src/cmd/compile/internal/walk/compare.go - go - Git at Google

 // 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 walk

 import (
 	"encoding/binary"
 	"go/constant"

 	"cmd/compile/internal/base"
 	"cmd/compile/internal/ir"
 	"cmd/compile/internal/reflectdata"
 	"cmd/compile/internal/ssagen"
 	"cmd/compile/internal/typecheck"
 	"cmd/compile/internal/types"
 	"cmd/internal/sys"
 )

 // The result of walkCompare MUST be assigned back to n, e.g.
 // 	n.Left = walkCompare(n.Left, init)
 func walkCompare(n *ir.BinaryExpr, init *ir.Nodes) ir.Node {
 	if n.X.Type().IsInterface() && n.Y.Type().IsInterface() && n.X.Op() != ir.ONIL && n.Y.Op() != ir.ONIL {
 		return walkCompareInterface(n, init)
 	}

 	if n.X.Type().IsString() && n.Y.Type().IsString() {
 		return walkCompareString(n, init)
 	}

 	n.X = walkExpr(n.X, init)
 	n.Y = walkExpr(n.Y, init)

 	// Given mixed interface/concrete comparison,
 	// rewrite into types-equal && data-equal.
 	// This is efficient, avoids allocations, and avoids runtime calls.
 	if n.X.Type().IsInterface() != n.Y.Type().IsInterface() {
 		// Preserve side-effects in case of short-circuiting; see #32187.
 		l := cheapExpr(n.X, init)
 		r := cheapExpr(n.Y, init)
 		// Swap so that l is the interface value and r is the concrete value.
 		if n.Y.Type().IsInterface() {
 			l, r = r, l
 		}

 		// Handle both == and !=.
 		eq := n.Op()
 		andor := ir.OOROR
 		if eq == ir.OEQ {
 			andor = ir.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 ir.Node
 		tab := ir.NewUnaryExpr(base.Pos, ir.OITAB, l)
 		rtyp := reflectdata.TypePtr(r.Type())
 		if l.Type().IsEmptyInterface() {
 			tab.SetType(types.NewPtr(types.Types[types.TUINT8]))
 			tab.SetTypecheck(1)
 			eqtype = ir.NewBinaryExpr(base.Pos, eq, tab, rtyp)
 		} else {
 			nonnil := ir.NewBinaryExpr(base.Pos, brcom(eq), typecheck.NodNil(), tab)
 			match := ir.NewBinaryExpr(base.Pos, eq, itabType(tab), rtyp)
 			eqtype = ir.NewLogicalExpr(base.Pos, andor, nonnil, match)
 		}
 		// Check for data equal.
 		eqdata := ir.NewBinaryExpr(base.Pos, eq, ifaceData(n.Pos(), l, r.Type()), r)
 		// Put it all together.
 		expr := ir.NewLogicalExpr(base.Pos, andor, eqtype, eqdata)
 		return finishCompare(n, expr, init)
 	}

 	// 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.X.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(ssagen.Arch.LinkArch.RegSize)
 	}

 	switch t.Kind() {
 	default:
 		if base.Debug.Libfuzzer != 0 && t.IsInteger() {
 			n.X = cheapExpr(n.X, init)
 			n.Y = cheapExpr(n.Y, 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.X, n.Y
 			if r.Op() == ir.OLITERAL {
 				l, r = r, l
 			}
 			constcmp := l.Op() == ir.OLITERAL && r.Op() != ir.OLITERAL

 			var fn string
 			var paramType *types.Type
 			switch t.Size() {
 			case 1:
 				fn = "libfuzzerTraceCmp1"
 				if constcmp {
 					fn = "libfuzzerTraceConstCmp1"
 				}
 				paramType = types.Types[types.TUINT8]
 			case 2:
 				fn = "libfuzzerTraceCmp2"
 				if constcmp {
 					fn = "libfuzzerTraceConstCmp2"
 				}
 				paramType = types.Types[types.TUINT16]
 			case 4:
 				fn = "libfuzzerTraceCmp4"
 				if constcmp {
 					fn = "libfuzzerTraceConstCmp4"
 				}
 				paramType = types.Types[types.TUINT32]
 			case 8:
 				fn = "libfuzzerTraceCmp8"
 				if constcmp {
 					fn = "libfuzzerTraceConstCmp8"
 				}
 				paramType = types.Types[types.TUINT64]
 			default:
 				base.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 types.TARRAY:
 		// We can compare several elements at once with 2/4/8 byte integer compares
 		inline = t.NumElem() <= 1 || (types.IsSimple[t.Elem().Kind()] && (t.NumElem() <= 4 || t.Elem().Width*t.NumElem() <= maxcmpsize))
 	case types.TSTRUCT:
 		inline = t.NumComponents(types.IgnoreBlankFields) <= 4
 	}

 	cmpl := n.X
 	for cmpl != nil && cmpl.Op() == ir.OCONVNOP {
 		cmpl = cmpl.(*ir.ConvExpr).X
 	}
 	cmpr := n.Y
 	for cmpr != nil && cmpr.Op() == ir.OCONVNOP {
 		cmpr = cmpr.(*ir.ConvExpr).X
 	}

 	// Chose not to inline. Call equality function directly.
 	if !inline {
 		// eq algs take pointers; cmpl and cmpr must be addressable
 		if !ir.IsAddressable(cmpl) || !ir.IsAddressable(cmpr) {
 			base.Fatalf("arguments of comparison must be lvalues - %v %v", cmpl, cmpr)
 		}

 		fn, needsize := eqFor(t)
 		call := ir.NewCallExpr(base.Pos, ir.OCALL, fn, nil)
 		call.Args.Append(typecheck.NodAddr(cmpl))
 		call.Args.Append(typecheck.NodAddr(cmpr))
 		if needsize {
 			call.Args.Append(ir.NewInt(t.Width))
 		}
 		res := ir.Node(call)
 		if n.Op() != ir.OEQ {
 			res = ir.NewUnaryExpr(base.Pos, ir.ONOT, res)
 		}
 		return finishCompare(n, res, init)
 	}

 	// inline: build boolean expression comparing element by element
 	andor := ir.OANDAND
 	if n.Op() == ir.ONE {
 		andor = ir.OOROR
 	}
 	var expr ir.Node
 	compare := func(el, er ir.Node) {
 		a := ir.NewBinaryExpr(base.Pos, n.Op(), el, er)
 		if expr == nil {
 			expr = a
 		} else {
 			expr = ir.NewLogicalExpr(base.Pos, 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(
 				ir.NewSelectorExpr(base.Pos, ir.OXDOT, cmpl, sym),
 				ir.NewSelectorExpr(base.Pos, ir.OXDOT, cmpr, sym),
 			)
 		}
 	} else {
 		step := int64(1)
 		remains := t.NumElem() * t.Elem().Width
 		combine64bit := unalignedLoad && types.RegSize == 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[types.TINT64]
 				step = 8 / t.Elem().Width
 			case remains >= 4 && combine32bit:
 				convType = types.Types[types.TUINT32]
 				step = 4 / t.Elem().Width
 			case remains >= 2 && combine16bit:
 				convType = types.Types[types.TUINT16]
 				step = 2 / t.Elem().Width
 			default:
 				step = 1
 			}
 			if step == 1 {
 				compare(
 					ir.NewIndexExpr(base.Pos, cmpl, ir.NewInt(i)),
 					ir.NewIndexExpr(base.Pos, cmpr, ir.NewInt(i)),
 				)
 				i++
 				remains -= t.Elem().Width
 			} else {
 				elemType := t.Elem().ToUnsigned()
 				cmplw := ir.Node(ir.NewIndexExpr(base.Pos, cmpl, ir.NewInt(i)))
 				cmplw = typecheck.Conv(cmplw, elemType) // convert to unsigned
 				cmplw = typecheck.Conv(cmplw, convType) // widen
 				cmprw := ir.Node(ir.NewIndexExpr(base.Pos, cmpr, ir.NewInt(i)))
 				cmprw = typecheck.Conv(cmprw, elemType)
 				cmprw = typecheck.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 := ir.Node(ir.NewIndexExpr(base.Pos, cmpl, ir.NewInt(i+offset)))
 					lb = typecheck.Conv(lb, elemType)
 					lb = typecheck.Conv(lb, convType)
 					lb = ir.NewBinaryExpr(base.Pos, ir.OLSH, lb, ir.NewInt(8*t.Elem().Width*offset))
 					cmplw = ir.NewBinaryExpr(base.Pos, ir.OOR, cmplw, lb)
 					rb := ir.Node(ir.NewIndexExpr(base.Pos, cmpr, ir.NewInt(i+offset)))
 					rb = typecheck.Conv(rb, elemType)
 					rb = typecheck.Conv(rb, convType)
 					rb = ir.NewBinaryExpr(base.Pos, ir.OLSH, rb, ir.NewInt(8*t.Elem().Width*offset))
 					cmprw = ir.NewBinaryExpr(base.Pos, ir.OOR, cmprw, rb)
 				}
 				compare(cmplw, cmprw)
 				i += step
 				remains -= step * t.Elem().Width
 			}
 		}
 	}
 	if expr == nil {
 		expr = ir.NewBool(n.Op() == ir.OEQ)
 		// We still need to use cmpl and cmpr, in case they contain
 		// an expression which might panic. See issue 23837.
 		t := typecheck.Temp(cmpl.Type())
 		a1 := typecheck.Stmt(ir.NewAssignStmt(base.Pos, t, cmpl))
 		a2 := typecheck.Stmt(ir.NewAssignStmt(base.Pos, t, cmpr))
 		init.Append(a1, a2)
 	}
 	return finishCompare(n, expr, init)
 }

 func walkCompareInterface(n *ir.BinaryExpr, init *ir.Nodes) ir.Node {
 	n.Y = cheapExpr(n.Y, init)
 	n.X = cheapExpr(n.X, init)
 	eqtab, eqdata := reflectdata.EqInterface(n.X, n.Y)
 	var cmp ir.Node
 	if n.Op() == ir.OEQ {
 		cmp = ir.NewLogicalExpr(base.Pos, ir.OANDAND, eqtab, eqdata)
 	} else {
 		eqtab.SetOp(ir.ONE)
 		cmp = ir.NewLogicalExpr(base.Pos, ir.OOROR, eqtab, ir.NewUnaryExpr(base.Pos, ir.ONOT, eqdata))
 	}
 	return finishCompare(n, cmp, init)
 }

 func walkCompareString(n *ir.BinaryExpr, init *ir.Nodes) ir.Node {
 	// Rewrite comparisons to short constant strings as length+byte-wise comparisons.
 	var cs, ncs ir.Node // const string, non-const string
 	switch {
 	case ir.IsConst(n.X, constant.String) && ir.IsConst(n.Y, constant.String):
 		// ignore; will be constant evaluated
 	case ir.IsConst(n.X, constant.String):
 		cs = n.X
 		ncs = n.Y
 	case ir.IsConst(n.Y, constant.String):
 		cs = n.Y
 		ncs = n.X
 	}
 	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 ir.IsConst(n.X, constant.String) {
 			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 * ssagen.Arch.LinkArch.RegSize
 			combine64bit = ssagen.Arch.LinkArch.RegSize >= 8
 		}

 		var and ir.Op
 		switch cmp {
 		case ir.OEQ:
 			and = ir.OANDAND
 		case ir.ONE:
 			and = ir.OOROR
 		default:
 			// Don't do byte-wise comparisons for <, <=, etc.
 			// They're fairly complicated.
 			// Length-only checks are ok, though.
 			maxRewriteLen = 0
 		}
 		if s := ir.StringVal(cs); len(s) <= maxRewriteLen {
 			if len(s) > 0 {
 				ncs = safeExpr(ncs, init)
 			}
 			r := ir.Node(ir.NewBinaryExpr(base.Pos, cmp, ir.NewUnaryExpr(base.Pos, ir.OLEN, ncs), ir.NewInt(int64(len(s)))))
 			remains := len(s)
 			for i := 0; remains > 0; {
 				if remains == 1 || !canCombineLoads {
 					cb := ir.NewInt(int64(s[i]))
 					ncb := ir.NewIndexExpr(base.Pos, ncs, ir.NewInt(int64(i)))
 					r = ir.NewLogicalExpr(base.Pos, and, r, ir.NewBinaryExpr(base.Pos, cmp, ncb, cb))
 					remains--
 					i++
 					continue
 				}
 				var step int
 				var convType *types.Type
 				switch {
 				case remains >= 8 && combine64bit:
 					convType = types.Types[types.TINT64]
 					step = 8
 				case remains >= 4:
 					convType = types.Types[types.TUINT32]
 					step = 4
 				case remains >= 2:
 					convType = types.Types[types.TUINT16]
 					step = 2
 				}
 				ncsubstr := typecheck.Conv(ir.NewIndexExpr(base.Pos, ncs, ir.NewInt(int64(i))), 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 := typecheck.Conv(ir.NewIndexExpr(base.Pos, ncs, ir.NewInt(int64(i+offset))), convType)
 					b = ir.NewBinaryExpr(base.Pos, ir.OLSH, b, ir.NewInt(int64(8*offset)))
 					ncsubstr = ir.NewBinaryExpr(base.Pos, ir.OOR, ncsubstr, b)
 					csubstr |= int64(s[i+offset]) << uint8(8*offset)
 				}
 				csubstrPart := ir.NewInt(csubstr)
 				// Compare "step" bytes as once
 				r = ir.NewLogicalExpr(base.Pos, and, r, ir.NewBinaryExpr(base.Pos, cmp, csubstrPart, ncsubstr))
 				remains -= step
 				i += step
 			}
 			return finishCompare(n, r, init)
 		}
 	}

 	var r ir.Node
 	if n.Op() == ir.OEQ || n.Op() == ir.ONE {
 		// prepare for rewrite below
 		n.X = cheapExpr(n.X, init)
 		n.Y = cheapExpr(n.Y, init)
 		eqlen, eqmem := reflectdata.EqString(n.X, n.Y)
 		// quick check of len before full compare for == or !=.
 		// memequal then tests equality up to length len.
 		if n.Op() == ir.OEQ {
 			// len(left) == len(right) && memequal(left, right, len)
 			r = ir.NewLogicalExpr(base.Pos, ir.OANDAND, eqlen, eqmem)
 		} else {
 			// len(left) != len(right) || !memequal(left, right, len)
 			eqlen.SetOp(ir.ONE)
 			r = ir.NewLogicalExpr(base.Pos, ir.OOROR, eqlen, ir.NewUnaryExpr(base.Pos, ir.ONOT, eqmem))
 		}
 	} else {
 		// sys_cmpstring(s1, s2) :: 0
 		r = mkcall("cmpstring", types.Types[types.TINT], init, typecheck.Conv(n.X, types.Types[types.TSTRING]), typecheck.Conv(n.Y, types.Types[types.TSTRING]))
 		r = ir.NewBinaryExpr(base.Pos, n.Op(), r, ir.NewInt(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 *ir.BinaryExpr, r ir.Node, init *ir.Nodes) ir.Node {
 	r = typecheck.Expr(r)
 	r = typecheck.Conv(r, n.Type())
 	r = walkExpr(r, init)
 	return r
 }

 func eqFor(t *types.Type) (n ir.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, _ := types.AlgType(t); a {
 	case types.AMEM:
 		n := typecheck.LookupRuntime("memequal")
 		n = typecheck.SubstArgTypes(n, t, t)
 		return n, true
 	case types.ASPECIAL:
 		sym := reflectdata.TypeSymPrefix(".eq", t)
 		// TODO(austin): This creates an ir.Name with a nil Func.
 		n := typecheck.NewName(sym)
 		ir.MarkFunc(n)
 		n.SetType(types.NewSignature(types.NoPkg, nil, nil, []*types.Field{
 			types.NewField(base.Pos, nil, types.NewPtr(t)),
 			types.NewField(base.Pos, nil, types.NewPtr(t)),
 		}, []*types.Field{
 			types.NewField(base.Pos, nil, types.Types[types.TBOOL]),
 		}))
 		return n, false
 	}
 	base.Fatalf("eqFor %v", t)
 	return nil, false
 }

 // brcom returns !(op).
 // For example, brcom(==) is !=.
 func brcom(op ir.Op) ir.Op {
 	switch op {
 	case ir.OEQ:
 		return ir.ONE
 	case ir.ONE:
 		return ir.OEQ
 	case ir.OLT:
 		return ir.OGE
 	case ir.OGT:
 		return ir.OLE
 	case ir.OLE:
 		return ir.OGT
 	case ir.OGE:
 		return ir.OLT
 	}
 	base.Fatalf("brcom: no com for %v\n", op)
 	return op
 }

 // brrev returns reverse(op).
 // For example, Brrev(<) is >.
 func brrev(op ir.Op) ir.Op {
 	switch op {
 	case ir.OEQ:
 		return ir.OEQ
 	case ir.ONE:
 		return ir.ONE
 	case ir.OLT:
 		return ir.OGT
 	case ir.OGT:
 		return ir.OLT
 	case ir.OLE:
 		return ir.OGE
 	case ir.OGE:
 		return ir.OLE
 	}
 	base.Fatalf("brrev: no rev for %v\n", op)
 	return op
 }

 func tracecmpArg(n ir.Node, t *types.Type, init *ir.Nodes) ir.Node {
 	// Ugly hack to avoid "constant -1 overflows uintptr" errors, etc.
 	if n.Op() == ir.OLITERAL && n.Type().IsSigned() && ir.Int64Val(n) < 0 {
 		n = copyExpr(n, n.Type(), init)
 	}

 	return typecheck.Conv(n, t)
 }

 // 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 ssagen.Arch.LinkArch.Family {
 	case sys.ARM64, sys.AMD64, sys.I386, sys.S390X:
 		return true
 	case sys.PPC64:
 		// Load combining only supported on ppc64le.
 		return ssagen.Arch.LinkArch.ByteOrder == binary.LittleEndian
 	}
 	return false
 }
	// 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 walk

	import (
	"encoding/binary"
	"go/constant"

	"cmd/compile/internal/base"
	"cmd/compile/internal/ir"
	"cmd/compile/internal/reflectdata"
	"cmd/compile/internal/ssagen"
	"cmd/compile/internal/typecheck"
	"cmd/compile/internal/types"
	"cmd/internal/sys"
	)

	// The result of walkCompare MUST be assigned back to n, e.g.
	// n.Left = walkCompare(n.Left, init)
	func walkCompare(n ir.BinaryExpr, init ir.Nodes) ir.Node {
	if n.X.Type().IsInterface() && n.Y.Type().IsInterface() && n.X.Op() != ir.ONIL && n.Y.Op() != ir.ONIL {
	return walkCompareInterface(n, init)
	}

	if n.X.Type().IsString() && n.Y.Type().IsString() {
	return walkCompareString(n, init)
	}

	n.X = walkExpr(n.X, init)
	n.Y = walkExpr(n.Y, init)

	// Given mixed interface/concrete comparison,
	// rewrite into types-equal && data-equal.
	// This is efficient, avoids allocations, and avoids runtime calls.
	if n.X.Type().IsInterface() != n.Y.Type().IsInterface() {
	// Preserve side-effects in case of short-circuiting; see #32187.
	l := cheapExpr(n.X, init)
	r := cheapExpr(n.Y, init)
	// Swap so that l is the interface value and r is the concrete value.
	if n.Y.Type().IsInterface() {
	l, r = r, l
	}

	// Handle both == and !=.
	eq := n.Op()
	andor := ir.OOROR
	if eq == ir.OEQ {
	andor = ir.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 ir.Node
	tab := ir.NewUnaryExpr(base.Pos, ir.OITAB, l)
	rtyp := reflectdata.TypePtr(r.Type())
	if l.Type().IsEmptyInterface() {
	tab.SetType(types.NewPtr(types.Types[types.TUINT8]))
	tab.SetTypecheck(1)
	eqtype = ir.NewBinaryExpr(base.Pos, eq, tab, rtyp)
	} else {
	nonnil := ir.NewBinaryExpr(base.Pos, brcom(eq), typecheck.NodNil(), tab)
	match := ir.NewBinaryExpr(base.Pos, eq, itabType(tab), rtyp)
	eqtype = ir.NewLogicalExpr(base.Pos, andor, nonnil, match)
	}
	// Check for data equal.
	eqdata := ir.NewBinaryExpr(base.Pos, eq, ifaceData(n.Pos(), l, r.Type()), r)
	// Put it all together.
	expr := ir.NewLogicalExpr(base.Pos, andor, eqtype, eqdata)
	return finishCompare(n, expr, init)
	}

	// 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.X.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(ssagen.Arch.LinkArch.RegSize)
	}

	switch t.Kind() {
	default:
	if base.Debug.Libfuzzer != 0 && t.IsInteger() {
	n.X = cheapExpr(n.X, init)
	n.Y = cheapExpr(n.Y, 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.X, n.Y
	if r.Op() == ir.OLITERAL {
	l, r = r, l
	}
	constcmp := l.Op() == ir.OLITERAL && r.Op() != ir.OLITERAL

	var fn string
	var paramType *types.Type
	switch t.Size() {
	case 1:
	fn = "libfuzzerTraceCmp1"
	if constcmp {
	fn = "libfuzzerTraceConstCmp1"
	}
	paramType = types.Types[types.TUINT8]
	case 2:
	fn = "libfuzzerTraceCmp2"
	if constcmp {
	fn = "libfuzzerTraceConstCmp2"
	}
	paramType = types.Types[types.TUINT16]
	case 4:
	fn = "libfuzzerTraceCmp4"
	if constcmp {
	fn = "libfuzzerTraceConstCmp4"
	}
	paramType = types.Types[types.TUINT32]
	case 8:
	fn = "libfuzzerTraceCmp8"
	if constcmp {
	fn = "libfuzzerTraceConstCmp8"
	}
	paramType = types.Types[types.TUINT64]
	default:
	base.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 types.TARRAY:
	// We can compare several elements at once with 2/4/8 byte integer compares
	inline = t.NumElem() <= 1 \|\| (types.IsSimple[t.Elem().Kind()] && (t.NumElem() <= 4 \|\| t.Elem().Width*t.NumElem() <= maxcmpsize))
	case types.TSTRUCT:
	inline = t.NumComponents(types.IgnoreBlankFields) <= 4
	}

	cmpl := n.X
	for cmpl != nil && cmpl.Op() == ir.OCONVNOP {
	cmpl = cmpl.(*ir.ConvExpr).X
	}
	cmpr := n.Y
	for cmpr != nil && cmpr.Op() == ir.OCONVNOP {
	cmpr = cmpr.(*ir.ConvExpr).X
	}

	// Chose not to inline. Call equality function directly.
	if !inline {
	// eq algs take pointers; cmpl and cmpr must be addressable
	if !ir.IsAddressable(cmpl) \|\| !ir.IsAddressable(cmpr) {
	base.Fatalf("arguments of comparison must be lvalues - %v %v", cmpl, cmpr)
	}

	fn, needsize := eqFor(t)
	call := ir.NewCallExpr(base.Pos, ir.OCALL, fn, nil)
	call.Args.Append(typecheck.NodAddr(cmpl))
	call.Args.Append(typecheck.NodAddr(cmpr))
	if needsize {
	call.Args.Append(ir.NewInt(t.Width))
	}
	res := ir.Node(call)
	if n.Op() != ir.OEQ {
	res = ir.NewUnaryExpr(base.Pos, ir.ONOT, res)
	}
	return finishCompare(n, res, init)
	}

	// inline: build boolean expression comparing element by element
	andor := ir.OANDAND
	if n.Op() == ir.ONE {
	andor = ir.OOROR
	}
	var expr ir.Node
	compare := func(el, er ir.Node) {
	a := ir.NewBinaryExpr(base.Pos, n.Op(), el, er)
	if expr == nil {
	expr = a
	} else {
	expr = ir.NewLogicalExpr(base.Pos, 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(
	ir.NewSelectorExpr(base.Pos, ir.OXDOT, cmpl, sym),
	ir.NewSelectorExpr(base.Pos, ir.OXDOT, cmpr, sym),
	)
	}
	} else {
	step := int64(1)
	remains := t.NumElem() * t.Elem().Width
	combine64bit := unalignedLoad && types.RegSize == 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[types.TINT64]
	step = 8 / t.Elem().Width
	case remains >= 4 && combine32bit:
	convType = types.Types[types.TUINT32]
	step = 4 / t.Elem().Width
	case remains >= 2 && combine16bit:
	convType = types.Types[types.TUINT16]
	step = 2 / t.Elem().Width
	default:
	step = 1
	}
	if step == 1 {
	compare(
	ir.NewIndexExpr(base.Pos, cmpl, ir.NewInt(i)),
	ir.NewIndexExpr(base.Pos, cmpr, ir.NewInt(i)),
	)
	i++
	remains -= t.Elem().Width
	} else {
	elemType := t.Elem().ToUnsigned()
	cmplw := ir.Node(ir.NewIndexExpr(base.Pos, cmpl, ir.NewInt(i)))
	cmplw = typecheck.Conv(cmplw, elemType) // convert to unsigned
	cmplw = typecheck.Conv(cmplw, convType) // widen
	cmprw := ir.Node(ir.NewIndexExpr(base.Pos, cmpr, ir.NewInt(i)))
	cmprw = typecheck.Conv(cmprw, elemType)
	cmprw = typecheck.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 := ir.Node(ir.NewIndexExpr(base.Pos, cmpl, ir.NewInt(i+offset)))
	lb = typecheck.Conv(lb, elemType)
	lb = typecheck.Conv(lb, convType)
	lb = ir.NewBinaryExpr(base.Pos, ir.OLSH, lb, ir.NewInt(8t.Elem().Widthoffset))
	cmplw = ir.NewBinaryExpr(base.Pos, ir.OOR, cmplw, lb)
	rb := ir.Node(ir.NewIndexExpr(base.Pos, cmpr, ir.NewInt(i+offset)))
	rb = typecheck.Conv(rb, elemType)
	rb = typecheck.Conv(rb, convType)
	rb = ir.NewBinaryExpr(base.Pos, ir.OLSH, rb, ir.NewInt(8t.Elem().Widthoffset))
	cmprw = ir.NewBinaryExpr(base.Pos, ir.OOR, cmprw, rb)
	}
	compare(cmplw, cmprw)
	i += step
	remains -= step * t.Elem().Width
	}
	}
	}
	if expr == nil {
	expr = ir.NewBool(n.Op() == ir.OEQ)
	// We still need to use cmpl and cmpr, in case they contain
	// an expression which might panic. See issue 23837.
	t := typecheck.Temp(cmpl.Type())
	a1 := typecheck.Stmt(ir.NewAssignStmt(base.Pos, t, cmpl))
	a2 := typecheck.Stmt(ir.NewAssignStmt(base.Pos, t, cmpr))
	init.Append(a1, a2)
	}
	return finishCompare(n, expr, init)
	}

	func walkCompareInterface(n ir.BinaryExpr, init ir.Nodes) ir.Node {
	n.Y = cheapExpr(n.Y, init)
	n.X = cheapExpr(n.X, init)
	eqtab, eqdata := reflectdata.EqInterface(n.X, n.Y)
	var cmp ir.Node
	if n.Op() == ir.OEQ {
	cmp = ir.NewLogicalExpr(base.Pos, ir.OANDAND, eqtab, eqdata)
	} else {
	eqtab.SetOp(ir.ONE)
	cmp = ir.NewLogicalExpr(base.Pos, ir.OOROR, eqtab, ir.NewUnaryExpr(base.Pos, ir.ONOT, eqdata))
	}
	return finishCompare(n, cmp, init)
	}

	func walkCompareString(n ir.BinaryExpr, init ir.Nodes) ir.Node {
	// Rewrite comparisons to short constant strings as length+byte-wise comparisons.
	var cs, ncs ir.Node // const string, non-const string
	switch {
	case ir.IsConst(n.X, constant.String) && ir.IsConst(n.Y, constant.String):
	// ignore; will be constant evaluated
	case ir.IsConst(n.X, constant.String):
	cs = n.X
	ncs = n.Y
	case ir.IsConst(n.Y, constant.String):
	cs = n.Y
	ncs = n.X
	}
	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 ir.IsConst(n.X, constant.String) {
	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 * ssagen.Arch.LinkArch.RegSize
	combine64bit = ssagen.Arch.LinkArch.RegSize >= 8
	}

	var and ir.Op
	switch cmp {
	case ir.OEQ:
	and = ir.OANDAND
	case ir.ONE:
	and = ir.OOROR
	default:
	// Don't do byte-wise comparisons for <, <=, etc.
	// They're fairly complicated.
	// Length-only checks are ok, though.
	maxRewriteLen = 0
	}
	if s := ir.StringVal(cs); len(s) <= maxRewriteLen {
	if len(s) > 0 {
	ncs = safeExpr(ncs, init)
	}
	r := ir.Node(ir.NewBinaryExpr(base.Pos, cmp, ir.NewUnaryExpr(base.Pos, ir.OLEN, ncs), ir.NewInt(int64(len(s)))))
	remains := len(s)
	for i := 0; remains > 0; {
	if remains == 1 \|\| !canCombineLoads {
	cb := ir.NewInt(int64(s[i]))
	ncb := ir.NewIndexExpr(base.Pos, ncs, ir.NewInt(int64(i)))
	r = ir.NewLogicalExpr(base.Pos, and, r, ir.NewBinaryExpr(base.Pos, cmp, ncb, cb))
	remains--
	i++
	continue
	}
	var step int
	var convType *types.Type
	switch {
	case remains >= 8 && combine64bit:
	convType = types.Types[types.TINT64]
	step = 8
	case remains >= 4:
	convType = types.Types[types.TUINT32]
	step = 4
	case remains >= 2:
	convType = types.Types[types.TUINT16]
	step = 2
	}
	ncsubstr := typecheck.Conv(ir.NewIndexExpr(base.Pos, ncs, ir.NewInt(int64(i))), 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 := typecheck.Conv(ir.NewIndexExpr(base.Pos, ncs, ir.NewInt(int64(i+offset))), convType)
	b = ir.NewBinaryExpr(base.Pos, ir.OLSH, b, ir.NewInt(int64(8*offset)))
	ncsubstr = ir.NewBinaryExpr(base.Pos, ir.OOR, ncsubstr, b)
	csubstr \|= int64(s[i+offset]) << uint8(8*offset)
	}
	csubstrPart := ir.NewInt(csubstr)
	// Compare "step" bytes as once
	r = ir.NewLogicalExpr(base.Pos, and, r, ir.NewBinaryExpr(base.Pos, cmp, csubstrPart, ncsubstr))
	remains -= step
	i += step
	}
	return finishCompare(n, r, init)
	}
	}

	var r ir.Node
	if n.Op() == ir.OEQ \|\| n.Op() == ir.ONE {
	// prepare for rewrite below
	n.X = cheapExpr(n.X, init)
	n.Y = cheapExpr(n.Y, init)
	eqlen, eqmem := reflectdata.EqString(n.X, n.Y)
	// quick check of len before full compare for == or !=.
	// memequal then tests equality up to length len.
	if n.Op() == ir.OEQ {
	// len(left) == len(right) && memequal(left, right, len)
	r = ir.NewLogicalExpr(base.Pos, ir.OANDAND, eqlen, eqmem)
	} else {
	// len(left) != len(right) \|\| !memequal(left, right, len)
	eqlen.SetOp(ir.ONE)
	r = ir.NewLogicalExpr(base.Pos, ir.OOROR, eqlen, ir.NewUnaryExpr(base.Pos, ir.ONOT, eqmem))
	}
	} else {
	// sys_cmpstring(s1, s2) :: 0
	r = mkcall("cmpstring", types.Types[types.TINT], init, typecheck.Conv(n.X, types.Types[types.TSTRING]), typecheck.Conv(n.Y, types.Types[types.TSTRING]))
	r = ir.NewBinaryExpr(base.Pos, n.Op(), r, ir.NewInt(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 ir.BinaryExpr, r ir.Node, init ir.Nodes) ir.Node {
	r = typecheck.Expr(r)
	r = typecheck.Conv(r, n.Type())
	r = walkExpr(r, init)
	return r
	}

	func eqFor(t *types.Type) (n ir.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, _ := types.AlgType(t); a {
	case types.AMEM:
	n := typecheck.LookupRuntime("memequal")
	n = typecheck.SubstArgTypes(n, t, t)
	return n, true
	case types.ASPECIAL:
	sym := reflectdata.TypeSymPrefix(".eq", t)
	// TODO(austin): This creates an ir.Name with a nil Func.
	n := typecheck.NewName(sym)
	ir.MarkFunc(n)
	n.SetType(types.NewSignature(types.NoPkg, nil, nil, []*types.Field{
	types.NewField(base.Pos, nil, types.NewPtr(t)),
	types.NewField(base.Pos, nil, types.NewPtr(t)),
	}, []*types.Field{
	types.NewField(base.Pos, nil, types.Types[types.TBOOL]),
	}))
	return n, false
	}
	base.Fatalf("eqFor %v", t)
	return nil, false
	}

	// brcom returns !(op).
	// For example, brcom(==) is !=.
	func brcom(op ir.Op) ir.Op {
	switch op {
	case ir.OEQ:
	return ir.ONE
	case ir.ONE:
	return ir.OEQ
	case ir.OLT:
	return ir.OGE
	case ir.OGT:
	return ir.OLE
	case ir.OLE:
	return ir.OGT
	case ir.OGE:
	return ir.OLT
	}
	base.Fatalf("brcom: no com for %v\n", op)
	return op
	}

	// brrev returns reverse(op).
	// For example, Brrev(<) is >.
	func brrev(op ir.Op) ir.Op {
	switch op {
	case ir.OEQ:
	return ir.OEQ
	case ir.ONE:
	return ir.ONE
	case ir.OLT:
	return ir.OGT
	case ir.OGT:
	return ir.OLT
	case ir.OLE:
	return ir.OGE
	case ir.OGE:
	return ir.OLE
	}
	base.Fatalf("brrev: no rev for %v\n", op)
	return op
	}

	func tracecmpArg(n ir.Node, t types.Type, init ir.Nodes) ir.Node {
	// Ugly hack to avoid "constant -1 overflows uintptr" errors, etc.
	if n.Op() == ir.OLITERAL && n.Type().IsSigned() && ir.Int64Val(n) < 0 {
	n = copyExpr(n, n.Type(), init)
	}

	return typecheck.Conv(n, t)
	}

	// 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 ssagen.Arch.LinkArch.Family {
	case sys.ARM64, sys.AMD64, sys.I386, sys.S390X:
	return true
	case sys.PPC64:
	// Load combining only supported on ppc64le.
	return ssagen.Arch.LinkArch.ByteOrder == binary.LittleEndian
	}
	return false
	}