/* ----------------------------------------------------------------------------- * This file is part of SWIG, which is licensed as a whole under version 3 * (or any later version) of the GNU General Public License. Some additional * terms also apply to certain portions of SWIG. The full details of the SWIG * license and copyrights can be found in the LICENSE and COPYRIGHT files * included with the SWIG source code as distributed by the SWIG developers * and at https://www.swig.org/legal.html. * * go.cxx * * Go language module for SWIG. * ----------------------------------------------------------------------------- */ #include "swigmod.h" #include "cparse.h" #include /* ---------------------------------------------------------------------- * siphash() * * 64-bit SipHash-2-4 to generate unique id for each module * ---------------------------------------------------------------------- */ // An unsigned 64-bit integer that works on a 32-bit host. typedef struct { // Assume unsigned long is at least 32 bits. unsigned long hi; unsigned long lo; } swig_uint64; // Rotate v left by bits, which must be <= 32. static inline void _rotl(swig_uint64 *v, int bits) { assert(bits <= 32); unsigned long tmp = v->hi; if (bits == 32) { v->hi = v->lo; v->lo = tmp; } else { v->hi = (tmp << bits) | ((0xfffffffful & v->lo) >> (32 - bits)); v->lo = (v->lo << bits) | ((0xfffffffful & tmp) >> (32 - bits)); } } // dst ^= src static inline void _xor(swig_uint64 *dst, swig_uint64 *src) { dst->lo ^= src->lo; dst->hi ^= src->hi; } // dst += src static inline void _add(swig_uint64 *dst, swig_uint64 *src) { dst->lo += src->lo; dst->hi += src->hi + ((dst->lo & 0xfffffffful) < (src->lo&0xfffffffful) ? 1 : 0); } #define SIPROUND \ do { \ _add(&v0, &v1); _rotl(&v1, 13); _xor(&v1, &v0); _rotl(&v0, 32); \ _add(&v2, &v3); _rotl(&v3, 16); _xor(&v3, &v2); \ _add(&v0, &v3); _rotl(&v3, 21); _xor(&v3, &v0); \ _add(&v2, &v1); _rotl(&v1, 17); _xor(&v1, &v2); _rotl(&v2, 32); \ } while(0) // Set out to the hash of inc/inlen. static void siphash(swig_uint64 *out, const char *inc, unsigned long inlen) { /* "somepseudorandomlygeneratedbytes" */ swig_uint64 v0 = {0x736f6d65UL, 0x70736575UL}; swig_uint64 v1 = {0x646f7261UL, 0x6e646f6dUL}; swig_uint64 v2 = {0x6c796765UL, 0x6e657261UL}; swig_uint64 v3 = {0x74656462UL, 0x79746573UL}; swig_uint64 b; /* hard-coded k. */ swig_uint64 k0 = {0x07060504UL, 0x03020100UL}; swig_uint64 k1 = {0x0F0E0D0CUL, 0x0B0A0908UL}; int i; const int cROUNDS = 2, dROUNDS = 4; const unsigned char *in = (const unsigned char *)inc; const unsigned char *end = in + inlen - (inlen % 8); int left = inlen & 7; _xor(&v3, &k1); _xor(&v2, &k0); _xor(&v1, &k1); _xor(&v0, &k0); for (; in != end; in += 8) { b.hi = 0; b.lo = 0; for (i = 0; i < 4; i++) { b.lo |= ((unsigned long)in[i]) << (8*i); } for (i = 0; i < 4; i++) { b.hi |= ((unsigned long)in[i+4]) << (8*i); } _xor(&v3, &b); for (i = 0; i < cROUNDS; i++) { SIPROUND; } _xor(&v0, &b); } b.hi = (inlen & 0xff)<<24; b.lo = 0; for (; left; left--) { if (left > 4) { b.hi |= ((unsigned long)in[left-1]) << (8*left-8-32); } else { b.lo |= ((unsigned long)in[left-1]) << (8*left-8); } } _xor(&v3, &b); for(i=0; ilo = 0; out->hi = 0; _xor(out, &v0); _xor(out, &v1); _xor(out, &v2); _xor(out, &v3); } #undef SIPROUND class GO:public Language { static const char *const usage; // Go package name. String *package; // SWIG module name. String *module; // Flag for generating gccgo output. bool gccgo_flag; // Prefix to use with gccgo. String *go_prefix; // -fgo-prefix option. String *prefix_option; // -fgo-pkgpath option. String *pkgpath_option; // Prefix for translating %import directive to import statements. String *import_prefix; // Whether to use a shared library. bool use_shlib; // Name of shared library to import. String *soname; // Size in bits of the Go type "int". 0 if not specified. int intgo_type_size; /* Output files */ File *f_c_begin; File *f_go_begin; /* Output fragments */ File *f_c_runtime; File *f_c_header; File *f_c_wrappers; File *f_c_init; File *f_c_directors; File *f_c_directors_h; File *f_go_imports; File *f_go_runtime; File *f_go_header; File *f_go_wrappers; File *f_go_directors; File *f_cgo_comment; File *f_cgo_comment_typedefs; // True if we imported a module. bool saw_import; // If not NULL, name of import package being processed. String *imported_package; // Build interface methods while handling a class. This is only // non-NULL when we are handling methods. String *interfaces; // The class node while handling a class. This is only non-NULL // when we are handling methods. Node *class_node; // The class name while handling a class. This is only non-NULL // when we are handling methods. This is the name of the class as // SWIG sees it. String *class_name; // The receiver name while handling a class. This is only non-NULL // when we are handling methods. This is the name of the class // as run through goCPointerType. String *class_receiver; // A hash table of method names that we have seen when processing a // class. This lets us detect base class methods that we don't want // to use. Hash *class_methods; // True when we are generating the wrapper functions for a variable. bool making_variable_wrappers; // True when working with a static member function. bool is_static_member_function; // A hash table of enum types that we have seen but which may not have // been defined. The index is a SwigType. Hash *undefined_enum_types; // A hash table of types that we have seen but which may not have // been defined. The index is a SwigType. Hash *undefined_types; // A hash table of classes which were defined. The index is a Go // type name. Hash *defined_types; // A hash table of all the go_imports already imported. The index is a full // import name e.g. '"runtime"' or '_ "runtime/cgo"' or 'sc "syscall"'. Hash *go_imports; // A unique ID used to make public symbols unique. String *unique_id; public: GO():package(NULL), module(NULL), gccgo_flag(false), go_prefix(NULL), prefix_option(NULL), pkgpath_option(NULL), import_prefix(NULL), use_shlib(false), soname(NULL), intgo_type_size(0), f_c_begin(NULL), f_go_begin(NULL), f_c_runtime(NULL), f_c_header(NULL), f_c_wrappers(NULL), f_c_init(NULL), f_c_directors(NULL), f_c_directors_h(NULL), f_go_imports(NULL), f_go_runtime(NULL), f_go_header(NULL), f_go_wrappers(NULL), f_go_directors(NULL), f_cgo_comment(NULL), f_cgo_comment_typedefs(NULL), saw_import(false), imported_package(NULL), interfaces(NULL), class_node(NULL), class_name(NULL), class_receiver(NULL), class_methods(NULL), making_variable_wrappers(false), is_static_member_function(false), undefined_enum_types(NULL), undefined_types(NULL), defined_types(NULL), go_imports(NULL), unique_id(NULL) { director_multiple_inheritance = 1; director_language = 1; director_prot_ctor_code = NewString("_swig_gopanic(\"accessing abstract class or protected constructor\");"); } private: /* ------------------------------------------------------------ * main() * ------------------------------------------------------------ */ virtual void main(int argc, char *argv[]) { SWIG_library_directory("go"); bool saw_nocgo_flag = false; // Process command line options. for (int i = 1; i < argc; i++) { if (argv[i]) { if (strcmp(argv[i], "-package") == 0) { if (argv[i + 1]) { package = NewString(argv[i + 1]); Swig_mark_arg(i); Swig_mark_arg(i + 1); i++; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-cgo") == 0) { Swig_mark_arg(i); } else if (strcmp(argv[i], "-no-cgo") == 0) { Swig_mark_arg(i); saw_nocgo_flag = true; } else if (strcmp(argv[i], "-gccgo") == 0) { Swig_mark_arg(i); gccgo_flag = true; } else if (strcmp(argv[i], "-go-prefix") == 0) { if (argv[i + 1]) { prefix_option = NewString(argv[i + 1]); Swig_mark_arg(i); Swig_mark_arg(i + 1); i++; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-go-pkgpath") == 0) { if (argv[i + 1]) { pkgpath_option = NewString(argv[i + 1]); Swig_mark_arg(i); Swig_mark_arg(i + 1); i++; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-import-prefix") == 0) { if (argv[i + 1]) { import_prefix = NewString(argv[i + 1]); Swig_mark_arg(i); Swig_mark_arg(i + 1); i++; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-use-shlib") == 0) { Swig_mark_arg(i); use_shlib = true; } else if (strcmp(argv[i], "-soname") == 0) { if (argv[i + 1]) { soname = NewString(argv[i + 1]); Swig_mark_arg(i); Swig_mark_arg(i + 1); i++; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-longsize") == 0) { // Ignore for backward compatibility. if (argv[i + 1]) { Swig_mark_arg(i); Swig_mark_arg(i + 1); ++i; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-intgosize") == 0) { if (argv[i + 1]) { intgo_type_size = atoi(argv[i + 1]); if (intgo_type_size != 32 && intgo_type_size != 64) { Printf(stderr, "-intgosize not 32 or 64\n"); Swig_arg_error(); } Swig_mark_arg(i); Swig_mark_arg(i + 1); ++i; } else { Swig_arg_error(); } } else if (strcmp(argv[i], "-help") == 0) { Printf(stdout, "%s\n", usage); } } } if (saw_nocgo_flag) { Printf(stderr, "SWIG -go: -no-cgo option is no longer supported\n"); Exit(EXIT_FAILURE); } if (gccgo_flag && !pkgpath_option && !prefix_option) { prefix_option = NewString("go"); } // Add preprocessor symbol to parser. Preprocessor_define("SWIGGO 1", 0); if (gccgo_flag) { Preprocessor_define("SWIGGO_GCCGO 1", 0); } if (intgo_type_size == 32) { Preprocessor_define("SWIGGO_INTGO_SIZE 32", 0); } else if (intgo_type_size == 64) { Preprocessor_define("SWIGGO_INTGO_SIZE 64", 0); } else { Preprocessor_define("SWIGGO_INTGO_SIZE 0", 0); } // Add typemap definitions. SWIG_typemap_lang("go"); SWIG_config_file("go.swg"); allow_overloading(); } /* --------------------------------------------------------------------- * top() * * For gc, we are going to create the following files: * * 1) A .c or .cxx file compiled with gcc. This file will contain * function wrappers. Each wrapper will take a pointer to a * struct holding the arguments, unpack them, and call the real * function. * * 2) A .go file which defines the Go form of all types, and which * defines Go function wrappers. Each wrapper will call the C * function wrapper in the second file. * * 3) A .c file compiled with 6c/8c. This file will define * Go-callable C function wrappers. Each wrapper will use * cgocall to call the function wrappers in the first file. * * When generating code for gccgo, we don't need the third file, and * the function wrappers in the first file have a different form. * * --------------------------------------------------------------------- */ virtual int top(Node *n) { Node *optionsnode = Getattr(Getattr(n, "module"), "options"); if (optionsnode) { if (Getattr(optionsnode, "directors")) { allow_directors(); } if (Getattr(optionsnode, "dirprot")) { allow_dirprot(); } allow_allprotected(GetFlag(optionsnode, "allprotected")); } module = Getattr(n, "name"); if (!package) { package = Copy(module); } if (!soname && use_shlib) { soname = Copy(package); Append(soname, ".so"); } if (gccgo_flag) { String *pref; if (pkgpath_option) { pref = pkgpath_option; } else { pref = prefix_option; } go_prefix = NewString(""); for (char *p = Char(pref); *p != '\0'; p++) { if ((*p >= 'A' && *p <= 'Z') || (*p >= 'a' && *p <= 'z') || (*p >= '0' && *p <= '9') || *p == '.' || *p == '$') { Putc(*p, go_prefix); } else { Putc('_', go_prefix); } } if (!pkgpath_option) { Append(go_prefix, "."); Append(go_prefix, getModuleName(package)); } } // Get filenames. String *swig_filename = Getattr(n, "infile"); String *c_filename = Getattr(n, "outfile"); String *c_filename_h = Getattr(n, "outfile_h"); String *go_filename = NewString(""); Printf(go_filename, "%s%s.go", SWIG_output_directory(), module); // Generate a unique ID based on a hash of the SWIG input. swig_uint64 hash = {0, 0}; FILE *swig_input = Swig_open(swig_filename); if (swig_input == NULL) { FileErrorDisplay(swig_filename); Exit(EXIT_FAILURE); } String *swig_input_content = Swig_read_file(swig_input); siphash(&hash, Char(swig_input_content), Len(swig_input_content)); Delete(swig_input_content); fclose(swig_input); unique_id = NewString(""); Printf(unique_id, "_%s_%08x%08x", getModuleName(package), hash.hi, hash.lo); // Open files. f_c_begin = NewFile(c_filename, "w", SWIG_output_files()); if (!f_c_begin) { FileErrorDisplay(c_filename); Exit(EXIT_FAILURE); } if (directorsEnabled()) { if (!c_filename_h) { Printf(stderr, "Unable to determine outfile_h\n"); Exit(EXIT_FAILURE); } f_c_directors_h = NewFile(c_filename_h, "w", SWIG_output_files()); if (!f_c_directors_h) { FileErrorDisplay(c_filename_h); Exit(EXIT_FAILURE); } } f_go_begin = NewFile(go_filename, "w", SWIG_output_files()); if (!f_go_begin) { FileErrorDisplay(go_filename); Exit(EXIT_FAILURE); } f_c_runtime = NewString(""); f_c_header = NewString(""); f_c_wrappers = NewString(""); f_c_init = NewString(""); f_c_directors = NewString(""); f_go_imports = NewString(""); f_go_runtime = NewString(""); f_go_header = NewString(""); f_go_wrappers = NewString(""); f_go_directors = NewString(""); f_cgo_comment = NewString(""); f_cgo_comment_typedefs = NewString(""); Swig_register_filebyname("begin", f_c_begin); Swig_register_filebyname("runtime", f_c_runtime); Swig_register_filebyname("header", f_c_header); Swig_register_filebyname("wrapper", f_c_wrappers); Swig_register_filebyname("init", f_c_init); Swig_register_filebyname("director", f_c_directors); Swig_register_filebyname("director_h", f_c_directors_h); Swig_register_filebyname("go_begin", f_go_begin); Swig_register_filebyname("go_imports", f_go_imports); Swig_register_filebyname("go_runtime", f_go_runtime); Swig_register_filebyname("go_header", f_go_header); Swig_register_filebyname("go_wrapper", f_go_wrappers); Swig_register_filebyname("go_director", f_go_directors); Swig_register_filebyname("cgo_comment", f_cgo_comment); Swig_register_filebyname("cgo_comment_typedefs", f_cgo_comment_typedefs); Swig_banner(f_c_begin); Swig_obligatory_macros(f_c_runtime, "GO"); if (CPlusPlus) { Printf(f_c_begin, "\n// source: %s\n\n", swig_filename); } else { Printf(f_c_begin, "\n/* source: %s */\n\n", swig_filename); } Printf(f_c_runtime, "#define SWIGMODULE %s\n", module); if (gccgo_flag) { Printf(f_c_runtime, "#define SWIGGO_PREFIX %s\n", go_prefix); } if (directorsEnabled()) { Printf(f_c_runtime, "#define SWIG_DIRECTORS\n"); Swig_banner(f_c_directors_h); Printf(f_c_directors_h, "\n// source: %s\n\n", swig_filename); Printf(f_c_directors_h, "#ifndef SWIG_%s_WRAP_H_\n", module); Printf(f_c_directors_h, "#define SWIG_%s_WRAP_H_\n\n", module); Printf(f_c_directors_h, "class Swig_memory;\n\n"); Printf(f_c_directors, "\n// C++ director class methods.\n"); String *filename = Swig_file_filename(c_filename_h); Printf(f_c_directors, "#include \"%s\"\n\n", filename); Delete(filename); } Swig_banner(f_go_begin); Printf(f_go_begin, "\n// source: %s\n", swig_filename); Printv(f_cgo_comment_typedefs, "/*\n", NULL); // The cgo program defines the intgo type after our function // definitions, but we want those definitions to be able to use // intgo also. Printv(f_cgo_comment_typedefs, "#define intgo swig_intgo\n", NULL); Printv(f_cgo_comment_typedefs, "typedef void *swig_voidp;\n", NULL); // Output module initialization code. Printf(f_go_begin, "\npackage %s\n\n", getModuleName(package)); // All the C++ wrappers should be extern "C". Printv(f_c_wrappers, "#ifdef __cplusplus\n", "extern \"C\" {\n", "#endif\n\n", NULL); // Set up the hash table for types not defined by SWIG. undefined_enum_types = NewHash(); undefined_types = NewHash(); defined_types = NewHash(); go_imports = NewHash(); // Emit code. Language::top(n); if (directorsEnabled()) { // Insert director runtime into the f_runtime file (make it occur before %header section) Swig_insert_file("director_common.swg", f_c_runtime); Swig_insert_file("director.swg", f_c_runtime); } Delete(go_imports); // Write out definitions for the types not defined by SWIG. if (Len(undefined_enum_types) > 0) Printv(f_go_wrappers, "\n", NULL); for (Iterator p = First(undefined_enum_types); p.key; p = Next(p)) { String *name = p.item; Printv(f_go_wrappers, "type ", name, " int\n", NULL); } Printv(f_go_wrappers, "\n", NULL); for (Iterator p = First(undefined_types); p.key; p = Next(p)) { String *ty = goType(NULL, p.key); if (!Getattr(defined_types, ty)) { String *cp = goCPointerType(p.key, false); if (!Getattr(defined_types, cp)) { Printv(f_go_wrappers, "type ", cp, " uintptr\n", NULL); Printv(f_go_wrappers, "type ", ty, " interface {\n", NULL); Printv(f_go_wrappers, "\tSwigcptr() uintptr;\n", NULL); Printv(f_go_wrappers, "}\n", NULL); Printv(f_go_wrappers, "func (p ", cp, ") Swigcptr() uintptr {\n", NULL); Printv(f_go_wrappers, "\treturn uintptr(p)\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); } Delete(cp); } Delete(ty); } Delete(undefined_enum_types); Delete(undefined_types); Delete(defined_types); /* Write and cleanup */ Dump(f_c_header, f_c_runtime); if (directorsEnabled()) { Printf(f_c_directors_h, "#endif\n"); Delete(f_c_directors_h); f_c_directors_h = NULL; Dump(f_c_directors, f_c_runtime); Delete(f_c_directors); f_c_directors = NULL; } // End the extern "C". Printv(f_c_wrappers, "#ifdef __cplusplus\n", "}\n", "#endif\n\n", NULL); // End the cgo comment. Printv(f_cgo_comment, "#undef intgo\n", NULL); Printv(f_cgo_comment, "*/\n", NULL); Printv(f_cgo_comment, "import \"C\"\n", NULL); Printv(f_cgo_comment, "\n", NULL); bool need_panic = false; if (Strstr(f_c_runtime, "SWIG_contract_assert(") != 0 || Strstr(f_c_wrappers, "SWIG_contract_assert(") != 0) { Printv(f_c_begin, "\n#define SWIG_contract_assert(expr, msg) if (!(expr)) { _swig_gopanic(msg); } else\n\n", NULL); need_panic = true; } if (!gccgo_flag && (need_panic || Strstr(f_c_runtime, "_swig_gopanic") != 0 || Strstr(f_c_wrappers, "_swig_gopanic") != 0)) { Printv(f_go_header, "//export cgo_panic_", unique_id, "\n", NULL); Printv(f_go_header, "func cgo_panic_", unique_id, "(p *byte) {\n", NULL); Printv(f_go_header, "\ts := (*[1024]byte)(unsafe.Pointer(p))[:]\n", NULL); Printv(f_go_header, "\tfor i, b := range s {\n", NULL); Printv(f_go_header, "\t\tif b == 0 {\n", NULL); Printv(f_go_header, "\t\t\tpanic(string(s[:i]))\n", NULL); Printv(f_go_header, "\t\t}\n", NULL); Printv(f_go_header, "\t}\n", NULL); Printv(f_go_header, "\tpanic(string(s))\n", NULL); Printv(f_go_header, "}\n\n", NULL); Printv(f_c_begin, "\nextern\n", NULL); Printv(f_c_begin, "#ifdef __cplusplus\n", NULL); Printv(f_c_begin, " \"C\"\n", NULL); Printv(f_c_begin, "#endif\n", NULL); Printv(f_c_begin, " void cgo_panic_", unique_id, "(const char*);\n", NULL); Printv(f_c_begin, "static void _swig_gopanic(const char *p) {\n", NULL); Printv(f_c_begin, " cgo_panic_", unique_id, "(p);\n", NULL); Printv(f_c_begin, "}\n\n", NULL); } Dump(f_c_runtime, f_c_begin); Dump(f_c_wrappers, f_c_begin); Dump(f_c_init, f_c_begin); Dump(f_cgo_comment_typedefs, f_go_begin); Dump(f_cgo_comment, f_go_begin); Dump(f_go_imports, f_go_begin); Dump(f_go_header, f_go_begin); Dump(f_go_runtime, f_go_begin); Dump(f_go_wrappers, f_go_begin); if (directorsEnabled()) { Dump(f_go_directors, f_go_begin); } Delete(f_c_runtime); Delete(f_c_header); Delete(f_c_wrappers); Delete(f_c_init); Delete(f_go_imports); Delete(f_go_runtime); Delete(f_go_header); Delete(f_go_wrappers); Delete(f_go_directors); Delete(f_cgo_comment); Delete(f_cgo_comment_typedefs); Delete(f_c_begin); Delete(f_go_begin); return SWIG_OK; } /* ------------------------------------------------------------ * importDirective() * * Handle a SWIG import statement by generating a Go import * statement. * ------------------------------------------------------------ */ virtual int importDirective(Node *n) { String *hold_import = imported_package; String *modname = Getattr(n, "module"); if (modname) { if (!Getattr(go_imports, modname)) { Setattr(go_imports, modname, modname); Printv(f_go_imports, "import \"", NULL); if (import_prefix) { Printv(f_go_imports, import_prefix, "/", NULL); } Printv(f_go_imports, modname, "\"\n", NULL); } imported_package = modname; saw_import = true; } int r = Language::importDirective(n); imported_package = hold_import; return r; } /* ---------------------------------------------------------------------- * Language::insertDirective() * * If the section is go_imports, store them for later. * ---------------------------------------------------------------------- */ virtual int insertDirective(Node *n) { char *section = Char(Getattr(n, "section")); if ((ImportMode && !Getattr(n, "generated")) || !section || (strcmp(section, "go_imports") != 0)) { return Language::insertDirective(n); } char *code = Char(Getattr(n, "code")); char *pch = strtok(code, ","); while (pch != NULL) { // Do not import same thing more than once. if (!Getattr(go_imports, pch)) { Setattr(go_imports, pch, pch); Printv(f_go_imports, "import ", pch, "\n", NULL); } pch = strtok(NULL, ","); } return SWIG_OK; } /* ---------------------------------------------------------------------- * functionWrapper() * * Implement a function. * ---------------------------------------------------------------------- */ virtual int functionWrapper(Node *n) { if (GetFlag(n, "feature:ignore")) { return SWIG_OK; } // We don't need explicit calls. if (GetFlag(n, "explicitcall")) { return SWIG_OK; } // Don't emit constructors for abstract director classes. They // will never succeed anyhow. if (Swig_methodclass(n) && Swig_directorclass(n) && Strcmp(Char(Getattr(n, "wrap:action")), director_prot_ctor_code) == 0) { return SWIG_OK; } String *name = Getattr(n, "sym:name"); String *nodetype = Getattr(n, "nodeType"); bool is_static = is_static_member_function || isStatic(n); bool is_friend = isFriend(n); bool is_ctor_dtor = false; SwigType *result = Getattr(n, "type"); // For some reason SWIG changs the "type" value during the call to // functionWrapper. We need to remember the type for possible // overload processing. Setattr(n, "go:type", Copy(result)); String *go_name; String *r1 = NULL; if (making_variable_wrappers) { // Change the name of the variable setter and getter functions // to be more Go like. bool is_set = Strcmp(Char(name) + Len(name) - 4, "_set") == 0; assert(is_set || Strcmp(Char(name) + Len(name) - 4, "_get") == 0); // Start with Set or Get. go_name = NewString(is_set ? "Set" : "Get"); // If this is a static variable, put in the class name, // capitalized. if (is_static && class_name) { String *ccn = exportedName(class_name); Append(go_name, ccn); Delete(ccn); } // Add the rest of the name, capitalized, dropping the _set or // _get. String *c1 = removeClassname(name); String *c2 = exportedName(c1); char *p = Char(c2); int len = Len(p); for (int i = 0; i < len - 4; ++i) { Putc(p[i], go_name); } Delete(c2); Delete(c1); if (!checkIgnoredParameters(n, go_name)) { Delete(go_name); return SWIG_NOWRAP; } } else if (Cmp(nodetype, "constructor") == 0) { is_ctor_dtor = true; // Change the name of a constructor to be more Go like. Change // new_ to New, and capitalize the class name. assert(Strncmp(name, "new_", 4) == 0); String *c1 = NewString(Char(name) + 4); String *c2 = exportedName(c1); go_name = NewString("New"); Append(go_name, c2); Delete(c2); Delete(c1); if (Swig_methodclass(n) && Swig_directorclass(n)) { // The core SWIG code skips the first parameter when // generating the $nondirector_new string. Recreate the // action in this case. But don't it if we are using the // special code for an abstract class. String *call = Swig_cppconstructor_call(getClassType(), Getattr(n, "parms")); SwigType *type = Copy(getClassType()); SwigType_add_pointer(type); String *cres = Swig_cresult(type, Swig_cresult_name(), call); Setattr(n, "wrap:action", cres); } } else if (Cmp(nodetype, "destructor") == 0) { // No need to emit protected destructors. if (!is_public(n)) { return SWIG_OK; } is_ctor_dtor = true; // Change the name of a destructor to be more Go like. Change // delete_ to Delete and capitalize the class name. assert(Strncmp(name, "delete_", 7) == 0); String *c1 = NewString(Char(name) + 7); String *c2 = exportedName(c1); go_name = NewString("Delete"); Append(go_name, c2); Delete(c2); Delete(c1); result = NewString("void"); r1 = result; } else { if (!checkFunctionVisibility(n, NULL)) { return SWIG_OK; } go_name = buildGoName(name, is_static, is_friend); if (!checkIgnoredParameters(n, go_name)) { Delete(go_name); return SWIG_NOWRAP; } } String *overname = NULL; if (Getattr(n, "sym:overloaded")) { overname = Getattr(n, "sym:overname"); } else { String *scope; if (!class_name || is_static || is_ctor_dtor) { scope = NULL; } else { scope = NewString("swiggoscope."); Append(scope, class_name); } if (!checkNameConflict(go_name, n, scope)) { Delete(go_name); return SWIG_NOWRAP; } } String *wname = Swig_name_wrapper(name); if (overname) { Append(wname, overname); } Append(wname, unique_id); Setattr(n, "wrap:name", wname); ParmList *parms = Getattr(n, "parms"); Setattr(n, "wrap:parms", parms); int r = makeWrappers(n, go_name, overname, wname, NULL, parms, result, is_static); if (r != SWIG_OK) { return r; } if (Getattr(n, "sym:overloaded") && !Getattr(n, "sym:nextSibling")) { String *scope ; if (!class_name || is_static || is_ctor_dtor) { scope = NULL; } else { scope = NewString("swiggoscope."); Append(scope, class_name); } if (!checkNameConflict(go_name, n, scope)) { Delete(go_name); return SWIG_NOWRAP; } String *receiver = class_receiver; if (is_static || is_ctor_dtor) { receiver = NULL; } r = makeDispatchFunction(n, go_name, receiver, is_static, NULL, false); if (r != SWIG_OK) { return r; } } Delete(wname); Delete(go_name); Delete(r1); return SWIG_OK; } /* ---------------------------------------------------------------------- * staticmemberfunctionHandler() * * For some reason the language code removes the "storage" attribute * for a static function before calling functionWrapper, which means * that we have no way of knowing whether a function is static or * not. That makes no sense in the Go context. Here we note that a * function is static. * ---------------------------------------------------------------------- */ int staticmemberfunctionHandler(Node *n) { assert(!is_static_member_function); is_static_member_function = true; int r = Language::staticmemberfunctionHandler(n); is_static_member_function = false; return r; } /* ---------------------------------------------------------------------- * makeWrappers() * * Write out the various function wrappers. * n: The function we are emitting. * go_name: The name of the function in Go. * overname: The overload string for overloaded function. * wname: The SWIG wrapped name--the name of the C function. * base: A list of the names of base classes, in the case where this * is a virtual method not defined in the current class. * parms: The parameters. * result: The result type. * is_static: Whether this is a static method or member. * ---------------------------------------------------------------------- */ int makeWrappers(Node *n, String *go_name, String *overname, String *wname, List *base, ParmList *parms, SwigType *result, bool is_static) { assert(result); int ret = SWIG_OK; int r = makeCgoWrappers(n, go_name, overname, wname, base, parms, result, is_static); if (r != SWIG_OK) { ret = r; } if (class_methods) { Setattr(class_methods, Getattr(n, "name"), NewString("")); } return ret; } /* ---------------------------------------------------------------------- * struct cgoWrapperInfo * * Information needed by the CGO wrapper functions. * ---------------------------------------------------------------------- */ struct cgoWrapperInfo { // The function we are generating code for. Node *n; // The name of the Go function. String *go_name; // The overload string for an overloaded function. String *overname; // The name of the C wrapper function. String *wname; // The base classes. List *base; // The parameters. ParmList *parms; // The result type. SwigType *result; // Whether this is a static function, not a class method. bool is_static; // The Go receiver type. String *receiver; // Whether this is a class constructor. bool is_constructor; // Whether this is a class destructor. bool is_destructor; }; /* ---------------------------------------------------------------------- * makeCgoWrappers() * * Write out the wrappers for a function when producing cgo input * files. * ---------------------------------------------------------------------- */ int makeCgoWrappers(Node *n, String *go_name, String *overname, String *wname, List *base, ParmList *parms, SwigType *result, bool is_static) { Swig_save("makeCgoWrappers", n, "emit:cgotype", "emit:cgotypestruct", NULL); cgoWrapperInfo info; info.n = n; info.go_name = go_name; info.overname = overname; info.wname = wname; info.base = base; info.parms = parms; info.result = result; info.is_static = is_static; info.receiver = class_receiver; if (is_static) { info.receiver = NULL; } String *nodetype = Getattr(n, "nodeType"); info.is_constructor = Cmp(nodetype, "constructor") == 0; info.is_destructor = Cmp(nodetype, "destructor") == 0; if (info.is_constructor || info.is_destructor) { assert(class_receiver); assert(!base); info.receiver = NULL; } int ret = SWIG_OK; int r = cgoGoWrapper(&info); if (r != SWIG_OK) { ret = r; } r = cgoCommentWrapper(&info); if (r != SWIG_OK) { ret = r; } r = cgoGccWrapper(&info); if (r != SWIG_OK) { ret = r; } Swig_restore(n); return ret; } /* ---------------------------------------------------------------------- * cgoGoWrapper() * * Write out Go code to call a cgo function. This code will go into * the generated Go output file. * ---------------------------------------------------------------------- */ int cgoGoWrapper(const cgoWrapperInfo *info) { Wrapper *dummy = initGoTypemaps(info->parms); bool add_to_interface = interfaces && !info->is_constructor && !info->is_destructor && !info->is_static && !info->overname && checkFunctionVisibility(info->n, NULL); Printv(f_go_wrappers, "func ", NULL); Parm *p = info->parms; int pi = 0; // Add the receiver first if this is a method. if (info->receiver) { Printv(f_go_wrappers, "(", NULL); if (info->base && info->receiver) { Printv(f_go_wrappers, "_swig_base", NULL); } else { Printv(f_go_wrappers, Getattr(p, "lname"), NULL); p = nextParm(p); ++pi; } Printv(f_go_wrappers, " ", info->receiver, ") ", NULL); } Printv(f_go_wrappers, info->go_name, NULL); if (info->overname) { Printv(f_go_wrappers, info->overname, NULL); } Printv(f_go_wrappers, "(", NULL); // If we are doing methods, add this method to the interface. if (add_to_interface) { Printv(interfaces, "\t", info->go_name, "(", NULL); } // Write out the parameters to both the function definition and // the interface. String *parm_print = NewString(""); int parm_count = emit_num_arguments(info->parms); int required_count = emit_num_required(info->parms); int args = 0; for (; pi < parm_count; ++pi) { p = getParm(p); if (pi == 0 && info->is_destructor) { String *cl = exportedName(class_name); Printv(parm_print, Getattr(p, "lname"), " ", cl, NULL); Delete(cl); ++args; } else { if (args > 0) { Printv(parm_print, ", ", NULL); } ++args; if (pi >= required_count) { Printv(parm_print, "_swig_args ...interface{}", NULL); break; } Printv(parm_print, Getattr(p, "lname"), " ", NULL); String *tm = goType(p, Getattr(p, "type")); Printv(parm_print, tm, NULL); Delete(tm); } p = nextParm(p); } Printv(parm_print, ")", NULL); // Write out the result type. if (info->is_constructor) { String *cl = exportedName(class_name); Printv(parm_print, " (_swig_ret ", cl, ")", NULL); Delete(cl); } else { if (SwigType_type(info->result) != T_VOID) { String *tm = goType(info->n, info->result); Printv(parm_print, " (_swig_ret ", tm, ")", NULL); Delete(tm); } } Printv(f_go_wrappers, parm_print, NULL); if (add_to_interface) { Printv(interfaces, parm_print, "\n", NULL); } // Write out the function body. Printv(f_go_wrappers, " {\n", NULL); if (parm_count > required_count) { Parm *p = info->parms; int i; for (i = 0; i < required_count; ++i) { p = getParm(p); p = nextParm(p); } for (; i < parm_count; ++i) { p = getParm(p); String *tm = goType(p, Getattr(p, "type")); Printv(f_go_wrappers, "\tvar ", Getattr(p, "lname"), " ", tm, "\n", NULL); Printf(f_go_wrappers, "\tif len(_swig_args) > %d {\n", i - required_count); Printf(f_go_wrappers, "\t\t%s = _swig_args[%d].(%s)\n", Getattr(p, "lname"), i - required_count, tm); Printv(f_go_wrappers, "\t}\n", NULL); Delete(tm); p = nextParm(p); } } String *call = NewString("\t"); String *ret_type = NULL; bool memcpy_ret = false; String *wt = NULL; if (SwigType_type(info->result) != T_VOID) { if (info->is_constructor) { ret_type = exportedName(class_name); } else { ret_type = goImType(info->n, info->result); } Printv(f_go_wrappers, "\tvar swig_r ", ret_type, "\n", NULL); bool c_struct_type; Delete(cgoTypeForGoValue(info->n, info->result, &c_struct_type)); if (c_struct_type) { memcpy_ret = true; } if (memcpy_ret) { Printv(call, "swig_r_p := ", NULL); } else { Printv(call, "swig_r = (", ret_type, ")(", NULL); } if (info->is_constructor || goTypeIsInterface(info->n, info->result)) { if (info->is_constructor) { wt = Copy(class_receiver); } else { wt = goWrapperType(info->n, info->result, true); } Printv(call, wt, "(", NULL); } } Printv(call, "C.", info->wname, "(", NULL); args = 0; if (parm_count > required_count) { Printv(call, "C.swig_intgo(len(_swig_args))", NULL); ++args; } if (info->base && info->receiver) { if (args > 0) { Printv(call, ", ", NULL); } ++args; Printv(call, "C.uintptr_t(_swig_base)", NULL); } p = info->parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (args > 0) { Printv(call, ", ", NULL); } ++args; SwigType *pt = Getattr(p, "type"); String *ln = Getattr(p, "lname"); String *ivar = NewStringf("_swig_i_%d", i); String *goin = goGetattr(p, "tmap:goin"); if (goin == NULL) { Printv(f_go_wrappers, "\t", ivar, " := ", NULL); bool need_close = false; if ((i == 0 && info->is_destructor) || ((i > 0 || !info->receiver || info->base || info->is_constructor) && goTypeIsInterface(p, pt))) { Printv(f_go_wrappers, "getSwigcptr(", NULL); need_close = true; } Printv(f_go_wrappers, ln, NULL); if (need_close) { Printv(f_go_wrappers, ")", NULL); } Printv(f_go_wrappers, "\n", NULL); Setattr(p, "emit:goinput", ln); } else { String *itm = goImType(p, pt); Printv(f_go_wrappers, "\tvar ", ivar, " ", itm, "\n", NULL); goin = Copy(goin); Replaceall(goin, "$input", ln); Replaceall(goin, "$result", ivar); Printv(f_go_wrappers, goin, "\n", NULL); Delete(goin); Setattr(p, "emit:goinput", ivar); } bool c_struct_type; String *ct = cgoTypeForGoValue(p, pt, &c_struct_type); if (c_struct_type) { Printv(call, "*(*C.", ct, ")(unsafe.Pointer(&", ivar, "))", NULL); } else { Printv(call, "C.", ct, "(", ivar, ")", NULL); } Delete(ct); p = nextParm(p); } Printv(f_go_wrappers, call, ")", NULL); Delete(call); if (wt) { // Close the type conversion to the wrapper type. Printv(f_go_wrappers, ")", NULL); } if (SwigType_type(info->result) != T_VOID && !memcpy_ret) { // Close the type conversion of the return value. Printv(f_go_wrappers, ")", NULL); } Printv(f_go_wrappers, "\n", NULL); if (memcpy_ret) { Printv(f_go_wrappers, "\tswig_r = *(*", ret_type, ")(unsafe.Pointer(&swig_r_p))\n", NULL); } if (ret_type) { Delete(ret_type); } goargout(info->parms); if (SwigType_type(info->result) != T_VOID) { Swig_save("cgoGoWrapper", info->n, "type", "tmap:goout", NULL); Setattr(info->n, "type", info->result); String *goout = goTypemapLookup("goout", info->n, "swig_r"); if (goout == NULL) { Printv(f_go_wrappers, "\treturn swig_r\n", NULL); } else { String *tm = goType(info->n, info->result); Printv(f_go_wrappers, "\tvar swig_r_1 ", tm, "\n", NULL); goout = Copy(goout); Replaceall(goout, "$input", "swig_r"); Replaceall(goout, "$result", "swig_r_1"); Printv(f_go_wrappers, goout, "\n", NULL); Printv(f_go_wrappers, "\treturn swig_r_1\n", NULL); } Swig_restore(info->n); } Printv(f_go_wrappers, "}\n\n", NULL); DelWrapper(dummy); return SWIG_OK; } /* ---------------------------------------------------------------------- * cgoCommentWrapper() * * Write out a cgo function to call a C/C++ function. This code * will go into the cgo comment in the generated Go output file. * ---------------------------------------------------------------------- */ int cgoCommentWrapper(const cgoWrapperInfo *info) { String *ret_type; if (SwigType_type(info->result) == T_VOID) { ret_type = NewString("void"); } else { bool c_struct_type; ret_type = cgoTypeForGoValue(info->n, info->result, &c_struct_type); } Printv(f_cgo_comment, "extern ", ret_type, " ", info->wname, "(", NULL); Delete(ret_type); int parm_count = emit_num_arguments(info->parms); int required_count = emit_num_required(info->parms); int args = 0; if (parm_count > required_count) { Printv(f_cgo_comment, "intgo _swig_args", NULL); ++args; } if (info->base && info->receiver) { if (args > 0) { Printv(f_cgo_comment, ", ", NULL); } ++args; Printv(f_cgo_comment, "uintptr_t _swig_base", NULL); } Parm *p = info->parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (args > 0) { Printv(f_cgo_comment, ", ", NULL); } ++args; SwigType *pt = Getattr(p, "type"); String *ln = Getattr(p, "lname"); bool c_struct_type; String *ct = cgoTypeForGoValue(p, pt, &c_struct_type); Printv(f_cgo_comment, ct, " ", ln, NULL); Delete(ct); p = nextParm(p); } if (args == 0) { Printv(f_cgo_comment, "void", NULL); } Printv(f_cgo_comment, ");\n", NULL); return SWIG_OK; } /* ---------------------------------------------------------------------- * cgoGccWrapper() * * Write out code to the C/C++ wrapper file. This code will be * called by the code generated by cgoCommentWrapper. * ---------------------------------------------------------------------- */ int cgoGccWrapper(const cgoWrapperInfo *info) { Wrapper *f = NewWrapper(); Swig_save("cgoGccWrapper", info->n, "parms", NULL); ParmList *parms = info->parms; Parm *base_parm = NULL; if (info->base && !isStatic(info->n)) { SwigType *base_type = Copy(getClassType()); SwigType_add_pointer(base_type); base_parm = NewParm(base_type, NewString("arg1"), info->n); set_nextSibling(base_parm, parms); parms = base_parm; } emit_parameter_variables(parms, f); emit_attach_parmmaps(parms, f); int parm_count = emit_num_arguments(parms); int required_count = emit_num_required(parms); emit_return_variable(info->n, info->result, f); // Start the function definition. String *fnname = NewString(""); Printv(fnname, info->wname, "(", NULL); int args = 0; if (parm_count > required_count) { Printv(fnname, "intgo _swig_optargc", NULL); ++args; } Parm *p = parms; for (int i = 0; i < parm_count; ++i) { if (args > 0) { Printv(fnname, ", ", NULL); } ++args; p = getParm(p); SwigType *pt = Copy(Getattr(p, "type")); if (SwigType_isarray(pt) && Getattr(p, "tmap:gotype") == NULL) { SwigType_del_array(pt); SwigType_add_pointer(pt); } String *pn = NewStringf("_swig_go_%d", i); String *ct = gcCTypeForGoValue(p, pt, pn); Printv(fnname, ct, NULL); Delete(ct); Delete(pn); Delete(pt); p = nextParm(p); } Printv(fnname, ")", NULL); if (SwigType_type(info->result) == T_VOID) { Printv(f->def, "void ", fnname, NULL); } else { String *ct = gcCTypeForGoValue(info->n, info->result, fnname); Printv(f->def, ct, NULL); Delete(ct); String *ln = NewString("_swig_go_result"); ct = gcCTypeForGoValue(info->n, info->result, ln); Wrapper_add_local(f, "_swig_go_result", ct); Delete(ct); Delete(ln); } Delete(fnname); Printv(f->def, " {\n", NULL); // Apply the in typemaps. p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); String *tm = Getattr(p, "tmap:in"); if (!tm) { Swig_warning(WARN_TYPEMAP_IN_UNDEF, input_file, line_number, "unable to use type %s as a function argument\n", SwigType_str(Getattr(p, "type"), 0)); } else { tm = Copy(tm); String *pn = NewStringf("_swig_go_%d", i); Replaceall(tm, "$input", pn); if (i < required_count) { Printv(f->code, "\t", tm, "\n", NULL); } else { Printf(f->code, "\tif (_swig_optargc > %d) {\n", i - required_count); Printv(f->code, "\t\t", tm, "\n", NULL); Printv(f->code, "\t}\n", NULL); } Delete(tm); Setattr(p, "emit:input", pn); } p = nextParm(p); } Printv(f->code, "\n", NULL); // Do the real work of the function. checkConstraints(parms, f); emitGoAction(info->n, info->base, parms, info->result, f); argout(parms, f); cleanupFunction(info->n, f, parms); if (SwigType_type(info->result) != T_VOID) { Printv(f->code, "\treturn _swig_go_result;\n", NULL); } Printv(f->code, "}\n", NULL); Wrapper_print(f, f_c_wrappers); Swig_restore(info->n); DelWrapper(f); if (base_parm) { Delete(base_parm); } return SWIG_OK; } /* ---------------------------------------------------------------------- * initGoTypemaps() * * Initialize the typenames for a Go wrapper, returning a dummy * Wrapper*. Also set consistent names for the parameters. * ---------------------------------------------------------------------- */ Wrapper* initGoTypemaps(ParmList *parms) { Wrapper *dummy = NewWrapper(); emit_attach_parmmaps(parms, dummy); Parm *p = parms; int parm_count = emit_num_arguments(parms); for (int i = 0; i < parm_count; ++i) { p = getParm(p); Swig_cparm_name(p, i); p = nextParm(p); } Swig_typemap_attach_parms("default", parms, dummy); Swig_typemap_attach_parms("gotype", parms, dummy); Swig_typemap_attach_parms("goin", parms, dummy); Swig_typemap_attach_parms("goargout", parms, dummy); Swig_typemap_attach_parms("imtype", parms, dummy); return dummy; } /* ----------------------------------------------------------------------- * checkConstraints() * * Check parameter constraints if any. This is used for the C/C++ * function. This assumes that each parameter has an "emit:input" * property with the name to use to refer to that parameter. * ----------------------------------------------------------------------- */ void checkConstraints(ParmList *parms, Wrapper *f) { Parm *p = parms; while (p) { String *tm = Getattr(p, "tmap:check"); if (!tm) { p = nextSibling(p); } else { tm = Copy(tm); Replaceall(tm, "$input", Getattr(p, "emit:input")); Printv(f->code, tm, "\n\n", NULL); Delete(tm); p = Getattr(p, "tmap:check:next"); } } } /* ----------------------------------------------------------------------- * emitGoAction() * * Emit the action of the function. This is used for the C/C++ function. * ----------------------------------------------------------------------- */ void emitGoAction(Node *n, List *base, ParmList *parms, SwigType *result, Wrapper *f) { String *actioncode; if (!base || isStatic(n)) { Swig_director_emit_dynamic_cast(n, f); actioncode = emit_action(n); } else { // Call the base class method. actioncode = NewString(""); String *current = NewString(""); Printv(current, Getattr(parms, "lname"), NULL); int vc = 0; for (Iterator bi = First(base); bi.item; bi = Next(bi)) { Printf(actioncode, " %s *swig_b%d = (%s *)%s;\n", bi.item, vc, bi.item, current); Delete(current); current = NewString(""); Printf(current, "swig_b%d", vc); ++vc; } String *code = Copy(Getattr(n, "wrap:action")); Replace(code, Getattr(parms, "lname"), current, DOH_REPLACE_ANY | DOH_REPLACE_ID); Delete(current); Printv(actioncode, code, "\n", NULL); } Swig_save("emitGoAction", n, "type", "tmap:out", NULL); Setattr(n, "type", result); String *tm = Swig_typemap_lookup_out("out", n, Swig_cresult_name(), f, actioncode); if (!tm) { Swig_warning(WARN_TYPEMAP_OUT_UNDEF, input_file, line_number, "Unable to use return type %s\n", SwigType_str(result, 0)); } else { Replaceall(tm, "$result", "_swig_go_result"); if (GetFlag(n, "feature:new")) { Replaceall(tm, "$owner", "1"); } else { Replaceall(tm, "$owner", "0"); } Printv(f->code, tm, "\n", NULL); Delete(tm); } Swig_restore(n); } /* ----------------------------------------------------------------------- * argout() * * Handle argument output code if any. This is used for the C/C++ * function. This assumes that each parameter has an "emit:input" * property with the name to use to refer to that parameter. * ----------------------------------------------------------------------- */ void argout(ParmList *parms, Wrapper *f) { Parm *p = parms; while (p) { String *tm = Getattr(p, "tmap:argout"); if (!tm) { p = nextSibling(p); } else { tm = Copy(tm); Replaceall(tm, "$result", Swig_cresult_name()); Replaceall(tm, "$input", Getattr(p, "emit:input")); Printv(f->code, tm, "\n", NULL); Delete(tm); p = Getattr(p, "tmap:argout:next"); } } } /* ----------------------------------------------------------------------- * goargout() * * Handle Go argument output code if any. This is used for the Go * function. This assumes that each parameter has an "emit:goinput" * property with the name to use to refer to that parameter. * ----------------------------------------------------------------------- */ void goargout(ParmList *parms) { Parm *p = parms; while (p) { String *tm = Getattr(p, "tmap:goargout"); if (!tm) { p = nextSibling(p); } else { tm = Copy(tm); Replaceall(tm, "$result", "swig_r"); Replaceall(tm, "$input", Getattr(p, "emit:goinput")); Printv(f_go_wrappers, tm, "\n", NULL); Delete(tm); p = Getattr(p, "tmap:goargout:next"); } } // If we need to memcpy a parameter to pass it to the C code, the // compiler may think that the parameter is not live during the // function call. If the garbage collector runs while the C/C++ // function is running, the parameter may be freed. Force the // compiler to see the parameter as live across the C/C++ function. int parm_count = emit_num_arguments(parms); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); bool c_struct_type; Delete(cgoTypeForGoValue(p, Getattr(p, "type"), &c_struct_type)); if (c_struct_type) { Printv(f_go_wrappers, "\tif Swig_escape_always_false {\n", NULL); Printv(f_go_wrappers, "\t\tSwig_escape_val = ", Getattr(p, "emit:goinput"), "\n", NULL); Printv(f_go_wrappers, "\t}\n", NULL); } p = nextParm(p); } } /* ----------------------------------------------------------------------- * freearg() * * Handle argument cleanup code if any. This is used for the C/C++ * function. This assumes that each parameter has an "emit:input" * property with the name to use to refer to that parameter. * ----------------------------------------------------------------------- */ String *freearg(ParmList *parms) { String *ret = NewString(""); Parm *p = parms; while (p) { String *tm = Getattr(p, "tmap:freearg"); if (!tm) { p = nextSibling(p); } else { tm = Copy(tm); Replaceall(tm, "$input", Getattr(p, "emit:input")); Printv(ret, tm, "\n", NULL); Delete(tm); p = Getattr(p, "tmap:freearg:next"); } } return ret; } /* ----------------------------------------------------------------------- * cleanupFunction() * * Final function cleanup code. * ----------------------------------------------------------------------- */ void cleanupFunction(Node *n, Wrapper *f, ParmList *parms) { String *cleanup = freearg(parms); Printv(f->code, cleanup, NULL); if (GetFlag(n, "feature:new")) { String *tm = Swig_typemap_lookup("newfree", n, Swig_cresult_name(), 0); if (tm) { Printv(f->code, tm, "\n", NULL); Delete(tm); } } Replaceall(f->code, "$cleanup", cleanup); Delete(cleanup); /* See if there is any return cleanup code */ String *tm; if ((tm = Swig_typemap_lookup("ret", n, Swig_cresult_name(), 0))) { Printf(f->code, "%s\n", tm); Delete(tm); } Replaceall(f->code, "$symname", Getattr(n, "sym:name")); } /* ----------------------------------------------------------------------- * variableHandler() * * This exists just to set the making_variable_wrappers flag. * ----------------------------------------------------------------------- */ virtual int variableHandler(Node *n) { assert(!making_variable_wrappers); making_variable_wrappers = true; int r = Language::variableHandler(n); making_variable_wrappers = false; return r; } /* ----------------------------------------------------------------------- * constantWrapper() * * Product a const declaration. * ------------------------------------------------------------------------ */ virtual int constantWrapper(Node *n) { SwigType *type = Getattr(n, "type"); if (!SwigType_issimple(type) && SwigType_type(type) != T_STRING) { return goComplexConstant(n, type); } if (Swig_storage_isstatic(n)) { return goComplexConstant(n, type); } String *go_name = buildGoName(Getattr(n, "sym:name"), false, false); String *tm = goType(n, type); String *value = Getattr(n, "value"); String *copy = NULL; if (SwigType_type(type) == T_BOOL) { if (Cmp(value, "true") != 0 && Cmp(value, "false") != 0) { return goComplexConstant(n, type); } } else if (SwigType_type(type) == T_STRING || SwigType_type(type) == T_CHAR) { // Backslash sequences are somewhat different in Go and C/C++. if (Strchr(value, '\\') != 0) { return goComplexConstant(n, type); } } else { // Accept a 0x prefix, and strip combinations of u and l // suffixes. Otherwise accept digits, decimal point, and // exponentiation. Treat anything else as too complicated to // handle as a Go constant. char *p = Char(value); int len = (int)strlen(p); bool need_copy = false; while (len > 0) { char c = p[len - 1]; if (c != 'l' && c != 'L' && c != 'u' && c != 'U') { break; } --len; need_copy = true; } bool is_hex = false; int i = 0; if (p[0] == '0' && (p[1] == 'x' || p[1] == 'X')) { i = 2; is_hex = true; } for (; i < len; ++i) { switch (p[i]) { case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': break; case 'a': case 'b': case 'c': case 'd': case 'f': case 'A': case 'B': case 'C': case 'D': case 'F': if (!is_hex) { return goComplexConstant(n, type); } break; case '.': case 'e': case 'E': case '+': case '-': break; default: return goComplexConstant(n, type); } } if (need_copy) { copy = Copy(value); Replaceall(copy, p + len, ""); value = copy; } } if (!checkNameConflict(go_name, n, NULL)) { Delete(tm); Delete(go_name); Delete(copy); return SWIG_NOWRAP; } Printv(f_go_wrappers, "const ", go_name, " ", tm, " = ", NULL); if (SwigType_type(type) == T_STRING) { Printv(f_go_wrappers, "\"", value, "\"", NULL); } else if (SwigType_type(type) == T_CHAR) { Printv(f_go_wrappers, "'", value, "'", NULL); } else { Printv(f_go_wrappers, value, NULL); } Printv(f_go_wrappers, "\n", NULL); Delete(tm); Delete(go_name); Delete(copy); return SWIG_OK; } /* ---------------------------------------------------------------------- * enumDeclaration() * * A C++ enum type turns into a Named go int type. * ---------------------------------------------------------------------- */ virtual int enumDeclaration(Node *n) { if (getCurrentClass() && (cplus_mode != PUBLIC)) return SWIG_NOWRAP; String *name = goEnumName(n); if (Strcmp(name, "int") != 0) { if (!ImportMode || !imported_package) { if (!checkNameConflict(name, n, NULL)) { Delete(name); return SWIG_NOWRAP; } Printv(f_go_wrappers, "type ", name, " int\n", NULL); } else { String *nw = NewString(""); Printv(nw, getModuleName(imported_package), ".", name, NULL); Setattr(n, "go:enumname", nw); } } Delete(name); return Language::enumDeclaration(n); } /* ----------------------------------------------------------------------- * enumvalueDeclaration() * * Declare a single value of an enum type. We fetch the value by * calling a C/C++ function. * ------------------------------------------------------------------------ */ virtual int enumvalueDeclaration(Node *n) { if (!is_public(n)) { return SWIG_OK; } Swig_require("enumvalueDeclaration", n, "*sym:name", NIL); Node *parent = parentNode(n); if (Getattr(parent, "unnamed")) { Setattr(n, "type", NewString("int")); } else { Setattr(n, "type", Getattr(parent, "enumtype")); } if (GetFlag(parent, "scopedenum")) { String *symname = Getattr(n, "sym:name"); symname = Swig_name_member(0, Getattr(parent, "sym:name"), symname); Setattr(n, "sym:name", symname); Delete(symname); } int ret = goComplexConstant(n, Getattr(n, "type")); Swig_restore(n); return ret; } /* ----------------------------------------------------------------------- * goComplexConstant() * * Handle a const declaration for something which is not a Go constant. * ------------------------------------------------------------------------ */ int goComplexConstant(Node *n, SwigType *type) { String *symname = Getattr(n, "sym:name"); if (!symname) { symname = Getattr(n, "name"); } String *varname = buildGoName(symname, true, false); if (!checkNameConflict(varname, n, NULL)) { Delete(varname); return SWIG_NOWRAP; } String *rawval = Getattr(n, "rawval"); if (rawval && Len(rawval)) { // Based on Swig_VargetToFunction String *nname = NewStringf("(%s)", rawval); String *call; if (SwigType_isclass(type)) { call = NewStringf("%s", nname); } else { call = SwigType_lcaststr(type, nname); } String *cres = Swig_cresult(type, Swig_cresult_name(), call); Setattr(n, "wrap:action", cres); Delete(nname); Delete(call); Delete(cres); } else { String *get = NewString(""); Printv(get, Swig_cresult_name(), " = ", NULL); char quote; if (Getattr(n, "wrappedasconstant")) { quote = '\0'; } else if (SwigType_type(type) == T_CHAR) { quote = '\''; } else if (SwigType_type(type) == T_STRING) { Printv(get, "(char *)", NULL); quote = '"'; } else { quote = '\0'; } if (quote != '\0') { Printf(get, "%c", quote); } Printv(get, Getattr(n, "value"), NULL); if (quote != '\0') { Printf(get, "%c", quote); } Printv(get, ";\n", NULL); Setattr(n, "wrap:action", get); Delete(get); } String *sname = Copy(symname); if (class_name) { Append(sname, "_"); Append(sname, class_name); } String *go_name = NewString("_swig_get"); if (class_name) { Append(go_name, class_name); Append(go_name, "_"); } Append(go_name, sname); String *wname = Swig_name_wrapper(sname); Append(wname, unique_id); Setattr(n, "wrap:name", wname); int r = makeWrappers(n, go_name, NULL, wname, NULL, NULL, type, true); if (r != SWIG_OK) { return r; } String *t = goType(n, type); Printv(f_go_wrappers, "var ", varname, " ", t, " = ", go_name, "()\n", NULL); Delete(varname); Delete(t); Delete(go_name); Delete(sname); return SWIG_OK; } /* ------------------------------------------------------------ * classHandler() * * For a C++ class, in Go we generate both a struct and an * interface. The interface will declare all the class public * methods. We will define all the methods on the struct, so that * the struct meets the interface. We then expect users of the * class to use the interface. * ------------------------------------------------------------ */ virtual int classHandler(Node *n) { class_node = n; List *baselist = Getattr(n, "bases"); bool has_base_classes = baselist && Len(baselist) > 0; String *name = Getattr(n, "sym:name"); String *go_name = exportedName(name); if (!checkNameConflict(go_name, n, NULL)) { Delete(go_name); SetFlag(n, "go:conflict"); return SWIG_NOWRAP; } String *go_type_name = goCPointerType(Getattr(n, "classtypeobj"), true); class_name = name; class_receiver = go_type_name; class_methods = NewHash(); int isdir = GetFlag(n, "feature:director"); int isnodir = GetFlag(n, "feature:nodirector"); bool is_director = isdir && !isnodir; Printv(f_go_wrappers, "type ", go_type_name, " uintptr\n\n", NULL); // A method to return the pointer to the C++ class. This is used // by generated code to convert between the interface and the C++ // value. Printv(f_go_wrappers, "func (p ", go_type_name, ") Swigcptr() uintptr {\n", NULL); Printv(f_go_wrappers, "\treturn (uintptr)(p)\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); // A method used as a marker for the class, to avoid invalid // interface conversions when using multiple inheritance. Printv(f_go_wrappers, "func (p ", go_type_name, ") SwigIs", go_name, "() {\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); if (is_director) { // Return the interface passed to the NewDirector function. Printv(f_go_wrappers, "func (p ", go_type_name, ") DirectorInterface() interface{} {\n", NULL); Printv(f_go_wrappers, "\treturn nil\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); } // We have seen a definition for this type. Setattr(defined_types, go_name, go_name); Setattr(defined_types, go_type_name, go_type_name); interfaces = NewString(""); int r = Language::classHandler(n); if (r != SWIG_OK) { return r; } if (has_base_classes) { // For each method defined in a base class but not defined in // this class, we need to define the method in this class. We // can't use anonymous field inheritance because it works // differently in Go and in C++. Hash *local = NewHash(); for (Node *ni = Getattr(n, "firstChild"); ni; ni = nextSibling(ni)) { if (!is_public(ni)) { continue; } String *type = Getattr(ni, "nodeType"); if (Cmp(type, "constructor") == 0 || Cmp(type, "destructor") == 0) { continue; } String *cname = Getattr(ni, "sym:name"); if (!cname) { cname = Getattr(ni, "name"); } if (cname) { Setattr(local, cname, NewString("")); } } for (Iterator b = First(baselist); b.item; b = Next(b)) { List *bases = NewList(); Append(bases, Getattr(b.item, "classtype")); int r = addBase(n, b.item, bases, local); if (r != SWIG_OK) { return r; } Delete(bases); } Delete(local); Hash *parents = NewHash(); addFirstBaseInterface(n, parents, baselist); int r = addExtraBaseInterfaces(n, parents, baselist); Delete(parents); if (r != SWIG_OK) { return r; } } Printv(f_go_wrappers, "type ", go_name, " interface {\n", NULL); Printv(f_go_wrappers, "\tSwigcptr() uintptr\n", NULL); Printv(f_go_wrappers, "\tSwigIs", go_name, "()\n", NULL); if (is_director) { Printv(f_go_wrappers, "\tDirectorInterface() interface{}\n", NULL); } Append(f_go_wrappers, interfaces); Printv(f_go_wrappers, "}\n\n", NULL); Delete(interfaces); interfaces = NULL; class_name = NULL; class_receiver = NULL; class_node = NULL; Delete(class_methods); class_methods = NULL; Delete(go_type_name); return SWIG_OK; } /* ------------------------------------------------------------ * addBase() * * Implement methods and members defined in a parent class for a * child class. * ------------------------------------------------------------ */ int addBase(Node *n, Node *base, List *bases, Hash *local) { if (GetFlag(base, "feature:ignore")) { return SWIG_OK; } for (Node *ni = Getattr(base, "firstChild"); ni; ni = nextSibling(ni)) { int r = goBaseEntry(n, bases, local, ni); if (r != SWIG_OK) { return r; } } List *baselist = Getattr(base, "bases"); if (baselist && Len(baselist) > 0) { for (Iterator b = First(baselist); b.item; b = Next(b)) { List *nb = Copy(bases); Append(nb, Getattr(b.item, "classtype")); int r = addBase(n, b.item, nb, local); Delete(nb); if (r != SWIG_OK) { return r; } } } return SWIG_OK; } /* ------------------------------------------------------------ * goBaseEntry() * * Implement one entry defined in a parent class for a child class. * n is the child class. * ------------------------------------------------------------ */ int goBaseEntry(Node* n, List* bases, Hash *local, Node* entry) { if (GetFlag(entry, "feature:ignore")) { return SWIG_OK; } if (!is_public(entry)) { return SWIG_OK; } String *type = Getattr(entry, "nodeType"); if (Strcmp(type, "constructor") == 0 || Strcmp(type, "destructor") == 0 || Strcmp(type, "enum") == 0 || Strcmp(type, "using") == 0 || Strcmp(type, "classforward") == 0 || Strcmp(type, "template") == 0) { return SWIG_OK; } if (Strcmp(type, "extend") == 0) { for (Node* extend = firstChild(entry); extend; extend = nextSibling(extend)) { if (isStatic(extend)) { // If we don't do this, the extend_default test case fails. continue; } int r = goBaseEntry(n, bases, local, extend); if (r != SWIG_OK) { return r; } } return SWIG_OK; } String *storage = Getattr(entry, "storage"); if (storage && (Strcmp(storage, "typedef") == 0 || Strstr(storage, "friend"))) { return SWIG_OK; } String *mname = Getattr(entry, "sym:name"); if (!mname) { return SWIG_OK; } String *lname = Getattr(entry, "name"); if (Getattr(class_methods, lname)) { return SWIG_OK; } if (Getattr(local, lname)) { return SWIG_OK; } Setattr(local, lname, NewString("")); String *ty = NewString(Getattr(entry, "type")); SwigType_push(ty, Getattr(entry, "decl")); String *fullty = SwigType_typedef_resolve_all(ty); bool is_function = SwigType_isfunction(fullty) ? true : false; Delete(ty); Delete(fullty); if (is_function) { int r = goBaseMethod(n, bases, entry); if (r != SWIG_OK) { return r; } if (Getattr(entry, "sym:overloaded")) { for (Node *on = Getattr(entry, "sym:nextSibling"); on; on = Getattr(on, "sym:nextSibling")) { r = goBaseMethod(n, bases, on); if (r != SWIG_OK) { return r; } } String *receiver = class_receiver; bool is_static = isStatic(entry); if (is_static) { receiver = NULL; } String *go_name = buildGoName(Getattr(entry, "sym:name"), is_static, false); r = makeDispatchFunction(entry, go_name, receiver, is_static, NULL, false); Delete(go_name); if (r != SWIG_OK) { return r; } } } else { int r = goBaseVariable(n, bases, entry); if (r != SWIG_OK) { return r; } } return SWIG_OK; } /* ------------------------------------------------------------ * goBaseMethod() * * Implement a method defined in a parent class for a child class. * ------------------------------------------------------------ */ int goBaseMethod(Node *method_class, List *bases, Node *method) { String *symname = Getattr(method, "sym:name"); if (!validIdentifier(symname)) { return SWIG_OK; } String *name = NewString(""); Printv(name, Getattr(method_class, "sym:name"), "_", symname, NULL); bool is_static = isStatic(method); String *go_name = buildGoName(name, is_static, false); String *overname = NULL; if (Getattr(method, "sym:overloaded")) { overname = Getattr(method, "sym:overname"); } String *wname = Swig_name_wrapper(name); if (overname) { Append(wname, overname); } Append(wname, unique_id); String *result = NewString(Getattr(method, "type")); SwigType_push(result, Getattr(method, "decl")); if (SwigType_isqualifier(result)) { Delete(SwigType_pop(result)); } Delete(SwigType_pop_function(result)); // If the base method is imported, wrap:action may not be set. Swig_save("goBaseMethod", method, "wrap:name", "wrap:action", "parms", NULL); Setattr(method, "wrap:name", wname); if (!Getattr(method, "wrap:action")) { if (!is_static) { Swig_MethodToFunction(method, getNSpace(), getClassType(), (Getattr(method, "template") ? SmartPointer : Extend | SmartPointer), NULL, false); // Remove any self parameter that was just added. ParmList *parms = Getattr(method, "parms"); if (parms && Getattr(parms, "self")) { parms = CopyParmList(nextSibling(parms)); Setattr(method, "parms", parms); } } else { String *call = Swig_cfunction_call(Getattr(method, "name"), Getattr(method, "parms")); Setattr(method, "wrap:action", Swig_cresult(Getattr(method, "type"), Swig_cresult_name(), call)); } } // A method added by %extend in a base class may have void parms. ParmList* parms = Getattr(method, "parms"); if (parms != NULL && SwigType_type(Getattr(parms, "type")) == T_VOID) { parms = NULL; } int r = makeWrappers(method, go_name, overname, wname, bases, parms, result, is_static); Swig_restore(method); Delete(result); Delete(go_name); Delete(name); return r; } /* ------------------------------------------------------------ * goBaseVariable() * * Add accessors for a member variable defined in a parent class for * a child class. * ------------------------------------------------------------ */ int goBaseVariable(Node *var_class, List *bases, Node *var) { if (isStatic(var)) { return SWIG_OK; } String *var_name = buildGoName(Getattr(var, "sym:name"), false, false); Swig_save("goBaseVariable", var, "type", "wrap:action", NULL); // For a pointer type we apparently have to wrap in the decl. SwigType *var_type = NewString(Getattr(var, "type")); SwigType_push(var_type, Getattr(var, "decl")); Setattr(var, "type", var_type); SwigType *vt = Copy(var_type); int flags = Extend | SmartPointer | use_naturalvar_mode(var); if (isNonVirtualProtectedAccess(var)) { flags |= CWRAP_ALL_PROTECTED_ACCESS; } // Copied from Swig_wrapped_member_var_type. if (SwigType_isclass(vt)) { if (flags & CWRAP_NATURAL_VAR) { if (CPlusPlus) { if (!SwigType_isconst(vt)) { SwigType_add_qualifier(vt, "const"); } SwigType_add_reference(vt); } } else { SwigType_add_pointer(vt); } } String *mname = Swig_name_member(getNSpace(), Getattr(var_class, "sym:name"), var_name); if (is_assignable(var)) { for (Iterator ki = First(var); ki.key; ki = Next(ki)) { if (Strncmp(ki.key, "tmap:", 5) == 0) { Delattr(var, ki.key); } } Swig_save("goBaseVariableSet", var, "name", "sym:name", "type", NULL); String *mname_set = NewString("Set"); Append(mname_set, mname); String *go_name = NewString("Set"); Append(go_name, var_name); Swig_MembersetToFunction(var, class_name, flags); String *wname = Swig_name_wrapper(mname_set); Append(wname, unique_id); ParmList *parms = NewParm(vt, var_name, var); String *result = NewString("void"); int r = makeWrappers(var, go_name, NULL, wname, bases, parms, result, false); if (r != SWIG_OK) { return r; } Delete(wname); Delete(parms); Delete(result); Delete(go_name); Delete(mname_set); Swig_restore(var); for (Iterator ki = First(var); ki.key; ki = Next(ki)) { if (Strncmp(ki.key, "tmap:", 5) == 0) { Delattr(var, ki.key); } } } Swig_MembergetToFunction(var, class_name, flags); String *mname_get = NewString("Get"); Append(mname_get, mname); String *go_name = NewString("Get"); Append(go_name, var_name); String *wname = Swig_name_wrapper(mname_get); Append(wname, unique_id); int r = makeWrappers(var, go_name, NULL, wname, bases, NULL, vt, false); if (r != SWIG_OK) { return r; } Delete(wname); Delete(mname_get); Delete(go_name); Delete(mname); Delete(var_name); Delete(var_type); Delete(vt); Swig_restore(var); return SWIG_OK; } /* ------------------------------------------------------------ * addFirstBaseInterface() * * When a C++ class uses multiple inheritance, we can use the C++ * pointer for the first base class but not for any subsequent base * classes. However, the Go interface will match the interface for * all the base classes. To avoid accidentally treating a class as * a pointer to a base class other than the first one, we use an * isClassname method. This function adds those methods as * required. * * For convenience when using multiple inheritance, we also add * functions to retrieve the base class pointers. * ------------------------------------------------------------ */ void addFirstBaseInterface(Node *n, Hash *parents, List *bases) { if (!bases || Len(bases) == 0) { return; } Iterator b = First(bases); if (!GetFlag(b.item, "feature:ignore")) { String *go_name = buildGoName(Getattr(n, "sym:name"), false, false); String *go_type_name = goCPointerType(Getattr(n, "classtypeobj"), true); String *go_base_name = exportedName(Getattr(b.item, "sym:name")); String *go_base_type = goType(n, Getattr(b.item, "classtypeobj")); String *go_base_type_name = goCPointerType(Getattr(b.item, "classtypeobj"), true); Printv(f_go_wrappers, "func (p ", go_type_name, ") SwigIs", go_base_name, "() {\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(interfaces, "\tSwigIs", go_base_name, "()\n", NULL); Printv(f_go_wrappers, "func (p ", go_type_name, ") SwigGet", go_base_name, "() ", go_base_type, " {\n", NULL); Printv(f_go_wrappers, "\treturn ", go_base_type_name, "(getSwigcptr(p))\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(interfaces, "\tSwigGet", go_base_name, "() ", go_base_type, "\n", NULL); Setattr(parents, go_base_name, NewString("")); Delete(go_name); Delete(go_type_name); Delete(go_base_type); Delete(go_base_type_name); } addFirstBaseInterface(n, parents, Getattr(b.item, "bases")); } /* ------------------------------------------------------------ * addExtraBaseInterfaces() * * Add functions to retrieve the base class pointers for all base * classes other than the first. * ------------------------------------------------------------ */ int addExtraBaseInterfaces(Node *n, Hash *parents, List *bases) { Iterator b = First(bases); Node *fb = b.item; for (b = Next(b); b.item; b = Next(b)) { if (GetFlag(b.item, "feature:ignore")) { continue; } String *go_base_name = exportedName(Getattr(b.item, "sym:name")); Swig_save("addExtraBaseInterface", n, "wrap:action", "wrap:name", "wrap:parms", NULL); SwigType *type = Copy(Getattr(n, "classtypeobj")); SwigType_add_pointer(type); Parm *parm = NewParm(type, "self", n); Setattr(n, "wrap:parms", parm); String *pn = Swig_cparm_name(parm, 0); String *action = NewString(""); Printv(action, Swig_cresult_name(), " = (", Getattr(b.item, "classtype"), "*)", pn, ";", NULL); Delete(pn); Setattr(n, "wrap:action", action); String *name = Copy(class_name); Append(name, "_SwigGet"); Append(name, go_base_name); String *go_name = NewString("SwigGet"); String *c1 = exportedName(go_base_name); Append(go_name, c1); Delete(c1); String *wname = Swig_name_wrapper(name); Append(wname, unique_id); Setattr(n, "wrap:name", wname); SwigType *result = Copy(Getattr(b.item, "classtypeobj")); SwigType_add_pointer(result); int r = makeWrappers(n, go_name, NULL, wname, NULL, parm, result, false); if (r != SWIG_OK) { return r; } Swig_restore(n); Setattr(parents, go_base_name, NewString("")); Delete(go_name); Delete(type); Delete(parm); Delete(action); Delete(result); String *ns = NewString(""); addParentExtraBaseInterfaces(n, parents, b.item, false, ns); Delete(ns); } if (!GetFlag(fb, "feature:ignore")) { String *ns = NewString(""); addParentExtraBaseInterfaces(n, parents, fb, true, ns); Delete(ns); } return SWIG_OK; } /* ------------------------------------------------------------ * addParentExtraBaseInterfaces() * * Add functions to retrieve the base class pointers for all base * classes of parents other than the first base class at each level. * ------------------------------------------------------------ */ void addParentExtraBaseInterfaces(Node *n, Hash *parents, Node *base, bool is_base_first, String *sofar) { List *baselist = Getattr(base, "bases"); if (!baselist || Len(baselist) == 0) { return; } String *go_this_base_name = exportedName(Getattr(base, "sym:name")); String *sf = NewString(""); Printv(sf, sofar, ".SwigGet", go_this_base_name, "()", NULL); Iterator b = First(baselist); if (is_base_first) { if (!b.item) { return; } if (!GetFlag(b.item, "feature:ignore")) { addParentExtraBaseInterfaces(n, parents, b.item, true, sf); } b = Next(b); } String *go_name = buildGoName(Getattr(n, "sym:name"), false, false); String *go_type_name = goCPointerType(Getattr(n, "classtypeobj"), true); for (; b.item; b = Next(b)) { if (GetFlag(b.item, "feature:ignore")) { continue; } String *go_base_name = exportedName(Getattr(b.item, "sym:name")); if (!Getattr(parents, go_base_name)) { Printv(f_go_wrappers, "func (p ", go_type_name, ") SwigGet", go_base_name, "() ", go_base_name, " {\n", NULL); Printv(f_go_wrappers, "\treturn p", sf, ".SwigGet", go_base_name, "()\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(interfaces, "\tSwigGet", go_base_name, "() ", go_base_name, "\n", NULL); addParentExtraBaseInterfaces(n, parents, b.item, false, sf); Setattr(parents, go_base_name, NewString("")); } } Delete(go_name); Delete(go_type_name); Delete(go_this_base_name); Delete(sf); } /* ------------------------------------------------------------ * classDirectorInit * * Add support for a director class. * * Virtual inheritance is different in Go and C++. We implement * director classes by defining a new function in Go, * NewDirectorClassname, which takes a empty interface value and * creates an instance of a new child class. The new child class * refers all methods back to Go. The Go code checks whether the * value passed to NewDirectorClassname implements that method; if * it does, it calls it, otherwise it calls back into C++. * ------------------------------------------------------------ */ int classDirectorInit(Node *n) { // Because we use a different function to handle inheritance in // Go, ordinary creations of the object should not create a // director object. Delete(director_ctor_code); director_ctor_code = NewString("$nondirector_new"); class_node = n; String *name = Getattr(n, "sym:name"); assert(!class_name); class_name = name; String *go_name = exportedName(name); String *go_type_name = goCPointerType(Getattr(n, "classtypeobj"), true); assert(!class_receiver); class_receiver = go_type_name; String *director_struct_name = NewString("_swig_Director"); Append(director_struct_name, go_name); String *cxx_director_name = NewString("SwigDirector_"); Append(cxx_director_name, name); // The Go type of the director class. Printv(f_go_wrappers, "type ", director_struct_name, " struct {\n", NULL); Printv(f_go_wrappers, "\t", go_type_name, "\n", NULL); Printv(f_go_wrappers, "\tv interface{}\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(f_go_wrappers, "func (p *", director_struct_name, ") Swigcptr() uintptr {\n", NULL); Printv(f_go_wrappers, "\treturn getSwigcptr(p.", go_type_name, ")\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(f_go_wrappers, "func (p *", director_struct_name, ") SwigIs", go_name, "() {\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(f_go_wrappers, "func (p *", director_struct_name, ") DirectorInterface() interface{} {\n", NULL); Printv(f_go_wrappers, "\treturn p.v\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); // Start defining the director class. Printv(f_c_directors_h, "class ", cxx_director_name, " : public ", Getattr(n, "classtype"), "\n", NULL); Printv(f_c_directors_h, "{\n", NULL); Printv(f_c_directors_h, " public:\n", NULL); Delete(director_struct_name); Delete(cxx_director_name); class_methods = NewHash(); return SWIG_OK; } /* ------------------------------------------------------------ * classDirectorConstructor * * Emit a constructor for a director class. * ------------------------------------------------------------ */ int classDirectorConstructor(Node *n) { bool is_ignored = GetFlag(n, "feature:ignore") ? true : false; String *name = Getattr(n, "sym:name"); if (!name) { assert(is_ignored); name = Getattr(n, "name"); } String *overname = NULL; if (Getattr(n, "sym:overloaded")) { overname = Getattr(n, "sym:overname"); } String *go_name = exportedName(name); ParmList *parms = Getattr(n, "parms"); Setattr(n, "wrap:parms", parms); String *cn = exportedName(Getattr(parentNode(n), "sym:name")); String *go_type_name = goCPointerType(Getattr(parentNode(n), "classtypeobj"), true); String *director_struct_name = NewString("_swig_Director"); Append(director_struct_name, cn); String *fn_name = NewString("_swig_NewDirector"); Append(fn_name, cn); Append(fn_name, go_name); if (!overname && !is_ignored) { if (!checkNameConflict(fn_name, n, NULL)) { return SWIG_NOWRAP; } } String *fn_with_over_name = Copy(fn_name); if (overname) { Append(fn_with_over_name, overname); } String *wname = Swig_name_wrapper(fn_name); if (overname) { Append(wname, overname); } Append(wname, unique_id); Setattr(n, "wrap:name", wname); bool is_static = isStatic(n); Wrapper *dummy = NewWrapper(); emit_attach_parmmaps(parms, dummy); DelWrapper(dummy); Swig_typemap_attach_parms("gotype", parms, NULL); Swig_typemap_attach_parms("goin", parms, NULL); Swig_typemap_attach_parms("goargout", parms, NULL); Swig_typemap_attach_parms("imtype", parms, NULL); int parm_count = emit_num_arguments(parms); String *func_name = NewString("NewDirector"); Append(func_name, go_name); String *func_with_over_name = Copy(func_name); if (overname) { Append(func_with_over_name, overname); } SwigType *first_type = NewString("int"); Parm *first_parm = NewParm(first_type, "swig_p", n); set_nextSibling(first_parm, parms); Setattr(first_parm, "lname", "p"); Parm *p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); Swig_cparm_name(p, i); p = nextParm(p); } if (!is_ignored) { Printv(f_cgo_comment, "extern uintptr_t ", wname, "(int", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); bool c_struct_type; String *ct = cgoTypeForGoValue(p, Getattr(p, "type"), &c_struct_type); Printv(f_cgo_comment, ", ", ct, " ", Getattr(p, "lname"), NULL); p = nextParm(p); } Printv(f_cgo_comment, ");\n", NULL); // Write out the Go function that calls the wrapper. Printv(f_go_wrappers, "func ", func_with_over_name, "(v interface{}", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); Printv(f_go_wrappers, ", ", Getattr(p, "lname"), " ", NULL); String *tm = goType(p, Getattr(p, "type")); Printv(f_go_wrappers, tm, NULL); Delete(tm); p = nextParm(p); } Printv(f_go_wrappers, ") ", cn, " {\n", NULL); Printv(f_go_wrappers, "\tp := &", director_struct_name, "{0, v}\n", NULL); String *call = NewString(""); Printv(call, "\tp.", class_receiver, " = ", NULL); Printv(call, go_type_name, "(C.", wname, "(C.int(swigDirectorAdd(p))", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { Printv(call, ", ", NULL); p = getParm(p); String *pt = Getattr(p, "type"); String *ln = Getattr(p, "lname"); String *ivar = NewStringf("_swig_i_%d", i); String *goin = goGetattr(p, "tmap:goin"); if (goin == NULL) { Printv(f_go_wrappers, "\t", ivar, " := ", NULL); bool need_close = false; if (goTypeIsInterface(p, pt)) { Printv(f_go_wrappers, "getSwigcptr(", NULL); need_close = true; } Printv(f_go_wrappers, ln, NULL); if (need_close) { Printv(f_go_wrappers, ")", NULL); } Printv(f_go_wrappers, "\n", NULL); } else { String *itm = goImType(p, pt); Printv(f_go_wrappers, "\tvar ", ivar, " ", itm, "\n", NULL); goin = Copy(goin); Replaceall(goin, "$input", ln); Replaceall(goin, "$result", ivar); Printv(f_go_wrappers, goin, "\n", NULL); Delete(goin); } Setattr(p, "emit:goinput", ivar); bool c_struct_type; String *ct = cgoTypeForGoValue(p, pt, &c_struct_type); if (c_struct_type) { Printv(call, "*(*C.", ct, ")(unsafe.Pointer(&", ivar, "))", NULL); } else { Printv(call, "C.", ct, "(", ivar, ")", NULL); } Delete(ct); p = nextParm(p); } Printv(call, "))", NULL); Printv(f_go_wrappers, call, "\n", NULL); goargout(parms); Printv(f_go_wrappers, "\treturn p\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); SwigType *result = Copy(Getattr(parentNode(n), "classtypeobj")); SwigType_add_pointer(result); Swig_save("classDirectorConstructor", n, "wrap:name", "wrap:action", NULL); String *dwname = Swig_name_wrapper(name); Append(dwname, unique_id); Setattr(n, "wrap:name", dwname); String *action = NewString(""); Printv(action, Swig_cresult_name(), " = new SwigDirector_", class_name, "(", NULL); String *pname = Swig_cparm_name(NULL, 0); Printv(action, pname, NULL); Delete(pname); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); String *pname = Swig_cparm_name(NULL, i + 1); Printv(action, ", ", NULL); if (SwigType_isreference(Getattr(p, "type"))) { Printv(action, "*", NULL); } Printv(action, pname, NULL); Delete(pname); p = nextParm(p); } Printv(action, ");", NULL); Setattr(n, "wrap:action", action); cgoWrapperInfo info; info.n = n; info.go_name = func_name; info.overname = overname; info.wname = wname; info.base = NULL; info.parms = first_parm; info.result = result; info.is_static = false; info.receiver = NULL; info.is_constructor = true; info.is_destructor = false; int r = cgoGccWrapper(&info); if (r != SWIG_OK) { return r; } Swig_restore(n); Delete(result); } String *cxx_director_name = NewString("SwigDirector_"); Append(cxx_director_name, class_name); String *decl = Swig_method_decl(NULL, Getattr(n, "decl"), cxx_director_name, first_parm, 0); Printv(f_c_directors_h, " ", decl, ";\n", NULL); Delete(decl); decl = Swig_method_decl(NULL, Getattr(n, "decl"), cxx_director_name, first_parm, 0); Printv(f_c_directors, cxx_director_name, "::", decl, "\n", NULL); Delete(decl); Printv(f_c_directors, " : ", Getattr(parentNode(n), "classtype"), "(", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (i > 0) { Printv(f_c_directors, ", ", NULL); } String *pn = Getattr(p, "name"); assert(pn); Printv(f_c_directors, pn, NULL); p = nextParm(p); } Printv(f_c_directors, "),\n", NULL); Printv(f_c_directors, " go_val(swig_p), swig_mem(0)\n", NULL); Printv(f_c_directors, "{ }\n\n", NULL); if (Getattr(n, "sym:overloaded") && !Getattr(n, "sym:nextSibling")) { int r = makeDispatchFunction(n, func_name, cn, is_static, Getattr(parentNode(n), "classtypeobj"), false); if (r != SWIG_OK) { return r; } } Delete(cxx_director_name); Delete(go_name); Delete(cn); Delete(go_type_name); Delete(director_struct_name); Delete(fn_name); Delete(fn_with_over_name); Delete(func_name); Delete(func_with_over_name); Delete(wname); Delete(first_type); Delete(first_parm); return SWIG_OK; } /* ------------------------------------------------------------ * classDirectorDestructor * * Emit a destructor for a director class. * ------------------------------------------------------------ */ int classDirectorDestructor(Node *n) { if (!is_public(n)) { return SWIG_OK; } bool is_ignored = GetFlag(n, "feature:ignore") ? true : false; if (!is_ignored) { String *fnname = NewString("DeleteDirector"); String *c1 = exportedName(class_name); Append(fnname, c1); Delete(c1); String *wname = Swig_name_wrapper(fnname); Append(wname, unique_id); Setattr(n, "wrap:name", fnname); Swig_DestructorToFunction(n, getNSpace(), getClassType(), CPlusPlus, Extend); ParmList *parms = Getattr(n, "parms"); Setattr(n, "wrap:parms", parms); String *result = NewString("void"); int r = makeWrappers(n, fnname, NULL, wname, NULL, parms, result, isStatic(n)); if (r != SWIG_OK) { return r; } Delete(result); Delete(fnname); Delete(wname); } // Generate the destructor for the C++ director class. Since the // Go code is keeping a pointer to the C++ object, we need to call // back to the Go code to let it know that the C++ object is gone. String *go_name = NewString("Swiggo_DeleteDirector_"); Append(go_name, class_name); String *cn = exportedName(class_name); String *director_struct_name = NewString("_swig_Director"); Append(director_struct_name, cn); Printv(f_c_directors_h, " virtual ~SwigDirector_", class_name, "()", NULL); String *throws = buildThrow(n); if (throws) { Printv(f_c_directors_h, " ", throws, NULL); } Printv(f_c_directors_h, ";\n", NULL); String *director_sig = NewString(""); Printv(director_sig, "SwigDirector_", class_name, "::~SwigDirector_", class_name, "()", NULL); if (throws) { Printv(director_sig, " ", throws, NULL); Delete(throws); } Printv(director_sig, "\n", NULL); Printv(director_sig, "{\n", NULL); if (is_ignored) { Printv(f_c_directors, director_sig, NULL); } else { makeDirectorDestructorWrapper(go_name, director_struct_name, director_sig); } Printv(f_c_directors, " delete swig_mem;\n", NULL); Printv(f_c_directors, "}\n\n", NULL); Delete(director_sig); Delete(go_name); Delete(cn); Delete(director_struct_name); return SWIG_OK; } /* ------------------------------------------------------------ * makeDirectorDestructorWrapper * * Emit the function wrapper for the destructor of a director class. * ------------------------------------------------------------ */ void makeDirectorDestructorWrapper(String *go_name, String *director_struct_name, String *director_sig) { String *wname = Copy(go_name); Append(wname, unique_id); Printv(f_go_wrappers, "//export ", wname, "\n", NULL); Printv(f_go_wrappers, "func ", wname, "(c int) {\n", NULL); Printv(f_go_wrappers, "\tswigDirectorLookup(c).(*", director_struct_name, ").", class_receiver, " = 0\n", NULL); Printv(f_go_wrappers, "\tswigDirectorDelete(c)\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Printv(f_c_directors, "extern \"C\" void ", wname, "(intgo);\n", NULL); Printv(f_c_directors, director_sig, NULL); Printv(f_c_directors, " ", wname, "(go_val);\n", NULL); } /* ------------------------------------------------------------ * classDirectorMethod * * Emit a method for a director class, plus its overloads. * ------------------------------------------------------------ */ int classDirectorMethod(Node *n, Node *parent, String *super) { bool is_ignored = GetFlag(n, "feature:ignore") ? true : false; // We don't need explicit calls. if (GetFlag(n, "explicitcall")) { return SWIG_OK; } String *name = Getattr(n, "sym:name"); if (!name) { assert(is_ignored); (void)is_ignored; name = Getattr(n, "name"); } bool overloaded = Getattr(n, "sym:overloaded") && !Getattr(n, "explicitcallnode"); if (!overloaded) { int r = oneClassDirectorMethod(n, parent, super); if (r != SWIG_OK) { return r; } } else { // Handle overloaded methods here, because otherwise we will // reject them in the class_methods hash table. We need to use // class_methods so that we correctly handle cases where a // function in one class hides a function of the same name in a // parent class. if (!Getattr(class_methods, name)) { for (Node *on = Getattr(n, "sym:overloaded"); on; on = Getattr(on, "sym:nextSibling")) { // Swig_overload_rank expects wrap:name and wrap:parms to be // set. String *wn = Swig_name_wrapper(Getattr(on, "sym:name")); Append(wn, Getattr(on, "sym:overname")); Append(wn, unique_id); Setattr(on, "wrap:name", wn); Delete(wn); Setattr(on, "wrap:parms", Getattr(on, "parms")); } } int r = oneClassDirectorMethod(n, parent, super); if (r != SWIG_OK) { return r; } if (!Getattr(n, "sym:nextSibling")) { // Last overloaded function Node *on = Getattr(n, "sym:overloaded"); bool is_static = isStatic(on); String *cn = exportedName(Getattr(parent, "sym:name")); String *go_name = buildGoName(name, is_static, false); String *director_struct_name = NewString("_swig_Director"); Append(director_struct_name, cn); int r = makeDispatchFunction(on, go_name, director_struct_name, is_static, director_struct_name, false); if (r != SWIG_OK) { return r; } if (!GetFlag(n, "abstract")) { String *go_upcall = NewString("Director"); Append(go_upcall, cn); Append(go_upcall, go_name); r = makeDispatchFunction(on, go_upcall, director_struct_name, is_static, director_struct_name, true); if (r != SWIG_OK) { return r; } Delete(go_upcall); } Delete(director_struct_name); Delete(go_name); Delete(cn); } } Setattr(class_methods, name, NewString("")); return SWIG_OK; } /* ------------------------------------------------------------ * oneClassDirectorMethod * * Emit a method for a director class. * ------------------------------------------------------------ */ int oneClassDirectorMethod(Node *n, Node *parent, String *super) { String *symname = Getattr(n, "sym:name"); if (!checkFunctionVisibility(n, parent)) { return SWIG_OK; } bool is_ignored = GetFlag(n, "feature:ignore") ? true : false; bool is_pure_virtual = (Cmp(Getattr(n, "storage"), "virtual") == 0 && Cmp(Getattr(n, "value"), "0") == 0); String *name = Getattr(n, "sym:name"); if (!name) { assert(is_ignored); name = Getattr(n, "name"); } String *overname = NULL; if (Getattr(n, "sym:overloaded")) { overname = Getattr(n, "sym:overname"); } String *cn = exportedName(Getattr(parent, "sym:name")); String *go_type_name = goCPointerType(Getattr(parent, "classtypeobj"), true); String *director_struct_name = NewString("_swig_Director"); Append(director_struct_name, cn); bool is_static = isStatic(n); String *go_name = buildGoName(name, is_static, false); ParmList *parms = Getattr(n, "parms"); Setattr(n, "wrap:parms", parms); Wrapper *dummy = NewWrapper(); emit_attach_parmmaps(parms, dummy); Swig_typemap_attach_parms("gotype", parms, NULL); Swig_typemap_attach_parms("imtype", parms, NULL); int parm_count = emit_num_arguments(parms); SwigType *result = Getattr(n, "type"); // Save the type for overload processing. Setattr(n, "go:type", result); String *interface_name = NewString("_swig_DirectorInterface"); Append(interface_name, cn); Append(interface_name, go_name); if (overname) { Append(interface_name, overname); } String *callback_name = Copy(director_struct_name); Append(callback_name, "_callback_"); Append(callback_name, name); Replace(callback_name, "_swig", "Swig", DOH_REPLACE_FIRST); if (overname) { Append(callback_name, overname); } Append(callback_name, unique_id); String *upcall_name = Copy(director_struct_name); Append(upcall_name, "_upcall_"); Append(upcall_name, go_name); String *upcall_wname = Swig_name_wrapper(upcall_name); if (overname) { Append(upcall_wname, overname); } Append(upcall_wname, unique_id); String *upcall_gc_name = buildGoWrapperName(upcall_name, overname); String *go_with_over_name = Copy(go_name); if (overname) { Append(go_with_over_name, overname); } Parm *p = 0; Wrapper *w = NewWrapper(); Swig_director_parms_fixup(parms); Swig_typemap_attach_parms("directorin", parms, w); Swig_typemap_attach_parms("directorargout", parms, w); Swig_typemap_attach_parms("godirectorin", parms, w); Swig_typemap_attach_parms("goin", parms, dummy); Swig_typemap_attach_parms("goargout", parms, dummy); DelWrapper(dummy); if (!is_ignored) { // We use an interface to see if this method is defined in Go. Printv(f_go_wrappers, "type ", interface_name, " interface {\n", NULL); Printv(f_go_wrappers, "\t", go_with_over_name, "(", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (i > 0) { Printv(f_go_wrappers, ", ", NULL); } String *tm = goType(p, Getattr(p, "type")); Printv(f_go_wrappers, tm, NULL); Delete(tm); p = nextParm(p); } Printv(f_go_wrappers, ")", NULL); if (SwigType_type(result) != T_VOID) { String *tm = goType(n, result); Printv(f_go_wrappers, " ", tm, NULL); Delete(tm); } Printv(f_go_wrappers, "\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); if (!GetFlag(n, "abstract")) { Printv(f_cgo_comment, "extern ", NULL); if (SwigType_type(result) == T_VOID) { Printv(f_cgo_comment, "void", NULL); } else { bool c_struct_type; String *ret_type = cgoTypeForGoValue(n, result, &c_struct_type); Printv(f_cgo_comment, ret_type, NULL); Delete(ret_type); } Printv(f_cgo_comment, " ", upcall_wname, "(uintptr_t", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); bool c_struct_type; String *ct = cgoTypeForGoValue(p, Getattr(p, "type"), &c_struct_type); Printv(f_cgo_comment, ", ", ct, " ", Getattr(p, "lname"), NULL); p = nextParm(p); } Printv(f_cgo_comment, ");\n", NULL); } // Define the method on the director class in Go. Printv(f_go_wrappers, "func (swig_p *", director_struct_name, ") ", go_with_over_name, "(", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (i > 0) { Printv(f_go_wrappers, ", ", NULL); } Printv(f_go_wrappers, Getattr(p, "lname"), " ", NULL); String *tm = goType(p, Getattr(p, "type")); Printv(f_go_wrappers, tm, NULL); Delete(tm); p = nextParm(p); } Printv(f_go_wrappers, ")", NULL); if (SwigType_type(result) != T_VOID) { String *tm = goType(n, result); Printv(f_go_wrappers, " ", tm, NULL); Delete(tm); } Printv(f_go_wrappers, " {\n", NULL); Printv(f_go_wrappers, "\tif swig_g, swig_ok := swig_p.v.(", interface_name, "); swig_ok {\n", NULL); Printv(f_go_wrappers, "\t\t", NULL); if (SwigType_type(result) != T_VOID) { Printv(f_go_wrappers, "return ", NULL); } Printv(f_go_wrappers, "swig_g.", go_with_over_name, "(", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (i > 0) { Printv(f_go_wrappers, ", ", NULL); } Printv(f_go_wrappers, Getattr(p, "lname"), NULL); p = nextParm(p); } Printv(f_go_wrappers, ")\n", NULL); if (SwigType_type(result) == T_VOID) { Printv(f_go_wrappers, "\t\treturn\n", NULL); } Printv(f_go_wrappers, "\t}\n", NULL); if (GetFlag(n, "abstract")) { Printv(f_go_wrappers, "\tpanic(\"call to pure virtual method\")\n", NULL); } else { String *ret_type = NULL; bool memcpy_ret = false; String *wt = NULL; String *goout = NULL; if (SwigType_type(result) != T_VOID) { ret_type = goImType(n, result); Printv(f_go_wrappers, "\tvar swig_r ", ret_type, "\n", NULL); goout = goTypemapLookup("goout", n, "swig_r"); bool c_struct_type; Delete(cgoTypeForGoValue(n, result, &c_struct_type)); if (c_struct_type) { memcpy_ret = true; } } String *call = NewString(""); Printv(call, "\t", NULL); if (SwigType_type(result) != T_VOID) { if (memcpy_ret) { Printv(call, "swig_r_p := ", NULL); } else { Printv(call, "swig_r = (", ret_type, ")(", NULL); } if (goTypeIsInterface(n, result)) { wt = goWrapperType(n, result, true); Printv(call, "(", wt, ")(", NULL); } } Printv(call, "C.", upcall_wname, "(C.uintptr_t(swig_p.", go_type_name, ")", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { Printv(call, ", ", NULL); p = getParm(p); SwigType *pt = Getattr(p, "type"); String *ln = Getattr(p, "lname"); String *ivar = NewStringf("_swig_i_%d", i); // This is an ordinary call from Go to C++, so adjust using // the goin typemap. String *goin = goGetattr(p, "tmap:goin"); if (goin == NULL) { Printv(f_go_wrappers, "\t", ivar, " := ", NULL); bool need_close = false; if (goTypeIsInterface(p, pt)) { Printv(f_go_wrappers, "getSwigcptr(", NULL); need_close = true; } Printv(f_go_wrappers, ln, NULL); if (need_close) { Printv(f_go_wrappers, ")", NULL); } Printv(f_go_wrappers, "\n", NULL); } else { String *itm = goImType(p, pt); Printv(f_go_wrappers, "\tvar ", ivar, " ", itm, "\n", NULL); goin = Copy(goin); Replaceall(goin, "$input", ln); Replaceall(goin, "$result", ivar); Printv(f_go_wrappers, goin, "\n", NULL); Delete(goin); } Setattr(p, "emit:goinput", ivar); bool c_struct_type; String *ct = cgoTypeForGoValue(p, pt, &c_struct_type); if (c_struct_type) { Printv(call, "*(*C.", ct, ")(unsafe.Pointer(&", ivar, "))", NULL); } else { Printv(call, "C.", ct, "(", ivar, ")", NULL); } p = nextParm(p); } Printv(call, ")", NULL); if (wt) { // Close the type conversion to the wrapper type. Printv(call, ")", NULL); } if (SwigType_type(result) != T_VOID && !memcpy_ret) { // Close the type conversion of the return value. Printv(call, ")", NULL); } Printv(call, "\n", NULL); Printv(f_go_wrappers, call, NULL); Delete(call); if (memcpy_ret) { Printv(f_go_wrappers, "\tswig_r = *(*", ret_type, ")(unsafe.Pointer(&swig_r_p))\n", NULL); } goargout(parms); if (SwigType_type(result) != T_VOID) { if (goout == NULL) { Printv(f_go_wrappers, "\treturn swig_r\n", NULL); } else { String *tm = goType(n, result); Printv(f_go_wrappers, "\tvar swig_r_1 ", tm, "\n", NULL); Replaceall(goout, "$input", "swig_r"); Replaceall(goout, "$result", "swig_r_1"); Printv(f_go_wrappers, goout, "\n", NULL); Printv(f_go_wrappers, "\treturn swig_r_1\n", NULL); } } if (ret_type) { Delete(ret_type); } if (wt) { Delete(wt); } } Printv(f_go_wrappers, "}\n\n", NULL); if (!GetFlag(n, "abstract")) { // Define a function that uses the Go director type that other // methods in the Go type can call to get parent methods. Printv(f_go_wrappers, "func Director", cn, go_with_over_name, "(swig_p ", cn, NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); Printv(f_go_wrappers, ", ", Getattr(p, "lname"), " ", NULL); String *tm = goType(p, Getattr(p, "type")); Printv(f_go_wrappers, tm, NULL); Delete(tm); p = nextParm(p); } Printv(f_go_wrappers, ")", NULL); if (SwigType_type(result) != T_VOID) { String *tm = goType(n, result); Printv(f_go_wrappers, " ", tm, NULL); Delete(tm); } Printv(f_go_wrappers, " {\n", NULL); String *ret_type = NULL; bool memcpy_ret = false; String *wt = NULL; String *goout = NULL; if (SwigType_type(result) != T_VOID) { ret_type = goImType(n, result); Printv(f_go_wrappers, "\tvar swig_r ", ret_type, "\n", NULL); goout = goTypemapLookup("goout", n, "swig_r"); bool c_struct_type; Delete(cgoTypeForGoValue(n, result, &c_struct_type)); if (c_struct_type) { memcpy_ret = true; } } String *call = NewString(""); Printv(call, "\t", NULL); if (SwigType_type(result) != T_VOID) { if (memcpy_ret) { Printv(call, "swig_r_p := ", NULL); } else { Printv(call, "swig_r = (", ret_type, ")(", NULL); } if (goTypeIsInterface(n, result)) { wt = goWrapperType(n, result, true); Printv(call, "(", wt, ")(", NULL); } } Printv(call, "C.", upcall_wname, "(C.uintptr_t(swig_p.(*", director_struct_name, ").", go_type_name, ")", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { Printv(call, ", ", NULL); p = getParm(p); SwigType *pt = Getattr(p, "type"); String *ivar = NewStringf("_swig_i_%d", i); String *ln = Copy(Getattr(p, "lname")); String *goin = goGetattr(p, "tmap:goin"); if (goin == NULL) { Printv(f_go_wrappers, "\t", ivar, " := ", NULL); bool need_close = false; if (goTypeIsInterface(p, pt)) { Printv(f_go_wrappers, "getSwigcptr(", NULL); need_close = true; } Printv(f_go_wrappers, ln, NULL); if (need_close) { Printv(f_go_wrappers, ")", NULL); } Printv(f_go_wrappers, "\n", NULL); } else { String *itm = goImType(p, pt); Printv(f_go_wrappers, "\tvar ", ivar, " ", itm, "\n", NULL); goin = Copy(goin); Replaceall(goin, "$input", ln); Replaceall(goin, "$result", ivar); Printv(f_go_wrappers, goin, "\n", NULL); Delete(goin); } Setattr(p, "emit:goinput", ivar); bool c_struct_type; String *ct = cgoTypeForGoValue(p, pt, &c_struct_type); if (c_struct_type) { Printv(call, "*(*C.", ct, ")(unsafe.Pointer(&", ivar, "))", NULL); } else { Printv(call, "C.", ct, "(", ivar, ")", NULL); } Delete(ln); p = nextParm(p); } Printv(call, ")", NULL); if (wt) { // Close the type conversion to the wrapper type. Printv(call, ")", NULL); } if (SwigType_type(result) != T_VOID && !memcpy_ret) { // Close the type conversion of the return value. Printv(call, ")", NULL); } Printv(call, "\n", NULL); Printv(f_go_wrappers, call, NULL); Delete(call); if (memcpy_ret) { Printv(f_go_wrappers, "\tswig_r = *(*", ret_type, ")(unsafe.Pointer(&swig_r_p))\n", NULL); } goargout(parms); if (SwigType_type(result) != T_VOID) { if (goout == NULL) { Printv(f_go_wrappers, "\treturn swig_r\n", NULL); } else { String *tm = goType(n, result); Printv(f_go_wrappers, "\tvar swig_r_1 ", tm, "\n", NULL); Replaceall(goout, "$input", "swig_r"); Replaceall(goout, "$result", "swig_r_1"); Printv(f_go_wrappers, goout, "\n", NULL); Printv(f_go_wrappers, "\treturn swig_r_1\n", NULL); } } Printv(f_go_wrappers, "}\n\n", NULL); if (ret_type) { Delete(ret_type); } if (wt) { Delete(wt); } // Define a method in the C++ director class that the C++ // upcall function can call. This permits an upcall to a // protected method. String *upcall_method_name = NewString("_swig_upcall_"); Append(upcall_method_name, name); if (overname) { Append(upcall_method_name, overname); } SwigType *rtype = Getattr(n, "classDirectorMethods:type"); String *upcall_decl = Swig_method_decl(rtype, Getattr(n, "decl"), upcall_method_name, parms, 0); Printv(f_c_directors_h, " ", upcall_decl, " {\n", NULL); Delete(upcall_decl); Printv(f_c_directors_h, " ", NULL); if (SwigType_type(result) != T_VOID) { Printv(f_c_directors_h, "return ", NULL); } String *super_call = Swig_method_call(super, parms); Printv(f_c_directors_h, super_call, ";\n", NULL); Delete(super_call); Printv(f_c_directors_h, " }\n", NULL); // Define the C++ function that the Go function calls. SwigType *first_type = NULL; Parm *first_parm = parms; if (!is_static) { first_type = NewString("SwigDirector_"); Append(first_type, class_name); SwigType_add_pointer(first_type); first_parm = NewParm(first_type, "p", n); set_nextSibling(first_parm, parms); } Swig_save("classDirectorMethod", n, "wrap:name", "wrap:action", NULL); Setattr(n, "wrap:name", upcall_wname); String *action = NewString(""); if (SwigType_type(result) != T_VOID) { Printv(action, Swig_cresult_name(), " = (", SwigType_lstr(result, 0), ")", NULL); if (SwigType_isreference(result)) { Printv(action, "&", NULL); } } Printv(action, Swig_cparm_name(NULL, 0), "->", upcall_method_name, "(", NULL); p = parms; int i = 0; while (p != NULL) { if (SwigType_type(Getattr(p, "type")) != T_VOID) { String *pname = Swig_cparm_name(NULL, i + 1); if (i > 0) { Printv(action, ", ", NULL); } // A parameter whose type is a reference is converted into a // pointer type by gcCTypeForGoValue. We are calling a // function which expects a reference so we need to convert // back. if (SwigType_isreference(Getattr(p, "type"))) { Printv(action, "*", NULL); } Printv(action, pname, NULL); Delete(pname); i++; } p = nextSibling(p); } Printv(action, ");", NULL); Setattr(n, "wrap:action", action); cgoWrapperInfo info; info.n = n; info.go_name = go_name; info.overname = overname; info.wname = upcall_wname; info.base = NULL; info.parms = first_parm; info.result = result; info.is_static = is_static; info.receiver = NULL; info.is_constructor = false; info.is_destructor = false; int r = cgoGccWrapper(&info); if (r != SWIG_OK) { return r; } Delete(first_type); if (first_parm != parms) { Delete(first_parm); } Swig_restore(n); Delete(upcall_method_name); } // The Go function which invokes the method. This is called by // the C++ method on the director class. Printv(f_go_wrappers, "//export ", callback_name, "\n", "func ", callback_name, "(swig_c int", NULL); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); String *tm = goWrapperType(p, Getattr(p, "type"), false); Printv(f_go_wrappers, ", ", Getattr(p, "lname"), " ", tm, NULL); Delete(tm); p = nextParm(p); } Printv(f_go_wrappers, ") ", NULL); String *result_wrapper = NULL; if (SwigType_type(result) != T_VOID) { result_wrapper = goWrapperType(n, result, true); Printv(f_go_wrappers, "(swig_result ", result_wrapper, ") ", NULL); } Printv(f_go_wrappers, "{\n", NULL); if (is_ignored) { Printv(f_go_wrappers, "\treturn\n", NULL); } else { bool result_is_interface = false; String *goout = NULL; if (SwigType_type(result) != T_VOID) { result_is_interface = goTypeIsInterface(NULL, result); Printv(f_go_wrappers, "\tvar swig_r ", NULL); if (!result_is_interface) { Printv(f_go_wrappers, goType(n, result), NULL); } else { Printv(f_go_wrappers, result_wrapper, NULL); } Printv(f_go_wrappers, "\n", NULL); goout = goTypemapLookup("godirectorout", n, "swig_r"); } String *call = NewString(""); Printv(call, "\t", NULL); if (SwigType_type(result) != T_VOID) { Printv(call, "swig_r = ", NULL); if (result_is_interface) { Printv(call, result_wrapper, "(getSwigcptr(", NULL); } } Printv(call, "swig_p.", go_with_over_name, "(", NULL); String *goincode = NewString(""); p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (i > 0) { Printv(call, ", ", NULL); } SwigType *pt = Getattr(p, "type"); String *ln = NewString(""); // If the Go representation is an interface type class, then // we are receiving a uintptr, and must convert to the // interface. bool is_interface = goTypeIsInterface(p, pt); if (is_interface) { // Passing is_result as true to goWrapperType gives us the // name of the Go type we need to convert to an interface. String *wt = goWrapperType(p, pt, true); Printv(ln, wt, "(", NULL); Delete(wt); } Printv(ln, Getattr(p, "lname"), NULL); if (is_interface) { Printv(ln, ")", NULL); } String *goin = goGetattr(p, "tmap:godirectorin"); if (goin == NULL) { Printv(call, ln, NULL); } else { String *ivar = NewString(""); Printf(ivar, "_swig_i_%d", i); String *itm = goType(p, pt); Printv(f_go_wrappers, "\tvar ", ivar, " ", itm, "\n", NULL); goin = Copy(goin); Replaceall(goin, "$input", ln); Replaceall(goin, "$result", ivar); Printv(goincode, goin, "\n", NULL); Delete(goin); Printv(call, ivar, NULL); Delete(ivar); } Delete(ln); p = nextParm(p); } Printv(call, ")", NULL); if (result_is_interface) { Printv(call, "))", NULL); } Printv(call, "\n", NULL); Printv(f_go_wrappers, "\tswig_p := swigDirectorLookup(swig_c).(*", director_struct_name, ")\n", NULL); Printv(f_go_wrappers, goincode, NULL); Printv(f_go_wrappers, call, NULL); Delete(call); if (SwigType_type(result) != T_VOID) { if (goout == NULL) { Printv(f_go_wrappers, "\treturn swig_r\n", NULL); } else { String *tm = goImType(n, result); Printv(f_go_wrappers, "\tvar swig_r_1 ", tm, "\n", NULL); Replaceall(goout, "$input", "swig_r"); Replaceall(goout, "$result", "swig_r_1"); Printv(f_go_wrappers, goout, "\n", NULL); Printv(f_go_wrappers, "\treturn swig_r_1\n", NULL); } } } Printv(f_go_wrappers, "}\n\n", NULL); Delete(result_wrapper); Delete(upcall_wname); Delete(upcall_gc_name); Delete(go_with_over_name); } if (!is_ignored || is_pure_virtual) { // Declare the method for the director class. SwigType *rtype = Getattr(n, "conversion_operator") ? 0 : Getattr(n, "classDirectorMethods:type"); String *decl = Swig_method_decl(rtype, Getattr(n, "decl"), Getattr(n, "name"), parms, 0); Printv(f_c_directors_h, " virtual ", decl, NULL); Delete(decl); String *qname = NewString(""); Printv(qname, "SwigDirector_", class_name, "::", Getattr(n, "name"), NULL); decl = Swig_method_decl(rtype, Getattr(n, "decl"), qname, parms, 0); Printv(w->def, decl, NULL); Delete(decl); Delete(qname); String *throws = buildThrow(n); if (throws) { Printv(f_c_directors_h, " ", throws, NULL); Printv(w->def, " ", throws, NULL); Delete(throws); } Printv(f_c_directors_h, ";\n", NULL); Printv(w->def, " {\n", NULL); if (SwigType_type(result) != T_VOID) { if (!SwigType_isclass(result)) { if (!(SwigType_ispointer(result) || SwigType_isreference(result))) { String *construct_result = NewStringf("= SwigValueInit< %s >()", SwigType_lstr(result, 0)); Wrapper_add_localv(w, "c_result", SwigType_lstr(result, "c_result"), construct_result, NIL); Delete(construct_result); } else { Wrapper_add_localv(w, "c_result", SwigType_lstr(result, "c_result"), "= 0", NIL); } } else { String *cres = SwigType_lstr(result, "c_result"); Printf(w->code, "%s;\n", cres); Delete(cres); } } if (!is_ignored) { makeDirectorMethodWrapper(n, w, callback_name); } else { assert(is_pure_virtual); Printv(w->code, " _swig_gopanic(\"call to pure virtual function ", Getattr(parent, "sym:name"), name, "\");\n", NULL); if (SwigType_type(result) != T_VOID) { String *retstr = SwigType_rcaststr(result, "c_result"); Printv(w->code, " return ", retstr, ";\n", NULL); Delete(retstr); } } Printv(w->code, "}", NULL); Replaceall(w->code, "$symname", symname); Wrapper_print(w, f_c_directors); } Delete(cn); Delete(go_type_name); Delete(director_struct_name); Delete(interface_name); Delete(callback_name); Delete(upcall_name); Delete(go_name); DelWrapper(w); return SWIG_OK; } /* ------------------------------------------------------------ * makeDirectorMethodWrapper * * Emit the function wrapper for a director method. * ------------------------------------------------------------ */ void makeDirectorMethodWrapper(Node *n, Wrapper *w, String *callback_name) { ParmList *parms = Getattr(n, "wrap:parms"); SwigType *result = Getattr(n, "type"); Printv(f_c_directors, "extern \"C\" ", NULL); String *fnname = Copy(callback_name); Append(fnname, "(int"); Parm *p = parms; while (p) { while (checkAttribute(p, "tmap:directorin:numinputs", "0")) { p = Getattr(p, "tmap:directorin:next"); } String *cg = gcCTypeForGoValue(p, Getattr(p, "type"), Getattr(p, "lname")); Printv(fnname, ", ", cg, NULL); Delete(cg); p = Getattr(p, "tmap:directorin:next"); } Printv(fnname, ")", NULL); if (SwigType_type(result) == T_VOID) { Printv(f_c_directors, "void ", fnname, NULL); } else { String *tm = gcCTypeForGoValue(n, result, fnname); Printv(f_c_directors, tm, NULL); Delete(tm); } Delete(fnname); Printv(f_c_directors, ";\n", NULL); if (SwigType_type(result) != T_VOID) { String *r = NewString(Swig_cresult_name()); String *tm = gcCTypeForGoValue(n, result, r); Wrapper_add_local(w, r, tm); Delete(tm); Delete(r); } String *args = NewString(""); p = parms; while (p) { while (checkAttribute(p, "tmap:directorin:numinputs", "0")) { p = Getattr(p, "tmap:directorin:next"); } String *pn = NewString("swig_"); Append(pn, Getattr(p, "lname")); Setattr(p, "emit:directorinput", pn); String *tm = gcCTypeForGoValue(p, Getattr(p, "type"), pn); Wrapper_add_local(w, pn, tm); Delete(tm); tm = Getattr(p, "tmap:directorin"); if (!tm) { Swig_warning(WARN_TYPEMAP_DIRECTORIN_UNDEF, input_file, line_number, "Unable to use type %s as director method argument\n", SwigType_str(Getattr(p, "type"), 0)); } else { tm = Copy(tm); Replaceall(tm, "$input", pn); Replaceall(tm, "$owner", 0); Printv(w->code, " ", tm, "\n", NULL); Delete(tm); Printv(args, ", ", pn, NULL); } p = Getattr(p, "tmap:directorin:next"); } Printv(w->code, " ", NULL); if (SwigType_type(result) != T_VOID) { Printv(w->code, Swig_cresult_name(), " = ", NULL); } Printv(w->code, callback_name, "(go_val", args, ");\n", NULL); /* Marshal outputs */ for (p = parms; p; ) { String *tm; if ((tm = Getattr(p, "tmap:directorargout"))) { tm = Copy(tm); Replaceall(tm, "$result", "jresult"); Replaceall(tm, "$input", Getattr(p, "emit:directorinput")); Printv(w->code, tm, "\n", NULL); Delete(tm); p = Getattr(p, "tmap:directorargout:next"); } else { p = nextSibling(p); } } if (SwigType_type(result) != T_VOID) { String *result_str = NewString("c_result"); String *tm = Swig_typemap_lookup("directorout", n, result_str, NULL); if (!tm) { Swig_warning(WARN_TYPEMAP_DIRECTOROUT_UNDEF, input_file, line_number, "Unable to use type %s as director method result\n", SwigType_str(result, 0)); } else { tm = Copy(tm); Replaceall(tm, "$input", Swig_cresult_name()); Replaceall(tm, "$result", "c_result"); Printv(w->code, " ", tm, "\n", NULL); String *retstr = SwigType_rcaststr(result, "c_result"); Printv(w->code, " return ", retstr, ";\n", NULL); Delete(retstr); Delete(tm); } Delete(result_str); } } /* ------------------------------------------------------------ * classDirectorEnd * * Complete support for a director class. * ------------------------------------------------------------ */ int classDirectorEnd(Node *n) { (void) n; Printv(f_c_directors_h, " private:\n", NULL); Printv(f_c_directors_h, " intgo go_val;\n", NULL); Printv(f_c_directors_h, " Swig_memory *swig_mem;\n", NULL); Printv(f_c_directors_h, "};\n\n", NULL); class_name = NULL; class_node = NULL; Delete(class_receiver); class_receiver = NULL; Delete(class_methods); class_methods = NULL; return SWIG_OK; } /* ------------------------------------------------------------ * classDirectorDisown * * I think Go does not require a disown method. * ------------------------------------------------------------ */ int classDirectorDisown(Node *n) { (void) n; return SWIG_OK; } /*---------------------------------------------------------------------- * buildThrow() * * Build and return a throw clause if needed. *--------------------------------------------------------------------*/ String *buildThrow(Node *n) { if (Getattr(n, "noexcept")) return NewString("noexcept"); ParmList *throw_parm_list = Getattr(n, "throws"); if (!throw_parm_list && !Getattr(n, "throw")) return NULL; String *ret = NewString("throw("); if (throw_parm_list) { Swig_typemap_attach_parms("throws", throw_parm_list, NULL); } bool first = true; for (Parm *p = throw_parm_list; p; p = nextSibling(p)) { if (Getattr(p, "tmap:throws")) { if (first) { first = false; } else { Printv(ret, ", ", NULL); } String *s = SwigType_str(Getattr(p, "type"), 0); Printv(ret, s, NULL); Delete(s); } } Printv(ret, ")", NULL); return ret; } /*---------------------------------------------------------------------- * extraDirectorProtectedCPPMethodsRequired() * * We don't need to check upcall when calling methods. *--------------------------------------------------------------------*/ bool extraDirectorProtectedCPPMethodsRequired() const { return false; } /*---------------------------------------------------------------------- * makeDispatchFunction * * Make a dispatch function for an overloaded C++ function. The * receiver parameter is the receiver for a method, unless is_upcall * is true. If is_upcall is true, then the receiver parameter is * the type of the first argument to the function. *--------------------------------------------------------------------*/ int makeDispatchFunction(Node *n, String *go_name, String *receiver, bool is_static, SwigType *director_struct, bool is_upcall) { bool is_director = director_struct ? true : false; String *nodetype = Getattr(n, "nodeType"); bool is_constructor = Cmp(nodetype, "constructor") == 0; bool is_destructor = Cmp(nodetype, "destructor") == 0; bool can_use_receiver = (!is_constructor && !is_destructor && !is_upcall); bool use_receiver = (!is_static && can_use_receiver); bool add_to_interface = (interfaces && !is_constructor && !is_destructor && !is_static && !is_upcall); List *dispatch = Swig_overload_rank(n, false); int nfunc = Len(dispatch); SwigType *all_result; bool mismatch; if (is_constructor) { assert(!is_upcall); if (!is_director) { all_result = Copy(Getattr(class_node, "classtypeobj")); } else { all_result = Copy(director_struct); } mismatch = false; } else { all_result = NULL; mismatch = false; bool any_void = false; for (int i = 0; i < nfunc; ++i) { Node *nn = Getitem(dispatch, i); Node *ni = Getattr(nn, "directorNode") ? Getattr(nn, "directorNode") : nn; SwigType *result = Getattr(ni, "go:type"); assert(result); if (SwigType_type(result) == T_VOID) { if (all_result) { mismatch = true; } any_void = true; } else { if (any_void) { mismatch = true; } else if (!all_result) { all_result = Copy(result); } else if (Cmp(result, all_result) != 0) { mismatch = true; } } } if (mismatch) { Delete(all_result); all_result = NULL; } else if (all_result) { ; } else { all_result = NewString("void"); } } Printv(f_go_wrappers, "func ", NULL); if (receiver && use_receiver) { Printv(f_go_wrappers, "(p ", receiver, ") ", NULL); } Printv(f_go_wrappers, go_name, "(", NULL); if (is_director && is_constructor) { Printv(f_go_wrappers, "abi interface{}, ", NULL); assert(!add_to_interface); } if (is_upcall) { Printv(f_go_wrappers, "p *", receiver, ", ", NULL); assert(!add_to_interface); } Printv(f_go_wrappers, "a ...interface{})", NULL); if (add_to_interface) { Printv(interfaces, "\t", go_name, "(a ...interface{})", NULL); } if (mismatch) { Printv(f_go_wrappers, " interface{}", NULL); if (add_to_interface) { Printv(interfaces, " interface{}", NULL); } } else if (all_result && SwigType_type(all_result) != T_VOID) { if (is_director && is_constructor) { Printv(f_go_wrappers, " ", receiver, NULL); if (add_to_interface) { Printv(interfaces, " ", receiver, NULL); } } else { String *tm = goType(n, all_result); Printv(f_go_wrappers, " ", tm, NULL); if (add_to_interface) { Printv(interfaces, " ", tm, NULL); } Delete(tm); } } Printv(f_go_wrappers, " {\n", NULL); if (add_to_interface) { Printv(interfaces, "\n", NULL); } Printv(f_go_wrappers, "\targc := len(a)\n", NULL); for (int i = 0; i < nfunc; ++i) { int fn = 0; Node *nn = Getitem(dispatch, i); Node *ni = Getattr(nn, "directorNode") ? Getattr(nn, "directorNode") : nn; Parm *pi = Getattr(ni, "wrap:parms"); // If we are using a receiver, we want to ignore a leading self // parameter. Because of the way this is called, there may or // may not be a self parameter at this point. if (use_receiver && pi && Getattr(pi, "self")) { pi = getParm(pi); if (pi) { pi = nextParm(pi); } } int num_required = emit_num_required(pi); int num_arguments = emit_num_arguments(pi); bool varargs = emit_isvarargs(pi) ? true : false; if (varargs) { Printf(f_go_wrappers, "\tif argc >= %d {\n", num_required); } else { if (num_required == num_arguments) { Printf(f_go_wrappers, "\tif argc == %d {\n", num_required); } else { Printf(f_go_wrappers, "\tif argc >= %d && argc <= %d {\n", num_required, num_arguments); } } // Build list of collisions with the same number of arguments. List *coll = NewList(); for (int k = i + 1; k < nfunc; ++k) { Node *nnk = Getitem(dispatch, k); Node *nk = Getattr(nnk, "directorNode") ? Getattr(nnk, "directorNode") : nnk; Parm *pk = Getattr(nk, "wrap:parms"); if (use_receiver && pk && Getattr(pk, "self")) { pk = getParm(pk); if (pk) { pk = nextParm(pk); } } int nrk = emit_num_required(pk); int nak = emit_num_arguments(pk); if ((nrk >= num_required && nrk <= num_arguments) || (nak >= num_required && nak <= num_arguments) || (nrk <= num_required && nak >= num_arguments) || (varargs && nrk >= num_required)) { Append(coll, nk); } } int num_braces = 0; if (Len(coll) > 0 && num_arguments > 0) { int j = 0; Parm *pj = pi; while (pj) { pj = getParm(pj); if (!pj) { break; } // If all the overloads have the same type in this position, // we can omit the check. SwigType *tm = goOverloadType(pj, Getattr(pj, "type")); bool emitcheck = false; for (int k = 0; k < Len(coll) && !emitcheck; ++k) { Node *nk = Getitem(coll, k); Parm *pk = Getattr(nk, "wrap:parms"); if (use_receiver && pk && Getattr(pk, "self")) { pk = getParm(pk); if (pk) { pk = nextParm(pk); } } int nak = emit_num_arguments(pk); if (nak <= j) continue; int l = 0; Parm *pl = pk; while (pl && l <= j) { pl = getParm(pl); if (!pl) { break; } if (l == j) { SwigType *tml = goOverloadType(pl, Getattr(pl, "type")); if (Cmp(tm, tml) != 0) { emitcheck = true; } Delete(tml); } pl = nextParm(pl); ++l; } } if (emitcheck) { if (j >= num_required) { Printf(f_go_wrappers, "\t\tif argc > %d {\n", j); ++num_braces; } fn = i + 1; Printf(f_go_wrappers, "\t\tif _, ok := a[%d].(%s); !ok {\n", j, tm); Printf(f_go_wrappers, "\t\t\tgoto check_%d\n", fn); Printv(f_go_wrappers, "\t\t}\n", NULL); } Delete(tm); pj = nextParm(pj); ++j; } } for (; num_braces > 0; --num_braces) { Printv(f_go_wrappers, "\t\t}\n", NULL); } // We may need to generate multiple calls if there are variable // argument lists involved. Build the start of the call. String *start = NewString(""); SwigType *result = Getattr(ni, "go:type"); if (is_constructor) { result = all_result; } else if (is_destructor) { result = NULL; } if (result && SwigType_type(result) != T_VOID && (!all_result || SwigType_type(all_result) != T_VOID)) { Printv(start, "return ", NULL); } bool advance_parm = false; if (receiver && use_receiver) { Printv(start, "p.", go_name, NULL); } else if (can_use_receiver && !isStatic(ni) && pi && Getattr(pi, "self")) { // This is an overload of a static function and a non-static // function. assert(num_required > 0); SwigType *tm = goWrapperType(pi, Getattr(pi, "type"), true); String *nm = buildGoName(Getattr(ni, "sym:name"), false, isFriend(ni)); Printv(start, "a[0].(", tm, ").", nm, NULL); Delete(nm); Delete(tm); advance_parm = true; } else { Printv(start, go_name, NULL); } Printv(start, Getattr(ni, "sym:overname"), "(", NULL); bool need_comma = false; if (is_director && is_constructor) { Printv(start, "abi", NULL); need_comma = true; } if (is_upcall) { Printv(start, "p", NULL); need_comma = true; } Parm *p = pi; int pn = 0; if (advance_parm) { p = getParm(p); if (p) { p = nextParm(p); } ++pn; } while (pn < num_required) { p = getParm(p); if (need_comma) { Printv(start, ", ", NULL); } SwigType *tm = goType(p, Getattr(p, "type")); Printf(start, "a[%d].(%s)", pn, tm); Delete(tm); need_comma = true; ++pn; p = nextParm(p); } String *end = NULL; if (!result || SwigType_type(result) == T_VOID || (all_result && SwigType_type(all_result) == T_VOID)) { end = NewString(""); Printv(end, "return", NULL); if (!all_result || SwigType_type(all_result) != T_VOID) { Printv(end, " 0", NULL); } } if (num_required == num_arguments) { Printv(f_go_wrappers, "\t\t", start, ")\n", NULL); if (end) { Printv(f_go_wrappers, "\t\t", end, "\n", NULL); } } else { Printv(f_go_wrappers, "\t\tswitch argc {\n", NULL); for (int j = num_required; j <= num_arguments; ++j) { Printf(f_go_wrappers, "\t\tcase %d:\n", j); Printv(f_go_wrappers, "\t\t\t", start, NULL); bool nc = need_comma; for (int k = num_required; k < j; ++k) { if (nc) { Printv(f_go_wrappers, ", ", NULL); } Printf(f_go_wrappers, "a[%d]", k); nc = true; } Printv(f_go_wrappers, ")\n", NULL); if (end) { Printv(f_go_wrappers, "\t\t\t", end, "\n", NULL); } } Printv(f_go_wrappers, "\t\t}\n", NULL); } Printv(f_go_wrappers, "\t}\n", NULL); if (fn != 0) { Printf(f_go_wrappers, "check_%d:\n", fn); } Delete(coll); } Printv(f_go_wrappers, "\tpanic(\"No match for overloaded function call\")\n", NULL); Printv(f_go_wrappers, "}\n\n", NULL); Delete(all_result); Delete(dispatch); return SWIG_OK; } /* ---------------------------------------------------------------------- * checkFunctionVisibility() * * Return true if we should write out a function based on its * visibility, false otherwise. * ---------------------------------------------------------------------- */ bool checkFunctionVisibility(Node *n, Node *parent) { // Write out a public function. if (is_public(n)) return true; // Don't write out a private function. if (is_private(n)) return false; // Write a protected function for a director class in // dirprot_mode. if (parent == NULL) { return false; } if (dirprot_mode() && Swig_directorclass(parent)) return true; // Otherwise don't write out a protected function. return false; } /* ---------------------------------------------------------------------- * exportedName() * * Given a C/C++ name, return a name in Go which will be exported. * If the first character is an upper case letter, this returns a * copy of its argument. If the first character is a lower case * letter, this forces it to upper case. Otherwise, this prepends * 'X'. * ---------------------------------------------------------------------- */ String *exportedName(SwigType *name) { SwigType *copy = Copy(name); char c = *Char(copy); if (islower(c)) { char l[2]; char u[2]; l[0] = c; l[1] = '\0'; u[0] = toupper(c); u[1] = '\0'; Replace(copy, l, u, DOH_REPLACE_FIRST); } else if (!isalpha(c)) { char l[2]; char u[3]; l[0] = c; l[1] = '\0'; u[0] = 'X'; u[1] = c; u[2] = '\0'; Replace(copy, l, u, DOH_REPLACE_FIRST); } String *ret = Swig_name_mangle_type(copy); Delete(copy); return ret; } /* ---------------------------------------------------------------------- * removeClassname() * * If the name starts with the current class name, followed by an * underscore, remove it. If there is no current class name, this * simply returns a copy of the name. This undoes Swig's way of * recording the class name in a member name. * ---------------------------------------------------------------------- */ String *removeClassname(String *name) { String *copy = Copy(name); if (class_name) { char *p = Char(name); if (Strncmp(name, class_name, Len(class_name)) == 0 && p[Len(class_name)] == '_') { Replace(copy, class_name, "", DOH_REPLACE_FIRST); Replace(copy, "_", "", DOH_REPLACE_FIRST); } } return copy; } /* ---------------------------------------------------------------------- * buildGoName() * * Build the name to use for an ordinary function, variable, or * whatever in Go. The name argument is something like the sym:name * attribute of the node. If is_static is false, this could be a * method, and the returned name will be the name of the * method--i.e., it will not include the class name. * ---------------------------------------------------------------------- */ String *buildGoName(String *name, bool is_static, bool is_friend) { String *nw = NewString(""); if (is_static && !is_friend && class_name) { String *c1 = exportedName(class_name); Append(nw, c1); Delete(c1); } String *c2 = removeClassname(name); String *c3 = exportedName(c2); Append(nw, c3); Delete(c2); Delete(c3); String *ret = Swig_name_mangle_string(nw); Delete(nw); return ret; } /* ---------------------------------------------------------------------- * buildGoWrapperName() * * Build the name to use for a Go wrapper function. This is a * function called by the real Go function in order to convert C++ * classes from interfaces to pointers, and other such conversions * between the Go type and the C++ type. * ---------------------------------------------------------------------- */ String *buildGoWrapperName(String *name, String *overname) { String *s1 = NewString("_swig_wrap_"); Append(s1, name); String *s2 = Swig_name_mangle_string(s1); Delete(s1); if (overname) { Append(s2, overname); } return s2; } /* ---------------------------------------------------------------------- * checkNameConflict() * * Check for a name conflict on the name we are going to use in Go. * These conflicts are likely because of the enforced * capitalization. When we find one, issue a warning and return * false. If the name is OK, return true. * ---------------------------------------------------------------------- */ bool checkNameConflict(String* name, Node* n, const_String_or_char_ptr scope) { Node *lk = symbolLookup(name, scope); if (lk) { String *n1 = Getattr(n, "sym:name"); if (!n1) { n1 = Getattr(n, "name"); } String *n2 = Getattr(lk, "sym:name"); if (!n2) { n2 = Getattr(lk, "name"); } Swig_warning(WARN_GO_NAME_CONFLICT, input_file, line_number, "Ignoring '%s' due to Go name ('%s') conflict with '%s'\n", n1, name, n2); return false; } bool r = addSymbol(name, n, scope) ? true : false; assert(r); (void)r; return true; } /* ---------------------------------------------------------------------- * checkIgnoredParameters() * * If any of the parameters of this function, or the return type, * are ignored due to a name conflict, give a warning and return * false. * ---------------------------------------------------------------------- */ bool checkIgnoredParameters(Node *n, String *go_name) { ParmList *parms = Getattr(n, "parms"); if (parms) { Wrapper *dummy = NewWrapper(); emit_attach_parmmaps(parms, dummy); int parm_count = emit_num_arguments(parms); Parm *p = parms; for (int i = 0; i < parm_count; ++i) { p = getParm(p); if (!checkIgnoredType(n, go_name, Getattr(p, "type"))) { DelWrapper(dummy); return false; } p = nextParm(p); } DelWrapper(dummy); } if (!checkIgnoredType(n, go_name, Getattr(n, "type"))) { return false; } return true; } /* ---------------------------------------------------------------------- * checkIgnoredType() * * If this type is being ignored due to a name conflict, give a * warning and return false. * ---------------------------------------------------------------------- */ bool checkIgnoredType(Node *n, String *go_name, SwigType *type) { if (hasGoTypemap(n, type)) { return true; } SwigType *t = SwigType_typedef_resolve_all(type); bool ret = true; bool is_conflict = false; Node *e = Language::enumLookup(t); if (e) { if (GetFlag(e, "go:conflict")) { is_conflict = true; } } else if (SwigType_issimple(t)) { Node *cn = classLookup(t); if (cn) { if (GetFlag(cn, "go:conflict")) { is_conflict = true; } } } else if (SwigType_ispointer(t) || SwigType_isarray(t) || SwigType_isqualifier(t) || SwigType_isreference(t)) { SwigType *r = Copy(t); if (SwigType_ispointer(r)) { SwigType_del_pointer(r); } else if (SwigType_isarray(r)) { SwigType_del_array(r); } else if (SwigType_isqualifier(r)) { SwigType_del_qualifier(r); } else { SwigType_del_reference(r); } if (!checkIgnoredType(n, go_name, r)) { ret = false; } Delete(r); } if (is_conflict) { String *s = SwigType_str(t, NULL); Swig_warning(WARN_GO_NAME_CONFLICT, input_file, line_number, "Ignoring '%s' (Go name '%s') due to Go name conflict for parameter or result type '%s'\n", Getattr(n, "name"), go_name, s); Delete(s); ret = false; } Delete(t); return ret; } /* ---------------------------------------------------------------------- * goType() * * Given a SWIG type, return a string for the type in Go. * ---------------------------------------------------------------------- */ String *goType(Node *n, SwigType *type) { return goTypeWithInfo(n, type, false, NULL); } /* ---------------------------------------------------------------------- * goImType() * * Given a SWIG type, return a string for the intermediate Go type * to pass to C/C++. This is like goType except that it looks for * an imtype typemap entry first. * ---------------------------------------------------------------------- */ String *goImType(Node *n, SwigType *type) { return goTypeWithInfo(n, type, true, NULL); } /* ---------------------------------------------------------------------- * goTypeWithInfo() * * Like goType, but return some more information. * * If use_imtype is true, this look for a imtype typemap entry. * * If the p_is_interface parameter is not NULL, this sets * *p_is_interface to indicate whether this type is going to be * represented by a Go interface type. These are cases where the Go * code needs to make some adjustments when passing values back and * forth with C/C++. * ---------------------------------------------------------------------- */ String *goTypeWithInfo(Node *n, SwigType *type, bool use_imtype, bool *p_is_interface) { if (p_is_interface) { *p_is_interface = false; } String *ret = NULL; if (use_imtype) { if (n && Cmp(type, Getattr(n, "type")) == 0) { if (Strcmp(Getattr(n, "nodeType"), "parm") == 0) { ret = Getattr(n, "tmap:imtype"); } if (!ret) { ret = Swig_typemap_lookup("imtype", n, "", NULL); } } else { Parm *p = NewParm(type, "goImType", n); ret = Swig_typemap_lookup("imtype", p, "", NULL); Delete(p); } } if (!ret) { if (n && Cmp(type, Getattr(n, "type")) == 0) { if (Strcmp(Getattr(n, "nodeType"), "parm") == 0) { ret = Getattr(n, "tmap:gotype"); } if (!ret) { ret = Swig_typemap_lookup("gotype", n, "", NULL); } } else { Parm *p = NewParm(type, "goType", n); ret = Swig_typemap_lookup("gotype", p, "", NULL); Delete(p); } } if (ret && Strstr(ret, "$gotypename") != 0) { ret = NULL; } if (ret) { return Copy(ret); } SwigType *t = SwigType_typedef_resolve_all(type); if (SwigType_isenum(t)) { Node *e = Language::enumLookup(t); if (e) { ret = goEnumName(e); } else if (Strcmp(t, "enum ") == 0) { ret = NewString("int"); } else { // An unknown enum - one that has not been parsed (neither a C enum forward reference nor a definition) or an ignored enum String *tt = Copy(t); Replace(tt, "enum ", "", DOH_REPLACE_ANY); ret = exportedName(tt); Setattr(undefined_enum_types, t, ret); Delete(tt); } } else if (SwigType_isfunctionpointer(t) || SwigType_isfunction(t)) { ret = NewString("_swig_fnptr"); } else if (SwigType_ismemberpointer(t)) { ret = NewString("_swig_memberptr"); } else if (SwigType_issimple(t)) { Node *cn = classLookup(t); if (cn) { ret = Getattr(cn, "sym:name"); if (!ret) { ret = Getattr(cn, "name"); } ret = exportedName(ret); Node *cnmod = Getattr(cn, "module"); if (!cnmod || Strcmp(Getattr(cnmod, "name"), module) == 0) { Setattr(undefined_types, t, t); } else { String *nw = NewString(""); Printv(nw, getModuleName(Getattr(cnmod, "name")), ".", ret, NULL); Delete(ret); ret = nw; } } else { // SWIG does not know about this type. ret = exportedName(t); Setattr(undefined_types, t, t); } if (p_is_interface) { *p_is_interface = true; } } else if (SwigType_ispointer(t) || SwigType_isarray(t)) { SwigType *r = Copy(t); if (SwigType_ispointer(r)) { SwigType_del_pointer(r); } else { SwigType_del_array(r); } if (SwigType_type(r) == T_VOID) { ret = NewString("uintptr"); } else { bool is_interface; String *base = goTypeWithInfo(n, r, false, &is_interface); // At the Go level, an unknown or class type is handled as an // interface wrapping a pointer. This means that if a // function returns the C type X, we will be wrapping the C // type X*. In Go we will call that type X. That means that // if a C function expects X*, we can pass the Go type X. And // that means that when we see the C type X*, we should use // the Go type X. // The is_interface variable tells us this. However, it will // be true both for the case of X and for the case of X*. If // r is a pointer here, then we are looking at X**. There is // really no good way for us to handle that. bool is_pointer_to_pointer = false; if (is_interface) { SwigType *c = Copy(r); if (SwigType_isqualifier(c)) { SwigType_del_qualifier(c); if (SwigType_ispointer(c) || SwigType_isarray(c)) { is_pointer_to_pointer = true; } } Delete(c); } if (is_interface) { if (!is_pointer_to_pointer) { ret = base; if (p_is_interface) { *p_is_interface = true; } } else { ret = NewString("uintptr"); } } else { ret = NewString("*"); Append(ret, base); Delete(base); } } Delete(r); } else if (SwigType_isreference(t)) { SwigType *r = Copy(t); SwigType_del_reference(r); // If this is a const reference, and we are looking at a pointer // to it, then we just use the pointer we already have. bool add_pointer = true; if (SwigType_isqualifier(r)) { String *q = SwigType_parm(r); if (Strcmp(q, "const") == 0) { SwigType *c = Copy(r); SwigType_del_qualifier(c); if (SwigType_ispointer(c)) { add_pointer = false; } Delete(c); } } if (add_pointer) { SwigType_add_pointer(r); } ret = goTypeWithInfo(n, r, false, p_is_interface); Delete(r); } else if (SwigType_isqualifier(t)) { SwigType *r = Copy(t); SwigType_del_qualifier(r); ret = goTypeWithInfo(n, r, false, p_is_interface); Delete(r); } else if (SwigType_isvarargs(t)) { ret = NewString("[]interface{}"); } Delete(t); if (!ret) { Swig_warning(WARN_LANG_NATIVE_UNIMPL, input_file, line_number, "No Go typemap defined for %s\n", SwigType_str(type, 0)); ret = NewString("uintptr"); } return ret; } /* ---------------------------------------------------------------------- * cgoTypeForGoValue() * * Given a SWIG type, return a string for the C type to use for the * cgo wrapper code. This always returns a simple identifier, since * it is used in Go code as C.name. * * This sets *c_struct_type if the C type uses a struct where the Go * type uses a simple type. This is true for strings and slices. * When this is true the Go code has to jump through unsafe hoops to * pass the type checker. * ---------------------------------------------------------------------- */ String *cgoTypeForGoValue(Node *n, SwigType *type, bool *c_struct_type) { *c_struct_type = false; bool is_interface; String *go_type = goTypeWithInfo(n, type, true, &is_interface); if (is_interface) { Delete(go_type); return NewString("uintptr_t"); } if (Strcmp(go_type, "uintptr") == 0) { Delete(go_type); return NewString("uintptr_t"); } if (((char*)Char(go_type))[0] == '*') { // Treat all pointers as void*. There is no meaningful type // checking going on here anyhow, and that lets us avoid // worrying about defining the base type of the pointer. Delete(go_type); return NewString("swig_voidp"); } // Check for some Go types that are really pointers under the covers. bool is_hidden_pointer = Strncmp(go_type, "func(", 5) == 0 || Strncmp(go_type, "map[", 4) == 0 || Strncmp(go_type, "chan ", 5) == 0; Delete(go_type); String *ct = Getattr(n, "emit:cgotype"); if (ct) { *c_struct_type = Getattr(n, "emit:cgotypestruct") ? true : false; return Copy(ct); } String *t = Copy(type); if (SwigType_isarray(t) && Getattr(n, "tmap:gotype") == NULL) { SwigType_del_array(t); SwigType_add_pointer(t); } bool add_typedef = true; static int count; ++count; ct = NewStringf("swig_type_%d", count); String *gct = gcCTypeForGoValue(n, t, ct); Delete(t); if (Strncmp(gct, "_gostring_", 10) == 0 || Strncmp(gct, "_goslice_", 9) == 0) { *c_struct_type = true; Setattr(n, "emit:cgotypestruct", type); } else { char *p = Strstr(gct, ct); if (p != NULL && p > (char*)Char(gct) && p[-1] == '*' && p[Len(ct)] == '\0') { // Treat all pointers as void*. See above. Delete(ct); --count; ct = NewString("swig_voidp"); add_typedef = false; if (is_hidden_pointer) { // A Go type that is really a pointer, like func, map, chan, // is being represented in C by a pointer. This is fine, // but we have to memcpy the type rather than simply // converting it. *c_struct_type = true; Setattr(n, "emit:cgotypestruct", type); } } if (Strncmp(gct, "bool ", 5) == 0) { // Change the C++ type bool to the C type _Bool. Replace(gct, "bool", "_Bool", DOH_REPLACE_FIRST); } if (Strncmp(gct, "intgo ", 6) == 0) { // We #define intgo to swig_intgo for the cgo comment. Replace(gct, "intgo", "swig_intgo", DOH_REPLACE_FIRST); } p = Strstr(gct, ct); if (p != NULL && p > (char*)Char(gct) && p[-1] == ' ' && p[Len(ct)] == '\0') { String *q = NewStringWithSize(gct, Len(gct) - Len(ct) - 1); if (validIdentifier(q)) { // This is a simple type name, and we can use it directly. Delete(ct); --count; ct = q; add_typedef = false; } } } if (add_typedef) { Printv(f_cgo_comment_typedefs, "typedef ", gct, ";\n", NULL); } Setattr(n, "emit:cgotype", ct); Delete(gct); return Copy(ct); } /* ---------------------------------------------------------------------- * goWrapperType() * * Given a type, return a string for the type to use for the wrapped * Go function. This function exists because for a C++ class we * need to convert interface and reference types. * ---------------------------------------------------------------------- */ String *goWrapperType(Node *n, SwigType *type, bool is_result) { bool is_interface; String *ret = goTypeWithInfo(n, type, true, &is_interface); // If this is an interface, we want to pass the real type. if (is_interface) { Delete(ret); if (!is_result) { ret = NewString("uintptr"); } else { SwigType *ty = SwigType_typedef_resolve_all(type); while (true) { if (SwigType_ispointer(ty)) { SwigType_del_pointer(ty); } else if (SwigType_isarray(ty)) { SwigType_del_array(ty); } else if (SwigType_isreference(ty)) { SwigType_del_reference(ty); } else if (SwigType_isqualifier(ty)) { SwigType_del_qualifier(ty); } else { break; } } assert(SwigType_issimple(ty)); String *p = goCPointerType(ty, true); Delete(ty); ret = p; } } return ret; } /* ---------------------------------------------------------------------- * goOverloadType() * * Given a type, return the Go type to use when dispatching of * overloaded functions. This is normally just the usual Go type. * However, for a C++ class, the usual Go type is an interface type. * And if that interface type represents a C++ type that SWIG does * not know about, then the interface type generated for any C++ * class will match that interface. So for that case, we match on * the underlying integer type. * * It has to work this way so that we can handle a derived type of a * %ignore'd type. It's unlikely that anybody will have a value of * an undefined type, but we support it because it worked in the * past. * ---------------------------------------------------------------------- */ String *goOverloadType(Node *n, SwigType *type) { SwigType *ty = SwigType_typedef_resolve_all(type); while (true) { if (SwigType_ispointer(ty)) { SwigType_del_pointer(ty); } else if (SwigType_isarray(ty)) { SwigType_del_array(ty); } else if (SwigType_isreference(ty)) { SwigType_del_reference(ty); } else if (SwigType_isqualifier(ty)) { SwigType_del_qualifier(ty); } else { break; } } String* go_type = goType(n, ty); if (Getattr(undefined_types, ty) && !Getattr(defined_types, go_type)) { Delete(go_type); return goWrapperType(n, type, true); } Delete(go_type); return goType(n, type); } /* ---------------------------------------------------------------------- * goCPointerType() * * Return the name of the Go type to use for the C pointer value. * The regular C type is the name of an interface type which wraps a * pointer whose name is returned by this function. * ---------------------------------------------------------------------- */ String *goCPointerType(SwigType *type, bool add_to_hash) { SwigType *ty = SwigType_typedef_resolve_all(type); Node *cn = classLookup(ty); String *ex; String *ret; if (!cn) { if (add_to_hash) { Setattr(undefined_types, ty, ty); } ret = NewString("Swigcptr"); ex = exportedName(ty); Append(ret, ex); } else { String *cname = Getattr(cn, "sym:name"); if (!cname) { cname = Getattr(cn, "name"); } ex = exportedName(cname); Node *cnmod = Getattr(cn, "module"); if (!cnmod || Strcmp(Getattr(cnmod, "name"), module) == 0) { if (add_to_hash) { Setattr(undefined_types, ty, ty); } ret = NewString("Swigcptr"); Append(ret, ex); } else { ret = NewString(""); Printv(ret, getModuleName(Getattr(cnmod, "name")), ".Swigcptr", ex, NULL); } } Delete(ty); Delete(ex); return ret; } /* ---------------------------------------------------------------------- * gcCTypeForGoValue() * * Given a type, return the C/C++ type which will be used to catch * the value in Go. This is the gc version. * ---------------------------------------------------------------------- */ String *gcCTypeForGoValue(Node *n, SwigType *type, String *name) { bool is_interface; String *gt = goTypeWithInfo(n, type, true, &is_interface); String *tail = NewString(""); SwigType *t = SwigType_typedef_resolve_all(type); bool is_const_ref = false; if (SwigType_isreference(t)) { SwigType* tt = Copy(t); SwigType_del_reference(tt); if (SwigType_isqualifier(tt)) { String* q = SwigType_parm(tt); if (Strcmp(q, "const") == 0) { is_const_ref = true; } } Delete(tt); } if (!is_const_ref) { while (Strncmp(gt, "*", 1) == 0) { Replace(gt, "*", "", DOH_REPLACE_FIRST); Printv(tail, "*", NULL); } } Delete(t); bool is_string = Strcmp(gt, "string") == 0; bool is_slice = Strncmp(gt, "[]", 2) == 0; bool is_function = Strcmp(gt, "_swig_fnptr") == 0; bool is_member = Strcmp(gt, "_swig_memberptr") == 0; bool is_complex64 = Strcmp(gt, "complex64") == 0; bool is_complex128 = Strcmp(gt, "complex128") == 0; bool is_bool = false; bool is_int8 = false; bool is_int16 = false; bool is_int = Strcmp(gt, "int") == 0 || Strcmp(gt, "uint") == 0; bool is_int32 = false; bool is_int64 = false; bool is_float32 = false; bool is_float64 = false; bool has_typemap = (n != NULL && Getattr(n, "tmap:gotype") != NULL) || hasGoTypemap(n, type); if (has_typemap) { is_bool = Strcmp(gt, "bool") == 0; is_int8 = Strcmp(gt, "int8") == 0 || Strcmp(gt, "uint8") == 0 || Strcmp(gt, "byte") == 0; is_int16 = Strcmp(gt, "int16") == 0 || Strcmp(gt, "uint16") == 0; is_int32 = Strcmp(gt, "int32") == 0 || Strcmp(gt, "uint32") == 0; is_int64 = Strcmp(gt, "int64") == 0 || Strcmp(gt, "uint64") == 0; is_float32 = Strcmp(gt, "float32") == 0; is_float64 = Strcmp(gt, "float64") == 0; } Delete(gt); String *ret; if (is_string) { // Note that we don't turn a reference to a string into a // pointer to a string. Strings are immutable anyhow. ret = NewString(""); Printv(ret, "_gostring_", tail, " ", name, NULL); Delete(tail); return ret; } else if (is_slice) { // Slices are always passed as a _goslice_, whether or not references // are involved. ret = NewString(""); Printv(ret, "_goslice_", tail, " ", name, NULL); Delete(tail); return ret; } else if (is_function || is_member) { ret = NewString(""); Printv(ret, "void*", tail, " ", name, NULL); Delete(tail); return ret; } else if (is_complex64) { ret = NewString("_Complex float "); } else if (is_complex128) { ret = NewString("_Complex double "); } else if (is_interface) { SwigType *t = SwigType_typedef_resolve_all(type); if (SwigType_ispointer(t)) { SwigType_del_pointer(t); } if (SwigType_isreference(t)) { SwigType_del_reference(t); } SwigType_add_pointer(t); ret = SwigType_lstr(t, name); Delete(t); Delete(tail); return ret; } else { SwigType *t = SwigType_typedef_resolve_all(type); if (!has_typemap && SwigType_isreference(t)) { // A const reference to a known type, or to a pointer, is not // mapped to a pointer. SwigType_del_reference(t); if (SwigType_isqualifier(t)) { String *q = SwigType_parm(t); if (Strcmp(q, "const") == 0) { SwigType_del_qualifier(t); if (hasGoTypemap(n, t) || SwigType_ispointer(t)) { if (is_int) { ret = NewString("intgo "); Append(ret, name); } else if (is_int64) { ret = NewString("long long "); Append(ret, name); } else { ret = SwigType_lstr(t, name); } Delete(q); Delete(t); Delete(tail); return ret; } } Delete(q); } } if (Language::enumLookup(t) != NULL) { is_int = true; } else { SwigType *tstripped = SwigType_strip_qualifiers(t); if (SwigType_isenum(tstripped)) is_int = true; Delete(tstripped); } Delete(t); if (is_bool) { ret = NewString("bool "); } else if (is_int8) { ret = NewString("char "); } else if (is_int16) { ret = NewString("short "); } else if (is_int) { ret = NewString("intgo "); } else if (is_int32) { ret = NewString("int "); } else if (is_int64) { ret = NewString("long long "); } else if (is_float32) { ret = NewString("float "); } else if (is_float64) { ret = NewString("double "); } else { Delete(tail); return SwigType_lstr(type, name); } } Append(ret, tail); if (!has_typemap && SwigType_isreference(type)) { Append(ret, "* "); } Append(ret, name); Delete(tail); return ret; } /* ---------------------------------------------------------------------- * goTypeIsInterface * * Return whether this C++ type is represented as an interface type * in Go. These types require adjustments in the Go code when * passing them back and forth between Go and C++. * ---------------------------------------------------------------------- */ bool goTypeIsInterface(Node *n, SwigType *type) { bool is_interface; Delete(goTypeWithInfo(n, type, false, &is_interface)); return is_interface; } /* ---------------------------------------------------------------------- * hasGoTypemap * * Return whether a type has a "gotype" typemap entry. * ---------------------------------------------------------------------- */ bool hasGoTypemap(Node *n, SwigType *type) { Parm *p = NewParm(type, "test", n); SwigType *tm = Swig_typemap_lookup("gotype", p, "", NULL); Delete(p); if (tm && Strstr(tm, "$gotypename") == 0) { Delete(tm); return true; } Delete(tm); return false; } /* ---------------------------------------------------------------------- * goEnumName() * * Given an enum node, return a string to use for the enum type in Go. * ---------------------------------------------------------------------- */ String *goEnumName(Node *n) { String *ret = Getattr(n, "go:enumname"); if (ret) { return Copy(ret); } if (Equal(Getattr(n, "type"), "enum ")) { return NewString("int"); } SwigType *type = Getattr(n, "enumtype"); assert(type); char *p = Char(type); int len = Len(type); SwigType *s = NewString(""); bool capitalize = true; for (int i = 0; i < len; ++i, ++p) { if (*p == ':') { ++i; ++p; assert(*p == ':'); capitalize = true; } else if (capitalize) { Putc(toupper(*p), s); capitalize = false; } else { Putc(*p, s); } } ret = Swig_name_mangle_type(s); Delete(s); return ret; } /* ---------------------------------------------------------------------- * getParm() * * Get the real parameter to use. * ---------------------------------------------------------------------- */ Parm *getParm(Parm *p) { while (p && checkAttribute(p, "tmap:in:numinputs", "0")) { p = Getattr(p, "tmap:in:next"); } return p; } /* ---------------------------------------------------------------------- * nextParm() * * Return the next parameter. * ---------------------------------------------------------------------- */ Parm *nextParm(Parm *p) { if (!p) { return NULL; } else if (Getattr(p, "tmap:in")) { return Getattr(p, "tmap:in:next"); } else { return nextSibling(p); } } /* ---------------------------------------------------------------------- * isStatic * * Return whether a node should be considered as static rather than * as a member. * ---------------------------------------------------------------------- */ bool isStatic(Node *n) { String *storage = Getattr(n, "storage"); return (storage && (Swig_storage_isstatic(n) || Strstr(storage, "friend")) && (!SmartPointer || !Getattr(n, "allocate:smartpointeraccess"))); } /* ---------------------------------------------------------------------- * isFriend * * Return whether a node is a friend. * ---------------------------------------------------------------------- */ bool isFriend(Node *n) { String *storage = Getattr(n, "storage"); return storage && Strstr(storage, "friend"); } /* ---------------------------------------------------------------------- * goGetattr * * Fetch an attribute from a node but return NULL if it is the empty string. * ---------------------------------------------------------------------- */ Node *goGetattr(Node *n, const char *name) { Node *ret = Getattr(n, name); if (ret != NULL && Len(ret) == 0) { ret = NULL; } return ret; } /* ---------------------------------------------------------------------- * goTypemapLookup * * Look up a typemap but return NULL if it is the empty string. * ---------------------------------------------------------------------- */ String *goTypemapLookup(const char *name, Node *node, const char *lname) { String *ret = Swig_typemap_lookup(name, node, lname, NULL); if (ret != NULL && Len(ret) == 0) { ret = NULL; } return ret; } /* ---------------------------------------------------------------------- * getModuleName * * Return the name of a module. This is different from module path: * "some/path/to/module" -> "module". * ---------------------------------------------------------------------- */ String *getModuleName(String *module_path) { char *suffix = strrchr(Char(module_path), '/'); if (suffix == NULL) { return module_path; } return Str(suffix + 1); } }; /* class GO */ /* ----------------------------------------------------------------------------- * swig_go() - Instantiate module * ----------------------------------------------------------------------------- */ static Language *new_swig_go() { return new GO(); } extern "C" Language *swig_go(void) { return new_swig_go(); } /* ----------------------------------------------------------------------------- * Static member variables * ----------------------------------------------------------------------------- */ // Usage message. const char * const GO::usage = "\ Go Options (available with -go)\n\ -cgo - Generate cgo input files\n\ -no-cgo - Do not generate cgo input files\n\ -gccgo - Generate code for gccgo rather than gc\n\ -go-pkgpath

- Like gccgo -fgo-pkgpath option\n\ -go-prefix

- Like gccgo -fgo-prefix option\n\ -import-prefix

- Prefix to add to %import directives\n\ -intgosize - Set size of Go int type--32 or 64 bits\n\ -package - Set name of the Go package to \n\ -use-shlib - Force use of a shared library\n\ -soname - Set shared library holding C/C++ code to \n\ \n";