src/cmd/compile/internal/ssa/rewritedec.go - go - Git at Google

 // Code generated from gen/dec.rules; DO NOT EDIT.
 // generated with: cd gen; go run *.go

 package ssa

 import "fmt"
 import "math"
 import "cmd/internal/obj"
 import "cmd/internal/objabi"
 import "cmd/compile/internal/types"

 var _ = fmt.Println   // in case not otherwise used
 var _ = math.MinInt8  // in case not otherwise used
 var _ = obj.ANOP      // in case not otherwise used
 var _ = objabi.GOROOT // in case not otherwise used
 var _ = types.TypeMem // in case not otherwise used

 func rewriteValuedec(v *Value) bool {
 	switch v.Op {
 	case OpComplexImag:
 		return rewriteValuedec_OpComplexImag_0(v)
 	case OpComplexReal:
 		return rewriteValuedec_OpComplexReal_0(v)
 	case OpIData:
 		return rewriteValuedec_OpIData_0(v)
 	case OpITab:
 		return rewriteValuedec_OpITab_0(v)
 	case OpLoad:
 		return rewriteValuedec_OpLoad_0(v)
 	case OpSliceCap:
 		return rewriteValuedec_OpSliceCap_0(v)
 	case OpSliceLen:
 		return rewriteValuedec_OpSliceLen_0(v)
 	case OpSlicePtr:
 		return rewriteValuedec_OpSlicePtr_0(v)
 	case OpStore:
 		return rewriteValuedec_OpStore_0(v)
 	case OpStringLen:
 		return rewriteValuedec_OpStringLen_0(v)
 	case OpStringPtr:
 		return rewriteValuedec_OpStringPtr_0(v)
 	}
 	return false
 }
 func rewriteValuedec_OpComplexImag_0(v *Value) bool {
 	// match: (ComplexImag (ComplexMake _ imag))
 	// cond:
 	// result: imag
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpComplexMake {
 			break
 		}
 		_ = v_0.Args[1]
 		imag := v_0.Args[1]
 		v.reset(OpCopy)
 		v.Type = imag.Type
 		v.AddArg(imag)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpComplexReal_0(v *Value) bool {
 	// match: (ComplexReal (ComplexMake real _))
 	// cond:
 	// result: real
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpComplexMake {
 			break
 		}
 		_ = v_0.Args[1]
 		real := v_0.Args[0]
 		v.reset(OpCopy)
 		v.Type = real.Type
 		v.AddArg(real)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpIData_0(v *Value) bool {
 	// match: (IData (IMake _ data))
 	// cond:
 	// result: data
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpIMake {
 			break
 		}
 		_ = v_0.Args[1]
 		data := v_0.Args[1]
 		v.reset(OpCopy)
 		v.Type = data.Type
 		v.AddArg(data)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpITab_0(v *Value) bool {
 	b := v.Block
 	_ = b
 	// match: (ITab (IMake itab _))
 	// cond:
 	// result: itab
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpIMake {
 			break
 		}
 		_ = v_0.Args[1]
 		itab := v_0.Args[0]
 		v.reset(OpCopy)
 		v.Type = itab.Type
 		v.AddArg(itab)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpLoad_0(v *Value) bool {
 	b := v.Block
 	_ = b
 	config := b.Func.Config
 	_ = config
 	typ := &b.Func.Config.Types
 	_ = typ
 	// match: (Load <t> ptr mem)
 	// cond: t.IsComplex() && t.Size() == 8
 	// result: (ComplexMake (Load <typ.Float32> ptr mem) (Load <typ.Float32> (OffPtr <typ.Float32Ptr> [4] ptr) mem) )
 	for {
 		t := v.Type
 		_ = v.Args[1]
 		ptr := v.Args[0]
 		mem := v.Args[1]
 		if !(t.IsComplex() && t.Size() == 8) {
 			break
 		}
 		v.reset(OpComplexMake)
 		v0 := b.NewValue0(v.Pos, OpLoad, typ.Float32)
 		v0.AddArg(ptr)
 		v0.AddArg(mem)
 		v.AddArg(v0)
 		v1 := b.NewValue0(v.Pos, OpLoad, typ.Float32)
 		v2 := b.NewValue0(v.Pos, OpOffPtr, typ.Float32Ptr)
 		v2.AuxInt = 4
 		v2.AddArg(ptr)
 		v1.AddArg(v2)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Load <t> ptr mem)
 	// cond: t.IsComplex() && t.Size() == 16
 	// result: (ComplexMake (Load <typ.Float64> ptr mem) (Load <typ.Float64> (OffPtr <typ.Float64Ptr> [8] ptr) mem) )
 	for {
 		t := v.Type
 		_ = v.Args[1]
 		ptr := v.Args[0]
 		mem := v.Args[1]
 		if !(t.IsComplex() && t.Size() == 16) {
 			break
 		}
 		v.reset(OpComplexMake)
 		v0 := b.NewValue0(v.Pos, OpLoad, typ.Float64)
 		v0.AddArg(ptr)
 		v0.AddArg(mem)
 		v.AddArg(v0)
 		v1 := b.NewValue0(v.Pos, OpLoad, typ.Float64)
 		v2 := b.NewValue0(v.Pos, OpOffPtr, typ.Float64Ptr)
 		v2.AuxInt = 8
 		v2.AddArg(ptr)
 		v1.AddArg(v2)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Load <t> ptr mem)
 	// cond: t.IsString()
 	// result: (StringMake (Load <typ.BytePtr> ptr mem) (Load <typ.Int> (OffPtr <typ.IntPtr> [config.PtrSize] ptr) mem))
 	for {
 		t := v.Type
 		_ = v.Args[1]
 		ptr := v.Args[0]
 		mem := v.Args[1]
 		if !(t.IsString()) {
 			break
 		}
 		v.reset(OpStringMake)
 		v0 := b.NewValue0(v.Pos, OpLoad, typ.BytePtr)
 		v0.AddArg(ptr)
 		v0.AddArg(mem)
 		v.AddArg(v0)
 		v1 := b.NewValue0(v.Pos, OpLoad, typ.Int)
 		v2 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
 		v2.AuxInt = config.PtrSize
 		v2.AddArg(ptr)
 		v1.AddArg(v2)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Load <t> ptr mem)
 	// cond: t.IsSlice()
 	// result: (SliceMake (Load <t.Elem().PtrTo()> ptr mem) (Load <typ.Int> (OffPtr <typ.IntPtr> [config.PtrSize] ptr) mem) (Load <typ.Int> (OffPtr <typ.IntPtr> [2*config.PtrSize] ptr) mem))
 	for {
 		t := v.Type
 		_ = v.Args[1]
 		ptr := v.Args[0]
 		mem := v.Args[1]
 		if !(t.IsSlice()) {
 			break
 		}
 		v.reset(OpSliceMake)
 		v0 := b.NewValue0(v.Pos, OpLoad, t.Elem().PtrTo())
 		v0.AddArg(ptr)
 		v0.AddArg(mem)
 		v.AddArg(v0)
 		v1 := b.NewValue0(v.Pos, OpLoad, typ.Int)
 		v2 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
 		v2.AuxInt = config.PtrSize
 		v2.AddArg(ptr)
 		v1.AddArg(v2)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		v3 := b.NewValue0(v.Pos, OpLoad, typ.Int)
 		v4 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
 		v4.AuxInt = 2 * config.PtrSize
 		v4.AddArg(ptr)
 		v3.AddArg(v4)
 		v3.AddArg(mem)
 		v.AddArg(v3)
 		return true
 	}
 	// match: (Load <t> ptr mem)
 	// cond: t.IsInterface()
 	// result: (IMake (Load <typ.Uintptr> ptr mem) (Load <typ.BytePtr> (OffPtr <typ.BytePtrPtr> [config.PtrSize] ptr) mem))
 	for {
 		t := v.Type
 		_ = v.Args[1]
 		ptr := v.Args[0]
 		mem := v.Args[1]
 		if !(t.IsInterface()) {
 			break
 		}
 		v.reset(OpIMake)
 		v0 := b.NewValue0(v.Pos, OpLoad, typ.Uintptr)
 		v0.AddArg(ptr)
 		v0.AddArg(mem)
 		v.AddArg(v0)
 		v1 := b.NewValue0(v.Pos, OpLoad, typ.BytePtr)
 		v2 := b.NewValue0(v.Pos, OpOffPtr, typ.BytePtrPtr)
 		v2.AuxInt = config.PtrSize
 		v2.AddArg(ptr)
 		v1.AddArg(v2)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpSliceCap_0(v *Value) bool {
 	// match: (SliceCap (SliceMake _ _ cap))
 	// cond:
 	// result: cap
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpSliceMake {
 			break
 		}
 		_ = v_0.Args[2]
 		cap := v_0.Args[2]
 		v.reset(OpCopy)
 		v.Type = cap.Type
 		v.AddArg(cap)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpSliceLen_0(v *Value) bool {
 	// match: (SliceLen (SliceMake _ len _))
 	// cond:
 	// result: len
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpSliceMake {
 			break
 		}
 		_ = v_0.Args[2]
 		len := v_0.Args[1]
 		v.reset(OpCopy)
 		v.Type = len.Type
 		v.AddArg(len)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpSlicePtr_0(v *Value) bool {
 	// match: (SlicePtr (SliceMake ptr _ _))
 	// cond:
 	// result: ptr
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpSliceMake {
 			break
 		}
 		_ = v_0.Args[2]
 		ptr := v_0.Args[0]
 		v.reset(OpCopy)
 		v.Type = ptr.Type
 		v.AddArg(ptr)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpStore_0(v *Value) bool {
 	b := v.Block
 	_ = b
 	config := b.Func.Config
 	_ = config
 	typ := &b.Func.Config.Types
 	_ = typ
 	// match: (Store {t} dst (ComplexMake real imag) mem)
 	// cond: t.(*types.Type).Size() == 8
 	// result: (Store {typ.Float32} (OffPtr <typ.Float32Ptr> [4] dst) imag (Store {typ.Float32} dst real mem))
 	for {
 		t := v.Aux
 		_ = v.Args[2]
 		dst := v.Args[0]
 		v_1 := v.Args[1]
 		if v_1.Op != OpComplexMake {
 			break
 		}
 		_ = v_1.Args[1]
 		real := v_1.Args[0]
 		imag := v_1.Args[1]
 		mem := v.Args[2]
 		if !(t.(*types.Type).Size() == 8) {
 			break
 		}
 		v.reset(OpStore)
 		v.Aux = typ.Float32
 		v0 := b.NewValue0(v.Pos, OpOffPtr, typ.Float32Ptr)
 		v0.AuxInt = 4
 		v0.AddArg(dst)
 		v.AddArg(v0)
 		v.AddArg(imag)
 		v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
 		v1.Aux = typ.Float32
 		v1.AddArg(dst)
 		v1.AddArg(real)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Store {t} dst (ComplexMake real imag) mem)
 	// cond: t.(*types.Type).Size() == 16
 	// result: (Store {typ.Float64} (OffPtr <typ.Float64Ptr> [8] dst) imag (Store {typ.Float64} dst real mem))
 	for {
 		t := v.Aux
 		_ = v.Args[2]
 		dst := v.Args[0]
 		v_1 := v.Args[1]
 		if v_1.Op != OpComplexMake {
 			break
 		}
 		_ = v_1.Args[1]
 		real := v_1.Args[0]
 		imag := v_1.Args[1]
 		mem := v.Args[2]
 		if !(t.(*types.Type).Size() == 16) {
 			break
 		}
 		v.reset(OpStore)
 		v.Aux = typ.Float64
 		v0 := b.NewValue0(v.Pos, OpOffPtr, typ.Float64Ptr)
 		v0.AuxInt = 8
 		v0.AddArg(dst)
 		v.AddArg(v0)
 		v.AddArg(imag)
 		v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
 		v1.Aux = typ.Float64
 		v1.AddArg(dst)
 		v1.AddArg(real)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Store dst (StringMake ptr len) mem)
 	// cond:
 	// result: (Store {typ.Int} (OffPtr <typ.IntPtr> [config.PtrSize] dst) len (Store {typ.BytePtr} dst ptr mem))
 	for {
 		_ = v.Args[2]
 		dst := v.Args[0]
 		v_1 := v.Args[1]
 		if v_1.Op != OpStringMake {
 			break
 		}
 		_ = v_1.Args[1]
 		ptr := v_1.Args[0]
 		len := v_1.Args[1]
 		mem := v.Args[2]
 		v.reset(OpStore)
 		v.Aux = typ.Int
 		v0 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
 		v0.AuxInt = config.PtrSize
 		v0.AddArg(dst)
 		v.AddArg(v0)
 		v.AddArg(len)
 		v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
 		v1.Aux = typ.BytePtr
 		v1.AddArg(dst)
 		v1.AddArg(ptr)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Store dst (SliceMake ptr len cap) mem)
 	// cond:
 	// 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)))
 	for {
 		_ = v.Args[2]
 		dst := v.Args[0]
 		v_1 := v.Args[1]
 		if v_1.Op != OpSliceMake {
 			break
 		}
 		_ = v_1.Args[2]
 		ptr := v_1.Args[0]
 		len := v_1.Args[1]
 		cap := v_1.Args[2]
 		mem := v.Args[2]
 		v.reset(OpStore)
 		v.Aux = typ.Int
 		v0 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
 		v0.AuxInt = 2 * config.PtrSize
 		v0.AddArg(dst)
 		v.AddArg(v0)
 		v.AddArg(cap)
 		v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
 		v1.Aux = typ.Int
 		v2 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
 		v2.AuxInt = config.PtrSize
 		v2.AddArg(dst)
 		v1.AddArg(v2)
 		v1.AddArg(len)
 		v3 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
 		v3.Aux = typ.BytePtr
 		v3.AddArg(dst)
 		v3.AddArg(ptr)
 		v3.AddArg(mem)
 		v1.AddArg(v3)
 		v.AddArg(v1)
 		return true
 	}
 	// match: (Store dst (IMake itab data) mem)
 	// cond:
 	// result: (Store {typ.BytePtr} (OffPtr <typ.BytePtrPtr> [config.PtrSize] dst) data (Store {typ.Uintptr} dst itab mem))
 	for {
 		_ = v.Args[2]
 		dst := v.Args[0]
 		v_1 := v.Args[1]
 		if v_1.Op != OpIMake {
 			break
 		}
 		_ = v_1.Args[1]
 		itab := v_1.Args[0]
 		data := v_1.Args[1]
 		mem := v.Args[2]
 		v.reset(OpStore)
 		v.Aux = typ.BytePtr
 		v0 := b.NewValue0(v.Pos, OpOffPtr, typ.BytePtrPtr)
 		v0.AuxInt = config.PtrSize
 		v0.AddArg(dst)
 		v.AddArg(v0)
 		v.AddArg(data)
 		v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
 		v1.Aux = typ.Uintptr
 		v1.AddArg(dst)
 		v1.AddArg(itab)
 		v1.AddArg(mem)
 		v.AddArg(v1)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpStringLen_0(v *Value) bool {
 	// match: (StringLen (StringMake _ len))
 	// cond:
 	// result: len
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpStringMake {
 			break
 		}
 		_ = v_0.Args[1]
 		len := v_0.Args[1]
 		v.reset(OpCopy)
 		v.Type = len.Type
 		v.AddArg(len)
 		return true
 	}
 	return false
 }
 func rewriteValuedec_OpStringPtr_0(v *Value) bool {
 	// match: (StringPtr (StringMake ptr _))
 	// cond:
 	// result: ptr
 	for {
 		v_0 := v.Args[0]
 		if v_0.Op != OpStringMake {
 			break
 		}
 		_ = v_0.Args[1]
 		ptr := v_0.Args[0]
 		v.reset(OpCopy)
 		v.Type = ptr.Type
 		v.AddArg(ptr)
 		return true
 	}
 	return false
 }
 func rewriteBlockdec(b *Block) bool {
 	config := b.Func.Config
 	_ = config
 	fe := b.Func.fe
 	_ = fe
 	typ := &config.Types
 	_ = typ
 	switch b.Kind {
 	}
 	return false
 }
	// Code generated from gen/dec.rules; DO NOT EDIT.
	// generated with: cd gen; go run *.go

	package ssa

	import "fmt"
	import "math"
	import "cmd/internal/obj"
	import "cmd/internal/objabi"
	import "cmd/compile/internal/types"

	var _ = fmt.Println // in case not otherwise used
	var _ = math.MinInt8 // in case not otherwise used
	var _ = obj.ANOP // in case not otherwise used
	var _ = objabi.GOROOT // in case not otherwise used
	var _ = types.TypeMem // in case not otherwise used

	func rewriteValuedec(v *Value) bool {
	switch v.Op {
	case OpComplexImag:
	return rewriteValuedec_OpComplexImag_0(v)
	case OpComplexReal:
	return rewriteValuedec_OpComplexReal_0(v)
	case OpIData:
	return rewriteValuedec_OpIData_0(v)
	case OpITab:
	return rewriteValuedec_OpITab_0(v)
	case OpLoad:
	return rewriteValuedec_OpLoad_0(v)
	case OpSliceCap:
	return rewriteValuedec_OpSliceCap_0(v)
	case OpSliceLen:
	return rewriteValuedec_OpSliceLen_0(v)
	case OpSlicePtr:
	return rewriteValuedec_OpSlicePtr_0(v)
	case OpStore:
	return rewriteValuedec_OpStore_0(v)
	case OpStringLen:
	return rewriteValuedec_OpStringLen_0(v)
	case OpStringPtr:
	return rewriteValuedec_OpStringPtr_0(v)
	}
	return false
	}
	func rewriteValuedec_OpComplexImag_0(v *Value) bool {
	// match: (ComplexImag (ComplexMake _ imag))
	// cond:
	// result: imag
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpComplexMake {
	break
	}
	_ = v_0.Args[1]
	imag := v_0.Args[1]
	v.reset(OpCopy)
	v.Type = imag.Type
	v.AddArg(imag)
	return true
	}
	return false
	}
	func rewriteValuedec_OpComplexReal_0(v *Value) bool {
	// match: (ComplexReal (ComplexMake real _))
	// cond:
	// result: real
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpComplexMake {
	break
	}
	_ = v_0.Args[1]
	real := v_0.Args[0]
	v.reset(OpCopy)
	v.Type = real.Type
	v.AddArg(real)
	return true
	}
	return false
	}
	func rewriteValuedec_OpIData_0(v *Value) bool {
	// match: (IData (IMake _ data))
	// cond:
	// result: data
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpIMake {
	break
	}
	_ = v_0.Args[1]
	data := v_0.Args[1]
	v.reset(OpCopy)
	v.Type = data.Type
	v.AddArg(data)
	return true
	}
	return false
	}
	func rewriteValuedec_OpITab_0(v *Value) bool {
	b := v.Block
	_ = b
	// match: (ITab (IMake itab _))
	// cond:
	// result: itab
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpIMake {
	break
	}
	_ = v_0.Args[1]
	itab := v_0.Args[0]
	v.reset(OpCopy)
	v.Type = itab.Type
	v.AddArg(itab)
	return true
	}
	return false
	}
	func rewriteValuedec_OpLoad_0(v *Value) bool {
	b := v.Block
	_ = b
	config := b.Func.Config
	_ = config
	typ := &b.Func.Config.Types
	_ = typ
	// match: (Load <t> ptr mem)
	// cond: t.IsComplex() && t.Size() == 8
	// result: (ComplexMake (Load <typ.Float32> ptr mem) (Load <typ.Float32> (OffPtr <typ.Float32Ptr> [4] ptr) mem) )
	for {
	t := v.Type
	_ = v.Args[1]
	ptr := v.Args[0]
	mem := v.Args[1]
	if !(t.IsComplex() && t.Size() == 8) {
	break
	}
	v.reset(OpComplexMake)
	v0 := b.NewValue0(v.Pos, OpLoad, typ.Float32)
	v0.AddArg(ptr)
	v0.AddArg(mem)
	v.AddArg(v0)
	v1 := b.NewValue0(v.Pos, OpLoad, typ.Float32)
	v2 := b.NewValue0(v.Pos, OpOffPtr, typ.Float32Ptr)
	v2.AuxInt = 4
	v2.AddArg(ptr)
	v1.AddArg(v2)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	// match: (Load <t> ptr mem)
	// cond: t.IsComplex() && t.Size() == 16
	// result: (ComplexMake (Load <typ.Float64> ptr mem) (Load <typ.Float64> (OffPtr <typ.Float64Ptr> [8] ptr) mem) )
	for {
	t := v.Type
	_ = v.Args[1]
	ptr := v.Args[0]
	mem := v.Args[1]
	if !(t.IsComplex() && t.Size() == 16) {
	break
	}
	v.reset(OpComplexMake)
	v0 := b.NewValue0(v.Pos, OpLoad, typ.Float64)
	v0.AddArg(ptr)
	v0.AddArg(mem)
	v.AddArg(v0)
	v1 := b.NewValue0(v.Pos, OpLoad, typ.Float64)
	v2 := b.NewValue0(v.Pos, OpOffPtr, typ.Float64Ptr)
	v2.AuxInt = 8
	v2.AddArg(ptr)
	v1.AddArg(v2)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	// match: (Load <t> ptr mem)
	// cond: t.IsString()
	// result: (StringMake (Load <typ.BytePtr> ptr mem) (Load <typ.Int> (OffPtr <typ.IntPtr> [config.PtrSize] ptr) mem))
	for {
	t := v.Type
	_ = v.Args[1]
	ptr := v.Args[0]
	mem := v.Args[1]
	if !(t.IsString()) {
	break
	}
	v.reset(OpStringMake)
	v0 := b.NewValue0(v.Pos, OpLoad, typ.BytePtr)
	v0.AddArg(ptr)
	v0.AddArg(mem)
	v.AddArg(v0)
	v1 := b.NewValue0(v.Pos, OpLoad, typ.Int)
	v2 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
	v2.AuxInt = config.PtrSize
	v2.AddArg(ptr)
	v1.AddArg(v2)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	// match: (Load <t> ptr mem)
	// cond: t.IsSlice()
	// result: (SliceMake (Load <t.Elem().PtrTo()> ptr mem) (Load <typ.Int> (OffPtr <typ.IntPtr> [config.PtrSize] ptr) mem) (Load <typ.Int> (OffPtr <typ.IntPtr> [2*config.PtrSize] ptr) mem))
	for {
	t := v.Type
	_ = v.Args[1]
	ptr := v.Args[0]
	mem := v.Args[1]
	if !(t.IsSlice()) {
	break
	}
	v.reset(OpSliceMake)
	v0 := b.NewValue0(v.Pos, OpLoad, t.Elem().PtrTo())
	v0.AddArg(ptr)
	v0.AddArg(mem)
	v.AddArg(v0)
	v1 := b.NewValue0(v.Pos, OpLoad, typ.Int)
	v2 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
	v2.AuxInt = config.PtrSize
	v2.AddArg(ptr)
	v1.AddArg(v2)
	v1.AddArg(mem)
	v.AddArg(v1)
	v3 := b.NewValue0(v.Pos, OpLoad, typ.Int)
	v4 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
	v4.AuxInt = 2 * config.PtrSize
	v4.AddArg(ptr)
	v3.AddArg(v4)
	v3.AddArg(mem)
	v.AddArg(v3)
	return true
	}
	// match: (Load <t> ptr mem)
	// cond: t.IsInterface()
	// result: (IMake (Load <typ.Uintptr> ptr mem) (Load <typ.BytePtr> (OffPtr <typ.BytePtrPtr> [config.PtrSize] ptr) mem))
	for {
	t := v.Type
	_ = v.Args[1]
	ptr := v.Args[0]
	mem := v.Args[1]
	if !(t.IsInterface()) {
	break
	}
	v.reset(OpIMake)
	v0 := b.NewValue0(v.Pos, OpLoad, typ.Uintptr)
	v0.AddArg(ptr)
	v0.AddArg(mem)
	v.AddArg(v0)
	v1 := b.NewValue0(v.Pos, OpLoad, typ.BytePtr)
	v2 := b.NewValue0(v.Pos, OpOffPtr, typ.BytePtrPtr)
	v2.AuxInt = config.PtrSize
	v2.AddArg(ptr)
	v1.AddArg(v2)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	return false
	}
	func rewriteValuedec_OpSliceCap_0(v *Value) bool {
	// match: (SliceCap (SliceMake _ _ cap))
	// cond:
	// result: cap
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpSliceMake {
	break
	}
	_ = v_0.Args[2]
	cap := v_0.Args[2]
	v.reset(OpCopy)
	v.Type = cap.Type
	v.AddArg(cap)
	return true
	}
	return false
	}
	func rewriteValuedec_OpSliceLen_0(v *Value) bool {
	// match: (SliceLen (SliceMake _ len _))
	// cond:
	// result: len
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpSliceMake {
	break
	}
	_ = v_0.Args[2]
	len := v_0.Args[1]
	v.reset(OpCopy)
	v.Type = len.Type
	v.AddArg(len)
	return true
	}
	return false
	}
	func rewriteValuedec_OpSlicePtr_0(v *Value) bool {
	// match: (SlicePtr (SliceMake ptr _ _))
	// cond:
	// result: ptr
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpSliceMake {
	break
	}
	_ = v_0.Args[2]
	ptr := v_0.Args[0]
	v.reset(OpCopy)
	v.Type = ptr.Type
	v.AddArg(ptr)
	return true
	}
	return false
	}
	func rewriteValuedec_OpStore_0(v *Value) bool {
	b := v.Block
	_ = b
	config := b.Func.Config
	_ = config
	typ := &b.Func.Config.Types
	_ = typ
	// match: (Store {t} dst (ComplexMake real imag) mem)
	// cond: t.(*types.Type).Size() == 8
	// result: (Store {typ.Float32} (OffPtr <typ.Float32Ptr> [4] dst) imag (Store {typ.Float32} dst real mem))
	for {
	t := v.Aux
	_ = v.Args[2]
	dst := v.Args[0]
	v_1 := v.Args[1]
	if v_1.Op != OpComplexMake {
	break
	}
	_ = v_1.Args[1]
	real := v_1.Args[0]
	imag := v_1.Args[1]
	mem := v.Args[2]
	if !(t.(*types.Type).Size() == 8) {
	break
	}
	v.reset(OpStore)
	v.Aux = typ.Float32
	v0 := b.NewValue0(v.Pos, OpOffPtr, typ.Float32Ptr)
	v0.AuxInt = 4
	v0.AddArg(dst)
	v.AddArg(v0)
	v.AddArg(imag)
	v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
	v1.Aux = typ.Float32
	v1.AddArg(dst)
	v1.AddArg(real)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	// match: (Store {t} dst (ComplexMake real imag) mem)
	// cond: t.(*types.Type).Size() == 16
	// result: (Store {typ.Float64} (OffPtr <typ.Float64Ptr> [8] dst) imag (Store {typ.Float64} dst real mem))
	for {
	t := v.Aux
	_ = v.Args[2]
	dst := v.Args[0]
	v_1 := v.Args[1]
	if v_1.Op != OpComplexMake {
	break
	}
	_ = v_1.Args[1]
	real := v_1.Args[0]
	imag := v_1.Args[1]
	mem := v.Args[2]
	if !(t.(*types.Type).Size() == 16) {
	break
	}
	v.reset(OpStore)
	v.Aux = typ.Float64
	v0 := b.NewValue0(v.Pos, OpOffPtr, typ.Float64Ptr)
	v0.AuxInt = 8
	v0.AddArg(dst)
	v.AddArg(v0)
	v.AddArg(imag)
	v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
	v1.Aux = typ.Float64
	v1.AddArg(dst)
	v1.AddArg(real)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	// match: (Store dst (StringMake ptr len) mem)
	// cond:
	// result: (Store {typ.Int} (OffPtr <typ.IntPtr> [config.PtrSize] dst) len (Store {typ.BytePtr} dst ptr mem))
	for {
	_ = v.Args[2]
	dst := v.Args[0]
	v_1 := v.Args[1]
	if v_1.Op != OpStringMake {
	break
	}
	_ = v_1.Args[1]
	ptr := v_1.Args[0]
	len := v_1.Args[1]
	mem := v.Args[2]
	v.reset(OpStore)
	v.Aux = typ.Int
	v0 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
	v0.AuxInt = config.PtrSize
	v0.AddArg(dst)
	v.AddArg(v0)
	v.AddArg(len)
	v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
	v1.Aux = typ.BytePtr
	v1.AddArg(dst)
	v1.AddArg(ptr)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	// match: (Store dst (SliceMake ptr len cap) mem)
	// cond:
	// 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)))
	for {
	_ = v.Args[2]
	dst := v.Args[0]
	v_1 := v.Args[1]
	if v_1.Op != OpSliceMake {
	break
	}
	_ = v_1.Args[2]
	ptr := v_1.Args[0]
	len := v_1.Args[1]
	cap := v_1.Args[2]
	mem := v.Args[2]
	v.reset(OpStore)
	v.Aux = typ.Int
	v0 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
	v0.AuxInt = 2 * config.PtrSize
	v0.AddArg(dst)
	v.AddArg(v0)
	v.AddArg(cap)
	v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
	v1.Aux = typ.Int
	v2 := b.NewValue0(v.Pos, OpOffPtr, typ.IntPtr)
	v2.AuxInt = config.PtrSize
	v2.AddArg(dst)
	v1.AddArg(v2)
	v1.AddArg(len)
	v3 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
	v3.Aux = typ.BytePtr
	v3.AddArg(dst)
	v3.AddArg(ptr)
	v3.AddArg(mem)
	v1.AddArg(v3)
	v.AddArg(v1)
	return true
	}
	// match: (Store dst (IMake itab data) mem)
	// cond:
	// result: (Store {typ.BytePtr} (OffPtr <typ.BytePtrPtr> [config.PtrSize] dst) data (Store {typ.Uintptr} dst itab mem))
	for {
	_ = v.Args[2]
	dst := v.Args[0]
	v_1 := v.Args[1]
	if v_1.Op != OpIMake {
	break
	}
	_ = v_1.Args[1]
	itab := v_1.Args[0]
	data := v_1.Args[1]
	mem := v.Args[2]
	v.reset(OpStore)
	v.Aux = typ.BytePtr
	v0 := b.NewValue0(v.Pos, OpOffPtr, typ.BytePtrPtr)
	v0.AuxInt = config.PtrSize
	v0.AddArg(dst)
	v.AddArg(v0)
	v.AddArg(data)
	v1 := b.NewValue0(v.Pos, OpStore, types.TypeMem)
	v1.Aux = typ.Uintptr
	v1.AddArg(dst)
	v1.AddArg(itab)
	v1.AddArg(mem)
	v.AddArg(v1)
	return true
	}
	return false
	}
	func rewriteValuedec_OpStringLen_0(v *Value) bool {
	// match: (StringLen (StringMake _ len))
	// cond:
	// result: len
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpStringMake {
	break
	}
	_ = v_0.Args[1]
	len := v_0.Args[1]
	v.reset(OpCopy)
	v.Type = len.Type
	v.AddArg(len)
	return true
	}
	return false
	}
	func rewriteValuedec_OpStringPtr_0(v *Value) bool {
	// match: (StringPtr (StringMake ptr _))
	// cond:
	// result: ptr
	for {
	v_0 := v.Args[0]
	if v_0.Op != OpStringMake {
	break
	}
	_ = v_0.Args[1]
	ptr := v_0.Args[0]
	v.reset(OpCopy)
	v.Type = ptr.Type
	v.AddArg(ptr)
	return true
	}
	return false
	}
	func rewriteBlockdec(b *Block) bool {
	config := b.Func.Config
	_ = config
	fe := b.Func.fe
	_ = fe
	typ := &config.Types
	_ = typ
	switch b.Kind {
	}
	return false
	}