src/cmd/compile/internal/ssagen/abi.go - toolchain/go - Git at Google

 // Copyright 2009 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package ssagen

 import (
 	"fmt"
 	"internal/buildcfg"
 	"log"
 	"os"
 	"strings"

 	"cmd/compile/internal/abi"
 	"cmd/compile/internal/base"
 	"cmd/compile/internal/ir"
 	"cmd/compile/internal/objw"
 	"cmd/compile/internal/typecheck"
 	"cmd/compile/internal/types"
 	"cmd/internal/obj"
 	"cmd/internal/obj/wasm"
 )

 // SymABIs records information provided by the assembler about symbol
 // definition ABIs and reference ABIs.
 type SymABIs struct {
 	defs map[string]obj.ABI
 	refs map[string]obj.ABISet
 }

 func NewSymABIs() *SymABIs {
 	return &SymABIs{
 		defs: make(map[string]obj.ABI),
 		refs: make(map[string]obj.ABISet),
 	}
 }

 // canonicalize returns the canonical name used for a linker symbol in
 // s's maps. Symbols in this package may be written either as "".X or
 // with the package's import path already in the symbol. This rewrites
 // both to use the full path, which matches compiler-generated linker
 // symbol names.
 func (s *SymABIs) canonicalize(linksym string) string {
 	// If the symbol is already prefixed with "", rewrite it to start
 	// with LocalPkg.Prefix.
 	//
 	// TODO(mdempsky): Have cmd/asm stop writing out symbols like this.
 	if strings.HasPrefix(linksym, `"".`) {
 		return types.LocalPkg.Prefix + linksym[2:]
 	}
 	return linksym
 }

 // ReadSymABIs reads a symabis file that specifies definitions and
 // references of text symbols by ABI.
 //
 // The symabis format is a set of lines, where each line is a sequence
 // of whitespace-separated fields. The first field is a verb and is
 // either "def" for defining a symbol ABI or "ref" for referencing a
 // symbol using an ABI. For both "def" and "ref", the second field is
 // the symbol name and the third field is the ABI name, as one of the
 // named cmd/internal/obj.ABI constants.
 func (s *SymABIs) ReadSymABIs(file string) {
 	data, err := os.ReadFile(file)
 	if err != nil {
 		log.Fatalf("-symabis: %v", err)
 	}

 	for lineNum, line := range strings.Split(string(data), "\n") {
 		lineNum++ // 1-based
 		line = strings.TrimSpace(line)
 		if line == "" || strings.HasPrefix(line, "#") {
 			continue
 		}

 		parts := strings.Fields(line)
 		switch parts[0] {
 		case "def", "ref":
 			// Parse line.
 			if len(parts) != 3 {
 				log.Fatalf(`%s:%d: invalid symabi: syntax is "%s sym abi"`, file, lineNum, parts[0])
 			}
 			sym, abistr := parts[1], parts[2]
 			abi, valid := obj.ParseABI(abistr)
 			if !valid {
 				log.Fatalf(`%s:%d: invalid symabi: unknown abi "%s"`, file, lineNum, abistr)
 			}

 			sym = s.canonicalize(sym)

 			// Record for later.
 			if parts[0] == "def" {
 				s.defs[sym] = abi
 			} else {
 				s.refs[sym] |= obj.ABISetOf(abi)
 			}
 		default:
 			log.Fatalf(`%s:%d: invalid symabi type "%s"`, file, lineNum, parts[0])
 		}
 	}
 }

 // GenABIWrappers applies ABI information to Funcs and generates ABI
 // wrapper functions where necessary.
 func (s *SymABIs) GenABIWrappers() {
 	// For cgo exported symbols, we tell the linker to export the
 	// definition ABI to C. That also means that we don't want to
 	// create ABI wrappers even if there's a linkname.
 	//
 	// TODO(austin): Maybe we want to create the ABI wrappers, but
 	// ensure the linker exports the right ABI definition under
 	// the unmangled name?
 	cgoExports := make(map[string][]*[]string)
 	for i, prag := range typecheck.Target.CgoPragmas {
 		switch prag[0] {
 		case "cgo_export_static", "cgo_export_dynamic":
 			symName := s.canonicalize(prag[1])
 			pprag := &typecheck.Target.CgoPragmas[i]
 			cgoExports[symName] = append(cgoExports[symName], pprag)
 		}
 	}

 	// Apply ABI defs and refs to Funcs and generate wrappers.
 	//
 	// This may generate new decls for the wrappers, but we
 	// specifically *don't* want to visit those, lest we create
 	// wrappers for wrappers.
 	for _, fn := range typecheck.Target.Decls {
 		if fn.Op() != ir.ODCLFUNC {
 			continue
 		}
 		fn := fn.(*ir.Func)
 		nam := fn.Nname
 		if ir.IsBlank(nam) {
 			continue
 		}
 		sym := nam.Sym()

 		symName := sym.Linkname
 		if symName == "" {
 			symName = sym.Pkg.Prefix + "." + sym.Name
 		}
 		symName = s.canonicalize(symName)

 		// Apply definitions.
 		defABI, hasDefABI := s.defs[symName]
 		if hasDefABI {
 			if len(fn.Body) != 0 {
 				base.ErrorfAt(fn.Pos(), 0, "%v defined in both Go and assembly", fn)
 			}
 			fn.ABI = defABI
 		}

 		if fn.Pragma&ir.CgoUnsafeArgs != 0 {
 			// CgoUnsafeArgs indicates the function (or its callee) uses
 			// offsets to dispatch arguments, which currently using ABI0
 			// frame layout. Pin it to ABI0.
 			fn.ABI = obj.ABI0
 		}

 		// If cgo-exported, add the definition ABI to the cgo
 		// pragmas.
 		cgoExport := cgoExports[symName]
 		for _, pprag := range cgoExport {
 			// The export pragmas have the form:
 			//
 			//   cgo_export_* <local> [<remote>]
 			//
 			// If <remote> is omitted, it's the same as
 			// <local>.
 			//
 			// Expand to
 			//
 			//   cgo_export_* <local> <remote> <ABI>
 			if len(*pprag) == 2 {
 				*pprag = append(*pprag, (*pprag)[1])
 			}
 			// Add the ABI argument.
 			*pprag = append(*pprag, fn.ABI.String())
 		}

 		// Apply references.
 		if abis, ok := s.refs[symName]; ok {
 			fn.ABIRefs |= abis
 		}
 		// Assume all functions are referenced at least as
 		// ABIInternal, since they may be referenced from
 		// other packages.
 		fn.ABIRefs.Set(obj.ABIInternal, true)

 		// If a symbol is defined in this package (either in
 		// Go or assembly) and given a linkname, it may be
 		// referenced from another package, so make it
 		// callable via any ABI. It's important that we know
 		// it's defined in this package since other packages
 		// may "pull" symbols using linkname and we don't want
 		// to create duplicate ABI wrappers.
 		//
 		// However, if it's given a linkname for exporting to
 		// C, then we don't make ABI wrappers because the cgo
 		// tool wants the original definition.
 		hasBody := len(fn.Body) != 0
 		if sym.Linkname != "" && (hasBody || hasDefABI) && len(cgoExport) == 0 {
 			fn.ABIRefs |= obj.ABISetCallable
 		}

 		// Double check that cgo-exported symbols don't get
 		// any wrappers.
 		if len(cgoExport) > 0 && fn.ABIRefs&^obj.ABISetOf(fn.ABI) != 0 {
 			base.Fatalf("cgo exported function %v cannot have ABI wrappers", fn)
 		}

 		if !buildcfg.Experiment.RegabiWrappers {
 			continue
 		}

 		forEachWrapperABI(fn, makeABIWrapper)
 	}
 }

 func forEachWrapperABI(fn *ir.Func, cb func(fn *ir.Func, wrapperABI obj.ABI)) {
 	need := fn.ABIRefs &^ obj.ABISetOf(fn.ABI)
 	if need == 0 {
 		return
 	}

 	for wrapperABI := obj.ABI(0); wrapperABI < obj.ABICount; wrapperABI++ {
 		if !need.Get(wrapperABI) {
 			continue
 		}
 		cb(fn, wrapperABI)
 	}
 }

 // makeABIWrapper creates a new function that will be called with
 // wrapperABI and calls "f" using f.ABI.
 func makeABIWrapper(f *ir.Func, wrapperABI obj.ABI) {
 	if base.Debug.ABIWrap != 0 {
 		fmt.Fprintf(os.Stderr, "=-= %v to %v wrapper for %v\n", wrapperABI, f.ABI, f)
 	}

 	// Q: is this needed?
 	savepos := base.Pos
 	savedclcontext := typecheck.DeclContext
 	savedcurfn := ir.CurFunc

 	base.Pos = base.AutogeneratedPos
 	typecheck.DeclContext = ir.PEXTERN

 	// At the moment we don't support wrapping a method, we'd need machinery
 	// below to handle the receiver. Panic if we see this scenario.
 	ft := f.Nname.Type()
 	if ft.NumRecvs() != 0 {
 		base.ErrorfAt(f.Pos(), 0, "makeABIWrapper support for wrapping methods not implemented")
 		return
 	}

 	// Reuse f's types.Sym to create a new ODCLFUNC/function.
 	fn := typecheck.DeclFunc(f.Nname.Sym(), nil,
 		typecheck.NewFuncParams(ft.Params(), true),
 		typecheck.NewFuncParams(ft.Results(), false))
 	fn.ABI = wrapperABI

 	fn.SetABIWrapper(true)
 	fn.SetDupok(true)

 	// ABI0-to-ABIInternal wrappers will be mainly loading params from
 	// stack into registers (and/or storing stack locations back to
 	// registers after the wrapped call); in most cases they won't
 	// need to allocate stack space, so it should be OK to mark them
 	// as NOSPLIT in these cases. In addition, my assumption is that
 	// functions written in assembly are NOSPLIT in most (but not all)
 	// cases. In the case of an ABIInternal target that has too many
 	// parameters to fit into registers, the wrapper would need to
 	// allocate stack space, but this seems like an unlikely scenario.
 	// Hence: mark these wrappers NOSPLIT.
 	//
 	// ABIInternal-to-ABI0 wrappers on the other hand will be taking
 	// things in registers and pushing them onto the stack prior to
 	// the ABI0 call, meaning that they will always need to allocate
 	// stack space. If the compiler marks them as NOSPLIT this seems
 	// as though it could lead to situations where the linker's
 	// nosplit-overflow analysis would trigger a link failure. On the
 	// other hand if they not tagged NOSPLIT then this could cause
 	// problems when building the runtime (since there may be calls to
 	// asm routine in cases where it's not safe to grow the stack). In
 	// most cases the wrapper would be (in effect) inlined, but are
 	// there (perhaps) indirect calls from the runtime that could run
 	// into trouble here.
 	// FIXME: at the moment all.bash does not pass when I leave out
 	// NOSPLIT for these wrappers, so all are currently tagged with NOSPLIT.
 	fn.Pragma |= ir.Nosplit

 	// Generate call. Use tail call if no params and no returns,
 	// but a regular call otherwise.
 	//
 	// Note: ideally we would be using a tail call in cases where
 	// there are params but no returns for ABI0->ABIInternal wrappers,
 	// provided that all params fit into registers (e.g. we don't have
 	// to allocate any stack space). Doing this will require some
 	// extra work in typecheck/walk/ssa, might want to add a new node
 	// OTAILCALL or something to this effect.
 	tailcall := fn.Type().NumResults() == 0 && fn.Type().NumParams() == 0 && fn.Type().NumRecvs() == 0
 	if base.Ctxt.Arch.Name == "ppc64le" && base.Ctxt.Flag_dynlink {
 		// cannot tailcall on PPC64 with dynamic linking, as we need
 		// to restore R2 after call.
 		tailcall = false
 	}
 	if base.Ctxt.Arch.Name == "amd64" && wrapperABI == obj.ABIInternal {
 		// cannot tailcall from ABIInternal to ABI0 on AMD64, as we need
 		// to special registers (X15) when returning to ABIInternal.
 		tailcall = false
 	}

 	var tail ir.Node
 	call := ir.NewCallExpr(base.Pos, ir.OCALL, f.Nname, nil)
 	call.Args = ir.ParamNames(fn.Type())
 	call.IsDDD = fn.Type().IsVariadic()
 	tail = call
 	if tailcall {
 		tail = ir.NewTailCallStmt(base.Pos, call)
 	} else if fn.Type().NumResults() > 0 {
 		n := ir.NewReturnStmt(base.Pos, nil)
 		n.Results = []ir.Node{call}
 		tail = n
 	}
 	fn.Body.Append(tail)

 	typecheck.FinishFuncBody()

 	typecheck.Func(fn)
 	ir.CurFunc = fn
 	typecheck.Stmts(fn.Body)

 	typecheck.Target.Decls = append(typecheck.Target.Decls, fn)

 	// Restore previous context.
 	base.Pos = savepos
 	typecheck.DeclContext = savedclcontext
 	ir.CurFunc = savedcurfn
 }

 // CreateWasmImportWrapper creates a wrapper for imported WASM functions to
 // adapt them to the Go calling convention. The body for this function is
 // generated in cmd/internal/obj/wasm/wasmobj.go
 func CreateWasmImportWrapper(fn *ir.Func) bool {
 	if fn.WasmImport == nil {
 		return false
 	}
 	if buildcfg.GOARCH != "wasm" {
 		base.FatalfAt(fn.Pos(), "CreateWasmImportWrapper call not supported on %s: func was %v", buildcfg.GOARCH, fn)
 	}

 	ir.InitLSym(fn, true)

 	setupWasmABI(fn)

 	pp := objw.NewProgs(fn, 0)
 	defer pp.Free()
 	pp.Text.To.Type = obj.TYPE_TEXTSIZE
 	pp.Text.To.Val = int32(types.RoundUp(fn.Type().ArgWidth(), int64(types.RegSize)))
 	// Wrapper functions never need their own stack frame
 	pp.Text.To.Offset = 0
 	pp.Flush()

 	return true
 }

 func paramsToWasmFields(f *ir.Func, result *abi.ABIParamResultInfo, abiParams []abi.ABIParamAssignment) []obj.WasmField {
 	wfs := make([]obj.WasmField, len(abiParams))
 	for i, p := range abiParams {
 		t := p.Type
 		switch t.Kind() {
 		case types.TINT32, types.TUINT32:
 			wfs[i].Type = obj.WasmI32
 		case types.TINT64, types.TUINT64:
 			wfs[i].Type = obj.WasmI64
 		case types.TFLOAT32:
 			wfs[i].Type = obj.WasmF32
 		case types.TFLOAT64:
 			wfs[i].Type = obj.WasmF64
 		case types.TUNSAFEPTR:
 			wfs[i].Type = obj.WasmPtr
 		default:
 			base.ErrorfAt(f.Pos(), 0, "go:wasmimport %s %s: unsupported parameter type %s", f.WasmImport.Module, f.WasmImport.Name, t.String())
 		}
 		wfs[i].Offset = p.FrameOffset(result)
 	}
 	return wfs
 }

 func resultsToWasmFields(f *ir.Func, result *abi.ABIParamResultInfo, abiParams []abi.ABIParamAssignment) []obj.WasmField {
 	if len(abiParams) > 1 {
 		base.ErrorfAt(f.Pos(), 0, "go:wasmimport %s %s: too many return values", f.WasmImport.Module, f.WasmImport.Name)
 		return nil
 	}
 	wfs := make([]obj.WasmField, len(abiParams))
 	for i, p := range abiParams {
 		t := p.Type
 		switch t.Kind() {
 		case types.TINT32, types.TUINT32:
 			wfs[i].Type = obj.WasmI32
 		case types.TINT64, types.TUINT64:
 			wfs[i].Type = obj.WasmI64
 		case types.TFLOAT32:
 			wfs[i].Type = obj.WasmF32
 		case types.TFLOAT64:
 			wfs[i].Type = obj.WasmF64
 		default:
 			base.ErrorfAt(f.Pos(), 0, "go:wasmimport %s %s: unsupported result type %s", f.WasmImport.Module, f.WasmImport.Name, t.String())
 		}
 		wfs[i].Offset = p.FrameOffset(result)
 	}
 	return wfs
 }

 // setupTextLSym initializes the LSym for a with-body text symbol.
 func setupWasmABI(f *ir.Func) {
 	wi := obj.WasmImport{
 		Module: f.WasmImport.Module,
 		Name:   f.WasmImport.Name,
 	}
 	if wi.Module == wasm.GojsModule {
 		// Functions that are imported from the "gojs" module use a special
 		// ABI that just accepts the stack pointer.
 		// Example:
 		//
 		// 	//go:wasmimport gojs add
 		// 	func importedAdd(a, b uint) uint
 		//
 		// will roughly become
 		//
 		// 	(import "gojs" "add" (func (param i32)))
 		wi.Params = []obj.WasmField{{Type: obj.WasmI32}}
 	} else {
 		// All other imported functions use the normal WASM ABI.
 		// Example:
 		//
 		// 	//go:wasmimport a_module add
 		// 	func importedAdd(a, b uint) uint
 		//
 		// will roughly become
 		//
 		// 	(import "a_module" "add" (func (param i32 i32) (result i32)))
 		abiConfig := AbiForBodylessFuncStackMap(f)
 		abiInfo := abiConfig.ABIAnalyzeFuncType(f.Type().FuncType())
 		wi.Params = paramsToWasmFields(f, abiInfo, abiInfo.InParams())
 		wi.Results = resultsToWasmFields(f, abiInfo, abiInfo.OutParams())
 	}
 	f.LSym.Func().WasmImport = &wi
 }
	// Copyright 2009 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package ssagen

	import (
	"fmt"
	"internal/buildcfg"
	"log"
	"os"
	"strings"

	"cmd/compile/internal/abi"
	"cmd/compile/internal/base"
	"cmd/compile/internal/ir"
	"cmd/compile/internal/objw"
	"cmd/compile/internal/typecheck"
	"cmd/compile/internal/types"
	"cmd/internal/obj"
	"cmd/internal/obj/wasm"
	)

	// SymABIs records information provided by the assembler about symbol
	// definition ABIs and reference ABIs.
	type SymABIs struct {
	defs map[string]obj.ABI
	refs map[string]obj.ABISet
	}

	func NewSymABIs() *SymABIs {
	return &SymABIs{
	defs: make(map[string]obj.ABI),
	refs: make(map[string]obj.ABISet),
	}
	}

	// canonicalize returns the canonical name used for a linker symbol in
	// s's maps. Symbols in this package may be written either as "".X or
	// with the package's import path already in the symbol. This rewrites
	// both to use the full path, which matches compiler-generated linker
	// symbol names.
	func (s *SymABIs) canonicalize(linksym string) string {
	// If the symbol is already prefixed with "", rewrite it to start
	// with LocalPkg.Prefix.
	//
	// TODO(mdempsky): Have cmd/asm stop writing out symbols like this.
	if strings.HasPrefix(linksym, `"".`) {
	return types.LocalPkg.Prefix + linksym[2:]
	}
	return linksym
	}

	// ReadSymABIs reads a symabis file that specifies definitions and
	// references of text symbols by ABI.
	//
	// The symabis format is a set of lines, where each line is a sequence
	// of whitespace-separated fields. The first field is a verb and is
	// either "def" for defining a symbol ABI or "ref" for referencing a
	// symbol using an ABI. For both "def" and "ref", the second field is
	// the symbol name and the third field is the ABI name, as one of the
	// named cmd/internal/obj.ABI constants.
	func (s *SymABIs) ReadSymABIs(file string) {
	data, err := os.ReadFile(file)
	if err != nil {
	log.Fatalf("-symabis: %v", err)
	}

	for lineNum, line := range strings.Split(string(data), "\n") {
	lineNum++ // 1-based
	line = strings.TrimSpace(line)
	if line == "" \|\| strings.HasPrefix(line, "#") {
	continue
	}

	parts := strings.Fields(line)
	switch parts[0] {
	case "def", "ref":
	// Parse line.
	if len(parts) != 3 {
	log.Fatalf(`%s:%d: invalid symabi: syntax is "%s sym abi"`, file, lineNum, parts[0])
	}
	sym, abistr := parts[1], parts[2]
	abi, valid := obj.ParseABI(abistr)
	if !valid {
	log.Fatalf(`%s:%d: invalid symabi: unknown abi "%s"`, file, lineNum, abistr)
	}

	sym = s.canonicalize(sym)

	// Record for later.
	if parts[0] == "def" {
	s.defs[sym] = abi
	} else {
	s.refs[sym] \|= obj.ABISetOf(abi)
	}
	default:
	log.Fatalf(`%s:%d: invalid symabi type "%s"`, file, lineNum, parts[0])
	}
	}
	}

	// GenABIWrappers applies ABI information to Funcs and generates ABI
	// wrapper functions where necessary.
	func (s *SymABIs) GenABIWrappers() {
	// For cgo exported symbols, we tell the linker to export the
	// definition ABI to C. That also means that we don't want to
	// create ABI wrappers even if there's a linkname.
	//
	// TODO(austin): Maybe we want to create the ABI wrappers, but
	// ensure the linker exports the right ABI definition under
	// the unmangled name?
	cgoExports := make(map[string][]*[]string)
	for i, prag := range typecheck.Target.CgoPragmas {
	switch prag[0] {
	case "cgo_export_static", "cgo_export_dynamic":
	symName := s.canonicalize(prag[1])
	pprag := &typecheck.Target.CgoPragmas[i]
	cgoExports[symName] = append(cgoExports[symName], pprag)
	}
	}

	// Apply ABI defs and refs to Funcs and generate wrappers.
	//
	// This may generate new decls for the wrappers, but we
	// specifically don't want to visit those, lest we create
	// wrappers for wrappers.
	for _, fn := range typecheck.Target.Decls {
	if fn.Op() != ir.ODCLFUNC {
	continue
	}
	fn := fn.(*ir.Func)
	nam := fn.Nname
	if ir.IsBlank(nam) {
	continue
	}
	sym := nam.Sym()

	symName := sym.Linkname
	if symName == "" {
	symName = sym.Pkg.Prefix + "." + sym.Name
	}
	symName = s.canonicalize(symName)

	// Apply definitions.
	defABI, hasDefABI := s.defs[symName]
	if hasDefABI {
	if len(fn.Body) != 0 {
	base.ErrorfAt(fn.Pos(), 0, "%v defined in both Go and assembly", fn)
	}
	fn.ABI = defABI
	}

	if fn.Pragma&ir.CgoUnsafeArgs != 0 {
	// CgoUnsafeArgs indicates the function (or its callee) uses
	// offsets to dispatch arguments, which currently using ABI0
	// frame layout. Pin it to ABI0.
	fn.ABI = obj.ABI0
	}

	// If cgo-exported, add the definition ABI to the cgo
	// pragmas.
	cgoExport := cgoExports[symName]
	for _, pprag := range cgoExport {
	// The export pragmas have the form:
	//
	// cgo_export_* <local> [<remote>]
	//
	// If <remote> is omitted, it's the same as
	// <local>.
	//
	// Expand to
	//
	// cgo_export_* <local> <remote> <ABI>
	if len(*pprag) == 2 {
	pprag = append(pprag, (*pprag)[1])
	}
	// Add the ABI argument.
	pprag = append(pprag, fn.ABI.String())
	}

	// Apply references.
	if abis, ok := s.refs[symName]; ok {
	fn.ABIRefs \|= abis
	}
	// Assume all functions are referenced at least as
	// ABIInternal, since they may be referenced from
	// other packages.
	fn.ABIRefs.Set(obj.ABIInternal, true)

	// If a symbol is defined in this package (either in
	// Go or assembly) and given a linkname, it may be
	// referenced from another package, so make it
	// callable via any ABI. It's important that we know
	// it's defined in this package since other packages
	// may "pull" symbols using linkname and we don't want
	// to create duplicate ABI wrappers.
	//
	// However, if it's given a linkname for exporting to
	// C, then we don't make ABI wrappers because the cgo
	// tool wants the original definition.
	hasBody := len(fn.Body) != 0
	if sym.Linkname != "" && (hasBody \|\| hasDefABI) && len(cgoExport) == 0 {
	fn.ABIRefs \|= obj.ABISetCallable
	}

	// Double check that cgo-exported symbols don't get
	// any wrappers.
	if len(cgoExport) > 0 && fn.ABIRefs&^obj.ABISetOf(fn.ABI) != 0 {
	base.Fatalf("cgo exported function %v cannot have ABI wrappers", fn)
	}

	if !buildcfg.Experiment.RegabiWrappers {
	continue
	}

	forEachWrapperABI(fn, makeABIWrapper)
	}
	}

	func forEachWrapperABI(fn ir.Func, cb func(fn ir.Func, wrapperABI obj.ABI)) {
	need := fn.ABIRefs &^ obj.ABISetOf(fn.ABI)
	if need == 0 {
	return
	}

	for wrapperABI := obj.ABI(0); wrapperABI < obj.ABICount; wrapperABI++ {
	if !need.Get(wrapperABI) {
	continue
	}
	cb(fn, wrapperABI)
	}
	}

	// makeABIWrapper creates a new function that will be called with
	// wrapperABI and calls "f" using f.ABI.
	func makeABIWrapper(f *ir.Func, wrapperABI obj.ABI) {
	if base.Debug.ABIWrap != 0 {
	fmt.Fprintf(os.Stderr, "=-= %v to %v wrapper for %v\n", wrapperABI, f.ABI, f)
	}

	// Q: is this needed?
	savepos := base.Pos
	savedclcontext := typecheck.DeclContext
	savedcurfn := ir.CurFunc

	base.Pos = base.AutogeneratedPos
	typecheck.DeclContext = ir.PEXTERN

	// At the moment we don't support wrapping a method, we'd need machinery
	// below to handle the receiver. Panic if we see this scenario.
	ft := f.Nname.Type()
	if ft.NumRecvs() != 0 {
	base.ErrorfAt(f.Pos(), 0, "makeABIWrapper support for wrapping methods not implemented")
	return
	}

	// Reuse f's types.Sym to create a new ODCLFUNC/function.
	fn := typecheck.DeclFunc(f.Nname.Sym(), nil,
	typecheck.NewFuncParams(ft.Params(), true),
	typecheck.NewFuncParams(ft.Results(), false))
	fn.ABI = wrapperABI

	fn.SetABIWrapper(true)
	fn.SetDupok(true)

	// ABI0-to-ABIInternal wrappers will be mainly loading params from
	// stack into registers (and/or storing stack locations back to
	// registers after the wrapped call); in most cases they won't
	// need to allocate stack space, so it should be OK to mark them
	// as NOSPLIT in these cases. In addition, my assumption is that
	// functions written in assembly are NOSPLIT in most (but not all)
	// cases. In the case of an ABIInternal target that has too many
	// parameters to fit into registers, the wrapper would need to
	// allocate stack space, but this seems like an unlikely scenario.
	// Hence: mark these wrappers NOSPLIT.
	//
	// ABIInternal-to-ABI0 wrappers on the other hand will be taking
	// things in registers and pushing them onto the stack prior to
	// the ABI0 call, meaning that they will always need to allocate
	// stack space. If the compiler marks them as NOSPLIT this seems
	// as though it could lead to situations where the linker's
	// nosplit-overflow analysis would trigger a link failure. On the
	// other hand if they not tagged NOSPLIT then this could cause
	// problems when building the runtime (since there may be calls to
	// asm routine in cases where it's not safe to grow the stack). In
	// most cases the wrapper would be (in effect) inlined, but are
	// there (perhaps) indirect calls from the runtime that could run
	// into trouble here.
	// FIXME: at the moment all.bash does not pass when I leave out
	// NOSPLIT for these wrappers, so all are currently tagged with NOSPLIT.
	fn.Pragma \|= ir.Nosplit

	// Generate call. Use tail call if no params and no returns,
	// but a regular call otherwise.
	//
	// Note: ideally we would be using a tail call in cases where
	// there are params but no returns for ABI0->ABIInternal wrappers,
	// provided that all params fit into registers (e.g. we don't have
	// to allocate any stack space). Doing this will require some
	// extra work in typecheck/walk/ssa, might want to add a new node
	// OTAILCALL or something to this effect.
	tailcall := fn.Type().NumResults() == 0 && fn.Type().NumParams() == 0 && fn.Type().NumRecvs() == 0
	if base.Ctxt.Arch.Name == "ppc64le" && base.Ctxt.Flag_dynlink {
	// cannot tailcall on PPC64 with dynamic linking, as we need
	// to restore R2 after call.
	tailcall = false
	}
	if base.Ctxt.Arch.Name == "amd64" && wrapperABI == obj.ABIInternal {
	// cannot tailcall from ABIInternal to ABI0 on AMD64, as we need
	// to special registers (X15) when returning to ABIInternal.
	tailcall = false
	}

	var tail ir.Node
	call := ir.NewCallExpr(base.Pos, ir.OCALL, f.Nname, nil)
	call.Args = ir.ParamNames(fn.Type())
	call.IsDDD = fn.Type().IsVariadic()
	tail = call
	if tailcall {
	tail = ir.NewTailCallStmt(base.Pos, call)
	} else if fn.Type().NumResults() > 0 {
	n := ir.NewReturnStmt(base.Pos, nil)
	n.Results = []ir.Node{call}
	tail = n
	}
	fn.Body.Append(tail)

	typecheck.FinishFuncBody()

	typecheck.Func(fn)
	ir.CurFunc = fn
	typecheck.Stmts(fn.Body)

	typecheck.Target.Decls = append(typecheck.Target.Decls, fn)

	// Restore previous context.
	base.Pos = savepos
	typecheck.DeclContext = savedclcontext
	ir.CurFunc = savedcurfn
	}

	// CreateWasmImportWrapper creates a wrapper for imported WASM functions to
	// adapt them to the Go calling convention. The body for this function is
	// generated in cmd/internal/obj/wasm/wasmobj.go
	func CreateWasmImportWrapper(fn *ir.Func) bool {
	if fn.WasmImport == nil {
	return false
	}
	if buildcfg.GOARCH != "wasm" {
	base.FatalfAt(fn.Pos(), "CreateWasmImportWrapper call not supported on %s: func was %v", buildcfg.GOARCH, fn)
	}

	ir.InitLSym(fn, true)

	setupWasmABI(fn)

	pp := objw.NewProgs(fn, 0)
	defer pp.Free()
	pp.Text.To.Type = obj.TYPE_TEXTSIZE
	pp.Text.To.Val = int32(types.RoundUp(fn.Type().ArgWidth(), int64(types.RegSize)))
	// Wrapper functions never need their own stack frame
	pp.Text.To.Offset = 0
	pp.Flush()

	return true
	}

	func paramsToWasmFields(f ir.Func, result abi.ABIParamResultInfo, abiParams []abi.ABIParamAssignment) []obj.WasmField {
	wfs := make([]obj.WasmField, len(abiParams))
	for i, p := range abiParams {
	t := p.Type
	switch t.Kind() {
	case types.TINT32, types.TUINT32:
	wfs[i].Type = obj.WasmI32
	case types.TINT64, types.TUINT64:
	wfs[i].Type = obj.WasmI64
	case types.TFLOAT32:
	wfs[i].Type = obj.WasmF32
	case types.TFLOAT64:
	wfs[i].Type = obj.WasmF64
	case types.TUNSAFEPTR:
	wfs[i].Type = obj.WasmPtr
	default:
	base.ErrorfAt(f.Pos(), 0, "go:wasmimport %s %s: unsupported parameter type %s", f.WasmImport.Module, f.WasmImport.Name, t.String())
	}
	wfs[i].Offset = p.FrameOffset(result)
	}
	return wfs
	}

	func resultsToWasmFields(f ir.Func, result abi.ABIParamResultInfo, abiParams []abi.ABIParamAssignment) []obj.WasmField {
	if len(abiParams) > 1 {
	base.ErrorfAt(f.Pos(), 0, "go:wasmimport %s %s: too many return values", f.WasmImport.Module, f.WasmImport.Name)
	return nil
	}
	wfs := make([]obj.WasmField, len(abiParams))
	for i, p := range abiParams {
	t := p.Type
	switch t.Kind() {
	case types.TINT32, types.TUINT32:
	wfs[i].Type = obj.WasmI32
	case types.TINT64, types.TUINT64:
	wfs[i].Type = obj.WasmI64
	case types.TFLOAT32:
	wfs[i].Type = obj.WasmF32
	case types.TFLOAT64:
	wfs[i].Type = obj.WasmF64
	default:
	base.ErrorfAt(f.Pos(), 0, "go:wasmimport %s %s: unsupported result type %s", f.WasmImport.Module, f.WasmImport.Name, t.String())
	}
	wfs[i].Offset = p.FrameOffset(result)
	}
	return wfs
	}

	// setupTextLSym initializes the LSym for a with-body text symbol.
	func setupWasmABI(f *ir.Func) {
	wi := obj.WasmImport{
	Module: f.WasmImport.Module,
	Name: f.WasmImport.Name,
	}
	if wi.Module == wasm.GojsModule {
	// Functions that are imported from the "gojs" module use a special
	// ABI that just accepts the stack pointer.
	// Example:
	//
	// //go:wasmimport gojs add
	// func importedAdd(a, b uint) uint
	//
	// will roughly become
	//
	// (import "gojs" "add" (func (param i32)))
	wi.Params = []obj.WasmField{{Type: obj.WasmI32}}
	} else {
	// All other imported functions use the normal WASM ABI.
	// Example:
	//
	// //go:wasmimport a_module add
	// func importedAdd(a, b uint) uint
	//
	// will roughly become
	//
	// (import "a_module" "add" (func (param i32 i32) (result i32)))
	abiConfig := AbiForBodylessFuncStackMap(f)
	abiInfo := abiConfig.ABIAnalyzeFuncType(f.Type().FuncType())
	wi.Params = paramsToWasmFields(f, abiInfo, abiInfo.InParams())
	wi.Results = resultsToWasmFields(f, abiInfo, abiInfo.OutParams())
	}
	f.LSym.Func().WasmImport = &wi
	}