src/cmd/link/internal/wasm/asm.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.

 package wasm

 import (
 	"bytes"
 	"cmd/internal/objabi"
 	"cmd/link/internal/ld"
 	"cmd/link/internal/loader"
 	"cmd/link/internal/sym"
 	"io"
 	"regexp"
 )

 const (
 	I32 = 0x7F
 	I64 = 0x7E
 	F32 = 0x7D
 	F64 = 0x7C
 )

 const (
 	sectionCustom   = 0
 	sectionType     = 1
 	sectionImport   = 2
 	sectionFunction = 3
 	sectionTable    = 4
 	sectionMemory   = 5
 	sectionGlobal   = 6
 	sectionExport   = 7
 	sectionStart    = 8
 	sectionElement  = 9
 	sectionCode     = 10
 	sectionData     = 11
 )

 // funcValueOffset is the offset between the PC_F value of a function and the index of the function in WebAssembly
 const funcValueOffset = 0x1000 // TODO(neelance): make function addresses play nice with heap addresses

 func gentext(ctxt *ld.Link, ldr *loader.Loader) {
 }

 type wasmFunc struct {
 	Name string
 	Type uint32
 	Code []byte
 }

 type wasmFuncType struct {
 	Params  []byte
 	Results []byte
 }

 var wasmFuncTypes = map[string]*wasmFuncType{
 	"_rt0_wasm_js":           {Params: []byte{}},                                         //
 	"wasm_export_run":        {Params: []byte{I32, I32}},                                 // argc, argv
 	"wasm_export_resume":     {Params: []byte{}},                                         //
 	"wasm_export_getsp":      {Results: []byte{I32}},                                     // sp
 	"wasm_pc_f_loop":         {Params: []byte{}},                                         //
 	"runtime.wasmMove":       {Params: []byte{I32, I32, I32}},                            // dst, src, len
 	"runtime.wasmZero":       {Params: []byte{I32, I32}},                                 // ptr, len
 	"runtime.wasmDiv":        {Params: []byte{I64, I64}, Results: []byte{I64}},           // x, y -> x/y
 	"runtime.wasmTruncS":     {Params: []byte{F64}, Results: []byte{I64}},                // x -> int(x)
 	"runtime.wasmTruncU":     {Params: []byte{F64}, Results: []byte{I64}},                // x -> uint(x)
 	"runtime.gcWriteBarrier": {Params: []byte{I64, I64}},                                 // ptr, val
 	"cmpbody":                {Params: []byte{I64, I64, I64, I64}, Results: []byte{I64}}, // a, alen, b, blen -> -1/0/1
 	"memeqbody":              {Params: []byte{I64, I64, I64}, Results: []byte{I64}},      // a, b, len -> 0/1
 	"memcmp":                 {Params: []byte{I32, I32, I32}, Results: []byte{I32}},      // a, b, len -> <0/0/>0
 	"memchr":                 {Params: []byte{I32, I32, I32}, Results: []byte{I32}},      // s, c, len -> index
 }

 func assignAddress(ldr *loader.Loader, sect *sym.Section, n int, s loader.Sym, va uint64, isTramp bool) (*sym.Section, int, uint64) {
 	// WebAssembly functions do not live in the same address space as the linear memory.
 	// Instead, WebAssembly automatically assigns indices. Imported functions (section "import")
 	// have indices 0 to n. They are followed by native functions (sections "function" and "code")
 	// with indices n+1 and following.
 	//
 	// The following rules describe how wasm handles function indices and addresses:
 	//   PC_F = funcValueOffset + WebAssembly function index (not including the imports)
 	//   s.Value = PC = PC_F<<16 + PC_B
 	//
 	// The funcValueOffset is necessary to avoid conflicts with expectations
 	// that the Go runtime has about function addresses.
 	// The field "s.Value" corresponds to the concept of PC at runtime.
 	// However, there is no PC register, only PC_F and PC_B. PC_F denotes the function,
 	// PC_B the resume point inside of that function. The entry of the function has PC_B = 0.
 	ldr.SetSymSect(s, sect)
 	ldr.SetSymValue(s, int64(funcValueOffset+va/ld.MINFUNC)<<16) // va starts at zero
 	va += uint64(ld.MINFUNC)
 	return sect, n, va
 }

 type wasmDataSect struct {
 	sect *sym.Section
 	data []byte
 }

 var dataSects []wasmDataSect

 func asmb(ctxt *ld.Link, ldr *loader.Loader) {
 	sections := []*sym.Section{
 		ldr.SymSect(ldr.Lookup("runtime.rodata", 0)),
 		ldr.SymSect(ldr.Lookup("runtime.typelink", 0)),
 		ldr.SymSect(ldr.Lookup("runtime.itablink", 0)),
 		ldr.SymSect(ldr.Lookup("runtime.symtab", 0)),
 		ldr.SymSect(ldr.Lookup("runtime.pclntab", 0)),
 		ldr.SymSect(ldr.Lookup("runtime.noptrdata", 0)),
 		ldr.SymSect(ldr.Lookup("runtime.data", 0)),
 	}

 	dataSects = make([]wasmDataSect, len(sections))
 	for i, sect := range sections {
 		data := ld.DatblkBytes(ctxt, int64(sect.Vaddr), int64(sect.Length))
 		dataSects[i] = wasmDataSect{sect, data}
 	}
 }

 // asmb writes the final WebAssembly module binary.
 // Spec: https://webassembly.github.io/spec/core/binary/modules.html
 func asmb2(ctxt *ld.Link, ldr *loader.Loader) {
 	types := []*wasmFuncType{
 		// For normal Go functions, the single parameter is PC_B,
 		// the return value is
 		// 0 if the function returned normally or
 		// 1 if the stack needs to be unwound.
 		{Params: []byte{I32}, Results: []byte{I32}},
 	}

 	// collect host imports (functions that get imported from the WebAssembly host, usually JavaScript)
 	hostImports := []*wasmFunc{
 		{
 			Name: "debug",
 			Type: lookupType(&wasmFuncType{Params: []byte{I32}}, &types),
 		},
 	}
 	hostImportMap := make(map[loader.Sym]int64)
 	for _, fn := range ctxt.Textp {
 		relocs := ldr.Relocs(fn)
 		for ri := 0; ri < relocs.Count(); ri++ {
 			r := relocs.At(ri)
 			if r.Type() == objabi.R_WASMIMPORT {
 				hostImportMap[r.Sym()] = int64(len(hostImports))
 				hostImports = append(hostImports, &wasmFunc{
 					Name: ldr.SymName(r.Sym()),
 					Type: lookupType(&wasmFuncType{Params: []byte{I32}}, &types),
 				})
 			}
 		}
 	}

 	// collect functions with WebAssembly body
 	var buildid []byte
 	fns := make([]*wasmFunc, len(ctxt.Textp))
 	for i, fn := range ctxt.Textp {
 		wfn := new(bytes.Buffer)
 		if ldr.SymName(fn) == "go.buildid" {
 			writeUleb128(wfn, 0) // number of sets of locals
 			writeI32Const(wfn, 0)
 			wfn.WriteByte(0x0b) // end
 			buildid = ldr.Data(fn)
 		} else {
 			// Relocations have variable length, handle them here.
 			relocs := ldr.Relocs(fn)
 			P := ldr.Data(fn)
 			off := int32(0)
 			for ri := 0; ri < relocs.Count(); ri++ {
 				r := relocs.At(ri)
 				if r.Siz() == 0 {
 					continue // skip marker relocations
 				}
 				wfn.Write(P[off:r.Off()])
 				off = r.Off()
 				rs := ldr.ResolveABIAlias(r.Sym())
 				switch r.Type() {
 				case objabi.R_ADDR:
 					writeSleb128(wfn, ldr.SymValue(rs)+r.Add())
 				case objabi.R_CALL:
 					writeSleb128(wfn, int64(len(hostImports))+ldr.SymValue(rs)>>16-funcValueOffset)
 				case objabi.R_WASMIMPORT:
 					writeSleb128(wfn, hostImportMap[rs])
 				default:
 					ldr.Errorf(fn, "bad reloc type %d (%s)", r.Type(), sym.RelocName(ctxt.Arch, r.Type()))
 					continue
 				}
 			}
 			wfn.Write(P[off:])
 		}

 		typ := uint32(0)
 		if sig, ok := wasmFuncTypes[ldr.SymName(fn)]; ok {
 			typ = lookupType(sig, &types)
 		}

 		name := nameRegexp.ReplaceAllString(ldr.SymName(fn), "_")
 		fns[i] = &wasmFunc{Name: name, Type: typ, Code: wfn.Bytes()}
 	}

 	ctxt.Out.Write([]byte{0x00, 0x61, 0x73, 0x6d}) // magic
 	ctxt.Out.Write([]byte{0x01, 0x00, 0x00, 0x00}) // version

 	// Add any buildid early in the binary:
 	if len(buildid) != 0 {
 		writeBuildID(ctxt, buildid)
 	}

 	writeTypeSec(ctxt, types)
 	writeImportSec(ctxt, hostImports)
 	writeFunctionSec(ctxt, fns)
 	writeTableSec(ctxt, fns)
 	writeMemorySec(ctxt, ldr)
 	writeGlobalSec(ctxt)
 	writeExportSec(ctxt, ldr, len(hostImports))
 	writeElementSec(ctxt, uint64(len(hostImports)), uint64(len(fns)))
 	writeCodeSec(ctxt, fns)
 	writeDataSec(ctxt)
 	writeProducerSec(ctxt)
 	if !*ld.FlagS {
 		writeNameSec(ctxt, len(hostImports), fns)
 	}
 }

 func lookupType(sig *wasmFuncType, types *[]*wasmFuncType) uint32 {
 	for i, t := range *types {
 		if bytes.Equal(sig.Params, t.Params) && bytes.Equal(sig.Results, t.Results) {
 			return uint32(i)
 		}
 	}
 	*types = append(*types, sig)
 	return uint32(len(*types) - 1)
 }

 func writeSecHeader(ctxt *ld.Link, id uint8) int64 {
 	ctxt.Out.WriteByte(id)
 	sizeOffset := ctxt.Out.Offset()
 	ctxt.Out.Write(make([]byte, 5)) // placeholder for length
 	return sizeOffset
 }

 func writeSecSize(ctxt *ld.Link, sizeOffset int64) {
 	endOffset := ctxt.Out.Offset()
 	ctxt.Out.SeekSet(sizeOffset)
 	writeUleb128FixedLength(ctxt.Out, uint64(endOffset-sizeOffset-5), 5)
 	ctxt.Out.SeekSet(endOffset)
 }

 func writeBuildID(ctxt *ld.Link, buildid []byte) {
 	sizeOffset := writeSecHeader(ctxt, sectionCustom)
 	writeName(ctxt.Out, "go.buildid")
 	ctxt.Out.Write(buildid)
 	writeSecSize(ctxt, sizeOffset)
 }

 // writeTypeSec writes the section that declares all function types
 // so they can be referenced by index.
 func writeTypeSec(ctxt *ld.Link, types []*wasmFuncType) {
 	sizeOffset := writeSecHeader(ctxt, sectionType)

 	writeUleb128(ctxt.Out, uint64(len(types)))

 	for _, t := range types {
 		ctxt.Out.WriteByte(0x60) // functype
 		writeUleb128(ctxt.Out, uint64(len(t.Params)))
 		for _, v := range t.Params {
 			ctxt.Out.WriteByte(byte(v))
 		}
 		writeUleb128(ctxt.Out, uint64(len(t.Results)))
 		for _, v := range t.Results {
 			ctxt.Out.WriteByte(byte(v))
 		}
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeImportSec writes the section that lists the functions that get
 // imported from the WebAssembly host, usually JavaScript.
 func writeImportSec(ctxt *ld.Link, hostImports []*wasmFunc) {
 	sizeOffset := writeSecHeader(ctxt, sectionImport)

 	writeUleb128(ctxt.Out, uint64(len(hostImports))) // number of imports
 	for _, fn := range hostImports {
 		writeName(ctxt.Out, "go") // provided by the import object in wasm_exec.js
 		writeName(ctxt.Out, fn.Name)
 		ctxt.Out.WriteByte(0x00) // func import
 		writeUleb128(ctxt.Out, uint64(fn.Type))
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeFunctionSec writes the section that declares the types of functions.
 // The bodies of these functions will later be provided in the "code" section.
 func writeFunctionSec(ctxt *ld.Link, fns []*wasmFunc) {
 	sizeOffset := writeSecHeader(ctxt, sectionFunction)

 	writeUleb128(ctxt.Out, uint64(len(fns)))
 	for _, fn := range fns {
 		writeUleb128(ctxt.Out, uint64(fn.Type))
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeTableSec writes the section that declares tables. Currently there is only a single table
 // that is used by the CallIndirect operation to dynamically call any function.
 // The contents of the table get initialized by the "element" section.
 func writeTableSec(ctxt *ld.Link, fns []*wasmFunc) {
 	sizeOffset := writeSecHeader(ctxt, sectionTable)

 	numElements := uint64(funcValueOffset + len(fns))
 	writeUleb128(ctxt.Out, 1)           // number of tables
 	ctxt.Out.WriteByte(0x70)            // type: anyfunc
 	ctxt.Out.WriteByte(0x00)            // no max
 	writeUleb128(ctxt.Out, numElements) // min

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeMemorySec writes the section that declares linear memories. Currently one linear memory is being used.
 // Linear memory always starts at address zero. More memory can be requested with the GrowMemory instruction.
 func writeMemorySec(ctxt *ld.Link, ldr *loader.Loader) {
 	sizeOffset := writeSecHeader(ctxt, sectionMemory)

 	dataSection := ldr.SymSect(ldr.Lookup("runtime.data", 0))
 	dataEnd := dataSection.Vaddr + dataSection.Length
 	var initialSize = dataEnd + 16<<20 // 16MB, enough for runtime init without growing

 	const wasmPageSize = 64 << 10 // 64KB

 	writeUleb128(ctxt.Out, 1)                        // number of memories
 	ctxt.Out.WriteByte(0x00)                         // no maximum memory size
 	writeUleb128(ctxt.Out, initialSize/wasmPageSize) // minimum (initial) memory size

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeGlobalSec writes the section that declares global variables.
 func writeGlobalSec(ctxt *ld.Link) {
 	sizeOffset := writeSecHeader(ctxt, sectionGlobal)

 	globalRegs := []byte{
 		I32, // 0: SP
 		I64, // 1: CTXT
 		I64, // 2: g
 		I64, // 3: RET0
 		I64, // 4: RET1
 		I64, // 5: RET2
 		I64, // 6: RET3
 		I32, // 7: PAUSE
 	}

 	writeUleb128(ctxt.Out, uint64(len(globalRegs))) // number of globals

 	for _, typ := range globalRegs {
 		ctxt.Out.WriteByte(typ)
 		ctxt.Out.WriteByte(0x01) // var
 		switch typ {
 		case I32:
 			writeI32Const(ctxt.Out, 0)
 		case I64:
 			writeI64Const(ctxt.Out, 0)
 		}
 		ctxt.Out.WriteByte(0x0b) // end
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeExportSec writes the section that declares exports.
 // Exports can be accessed by the WebAssembly host, usually JavaScript.
 // The wasm_export_* functions and the linear memory get exported.
 func writeExportSec(ctxt *ld.Link, ldr *loader.Loader, lenHostImports int) {
 	sizeOffset := writeSecHeader(ctxt, sectionExport)

 	writeUleb128(ctxt.Out, 4) // number of exports

 	for _, name := range []string{"run", "resume", "getsp"} {
 		s := ldr.Lookup("wasm_export_"+name, 0)
 		idx := uint32(lenHostImports) + uint32(ldr.SymValue(s)>>16) - funcValueOffset
 		writeName(ctxt.Out, name)           // inst.exports.run/resume/getsp in wasm_exec.js
 		ctxt.Out.WriteByte(0x00)            // func export
 		writeUleb128(ctxt.Out, uint64(idx)) // funcidx
 	}

 	writeName(ctxt.Out, "mem") // inst.exports.mem in wasm_exec.js
 	ctxt.Out.WriteByte(0x02)   // mem export
 	writeUleb128(ctxt.Out, 0)  // memidx

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeElementSec writes the section that initializes the tables declared by the "table" section.
 // The table for CallIndirect gets initialized in a very simple way so that each table index (PC_F value)
 // maps linearly to the function index (numImports + PC_F).
 func writeElementSec(ctxt *ld.Link, numImports, numFns uint64) {
 	sizeOffset := writeSecHeader(ctxt, sectionElement)

 	writeUleb128(ctxt.Out, 1) // number of element segments

 	writeUleb128(ctxt.Out, 0) // tableidx
 	writeI32Const(ctxt.Out, funcValueOffset)
 	ctxt.Out.WriteByte(0x0b) // end

 	writeUleb128(ctxt.Out, numFns) // number of entries
 	for i := uint64(0); i < numFns; i++ {
 		writeUleb128(ctxt.Out, numImports+i)
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeElementSec writes the section that provides the function bodies for the functions
 // declared by the "func" section.
 func writeCodeSec(ctxt *ld.Link, fns []*wasmFunc) {
 	sizeOffset := writeSecHeader(ctxt, sectionCode)

 	writeUleb128(ctxt.Out, uint64(len(fns))) // number of code entries
 	for _, fn := range fns {
 		writeUleb128(ctxt.Out, uint64(len(fn.Code)))
 		ctxt.Out.Write(fn.Code)
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeDataSec writes the section that provides data that will be used to initialize the linear memory.
 func writeDataSec(ctxt *ld.Link) {
 	sizeOffset := writeSecHeader(ctxt, sectionData)

 	type dataSegment struct {
 		offset int32
 		data   []byte
 	}

 	// Omit blocks of zeroes and instead emit data segments with offsets skipping the zeroes.
 	// This reduces the size of the WebAssembly binary. We use 8 bytes as an estimate for the
 	// overhead of adding a new segment (same as wasm-opt's memory-packing optimization uses).
 	const segmentOverhead = 8

 	// Generate at most this many segments. A higher number of segments gets rejected by some WebAssembly runtimes.
 	const maxNumSegments = 100000

 	var segments []*dataSegment
 	for secIndex, ds := range dataSects {
 		data := ds.data
 		offset := int32(ds.sect.Vaddr)

 		// skip leading zeroes
 		for len(data) > 0 && data[0] == 0 {
 			data = data[1:]
 			offset++
 		}

 		for len(data) > 0 {
 			dataLen := int32(len(data))
 			var segmentEnd, zeroEnd int32
 			if len(segments)+(len(dataSects)-secIndex) == maxNumSegments {
 				segmentEnd = dataLen
 				zeroEnd = dataLen
 			} else {
 				for {
 					// look for beginning of zeroes
 					for segmentEnd < dataLen && data[segmentEnd] != 0 {
 						segmentEnd++
 					}
 					// look for end of zeroes
 					zeroEnd = segmentEnd
 					for zeroEnd < dataLen && data[zeroEnd] == 0 {
 						zeroEnd++
 					}
 					// emit segment if omitting zeroes reduces the output size
 					if zeroEnd-segmentEnd >= segmentOverhead || zeroEnd == dataLen {
 						break
 					}
 					segmentEnd = zeroEnd
 				}
 			}

 			segments = append(segments, &dataSegment{
 				offset: offset,
 				data:   data[:segmentEnd],
 			})
 			data = data[zeroEnd:]
 			offset += zeroEnd
 		}
 	}

 	writeUleb128(ctxt.Out, uint64(len(segments))) // number of data entries
 	for _, seg := range segments {
 		writeUleb128(ctxt.Out, 0) // memidx
 		writeI32Const(ctxt.Out, seg.offset)
 		ctxt.Out.WriteByte(0x0b) // end
 		writeUleb128(ctxt.Out, uint64(len(seg.data)))
 		ctxt.Out.Write(seg.data)
 	}

 	writeSecSize(ctxt, sizeOffset)
 }

 // writeProducerSec writes an optional section that reports the source language and compiler version.
 func writeProducerSec(ctxt *ld.Link) {
 	sizeOffset := writeSecHeader(ctxt, sectionCustom)
 	writeName(ctxt.Out, "producers")

 	writeUleb128(ctxt.Out, 2) // number of fields

 	writeName(ctxt.Out, "language")     // field name
 	writeUleb128(ctxt.Out, 1)           // number of values
 	writeName(ctxt.Out, "Go")           // value: name
 	writeName(ctxt.Out, objabi.Version) // value: version

 	writeName(ctxt.Out, "processed-by")   // field name
 	writeUleb128(ctxt.Out, 1)             // number of values
 	writeName(ctxt.Out, "Go cmd/compile") // value: name
 	writeName(ctxt.Out, objabi.Version)   // value: version

 	writeSecSize(ctxt, sizeOffset)
 }

 var nameRegexp = regexp.MustCompile(`[^\w\.]`)

 // writeNameSec writes an optional section that assigns names to the functions declared by the "func" section.
 // The names are only used by WebAssembly stack traces, debuggers and decompilers.
 // TODO(neelance): add symbol table of DATA symbols
 func writeNameSec(ctxt *ld.Link, firstFnIndex int, fns []*wasmFunc) {
 	sizeOffset := writeSecHeader(ctxt, sectionCustom)
 	writeName(ctxt.Out, "name")

 	sizeOffset2 := writeSecHeader(ctxt, 0x01) // function names
 	writeUleb128(ctxt.Out, uint64(len(fns)))
 	for i, fn := range fns {
 		writeUleb128(ctxt.Out, uint64(firstFnIndex+i))
 		writeName(ctxt.Out, fn.Name)
 	}
 	writeSecSize(ctxt, sizeOffset2)

 	writeSecSize(ctxt, sizeOffset)
 }

 type nameWriter interface {
 	io.ByteWriter
 	io.Writer
 }

 func writeI32Const(w io.ByteWriter, v int32) {
 	w.WriteByte(0x41) // i32.const
 	writeSleb128(w, int64(v))
 }

 func writeI64Const(w io.ByteWriter, v int64) {
 	w.WriteByte(0x42) // i64.const
 	writeSleb128(w, v)
 }

 func writeName(w nameWriter, name string) {
 	writeUleb128(w, uint64(len(name)))
 	w.Write([]byte(name))
 }

 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 writeUleb128FixedLength(w io.ByteWriter, v uint64, length int) {
 	for i := 0; i < length; i++ {
 		c := uint8(v & 0x7f)
 		v >>= 7
 		if i < length-1 {
 			c |= 0x80
 		}
 		w.WriteByte(c)
 	}
 	if v != 0 {
 		panic("writeUleb128FixedLength: length too small")
 	}
 }

 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)
 	}
 }
	// 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/objabi"
	"cmd/link/internal/ld"
	"cmd/link/internal/loader"
	"cmd/link/internal/sym"
	"io"
	"regexp"
	)

	const (
	I32 = 0x7F
	I64 = 0x7E
	F32 = 0x7D
	F64 = 0x7C
	)

	const (
	sectionCustom = 0
	sectionType = 1
	sectionImport = 2
	sectionFunction = 3
	sectionTable = 4
	sectionMemory = 5
	sectionGlobal = 6
	sectionExport = 7
	sectionStart = 8
	sectionElement = 9
	sectionCode = 10
	sectionData = 11
	)

	// funcValueOffset is the offset between the PC_F value of a function and the index of the function in WebAssembly
	const funcValueOffset = 0x1000 // TODO(neelance): make function addresses play nice with heap addresses

	func gentext(ctxt ld.Link, ldr loader.Loader) {
	}

	type wasmFunc struct {
	Name string
	Type uint32
	Code []byte
	}

	type wasmFuncType struct {
	Params []byte
	Results []byte
	}

	var wasmFuncTypes = map[string]*wasmFuncType{
	"_rt0_wasm_js": {Params: []byte{}}, //
	"wasm_export_run": {Params: []byte{I32, I32}}, // argc, argv
	"wasm_export_resume": {Params: []byte{}}, //
	"wasm_export_getsp": {Results: []byte{I32}}, // sp
	"wasm_pc_f_loop": {Params: []byte{}}, //
	"runtime.wasmMove": {Params: []byte{I32, I32, I32}}, // dst, src, len
	"runtime.wasmZero": {Params: []byte{I32, I32}}, // ptr, len
	"runtime.wasmDiv": {Params: []byte{I64, I64}, Results: []byte{I64}}, // x, y -> x/y
	"runtime.wasmTruncS": {Params: []byte{F64}, Results: []byte{I64}}, // x -> int(x)
	"runtime.wasmTruncU": {Params: []byte{F64}, Results: []byte{I64}}, // x -> uint(x)
	"runtime.gcWriteBarrier": {Params: []byte{I64, I64}}, // ptr, val
	"cmpbody": {Params: []byte{I64, I64, I64, I64}, Results: []byte{I64}}, // a, alen, b, blen -> -1/0/1
	"memeqbody": {Params: []byte{I64, I64, I64}, Results: []byte{I64}}, // a, b, len -> 0/1
	"memcmp": {Params: []byte{I32, I32, I32}, Results: []byte{I32}}, // a, b, len -> <0/0/>0
	"memchr": {Params: []byte{I32, I32, I32}, Results: []byte{I32}}, // s, c, len -> index
	}

	func assignAddress(ldr loader.Loader, sect sym.Section, n int, s loader.Sym, va uint64, isTramp bool) (*sym.Section, int, uint64) {
	// WebAssembly functions do not live in the same address space as the linear memory.
	// Instead, WebAssembly automatically assigns indices. Imported functions (section "import")
	// have indices 0 to n. They are followed by native functions (sections "function" and "code")
	// with indices n+1 and following.
	//
	// The following rules describe how wasm handles function indices and addresses:
	// PC_F = funcValueOffset + WebAssembly function index (not including the imports)
	// s.Value = PC = PC_F<<16 + PC_B
	//
	// The funcValueOffset is necessary to avoid conflicts with expectations
	// that the Go runtime has about function addresses.
	// The field "s.Value" corresponds to the concept of PC at runtime.
	// However, there is no PC register, only PC_F and PC_B. PC_F denotes the function,
	// PC_B the resume point inside of that function. The entry of the function has PC_B = 0.
	ldr.SetSymSect(s, sect)
	ldr.SetSymValue(s, int64(funcValueOffset+va/ld.MINFUNC)<<16) // va starts at zero
	va += uint64(ld.MINFUNC)
	return sect, n, va
	}

	type wasmDataSect struct {
	sect *sym.Section
	data []byte
	}

	var dataSects []wasmDataSect

	func asmb(ctxt ld.Link, ldr loader.Loader) {
	sections := []*sym.Section{
	ldr.SymSect(ldr.Lookup("runtime.rodata", 0)),
	ldr.SymSect(ldr.Lookup("runtime.typelink", 0)),
	ldr.SymSect(ldr.Lookup("runtime.itablink", 0)),
	ldr.SymSect(ldr.Lookup("runtime.symtab", 0)),
	ldr.SymSect(ldr.Lookup("runtime.pclntab", 0)),
	ldr.SymSect(ldr.Lookup("runtime.noptrdata", 0)),
	ldr.SymSect(ldr.Lookup("runtime.data", 0)),
	}

	dataSects = make([]wasmDataSect, len(sections))
	for i, sect := range sections {
	data := ld.DatblkBytes(ctxt, int64(sect.Vaddr), int64(sect.Length))
	dataSects[i] = wasmDataSect{sect, data}
	}
	}

	// asmb writes the final WebAssembly module binary.
	// Spec: https://webassembly.github.io/spec/core/binary/modules.html
	func asmb2(ctxt ld.Link, ldr loader.Loader) {
	types := []*wasmFuncType{
	// For normal Go functions, the single parameter is PC_B,
	// the return value is
	// 0 if the function returned normally or
	// 1 if the stack needs to be unwound.
	{Params: []byte{I32}, Results: []byte{I32}},
	}

	// collect host imports (functions that get imported from the WebAssembly host, usually JavaScript)
	hostImports := []*wasmFunc{
	{
	Name: "debug",
	Type: lookupType(&wasmFuncType{Params: []byte{I32}}, &types),
	},
	}
	hostImportMap := make(map[loader.Sym]int64)
	for _, fn := range ctxt.Textp {
	relocs := ldr.Relocs(fn)
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	if r.Type() == objabi.R_WASMIMPORT {
	hostImportMap[r.Sym()] = int64(len(hostImports))
	hostImports = append(hostImports, &wasmFunc{
	Name: ldr.SymName(r.Sym()),
	Type: lookupType(&wasmFuncType{Params: []byte{I32}}, &types),
	})
	}
	}
	}

	// collect functions with WebAssembly body
	var buildid []byte
	fns := make([]*wasmFunc, len(ctxt.Textp))
	for i, fn := range ctxt.Textp {
	wfn := new(bytes.Buffer)
	if ldr.SymName(fn) == "go.buildid" {
	writeUleb128(wfn, 0) // number of sets of locals
	writeI32Const(wfn, 0)
	wfn.WriteByte(0x0b) // end
	buildid = ldr.Data(fn)
	} else {
	// Relocations have variable length, handle them here.
	relocs := ldr.Relocs(fn)
	P := ldr.Data(fn)
	off := int32(0)
	for ri := 0; ri < relocs.Count(); ri++ {
	r := relocs.At(ri)
	if r.Siz() == 0 {
	continue // skip marker relocations
	}
	wfn.Write(P[off:r.Off()])
	off = r.Off()
	rs := ldr.ResolveABIAlias(r.Sym())
	switch r.Type() {
	case objabi.R_ADDR:
	writeSleb128(wfn, ldr.SymValue(rs)+r.Add())
	case objabi.R_CALL:
	writeSleb128(wfn, int64(len(hostImports))+ldr.SymValue(rs)>>16-funcValueOffset)
	case objabi.R_WASMIMPORT:
	writeSleb128(wfn, hostImportMap[rs])
	default:
	ldr.Errorf(fn, "bad reloc type %d (%s)", r.Type(), sym.RelocName(ctxt.Arch, r.Type()))
	continue
	}
	}
	wfn.Write(P[off:])
	}

	typ := uint32(0)
	if sig, ok := wasmFuncTypes[ldr.SymName(fn)]; ok {
	typ = lookupType(sig, &types)
	}

	name := nameRegexp.ReplaceAllString(ldr.SymName(fn), "_")
	fns[i] = &wasmFunc{Name: name, Type: typ, Code: wfn.Bytes()}
	}

	ctxt.Out.Write([]byte{0x00, 0x61, 0x73, 0x6d}) // magic
	ctxt.Out.Write([]byte{0x01, 0x00, 0x00, 0x00}) // version

	// Add any buildid early in the binary:
	if len(buildid) != 0 {
	writeBuildID(ctxt, buildid)
	}

	writeTypeSec(ctxt, types)
	writeImportSec(ctxt, hostImports)
	writeFunctionSec(ctxt, fns)
	writeTableSec(ctxt, fns)
	writeMemorySec(ctxt, ldr)
	writeGlobalSec(ctxt)
	writeExportSec(ctxt, ldr, len(hostImports))
	writeElementSec(ctxt, uint64(len(hostImports)), uint64(len(fns)))
	writeCodeSec(ctxt, fns)
	writeDataSec(ctxt)
	writeProducerSec(ctxt)
	if !*ld.FlagS {
	writeNameSec(ctxt, len(hostImports), fns)
	}
	}

	func lookupType(sig wasmFuncType, types []*wasmFuncType) uint32 {
	for i, t := range *types {
	if bytes.Equal(sig.Params, t.Params) && bytes.Equal(sig.Results, t.Results) {
	return uint32(i)
	}
	}
	types = append(types, sig)
	return uint32(len(*types) - 1)
	}

	func writeSecHeader(ctxt *ld.Link, id uint8) int64 {
	ctxt.Out.WriteByte(id)
	sizeOffset := ctxt.Out.Offset()
	ctxt.Out.Write(make([]byte, 5)) // placeholder for length
	return sizeOffset
	}

	func writeSecSize(ctxt *ld.Link, sizeOffset int64) {
	endOffset := ctxt.Out.Offset()
	ctxt.Out.SeekSet(sizeOffset)
	writeUleb128FixedLength(ctxt.Out, uint64(endOffset-sizeOffset-5), 5)
	ctxt.Out.SeekSet(endOffset)
	}

	func writeBuildID(ctxt *ld.Link, buildid []byte) {
	sizeOffset := writeSecHeader(ctxt, sectionCustom)
	writeName(ctxt.Out, "go.buildid")
	ctxt.Out.Write(buildid)
	writeSecSize(ctxt, sizeOffset)
	}

	// writeTypeSec writes the section that declares all function types
	// so they can be referenced by index.
	func writeTypeSec(ctxt ld.Link, types []wasmFuncType) {
	sizeOffset := writeSecHeader(ctxt, sectionType)

	writeUleb128(ctxt.Out, uint64(len(types)))

	for _, t := range types {
	ctxt.Out.WriteByte(0x60) // functype
	writeUleb128(ctxt.Out, uint64(len(t.Params)))
	for _, v := range t.Params {
	ctxt.Out.WriteByte(byte(v))
	}
	writeUleb128(ctxt.Out, uint64(len(t.Results)))
	for _, v := range t.Results {
	ctxt.Out.WriteByte(byte(v))
	}
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeImportSec writes the section that lists the functions that get
	// imported from the WebAssembly host, usually JavaScript.
	func writeImportSec(ctxt ld.Link, hostImports []wasmFunc) {
	sizeOffset := writeSecHeader(ctxt, sectionImport)

	writeUleb128(ctxt.Out, uint64(len(hostImports))) // number of imports
	for _, fn := range hostImports {
	writeName(ctxt.Out, "go") // provided by the import object in wasm_exec.js
	writeName(ctxt.Out, fn.Name)
	ctxt.Out.WriteByte(0x00) // func import
	writeUleb128(ctxt.Out, uint64(fn.Type))
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeFunctionSec writes the section that declares the types of functions.
	// The bodies of these functions will later be provided in the "code" section.
	func writeFunctionSec(ctxt ld.Link, fns []wasmFunc) {
	sizeOffset := writeSecHeader(ctxt, sectionFunction)

	writeUleb128(ctxt.Out, uint64(len(fns)))
	for _, fn := range fns {
	writeUleb128(ctxt.Out, uint64(fn.Type))
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeTableSec writes the section that declares tables. Currently there is only a single table
	// that is used by the CallIndirect operation to dynamically call any function.
	// The contents of the table get initialized by the "element" section.
	func writeTableSec(ctxt ld.Link, fns []wasmFunc) {
	sizeOffset := writeSecHeader(ctxt, sectionTable)

	numElements := uint64(funcValueOffset + len(fns))
	writeUleb128(ctxt.Out, 1) // number of tables
	ctxt.Out.WriteByte(0x70) // type: anyfunc
	ctxt.Out.WriteByte(0x00) // no max
	writeUleb128(ctxt.Out, numElements) // min

	writeSecSize(ctxt, sizeOffset)
	}

	// writeMemorySec writes the section that declares linear memories. Currently one linear memory is being used.
	// Linear memory always starts at address zero. More memory can be requested with the GrowMemory instruction.
	func writeMemorySec(ctxt ld.Link, ldr loader.Loader) {
	sizeOffset := writeSecHeader(ctxt, sectionMemory)

	dataSection := ldr.SymSect(ldr.Lookup("runtime.data", 0))
	dataEnd := dataSection.Vaddr + dataSection.Length
	var initialSize = dataEnd + 16<<20 // 16MB, enough for runtime init without growing

	const wasmPageSize = 64 << 10 // 64KB

	writeUleb128(ctxt.Out, 1) // number of memories
	ctxt.Out.WriteByte(0x00) // no maximum memory size
	writeUleb128(ctxt.Out, initialSize/wasmPageSize) // minimum (initial) memory size

	writeSecSize(ctxt, sizeOffset)
	}

	// writeGlobalSec writes the section that declares global variables.
	func writeGlobalSec(ctxt *ld.Link) {
	sizeOffset := writeSecHeader(ctxt, sectionGlobal)

	globalRegs := []byte{
	I32, // 0: SP
	I64, // 1: CTXT
	I64, // 2: g
	I64, // 3: RET0
	I64, // 4: RET1
	I64, // 5: RET2
	I64, // 6: RET3
	I32, // 7: PAUSE
	}

	writeUleb128(ctxt.Out, uint64(len(globalRegs))) // number of globals

	for _, typ := range globalRegs {
	ctxt.Out.WriteByte(typ)
	ctxt.Out.WriteByte(0x01) // var
	switch typ {
	case I32:
	writeI32Const(ctxt.Out, 0)
	case I64:
	writeI64Const(ctxt.Out, 0)
	}
	ctxt.Out.WriteByte(0x0b) // end
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeExportSec writes the section that declares exports.
	// Exports can be accessed by the WebAssembly host, usually JavaScript.
	// The wasm_export_* functions and the linear memory get exported.
	func writeExportSec(ctxt ld.Link, ldr loader.Loader, lenHostImports int) {
	sizeOffset := writeSecHeader(ctxt, sectionExport)

	writeUleb128(ctxt.Out, 4) // number of exports

	for _, name := range []string{"run", "resume", "getsp"} {
	s := ldr.Lookup("wasm_export_"+name, 0)
	idx := uint32(lenHostImports) + uint32(ldr.SymValue(s)>>16) - funcValueOffset
	writeName(ctxt.Out, name) // inst.exports.run/resume/getsp in wasm_exec.js
	ctxt.Out.WriteByte(0x00) // func export
	writeUleb128(ctxt.Out, uint64(idx)) // funcidx
	}

	writeName(ctxt.Out, "mem") // inst.exports.mem in wasm_exec.js
	ctxt.Out.WriteByte(0x02) // mem export
	writeUleb128(ctxt.Out, 0) // memidx

	writeSecSize(ctxt, sizeOffset)
	}

	// writeElementSec writes the section that initializes the tables declared by the "table" section.
	// The table for CallIndirect gets initialized in a very simple way so that each table index (PC_F value)
	// maps linearly to the function index (numImports + PC_F).
	func writeElementSec(ctxt *ld.Link, numImports, numFns uint64) {
	sizeOffset := writeSecHeader(ctxt, sectionElement)

	writeUleb128(ctxt.Out, 1) // number of element segments

	writeUleb128(ctxt.Out, 0) // tableidx
	writeI32Const(ctxt.Out, funcValueOffset)
	ctxt.Out.WriteByte(0x0b) // end

	writeUleb128(ctxt.Out, numFns) // number of entries
	for i := uint64(0); i < numFns; i++ {
	writeUleb128(ctxt.Out, numImports+i)
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeElementSec writes the section that provides the function bodies for the functions
	// declared by the "func" section.
	func writeCodeSec(ctxt ld.Link, fns []wasmFunc) {
	sizeOffset := writeSecHeader(ctxt, sectionCode)

	writeUleb128(ctxt.Out, uint64(len(fns))) // number of code entries
	for _, fn := range fns {
	writeUleb128(ctxt.Out, uint64(len(fn.Code)))
	ctxt.Out.Write(fn.Code)
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeDataSec writes the section that provides data that will be used to initialize the linear memory.
	func writeDataSec(ctxt *ld.Link) {
	sizeOffset := writeSecHeader(ctxt, sectionData)

	type dataSegment struct {
	offset int32
	data []byte
	}

	// Omit blocks of zeroes and instead emit data segments with offsets skipping the zeroes.
	// This reduces the size of the WebAssembly binary. We use 8 bytes as an estimate for the
	// overhead of adding a new segment (same as wasm-opt's memory-packing optimization uses).
	const segmentOverhead = 8

	// Generate at most this many segments. A higher number of segments gets rejected by some WebAssembly runtimes.
	const maxNumSegments = 100000

	var segments []*dataSegment
	for secIndex, ds := range dataSects {
	data := ds.data
	offset := int32(ds.sect.Vaddr)

	// skip leading zeroes
	for len(data) > 0 && data[0] == 0 {
	data = data[1:]
	offset++
	}

	for len(data) > 0 {
	dataLen := int32(len(data))
	var segmentEnd, zeroEnd int32
	if len(segments)+(len(dataSects)-secIndex) == maxNumSegments {
	segmentEnd = dataLen
	zeroEnd = dataLen
	} else {
	for {
	// look for beginning of zeroes
	for segmentEnd < dataLen && data[segmentEnd] != 0 {
	segmentEnd++
	}
	// look for end of zeroes
	zeroEnd = segmentEnd
	for zeroEnd < dataLen && data[zeroEnd] == 0 {
	zeroEnd++
	}
	// emit segment if omitting zeroes reduces the output size
	if zeroEnd-segmentEnd >= segmentOverhead \|\| zeroEnd == dataLen {
	break
	}
	segmentEnd = zeroEnd
	}
	}

	segments = append(segments, &dataSegment{
	offset: offset,
	data: data[:segmentEnd],
	})
	data = data[zeroEnd:]
	offset += zeroEnd
	}
	}

	writeUleb128(ctxt.Out, uint64(len(segments))) // number of data entries
	for _, seg := range segments {
	writeUleb128(ctxt.Out, 0) // memidx
	writeI32Const(ctxt.Out, seg.offset)
	ctxt.Out.WriteByte(0x0b) // end
	writeUleb128(ctxt.Out, uint64(len(seg.data)))
	ctxt.Out.Write(seg.data)
	}

	writeSecSize(ctxt, sizeOffset)
	}

	// writeProducerSec writes an optional section that reports the source language and compiler version.
	func writeProducerSec(ctxt *ld.Link) {
	sizeOffset := writeSecHeader(ctxt, sectionCustom)
	writeName(ctxt.Out, "producers")

	writeUleb128(ctxt.Out, 2) // number of fields

	writeName(ctxt.Out, "language") // field name
	writeUleb128(ctxt.Out, 1) // number of values
	writeName(ctxt.Out, "Go") // value: name
	writeName(ctxt.Out, objabi.Version) // value: version

	writeName(ctxt.Out, "processed-by") // field name
	writeUleb128(ctxt.Out, 1) // number of values
	writeName(ctxt.Out, "Go cmd/compile") // value: name
	writeName(ctxt.Out, objabi.Version) // value: version

	writeSecSize(ctxt, sizeOffset)
	}

	var nameRegexp = regexp.MustCompile(`[^\w\.]`)

	// writeNameSec writes an optional section that assigns names to the functions declared by the "func" section.
	// The names are only used by WebAssembly stack traces, debuggers and decompilers.
	// TODO(neelance): add symbol table of DATA symbols
	func writeNameSec(ctxt ld.Link, firstFnIndex int, fns []wasmFunc) {
	sizeOffset := writeSecHeader(ctxt, sectionCustom)
	writeName(ctxt.Out, "name")

	sizeOffset2 := writeSecHeader(ctxt, 0x01) // function names
	writeUleb128(ctxt.Out, uint64(len(fns)))
	for i, fn := range fns {
	writeUleb128(ctxt.Out, uint64(firstFnIndex+i))
	writeName(ctxt.Out, fn.Name)
	}
	writeSecSize(ctxt, sizeOffset2)

	writeSecSize(ctxt, sizeOffset)
	}

	type nameWriter interface {
	io.ByteWriter
	io.Writer
	}

	func writeI32Const(w io.ByteWriter, v int32) {
	w.WriteByte(0x41) // i32.const
	writeSleb128(w, int64(v))
	}

	func writeI64Const(w io.ByteWriter, v int64) {
	w.WriteByte(0x42) // i64.const
	writeSleb128(w, v)
	}

	func writeName(w nameWriter, name string) {
	writeUleb128(w, uint64(len(name)))
	w.Write([]byte(name))
	}

	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 writeUleb128FixedLength(w io.ByteWriter, v uint64, length int) {
	for i := 0; i < length; i++ {
	c := uint8(v & 0x7f)
	v >>= 7
	if i < length-1 {
	c \|= 0x80
	}
	w.WriteByte(c)
	}
	if v != 0 {
	panic("writeUleb128FixedLength: length too small")
	}
	}

	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)
	}
	}