virtualx-engine/modules/mono/editor/bindings_generator.cpp
Ignacio Roldán Etcheverry 17b2838f39 C#: Cleanup Variant marshaling code in source/bindings generators
This change aims to reduce the number of places that need to be changed
when adding or editing a Godot type to the bindings.

Since the addition of `Variant.From<T>/As<T>` and
`VariantUtils.CreateFrom<T>/ConvertTo<T>`, we can now replace a lot of
the previous code in the bindings generator and the source generators
that specify these conversions for each type manually.

The only exceptions are the generic Godot collections (`Array<T>` and
`Dictionary<TKey, TValue>`) which still use the old version, as that
one cannot be matched by our new conversion methods (limitation in the
language with generics, forcing us to use delegate pointers).

The cleanup applies to:

- Bindings generator:
  - `TypeInterface.cs_variant_to_managed`
  - `TypeInterface.cs_managed_to_variant`
- Source generators:
  - `MarshalUtils.AppendNativeVariantToManagedExpr`
  - `MarshalUtils.AppendManagedToNativeVariantExpr`
  - `MarshalUtils.AppendVariantToManagedExpr`
  - `MarshalUtils.AppendManagedToVariantExpr`
2022-12-02 14:47:12 +01:00

3960 lines
141 KiB
C++

/*************************************************************************/
/* bindings_generator.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */
/* */
/* 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 "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 "core/string/ucaps.h"
#include "main/main.h"
#include "../godotsharp_defs.h"
#include "../utils/path_utils.h"
#include "../utils/string_utils.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 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_METHOD_INVOKE_GODOT_CLASS_METHOD "InvokeGodotClassMethod"
#define CS_METHOD_HAS_GODOT_CLASS_METHOD "HasGodotClassMethod"
#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 ICALL_PREFIX "godot_icall_"
#define ICALL_CLASSDB_GET_METHOD "ClassDB_get_method"
#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#.
const Vector<String> ignored_types = { "PhysicsServer2DExtension", "PhysicsServer3DExtension" };
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();
}
static String snake_to_pascal_case(const String &p_identifier, bool p_input_is_upper = false) {
String ret;
Vector<String> parts = p_identifier.split("_", true);
for (int i = 0; i < parts.size(); i++) {
String part = parts[i];
if (part.length()) {
part[0] = _find_upper(part[0]);
if (p_input_is_upper) {
for (int j = 1; j < part.length(); j++) {
part[j] = _find_lower(part[j]);
}
}
ret += part;
} else {
if (i == 0 || i == (parts.size() - 1)) {
// Preserve underscores at the beginning and end
ret += "_";
} else {
// Preserve contiguous underscores
if (parts[i - 1].length()) {
ret += "__";
} else {
ret += "_";
}
}
}
}
return ret;
}
static String snake_to_camel_case(const String &p_identifier, bool p_input_is_upper = false) {
String ret;
Vector<String> parts = p_identifier.split("_", true);
for (int i = 0; i < parts.size(); i++) {
String part = parts[i];
if (part.length()) {
if (i != 0) {
part[0] = _find_upper(part[0]);
}
if (p_input_is_upper) {
for (int j = i != 0 ? 1 : 0; j < part.length(); j++) {
part[j] = _find_lower(part[j]);
}
}
ret += part;
} else {
if (i == 0 || i == (parts.size() - 1)) {
// Preserve underscores at the beginning and end
ret += "_";
} else {
// Preserve contiguous underscores
if (parts[i - 1].length()) {
ret += "__";
} else {
ret += "_";
}
}
}
}
return ret;
}
String BindingsGenerator::bbcode_to_xml(const String &p_bbcode, const TypeInterface *p_itype) {
// 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("<para>");
List<String> tag_stack;
bool code_tag = 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) {
String text = bbcode.substr(pos, brk_pos - pos);
if (code_tag || tag_stack.size() > 0) {
xml_output.append(text.xml_escape());
} else {
Vector<String> lines = text.split("\n");
for (int i = 0; i < lines.size(); i++) {
if (i != 0) {
xml_output.append("<para>");
}
xml_output.append(lines[i].xml_escape());
if (i != lines.size() - 1) {
xml_output.append("</para>\n");
}
}
}
}
if (brk_pos == bbcode.length()) {
break; // nothing else to add
}
int brk_end = bbcode.find("]", brk_pos + 1);
if (brk_end == -1) {
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<String> lines = text.split("\n");
for (int i = 0; i < lines.size(); i++) {
if (i != 0) {
xml_output.append("<para>");
}
xml_output.append(lines[i].xml_escape());
if (i != lines.size() - 1) {
xml_output.append("</para>\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) {
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("</a>");
} else if (tag == "/code") {
xml_output.append("</c>");
} else if (tag == "/codeblock") {
xml_output.append("</code>");
}
} else if (code_tag) {
xml_output.append("[");
pos = brk_pos + 1;
} else if (tag.begins_with("method ") || tag.begins_with("member ") || tag.begins_with("signal ") || tag.begins_with("enum ") || tag.begins_with("constant ") || tag.begins_with("theme_item ")) {
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<String> 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("<c>");
xml_output.append(tag);
xml_output.append("</c>");
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 == "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 == "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("<see cref=\"" BINDINGS_NAMESPACE_COLLECTIONS ".");
xml_output.append(tag);
xml_output.append("\"/>");
} else if (tag == "bool" || tag == "int") {
xml_output.append("<see cref=\"");
xml_output.append(tag);
xml_output.append("\"/>");
} else if (tag == "float") {
xml_output.append("<see cref=\""
#ifdef REAL_T_IS_DOUBLE
"double"
#else
"float"
#endif
"\"/>");
} else if (tag == "Variant") {
// We use System.Object for Variant, so there is no Variant type in C#
xml_output.append("<c>Variant</c>");
} else if (tag == "String") {
xml_output.append("<see cref=\"string\"/>");
} else if (tag == "Nil") {
xml_output.append("<see langword=\"null\"/>");
} else if (tag.begins_with("@")) {
// @GlobalScope, @GDScript, etc
xml_output.append("<c>");
xml_output.append(tag);
xml_output.append("</c>");
} else if (tag == "PackedByteArray") {
xml_output.append("<see cref=\"byte\"/>[]");
} else if (tag == "PackedInt32Array") {
xml_output.append("<see cref=\"int\"/>[]");
} else if (tag == "PackedInt64Array") {
xml_output.append("<see cref=\"long\"/>[]");
} else if (tag == "PackedFloat32Array") {
xml_output.append("<see cref=\"float\"/>[]");
} else if (tag == "PackedFloat64Array") {
xml_output.append("<see cref=\"double\"/>[]");
} else if (tag == "PackedStringArray") {
xml_output.append("<see cref=\"string\"/>[]");
} else if (tag == "PackedVector2Array") {
xml_output.append("<see cref=\"" BINDINGS_NAMESPACE ".Vector2\"/>[]");
} else if (tag == "PackedVector3Array") {
xml_output.append("<see cref=\"" BINDINGS_NAMESPACE ".Vector3\"/>[]");
} else if (tag == "PackedColorArray") {
xml_output.append("<see cref=\"" BINDINGS_NAMESPACE ".Color\"/>[]");
} 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) {
xml_output.append("<see cref=\"" BINDINGS_NAMESPACE ".");
xml_output.append(target_itype->proxy_name);
xml_output.append("\"/>");
} else {
ERR_PRINT("Cannot resolve type reference in documentation: '" + tag + "'.");
xml_output.append("<c>");
xml_output.append(tag);
xml_output.append("</c>");
}
}
pos = brk_end + 1;
} else if (tag == "b") {
// bold is not supported in xml comments
pos = brk_end + 1;
tag_stack.push_front(tag);
} else if (tag == "i") {
// italics is not supported in xml comments
pos = brk_end + 1;
tag_stack.push_front(tag);
} else if (tag == "code") {
xml_output.append("<c>");
code_tag = true;
pos = brk_end + 1;
tag_stack.push_front(tag);
} else if (tag == "codeblock") {
xml_output.append("<code>");
code_tag = true;
pos = brk_end + 1;
tag_stack.push_front(tag);
} 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 <para> instead. Luckily this tag isn't used for now.
pos = brk_end + 1;
} else if (tag == "u") {
// underline is not supported in 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("<a href=\"");
xml_output.append(url);
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("<a href=\"");
xml_output.append(url);
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 {
xml_output.append("["); // ignore
pos = brk_pos + 1;
}
}
xml_output.append("</para>");
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<String> &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-Godot.Object 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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(p_target_itype->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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(p_target_itype->proxy_name);
p_xml_output.append(".");
p_xml_output.append(target_imethod->proxy_name);
p_xml_output.append("\"/>");
} else {
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<String> &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-Godot.Object 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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(current_itype->proxy_name);
p_xml_output.append(".");
p_xml_output.append(target_iprop->proxy_name);
p_xml_output.append("\"/>");
} else {
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<String> &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-Godot.Object 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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(p_target_itype->proxy_name);
p_xml_output.append(".");
p_xml_output.append(target_isignal->proxy_name);
p_xml_output.append("\"/>");
} else {
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<String> &p_link_target_parts) {
const StringName search_cname = !p_target_itype ? p_target_cname : StringName(p_target_itype->name + "." + (String)p_target_cname);
HashMap<StringName, TypeInterface>::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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(target_enum_itype.proxy_name); // Includes nesting class if any
p_xml_output.append("\"/>");
} else {
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<String> &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-Godot.Object 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
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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(p_target_itype->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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(p_target_itype->proxy_name);
p_xml_output.append(".");
p_xml_output.append(target_ienum->cname);
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 {
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("<see cref=\"" BINDINGS_NAMESPACE "." BINDINGS_GLOBAL_SCOPE_CLASS ".");
p_xml_output.append(target_iconst->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("<see cref=\"" BINDINGS_NAMESPACE ".");
p_xml_output.append(target_ienum->cname);
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_undeclared(StringBuilder &p_xml_output, const String &p_link_target) {
p_xml_output.append("<c>");
p_xml_output.append(p_link_target);
p_xml_output.append("</c>");
}
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<String> 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<String> 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<String> 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<ArgumentInterface>::Element *F = imethod.arguments.front(); F; F = F->next()) {
im_icall.argument_types.push_back(F->get().type);
}
List<InternalCall>::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<InternalCall>::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 "/// <summary>\n"); \
p_output.append(INDENT1 "/// Returns true if this " #m_type " array is empty or doesn't exist.\n"); \
p_output.append(INDENT1 "/// </summary>\n"); \
p_output.append(INDENT1 "/// <param name=\"instance\">The " #m_type " array check.</param>\n"); \
p_output.append(INDENT1 "/// <returns>Whether or not the array is empty.</returns>\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 "/// <summary>\n"); \
p_output.append(INDENT1 "/// Converts this " #m_type " array to a string delimited by the given string.\n"); \
p_output.append(INDENT1 "/// </summary>\n"); \
p_output.append(INDENT1 "/// <param name=\"instance\">The " #m_type " array to convert.</param>\n"); \
p_output.append(INDENT1 "/// <param name=\"delimiter\">The delimiter to use between items.</param>\n"); \
p_output.append(INDENT1 "/// <returns>A single string with all items.</returns>\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 "/// <summary>\n"); \
p_output.append(INDENT1 "/// Converts this " #m_type " array to a string with brackets.\n"); \
p_output.append(INDENT1 "/// </summary>\n"); \
p_output.append(INDENT1 "/// <param name=\"instance\">The " #m_type " array to convert.</param>\n"); \
p_output.append(INDENT1 "/// <returns>A single string with all items.</returns>\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("\n#pragma warning disable CS1591 // Disable warning: "
"'Missing XML comment for publicly visible type or member'\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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
p_output.append(MEMBER_BEGIN "/// <summary>\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 "/// </summary>");
}
}
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.cname.operator String();
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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
p_output.append(INDENT1 "/// <summary>\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 "/// </summary>\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);
}
}
p_output.append("\n#pragma warning restore CS1591\n");
}
Error BindingsGenerator::generate_cs_core_project(const String &p_proj_dir) {
ERR_FAIL_COND_V(!initialized, ERR_UNCONFIGURED);
Ref<DirAccess> 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<String> 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<StringName, TypeInterface> &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("<Project>\n"
" <ItemGroup>\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(" <Compile Include=\"" + include + "\" />\n");
}
includes_props_content.append(" </ItemGroup>\n"
"</Project>\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<DirAccess> 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<String> compile_items;
for (const KeyValue<StringName, TypeInterface> &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("<Project>\n"
" <ItemGroup>\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(" <Compile Include=\"" + include + "\" />\n");
}
includes_props_content.append(" </ItemGroup>\n"
"</Project>\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<DirAccess> 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 Godot.Object 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.Diagnostics;\n"); // DebuggerBrowsable
output.append("using Godot.NativeInterop;\n");
output.append("\n"
"#pragma warning disable CS1591 // Disable warning: "
"'Missing XML comment for publicly visible type or member'\n"
"#pragma warning disable CS1573 // Disable warning: "
"'Parameter has no matching param tag in the XML comment'\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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
output.append("/// <summary>\n");
for (int i = 0; i < summary_lines.size(); i++) {
output.append("/// ");
output.append(summary_lines[i]);
output.append("\n");
}
output.append("/// </summary>\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)) {
output.append(" : ");
output.append(obj_types[itype.base_name].proxy_name);
} 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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
output.append(MEMBER_BEGIN "/// <summary>\n");
for (int i = 0; i < summary_lines.size(); i++) {
output.append(INDENT1 "/// ");
output.append(summary_lines[i]);
output.append("\n");
}
output.append(INDENT1 "/// </summary>");
}
}
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.cname.operator String());
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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
output.append(INDENT2 "/// <summary>\n");
for (int i = 0; i < summary_lines.size(); i++) {
output.append(INDENT2 "/// ");
output.append(summary_lines[i]);
output.append("\n");
}
output.append(INDENT2 "/// </summary>\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 + "'.");
}
if (itype.is_singleton) {
// Add the type name and the singleton pointer as static fields
output.append(MEMBER_BEGIN "private static Godot.Object singleton;\n");
output << MEMBER_BEGIN "public static Godot.Object " CS_PROPERTY_SINGLETON "\n" INDENT1 "{\n"
<< INDENT2 "get\n" INDENT2 "{\n" INDENT3 "if (singleton == null)\n"
<< INDENT4 "singleton = " C_METHOD_ENGINE_GET_SINGLETON "(typeof("
<< itype.proxy_name
<< ").Name);\n" INDENT3 "return singleton;\n" INDENT2 "}\n" INDENT1 "}\n";
output.append(MEMBER_BEGIN "private static readonly StringName " BINDINGS_NATIVE_NAME_FIELD " = \"");
output.append(itype.name);
output.append("\";\n");
} else {
// IMPORTANT: We also generate the static fields for Godot.Object instead of declaring
// them manually in the `Object.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).
// Add native name static field
if (is_derived_type) {
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_instantiable) {
// Add native constructor static field
output << MEMBER_BEGIN << "[DebuggerBrowsable(DebuggerBrowsableState.Never)]\n"
<< INDENT1 "private static readonly unsafe delegate* unmanaged<IntPtr> "
<< 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";
}
// TODO: Only generate HasGodotClassMethod and InvokeGodotClassMethod if there's any method
// Generate InvokeGodotClassMethod
output << MEMBER_BEGIN "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 "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 StringName for all class members
bool is_inherit = !itype.is_singleton && obj_types.has(itype.base_name);
//PropertyName
if (is_inherit) {
output << MEMBER_BEGIN "public new class PropertyName : " << obj_types[itype.base_name].proxy_name << ".PropertyName";
} else {
output << MEMBER_BEGIN "public class PropertyName";
}
output << "\n"
<< INDENT1 "{\n";
for (const PropertyInterface &iprop : itype.properties) {
output << INDENT2 "public static readonly StringName " << iprop.proxy_name << " = \"" << iprop.cname << "\";\n";
}
output << INDENT1 "}\n";
//MethodName
if (is_inherit) {
output << MEMBER_BEGIN "public new class MethodName : " << obj_types[itype.base_name].proxy_name << ".MethodName";
} else {
output << MEMBER_BEGIN "public class MethodName";
}
output << "\n"
<< INDENT1 "{\n";
for (const MethodInterface &imethod : itype.methods) {
output << INDENT2 "public static readonly StringName " << imethod.proxy_name << " = \"" << imethod.cname << "\";\n";
}
output << INDENT1 "}\n";
//SignalName
if (is_inherit) {
output << MEMBER_BEGIN "public new class SignalName : " << obj_types[itype.base_name].proxy_name << ".SignalName";
} else {
output << MEMBER_BEGIN "public class SignalName";
}
output << "\n"
<< INDENT1 "{\n";
for (const SignalInterface &isignal : itype.signals_) {
output << INDENT2 "public static readonly StringName " << isignal.proxy_name << " = \"" << isignal.cname << "\";\n";
}
output << INDENT1 "}\n";
output.append(CLOSE_BLOCK /* class */);
output.append("\n"
"#pragma warning restore CS1591\n"
"#pragma warning restore CS1573\n");
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<StringName, TypeInterface>::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<StringName, TypeInterface>::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_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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
p_output.append(MEMBER_BEGIN "/// <summary>\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 "/// </summary>");
}
}
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"
// TODO Remove this once we make accessor methods private/internal (they will no longer be marked as obsolete after that)
"#pragma warning disable CS0618 // Disable warning about obsolete method\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
// TODO Remove this once we make accessor methods private/internal (they will no longer be marked as obsolete after that)
"#pragma warning restore CS0618\n");
}
if (setter) {
p_output.append(INDENT2 "set\n"
// TODO Remove this once we make accessor methods private/internal (they will no longer be marked as obsolete after that)
"#pragma warning disable CS0618 // Disable warning about obsolete method\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
// TODO Remove this once we make accessor methods private/internal (they will no longer be marked as obsolete after that)
"#pragma warning restore CS0618\n");
}
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_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) {
if (p_itype.cs_in.size()) {
cs_in_statements << sformat(p_itype.cs_in, p_itype.c_type, "this",
String(), String(), String(), INDENT2);
}
icall_params += ", " + sformat(p_itype.cs_in_expr, "this");
}
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_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 (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 : <non-const default 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("<", "&lt;").replacen(">", "&gt;");
default_args_doc.append(MEMBER_BEGIN "/// <param name=\"" + param_tag_name + "\">If the parameter is null, then the default value is <c>" + param_def_arg + "</c>.</param>");
} 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;
}
// 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 Godot.Object,
// so we need to specify the type to call the static method.
p_output << "Object.";
}
p_output << ICALL_CLASSDB_GET_METHOD "(" BINDINGS_NATIVE_NAME_FIELD ", MethodName."
<< p_imethod.proxy_name
<< ");\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<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
p_output.append(MEMBER_BEGIN "/// <summary>\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 "/// </summary>");
}
}
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("\")]");
}
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<const MethodInterface *, const InternalCall *>::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_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
{
p_output.append(MEMBER_BEGIN "/// <summary>\n");
p_output.append(INDENT1 "/// ");
p_output.append("Represents the method that handles the ");
p_output.append("<see cref=\"" BINDINGS_NAMESPACE "." + p_itype.proxy_name + "." + p_isignal.proxy_name + "\"/>");
p_output.append(" event of a ");
p_output.append("<see cref=\"" BINDINGS_NAMESPACE "." + p_itype.proxy_name + "\"/>");
p_output.append(" class.\n");
p_output.append(INDENT1 "/// </summary>");
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("\")]");
}
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) {
// 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);
Vector<String> summary_lines = xml_summary.length() ? xml_summary.split("\n") : Vector<String>();
if (summary_lines.size()) {
p_output.append(MEMBER_BEGIN "/// <summary>\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 "/// </summary>");
}
}
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++;
}
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() << ") " OPEN_BLOCK;
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";
}
if (!p_icall.is_static) {
r_output << INDENT2 "if (" CS_PARAM_INSTANCE " == IntPtr.Zero)\n"
<< INDENT3 "throw new ArgumentNullException(nameof(" CS_PARAM_INSTANCE "));\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) {
r_output << "using godot_variant " << C_LOCAL_VARARG_RET " = ";
} else {
r_output << "using 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 _);\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<godot_variant.movable> 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<IntPtr> " 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++) " OPEN_BLOCK
<< 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<FileAccess> 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<StringName, TypeInterface>::ConstIterator builtin_type_match = builtin_types.find(p_typeref.cname);
if (builtin_type_match) {
return &builtin_type_match->value;
}
HashMap<StringName, TypeInterface>::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<StringName, TypeInterface>::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<StringName, TypeInterface>::ConstIterator int_match = builtin_types.find(name_cache.type_int);
ERR_FAIL_NULL_V(int_match, nullptr);
return &int_match->value;
}
return nullptr;
}
const String BindingsGenerator::_get_generic_type_parameters(const TypeInterface &p_itype, const List<TypeReference> &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 &param_type : p_generic_type_parameters) {
const TypeInterface *param_itype = _get_type_or_null(param_type);
ERR_FAIL_NULL_V(param_itype, "");
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 BindingsGenerator::_populate_object_type_interfaces() {
obj_types.clear();
List<StringName> class_list;
ClassDB::get_class_list(&class_list);
class_list.sort_custom<StringName::AlphCompare>();
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, api_type);
itype.base_name = ClassDB::get_parent_class(type_cname);
itype.is_singleton = Engine::get_singleton()->has_singleton(itype.proxy_name);
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;
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;
if (itype.is_singleton) {
itype.cs_in_expr = "Object." CS_STATIC_METHOD_GETINSTANCE "(" CS_PROPERTY_SINGLETON ")";
} else {
itype.cs_in_expr = "Object." CS_STATIC_METHOD_GETINSTANCE "(%0)";
}
itype.cs_out = "%5return (%2)%0(%1);";
itype.c_arg_in = "(void*)%s";
itype.c_type = "IntPtr";
itype.c_type_in = itype.c_type;
itype.c_type_out = "Object";
// Populate properties
List<PropertyInfo> property_list;
ClassDB::get_property_list(type_cname, &property_list, true);
HashMap<StringName, StringName> 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<MethodInfo> virtual_method_list;
ClassDB::get_virtual_methods(type_cname, &virtual_method_list, true);
List<MethodInfo> method_list;
ClassDB::get_method_list(type_cname, &method_list, true);
method_list.sort();
for (const MethodInfo &method_info : method_list) {
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;
}
MethodInterface imethod;
imethod.name = method_info.name;
imethod.cname = cname;
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 = imethod.is_virtual ? nullptr : ClassDB::get_method(type_cname, method_info.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_NONE);
}
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_NONE);
}
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<StringName, StringName>::Iterator accessor = accessor_methods.find(imethod.cname);
if (accessor) {
const PropertyInterface *accessor_property = itype.find_property_by_name(accessor->value);
// We only deprecate 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_deprecated = true;
imethod.deprecation_message = imethod.proxy_name + " is deprecated. Use the " + accessor_property->proxy_name + " property instead.";
}
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 + "'.");
// 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);
}
}
// Populate signals
const HashMap<StringName, MethodInfo> &signal_map = class_info->signal_map;
for (const KeyValue<StringName, MethodInfo> &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_NONE);
}
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<String> constants;
ClassDB::get_integer_constant_list(type_cname, &constants, true);
const HashMap<StringName, ClassDB::ClassInfo::EnumInfo> &enum_map = class_info->enum_map;
for (const KeyValue<StringName, ClassDB::ClassInfo::EnumInfo> &E : enum_map) {
StringName enum_proxy_cname = E.key;
String enum_proxy_name = 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);
ienum.is_flags = E.value.is_bitfield;
const List<StringName> &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);
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) \
{ \
itype = TypeInterface::create_value_type(String(#m_type)); \
itype.c_type_in = #m_type "*"; \
itype.c_type_out = itype.cs_type; \
itype.cs_in_expr = "&%0"; \
itype.cs_in_expr_is_unsafe = true; \
builtin_types.insert(itype.cname, itype); \
}
INSERT_STRUCT_TYPE(Vector2)
INSERT_STRUCT_TYPE(Vector2i)
INSERT_STRUCT_TYPE(Rect2)
INSERT_STRUCT_TYPE(Rect2i)
INSERT_STRUCT_TYPE(Transform2D)
INSERT_STRUCT_TYPE(Vector3)
INSERT_STRUCT_TYPE(Vector3i)
INSERT_STRUCT_TYPE(Basis)
INSERT_STRUCT_TYPE(Quaternion)
INSERT_STRUCT_TYPE(Transform3D)
INSERT_STRUCT_TYPE(AABB)
INSERT_STRUCT_TYPE(Color)
INSERT_STRUCT_TYPE(Plane)
INSERT_STRUCT_TYPE(Vector4)
INSERT_STRUCT_TYPE(Vector4i)
INSERT_STRUCT_TYPE(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 = "SignalInfo";
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 "(&%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<Variant>()";
// 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
// Re-use 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<T>/As<T> is slower, so we need this special case
itype.cs_variant_to_managed = "VariantUtils.ConvertToArrayObject(%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
// Re-use 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<T>/As<T> is slower, so we need this special case
itype.cs_variant_to_managed = "VariantUtils.ConvertToDictionaryObject(%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<String, DocData::ClassDoc>::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);
// TODO: ienum.is_flags is always false for core constants since they don't seem to support bitfield enums
List<EnumInterface>::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 = enum_itype.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<StringName> 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 = enum_itype.name;
TypeInterface::postsetup_enum_type(enum_itype);
enum_types.insert(enum_itype.cname, enum_itype);
}
}
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::_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();
enum_types.clear();
_initialize_blacklisted_methods();
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<StringName, TypeInterface> &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<String> &p_cmdline_args) {
String glue_dir_path;
const List<String>::Element *elem = p_cmdline_args.front();
while (elem) {
if (elem->get() == generate_all_glue_option) {
const List<String>::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