virtualx-engine/core/extension/extension_api_dump.cpp

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/**************************************************************************/
/* extension_api_dump.cpp */
/**************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
/**************************************************************************/
/* Copyright (c) 2014-present Godot Engine contributors (see AUTHORS.md). */
/* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */
/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. */
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/**************************************************************************/
#include "extension_api_dump.h"
2022-11-07 14:31:10 +01:00
#include "core/config/engine.h"
#include "core/core_constants.h"
#include "core/io/file_access.h"
#include "core/io/json.h"
#include "core/templates/pair.h"
#include "core/version.h"
#ifdef TOOLS_ENABLED
static String get_builtin_or_variant_type_name(const Variant::Type p_type) {
if (p_type == Variant::NIL) {
return "Variant";
} else {
return Variant::get_type_name(p_type);
}
}
static String get_property_info_type_name(const PropertyInfo &p_info) {
if (p_info.type == Variant::INT && (p_info.hint == PROPERTY_HINT_INT_IS_POINTER)) {
if (p_info.hint_string.is_empty()) {
return "void*";
} else {
return p_info.hint_string + "*";
}
}
if (p_info.type == Variant::ARRAY && (p_info.hint == PROPERTY_HINT_ARRAY_TYPE)) {
return String("typedarray::") + p_info.hint_string;
}
if (p_info.type == Variant::INT && (p_info.usage & (PROPERTY_USAGE_CLASS_IS_ENUM))) {
return String("enum::") + String(p_info.class_name);
}
if (p_info.type == Variant::INT && (p_info.usage & (PROPERTY_USAGE_CLASS_IS_BITFIELD))) {
return String("bitfield::") + String(p_info.class_name);
}
if (p_info.type == Variant::INT && (p_info.usage & PROPERTY_USAGE_ARRAY)) {
return "int";
}
if (p_info.class_name != StringName()) {
return p_info.class_name;
}
if (p_info.hint == PROPERTY_HINT_RESOURCE_TYPE) {
return p_info.hint_string;
}
if (p_info.type == Variant::NIL && (p_info.usage & PROPERTY_USAGE_NIL_IS_VARIANT)) {
return "Variant";
}
if (p_info.type == Variant::NIL) {
return "void";
}
return get_builtin_or_variant_type_name(p_info.type);
}
static String get_type_meta_name(const GodotTypeInfo::Metadata metadata) {
static const char *argmeta[11] = { "none", "int8", "int16", "int32", "int64", "uint8", "uint16", "uint32", "uint64", "float", "double" };
return argmeta[metadata];
}
Dictionary GDExtensionAPIDump::generate_extension_api() {
Dictionary api_dump;
{
//header
Dictionary header;
header["version_major"] = VERSION_MAJOR;
header["version_minor"] = VERSION_MINOR;
#if VERSION_PATCH
header["version_patch"] = VERSION_PATCH;
#else
header["version_patch"] = 0;
#endif
header["version_status"] = VERSION_STATUS;
header["version_build"] = VERSION_BUILD;
header["version_full_name"] = VERSION_FULL_NAME;
api_dump["header"] = header;
}
const uint32_t vec3_elems = 3;
const uint32_t vec4_elems = 4;
const uint32_t ptrsize_32 = 4;
const uint32_t ptrsize_64 = 8;
static const char *build_config_name[4] = { "float_32", "float_64", "double_32", "double_64" };
{
//type sizes
constexpr struct {
Variant::Type type;
uint32_t size_32_bits_real_float;
uint32_t size_64_bits_real_float;
uint32_t size_32_bits_real_double;
uint32_t size_64_bits_real_double;
// For compile-time size check.
constexpr uint32_t operator[](int index) const {
switch (index) {
#ifndef REAL_T_IS_DOUBLE
case sizeof(uint32_t):
return size_32_bits_real_float;
case sizeof(uint64_t):
return size_64_bits_real_float;
#else // REAL_T_IS_DOUBLE
case sizeof(uint32_t):
return size_32_bits_real_double;
case sizeof(uint64_t):
return size_64_bits_real_double;
#endif
}
return -1;
}
} type_size_array[Variant::VARIANT_MAX + 1] = {
{ Variant::NIL, 0, 0, 0, 0 },
{ Variant::BOOL, sizeof(uint8_t), sizeof(uint8_t), sizeof(uint8_t), sizeof(uint8_t) },
{ Variant::INT, sizeof(int64_t), sizeof(int64_t), sizeof(int64_t), sizeof(int64_t) },
{ Variant::FLOAT, sizeof(double), sizeof(double), sizeof(double), sizeof(double) },
{ Variant::STRING, ptrsize_32, ptrsize_64, ptrsize_32, ptrsize_64 },
{ Variant::VECTOR2, 2 * sizeof(float), 2 * sizeof(float), 2 * sizeof(double), 2 * sizeof(double) },
{ Variant::VECTOR2I, 2 * sizeof(int32_t), 2 * sizeof(int32_t), 2 * sizeof(int32_t), 2 * sizeof(int32_t) },
{ Variant::RECT2, 4 * sizeof(float), 4 * sizeof(float), 4 * sizeof(double), 4 * sizeof(double) },
{ Variant::RECT2I, 4 * sizeof(int32_t), 4 * sizeof(int32_t), 4 * sizeof(int32_t), 4 * sizeof(int32_t) },
{ Variant::VECTOR3, vec3_elems * sizeof(float), vec3_elems * sizeof(float), vec3_elems * sizeof(double), vec3_elems * sizeof(double) },
{ Variant::VECTOR3I, 3 * sizeof(int32_t), 3 * sizeof(int32_t), 3 * sizeof(int32_t), 3 * sizeof(int32_t) },
{ Variant::TRANSFORM2D, 6 * sizeof(float), 6 * sizeof(float), 6 * sizeof(double), 6 * sizeof(double) },
{ Variant::VECTOR4, 4 * sizeof(float), 4 * sizeof(float), 4 * sizeof(double), 4 * sizeof(double) },
{ Variant::VECTOR4I, 4 * sizeof(int32_t), 4 * sizeof(int32_t), 4 * sizeof(int32_t), 4 * sizeof(int32_t) },
{ Variant::PLANE, (vec3_elems + 1) * sizeof(float), (vec3_elems + 1) * sizeof(float), (vec3_elems + 1) * sizeof(double), (vec3_elems + 1) * sizeof(double) },
{ Variant::QUATERNION, 4 * sizeof(float), 4 * sizeof(float), 4 * sizeof(double), 4 * sizeof(double) },
{ Variant::AABB, (vec3_elems * 2) * sizeof(float), (vec3_elems * 2) * sizeof(float), (vec3_elems * 2) * sizeof(double), (vec3_elems * 2) * sizeof(double) },
{ Variant::BASIS, (vec3_elems * 3) * sizeof(float), (vec3_elems * 3) * sizeof(float), (vec3_elems * 3) * sizeof(double), (vec3_elems * 3) * sizeof(double) },
{ Variant::TRANSFORM3D, (vec3_elems * 4) * sizeof(float), (vec3_elems * 4) * sizeof(float), (vec3_elems * 4) * sizeof(double), (vec3_elems * 4) * sizeof(double) },
{ Variant::PROJECTION, (vec4_elems * 4) * sizeof(float), (vec4_elems * 4) * sizeof(float), (vec4_elems * 4) * sizeof(double), (vec4_elems * 4) * sizeof(double) },
{ Variant::COLOR, 4 * sizeof(float), 4 * sizeof(float), 4 * sizeof(float), 4 * sizeof(float) },
{ Variant::STRING_NAME, ptrsize_32, ptrsize_64, ptrsize_32, ptrsize_64 },
{ Variant::NODE_PATH, ptrsize_32, ptrsize_64, ptrsize_32, ptrsize_64 },
{ Variant::RID, sizeof(uint64_t), sizeof(uint64_t), sizeof(uint64_t), sizeof(uint64_t) },
{ Variant::OBJECT, ptrsize_32, ptrsize_64, ptrsize_32, ptrsize_64 },
{ Variant::CALLABLE, sizeof(Callable), sizeof(Callable), sizeof(Callable), sizeof(Callable) }, // Hardcoded align.
{ Variant::SIGNAL, sizeof(Signal), sizeof(Signal), sizeof(Signal), sizeof(Signal) }, // Hardcoded align.
{ Variant::DICTIONARY, ptrsize_32, ptrsize_64, ptrsize_32, ptrsize_64 },
{ Variant::ARRAY, ptrsize_32, ptrsize_64, ptrsize_32, ptrsize_64 },
{ Variant::PACKED_BYTE_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_INT32_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_INT64_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_FLOAT32_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_FLOAT64_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_STRING_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_VECTOR2_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_VECTOR3_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::PACKED_COLOR_ARRAY, ptrsize_32 * 2, ptrsize_64 * 2, ptrsize_32 * 2, ptrsize_64 * 2 },
{ Variant::VARIANT_MAX, sizeof(uint64_t) + sizeof(float) * 4, sizeof(uint64_t) + sizeof(float) * 4, sizeof(uint64_t) + sizeof(double) * 4, sizeof(uint64_t) + sizeof(double) * 4 },
};
// Validate sizes at compile time for the current build configuration.
static_assert(type_size_array[Variant::BOOL][sizeof(void *)] == sizeof(GDExtensionBool), "Size of bool mismatch");
static_assert(type_size_array[Variant::INT][sizeof(void *)] == sizeof(GDExtensionInt), "Size of int mismatch");
static_assert(type_size_array[Variant::FLOAT][sizeof(void *)] == sizeof(double), "Size of float mismatch");
static_assert(type_size_array[Variant::STRING][sizeof(void *)] == sizeof(String), "Size of String mismatch");
static_assert(type_size_array[Variant::VECTOR2][sizeof(void *)] == sizeof(Vector2), "Size of Vector2 mismatch");
static_assert(type_size_array[Variant::VECTOR2I][sizeof(void *)] == sizeof(Vector2i), "Size of Vector2i mismatch");
static_assert(type_size_array[Variant::RECT2][sizeof(void *)] == sizeof(Rect2), "Size of Rect2 mismatch");
static_assert(type_size_array[Variant::RECT2I][sizeof(void *)] == sizeof(Rect2i), "Size of Rect2i mismatch");
static_assert(type_size_array[Variant::VECTOR3][sizeof(void *)] == sizeof(Vector3), "Size of Vector3 mismatch");
static_assert(type_size_array[Variant::VECTOR3I][sizeof(void *)] == sizeof(Vector3i), "Size of Vector3i mismatch");
static_assert(type_size_array[Variant::TRANSFORM2D][sizeof(void *)] == sizeof(Transform2D), "Size of Transform2D mismatch");
static_assert(type_size_array[Variant::VECTOR4][sizeof(void *)] == sizeof(Vector4), "Size of Vector4 mismatch");
static_assert(type_size_array[Variant::VECTOR4I][sizeof(void *)] == sizeof(Vector4i), "Size of Vector4i mismatch");
static_assert(type_size_array[Variant::PLANE][sizeof(void *)] == sizeof(Plane), "Size of Plane mismatch");
static_assert(type_size_array[Variant::QUATERNION][sizeof(void *)] == sizeof(Quaternion), "Size of Quaternion mismatch");
static_assert(type_size_array[Variant::AABB][sizeof(void *)] == sizeof(AABB), "Size of AABB mismatch");
static_assert(type_size_array[Variant::BASIS][sizeof(void *)] == sizeof(Basis), "Size of Basis mismatch");
static_assert(type_size_array[Variant::TRANSFORM3D][sizeof(void *)] == sizeof(Transform3D), "Size of Transform3D mismatch");
static_assert(type_size_array[Variant::PROJECTION][sizeof(void *)] == sizeof(Projection), "Size of Projection mismatch");
static_assert(type_size_array[Variant::COLOR][sizeof(void *)] == sizeof(Color), "Size of Color mismatch");
static_assert(type_size_array[Variant::STRING_NAME][sizeof(void *)] == sizeof(StringName), "Size of StringName mismatch");
static_assert(type_size_array[Variant::NODE_PATH][sizeof(void *)] == sizeof(NodePath), "Size of NodePath mismatch");
static_assert(type_size_array[Variant::RID][sizeof(void *)] == sizeof(RID), "Size of RID mismatch");
static_assert(type_size_array[Variant::OBJECT][sizeof(void *)] == sizeof(Object *), "Size of Object mismatch");
static_assert(type_size_array[Variant::CALLABLE][sizeof(void *)] == sizeof(Callable), "Size of Callable mismatch");
static_assert(type_size_array[Variant::SIGNAL][sizeof(void *)] == sizeof(Signal), "Size of Signal mismatch");
static_assert(type_size_array[Variant::DICTIONARY][sizeof(void *)] == sizeof(Dictionary), "Size of Dictionary mismatch");
static_assert(type_size_array[Variant::ARRAY][sizeof(void *)] == sizeof(Array), "Size of Array mismatch");
static_assert(type_size_array[Variant::PACKED_BYTE_ARRAY][sizeof(void *)] == sizeof(PackedByteArray), "Size of PackedByteArray mismatch");
static_assert(type_size_array[Variant::PACKED_INT32_ARRAY][sizeof(void *)] == sizeof(PackedInt32Array), "Size of PackedInt32Array mismatch");
static_assert(type_size_array[Variant::PACKED_INT64_ARRAY][sizeof(void *)] == sizeof(PackedInt64Array), "Size of PackedInt64Array mismatch");
static_assert(type_size_array[Variant::PACKED_FLOAT32_ARRAY][sizeof(void *)] == sizeof(PackedFloat32Array), "Size of PackedFloat32Array mismatch");
static_assert(type_size_array[Variant::PACKED_FLOAT64_ARRAY][sizeof(void *)] == sizeof(PackedFloat64Array), "Size of PackedFloat64Array mismatch");
static_assert(type_size_array[Variant::PACKED_STRING_ARRAY][sizeof(void *)] == sizeof(PackedStringArray), "Size of PackedStringArray mismatch");
static_assert(type_size_array[Variant::PACKED_VECTOR2_ARRAY][sizeof(void *)] == sizeof(PackedVector2Array), "Size of PackedVector2Array mismatch");
static_assert(type_size_array[Variant::PACKED_VECTOR3_ARRAY][sizeof(void *)] == sizeof(PackedVector3Array), "Size of PackedVector3Array mismatch");
static_assert(type_size_array[Variant::PACKED_COLOR_ARRAY][sizeof(void *)] == sizeof(PackedColorArray), "Size of PackedColorArray mismatch");
static_assert(type_size_array[Variant::VARIANT_MAX][sizeof(void *)] == sizeof(Variant), "Size of Variant mismatch");
Array core_type_sizes;
for (int i = 0; i < 4; i++) {
Dictionary d;
d["build_configuration"] = build_config_name[i];
Array sizes;
for (int j = 0; j <= Variant::VARIANT_MAX; j++) {
Variant::Type t = type_size_array[j].type;
String name = t == Variant::VARIANT_MAX ? String("Variant") : Variant::get_type_name(t);
Dictionary d2;
d2["name"] = name;
uint32_t size = 0;
switch (i) {
case 0:
size = type_size_array[j].size_32_bits_real_float;
break;
case 1:
size = type_size_array[j].size_64_bits_real_float;
break;
case 2:
size = type_size_array[j].size_32_bits_real_double;
break;
case 3:
size = type_size_array[j].size_64_bits_real_double;
break;
}
d2["size"] = size;
sizes.push_back(d2);
}
d["sizes"] = sizes;
core_type_sizes.push_back(d);
}
api_dump["builtin_class_sizes"] = core_type_sizes;
}
{
// Member offsets, meta types and sizes.
#define REAL_MEMBER_OFFSET(type, member) \
{ \
type, \
member, \
"float", \
sizeof(float), \
"float", \
sizeof(float), \
"double", \
sizeof(double), \
"double", \
sizeof(double), \
}
#define INT32_MEMBER_OFFSET(type, member) \
{ \
type, \
member, \
"int32", \
sizeof(int32_t), \
"int32", \
sizeof(int32_t), \
"int32", \
sizeof(int32_t), \
"int32", \
sizeof(int32_t), \
}
#define INT32_BASED_BUILTIN_MEMBER_OFFSET(type, member, member_type, member_elems) \
{ \
type, \
member, \
member_type, \
sizeof(int32_t) * member_elems, \
member_type, \
sizeof(int32_t) * member_elems, \
member_type, \
sizeof(int32_t) * member_elems, \
member_type, \
sizeof(int32_t) * member_elems, \
}
#define REAL_BASED_BUILTIN_MEMBER_OFFSET(type, member, member_type, member_elems) \
{ \
type, \
member, \
member_type, \
sizeof(float) * member_elems, \
member_type, \
sizeof(float) * member_elems, \
member_type, \
sizeof(double) * member_elems, \
member_type, \
sizeof(double) * member_elems, \
}
struct {
Variant::Type type;
const char *member;
const char *member_meta_32_bits_real_float;
const uint32_t member_size_32_bits_real_float;
const char *member_meta_64_bits_real_float;
const uint32_t member_size_64_bits_real_float;
const char *member_meta_32_bits_real_double;
const uint32_t member_size_32_bits_real_double;
const char *member_meta_64_bits_real_double;
const uint32_t member_size_64_bits_real_double;
} member_offset_array[] = {
// Vector2
REAL_MEMBER_OFFSET(Variant::VECTOR2, "x"),
REAL_MEMBER_OFFSET(Variant::VECTOR2, "y"),
// Vector2i
INT32_MEMBER_OFFSET(Variant::VECTOR2I, "x"),
INT32_MEMBER_OFFSET(Variant::VECTOR2I, "y"),
// Rect2
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::RECT2, "position", "Vector2", 2),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::RECT2, "size", "Vector2", 2),
// Rect2i
INT32_BASED_BUILTIN_MEMBER_OFFSET(Variant::RECT2I, "position", "Vector2i", 2),
INT32_BASED_BUILTIN_MEMBER_OFFSET(Variant::RECT2I, "size", "Vector2i", 2),
// Vector3
REAL_MEMBER_OFFSET(Variant::VECTOR3, "x"),
REAL_MEMBER_OFFSET(Variant::VECTOR3, "y"),
REAL_MEMBER_OFFSET(Variant::VECTOR3, "z"),
// Vector3i
INT32_MEMBER_OFFSET(Variant::VECTOR3I, "x"),
INT32_MEMBER_OFFSET(Variant::VECTOR3I, "y"),
INT32_MEMBER_OFFSET(Variant::VECTOR3I, "z"),
// Transform2D
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::TRANSFORM2D, "x", "Vector2", 2),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::TRANSFORM2D, "y", "Vector2", 2),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::TRANSFORM2D, "origin", "Vector2", 2),
// Vector4
REAL_MEMBER_OFFSET(Variant::VECTOR4, "x"),
REAL_MEMBER_OFFSET(Variant::VECTOR4, "y"),
REAL_MEMBER_OFFSET(Variant::VECTOR4, "z"),
REAL_MEMBER_OFFSET(Variant::VECTOR4, "w"),
// Vector4i
INT32_MEMBER_OFFSET(Variant::VECTOR4I, "x"),
INT32_MEMBER_OFFSET(Variant::VECTOR4I, "y"),
INT32_MEMBER_OFFSET(Variant::VECTOR4I, "z"),
INT32_MEMBER_OFFSET(Variant::VECTOR4I, "w"),
// Plane
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::PLANE, "normal", "Vector3", vec3_elems),
REAL_MEMBER_OFFSET(Variant::PLANE, "d"),
// Quaternion
REAL_MEMBER_OFFSET(Variant::QUATERNION, "x"),
REAL_MEMBER_OFFSET(Variant::QUATERNION, "y"),
REAL_MEMBER_OFFSET(Variant::QUATERNION, "z"),
REAL_MEMBER_OFFSET(Variant::QUATERNION, "w"),
// AABB
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::AABB, "position", "Vector3", vec3_elems),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::AABB, "size", "Vector3", vec3_elems),
// Basis (remember that basis vectors are flipped!)
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::BASIS, "x", "Vector3", vec3_elems),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::BASIS, "y", "Vector3", vec3_elems),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::BASIS, "z", "Vector3", vec3_elems),
// Transform3D
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::TRANSFORM3D, "basis", "Basis", vec3_elems * 3),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::TRANSFORM3D, "origin", "Vector3", vec3_elems),
// Projection
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::PROJECTION, "x", "Vector4", vec4_elems),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::PROJECTION, "y", "Vector4", vec4_elems),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::PROJECTION, "z", "Vector4", vec4_elems),
REAL_BASED_BUILTIN_MEMBER_OFFSET(Variant::PROJECTION, "w", "Vector4", vec4_elems),
// Color (always composed of 4bytes floats)
{ Variant::COLOR, "r", "float", sizeof(float), "float", sizeof(float), "float", sizeof(float), "float", sizeof(float) },
{ Variant::COLOR, "g", "float", sizeof(float), "float", sizeof(float), "float", sizeof(float), "float", sizeof(float) },
{ Variant::COLOR, "b", "float", sizeof(float), "float", sizeof(float), "float", sizeof(float), "float", sizeof(float) },
{ Variant::COLOR, "a", "float", sizeof(float), "float", sizeof(float), "float", sizeof(float), "float", sizeof(float) },
// End marker, must stay last
{ Variant::NIL, nullptr, nullptr, 0, nullptr, 0, nullptr, 0, nullptr, 0 },
};
Array core_type_member_offsets;
for (int i = 0; i < 4; i++) {
Dictionary d;
d["build_configuration"] = build_config_name[i];
Array type_offsets;
uint32_t idx = 0;
Variant::Type previous_type = Variant::NIL;
Dictionary d2;
Array members;
uint32_t offset = 0;
while (true) {
Variant::Type t = member_offset_array[idx].type;
if (t != previous_type) {
if (previous_type != Variant::NIL) {
d2["members"] = members;
type_offsets.push_back(d2);
}
if (t == Variant::NIL) {
break;
}
String name = t == Variant::VARIANT_MAX ? String("Variant") : Variant::get_type_name(t);
d2 = Dictionary();
members = Array();
offset = 0;
d2["name"] = name;
previous_type = t;
}
Dictionary d3;
const char *member_meta = nullptr;
uint32_t member_size = 0;
switch (i) {
case 0:
member_meta = member_offset_array[idx].member_meta_32_bits_real_float;
member_size = member_offset_array[idx].member_size_32_bits_real_float;
break;
case 1:
member_meta = member_offset_array[idx].member_meta_64_bits_real_float;
member_size = member_offset_array[idx].member_size_64_bits_real_float;
break;
case 2:
member_meta = member_offset_array[idx].member_meta_32_bits_real_double;
member_size = member_offset_array[idx].member_size_32_bits_real_double;
break;
case 3:
member_meta = member_offset_array[idx].member_meta_64_bits_real_double;
member_size = member_offset_array[idx].member_size_64_bits_real_double;
break;
}
d3["member"] = member_offset_array[idx].member;
d3["offset"] = offset;
d3["meta"] = member_meta;
offset += member_size;
members.push_back(d3);
idx++;
}
d["classes"] = type_offsets;
core_type_member_offsets.push_back(d);
}
api_dump["builtin_class_member_offsets"] = core_type_member_offsets;
}
{
// Global enums and constants.
Array constants;
2022-05-09 11:47:10 +02:00
HashMap<String, List<Pair<String, int64_t>>> enum_list;
HashMap<String, bool> enum_is_bitfield;
for (int i = 0; i < CoreConstants::get_global_constant_count(); i++) {
2022-05-09 11:47:10 +02:00
int64_t value = CoreConstants::get_global_constant_value(i);
String enum_name = CoreConstants::get_global_constant_enum(i);
String name = CoreConstants::get_global_constant_name(i);
bool bitfield = CoreConstants::is_global_constant_bitfield(i);
if (!enum_name.is_empty()) {
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enum_list[enum_name].push_back(Pair<String, int64_t>(name, value));
enum_is_bitfield[enum_name] = bitfield;
} else {
Dictionary d;
d["name"] = name;
d["value"] = value;
d["is_bitfield"] = bitfield;
constants.push_back(d);
}
}
api_dump["global_constants"] = constants;
Array enums;
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for (const KeyValue<String, List<Pair<String, int64_t>>> &E : enum_list) {
Dictionary d1;
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d1["name"] = E.key;
d1["is_bitfield"] = enum_is_bitfield[E.key];
Array values;
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for (const Pair<String, int64_t> &F : E.value) {
Dictionary d2;
d2["name"] = F.first;
d2["value"] = F.second;
values.push_back(d2);
}
d1["values"] = values;
enums.push_back(d1);
}
api_dump["global_enums"] = enums;
}
{
Array utility_funcs;
List<StringName> utility_func_names;
Variant::get_utility_function_list(&utility_func_names);
for (const StringName &name : utility_func_names) {
Dictionary func;
func["name"] = String(name);
if (Variant::has_utility_function_return_value(name)) {
Variant::Type rt = Variant::get_utility_function_return_type(name);
func["return_type"] = rt == Variant::NIL ? String("Variant") : Variant::get_type_name(rt);
}
switch (Variant::get_utility_function_type(name)) {
case Variant::UTILITY_FUNC_TYPE_MATH:
func["category"] = "math";
break;
case Variant::UTILITY_FUNC_TYPE_RANDOM:
func["category"] = "random";
break;
case Variant::UTILITY_FUNC_TYPE_GENERAL:
func["category"] = "general";
break;
}
bool vararg = Variant::is_utility_function_vararg(name);
func["is_vararg"] = Variant::is_utility_function_vararg(name);
func["hash"] = Variant::get_utility_function_hash(name);
Array arguments;
int argcount = Variant::get_utility_function_argument_count(name);
for (int i = 0; i < argcount; i++) {
Dictionary arg;
String argname = vararg ? "arg" + itos(i + 1) : Variant::get_utility_function_argument_name(name, i);
arg["name"] = argname;
arg["type"] = get_builtin_or_variant_type_name(Variant::get_utility_function_argument_type(name, i));
//no default value support in utility functions
arguments.push_back(arg);
}
if (arguments.size()) {
func["arguments"] = arguments;
}
utility_funcs.push_back(func);
}
api_dump["utility_functions"] = utility_funcs;
}
{
// builtin types
Array builtins;
for (int i = 0; i < Variant::VARIANT_MAX; i++) {
if (i == Variant::OBJECT) {
continue;
}
Variant::Type type = Variant::Type(i);
Dictionary d;
d["name"] = Variant::get_type_name(type);
if (Variant::has_indexing(type)) {
d["indexing_return_type"] = get_builtin_or_variant_type_name(Variant::get_indexed_element_type(type));
}
d["is_keyed"] = Variant::is_keyed(type);
{
//members
Array members;
List<StringName> member_names;
Variant::get_member_list(type, &member_names);
for (const StringName &member_name : member_names) {
Dictionary d2;
d2["name"] = String(member_name);
d2["type"] = get_builtin_or_variant_type_name(Variant::get_member_type(type, member_name));
members.push_back(d2);
}
if (members.size()) {
d["members"] = members;
}
}
{
//constants
Array constants;
List<StringName> constant_names;
Variant::get_constants_for_type(type, &constant_names);
for (const StringName &constant_name : constant_names) {
Dictionary d2;
d2["name"] = String(constant_name);
Variant constant = Variant::get_constant_value(type, constant_name);
d2["type"] = get_builtin_or_variant_type_name(constant.get_type());
d2["value"] = constant.get_construct_string();
constants.push_back(d2);
}
if (constants.size()) {
d["constants"] = constants;
}
}
{
//enums
Array enums;
List<StringName> enum_names;
Variant::get_enums_for_type(type, &enum_names);
for (const StringName &enum_name : enum_names) {
Dictionary enum_dict;
enum_dict["name"] = String(enum_name);
List<StringName> enumeration_names;
Variant::get_enumerations_for_enum(type, enum_name, &enumeration_names);
Array values;
for (const StringName &enumeration : enumeration_names) {
Dictionary values_dict;
values_dict["name"] = String(enumeration);
values_dict["value"] = Variant::get_enum_value(type, enum_name, enumeration);
values.push_back(values_dict);
}
if (values.size()) {
enum_dict["values"] = values;
}
enums.push_back(enum_dict);
}
if (enums.size()) {
d["enums"] = enums;
}
}
{
//operators
Array operators;
for (int j = 0; j < Variant::VARIANT_MAX; j++) {
for (int k = 0; k < Variant::OP_MAX; k++) {
Variant::Type rt = Variant::get_operator_return_type(Variant::Operator(k), type, Variant::Type(j));
if (rt != Variant::NIL) {
Dictionary d2;
d2["name"] = Variant::get_operator_name(Variant::Operator(k));
if (k != Variant::OP_NEGATE && k != Variant::OP_POSITIVE && k != Variant::OP_NOT && k != Variant::OP_BIT_NEGATE) {
d2["right_type"] = get_builtin_or_variant_type_name(Variant::Type(j));
}
d2["return_type"] = get_builtin_or_variant_type_name(Variant::get_operator_return_type(Variant::Operator(k), type, Variant::Type(j)));
operators.push_back(d2);
}
}
}
if (operators.size()) {
d["operators"] = operators;
}
}
{
//methods
Array methods;
List<StringName> method_names;
Variant::get_builtin_method_list(type, &method_names);
for (const StringName &method_name : method_names) {
Dictionary d2;
d2["name"] = String(method_name);
if (Variant::has_builtin_method_return_value(type, method_name)) {
Variant::Type ret_type = Variant::get_builtin_method_return_type(type, method_name);
d2["return_type"] = ret_type == Variant::NIL ? String("Variant") : Variant::get_type_name(ret_type);
}
d2["is_vararg"] = Variant::is_builtin_method_vararg(type, method_name);
d2["is_const"] = Variant::is_builtin_method_const(type, method_name);
d2["is_static"] = Variant::is_builtin_method_static(type, method_name);
d2["hash"] = Variant::get_builtin_method_hash(type, method_name);
Vector<Variant> default_args = Variant::get_builtin_method_default_arguments(type, method_name);
Array arguments;
int argcount = Variant::get_builtin_method_argument_count(type, method_name);
for (int j = 0; j < argcount; j++) {
Dictionary d3;
d3["name"] = Variant::get_builtin_method_argument_name(type, method_name, j);
d3["type"] = get_builtin_or_variant_type_name(Variant::get_builtin_method_argument_type(type, method_name, j));
if (j >= (argcount - default_args.size())) {
int dargidx = j - (argcount - default_args.size());
d3["default_value"] = default_args[dargidx].get_construct_string();
}
arguments.push_back(d3);
}
if (arguments.size()) {
d2["arguments"] = arguments;
}
methods.push_back(d2);
}
if (methods.size()) {
d["methods"] = methods;
}
}
{
//constructors
Array constructors;
for (int j = 0; j < Variant::get_constructor_count(type); j++) {
Dictionary d2;
d2["index"] = j;
Array arguments;
int argcount = Variant::get_constructor_argument_count(type, j);
for (int k = 0; k < argcount; k++) {
Dictionary d3;
d3["name"] = Variant::get_constructor_argument_name(type, j, k);
d3["type"] = get_builtin_or_variant_type_name(Variant::get_constructor_argument_type(type, j, k));
arguments.push_back(d3);
}
if (arguments.size()) {
d2["arguments"] = arguments;
}
constructors.push_back(d2);
}
if (constructors.size()) {
d["constructors"] = constructors;
}
}
{
//destructor
d["has_destructor"] = Variant::has_destructor(type);
}
builtins.push_back(d);
}
api_dump["builtin_classes"] = builtins;
}
{
// classes
Array classes;
List<StringName> class_list;
ClassDB::get_class_list(&class_list);
class_list.sort_custom<StringName::AlphCompare>();
for (const StringName &class_name : class_list) {
Dictionary d;
d["name"] = String(class_name);
d["is_refcounted"] = ClassDB::is_parent_class(class_name, "RefCounted");
d["is_instantiable"] = ClassDB::can_instantiate(class_name);
StringName parent_class = ClassDB::get_parent_class(class_name);
if (parent_class != StringName()) {
d["inherits"] = String(parent_class);
}
{
ClassDB::APIType api = ClassDB::get_api_type(class_name);
static const char *api_type[5] = { "core", "editor", "extension", "editor_extension" };
d["api_type"] = api_type[api];
}
{
//constants
Array constants;
List<String> constant_list;
ClassDB::get_integer_constant_list(class_name, &constant_list, true);
for (const String &F : constant_list) {
StringName enum_name = ClassDB::get_integer_constant_enum(class_name, F);
if (enum_name != StringName()) {
continue; //enums will be handled on their own
}
Dictionary d2;
d2["name"] = String(F);
d2["value"] = ClassDB::get_integer_constant(class_name, F);
constants.push_back(d2);
}
if (constants.size()) {
d["constants"] = constants;
}
}
{
//enum
Array enums;
List<StringName> enum_list;
ClassDB::get_enum_list(class_name, &enum_list, true);
for (const StringName &F : enum_list) {
Dictionary d2;
d2["name"] = String(F);
d2["is_bitfield"] = ClassDB::is_enum_bitfield(class_name, F);
Array values;
List<StringName> enum_constant_list;
ClassDB::get_enum_constants(class_name, F, &enum_constant_list, true);
for (List<StringName>::Element *G = enum_constant_list.front(); G; G = G->next()) {
Dictionary d3;
d3["name"] = String(G->get());
d3["value"] = ClassDB::get_integer_constant(class_name, G->get());
values.push_back(d3);
}
d2["values"] = values;
enums.push_back(d2);
}
if (enums.size()) {
d["enums"] = enums;
}
}
{
//methods
Array methods;
List<MethodInfo> method_list;
ClassDB::get_method_list(class_name, &method_list, true);
for (const MethodInfo &F : method_list) {
StringName method_name = F.name;
if ((F.flags & METHOD_FLAG_VIRTUAL) && !(F.flags & METHOD_FLAG_OBJECT_CORE)) {
//virtual method
const MethodInfo &mi = F;
Dictionary d2;
d2["name"] = String(method_name);
d2["is_const"] = (F.flags & METHOD_FLAG_CONST) ? true : false;
d2["is_static"] = (F.flags & METHOD_FLAG_STATIC) ? true : false;
d2["is_vararg"] = false;
d2["is_virtual"] = true;
// virtual functions have no hash since no MethodBind is involved
bool has_return = mi.return_val.type != Variant::NIL || (mi.return_val.usage & PROPERTY_USAGE_NIL_IS_VARIANT);
Array arguments;
for (int i = (has_return ? -1 : 0); i < mi.arguments.size(); i++) {
PropertyInfo pinfo = i == -1 ? mi.return_val : mi.arguments[i];
Dictionary d3;
if (i >= 0) {
d3["name"] = pinfo.name;
}
d3["type"] = get_property_info_type_name(pinfo);
if (mi.get_argument_meta(i) > 0) {
d3["meta"] = get_type_meta_name((GodotTypeInfo::Metadata)mi.get_argument_meta(i));
}
if (i == -1) {
d2["return_value"] = d3;
} else {
arguments.push_back(d3);
}
}
if (arguments.size()) {
d2["arguments"] = arguments;
}
methods.push_back(d2);
} else if (F.name.begins_with("_")) {
//hidden method, ignore
} else {
Dictionary d2;
d2["name"] = String(method_name);
MethodBind *method = ClassDB::get_method(class_name, method_name);
if (!method) {
continue;
}
d2["is_const"] = method->is_const();
d2["is_vararg"] = method->is_vararg();
d2["is_static"] = method->is_static();
d2["is_virtual"] = false;
d2["hash"] = method->get_hash();
Vector<Variant> default_args = method->get_default_arguments();
Array arguments;
for (int i = (method->has_return() ? -1 : 0); i < method->get_argument_count(); i++) {
PropertyInfo pinfo = i == -1 ? method->get_return_info() : method->get_argument_info(i);
Dictionary d3;
if (i >= 0) {
d3["name"] = pinfo.name;
}
d3["type"] = get_property_info_type_name(pinfo);
if (method->get_argument_meta(i) > 0) {
d3["meta"] = get_type_meta_name(method->get_argument_meta(i));
}
if (i >= 0 && i >= (method->get_argument_count() - default_args.size())) {
int dargidx = i - (method->get_argument_count() - default_args.size());
d3["default_value"] = default_args[dargidx].get_construct_string();
}
if (i == -1) {
d2["return_value"] = d3;
} else {
arguments.push_back(d3);
}
}
if (arguments.size()) {
d2["arguments"] = arguments;
}
methods.push_back(d2);
}
}
if (methods.size()) {
d["methods"] = methods;
}
}
{
//signals
Array signals;
List<MethodInfo> signal_list;
ClassDB::get_signal_list(class_name, &signal_list, true);
for (const MethodInfo &F : signal_list) {
StringName signal_name = F.name;
Dictionary d2;
d2["name"] = String(signal_name);
Array arguments;
for (int i = 0; i < F.arguments.size(); i++) {
Dictionary d3;
d3["name"] = F.arguments[i].name;
d3["type"] = get_property_info_type_name(F.arguments[i]);
if (F.get_argument_meta(i) > 0) {
d3["meta"] = get_type_meta_name((GodotTypeInfo::Metadata)F.get_argument_meta(i));
}
arguments.push_back(d3);
}
if (arguments.size()) {
d2["arguments"] = arguments;
}
signals.push_back(d2);
}
if (signals.size()) {
d["signals"] = signals;
}
}
{
//properties
Array properties;
List<PropertyInfo> property_list;
ClassDB::get_property_list(class_name, &property_list, true);
for (const PropertyInfo &F : property_list) {
if (F.usage & PROPERTY_USAGE_CATEGORY || F.usage & PROPERTY_USAGE_GROUP || F.usage & PROPERTY_USAGE_SUBGROUP || (F.type == Variant::NIL && F.usage & PROPERTY_USAGE_ARRAY)) {
continue; //not real properties
}
if (F.name.begins_with("_")) {
continue; //hidden property
}
if (F.name.find("/") >= 0) {
// Ignore properties with '/' (slash) in the name. These are only meant for use in the inspector.
continue;
}
StringName property_name = F.name;
Dictionary d2;
d2["type"] = get_property_info_type_name(F);
d2["name"] = String(property_name);
StringName setter = ClassDB::get_property_setter(class_name, F.name);
if (!(setter == "")) {
d2["setter"] = setter;
}
StringName getter = ClassDB::get_property_getter(class_name, F.name);
if (!(getter == "")) {
d2["getter"] = getter;
}
int index = ClassDB::get_property_index(class_name, F.name);
if (index != -1) {
d2["index"] = index;
}
properties.push_back(d2);
}
if (properties.size()) {
d["properties"] = properties;
}
}
classes.push_back(d);
}
api_dump["classes"] = classes;
}
{
// singletons
Array singletons;
List<Engine::Singleton> singleton_list;
Engine::get_singleton()->get_singletons(&singleton_list);
for (const Engine::Singleton &s : singleton_list) {
Dictionary d;
d["name"] = s.name;
if (s.class_name != StringName()) {
d["type"] = String(s.class_name);
} else {
d["type"] = String(s.ptr->get_class());
}
singletons.push_back(d);
}
if (singletons.size()) {
api_dump["singletons"] = singletons;
}
}
{
Array native_structures;
List<StringName> native_structs;
ClassDB::get_native_struct_list(&native_structs);
native_structs.sort_custom<StringName::AlphCompare>();
for (const StringName &E : native_structs) {
String code = ClassDB::get_native_struct_code(E);
Dictionary d;
d["name"] = String(E);
d["format"] = code;
native_structures.push_back(d);
}
api_dump["native_structures"] = native_structures;
}
return api_dump;
}
void GDExtensionAPIDump::generate_extension_json_file(const String &p_path) {
Dictionary api = generate_extension_api();
Ref<JSON> json;
json.instantiate();
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String text = json->stringify(api, "\t", false) + "\n";
Ref<FileAccess> fa = FileAccess::open(p_path, FileAccess::WRITE);
ERR_FAIL_COND_MSG(fa.is_null(), vformat("Cannot open file '%s' for writing.", p_path));
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fa->store_string(text);
}
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#endif // TOOLS_ENABLED