| // 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 main |
| |
| import ( |
| "bytes" |
| "cmd/internal/pkgpath" |
| "debug/elf" |
| "debug/macho" |
| "debug/pe" |
| "fmt" |
| "go/ast" |
| "go/printer" |
| "go/token" |
| "internal/xcoff" |
| "io" |
| "os" |
| "os/exec" |
| "path/filepath" |
| "regexp" |
| "sort" |
| "strings" |
| "unicode" |
| ) |
| |
| var ( |
| conf = printer.Config{Mode: printer.SourcePos, Tabwidth: 8} |
| noSourceConf = printer.Config{Tabwidth: 8} |
| ) |
| |
| // writeDefs creates output files to be compiled by gc and gcc. |
| func (p *Package) writeDefs() { |
| var fgo2, fc io.Writer |
| f := creat(*objDir + "_cgo_gotypes.go") |
| defer f.Close() |
| fgo2 = f |
| if *gccgo { |
| f := creat(*objDir + "_cgo_defun.c") |
| defer f.Close() |
| fc = f |
| } |
| fm := creat(*objDir + "_cgo_main.c") |
| |
| var gccgoInit strings.Builder |
| |
| fflg := creat(*objDir + "_cgo_flags") |
| for k, v := range p.CgoFlags { |
| fmt.Fprintf(fflg, "_CGO_%s=%s\n", k, strings.Join(v, " ")) |
| if k == "LDFLAGS" && !*gccgo { |
| for _, arg := range v { |
| fmt.Fprintf(fgo2, "//go:cgo_ldflag %q\n", arg) |
| } |
| } |
| } |
| fflg.Close() |
| |
| // Write C main file for using gcc to resolve imports. |
| fmt.Fprintf(fm, "#include <stddef.h>\n") // For size_t below. |
| fmt.Fprintf(fm, "int main() { return 0; }\n") |
| if *importRuntimeCgo { |
| fmt.Fprintf(fm, "void crosscall2(void(*fn)(void*) __attribute__((unused)), void *a __attribute__((unused)), int c __attribute__((unused)), size_t ctxt __attribute__((unused))) { }\n") |
| fmt.Fprintf(fm, "size_t _cgo_wait_runtime_init_done(void) { return 0; }\n") |
| fmt.Fprintf(fm, "void _cgo_release_context(size_t ctxt __attribute__((unused))) { }\n") |
| fmt.Fprintf(fm, "char* _cgo_topofstack(void) { return (char*)0; }\n") |
| } else { |
| // If we're not importing runtime/cgo, we *are* runtime/cgo, |
| // which provides these functions. We just need a prototype. |
| fmt.Fprintf(fm, "void crosscall2(void(*fn)(void*), void *a, int c, size_t ctxt);\n") |
| fmt.Fprintf(fm, "size_t _cgo_wait_runtime_init_done(void);\n") |
| fmt.Fprintf(fm, "void _cgo_release_context(size_t);\n") |
| } |
| fmt.Fprintf(fm, "void _cgo_allocate(void *a __attribute__((unused)), int c __attribute__((unused))) { }\n") |
| fmt.Fprintf(fm, "void _cgo_panic(void *a __attribute__((unused)), int c __attribute__((unused))) { }\n") |
| fmt.Fprintf(fm, "void _cgo_reginit(void) { }\n") |
| |
| // Write second Go output: definitions of _C_xxx. |
| // In a separate file so that the import of "unsafe" does not |
| // pollute the original file. |
| fmt.Fprintf(fgo2, "// Code generated by cmd/cgo; DO NOT EDIT.\n\n") |
| fmt.Fprintf(fgo2, "package %s\n\n", p.PackageName) |
| fmt.Fprintf(fgo2, "import \"unsafe\"\n\n") |
| if *importSyscall { |
| fmt.Fprintf(fgo2, "import \"syscall\"\n\n") |
| } |
| if *importRuntimeCgo { |
| if !*gccgoDefineCgoIncomplete { |
| fmt.Fprintf(fgo2, "import _cgopackage \"runtime/cgo\"\n\n") |
| fmt.Fprintf(fgo2, "type _ _cgopackage.Incomplete\n") // prevent import-not-used error |
| } else { |
| fmt.Fprintf(fgo2, "//go:notinheap\n") |
| fmt.Fprintf(fgo2, "type _cgopackage_Incomplete struct{ _ struct{ _ struct{} } }\n") |
| } |
| } |
| if *importSyscall { |
| fmt.Fprintf(fgo2, "var _ syscall.Errno\n") |
| } |
| fmt.Fprintf(fgo2, "func _Cgo_ptr(ptr unsafe.Pointer) unsafe.Pointer { return ptr }\n\n") |
| |
| if !*gccgo { |
| fmt.Fprintf(fgo2, "//go:linkname _Cgo_always_false runtime.cgoAlwaysFalse\n") |
| fmt.Fprintf(fgo2, "var _Cgo_always_false bool\n") |
| fmt.Fprintf(fgo2, "//go:linkname _Cgo_use runtime.cgoUse\n") |
| fmt.Fprintf(fgo2, "func _Cgo_use(interface{})\n") |
| } |
| |
| typedefNames := make([]string, 0, len(typedef)) |
| for name := range typedef { |
| if name == "_Ctype_void" { |
| // We provide an appropriate declaration for |
| // _Ctype_void below (#39877). |
| continue |
| } |
| typedefNames = append(typedefNames, name) |
| } |
| sort.Strings(typedefNames) |
| for _, name := range typedefNames { |
| def := typedef[name] |
| fmt.Fprintf(fgo2, "type %s ", name) |
| // We don't have source info for these types, so write them out without source info. |
| // Otherwise types would look like: |
| // |
| // type _Ctype_struct_cb struct { |
| // //line :1 |
| // on_test *[0]byte |
| // //line :1 |
| // } |
| // |
| // Which is not useful. Moreover we never override source info, |
| // so subsequent source code uses the same source info. |
| // Moreover, empty file name makes compile emit no source debug info at all. |
| var buf bytes.Buffer |
| noSourceConf.Fprint(&buf, fset, def.Go) |
| if bytes.HasPrefix(buf.Bytes(), []byte("_Ctype_")) || |
| strings.HasPrefix(name, "_Ctype_enum_") || |
| strings.HasPrefix(name, "_Ctype_union_") { |
| // This typedef is of the form `typedef a b` and should be an alias. |
| fmt.Fprintf(fgo2, "= ") |
| } |
| fmt.Fprintf(fgo2, "%s", buf.Bytes()) |
| fmt.Fprintf(fgo2, "\n\n") |
| } |
| if *gccgo { |
| fmt.Fprintf(fgo2, "type _Ctype_void byte\n") |
| } else { |
| fmt.Fprintf(fgo2, "type _Ctype_void [0]byte\n") |
| } |
| |
| if *gccgo { |
| fmt.Fprint(fgo2, gccgoGoProlog) |
| fmt.Fprint(fc, p.cPrologGccgo()) |
| } else { |
| fmt.Fprint(fgo2, goProlog) |
| } |
| |
| if fc != nil { |
| fmt.Fprintf(fc, "#line 1 \"cgo-generated-wrappers\"\n") |
| } |
| if fm != nil { |
| fmt.Fprintf(fm, "#line 1 \"cgo-generated-wrappers\"\n") |
| } |
| |
| gccgoSymbolPrefix := p.gccgoSymbolPrefix() |
| |
| cVars := make(map[string]bool) |
| for _, key := range nameKeys(p.Name) { |
| n := p.Name[key] |
| if !n.IsVar() { |
| continue |
| } |
| |
| if !cVars[n.C] { |
| if *gccgo { |
| fmt.Fprintf(fc, "extern byte *%s;\n", n.C) |
| } else { |
| // Force a reference to all symbols so that |
| // the external linker will add DT_NEEDED |
| // entries as needed on ELF systems. |
| // Treat function variables differently |
| // to avoid type conflict errors from LTO |
| // (Link Time Optimization). |
| if n.Kind == "fpvar" { |
| fmt.Fprintf(fm, "extern void %s();\n", n.C) |
| } else { |
| fmt.Fprintf(fm, "extern char %s[];\n", n.C) |
| fmt.Fprintf(fm, "void *_cgohack_%s = %s;\n\n", n.C, n.C) |
| } |
| fmt.Fprintf(fgo2, "//go:linkname __cgo_%s %s\n", n.C, n.C) |
| fmt.Fprintf(fgo2, "//go:cgo_import_static %s\n", n.C) |
| fmt.Fprintf(fgo2, "var __cgo_%s byte\n", n.C) |
| } |
| cVars[n.C] = true |
| } |
| |
| var node ast.Node |
| if n.Kind == "var" { |
| node = &ast.StarExpr{X: n.Type.Go} |
| } else if n.Kind == "fpvar" { |
| node = n.Type.Go |
| } else { |
| panic(fmt.Errorf("invalid var kind %q", n.Kind)) |
| } |
| if *gccgo { |
| fmt.Fprintf(fc, `extern void *%s __asm__("%s.%s");`, n.Mangle, gccgoSymbolPrefix, gccgoToSymbol(n.Mangle)) |
| fmt.Fprintf(&gccgoInit, "\t%s = &%s;\n", n.Mangle, n.C) |
| fmt.Fprintf(fc, "\n") |
| } |
| |
| fmt.Fprintf(fgo2, "var %s ", n.Mangle) |
| conf.Fprint(fgo2, fset, node) |
| if !*gccgo { |
| fmt.Fprintf(fgo2, " = (") |
| conf.Fprint(fgo2, fset, node) |
| fmt.Fprintf(fgo2, ")(unsafe.Pointer(&__cgo_%s))", n.C) |
| } |
| fmt.Fprintf(fgo2, "\n") |
| } |
| if *gccgo { |
| fmt.Fprintf(fc, "\n") |
| } |
| |
| for _, key := range nameKeys(p.Name) { |
| n := p.Name[key] |
| if n.Const != "" { |
| fmt.Fprintf(fgo2, "const %s = %s\n", n.Mangle, n.Const) |
| } |
| } |
| fmt.Fprintf(fgo2, "\n") |
| |
| callsMalloc := false |
| for _, key := range nameKeys(p.Name) { |
| n := p.Name[key] |
| if n.FuncType != nil { |
| p.writeDefsFunc(fgo2, n, &callsMalloc) |
| } |
| } |
| |
| fgcc := creat(*objDir + "_cgo_export.c") |
| fgcch := creat(*objDir + "_cgo_export.h") |
| if *gccgo { |
| p.writeGccgoExports(fgo2, fm, fgcc, fgcch) |
| } else { |
| p.writeExports(fgo2, fm, fgcc, fgcch) |
| } |
| |
| if callsMalloc && !*gccgo { |
| fmt.Fprint(fgo2, strings.Replace(cMallocDefGo, "PREFIX", cPrefix, -1)) |
| fmt.Fprint(fgcc, strings.Replace(strings.Replace(cMallocDefC, "PREFIX", cPrefix, -1), "PACKED", p.packedAttribute(), -1)) |
| } |
| |
| if err := fgcc.Close(); err != nil { |
| fatalf("%s", err) |
| } |
| if err := fgcch.Close(); err != nil { |
| fatalf("%s", err) |
| } |
| |
| if *exportHeader != "" && len(p.ExpFunc) > 0 { |
| fexp := creat(*exportHeader) |
| fgcch, err := os.Open(*objDir + "_cgo_export.h") |
| if err != nil { |
| fatalf("%s", err) |
| } |
| defer fgcch.Close() |
| _, err = io.Copy(fexp, fgcch) |
| if err != nil { |
| fatalf("%s", err) |
| } |
| if err = fexp.Close(); err != nil { |
| fatalf("%s", err) |
| } |
| } |
| |
| init := gccgoInit.String() |
| if init != "" { |
| // The init function does nothing but simple |
| // assignments, so it won't use much stack space, so |
| // it's OK to not split the stack. Splitting the stack |
| // can run into a bug in clang (as of 2018-11-09): |
| // this is a leaf function, and when clang sees a leaf |
| // function it won't emit the split stack prologue for |
| // the function. However, if this function refers to a |
| // non-split-stack function, which will happen if the |
| // cgo code refers to a C function not compiled with |
| // -fsplit-stack, then the linker will think that it |
| // needs to adjust the split stack prologue, but there |
| // won't be one. Marking the function explicitly |
| // no_split_stack works around this problem by telling |
| // the linker that it's OK if there is no split stack |
| // prologue. |
| fmt.Fprintln(fc, "static void init(void) __attribute__ ((constructor, no_split_stack));") |
| fmt.Fprintln(fc, "static void init(void) {") |
| fmt.Fprint(fc, init) |
| fmt.Fprintln(fc, "}") |
| } |
| } |
| |
| // elfImportedSymbols is like elf.File.ImportedSymbols, but it |
| // includes weak symbols. |
| // |
| // A bug in some versions of LLD (at least LLD 8) cause it to emit |
| // several pthreads symbols as weak, but we need to import those. See |
| // issue #31912 or https://bugs.llvm.org/show_bug.cgi?id=42442. |
| // |
| // When doing external linking, we hand everything off to the external |
| // linker, which will create its own dynamic symbol tables. For |
| // internal linking, this may turn weak imports into strong imports, |
| // which could cause dynamic linking to fail if a symbol really isn't |
| // defined. However, the standard library depends on everything it |
| // imports, and this is the primary use of dynamic symbol tables with |
| // internal linking. |
| func elfImportedSymbols(f *elf.File) []elf.ImportedSymbol { |
| syms, _ := f.DynamicSymbols() |
| var imports []elf.ImportedSymbol |
| for _, s := range syms { |
| if (elf.ST_BIND(s.Info) == elf.STB_GLOBAL || elf.ST_BIND(s.Info) == elf.STB_WEAK) && s.Section == elf.SHN_UNDEF { |
| imports = append(imports, elf.ImportedSymbol{ |
| Name: s.Name, |
| Library: s.Library, |
| Version: s.Version, |
| }) |
| } |
| } |
| return imports |
| } |
| |
| func dynimport(obj string) { |
| stdout := os.Stdout |
| if *dynout != "" { |
| f, err := os.Create(*dynout) |
| if err != nil { |
| fatalf("%s", err) |
| } |
| stdout = f |
| } |
| |
| fmt.Fprintf(stdout, "package %s\n", *dynpackage) |
| |
| if f, err := elf.Open(obj); err == nil { |
| if *dynlinker { |
| // Emit the cgo_dynamic_linker line. |
| if sec := f.Section(".interp"); sec != nil { |
| if data, err := sec.Data(); err == nil && len(data) > 1 { |
| // skip trailing \0 in data |
| fmt.Fprintf(stdout, "//go:cgo_dynamic_linker %q\n", string(data[:len(data)-1])) |
| } |
| } |
| } |
| sym := elfImportedSymbols(f) |
| for _, s := range sym { |
| targ := s.Name |
| if s.Version != "" { |
| targ += "#" + s.Version |
| } |
| checkImportSymName(s.Name) |
| checkImportSymName(targ) |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic %s %s %q\n", s.Name, targ, s.Library) |
| } |
| lib, _ := f.ImportedLibraries() |
| for _, l := range lib { |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic _ _ %q\n", l) |
| } |
| return |
| } |
| |
| if f, err := macho.Open(obj); err == nil { |
| sym, _ := f.ImportedSymbols() |
| for _, s := range sym { |
| if len(s) > 0 && s[0] == '_' { |
| s = s[1:] |
| } |
| checkImportSymName(s) |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic %s %s %q\n", s, s, "") |
| } |
| lib, _ := f.ImportedLibraries() |
| for _, l := range lib { |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic _ _ %q\n", l) |
| } |
| return |
| } |
| |
| if f, err := pe.Open(obj); err == nil { |
| sym, _ := f.ImportedSymbols() |
| for _, s := range sym { |
| ss := strings.Split(s, ":") |
| name := strings.Split(ss[0], "@")[0] |
| checkImportSymName(name) |
| checkImportSymName(ss[0]) |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic %s %s %q\n", name, ss[0], strings.ToLower(ss[1])) |
| } |
| return |
| } |
| |
| if f, err := xcoff.Open(obj); err == nil { |
| sym, err := f.ImportedSymbols() |
| if err != nil { |
| fatalf("cannot load imported symbols from XCOFF file %s: %v", obj, err) |
| } |
| for _, s := range sym { |
| if s.Name == "runtime_rt0_go" || s.Name == "_rt0_ppc64_aix_lib" { |
| // These symbols are imported by runtime/cgo but |
| // must not be added to _cgo_import.go as there are |
| // Go symbols. |
| continue |
| } |
| checkImportSymName(s.Name) |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic %s %s %q\n", s.Name, s.Name, s.Library) |
| } |
| lib, err := f.ImportedLibraries() |
| if err != nil { |
| fatalf("cannot load imported libraries from XCOFF file %s: %v", obj, err) |
| } |
| for _, l := range lib { |
| fmt.Fprintf(stdout, "//go:cgo_import_dynamic _ _ %q\n", l) |
| } |
| return |
| } |
| |
| fatalf("cannot parse %s as ELF, Mach-O, PE or XCOFF", obj) |
| } |
| |
| // checkImportSymName checks a symbol name we are going to emit as part |
| // of a //go:cgo_import_dynamic pragma. These names come from object |
| // files, so they may be corrupt. We are going to emit them unquoted, |
| // so while they don't need to be valid symbol names (and in some cases, |
| // involving symbol versions, they won't be) they must contain only |
| // graphic characters and must not contain Go comments. |
| func checkImportSymName(s string) { |
| for _, c := range s { |
| if !unicode.IsGraphic(c) || unicode.IsSpace(c) { |
| fatalf("dynamic symbol %q contains unsupported character", s) |
| } |
| } |
| if strings.Contains(s, "//") || strings.Contains(s, "/*") { |
| fatalf("dynamic symbol %q contains Go comment") |
| } |
| } |
| |
| // Construct a gcc struct matching the gc argument frame. |
| // Assumes that in gcc, char is 1 byte, short 2 bytes, int 4 bytes, long long 8 bytes. |
| // These assumptions are checked by the gccProlog. |
| // Also assumes that gc convention is to word-align the |
| // input and output parameters. |
| func (p *Package) structType(n *Name) (string, int64) { |
| var buf strings.Builder |
| fmt.Fprint(&buf, "struct {\n") |
| off := int64(0) |
| for i, t := range n.FuncType.Params { |
| if off%t.Align != 0 { |
| pad := t.Align - off%t.Align |
| fmt.Fprintf(&buf, "\t\tchar __pad%d[%d];\n", off, pad) |
| off += pad |
| } |
| c := t.Typedef |
| if c == "" { |
| c = t.C.String() |
| } |
| fmt.Fprintf(&buf, "\t\t%s p%d;\n", c, i) |
| off += t.Size |
| } |
| if off%p.PtrSize != 0 { |
| pad := p.PtrSize - off%p.PtrSize |
| fmt.Fprintf(&buf, "\t\tchar __pad%d[%d];\n", off, pad) |
| off += pad |
| } |
| if t := n.FuncType.Result; t != nil { |
| if off%t.Align != 0 { |
| pad := t.Align - off%t.Align |
| fmt.Fprintf(&buf, "\t\tchar __pad%d[%d];\n", off, pad) |
| off += pad |
| } |
| fmt.Fprintf(&buf, "\t\t%s r;\n", t.C) |
| off += t.Size |
| } |
| if off%p.PtrSize != 0 { |
| pad := p.PtrSize - off%p.PtrSize |
| fmt.Fprintf(&buf, "\t\tchar __pad%d[%d];\n", off, pad) |
| off += pad |
| } |
| if off == 0 { |
| fmt.Fprintf(&buf, "\t\tchar unused;\n") // avoid empty struct |
| } |
| fmt.Fprintf(&buf, "\t}") |
| return buf.String(), off |
| } |
| |
| func (p *Package) writeDefsFunc(fgo2 io.Writer, n *Name, callsMalloc *bool) { |
| name := n.Go |
| gtype := n.FuncType.Go |
| void := gtype.Results == nil || len(gtype.Results.List) == 0 |
| if n.AddError { |
| // Add "error" to return type list. |
| // Type list is known to be 0 or 1 element - it's a C function. |
| err := &ast.Field{Type: ast.NewIdent("error")} |
| l := gtype.Results.List |
| if len(l) == 0 { |
| l = []*ast.Field{err} |
| } else { |
| l = []*ast.Field{l[0], err} |
| } |
| t := new(ast.FuncType) |
| *t = *gtype |
| t.Results = &ast.FieldList{List: l} |
| gtype = t |
| } |
| |
| // Go func declaration. |
| d := &ast.FuncDecl{ |
| Name: ast.NewIdent(n.Mangle), |
| Type: gtype, |
| } |
| |
| // Builtins defined in the C prolog. |
| inProlog := builtinDefs[name] != "" |
| cname := fmt.Sprintf("_cgo%s%s", cPrefix, n.Mangle) |
| paramnames := []string(nil) |
| if d.Type.Params != nil { |
| for i, param := range d.Type.Params.List { |
| paramName := fmt.Sprintf("p%d", i) |
| param.Names = []*ast.Ident{ast.NewIdent(paramName)} |
| paramnames = append(paramnames, paramName) |
| } |
| } |
| |
| if *gccgo { |
| // Gccgo style hooks. |
| fmt.Fprint(fgo2, "\n") |
| conf.Fprint(fgo2, fset, d) |
| fmt.Fprint(fgo2, " {\n") |
| if !inProlog { |
| fmt.Fprint(fgo2, "\tdefer syscall.CgocallDone()\n") |
| fmt.Fprint(fgo2, "\tsyscall.Cgocall()\n") |
| } |
| if n.AddError { |
| fmt.Fprint(fgo2, "\tsyscall.SetErrno(0)\n") |
| } |
| fmt.Fprint(fgo2, "\t") |
| if !void { |
| fmt.Fprint(fgo2, "r := ") |
| } |
| fmt.Fprintf(fgo2, "%s(%s)\n", cname, strings.Join(paramnames, ", ")) |
| |
| if n.AddError { |
| fmt.Fprint(fgo2, "\te := syscall.GetErrno()\n") |
| fmt.Fprint(fgo2, "\tif e != 0 {\n") |
| fmt.Fprint(fgo2, "\t\treturn ") |
| if !void { |
| fmt.Fprint(fgo2, "r, ") |
| } |
| fmt.Fprint(fgo2, "e\n") |
| fmt.Fprint(fgo2, "\t}\n") |
| fmt.Fprint(fgo2, "\treturn ") |
| if !void { |
| fmt.Fprint(fgo2, "r, ") |
| } |
| fmt.Fprint(fgo2, "nil\n") |
| } else if !void { |
| fmt.Fprint(fgo2, "\treturn r\n") |
| } |
| |
| fmt.Fprint(fgo2, "}\n") |
| |
| // declare the C function. |
| fmt.Fprintf(fgo2, "//extern %s\n", cname) |
| d.Name = ast.NewIdent(cname) |
| if n.AddError { |
| l := d.Type.Results.List |
| d.Type.Results.List = l[:len(l)-1] |
| } |
| conf.Fprint(fgo2, fset, d) |
| fmt.Fprint(fgo2, "\n") |
| |
| return |
| } |
| |
| if inProlog { |
| fmt.Fprint(fgo2, builtinDefs[name]) |
| if strings.Contains(builtinDefs[name], "_cgo_cmalloc") { |
| *callsMalloc = true |
| } |
| return |
| } |
| |
| // Wrapper calls into gcc, passing a pointer to the argument frame. |
| fmt.Fprintf(fgo2, "//go:cgo_import_static %s\n", cname) |
| fmt.Fprintf(fgo2, "//go:linkname __cgofn_%s %s\n", cname, cname) |
| fmt.Fprintf(fgo2, "var __cgofn_%s byte\n", cname) |
| fmt.Fprintf(fgo2, "var %s = unsafe.Pointer(&__cgofn_%s)\n", cname, cname) |
| |
| nret := 0 |
| if !void { |
| d.Type.Results.List[0].Names = []*ast.Ident{ast.NewIdent("r1")} |
| nret = 1 |
| } |
| if n.AddError { |
| d.Type.Results.List[nret].Names = []*ast.Ident{ast.NewIdent("r2")} |
| } |
| |
| fmt.Fprint(fgo2, "\n") |
| fmt.Fprint(fgo2, "//go:cgo_unsafe_args\n") |
| conf.Fprint(fgo2, fset, d) |
| fmt.Fprint(fgo2, " {\n") |
| |
| // NOTE: Using uintptr to hide from escape analysis. |
| arg := "0" |
| if len(paramnames) > 0 { |
| arg = "uintptr(unsafe.Pointer(&p0))" |
| } else if !void { |
| arg = "uintptr(unsafe.Pointer(&r1))" |
| } |
| |
| prefix := "" |
| if n.AddError { |
| prefix = "errno := " |
| } |
| fmt.Fprintf(fgo2, "\t%s_cgo_runtime_cgocall(%s, %s)\n", prefix, cname, arg) |
| if n.AddError { |
| fmt.Fprintf(fgo2, "\tif errno != 0 { r2 = syscall.Errno(errno) }\n") |
| } |
| fmt.Fprintf(fgo2, "\tif _Cgo_always_false {\n") |
| if d.Type.Params != nil { |
| for i := range d.Type.Params.List { |
| fmt.Fprintf(fgo2, "\t\t_Cgo_use(p%d)\n", i) |
| } |
| } |
| fmt.Fprintf(fgo2, "\t}\n") |
| fmt.Fprintf(fgo2, "\treturn\n") |
| fmt.Fprintf(fgo2, "}\n") |
| } |
| |
| // writeOutput creates stubs for a specific source file to be compiled by gc |
| func (p *Package) writeOutput(f *File, srcfile string) { |
| base := srcfile |
| base = strings.TrimSuffix(base, ".go") |
| base = filepath.Base(base) |
| fgo1 := creat(*objDir + base + ".cgo1.go") |
| fgcc := creat(*objDir + base + ".cgo2.c") |
| |
| p.GoFiles = append(p.GoFiles, base+".cgo1.go") |
| p.GccFiles = append(p.GccFiles, base+".cgo2.c") |
| |
| // Write Go output: Go input with rewrites of C.xxx to _C_xxx. |
| fmt.Fprintf(fgo1, "// Code generated by cmd/cgo; DO NOT EDIT.\n\n") |
| fmt.Fprintf(fgo1, "//line %s:1:1\n", srcfile) |
| fgo1.Write(f.Edit.Bytes()) |
| |
| // While we process the vars and funcs, also write gcc output. |
| // Gcc output starts with the preamble. |
| fmt.Fprintf(fgcc, "%s\n", builtinProlog) |
| fmt.Fprintf(fgcc, "%s\n", f.Preamble) |
| fmt.Fprintf(fgcc, "%s\n", gccProlog) |
| fmt.Fprintf(fgcc, "%s\n", tsanProlog) |
| fmt.Fprintf(fgcc, "%s\n", msanProlog) |
| |
| for _, key := range nameKeys(f.Name) { |
| n := f.Name[key] |
| if n.FuncType != nil { |
| p.writeOutputFunc(fgcc, n) |
| } |
| } |
| |
| fgo1.Close() |
| fgcc.Close() |
| } |
| |
| // fixGo converts the internal Name.Go field into the name we should show |
| // to users in error messages. There's only one for now: on input we rewrite |
| // C.malloc into C._CMalloc, so change it back here. |
| func fixGo(name string) string { |
| if name == "_CMalloc" { |
| return "malloc" |
| } |
| return name |
| } |
| |
| var isBuiltin = map[string]bool{ |
| "_Cfunc_CString": true, |
| "_Cfunc_CBytes": true, |
| "_Cfunc_GoString": true, |
| "_Cfunc_GoStringN": true, |
| "_Cfunc_GoBytes": true, |
| "_Cfunc__CMalloc": true, |
| } |
| |
| func (p *Package) writeOutputFunc(fgcc *os.File, n *Name) { |
| name := n.Mangle |
| if isBuiltin[name] || p.Written[name] { |
| // The builtins are already defined in the C prolog, and we don't |
| // want to duplicate function definitions we've already done. |
| return |
| } |
| p.Written[name] = true |
| |
| if *gccgo { |
| p.writeGccgoOutputFunc(fgcc, n) |
| return |
| } |
| |
| ctype, _ := p.structType(n) |
| |
| // Gcc wrapper unpacks the C argument struct |
| // and calls the actual C function. |
| fmt.Fprintf(fgcc, "CGO_NO_SANITIZE_THREAD\n") |
| if n.AddError { |
| fmt.Fprintf(fgcc, "int\n") |
| } else { |
| fmt.Fprintf(fgcc, "void\n") |
| } |
| fmt.Fprintf(fgcc, "_cgo%s%s(void *v)\n", cPrefix, n.Mangle) |
| fmt.Fprintf(fgcc, "{\n") |
| if n.AddError { |
| fmt.Fprintf(fgcc, "\tint _cgo_errno;\n") |
| } |
| // We're trying to write a gcc struct that matches gc's layout. |
| // Use packed attribute to force no padding in this struct in case |
| // gcc has different packing requirements. |
| fmt.Fprintf(fgcc, "\t%s %v *_cgo_a = v;\n", ctype, p.packedAttribute()) |
| if n.FuncType.Result != nil { |
| // Save the stack top for use below. |
| fmt.Fprintf(fgcc, "\tchar *_cgo_stktop = _cgo_topofstack();\n") |
| } |
| tr := n.FuncType.Result |
| if tr != nil { |
| fmt.Fprintf(fgcc, "\t__typeof__(_cgo_a->r) _cgo_r;\n") |
| } |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_acquire();\n") |
| if n.AddError { |
| fmt.Fprintf(fgcc, "\terrno = 0;\n") |
| } |
| fmt.Fprintf(fgcc, "\t") |
| if tr != nil { |
| fmt.Fprintf(fgcc, "_cgo_r = ") |
| if c := tr.C.String(); c[len(c)-1] == '*' { |
| fmt.Fprint(fgcc, "(__typeof__(_cgo_a->r)) ") |
| } |
| } |
| if n.Kind == "macro" { |
| fmt.Fprintf(fgcc, "%s;\n", n.C) |
| } else { |
| fmt.Fprintf(fgcc, "%s(", n.C) |
| for i := range n.FuncType.Params { |
| if i > 0 { |
| fmt.Fprintf(fgcc, ", ") |
| } |
| fmt.Fprintf(fgcc, "_cgo_a->p%d", i) |
| } |
| fmt.Fprintf(fgcc, ");\n") |
| } |
| if n.AddError { |
| fmt.Fprintf(fgcc, "\t_cgo_errno = errno;\n") |
| } |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_release();\n") |
| if n.FuncType.Result != nil { |
| // The cgo call may have caused a stack copy (via a callback). |
| // Adjust the return value pointer appropriately. |
| fmt.Fprintf(fgcc, "\t_cgo_a = (void*)((char*)_cgo_a + (_cgo_topofstack() - _cgo_stktop));\n") |
| // Save the return value. |
| fmt.Fprintf(fgcc, "\t_cgo_a->r = _cgo_r;\n") |
| // The return value is on the Go stack. If we are using msan, |
| // and if the C value is partially or completely uninitialized, |
| // the assignment will mark the Go stack as uninitialized. |
| // The Go compiler does not update msan for changes to the |
| // stack. It is possible that the stack will remain |
| // uninitialized, and then later be used in a way that is |
| // visible to msan, possibly leading to a false positive. |
| // Mark the stack space as written, to avoid this problem. |
| // See issue 26209. |
| fmt.Fprintf(fgcc, "\t_cgo_msan_write(&_cgo_a->r, sizeof(_cgo_a->r));\n") |
| } |
| if n.AddError { |
| fmt.Fprintf(fgcc, "\treturn _cgo_errno;\n") |
| } |
| fmt.Fprintf(fgcc, "}\n") |
| fmt.Fprintf(fgcc, "\n") |
| } |
| |
| // Write out a wrapper for a function when using gccgo. This is a |
| // simple wrapper that just calls the real function. We only need a |
| // wrapper to support static functions in the prologue--without a |
| // wrapper, we can't refer to the function, since the reference is in |
| // a different file. |
| func (p *Package) writeGccgoOutputFunc(fgcc *os.File, n *Name) { |
| fmt.Fprintf(fgcc, "CGO_NO_SANITIZE_THREAD\n") |
| if t := n.FuncType.Result; t != nil { |
| fmt.Fprintf(fgcc, "%s\n", t.C.String()) |
| } else { |
| fmt.Fprintf(fgcc, "void\n") |
| } |
| fmt.Fprintf(fgcc, "_cgo%s%s(", cPrefix, n.Mangle) |
| for i, t := range n.FuncType.Params { |
| if i > 0 { |
| fmt.Fprintf(fgcc, ", ") |
| } |
| c := t.Typedef |
| if c == "" { |
| c = t.C.String() |
| } |
| fmt.Fprintf(fgcc, "%s p%d", c, i) |
| } |
| fmt.Fprintf(fgcc, ")\n") |
| fmt.Fprintf(fgcc, "{\n") |
| if t := n.FuncType.Result; t != nil { |
| fmt.Fprintf(fgcc, "\t%s _cgo_r;\n", t.C.String()) |
| } |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_acquire();\n") |
| fmt.Fprintf(fgcc, "\t") |
| if t := n.FuncType.Result; t != nil { |
| fmt.Fprintf(fgcc, "_cgo_r = ") |
| // Cast to void* to avoid warnings due to omitted qualifiers. |
| if c := t.C.String(); c[len(c)-1] == '*' { |
| fmt.Fprintf(fgcc, "(void*)") |
| } |
| } |
| if n.Kind == "macro" { |
| fmt.Fprintf(fgcc, "%s;\n", n.C) |
| } else { |
| fmt.Fprintf(fgcc, "%s(", n.C) |
| for i := range n.FuncType.Params { |
| if i > 0 { |
| fmt.Fprintf(fgcc, ", ") |
| } |
| fmt.Fprintf(fgcc, "p%d", i) |
| } |
| fmt.Fprintf(fgcc, ");\n") |
| } |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_release();\n") |
| if t := n.FuncType.Result; t != nil { |
| fmt.Fprintf(fgcc, "\treturn ") |
| // Cast to void* to avoid warnings due to omitted qualifiers |
| // and explicit incompatible struct types. |
| if c := t.C.String(); c[len(c)-1] == '*' { |
| fmt.Fprintf(fgcc, "(void*)") |
| } |
| fmt.Fprintf(fgcc, "_cgo_r;\n") |
| } |
| fmt.Fprintf(fgcc, "}\n") |
| fmt.Fprintf(fgcc, "\n") |
| } |
| |
| // packedAttribute returns host compiler struct attribute that will be |
| // used to match gc's struct layout. For example, on 386 Windows, |
| // gcc wants to 8-align int64s, but gc does not. |
| // Use __gcc_struct__ to work around https://gcc.gnu.org/PR52991 on x86, |
| // and https://golang.org/issue/5603. |
| func (p *Package) packedAttribute() string { |
| s := "__attribute__((__packed__" |
| if !p.GccIsClang && (goarch == "amd64" || goarch == "386") { |
| s += ", __gcc_struct__" |
| } |
| return s + "))" |
| } |
| |
| // exportParamName returns the value of param as it should be |
| // displayed in a c header file. If param contains any non-ASCII |
| // characters, this function will return the character p followed by |
| // the value of position; otherwise, this function will return the |
| // value of param. |
| func exportParamName(param string, position int) string { |
| if param == "" { |
| return fmt.Sprintf("p%d", position) |
| } |
| |
| pname := param |
| |
| for i := 0; i < len(param); i++ { |
| if param[i] > unicode.MaxASCII { |
| pname = fmt.Sprintf("p%d", position) |
| break |
| } |
| } |
| |
| return pname |
| } |
| |
| // Write out the various stubs we need to support functions exported |
| // from Go so that they are callable from C. |
| func (p *Package) writeExports(fgo2, fm, fgcc, fgcch io.Writer) { |
| p.writeExportHeader(fgcch) |
| |
| fmt.Fprintf(fgcc, "/* Code generated by cmd/cgo; DO NOT EDIT. */\n\n") |
| fmt.Fprintf(fgcc, "#include <stdlib.h>\n") |
| fmt.Fprintf(fgcc, "#include \"_cgo_export.h\"\n\n") |
| |
| // We use packed structs, but they are always aligned. |
| // The pragmas and address-of-packed-member are only recognized as |
| // warning groups in clang 4.0+, so ignore unknown pragmas first. |
| fmt.Fprintf(fgcc, "#pragma GCC diagnostic ignored \"-Wunknown-pragmas\"\n") |
| fmt.Fprintf(fgcc, "#pragma GCC diagnostic ignored \"-Wpragmas\"\n") |
| fmt.Fprintf(fgcc, "#pragma GCC diagnostic ignored \"-Waddress-of-packed-member\"\n") |
| |
| fmt.Fprintf(fgcc, "extern void crosscall2(void (*fn)(void *), void *, int, size_t);\n") |
| fmt.Fprintf(fgcc, "extern size_t _cgo_wait_runtime_init_done(void);\n") |
| fmt.Fprintf(fgcc, "extern void _cgo_release_context(size_t);\n\n") |
| fmt.Fprintf(fgcc, "extern char* _cgo_topofstack(void);") |
| fmt.Fprintf(fgcc, "%s\n", tsanProlog) |
| fmt.Fprintf(fgcc, "%s\n", msanProlog) |
| |
| for _, exp := range p.ExpFunc { |
| fn := exp.Func |
| |
| // Construct a struct that will be used to communicate |
| // arguments from C to Go. The C and Go definitions |
| // just have to agree. The gcc struct will be compiled |
| // with __attribute__((packed)) so all padding must be |
| // accounted for explicitly. |
| ctype := "struct {\n" |
| gotype := new(bytes.Buffer) |
| fmt.Fprintf(gotype, "struct {\n") |
| off := int64(0) |
| npad := 0 |
| argField := func(typ ast.Expr, namePat string, args ...interface{}) { |
| name := fmt.Sprintf(namePat, args...) |
| t := p.cgoType(typ) |
| if off%t.Align != 0 { |
| pad := t.Align - off%t.Align |
| ctype += fmt.Sprintf("\t\tchar __pad%d[%d];\n", npad, pad) |
| off += pad |
| npad++ |
| } |
| ctype += fmt.Sprintf("\t\t%s %s;\n", t.C, name) |
| fmt.Fprintf(gotype, "\t\t%s ", name) |
| noSourceConf.Fprint(gotype, fset, typ) |
| fmt.Fprintf(gotype, "\n") |
| off += t.Size |
| } |
| if fn.Recv != nil { |
| argField(fn.Recv.List[0].Type, "recv") |
| } |
| fntype := fn.Type |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| argField(atype, "p%d", i) |
| }) |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| argField(atype, "r%d", i) |
| }) |
| if ctype == "struct {\n" { |
| ctype += "\t\tchar unused;\n" // avoid empty struct |
| } |
| ctype += "\t}" |
| fmt.Fprintf(gotype, "\t}") |
| |
| // Get the return type of the wrapper function |
| // compiled by gcc. |
| gccResult := "" |
| if fntype.Results == nil || len(fntype.Results.List) == 0 { |
| gccResult = "void" |
| } else if len(fntype.Results.List) == 1 && len(fntype.Results.List[0].Names) <= 1 { |
| gccResult = p.cgoType(fntype.Results.List[0].Type).C.String() |
| } else { |
| fmt.Fprintf(fgcch, "\n/* Return type for %s */\n", exp.ExpName) |
| fmt.Fprintf(fgcch, "struct %s_return {\n", exp.ExpName) |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| fmt.Fprintf(fgcch, "\t%s r%d;", p.cgoType(atype).C, i) |
| if len(aname) > 0 { |
| fmt.Fprintf(fgcch, " /* %s */", aname) |
| } |
| fmt.Fprint(fgcch, "\n") |
| }) |
| fmt.Fprintf(fgcch, "};\n") |
| gccResult = "struct " + exp.ExpName + "_return" |
| } |
| |
| // Build the wrapper function compiled by gcc. |
| gccExport := "" |
| if goos == "windows" { |
| gccExport = "__declspec(dllexport) " |
| } |
| s := fmt.Sprintf("%s%s %s(", gccExport, gccResult, exp.ExpName) |
| if fn.Recv != nil { |
| s += p.cgoType(fn.Recv.List[0].Type).C.String() |
| s += " recv" |
| } |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 || fn.Recv != nil { |
| s += ", " |
| } |
| s += fmt.Sprintf("%s %s", p.cgoType(atype).C, exportParamName(aname, i)) |
| }) |
| s += ")" |
| |
| if len(exp.Doc) > 0 { |
| fmt.Fprintf(fgcch, "\n%s", exp.Doc) |
| if !strings.HasSuffix(exp.Doc, "\n") { |
| fmt.Fprint(fgcch, "\n") |
| } |
| } |
| fmt.Fprintf(fgcch, "extern %s;\n", s) |
| |
| fmt.Fprintf(fgcc, "extern void _cgoexp%s_%s(void *);\n", cPrefix, exp.ExpName) |
| fmt.Fprintf(fgcc, "\nCGO_NO_SANITIZE_THREAD") |
| fmt.Fprintf(fgcc, "\n%s\n", s) |
| fmt.Fprintf(fgcc, "{\n") |
| fmt.Fprintf(fgcc, "\tsize_t _cgo_ctxt = _cgo_wait_runtime_init_done();\n") |
| // The results part of the argument structure must be |
| // initialized to 0 so the write barriers generated by |
| // the assignments to these fields in Go are safe. |
| // |
| // We use a local static variable to get the zeroed |
| // value of the argument type. This avoids including |
| // string.h for memset, and is also robust to C++ |
| // types with constructors. Both GCC and LLVM optimize |
| // this into just zeroing _cgo_a. |
| fmt.Fprintf(fgcc, "\ttypedef %s %v _cgo_argtype;\n", ctype, p.packedAttribute()) |
| fmt.Fprintf(fgcc, "\tstatic _cgo_argtype _cgo_zero;\n") |
| fmt.Fprintf(fgcc, "\t_cgo_argtype _cgo_a = _cgo_zero;\n") |
| if gccResult != "void" && (len(fntype.Results.List) > 1 || len(fntype.Results.List[0].Names) > 1) { |
| fmt.Fprintf(fgcc, "\t%s r;\n", gccResult) |
| } |
| if fn.Recv != nil { |
| fmt.Fprintf(fgcc, "\t_cgo_a.recv = recv;\n") |
| } |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| fmt.Fprintf(fgcc, "\t_cgo_a.p%d = %s;\n", i, exportParamName(aname, i)) |
| }) |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_release();\n") |
| fmt.Fprintf(fgcc, "\tcrosscall2(_cgoexp%s_%s, &_cgo_a, %d, _cgo_ctxt);\n", cPrefix, exp.ExpName, off) |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_acquire();\n") |
| fmt.Fprintf(fgcc, "\t_cgo_release_context(_cgo_ctxt);\n") |
| if gccResult != "void" { |
| if len(fntype.Results.List) == 1 && len(fntype.Results.List[0].Names) <= 1 { |
| fmt.Fprintf(fgcc, "\treturn _cgo_a.r0;\n") |
| } else { |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| fmt.Fprintf(fgcc, "\tr.r%d = _cgo_a.r%d;\n", i, i) |
| }) |
| fmt.Fprintf(fgcc, "\treturn r;\n") |
| } |
| } |
| fmt.Fprintf(fgcc, "}\n") |
| |
| // In internal linking mode, the Go linker sees both |
| // the C wrapper written above and the Go wrapper it |
| // references. Hence, export the C wrapper (e.g., for |
| // if we're building a shared object). The Go linker |
| // will resolve the C wrapper's reference to the Go |
| // wrapper without a separate export. |
| fmt.Fprintf(fgo2, "//go:cgo_export_dynamic %s\n", exp.ExpName) |
| // cgo_export_static refers to a symbol by its linker |
| // name, so set the linker name of the Go wrapper. |
| fmt.Fprintf(fgo2, "//go:linkname _cgoexp%s_%s _cgoexp%s_%s\n", cPrefix, exp.ExpName, cPrefix, exp.ExpName) |
| // In external linking mode, the Go linker sees the Go |
| // wrapper, but not the C wrapper. For this case, |
| // export the Go wrapper so the host linker can |
| // resolve the reference from the C wrapper to the Go |
| // wrapper. |
| fmt.Fprintf(fgo2, "//go:cgo_export_static _cgoexp%s_%s\n", cPrefix, exp.ExpName) |
| |
| // Build the wrapper function compiled by cmd/compile. |
| // This unpacks the argument struct above and calls the Go function. |
| fmt.Fprintf(fgo2, "func _cgoexp%s_%s(a *%s) {\n", cPrefix, exp.ExpName, gotype) |
| |
| fmt.Fprintf(fm, "void _cgoexp%s_%s(void* p){}\n", cPrefix, exp.ExpName) |
| |
| fmt.Fprintf(fgo2, "\t") |
| |
| if gccResult != "void" { |
| // Write results back to frame. |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 { |
| fmt.Fprintf(fgo2, ", ") |
| } |
| fmt.Fprintf(fgo2, "a.r%d", i) |
| }) |
| fmt.Fprintf(fgo2, " = ") |
| } |
| if fn.Recv != nil { |
| fmt.Fprintf(fgo2, "a.recv.") |
| } |
| fmt.Fprintf(fgo2, "%s(", exp.Func.Name) |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 { |
| fmt.Fprint(fgo2, ", ") |
| } |
| fmt.Fprintf(fgo2, "a.p%d", i) |
| }) |
| fmt.Fprint(fgo2, ")\n") |
| if gccResult != "void" { |
| // Verify that any results don't contain any |
| // Go pointers. |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| if !p.hasPointer(nil, atype, false) { |
| return |
| } |
| fmt.Fprintf(fgo2, "\t_cgoCheckResult(a.r%d)\n", i) |
| }) |
| } |
| fmt.Fprint(fgo2, "}\n") |
| } |
| |
| fmt.Fprintf(fgcch, "%s", gccExportHeaderEpilog) |
| } |
| |
| // Write out the C header allowing C code to call exported gccgo functions. |
| func (p *Package) writeGccgoExports(fgo2, fm, fgcc, fgcch io.Writer) { |
| gccgoSymbolPrefix := p.gccgoSymbolPrefix() |
| |
| p.writeExportHeader(fgcch) |
| |
| fmt.Fprintf(fgcc, "/* Code generated by cmd/cgo; DO NOT EDIT. */\n\n") |
| fmt.Fprintf(fgcc, "#include \"_cgo_export.h\"\n") |
| |
| fmt.Fprintf(fgcc, "%s\n", gccgoExportFileProlog) |
| fmt.Fprintf(fgcc, "%s\n", tsanProlog) |
| fmt.Fprintf(fgcc, "%s\n", msanProlog) |
| |
| for _, exp := range p.ExpFunc { |
| fn := exp.Func |
| fntype := fn.Type |
| |
| cdeclBuf := new(strings.Builder) |
| resultCount := 0 |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { resultCount++ }) |
| switch resultCount { |
| case 0: |
| fmt.Fprintf(cdeclBuf, "void") |
| case 1: |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| t := p.cgoType(atype) |
| fmt.Fprintf(cdeclBuf, "%s", t.C) |
| }) |
| default: |
| // Declare a result struct. |
| fmt.Fprintf(fgcch, "\n/* Return type for %s */\n", exp.ExpName) |
| fmt.Fprintf(fgcch, "struct %s_return {\n", exp.ExpName) |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| t := p.cgoType(atype) |
| fmt.Fprintf(fgcch, "\t%s r%d;", t.C, i) |
| if len(aname) > 0 { |
| fmt.Fprintf(fgcch, " /* %s */", aname) |
| } |
| fmt.Fprint(fgcch, "\n") |
| }) |
| fmt.Fprintf(fgcch, "};\n") |
| fmt.Fprintf(cdeclBuf, "struct %s_return", exp.ExpName) |
| } |
| |
| cRet := cdeclBuf.String() |
| |
| cdeclBuf = new(strings.Builder) |
| fmt.Fprintf(cdeclBuf, "(") |
| if fn.Recv != nil { |
| fmt.Fprintf(cdeclBuf, "%s recv", p.cgoType(fn.Recv.List[0].Type).C.String()) |
| } |
| // Function parameters. |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 || fn.Recv != nil { |
| fmt.Fprintf(cdeclBuf, ", ") |
| } |
| t := p.cgoType(atype) |
| fmt.Fprintf(cdeclBuf, "%s p%d", t.C, i) |
| }) |
| fmt.Fprintf(cdeclBuf, ")") |
| cParams := cdeclBuf.String() |
| |
| if len(exp.Doc) > 0 { |
| fmt.Fprintf(fgcch, "\n%s", exp.Doc) |
| } |
| |
| fmt.Fprintf(fgcch, "extern %s %s%s;\n", cRet, exp.ExpName, cParams) |
| |
| // We need to use a name that will be exported by the |
| // Go code; otherwise gccgo will make it static and we |
| // will not be able to link against it from the C |
| // code. |
| goName := "Cgoexp_" + exp.ExpName |
| fmt.Fprintf(fgcc, `extern %s %s %s __asm__("%s.%s");`, cRet, goName, cParams, gccgoSymbolPrefix, gccgoToSymbol(goName)) |
| fmt.Fprint(fgcc, "\n") |
| |
| fmt.Fprint(fgcc, "\nCGO_NO_SANITIZE_THREAD\n") |
| fmt.Fprintf(fgcc, "%s %s %s {\n", cRet, exp.ExpName, cParams) |
| if resultCount > 0 { |
| fmt.Fprintf(fgcc, "\t%s r;\n", cRet) |
| } |
| fmt.Fprintf(fgcc, "\tif(_cgo_wait_runtime_init_done)\n") |
| fmt.Fprintf(fgcc, "\t\t_cgo_wait_runtime_init_done();\n") |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_release();\n") |
| fmt.Fprint(fgcc, "\t") |
| if resultCount > 0 { |
| fmt.Fprint(fgcc, "r = ") |
| } |
| fmt.Fprintf(fgcc, "%s(", goName) |
| if fn.Recv != nil { |
| fmt.Fprint(fgcc, "recv") |
| } |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 || fn.Recv != nil { |
| fmt.Fprintf(fgcc, ", ") |
| } |
| fmt.Fprintf(fgcc, "p%d", i) |
| }) |
| fmt.Fprint(fgcc, ");\n") |
| fmt.Fprintf(fgcc, "\t_cgo_tsan_acquire();\n") |
| if resultCount > 0 { |
| fmt.Fprint(fgcc, "\treturn r;\n") |
| } |
| fmt.Fprint(fgcc, "}\n") |
| |
| // Dummy declaration for _cgo_main.c |
| fmt.Fprintf(fm, `char %s[1] __asm__("%s.%s");`, goName, gccgoSymbolPrefix, gccgoToSymbol(goName)) |
| fmt.Fprint(fm, "\n") |
| |
| // For gccgo we use a wrapper function in Go, in order |
| // to call CgocallBack and CgocallBackDone. |
| |
| // This code uses printer.Fprint, not conf.Fprint, |
| // because we don't want //line comments in the middle |
| // of the function types. |
| fmt.Fprint(fgo2, "\n") |
| fmt.Fprintf(fgo2, "func %s(", goName) |
| if fn.Recv != nil { |
| fmt.Fprint(fgo2, "recv ") |
| printer.Fprint(fgo2, fset, fn.Recv.List[0].Type) |
| } |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 || fn.Recv != nil { |
| fmt.Fprintf(fgo2, ", ") |
| } |
| fmt.Fprintf(fgo2, "p%d ", i) |
| printer.Fprint(fgo2, fset, atype) |
| }) |
| fmt.Fprintf(fgo2, ")") |
| if resultCount > 0 { |
| fmt.Fprintf(fgo2, " (") |
| forFieldList(fntype.Results, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 { |
| fmt.Fprint(fgo2, ", ") |
| } |
| printer.Fprint(fgo2, fset, atype) |
| }) |
| fmt.Fprint(fgo2, ")") |
| } |
| fmt.Fprint(fgo2, " {\n") |
| fmt.Fprint(fgo2, "\tsyscall.CgocallBack()\n") |
| fmt.Fprint(fgo2, "\tdefer syscall.CgocallBackDone()\n") |
| fmt.Fprint(fgo2, "\t") |
| if resultCount > 0 { |
| fmt.Fprint(fgo2, "return ") |
| } |
| if fn.Recv != nil { |
| fmt.Fprint(fgo2, "recv.") |
| } |
| fmt.Fprintf(fgo2, "%s(", exp.Func.Name) |
| forFieldList(fntype.Params, |
| func(i int, aname string, atype ast.Expr) { |
| if i > 0 { |
| fmt.Fprint(fgo2, ", ") |
| } |
| fmt.Fprintf(fgo2, "p%d", i) |
| }) |
| fmt.Fprint(fgo2, ")\n") |
| fmt.Fprint(fgo2, "}\n") |
| } |
| |
| fmt.Fprintf(fgcch, "%s", gccExportHeaderEpilog) |
| } |
| |
| // writeExportHeader writes out the start of the _cgo_export.h file. |
| func (p *Package) writeExportHeader(fgcch io.Writer) { |
| fmt.Fprintf(fgcch, "/* Code generated by cmd/cgo; DO NOT EDIT. */\n\n") |
| pkg := *importPath |
| if pkg == "" { |
| pkg = p.PackagePath |
| } |
| fmt.Fprintf(fgcch, "/* package %s */\n\n", pkg) |
| fmt.Fprintf(fgcch, "%s\n", builtinExportProlog) |
| |
| // Remove absolute paths from #line comments in the preamble. |
| // They aren't useful for people using the header file, |
| // and they mean that the header files change based on the |
| // exact location of GOPATH. |
| re := regexp.MustCompile(`(?m)^(#line\s+\d+\s+")[^"]*[/\\]([^"]*")`) |
| preamble := re.ReplaceAllString(p.Preamble, "$1$2") |
| |
| fmt.Fprintf(fgcch, "/* Start of preamble from import \"C\" comments. */\n\n") |
| fmt.Fprintf(fgcch, "%s\n", preamble) |
| fmt.Fprintf(fgcch, "\n/* End of preamble from import \"C\" comments. */\n\n") |
| |
| fmt.Fprintf(fgcch, "%s\n", p.gccExportHeaderProlog()) |
| } |
| |
| // gccgoToSymbol converts a name to a mangled symbol for gccgo. |
| func gccgoToSymbol(ppath string) string { |
| if gccgoMangler == nil { |
| var err error |
| cmd := os.Getenv("GCCGO") |
| if cmd == "" { |
| cmd, err = exec.LookPath("gccgo") |
| if err != nil { |
| fatalf("unable to locate gccgo: %v", err) |
| } |
| } |
| gccgoMangler, err = pkgpath.ToSymbolFunc(cmd, *objDir) |
| if err != nil { |
| fatalf("%v", err) |
| } |
| } |
| return gccgoMangler(ppath) |
| } |
| |
| // Return the package prefix when using gccgo. |
| func (p *Package) gccgoSymbolPrefix() string { |
| if !*gccgo { |
| return "" |
| } |
| |
| if *gccgopkgpath != "" { |
| return gccgoToSymbol(*gccgopkgpath) |
| } |
| if *gccgoprefix == "" && p.PackageName == "main" { |
| return "main" |
| } |
| prefix := gccgoToSymbol(*gccgoprefix) |
| if prefix == "" { |
| prefix = "go" |
| } |
| return prefix + "." + p.PackageName |
| } |
| |
| // Call a function for each entry in an ast.FieldList, passing the |
| // index into the list, the name if any, and the type. |
| func forFieldList(fl *ast.FieldList, fn func(int, string, ast.Expr)) { |
| if fl == nil { |
| return |
| } |
| i := 0 |
| for _, r := range fl.List { |
| if r.Names == nil { |
| fn(i, "", r.Type) |
| i++ |
| } else { |
| for _, n := range r.Names { |
| fn(i, n.Name, r.Type) |
| i++ |
| } |
| } |
| } |
| } |
| |
| func c(repr string, args ...interface{}) *TypeRepr { |
| return &TypeRepr{repr, args} |
| } |
| |
| // Map predeclared Go types to Type. |
| var goTypes = map[string]*Type{ |
| "bool": {Size: 1, Align: 1, C: c("GoUint8")}, |
| "byte": {Size: 1, Align: 1, C: c("GoUint8")}, |
| "int": {Size: 0, Align: 0, C: c("GoInt")}, |
| "uint": {Size: 0, Align: 0, C: c("GoUint")}, |
| "rune": {Size: 4, Align: 4, C: c("GoInt32")}, |
| "int8": {Size: 1, Align: 1, C: c("GoInt8")}, |
| "uint8": {Size: 1, Align: 1, C: c("GoUint8")}, |
| "int16": {Size: 2, Align: 2, C: c("GoInt16")}, |
| "uint16": {Size: 2, Align: 2, C: c("GoUint16")}, |
| "int32": {Size: 4, Align: 4, C: c("GoInt32")}, |
| "uint32": {Size: 4, Align: 4, C: c("GoUint32")}, |
| "int64": {Size: 8, Align: 8, C: c("GoInt64")}, |
| "uint64": {Size: 8, Align: 8, C: c("GoUint64")}, |
| "float32": {Size: 4, Align: 4, C: c("GoFloat32")}, |
| "float64": {Size: 8, Align: 8, C: c("GoFloat64")}, |
| "complex64": {Size: 8, Align: 4, C: c("GoComplex64")}, |
| "complex128": {Size: 16, Align: 8, C: c("GoComplex128")}, |
| } |
| |
| // Map an ast type to a Type. |
| func (p *Package) cgoType(e ast.Expr) *Type { |
| switch t := e.(type) { |
| case *ast.StarExpr: |
| x := p.cgoType(t.X) |
| return &Type{Size: p.PtrSize, Align: p.PtrSize, C: c("%s*", x.C)} |
| case *ast.ArrayType: |
| if t.Len == nil { |
| // Slice: pointer, len, cap. |
| return &Type{Size: p.PtrSize * 3, Align: p.PtrSize, C: c("GoSlice")} |
| } |
| // Non-slice array types are not supported. |
| case *ast.StructType: |
| // Not supported. |
| case *ast.FuncType: |
| return &Type{Size: p.PtrSize, Align: p.PtrSize, C: c("void*")} |
| case *ast.InterfaceType: |
| return &Type{Size: 2 * p.PtrSize, Align: p.PtrSize, C: c("GoInterface")} |
| case *ast.MapType: |
| return &Type{Size: p.PtrSize, Align: p.PtrSize, C: c("GoMap")} |
| case *ast.ChanType: |
| return &Type{Size: p.PtrSize, Align: p.PtrSize, C: c("GoChan")} |
| case *ast.Ident: |
| goTypesFixup := func(r *Type) *Type { |
| if r.Size == 0 { // int or uint |
| rr := new(Type) |
| *rr = *r |
| rr.Size = p.IntSize |
| rr.Align = p.IntSize |
| r = rr |
| } |
| if r.Align > p.PtrSize { |
| r.Align = p.PtrSize |
| } |
| return r |
| } |
| // Look up the type in the top level declarations. |
| // TODO: Handle types defined within a function. |
| for _, d := range p.Decl { |
| gd, ok := d.(*ast.GenDecl) |
| if !ok || gd.Tok != token.TYPE { |
| continue |
| } |
| for _, spec := range gd.Specs { |
| ts, ok := spec.(*ast.TypeSpec) |
| if !ok { |
| continue |
| } |
| if ts.Name.Name == t.Name { |
| return p.cgoType(ts.Type) |
| } |
| } |
| } |
| if def := typedef[t.Name]; def != nil { |
| if defgo, ok := def.Go.(*ast.Ident); ok { |
| switch defgo.Name { |
| case "complex64", "complex128": |
| // MSVC does not support the _Complex keyword |
| // nor the complex macro. |
| // Use GoComplex64 and GoComplex128 instead, |
| // which are typedef-ed to a compatible type. |
| // See go.dev/issues/36233. |
| return goTypesFixup(goTypes[defgo.Name]) |
| } |
| } |
| return def |
| } |
| if t.Name == "uintptr" { |
| return &Type{Size: p.PtrSize, Align: p.PtrSize, C: c("GoUintptr")} |
| } |
| if t.Name == "string" { |
| // The string data is 1 pointer + 1 (pointer-sized) int. |
| return &Type{Size: 2 * p.PtrSize, Align: p.PtrSize, C: c("GoString")} |
| } |
| if t.Name == "error" { |
| return &Type{Size: 2 * p.PtrSize, Align: p.PtrSize, C: c("GoInterface")} |
| } |
| if r, ok := goTypes[t.Name]; ok { |
| return goTypesFixup(r) |
| } |
| error_(e.Pos(), "unrecognized Go type %s", t.Name) |
| return &Type{Size: 4, Align: 4, C: c("int")} |
| case *ast.SelectorExpr: |
| id, ok := t.X.(*ast.Ident) |
| if ok && id.Name == "unsafe" && t.Sel.Name == "Pointer" { |
| return &Type{Size: p.PtrSize, Align: p.PtrSize, C: c("void*")} |
| } |
| } |
| error_(e.Pos(), "Go type not supported in export: %s", gofmt(e)) |
| return &Type{Size: 4, Align: 4, C: c("int")} |
| } |
| |
| const gccProlog = ` |
| #line 1 "cgo-gcc-prolog" |
| /* |
| If x and y are not equal, the type will be invalid |
| (have a negative array count) and an inscrutable error will come |
| out of the compiler and hopefully mention "name". |
| */ |
| #define __cgo_compile_assert_eq(x, y, name) typedef char name[(x-y)*(x-y)*-2UL+1UL]; |
| |
| /* Check at compile time that the sizes we use match our expectations. */ |
| #define __cgo_size_assert(t, n) __cgo_compile_assert_eq(sizeof(t), (size_t)n, _cgo_sizeof_##t##_is_not_##n) |
| |
| __cgo_size_assert(char, 1) |
| __cgo_size_assert(short, 2) |
| __cgo_size_assert(int, 4) |
| typedef long long __cgo_long_long; |
| __cgo_size_assert(__cgo_long_long, 8) |
| __cgo_size_assert(float, 4) |
| __cgo_size_assert(double, 8) |
| |
| extern char* _cgo_topofstack(void); |
| |
| /* |
| We use packed structs, but they are always aligned. |
| The pragmas and address-of-packed-member are only recognized as warning |
| groups in clang 4.0+, so ignore unknown pragmas first. |
| */ |
| #pragma GCC diagnostic ignored "-Wunknown-pragmas" |
| #pragma GCC diagnostic ignored "-Wpragmas" |
| #pragma GCC diagnostic ignored "-Waddress-of-packed-member" |
| |
| #include <errno.h> |
| #include <string.h> |
| ` |
| |
| // Prologue defining TSAN functions in C. |
| const noTsanProlog = ` |
| #define CGO_NO_SANITIZE_THREAD |
| #define _cgo_tsan_acquire() |
| #define _cgo_tsan_release() |
| ` |
| |
| // This must match the TSAN code in runtime/cgo/libcgo.h. |
| // This is used when the code is built with the C/C++ Thread SANitizer, |
| // which is not the same as the Go race detector. |
| // __tsan_acquire tells TSAN that we are acquiring a lock on a variable, |
| // in this case _cgo_sync. __tsan_release releases the lock. |
| // (There is no actual lock, we are just telling TSAN that there is.) |
| // |
| // When we call from Go to C we call _cgo_tsan_acquire. |
| // When the C function returns we call _cgo_tsan_release. |
| // Similarly, when C calls back into Go we call _cgo_tsan_release |
| // and then call _cgo_tsan_acquire when we return to C. |
| // These calls tell TSAN that there is a serialization point at the C call. |
| // |
| // This is necessary because TSAN, which is a C/C++ tool, can not see |
| // the synchronization in the Go code. Without these calls, when |
| // multiple goroutines call into C code, TSAN does not understand |
| // that the calls are properly synchronized on the Go side. |
| // |
| // To be clear, if the calls are not properly synchronized on the Go side, |
| // we will be hiding races. But when using TSAN on mixed Go C/C++ code |
| // it is more important to avoid false positives, which reduce confidence |
| // in the tool, than to avoid false negatives. |
| const yesTsanProlog = ` |
| #line 1 "cgo-tsan-prolog" |
| #define CGO_NO_SANITIZE_THREAD __attribute__ ((no_sanitize_thread)) |
| |
| long long _cgo_sync __attribute__ ((common)); |
| |
| extern void __tsan_acquire(void*); |
| extern void __tsan_release(void*); |
| |
| __attribute__ ((unused)) |
| static void _cgo_tsan_acquire() { |
| __tsan_acquire(&_cgo_sync); |
| } |
| |
| __attribute__ ((unused)) |
| static void _cgo_tsan_release() { |
| __tsan_release(&_cgo_sync); |
| } |
| ` |
| |
| // Set to yesTsanProlog if we see -fsanitize=thread in the flags for gcc. |
| var tsanProlog = noTsanProlog |
| |
| // noMsanProlog is a prologue defining an MSAN function in C. |
| // This is used when not compiling with -fsanitize=memory. |
| const noMsanProlog = ` |
| #define _cgo_msan_write(addr, sz) |
| ` |
| |
| // yesMsanProlog is a prologue defining an MSAN function in C. |
| // This is used when compiling with -fsanitize=memory. |
| // See the comment above where _cgo_msan_write is called. |
| const yesMsanProlog = ` |
| extern void __msan_unpoison(const volatile void *, size_t); |
| |
| #define _cgo_msan_write(addr, sz) __msan_unpoison((addr), (sz)) |
| ` |
| |
| // msanProlog is set to yesMsanProlog if we see -fsanitize=memory in the flags |
| // for the C compiler. |
| var msanProlog = noMsanProlog |
| |
| const builtinProlog = ` |
| #line 1 "cgo-builtin-prolog" |
| #include <stddef.h> |
| |
| /* Define intgo when compiling with GCC. */ |
| typedef ptrdiff_t intgo; |
| |
| #define GO_CGO_GOSTRING_TYPEDEF |
| typedef struct { const char *p; intgo n; } _GoString_; |
| typedef struct { char *p; intgo n; intgo c; } _GoBytes_; |
| _GoString_ GoString(char *p); |
| _GoString_ GoStringN(char *p, int l); |
| _GoBytes_ GoBytes(void *p, int n); |
| char *CString(_GoString_); |
| void *CBytes(_GoBytes_); |
| void *_CMalloc(size_t); |
| |
| __attribute__ ((unused)) |
| static size_t _GoStringLen(_GoString_ s) { return (size_t)s.n; } |
| |
| __attribute__ ((unused)) |
| static const char *_GoStringPtr(_GoString_ s) { return s.p; } |
| ` |
| |
| const goProlog = ` |
| //go:linkname _cgo_runtime_cgocall runtime.cgocall |
| func _cgo_runtime_cgocall(unsafe.Pointer, uintptr) int32 |
| |
| //go:linkname _cgoCheckPointer runtime.cgoCheckPointer |
| func _cgoCheckPointer(interface{}, interface{}) |
| |
| //go:linkname _cgoCheckResult runtime.cgoCheckResult |
| func _cgoCheckResult(interface{}) |
| ` |
| |
| const gccgoGoProlog = ` |
| func _cgoCheckPointer(interface{}, interface{}) |
| |
| func _cgoCheckResult(interface{}) |
| ` |
| |
| const goStringDef = ` |
| //go:linkname _cgo_runtime_gostring runtime.gostring |
| func _cgo_runtime_gostring(*_Ctype_char) string |
| |
| // GoString converts the C string p into a Go string. |
| func _Cfunc_GoString(p *_Ctype_char) string { |
| return _cgo_runtime_gostring(p) |
| } |
| ` |
| |
| const goStringNDef = ` |
| //go:linkname _cgo_runtime_gostringn runtime.gostringn |
| func _cgo_runtime_gostringn(*_Ctype_char, int) string |
| |
| // GoStringN converts the C data p with explicit length l to a Go string. |
| func _Cfunc_GoStringN(p *_Ctype_char, l _Ctype_int) string { |
| return _cgo_runtime_gostringn(p, int(l)) |
| } |
| ` |
| |
| const goBytesDef = ` |
| //go:linkname _cgo_runtime_gobytes runtime.gobytes |
| func _cgo_runtime_gobytes(unsafe.Pointer, int) []byte |
| |
| // GoBytes converts the C data p with explicit length l to a Go []byte. |
| func _Cfunc_GoBytes(p unsafe.Pointer, l _Ctype_int) []byte { |
| return _cgo_runtime_gobytes(p, int(l)) |
| } |
| ` |
| |
| const cStringDef = ` |
| // CString converts the Go string s to a C string. |
| // |
| // The C string is allocated in the C heap using malloc. |
| // It is the caller's responsibility to arrange for it to be |
| // freed, such as by calling C.free (be sure to include stdlib.h |
| // if C.free is needed). |
| func _Cfunc_CString(s string) *_Ctype_char { |
| if len(s)+1 <= 0 { |
| panic("string too large") |
| } |
| p := _cgo_cmalloc(uint64(len(s)+1)) |
| sliceHeader := struct { |
| p unsafe.Pointer |
| len int |
| cap int |
| }{p, len(s)+1, len(s)+1} |
| b := *(*[]byte)(unsafe.Pointer(&sliceHeader)) |
| copy(b, s) |
| b[len(s)] = 0 |
| return (*_Ctype_char)(p) |
| } |
| ` |
| |
| const cBytesDef = ` |
| // CBytes converts the Go []byte slice b to a C array. |
| // |
| // The C array is allocated in the C heap using malloc. |
| // It is the caller's responsibility to arrange for it to be |
| // freed, such as by calling C.free (be sure to include stdlib.h |
| // if C.free is needed). |
| func _Cfunc_CBytes(b []byte) unsafe.Pointer { |
| p := _cgo_cmalloc(uint64(len(b))) |
| sliceHeader := struct { |
| p unsafe.Pointer |
| len int |
| cap int |
| }{p, len(b), len(b)} |
| s := *(*[]byte)(unsafe.Pointer(&sliceHeader)) |
| copy(s, b) |
| return p |
| } |
| ` |
| |
| const cMallocDef = ` |
| func _Cfunc__CMalloc(n _Ctype_size_t) unsafe.Pointer { |
| return _cgo_cmalloc(uint64(n)) |
| } |
| ` |
| |
| var builtinDefs = map[string]string{ |
| "GoString": goStringDef, |
| "GoStringN": goStringNDef, |
| "GoBytes": goBytesDef, |
| "CString": cStringDef, |
| "CBytes": cBytesDef, |
| "_CMalloc": cMallocDef, |
| } |
| |
| // Definitions for C.malloc in Go and in C. We define it ourselves |
| // since we call it from functions we define, such as C.CString. |
| // Also, we have historically ensured that C.malloc does not return |
| // nil even for an allocation of 0. |
| |
| const cMallocDefGo = ` |
| //go:cgo_import_static _cgoPREFIX_Cfunc__Cmalloc |
| //go:linkname __cgofn__cgoPREFIX_Cfunc__Cmalloc _cgoPREFIX_Cfunc__Cmalloc |
| var __cgofn__cgoPREFIX_Cfunc__Cmalloc byte |
| var _cgoPREFIX_Cfunc__Cmalloc = unsafe.Pointer(&__cgofn__cgoPREFIX_Cfunc__Cmalloc) |
| |
| //go:linkname runtime_throw runtime.throw |
| func runtime_throw(string) |
| |
| //go:cgo_unsafe_args |
| func _cgo_cmalloc(p0 uint64) (r1 unsafe.Pointer) { |
| _cgo_runtime_cgocall(_cgoPREFIX_Cfunc__Cmalloc, uintptr(unsafe.Pointer(&p0))) |
| if r1 == nil { |
| runtime_throw("runtime: C malloc failed") |
| } |
| return |
| } |
| ` |
| |
| // cMallocDefC defines the C version of C.malloc for the gc compiler. |
| // It is defined here because C.CString and friends need a definition. |
| // We define it by hand, rather than simply inventing a reference to |
| // C.malloc, because <stdlib.h> may not have been included. |
| // This is approximately what writeOutputFunc would generate, but |
| // skips the cgo_topofstack code (which is only needed if the C code |
| // calls back into Go). This also avoids returning nil for an |
| // allocation of 0 bytes. |
| const cMallocDefC = ` |
| CGO_NO_SANITIZE_THREAD |
| void _cgoPREFIX_Cfunc__Cmalloc(void *v) { |
| struct { |
| unsigned long long p0; |
| void *r1; |
| } PACKED *a = v; |
| void *ret; |
| _cgo_tsan_acquire(); |
| ret = malloc(a->p0); |
| if (ret == 0 && a->p0 == 0) { |
| ret = malloc(1); |
| } |
| a->r1 = ret; |
| _cgo_tsan_release(); |
| } |
| ` |
| |
| func (p *Package) cPrologGccgo() string { |
| r := strings.NewReplacer( |
| "PREFIX", cPrefix, |
| "GCCGOSYMBOLPREF", p.gccgoSymbolPrefix(), |
| "_cgoCheckPointer", gccgoToSymbol("_cgoCheckPointer"), |
| "_cgoCheckResult", gccgoToSymbol("_cgoCheckResult")) |
| return r.Replace(cPrologGccgo) |
| } |
| |
| const cPrologGccgo = ` |
| #line 1 "cgo-c-prolog-gccgo" |
| #include <stdint.h> |
| #include <stdlib.h> |
| #include <string.h> |
| |
| typedef unsigned char byte; |
| typedef intptr_t intgo; |
| |
| struct __go_string { |
| const unsigned char *__data; |
| intgo __length; |
| }; |
| |
| typedef struct __go_open_array { |
| void* __values; |
| intgo __count; |
| intgo __capacity; |
| } Slice; |
| |
| struct __go_string __go_byte_array_to_string(const void* p, intgo len); |
| struct __go_open_array __go_string_to_byte_array (struct __go_string str); |
| |
| extern void runtime_throw(const char *); |
| |
| const char *_cgoPREFIX_Cfunc_CString(struct __go_string s) { |
| char *p = malloc(s.__length+1); |
| if(p == NULL) |
| runtime_throw("runtime: C malloc failed"); |
| memmove(p, s.__data, s.__length); |
| p[s.__length] = 0; |
| return p; |
| } |
| |
| void *_cgoPREFIX_Cfunc_CBytes(struct __go_open_array b) { |
| char *p = malloc(b.__count); |
| if(p == NULL) |
| runtime_throw("runtime: C malloc failed"); |
| memmove(p, b.__values, b.__count); |
| return p; |
| } |
| |
| struct __go_string _cgoPREFIX_Cfunc_GoString(char *p) { |
| intgo len = (p != NULL) ? strlen(p) : 0; |
| return __go_byte_array_to_string(p, len); |
| } |
| |
| struct __go_string _cgoPREFIX_Cfunc_GoStringN(char *p, int32_t n) { |
| return __go_byte_array_to_string(p, n); |
| } |
| |
| Slice _cgoPREFIX_Cfunc_GoBytes(char *p, int32_t n) { |
| struct __go_string s = { (const unsigned char *)p, n }; |
| return __go_string_to_byte_array(s); |
| } |
| |
| void *_cgoPREFIX_Cfunc__CMalloc(size_t n) { |
| void *p = malloc(n); |
| if(p == NULL && n == 0) |
| p = malloc(1); |
| if(p == NULL) |
| runtime_throw("runtime: C malloc failed"); |
| return p; |
| } |
| |
| struct __go_type_descriptor; |
| typedef struct __go_empty_interface { |
| const struct __go_type_descriptor *__type_descriptor; |
| void *__object; |
| } Eface; |
| |
| extern void runtimeCgoCheckPointer(Eface, Eface) |
| __asm__("runtime.cgoCheckPointer") |
| __attribute__((weak)); |
| |
| extern void localCgoCheckPointer(Eface, Eface) |
| __asm__("GCCGOSYMBOLPREF._cgoCheckPointer"); |
| |
| void localCgoCheckPointer(Eface ptr, Eface arg) { |
| if(runtimeCgoCheckPointer) { |
| runtimeCgoCheckPointer(ptr, arg); |
| } |
| } |
| |
| extern void runtimeCgoCheckResult(Eface) |
| __asm__("runtime.cgoCheckResult") |
| __attribute__((weak)); |
| |
| extern void localCgoCheckResult(Eface) |
| __asm__("GCCGOSYMBOLPREF._cgoCheckResult"); |
| |
| void localCgoCheckResult(Eface val) { |
| if(runtimeCgoCheckResult) { |
| runtimeCgoCheckResult(val); |
| } |
| } |
| ` |
| |
| // builtinExportProlog is a shorter version of builtinProlog, |
| // to be put into the _cgo_export.h file. |
| // For historical reasons we can't use builtinProlog in _cgo_export.h, |
| // because _cgo_export.h defines GoString as a struct while builtinProlog |
| // defines it as a function. We don't change this to avoid unnecessarily |
| // breaking existing code. |
| // The test of GO_CGO_GOSTRING_TYPEDEF avoids a duplicate definition |
| // error if a Go file with a cgo comment #include's the export header |
| // generated by a different package. |
| const builtinExportProlog = ` |
| #line 1 "cgo-builtin-export-prolog" |
| |
| #include <stddef.h> |
| |
| #ifndef GO_CGO_EXPORT_PROLOGUE_H |
| #define GO_CGO_EXPORT_PROLOGUE_H |
| |
| #ifndef GO_CGO_GOSTRING_TYPEDEF |
| typedef struct { const char *p; ptrdiff_t n; } _GoString_; |
| #endif |
| |
| #endif |
| ` |
| |
| func (p *Package) gccExportHeaderProlog() string { |
| return strings.Replace(gccExportHeaderProlog, "GOINTBITS", fmt.Sprint(8*p.IntSize), -1) |
| } |
| |
| // gccExportHeaderProlog is written to the exported header, after the |
| // import "C" comment preamble but before the generated declarations |
| // of exported functions. This permits the generated declarations to |
| // use the type names that appear in goTypes, above. |
| // |
| // The test of GO_CGO_GOSTRING_TYPEDEF avoids a duplicate definition |
| // error if a Go file with a cgo comment #include's the export header |
| // generated by a different package. Unfortunately GoString means two |
| // different things: in this prolog it means a C name for the Go type, |
| // while in the prolog written into the start of the C code generated |
| // from a cgo-using Go file it means the C.GoString function. There is |
| // no way to resolve this conflict, but it also doesn't make much |
| // difference, as Go code never wants to refer to the latter meaning. |
| const gccExportHeaderProlog = ` |
| /* Start of boilerplate cgo prologue. */ |
| #line 1 "cgo-gcc-export-header-prolog" |
| |
| #ifndef GO_CGO_PROLOGUE_H |
| #define GO_CGO_PROLOGUE_H |
| |
| typedef signed char GoInt8; |
| typedef unsigned char GoUint8; |
| typedef short GoInt16; |
| typedef unsigned short GoUint16; |
| typedef int GoInt32; |
| typedef unsigned int GoUint32; |
| typedef long long GoInt64; |
| typedef unsigned long long GoUint64; |
| typedef GoIntGOINTBITS GoInt; |
| typedef GoUintGOINTBITS GoUint; |
| typedef size_t GoUintptr; |
| typedef float GoFloat32; |
| typedef double GoFloat64; |
| #ifdef _MSC_VER |
| #include <complex.h> |
| typedef _Fcomplex GoComplex64; |
| typedef _Dcomplex GoComplex128; |
| #else |
| typedef float _Complex GoComplex64; |
| typedef double _Complex GoComplex128; |
| #endif |
| |
| /* |
| static assertion to make sure the file is being used on architecture |
| at least with matching size of GoInt. |
| */ |
| typedef char _check_for_GOINTBITS_bit_pointer_matching_GoInt[sizeof(void*)==GOINTBITS/8 ? 1:-1]; |
| |
| #ifndef GO_CGO_GOSTRING_TYPEDEF |
| typedef _GoString_ GoString; |
| #endif |
| typedef void *GoMap; |
| typedef void *GoChan; |
| typedef struct { void *t; void *v; } GoInterface; |
| typedef struct { void *data; GoInt len; GoInt cap; } GoSlice; |
| |
| #endif |
| |
| /* End of boilerplate cgo prologue. */ |
| |
| #ifdef __cplusplus |
| extern "C" { |
| #endif |
| ` |
| |
| // gccExportHeaderEpilog goes at the end of the generated header file. |
| const gccExportHeaderEpilog = ` |
| #ifdef __cplusplus |
| } |
| #endif |
| ` |
| |
| // gccgoExportFileProlog is written to the _cgo_export.c file when |
| // using gccgo. |
| // We use weak declarations, and test the addresses, so that this code |
| // works with older versions of gccgo. |
| const gccgoExportFileProlog = ` |
| #line 1 "cgo-gccgo-export-file-prolog" |
| extern _Bool runtime_iscgo __attribute__ ((weak)); |
| |
| static void GoInit(void) __attribute__ ((constructor)); |
| static void GoInit(void) { |
| if(&runtime_iscgo) |
| runtime_iscgo = 1; |
| } |
| |
| extern size_t _cgo_wait_runtime_init_done(void) __attribute__ ((weak)); |
| ` |