(n, init)
}
case ORUNESTR:
a := nodnil()
if n.Esc == EscNone {
t := types.NewArray(types.Types[TUINT8], 4)
a = nod(OADDR, temp(t), nil)
}
// intstring(*[4]byte, rune)
n = mkcall("intstring", n.Type, init, a, conv(n.Left, types.Types[TINT64]))
case OBYTES2STR, ORUNES2STR:
a := nodnil()
if n.Esc == EscNone {
// Create temporary buffer for string on stack.
t := types.NewArray(types.Types[TUINT8], tmpstringbufsize)
a = nod(OADDR, temp(t), nil)
}
if n.Op == ORUNES2STR {
// slicerunetostring(*[32]byte, []rune) string
n = mkcall("slicerunetostring", n.Type, init, a, n.Left)
} else {
// slicebytetostring(*[32]byte, ptr *byte, n int) string
n.Left = cheapexpr(n.Left, init)
ptr, len := n.Left.slicePtrLen()
n = mkcall("slicebytetostring", n.Type, init, a, ptr, len)
}
case OBYTES2STRTMP:
n.Left = walkexpr(n.Left, init)
if !instrumenting {
// Let the backend handle OBYTES2STRTMP directly
// to avoid a function call to slicebytetostringtmp.
break
}
// slicebytetostringtmp(ptr *byte, n int) string
n.Left = cheapexpr(n.Left, init)
ptr, len := n.Left.slicePtrLen()
n = mkcall("slicebytetostringtmp", n.Type, init, ptr, len)
case OSTR2BYTES:
s := n.Left
if Isconst(s, CTSTR) {
sc := strlit(s)
// Allocate a [n]byte of the right size.
t := types.NewArray(types.Types[TUINT8], int64(len(sc)))
var a *Node
if n.Esc == EscNone && len(sc) <= int(maxImplicitStackVarSize) {
a = nod(OADDR, temp(t), nil)
} else {
a = callnew(t)
}
p := temp(t.PtrTo()) // *[n]byte
init.Append(typecheck(nod(OAS, p, a), ctxStmt))
// Copy from the static string data to the [n]byte.
if len(sc) > 0 {
as := nod(OAS,
nod(ODEREF, p, nil),
nod(ODEREF, convnop(nod(OSPTR, s, nil), t.PtrTo()), nil))
as = typecheck(as, ctxStmt)
as = walkstmt(as)
init.Append(as)
}
// Slice the [n]byte to a []byte.
n.Op = OSLICEARR
n.Left = p
n = walkexpr(n, init)
break
}
a := nodnil()
if n.Esc == EscNone {
// Create temporary buffer for slice on stack.
t := types.NewArray(types.Types[TUINT8], tmpstringbufsize)
a = nod(OADDR, temp(t), nil)
}
// stringtoslicebyte(*32[byte], string) []byte
n = mkcall("stringtoslicebyte", n.Type, init, a, conv(s, types.Types[TSTRING]))
case OSTR2BYTESTMP:
// []byte(string) conversion that creates a slice
// referring to the actual string bytes.
// This conversion is handled later by the backend and
// is only for use by internal compiler optimizations
// that know that the slice won't be mutated.
// The only such case today is:
// for i, c := range []byte(string)
n.Left = walkexpr(n.Left, init)
case OSTR2RUNES:
a := nodnil()
if n.Esc == EscNone {
// Create temporary buffer for slice on stack.
t := types.NewArray(types.Types[TINT32], tmpstringbufsize)
a = nod(OADDR, temp(t), nil)
}
// stringtoslicerune(*[32]rune, string) []rune
n = mkcall("stringtoslicerune", n.Type, init, a, conv(n.Left, types.Types[TSTRING]))
case OARRAYLIT, OSLICELIT, OMAPLIT, OSTRUCTLIT, OPTRLIT:
if isStaticCompositeLiteral(n) && !canSSAType(n.Type) {
// n can be directly represented in the read-only data section.
// Make direct reference to the static data. See issue 12841.
vstat := staticname(n.Type)
vstat.MarkReadonly()
fixedlit(inInitFunction, initKindStatic, n, vstat, init)
n = vstat
n = typecheck(n, ctxExpr)
break
}
var_ := temp(n.Type)
anylit(n, var_, init)
n = var_
case OSEND:
n1 := n.Right
n1 = assignconv(n1, n.Left.Type.Elem(), "chan send")
n1 = walkexpr(n1, init)
n1 = nod(OADDR, n1, nil)
n = mkcall1(chanfn("chansend1", 2, n.Left.Type), nil, init, n.Left, n1)
case OCLOSURE:
n = walkclosure(n, init)
case OCALLPART:
n = walkpartialcall(n, init)
}
// Expressions that are constant at run time but not
// considered const by the language spec are not turned into
// constants until walk. For example, if n is y%1 == 0, the
// walk of y%1 may have replaced it by 0.
// Check whether n with its updated args is itself now a constant.
t := n.Type
evconst(n)
if n.Type != t {
Fatalf("evconst changed Type: %v had type %v, now %v", n, t, n.Type)
}
if n.Op == OLITERAL {
n = typecheck(n, ctxExpr)
// Emit string symbol now to avoid emitting
// any concurrently during the backend.
if s, ok := n.Val().U.(string); ok {
_ = stringsym(n.Pos, s)
}
}
updateHasCall(n)
if Debug['w'] != 0 && n != nil {
Dump("after walk expr", n)
}
lineno = lno
return n
}
// rtconvfn returns the parameter and result types that will be used by a
// runtime function to convert from type src to type dst. The runtime function
// name can be derived from the names of the returned types.
//
// If no such function is necessary, it returns (Txxx, Txxx).
func rtconvfn(src, dst *types.Type) (param, result types.EType) {
if thearch.SoftFloat {
return Txxx, Txxx
}
switch thearch.LinkArch.Family {
case sys.ARM, sys.MIPS:
if src.IsFloat() {
switch dst.Etype {
case TINT64, TUINT64:
return TFLOAT64, dst.Etype
}
}
if dst.IsFloat() {
switch src.Etype {
case TINT64, TUINT64:
return src.Etype, TFLOAT64
}
}
case sys.I386:
if src.IsFloat() {
switch dst.Etype {
case TINT64, TUINT64:
return TFLOAT64, dst.Etype
case TUINT32, TUINT, TUINTPTR:
return TFLOAT64, TUINT32
}
}
if dst.IsFloat() {
switch src.Etype {
case TINT64, TUINT64:
return src.Etype, TFLOAT64
case TUINT32, TUINT, TUINTPTR:
return TUINT32, TFLOAT64
}
}
}
return Txxx, Txxx
}
// TODO(josharian): combine this with its caller and simplify
func reduceSlice(n *Node) *Node {
low, high, max := n.SliceBounds()
if high != nil && high.Op == OLEN && samesafeexpr(n.Left, high.Left) {
// Reduce x[i:len(x)] to x[i:].
high = nil
}
n.SetSliceBounds(low, high, max)
if (n.Op == OSLICE || n.Op == OSLICESTR) && low == nil && high == nil {
// Reduce x[:] to x.
if Debug_slice > 0 {
Warn("slice: omit slice operation")
}
return n.Left
}
return n
}
func ascompatee1(l *Node, r *Node, init *Nodes) *Node {
// convas will turn map assigns into function calls,
// making it impossible for reorder3 to work.
n := nod(OAS, l, r)
if l.Op == OINDEXMAP {
return n
}
return convas(n, init)
}
func ascompatee(op Op, nl, nr []*Node, init *Nodes) []*Node {
// check assign expression list to
// an expression list. called in
// expr-list = expr-list
// ensure order of evaluation for function calls
for i := range nl {
nl[i] = safeexpr(nl[i], init)
}
for i1 := range nr {
nr[i1] = safeexpr(nr[i1], init)
}
var nn []*Node
i := 0
for ; i < len(nl); i++ {
if i >= len(nr) {
break
}
// Do not generate 'x = x' during return. See issue 4014.
if op == ORETURN && samesafeexpr(nl[i], nr[i]) {
continue
}
nn = append(nn, ascompatee1(nl[i], nr[i], init))
}
// cannot happen: caller checked that lists had same length
if i < len(nl) || i < len(nr) {
var nln, nrn Nodes
nln.Set(nl)
nrn.Set(nr)
Fatalf("error in shape across %+v %v %+v / %d %d [%s]", nln, op, nrn, len(nl), len(nr), Curfn.funcname())
}
return nn
}
// fncall reports whether assigning an rvalue of type rt to an lvalue l might involve a function call.
func fncall(l *Node, rt *types.Type) bool {
if l.HasCall() || l.Op == OINDEXMAP {
return true
}
if types.Identical(l.Type, rt) {
return false
}
// There might be a conversion required, which might involve a runtime call.
return true
}
// check assign type list to
// an expression list. called in
// expr-list = func()
func ascompatet(nl Nodes, nr *types.Type) []*Node {
if nl.Len() != nr.NumFields() {
Fatalf("ascompatet: assignment count mismatch: %d = %d", nl.Len(), nr.NumFields())
}
var nn, mm Nodes
for i, l := range nl.Slice() {
if l.isBlank() {
continue
}
r := nr.Field(i)
// Any assignment to an lvalue that might cause a function call must be
// deferred until all the returned values have been read.
if fncall(l, r.Type) {
tmp := temp(r.Type)
tmp = typecheck(tmp, ctxExpr)
a := nod(OAS, l, tmp)
a = convas(a, &mm)
mm.Append(a)
l = tmp
}
res := nod(ORESULT, nil, nil)
res.Xoffset = Ctxt.FixedFrameSize() + r.Offset
res.Type = r.Type
res.SetTypecheck(1)
a := nod(OAS, l, res)
a = convas(a, &nn)
updateHasCall(a)
if a.HasCall() {
Dump("ascompatet ucount", a)
Fatalf("ascompatet: too many function calls evaluating parameters")
}
nn.Append(a)
}
return append(nn.Slice(), mm.Slice()...)
}
// package all the arguments that match a ... T parameter into a []T.
func mkdotargslice(typ *types.Type, args []*Node) *Node {
var n *Node
if len(args) == 0 {
n = nodnil()
n.Type = typ
} else {
n = nod(OCOMPLIT, nil, typenod(typ))
n.List.Append(args...)
n.SetImplicit(true)
}
n = typecheck(n, ctxExpr)
if n.Type == nil {
Fatalf("mkdotargslice: typecheck failed")
}
return n
}
// fixVariadicCall rewrites calls to variadic functions to use an
// explicit ... argument if one is not already present.
func fixVariadicCall(call *Node) {
fntype := call.Left.Type
if !fntype.IsVariadic() || call.IsDDD() {
return
}
vi := fntype.NumParams() - 1
vt := fntype.Params().Field(vi).Type
args := call.List.Slice()
extra := args[vi:]
slice := mkdotargslice(vt, extra)
for i := range extra {
extra[i] = nil // allow GC
}
call.List.Set(append(args[:vi], slice))
call.SetIsDDD(true)
}
func walkCall(n *Node, init *Nodes) {
if n.Rlist.Len() != 0 {
return // already walked
}
params := n.Left.Type.Params()
args := n.List.Slice()
n.Left = walkexpr(n.Left, init)
walkexprlist(args, init)
// If this is a method call, add the receiver at the beginning of the args.
if n.Op == OCALLMETH {
withRecv := make([]*Node, len(args)+1)
withRecv[0] = n.Left.Left
n.Left.Left = nil
copy(withRecv[1:], args)
args = withRecv
}
// For any argument whose evaluation might require a function call,
// store that argument into a temporary variable,
// to prevent that calls from clobbering arguments already on the stack.
// When instrumenting, all arguments might require function calls.
var tempAssigns []*Node
for i, arg := range args {
updateHasCall(arg)
// Determine param type.
var t *types.Type
if n.Op == OCALLMETH {
if i == 0 {
t = n.Left.Type.Recv().Type
} else {
t = params.Field(i - 1).Type
}
} else {
t = params.Field(i).Type
}
if instrumenting || fncall(arg, t) {
// make assignment of fncall to tempAt
tmp := temp(t)
a := nod(OAS, tmp, arg)
a = convas(a, init)
tempAssigns = append(tempAssigns, a)
// replace arg with temp
args[i] = tmp
}
}
n.List.Set(tempAssigns)
n.Rlist.Set(args)
}
// generate code for print
func walkprint(nn *Node, init *Nodes) *Node {
// Hoist all the argument evaluation up before the lock.
walkexprlistcheap(nn.List.Slice(), init)
// For println, add " " between elements and "\n" at the end.
if nn.Op == OPRINTN {
s := nn.List.Slice()
t := make([]*Node, 0, len(s)*2)
for i, n := range s {
if i != 0 {
t = append(t, nodstr(" "))
}
t = append(t, n)
}
t = append(t, nodstr("\n"))
nn.List.Set(t)
}
// Collapse runs of constant strings.
s := nn.List.Slice()
t := make([]*Node, 0, len(s))
for i := 0; i < len(s); {
var strs []string
for i < len(s) && Isconst(s[i], CTSTR) {
strs = append(strs, strlit(s[i]))
i++
}
if len(strs) > 0 {
t = append(t, nodstr(strings.Join(strs, "")))
}
if i < len(s) {
t = append(t, s[i])
i++
}
}
nn.List.Set(t)
calls := []*Node{mkcall("printlock", nil, init)}
for i, n := range nn.List.Slice() {
if n.Op == OLITERAL {
switch n.Val().Ctype() {
case CTRUNE:
n = defaultlit(n, types.Runetype)
case CTINT:
n = defaultlit(n, types.Types[TINT64])
case CTFLT:
n = defaultlit(n, types.Types[TFLOAT64])
}
}
if n.Op != OLITERAL && n.Type != nil && n.Type.Etype == TIDEAL {
n = defaultlit(n, types.Types[TINT64])
}
n = defaultlit(n, nil)
nn.List.SetIndex(i, n)
if n.Type == nil || n.Type.Etype == TFORW {
continue
}
var on *Node
switch n.Type.Etype {
case TINTER:
if n.Type.IsEmptyInterface() {
on = syslook("printeface")
} else {
on = syslook("printiface")
}
on = substArgTypes(on, n.Type) // any-1
case TPTR, TCHAN, TMAP, TFUNC, TUNSAFEPTR:
on = syslook("printpointer")
on = substArgTypes(on, n.Type) // any-1
case TSLICE:
on = syslook("printslice")
on = substArgTypes(on, n.Type) // any-1
case TUINT, TUINT8, TUINT16, TUINT32, TUINT64, TUINTPTR:
if isRuntimePkg(n.Type.Sym.Pkg) && n.Type.Sym.Name == "hex" {
on = syslook("printhex")
} else {
on = syslook("printuint")
}
case TINT, TINT8, TINT16, TINT32, TINT64:
on = syslook("printint")
case TFLOAT32, TFLOAT64:
on = syslook("printfloat")
case TCOMPLEX64, TCOMPLEX128:
on = syslook("printcomplex")
case TBOOL:
on = syslook("printbool")
case TSTRING:
cs := ""
if Isconst(n, CTSTR) {
cs = strlit(n)
}
switch cs {
case " ":
on = syslook("printsp")
case "\n":
on = syslook("printnl")
default:
on = syslook("printstring")
}
default:
badtype(OPRINT, n.Type, nil)
continue
}
r := nod(OCALL, on, nil)
if params := on.Type.Params().FieldSlice(); len(params) > 0 {
t := params[0].Type
if !types.Identical(t, n.Type) {
n = nod(OCONV, n, nil)
n.Type = t
}
r.List.Append(n)
}
calls = append(calls, r)
}
calls = append(calls, mkcall("printunlock", nil, init))
typecheckslice(calls, ctxStmt)
walkexprlist(calls, init)
r := nod(OEMPTY, nil, nil)
r = typecheck(r, ctxStmt)
r = walkexpr(r, init)
r.Ninit.Set(calls)
return r
}
func callnew(t *types.Type) *Node {
if t.NotInHeap() {
yyerror("%v is go:notinheap; heap allocation disallowed", t)
}
dowidth(t)
n := nod(ONEWOBJ, typename(t), nil)
n.Type = types.NewPtr(t)
n.SetTypecheck(1)
n.MarkNonNil()
return n
}
// isReflectHeaderDataField reports whether l is an expression p.Data
// where p has type reflect.SliceHeader or reflect.StringHeader.
func isReflectHeaderDataField(l *Node) bool {
if l.Type != types.Types[TUINTPTR] {
return false
}
var tsym *types.Sym
switch l.Op {
case ODOT:
tsym = l.Left.Type.Sym
case ODOTPTR:
tsym = l.Left.Type.Elem().Sym
default:
return false
}
if tsym == nil || l.Sym.Name != "Data" || tsym.Pkg.Path != "reflect" {
return false
}
return tsym.Name == "SliceHeader" || tsym.Name == "StringHeader"
}
func convas(n *Node, init *Nodes) *Node {
if n.Op != OAS {
Fatalf("convas: not OAS %v", n.Op)
}
defer updateHasCall(n)
n.SetTypecheck(1)
if n.Left == nil || n.Right == nil {
return n
}
lt := n.Left.Type
rt := n.Right.Type
if lt == nil || rt == nil {
return n
}
if n.Left.isBlank() {
n.Right = defaultlit(n.Right, nil)
return n
}
if !types.Identical(lt, rt) {
n.Right = assignconv(n.Right, lt, "assignment")
n.Right = walkexpr(n.Right, init)
}
dowidth(n.Right.Type)
return n
}
// from ascompat[ee]
// a,b = c,d
// simultaneous assignment. there cannot
// be later use of an earlier lvalue.
//
// function calls have been removed.
func reorder3(all []*Node) []*Node {
// If a needed expression may be affected by an
// earlier assignment, make an early copy of that
// expression and use the copy instead.
var early []*Node
var mapinit Nodes
for i, n := range all {
l := n.Left
// Save subexpressions needed on left side.
// Drill through non-dereferences.
for {
if l.Op == ODOT || l.Op == OPAREN {
l = l.Left
continue
}
if l.Op == OINDEX && l.Left.Type.IsArray() {
l.Right = reorder3save(l.Right, all, i, &early)
l = l.Left
continue
}
break
}
switch l.Op {
default:
Fatalf("reorder3 unexpected lvalue %#v", l.Op)
case ONAME:
break
case OINDEX, OINDEXMAP:
l.Left = reorder3save(l.Left, all, i, &early)
l.Right = reorder3save(l.Right, all, i, &early)
if l.Op == OINDEXMAP {
all[i] = convas(all[i], &mapinit)
}
case ODEREF, ODOTPTR:
l.Left = reorder3save(l.Left, all, i, &early)
}
// Save expression on right side.
all[i].Right = reorder3save(all[i].Right, all, i, &early)
}
early = append(mapinit.Slice(), early...)
return append(early, all...)
}
// if the evaluation of *np would be affected by the
// assignments in all up to but not including the ith assignment,
// copy into a temporary during *early and
// replace *np with that temp.
// The result of reorder3save MUST be assigned back to n, e.g.
// n.Left = reorder3save(n.Left, all, i, early)
func reorder3save(n *Node, all []*Node, i int, early *[]*Node) *Node {
if !aliased(n, all, i) {
return n
}
q := temp(n.Type)
q = nod(OAS, q, n)
q = typecheck(q, ctxStmt)
*early = append(*early, q)
return q.Left
}
// 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 n.Op {
case OXDOT:
Fatalf("OXDOT in walk")
case ODOT, OPAREN, OCONVNOP:
n = n.Left
continue
case OINDEX:
if n.Left.Type != nil && n.Left.Type.IsArray() {
n = n.Left
continue
}
}
return n
}
}
// Is it possible that the computation of n might be
// affected by writes in as up to but not including the ith element?
func aliased(n *Node, all []*Node, i int) bool {
if n == nil {
return false
}
// Treat all fields of a struct as referring to the whole struct.
// We could do better but we would have to keep track of the fields.
for n.Op == ODOT {
n = n.Left
}
// Look for obvious aliasing: a variable being assigned
// during the all list and appearing in n.
// Also record whether there are any writes to main memory.
// Also record whether there are any writes to variables
// whose addresses have been taken.
memwrite := false
varwrite := false
for _, an := range all[:i] {
a := outervalue(an.Left)
for a.Op == ODOT {
a = a.Left
}
if a.Op != ONAME {
memwrite = true
continue
}
switch n.Class() {
default:
varwrite = true
continue
case PAUTO, PPARAM, PPARAMOUT:
if n.Name.Addrtaken() {
varwrite = true
continue
}
if vmatch2(a, n) {
// Direct hit.
return true
}
}
}
// The variables being written do not appear in n.
// However, n might refer to computed addresses
// that are being written.
// If no computed addresses are affected by the writes, no aliasing.
if !memwrite && !varwrite {
return false
}
// If n does not refer to computed addresses
// (that is, if n only refers to variables whose addresses
// have not been taken), no aliasing.
if varexpr(n) {
return false
}
// Otherwise, both the writes and n refer to computed memory addresses.
// Assume that they might conflict.
return true
}
// does the evaluation of n only refer to variables
// whose addresses have not been taken?
// (and no other memory)
func varexpr(n *Node) bool {
if n == nil {
return true
}
switch n.Op {
case OLITERAL:
return true
case ONAME:
switch n.Class() {
case PAUTO, PPARAM, PPARAMOUT:
if !n.Name.Addrtaken() {
return true
}
}
return false
case OADD,
OSUB,
OOR,
OXOR,
OMUL,
ODIV,
OMOD,
OLSH,
ORSH,
OAND,
OANDNOT,
OPLUS,
ONEG,
OBITNOT,
OPAREN,
OANDAND,
OOROR,
OCONV,
OCONVNOP,
OCONVIFACE,
ODOTTYPE:
return varexpr(n.Left) && varexpr(n.Right)
case ODOT: // but not ODOTPTR
// Should have been handled in aliased.
Fatalf("varexpr unexpected ODOT")
}
// Be conservative.
return false
}
// is the name l mentioned in r?
func vmatch2(l *Node, r *Node) bool {
if r == nil {
return false
}
switch r.Op {
// match each right given left
case ONAME:
return l == r
case OLITERAL:
return false
}
if vmatch2(l, r.Left) {
return true
}
if vmatch2(l, r.Right) {
return true
}
for _, n := range r.List.Slice() {
if vmatch2(l, n) {
return true
}
}
return false
}
// is any name mentioned in l also mentioned in r?
// called by sinit.go
func vmatch1(l *Node, r *Node) bool {
// isolate all left sides
if l == nil || r == nil {
return false
}
switch l.Op {
case ONAME:
switch l.Class() {
case PPARAM, PAUTO:
break
default:
// assignment to non-stack variable must be
// delayed if right has function calls.
if r.HasCall() {
return true
}
}
return vmatch2(l, r)
case OLITERAL:
return false
}
if vmatch1(l.Left, r) {
return true
}
if vmatch1(l.Right, r) {
return true
}
for _, n := range l.List.Slice() {
if vmatch1(n, r) {
return true
}
}
return false
}
// paramstoheap returns code to allocate memory for heap-escaped parameters
// and to copy non-result parameters' values from the stack.
func paramstoheap(params *types.Type) []*Node {
var nn []*Node
for _, t := range params.Fields().Slice() {
v := asNode(t.Nname)
if v != nil && v.Sym != nil && strings.HasPrefix(v.Sym.Name, "~r") { // unnamed result
v = nil
}
if v == nil {
continue
}
if stackcopy := v.Name.Param.Stackcopy; stackcopy != nil {
nn = append(nn, walkstmt(nod(ODCL, v, nil)))
if stackcopy.Class() == PPARAM {
nn = append(nn, walkstmt(typecheck(nod(OAS, v, stackcopy), ctxStmt)))
}
}
}
return nn
}
// zeroResults zeros the return values at the start of the function.
// We need to do this very early in the function. Defer might stop a
// panic and show the return values as they exist at the time of
// panic. For precise stacks, the garbage collector assumes results
// are always live, so we need to zero them before any allocations,
// even allocations to move params/results to the heap.
// The generated code is added to Curfn's Enter list.
func zeroResults() {
for _, f := range Curfn.Type.Results().Fields().Slice() {
v := asNode(f.Nname)
if v != nil && v.Name.Param.Heapaddr != nil {
// The local which points to the return value is the
// thing that needs zeroing. This is already handled
// by a Needzero annotation in plive.go:livenessepilogue.
continue
}
if v.isParamHeapCopy() {
// TODO(josharian/khr): Investigate whether we can switch to "continue" here,
// and document more in either case.
// In the review of CL 114797, Keith wrote (roughly):
// I don't think the zeroing below matters.
// The stack return value will never be marked as live anywhere in the function.
// It is not written to until deferreturn returns.
v = v.Name.Param.Stackcopy
}
// Zero the stack location containing f.
Curfn.Func.Enter.Append(nodl(Curfn.Pos, OAS, v, nil))
}
}
// returnsfromheap returns code to copy values for heap-escaped parameters
// back to the stack.
func returnsfromheap(params *types.Type) []*Node {
var nn []*Node
for _, t := range params.Fields().Slice() {
v := asNode(t.Nname)
if v == nil {
continue
}
if stackcopy := v.Name.Param.Stackcopy; stackcopy != nil && stackcopy.Class() == PPARAMOUT {
nn = append(nn, walkstmt(typecheck(nod(OAS, stackcopy, v), ctxStmt)))
}
}
return nn
}
// heapmoves generates code to handle migrating heap-escaped parameters
// between the stack and the heap. The generated code is added to Curfn's
// Enter and Exit lists.
func heapmoves() {
lno := lineno
lineno = Curfn.Pos
nn := paramstoheap(Curfn.Type.Recvs())
nn = append(nn, paramstoheap(Curfn.Type.Params())...)
nn = append(nn, paramstoheap(Curfn.Type.Results())...)
Curfn.Func.Enter.Append(nn...)
lineno = Curfn.Func.Endlineno
Curfn.Func.Exit.Append(returnsfromheap(Curfn.Type.Results())...)
lineno = lno
}
func vmkcall(fn *Node, t *types.Type, init *Nodes, va []*Node) *Node {
if fn.Type == nil || fn.Type.Etype != TFUNC {
Fatalf("mkcall %v %v", fn, fn.Type)
}
n := fn.Type.NumParams()
if n != len(va) {
Fatalf("vmkcall %v needs %v args got %v", fn, n, len(va))
}
r := nod(OCALL, fn, nil)
r.List.Set(va)
if fn.Type.NumResults() > 0 {
r = typecheck(r, ctxExpr|ctxMultiOK)
} else {
r = typecheck(r, ctxStmt)
}
r = walkexpr(r, init)
r.Type = t
return r
}
func mkcall(name string, t *types.Type, init *Nodes, args ...*Node) *Node {
return vmkcall(syslook(name), t, init, args)
}
func mkcall1(fn *Node, t *types.Type, init *Nodes, args ...*Node) *Node {
return vmkcall(fn, t, init, args)
}
func conv(n *Node, t *types.Type) *Node {
if types.Identical(n.Type, t) {
return n
}
n = nod(OCONV, n, nil)
n.Type = t
n = typecheck(n, ctxExpr)
return n
}
// convnop converts node n to type t using the OCONVNOP op
// and typechecks the result with ctxExpr.
func convnop(n *Node, t *types.Type) *Node {
if types.Identical(n.Type, t) {
return n
}
n = nod(OCONVNOP, n, nil)
n.Type = t
n = typecheck(n, ctxExpr)
return n
}
// byteindex converts n, which is byte-sized, to an int used to index into an array.
// We cannot use conv, because we allow converting bool to int here,
// which is forbidden in user code.
func byteindex(n *Node) *Node {
// We cannot convert from bool to int directly.
// While converting from int8 to int is possible, it would yield
// the wrong result for negative values.
// Reinterpreting the value as an unsigned byte solves both cases.
if !types.Identical(n.Type, types.Types[TUINT8]) {
n = nod(OCONV, n, nil)
n.Type = types.Types[TUINT8]
n.SetTypecheck(1)
}
n = nod(OCONV, n, nil)
n.Type = types.Types[TINT]
n.SetTypecheck(1)
return n
}
func chanfn(name string, n int, t *types.Type) *Node {
if !t.IsChan() {
Fatalf("chanfn %v", t)
}
fn := syslook(name)
switch n {
default:
Fatalf("chanfn %d", n)
case 1:
fn = substArgTypes(fn, t.Elem())
case 2:
fn = substArgTypes(fn, t.Elem(), t.Elem())
}
return fn
}
func mapfn(name string, t *types.Type) *Node {
if !t.IsMap() {
Fatalf("mapfn %v", t)
}
fn := syslook(name)
fn = substArgTypes(fn, t.Key(), t.Elem(), t.Key(), t.Elem())
return fn
}
func mapfndel(name string, t *types.Type) *Node {
if !t.IsMap() {
Fatalf("mapfn %v", t)
}
fn := syslook(name)
fn = substArgTypes(fn, t.Key(), t.Elem(), t.Key())
return fn
}
const (
mapslow = iota
mapfast32
mapfast32ptr
mapfast64
mapfast64ptr
mapfaststr
nmapfast
)
type mapnames [nmapfast]string
func mkmapnames(base string, ptr string) mapnames {
return mapnames{base, base + "_fast32", base + "_fast32" + ptr, base + "_fast64", base + "_fast64" + ptr, base + "_faststr"}
}
var mapaccess1 = mkmapnames("mapaccess1", "")
var mapaccess2 = mkmapnames("mapaccess2", "")
var mapassign = mkmapnames("mapassign", "ptr")
var mapdelete = mkmapnames("mapdelete", "")
func mapfast(t *types.Type) int {
// Check runtime/map.go:maxElemSize before changing.
if t.Elem().Width > 128 {
return mapslow
}
switch algtype(t.Key()) {
case AMEM32:
if !t.Key().HasHeapPointer() {
return mapfast32
}
if Widthptr == 4 {
return mapfast32ptr
}
Fatalf("small pointer %v", t.Key())
case AMEM64:
if !t.Key().HasHeapPointer() {
return mapfast64
}
if Widthptr == 8 {
return mapfast64ptr
}
// Two-word object, at least one of which is a pointer.
// Use the slow path.
case ASTRING:
return mapfaststr
}
return mapslow
}
func writebarrierfn(name string, l *types.Type, r *types.Type) *Node {
fn := syslook(name)
fn = substArgTypes(fn, l, r)
return fn
}
func addstr(n *Node, init *Nodes) *Node {
// order.expr rewrote OADDSTR to have a list of strings.
c := n.List.Len()
if c < 2 {
Fatalf("addstr count %d too small", c)
}
buf := nodnil()
if n.Esc == EscNone {
sz := int64(0)
for _, n1 := range n.List.Slice() {
if n1.Op == OLITERAL {
sz += int64(len(strlit(n1)))
}
}
// Don't allocate the buffer if the result won't fit.
if sz < tmpstringbufsize {
// Create temporary buffer for result string on stack.
t := types.NewArray(types.Types[TUINT8], tmpstringbufsize)
buf = nod(OADDR, temp(t), nil)
}
}
// build list of string arguments
args := []*Node{buf}
for _, n2 := range n.List.Slice() {
args = append(args, conv(n2, types.Types[TSTRING]))
}
var fn string
if c <= 5 {
// small numbers of strings use direct runtime helpers.
// note: order.expr knows this cutoff too.
fn = fmt.Sprintf("concatstring%d", c)
} else {
// large numbers of strings are passed to the runtime as a slice.
fn = "concatstrings"
t := types.NewSlice(types.Types[TSTRING])
slice := nod(OCOMPLIT, nil, typenod(t))
if prealloc[n] != nil {
prealloc[slice] = prealloc[n]
}
slice.List.Set(args[1:]) // skip buf arg
args = []*Node{buf, slice}
slice.Esc = EscNone
}
cat := syslook(fn)
r := nod(OCALL, cat, nil)
r.List.Set(args)
r = typecheck(r, ctxExpr)
r = walkexpr(r, init)
r.Type = n.Type
return r
}
func walkAppendArgs(n *Node, init *Nodes) {
walkexprlistsafe(n.List.Slice(), init)
// walkexprlistsafe will leave OINDEX (s[n]) alone if both s
// and n are name or literal, but those may index the slice we're
// modifying here. Fix explicitly.
ls := n.List.Slice()
for i1, n1 := range ls {
ls[i1] = cheapexpr(n1, init)
}
}
// expand append(l1, l2...) to
// init {
// s := l1
// n := len(s) + len(l2)
// // Compare as uint so growslice can panic on overflow.
// if uint(n) > uint(cap(s)) {
// s = growslice(s, n)
// }
// s = s[:n]
// memmove(&s[len(l1)], &l2[0], len(l2)*sizeof(T))
// }
// s
//
// l2 is allowed to be a string.
func appendslice(n *Node, init *Nodes) *Node {
walkAppendArgs(n, init)
l1 := n.List.First()
l2 := n.List.Second()
l2 = cheapexpr(l2, init)
n.List.SetSecond(l2)
var nodes Nodes
// var s []T
s := temp(l1.Type)
nodes.Append(nod(OAS, s, l1)) // s = l1
elemtype := s.Type.Elem()
// n := len(s) + len(l2)
nn := temp(types.Types[TINT])
nodes.Append(nod(OAS, nn, nod(OADD, nod(OLEN, s, nil), nod(OLEN, l2, nil))))
// if uint(n) > uint(cap(s))
nif := nod(OIF, nil, nil)
nuint := conv(nn, types.Types[TUINT])
scapuint := conv(nod(OCAP, s, nil), types.Types[TUINT])
nif.Left = nod(OGT, nuint, scapuint)
// instantiate growslice(typ *type, []any, int) []any
fn := syslook("growslice")
fn = substArgTypes(fn, elemtype, elemtype)
// s = growslice(T, s, n)
nif.Nbody.Set1(nod(OAS, s, mkcall1(fn, s.Type, &nif.Ninit, typename(elemtype), s, nn)))
nodes.Append(nif)
// s = s[:n]
nt := nod(OSLICE, s, nil)
nt.SetSliceBounds(nil, nn, nil)
nt.SetBounded(true)
nodes.Append(nod(OAS, s, nt))
var ncopy *Node
if elemtype.HasHeapPointer() {
// copy(s[len(l1):], l2)
nptr1 := nod(OSLICE, s, nil)
nptr1.Type = s.Type
nptr1.SetSliceBounds(nod(OLEN, l1, nil), nil, nil)
nptr1 = cheapexpr(nptr1, &nodes)
nptr2 := l2
Curfn.Func.setWBPos(n.Pos)
// instantiate typedslicecopy(typ *type, dstPtr *any, dstLen int, srcPtr *any, srcLen int) int
fn := syslook("typedslicecopy")
fn = substArgTypes(fn, l1.Type.Elem(), l2.Type.Elem())
ptr1, len1 := nptr1.slicePtrLen()
ptr2, len2 := nptr2.slicePtrLen()
ncopy = mkcall1(fn, types.Types[TINT], &nodes, typename(elemtype), ptr1, len1, ptr2, len2)
} else if instrumenting && !compiling_runtime {
// rely on runtime to instrument copy.
// copy(s[len(l1):], l2)
nptr1 := nod(OSLICE, s, nil)
nptr1.Type = s.Type
nptr1.SetSliceBounds(nod(OLEN, l1, nil), nil, nil)
nptr1 = cheapexpr(nptr1, &nodes)
nptr2 := l2
if l2.Type.IsString() {
// instantiate func slicestringcopy(toPtr *byte, toLen int, fr string) int
fn := syslook("slicestringcopy")
ptr, len := nptr1.slicePtrLen()
str := nod(OCONVNOP, nptr2, nil)
str.Type = types.Types[TSTRING]
ncopy = mkcall1(fn, types.Types[TINT], &nodes, ptr, len, str)
} else {
// instantiate func slicecopy(to any, fr any, wid uintptr) int
fn := syslook("slicecopy")
fn = substArgTypes(fn, l1.Type.Elem(), l2.Type.Elem())
ptr1, len1 := nptr1.slicePtrLen()
ptr2, len2 := nptr2.slicePtrLen()
ncopy = mkcall1(fn, types.Types[TINT], &nodes, ptr1, len1, ptr2, len2, nodintconst(elemtype.Width))
}
} else {
// memmove(&s[len(l1)], &l2[0], len(l2)*sizeof(T))
nptr1 := nod(OINDEX, s, nod(OLEN, l1, nil))
nptr1.SetBounded(true)
nptr1 = nod(OADDR, nptr1, nil)
nptr2 := nod(OSPTR, l2, nil)
nwid := cheapexpr(conv(nod(OLEN, l2, nil), types.Types[TUINTPTR]), &nodes)
nwid = nod(OMUL, nwid, nodintconst(elemtype.Width))
// instantiate func memmove(to *any, frm *any, length uintptr)
fn := syslook("memmove")
fn = substArgTypes(fn, elemtype, elemtype)
ncopy = mkcall1(fn, nil, &nodes, nptr1, nptr2, nwid)
}
ln := append(nodes.Slice(), ncopy)
typecheckslice(ln, ctxStmt)
walkstmtlist(ln)
init.Append(ln...)
return s
}
// isAppendOfMake reports whether n is of the form append(x , make([]T, y)...).
// isAppendOfMake assumes n has already been typechecked.
func isAppendOfMake(n *Node) bool {
if Debug['N'] != 0 || instrumenting {
return false
}
if n.Typecheck() == 0 {
Fatalf("missing typecheck: %+v", n)
}
if n.Op != OAPPEND || !n.IsDDD() || n.List.Len() != 2 {
return false
}
second := n.List.Second()
if second.Op != OMAKESLICE || second.Right != nil {
return false
}
// y must be either an integer constant or the largest possible positive value
// of variable y needs to fit into an uint.
// typecheck made sure that constant arguments to make are not negative and fit into an int.
// The care of overflow of the len argument to make will be handled by an explicit check of int(len) < 0 during runtime.
y := second.Left
if !Isconst(y, CTINT) && maxintval[y.Type.Etype].Cmp(maxintval[TUINT]) > 0 {
return false
}
return true
}
// extendslice rewrites append(l1, make([]T, l2)...) to
// init {
// if l2 >= 0 { // Empty if block here for more meaningful node.SetLikely(true)
// } else {
// panicmakeslicelen()
// }
// s := l1
// n := len(s) + l2
// // Compare n and s as uint so growslice can panic on overflow of len(s) + l2.
// // cap is a positive int and n can become negative when len(s) + l2
// // overflows int. Interpreting n when negative as uint makes it larger
// // than cap(s). growslice will check the int n arg and panic if n is
// // negative. This prevents the overflow from being undetected.
// if uint(n) > uint(cap(s)) {
// s = growslice(T, s, n)
// }
// s = s[:n]
// lptr := &l1[0]
// sptr := &s[0]
// if lptr == sptr || !hasPointers(T) {
// // growslice did not clear the whole underlying array (or did not get called)
// hp := &s[len(l1)]
// hn := l2 * sizeof(T)
// memclr(hp, hn)
// }
// }
// s
func extendslice(n *Node, init *Nodes) *Node {
// isAppendOfMake made sure all possible positive values of l2 fit into an uint.
// The case of l2 overflow when converting from e.g. uint to int is handled by an explicit
// check of l2 < 0 at runtime which is generated below.
l2 := conv(n.List.Second().Left, types.Types[TINT])
l2 = typecheck(l2, ctxExpr)
n.List.SetSecond(l2) // walkAppendArgs expects l2 in n.List.Second().
walkAppendArgs(n, init)
l1 := n.List.First()
l2 = n.List.Second() // re-read l2, as it may have been updated by walkAppendArgs
var nodes []*Node
// if l2 >= 0 (likely happens), do nothing
nifneg := nod(OIF, nod(OGE, l2, nodintconst(0)), nil)
nifneg.SetLikely(true)
// else panicmakeslicelen()
nifneg.Rlist.Set1(mkcall("panicmakeslicelen", nil, init))
nodes = append(nodes, nifneg)
// s := l1
s := temp(l1.Type)
nodes = append(nodes, nod(OAS, s, l1))
elemtype := s.Type.Elem()
// n := len(s) + l2
nn := temp(types.Types[TINT])
nodes = append(nodes, nod(OAS, nn, nod(OADD, nod(OLEN, s, nil), l2)))
// if uint(n) > uint(cap(s))
nuint := conv(nn, types.Types[TUINT])
capuint := conv(nod(OCAP, s, nil), types.Types[TUINT])
nif := nod(OIF, nod(OGT, nuint, capuint), nil)
// instantiate growslice(typ *type, old []any, newcap int) []any
fn := syslook("growslice")
fn = substArgTypes(fn, elemtype, elemtype)
// s = growslice(T, s, n)
nif.Nbody.Set1(nod(OAS, s, mkcall1(fn, s.Type, &nif.Ninit, typename(elemtype), s, nn)))
nodes = append(nodes, nif)
// s = s[:n]
nt := nod(OSLICE, s, nil)
nt.SetSliceBounds(nil, nn, nil)
nt.SetBounded(true)
nodes = append(nodes, nod(OAS, s, nt))
// lptr := &l1[0]
l1ptr := temp(l1.Type.Elem().PtrTo())
tmp := nod(OSPTR, l1, nil)
nodes = append(nodes, nod(OAS, l1ptr, tmp))
// sptr := &s[0]
sptr := temp(elemtype.PtrTo())
tmp = nod(OSPTR, s, nil)
nodes = append(nodes, nod(OAS, sptr, tmp))
// hp := &s[len(l1)]
hp := nod(OINDEX, s, nod(OLEN, l1, nil))
hp.SetBounded(true)
hp = nod(OADDR, hp, nil)
hp = convnop(hp, types.Types[TUNSAFEPTR])
// hn := l2 * sizeof(elem(s))
hn := nod(OMUL, l2, nodintconst(elemtype.Width))
hn = conv(hn, types.Types[TUINTPTR])
clrname := "memclrNoHeapPointers"
hasPointers := types.Haspointers(elemtype)
if hasPointers {
clrname = "memclrHasPointers"
Curfn.Func.setWBPos(n.Pos)
}
var clr Nodes
clrfn := mkcall(clrname, nil, &clr, hp, hn)
clr.Append(clrfn)
if hasPointers {
// if l1ptr == sptr
nifclr := nod(OIF, nod(OEQ, l1ptr, sptr), nil)
nifclr.Nbody = clr
nodes = append(nodes, nifclr)
} else {
nodes = append(nodes, clr.Slice()...)
}
typecheckslice(nodes, ctxStmt)
walkstmtlist(nodes)
init.Append(nodes...)
return s
}
// Rewrite append(src, x, y, z) so that any side effects in
// x, y, z (including runtime panics) are evaluated in
// initialization statements before the append.
// For normal code generation, stop there and leave the
// rest to cgen_append.
//
// For race detector, expand append(src, a [, b]* ) to
//
// init {
// s := src
// const argc = len(args) - 1
// if cap(s) - len(s) < argc {
// s = growslice(s, len(s)+argc)
// }
// n := len(s)
// s = s[:n+argc]
// s[n] = a
// s[n+1] = b
// ...
// }
// s
func walkappend(n *Node, init *Nodes, dst *Node) *Node {
if !samesafeexpr(dst, n.List.First()) {
n.List.SetFirst(safeexpr(n.List.First(), init))
n.List.SetFirst(walkexpr(n.List.First(), init))
}
walkexprlistsafe(n.List.Slice()[1:], init)
nsrc := n.List.First()
// walkexprlistsafe will leave OINDEX (s[n]) alone if both s
// and n are name or literal, but those may index the slice we're
// modifying here. Fix explicitly.
// Using cheapexpr also makes sure that the evaluation
// of all arguments (and especially any panics) happen
// before we begin to modify the slice in a visible way.
ls := n.List.Slice()[1:]
for i, n := range ls {
n = cheapexpr(n, init)
if !types.Identical(n.Type, nsrc.Type.Elem()) {
n = assignconv(n, nsrc.Type.Elem(), "append")
n = walkexpr(n, init)
}
ls[i] = n
}
argc := n.List.Len() - 1
if argc < 1 {
return nsrc
}
// General case, with no function calls left as arguments.
// Leave for gen, except that instrumentation requires old form.
if !instrumenting || compiling_runtime {
return n
}
var l []*Node
ns := temp(nsrc.Type)
l = append(l, nod(OAS, ns, nsrc)) // s = src
na := nodintconst(int64(argc)) // const argc
nx := nod(OIF, nil, nil) // if cap(s) - len(s) < argc
nx.Left = nod(OLT, nod(OSUB, nod(OCAP, ns, nil), nod(OLEN, ns, nil)), na)
fn := syslook("growslice") // growslice(<type>, old []T, mincap int) (ret []T)
fn = substArgTypes(fn, ns.Type.Elem(), ns.Type.Elem())
nx.Nbody.Set1(nod(OAS, ns,
mkcall1(fn, ns.Type, &nx.Ninit, typename(ns.Type.Elem()), ns,
nod(OADD, nod(OLEN, ns, nil), na))))
l = append(l, nx)
nn := temp(types.Types[TINT])
l = append(l, nod(OAS, nn, nod(OLEN, ns, nil))) // n = len(s)
nx = nod(OSLICE, ns, nil) // ...s[:n+argc]
nx.SetSliceBounds(nil, nod(OADD, nn, na), nil)
nx.SetBounded(true)
l = append(l, nod(OAS, ns, nx)) // s = s[:n+argc]
ls = n.List.Slice()[1:]
for i, n := range ls {
nx = nod(OINDEX, ns, nn) // s[n] ...
nx.SetBounded(true)
l = append(l, nod(OAS, nx, n)) // s[n] = arg
if i+1 < len(ls) {
l = append(l, nod(OAS, nn, nod(OADD, nn, nodintconst(1)))) // n = n + 1
}
}
typecheckslice(l, ctxStmt)
walkstmtlist(l)
init.Append(l...)
return ns
}
// Lower copy(a, b) to a memmove call or a runtime call.
//
// init {
// n := len(a)
// if n > len(b) { n = len(b) }
// if a.ptr != b.ptr { memmove(a.ptr, b.ptr, n*sizeof(elem(a))) }
// }
// n;
//
// Also works if b is a string.
//
func copyany(n *Node, init *Nodes, runtimecall bool) *Node {
if n.Left.Type.Elem().HasHeapPointer() {
Curfn.Func.setWBPos(n.Pos)
fn := writebarrierfn("typedslicecopy", n.Left.Type.Elem(), n.Right.Type.Elem())
n.Left = cheapexpr(n.Left, init)
ptrL, lenL := n.Left.slicePtrLen()
n.Right = cheapexpr(n.Right, init)
ptrR, lenR := n.Right.slicePtrLen()
return mkcall1(fn, n.Type, init, typename(n.Left.Type.Elem()), ptrL, lenL, ptrR, lenR)
}
if runtimecall {
if n.Right.Type.IsString() {
fn := syslook("slicestringcopy")
n.Left = cheapexpr(n.Left, init)
ptr, len := n.Left.slicePtrLen()
str := nod(OCONVNOP, n.Right, nil)
str.Type = types.Types[TSTRING]
return mkcall1(fn, n.Type, init, ptr, len, str)
}
fn := syslook("slicecopy")
fn = substArgTypes(fn, n.Left.Type.Elem(), n.Right.Type.Elem())
n.Left = cheapexpr(n.Left, init)
ptrL, lenL := n.Left.slicePtrLen()
n.Right = cheapexpr(n.Right, init)
ptrR, lenR := n.Right.slicePtrLen()
return mkcall1(fn, n.Type, init, ptrL, lenL, ptrR, lenR, nodintconst(n.Left.Type.Elem().Width))
}
n.Left = walkexpr(n.Left, init)
n.Right = walkexpr(n.Right, init)
nl := temp(n.Left.Type)
nr := temp(n.Right.Type)
var l []*Node
l = append(l, nod(OAS, nl, n.Left))
l = append(l, nod(OAS, nr, n.Right))
nfrm := nod(OSPTR, nr, nil)
nto := nod(OSPTR, nl, nil)
nlen := temp(types.Types[TINT])
// n = len(to)
l = append(l, nod(OAS, nlen, nod(OLEN, nl, nil)))
// if n > len(frm) { n = len(frm) }
nif := nod(OIF, nil, nil)
nif.Left = nod(OGT, nlen, nod(OLEN, nr, nil))
nif.Nbody.Append(nod(OAS, nlen, nod(OLEN, nr, nil)))
l = append(l, nif)
// if to.ptr != frm.ptr { memmove( ... ) }
ne := nod(OIF, nod(ONE, nto, nfrm), nil)
ne.SetLikely(true)
l = append(l, ne)
fn := syslook("memmove")
fn = substArgTypes(fn, nl.Type.Elem(), nl.Type.Elem())
nwid := temp(types.Types[TUINTPTR])
setwid := nod(OAS, nwid, conv(nlen, types.Types[TUINTPTR]))
ne.Nbody.Append(setwid)
nwid = nod(OMUL, nwid, nodintconst(nl.Type.Elem().Width))
call := mkcall1(fn, nil, init, nto, nfrm, nwid)
ne.Nbody.Append(call)
typecheckslice(l, ctxStmt)
walkstmtlist(l)
init.Append(l...)
return nlen
}
func eqfor(t *types.Type) (n *Node, needsize bool) {
// Should only arrive here with large memory or
// a struct/array containing a non-memory field/element.
// Small memory is handled inline, and single non-memory
// is handled by walkcompare.
switch a, _ := algtype1(t); a {
case AMEM:
n := syslook("memequal")
n = substArgTypes(n, t, t)
return n, true
case ASPECIAL:
sym := typesymprefix(".eq", t)
n := newname(sym)
n.SetClass(PFUNC)
n.Sym.SetFunc(true)
n.Type = functype(nil, []*Node{
anonfield(types.NewPtr(t)),
anonfield(types.NewPtr(t)),
}, []*Node{
anonfield(types.Types[TBOOL]),
})
return n, false
}
Fatalf("eqfor %v", t)
return nil, false
}
// The result of walkcompare MUST be assigned back to n, e.g.
// n.Left = walkcompare(n.Left, init)
func walkcompare(n *Node, init *Nodes) *Node {
if n.Left.Type.IsInterface() && n.Right.Type.IsInterface() && n.Left.Op != OLITERAL && n.Right.Op != OLITERAL {
return walkcompareInterface(n, init)
}
if n.Left.Type.IsString() && n.Right.Type.IsString() {
return walkcompareString(n, init)
}
n.Left = walkexpr(n.Left, init)
n.Right = walkexpr(n.Right, init)
// Given mixed interface/concrete comparison,
// rewrite into types-equal && data-equal.
// This is efficient, avoids allocations, and avoids runtime calls.
if n.Left.Type.IsInterface() != n.Right.Type.IsInterface() {
// Preserve side-effects in case of short-circuiting; see #32187.
l := cheapexpr(n.Left, init)
r := cheapexpr(n.Right, init)
// Swap so that l is the interface value and r is the concrete value.
if n.Right.Type.IsInterface() {
l, r = r, l
}
// Handle both == and !=.
eq := n.Op
andor := OOROR
if eq == OEQ {
andor = OANDAND
}
// Check for types equal.
// For empty interface, this is:
// l.tab == type(r)
// For non-empty interface, this is:
// l.tab != nil && l.tab._type == type(r)
var eqtype *Node
tab := nod(OITAB, l, nil)
rtyp := typename(r.Type)
if l.Type.IsEmptyInterface() {
tab.Type = types.NewPtr(types.Types[TUINT8])
tab.SetTypecheck(1)
eqtype = nod(eq, tab, rtyp)
} else {
nonnil := nod(brcom(eq), nodnil(), tab)
match := nod(eq, itabType(tab), rtyp)
eqtype = nod(andor, nonnil, match)
}
// Check for data equal.
eqdata := nod(eq, ifaceData(n.Pos, l, r.Type), r)
// Put it all together.
expr := nod(andor, eqtype, eqdata)
n = finishcompare(n, expr, init)
return n
}
// Must be comparison of array or struct.
// Otherwise back end handles it.
// While we're here, decide whether to
// inline or call an eq alg.
t := n.Left.Type
var inline bool
maxcmpsize := int64(4)
unalignedLoad := canMergeLoads()
if unalignedLoad {
// Keep this low enough to generate less code than a function call.
maxcmpsize = 2 * int64(thearch.LinkArch.RegSize)
}
switch t.Etype {
default:
if Debug_libfuzzer != 0 && t.IsInteger() {
n.Left = cheapexpr(n.Left, init)
n.Right = cheapexpr(n.Right, init)
// If exactly one comparison operand is
// constant, invoke the constcmp functions
// instead, and arrange for the constant
// operand to be the first argument.
l, r := n.Left, n.Right
if r.Op == OLITERAL {
l, r = r, l
}
constcmp := l.Op == OLITERAL && r.Op != OLITERAL
var fn string
var paramType *types.Type
switch t.Size() {
case 1:
fn = "libfuzzerTraceCmp1"
if constcmp {
fn = "libfuzzerTraceConstCmp1"
}
paramType = types.Types[TUINT8]
case 2:
fn = "libfuzzerTraceCmp2"
if constcmp {
fn = "libfuzzerTraceConstCmp2"
}
paramType = types.Types[TUINT16]
case 4:
fn = "libfuzzerTraceCmp4"
if constcmp {
fn = "libfuzzerTraceConstCmp4"
}
paramType = types.Types[TUINT32]
case 8:
fn = "libfuzzerTraceCmp8"
if constcmp {
fn = "libfuzzerTraceConstCmp8"
}
paramType = types.Types[TUINT64]
default:
Fatalf("unexpected integer size %d for %v", t.Size(), t)
}
init.Append(mkcall(fn, nil, init, tracecmpArg(l, paramType, init), tracecmpArg(r, paramType, init)))
}
return n
case TARRAY:
// We can compare several elements at once with 2/4/8 byte integer compares
inline = t.NumElem() <= 1 || (issimple[t.Elem().Etype] && (t.NumElem() <= 4 || t.Elem().Width*t.NumElem() <= maxcmpsize))
case TSTRUCT:
inline = t.NumComponents(types.IgnoreBlankFields) <= 4
}
cmpl := n.Left
for cmpl != nil && cmpl.Op == OCONVNOP {
cmpl = cmpl.Left
}
cmpr := n.Right
for cmpr != nil && cmpr.Op == OCONVNOP {
cmpr = cmpr.Left
}
// Chose not to inline. Call equality function directly.
if !inline {
// eq algs take pointers; cmpl and cmpr must be addressable
if !islvalue(cmpl) || !islvalue(cmpr) {
Fatalf("arguments of comparison must be lvalues - %v %v", cmpl, cmpr)
}
fn, needsize := eqfor(t)
call := nod(OCALL, fn, nil)
call.List.Append(nod(OADDR, cmpl, nil))
call.List.Append(nod(OADDR, cmpr, nil))
if needsize {
call.List.Append(nodintconst(t.Width))
}
res := call
if n.Op != OEQ {
res = nod(ONOT, res, nil)
}
n = finishcompare(n, res, init)
return n
}
// inline: build boolean expression comparing element by element
andor := OANDAND
if n.Op == ONE {
andor = OOROR
}
var expr *Node
compare := func(el, er *Node) {
a := nod(n.Op, el, er)
if expr == nil {
expr = a
} else {
expr = nod(andor, expr, a)
}
}
cmpl = safeexpr(cmpl, init)
cmpr = safeexpr(cmpr, init)
if t.IsStruct() {
for _, f := range t.Fields().Slice() {
sym := f.Sym
if sym.IsBlank() {
continue
}
compare(
nodSym(OXDOT, cmpl, sym),
nodSym(OXDOT, cmpr, sym),
)
}
} else {
step := int64(1)
remains := t.NumElem() * t.Elem().Width
combine64bit := unalignedLoad && Widthreg == 8 && t.Elem().Width <= 4 && t.Elem().IsInteger()
combine32bit := unalignedLoad && t.Elem().Width <= 2 && t.Elem().IsInteger()
combine16bit := unalignedLoad && t.Elem().Width == 1 && t.Elem().IsInteger()
for i := int64(0); remains > 0; {
var convType *types.Type
switch {
case remains >= 8 && combine64bit:
convType = types.Types[TINT64]
step = 8 / t.Elem().Width
case remains >= 4 && combine32bit:
convType = types.Types[TUINT32]
step = 4 / t.Elem().Width
case remains >= 2 && combine16bit:
convType = types.Types[TUINT16]
step = 2 / t.Elem().Width
default:
step = 1
}
if step == 1 {
compare(
nod(OINDEX, cmpl, nodintconst(i)),
nod(OINDEX, cmpr, nodintconst(i)),
)
i++
remains -= t.Elem().Width
} else {
elemType := t.Elem().ToUnsigned()
cmplw := nod(OINDEX, cmpl, nodintconst(i))
cmplw = conv(cmplw, elemType) // convert to unsigned
cmplw = conv(cmplw, convType) // widen
cmprw := nod(OINDEX, cmpr, nodintconst(i))
cmprw = conv(cmprw, elemType)
cmprw = conv(cmprw, convType)
// For code like this: uint32(s[0]) | uint32(s[1])<<8 | uint32(s[2])<<16 ...
// ssa will generate a single large load.
for offset := int64(1); offset < step; offset++ {
lb := nod(OINDEX, cmpl, nodintconst(i+offset))
lb = conv(lb, elemType)
lb = conv(lb, convType)
lb = nod(OLSH, lb, nodintconst(8*t.Elem().Width*offset))
cmplw = nod(OOR, cmplw, lb)
rb := nod(OINDEX, cmpr, nodintconst(i+offset))
rb = conv(rb, elemType)
rb = conv(rb, convType)
rb = nod(OLSH, rb, nodintconst(8*t.Elem().Width*offset))
cmprw = nod(OOR, cmprw, rb)
}
compare(cmplw, cmprw)
i += step
remains -= step * t.Elem().Width
}
}
}
if expr == nil {
expr = nodbool(n.Op == OEQ)
// We still need to use cmpl and cmpr, in case they contain
// an expression which might panic. See issue 23837.
t := temp(cmpl.Type)
a1 := nod(OAS, t, cmpl)
a1 = typecheck(a1, ctxStmt)
a2 := nod(OAS, t, cmpr)
a2 = typecheck(a2, ctxStmt)
init.Append(a1, a2)
}
n = finishcompare(n, expr, init)
return n
}
func tracecmpArg(n *Node, t *types.Type, init *Nodes) *Node {
// Ugly hack to avoid "constant -1 overflows uintptr" errors, etc.
if n.Op == OLITERAL && n.Type.IsSigned() && n.Int64() < 0 {
n = copyexpr(n, n.Type, init)
}
return conv(n, t)
}
func walkcompareInterface(n *Node, init *Nodes) *Node {
n.Right = cheapexpr(n.Right, init)
n.Left = cheapexpr(n.Left, init)
eqtab, eqdata := eqinterface(n.Left, n.Right)
var cmp *Node
if n.Op == OEQ {
cmp = nod(OANDAND, eqtab, eqdata)
} else {
eqtab.Op = ONE
cmp = nod(OOROR, eqtab, nod(ONOT, eqdata, nil))
}
return finishcompare(n, cmp, init)
}
func walkcompareString(n *Node, init *Nodes) *Node {
// Rewrite comparisons to short constant strings as length+byte-wise comparisons.
var cs, ncs *Node // const string, non-const string
switch {
case Isconst(n.Left, CTSTR) && Isconst(n.Right, CTSTR):
// ignore; will be constant evaluated
case Isconst(n.Left, CTSTR):
cs = n.Left
ncs = n.Right
case Isconst(n.Right, CTSTR):
cs = n.Right
ncs = n.Left
}
if cs != nil {
cmp := n.Op
// Our comparison below assumes that the non-constant string
// is on the left hand side, so rewrite "" cmp x to x cmp "".
// See issue 24817.
if Isconst(n.Left, CTSTR) {
cmp = brrev(cmp)
}
// maxRewriteLen was chosen empirically.
// It is the value that minimizes cmd/go file size
// across most architectures.
// See the commit description for CL 26758 for details.
maxRewriteLen := 6
// Some architectures can load unaligned byte sequence as 1 word.
// So we can cover longer strings with the same amount of code.
canCombineLoads := canMergeLoads()
combine64bit := false
if canCombineLoads {
// Keep this low enough to generate less code than a function call.
maxRewriteLen = 2 * thearch.LinkArch.RegSize
combine64bit = thearch.LinkArch.RegSize >= 8
}
var and Op
switch cmp {
case OEQ:
and = OANDAND
case ONE:
and = OOROR
default:
// Don't do byte-wise comparisons for <, <=, etc.
// They're fairly complicated.
// Length-only checks are ok, though.
maxRewriteLen = 0
}
if s := strlit(cs); len(s) <= maxRewriteLen {
if len(s) > 0 {
ncs = safeexpr(ncs, init)
}
r := nod(cmp, nod(OLEN, ncs, nil), nodintconst(int64(len(s))))
remains := len(s)
for i := 0; remains > 0; {
if remains == 1 || !canCombineLoads {
cb := nodintconst(int64(s[i]))
ncb := nod(OINDEX, ncs, nodintconst(int64(i)))
r = nod(and, r, nod(cmp, ncb, cb))
remains--
i++
continue
}
var step int
var convType *types.Type
switch {
case remains >= 8 && combine64bit:
convType = types.Types[TINT64]
step = 8
case remains >= 4:
convType = types.Types[TUINT32]
step = 4
case remains >= 2:
convType = types.Types[TUINT16]
step = 2
}
ncsubstr := nod(OINDEX, ncs, nodintconst(int64(i)))
ncsubstr = conv(ncsubstr, convType)
csubstr := int64(s[i])
// Calculate large constant from bytes as sequence of shifts and ors.
// Like this: uint32(s[0]) | uint32(s[1])<<8 | uint32(s[2])<<16 ...
// ssa will combine this into a single large load.
for offset := 1; offset < step; offset++ {
b := nod(OINDEX, ncs, nodintconst(int64(i+offset)))
b = conv(b, convType)
b = nod(OLSH, b, nodintconst(int64(8*offset)))
ncsubstr = nod(OOR, ncsubstr, b)
csubstr |= int64(s[i+offset]) << uint8(8*offset)
}
csubstrPart := nodintconst(csubstr)
// Compare "step" bytes as once
r = nod(and, r, nod(cmp, csubstrPart, ncsubstr))
remains -= step
i += step
}
return finishcompare(n, r, init)
}
}
var r *Node
if n.Op == OEQ || n.Op == ONE {
// prepare for rewrite below
n.Left = cheapexpr(n.Left, init)
n.Right = cheapexpr(n.Right, init)
eqlen, eqmem := eqstring(n.Left, n.Right)
// quick check of len before full compare for == or !=.
// memequal then tests equality up to length len.
if n.Op == OEQ {
// len(left) == len(right) && memequal(left, right, len)
r = nod(OANDAND, eqlen, eqmem)
} else {
// len(left) != len(right) || !memequal(left, right, len)
eqlen.Op = ONE
r = nod(OOROR, eqlen, nod(ONOT, eqmem, nil))
}
} else {
// sys_cmpstring(s1, s2) :: 0
r = mkcall("cmpstring", types.Types[TINT], init, conv(n.Left, types.Types[TSTRING]), conv(n.Right, types.Types[TSTRING]))
r = nod(n.Op, r, nodintconst(0))
}
return finishcompare(n, r, init)
}
// The result of finishcompare MUST be assigned back to n, e.g.
// n.Left = finishcompare(n.Left, x, r, init)
func finishcompare(n, r *Node, init *Nodes) *Node {
r = typecheck(r, ctxExpr)
r = conv(r, n.Type)
r = walkexpr(r, init)
return r
}
// return 1 if integer n must be in range [0, max), 0 otherwise
func bounded(n *Node, max int64) bool {
if n.Type == nil || !n.Type.IsInteger() {
return false
}
sign := n.Type.IsSigned()
bits := int32(8 * n.Type.Width)
if smallintconst(n) {
v := n.Int64()
return 0 <= v && v < max
}
switch n.Op {
case OAND:
v := int64(-1)
if smallintconst(n.Left) {
v = n.Left.Int64()
} else if smallintconst(n.Right) {
v = n.Right.Int64()
}
if 0 <= v && v < max {
return true
}
case OMOD:
if !sign && smallintconst(n.Right) {
v := n.Right.Int64()
if 0 <= v && v <= max {
return true
}
}
case ODIV:
if !sign && smallintconst(n.Right) {
v := n.Right.Int64()
for bits > 0 && v >= 2 {
bits--
v >>= 1
}
}
case ORSH:
if !sign && smallintconst(n.Right) {
v := n.Right.Int64()
if v > int64(bits) {
return true
}
bits -= int32(v)
}
}
if !sign && bits <= 62 && 1<<uint(bits) <= max {
return true
}
return false
}
// usemethod checks interface method calls for uses of reflect.Type.Method.
func usemethod(n *Node) {
t := n.Left.Type
// Looking for either of:
// Method(int) reflect.Method
// MethodByName(string) (reflect.Method, bool)
//
// TODO(crawshaw): improve precision of match by working out
// how to check the method name.
if n := t.NumParams(); n != 1 {
return
}
if n := t.NumResults(); n != 1 && n != 2 {
return
}
p0 := t.Params().Field(0)
res0 := t.Results().Field(0)
var res1 *types.Field
if t.NumResults() == 2 {
res1 = t.Results().Field(1)
}
if res1 == nil {
if p0.Type.Etype != TINT {
return
}
} else {
if !p0.Type.IsString() {
return
}
if !res1.Type.IsBoolean() {
return
}
}
// Note: Don't rely on res0.Type.String() since its formatting depends on multiple factors
// (including global variables such as numImports - was issue #19028).
// Also need to check for reflect package itself (see Issue #38515).
if s := res0.Type.Sym; s != nil && s.Name == "Method" && isReflectPkg(s.Pkg) {
Curfn.Func.SetReflectMethod(true)
}
}
func usefield(n *Node) {
if objabi.Fieldtrack_enabled == 0 {
return
}
switch n.Op {
default:
Fatalf("usefield %v", n.Op)
case ODOT, ODOTPTR:
break
}
if n.Sym == nil {
// No field name. This DOTPTR was built by the compiler for access
// to runtime data structures. Ignore.
return
}
t := n.Left.Type
if t.IsPtr() {
t = t.Elem()
}
field := dotField[typeSymKey{t.Orig, n.Sym}]
if field == nil {
Fatalf("usefield %v %v without paramfld", n.Left.Type, n.Sym)
}
if !strings.Contains(field.Note, "go:\"track\"") {
return
}
outer := n.Left.Type
if outer.IsPtr() {
outer = outer.Elem()
}
if outer.Sym == nil {
yyerror("tracked field must be in named struct type")
}
if !types.IsExported(field.Sym.Name) {
yyerror("tracked field must be exported (upper case)")
}
sym := tracksym(outer, field)
if Curfn.Func.FieldTrack == nil {
Curfn.Func.FieldTrack = make(map[*types.Sym]struct{})
}
Curfn.Func.FieldTrack[sym] = struct{}{}
}
func candiscardlist(l Nodes) bool {
for _, n := range l.Slice() {
if !candiscard(n) {
return false
}
}
return true
}
func candiscard(n *Node) bool {
if n == nil {
return true
}
switch n.Op {
default:
return false
// Discardable as long as the subpieces are.
case ONAME,
ONONAME,
OTYPE,
OPACK,
OLITERAL,
OADD,
OSUB,
OOR,
OXOR,
OADDSTR,
OADDR,
OANDAND,
OBYTES2STR,
ORUNES2STR,
OSTR2BYTES,
OSTR2RUNES,
OCAP,
OCOMPLIT,
OMAPLIT,
OSTRUCTLIT,
OARRAYLIT,
OSLICELIT,
OPTRLIT,
OCONV,
OCONVIFACE,
OCONVNOP,
ODOT,
OEQ,
ONE,
OLT,
OLE,
OGT,
OGE,
OKEY,
OSTRUCTKEY,
OLEN,
OMUL,
OLSH,
ORSH,
OAND,
OANDNOT,
ONEW,
ONOT,
OBITNOT,
OPLUS,
ONEG,
OOROR,
OPAREN,
ORUNESTR,
OREAL,
OIMAG,
OCOMPLEX:
break
// Discardable as long as we know it's not division by zero.
case ODIV, OMOD:
if Isconst(n.Right, CTINT) && n.Right.Val().U.(*Mpint).CmpInt64(0) != 0 {
break
}
if Isconst(n.Right, CTFLT) && n.Right.Val().U.(*Mpflt).CmpFloat64(0) != 0 {
break
}
return false
// Discardable as long as we know it won't fail because of a bad size.
case OMAKECHAN, OMAKEMAP:
if Isconst(n.Left, CTINT) && n.Left.Val().U.(*Mpint).CmpInt64(0) == 0 {
break
}
return false
// Difficult to tell what sizes are okay.
case OMAKESLICE:
return false
case OMAKESLICECOPY:
return false
}
if !candiscard(n.Left) || !candiscard(n.Right) || !candiscardlist(n.Ninit) || !candiscardlist(n.Nbody) || !candiscardlist(n.List) || !candiscardlist(n.Rlist) {
return false
}
return true
}
// Rewrite
// go builtin(x, y, z)
// into
// go func(a1, a2, a3) {
// builtin(a1, a2, a3)
// }(x, y, z)
// for print, println, and delete.
var wrapCall_prgen int
// The result of wrapCall MUST be assigned back to n, e.g.
// n.Left = wrapCall(n.Left, init)
func wrapCall(n *Node, init *Nodes) *Node {
if n.Ninit.Len() != 0 {
walkstmtlist(n.Ninit.Slice())
init.AppendNodes(&n.Ninit)
}
t := nod(OTFUNC, nil, nil)
for i, arg := range n.List.Slice() {
s := lookupN("a", i)
t.List.Append(symfield(s, arg.Type))
}
wrapCall_prgen++
sym := lookupN("wrap·", wrapCall_prgen)
fn := dclfunc(sym, t)
a := nod(n.Op, nil, nil)
a.List.Set(paramNnames(t.Type))
a = typecheck(a, ctxStmt)
fn.Nbody.Set1(a)
funcbody()
fn = typecheck(fn, ctxStmt)
typecheckslice(fn.Nbody.Slice(), ctxStmt)
xtop = append(xtop, fn)
a = nod(OCALL, nil, nil)
a.Left = fn.Func.Nname
a.List.Set(n.List.Slice())
a = typecheck(a, ctxStmt)
a = walkexpr(a, init)
return a
}
// substArgTypes substitutes the given list of types for
// successive occurrences of the "any" placeholder in the
// type syntax expression n.Type.
// The result of substArgTypes MUST be assigned back to old, e.g.
// n.Left = substArgTypes(n.Left, t1, t2)
func substArgTypes(old *Node, types_ ...*types.Type) *Node {
n := old.copy()
for _, t := range types_ {
dowidth(t)
}
n.Type = types.SubstAny(n.Type, &types_)
if len(types_) > 0 {
Fatalf("substArgTypes: too many argument types")
}
return n
}
// canMergeLoads reports whether the backend optimization passes for
// the current architecture can combine adjacent loads into a single
// larger, possibly unaligned, load. Note that currently the
// optimizations must be able to handle little endian byte order.
func canMergeLoads() bool {
switch thearch.LinkArch.Family {
case sys.ARM64, sys.AMD64, sys.I386, sys.S390X:
return true
case sys.PPC64:
// Load combining only supported on ppc64le.
return thearch.LinkArch.ByteOrder == binary.LittleEndian
}
return false
}
// isRuneCount reports whether n is of the form len([]rune(string)).
// These are optimized into a call to runtime.countrunes.
func isRuneCount(n *Node) bool {
return Debug['N'] == 0 && !instrumenting && n.Op == OLEN && n.Left.Op == OSTR2RUNES
}
func walkCheckPtrAlignment(n *Node, init *Nodes, count *Node) *Node {
if !n.Type.IsPtr() {
Fatalf("expected pointer type: %v", n.Type)
}
elem := n.Type.Elem()
if count != nil {
if !elem.IsArray() {
Fatalf("expected array type: %v", elem)
}
elem = elem.Elem()
}
size := elem.Size()
if elem.Alignment() == 1 && (size == 0 || size == 1 && count == nil) {
return n
}
if count == nil {
count = nodintconst(1)
}
n.Left = cheapexpr(n.Left, init)
init.Append(mkcall("checkptrAlignment", nil, init, convnop(n.Left, types.Types[TUNSAFEPTR]), typename(elem), conv(count, types.Types[TUINTPTR])))
return n
}
var walkCheckPtrArithmeticMarker byte
func walkCheckPtrArithmetic(n *Node, init *Nodes) *Node {
// Calling cheapexpr(n, init) below leads to a recursive call
// to walkexpr, which leads us back here again. Use n.Opt to
// prevent infinite loops.
if opt := n.Opt(); opt == &walkCheckPtrArithmeticMarker {
return n
} else if opt != nil {
// We use n.Opt() here because today it's not used for OCONVNOP. If that changes,
// there's no guarantee that temporarily replacing it is safe, so just hard fail here.
Fatalf("unexpected Opt: %v", opt)
}
n.SetOpt(&walkCheckPtrArithmeticMarker)
defer n.SetOpt(nil)
// TODO(mdempsky): Make stricter. We only need to exempt
// reflect.Value.Pointer and reflect.Value.UnsafeAddr.
switch n.Left.Op {
case OCALLFUNC, OCALLMETH, OCALLINTER:
return n
}
if n.Left.Op == ODOTPTR && isReflectHeaderDataField(n.Left) {
return n
}
// Find original unsafe.Pointer operands involved in this
// arithmetic expression.
//
// "It is valid both to add and to subtract offsets from a
// pointer in this way. It is also valid to use &^ to round
// pointers, usually for alignment."
var originals []*Node
var walk func(n *Node)
walk = func(n *Node) {
switch n.Op {
case OADD:
walk(n.Left)
walk(n.Right)
case OSUB, OANDNOT:
walk(n.Left)
case OCONVNOP:
if n.Left.Type.Etype == TUNSAFEPTR {
n.Left = cheapexpr(n.Left, init)
originals = append(originals, convnop(n.Left, types.Types[TUNSAFEPTR]))
}
}
}
walk(n.Left)
n = cheapexpr(n, init)
slice := mkdotargslice(types.NewSlice(types.Types[TUNSAFEPTR]), originals)
slice.Esc = EscNone
init.Append(mkcall("checkptrArithmetic", nil, init, convnop(n, types.Types[TUNSAFEPTR]), slice))
// TODO(khr): Mark backing store of slice as dead. This will allow us to reuse
// the backing store for multiple calls to checkptrArithmetic.
return n
}
// checkPtr reports whether pointer checking should be enabled for
// function fn at a given level. See debugHelpFooter for defined
// levels.
func checkPtr(fn *Node, level int) bool {
return Debug_checkptr >= level && fn.Func.Pragma&NoCheckPtr == 0
}