src/cmd/compile/internal/escape/utils.go - toolchain/go - Git at Google

 // 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, ir.OALIGNOF, ir.OOFFSETOF, ir.OSIZEOF:
 		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 r == nil {
 			r = n.Len
 		}
 		if !ir.IsSmallIntConst(r) {
 			return "non-constant size"
 		}
 		if t := n.Type(); t.Elem().Size() != 0 && ir.Int64Val(r) > ir.MaxImplicitStackVarSize/t.Elem().Size() {
 			return "too large for stack"
 		}
 	}

 	return ""
 }
	// 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, ir.OALIGNOF, ir.OOFFSETOF, ir.OSIZEOF:
	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 r == nil {
	r = n.Len
	}
	if !ir.IsSmallIntConst(r) {
	return "non-constant size"
	}
	if t := n.Type(); t.Elem().Size() != 0 && ir.Int64Val(r) > ir.MaxImplicitStackVarSize/t.Elem().Size() {
	return "too large for stack"
	}
	}

	return ""
	}