src/cmd/compile/internal/ssa/gen/WasmOps.go - 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.

 //go:build ignore
 // +build ignore

 package main

 import "strings"

 var regNamesWasm = []string{
 	"R0",
 	"R1",
 	"R2",
 	"R3",
 	"R4",
 	"R5",
 	"R6",
 	"R7",
 	"R8",
 	"R9",
 	"R10",
 	"R11",
 	"R12",
 	"R13",
 	"R14",
 	"R15",

 	"F0",
 	"F1",
 	"F2",
 	"F3",
 	"F4",
 	"F5",
 	"F6",
 	"F7",
 	"F8",
 	"F9",
 	"F10",
 	"F11",
 	"F12",
 	"F13",
 	"F14",
 	"F15",

 	"F16",
 	"F17",
 	"F18",
 	"F19",
 	"F20",
 	"F21",
 	"F22",
 	"F23",
 	"F24",
 	"F25",
 	"F26",
 	"F27",
 	"F28",
 	"F29",
 	"F30",
 	"F31",

 	"SP",
 	"g",

 	// pseudo-registers
 	"SB",
 }

 func init() {
 	// Make map from reg names to reg integers.
 	if len(regNamesWasm) > 64 {
 		panic("too many registers")
 	}
 	num := map[string]int{}
 	for i, name := range regNamesWasm {
 		num[name] = i
 	}
 	buildReg := func(s string) regMask {
 		m := regMask(0)
 		for _, r := range strings.Split(s, " ") {
 			if n, ok := num[r]; ok {
 				m |= regMask(1) << uint(n)
 				continue
 			}
 			panic("register " + r + " not found")
 		}
 		return m
 	}

 	var (
 		gp     = buildReg("R0 R1 R2 R3 R4 R5 R6 R7 R8 R9 R10 R11 R12 R13 R14 R15")
 		fp32   = buildReg("F0 F1 F2 F3 F4 F5 F6 F7 F8 F9 F10 F11 F12 F13 F14 F15")
 		fp64   = buildReg("F16 F17 F18 F19 F20 F21 F22 F23 F24 F25 F26 F27 F28 F29 F30 F31")
 		gpsp   = gp | buildReg("SP")
 		gpspsb = gpsp | buildReg("SB")
 		// The "registers", which are actually local variables, can get clobbered
 		// if we're switching goroutines, because it unwinds the WebAssembly stack.
 		callerSave = gp | fp32 | fp64 | buildReg("g")
 	)

 	// Common regInfo
 	var (
 		gp01      = regInfo{inputs: nil, outputs: []regMask{gp}}
 		gp11      = regInfo{inputs: []regMask{gpsp}, outputs: []regMask{gp}}
 		gp21      = regInfo{inputs: []regMask{gpsp, gpsp}, outputs: []regMask{gp}}
 		gp31      = regInfo{inputs: []regMask{gpsp, gpsp, gpsp}, outputs: []regMask{gp}}
 		fp32_01   = regInfo{inputs: nil, outputs: []regMask{fp32}}
 		fp32_11   = regInfo{inputs: []regMask{fp32}, outputs: []regMask{fp32}}
 		fp32_21   = regInfo{inputs: []regMask{fp32, fp32}, outputs: []regMask{fp32}}
 		fp32_21gp = regInfo{inputs: []regMask{fp32, fp32}, outputs: []regMask{gp}}
 		fp64_01   = regInfo{inputs: nil, outputs: []regMask{fp64}}
 		fp64_11   = regInfo{inputs: []regMask{fp64}, outputs: []regMask{fp64}}
 		fp64_21   = regInfo{inputs: []regMask{fp64, fp64}, outputs: []regMask{fp64}}
 		fp64_21gp = regInfo{inputs: []regMask{fp64, fp64}, outputs: []regMask{gp}}
 		gpload    = regInfo{inputs: []regMask{gpspsb, 0}, outputs: []regMask{gp}}
 		gpstore   = regInfo{inputs: []regMask{gpspsb, gpsp, 0}}
 		fp32load  = regInfo{inputs: []regMask{gpspsb, 0}, outputs: []regMask{fp32}}
 		fp32store = regInfo{inputs: []regMask{gpspsb, fp32, 0}}
 		fp64load  = regInfo{inputs: []regMask{gpspsb, 0}, outputs: []regMask{fp64}}
 		fp64store = regInfo{inputs: []regMask{gpspsb, fp64, 0}}
 	)

 	var WasmOps = []opData{
 		{name: "LoweredStaticCall", argLength: 1, reg: regInfo{clobbers: callerSave}, aux: "CallOff", call: true},                                // call static function aux.(*obj.LSym). arg0=mem, auxint=argsize, returns mem
 		{name: "LoweredTailCall", argLength: 1, reg: regInfo{clobbers: callerSave}, aux: "CallOff", call: true, tailCall: true},                  // tail call static function aux.(*obj.LSym). arg0=mem, auxint=argsize, returns mem
 		{name: "LoweredClosureCall", argLength: 3, reg: regInfo{inputs: []regMask{gp, gp, 0}, clobbers: callerSave}, aux: "CallOff", call: true}, // call function via closure. arg0=codeptr, arg1=closure, arg2=mem, auxint=argsize, returns mem
 		{name: "LoweredInterCall", argLength: 2, reg: regInfo{inputs: []regMask{gp}, clobbers: callerSave}, aux: "CallOff", call: true},          // call fn by pointer. arg0=codeptr, arg1=mem, auxint=argsize, returns mem

 		{name: "LoweredAddr", argLength: 1, reg: gp11, aux: "SymOff", rematerializeable: true, symEffect: "Addr"}, // returns base+aux+auxint, arg0=base
 		{name: "LoweredMove", argLength: 3, reg: regInfo{inputs: []regMask{gp, gp}}, aux: "Int64"},                // large move. arg0=dst, arg1=src, arg2=mem, auxint=len/8, returns mem
 		{name: "LoweredZero", argLength: 2, reg: regInfo{inputs: []regMask{gp}}, aux: "Int64"},                    // large zeroing. arg0=start, arg1=mem, auxint=len/8, returns mem

 		{name: "LoweredGetClosurePtr", reg: gp01},                                                                          // returns wasm.REG_CTXT, the closure pointer
 		{name: "LoweredGetCallerPC", reg: gp01, rematerializeable: true},                                                   // returns the PC of the caller of the current function
 		{name: "LoweredGetCallerSP", reg: gp01, rematerializeable: true},                                                   // returns the SP of the caller of the current function
 		{name: "LoweredNilCheck", argLength: 2, reg: regInfo{inputs: []regMask{gp}}, nilCheck: true, faultOnNilArg0: true}, // panic if arg0 is nil. arg1=mem
 		{name: "LoweredWB", argLength: 3, reg: regInfo{inputs: []regMask{gp, gp}}, aux: "Sym", symEffect: "None"},          // invokes runtime.gcWriteBarrier. arg0=destptr, arg1=srcptr, arg2=mem, aux=runtime.gcWriteBarrier

 		// LoweredConvert converts between pointers and integers.
 		// We have a special op for this so as to not confuse GCCallOff
 		// (particularly stack maps). It takes a memory arg so it
 		// gets correctly ordered with respect to GC safepoints.
 		// arg0=ptr/int arg1=mem, output=int/ptr
 		//
 		// TODO(neelance): LoweredConvert should not be necessary any more, since OpConvert does not need to be lowered any more (CL 108496).
 		{name: "LoweredConvert", argLength: 2, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{gp}}},

 		// The following are native WebAssembly instructions, see https://webassembly.github.io/spec/core/syntax/instructions.html

 		{name: "Select", asm: "Select", argLength: 3, reg: gp31}, // returns arg0 if arg2 != 0, otherwise returns arg1

 		{name: "I64Load8U", asm: "I64Load8U", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt8"},    // read unsigned 8-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Load8S", asm: "I64Load8S", argLength: 2, reg: gpload, aux: "Int64", typ: "Int8"},     // read signed 8-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Load16U", asm: "I64Load16U", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt16"}, // read unsigned 16-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Load16S", asm: "I64Load16S", argLength: 2, reg: gpload, aux: "Int64", typ: "Int16"},  // read signed 16-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Load32U", asm: "I64Load32U", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt32"}, // read unsigned 32-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Load32S", asm: "I64Load32S", argLength: 2, reg: gpload, aux: "Int64", typ: "Int32"},  // read signed 32-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Load", asm: "I64Load", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt64"},       // read 64-bit integer from address arg0+aux, arg1=mem
 		{name: "I64Store8", asm: "I64Store8", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"},     // store 8-bit integer arg1 at address arg0+aux, arg2=mem, returns mem
 		{name: "I64Store16", asm: "I64Store16", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"},   // store 16-bit integer arg1 at address arg0+aux, arg2=mem, returns mem
 		{name: "I64Store32", asm: "I64Store32", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"},   // store 32-bit integer arg1 at address arg0+aux, arg2=mem, returns mem
 		{name: "I64Store", asm: "I64Store", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"},       // store 64-bit integer arg1 at address arg0+aux, arg2=mem, returns mem

 		{name: "F32Load", asm: "F32Load", argLength: 2, reg: fp32load, aux: "Int64", typ: "Float32"}, // read 32-bit float from address arg0+aux, arg1=mem
 		{name: "F64Load", asm: "F64Load", argLength: 2, reg: fp64load, aux: "Int64", typ: "Float64"}, // read 64-bit float from address arg0+aux, arg1=mem
 		{name: "F32Store", asm: "F32Store", argLength: 3, reg: fp32store, aux: "Int64", typ: "Mem"},  // store 32-bit float arg1 at address arg0+aux, arg2=mem, returns mem
 		{name: "F64Store", asm: "F64Store", argLength: 3, reg: fp64store, aux: "Int64", typ: "Mem"},  // store 64-bit float arg1 at address arg0+aux, arg2=mem, returns mem

 		{name: "I64Const", reg: gp01, aux: "Int64", rematerializeable: true, typ: "Int64"},        // returns the constant integer aux
 		{name: "F32Const", reg: fp32_01, aux: "Float32", rematerializeable: true, typ: "Float32"}, // returns the constant float aux
 		{name: "F64Const", reg: fp64_01, aux: "Float64", rematerializeable: true, typ: "Float64"}, // returns the constant float aux

 		{name: "I64Eqz", asm: "I64Eqz", argLength: 1, reg: gp11, typ: "Bool"}, // arg0 == 0
 		{name: "I64Eq", asm: "I64Eq", argLength: 2, reg: gp21, typ: "Bool"},   // arg0 == arg1
 		{name: "I64Ne", asm: "I64Ne", argLength: 2, reg: gp21, typ: "Bool"},   // arg0 != arg1
 		{name: "I64LtS", asm: "I64LtS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 < arg1 (signed)
 		{name: "I64LtU", asm: "I64LtU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 < arg1 (unsigned)
 		{name: "I64GtS", asm: "I64GtS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 > arg1 (signed)
 		{name: "I64GtU", asm: "I64GtU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 > arg1 (unsigned)
 		{name: "I64LeS", asm: "I64LeS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 <= arg1 (signed)
 		{name: "I64LeU", asm: "I64LeU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 <= arg1 (unsigned)
 		{name: "I64GeS", asm: "I64GeS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 >= arg1 (signed)
 		{name: "I64GeU", asm: "I64GeU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 >= arg1 (unsigned)

 		{name: "F32Eq", asm: "F32Eq", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 == arg1
 		{name: "F32Ne", asm: "F32Ne", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 != arg1
 		{name: "F32Lt", asm: "F32Lt", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 < arg1
 		{name: "F32Gt", asm: "F32Gt", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 > arg1
 		{name: "F32Le", asm: "F32Le", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 <= arg1
 		{name: "F32Ge", asm: "F32Ge", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 >= arg1

 		{name: "F64Eq", asm: "F64Eq", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 == arg1
 		{name: "F64Ne", asm: "F64Ne", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 != arg1
 		{name: "F64Lt", asm: "F64Lt", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 < arg1
 		{name: "F64Gt", asm: "F64Gt", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 > arg1
 		{name: "F64Le", asm: "F64Le", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 <= arg1
 		{name: "F64Ge", asm: "F64Ge", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 >= arg1

 		{name: "I64Add", asm: "I64Add", argLength: 2, reg: gp21, typ: "Int64"},                    // arg0 + arg1
 		{name: "I64AddConst", asm: "I64Add", argLength: 1, reg: gp11, aux: "Int64", typ: "Int64"}, // arg0 + aux
 		{name: "I64Sub", asm: "I64Sub", argLength: 2, reg: gp21, typ: "Int64"},                    // arg0 - arg1
 		{name: "I64Mul", asm: "I64Mul", argLength: 2, reg: gp21, typ: "Int64"},                    // arg0 * arg1
 		{name: "I64DivS", asm: "I64DivS", argLength: 2, reg: gp21, typ: "Int64"},                  // arg0 / arg1 (signed)
 		{name: "I64DivU", asm: "I64DivU", argLength: 2, reg: gp21, typ: "Int64"},                  // arg0 / arg1 (unsigned)
 		{name: "I64RemS", asm: "I64RemS", argLength: 2, reg: gp21, typ: "Int64"},                  // arg0 % arg1 (signed)
 		{name: "I64RemU", asm: "I64RemU", argLength: 2, reg: gp21, typ: "Int64"},                  // arg0 % arg1 (unsigned)
 		{name: "I64And", asm: "I64And", argLength: 2, reg: gp21, typ: "Int64"},                    // arg0 & arg1
 		{name: "I64Or", asm: "I64Or", argLength: 2, reg: gp21, typ: "Int64"},                      // arg0 | arg1
 		{name: "I64Xor", asm: "I64Xor", argLength: 2, reg: gp21, typ: "Int64"},                    // arg0 ^ arg1
 		{name: "I64Shl", asm: "I64Shl", argLength: 2, reg: gp21, typ: "Int64"},                    // arg0 << (arg1 % 64)
 		{name: "I64ShrS", asm: "I64ShrS", argLength: 2, reg: gp21, typ: "Int64"},                  // arg0 >> (arg1 % 64) (signed)
 		{name: "I64ShrU", asm: "I64ShrU", argLength: 2, reg: gp21, typ: "Int64"},                  // arg0 >> (arg1 % 64) (unsigned)

 		{name: "F32Neg", asm: "F32Neg", argLength: 1, reg: fp32_11, typ: "Float32"}, // -arg0
 		{name: "F32Add", asm: "F32Add", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 + arg1
 		{name: "F32Sub", asm: "F32Sub", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 - arg1
 		{name: "F32Mul", asm: "F32Mul", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 * arg1
 		{name: "F32Div", asm: "F32Div", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 / arg1

 		{name: "F64Neg", asm: "F64Neg", argLength: 1, reg: fp64_11, typ: "Float64"}, // -arg0
 		{name: "F64Add", asm: "F64Add", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 + arg1
 		{name: "F64Sub", asm: "F64Sub", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 - arg1
 		{name: "F64Mul", asm: "F64Mul", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 * arg1
 		{name: "F64Div", asm: "F64Div", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 / arg1

 		{name: "I64TruncSatF64S", asm: "I64TruncSatF64S", argLength: 1, reg: regInfo{inputs: []regMask{fp64}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to a signed integer (saturating)
 		{name: "I64TruncSatF64U", asm: "I64TruncSatF64U", argLength: 1, reg: regInfo{inputs: []regMask{fp64}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to an unsigned integer (saturating)
 		{name: "I64TruncSatF32S", asm: "I64TruncSatF32S", argLength: 1, reg: regInfo{inputs: []regMask{fp32}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to a signed integer (saturating)
 		{name: "I64TruncSatF32U", asm: "I64TruncSatF32U", argLength: 1, reg: regInfo{inputs: []regMask{fp32}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to an unsigned integer (saturating)
 		{name: "F32ConvertI64S", asm: "F32ConvertI64S", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp32}}, typ: "Float32"}, // converts the signed integer arg0 to a float
 		{name: "F32ConvertI64U", asm: "F32ConvertI64U", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp32}}, typ: "Float32"}, // converts the unsigned integer arg0 to a float
 		{name: "F64ConvertI64S", asm: "F64ConvertI64S", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp64}}, typ: "Float64"}, // converts the signed integer arg0 to a float
 		{name: "F64ConvertI64U", asm: "F64ConvertI64U", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp64}}, typ: "Float64"}, // converts the unsigned integer arg0 to a float
 		{name: "F32DemoteF64", asm: "F32DemoteF64", argLength: 1, reg: regInfo{inputs: []regMask{fp64}, outputs: []regMask{fp32}}, typ: "Float32"},
 		{name: "F64PromoteF32", asm: "F64PromoteF32", argLength: 1, reg: regInfo{inputs: []regMask{fp32}, outputs: []regMask{fp64}}, typ: "Float64"},

 		{name: "I64Extend8S", asm: "I64Extend8S", argLength: 1, reg: gp11, typ: "Int64"},   // sign-extend arg0 from 8 to 64 bit
 		{name: "I64Extend16S", asm: "I64Extend16S", argLength: 1, reg: gp11, typ: "Int64"}, // sign-extend arg0 from 16 to 64 bit
 		{name: "I64Extend32S", asm: "I64Extend32S", argLength: 1, reg: gp11, typ: "Int64"}, // sign-extend arg0 from 32 to 64 bit

 		{name: "F32Sqrt", asm: "F32Sqrt", argLength: 1, reg: fp32_11, typ: "Float32"},         // sqrt(arg0)
 		{name: "F32Trunc", asm: "F32Trunc", argLength: 1, reg: fp32_11, typ: "Float32"},       // trunc(arg0)
 		{name: "F32Ceil", asm: "F32Ceil", argLength: 1, reg: fp32_11, typ: "Float32"},         // ceil(arg0)
 		{name: "F32Floor", asm: "F32Floor", argLength: 1, reg: fp32_11, typ: "Float32"},       // floor(arg0)
 		{name: "F32Nearest", asm: "F32Nearest", argLength: 1, reg: fp32_11, typ: "Float32"},   // round(arg0)
 		{name: "F32Abs", asm: "F32Abs", argLength: 1, reg: fp32_11, typ: "Float32"},           // abs(arg0)
 		{name: "F32Copysign", asm: "F32Copysign", argLength: 2, reg: fp32_21, typ: "Float32"}, // copysign(arg0, arg1)

 		{name: "F64Sqrt", asm: "F64Sqrt", argLength: 1, reg: fp64_11, typ: "Float64"},         // sqrt(arg0)
 		{name: "F64Trunc", asm: "F64Trunc", argLength: 1, reg: fp64_11, typ: "Float64"},       // trunc(arg0)
 		{name: "F64Ceil", asm: "F64Ceil", argLength: 1, reg: fp64_11, typ: "Float64"},         // ceil(arg0)
 		{name: "F64Floor", asm: "F64Floor", argLength: 1, reg: fp64_11, typ: "Float64"},       // floor(arg0)
 		{name: "F64Nearest", asm: "F64Nearest", argLength: 1, reg: fp64_11, typ: "Float64"},   // round(arg0)
 		{name: "F64Abs", asm: "F64Abs", argLength: 1, reg: fp64_11, typ: "Float64"},           // abs(arg0)
 		{name: "F64Copysign", asm: "F64Copysign", argLength: 2, reg: fp64_21, typ: "Float64"}, // copysign(arg0, arg1)

 		{name: "I64Ctz", asm: "I64Ctz", argLength: 1, reg: gp11, typ: "Int64"},       // ctz(arg0)
 		{name: "I64Clz", asm: "I64Clz", argLength: 1, reg: gp11, typ: "Int64"},       // clz(arg0)
 		{name: "I32Rotl", asm: "I32Rotl", argLength: 2, reg: gp21, typ: "Int32"},     // rotl(arg0, arg1)
 		{name: "I64Rotl", asm: "I64Rotl", argLength: 2, reg: gp21, typ: "Int64"},     // rotl(arg0, arg1)
 		{name: "I64Popcnt", asm: "I64Popcnt", argLength: 1, reg: gp11, typ: "Int64"}, // popcnt(arg0)
 	}

 	archs = append(archs, arch{
 		name:            "Wasm",
 		pkg:             "cmd/internal/obj/wasm",
 		genfile:         "../../wasm/ssa.go",
 		ops:             WasmOps,
 		blocks:          nil,
 		regnames:        regNamesWasm,
 		gpregmask:       gp,
 		fpregmask:       fp32 | fp64,
 		fp32regmask:     fp32,
 		fp64regmask:     fp64,
 		framepointerreg: -1, // not used
 		linkreg:         -1, // not used
 	})
 }
	// 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.

	//go:build ignore
	// +build ignore

	package main

	import "strings"

	var regNamesWasm = []string{
	"R0",
	"R1",
	"R2",
	"R3",
	"R4",
	"R5",
	"R6",
	"R7",
	"R8",
	"R9",
	"R10",
	"R11",
	"R12",
	"R13",
	"R14",
	"R15",

	"F0",
	"F1",
	"F2",
	"F3",
	"F4",
	"F5",
	"F6",
	"F7",
	"F8",
	"F9",
	"F10",
	"F11",
	"F12",
	"F13",
	"F14",
	"F15",

	"F16",
	"F17",
	"F18",
	"F19",
	"F20",
	"F21",
	"F22",
	"F23",
	"F24",
	"F25",
	"F26",
	"F27",
	"F28",
	"F29",
	"F30",
	"F31",

	"SP",
	"g",

	// pseudo-registers
	"SB",
	}

	func init() {
	// Make map from reg names to reg integers.
	if len(regNamesWasm) > 64 {
	panic("too many registers")
	}
	num := map[string]int{}
	for i, name := range regNamesWasm {
	num[name] = i
	}
	buildReg := func(s string) regMask {
	m := regMask(0)
	for _, r := range strings.Split(s, " ") {
	if n, ok := num[r]; ok {
	m \|= regMask(1) << uint(n)
	continue
	}
	panic("register " + r + " not found")
	}
	return m
	}

	var (
	gp = buildReg("R0 R1 R2 R3 R4 R5 R6 R7 R8 R9 R10 R11 R12 R13 R14 R15")
	fp32 = buildReg("F0 F1 F2 F3 F4 F5 F6 F7 F8 F9 F10 F11 F12 F13 F14 F15")
	fp64 = buildReg("F16 F17 F18 F19 F20 F21 F22 F23 F24 F25 F26 F27 F28 F29 F30 F31")
	gpsp = gp \| buildReg("SP")
	gpspsb = gpsp \| buildReg("SB")
	// The "registers", which are actually local variables, can get clobbered
	// if we're switching goroutines, because it unwinds the WebAssembly stack.
	callerSave = gp \| fp32 \| fp64 \| buildReg("g")
	)

	// Common regInfo
	var (
	gp01 = regInfo{inputs: nil, outputs: []regMask{gp}}
	gp11 = regInfo{inputs: []regMask{gpsp}, outputs: []regMask{gp}}
	gp21 = regInfo{inputs: []regMask{gpsp, gpsp}, outputs: []regMask{gp}}
	gp31 = regInfo{inputs: []regMask{gpsp, gpsp, gpsp}, outputs: []regMask{gp}}
	fp32_01 = regInfo{inputs: nil, outputs: []regMask{fp32}}
	fp32_11 = regInfo{inputs: []regMask{fp32}, outputs: []regMask{fp32}}
	fp32_21 = regInfo{inputs: []regMask{fp32, fp32}, outputs: []regMask{fp32}}
	fp32_21gp = regInfo{inputs: []regMask{fp32, fp32}, outputs: []regMask{gp}}
	fp64_01 = regInfo{inputs: nil, outputs: []regMask{fp64}}
	fp64_11 = regInfo{inputs: []regMask{fp64}, outputs: []regMask{fp64}}
	fp64_21 = regInfo{inputs: []regMask{fp64, fp64}, outputs: []regMask{fp64}}
	fp64_21gp = regInfo{inputs: []regMask{fp64, fp64}, outputs: []regMask{gp}}
	gpload = regInfo{inputs: []regMask{gpspsb, 0}, outputs: []regMask{gp}}
	gpstore = regInfo{inputs: []regMask{gpspsb, gpsp, 0}}
	fp32load = regInfo{inputs: []regMask{gpspsb, 0}, outputs: []regMask{fp32}}
	fp32store = regInfo{inputs: []regMask{gpspsb, fp32, 0}}
	fp64load = regInfo{inputs: []regMask{gpspsb, 0}, outputs: []regMask{fp64}}
	fp64store = regInfo{inputs: []regMask{gpspsb, fp64, 0}}
	)

	var WasmOps = []opData{
	{name: "LoweredStaticCall", argLength: 1, reg: regInfo{clobbers: callerSave}, aux: "CallOff", call: true}, // call static function aux.(*obj.LSym). arg0=mem, auxint=argsize, returns mem
	{name: "LoweredTailCall", argLength: 1, reg: regInfo{clobbers: callerSave}, aux: "CallOff", call: true, tailCall: true}, // tail call static function aux.(*obj.LSym). arg0=mem, auxint=argsize, returns mem
	{name: "LoweredClosureCall", argLength: 3, reg: regInfo{inputs: []regMask{gp, gp, 0}, clobbers: callerSave}, aux: "CallOff", call: true}, // call function via closure. arg0=codeptr, arg1=closure, arg2=mem, auxint=argsize, returns mem
	{name: "LoweredInterCall", argLength: 2, reg: regInfo{inputs: []regMask{gp}, clobbers: callerSave}, aux: "CallOff", call: true}, // call fn by pointer. arg0=codeptr, arg1=mem, auxint=argsize, returns mem

	{name: "LoweredAddr", argLength: 1, reg: gp11, aux: "SymOff", rematerializeable: true, symEffect: "Addr"}, // returns base+aux+auxint, arg0=base
	{name: "LoweredMove", argLength: 3, reg: regInfo{inputs: []regMask{gp, gp}}, aux: "Int64"}, // large move. arg0=dst, arg1=src, arg2=mem, auxint=len/8, returns mem
	{name: "LoweredZero", argLength: 2, reg: regInfo{inputs: []regMask{gp}}, aux: "Int64"}, // large zeroing. arg0=start, arg1=mem, auxint=len/8, returns mem

	{name: "LoweredGetClosurePtr", reg: gp01}, // returns wasm.REG_CTXT, the closure pointer
	{name: "LoweredGetCallerPC", reg: gp01, rematerializeable: true}, // returns the PC of the caller of the current function
	{name: "LoweredGetCallerSP", reg: gp01, rematerializeable: true}, // returns the SP of the caller of the current function
	{name: "LoweredNilCheck", argLength: 2, reg: regInfo{inputs: []regMask{gp}}, nilCheck: true, faultOnNilArg0: true}, // panic if arg0 is nil. arg1=mem
	{name: "LoweredWB", argLength: 3, reg: regInfo{inputs: []regMask{gp, gp}}, aux: "Sym", symEffect: "None"}, // invokes runtime.gcWriteBarrier. arg0=destptr, arg1=srcptr, arg2=mem, aux=runtime.gcWriteBarrier

	// LoweredConvert converts between pointers and integers.
	// We have a special op for this so as to not confuse GCCallOff
	// (particularly stack maps). It takes a memory arg so it
	// gets correctly ordered with respect to GC safepoints.
	// arg0=ptr/int arg1=mem, output=int/ptr
	//
	// TODO(neelance): LoweredConvert should not be necessary any more, since OpConvert does not need to be lowered any more (CL 108496).
	{name: "LoweredConvert", argLength: 2, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{gp}}},

	// The following are native WebAssembly instructions, see https://webassembly.github.io/spec/core/syntax/instructions.html

	{name: "Select", asm: "Select", argLength: 3, reg: gp31}, // returns arg0 if arg2 != 0, otherwise returns arg1

	{name: "I64Load8U", asm: "I64Load8U", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt8"}, // read unsigned 8-bit integer from address arg0+aux, arg1=mem
	{name: "I64Load8S", asm: "I64Load8S", argLength: 2, reg: gpload, aux: "Int64", typ: "Int8"}, // read signed 8-bit integer from address arg0+aux, arg1=mem
	{name: "I64Load16U", asm: "I64Load16U", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt16"}, // read unsigned 16-bit integer from address arg0+aux, arg1=mem
	{name: "I64Load16S", asm: "I64Load16S", argLength: 2, reg: gpload, aux: "Int64", typ: "Int16"}, // read signed 16-bit integer from address arg0+aux, arg1=mem
	{name: "I64Load32U", asm: "I64Load32U", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt32"}, // read unsigned 32-bit integer from address arg0+aux, arg1=mem
	{name: "I64Load32S", asm: "I64Load32S", argLength: 2, reg: gpload, aux: "Int64", typ: "Int32"}, // read signed 32-bit integer from address arg0+aux, arg1=mem
	{name: "I64Load", asm: "I64Load", argLength: 2, reg: gpload, aux: "Int64", typ: "UInt64"}, // read 64-bit integer from address arg0+aux, arg1=mem
	{name: "I64Store8", asm: "I64Store8", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"}, // store 8-bit integer arg1 at address arg0+aux, arg2=mem, returns mem
	{name: "I64Store16", asm: "I64Store16", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"}, // store 16-bit integer arg1 at address arg0+aux, arg2=mem, returns mem
	{name: "I64Store32", asm: "I64Store32", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"}, // store 32-bit integer arg1 at address arg0+aux, arg2=mem, returns mem
	{name: "I64Store", asm: "I64Store", argLength: 3, reg: gpstore, aux: "Int64", typ: "Mem"}, // store 64-bit integer arg1 at address arg0+aux, arg2=mem, returns mem

	{name: "F32Load", asm: "F32Load", argLength: 2, reg: fp32load, aux: "Int64", typ: "Float32"}, // read 32-bit float from address arg0+aux, arg1=mem
	{name: "F64Load", asm: "F64Load", argLength: 2, reg: fp64load, aux: "Int64", typ: "Float64"}, // read 64-bit float from address arg0+aux, arg1=mem
	{name: "F32Store", asm: "F32Store", argLength: 3, reg: fp32store, aux: "Int64", typ: "Mem"}, // store 32-bit float arg1 at address arg0+aux, arg2=mem, returns mem
	{name: "F64Store", asm: "F64Store", argLength: 3, reg: fp64store, aux: "Int64", typ: "Mem"}, // store 64-bit float arg1 at address arg0+aux, arg2=mem, returns mem

	{name: "I64Const", reg: gp01, aux: "Int64", rematerializeable: true, typ: "Int64"}, // returns the constant integer aux
	{name: "F32Const", reg: fp32_01, aux: "Float32", rematerializeable: true, typ: "Float32"}, // returns the constant float aux
	{name: "F64Const", reg: fp64_01, aux: "Float64", rematerializeable: true, typ: "Float64"}, // returns the constant float aux

	{name: "I64Eqz", asm: "I64Eqz", argLength: 1, reg: gp11, typ: "Bool"}, // arg0 == 0
	{name: "I64Eq", asm: "I64Eq", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 == arg1
	{name: "I64Ne", asm: "I64Ne", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 != arg1
	{name: "I64LtS", asm: "I64LtS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 < arg1 (signed)
	{name: "I64LtU", asm: "I64LtU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 < arg1 (unsigned)
	{name: "I64GtS", asm: "I64GtS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 > arg1 (signed)
	{name: "I64GtU", asm: "I64GtU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 > arg1 (unsigned)
	{name: "I64LeS", asm: "I64LeS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 <= arg1 (signed)
	{name: "I64LeU", asm: "I64LeU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 <= arg1 (unsigned)
	{name: "I64GeS", asm: "I64GeS", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 >= arg1 (signed)
	{name: "I64GeU", asm: "I64GeU", argLength: 2, reg: gp21, typ: "Bool"}, // arg0 >= arg1 (unsigned)

	{name: "F32Eq", asm: "F32Eq", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 == arg1
	{name: "F32Ne", asm: "F32Ne", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 != arg1
	{name: "F32Lt", asm: "F32Lt", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 < arg1
	{name: "F32Gt", asm: "F32Gt", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 > arg1
	{name: "F32Le", asm: "F32Le", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 <= arg1
	{name: "F32Ge", asm: "F32Ge", argLength: 2, reg: fp32_21gp, typ: "Bool"}, // arg0 >= arg1

	{name: "F64Eq", asm: "F64Eq", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 == arg1
	{name: "F64Ne", asm: "F64Ne", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 != arg1
	{name: "F64Lt", asm: "F64Lt", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 < arg1
	{name: "F64Gt", asm: "F64Gt", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 > arg1
	{name: "F64Le", asm: "F64Le", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 <= arg1
	{name: "F64Ge", asm: "F64Ge", argLength: 2, reg: fp64_21gp, typ: "Bool"}, // arg0 >= arg1

	{name: "I64Add", asm: "I64Add", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 + arg1
	{name: "I64AddConst", asm: "I64Add", argLength: 1, reg: gp11, aux: "Int64", typ: "Int64"}, // arg0 + aux
	{name: "I64Sub", asm: "I64Sub", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 - arg1
	{name: "I64Mul", asm: "I64Mul", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 * arg1
	{name: "I64DivS", asm: "I64DivS", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 / arg1 (signed)
	{name: "I64DivU", asm: "I64DivU", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 / arg1 (unsigned)
	{name: "I64RemS", asm: "I64RemS", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 % arg1 (signed)
	{name: "I64RemU", asm: "I64RemU", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 % arg1 (unsigned)
	{name: "I64And", asm: "I64And", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 & arg1
	{name: "I64Or", asm: "I64Or", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 \| arg1
	{name: "I64Xor", asm: "I64Xor", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 ^ arg1
	{name: "I64Shl", asm: "I64Shl", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 << (arg1 % 64)
	{name: "I64ShrS", asm: "I64ShrS", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 >> (arg1 % 64) (signed)
	{name: "I64ShrU", asm: "I64ShrU", argLength: 2, reg: gp21, typ: "Int64"}, // arg0 >> (arg1 % 64) (unsigned)

	{name: "F32Neg", asm: "F32Neg", argLength: 1, reg: fp32_11, typ: "Float32"}, // -arg0
	{name: "F32Add", asm: "F32Add", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 + arg1
	{name: "F32Sub", asm: "F32Sub", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 - arg1
	{name: "F32Mul", asm: "F32Mul", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 * arg1
	{name: "F32Div", asm: "F32Div", argLength: 2, reg: fp32_21, typ: "Float32"}, // arg0 / arg1

	{name: "F64Neg", asm: "F64Neg", argLength: 1, reg: fp64_11, typ: "Float64"}, // -arg0
	{name: "F64Add", asm: "F64Add", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 + arg1
	{name: "F64Sub", asm: "F64Sub", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 - arg1
	{name: "F64Mul", asm: "F64Mul", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 * arg1
	{name: "F64Div", asm: "F64Div", argLength: 2, reg: fp64_21, typ: "Float64"}, // arg0 / arg1

	{name: "I64TruncSatF64S", asm: "I64TruncSatF64S", argLength: 1, reg: regInfo{inputs: []regMask{fp64}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to a signed integer (saturating)
	{name: "I64TruncSatF64U", asm: "I64TruncSatF64U", argLength: 1, reg: regInfo{inputs: []regMask{fp64}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to an unsigned integer (saturating)
	{name: "I64TruncSatF32S", asm: "I64TruncSatF32S", argLength: 1, reg: regInfo{inputs: []regMask{fp32}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to a signed integer (saturating)
	{name: "I64TruncSatF32U", asm: "I64TruncSatF32U", argLength: 1, reg: regInfo{inputs: []regMask{fp32}, outputs: []regMask{gp}}, typ: "Int64"}, // truncates the float arg0 to an unsigned integer (saturating)
	{name: "F32ConvertI64S", asm: "F32ConvertI64S", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp32}}, typ: "Float32"}, // converts the signed integer arg0 to a float
	{name: "F32ConvertI64U", asm: "F32ConvertI64U", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp32}}, typ: "Float32"}, // converts the unsigned integer arg0 to a float
	{name: "F64ConvertI64S", asm: "F64ConvertI64S", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp64}}, typ: "Float64"}, // converts the signed integer arg0 to a float
	{name: "F64ConvertI64U", asm: "F64ConvertI64U", argLength: 1, reg: regInfo{inputs: []regMask{gp}, outputs: []regMask{fp64}}, typ: "Float64"}, // converts the unsigned integer arg0 to a float
	{name: "F32DemoteF64", asm: "F32DemoteF64", argLength: 1, reg: regInfo{inputs: []regMask{fp64}, outputs: []regMask{fp32}}, typ: "Float32"},
	{name: "F64PromoteF32", asm: "F64PromoteF32", argLength: 1, reg: regInfo{inputs: []regMask{fp32}, outputs: []regMask{fp64}}, typ: "Float64"},

	{name: "I64Extend8S", asm: "I64Extend8S", argLength: 1, reg: gp11, typ: "Int64"}, // sign-extend arg0 from 8 to 64 bit
	{name: "I64Extend16S", asm: "I64Extend16S", argLength: 1, reg: gp11, typ: "Int64"}, // sign-extend arg0 from 16 to 64 bit
	{name: "I64Extend32S", asm: "I64Extend32S", argLength: 1, reg: gp11, typ: "Int64"}, // sign-extend arg0 from 32 to 64 bit

	{name: "F32Sqrt", asm: "F32Sqrt", argLength: 1, reg: fp32_11, typ: "Float32"}, // sqrt(arg0)
	{name: "F32Trunc", asm: "F32Trunc", argLength: 1, reg: fp32_11, typ: "Float32"}, // trunc(arg0)
	{name: "F32Ceil", asm: "F32Ceil", argLength: 1, reg: fp32_11, typ: "Float32"}, // ceil(arg0)
	{name: "F32Floor", asm: "F32Floor", argLength: 1, reg: fp32_11, typ: "Float32"}, // floor(arg0)
	{name: "F32Nearest", asm: "F32Nearest", argLength: 1, reg: fp32_11, typ: "Float32"}, // round(arg0)
	{name: "F32Abs", asm: "F32Abs", argLength: 1, reg: fp32_11, typ: "Float32"}, // abs(arg0)
	{name: "F32Copysign", asm: "F32Copysign", argLength: 2, reg: fp32_21, typ: "Float32"}, // copysign(arg0, arg1)

	{name: "F64Sqrt", asm: "F64Sqrt", argLength: 1, reg: fp64_11, typ: "Float64"}, // sqrt(arg0)
	{name: "F64Trunc", asm: "F64Trunc", argLength: 1, reg: fp64_11, typ: "Float64"}, // trunc(arg0)
	{name: "F64Ceil", asm: "F64Ceil", argLength: 1, reg: fp64_11, typ: "Float64"}, // ceil(arg0)
	{name: "F64Floor", asm: "F64Floor", argLength: 1, reg: fp64_11, typ: "Float64"}, // floor(arg0)
	{name: "F64Nearest", asm: "F64Nearest", argLength: 1, reg: fp64_11, typ: "Float64"}, // round(arg0)
	{name: "F64Abs", asm: "F64Abs", argLength: 1, reg: fp64_11, typ: "Float64"}, // abs(arg0)
	{name: "F64Copysign", asm: "F64Copysign", argLength: 2, reg: fp64_21, typ: "Float64"}, // copysign(arg0, arg1)

	{name: "I64Ctz", asm: "I64Ctz", argLength: 1, reg: gp11, typ: "Int64"}, // ctz(arg0)
	{name: "I64Clz", asm: "I64Clz", argLength: 1, reg: gp11, typ: "Int64"}, // clz(arg0)
	{name: "I32Rotl", asm: "I32Rotl", argLength: 2, reg: gp21, typ: "Int32"}, // rotl(arg0, arg1)
	{name: "I64Rotl", asm: "I64Rotl", argLength: 2, reg: gp21, typ: "Int64"}, // rotl(arg0, arg1)
	{name: "I64Popcnt", asm: "I64Popcnt", argLength: 1, reg: gp11, typ: "Int64"}, // popcnt(arg0)
	}

	archs = append(archs, arch{
	name: "Wasm",
	pkg: "cmd/internal/obj/wasm",
	genfile: "../../wasm/ssa.go",
	ops: WasmOps,
	blocks: nil,
	regnames: regNamesWasm,
	gpregmask: gp,
	fpregmask: fp32 \| fp64,
	fp32regmask: fp32,
	fp64regmask: fp64,
	framepointerreg: -1, // not used
	linkreg: -1, // not used
	})
	}