File size: 6,965 Bytes
fc11197 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 | // Copyright 2018 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 escape
import (
"cmd/compile/internal/ir"
"cmd/compile/internal/typecheck"
"cmd/compile/internal/types"
)
func isSliceSelfAssign(dst, src ir.Node) bool {
// Detect the following special case.
//
// func (b *Buffer) Foo() {
// n, m := ...
// b.buf = b.buf[n:m]
// }
//
// This assignment is a no-op for escape analysis,
// it does not store any new pointers into b that were not already there.
// However, without this special case b will escape, because we assign to OIND/ODOTPTR.
// Here we assume that the statement will not contain calls,
// that is, that order will move any calls to init.
// Otherwise base ONAME value could change between the moments
// when we evaluate it for dst and for src.
// dst is ONAME dereference.
var dstX ir.Node
switch dst.Op() {
default:
return false
case ir.ODEREF:
dst := dst.(*ir.StarExpr)
dstX = dst.X
case ir.ODOTPTR:
dst := dst.(*ir.SelectorExpr)
dstX = dst.X
}
if dstX.Op() != ir.ONAME {
return false
}
// src is a slice operation.
switch src.Op() {
case ir.OSLICE, ir.OSLICE3, ir.OSLICESTR:
// OK.
case ir.OSLICEARR, ir.OSLICE3ARR:
// Since arrays are embedded into containing object,
// slice of non-pointer array will introduce a new pointer into b that was not already there
// (pointer to b itself). After such assignment, if b contents escape,
// b escapes as well. If we ignore such OSLICEARR, we will conclude
// that b does not escape when b contents do.
//
// Pointer to an array is OK since it's not stored inside b directly.
// For slicing an array (not pointer to array), there is an implicit OADDR.
// We check that to determine non-pointer array slicing.
src := src.(*ir.SliceExpr)
if src.X.Op() == ir.OADDR {
return false
}
default:
return false
}
// slice is applied to ONAME dereference.
var baseX ir.Node
switch base := src.(*ir.SliceExpr).X; base.Op() {
default:
return false
case ir.ODEREF:
base := base.(*ir.StarExpr)
baseX = base.X
case ir.ODOTPTR:
base := base.(*ir.SelectorExpr)
baseX = base.X
}
if baseX.Op() != ir.ONAME {
return false
}
// dst and src reference the same base ONAME.
return dstX.(*ir.Name) == baseX.(*ir.Name)
}
// isSelfAssign reports whether assignment from src to dst can
// be ignored by the escape analysis as it's effectively a self-assignment.
func isSelfAssign(dst, src ir.Node) bool {
if isSliceSelfAssign(dst, src) {
return true
}
// Detect trivial assignments that assign back to the same object.
//
// It covers these cases:
// val.x = val.y
// val.x[i] = val.y[j]
// val.x1.x2 = val.x1.y2
// ... etc
//
// These assignments do not change assigned object lifetime.
if dst == nil || src == nil || dst.Op() != src.Op() {
return false
}
// The expression prefix must be both "safe" and identical.
switch dst.Op() {
case ir.ODOT, ir.ODOTPTR:
// Safe trailing accessors that are permitted to differ.
dst := dst.(*ir.SelectorExpr)
src := src.(*ir.SelectorExpr)
return ir.SameSafeExpr(dst.X, src.X)
case ir.OINDEX:
dst := dst.(*ir.IndexExpr)
src := src.(*ir.IndexExpr)
if mayAffectMemory(dst.Index) || mayAffectMemory(src.Index) {
return false
}
return ir.SameSafeExpr(dst.X, src.X)
default:
return false
}
}
// mayAffectMemory reports whether evaluation of n may affect the program's
// memory state. If the expression can't affect memory state, then it can be
// safely ignored by the escape analysis.
func mayAffectMemory(n ir.Node) bool {
// We may want to use a list of "memory safe" ops instead of generally
// "side-effect free", which would include all calls and other ops that can
// allocate or change global state. For now, it's safer to start with the latter.
//
// We're ignoring things like division by zero, index out of range,
// and nil pointer dereference here.
// TODO(rsc): It seems like it should be possible to replace this with
// an ir.Any looking for any op that's not the ones in the case statement.
// But that produces changes in the compiled output detected by buildall.
switch n.Op() {
case ir.ONAME, ir.OLITERAL, ir.ONIL:
return false
case ir.OADD, ir.OSUB, ir.OOR, ir.OXOR, ir.OMUL, ir.OLSH, ir.ORSH, ir.OAND, ir.OANDNOT, ir.ODIV, ir.OMOD:
n := n.(*ir.BinaryExpr)
return mayAffectMemory(n.X) || mayAffectMemory(n.Y)
case ir.OINDEX:
n := n.(*ir.IndexExpr)
return mayAffectMemory(n.X) || mayAffectMemory(n.Index)
case ir.OCONVNOP, ir.OCONV:
n := n.(*ir.ConvExpr)
return mayAffectMemory(n.X)
case ir.OLEN, ir.OCAP, ir.ONOT, ir.OBITNOT, ir.OPLUS, ir.ONEG:
n := n.(*ir.UnaryExpr)
return mayAffectMemory(n.X)
case ir.ODOT, ir.ODOTPTR:
n := n.(*ir.SelectorExpr)
return mayAffectMemory(n.X)
case ir.ODEREF:
n := n.(*ir.StarExpr)
return mayAffectMemory(n.X)
default:
return true
}
}
// HeapAllocReason returns the reason the given Node must be heap
// allocated, or the empty string if it doesn't.
func HeapAllocReason(n ir.Node) string {
if n == nil || n.Type() == nil {
return ""
}
// Parameters are always passed via the stack.
if n.Op() == ir.ONAME {
n := n.(*ir.Name)
if n.Class == ir.PPARAM || n.Class == ir.PPARAMOUT {
return ""
}
}
if n.Type().Size() > ir.MaxStackVarSize {
return "too large for stack"
}
if n.Type().Alignment() > int64(types.PtrSize) {
return "too aligned for stack"
}
if (n.Op() == ir.ONEW || n.Op() == ir.OPTRLIT) && n.Type().Elem().Size() > ir.MaxImplicitStackVarSize {
return "too large for stack"
}
if (n.Op() == ir.ONEW || n.Op() == ir.OPTRLIT) && n.Type().Elem().Alignment() > int64(types.PtrSize) {
return "too aligned for stack"
}
if n.Op() == ir.OCLOSURE && typecheck.ClosureType(n.(*ir.ClosureExpr)).Size() > ir.MaxImplicitStackVarSize {
return "too large for stack"
}
if n.Op() == ir.OMETHVALUE && typecheck.MethodValueType(n.(*ir.SelectorExpr)).Size() > ir.MaxImplicitStackVarSize {
return "too large for stack"
}
if n.Op() == ir.OMAKESLICE {
n := n.(*ir.MakeExpr)
r := n.Cap
if n.Cap == nil {
r = n.Len
}
elem := n.Type().Elem()
if elem.Size() == 0 {
// TODO: stack allocate these? See #65685.
return "zero-sized element"
}
if !ir.IsSmallIntConst(r) {
// For non-constant sizes, we do a hybrid approach:
//
// if cap <= K {
// var backing [K]E
// s = backing[:len:cap]
// } else {
// s = makeslice(E, len, cap)
// }
//
// It costs a constant amount of stack space, but may
// avoid a heap allocation.
// Note we have to be careful that assigning s[i] = v
// still escapes v, because we forbid heap->stack pointers.
// Implementation is in ../walk/builtin.go:walkMakeSlice.
return ""
}
if ir.Int64Val(r) > ir.MaxImplicitStackVarSize/elem.Size() {
return "too large for stack"
}
}
return ""
}
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