/**************************************************************************/ /* bindings_generator.cpp */ /**************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /**************************************************************************/ /* Copyright (c) 2014-present Godot Engine contributors (see AUTHORS.md). */ /* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */ /* */ /* Permission is hereby granted, free of charge, to any person obtaining */ /* a copy of this software and associated documentation files (the */ /* "Software"), to deal in the Software without restriction, including */ /* without limitation the rights to use, copy, modify, merge, publish, */ /* distribute, sublicense, and/or sell copies of the Software, and to */ /* permit persons to whom the Software is furnished to do so, subject to */ /* the following conditions: */ /* */ /* The above copyright notice and this permission notice shall be */ /* included in all copies or substantial portions of the Software. */ /* */ /* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */ /* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */ /* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. */ /* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */ /* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */ /* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */ /* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /**************************************************************************/ #include "bindings_generator.h" #if defined(DEBUG_METHODS_ENABLED) && defined(TOOLS_ENABLED) #include "../godotsharp_defs.h" #include "../utils/naming_utils.h" #include "../utils/path_utils.h" #include "../utils/string_utils.h" #include "core/config/engine.h" #include "core/core_constants.h" #include "core/io/compression.h" #include "core/io/dir_access.h" #include "core/io/file_access.h" #include "core/os/os.h" #include "main/main.h" StringBuilder &operator<<(StringBuilder &r_sb, const String &p_string) { r_sb.append(p_string); return r_sb; } StringBuilder &operator<<(StringBuilder &r_sb, const char *p_cstring) { r_sb.append(p_cstring); return r_sb; } #define CS_INDENT " " // 4 whitespaces #define INDENT1 CS_INDENT #define INDENT2 INDENT1 INDENT1 #define INDENT3 INDENT2 INDENT1 #define INDENT4 INDENT3 INDENT1 #define MEMBER_BEGIN "\n" INDENT1 #define OPEN_BLOCK "{\n" #define CLOSE_BLOCK "}\n" #define OPEN_BLOCK_L1 INDENT1 OPEN_BLOCK #define OPEN_BLOCK_L2 INDENT2 OPEN_BLOCK #define OPEN_BLOCK_L3 INDENT3 OPEN_BLOCK #define CLOSE_BLOCK_L1 INDENT1 CLOSE_BLOCK #define CLOSE_BLOCK_L2 INDENT2 CLOSE_BLOCK #define CLOSE_BLOCK_L3 INDENT3 CLOSE_BLOCK #define BINDINGS_GLOBAL_SCOPE_CLASS "GD" #define BINDINGS_NATIVE_NAME_FIELD "NativeName" #define CS_PARAM_MEMORYOWN "memoryOwn" #define CS_PARAM_METHODBIND "method" #define CS_PARAM_INSTANCE "ptr" #define CS_STATIC_METHOD_GETINSTANCE "GetPtr" #define CS_METHOD_CALL "Call" #define CS_PROPERTY_SINGLETON "Singleton" #define CS_SINGLETON_INSTANCE_SUFFIX "Instance" #define CS_METHOD_INVOKE_GODOT_CLASS_METHOD "InvokeGodotClassMethod" #define CS_METHOD_HAS_GODOT_CLASS_METHOD "HasGodotClassMethod" #define CS_METHOD_HAS_GODOT_CLASS_SIGNAL "HasGodotClassSignal" #define CS_STATIC_FIELD_NATIVE_CTOR "NativeCtor" #define CS_STATIC_FIELD_METHOD_BIND_PREFIX "MethodBind" #define CS_STATIC_FIELD_METHOD_PROXY_NAME_PREFIX "MethodProxyName_" #define CS_STATIC_FIELD_SIGNAL_PROXY_NAME_PREFIX "SignalProxyName_" #define ICALL_PREFIX "godot_icall_" #define ICALL_CLASSDB_GET_METHOD "ClassDB_get_method" #define ICALL_CLASSDB_GET_METHOD_WITH_COMPATIBILITY "ClassDB_get_method_with_compatibility" #define ICALL_CLASSDB_GET_CONSTRUCTOR "ClassDB_get_constructor" #define C_LOCAL_RET "ret" #define C_LOCAL_VARARG_RET "vararg_ret" #define C_LOCAL_PTRCALL_ARGS "call_args" #define C_CLASS_NATIVE_FUNCS "NativeFuncs" #define C_NS_MONOUTILS "InteropUtils" #define C_METHOD_UNMANAGED_GET_MANAGED C_NS_MONOUTILS ".UnmanagedGetManaged" #define C_METHOD_ENGINE_GET_SINGLETON C_NS_MONOUTILS ".EngineGetSingleton" #define C_NS_MONOMARSHAL "Marshaling" #define C_METHOD_MONOSTR_TO_GODOT C_NS_MONOMARSHAL ".ConvertStringToNative" #define C_METHOD_MONOSTR_FROM_GODOT C_NS_MONOMARSHAL ".ConvertStringToManaged" #define C_METHOD_MONOARRAY_TO(m_type) C_NS_MONOMARSHAL ".ConvertSystemArrayToNative" #m_type #define C_METHOD_MONOARRAY_FROM(m_type) C_NS_MONOMARSHAL ".ConvertNative" #m_type "ToSystemArray" #define C_METHOD_MANAGED_TO_CALLABLE C_NS_MONOMARSHAL ".ConvertCallableToNative" #define C_METHOD_MANAGED_FROM_CALLABLE C_NS_MONOMARSHAL ".ConvertCallableToManaged" #define C_METHOD_MANAGED_TO_SIGNAL C_NS_MONOMARSHAL ".ConvertSignalToNative" #define C_METHOD_MANAGED_FROM_SIGNAL C_NS_MONOMARSHAL ".ConvertSignalToManaged" // Types that will be ignored by the generator and won't be available in C#. // This must be kept in sync with `ignored_types` in csharp_script.cpp const Vector ignored_types = {}; void BindingsGenerator::TypeInterface::postsetup_enum_type(BindingsGenerator::TypeInterface &r_enum_itype) { // C interface for enums is the same as that of 'uint32_t'. Remember to apply // any of the changes done here to the 'uint32_t' type interface as well. r_enum_itype.cs_type = r_enum_itype.proxy_name; r_enum_itype.cs_in_expr = "(int)%0"; r_enum_itype.cs_out = "%5return (%2)%0(%1);"; { // The expected types for parameters and return value in ptrcall are 'int64_t' or 'uint64_t'. r_enum_itype.c_in = "%5%0 %1_in = %1;\n"; r_enum_itype.c_out = "%5return (%0)(%1);\n"; r_enum_itype.c_type = "long"; r_enum_itype.c_arg_in = "&%s_in"; } r_enum_itype.c_type_in = "int"; r_enum_itype.c_type_out = r_enum_itype.c_type_in; r_enum_itype.class_doc = &EditorHelp::get_doc_data()->class_list[r_enum_itype.proxy_name]; } static String fix_doc_description(const String &p_bbcode) { // This seems to be the correct way to do this. It's the same EditorHelp does. return p_bbcode.dedent() .replace("\t", "") .replace("\r", "") .strip_edges(); } String BindingsGenerator::bbcode_to_xml(const String &p_bbcode, const TypeInterface *p_itype, bool p_is_signal) { // Based on the version in EditorHelp if (p_bbcode.is_empty()) { return String(); } DocTools *doc = EditorHelp::get_doc_data(); String bbcode = p_bbcode; StringBuilder xml_output; xml_output.append(""); List tag_stack; bool code_tag = false; bool line_del = false; int pos = 0; while (pos < bbcode.length()) { int brk_pos = bbcode.find("[", pos); if (brk_pos < 0) { brk_pos = bbcode.length(); } if (brk_pos > pos) { if (!line_del) { String text = bbcode.substr(pos, brk_pos - pos); if (code_tag || tag_stack.size() > 0) { xml_output.append(text.xml_escape()); } else { Vector lines = text.split("\n"); for (int i = 0; i < lines.size(); i++) { if (i != 0) { xml_output.append(""); } xml_output.append(lines[i].xml_escape()); if (i != lines.size() - 1) { xml_output.append("\n"); } } } } } if (brk_pos == bbcode.length()) { break; // nothing else to add } int brk_end = bbcode.find("]", brk_pos + 1); if (brk_end == -1) { if (!line_del) { String text = bbcode.substr(brk_pos, bbcode.length() - brk_pos); if (code_tag || tag_stack.size() > 0) { xml_output.append(text.xml_escape()); } else { Vector lines = text.split("\n"); for (int i = 0; i < lines.size(); i++) { if (i != 0) { xml_output.append(""); } xml_output.append(lines[i].xml_escape()); if (i != lines.size() - 1) { xml_output.append("\n"); } } } } break; } String tag = bbcode.substr(brk_pos + 1, brk_end - brk_pos - 1); if (tag.begins_with("/")) { bool tag_ok = tag_stack.size() && tag_stack.front()->get() == tag.substr(1, tag.length()); if (!tag_ok) { if (!line_del) { xml_output.append("["); } pos = brk_pos + 1; continue; } tag_stack.pop_front(); pos = brk_end + 1; code_tag = false; if (tag == "/url") { xml_output.append(""); } else if (tag == "/code") { xml_output.append(""); } else if (tag == "/codeblock") { xml_output.append(""); } else if (tag == "/b") { xml_output.append(""); } else if (tag == "/i") { xml_output.append(""); } else if (tag == "/csharp") { xml_output.append(""); line_del = true; } else if (tag == "/codeblocks") { line_del = false; } } else if (code_tag) { xml_output.append("["); pos = brk_pos + 1; } else if (tag.begins_with("method ") || tag.begins_with("constructor ") || tag.begins_with("operator ") || tag.begins_with("member ") || tag.begins_with("signal ") || tag.begins_with("enum ") || tag.begins_with("constant ") || tag.begins_with("theme_item ") || tag.begins_with("param ")) { const int tag_end = tag.find(" "); const String link_tag = tag.substr(0, tag_end); const String link_target = tag.substr(tag_end + 1, tag.length()).lstrip(" "); const Vector link_target_parts = link_target.split("."); if (link_target_parts.size() <= 0 || link_target_parts.size() > 2) { ERR_PRINT("Invalid reference format: '" + tag + "'."); xml_output.append(""); xml_output.append(tag); xml_output.append(""); pos = brk_end + 1; continue; } const TypeInterface *target_itype; StringName target_cname; if (link_target_parts.size() == 2) { target_itype = _get_type_or_null(TypeReference(link_target_parts[0])); if (!target_itype) { target_itype = _get_type_or_null(TypeReference("_" + link_target_parts[0])); } target_cname = link_target_parts[1]; } else { target_itype = p_itype; target_cname = link_target_parts[0]; } if (link_tag == "method") { _append_xml_method(xml_output, target_itype, target_cname, link_target, link_target_parts); } else if (link_tag == "constructor") { // TODO: Support constructors? _append_xml_undeclared(xml_output, link_target); } else if (link_tag == "operator") { // TODO: Support operators? _append_xml_undeclared(xml_output, link_target); } else if (link_tag == "member") { _append_xml_member(xml_output, target_itype, target_cname, link_target, link_target_parts); } else if (link_tag == "signal") { _append_xml_signal(xml_output, target_itype, target_cname, link_target, link_target_parts); } else if (link_tag == "enum") { _append_xml_enum(xml_output, target_itype, target_cname, link_target, link_target_parts); } else if (link_tag == "constant") { _append_xml_constant(xml_output, target_itype, target_cname, link_target, link_target_parts); } else if (link_tag == "param") { _append_xml_param(xml_output, link_target, p_is_signal); } else if (link_tag == "theme_item") { // We do not declare theme_items in any way in C#, so there is nothing to reference _append_xml_undeclared(xml_output, link_target); } pos = brk_end + 1; } else if (doc->class_list.has(tag)) { if (tag == "Array" || tag == "Dictionary") { xml_output.append(""); } else if (tag == "bool" || tag == "int") { xml_output.append(""); } else if (tag == "float") { xml_output.append(""); } else if (tag == "Variant") { xml_output.append(""); } else if (tag == "String") { xml_output.append(""); } else if (tag == "Nil") { xml_output.append(""); } else if (tag.begins_with("@")) { // @GlobalScope, @GDScript, etc xml_output.append(""); xml_output.append(tag); xml_output.append(""); } else if (tag == "PackedByteArray") { xml_output.append("[]"); } else if (tag == "PackedInt32Array") { xml_output.append("[]"); } else if (tag == "PackedInt64Array") { xml_output.append("[]"); } else if (tag == "PackedFloat32Array") { xml_output.append("[]"); } else if (tag == "PackedFloat64Array") { xml_output.append("[]"); } else if (tag == "PackedStringArray") { xml_output.append("[]"); } else if (tag == "PackedVector2Array") { xml_output.append("[]"); } else if (tag == "PackedVector3Array") { xml_output.append("[]"); } else if (tag == "PackedColorArray") { xml_output.append("[]"); } else { const TypeInterface *target_itype = _get_type_or_null(TypeReference(tag)); if (!target_itype) { target_itype = _get_type_or_null(TypeReference("_" + tag)); } if (target_itype) { if ((!p_itype || p_itype->api_type == ClassDB::API_CORE) && target_itype->api_type == ClassDB::API_EDITOR) { // Editor references in core documentation cannot be resolved, // handle as standard codeblock. _log("Cannot reference editor type '%s' in documentation for core type '%s'\n", target_itype->proxy_name.utf8().get_data(), p_itype ? p_itype->proxy_name.utf8().get_data() : "@GlobalScope"); xml_output.append(""); xml_output.append(target_itype->proxy_name); xml_output.append(""); } else { xml_output.append("proxy_name); xml_output.append("\"/>"); } } else { ERR_PRINT("Cannot resolve type reference in documentation: '" + tag + "'."); xml_output.append(""); xml_output.append(tag); xml_output.append(""); } } pos = brk_end + 1; } else if (tag == "b") { xml_output.append(""); pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "i") { xml_output.append(""); pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "code" || tag.begins_with("code ")) { xml_output.append(""); code_tag = true; pos = brk_end + 1; tag_stack.push_front("code"); } else if (tag == "codeblock" || tag.begins_with("codeblock ")) { xml_output.append(""); code_tag = true; pos = brk_end + 1; tag_stack.push_front("codeblock"); } else if (tag == "codeblocks") { line_del = true; pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "csharp" || tag.begins_with("csharp ")) { xml_output.append(""); line_del = false; code_tag = true; pos = brk_end + 1; tag_stack.push_front("csharp"); } else if (tag == "kbd") { // keyboard combinations are not supported in xml comments pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "center") { // center alignment is not supported in xml comments pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "br") { xml_output.append("\n"); // FIXME: Should use instead. Luckily this tag isn't used for now. pos = brk_end + 1; } else if (tag == "u") { // underline is not supported in Rider xml comments pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "s") { // strikethrough is not supported in xml comments pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag == "url") { int end = bbcode.find("[", brk_end); if (end == -1) { end = bbcode.length(); } String url = bbcode.substr(brk_end + 1, end - brk_end - 1); xml_output.append(""); xml_output.append(url); pos = brk_end + 1; tag_stack.push_front(tag); } else if (tag.begins_with("url=")) { String url = tag.substr(4, tag.length()); xml_output.append(""); pos = brk_end + 1; tag_stack.push_front("url"); } else if (tag == "img") { int end = bbcode.find("[", brk_end); if (end == -1) { end = bbcode.length(); } String image = bbcode.substr(brk_end + 1, end - brk_end - 1); // Not supported. Just append the bbcode. xml_output.append("[img]"); xml_output.append(image); xml_output.append("[/img]"); pos = end; tag_stack.push_front(tag); } else if (tag.begins_with("color=")) { // Not supported. pos = brk_end + 1; tag_stack.push_front("color"); } else if (tag.begins_with("font=")) { // Not supported. pos = brk_end + 1; tag_stack.push_front("font"); } else { if (!line_del) { xml_output.append("["); // ignore } pos = brk_pos + 1; } } xml_output.append(""); return xml_output.as_string(); } void BindingsGenerator::_append_xml_method(StringBuilder &p_xml_output, const TypeInterface *p_target_itype, const StringName &p_target_cname, const String &p_link_target, const Vector &p_link_target_parts) { if (p_link_target_parts[0] == name_cache.type_at_GlobalScope) { if (OS::get_singleton()->is_stdout_verbose()) { OS::get_singleton()->print("Cannot resolve @GlobalScope method reference in documentation: %s\n", p_link_target.utf8().get_data()); } // TODO Map what we can _append_xml_undeclared(p_xml_output, p_link_target); } else if (!p_target_itype || !p_target_itype->is_object_type) { if (OS::get_singleton()->is_stdout_verbose()) { if (p_target_itype) { OS::get_singleton()->print("Cannot resolve method reference for non-GodotObject type in documentation: %s\n", p_link_target.utf8().get_data()); } else { OS::get_singleton()->print("Cannot resolve type from method reference in documentation: %s\n", p_link_target.utf8().get_data()); } } // TODO Map what we can _append_xml_undeclared(p_xml_output, p_link_target); } else { if (p_target_cname == "_init") { // The _init method is not declared in C#, reference the constructor instead p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(p_target_itype->proxy_name); p_xml_output.append("()\"/>"); } else { const MethodInterface *target_imethod = p_target_itype->find_method_by_name(p_target_cname); if (target_imethod) { p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(target_imethod->proxy_name); p_xml_output.append("("); bool first_key = true; for (const ArgumentInterface &iarg : target_imethod->arguments) { const TypeInterface *arg_type = _get_type_or_null(iarg.type); if (first_key) { first_key = false; } else { p_xml_output.append(", "); } if (!arg_type) { ERR_PRINT("Cannot resolve argument type in documentation: '" + p_link_target + "'."); p_xml_output.append(iarg.type.cname); continue; } if (iarg.def_param_mode == ArgumentInterface::NULLABLE_VAL) { p_xml_output.append("Nullable{"); } String arg_cs_type = arg_type->cs_type + _get_generic_type_parameters(*arg_type, iarg.type.generic_type_parameters); p_xml_output.append(arg_cs_type.replacen("<", "{").replacen(">", "}").replacen("params ", "")); if (iarg.def_param_mode == ArgumentInterface::NULLABLE_VAL) { p_xml_output.append("}"); } } p_xml_output.append(")\"/>"); } else { if (!p_target_itype->is_intentionally_ignored(p_link_target)) { ERR_PRINT("Cannot resolve method reference in documentation: '" + p_link_target + "'."); } _append_xml_undeclared(p_xml_output, p_link_target); } } } } void BindingsGenerator::_append_xml_member(StringBuilder &p_xml_output, const TypeInterface *p_target_itype, const StringName &p_target_cname, const String &p_link_target, const Vector &p_link_target_parts) { if (p_link_target.find("/") >= 0) { // Properties with '/' (slash) in the name are not declared in C#, so there is nothing to reference. _append_xml_undeclared(p_xml_output, p_link_target); } else if (!p_target_itype || !p_target_itype->is_object_type) { if (OS::get_singleton()->is_stdout_verbose()) { if (p_target_itype) { OS::get_singleton()->print("Cannot resolve member reference for non-GodotObject type in documentation: %s\n", p_link_target.utf8().get_data()); } else { OS::get_singleton()->print("Cannot resolve type from member reference in documentation: %s\n", p_link_target.utf8().get_data()); } } // TODO Map what we can _append_xml_undeclared(p_xml_output, p_link_target); } else { const TypeInterface *current_itype = p_target_itype; const PropertyInterface *target_iprop = nullptr; while (target_iprop == nullptr && current_itype != nullptr) { target_iprop = current_itype->find_property_by_name(p_target_cname); if (target_iprop == nullptr) { current_itype = _get_type_or_null(TypeReference(current_itype->base_name)); } } if (target_iprop) { p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(target_iprop->proxy_name); p_xml_output.append("\"/>"); } else { if (!p_target_itype->is_intentionally_ignored(p_link_target)) { ERR_PRINT("Cannot resolve member reference in documentation: '" + p_link_target + "'."); } _append_xml_undeclared(p_xml_output, p_link_target); } } } void BindingsGenerator::_append_xml_signal(StringBuilder &p_xml_output, const TypeInterface *p_target_itype, const StringName &p_target_cname, const String &p_link_target, const Vector &p_link_target_parts) { if (!p_target_itype || !p_target_itype->is_object_type) { if (OS::get_singleton()->is_stdout_verbose()) { if (p_target_itype) { OS::get_singleton()->print("Cannot resolve signal reference for non-GodotObject type in documentation: %s\n", p_link_target.utf8().get_data()); } else { OS::get_singleton()->print("Cannot resolve type from signal reference in documentation: %s\n", p_link_target.utf8().get_data()); } } // TODO Map what we can _append_xml_undeclared(p_xml_output, p_link_target); } else { const SignalInterface *target_isignal = p_target_itype->find_signal_by_name(p_target_cname); if (target_isignal) { p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(target_isignal->proxy_name); p_xml_output.append("\"/>"); } else { if (!p_target_itype->is_intentionally_ignored(p_link_target)) { ERR_PRINT("Cannot resolve signal reference in documentation: '" + p_link_target + "'."); } _append_xml_undeclared(p_xml_output, p_link_target); } } } void BindingsGenerator::_append_xml_enum(StringBuilder &p_xml_output, const TypeInterface *p_target_itype, const StringName &p_target_cname, const String &p_link_target, const Vector &p_link_target_parts) { const StringName search_cname = !p_target_itype ? p_target_cname : StringName(p_target_itype->name + "." + (String)p_target_cname); HashMap::ConstIterator enum_match = enum_types.find(search_cname); if (!enum_match && search_cname != p_target_cname) { enum_match = enum_types.find(p_target_cname); } if (enum_match) { const TypeInterface &target_enum_itype = enum_match->value; p_xml_output.append(""); } else { if (!p_target_itype->is_intentionally_ignored(p_link_target)) { ERR_PRINT("Cannot resolve enum reference in documentation: '" + p_link_target + "'."); } _append_xml_undeclared(p_xml_output, p_link_target); } } void BindingsGenerator::_append_xml_constant(StringBuilder &p_xml_output, const TypeInterface *p_target_itype, const StringName &p_target_cname, const String &p_link_target, const Vector &p_link_target_parts) { if (p_link_target_parts[0] == name_cache.type_at_GlobalScope) { _append_xml_constant_in_global_scope(p_xml_output, p_target_cname, p_link_target); } else if (!p_target_itype || !p_target_itype->is_object_type) { // Search in @GlobalScope as a last resort if no class was specified if (p_link_target_parts.size() == 1) { _append_xml_constant_in_global_scope(p_xml_output, p_target_cname, p_link_target); return; } if (OS::get_singleton()->is_stdout_verbose()) { if (p_target_itype) { OS::get_singleton()->print("Cannot resolve constant reference for non-GodotObject type in documentation: %s\n", p_link_target.utf8().get_data()); } else { OS::get_singleton()->print("Cannot resolve type from constant reference in documentation: %s\n", p_link_target.utf8().get_data()); } } // TODO Map what we can _append_xml_undeclared(p_xml_output, p_link_target); } else { // Try to find the constant in the current class if (p_target_itype->is_singleton_instance) { // Constants and enums are declared in the static singleton class. p_target_itype = &obj_types[p_target_itype->cname]; } const ConstantInterface *target_iconst = find_constant_by_name(p_target_cname, p_target_itype->constants); if (target_iconst) { // Found constant in current class p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(target_iconst->proxy_name); p_xml_output.append("\"/>"); } else { // Try to find as enum constant in the current class const EnumInterface *target_ienum = nullptr; for (const EnumInterface &ienum : p_target_itype->enums) { target_ienum = &ienum; target_iconst = find_constant_by_name(p_target_cname, target_ienum->constants); if (target_iconst) { break; } } if (target_iconst) { p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(target_ienum->proxy_name); p_xml_output.append("."); p_xml_output.append(target_iconst->proxy_name); p_xml_output.append("\"/>"); } else if (p_link_target_parts.size() == 1) { // Also search in @GlobalScope as a last resort if no class was specified _append_xml_constant_in_global_scope(p_xml_output, p_target_cname, p_link_target); } else { if (!p_target_itype->is_intentionally_ignored(p_link_target)) { ERR_PRINT("Cannot resolve constant reference in documentation: '" + p_link_target + "'."); } _append_xml_undeclared(p_xml_output, p_link_target); } } } } void BindingsGenerator::_append_xml_constant_in_global_scope(StringBuilder &p_xml_output, const String &p_target_cname, const String &p_link_target) { // Try to find as a global constant const ConstantInterface *target_iconst = find_constant_by_name(p_target_cname, global_constants); if (target_iconst) { // Found global constant p_xml_output.append("proxy_name); p_xml_output.append("\"/>"); } else { // Try to find as global enum constant const EnumInterface *target_ienum = nullptr; for (const EnumInterface &ienum : global_enums) { target_ienum = &ienum; target_iconst = find_constant_by_name(p_target_cname, target_ienum->constants); if (target_iconst) { break; } } if (target_iconst) { p_xml_output.append("proxy_name); p_xml_output.append("."); p_xml_output.append(target_iconst->proxy_name); p_xml_output.append("\"/>"); } else { ERR_PRINT("Cannot resolve global constant reference in documentation: '" + p_link_target + "'."); _append_xml_undeclared(p_xml_output, p_link_target); } } } void BindingsGenerator::_append_xml_param(StringBuilder &p_xml_output, const String &p_link_target, bool p_is_signal) { const String link_target = snake_to_camel_case(p_link_target); if (!p_is_signal) { p_xml_output.append(""); } else { // Documentation in C# is added to an event, not the delegate itself; // as such, we treat these parameters as codeblocks instead. // See: https://github.com/godotengine/godot/pull/65529 _append_xml_undeclared(p_xml_output, link_target); } } void BindingsGenerator::_append_xml_undeclared(StringBuilder &p_xml_output, const String &p_link_target) { p_xml_output.append(""); p_xml_output.append(p_link_target); p_xml_output.append(""); } int BindingsGenerator::_determine_enum_prefix(const EnumInterface &p_ienum) { CRASH_COND(p_ienum.constants.is_empty()); const ConstantInterface &front_iconstant = p_ienum.constants.front()->get(); Vector front_parts = front_iconstant.name.split("_", /* p_allow_empty: */ true); int candidate_len = front_parts.size() - 1; if (candidate_len == 0) { return 0; } for (const ConstantInterface &iconstant : p_ienum.constants) { Vector parts = iconstant.name.split("_", /* p_allow_empty: */ true); int i; for (i = 0; i < candidate_len && i < parts.size(); i++) { if (front_parts[i] != parts[i]) { // HARDCODED: Some Flag enums have the prefix 'FLAG_' for everything except 'FLAGS_DEFAULT' (same for 'METHOD_FLAG_' and'METHOD_FLAGS_DEFAULT'). bool hardcoded_exc = (i == candidate_len - 1 && ((front_parts[i] == "FLAGS" && parts[i] == "FLAG") || (front_parts[i] == "FLAG" && parts[i] == "FLAGS"))); if (!hardcoded_exc) { break; } } } candidate_len = i; if (candidate_len == 0) { return 0; } } return candidate_len; } void BindingsGenerator::_apply_prefix_to_enum_constants(BindingsGenerator::EnumInterface &p_ienum, int p_prefix_length) { if (p_prefix_length > 0) { for (ConstantInterface &iconstant : p_ienum.constants) { int curr_prefix_length = p_prefix_length; String constant_name = iconstant.name; Vector parts = constant_name.split("_", /* p_allow_empty: */ true); if (parts.size() <= curr_prefix_length) { continue; } if (is_digit(parts[curr_prefix_length][0])) { // The name of enum constants may begin with a numeric digit when strip from the enum prefix, // so we make the prefix for this constant one word shorter in those cases. for (curr_prefix_length = curr_prefix_length - 1; curr_prefix_length > 0; curr_prefix_length--) { if (!is_digit(parts[curr_prefix_length][0])) { break; } } } constant_name = ""; for (int i = curr_prefix_length; i < parts.size(); i++) { if (i > curr_prefix_length) { constant_name += "_"; } constant_name += parts[i]; } iconstant.proxy_name = snake_to_pascal_case(constant_name, true); } } } Error BindingsGenerator::_populate_method_icalls_table(const TypeInterface &p_itype) { for (const MethodInterface &imethod : p_itype.methods) { if (imethod.is_virtual) { continue; } const TypeInterface *return_type = _get_type_or_null(imethod.return_type); ERR_FAIL_NULL_V(return_type, ERR_BUG); // Return type not found String im_unique_sig = get_ret_unique_sig(return_type) + ",CallMethodBind"; if (!imethod.is_static) { im_unique_sig += ",CallInstance"; } // Get arguments information for (const ArgumentInterface &iarg : imethod.arguments) { const TypeInterface *arg_type = _get_type_or_null(iarg.type); ERR_FAIL_NULL_V(arg_type, ERR_BUG); // Argument type not found im_unique_sig += ","; im_unique_sig += get_arg_unique_sig(*arg_type); } // godot_icall_{argc}_{icallcount} String icall_method = ICALL_PREFIX; icall_method += itos(imethod.arguments.size()); icall_method += "_"; icall_method += itos(method_icalls.size()); InternalCall im_icall = InternalCall(p_itype.api_type, icall_method, im_unique_sig); im_icall.is_vararg = imethod.is_vararg; im_icall.is_static = imethod.is_static; im_icall.return_type = imethod.return_type; for (const List::Element *F = imethod.arguments.front(); F; F = F->next()) { im_icall.argument_types.push_back(F->get().type); } List::Element *match = method_icalls.find(im_icall); if (match) { if (p_itype.api_type != ClassDB::API_EDITOR) { match->get().editor_only = false; } method_icalls_map.insert(&imethod, &match->get()); } else { List::Element *added = method_icalls.push_back(im_icall); method_icalls_map.insert(&imethod, &added->get()); } } return OK; } void BindingsGenerator::_generate_array_extensions(StringBuilder &p_output) { p_output.append("namespace " BINDINGS_NAMESPACE ";\n\n"); p_output.append("using System;\n\n"); // The class where we put the extensions doesn't matter, so just use "GD". p_output.append("public static partial class " BINDINGS_GLOBAL_SCOPE_CLASS "\n{"); #define ARRAY_IS_EMPTY(m_type) \ p_output.append("\n" INDENT1 "/// \n"); \ p_output.append(INDENT1 "/// Returns true if this " #m_type " array is empty or doesn't exist.\n"); \ p_output.append(INDENT1 "/// \n"); \ p_output.append(INDENT1 "/// The " #m_type " array check.\n"); \ p_output.append(INDENT1 "/// Whether or not the array is empty.\n"); \ p_output.append(INDENT1 "public static bool IsEmpty(this " #m_type "[] instance)\n"); \ p_output.append(OPEN_BLOCK_L1); \ p_output.append(INDENT2 "return instance == null || instance.Length == 0;\n"); \ p_output.append(INDENT1 CLOSE_BLOCK); #define ARRAY_JOIN(m_type) \ p_output.append("\n" INDENT1 "/// \n"); \ p_output.append(INDENT1 "/// Converts this " #m_type " array to a string delimited by the given string.\n"); \ p_output.append(INDENT1 "/// \n"); \ p_output.append(INDENT1 "/// The " #m_type " array to convert.\n"); \ p_output.append(INDENT1 "/// The delimiter to use between items.\n"); \ p_output.append(INDENT1 "/// A single string with all items.\n"); \ p_output.append(INDENT1 "public static string Join(this " #m_type "[] instance, string delimiter = \", \")\n"); \ p_output.append(OPEN_BLOCK_L1); \ p_output.append(INDENT2 "return String.Join(delimiter, instance);\n"); \ p_output.append(INDENT1 CLOSE_BLOCK); #define ARRAY_STRINGIFY(m_type) \ p_output.append("\n" INDENT1 "/// \n"); \ p_output.append(INDENT1 "/// Converts this " #m_type " array to a string with brackets.\n"); \ p_output.append(INDENT1 "/// \n"); \ p_output.append(INDENT1 "/// The " #m_type " array to convert.\n"); \ p_output.append(INDENT1 "/// A single string with all items.\n"); \ p_output.append(INDENT1 "public static string Stringify(this " #m_type "[] instance)\n"); \ p_output.append(OPEN_BLOCK_L1); \ p_output.append(INDENT2 "return \"[\" + instance.Join() + \"]\";\n"); \ p_output.append(INDENT1 CLOSE_BLOCK); #define ARRAY_ALL(m_type) \ ARRAY_IS_EMPTY(m_type) \ ARRAY_JOIN(m_type) \ ARRAY_STRINGIFY(m_type) ARRAY_ALL(byte); ARRAY_ALL(int); ARRAY_ALL(long); ARRAY_ALL(float); ARRAY_ALL(double); ARRAY_ALL(string); ARRAY_ALL(Color); ARRAY_ALL(Vector2); ARRAY_ALL(Vector2I); ARRAY_ALL(Vector3); ARRAY_ALL(Vector3I); ARRAY_ALL(Vector4); ARRAY_ALL(Vector4I); #undef ARRAY_ALL #undef ARRAY_IS_EMPTY #undef ARRAY_JOIN #undef ARRAY_STRINGIFY p_output.append(CLOSE_BLOCK); // End of GD class. } void BindingsGenerator::_generate_global_constants(StringBuilder &p_output) { // Constants (in partial GD class) p_output.append("namespace " BINDINGS_NAMESPACE ";\n\n"); p_output.append("public static partial class " BINDINGS_GLOBAL_SCOPE_CLASS "\n{"); for (const ConstantInterface &iconstant : global_constants) { if (iconstant.const_doc && iconstant.const_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(iconstant.const_doc->description), nullptr); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { p_output.append(MEMBER_BEGIN "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { p_output.append(INDENT1 "/// "); p_output.append(summary_lines[i]); p_output.append("\n"); } p_output.append(INDENT1 "/// "); } } p_output.append(MEMBER_BEGIN "public const long "); p_output.append(iconstant.proxy_name); p_output.append(" = "); p_output.append(itos(iconstant.value)); p_output.append(";"); } if (!global_constants.is_empty()) { p_output.append("\n"); } p_output.append(CLOSE_BLOCK); // end of GD class // Enums for (const EnumInterface &ienum : global_enums) { CRASH_COND(ienum.constants.is_empty()); String enum_proxy_name = ienum.proxy_name; bool enum_in_static_class = false; if (enum_proxy_name.find(".") > 0) { enum_in_static_class = true; String enum_class_name = enum_proxy_name.get_slicec('.', 0); enum_proxy_name = enum_proxy_name.get_slicec('.', 1); CRASH_COND(enum_class_name != "Variant"); // Hard-coded... _log("Declaring global enum '%s' inside struct '%s'\n", enum_proxy_name.utf8().get_data(), enum_class_name.utf8().get_data()); p_output.append("\npublic partial struct "); p_output.append(enum_class_name); p_output.append("\n" OPEN_BLOCK); } if (ienum.is_flags) { p_output.append("\n[System.Flags]"); } p_output.append("\npublic enum "); p_output.append(enum_proxy_name); p_output.append(" : long"); p_output.append("\n" OPEN_BLOCK); const ConstantInterface &last = ienum.constants.back()->get(); for (const ConstantInterface &iconstant : ienum.constants) { if (iconstant.const_doc && iconstant.const_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(iconstant.const_doc->description), nullptr); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { p_output.append(INDENT1 "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { p_output.append(INDENT1 "/// "); p_output.append(summary_lines[i]); p_output.append("\n"); } p_output.append(INDENT1 "/// \n"); } } p_output.append(INDENT1); p_output.append(iconstant.proxy_name); p_output.append(" = "); p_output.append(itos(iconstant.value)); p_output.append(&iconstant != &last ? ",\n" : "\n"); } p_output.append(CLOSE_BLOCK); if (enum_in_static_class) { p_output.append(CLOSE_BLOCK); } } } Error BindingsGenerator::generate_cs_core_project(const String &p_proj_dir) { ERR_FAIL_COND_V(!initialized, ERR_UNCONFIGURED); Ref da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM); ERR_FAIL_COND_V(da.is_null(), ERR_CANT_CREATE); if (!DirAccess::exists(p_proj_dir)) { Error err = da->make_dir_recursive(p_proj_dir); ERR_FAIL_COND_V_MSG(err != OK, ERR_CANT_CREATE, "Cannot create directory '" + p_proj_dir + "'."); } da->change_dir(p_proj_dir); da->make_dir("Generated"); da->make_dir("Generated/GodotObjects"); String base_gen_dir = path::join(p_proj_dir, "Generated"); String godot_objects_gen_dir = path::join(base_gen_dir, "GodotObjects"); Vector compile_items; // Generate source file for global scope constants and enums { StringBuilder constants_source; _generate_global_constants(constants_source); String output_file = path::join(base_gen_dir, BINDINGS_GLOBAL_SCOPE_CLASS "_constants.cs"); Error save_err = _save_file(output_file, constants_source); if (save_err != OK) { return save_err; } compile_items.push_back(output_file); } // Generate source file for array extensions { StringBuilder extensions_source; _generate_array_extensions(extensions_source); String output_file = path::join(base_gen_dir, BINDINGS_GLOBAL_SCOPE_CLASS "_extensions.cs"); Error save_err = _save_file(output_file, extensions_source); if (save_err != OK) { return save_err; } compile_items.push_back(output_file); } for (const KeyValue &E : obj_types) { const TypeInterface &itype = E.value; if (itype.api_type == ClassDB::API_EDITOR) { continue; } String output_file = path::join(godot_objects_gen_dir, itype.proxy_name + ".cs"); Error err = _generate_cs_type(itype, output_file); if (err == ERR_SKIP) { continue; } if (err != OK) { return err; } compile_items.push_back(output_file); } // Generate native calls StringBuilder cs_icalls_content; cs_icalls_content.append("namespace " BINDINGS_NAMESPACE ";\n\n"); cs_icalls_content.append("using System;\n" "using System.Diagnostics.CodeAnalysis;\n" "using System.Runtime.InteropServices;\n" "using Godot.NativeInterop;\n" "\n"); cs_icalls_content.append("[SuppressMessage(\"ReSharper\", \"InconsistentNaming\")]\n"); cs_icalls_content.append("[SuppressMessage(\"ReSharper\", \"RedundantUnsafeContext\")]\n"); cs_icalls_content.append("[SuppressMessage(\"ReSharper\", \"RedundantNameQualifier\")]\n"); cs_icalls_content.append("[System.Runtime.CompilerServices.SkipLocalsInit]\n"); cs_icalls_content.append("internal static class " BINDINGS_CLASS_NATIVECALLS "\n{"); cs_icalls_content.append(MEMBER_BEGIN "internal static ulong godot_api_hash = "); cs_icalls_content.append(String::num_uint64(ClassDB::get_api_hash(ClassDB::API_CORE)) + ";\n"); cs_icalls_content.append(MEMBER_BEGIN "private const int VarArgsSpanThreshold = 10;\n"); for (const InternalCall &icall : method_icalls) { if (icall.editor_only) { continue; } Error err = _generate_cs_native_calls(icall, cs_icalls_content); if (err != OK) { return err; } } cs_icalls_content.append(CLOSE_BLOCK); String internal_methods_file = path::join(base_gen_dir, BINDINGS_CLASS_NATIVECALLS ".cs"); Error err = _save_file(internal_methods_file, cs_icalls_content); if (err != OK) { return err; } compile_items.push_back(internal_methods_file); // Generate GeneratedIncludes.props StringBuilder includes_props_content; includes_props_content.append("\n" " \n"); for (int i = 0; i < compile_items.size(); i++) { String include = path::relative_to(compile_items[i], p_proj_dir).replace("/", "\\"); includes_props_content.append(" \n"); } includes_props_content.append(" \n" "\n"); String includes_props_file = path::join(base_gen_dir, "GeneratedIncludes.props"); err = _save_file(includes_props_file, includes_props_content); if (err != OK) { return err; } return OK; } Error BindingsGenerator::generate_cs_editor_project(const String &p_proj_dir) { ERR_FAIL_COND_V(!initialized, ERR_UNCONFIGURED); Ref da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM); ERR_FAIL_COND_V(da.is_null(), ERR_CANT_CREATE); if (!DirAccess::exists(p_proj_dir)) { Error err = da->make_dir_recursive(p_proj_dir); ERR_FAIL_COND_V(err != OK, ERR_CANT_CREATE); } da->change_dir(p_proj_dir); da->make_dir("Generated"); da->make_dir("Generated/GodotObjects"); String base_gen_dir = path::join(p_proj_dir, "Generated"); String godot_objects_gen_dir = path::join(base_gen_dir, "GodotObjects"); Vector compile_items; for (const KeyValue &E : obj_types) { const TypeInterface &itype = E.value; if (itype.api_type != ClassDB::API_EDITOR) { continue; } String output_file = path::join(godot_objects_gen_dir, itype.proxy_name + ".cs"); Error err = _generate_cs_type(itype, output_file); if (err == ERR_SKIP) { continue; } if (err != OK) { return err; } compile_items.push_back(output_file); } // Generate native calls StringBuilder cs_icalls_content; cs_icalls_content.append("namespace " BINDINGS_NAMESPACE ";\n\n"); cs_icalls_content.append("using System;\n" "using System.Diagnostics.CodeAnalysis;\n" "using System.Runtime.InteropServices;\n" "using Godot.NativeInterop;\n" "\n"); cs_icalls_content.append("[SuppressMessage(\"ReSharper\", \"InconsistentNaming\")]\n"); cs_icalls_content.append("[SuppressMessage(\"ReSharper\", \"RedundantUnsafeContext\")]\n"); cs_icalls_content.append("[SuppressMessage(\"ReSharper\", \"RedundantNameQualifier\")]\n"); cs_icalls_content.append("[System.Runtime.CompilerServices.SkipLocalsInit]\n"); cs_icalls_content.append("internal static class " BINDINGS_CLASS_NATIVECALLS_EDITOR "\n" OPEN_BLOCK); cs_icalls_content.append(INDENT1 "internal static ulong godot_api_hash = "); cs_icalls_content.append(String::num_uint64(ClassDB::get_api_hash(ClassDB::API_EDITOR)) + ";\n"); cs_icalls_content.append(MEMBER_BEGIN "private const int VarArgsSpanThreshold = 10;\n"); cs_icalls_content.append("\n"); for (const InternalCall &icall : method_icalls) { if (!icall.editor_only) { continue; } Error err = _generate_cs_native_calls(icall, cs_icalls_content); if (err != OK) { return err; } } cs_icalls_content.append(CLOSE_BLOCK); String internal_methods_file = path::join(base_gen_dir, BINDINGS_CLASS_NATIVECALLS_EDITOR ".cs"); Error err = _save_file(internal_methods_file, cs_icalls_content); if (err != OK) { return err; } compile_items.push_back(internal_methods_file); // Generate GeneratedIncludes.props StringBuilder includes_props_content; includes_props_content.append("\n" " \n"); for (int i = 0; i < compile_items.size(); i++) { String include = path::relative_to(compile_items[i], p_proj_dir).replace("/", "\\"); includes_props_content.append(" \n"); } includes_props_content.append(" \n" "\n"); String includes_props_file = path::join(base_gen_dir, "GeneratedIncludes.props"); err = _save_file(includes_props_file, includes_props_content); if (err != OK) { return err; } return OK; } Error BindingsGenerator::generate_cs_api(const String &p_output_dir) { ERR_FAIL_COND_V(!initialized, ERR_UNCONFIGURED); String output_dir = path::abspath(path::realpath(p_output_dir)); Ref da = DirAccess::create(DirAccess::ACCESS_FILESYSTEM); ERR_FAIL_COND_V(da.is_null(), ERR_CANT_CREATE); if (!DirAccess::exists(output_dir)) { Error err = da->make_dir_recursive(output_dir); ERR_FAIL_COND_V(err != OK, ERR_CANT_CREATE); } Error proj_err; // Generate GodotSharp source files String core_proj_dir = output_dir.path_join(CORE_API_ASSEMBLY_NAME); proj_err = generate_cs_core_project(core_proj_dir); if (proj_err != OK) { ERR_PRINT("Generation of the Core API C# project failed."); return proj_err; } // Generate GodotSharpEditor source files String editor_proj_dir = output_dir.path_join(EDITOR_API_ASSEMBLY_NAME); proj_err = generate_cs_editor_project(editor_proj_dir); if (proj_err != OK) { ERR_PRINT("Generation of the Editor API C# project failed."); return proj_err; } _log("The Godot API sources were successfully generated\n"); return OK; } // FIXME: There are some members that hide other inherited members. // - In the case of both members being the same kind, the new one must be declared // explicitly as 'new' to avoid the warning (and we must print a message about it). // - In the case of both members being of a different kind, then the new one must // be renamed to avoid the name collision (and we must print a warning about it). // - Csc warning e.g.: // ObjectType/LineEdit.cs(140,38): warning CS0108: 'LineEdit.FocusMode' hides inherited member 'Control.FocusMode'. Use the new keyword if hiding was intended. Error BindingsGenerator::_generate_cs_type(const TypeInterface &itype, const String &p_output_file) { CRASH_COND(!itype.is_object_type); bool is_derived_type = itype.base_name != StringName(); if (!is_derived_type) { // Some GodotObject assertions CRASH_COND(itype.cname != name_cache.type_Object); CRASH_COND(!itype.is_instantiable); CRASH_COND(itype.api_type != ClassDB::API_CORE); CRASH_COND(itype.is_ref_counted); CRASH_COND(itype.is_singleton); } _log("Generating %s.cs...\n", itype.proxy_name.utf8().get_data()); StringBuilder output; output.append("namespace " BINDINGS_NAMESPACE ";\n\n"); output.append("using System;\n"); // IntPtr output.append("using System.ComponentModel;\n"); // EditorBrowsable output.append("using System.Diagnostics;\n"); // DebuggerBrowsable output.append("using Godot.NativeInterop;\n"); output.append("\n#nullable disable\n"); const DocData::ClassDoc *class_doc = itype.class_doc; if (class_doc && class_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(class_doc->description), &itype); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { output.append("/// \n"); for (int i = 0; i < summary_lines.size(); i++) { output.append("/// "); output.append(summary_lines[i]); output.append("\n"); } output.append("/// \n"); } if (class_doc->is_deprecated) { output.append("[Obsolete(\"This class is deprecated.\")]\n"); } } // We generate a `GodotClassName` attribute if the engine class name is not the same as the // generated C# class name. This allows introspection code to find the name associated with // the class. If the attribute is not present, the C# class name can be used instead. if (itype.name != itype.proxy_name) { output << "[GodotClassName(\"" << itype.name << "\")]\n"; } output.append("public "); if (itype.is_singleton) { output.append("static partial class "); } else { // Even if the class is not instantiable, we can't declare it abstract because // the engine can still instantiate them and return them via the scripting API. // Example: `SceneTreeTimer` returned from `SceneTree.create_timer`. // See the reverted commit: ef5672d3f94a7321ed779c922088bb72adbb1521 output.append("partial class "); } output.append(itype.proxy_name); if (is_derived_type && !itype.is_singleton) { if (obj_types.has(itype.base_name)) { TypeInterface base_type = obj_types[itype.base_name]; output.append(" : "); output.append(base_type.proxy_name); if (base_type.is_singleton) { // If the type is a singleton, use the instance type. output.append(CS_SINGLETON_INSTANCE_SUFFIX); } } else { ERR_PRINT("Base type '" + itype.base_name.operator String() + "' does not exist, for class '" + itype.name + "'."); return ERR_INVALID_DATA; } } output.append("\n{"); // Add constants for (const ConstantInterface &iconstant : itype.constants) { if (iconstant.const_doc && iconstant.const_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(iconstant.const_doc->description), &itype); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { output.append(MEMBER_BEGIN "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { output.append(INDENT1 "/// "); output.append(summary_lines[i]); output.append("\n"); } output.append(INDENT1 "/// "); } if (iconstant.const_doc->is_deprecated) { output.append(MEMBER_BEGIN "[Obsolete(\"This constant is deprecated.\")]"); } } output.append(MEMBER_BEGIN "public const long "); output.append(iconstant.proxy_name); output.append(" = "); output.append(itos(iconstant.value)); output.append(";"); } if (itype.constants.size()) { output.append("\n"); } // Add enums for (const EnumInterface &ienum : itype.enums) { ERR_FAIL_COND_V(ienum.constants.is_empty(), ERR_BUG); if (ienum.is_flags) { output.append(MEMBER_BEGIN "[System.Flags]"); } output.append(MEMBER_BEGIN "public enum "); output.append(ienum.proxy_name); output.append(" : long"); output.append(MEMBER_BEGIN OPEN_BLOCK); const ConstantInterface &last = ienum.constants.back()->get(); for (const ConstantInterface &iconstant : ienum.constants) { if (iconstant.const_doc && iconstant.const_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(iconstant.const_doc->description), &itype); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { output.append(INDENT2 "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { output.append(INDENT2 "/// "); output.append(summary_lines[i]); output.append("\n"); } output.append(INDENT2 "/// \n"); } if (iconstant.const_doc->is_deprecated) { output.append(INDENT2 "[Obsolete(\"This enum member is deprecated.\")]\n"); } } output.append(INDENT2); output.append(iconstant.proxy_name); output.append(" = "); output.append(itos(iconstant.value)); output.append(&iconstant != &last ? ",\n" : "\n"); } output.append(INDENT1 CLOSE_BLOCK); } // Add properties for (const PropertyInterface &iprop : itype.properties) { Error prop_err = _generate_cs_property(itype, iprop, output); ERR_FAIL_COND_V_MSG(prop_err != OK, prop_err, "Failed to generate property '" + iprop.cname.operator String() + "' for class '" + itype.name + "'."); } // Add native name static field and cached type. if (is_derived_type && !itype.is_singleton) { output << MEMBER_BEGIN "private static readonly System.Type CachedType = typeof(" << itype.proxy_name << ");\n"; } output.append(MEMBER_BEGIN "private static readonly StringName " BINDINGS_NATIVE_NAME_FIELD " = \""); output.append(itype.name); output.append("\";\n"); if (itype.is_singleton || itype.is_compat_singleton) { // Add the Singleton static property. String instance_type_name; if (itype.is_singleton) { StringName instance_name = itype.name + CS_SINGLETON_INSTANCE_SUFFIX; instance_type_name = obj_types.has(instance_name) ? obj_types[instance_name].proxy_name : "GodotObject"; } else { instance_type_name = itype.proxy_name; } output.append(MEMBER_BEGIN "private static " + instance_type_name + " singleton;\n"); output << MEMBER_BEGIN "public static " + instance_type_name + " " CS_PROPERTY_SINGLETON " =>\n" << INDENT2 "singleton \?\?= (" + instance_type_name + ")" << C_METHOD_ENGINE_GET_SINGLETON "(\"" << itype.name << "\");\n"; } if (!itype.is_singleton) { // IMPORTANT: We also generate the static fields for GodotObject instead of declaring // them manually in the `GodotObject.base.cs` partial class declaration, because they're // required by other static fields in this generated partial class declaration. // Static fields are initialized in order of declaration, but when they're in different // partial class declarations then it becomes harder to tell (Rider warns about this). if (itype.is_instantiable) { // Add native constructor static field output << MEMBER_BEGIN << "[DebuggerBrowsable(DebuggerBrowsableState.Never)]\n" << INDENT1 "private static readonly unsafe delegate* unmanaged " << CS_STATIC_FIELD_NATIVE_CTOR " = " ICALL_CLASSDB_GET_CONSTRUCTOR << "(" BINDINGS_NATIVE_NAME_FIELD ");\n"; } if (is_derived_type) { // Add default constructor if (itype.is_instantiable) { output << MEMBER_BEGIN "public " << itype.proxy_name << "() : this(" << (itype.memory_own ? "true" : "false") << ")\n" OPEN_BLOCK_L1 << INDENT2 "unsafe\n" INDENT2 OPEN_BLOCK << INDENT3 "_ConstructAndInitialize(" CS_STATIC_FIELD_NATIVE_CTOR ", " << BINDINGS_NATIVE_NAME_FIELD ", CachedType, refCounted: " << (itype.is_ref_counted ? "true" : "false") << ");\n" << CLOSE_BLOCK_L2 CLOSE_BLOCK_L1; } else { // Hide the constructor output.append(MEMBER_BEGIN "internal "); output.append(itype.proxy_name); output.append("() {}\n"); } // Add.. em.. trick constructor. Sort of. output.append(MEMBER_BEGIN "internal "); output.append(itype.proxy_name); output.append("(bool " CS_PARAM_MEMORYOWN ") : base(" CS_PARAM_MEMORYOWN ") {}\n"); } } // Methods int method_bind_count = 0; for (const MethodInterface &imethod : itype.methods) { Error method_err = _generate_cs_method(itype, imethod, method_bind_count, output); ERR_FAIL_COND_V_MSG(method_err != OK, method_err, "Failed to generate method '" + imethod.name + "' for class '" + itype.name + "'."); } // Signals for (const SignalInterface &isignal : itype.signals_) { Error method_err = _generate_cs_signal(itype, isignal, output); ERR_FAIL_COND_V_MSG(method_err != OK, method_err, "Failed to generate signal '" + isignal.name + "' for class '" + itype.name + "'."); } // Script members look-up if (!itype.is_singleton && (is_derived_type || itype.has_virtual_methods)) { // Generate method names cache fields for (const MethodInterface &imethod : itype.methods) { if (!imethod.is_virtual) { continue; } output << MEMBER_BEGIN "// ReSharper disable once InconsistentNaming\n" << INDENT1 "[DebuggerBrowsable(DebuggerBrowsableState.Never)]\n" << INDENT1 "private static readonly StringName " << CS_STATIC_FIELD_METHOD_PROXY_NAME_PREFIX << imethod.name << " = \"" << imethod.proxy_name << "\";\n"; } // Generate signal names cache fields for (const SignalInterface &isignal : itype.signals_) { output << MEMBER_BEGIN "// ReSharper disable once InconsistentNaming\n" << INDENT1 "[DebuggerBrowsable(DebuggerBrowsableState.Never)]\n" << INDENT1 "private static readonly StringName " << CS_STATIC_FIELD_SIGNAL_PROXY_NAME_PREFIX << isignal.name << " = \"" << isignal.proxy_name << "\";\n"; } // TODO: Only generate HasGodotClassMethod and InvokeGodotClassMethod if there's any method // Generate InvokeGodotClassMethod output << MEMBER_BEGIN "/// \n" << INDENT1 "/// Invokes the method with the given name, using the given arguments.\n" << INDENT1 "/// This method is used by Godot to invoke methods from the engine side.\n" << INDENT1 "/// Do not call or override this method.\n" << INDENT1 "/// \n" << INDENT1 "/// Name of the method to invoke.\n" << INDENT1 "/// Arguments to use with the invoked method.\n" << INDENT1 "/// Value returned by the invoked method.\n"; output << INDENT1 "protected internal " << (is_derived_type ? "override" : "virtual") << " bool " CS_METHOD_INVOKE_GODOT_CLASS_METHOD "(in godot_string_name method, " << "NativeVariantPtrArgs args, out godot_variant ret)\n" << INDENT1 "{\n"; for (const MethodInterface &imethod : itype.methods) { if (!imethod.is_virtual) { continue; } // We also call HasGodotClassMethod to ensure the method is overridden and avoid calling // the stub implementation. This solution adds some extra overhead to calls, but it's // much simpler than other solutions. This won't be a problem once we move to function // pointers of generated wrappers for each method, as lookup will only happen once. // We check both native names (snake_case) and proxy names (PascalCase) output << INDENT2 "if ((method == " << CS_STATIC_FIELD_METHOD_PROXY_NAME_PREFIX << imethod.name << " || method == MethodName." << imethod.proxy_name << ") && args.Count == " << itos(imethod.arguments.size()) << " && " << CS_METHOD_HAS_GODOT_CLASS_METHOD << "((godot_string_name)" << CS_STATIC_FIELD_METHOD_PROXY_NAME_PREFIX << imethod.name << ".NativeValue))\n" << INDENT2 "{\n"; if (imethod.return_type.cname != name_cache.type_void) { output << INDENT3 "var callRet = "; } else { output << INDENT3; } output << imethod.proxy_name << "("; for (int i = 0; i < imethod.arguments.size(); i++) { const ArgumentInterface &iarg = imethod.arguments[i]; const TypeInterface *arg_type = _get_type_or_null(iarg.type); ERR_FAIL_NULL_V(arg_type, ERR_BUG); // Argument type not found if (i != 0) { output << ", "; } if (arg_type->cname == name_cache.type_Array_generic || arg_type->cname == name_cache.type_Dictionary_generic) { String arg_cs_type = arg_type->cs_type + _get_generic_type_parameters(*arg_type, iarg.type.generic_type_parameters); output << "new " << arg_cs_type << "(" << sformat(arg_type->cs_variant_to_managed, "args[" + itos(i) + "]", arg_type->cs_type, arg_type->name) << ")"; } else { output << sformat(arg_type->cs_variant_to_managed, "args[" + itos(i) + "]", arg_type->cs_type, arg_type->name); } } output << ");\n"; if (imethod.return_type.cname != name_cache.type_void) { const TypeInterface *return_type = _get_type_or_null(imethod.return_type); ERR_FAIL_NULL_V(return_type, ERR_BUG); // Return type not found output << INDENT3 "ret = " << sformat(return_type->cs_managed_to_variant, "callRet", return_type->cs_type, return_type->name) << ";\n" << INDENT3 "return true;\n"; } else { output << INDENT3 "ret = default;\n" << INDENT3 "return true;\n"; } output << INDENT2 "}\n"; } if (is_derived_type) { output << INDENT2 "return base." CS_METHOD_INVOKE_GODOT_CLASS_METHOD "(method, args, out ret);\n"; } else { output << INDENT2 "ret = default;\n" << INDENT2 "return false;\n"; } output << INDENT1 "}\n"; // Generate HasGodotClassMethod output << MEMBER_BEGIN "/// \n" << INDENT1 "/// Check if the type contains a method with the given name.\n" << INDENT1 "/// This method is used by Godot to check if a method exists before invoking it.\n" << INDENT1 "/// Do not call or override this method.\n" << INDENT1 "/// \n" << INDENT1 "/// Name of the method to check for.\n"; output << MEMBER_BEGIN "protected internal " << (is_derived_type ? "override" : "virtual") << " bool " CS_METHOD_HAS_GODOT_CLASS_METHOD "(in godot_string_name method)\n" << INDENT1 "{\n"; for (const MethodInterface &imethod : itype.methods) { if (!imethod.is_virtual) { continue; } // We check for native names (snake_case). If we detect one, we call HasGodotClassMethod // again, but this time with the respective proxy name (PascalCase). It's the job of // user derived classes to override the method and check for those. Our C# source // generators take care of generating those override methods. output << INDENT2 "if (method == MethodName." << imethod.proxy_name << ")\n" INDENT2 "{\n" << INDENT3 "if (" CS_METHOD_HAS_GODOT_CLASS_METHOD "(" << CS_STATIC_FIELD_METHOD_PROXY_NAME_PREFIX << imethod.name << ".NativeValue.DangerousSelfRef))\n" INDENT3 "{\n" << INDENT4 "return true;\n" << INDENT3 "}\n" INDENT2 "}\n"; } if (is_derived_type) { output << INDENT2 "return base." CS_METHOD_HAS_GODOT_CLASS_METHOD "(method);\n"; } else { output << INDENT2 "return false;\n"; } output << INDENT1 "}\n"; // Generate HasGodotClassSignal output << MEMBER_BEGIN "/// \n" << INDENT1 "/// Check if the type contains a signal with the given name.\n" << INDENT1 "/// This method is used by Godot to check if a signal exists before raising it.\n" << INDENT1 "/// Do not call or override this method.\n" << INDENT1 "/// \n" << INDENT1 "/// Name of the signal to check for.\n"; output << MEMBER_BEGIN "protected internal " << (is_derived_type ? "override" : "virtual") << " bool " CS_METHOD_HAS_GODOT_CLASS_SIGNAL "(in godot_string_name signal)\n" << INDENT1 "{\n"; for (const SignalInterface &isignal : itype.signals_) { // We check for native names (snake_case). If we detect one, we call HasGodotClassSignal // again, but this time with the respective proxy name (PascalCase). It's the job of // user derived classes to override the method and check for those. Our C# source // generators take care of generating those override methods. output << INDENT2 "if (signal == SignalName." << isignal.proxy_name << ")\n" INDENT2 "{\n" << INDENT3 "if (" CS_METHOD_HAS_GODOT_CLASS_SIGNAL "(" << CS_STATIC_FIELD_SIGNAL_PROXY_NAME_PREFIX << isignal.name << ".NativeValue.DangerousSelfRef))\n" INDENT3 "{\n" << INDENT4 "return true;\n" << INDENT3 "}\n" INDENT2 "}\n"; } if (is_derived_type) { output << INDENT2 "return base." CS_METHOD_HAS_GODOT_CLASS_SIGNAL "(signal);\n"; } else { output << INDENT2 "return false;\n"; } output << INDENT1 "}\n"; } //Generate StringName for all class members bool is_inherit = !itype.is_singleton && obj_types.has(itype.base_name); //PropertyName output << MEMBER_BEGIN "/// \n" << INDENT1 "/// Cached StringNames for the properties and fields contained in this class, for fast lookup.\n" << INDENT1 "/// \n"; if (is_inherit) { output << INDENT1 "public new class PropertyName : " << obj_types[itype.base_name].proxy_name << ".PropertyName"; } else { output << INDENT1 "public class PropertyName"; } output << "\n" << INDENT1 "{\n"; for (const PropertyInterface &iprop : itype.properties) { output << INDENT2 "/// \n" << INDENT2 "/// Cached name for the '" << iprop.cname << "' property.\n" << INDENT2 "/// \n" << INDENT2 "public static readonly StringName " << iprop.proxy_name << " = \"" << iprop.cname << "\";\n"; } output << INDENT1 "}\n"; //MethodName output << MEMBER_BEGIN "/// \n" << INDENT1 "/// Cached StringNames for the methods contained in this class, for fast lookup.\n" << INDENT1 "/// \n"; if (is_inherit) { output << INDENT1 "public new class MethodName : " << obj_types[itype.base_name].proxy_name << ".MethodName"; } else { output << INDENT1 "public class MethodName"; } output << "\n" << INDENT1 "{\n"; HashMap method_names; for (const MethodInterface &imethod : itype.methods) { if (method_names.has(imethod.proxy_name)) { ERR_FAIL_COND_V_MSG(method_names[imethod.proxy_name] != imethod.cname, ERR_BUG, "Method name '" + imethod.proxy_name + "' already exists with a different value."); continue; } method_names[imethod.proxy_name] = imethod.cname; output << INDENT2 "/// \n" << INDENT2 "/// Cached name for the '" << imethod.cname << "' method.\n" << INDENT2 "/// \n" << INDENT2 "public static readonly StringName " << imethod.proxy_name << " = \"" << imethod.cname << "\";\n"; } output << INDENT1 "}\n"; //SignalName output << MEMBER_BEGIN "/// \n" << INDENT1 "/// Cached StringNames for the signals contained in this class, for fast lookup.\n" << INDENT1 "/// \n"; if (is_inherit) { output << INDENT1 "public new class SignalName : " << obj_types[itype.base_name].proxy_name << ".SignalName"; } else { output << INDENT1 "public class SignalName"; } output << "\n" << INDENT1 "{\n"; for (const SignalInterface &isignal : itype.signals_) { output << INDENT2 "/// \n" << INDENT2 "/// Cached name for the '" << isignal.cname << "' signal.\n" << INDENT2 "/// \n" << INDENT2 "public static readonly StringName " << isignal.proxy_name << " = \"" << isignal.cname << "\";\n"; } output << INDENT1 "}\n"; output.append(CLOSE_BLOCK /* class */); return _save_file(p_output_file, output); } Error BindingsGenerator::_generate_cs_property(const BindingsGenerator::TypeInterface &p_itype, const PropertyInterface &p_iprop, StringBuilder &p_output) { const MethodInterface *setter = p_itype.find_method_by_name(p_iprop.setter); // Search it in base types too const TypeInterface *current_type = &p_itype; while (!setter && current_type->base_name != StringName()) { HashMap::Iterator base_match = obj_types.find(current_type->base_name); ERR_FAIL_COND_V_MSG(!base_match, ERR_BUG, "Type not found '" + current_type->base_name + "'. Inherited by '" + current_type->name + "'."); current_type = &base_match->value; setter = current_type->find_method_by_name(p_iprop.setter); } const MethodInterface *getter = p_itype.find_method_by_name(p_iprop.getter); // Search it in base types too current_type = &p_itype; while (!getter && current_type->base_name != StringName()) { HashMap::Iterator base_match = obj_types.find(current_type->base_name); ERR_FAIL_COND_V_MSG(!base_match, ERR_BUG, "Type not found '" + current_type->base_name + "'. Inherited by '" + current_type->name + "'."); current_type = &base_match->value; getter = current_type->find_method_by_name(p_iprop.getter); } ERR_FAIL_COND_V(!setter && !getter, ERR_BUG); if (setter) { int setter_argc = p_iprop.index != -1 ? 2 : 1; ERR_FAIL_COND_V(setter->arguments.size() != setter_argc, ERR_BUG); } if (getter) { int getter_argc = p_iprop.index != -1 ? 1 : 0; ERR_FAIL_COND_V(getter->arguments.size() != getter_argc, ERR_BUG); } if (getter && setter) { const ArgumentInterface &setter_first_arg = setter->arguments.back()->get(); if (getter->return_type.cname != setter_first_arg.type.cname) { // Special case for Node::set_name bool whitelisted = getter->return_type.cname == name_cache.type_StringName && setter_first_arg.type.cname == name_cache.type_String; ERR_FAIL_COND_V_MSG(!whitelisted, ERR_BUG, "Return type from getter doesn't match first argument of setter for property: '" + p_itype.name + "." + String(p_iprop.cname) + "'."); } } const TypeReference &proptype_name = getter ? getter->return_type : setter->arguments.back()->get().type; const TypeInterface *prop_itype = _get_type_or_singleton_or_null(proptype_name); ERR_FAIL_NULL_V(prop_itype, ERR_BUG); // Property type not found ERR_FAIL_COND_V_MSG(prop_itype->is_singleton, ERR_BUG, "Property type is a singleton: '" + p_itype.name + "." + String(p_iprop.cname) + "'."); if (p_itype.api_type == ClassDB::API_CORE) { ERR_FAIL_COND_V_MSG(prop_itype->api_type == ClassDB::API_EDITOR, ERR_BUG, "Property '" + p_itype.name + "." + String(p_iprop.cname) + "' has type '" + prop_itype->name + "' from the editor API. Core API cannot have dependencies on the editor API."); } if (p_iprop.prop_doc && p_iprop.prop_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(p_iprop.prop_doc->description), &p_itype); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { p_output.append(MEMBER_BEGIN "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { p_output.append(INDENT1 "/// "); p_output.append(summary_lines[i]); p_output.append("\n"); } p_output.append(INDENT1 "/// "); } if (p_iprop.prop_doc->is_deprecated) { p_output.append(MEMBER_BEGIN "[Obsolete(\"This property is deprecated.\")]"); } } p_output.append(MEMBER_BEGIN "public "); if (p_itype.is_singleton) { p_output.append("static "); } String prop_cs_type = prop_itype->cs_type + _get_generic_type_parameters(*prop_itype, proptype_name.generic_type_parameters); p_output.append(prop_cs_type); p_output.append(" "); p_output.append(p_iprop.proxy_name); p_output.append("\n" OPEN_BLOCK_L1); if (getter) { p_output.append(INDENT2 "get\n" OPEN_BLOCK_L2 INDENT3); p_output.append("return "); p_output.append(getter->proxy_name + "("); if (p_iprop.index != -1) { const ArgumentInterface &idx_arg = getter->arguments.front()->get(); if (idx_arg.type.cname != name_cache.type_int) { // Assume the index parameter is an enum const TypeInterface *idx_arg_type = _get_type_or_null(idx_arg.type); CRASH_COND(idx_arg_type == nullptr); p_output.append("(" + idx_arg_type->proxy_name + ")(" + itos(p_iprop.index) + ")"); } else { p_output.append(itos(p_iprop.index)); } } p_output.append(");\n" CLOSE_BLOCK_L2); } if (setter) { p_output.append(INDENT2 "set\n" OPEN_BLOCK_L2 INDENT3); p_output.append(setter->proxy_name + "("); if (p_iprop.index != -1) { const ArgumentInterface &idx_arg = setter->arguments.front()->get(); if (idx_arg.type.cname != name_cache.type_int) { // Assume the index parameter is an enum const TypeInterface *idx_arg_type = _get_type_or_null(idx_arg.type); CRASH_COND(idx_arg_type == nullptr); p_output.append("(" + idx_arg_type->proxy_name + ")(" + itos(p_iprop.index) + "), "); } else { p_output.append(itos(p_iprop.index) + ", "); } } p_output.append("value);\n" CLOSE_BLOCK_L2); } p_output.append(CLOSE_BLOCK_L1); return OK; } Error BindingsGenerator::_generate_cs_method(const BindingsGenerator::TypeInterface &p_itype, const BindingsGenerator::MethodInterface &p_imethod, int &p_method_bind_count, StringBuilder &p_output) { const TypeInterface *return_type = _get_type_or_singleton_or_null(p_imethod.return_type); ERR_FAIL_NULL_V(return_type, ERR_BUG); // Return type not found ERR_FAIL_COND_V_MSG(return_type->is_singleton, ERR_BUG, "Method return type is a singleton: '" + p_itype.name + "." + p_imethod.name + "'."); if (p_itype.api_type == ClassDB::API_CORE) { ERR_FAIL_COND_V_MSG(return_type->api_type == ClassDB::API_EDITOR, ERR_BUG, "Method '" + p_itype.name + "." + p_imethod.name + "' has return type '" + return_type->name + "' from the editor API. Core API cannot have dependencies on the editor API."); } String method_bind_field = CS_STATIC_FIELD_METHOD_BIND_PREFIX + itos(p_method_bind_count); String arguments_sig; StringBuilder cs_in_statements; bool cs_in_expr_is_unsafe = false; String icall_params = method_bind_field; if (!p_imethod.is_static) { String self_reference = "this"; if (p_itype.is_singleton) { self_reference = CS_PROPERTY_SINGLETON; } if (p_itype.cs_in.size()) { cs_in_statements << sformat(p_itype.cs_in, p_itype.c_type, self_reference, String(), String(), String(), INDENT2); } icall_params += ", " + sformat(p_itype.cs_in_expr, self_reference); } StringBuilder default_args_doc; // Retrieve information from the arguments const ArgumentInterface &first = p_imethod.arguments.front()->get(); for (const ArgumentInterface &iarg : p_imethod.arguments) { const TypeInterface *arg_type = _get_type_or_singleton_or_null(iarg.type); ERR_FAIL_NULL_V(arg_type, ERR_BUG); // Argument type not found ERR_FAIL_COND_V_MSG(arg_type->is_singleton, ERR_BUG, "Argument type is a singleton: '" + iarg.name + "' of method '" + p_itype.name + "." + p_imethod.name + "'."); if (p_itype.api_type == ClassDB::API_CORE) { ERR_FAIL_COND_V_MSG(arg_type->api_type == ClassDB::API_EDITOR, ERR_BUG, "Argument '" + iarg.name + "' of method '" + p_itype.name + "." + p_imethod.name + "' has type '" + arg_type->name + "' from the editor API. Core API cannot have dependencies on the editor API."); } if (iarg.default_argument.size()) { CRASH_COND_MSG(!_arg_default_value_is_assignable_to_type(iarg.def_param_value, *arg_type), "Invalid default value for parameter '" + iarg.name + "' of method '" + p_itype.name + "." + p_imethod.name + "'."); } String arg_cs_type = arg_type->cs_type + _get_generic_type_parameters(*arg_type, iarg.type.generic_type_parameters); // Add the current arguments to the signature // If the argument has a default value which is not a constant, we will make it Nullable { if (&iarg != &first) { arguments_sig += ", "; } if (iarg.def_param_mode == ArgumentInterface::NULLABLE_VAL) { arguments_sig += "Nullable<"; } arguments_sig += arg_cs_type; if (iarg.def_param_mode == ArgumentInterface::NULLABLE_VAL) { arguments_sig += "> "; } else { arguments_sig += " "; } arguments_sig += iarg.name; if (!p_imethod.is_compat && iarg.default_argument.size()) { if (iarg.def_param_mode != ArgumentInterface::CONSTANT) { arguments_sig += " = null"; } else { arguments_sig += " = " + sformat(iarg.default_argument, arg_type->cs_type); } } } icall_params += ", "; if (iarg.default_argument.size() && iarg.def_param_mode != ArgumentInterface::CONSTANT) { // The default value of an argument must be constant. Otherwise we make it Nullable and do the following: // Type arg_in = arg.HasValue ? arg.Value : ; String arg_or_defval_local = iarg.name; arg_or_defval_local += "OrDefVal"; cs_in_statements << INDENT2 << arg_cs_type << " " << arg_or_defval_local << " = " << iarg.name; if (iarg.def_param_mode == ArgumentInterface::NULLABLE_VAL) { cs_in_statements << ".HasValue ? "; } else { cs_in_statements << " != null ? "; } cs_in_statements << iarg.name; if (iarg.def_param_mode == ArgumentInterface::NULLABLE_VAL) { cs_in_statements << ".Value : "; } else { cs_in_statements << " : "; } String cs_type = arg_cs_type; if (cs_type.ends_with("[]")) { cs_type = cs_type.substr(0, cs_type.length() - 2); } String def_arg = sformat(iarg.default_argument, cs_type); cs_in_statements << def_arg << ";\n"; if (arg_type->cs_in.size()) { cs_in_statements << sformat(arg_type->cs_in, arg_type->c_type, arg_or_defval_local, String(), String(), String(), INDENT2); } if (arg_type->cs_in_expr.is_empty()) { icall_params += arg_or_defval_local; } else { icall_params += sformat(arg_type->cs_in_expr, arg_or_defval_local, arg_type->c_type); } // Apparently the name attribute must not include the @ String param_tag_name = iarg.name.begins_with("@") ? iarg.name.substr(1, iarg.name.length()) : iarg.name; // Escape < and > in the attribute default value String param_def_arg = def_arg.replacen("<", "<").replacen(">", ">"); default_args_doc.append(MEMBER_BEGIN "/// If the parameter is null, then the default value is " + param_def_arg + "."); } else { if (arg_type->cs_in.size()) { cs_in_statements << sformat(arg_type->cs_in, arg_type->c_type, iarg.name, String(), String(), String(), INDENT2); } icall_params += arg_type->cs_in_expr.is_empty() ? iarg.name : sformat(arg_type->cs_in_expr, iarg.name, arg_type->c_type); } cs_in_expr_is_unsafe |= arg_type->cs_in_expr_is_unsafe; } // Collect caller name for MethodBind if (p_imethod.is_vararg) { icall_params += ", (godot_string_name)MethodName." + p_imethod.proxy_name + ".NativeValue"; } // Generate method { if (!p_imethod.is_virtual && !p_imethod.requires_object_call) { p_output << MEMBER_BEGIN "[DebuggerBrowsable(DebuggerBrowsableState.Never)]\n" << INDENT1 "private static readonly IntPtr " << method_bind_field << " = "; if (p_itype.is_singleton) { // Singletons are static classes. They don't derive GodotObject, // so we need to specify the type to call the static method. p_output << "GodotObject."; } p_output << ICALL_CLASSDB_GET_METHOD_WITH_COMPATIBILITY "(" BINDINGS_NATIVE_NAME_FIELD ", MethodName." << p_imethod.proxy_name << ", " << itos(p_imethod.hash) << "ul" << ");\n"; } if (p_imethod.method_doc && p_imethod.method_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(p_imethod.method_doc->description), &p_itype); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { p_output.append(MEMBER_BEGIN "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { p_output.append(INDENT1 "/// "); p_output.append(summary_lines[i]); p_output.append("\n"); } p_output.append(INDENT1 "/// "); } if (p_imethod.method_doc->is_deprecated) { p_output.append(MEMBER_BEGIN "[Obsolete(\"This method is deprecated.\")]"); } } if (default_args_doc.get_string_length()) { p_output.append(default_args_doc.as_string()); } if (p_imethod.is_deprecated) { if (p_imethod.deprecation_message.is_empty()) { WARN_PRINT("An empty deprecation message is discouraged. Method: '" + p_imethod.proxy_name + "'."); } p_output.append(MEMBER_BEGIN "[Obsolete(\""); p_output.append(p_imethod.deprecation_message); p_output.append("\")]"); } if (p_imethod.is_compat) { p_output.append(MEMBER_BEGIN "[EditorBrowsable(EditorBrowsableState.Never)]"); } p_output.append(MEMBER_BEGIN); p_output.append(p_imethod.is_internal ? "internal " : "public "); if (p_itype.is_singleton || p_imethod.is_static) { p_output.append("static "); } else if (p_imethod.is_virtual) { p_output.append("virtual "); } if (cs_in_expr_is_unsafe) { p_output.append("unsafe "); } String return_cs_type = return_type->cs_type + _get_generic_type_parameters(*return_type, p_imethod.return_type.generic_type_parameters); p_output.append(return_cs_type + " "); p_output.append(p_imethod.proxy_name + "("); p_output.append(arguments_sig + ")\n" OPEN_BLOCK_L1); if (p_imethod.is_virtual) { // Godot virtual method must be overridden, therefore we return a default value by default. if (return_type->cname == name_cache.type_void) { p_output.append(CLOSE_BLOCK_L1); } else { p_output.append(INDENT2 "return default;\n" CLOSE_BLOCK_L1); } return OK; // Won't increment method bind count } if (p_imethod.requires_object_call) { // Fallback to Godot's object.Call(string, params) p_output.append(INDENT2 CS_METHOD_CALL "(\""); p_output.append(p_imethod.name); p_output.append("\""); for (const ArgumentInterface &iarg : p_imethod.arguments) { p_output.append(", "); p_output.append(iarg.name); } p_output.append(");\n" CLOSE_BLOCK_L1); return OK; // Won't increment method bind count } HashMap::ConstIterator match = method_icalls_map.find(&p_imethod); ERR_FAIL_NULL_V(match, ERR_BUG); const InternalCall *im_icall = match->value; String im_call = im_icall->editor_only ? BINDINGS_CLASS_NATIVECALLS_EDITOR : BINDINGS_CLASS_NATIVECALLS; im_call += "."; im_call += im_icall->name; if (p_imethod.arguments.size() && cs_in_statements.get_string_length() > 0) { p_output.append(cs_in_statements.as_string()); } if (return_type->cname == name_cache.type_void) { p_output << INDENT2 << im_call << "(" << icall_params << ");\n"; } else if (return_type->cs_out.is_empty()) { p_output << INDENT2 "return " << im_call << "(" << icall_params << ");\n"; } else { p_output.append(sformat(return_type->cs_out, im_call, icall_params, return_cs_type, return_type->c_type_out, String(), INDENT2)); p_output.append("\n"); } p_output.append(CLOSE_BLOCK_L1); } p_method_bind_count++; return OK; } Error BindingsGenerator::_generate_cs_signal(const BindingsGenerator::TypeInterface &p_itype, const BindingsGenerator::SignalInterface &p_isignal, StringBuilder &p_output) { String arguments_sig; String delegate_type_params; if (!p_isignal.arguments.is_empty()) { delegate_type_params += "<"; } // Retrieve information from the arguments const ArgumentInterface &first = p_isignal.arguments.front()->get(); for (const ArgumentInterface &iarg : p_isignal.arguments) { const TypeInterface *arg_type = _get_type_or_singleton_or_null(iarg.type); ERR_FAIL_NULL_V(arg_type, ERR_BUG); // Argument type not found ERR_FAIL_COND_V_MSG(arg_type->is_singleton, ERR_BUG, "Argument type is a singleton: '" + iarg.name + "' of signal '" + p_itype.name + "." + p_isignal.name + "'."); if (p_itype.api_type == ClassDB::API_CORE) { ERR_FAIL_COND_V_MSG(arg_type->api_type == ClassDB::API_EDITOR, ERR_BUG, "Argument '" + iarg.name + "' of signal '" + p_itype.name + "." + p_isignal.name + "' has type '" + arg_type->name + "' from the editor API. Core API cannot have dependencies on the editor API."); } // Add the current arguments to the signature if (&iarg != &first) { arguments_sig += ", "; delegate_type_params += ", "; } arguments_sig += arg_type->cs_type; arguments_sig += " "; arguments_sig += iarg.name; delegate_type_params += arg_type->cs_type; } if (!p_isignal.arguments.is_empty()) { delegate_type_params += ">"; } // Generate signal { bool is_parameterless = p_isignal.arguments.size() == 0; // Delegate name is [SignalName]EventHandler String delegate_name = is_parameterless ? "Action" : p_isignal.proxy_name + "EventHandler"; if (!is_parameterless) { p_output.append(MEMBER_BEGIN "/// \n"); p_output.append(INDENT1 "/// "); p_output.append("Represents the method that handles the "); p_output.append(""); p_output.append(" event of a "); p_output.append(""); p_output.append(" class.\n"); p_output.append(INDENT1 "/// "); if (p_isignal.is_deprecated) { if (p_isignal.deprecation_message.is_empty()) { WARN_PRINT("An empty deprecation message is discouraged. Signal: '" + p_isignal.proxy_name + "'."); } p_output.append(MEMBER_BEGIN "[Obsolete(\""); p_output.append(p_isignal.deprecation_message); p_output.append("\")]"); } // Generate delegate p_output.append(MEMBER_BEGIN "public delegate void "); p_output.append(delegate_name); p_output.append("("); p_output.append(arguments_sig); p_output.append(");\n"); // Generate Callable trampoline for the delegate p_output << MEMBER_BEGIN "private static void " << p_isignal.proxy_name << "Trampoline" << "(object delegateObj, NativeVariantPtrArgs args, out godot_variant ret)\n" << INDENT1 "{\n" << INDENT2 "Callable.ThrowIfArgCountMismatch(args, " << itos(p_isignal.arguments.size()) << ");\n" << INDENT2 "((" << delegate_name << ")delegateObj)("; int idx = 0; for (const ArgumentInterface &iarg : p_isignal.arguments) { const TypeInterface *arg_type = _get_type_or_null(iarg.type); ERR_FAIL_NULL_V(arg_type, ERR_BUG); // Argument type not found if (idx != 0) { p_output << ","; } p_output << sformat(arg_type->cs_variant_to_managed, "args[" + itos(idx) + "]", arg_type->cs_type, arg_type->name); idx++; } p_output << ");\n" << INDENT2 "ret = default;\n" << INDENT1 "}\n"; } if (p_isignal.method_doc && p_isignal.method_doc->description.size()) { String xml_summary = bbcode_to_xml(fix_doc_description(p_isignal.method_doc->description), &p_itype, true); Vector summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector(); if (summary_lines.size()) { p_output.append(MEMBER_BEGIN "/// \n"); for (int i = 0; i < summary_lines.size(); i++) { p_output.append(INDENT1 "/// "); p_output.append(summary_lines[i]); p_output.append("\n"); } p_output.append(INDENT1 "/// "); } if (p_isignal.method_doc->is_deprecated) { p_output.append(MEMBER_BEGIN "[Obsolete(\"This signal is deprecated.\")]"); } } if (p_isignal.is_deprecated) { p_output.append(MEMBER_BEGIN "[Obsolete(\""); p_output.append(p_isignal.deprecation_message); p_output.append("\")]"); } // TODO: // Could we assume the StringName instance of signal name will never be freed (it's stored in ClassDB) before the managed world is unloaded? // If so, we could store the pointer we get from `data_unique_pointer()` instead of allocating StringName here. // Generate event p_output.append(MEMBER_BEGIN "public "); if (p_itype.is_singleton) { p_output.append("static "); } if (!is_parameterless) { // `unsafe` is needed for taking the trampoline's function pointer p_output << "unsafe "; } p_output.append("event "); p_output.append(delegate_name); p_output.append(" "); p_output.append(p_isignal.proxy_name); p_output.append("\n" OPEN_BLOCK_L1 INDENT2); if (p_itype.is_singleton) { p_output.append("add => " CS_PROPERTY_SINGLETON ".Connect(SignalName."); } else { p_output.append("add => Connect(SignalName."); } if (is_parameterless) { // Delegate type is Action. No need for custom trampoline. p_output << p_isignal.proxy_name << ", Callable.From(value));\n"; } else { p_output << p_isignal.proxy_name << ", Callable.CreateWithUnsafeTrampoline(value, &" << p_isignal.proxy_name << "Trampoline));\n"; } if (p_itype.is_singleton) { p_output.append(INDENT2 "remove => " CS_PROPERTY_SINGLETON ".Disconnect(SignalName."); } else { p_output.append(INDENT2 "remove => Disconnect(SignalName."); } if (is_parameterless) { // Delegate type is Action. No need for custom trampoline. p_output << p_isignal.proxy_name << ", Callable.From(value));\n"; } else { p_output << p_isignal.proxy_name << ", Callable.CreateWithUnsafeTrampoline(value, &" << p_isignal.proxy_name << "Trampoline));\n"; } p_output.append(CLOSE_BLOCK_L1); } return OK; } Error BindingsGenerator::_generate_cs_native_calls(const InternalCall &p_icall, StringBuilder &r_output) { bool ret_void = p_icall.return_type.cname == name_cache.type_void; const TypeInterface *return_type = _get_type_or_null(p_icall.return_type); ERR_FAIL_NULL_V(return_type, ERR_BUG); // Return type not found StringBuilder c_func_sig; StringBuilder c_in_statements; StringBuilder c_args_var_content; c_func_sig << "IntPtr " CS_PARAM_METHODBIND; if (!p_icall.is_static) { c_func_sig += ", IntPtr " CS_PARAM_INSTANCE; } // Get arguments information int i = 0; for (const TypeReference &arg_type_ref : p_icall.argument_types) { const TypeInterface *arg_type = _get_type_or_null(arg_type_ref); ERR_FAIL_NULL_V(arg_type, ERR_BUG); // Return type not found String c_param_name = "arg" + itos(i + 1); if (p_icall.is_vararg) { if (i < p_icall.get_arguments_count() - 1) { String c_in_vararg = arg_type->c_in_vararg; if (arg_type->is_object_type) { c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromGodotObjectPtr(%1);\n"; } ERR_FAIL_COND_V_MSG(c_in_vararg.is_empty(), ERR_BUG, "VarArg support not implemented for parameter type: " + arg_type->name); c_in_statements << sformat(c_in_vararg, return_type->c_type, c_param_name, String(), String(), String(), INDENT3) << INDENT3 C_LOCAL_PTRCALL_ARGS "[" << itos(i) << "] = new IntPtr(&" << c_param_name << "_in);\n"; } } else { if (i > 0) { c_args_var_content << ", "; } if (arg_type->c_in.size()) { c_in_statements << sformat(arg_type->c_in, arg_type->c_type, c_param_name, String(), String(), String(), INDENT2); } c_args_var_content << sformat(arg_type->c_arg_in, c_param_name); } c_func_sig << ", " << arg_type->c_type_in << " " << c_param_name; i++; } // Collect caller name for MethodBind if (p_icall.is_vararg) { c_func_sig << ", godot_string_name caller"; } String icall_method = p_icall.name; // Generate icall function r_output << MEMBER_BEGIN "internal static unsafe " << (ret_void ? "void" : return_type->c_type_out) << " " << icall_method << "(" << c_func_sig.as_string() << ")\n" OPEN_BLOCK_L1; if (!p_icall.is_static) { r_output << INDENT2 "ExceptionUtils.ThrowIfNullPtr(" CS_PARAM_INSTANCE ");\n"; } if (!ret_void && (!p_icall.is_vararg || return_type->cname != name_cache.type_Variant)) { String ptrcall_return_type; String initialization; if (return_type->is_object_type) { ptrcall_return_type = return_type->is_ref_counted ? "godot_ref" : return_type->c_type; initialization = " = default"; } else { ptrcall_return_type = return_type->c_type; } r_output << INDENT2; if (return_type->is_ref_counted || return_type->c_type_is_disposable_struct) { r_output << "using "; if (initialization.is_empty()) { initialization = " = default"; } } else if (return_type->c_ret_needs_default_initialization) { initialization = " = default"; } r_output << ptrcall_return_type << " " C_LOCAL_RET << initialization << ";\n"; } String argc_str = itos(p_icall.get_arguments_count()); auto generate_call_and_return_stmts = [&](const char *base_indent) { if (p_icall.is_vararg) { // MethodBind Call r_output << base_indent; // VarArg methods always return Variant, but there are some cases in which MethodInfo provides // a specific return type. We trust this information is valid. We need a temporary local to keep // the Variant alive until the method returns. Otherwise, if the returned Variant holds a RefPtr, // it could be deleted too early. This is the case with GDScript.new() which returns OBJECT. // Alternatively, we could just return Variant, but that would result in a worse API. if (!ret_void) { if (return_type->cname != name_cache.type_Variant) { // Usually the return value takes ownership, but in this case the variant is only used // for conversion to another return type. As such, the local variable takes ownership. r_output << "using godot_variant " << C_LOCAL_VARARG_RET " = "; } else { // Variant's [c_out] takes ownership of the variant value r_output << "godot_variant " << C_LOCAL_RET " = "; } } r_output << C_CLASS_NATIVE_FUNCS ".godotsharp_method_bind_call(" << CS_PARAM_METHODBIND ", " << (p_icall.is_static ? "IntPtr.Zero" : CS_PARAM_INSTANCE) << ", " << (p_icall.get_arguments_count() ? "(godot_variant**)" C_LOCAL_PTRCALL_ARGS : "null") << ", total_length, out godot_variant_call_error vcall_error);\n"; r_output << base_indent << "ExceptionUtils.DebugCheckCallError(caller" << ", " << (p_icall.is_static ? "IntPtr.Zero" : CS_PARAM_INSTANCE) << ", " << (p_icall.get_arguments_count() ? "(godot_variant**)" C_LOCAL_PTRCALL_ARGS : "null") << ", total_length, vcall_error);\n"; if (!ret_void) { if (return_type->cname != name_cache.type_Variant) { if (return_type->cname == name_cache.enum_Error) { r_output << base_indent << C_LOCAL_RET " = VariantUtils.ConvertToInt64(" C_LOCAL_VARARG_RET ");\n"; } else { // TODO: Use something similar to c_in_vararg (see usage above, with error if not implemented) CRASH_NOW_MSG("Custom VarArg return type not implemented: " + return_type->name); r_output << base_indent << C_LOCAL_RET " = " C_LOCAL_VARARG_RET ";\n"; } } } } else { // MethodBind PtrCall r_output << base_indent << C_CLASS_NATIVE_FUNCS ".godotsharp_method_bind_ptrcall(" << CS_PARAM_METHODBIND ", " << (p_icall.is_static ? "IntPtr.Zero" : CS_PARAM_INSTANCE) << ", " << (p_icall.get_arguments_count() ? C_LOCAL_PTRCALL_ARGS : "null") << ", " << (!ret_void ? "&" C_LOCAL_RET ");\n" : "null);\n"); } // Return statement if (!ret_void) { if (return_type->c_out.is_empty()) { r_output << base_indent << "return " C_LOCAL_RET ";\n"; } else { r_output << sformat(return_type->c_out, return_type->c_type_out, C_LOCAL_RET, return_type->name, String(), String(), base_indent); } } }; if (p_icall.get_arguments_count()) { if (p_icall.is_vararg) { String vararg_arg = "arg" + argc_str; String real_argc_str = itos(p_icall.get_arguments_count() - 1); // Arguments count without vararg p_icall.get_arguments_count(); r_output << INDENT2 "int vararg_length = " << vararg_arg << ".Length;\n" << INDENT2 "int total_length = " << real_argc_str << " + vararg_length;\n"; r_output << INDENT2 "Span varargs_span = vararg_length <= VarArgsSpanThreshold ?\n" << INDENT3 "stackalloc godot_variant.movable[VarArgsSpanThreshold] :\n" << INDENT3 "new godot_variant.movable[vararg_length];\n"; r_output << INDENT2 "Span " C_LOCAL_PTRCALL_ARGS "_span = total_length <= VarArgsSpanThreshold ?\n" << INDENT3 "stackalloc IntPtr[VarArgsSpanThreshold] :\n" << INDENT3 "new IntPtr[total_length];\n"; r_output << INDENT2 "fixed (godot_variant.movable* varargs = &MemoryMarshal.GetReference(varargs_span))\n" << INDENT2 "fixed (IntPtr* " C_LOCAL_PTRCALL_ARGS " = " "&MemoryMarshal.GetReference(" C_LOCAL_PTRCALL_ARGS "_span))\n" << OPEN_BLOCK_L2; r_output << c_in_statements.as_string(); r_output << INDENT3 "for (int i = 0; i < vararg_length; i++)\n" OPEN_BLOCK_L3 << INDENT4 "varargs[i] = " << vararg_arg << "[i].NativeVar;\n" << INDENT4 C_LOCAL_PTRCALL_ARGS "[" << real_argc_str << " + i] = new IntPtr(&varargs[i]);\n" << CLOSE_BLOCK_L3; generate_call_and_return_stmts(INDENT3); r_output << CLOSE_BLOCK_L2; } else { r_output << c_in_statements.as_string(); r_output << INDENT2 "void** " C_LOCAL_PTRCALL_ARGS " = stackalloc void*[" << argc_str << "] { " << c_args_var_content.as_string() << " };\n"; generate_call_and_return_stmts(INDENT2); } } else { generate_call_and_return_stmts(INDENT2); } r_output << CLOSE_BLOCK_L1; return OK; } Error BindingsGenerator::_save_file(const String &p_path, const StringBuilder &p_content) { Ref file = FileAccess::open(p_path, FileAccess::WRITE); ERR_FAIL_COND_V_MSG(file.is_null(), ERR_FILE_CANT_WRITE, "Cannot open file: '" + p_path + "'."); file->store_string(p_content.as_string()); return OK; } const BindingsGenerator::TypeInterface *BindingsGenerator::_get_type_or_null(const TypeReference &p_typeref) { HashMap::ConstIterator builtin_type_match = builtin_types.find(p_typeref.cname); if (builtin_type_match) { return &builtin_type_match->value; } HashMap::ConstIterator obj_type_match = obj_types.find(p_typeref.cname); if (obj_type_match) { return &obj_type_match->value; } if (p_typeref.is_enum) { HashMap::ConstIterator enum_match = enum_types.find(p_typeref.cname); if (enum_match) { return &enum_match->value; } // Enum not found. Most likely because none of its constants were bound, so it's empty. That's fine. Use int instead. HashMap::ConstIterator int_match = builtin_types.find(name_cache.type_int); ERR_FAIL_NULL_V(int_match, nullptr); return &int_match->value; } return nullptr; } const BindingsGenerator::TypeInterface *BindingsGenerator::_get_type_or_singleton_or_null(const TypeReference &p_typeref) { const TypeInterface *itype = _get_type_or_null(p_typeref); if (itype == nullptr) { return nullptr; } if (itype->is_singleton) { StringName instance_type_name = itype->name + CS_SINGLETON_INSTANCE_SUFFIX; itype = &obj_types.find(instance_type_name)->value; } return itype; } const String BindingsGenerator::_get_generic_type_parameters(const TypeInterface &p_itype, const List &p_generic_type_parameters) { if (p_generic_type_parameters.is_empty()) { return ""; } ERR_FAIL_COND_V_MSG(p_itype.type_parameter_count != p_generic_type_parameters.size(), "", "Generic type parameter count mismatch for type '" + p_itype.name + "'." + " Found " + itos(p_generic_type_parameters.size()) + ", but requires " + itos(p_itype.type_parameter_count) + "."); int i = 0; String params = "<"; for (const TypeReference ¶m_type : p_generic_type_parameters) { const TypeInterface *param_itype = _get_type_or_singleton_or_null(param_type); ERR_FAIL_NULL_V(param_itype, ""); // Parameter type not found ERR_FAIL_COND_V_MSG(param_itype->is_singleton, "", "Generic type parameter is a singleton: '" + param_itype->name + "'."); if (p_itype.api_type == ClassDB::API_CORE) { ERR_FAIL_COND_V_MSG(param_itype->api_type == ClassDB::API_EDITOR, "", "Generic type parameter '" + param_itype->name + "' has type from the editor API." + " Core API cannot have dependencies on the editor API."); } params += param_itype->cs_type; if (i < p_generic_type_parameters.size() - 1) { params += ", "; } i++; } params += ">"; return params; } StringName BindingsGenerator::_get_type_name_from_meta(Variant::Type p_type, GodotTypeInfo::Metadata p_meta) { if (p_type == Variant::INT) { return _get_int_type_name_from_meta(p_meta); } else if (p_type == Variant::FLOAT) { return _get_float_type_name_from_meta(p_meta); } else { return Variant::get_type_name(p_type); } } StringName BindingsGenerator::_get_int_type_name_from_meta(GodotTypeInfo::Metadata p_meta) { switch (p_meta) { case GodotTypeInfo::METADATA_INT_IS_INT8: return "sbyte"; break; case GodotTypeInfo::METADATA_INT_IS_INT16: return "short"; break; case GodotTypeInfo::METADATA_INT_IS_INT32: return "int"; break; case GodotTypeInfo::METADATA_INT_IS_INT64: return "long"; break; case GodotTypeInfo::METADATA_INT_IS_UINT8: return "byte"; break; case GodotTypeInfo::METADATA_INT_IS_UINT16: return "ushort"; break; case GodotTypeInfo::METADATA_INT_IS_UINT32: return "uint"; break; case GodotTypeInfo::METADATA_INT_IS_UINT64: return "ulong"; break; default: // Assume INT64 return "long"; } } StringName BindingsGenerator::_get_float_type_name_from_meta(GodotTypeInfo::Metadata p_meta) { switch (p_meta) { case GodotTypeInfo::METADATA_REAL_IS_FLOAT: return "float"; break; case GodotTypeInfo::METADATA_REAL_IS_DOUBLE: return "double"; break; default: // Assume FLOAT64 return "double"; } } bool BindingsGenerator::_arg_default_value_is_assignable_to_type(const Variant &p_val, const TypeInterface &p_arg_type) { if (p_arg_type.name == name_cache.type_Variant) { // Variant can take anything return true; } switch (p_val.get_type()) { case Variant::NIL: return p_arg_type.is_object_type || name_cache.is_nullable_type(p_arg_type.name); case Variant::BOOL: return p_arg_type.name == name_cache.type_bool; case Variant::INT: return p_arg_type.name == name_cache.type_sbyte || p_arg_type.name == name_cache.type_short || p_arg_type.name == name_cache.type_int || p_arg_type.name == name_cache.type_byte || p_arg_type.name == name_cache.type_ushort || p_arg_type.name == name_cache.type_uint || p_arg_type.name == name_cache.type_long || p_arg_type.name == name_cache.type_ulong || p_arg_type.name == name_cache.type_float || p_arg_type.name == name_cache.type_double || p_arg_type.is_enum; case Variant::FLOAT: return p_arg_type.name == name_cache.type_float || p_arg_type.name == name_cache.type_double; case Variant::STRING: case Variant::STRING_NAME: return p_arg_type.name == name_cache.type_String || p_arg_type.name == name_cache.type_StringName || p_arg_type.name == name_cache.type_NodePath; case Variant::NODE_PATH: return p_arg_type.name == name_cache.type_NodePath; case Variant::TRANSFORM2D: case Variant::TRANSFORM3D: case Variant::BASIS: case Variant::QUATERNION: case Variant::PLANE: case Variant::AABB: case Variant::COLOR: case Variant::VECTOR2: case Variant::RECT2: case Variant::VECTOR3: case Variant::RID: case Variant::PACKED_BYTE_ARRAY: case Variant::PACKED_INT32_ARRAY: case Variant::PACKED_INT64_ARRAY: case Variant::PACKED_FLOAT32_ARRAY: case Variant::PACKED_FLOAT64_ARRAY: case Variant::PACKED_STRING_ARRAY: case Variant::PACKED_VECTOR2_ARRAY: case Variant::PACKED_VECTOR3_ARRAY: case Variant::PACKED_COLOR_ARRAY: case Variant::CALLABLE: case Variant::SIGNAL: return p_arg_type.name == Variant::get_type_name(p_val.get_type()); case Variant::ARRAY: return p_arg_type.name == Variant::get_type_name(p_val.get_type()) || p_arg_type.cname == name_cache.type_Array_generic; case Variant::DICTIONARY: return p_arg_type.name == Variant::get_type_name(p_val.get_type()) || p_arg_type.cname == name_cache.type_Dictionary_generic; case Variant::OBJECT: return p_arg_type.is_object_type; case Variant::VECTOR2I: return p_arg_type.name == name_cache.type_Vector2 || p_arg_type.name == Variant::get_type_name(p_val.get_type()); case Variant::RECT2I: return p_arg_type.name == name_cache.type_Rect2 || p_arg_type.name == Variant::get_type_name(p_val.get_type()); case Variant::VECTOR3I: return p_arg_type.name == name_cache.type_Vector3 || p_arg_type.name == Variant::get_type_name(p_val.get_type()); default: CRASH_NOW_MSG("Unexpected Variant type: " + itos(p_val.get_type())); break; } return false; } bool method_has_ptr_parameter(MethodInfo p_method_info) { if (p_method_info.return_val.type == Variant::INT && p_method_info.return_val.hint == PROPERTY_HINT_INT_IS_POINTER) { return true; } for (PropertyInfo arg : p_method_info.arguments) { if (arg.type == Variant::INT && arg.hint == PROPERTY_HINT_INT_IS_POINTER) { return true; } } return false; } struct SortMethodWithHashes { _FORCE_INLINE_ bool operator()(const Pair &p_a, const Pair &p_b) const { return p_a.first < p_b.first; } }; bool BindingsGenerator::_populate_object_type_interfaces() { obj_types.clear(); List class_list; ClassDB::get_class_list(&class_list); class_list.sort_custom(); while (class_list.size()) { StringName type_cname = class_list.front()->get(); ClassDB::APIType api_type = ClassDB::get_api_type(type_cname); if (api_type == ClassDB::API_NONE) { class_list.pop_front(); continue; } if (ignored_types.has(type_cname)) { _log("Ignoring type '%s' because it's in the list of ignored types\n", String(type_cname).utf8().get_data()); class_list.pop_front(); continue; } if (!ClassDB::is_class_exposed(type_cname)) { _log("Ignoring type '%s' because it's not exposed\n", String(type_cname).utf8().get_data()); class_list.pop_front(); continue; } if (!ClassDB::is_class_enabled(type_cname)) { _log("Ignoring type '%s' because it's not enabled\n", String(type_cname).utf8().get_data()); class_list.pop_front(); continue; } ClassDB::ClassInfo *class_info = ClassDB::classes.getptr(type_cname); TypeInterface itype = TypeInterface::create_object_type(type_cname, pascal_to_pascal_case(type_cname), api_type); itype.base_name = ClassDB::get_parent_class(type_cname); itype.is_singleton = Engine::get_singleton()->has_singleton(type_cname); itype.is_instantiable = class_info->creation_func && !itype.is_singleton; itype.is_ref_counted = ClassDB::is_parent_class(type_cname, name_cache.type_RefCounted); itype.memory_own = itype.is_ref_counted; if (itype.is_singleton && compat_singletons.has(itype.cname)) { itype.is_singleton = false; itype.is_compat_singleton = true; } itype.c_out = "%5return "; itype.c_out += C_METHOD_UNMANAGED_GET_MANAGED; itype.c_out += itype.is_ref_counted ? "(%1.Reference);\n" : "(%1);\n"; itype.cs_type = itype.proxy_name; itype.cs_in_expr = "GodotObject." CS_STATIC_METHOD_GETINSTANCE "(%0)"; itype.cs_out = "%5return (%2)%0(%1);"; itype.c_arg_in = "&%s"; itype.c_type = "IntPtr"; itype.c_type_in = itype.c_type; itype.c_type_out = "GodotObject"; // Populate properties List property_list; ClassDB::get_property_list(type_cname, &property_list, true); HashMap accessor_methods; for (const PropertyInfo &property : property_list) { if (property.usage & PROPERTY_USAGE_GROUP || property.usage & PROPERTY_USAGE_SUBGROUP || property.usage & PROPERTY_USAGE_CATEGORY || (property.type == Variant::NIL && property.usage & PROPERTY_USAGE_ARRAY)) { continue; } if (property.name.find("/") >= 0) { // Ignore properties with '/' (slash) in the name. These are only meant for use in the inspector. continue; } PropertyInterface iprop; iprop.cname = property.name; iprop.setter = ClassDB::get_property_setter(type_cname, iprop.cname); iprop.getter = ClassDB::get_property_getter(type_cname, iprop.cname); if (iprop.setter != StringName()) { accessor_methods[iprop.setter] = iprop.cname; } if (iprop.getter != StringName()) { accessor_methods[iprop.getter] = iprop.cname; } bool valid = false; iprop.index = ClassDB::get_property_index(type_cname, iprop.cname, &valid); ERR_FAIL_COND_V_MSG(!valid, false, "Invalid property: '" + itype.name + "." + String(iprop.cname) + "'."); iprop.proxy_name = escape_csharp_keyword(snake_to_pascal_case(iprop.cname)); // Prevent the property and its enclosing type from sharing the same name if (iprop.proxy_name == itype.proxy_name) { _log("Name of property '%s' is ambiguous with the name of its enclosing class '%s'. Renaming property to '%s_'\n", iprop.proxy_name.utf8().get_data(), itype.proxy_name.utf8().get_data(), iprop.proxy_name.utf8().get_data()); iprop.proxy_name += "_"; } iprop.prop_doc = nullptr; for (int i = 0; i < itype.class_doc->properties.size(); i++) { const DocData::PropertyDoc &prop_doc = itype.class_doc->properties[i]; if (prop_doc.name == iprop.cname) { iprop.prop_doc = &prop_doc; break; } } itype.properties.push_back(iprop); } // Populate methods List virtual_method_list; ClassDB::get_virtual_methods(type_cname, &virtual_method_list, true); List> method_list_with_hashes; ClassDB::get_method_list_with_compatibility(type_cname, &method_list_with_hashes, true); method_list_with_hashes.sort_custom_inplace(); List compat_methods; for (const Pair &E : method_list_with_hashes) { const MethodInfo &method_info = E.first; const uint32_t hash = E.second; int argc = method_info.arguments.size(); if (method_info.name.is_empty()) { continue; } String cname = method_info.name; if (blacklisted_methods.find(itype.cname) && blacklisted_methods[itype.cname].find(cname)) { continue; } if (method_has_ptr_parameter(method_info)) { // Pointers are not supported. itype.ignored_members.insert(method_info.name); continue; } MethodInterface imethod; imethod.name = method_info.name; imethod.cname = cname; imethod.hash = hash; if (method_info.flags & METHOD_FLAG_STATIC) { imethod.is_static = true; } if (method_info.flags & METHOD_FLAG_VIRTUAL) { imethod.is_virtual = true; itype.has_virtual_methods = true; } PropertyInfo return_info = method_info.return_val; MethodBind *m = nullptr; if (!imethod.is_virtual) { bool method_exists = false; m = ClassDB::get_method_with_compatibility(type_cname, method_info.name, hash, &method_exists, &imethod.is_compat); if (unlikely(!method_exists)) { ERR_FAIL_COND_V_MSG(!virtual_method_list.find(method_info), false, "Missing MethodBind for non-virtual method: '" + itype.name + "." + imethod.name + "'."); } } imethod.is_vararg = m && m->is_vararg(); if (!m && !imethod.is_virtual) { ERR_FAIL_COND_V_MSG(!virtual_method_list.find(method_info), false, "Missing MethodBind for non-virtual method: '" + itype.name + "." + imethod.name + "'."); // A virtual method without the virtual flag. This is a special case. // There is no method bind, so let's fallback to Godot's object.Call(string, params) imethod.requires_object_call = true; // The method Object.free is registered as a virtual method, but without the virtual flag. // This is because this method is not supposed to be overridden, but called. // We assume the return type is void. imethod.return_type.cname = name_cache.type_void; // Actually, more methods like this may be added in the future, which could return // something different. Let's put this check to notify us if that ever happens. if (itype.cname != name_cache.type_Object || imethod.name != "free") { WARN_PRINT("Notification: New unexpected virtual non-overridable method found." " We only expected Object.free, but found '" + itype.name + "." + imethod.name + "'."); } } else if (return_info.type == Variant::INT && return_info.usage & (PROPERTY_USAGE_CLASS_IS_ENUM | PROPERTY_USAGE_CLASS_IS_BITFIELD)) { imethod.return_type.cname = return_info.class_name; imethod.return_type.is_enum = true; } else if (return_info.class_name != StringName()) { imethod.return_type.cname = return_info.class_name; bool bad_reference_hint = !imethod.is_virtual && return_info.hint != PROPERTY_HINT_RESOURCE_TYPE && ClassDB::is_parent_class(return_info.class_name, name_cache.type_RefCounted); ERR_FAIL_COND_V_MSG(bad_reference_hint, false, String() + "Return type is reference but hint is not '" _STR(PROPERTY_HINT_RESOURCE_TYPE) "'." + " Are you returning a reference type by pointer? Method: '" + itype.name + "." + imethod.name + "'."); } else if (return_info.type == Variant::ARRAY && return_info.hint == PROPERTY_HINT_ARRAY_TYPE) { imethod.return_type.cname = Variant::get_type_name(return_info.type) + "_@generic"; imethod.return_type.generic_type_parameters.push_back(TypeReference(return_info.hint_string)); } else if (return_info.hint == PROPERTY_HINT_RESOURCE_TYPE) { imethod.return_type.cname = return_info.hint_string; } else if (return_info.type == Variant::NIL && return_info.usage & PROPERTY_USAGE_NIL_IS_VARIANT) { imethod.return_type.cname = name_cache.type_Variant; } else if (return_info.type == Variant::NIL) { imethod.return_type.cname = name_cache.type_void; } else { imethod.return_type.cname = _get_type_name_from_meta(return_info.type, m ? m->get_argument_meta(-1) : (GodotTypeInfo::Metadata)method_info.return_val_metadata); } for (int i = 0; i < argc; i++) { PropertyInfo arginfo = method_info.arguments[i]; String orig_arg_name = arginfo.name; ArgumentInterface iarg; iarg.name = orig_arg_name; if (arginfo.type == Variant::INT && arginfo.usage & (PROPERTY_USAGE_CLASS_IS_ENUM | PROPERTY_USAGE_CLASS_IS_BITFIELD)) { iarg.type.cname = arginfo.class_name; iarg.type.is_enum = true; } else if (arginfo.class_name != StringName()) { iarg.type.cname = arginfo.class_name; } else if (arginfo.type == Variant::ARRAY && arginfo.hint == PROPERTY_HINT_ARRAY_TYPE) { iarg.type.cname = Variant::get_type_name(arginfo.type) + "_@generic"; iarg.type.generic_type_parameters.push_back(TypeReference(arginfo.hint_string)); } else if (arginfo.hint == PROPERTY_HINT_RESOURCE_TYPE) { iarg.type.cname = arginfo.hint_string; } else if (arginfo.type == Variant::NIL) { iarg.type.cname = name_cache.type_Variant; } else { iarg.type.cname = _get_type_name_from_meta(arginfo.type, m ? m->get_argument_meta(i) : (GodotTypeInfo::Metadata)method_info.get_argument_meta(i)); } iarg.name = escape_csharp_keyword(snake_to_camel_case(iarg.name)); if (m && m->has_default_argument(i)) { bool defval_ok = _arg_default_value_from_variant(m->get_default_argument(i), iarg); ERR_FAIL_COND_V_MSG(!defval_ok, false, "Cannot determine default value for argument '" + orig_arg_name + "' of method '" + itype.name + "." + imethod.name + "'."); } imethod.add_argument(iarg); } if (imethod.is_vararg) { ArgumentInterface ivararg; ivararg.type.cname = name_cache.type_VarArg; ivararg.name = "@args"; imethod.add_argument(ivararg); } imethod.proxy_name = escape_csharp_keyword(snake_to_pascal_case(imethod.name)); // Prevent the method and its enclosing type from sharing the same name if (imethod.proxy_name == itype.proxy_name) { _log("Name of method '%s' is ambiguous with the name of its enclosing class '%s'. Renaming method to '%s_'\n", imethod.proxy_name.utf8().get_data(), itype.proxy_name.utf8().get_data(), imethod.proxy_name.utf8().get_data()); imethod.proxy_name += "_"; } HashMap::Iterator accessor = accessor_methods.find(imethod.cname); if (accessor) { // We only make internal an accessor method if it's in the same class as the property. // It's easier this way, but also we don't know if an accessor method in a different class // could have other purposes, so better leave those untouched. imethod.is_internal = true; } if (itype.class_doc) { for (int i = 0; i < itype.class_doc->methods.size(); i++) { if (itype.class_doc->methods[i].name == imethod.name) { imethod.method_doc = &itype.class_doc->methods[i]; break; } } } ERR_FAIL_COND_V_MSG(itype.find_property_by_name(imethod.cname), false, "Method name conflicts with property: '" + itype.name + "." + imethod.name + "'."); // Compat methods aren't added to the type yet, they need to be checked for conflicts // after all the non-compat methods have been added. The compat methods are added in // reverse so the most recently added ones take precedence over older compat methods. if (imethod.is_compat) { compat_methods.push_front(imethod); continue; } // Methods starting with an underscore are ignored unless they're used as a property setter or getter if (!imethod.is_virtual && imethod.name[0] == '_') { for (const PropertyInterface &iprop : itype.properties) { if (iprop.setter == imethod.name || iprop.getter == imethod.name) { imethod.is_internal = true; itype.methods.push_back(imethod); break; } } } else { itype.methods.push_back(imethod); } } // Add compat methods that don't conflict with other methods in the type. for (const MethodInterface &imethod : compat_methods) { if (_method_has_conflicting_signature(imethod, itype)) { WARN_PRINT("Method '" + imethod.name + "' conflicts with an already existing method in type '" + itype.name + "' and has been ignored."); continue; } itype.methods.push_back(imethod); } // Populate signals const HashMap &signal_map = class_info->signal_map; for (const KeyValue &E : signal_map) { SignalInterface isignal; const MethodInfo &method_info = E.value; isignal.name = method_info.name; isignal.cname = method_info.name; int argc = method_info.arguments.size(); for (int i = 0; i < argc; i++) { PropertyInfo arginfo = method_info.arguments[i]; String orig_arg_name = arginfo.name; ArgumentInterface iarg; iarg.name = orig_arg_name; if (arginfo.type == Variant::INT && arginfo.usage & (PROPERTY_USAGE_CLASS_IS_ENUM | PROPERTY_USAGE_CLASS_IS_BITFIELD)) { iarg.type.cname = arginfo.class_name; iarg.type.is_enum = true; } else if (arginfo.class_name != StringName()) { iarg.type.cname = arginfo.class_name; } else if (arginfo.type == Variant::ARRAY && arginfo.hint == PROPERTY_HINT_ARRAY_TYPE) { iarg.type.cname = Variant::get_type_name(arginfo.type) + "_@generic"; iarg.type.generic_type_parameters.push_back(TypeReference(arginfo.hint_string)); } else if (arginfo.hint == PROPERTY_HINT_RESOURCE_TYPE) { iarg.type.cname = arginfo.hint_string; } else if (arginfo.type == Variant::NIL) { iarg.type.cname = name_cache.type_Variant; } else { iarg.type.cname = _get_type_name_from_meta(arginfo.type, (GodotTypeInfo::Metadata)method_info.get_argument_meta(i)); } iarg.name = escape_csharp_keyword(snake_to_camel_case(iarg.name)); isignal.add_argument(iarg); } isignal.proxy_name = escape_csharp_keyword(snake_to_pascal_case(isignal.name)); // Prevent the signal and its enclosing type from sharing the same name if (isignal.proxy_name == itype.proxy_name) { _log("Name of signal '%s' is ambiguous with the name of its enclosing class '%s'. Renaming signal to '%s_'\n", isignal.proxy_name.utf8().get_data(), itype.proxy_name.utf8().get_data(), isignal.proxy_name.utf8().get_data()); isignal.proxy_name += "_"; } if (itype.find_property_by_proxy_name(isignal.proxy_name) || itype.find_method_by_proxy_name(isignal.proxy_name)) { // ClassDB allows signal names that conflict with method or property names. // While registering a signal with a conflicting name is considered wrong, // it may still happen and it may take some time until someone fixes the name. // We can't allow the bindings to be in a broken state while we wait for a fix; // that's why we must handle this possibility by renaming the signal. isignal.proxy_name += "Signal"; } if (itype.class_doc) { for (int i = 0; i < itype.class_doc->signals.size(); i++) { const DocData::MethodDoc &signal_doc = itype.class_doc->signals[i]; if (signal_doc.name == isignal.name) { isignal.method_doc = &signal_doc; break; } } } itype.signals_.push_back(isignal); } // Populate enums and constants List constants; ClassDB::get_integer_constant_list(type_cname, &constants, true); const HashMap &enum_map = class_info->enum_map; for (const KeyValue &E : enum_map) { StringName enum_proxy_cname = E.key; String enum_proxy_name = pascal_to_pascal_case(enum_proxy_cname.operator String()); if (itype.find_property_by_proxy_name(enum_proxy_name) || itype.find_method_by_proxy_name(enum_proxy_name) || itype.find_signal_by_proxy_name(enum_proxy_name)) { // In case the enum name conflicts with other PascalCase members, // we append 'Enum' to the enum name in those cases. // We have several conflicts between enums and PascalCase properties. enum_proxy_name += "Enum"; enum_proxy_cname = StringName(enum_proxy_name); } EnumInterface ienum(enum_proxy_cname, enum_proxy_name, E.value.is_bitfield); const List &enum_constants = E.value.constants; for (const StringName &constant_cname : enum_constants) { String constant_name = constant_cname.operator String(); int64_t *value = class_info->constant_map.getptr(constant_cname); ERR_FAIL_NULL_V(value, false); constants.erase(constant_name); ConstantInterface iconstant(constant_name, snake_to_pascal_case(constant_name, true), *value); iconstant.const_doc = nullptr; for (int i = 0; i < itype.class_doc->constants.size(); i++) { const DocData::ConstantDoc &const_doc = itype.class_doc->constants[i]; if (const_doc.name == iconstant.name) { iconstant.const_doc = &const_doc; break; } } ienum.constants.push_back(iconstant); } int prefix_length = _determine_enum_prefix(ienum); _apply_prefix_to_enum_constants(ienum, prefix_length); itype.enums.push_back(ienum); TypeInterface enum_itype; enum_itype.is_enum = true; enum_itype.name = itype.name + "." + String(E.key); enum_itype.cname = StringName(enum_itype.name); enum_itype.proxy_name = itype.proxy_name + "." + enum_proxy_name; TypeInterface::postsetup_enum_type(enum_itype); enum_types.insert(enum_itype.cname, enum_itype); } for (const String &constant_name : constants) { int64_t *value = class_info->constant_map.getptr(StringName(constant_name)); ERR_FAIL_NULL_V(value, false); String constant_proxy_name = snake_to_pascal_case(constant_name, true); if (itype.find_property_by_proxy_name(constant_proxy_name) || itype.find_method_by_proxy_name(constant_proxy_name) || itype.find_signal_by_proxy_name(constant_proxy_name)) { // In case the constant name conflicts with other PascalCase members, // we append 'Constant' to the constant name in those cases. constant_proxy_name += "Constant"; } ConstantInterface iconstant(constant_name, constant_proxy_name, *value); iconstant.const_doc = nullptr; for (int i = 0; i < itype.class_doc->constants.size(); i++) { const DocData::ConstantDoc &const_doc = itype.class_doc->constants[i]; if (const_doc.name == iconstant.name) { iconstant.const_doc = &const_doc; break; } } itype.constants.push_back(iconstant); } obj_types.insert(itype.cname, itype); if (itype.is_singleton) { // Add singleton instance type. itype.proxy_name += CS_SINGLETON_INSTANCE_SUFFIX; itype.is_singleton = false; itype.is_singleton_instance = true; // Remove constants and enums, those will remain in the static class. itype.constants.clear(); itype.enums.clear(); obj_types.insert(itype.name + CS_SINGLETON_INSTANCE_SUFFIX, itype); } class_list.pop_front(); } return true; } bool BindingsGenerator::_arg_default_value_from_variant(const Variant &p_val, ArgumentInterface &r_iarg) { r_iarg.def_param_value = p_val; r_iarg.default_argument = p_val.operator String(); switch (p_val.get_type()) { case Variant::NIL: // Either Object type or Variant r_iarg.default_argument = "default"; break; // Atomic types case Variant::BOOL: r_iarg.default_argument = bool(p_val) ? "true" : "false"; break; case Variant::INT: if (r_iarg.type.cname != name_cache.type_int) { r_iarg.default_argument = "(%s)(" + r_iarg.default_argument + ")"; } break; case Variant::FLOAT: if (r_iarg.type.cname == name_cache.type_float) { r_iarg.default_argument += "f"; } break; case Variant::STRING: case Variant::STRING_NAME: case Variant::NODE_PATH: if (r_iarg.type.cname == name_cache.type_StringName || r_iarg.type.cname == name_cache.type_NodePath) { if (r_iarg.default_argument.length() > 0) { r_iarg.default_argument = "(%s)\"" + r_iarg.default_argument + "\""; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_REF; } else { // No need for a special `in` statement to change `null` to `""`. Marshaling takes care of this already. r_iarg.default_argument = "null"; } } else { CRASH_COND(r_iarg.type.cname != name_cache.type_String); r_iarg.default_argument = "\"" + r_iarg.default_argument + "\""; } break; case Variant::PLANE: { Plane plane = p_val.operator Plane(); r_iarg.default_argument = "new Plane(new Vector3" + plane.normal.operator String() + ", " + rtos(plane.d) + ")"; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::AABB: { AABB aabb = p_val.operator ::AABB(); r_iarg.default_argument = "new Aabb(new Vector3" + aabb.position.operator String() + ", new Vector3" + aabb.size.operator String() + ")"; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::RECT2: { Rect2 rect = p_val.operator Rect2(); r_iarg.default_argument = "new Rect2(new Vector2" + rect.position.operator String() + ", new Vector2" + rect.size.operator String() + ")"; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::RECT2I: { Rect2i rect = p_val.operator Rect2i(); r_iarg.default_argument = "new Rect2I(new Vector2I" + rect.position.operator String() + ", new Vector2I" + rect.size.operator String() + ")"; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::COLOR: case Variant::VECTOR2: case Variant::VECTOR2I: case Variant::VECTOR3: case Variant::VECTOR3I: r_iarg.default_argument = "new %s" + r_iarg.default_argument; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; break; case Variant::VECTOR4: case Variant::VECTOR4I: r_iarg.default_argument = "new %s" + r_iarg.default_argument; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; break; case Variant::OBJECT: ERR_FAIL_COND_V_MSG(!p_val.is_zero(), false, "Parameter of type '" + String(r_iarg.type.cname) + "' can only have null/zero as the default value."); r_iarg.default_argument = "null"; break; case Variant::DICTIONARY: ERR_FAIL_COND_V_MSG(!p_val.operator Dictionary().is_empty(), false, "Default value of type 'Dictionary' must be an empty dictionary."); // The [cs_in] expression already interprets null values as empty dictionaries. r_iarg.default_argument = "null"; r_iarg.def_param_mode = ArgumentInterface::CONSTANT; break; case Variant::RID: ERR_FAIL_COND_V_MSG(r_iarg.type.cname != name_cache.type_RID, false, "Parameter of type '" + String(r_iarg.type.cname) + "' cannot have a default value of type '" + String(name_cache.type_RID) + "'."); ERR_FAIL_COND_V_MSG(!p_val.is_zero(), false, "Parameter of type '" + String(r_iarg.type.cname) + "' can only have null/zero as the default value."); r_iarg.default_argument = "default"; break; case Variant::ARRAY: ERR_FAIL_COND_V_MSG(!p_val.operator Array().is_empty(), false, "Default value of type 'Array' must be an empty array."); // The [cs_in] expression already interprets null values as empty arrays. r_iarg.default_argument = "null"; r_iarg.def_param_mode = ArgumentInterface::CONSTANT; break; case Variant::PACKED_BYTE_ARRAY: case Variant::PACKED_INT32_ARRAY: case Variant::PACKED_INT64_ARRAY: case Variant::PACKED_FLOAT32_ARRAY: case Variant::PACKED_FLOAT64_ARRAY: case Variant::PACKED_STRING_ARRAY: case Variant::PACKED_VECTOR2_ARRAY: case Variant::PACKED_VECTOR3_ARRAY: case Variant::PACKED_COLOR_ARRAY: r_iarg.default_argument = "Array.Empty<%s>()"; r_iarg.def_param_mode = ArgumentInterface::NULLABLE_REF; break; case Variant::TRANSFORM2D: { Transform2D transform = p_val.operator Transform2D(); if (transform == Transform2D()) { r_iarg.default_argument = "Transform2D.Identity"; } else { r_iarg.default_argument = "new Transform2D(new Vector2" + transform.columns[0].operator String() + ", new Vector2" + transform.columns[1].operator String() + ", new Vector2" + transform.columns[2].operator String() + ")"; } r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::TRANSFORM3D: { Transform3D transform = p_val.operator Transform3D(); if (transform == Transform3D()) { r_iarg.default_argument = "Transform3D.Identity"; } else { Basis basis = transform.basis; r_iarg.default_argument = "new Transform3D(new Vector3" + basis.get_column(0).operator String() + ", new Vector3" + basis.get_column(1).operator String() + ", new Vector3" + basis.get_column(2).operator String() + ", new Vector3" + transform.origin.operator String() + ")"; } r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::PROJECTION: { Projection projection = p_val.operator Projection(); if (projection == Projection()) { r_iarg.default_argument = "Projection.Identity"; } else { r_iarg.default_argument = "new Projection(new Vector4" + projection.columns[0].operator String() + ", new Vector4" + projection.columns[1].operator String() + ", new Vector4" + projection.columns[2].operator String() + ", new Vector4" + projection.columns[3].operator String() + ")"; } r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::BASIS: { Basis basis = p_val.operator Basis(); if (basis == Basis()) { r_iarg.default_argument = "Basis.Identity"; } else { r_iarg.default_argument = "new Basis(new Vector3" + basis.get_column(0).operator String() + ", new Vector3" + basis.get_column(1).operator String() + ", new Vector3" + basis.get_column(2).operator String() + ")"; } r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::QUATERNION: { Quaternion quaternion = p_val.operator Quaternion(); if (quaternion == Quaternion()) { r_iarg.default_argument = "Quaternion.Identity"; } else { r_iarg.default_argument = "new Quaternion" + quaternion.operator String(); } r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } break; case Variant::CALLABLE: ERR_FAIL_COND_V_MSG(r_iarg.type.cname != name_cache.type_Callable, false, "Parameter of type '" + String(r_iarg.type.cname) + "' cannot have a default value of type '" + String(name_cache.type_Callable) + "'."); ERR_FAIL_COND_V_MSG(!p_val.is_zero(), false, "Parameter of type '" + String(r_iarg.type.cname) + "' can only have null/zero as the default value."); r_iarg.default_argument = "default"; break; case Variant::SIGNAL: ERR_FAIL_COND_V_MSG(r_iarg.type.cname != name_cache.type_Signal, false, "Parameter of type '" + String(r_iarg.type.cname) + "' cannot have a default value of type '" + String(name_cache.type_Signal) + "'."); ERR_FAIL_COND_V_MSG(!p_val.is_zero(), false, "Parameter of type '" + String(r_iarg.type.cname) + "' can only have null/zero as the default value."); r_iarg.default_argument = "default"; break; default: ERR_FAIL_V_MSG(false, "Unexpected Variant type: " + itos(p_val.get_type())); break; } if (r_iarg.def_param_mode == ArgumentInterface::CONSTANT && r_iarg.type.cname == name_cache.type_Variant && r_iarg.default_argument != "default") { r_iarg.def_param_mode = ArgumentInterface::NULLABLE_VAL; } return true; } void BindingsGenerator::_populate_builtin_type_interfaces() { builtin_types.clear(); TypeInterface itype; #define INSERT_STRUCT_TYPE(m_type, m_proxy_name) \ { \ itype = TypeInterface::create_value_type(String(#m_type), String(#m_proxy_name)); \ itype.cs_in_expr = "&%0"; \ itype.cs_in_expr_is_unsafe = true; \ builtin_types.insert(itype.cname, itype); \ } INSERT_STRUCT_TYPE(Vector2, Vector2) INSERT_STRUCT_TYPE(Vector2i, Vector2I) INSERT_STRUCT_TYPE(Rect2, Rect2) INSERT_STRUCT_TYPE(Rect2i, Rect2I) INSERT_STRUCT_TYPE(Transform2D, Transform2D) INSERT_STRUCT_TYPE(Vector3, Vector3) INSERT_STRUCT_TYPE(Vector3i, Vector3I) INSERT_STRUCT_TYPE(Basis, Basis) INSERT_STRUCT_TYPE(Quaternion, Quaternion) INSERT_STRUCT_TYPE(Transform3D, Transform3D) INSERT_STRUCT_TYPE(AABB, Aabb) INSERT_STRUCT_TYPE(Color, Color) INSERT_STRUCT_TYPE(Plane, Plane) INSERT_STRUCT_TYPE(Vector4, Vector4) INSERT_STRUCT_TYPE(Vector4i, Vector4I) INSERT_STRUCT_TYPE(Projection, Projection) #undef INSERT_STRUCT_TYPE // bool itype = TypeInterface::create_value_type(String("bool")); itype.cs_in_expr = "%0.ToGodotBool()"; itype.cs_out = "%5return %0(%1).ToBool();"; itype.c_type = "godot_bool"; itype.c_type_in = itype.c_type; itype.c_type_out = itype.c_type; itype.c_arg_in = "&%s"; itype.c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromBool(%1);\n"; builtin_types.insert(itype.cname, itype); // Integer types { // C interface for 'uint32_t' is the same as that of enums. Remember to apply // any of the changes done here to 'TypeInterface::postsetup_enum_type' as well. #define INSERT_INT_TYPE(m_name, m_int_struct_name) \ { \ itype = TypeInterface::create_value_type(String(m_name)); \ if (itype.name != "long" && itype.name != "ulong") { \ itype.c_in = "%5%0 %1_in = %1;\n"; \ itype.c_out = "%5return (%0)(%1);\n"; \ itype.c_type = "long"; \ itype.c_arg_in = "&%s_in"; \ } else { \ itype.c_arg_in = "&%s"; \ } \ itype.c_type_in = itype.name; \ itype.c_type_out = itype.name; \ itype.c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromInt(%1);\n"; \ builtin_types.insert(itype.cname, itype); \ } // The expected type for all integers in ptrcall is 'int64_t', so that's what we use for 'c_type' INSERT_INT_TYPE("sbyte", "Int8"); INSERT_INT_TYPE("short", "Int16"); INSERT_INT_TYPE("int", "Int32"); INSERT_INT_TYPE("long", "Int64"); INSERT_INT_TYPE("byte", "UInt8"); INSERT_INT_TYPE("ushort", "UInt16"); INSERT_INT_TYPE("uint", "UInt32"); INSERT_INT_TYPE("ulong", "UInt64"); #undef INSERT_INT_TYPE } // Floating point types { // float itype = TypeInterface(); itype.name = "float"; itype.cname = itype.name; itype.proxy_name = "float"; itype.cs_type = itype.proxy_name; { // The expected type for 'float' in ptrcall is 'double' itype.c_in = "%5%0 %1_in = %1;\n"; itype.c_out = "%5return (%0)%1;\n"; itype.c_type = "double"; itype.c_arg_in = "&%s_in"; } itype.c_type_in = itype.proxy_name; itype.c_type_out = itype.proxy_name; itype.c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromFloat(%1);\n"; builtin_types.insert(itype.cname, itype); // double itype = TypeInterface(); itype.name = "double"; itype.cname = itype.name; itype.proxy_name = "double"; itype.cs_type = itype.proxy_name; itype.c_type = "double"; itype.c_arg_in = "&%s"; itype.c_type_in = itype.proxy_name; itype.c_type_out = itype.proxy_name; itype.c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromFloat(%1);\n"; builtin_types.insert(itype.cname, itype); } // String itype = TypeInterface(); itype.name = "String"; itype.cname = itype.name; itype.proxy_name = "string"; itype.cs_type = itype.proxy_name; itype.c_in = "%5using %0 %1_in = " C_METHOD_MONOSTR_TO_GODOT "(%1);\n"; itype.c_out = "%5return " C_METHOD_MONOSTR_FROM_GODOT "(%1);\n"; itype.c_arg_in = "&%s_in"; itype.c_type = "godot_string"; itype.c_type_in = itype.cs_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = true; itype.c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromString(%1);\n"; builtin_types.insert(itype.cname, itype); // StringName itype = TypeInterface(); itype.name = "StringName"; itype.cname = itype.name; itype.proxy_name = "StringName"; itype.cs_type = itype.proxy_name; itype.cs_in_expr = "(%1)(%0?.NativeValue ?? default)"; // Cannot pass null StringName to ptrcall itype.c_out = "%5return %0.CreateTakingOwnershipOfDisposableValue(%1);\n"; itype.c_arg_in = "&%s"; itype.c_type = "godot_string_name"; itype.c_type_in = itype.c_type; itype.c_type_out = itype.cs_type; itype.c_in_vararg = "%5using godot_variant %1_in = VariantUtils.CreateFromStringName(%1);\n"; itype.c_type_is_disposable_struct = false; // [c_out] takes ownership itype.c_ret_needs_default_initialization = true; builtin_types.insert(itype.cname, itype); // NodePath itype = TypeInterface(); itype.name = "NodePath"; itype.cname = itype.name; itype.proxy_name = "NodePath"; itype.cs_type = itype.proxy_name; itype.cs_in_expr = "(%1)(%0?.NativeValue ?? default)"; // Cannot pass null NodePath to ptrcall itype.c_out = "%5return %0.CreateTakingOwnershipOfDisposableValue(%1);\n"; itype.c_arg_in = "&%s"; itype.c_type = "godot_node_path"; itype.c_type_in = itype.c_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = false; // [c_out] takes ownership itype.c_ret_needs_default_initialization = true; builtin_types.insert(itype.cname, itype); // RID itype = TypeInterface(); itype.name = "RID"; itype.cname = itype.name; itype.proxy_name = "Rid"; itype.cs_type = itype.proxy_name; itype.c_arg_in = "&%s"; itype.c_type = itype.cs_type; itype.c_type_in = itype.c_type; itype.c_type_out = itype.c_type; builtin_types.insert(itype.cname, itype); // Variant itype = TypeInterface(); itype.name = "Variant"; itype.cname = itype.name; itype.proxy_name = "Variant"; itype.cs_type = itype.proxy_name; itype.c_in = "%5%0 %1_in = (%0)%1.NativeVar;\n"; itype.c_out = "%5return Variant.CreateTakingOwnershipOfDisposableValue(%1);\n"; itype.c_arg_in = "&%s_in"; itype.c_type = "godot_variant"; itype.c_type_in = itype.cs_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = false; // [c_out] takes ownership itype.c_ret_needs_default_initialization = true; builtin_types.insert(itype.cname, itype); // Callable itype = TypeInterface::create_value_type(String("Callable")); itype.cs_in_expr = "%0"; itype.c_in = "%5using %0 %1_in = " C_METHOD_MANAGED_TO_CALLABLE "(in %1);\n"; itype.c_out = "%5return " C_METHOD_MANAGED_FROM_CALLABLE "(in %1);\n"; itype.c_arg_in = "&%s_in"; itype.c_type = "godot_callable"; itype.c_type_in = "in " + itype.cs_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = true; builtin_types.insert(itype.cname, itype); // Signal itype = TypeInterface(); itype.name = "Signal"; itype.cname = itype.name; itype.proxy_name = "Signal"; itype.cs_type = itype.proxy_name; itype.cs_in_expr = "%0"; itype.c_in = "%5using %0 %1_in = " C_METHOD_MANAGED_TO_SIGNAL "(in %1);\n"; itype.c_out = "%5return " C_METHOD_MANAGED_FROM_SIGNAL "(in %1);\n"; itype.c_arg_in = "&%s_in"; itype.c_type = "godot_signal"; itype.c_type_in = "in " + itype.cs_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = true; builtin_types.insert(itype.cname, itype); // VarArg (fictitious type to represent variable arguments) itype = TypeInterface(); itype.name = "VarArg"; itype.cname = itype.name; itype.proxy_name = "Variant[]"; itype.cs_type = "params Variant[]"; itype.cs_in_expr = "%0 ?? Array.Empty()"; // c_type, c_in and c_arg_in are hard-coded in the generator. // c_out and c_type_out are not applicable to VarArg. itype.c_arg_in = "&%s_in"; itype.c_type_in = "Variant[]"; builtin_types.insert(itype.cname, itype); #define INSERT_ARRAY_FULL(m_name, m_type, m_managed_type, m_proxy_t) \ { \ itype = TypeInterface(); \ itype.name = #m_name; \ itype.cname = itype.name; \ itype.proxy_name = #m_proxy_t "[]"; \ itype.cs_type = itype.proxy_name; \ itype.c_in = "%5using %0 %1_in = " C_METHOD_MONOARRAY_TO(m_type) "(%1);\n"; \ itype.c_out = "%5return " C_METHOD_MONOARRAY_FROM(m_type) "(%1);\n"; \ itype.c_arg_in = "&%s_in"; \ itype.c_type = #m_managed_type; \ itype.c_type_in = itype.proxy_name; \ itype.c_type_out = itype.proxy_name; \ itype.c_type_is_disposable_struct = true; \ builtin_types.insert(itype.name, itype); \ } #define INSERT_ARRAY(m_type, m_managed_type, m_proxy_t) INSERT_ARRAY_FULL(m_type, m_type, m_managed_type, m_proxy_t) INSERT_ARRAY(PackedInt32Array, godot_packed_int32_array, int); INSERT_ARRAY(PackedInt64Array, godot_packed_int64_array, long); INSERT_ARRAY_FULL(PackedByteArray, PackedByteArray, godot_packed_byte_array, byte); INSERT_ARRAY(PackedFloat32Array, godot_packed_float32_array, float); INSERT_ARRAY(PackedFloat64Array, godot_packed_float64_array, double); INSERT_ARRAY(PackedStringArray, godot_packed_string_array, string); INSERT_ARRAY(PackedColorArray, godot_packed_color_array, Color); INSERT_ARRAY(PackedVector2Array, godot_packed_vector2_array, Vector2); INSERT_ARRAY(PackedVector3Array, godot_packed_vector3_array, Vector3); #undef INSERT_ARRAY // Array itype = TypeInterface(); itype.name = "Array"; itype.cname = itype.name; itype.proxy_name = itype.name; itype.type_parameter_count = 1; itype.cs_type = BINDINGS_NAMESPACE_COLLECTIONS "." + itype.proxy_name; itype.cs_in_expr = "(%1)(%0 ?? new()).NativeValue"; itype.c_out = "%5return %0.CreateTakingOwnershipOfDisposableValue(%1);\n"; itype.c_arg_in = "&%s"; itype.c_type = "godot_array"; itype.c_type_in = itype.c_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = false; // [c_out] takes ownership itype.c_ret_needs_default_initialization = true; builtin_types.insert(itype.cname, itype); // Array_@generic // Reuse Array's itype itype.name = "Array_@generic"; itype.cname = itype.name; itype.cs_out = "%5return new %2(%0(%1));"; // For generic Godot collections, Variant.From/As is slower, so we need this special case itype.cs_variant_to_managed = "VariantUtils.ConvertToArray(%0)"; itype.cs_managed_to_variant = "VariantUtils.CreateFromArray(%0)"; builtin_types.insert(itype.cname, itype); // Dictionary itype = TypeInterface(); itype.name = "Dictionary"; itype.cname = itype.name; itype.proxy_name = itype.name; itype.type_parameter_count = 2; itype.cs_type = BINDINGS_NAMESPACE_COLLECTIONS "." + itype.proxy_name; itype.cs_in_expr = "(%1)(%0 ?? new()).NativeValue"; itype.c_out = "%5return %0.CreateTakingOwnershipOfDisposableValue(%1);\n"; itype.c_arg_in = "&%s"; itype.c_type = "godot_dictionary"; itype.c_type_in = itype.c_type; itype.c_type_out = itype.cs_type; itype.c_type_is_disposable_struct = false; // [c_out] takes ownership itype.c_ret_needs_default_initialization = true; builtin_types.insert(itype.cname, itype); // Dictionary_@generic // Reuse Dictionary's itype itype.name = "Dictionary_@generic"; itype.cname = itype.name; itype.cs_out = "%5return new %2(%0(%1));"; // For generic Godot collections, Variant.From/As is slower, so we need this special case itype.cs_variant_to_managed = "VariantUtils.ConvertToDictionary(%0)"; itype.cs_managed_to_variant = "VariantUtils.CreateFromDictionary(%0)"; builtin_types.insert(itype.cname, itype); // void (fictitious type to represent the return type of methods that do not return anything) itype = TypeInterface(); itype.name = "void"; itype.cname = itype.name; itype.proxy_name = itype.name; itype.cs_type = itype.proxy_name; itype.c_type = itype.proxy_name; itype.c_type_in = itype.c_type; itype.c_type_out = itype.c_type; builtin_types.insert(itype.cname, itype); } void BindingsGenerator::_populate_global_constants() { int global_constants_count = CoreConstants::get_global_constant_count(); if (global_constants_count > 0) { HashMap::Iterator match = EditorHelp::get_doc_data()->class_list.find("@GlobalScope"); CRASH_COND_MSG(!match, "Could not find '@GlobalScope' in DocData."); const DocData::ClassDoc &global_scope_doc = match->value; for (int i = 0; i < global_constants_count; i++) { String constant_name = CoreConstants::get_global_constant_name(i); const DocData::ConstantDoc *const_doc = nullptr; for (int j = 0; j < global_scope_doc.constants.size(); j++) { const DocData::ConstantDoc &curr_const_doc = global_scope_doc.constants[j]; if (curr_const_doc.name == constant_name) { const_doc = &curr_const_doc; break; } } int64_t constant_value = CoreConstants::get_global_constant_value(i); StringName enum_name = CoreConstants::get_global_constant_enum(i); ConstantInterface iconstant(constant_name, snake_to_pascal_case(constant_name, true), constant_value); iconstant.const_doc = const_doc; if (enum_name != StringName()) { EnumInterface ienum(enum_name, pascal_to_pascal_case(enum_name.operator String()), CoreConstants::is_global_constant_bitfield(i)); List::Element *enum_match = global_enums.find(ienum); if (enum_match) { enum_match->get().constants.push_back(iconstant); } else { ienum.constants.push_back(iconstant); global_enums.push_back(ienum); } } else { global_constants.push_back(iconstant); } } for (EnumInterface &ienum : global_enums) { TypeInterface enum_itype; enum_itype.is_enum = true; enum_itype.name = ienum.cname.operator String(); enum_itype.cname = ienum.cname; enum_itype.proxy_name = ienum.proxy_name; TypeInterface::postsetup_enum_type(enum_itype); enum_types.insert(enum_itype.cname, enum_itype); int prefix_length = _determine_enum_prefix(ienum); // HARDCODED: The Error enum have the prefix 'ERR_' for everything except 'OK' and 'FAILED'. if (ienum.cname == name_cache.enum_Error) { if (prefix_length > 0) { // Just in case it ever changes ERR_PRINT("Prefix for enum '" _STR(Error) "' is not empty."); } prefix_length = 1; // 'ERR_' } _apply_prefix_to_enum_constants(ienum, prefix_length); } } // HARDCODED List hardcoded_enums; hardcoded_enums.push_back("Vector2.Axis"); hardcoded_enums.push_back("Vector2I.Axis"); hardcoded_enums.push_back("Vector3.Axis"); hardcoded_enums.push_back("Vector3I.Axis"); for (const StringName &enum_cname : hardcoded_enums) { // These enums are not generated and must be written manually (e.g.: Vector3.Axis) // Here, we assume core types do not begin with underscore TypeInterface enum_itype; enum_itype.is_enum = true; enum_itype.name = enum_cname.operator String(); enum_itype.cname = enum_cname; enum_itype.proxy_name = pascal_to_pascal_case(enum_itype.name); TypeInterface::postsetup_enum_type(enum_itype); enum_types.insert(enum_itype.cname, enum_itype); } } bool BindingsGenerator::_method_has_conflicting_signature(const MethodInterface &p_imethod, const TypeInterface &p_itype) { // Compare p_imethod with all the methods already registered in p_itype. for (const MethodInterface &method : p_itype.methods) { if (method.proxy_name == p_imethod.proxy_name) { if (_method_has_conflicting_signature(p_imethod, method)) { return true; } } } return false; } bool BindingsGenerator::_method_has_conflicting_signature(const MethodInterface &p_imethod_left, const MethodInterface &p_imethod_right) { // Check if a method already exists in p_itype with a method signature that would conflict with p_imethod. // The return type is ignored because only changing the return type is not enough to avoid conflicts. // The const keyword is also ignored since it doesn't generate different C# code. if (p_imethod_left.arguments.size() != p_imethod_right.arguments.size()) { // Different argument count, so no conflict. return false; } for (int i = 0; i < p_imethod_left.arguments.size(); i++) { const ArgumentInterface &iarg_left = p_imethod_left.arguments[i]; const ArgumentInterface &iarg_right = p_imethod_right.arguments[i]; if (iarg_left.type.cname != iarg_right.type.cname) { // Different types for arguments in the same position, so no conflict. return false; } if (iarg_left.def_param_mode != iarg_right.def_param_mode) { // If the argument is a value type and nullable, it will be 'Nullable' instead of 'T' // and will not create a conflict. if (iarg_left.def_param_mode == ArgumentInterface::NULLABLE_VAL || iarg_right.def_param_mode == ArgumentInterface::NULLABLE_VAL) { return false; } } } return true; } void BindingsGenerator::_initialize_blacklisted_methods() { blacklisted_methods["Object"].push_back("to_string"); // there is already ToString blacklisted_methods["Object"].push_back("_to_string"); // override ToString instead blacklisted_methods["Object"].push_back("_init"); // never called in C# (TODO: implement it) } void BindingsGenerator::_initialize_compat_singletons() { compat_singletons.insert("EditorInterface"); } void BindingsGenerator::_log(const char *p_format, ...) { if (log_print_enabled) { va_list list; va_start(list, p_format); OS::get_singleton()->print("%s", str_format(p_format, list).utf8().get_data()); va_end(list); } } void BindingsGenerator::_initialize() { initialized = false; EditorHelp::generate_doc(false); enum_types.clear(); _initialize_blacklisted_methods(); _initialize_compat_singletons(); bool obj_type_ok = _populate_object_type_interfaces(); ERR_FAIL_COND_MSG(!obj_type_ok, "Failed to generate object type interfaces"); _populate_builtin_type_interfaces(); _populate_global_constants(); // Generate internal calls (after populating type interfaces and global constants) for (const KeyValue &E : obj_types) { const TypeInterface &itype = E.value; Error err = _populate_method_icalls_table(itype); ERR_FAIL_COND_MSG(err != OK, "Failed to generate icalls table for type: " + itype.name); } initialized = true; } static String generate_all_glue_option = "--generate-mono-glue"; static void handle_cmdline_options(String glue_dir_path) { BindingsGenerator bindings_generator; bindings_generator.set_log_print_enabled(true); if (!bindings_generator.is_initialized()) { ERR_PRINT("Failed to initialize the bindings generator"); return; } CRASH_COND(glue_dir_path.is_empty()); if (bindings_generator.generate_cs_api(glue_dir_path.path_join(API_SOLUTION_NAME)) != OK) { ERR_PRINT(generate_all_glue_option + ": Failed to generate the C# API."); } } static void cleanup_and_exit_godot() { // Exit once done Main::cleanup(true); ::exit(0); } void BindingsGenerator::handle_cmdline_args(const List &p_cmdline_args) { String glue_dir_path; const List::Element *elem = p_cmdline_args.front(); while (elem) { if (elem->get() == generate_all_glue_option) { const List::Element *path_elem = elem->next(); if (path_elem) { glue_dir_path = path_elem->get(); elem = elem->next(); } else { ERR_PRINT(generate_all_glue_option + ": No output directory specified (expected path to '{GODOT_ROOT}/modules/mono/glue')."); // Exit once done with invalid command line arguments cleanup_and_exit_godot(); } break; } elem = elem->next(); } if (glue_dir_path.length()) { handle_cmdline_options(glue_dir_path); // Exit once done cleanup_and_exit_godot(); } } #endif