// 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 (
"fmt";
"go/ast";
"go/printer";
"os";
"strings";
)
func creat(name string) *os.File {
f, err := os.Open(name, os.O_WRONLY|os.O_CREAT|os.O_TRUNC, 0666);
if err != nil {
fatal("%s", err)
}
return f;
}
// writeOutput creates output files to be compiled by 6g, 6c, and gcc.
// (The comments here say 6g and 6c but the code applies to the 8 and 5 tools too.)
func (p *Prog) writeOutput(srcfile string) {
pkgroot := os.Getenv("GOROOT") + "/pkg/" + os.Getenv("GOOS") + "_" + os.Getenv("GOARCH");
base := srcfile;
if strings.HasSuffix(base, ".go") {
base = base[0 : len(base)-3]
}
fgo1 := creat(base + ".cgo1.go");
fgo2 := creat(base + ".cgo2.go");
fc := creat(base + ".cgo3.c");
fgcc := creat(base + ".cgo4.c");
// Write Go output: Go input with rewrites of C.xxx to _C_xxx.
fmt.Fprintf(fgo1, "// Created by cgo - DO NOT EDIT\n");
fmt.Fprintf(fgo1, "//line %s:1\n", srcfile);
printer.Fprint(fgo1, p.AST);
// 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, "// Created by cgo - DO NOT EDIT\n");
fmt.Fprintf(fgo2, "package %s\n\n", p.Package);
fmt.Fprintf(fgo2, "import \"unsafe\"\n\n");
fmt.Fprintf(fgo2, "type _ unsafe.Pointer\n\n");
for name, def := range p.Typedef {
fmt.Fprintf(fgo2, "type %s ", name);
printer.Fprint(fgo2, def);
fmt.Fprintf(fgo2, "\n");
}
fmt.Fprintf(fgo2, "type _C_void [0]byte\n");
// While we process the vars and funcs, also write 6c and gcc output.
// Gcc output starts with the preamble.
fmt.Fprintf(fgcc, "%s\n", p.Preamble);
fmt.Fprintf(fgcc, "%s\n", gccProlog);
fmt.Fprintf(fc, cProlog, pkgroot, pkgroot, pkgroot, pkgroot, p.Package, p.Package);
for name, def := range p.Vardef {
fmt.Fprintf(fc, "#pragma dynld %s·_C_%s %s \"%s/%s_%s.so\"\n", p.Package, name, name, pkgroot, p.PackagePath, base);
fmt.Fprintf(fgo2, "var _C_%s ", name);
printer.Fprint(fgo2, &ast.StarExpr{X: def.Go});
fmt.Fprintf(fgo2, "\n");
}
fmt.Fprintf(fc, "\n");
for name, def := range p.Funcdef {
// Go func declaration.
d := &ast.FuncDecl{
Name: &ast.Ident{Value: "_C_" + name},
Type: def.Go,
};
printer.Fprint(fgo2, d);
fmt.Fprintf(fgo2, "\n");
if name == "CString" || name == "GoString" {
// The builtins are already defined in the C prolog.
continue
}
// Construct a gcc struct matching the 6c 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 6c convention is to word-align the
// input and output parameters.
structType := "struct {\n";
off := int64(0);
npad := 0;
for i, t := range def.Params {
if off%t.Align != 0 {
pad := t.Align - off%t.Align;
structType += fmt.Sprintf("\t\tchar __pad%d[%d];\n", npad, pad);
off += pad;
npad++;
}
structType += fmt.Sprintf("\t\t%s p%d;\n", t.C, i);
off += t.Size;
}
if off%p.PtrSize != 0 {
pad := p.PtrSize - off%p.PtrSize;
structType += fmt.Sprintf("\t\tchar __pad%d[%d];\n", npad, pad);
off += pad;
npad++;
}
if t := def.Result; t != nil {
if off%t.Align != 0 {
pad := t.Align - off%t.Align;
structType += fmt.Sprintf("\t\tchar __pad%d[%d];\n", npad, pad);
off += pad;
npad++;
}
structType += fmt.Sprintf("\t\t%s r;\n", t.C);
off += t.Size;
}
if off%p.PtrSize != 0 {
pad := p.PtrSize - off%p.PtrSize;
structType += fmt.Sprintf("\t\tchar __pad%d[%d];\n", npad, pad);
off += pad;
npad++;
}
if len(def.Params) == 0 && def.Result == nil {
structType += "\t\tchar unused;\n"; // avoid empty struct
off++;
}
structType += "\t}";
argSize := off;
// C wrapper calls into gcc, passing a pointer to the argument frame.
// Also emit #pragma to get a pointer to the gcc wrapper.
fmt.Fprintf(fc, "#pragma dynld _cgo_%s _cgo_%s \"%s/%s_%s.so\"\n", name, name, pkgroot, p.PackagePath, base);
fmt.Fprintf(fc, "void (*_cgo_%s)(void*);\n", name);
fmt.Fprintf(fc, "\n");
fmt.Fprintf(fc, "void\n");
fmt.Fprintf(fc, "%s·_C_%s(struct{uint8 x[%d];}p)\n", p.Package, name, argSize);
fmt.Fprintf(fc, "{\n");
fmt.Fprintf(fc, "\tcgocall(_cgo_%s, &p);\n", name);
fmt.Fprintf(fc, "}\n");
fmt.Fprintf(fc, "\n");
// Gcc wrapper unpacks the C argument struct
// and calls the actual C function.
fmt.Fprintf(fgcc, "void\n");
fmt.Fprintf(fgcc, "_cgo_%s(void *v)\n", name);
fmt.Fprintf(fgcc, "{\n");
fmt.Fprintf(fgcc, "\t%s *a = v;\n", structType);
fmt.Fprintf(fgcc, "\t");
if def.Result != nil {
fmt.Fprintf(fgcc, "a->r = ")
}
fmt.Fprintf(fgcc, "%s(", name);
for i := range def.Params {
if i > 0 {
fmt.Fprintf(fgcc, ", ")
}
fmt.Fprintf(fgcc, "a->p%d", i);
}
fmt.Fprintf(fgcc, ");\n");
fmt.Fprintf(fgcc, "}\n");
fmt.Fprintf(fgcc, "\n");
}
fgo1.Close();
fgo2.Close();
fc.Close();
fgcc.Close();
}
const gccProlog = `
// Usual nonsense: 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)*-2+1];
// Check at compile time that the sizes we use match our expectations.
#define __cgo_size_assert(t, n) __cgo_compile_assert_eq(sizeof(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)
`
const builtinProlog = `
typedef struct { char *p; int n; } _GoString_;
_GoString_ GoString(char *p);
char *CString(_GoString_);
`
const cProlog = `
#include "runtime.h"
#include "cgocall.h"
#pragma dynld initcgo initcgo "%s/libcgo.so"
#pragma dynld libcgo_thread_start libcgo_thread_start "%s/libcgo.so"
#pragma dynld _cgo_malloc _cgo_malloc "%s/libcgo.so"
#pragma dynld _cgo_free free "%s/libcgo.so"
void
%s·_C_GoString(int8 *p, String s)
{
s = gostring((byte*)p);
FLUSH(&s);
}
void
%s·_C_CString(String s, int8 *p)
{
p = cmalloc(s.len+1);
mcpy((byte*)p, s.str, s.len);
p[s.len] = 0;
FLUSH(&p);
}
`
|