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|
// 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 wasm
import (
"bytes"
"cmd/internal/obj"
"cmd/internal/objabi"
"cmd/internal/sys"
"encoding/binary"
"fmt"
"internal/abi"
"io"
"math"
)
var Register = map[string]int16{
"SP": REG_SP,
"CTXT": REG_CTXT,
"g": REG_g,
"RET0": REG_RET0,
"RET1": REG_RET1,
"RET2": REG_RET2,
"RET3": REG_RET3,
"PAUSE": REG_PAUSE,
"R0": REG_R0,
"R1": REG_R1,
"R2": REG_R2,
"R3": REG_R3,
"R4": REG_R4,
"R5": REG_R5,
"R6": REG_R6,
"R7": REG_R7,
"R8": REG_R8,
"R9": REG_R9,
"R10": REG_R10,
"R11": REG_R11,
"R12": REG_R12,
"R13": REG_R13,
"R14": REG_R14,
"R15": REG_R15,
"F0": REG_F0,
"F1": REG_F1,
"F2": REG_F2,
"F3": REG_F3,
"F4": REG_F4,
"F5": REG_F5,
"F6": REG_F6,
"F7": REG_F7,
"F8": REG_F8,
"F9": REG_F9,
"F10": REG_F10,
"F11": REG_F11,
"F12": REG_F12,
"F13": REG_F13,
"F14": REG_F14,
"F15": REG_F15,
"F16": REG_F16,
"F17": REG_F17,
"F18": REG_F18,
"F19": REG_F19,
"F20": REG_F20,
"F21": REG_F21,
"F22": REG_F22,
"F23": REG_F23,
"F24": REG_F24,
"F25": REG_F25,
"F26": REG_F26,
"F27": REG_F27,
"F28": REG_F28,
"F29": REG_F29,
"F30": REG_F30,
"F31": REG_F31,
"PC_B": REG_PC_B,
}
var registerNames []string
func init() {
obj.RegisterRegister(MINREG, MAXREG, rconv)
obj.RegisterOpcode(obj.ABaseWasm, Anames)
registerNames = make([]string, MAXREG-MINREG)
for name, reg := range Register {
registerNames[reg-MINREG] = name
}
}
func rconv(r int) string {
return registerNames[r-MINREG]
}
var unaryDst = map[obj.As]bool{
ASet: true,
ATee: true,
ACall: true,
ACallIndirect: true,
ABr: true,
ABrIf: true,
ABrTable: true,
AI32Store: true,
AI64Store: true,
AF32Store: true,
AF64Store: true,
AI32Store8: true,
AI32Store16: true,
AI64Store8: true,
AI64Store16: true,
AI64Store32: true,
ACALLNORESUME: true,
}
var Linkwasm = obj.LinkArch{
Arch: sys.ArchWasm,
Init: instinit,
Preprocess: preprocess,
Assemble: assemble,
UnaryDst: unaryDst,
}
var (
morestack *obj.LSym
morestackNoCtxt *obj.LSym
sigpanic *obj.LSym
)
const (
/* mark flags */
WasmImport = 1 << 0
)
const (
// This is a special wasm module name that when used as the module name
// in //go:wasmimport will cause the generated code to pass the stack pointer
// directly to the imported function. In other words, any function that
// uses the gojs module understands the internal Go WASM ABI directly.
GojsModule = "gojs"
)
func instinit(ctxt *obj.Link) {
morestack = ctxt.Lookup("runtime.morestack")
morestackNoCtxt = ctxt.Lookup("runtime.morestack_noctxt")
sigpanic = ctxt.LookupABI("runtime.sigpanic", obj.ABIInternal)
}
func preprocess(ctxt *obj.Link, s *obj.LSym, newprog obj.ProgAlloc) {
appendp := func(p *obj.Prog, as obj.As, args ...obj.Addr) *obj.Prog {
if p.As != obj.ANOP {
p2 := obj.Appendp(p, newprog)
p2.Pc = p.Pc
p = p2
}
p.As = as
switch len(args) {
case 0:
p.From = obj.Addr{}
p.To = obj.Addr{}
case 1:
if unaryDst[as] {
p.From = obj.Addr{}
p.To = args[0]
} else {
p.From = args[0]
p.To = obj.Addr{}
}
case 2:
p.From = args[0]
p.To = args[1]
default:
panic("bad args")
}
return p
}
framesize := s.Func().Text.To.Offset
if framesize < 0 {
panic("bad framesize")
}
s.Func().Args = s.Func().Text.To.Val.(int32)
s.Func().Locals = int32(framesize)
// If the function exits just to call out to a wasmimport, then
// generate the code to translate from our internal Go-stack
// based call convention to the native webassembly call convention.
if wi := s.Func().WasmImport; wi != nil {
s.Func().WasmImportSym = wi.CreateSym(ctxt)
p := s.Func().Text
if p.Link != nil {
panic("wrapper functions for WASM imports should not have a body")
}
to := obj.Addr{
Type: obj.TYPE_MEM,
Name: obj.NAME_EXTERN,
Sym: s,
}
// If the module that the import is for is our magic "gojs" module, then this
// indicates that the called function understands the Go stack-based call convention
// so we just pass the stack pointer to it, knowing it will read the params directly
// off the stack and push the results into memory based on the stack pointer.
if wi.Module == GojsModule {
// The called function has a signature of 'func(sp int)'. It has access to the memory
// value somewhere to be able to address the memory based on the "sp" value.
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, ACall, to)
p.Mark = WasmImport
} else {
if len(wi.Results) > 1 {
// TODO(evanphx) implement support for the multi-value proposal:
// https://github.com/WebAssembly/multi-value/blob/master/proposals/multi-value/Overview.md
panic("invalid results type") // impossible until multi-value proposal has landed
}
if len(wi.Results) == 1 {
// If we have a result (rather than returning nothing at all), then
// we'll write the result to the Go stack relative to the current stack pointer.
// We cache the current stack pointer value on the wasm stack here and then use
// it after the Call instruction to store the result.
p = appendp(p, AGet, regAddr(REG_SP))
}
for _, f := range wi.Params {
// Each load instructions will consume the value of sp on the stack, so
// we need to read sp for each param. WASM appears to not have a stack dup instruction
// (a strange omission for a stack-based VM), if it did, we'd be using the dup here.
p = appendp(p, AGet, regAddr(REG_SP))
// Offset is the location of the param on the Go stack (ie relative to sp).
// Because of our call convention, the parameters are located an additional 8 bytes
// from sp because we store the return address as an int64 at the bottom of the stack.
// Ie the stack looks like [return_addr, param3, param2, param1, etc]
// Ergo, we add 8 to the true byte offset of the param to skip the return address.
loadOffset := f.Offset + 8
// We're reading the value from the Go stack onto the WASM stack and leaving it there
// for CALL to pick them up.
switch f.Type {
case obj.WasmI32:
p = appendp(p, AI32Load, constAddr(loadOffset))
case obj.WasmI64:
p = appendp(p, AI64Load, constAddr(loadOffset))
case obj.WasmF32:
p = appendp(p, AF32Load, constAddr(loadOffset))
case obj.WasmF64:
p = appendp(p, AF64Load, constAddr(loadOffset))
case obj.WasmPtr:
p = appendp(p, AI64Load, constAddr(loadOffset))
p = appendp(p, AI32WrapI64)
default:
panic("bad param type")
}
}
// The call instruction is marked as being for a wasm import so that a later phase
// will generate relocation information that allows us to patch this with then
// offset of the imported function in the wasm imports.
p = appendp(p, ACall, to)
p.Mark = WasmImport
if len(wi.Results) == 1 {
f := wi.Results[0]
// Much like with the params, we need to adjust the offset we store the result value
// to by 8 bytes to account for the return address on the Go stack.
storeOffset := f.Offset + 8
// This code is paired the code above that reads the stack pointer onto the wasm
// stack. We've done this so we have a consistent view of the sp value as it might
// be manipulated by the call and we want to ignore that manipulation here.
switch f.Type {
case obj.WasmI32:
p = appendp(p, AI32Store, constAddr(storeOffset))
case obj.WasmI64:
p = appendp(p, AI64Store, constAddr(storeOffset))
case obj.WasmF32:
p = appendp(p, AF32Store, constAddr(storeOffset))
case obj.WasmF64:
p = appendp(p, AF64Store, constAddr(storeOffset))
case obj.WasmPtr:
p = appendp(p, AI64ExtendI32U)
p = appendp(p, AI64Store, constAddr(storeOffset))
default:
panic("bad result type")
}
}
}
p = appendp(p, obj.ARET)
// It should be 0 already, but we'll set it to 0 anyway just to be sure
// that the code below which adds frame expansion code to the function body
// isn't run. We don't want the frame expansion code because our function
// body is just the code to translate and call the imported function.
framesize = 0
} else if s.Func().Text.From.Sym.Wrapper() {
// if g._panic != nil && g._panic.argp == FP {
// g._panic.argp = bottom-of-frame
// }
//
// MOVD g_panic(g), R0
// Get R0
// I64Eqz
// Not
// If
// Get SP
// I64ExtendI32U
// I64Const $framesize+8
// I64Add
// I64Load panic_argp(R0)
// I64Eq
// If
// MOVD SP, panic_argp(R0)
// End
// End
gpanic := obj.Addr{
Type: obj.TYPE_MEM,
Reg: REGG,
Offset: 4 * 8, // g_panic
}
panicargp := obj.Addr{
Type: obj.TYPE_MEM,
Reg: REG_R0,
Offset: 0, // panic.argp
}
p := s.Func().Text
p = appendp(p, AMOVD, gpanic, regAddr(REG_R0))
p = appendp(p, AGet, regAddr(REG_R0))
p = appendp(p, AI64Eqz)
p = appendp(p, ANot)
p = appendp(p, AIf)
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI64ExtendI32U)
p = appendp(p, AI64Const, constAddr(framesize+8))
p = appendp(p, AI64Add)
p = appendp(p, AI64Load, panicargp)
p = appendp(p, AI64Eq)
p = appendp(p, AIf)
p = appendp(p, AMOVD, regAddr(REG_SP), panicargp)
p = appendp(p, AEnd)
p = appendp(p, AEnd)
}
if framesize > 0 {
p := s.Func().Text
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI32Const, constAddr(framesize))
p = appendp(p, AI32Sub)
p = appendp(p, ASet, regAddr(REG_SP))
p.Spadj = int32(framesize)
}
// If the framesize is 0, then imply nosplit because it's a specially
// generated function.
needMoreStack := framesize > 0 && !s.Func().Text.From.Sym.NoSplit()
// If the maymorestack debug option is enabled, insert the
// call to maymorestack *before* processing resume points so
// we can construct a resume point after maymorestack for
// morestack to resume at.
var pMorestack = s.Func().Text
if needMoreStack && ctxt.Flag_maymorestack != "" {
p := pMorestack
// Save REGCTXT on the stack.
const tempFrame = 8
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI32Const, constAddr(tempFrame))
p = appendp(p, AI32Sub)
p = appendp(p, ASet, regAddr(REG_SP))
p.Spadj = tempFrame
ctxtp := obj.Addr{
Type: obj.TYPE_MEM,
Reg: REG_SP,
Offset: 0,
}
p = appendp(p, AMOVD, regAddr(REGCTXT), ctxtp)
// maymorestack must not itself preempt because we
// don't have full stack information, so this can be
// ACALLNORESUME.
p = appendp(p, ACALLNORESUME, constAddr(0))
// See ../x86/obj6.go
sym := ctxt.LookupABI(ctxt.Flag_maymorestack, s.ABI())
p.To = obj.Addr{Type: obj.TYPE_MEM, Name: obj.NAME_EXTERN, Sym: sym}
// Restore REGCTXT.
p = appendp(p, AMOVD, ctxtp, regAddr(REGCTXT))
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI32Const, constAddr(tempFrame))
p = appendp(p, AI32Add)
p = appendp(p, ASet, regAddr(REG_SP))
p.Spadj = -tempFrame
// Add an explicit ARESUMEPOINT after maymorestack for
// morestack to resume at.
pMorestack = appendp(p, ARESUMEPOINT)
}
// Introduce resume points for CALL instructions
// and collect other explicit resume points.
numResumePoints := 0
explicitBlockDepth := 0
pc := int64(0) // pc is only incremented when necessary, this avoids bloat of the BrTable instruction
var tableIdxs []uint64
tablePC := int64(0)
base := ctxt.PosTable.Pos(s.Func().Text.Pos).Base()
for p := s.Func().Text; p != nil; p = p.Link {
prevBase := base
base = ctxt.PosTable.Pos(p.Pos).Base()
switch p.As {
case ABlock, ALoop, AIf:
explicitBlockDepth++
case AEnd:
if explicitBlockDepth == 0 {
panic("End without block")
}
explicitBlockDepth--
case ARESUMEPOINT:
if explicitBlockDepth != 0 {
panic("RESUME can only be used on toplevel")
}
p.As = AEnd
for tablePC <= pc {
tableIdxs = append(tableIdxs, uint64(numResumePoints))
tablePC++
}
numResumePoints++
pc++
case obj.ACALL:
if explicitBlockDepth != 0 {
panic("CALL can only be used on toplevel, try CALLNORESUME instead")
}
appendp(p, ARESUMEPOINT)
}
p.Pc = pc
// Increase pc whenever some pc-value table needs a new entry. Don't increase it
// more often to avoid bloat of the BrTable instruction.
// The "base != prevBase" condition detects inlined instructions. They are an
// implicit call, so entering and leaving this section affects the stack trace.
if p.As == ACALLNORESUME || p.As == obj.ANOP || p.As == ANop || p.Spadj != 0 || base != prevBase {
pc++
if p.To.Sym == sigpanic {
// The panic stack trace expects the PC at the call of sigpanic,
// not the next one. However, runtime.Caller subtracts 1 from the
// PC. To make both PC and PC-1 work (have the same line number),
// we advance the PC by 2 at sigpanic.
pc++
}
}
}
tableIdxs = append(tableIdxs, uint64(numResumePoints))
s.Size = pc + 1
if needMoreStack {
p := pMorestack
if framesize <= abi.StackSmall {
// small stack: SP <= stackguard
// Get SP
// Get g
// I32WrapI64
// I32Load $stackguard0
// I32GtU
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AGet, regAddr(REGG))
p = appendp(p, AI32WrapI64)
p = appendp(p, AI32Load, constAddr(2*int64(ctxt.Arch.PtrSize))) // G.stackguard0
p = appendp(p, AI32LeU)
} else {
// large stack: SP-framesize <= stackguard-StackSmall
// SP <= stackguard+(framesize-StackSmall)
// Get SP
// Get g
// I32WrapI64
// I32Load $stackguard0
// I32Const $(framesize-StackSmall)
// I32Add
// I32GtU
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AGet, regAddr(REGG))
p = appendp(p, AI32WrapI64)
p = appendp(p, AI32Load, constAddr(2*int64(ctxt.Arch.PtrSize))) // G.stackguard0
p = appendp(p, AI32Const, constAddr(framesize-abi.StackSmall))
p = appendp(p, AI32Add)
p = appendp(p, AI32LeU)
}
// TODO(neelance): handle wraparound case
p = appendp(p, AIf)
// This CALL does *not* have a resume point after it
// (we already inserted all of the resume points). As
// a result, morestack will resume at the *previous*
// resume point (typically, the beginning of the
// function) and perform the morestack check again.
// This is why we don't need an explicit loop like
// other architectures.
p = appendp(p, obj.ACALL, constAddr(0))
if s.Func().Text.From.Sym.NeedCtxt() {
p.To = obj.Addr{Type: obj.TYPE_MEM, Name: obj.NAME_EXTERN, Sym: morestack}
} else {
p.To = obj.Addr{Type: obj.TYPE_MEM, Name: obj.NAME_EXTERN, Sym: morestackNoCtxt}
}
p = appendp(p, AEnd)
}
// record the branches targeting the entry loop and the unwind exit,
// their targets with be filled in later
var entryPointLoopBranches []*obj.Prog
var unwindExitBranches []*obj.Prog
currentDepth := 0
for p := s.Func().Text; p != nil; p = p.Link {
switch p.As {
case ABlock, ALoop, AIf:
currentDepth++
case AEnd:
currentDepth--
}
switch p.As {
case obj.AJMP:
jmp := *p
p.As = obj.ANOP
if jmp.To.Type == obj.TYPE_BRANCH {
// jump to basic block
p = appendp(p, AI32Const, constAddr(jmp.To.Val.(*obj.Prog).Pc))
p = appendp(p, ASet, regAddr(REG_PC_B)) // write next basic block to PC_B
p = appendp(p, ABr) // jump to beginning of entryPointLoop
entryPointLoopBranches = append(entryPointLoopBranches, p)
break
}
// low-level WebAssembly call to function
switch jmp.To.Type {
case obj.TYPE_MEM:
if !notUsePC_B[jmp.To.Sym.Name] {
// Set PC_B parameter to function entry.
p = appendp(p, AI32Const, constAddr(0))
}
p = appendp(p, ACall, jmp.To)
case obj.TYPE_NONE:
// (target PC is on stack)
p = appendp(p, AI32WrapI64)
p = appendp(p, AI32Const, constAddr(16)) // only needs PC_F bits (16-31), PC_B bits (0-15) are zero
p = appendp(p, AI32ShrU)
// Set PC_B parameter to function entry.
// We need to push this before pushing the target PC_F,
// so temporarily pop PC_F, using our REG_PC_B as a
// scratch register, and push it back after pushing 0.
p = appendp(p, ASet, regAddr(REG_PC_B))
p = appendp(p, AI32Const, constAddr(0))
p = appendp(p, AGet, regAddr(REG_PC_B))
p = appendp(p, ACallIndirect)
default:
panic("bad target for JMP")
}
p = appendp(p, AReturn)
case obj.ACALL, ACALLNORESUME:
call := *p
p.As = obj.ANOP
pcAfterCall := call.Link.Pc
if call.To.Sym == sigpanic {
pcAfterCall-- // sigpanic expects to be called without advancing the pc
}
// SP -= 8
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI32Const, constAddr(8))
p = appendp(p, AI32Sub)
p = appendp(p, ASet, regAddr(REG_SP))
// write return address to Go stack
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI64Const, obj.Addr{
Type: obj.TYPE_ADDR,
Name: obj.NAME_EXTERN,
Sym: s, // PC_F
Offset: pcAfterCall, // PC_B
})
p = appendp(p, AI64Store, constAddr(0))
// low-level WebAssembly call to function
switch call.To.Type {
case obj.TYPE_MEM:
if !notUsePC_B[call.To.Sym.Name] {
// Set PC_B parameter to function entry.
p = appendp(p, AI32Const, constAddr(0))
}
p = appendp(p, ACall, call.To)
case obj.TYPE_NONE:
// (target PC is on stack)
p = appendp(p, AI32WrapI64)
p = appendp(p, AI32Const, constAddr(16)) // only needs PC_F bits (16-31), PC_B bits (0-15) are zero
p = appendp(p, AI32ShrU)
// Set PC_B parameter to function entry.
// We need to push this before pushing the target PC_F,
// so temporarily pop PC_F, using our PC_B as a
// scratch register, and push it back after pushing 0.
p = appendp(p, ASet, regAddr(REG_PC_B))
p = appendp(p, AI32Const, constAddr(0))
p = appendp(p, AGet, regAddr(REG_PC_B))
p = appendp(p, ACallIndirect)
default:
panic("bad target for CALL")
}
// return value of call is on the top of the stack, indicating whether to unwind the WebAssembly stack
if call.As == ACALLNORESUME && call.To.Sym != sigpanic { // sigpanic unwinds the stack, but it never resumes
// trying to unwind WebAssembly stack but call has no resume point, terminate with error
p = appendp(p, AIf)
p = appendp(p, obj.AUNDEF)
p = appendp(p, AEnd)
} else {
// unwinding WebAssembly stack to switch goroutine, return 1
p = appendp(p, ABrIf)
unwindExitBranches = append(unwindExitBranches, p)
}
case obj.ARET, ARETUNWIND:
ret := *p
p.As = obj.ANOP
if framesize > 0 {
// SP += framesize
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI32Const, constAddr(framesize))
p = appendp(p, AI32Add)
p = appendp(p, ASet, regAddr(REG_SP))
// TODO(neelance): This should theoretically set Spadj, but it only works without.
// p.Spadj = int32(-framesize)
}
if ret.To.Type == obj.TYPE_MEM {
// Set PC_B parameter to function entry.
p = appendp(p, AI32Const, constAddr(0))
// low-level WebAssembly call to function
p = appendp(p, ACall, ret.To)
p = appendp(p, AReturn)
break
}
// SP += 8
p = appendp(p, AGet, regAddr(REG_SP))
p = appendp(p, AI32Const, constAddr(8))
p = appendp(p, AI32Add)
p = appendp(p, ASet, regAddr(REG_SP))
if ret.As == ARETUNWIND {
// function needs to unwind the WebAssembly stack, return 1
p = appendp(p, AI32Const, constAddr(1))
p = appendp(p, AReturn)
break
}
// not unwinding the WebAssembly stack, return 0
p = appendp(p, AI32Const, constAddr(0))
p = appendp(p, AReturn)
}
}
for p := s.Func().Text; p != nil; p = p.Link {
switch p.From.Name {
case obj.NAME_AUTO:
p.From.Offset += framesize
case obj.NAME_PARAM:
p.From.Reg = REG_SP
p.From.Offset += framesize + 8 // parameters are after the frame and the 8-byte return address
}
switch p.To.Name {
case obj.NAME_AUTO:
p.To.Offset += framesize
case obj.NAME_PARAM:
p.To.Reg = REG_SP
p.To.Offset += framesize + 8 // parameters are after the frame and the 8-byte return address
}
switch p.As {
case AGet:
if p.From.Type == obj.TYPE_ADDR {
get := *p
p.As = obj.ANOP
switch get.From.Name {
case obj.NAME_EXTERN:
p = appendp(p, AI64Const, get.From)
case obj.NAME_AUTO, obj.NAME_PARAM:
p = appendp(p, AGet, regAddr(get.From.Reg))
if get.From.Reg == REG_SP {
p = appendp(p, AI64ExtendI32U)
}
if get.From.Offset != 0 {
p = appendp(p, AI64Const, constAddr(get.From.Offset))
p = appendp(p, AI64Add)
}
default:
panic("bad Get: invalid name")
}
}
case AI32Load, AI64Load, AF32Load, AF64Load, AI32Load8S, AI32Load8U, AI32Load16S, AI32Load16U, AI64Load8S, AI64Load8U, AI64Load16S, AI64Load16U, AI64Load32S, AI64Load32U:
if p.From.Type == obj.TYPE_MEM {
as := p.As
from := p.From
p.As = AGet
p.From = regAddr(from.Reg)
if from.Reg != REG_SP {
p = appendp(p, AI32WrapI64)
}
p = appendp(p, as, constAddr(from.Offset))
}
case AMOVB, AMOVH, AMOVW, AMOVD:
mov := *p
p.As = obj.ANOP
var loadAs obj.As
var storeAs obj.As
switch mov.As {
case AMOVB:
loadAs = AI64Load8U
storeAs = AI64Store8
case AMOVH:
loadAs = AI64Load16U
storeAs = AI64Store16
case AMOVW:
loadAs = AI64Load32U
storeAs = AI64Store32
case AMOVD:
loadAs = AI64Load
storeAs = AI64Store
}
appendValue := func() {
switch mov.From.Type {
case obj.TYPE_CONST:
p = appendp(p, AI64Const, constAddr(mov.From.Offset))
case obj.TYPE_ADDR:
switch mov.From.Name {
case obj.NAME_NONE, obj.NAME_PARAM, obj.NAME_AUTO:
p = appendp(p, AGet, regAddr(mov.From.Reg))
if mov.From.Reg == REG_SP {
p = appendp(p, AI64ExtendI32U)
}
p = appendp(p, AI64Const, constAddr(mov.From.Offset))
p = appendp(p, AI64Add)
case obj.NAME_EXTERN:
p = appendp(p, AI64Const, mov.From)
default:
panic("bad name for MOV")
}
case obj.TYPE_REG:
p = appendp(p, AGet, mov.From)
if mov.From.Reg == REG_SP {
p = appendp(p, AI64ExtendI32U)
}
case obj.TYPE_MEM:
p = appendp(p, AGet, regAddr(mov.From.Reg))
if mov.From.Reg != REG_SP {
p = appendp(p, AI32WrapI64)
}
p = appendp(p, loadAs, constAddr(mov.From.Offset))
default:
panic("bad MOV type")
}
}
switch mov.To.Type {
case obj.TYPE_REG:
appendValue()
if mov.To.Reg == REG_SP {
p = appendp(p, AI32WrapI64)
}
p = appendp(p, ASet, mov.To)
case obj.TYPE_MEM:
switch mov.To.Name {
case obj.NAME_NONE, obj.NAME_PARAM:
p = appendp(p, AGet, regAddr(mov.To.Reg))
if mov.To.Reg != REG_SP {
p = appendp(p, AI32WrapI64)
}
case obj.NAME_EXTERN:
p = appendp(p, AI32Const, obj.Addr{Type: obj.TYPE_ADDR, Name: obj.NAME_EXTERN, Sym: mov.To.Sym})
default:
panic("bad MOV name")
}
appendValue()
p = appendp(p, storeAs, constAddr(mov.To.Offset))
default:
panic("bad MOV type")
}
}
}
{
p := s.Func().Text
if len(unwindExitBranches) > 0 {
p = appendp(p, ABlock) // unwindExit, used to return 1 when unwinding the stack
for _, b := range unwindExitBranches {
b.To = obj.Addr{Type: obj.TYPE_BRANCH, Val: p}
}
}
if len(entryPointLoopBranches) > 0 {
p = appendp(p, ALoop) // entryPointLoop, used to jump between basic blocks
for _, b := range entryPointLoopBranches {
b.To = obj.Addr{Type: obj.TYPE_BRANCH, Val: p}
}
}
if numResumePoints > 0 {
// Add Block instructions for resume points and BrTable to jump to selected resume point.
for i := 0; i < numResumePoints+1; i++ {
p = appendp(p, ABlock)
}
p = appendp(p, AGet, regAddr(REG_PC_B)) // read next basic block from PC_B
p = appendp(p, ABrTable, obj.Addr{Val: tableIdxs})
p = appendp(p, AEnd) // end of Block
}
for p.Link != nil {
p = p.Link // function instructions
}
if len(entryPointLoopBranches) > 0 {
p = appendp(p, AEnd) // end of entryPointLoop
}
p = appendp(p, obj.AUNDEF)
if len(unwindExitBranches) > 0 {
p = appendp(p, AEnd) // end of unwindExit
p = appendp(p, AI32Const, constAddr(1))
}
}
currentDepth = 0
blockDepths := make(map[*obj.Prog]int)
for p := s.Func().Text; p != nil; p = p.Link {
switch p.As {
case ABlock, ALoop, AIf:
currentDepth++
blockDepths[p] = currentDepth
case AEnd:
currentDepth--
}
switch p.As {
case ABr, ABrIf:
if p.To.Type == obj.TYPE_BRANCH {
blockDepth, ok := blockDepths[p.To.Val.(*obj.Prog)]
if !ok {
panic("label not at block")
}
p.To = constAddr(int64(currentDepth - blockDepth))
}
}
}
}
func constAddr(value int64) obj.Addr {
return obj.Addr{Type: obj.TYPE_CONST, Offset: value}
}
func regAddr(reg int16) obj.Addr {
return obj.Addr{Type: obj.TYPE_REG, Reg: reg}
}
// Most of the Go functions has a single parameter (PC_B) in
// Wasm ABI. This is a list of exceptions.
var notUsePC_B = map[string]bool{
"_rt0_wasm_js": true,
"_rt0_wasm_wasip1": true,
"wasm_export_run": true,
"wasm_export_resume": true,
"wasm_export_getsp": true,
"wasm_pc_f_loop": true,
"gcWriteBarrier": true,
"runtime.gcWriteBarrier1": true,
"runtime.gcWriteBarrier2": true,
"runtime.gcWriteBarrier3": true,
"runtime.gcWriteBarrier4": true,
"runtime.gcWriteBarrier5": true,
"runtime.gcWriteBarrier6": true,
"runtime.gcWriteBarrier7": true,
"runtime.gcWriteBarrier8": true,
"runtime.wasmDiv": true,
"runtime.wasmTruncS": true,
"runtime.wasmTruncU": true,
"cmpbody": true,
"memeqbody": true,
"memcmp": true,
"memchr": true,
}
func assemble(ctxt *obj.Link, s *obj.LSym, newprog obj.ProgAlloc) {
type regVar struct {
global bool
index uint64
}
type varDecl struct {
count uint64
typ valueType
}
hasLocalSP := false
regVars := [MAXREG - MINREG]*regVar{
REG_SP - MINREG: {true, 0},
REG_CTXT - MINREG: {true, 1},
REG_g - MINREG: {true, 2},
REG_RET0 - MINREG: {true, 3},
REG_RET1 - MINREG: {true, 4},
REG_RET2 - MINREG: {true, 5},
REG_RET3 - MINREG: {true, 6},
REG_PAUSE - MINREG: {true, 7},
}
var varDecls []*varDecl
useAssemblyRegMap := func() {
for i := int16(0); i < 16; i++ {
regVars[REG_R0+i-MINREG] = ®Var{false, uint64(i)}
}
}
// Function starts with declaration of locals: numbers and types.
// Some functions use a special calling convention.
switch s.Name {
case "_rt0_wasm_js", "_rt0_wasm_wasip1", "wasm_export_run", "wasm_export_resume", "wasm_export_getsp",
"wasm_pc_f_loop", "runtime.wasmDiv", "runtime.wasmTruncS", "runtime.wasmTruncU", "memeqbody":
varDecls = []*varDecl{}
useAssemblyRegMap()
case "memchr", "memcmp":
varDecls = []*varDecl{{count: 2, typ: i32}}
useAssemblyRegMap()
case "cmpbody":
varDecls = []*varDecl{{count: 2, typ: i64}}
useAssemblyRegMap()
case "gcWriteBarrier":
varDecls = []*varDecl{{count: 5, typ: i64}}
useAssemblyRegMap()
case "runtime.gcWriteBarrier1",
"runtime.gcWriteBarrier2",
"runtime.gcWriteBarrier3",
"runtime.gcWriteBarrier4",
"runtime.gcWriteBarrier5",
"runtime.gcWriteBarrier6",
"runtime.gcWriteBarrier7",
"runtime.gcWriteBarrier8":
// no locals
useAssemblyRegMap()
default:
// Normal calling convention: PC_B as WebAssembly parameter. First local variable is local SP cache.
regVars[REG_PC_B-MINREG] = ®Var{false, 0}
hasLocalSP = true
var regUsed [MAXREG - MINREG]bool
for p := s.Func().Text; p != nil; p = p.Link {
if p.From.Reg != 0 {
regUsed[p.From.Reg-MINREG] = true
}
if p.To.Reg != 0 {
regUsed[p.To.Reg-MINREG] = true
}
}
regs := []int16{REG_SP}
for reg := int16(REG_R0); reg <= REG_F31; reg++ {
if regUsed[reg-MINREG] {
regs = append(regs, reg)
}
}
var lastDecl *varDecl
for i, reg := range regs {
t := regType(reg)
if lastDecl == nil || lastDecl.typ != t {
lastDecl = &varDecl{
count: 0,
typ: t,
}
varDecls = append(varDecls, lastDecl)
}
lastDecl.count++
if reg != REG_SP {
regVars[reg-MINREG] = ®Var{false, 1 + uint64(i)}
}
}
}
w := new(bytes.Buffer)
writeUleb128(w, uint64(len(varDecls)))
for _, decl := range varDecls {
writeUleb128(w, decl.count)
w.WriteByte(byte(decl.typ))
}
if hasLocalSP {
// Copy SP from its global variable into a local variable. Accessing a local variable is more efficient.
updateLocalSP(w)
}
for p := s.Func().Text; p != nil; p = p.Link {
switch p.As {
case AGet:
if p.From.Type != obj.TYPE_REG {
panic("bad Get: argument is not a register")
}
reg := p.From.Reg
v := regVars[reg-MINREG]
if v == nil {
panic("bad Get: invalid register")
}
if reg == REG_SP && hasLocalSP {
writeOpcode(w, ALocalGet)
writeUleb128(w, 1) // local SP
continue
}
if v.global {
writeOpcode(w, AGlobalGet)
} else {
writeOpcode(w, ALocalGet)
}
writeUleb128(w, v.index)
continue
case ASet:
if p.To.Type != obj.TYPE_REG {
panic("bad Set: argument is not a register")
}
reg := p.To.Reg
v := regVars[reg-MINREG]
if v == nil {
panic("bad Set: invalid register")
}
if reg == REG_SP && hasLocalSP {
writeOpcode(w, ALocalTee)
writeUleb128(w, 1) // local SP
}
if v.global {
writeOpcode(w, AGlobalSet)
} else {
if p.Link.As == AGet && p.Link.From.Reg == reg {
writeOpcode(w, ALocalTee)
p = p.Link
} else {
writeOpcode(w, ALocalSet)
}
}
writeUleb128(w, v.index)
continue
case ATee:
if p.To.Type != obj.TYPE_REG {
panic("bad Tee: argument is not a register")
}
reg := p.To.Reg
v := regVars[reg-MINREG]
if v == nil {
panic("bad Tee: invalid register")
}
writeOpcode(w, ALocalTee)
writeUleb128(w, v.index)
continue
case ANot:
writeOpcode(w, AI32Eqz)
continue
case obj.AUNDEF:
writeOpcode(w, AUnreachable)
continue
case obj.ANOP, obj.ATEXT, obj.AFUNCDATA, obj.APCDATA:
// ignore
continue
}
writeOpcode(w, p.As)
switch p.As {
case ABlock, ALoop, AIf:
if p.From.Offset != 0 {
// block type, rarely used, e.g. for code compiled with emscripten
w.WriteByte(0x80 - byte(p.From.Offset))
continue
}
w.WriteByte(0x40)
case ABr, ABrIf:
if p.To.Type != obj.TYPE_CONST {
panic("bad Br/BrIf")
}
writeUleb128(w, uint64(p.To.Offset))
case ABrTable:
idxs := p.To.Val.([]uint64)
writeUleb128(w, uint64(len(idxs)-1))
for _, idx := range idxs {
writeUleb128(w, idx)
}
case ACall:
switch p.To.Type {
case obj.TYPE_CONST:
writeUleb128(w, uint64(p.To.Offset))
case obj.TYPE_MEM:
if p.To.Name != obj.NAME_EXTERN && p.To.Name != obj.NAME_STATIC {
fmt.Println(p.To)
panic("bad name for Call")
}
r := obj.Addrel(s)
r.Siz = 1 // actually variable sized
r.Off = int32(w.Len())
r.Type = objabi.R_CALL
if p.Mark&WasmImport != 0 {
r.Type = objabi.R_WASMIMPORT
}
r.Sym = p.To.Sym
if hasLocalSP {
// The stack may have moved, which changes SP. Update the local SP variable.
updateLocalSP(w)
}
default:
panic("bad type for Call")
}
case ACallIndirect:
writeUleb128(w, uint64(p.To.Offset))
w.WriteByte(0x00) // reserved value
if hasLocalSP {
// The stack may have moved, which changes SP. Update the local SP variable.
updateLocalSP(w)
}
case AI32Const, AI64Const:
if p.From.Name == obj.NAME_EXTERN {
r := obj.Addrel(s)
r.Siz = 1 // actually variable sized
r.Off = int32(w.Len())
r.Type = objabi.R_ADDR
r.Sym = p.From.Sym
r.Add = p.From.Offset
break
}
writeSleb128(w, p.From.Offset)
case AF32Const:
b := make([]byte, 4)
binary.LittleEndian.PutUint32(b, math.Float32bits(float32(p.From.Val.(float64))))
w.Write(b)
case AF64Const:
b := make([]byte, 8)
binary.LittleEndian.PutUint64(b, math.Float64bits(p.From.Val.(float64)))
w.Write(b)
case AI32Load, AI64Load, AF32Load, AF64Load, AI32Load8S, AI32Load8U, AI32Load16S, AI32Load16U, AI64Load8S, AI64Load8U, AI64Load16S, AI64Load16U, AI64Load32S, AI64Load32U:
if p.From.Offset < 0 {
panic("negative offset for *Load")
}
if p.From.Type != obj.TYPE_CONST {
panic("bad type for *Load")
}
if p.From.Offset > math.MaxUint32 {
ctxt.Diag("bad offset in %v", p)
}
writeUleb128(w, align(p.As))
writeUleb128(w, uint64(p.From.Offset))
case AI32Store, AI64Store, AF32Store, AF64Store, AI32Store8, AI32Store16, AI64Store8, AI64Store16, AI64Store32:
if p.To.Offset < 0 {
panic("negative offset")
}
if p.From.Offset > math.MaxUint32 {
ctxt.Diag("bad offset in %v", p)
}
writeUleb128(w, align(p.As))
writeUleb128(w, uint64(p.To.Offset))
case ACurrentMemory, AGrowMemory, AMemoryFill:
w.WriteByte(0x00)
case AMemoryCopy:
w.WriteByte(0x00)
w.WriteByte(0x00)
}
}
w.WriteByte(0x0b) // end
s.P = w.Bytes()
}
func updateLocalSP(w *bytes.Buffer) {
writeOpcode(w, AGlobalGet)
writeUleb128(w, 0) // global SP
writeOpcode(w, ALocalSet)
writeUleb128(w, 1) // local SP
}
func writeOpcode(w *bytes.Buffer, as obj.As) {
switch {
case as < AUnreachable:
panic(fmt.Sprintf("unexpected assembler op: %s", as))
case as < AEnd:
w.WriteByte(byte(as - AUnreachable + 0x00))
case as < ADrop:
w.WriteByte(byte(as - AEnd + 0x0B))
case as < ALocalGet:
w.WriteByte(byte(as - ADrop + 0x1A))
case as < AI32Load:
w.WriteByte(byte(as - ALocalGet + 0x20))
case as < AI32TruncSatF32S:
w.WriteByte(byte(as - AI32Load + 0x28))
case as < ALast:
w.WriteByte(0xFC)
w.WriteByte(byte(as - AI32TruncSatF32S + 0x00))
default:
panic(fmt.Sprintf("unexpected assembler op: %s", as))
}
}
type valueType byte
const (
i32 valueType = 0x7F
i64 valueType = 0x7E
f32 valueType = 0x7D
f64 valueType = 0x7C
)
func regType(reg int16) valueType {
switch {
case reg == REG_SP:
return i32
case reg >= REG_R0 && reg <= REG_R15:
return i64
case reg >= REG_F0 && reg <= REG_F15:
return f32
case reg >= REG_F16 && reg <= REG_F31:
return f64
default:
panic("invalid register")
}
}
func align(as obj.As) uint64 {
switch as {
case AI32Load8S, AI32Load8U, AI64Load8S, AI64Load8U, AI32Store8, AI64Store8:
return 0
case AI32Load16S, AI32Load16U, AI64Load16S, AI64Load16U, AI32Store16, AI64Store16:
return 1
case AI32Load, AF32Load, AI64Load32S, AI64Load32U, AI32Store, AF32Store, AI64Store32:
return 2
case AI64Load, AF64Load, AI64Store, AF64Store:
return 3
default:
panic("align: bad op")
}
}
func writeUleb128(w io.ByteWriter, v uint64) {
if v < 128 {
w.WriteByte(uint8(v))
return
}
more := true
for more {
c := uint8(v & 0x7f)
v >>= 7
more = v != 0
if more {
c |= 0x80
}
w.WriteByte(c)
}
}
func writeSleb128(w io.ByteWriter, v int64) {
more := true
for more {
c := uint8(v & 0x7f)
s := uint8(v & 0x40)
v >>= 7
more = !((v == 0 && s == 0) || (v == -1 && s != 0))
if more {
c |= 0x80
}
w.WriteByte(c)
}
}
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