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mirror of https://github.com/golang/go synced 2024-11-23 00:20:12 -07:00

cmd/compile: don't allow go:notinheap on the heap or stack

Right now we just prevent such types from being on the heap. This CL
makes it so they cannot appear on the stack either. The distinction
between heap and stack is pretty vague at the language level (e.g. it
is affected by -N), and we don't need the flexibility anyway.

Once go:notinheap types cannot be in either place, we don't need to
consider pointers to such types to be pointers, at least according to
the garbage collector and stack copying. (This is the big win of this
CL, in my opinion.)

The distinction between HasPointers and HasHeapPointer no longer
exists. There is only HasPointers.

This CL is cleanup before possible use of go:notinheap to fix #40954.

Update #13386

Change-Id: Ibd895aadf001c0385078a6d4809c3f374991231a
Reviewed-on: https://go-review.googlesource.com/c/go/+/249917
Run-TryBot: Keith Randall <khr@golang.org>
TryBot-Result: Gobot Gobot <gobot@golang.org>
Reviewed-by: Matthew Dempsky <mdempsky@google.com>
Reviewed-by: Cuong Manh Le <cuong.manhle.vn@gmail.com>
This commit is contained in:
Keith Randall 2020-08-21 20:20:12 -07:00
parent 95df156e6a
commit d9a6bdf7ef
16 changed files with 54 additions and 68 deletions

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@ -1029,6 +1029,9 @@ func (e *Escape) newLoc(n *Node, transient bool) *EscLocation {
if e.curfn == nil { if e.curfn == nil {
Fatalf("e.curfn isn't set") Fatalf("e.curfn isn't set")
} }
if n != nil && n.Type != nil && n.Type.NotInHeap() {
yyerrorl(n.Pos, "%v is go:notinheap; stack allocation disallowed", n.Type)
}
n = canonicalNode(n) n = canonicalNode(n)
loc := &EscLocation{ loc := &EscLocation{

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@ -20,7 +20,7 @@ func typeWithoutPointers() *types.Type {
func typeWithPointers() *types.Type { func typeWithPointers() *types.Type {
t := types.New(TSTRUCT) t := types.New(TSTRUCT)
f := &types.Field{Type: types.New(TPTR)} f := &types.Field{Type: types.NewPtr(types.New(TINT))}
t.SetFields([]*types.Field{f}) t.SetFields([]*types.Field{f})
return t return t
} }
@ -181,14 +181,6 @@ func TestStackvarSort(t *testing.T) {
nodeWithClass(Node{Type: &types.Type{}, Sym: &types.Sym{Name: "xyz"}}, PAUTO), nodeWithClass(Node{Type: &types.Type{}, Sym: &types.Sym{Name: "xyz"}}, PAUTO),
nodeWithClass(Node{Type: typeWithoutPointers(), Sym: &types.Sym{}}, PAUTO), nodeWithClass(Node{Type: typeWithoutPointers(), Sym: &types.Sym{}}, PAUTO),
} }
// haspointers updates Type.Haspointers as a side effect, so
// exercise this function on all inputs so that reflect.DeepEqual
// doesn't produce false positives.
for i := range want {
want[i].Type.HasPointers()
inp[i].Type.HasPointers()
}
sort.Sort(byStackVar(inp)) sort.Sort(byStackVar(inp))
if !reflect.DeepEqual(want, inp) { if !reflect.DeepEqual(want, inp) {
t.Error("sort failed") t.Error("sort failed")

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@ -436,7 +436,7 @@ func (lv *Liveness) regEffects(v *ssa.Value) (uevar, kill liveRegMask) {
case ssa.LocalSlot: case ssa.LocalSlot:
return mask return mask
case *ssa.Register: case *ssa.Register:
if ptrOnly && !v.Type.HasHeapPointer() { if ptrOnly && !v.Type.HasPointers() {
return mask return mask
} }
regs[0] = loc regs[0] = loc
@ -451,7 +451,7 @@ func (lv *Liveness) regEffects(v *ssa.Value) (uevar, kill liveRegMask) {
if loc1 == nil { if loc1 == nil {
continue continue
} }
if ptrOnly && !v.Type.FieldType(i).HasHeapPointer() { if ptrOnly && !v.Type.FieldType(i).HasPointers() {
continue continue
} }
regs[nreg] = loc1.(*ssa.Register) regs[nreg] = loc1.(*ssa.Register)
@ -568,13 +568,13 @@ func onebitwalktype1(t *types.Type, off int64, bv bvec) {
if t.Align > 0 && off&int64(t.Align-1) != 0 { if t.Align > 0 && off&int64(t.Align-1) != 0 {
Fatalf("onebitwalktype1: invalid initial alignment: type %v has alignment %d, but offset is %v", t, t.Align, off) Fatalf("onebitwalktype1: invalid initial alignment: type %v has alignment %d, but offset is %v", t, t.Align, off)
} }
if !t.HasPointers() {
// Note: this case ensures that pointers to go:notinheap types
// are not considered pointers by garbage collection and stack copying.
return
}
switch t.Etype { switch t.Etype {
case TINT8, TUINT8, TINT16, TUINT16,
TINT32, TUINT32, TINT64, TUINT64,
TINT, TUINT, TUINTPTR, TBOOL,
TFLOAT32, TFLOAT64, TCOMPLEX64, TCOMPLEX128:
case TPTR, TUNSAFEPTR, TFUNC, TCHAN, TMAP: case TPTR, TUNSAFEPTR, TFUNC, TCHAN, TMAP:
if off&int64(Widthptr-1) != 0 { if off&int64(Widthptr-1) != 0 {
Fatalf("onebitwalktype1: invalid alignment, %v", t) Fatalf("onebitwalktype1: invalid alignment, %v", t)

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@ -586,7 +586,7 @@ func arrayClear(n, v1, v2, a *Node) bool {
n.Nbody.Append(nod(OAS, hn, tmp)) n.Nbody.Append(nod(OAS, hn, tmp))
var fn *Node var fn *Node
if a.Type.Elem().HasHeapPointer() { if a.Type.Elem().HasPointers() {
// memclrHasPointers(hp, hn) // memclrHasPointers(hp, hn)
Curfn.Func.setWBPos(stmt.Pos) Curfn.Func.setWBPos(stmt.Pos)
fn = mkcall("memclrHasPointers", nil, nil, hp, hn) fn = mkcall("memclrHasPointers", nil, nil, hp, hn)

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@ -1156,6 +1156,9 @@ opswitch:
} }
case ONEW: case ONEW:
if n.Type.Elem().NotInHeap() {
yyerror("%v is go:notinheap; heap allocation disallowed", n.Type.Elem())
}
if n.Esc == EscNone { if n.Esc == EscNone {
if n.Type.Elem().Width >= maxImplicitStackVarSize { if n.Type.Elem().Width >= maxImplicitStackVarSize {
Fatalf("large ONEW with EscNone: %v", n) Fatalf("large ONEW with EscNone: %v", n)
@ -1324,6 +1327,9 @@ opswitch:
l = r l = r
} }
t := n.Type t := n.Type
if t.Elem().NotInHeap() {
yyerror("%v is go:notinheap; heap allocation disallowed", t.Elem())
}
if n.Esc == EscNone { if n.Esc == EscNone {
if !isSmallMakeSlice(n) { if !isSmallMakeSlice(n) {
Fatalf("non-small OMAKESLICE with EscNone: %v", n) Fatalf("non-small OMAKESLICE with EscNone: %v", n)
@ -1365,10 +1371,6 @@ opswitch:
// When len and cap can fit into int, use makeslice instead of // When len and cap can fit into int, use makeslice instead of
// makeslice64, which is faster and shorter on 32 bit platforms. // 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 len, cap := l, r
fnname := "makeslice64" fnname := "makeslice64"
@ -1403,7 +1405,7 @@ opswitch:
t := n.Type t := n.Type
if t.Elem().NotInHeap() { if t.Elem().NotInHeap() {
Fatalf("%v is go:notinheap; heap allocation disallowed", t.Elem()) yyerror("%v is go:notinheap; heap allocation disallowed", t.Elem())
} }
length := conv(n.Left, types.Types[TINT]) length := conv(n.Left, types.Types[TINT])
@ -2012,9 +2014,6 @@ func walkprint(nn *Node, init *Nodes) *Node {
} }
func callnew(t *types.Type) *Node { func callnew(t *types.Type) *Node {
if t.NotInHeap() {
yyerror("%v is go:notinheap; heap allocation disallowed", t)
}
dowidth(t) dowidth(t)
n := nod(ONEWOBJ, typename(t), nil) n := nod(ONEWOBJ, typename(t), nil)
n.Type = types.NewPtr(t) n.Type = types.NewPtr(t)
@ -2589,7 +2588,7 @@ func mapfast(t *types.Type) int {
} }
switch algtype(t.Key()) { switch algtype(t.Key()) {
case AMEM32: case AMEM32:
if !t.Key().HasHeapPointer() { if !t.Key().HasPointers() {
return mapfast32 return mapfast32
} }
if Widthptr == 4 { if Widthptr == 4 {
@ -2597,7 +2596,7 @@ func mapfast(t *types.Type) int {
} }
Fatalf("small pointer %v", t.Key()) Fatalf("small pointer %v", t.Key())
case AMEM64: case AMEM64:
if !t.Key().HasHeapPointer() { if !t.Key().HasPointers() {
return mapfast64 return mapfast64
} }
if Widthptr == 8 { if Widthptr == 8 {
@ -2744,7 +2743,7 @@ func appendslice(n *Node, init *Nodes) *Node {
nodes.Append(nod(OAS, s, nt)) nodes.Append(nod(OAS, s, nt))
var ncopy *Node var ncopy *Node
if elemtype.HasHeapPointer() { if elemtype.HasPointers() {
// copy(s[len(l1):], l2) // copy(s[len(l1):], l2)
nptr1 := nod(OSLICE, s, nil) nptr1 := nod(OSLICE, s, nil)
nptr1.Type = s.Type nptr1.Type = s.Type
@ -3082,7 +3081,7 @@ func walkappend(n *Node, init *Nodes, dst *Node) *Node {
// Also works if b is a string. // Also works if b is a string.
// //
func copyany(n *Node, init *Nodes, runtimecall bool) *Node { func copyany(n *Node, init *Nodes, runtimecall bool) *Node {
if n.Left.Type.Elem().HasHeapPointer() { if n.Left.Type.Elem().HasPointers() {
Curfn.Func.setWBPos(n.Pos) Curfn.Func.setWBPos(n.Pos)
fn := writebarrierfn("typedslicecopy", n.Left.Type.Elem(), n.Right.Type.Elem()) fn := writebarrierfn("typedslicecopy", n.Left.Type.Elem(), n.Right.Type.Elem())
n.Left = cheapexpr(n.Left, init) n.Left = cheapexpr(n.Left, init)

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@ -139,7 +139,7 @@ func decomposeStringPhi(v *Value) {
func decomposeSlicePhi(v *Value) { func decomposeSlicePhi(v *Value) {
types := &v.Block.Func.Config.Types types := &v.Block.Func.Config.Types
ptrType := types.BytePtr ptrType := v.Type.Elem().PtrTo()
lenType := types.Int lenType := types.Int
ptr := v.Block.NewValue0(v.Pos, OpPhi, ptrType) ptr := v.Block.NewValue0(v.Pos, OpPhi, ptrType)

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@ -66,14 +66,14 @@
(Load <typ.Int> (Load <typ.Int>
(OffPtr <typ.IntPtr> [2*config.PtrSize] ptr) (OffPtr <typ.IntPtr> [2*config.PtrSize] ptr)
mem)) mem))
(Store dst (SliceMake ptr len cap) mem) => (Store {t} dst (SliceMake ptr len cap) mem) =>
(Store {typ.Int} (Store {typ.Int}
(OffPtr <typ.IntPtr> [2*config.PtrSize] dst) (OffPtr <typ.IntPtr> [2*config.PtrSize] dst)
cap cap
(Store {typ.Int} (Store {typ.Int}
(OffPtr <typ.IntPtr> [config.PtrSize] dst) (OffPtr <typ.IntPtr> [config.PtrSize] dst)
len len
(Store {typ.BytePtr} dst ptr mem))) (Store {t.Elem().PtrTo()} dst ptr mem)))
// interface ops // interface ops
(ITab (IMake itab _)) => itab (ITab (IMake itab _)) => itab

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@ -235,7 +235,7 @@ func nilcheckelim2(f *Func) {
continue continue
} }
if v.Type.IsMemory() || v.Type.IsTuple() && v.Type.FieldType(1).IsMemory() { if v.Type.IsMemory() || v.Type.IsTuple() && v.Type.FieldType(1).IsMemory() {
if v.Op == OpVarKill || v.Op == OpVarLive || (v.Op == OpVarDef && !v.Aux.(GCNode).Typ().HasHeapPointer()) { if v.Op == OpVarKill || v.Op == OpVarLive || (v.Op == OpVarDef && !v.Aux.(GCNode).Typ().HasPointers()) {
// These ops don't really change memory. // These ops don't really change memory.
continue continue
// Note: OpVarDef requires that the defined variable not have pointers. // Note: OpVarDef requires that the defined variable not have pointers.

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@ -328,9 +328,10 @@ func rewriteValuedec_OpStore(v *Value) bool {
v.AddArg3(v0, len, v1) v.AddArg3(v0, len, v1)
return true return true
} }
// match: (Store dst (SliceMake ptr len cap) mem) // match: (Store {t} dst (SliceMake ptr len cap) mem)
// result: (Store {typ.Int} (OffPtr <typ.IntPtr> [2*config.PtrSize] dst) cap (Store {typ.Int} (OffPtr <typ.IntPtr> [config.PtrSize] dst) len (Store {typ.BytePtr} dst ptr mem))) // result: (Store {typ.Int} (OffPtr <typ.IntPtr> [2*config.PtrSize] dst) cap (Store {typ.Int} (OffPtr <typ.IntPtr> [config.PtrSize] dst) len (Store {t.Elem().PtrTo()} dst ptr mem)))
for { for {
t := auxToType(v.Aux)
dst := v_0 dst := v_0
if v_1.Op != OpSliceMake { if v_1.Op != OpSliceMake {
break break
@ -350,7 +351,7 @@ func rewriteValuedec_OpStore(v *Value) bool {
v2.AuxInt = int64ToAuxInt(config.PtrSize) v2.AuxInt = int64ToAuxInt(config.PtrSize)
v2.AddArg(dst) v2.AddArg(dst)
v3 := b.NewValue0(v.Pos, OpStore, types.TypeMem) v3 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
v3.Aux = typeToAux(typ.BytePtr) v3.Aux = typeToAux(t.Elem().PtrTo())
v3.AddArg3(dst, ptr, mem) v3.AddArg3(dst, ptr, mem)
v1.AddArg3(v2, len, v3) v1.AddArg3(v2, len, v3)
v.AddArg3(v0, cap, v1) v.AddArg3(v0, cap, v1)

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@ -31,7 +31,7 @@ func needwb(v *Value, zeroes map[ID]ZeroRegion) bool {
if !ok { if !ok {
v.Fatalf("store aux is not a type: %s", v.LongString()) v.Fatalf("store aux is not a type: %s", v.LongString())
} }
if !t.HasHeapPointer() { if !t.HasPointers() {
return false return false
} }
if IsStackAddr(v.Args[0]) { if IsStackAddr(v.Args[0]) {

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@ -1398,14 +1398,9 @@ func (t *Type) IsUntyped() bool {
return false return false
} }
// TODO(austin): We probably only need HasHeapPointer. See // HasPointers reports whether t contains a heap pointer.
// golang.org/cl/73412 for discussion. // Note that this function ignores pointers to go:notinheap types.
func (t *Type) HasPointers() bool { func (t *Type) HasPointers() bool {
return t.hasPointers1(false)
}
func (t *Type) hasPointers1(ignoreNotInHeap bool) bool {
switch t.Etype { switch t.Etype {
case TINT, TUINT, TINT8, TUINT8, TINT16, TUINT16, TINT32, TUINT32, TINT64, case TINT, TUINT, TINT8, TUINT8, TINT16, TUINT16, TINT32, TUINT32, TINT64,
TUINT64, TUINTPTR, TFLOAT32, TFLOAT64, TCOMPLEX64, TCOMPLEX128, TBOOL, TSSA: TUINT64, TUINTPTR, TFLOAT32, TFLOAT64, TCOMPLEX64, TCOMPLEX128, TBOOL, TSSA:
@ -1415,34 +1410,27 @@ func (t *Type) hasPointers1(ignoreNotInHeap bool) bool {
if t.NumElem() == 0 { // empty array has no pointers if t.NumElem() == 0 { // empty array has no pointers
return false return false
} }
return t.Elem().hasPointers1(ignoreNotInHeap) return t.Elem().HasPointers()
case TSTRUCT: case TSTRUCT:
for _, t1 := range t.Fields().Slice() { for _, t1 := range t.Fields().Slice() {
if t1.Type.hasPointers1(ignoreNotInHeap) { if t1.Type.HasPointers() {
return true return true
} }
} }
return false return false
case TPTR, TSLICE: case TPTR, TSLICE:
return !(ignoreNotInHeap && t.Elem().NotInHeap()) return !t.Elem().NotInHeap()
case TTUPLE: case TTUPLE:
ttup := t.Extra.(*Tuple) ttup := t.Extra.(*Tuple)
return ttup.first.hasPointers1(ignoreNotInHeap) || ttup.second.hasPointers1(ignoreNotInHeap) return ttup.first.HasPointers() || ttup.second.HasPointers()
} }
return true return true
} }
// HasHeapPointer reports whether t contains a heap pointer.
// This is used for write barrier insertion, so it ignores
// pointers to go:notinheap types.
func (t *Type) HasHeapPointer() bool {
return t.hasPointers1(true)
}
func (t *Type) Symbol() *obj.LSym { func (t *Type) Symbol() *obj.LSym {
return TypeLinkSym(t) return TypeLinkSym(t)
} }

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@ -981,9 +981,8 @@ func MapHashCheck(m interface{}, k interface{}) (uintptr, uintptr) {
} }
func MSpanCountAlloc(bits []byte) int { func MSpanCountAlloc(bits []byte) int {
s := mspan{ s := (*mspan)(mheap_.spanalloc.alloc())
nelems: uintptr(len(bits) * 8), s.nelems = uintptr(len(bits) * 8)
gcmarkBits: (*gcBits)(unsafe.Pointer(&bits[0])), s.gcmarkBits = (*gcBits)(unsafe.Pointer(&bits[0]))
}
return s.countAlloc() return s.countAlloc()
} }

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@ -837,7 +837,8 @@ func scanstack(gp *g, gcw *gcWork) {
x := state.head x := state.head
state.head = x.next state.head = x.next
if stackTraceDebug { if stackTraceDebug {
for _, obj := range x.obj[:x.nobj] { for i := 0; i < x.nobj; i++ {
obj := &x.obj[i]
if obj.typ == nil { // reachable if obj.typ == nil { // reachable
continue continue
} }

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@ -167,8 +167,6 @@ func (obj *stackObject) setType(typ *_type) {
// A stackScanState keeps track of the state used during the GC walk // A stackScanState keeps track of the state used during the GC walk
// of a goroutine. // of a goroutine.
//
//go:notinheap
type stackScanState struct { type stackScanState struct {
cache pcvalueCache cache pcvalueCache

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@ -909,15 +909,12 @@ type _defer struct {
// A _panic holds information about an active panic. // A _panic holds information about an active panic.
// //
// This is marked go:notinheap because _panic values must only ever // A _panic value must only ever live on the stack.
// live on the stack.
// //
// The argp and link fields are stack pointers, but don't need special // The argp and link fields are stack pointers, but don't need special
// handling during stack growth: because they are pointer-typed and // handling during stack growth: because they are pointer-typed and
// _panic values only live on the stack, regular stack pointer // _panic values only live on the stack, regular stack pointer
// adjustment takes care of them. // adjustment takes care of them.
//
//go:notinheap
type _panic struct { type _panic struct {
argp unsafe.Pointer // pointer to arguments of deferred call run during panic; cannot move - known to liblink argp unsafe.Pointer // pointer to arguments of deferred call run during panic; cannot move - known to liblink
arg interface{} // argument to panic arg interface{} // argument to panic

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@ -13,12 +13,14 @@ type nih struct {
next *nih next *nih
} }
// Globals and stack variables are okay. // Global variables are okay.
var x nih var x nih
// Stack variables are not okay.
func f() { func f() {
var y nih var y nih // ERROR "nih is go:notinheap; stack allocation disallowed"
x = y x = y
} }
@ -26,11 +28,17 @@ func f() {
var y *nih var y *nih
var z []nih var z []nih
var w []nih
var n int
func g() { func g() {
y = new(nih) // ERROR "heap allocation disallowed" y = new(nih) // ERROR "heap allocation disallowed"
z = make([]nih, 1) // ERROR "heap allocation disallowed" z = make([]nih, 1) // ERROR "heap allocation disallowed"
z = append(z, x) // ERROR "heap allocation disallowed" z = append(z, x) // ERROR "heap allocation disallowed"
// Test for special case of OMAKESLICECOPY
x := make([]nih, n) // ERROR "heap allocation disallowed"
copy(x, z)
z = x
} }
// Writes don't produce write barriers. // Writes don't produce write barriers.