godot/core/variant/variant.cpp
George Marques 511a4b761c
GDScript: Fix setter being called in chains for shared types
When a type is shared (i.e. passed by reference) it doesn't need to be
called in a setter chain (e.g. `a.b.c = 0`) since it will be updated in
place.

This commit adds an instruction that jumps when the value is shared so
it can be used to skip those cases and avoid redundant calls of setters.
It also solves issues when assigning to sub-properties of read-only
properties.
2022-06-27 12:09:51 -03:00

3474 lines
82 KiB
C++

/*************************************************************************/
/* variant.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 "variant.h"
#include "core/core_string_names.h"
#include "core/debugger/engine_debugger.h"
#include "core/io/json.h"
#include "core/io/marshalls.h"
#include "core/io/resource.h"
#include "core/math/math_funcs.h"
#include "core/string/print_string.h"
#include "core/variant/variant_parser.h"
String Variant::get_type_name(Variant::Type p_type) {
switch (p_type) {
case NIL: {
return "Nil";
} break;
// atomic types
case BOOL: {
return "bool";
} break;
case INT: {
return "int";
} break;
case FLOAT: {
return "float";
} break;
case STRING: {
return "String";
} break;
// math types
case VECTOR2: {
return "Vector2";
} break;
case VECTOR2I: {
return "Vector2i";
} break;
case RECT2: {
return "Rect2";
} break;
case RECT2I: {
return "Rect2i";
} break;
case TRANSFORM2D: {
return "Transform2D";
} break;
case VECTOR3: {
return "Vector3";
} break;
case VECTOR3I: {
return "Vector3i";
} break;
case PLANE: {
return "Plane";
} break;
case AABB: {
return "AABB";
} break;
case QUATERNION: {
return "Quaternion";
} break;
case BASIS: {
return "Basis";
} break;
case TRANSFORM3D: {
return "Transform3D";
} break;
// misc types
case COLOR: {
return "Color";
} break;
case RID: {
return "RID";
} break;
case OBJECT: {
return "Object";
} break;
case CALLABLE: {
return "Callable";
} break;
case SIGNAL: {
return "Signal";
} break;
case STRING_NAME: {
return "StringName";
} break;
case NODE_PATH: {
return "NodePath";
} break;
case DICTIONARY: {
return "Dictionary";
} break;
case ARRAY: {
return "Array";
} break;
// arrays
case PACKED_BYTE_ARRAY: {
return "PackedByteArray";
} break;
case PACKED_INT32_ARRAY: {
return "PackedInt32Array";
} break;
case PACKED_INT64_ARRAY: {
return "PackedInt64Array";
} break;
case PACKED_FLOAT32_ARRAY: {
return "PackedFloat32Array";
} break;
case PACKED_FLOAT64_ARRAY: {
return "PackedFloat64Array";
} break;
case PACKED_STRING_ARRAY: {
return "PackedStringArray";
} break;
case PACKED_VECTOR2_ARRAY: {
return "PackedVector2Array";
} break;
case PACKED_VECTOR3_ARRAY: {
return "PackedVector3Array";
} break;
case PACKED_COLOR_ARRAY: {
return "PackedColorArray";
} break;
default: {
}
}
return "";
}
bool Variant::can_convert(Variant::Type p_type_from, Variant::Type p_type_to) {
if (p_type_from == p_type_to) {
return true;
}
if (p_type_to == NIL) { //nil can convert to anything
return true;
}
if (p_type_from == NIL) {
return (p_type_to == OBJECT);
}
const Type *valid_types = nullptr;
const Type *invalid_types = nullptr;
switch (p_type_to) {
case BOOL: {
static const Type valid[] = {
INT,
FLOAT,
STRING,
NIL,
};
valid_types = valid;
} break;
case INT: {
static const Type valid[] = {
BOOL,
FLOAT,
STRING,
NIL,
};
valid_types = valid;
} break;
case FLOAT: {
static const Type valid[] = {
BOOL,
INT,
STRING,
NIL,
};
valid_types = valid;
} break;
case STRING: {
static const Type invalid[] = {
OBJECT,
NIL
};
invalid_types = invalid;
} break;
case VECTOR2: {
static const Type valid[] = {
VECTOR2I,
NIL,
};
valid_types = valid;
} break;
case VECTOR2I: {
static const Type valid[] = {
VECTOR2,
NIL,
};
valid_types = valid;
} break;
case RECT2: {
static const Type valid[] = {
RECT2I,
NIL,
};
valid_types = valid;
} break;
case RECT2I: {
static const Type valid[] = {
RECT2,
NIL,
};
valid_types = valid;
} break;
case TRANSFORM2D: {
static const Type valid[] = {
TRANSFORM3D,
NIL
};
valid_types = valid;
} break;
case VECTOR3: {
static const Type valid[] = {
VECTOR3I,
NIL,
};
valid_types = valid;
} break;
case VECTOR3I: {
static const Type valid[] = {
VECTOR3,
NIL,
};
valid_types = valid;
} break;
case QUATERNION: {
static const Type valid[] = {
BASIS,
NIL
};
valid_types = valid;
} break;
case BASIS: {
static const Type valid[] = {
QUATERNION,
NIL
};
valid_types = valid;
} break;
case TRANSFORM3D: {
static const Type valid[] = {
TRANSFORM2D,
QUATERNION,
BASIS,
NIL
};
valid_types = valid;
} break;
case COLOR: {
static const Type valid[] = {
STRING,
INT,
NIL,
};
valid_types = valid;
} break;
case RID: {
static const Type valid[] = {
OBJECT,
NIL
};
valid_types = valid;
} break;
case OBJECT: {
static const Type valid[] = {
NIL
};
valid_types = valid;
} break;
case STRING_NAME: {
static const Type valid[] = {
STRING,
NIL
};
valid_types = valid;
} break;
case NODE_PATH: {
static const Type valid[] = {
STRING,
NIL
};
valid_types = valid;
} break;
case ARRAY: {
static const Type valid[] = {
PACKED_BYTE_ARRAY,
PACKED_INT32_ARRAY,
PACKED_INT64_ARRAY,
PACKED_FLOAT32_ARRAY,
PACKED_FLOAT64_ARRAY,
PACKED_STRING_ARRAY,
PACKED_COLOR_ARRAY,
PACKED_VECTOR2_ARRAY,
PACKED_VECTOR3_ARRAY,
NIL
};
valid_types = valid;
} break;
// arrays
case PACKED_BYTE_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_INT32_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_INT64_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_FLOAT32_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_FLOAT64_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_STRING_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_VECTOR2_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_VECTOR3_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_COLOR_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
default: {
}
}
if (valid_types) {
int i = 0;
while (valid_types[i] != NIL) {
if (p_type_from == valid_types[i]) {
return true;
}
i++;
}
} else if (invalid_types) {
int i = 0;
while (invalid_types[i] != NIL) {
if (p_type_from == invalid_types[i]) {
return false;
}
i++;
}
return true;
}
return false;
}
bool Variant::can_convert_strict(Variant::Type p_type_from, Variant::Type p_type_to) {
if (p_type_from == p_type_to) {
return true;
}
if (p_type_to == NIL) { //nil can convert to anything
return true;
}
if (p_type_from == NIL) {
return (p_type_to == OBJECT);
}
const Type *valid_types = nullptr;
switch (p_type_to) {
case BOOL: {
static const Type valid[] = {
INT,
FLOAT,
//STRING,
NIL,
};
valid_types = valid;
} break;
case INT: {
static const Type valid[] = {
BOOL,
FLOAT,
//STRING,
NIL,
};
valid_types = valid;
} break;
case FLOAT: {
static const Type valid[] = {
BOOL,
INT,
//STRING,
NIL,
};
valid_types = valid;
} break;
case STRING: {
static const Type valid[] = {
NODE_PATH,
STRING_NAME,
NIL
};
valid_types = valid;
} break;
case VECTOR2: {
static const Type valid[] = {
VECTOR2I,
NIL,
};
valid_types = valid;
} break;
case VECTOR2I: {
static const Type valid[] = {
VECTOR2,
NIL,
};
valid_types = valid;
} break;
case RECT2: {
static const Type valid[] = {
RECT2I,
NIL,
};
valid_types = valid;
} break;
case RECT2I: {
static const Type valid[] = {
RECT2,
NIL,
};
valid_types = valid;
} break;
case TRANSFORM2D: {
static const Type valid[] = {
TRANSFORM3D,
NIL
};
valid_types = valid;
} break;
case VECTOR3: {
static const Type valid[] = {
VECTOR3I,
NIL,
};
valid_types = valid;
} break;
case VECTOR3I: {
static const Type valid[] = {
VECTOR3,
NIL,
};
valid_types = valid;
} break;
case QUATERNION: {
static const Type valid[] = {
BASIS,
NIL
};
valid_types = valid;
} break;
case BASIS: {
static const Type valid[] = {
QUATERNION,
NIL
};
valid_types = valid;
} break;
case TRANSFORM3D: {
static const Type valid[] = {
TRANSFORM2D,
QUATERNION,
BASIS,
NIL
};
valid_types = valid;
} break;
case COLOR: {
static const Type valid[] = {
STRING,
INT,
NIL,
};
valid_types = valid;
} break;
case RID: {
static const Type valid[] = {
OBJECT,
NIL
};
valid_types = valid;
} break;
case OBJECT: {
static const Type valid[] = {
NIL
};
valid_types = valid;
} break;
case STRING_NAME: {
static const Type valid[] = {
STRING,
NIL
};
valid_types = valid;
} break;
case NODE_PATH: {
static const Type valid[] = {
STRING,
NIL
};
valid_types = valid;
} break;
case ARRAY: {
static const Type valid[] = {
PACKED_BYTE_ARRAY,
PACKED_INT32_ARRAY,
PACKED_INT64_ARRAY,
PACKED_FLOAT32_ARRAY,
PACKED_FLOAT64_ARRAY,
PACKED_STRING_ARRAY,
PACKED_COLOR_ARRAY,
PACKED_VECTOR2_ARRAY,
PACKED_VECTOR3_ARRAY,
NIL
};
valid_types = valid;
} break;
// arrays
case PACKED_BYTE_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_INT32_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_INT64_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_FLOAT32_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_FLOAT64_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_STRING_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_VECTOR2_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_VECTOR3_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
case PACKED_COLOR_ARRAY: {
static const Type valid[] = {
ARRAY,
NIL
};
valid_types = valid;
} break;
default: {
}
}
if (valid_types) {
int i = 0;
while (valid_types[i] != NIL) {
if (p_type_from == valid_types[i]) {
return true;
}
i++;
}
}
return false;
}
bool Variant::operator==(const Variant &p_variant) const {
return hash_compare(p_variant);
}
bool Variant::operator!=(const Variant &p_variant) const {
// Don't use `!hash_compare(p_variant)` given it makes use of OP_EQUAL
if (type != p_variant.type) { //evaluation of operator== needs to be more strict
return true;
}
bool v;
Variant r;
evaluate(OP_NOT_EQUAL, *this, p_variant, r, v);
return r;
}
bool Variant::operator<(const Variant &p_variant) const {
if (type != p_variant.type) { //if types differ, then order by type first
return type < p_variant.type;
}
bool v;
Variant r;
evaluate(OP_LESS, *this, p_variant, r, v);
return r;
}
bool Variant::is_zero() const {
switch (type) {
case NIL: {
return true;
} break;
// atomic types
case BOOL: {
return !(_data._bool);
} break;
case INT: {
return _data._int == 0;
} break;
case FLOAT: {
return _data._float == 0;
} break;
case STRING: {
return *reinterpret_cast<const String *>(_data._mem) == String();
} break;
// math types
case VECTOR2: {
return *reinterpret_cast<const Vector2 *>(_data._mem) == Vector2();
} break;
case VECTOR2I: {
return *reinterpret_cast<const Vector2i *>(_data._mem) == Vector2i();
} break;
case RECT2: {
return *reinterpret_cast<const Rect2 *>(_data._mem) == Rect2();
} break;
case RECT2I: {
return *reinterpret_cast<const Rect2i *>(_data._mem) == Rect2i();
} break;
case TRANSFORM2D: {
return *_data._transform2d == Transform2D();
} break;
case VECTOR3: {
return *reinterpret_cast<const Vector3 *>(_data._mem) == Vector3();
} break;
case VECTOR3I: {
return *reinterpret_cast<const Vector3i *>(_data._mem) == Vector3i();
} break;
case PLANE: {
return *reinterpret_cast<const Plane *>(_data._mem) == Plane();
} break;
case AABB: {
return *_data._aabb == ::AABB();
} break;
case QUATERNION: {
return *reinterpret_cast<const Quaternion *>(_data._mem) == Quaternion();
} break;
case BASIS: {
return *_data._basis == Basis();
} break;
case TRANSFORM3D: {
return *_data._transform3d == Transform3D();
} break;
// misc types
case COLOR: {
return *reinterpret_cast<const Color *>(_data._mem) == Color();
} break;
case RID: {
return *reinterpret_cast<const ::RID *>(_data._mem) == ::RID();
} break;
case OBJECT: {
return _get_obj().obj == nullptr;
} break;
case CALLABLE: {
return reinterpret_cast<const Callable *>(_data._mem)->is_null();
} break;
case SIGNAL: {
return reinterpret_cast<const Signal *>(_data._mem)->is_null();
} break;
case STRING_NAME: {
return *reinterpret_cast<const StringName *>(_data._mem) != StringName();
} break;
case NODE_PATH: {
return reinterpret_cast<const NodePath *>(_data._mem)->is_empty();
} break;
case DICTIONARY: {
return reinterpret_cast<const Dictionary *>(_data._mem)->is_empty();
} break;
case ARRAY: {
return reinterpret_cast<const Array *>(_data._mem)->is_empty();
} break;
// arrays
case PACKED_BYTE_ARRAY: {
return PackedArrayRef<uint8_t>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_INT32_ARRAY: {
return PackedArrayRef<int32_t>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_INT64_ARRAY: {
return PackedArrayRef<int64_t>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_FLOAT32_ARRAY: {
return PackedArrayRef<float>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_FLOAT64_ARRAY: {
return PackedArrayRef<double>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_STRING_ARRAY: {
return PackedArrayRef<String>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_VECTOR2_ARRAY: {
return PackedArrayRef<Vector2>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_VECTOR3_ARRAY: {
return PackedArrayRef<Vector3>::get_array(_data.packed_array).size() == 0;
} break;
case PACKED_COLOR_ARRAY: {
return PackedArrayRef<Color>::get_array(_data.packed_array).size() == 0;
} break;
default: {
}
}
return false;
}
bool Variant::is_one() const {
switch (type) {
case NIL: {
return true;
} break;
// atomic types
case BOOL: {
return _data._bool;
} break;
case INT: {
return _data._int == 1;
} break;
case FLOAT: {
return _data._float == 1;
} break;
case VECTOR2: {
return *reinterpret_cast<const Vector2 *>(_data._mem) == Vector2(1, 1);
} break;
case VECTOR2I: {
return *reinterpret_cast<const Vector2i *>(_data._mem) == Vector2i(1, 1);
} break;
case RECT2: {
return *reinterpret_cast<const Rect2 *>(_data._mem) == Rect2(1, 1, 1, 1);
} break;
case RECT2I: {
return *reinterpret_cast<const Rect2i *>(_data._mem) == Rect2i(1, 1, 1, 1);
} break;
case VECTOR3: {
return *reinterpret_cast<const Vector3 *>(_data._mem) == Vector3(1, 1, 1);
} break;
case VECTOR3I: {
return *reinterpret_cast<const Vector3i *>(_data._mem) == Vector3i(1, 1, 1);
} break;
case PLANE: {
return *reinterpret_cast<const Plane *>(_data._mem) == Plane(1, 1, 1, 1);
} break;
case COLOR: {
return *reinterpret_cast<const Color *>(_data._mem) == Color(1, 1, 1, 1);
} break;
default: {
return !is_zero();
}
}
return false;
}
bool Variant::is_null() const {
if (type == OBJECT && _get_obj().obj) {
return false;
} else {
return true;
}
}
bool Variant::initialize_ref(Object *p_object) {
RefCounted *ref_counted = const_cast<RefCounted *>(static_cast<const RefCounted *>(p_object));
if (!ref_counted->init_ref()) {
return false;
}
return true;
}
void Variant::reference(const Variant &p_variant) {
switch (type) {
case NIL:
case BOOL:
case INT:
case FLOAT:
break;
default:
clear();
}
type = p_variant.type;
switch (p_variant.type) {
case NIL: {
// none
} break;
// atomic types
case BOOL: {
_data._bool = p_variant._data._bool;
} break;
case INT: {
_data._int = p_variant._data._int;
} break;
case FLOAT: {
_data._float = p_variant._data._float;
} break;
case STRING: {
memnew_placement(_data._mem, String(*reinterpret_cast<const String *>(p_variant._data._mem)));
} break;
// math types
case VECTOR2: {
memnew_placement(_data._mem, Vector2(*reinterpret_cast<const Vector2 *>(p_variant._data._mem)));
} break;
case VECTOR2I: {
memnew_placement(_data._mem, Vector2i(*reinterpret_cast<const Vector2i *>(p_variant._data._mem)));
} break;
case RECT2: {
memnew_placement(_data._mem, Rect2(*reinterpret_cast<const Rect2 *>(p_variant._data._mem)));
} break;
case RECT2I: {
memnew_placement(_data._mem, Rect2i(*reinterpret_cast<const Rect2i *>(p_variant._data._mem)));
} break;
case TRANSFORM2D: {
_data._transform2d = memnew(Transform2D(*p_variant._data._transform2d));
} break;
case VECTOR3: {
memnew_placement(_data._mem, Vector3(*reinterpret_cast<const Vector3 *>(p_variant._data._mem)));
} break;
case VECTOR3I: {
memnew_placement(_data._mem, Vector3i(*reinterpret_cast<const Vector3i *>(p_variant._data._mem)));
} break;
case PLANE: {
memnew_placement(_data._mem, Plane(*reinterpret_cast<const Plane *>(p_variant._data._mem)));
} break;
case AABB: {
_data._aabb = memnew(::AABB(*p_variant._data._aabb));
} break;
case QUATERNION: {
memnew_placement(_data._mem, Quaternion(*reinterpret_cast<const Quaternion *>(p_variant._data._mem)));
} break;
case BASIS: {
_data._basis = memnew(Basis(*p_variant._data._basis));
} break;
case TRANSFORM3D: {
_data._transform3d = memnew(Transform3D(*p_variant._data._transform3d));
} break;
// misc types
case COLOR: {
memnew_placement(_data._mem, Color(*reinterpret_cast<const Color *>(p_variant._data._mem)));
} break;
case RID: {
memnew_placement(_data._mem, ::RID(*reinterpret_cast<const ::RID *>(p_variant._data._mem)));
} break;
case OBJECT: {
memnew_placement(_data._mem, ObjData);
if (p_variant._get_obj().obj && p_variant._get_obj().id.is_ref_counted()) {
RefCounted *ref_counted = static_cast<RefCounted *>(p_variant._get_obj().obj);
if (!ref_counted->reference()) {
_get_obj().obj = nullptr;
_get_obj().id = ObjectID();
break;
}
}
_get_obj().obj = const_cast<Object *>(p_variant._get_obj().obj);
_get_obj().id = p_variant._get_obj().id;
} break;
case CALLABLE: {
memnew_placement(_data._mem, Callable(*reinterpret_cast<const Callable *>(p_variant._data._mem)));
} break;
case SIGNAL: {
memnew_placement(_data._mem, Signal(*reinterpret_cast<const Signal *>(p_variant._data._mem)));
} break;
case STRING_NAME: {
memnew_placement(_data._mem, StringName(*reinterpret_cast<const StringName *>(p_variant._data._mem)));
} break;
case NODE_PATH: {
memnew_placement(_data._mem, NodePath(*reinterpret_cast<const NodePath *>(p_variant._data._mem)));
} break;
case DICTIONARY: {
memnew_placement(_data._mem, Dictionary(*reinterpret_cast<const Dictionary *>(p_variant._data._mem)));
} break;
case ARRAY: {
memnew_placement(_data._mem, Array(*reinterpret_cast<const Array *>(p_variant._data._mem)));
} break;
// arrays
case PACKED_BYTE_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<uint8_t> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<uint8_t>::create();
}
} break;
case PACKED_INT32_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<int32_t> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<int32_t>::create();
}
} break;
case PACKED_INT64_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<int64_t> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<int64_t>::create();
}
} break;
case PACKED_FLOAT32_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<float> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<float>::create();
}
} break;
case PACKED_FLOAT64_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<double> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<double>::create();
}
} break;
case PACKED_STRING_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<String> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<String>::create();
}
} break;
case PACKED_VECTOR2_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<Vector2> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<Vector2>::create();
}
} break;
case PACKED_VECTOR3_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<Vector3> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<Vector3>::create();
}
} break;
case PACKED_COLOR_ARRAY: {
_data.packed_array = static_cast<PackedArrayRef<Color> *>(p_variant._data.packed_array)->reference();
if (!_data.packed_array) {
_data.packed_array = PackedArrayRef<Color>::create();
}
} break;
default: {
}
}
}
void Variant::zero() {
switch (type) {
case NIL:
break;
case BOOL:
this->_data._bool = false;
break;
case INT:
this->_data._int = 0;
break;
case FLOAT:
this->_data._float = 0;
break;
case VECTOR2:
*reinterpret_cast<Vector2 *>(this->_data._mem) = Vector2();
break;
case VECTOR2I:
*reinterpret_cast<Vector2i *>(this->_data._mem) = Vector2i();
break;
case RECT2:
*reinterpret_cast<Rect2 *>(this->_data._mem) = Rect2();
break;
case RECT2I:
*reinterpret_cast<Rect2i *>(this->_data._mem) = Rect2i();
break;
case VECTOR3:
*reinterpret_cast<Vector3 *>(this->_data._mem) = Vector3();
break;
case VECTOR3I:
*reinterpret_cast<Vector3i *>(this->_data._mem) = Vector3i();
break;
case PLANE:
*reinterpret_cast<Plane *>(this->_data._mem) = Plane();
break;
case QUATERNION:
*reinterpret_cast<Quaternion *>(this->_data._mem) = Quaternion();
break;
case COLOR:
*reinterpret_cast<Color *>(this->_data._mem) = Color();
break;
default:
this->clear();
break;
}
}
void Variant::_clear_internal() {
switch (type) {
case STRING: {
reinterpret_cast<String *>(_data._mem)->~String();
} break;
/*
// no point, they don't allocate memory
VECTOR3,
PLANE,
QUATERNION,
COLOR,
VECTOR2,
RECT2
*/
case TRANSFORM2D: {
memdelete(_data._transform2d);
} break;
case AABB: {
memdelete(_data._aabb);
} break;
case BASIS: {
memdelete(_data._basis);
} break;
case TRANSFORM3D: {
memdelete(_data._transform3d);
} break;
// misc types
case STRING_NAME: {
reinterpret_cast<StringName *>(_data._mem)->~StringName();
} break;
case NODE_PATH: {
reinterpret_cast<NodePath *>(_data._mem)->~NodePath();
} break;
case OBJECT: {
if (_get_obj().id.is_ref_counted()) {
//we are safe that there is a reference here
RefCounted *ref_counted = static_cast<RefCounted *>(_get_obj().obj);
if (ref_counted->unreference()) {
memdelete(ref_counted);
}
}
_get_obj().obj = nullptr;
_get_obj().id = ObjectID();
} break;
case RID: {
// not much need probably
// Can't seem to use destructor + scoping operator, so hack.
typedef ::RID RID_Class;
reinterpret_cast<RID_Class *>(_data._mem)->~RID_Class();
} break;
case CALLABLE: {
reinterpret_cast<Callable *>(_data._mem)->~Callable();
} break;
case SIGNAL: {
reinterpret_cast<Signal *>(_data._mem)->~Signal();
} break;
case DICTIONARY: {
reinterpret_cast<Dictionary *>(_data._mem)->~Dictionary();
} break;
case ARRAY: {
reinterpret_cast<Array *>(_data._mem)->~Array();
} break;
// arrays
case PACKED_BYTE_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_INT32_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_INT64_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_FLOAT32_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_FLOAT64_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_STRING_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_VECTOR2_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_VECTOR3_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
case PACKED_COLOR_ARRAY: {
PackedArrayRefBase::destroy(_data.packed_array);
} break;
default: {
} /* not needed */
}
}
Variant::operator signed int() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator unsigned int() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator int64_t() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator uint64_t() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator ObjectID() const {
if (type == INT) {
return ObjectID(_data._int);
} else if (type == OBJECT) {
return _get_obj().id;
} else {
return ObjectID();
}
}
#ifdef NEED_LONG_INT
Variant::operator signed long() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
return 0;
}
Variant::operator unsigned long() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
return 0;
}
#endif
Variant::operator signed short() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator unsigned short() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator signed char() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator unsigned char() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1 : 0;
case INT:
return _data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_int();
default: {
return 0;
}
}
}
Variant::operator char32_t() const {
return operator unsigned int();
}
Variant::operator float() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1.0 : 0.0;
case INT:
return (float)_data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_float();
default: {
return 0;
}
}
}
Variant::operator double() const {
switch (type) {
case NIL:
return 0;
case BOOL:
return _data._bool ? 1.0 : 0.0;
case INT:
return (double)_data._int;
case FLOAT:
return _data._float;
case STRING:
return operator String().to_float();
default: {
return 0;
}
}
}
Variant::operator StringName() const {
if (type == STRING_NAME) {
return *reinterpret_cast<const StringName *>(_data._mem);
} else if (type == STRING) {
return *reinterpret_cast<const String *>(_data._mem);
}
return StringName();
}
struct _VariantStrPair {
String key;
String value;
bool operator<(const _VariantStrPair &p) const {
return key < p.key;
}
};
Variant::operator String() const {
return stringify(0);
}
String stringify_variant_clean(const Variant p_variant, int recursion_count) {
String s = p_variant.stringify(recursion_count);
// Wrap strings in quotes to avoid ambiguity.
switch (p_variant.get_type()) {
case Variant::STRING: {
s = s.c_escape().quote();
} break;
case Variant::STRING_NAME: {
s = "&" + s.c_escape().quote();
} break;
case Variant::NODE_PATH: {
s = "^" + s.c_escape().quote();
} break;
default: {
} break;
}
return s;
}
template <class T>
String stringify_vector(const T &vec, int recursion_count) {
String str("[");
for (int i = 0; i < vec.size(); i++) {
if (i > 0) {
str += ", ";
}
str += stringify_variant_clean(vec[i], recursion_count);
}
str += "]";
return str;
}
String Variant::stringify(int recursion_count) const {
switch (type) {
case NIL:
return "null";
case BOOL:
return _data._bool ? "true" : "false";
case INT:
return itos(_data._int);
case FLOAT:
return rtos(_data._float);
case STRING:
return *reinterpret_cast<const String *>(_data._mem);
case VECTOR2:
return operator Vector2();
case VECTOR2I:
return operator Vector2i();
case RECT2:
return operator Rect2();
case RECT2I:
return operator Rect2i();
case TRANSFORM2D:
return operator Transform2D();
case VECTOR3:
return operator Vector3();
case VECTOR3I:
return operator Vector3i();
case PLANE:
return operator Plane();
case AABB:
return operator ::AABB();
case QUATERNION:
return operator Quaternion();
case BASIS:
return operator Basis();
case TRANSFORM3D:
return operator Transform3D();
case STRING_NAME:
return operator StringName();
case NODE_PATH:
return operator NodePath();
case COLOR:
return operator Color();
case DICTIONARY: {
const Dictionary &d = *reinterpret_cast<const Dictionary *>(_data._mem);
if (recursion_count > MAX_RECURSION) {
ERR_PRINT("Max recursion reached");
return "{...}";
}
String str("{");
List<Variant> keys;
d.get_key_list(&keys);
Vector<_VariantStrPair> pairs;
recursion_count++;
for (List<Variant>::Element *E = keys.front(); E; E = E->next()) {
_VariantStrPair sp;
sp.key = stringify_variant_clean(E->get(), recursion_count);
sp.value = stringify_variant_clean(d[E->get()], recursion_count);
pairs.push_back(sp);
}
for (int i = 0; i < pairs.size(); i++) {
if (i > 0) {
str += ", ";
}
str += pairs[i].key + ":" + pairs[i].value;
}
str += "}";
return str;
} break;
case PACKED_VECTOR2_ARRAY: {
return stringify_vector(operator Vector<Vector2>(), recursion_count);
} break;
case PACKED_VECTOR3_ARRAY: {
return stringify_vector(operator Vector<Vector3>(), recursion_count);
} break;
case PACKED_COLOR_ARRAY: {
return stringify_vector(operator Vector<Color>(), recursion_count);
} break;
case PACKED_STRING_ARRAY: {
return stringify_vector(operator Vector<String>(), recursion_count);
} break;
case PACKED_BYTE_ARRAY: {
return stringify_vector(operator Vector<uint8_t>(), recursion_count);
} break;
case PACKED_INT32_ARRAY: {
return stringify_vector(operator Vector<int32_t>(), recursion_count);
} break;
case PACKED_INT64_ARRAY: {
return stringify_vector(operator Vector<int64_t>(), recursion_count);
} break;
case PACKED_FLOAT32_ARRAY: {
return stringify_vector(operator Vector<float>(), recursion_count);
} break;
case PACKED_FLOAT64_ARRAY: {
return stringify_vector(operator Vector<double>(), recursion_count);
} break;
case ARRAY: {
Array arr = operator Array();
if (recursion_count > MAX_RECURSION) {
ERR_PRINT("Max recursion reached");
return "[...]";
}
return stringify_vector(arr, recursion_count);
} break;
case OBJECT: {
if (_get_obj().obj) {
if (!_get_obj().id.is_ref_counted() && ObjectDB::get_instance(_get_obj().id) == nullptr) {
return "[Freed Object]";
}
return _get_obj().obj->to_string();
} else {
return "[Object:null]";
}
} break;
case CALLABLE: {
const Callable &c = *reinterpret_cast<const Callable *>(_data._mem);
return c;
} break;
case SIGNAL: {
const Signal &s = *reinterpret_cast<const Signal *>(_data._mem);
return s;
} break;
case RID: {
const ::RID &s = *reinterpret_cast<const ::RID *>(_data._mem);
return "RID(" + itos(s.get_id()) + ")";
} break;
default: {
return "[" + get_type_name(type) + "]";
}
}
return "";
}
String Variant::to_json_string() const {
JSON json;
return json.stringify(*this);
}
Variant::operator Vector2() const {
if (type == VECTOR2) {
return *reinterpret_cast<const Vector2 *>(_data._mem);
} else if (type == VECTOR2I) {
return *reinterpret_cast<const Vector2i *>(_data._mem);
} else if (type == VECTOR3) {
return Vector2(reinterpret_cast<const Vector3 *>(_data._mem)->x, reinterpret_cast<const Vector3 *>(_data._mem)->y);
} else if (type == VECTOR3I) {
return Vector2(reinterpret_cast<const Vector3i *>(_data._mem)->x, reinterpret_cast<const Vector3i *>(_data._mem)->y);
} else {
return Vector2();
}
}
Variant::operator Vector2i() const {
if (type == VECTOR2I) {
return *reinterpret_cast<const Vector2i *>(_data._mem);
} else if (type == VECTOR2) {
return *reinterpret_cast<const Vector2 *>(_data._mem);
} else if (type == VECTOR3) {
return Vector2(reinterpret_cast<const Vector3 *>(_data._mem)->x, reinterpret_cast<const Vector3 *>(_data._mem)->y);
} else if (type == VECTOR3I) {
return Vector2(reinterpret_cast<const Vector3i *>(_data._mem)->x, reinterpret_cast<const Vector3i *>(_data._mem)->y);
} else {
return Vector2i();
}
}
Variant::operator Rect2() const {
if (type == RECT2) {
return *reinterpret_cast<const Rect2 *>(_data._mem);
} else if (type == RECT2I) {
return *reinterpret_cast<const Rect2i *>(_data._mem);
} else {
return Rect2();
}
}
Variant::operator Rect2i() const {
if (type == RECT2I) {
return *reinterpret_cast<const Rect2i *>(_data._mem);
} else if (type == RECT2) {
return *reinterpret_cast<const Rect2 *>(_data._mem);
} else {
return Rect2i();
}
}
Variant::operator Vector3() const {
if (type == VECTOR3) {
return *reinterpret_cast<const Vector3 *>(_data._mem);
} else if (type == VECTOR3I) {
return *reinterpret_cast<const Vector3i *>(_data._mem);
} else if (type == VECTOR2) {
return Vector3(reinterpret_cast<const Vector2 *>(_data._mem)->x, reinterpret_cast<const Vector2 *>(_data._mem)->y, 0.0);
} else if (type == VECTOR2I) {
return Vector3(reinterpret_cast<const Vector2i *>(_data._mem)->x, reinterpret_cast<const Vector2i *>(_data._mem)->y, 0.0);
} else {
return Vector3();
}
}
Variant::operator Vector3i() const {
if (type == VECTOR3I) {
return *reinterpret_cast<const Vector3i *>(_data._mem);
} else if (type == VECTOR3) {
return *reinterpret_cast<const Vector3 *>(_data._mem);
} else if (type == VECTOR2) {
return Vector3i(reinterpret_cast<const Vector2 *>(_data._mem)->x, reinterpret_cast<const Vector2 *>(_data._mem)->y, 0.0);
} else if (type == VECTOR2I) {
return Vector3i(reinterpret_cast<const Vector2i *>(_data._mem)->x, reinterpret_cast<const Vector2i *>(_data._mem)->y, 0.0);
} else {
return Vector3i();
}
}
Variant::operator Plane() const {
if (type == PLANE) {
return *reinterpret_cast<const Plane *>(_data._mem);
} else {
return Plane();
}
}
Variant::operator ::AABB() const {
if (type == AABB) {
return *_data._aabb;
} else {
return ::AABB();
}
}
Variant::operator Basis() const {
if (type == BASIS) {
return *_data._basis;
} else if (type == QUATERNION) {
return *reinterpret_cast<const Quaternion *>(_data._mem);
} else if (type == TRANSFORM3D) { // unexposed in Variant::can_convert?
return _data._transform3d->basis;
} else {
return Basis();
}
}
Variant::operator Quaternion() const {
if (type == QUATERNION) {
return *reinterpret_cast<const Quaternion *>(_data._mem);
} else if (type == BASIS) {
return *_data._basis;
} else if (type == TRANSFORM3D) {
return _data._transform3d->basis;
} else {
return Quaternion();
}
}
Variant::operator Transform3D() const {
if (type == TRANSFORM3D) {
return *_data._transform3d;
} else if (type == BASIS) {
return Transform3D(*_data._basis, Vector3());
} else if (type == QUATERNION) {
return Transform3D(Basis(*reinterpret_cast<const Quaternion *>(_data._mem)), Vector3());
} else if (type == TRANSFORM2D) {
const Transform2D &t = *_data._transform2d;
Transform3D m;
m.basis.rows[0][0] = t.columns[0][0];
m.basis.rows[1][0] = t.columns[0][1];
m.basis.rows[0][1] = t.columns[1][0];
m.basis.rows[1][1] = t.columns[1][1];
m.origin[0] = t.columns[2][0];
m.origin[1] = t.columns[2][1];
return m;
} else {
return Transform3D();
}
}
Variant::operator Transform2D() const {
if (type == TRANSFORM2D) {
return *_data._transform2d;
} else if (type == TRANSFORM3D) {
const Transform3D &t = *_data._transform3d;
Transform2D m;
m.columns[0][0] = t.basis.rows[0][0];
m.columns[0][1] = t.basis.rows[1][0];
m.columns[1][0] = t.basis.rows[0][1];
m.columns[1][1] = t.basis.rows[1][1];
m.columns[2][0] = t.origin[0];
m.columns[2][1] = t.origin[1];
return m;
} else {
return Transform2D();
}
}
Variant::operator Color() const {
if (type == COLOR) {
return *reinterpret_cast<const Color *>(_data._mem);
} else if (type == STRING) {
return Color(operator String());
} else if (type == INT) {
return Color::hex(operator int());
} else {
return Color();
}
}
Variant::operator NodePath() const {
if (type == NODE_PATH) {
return *reinterpret_cast<const NodePath *>(_data._mem);
} else if (type == STRING) {
return NodePath(operator String());
} else {
return NodePath();
}
}
Variant::operator ::RID() const {
if (type == RID) {
return *reinterpret_cast<const ::RID *>(_data._mem);
} else if (type == OBJECT && _get_obj().obj == nullptr) {
return ::RID();
} else if (type == OBJECT && _get_obj().obj) {
#ifdef DEBUG_ENABLED
if (EngineDebugger::is_active()) {
ERR_FAIL_COND_V_MSG(ObjectDB::get_instance(_get_obj().id) == nullptr, ::RID(), "Invalid pointer (object was freed).");
}
#endif
Callable::CallError ce;
Variant ret = _get_obj().obj->callp(CoreStringNames::get_singleton()->get_rid, nullptr, 0, ce);
if (ce.error == Callable::CallError::CALL_OK && ret.get_type() == Variant::RID) {
return ret;
}
return ::RID();
} else {
return ::RID();
}
}
Variant::operator Object *() const {
if (type == OBJECT) {
return _get_obj().obj;
} else {
return nullptr;
}
}
Object *Variant::get_validated_object_with_check(bool &r_previously_freed) const {
if (type == OBJECT) {
Object *instance = ObjectDB::get_instance(_get_obj().id);
r_previously_freed = !instance && _get_obj().id != ObjectID();
return instance;
} else {
r_previously_freed = false;
return nullptr;
}
}
Object *Variant::get_validated_object() const {
if (type == OBJECT) {
return ObjectDB::get_instance(_get_obj().id);
} else {
return nullptr;
}
}
Variant::operator Dictionary() const {
if (type == DICTIONARY) {
return *reinterpret_cast<const Dictionary *>(_data._mem);
} else {
return Dictionary();
}
}
Variant::operator Callable() const {
if (type == CALLABLE) {
return *reinterpret_cast<const Callable *>(_data._mem);
} else {
return Callable();
}
}
Variant::operator Signal() const {
if (type == SIGNAL) {
return *reinterpret_cast<const Signal *>(_data._mem);
} else {
return Signal();
}
}
template <class DA, class SA>
inline DA _convert_array(const SA &p_array) {
DA da;
da.resize(p_array.size());
for (int i = 0; i < p_array.size(); i++) {
da.set(i, Variant(p_array.get(i)));
}
return da;
}
template <class DA>
inline DA _convert_array_from_variant(const Variant &p_variant) {
switch (p_variant.get_type()) {
case Variant::ARRAY: {
return _convert_array<DA, Array>(p_variant.operator Array());
}
case Variant::PACKED_BYTE_ARRAY: {
return _convert_array<DA, Vector<uint8_t>>(p_variant.operator Vector<uint8_t>());
}
case Variant::PACKED_INT32_ARRAY: {
return _convert_array<DA, Vector<int32_t>>(p_variant.operator Vector<int32_t>());
}
case Variant::PACKED_INT64_ARRAY: {
return _convert_array<DA, Vector<int64_t>>(p_variant.operator Vector<int64_t>());
}
case Variant::PACKED_FLOAT32_ARRAY: {
return _convert_array<DA, Vector<float>>(p_variant.operator Vector<float>());
}
case Variant::PACKED_FLOAT64_ARRAY: {
return _convert_array<DA, Vector<double>>(p_variant.operator Vector<double>());
}
case Variant::PACKED_STRING_ARRAY: {
return _convert_array<DA, Vector<String>>(p_variant.operator Vector<String>());
}
case Variant::PACKED_VECTOR2_ARRAY: {
return _convert_array<DA, Vector<Vector2>>(p_variant.operator Vector<Vector2>());
}
case Variant::PACKED_VECTOR3_ARRAY: {
return _convert_array<DA, Vector<Vector3>>(p_variant.operator Vector<Vector3>());
}
case Variant::PACKED_COLOR_ARRAY: {
return _convert_array<DA, Vector<Color>>(p_variant.operator Vector<Color>());
}
default: {
return DA();
}
}
}
Variant::operator Array() const {
if (type == ARRAY) {
return *reinterpret_cast<const Array *>(_data._mem);
} else {
return _convert_array_from_variant<Array>(*this);
}
}
Variant::operator Vector<uint8_t>() const {
if (type == PACKED_BYTE_ARRAY) {
return static_cast<PackedArrayRef<uint8_t> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<uint8_t>>(*this);
}
}
Variant::operator Vector<int32_t>() const {
if (type == PACKED_INT32_ARRAY) {
return static_cast<PackedArrayRef<int32_t> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<int>>(*this);
}
}
Variant::operator Vector<int64_t>() const {
if (type == PACKED_INT64_ARRAY) {
return static_cast<PackedArrayRef<int64_t> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<int64_t>>(*this);
}
}
Variant::operator Vector<float>() const {
if (type == PACKED_FLOAT32_ARRAY) {
return static_cast<PackedArrayRef<float> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<float>>(*this);
}
}
Variant::operator Vector<double>() const {
if (type == PACKED_FLOAT64_ARRAY) {
return static_cast<PackedArrayRef<double> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<double>>(*this);
}
}
Variant::operator Vector<String>() const {
if (type == PACKED_STRING_ARRAY) {
return static_cast<PackedArrayRef<String> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<String>>(*this);
}
}
Variant::operator Vector<Vector3>() const {
if (type == PACKED_VECTOR3_ARRAY) {
return static_cast<PackedArrayRef<Vector3> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<Vector3>>(*this);
}
}
Variant::operator Vector<Vector2>() const {
if (type == PACKED_VECTOR2_ARRAY) {
return static_cast<PackedArrayRef<Vector2> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<Vector2>>(*this);
}
}
Variant::operator Vector<Color>() const {
if (type == PACKED_COLOR_ARRAY) {
return static_cast<PackedArrayRef<Color> *>(_data.packed_array)->array;
} else {
return _convert_array_from_variant<Vector<Color>>(*this);
}
}
/* helpers */
Variant::operator Vector<::RID>() const {
Array va = operator Array();
Vector<::RID> rids;
rids.resize(va.size());
for (int i = 0; i < rids.size(); i++) {
rids.write[i] = va[i];
}
return rids;
}
Variant::operator Vector<Plane>() const {
Array va = operator Array();
Vector<Plane> planes;
int va_size = va.size();
if (va_size == 0) {
return planes;
}
planes.resize(va_size);
Plane *w = planes.ptrw();
for (int i = 0; i < va_size; i++) {
w[i] = va[i];
}
return planes;
}
Variant::operator Vector<Face3>() const {
Vector<Vector3> va = operator Vector<Vector3>();
Vector<Face3> faces;
int va_size = va.size();
if (va_size == 0) {
return faces;
}
faces.resize(va_size / 3);
Face3 *w = faces.ptrw();
const Vector3 *r = va.ptr();
for (int i = 0; i < va_size; i++) {
w[i / 3].vertex[i % 3] = r[i];
}
return faces;
}
Variant::operator Vector<Variant>() const {
Array va = operator Array();
Vector<Variant> variants;
int va_size = va.size();
if (va_size == 0) {
return variants;
}
variants.resize(va_size);
Variant *w = variants.ptrw();
for (int i = 0; i < va_size; i++) {
w[i] = va[i];
}
return variants;
}
Variant::operator Vector<StringName>() const {
Vector<String> from = operator Vector<String>();
Vector<StringName> to;
int len = from.size();
to.resize(len);
for (int i = 0; i < len; i++) {
to.write[i] = from[i];
}
return to;
}
Variant::operator Side() const {
return (Side) operator int();
}
Variant::operator Orientation() const {
return (Orientation) operator int();
}
Variant::operator IPAddress() const {
if (type == PACKED_FLOAT32_ARRAY || type == PACKED_INT32_ARRAY || type == PACKED_FLOAT64_ARRAY || type == PACKED_INT64_ARRAY || type == PACKED_BYTE_ARRAY) {
Vector<int> addr = operator Vector<int>();
if (addr.size() == 4) {
return IPAddress(addr.get(0), addr.get(1), addr.get(2), addr.get(3));
}
}
return IPAddress(operator String());
}
Variant::Variant(bool p_bool) {
type = BOOL;
_data._bool = p_bool;
}
Variant::Variant(signed int p_int) {
type = INT;
_data._int = p_int;
}
Variant::Variant(unsigned int p_int) {
type = INT;
_data._int = p_int;
}
#ifdef NEED_LONG_INT
Variant::Variant(signed long p_int) {
type = INT;
_data._int = p_int;
}
Variant::Variant(unsigned long p_int) {
type = INT;
_data._int = p_int;
}
#endif
Variant::Variant(int64_t p_int) {
type = INT;
_data._int = p_int;
}
Variant::Variant(uint64_t p_int) {
type = INT;
_data._int = p_int;
}
Variant::Variant(signed short p_short) {
type = INT;
_data._int = p_short;
}
Variant::Variant(unsigned short p_short) {
type = INT;
_data._int = p_short;
}
Variant::Variant(signed char p_char) {
type = INT;
_data._int = p_char;
}
Variant::Variant(unsigned char p_char) {
type = INT;
_data._int = p_char;
}
Variant::Variant(float p_float) {
type = FLOAT;
_data._float = p_float;
}
Variant::Variant(double p_double) {
type = FLOAT;
_data._float = p_double;
}
Variant::Variant(const ObjectID &p_id) {
type = INT;
_data._int = p_id;
}
Variant::Variant(const StringName &p_string) {
type = STRING_NAME;
memnew_placement(_data._mem, StringName(p_string));
}
Variant::Variant(const String &p_string) {
type = STRING;
memnew_placement(_data._mem, String(p_string));
}
Variant::Variant(const char *const p_cstring) {
type = STRING;
memnew_placement(_data._mem, String((const char *)p_cstring));
}
Variant::Variant(const char32_t *p_wstring) {
type = STRING;
memnew_placement(_data._mem, String(p_wstring));
}
Variant::Variant(const Vector3 &p_vector3) {
type = VECTOR3;
memnew_placement(_data._mem, Vector3(p_vector3));
}
Variant::Variant(const Vector3i &p_vector3i) {
type = VECTOR3I;
memnew_placement(_data._mem, Vector3i(p_vector3i));
}
Variant::Variant(const Vector2 &p_vector2) {
type = VECTOR2;
memnew_placement(_data._mem, Vector2(p_vector2));
}
Variant::Variant(const Vector2i &p_vector2i) {
type = VECTOR2I;
memnew_placement(_data._mem, Vector2i(p_vector2i));
}
Variant::Variant(const Rect2 &p_rect2) {
type = RECT2;
memnew_placement(_data._mem, Rect2(p_rect2));
}
Variant::Variant(const Rect2i &p_rect2i) {
type = RECT2I;
memnew_placement(_data._mem, Rect2i(p_rect2i));
}
Variant::Variant(const Plane &p_plane) {
type = PLANE;
memnew_placement(_data._mem, Plane(p_plane));
}
Variant::Variant(const ::AABB &p_aabb) {
type = AABB;
_data._aabb = memnew(::AABB(p_aabb));
}
Variant::Variant(const Basis &p_matrix) {
type = BASIS;
_data._basis = memnew(Basis(p_matrix));
}
Variant::Variant(const Quaternion &p_quaternion) {
type = QUATERNION;
memnew_placement(_data._mem, Quaternion(p_quaternion));
}
Variant::Variant(const Transform3D &p_transform) {
type = TRANSFORM3D;
_data._transform3d = memnew(Transform3D(p_transform));
}
Variant::Variant(const Transform2D &p_transform) {
type = TRANSFORM2D;
_data._transform2d = memnew(Transform2D(p_transform));
}
Variant::Variant(const Color &p_color) {
type = COLOR;
memnew_placement(_data._mem, Color(p_color));
}
Variant::Variant(const NodePath &p_node_path) {
type = NODE_PATH;
memnew_placement(_data._mem, NodePath(p_node_path));
}
Variant::Variant(const ::RID &p_rid) {
type = RID;
memnew_placement(_data._mem, ::RID(p_rid));
}
Variant::Variant(const Object *p_object) {
type = OBJECT;
memnew_placement(_data._mem, ObjData);
if (p_object) {
if (p_object->is_ref_counted()) {
RefCounted *ref_counted = const_cast<RefCounted *>(static_cast<const RefCounted *>(p_object));
if (!ref_counted->init_ref()) {
_get_obj().obj = nullptr;
_get_obj().id = ObjectID();
return;
}
}
_get_obj().obj = const_cast<Object *>(p_object);
_get_obj().id = p_object->get_instance_id();
} else {
_get_obj().obj = nullptr;
_get_obj().id = ObjectID();
}
}
Variant::Variant(const Callable &p_callable) {
type = CALLABLE;
memnew_placement(_data._mem, Callable(p_callable));
}
Variant::Variant(const Signal &p_callable) {
type = SIGNAL;
memnew_placement(_data._mem, Signal(p_callable));
}
Variant::Variant(const Dictionary &p_dictionary) {
type = DICTIONARY;
memnew_placement(_data._mem, Dictionary(p_dictionary));
}
Variant::Variant(const Array &p_array) {
type = ARRAY;
memnew_placement(_data._mem, Array(p_array));
}
Variant::Variant(const Vector<Plane> &p_array) {
type = ARRAY;
Array *plane_array = memnew_placement(_data._mem, Array);
plane_array->resize(p_array.size());
for (int i = 0; i < p_array.size(); i++) {
plane_array->operator[](i) = Variant(p_array[i]);
}
}
Variant::Variant(const Vector<::RID> &p_array) {
type = ARRAY;
Array *rid_array = memnew_placement(_data._mem, Array);
rid_array->resize(p_array.size());
for (int i = 0; i < p_array.size(); i++) {
rid_array->set(i, Variant(p_array[i]));
}
}
Variant::Variant(const Vector<uint8_t> &p_byte_array) {
type = PACKED_BYTE_ARRAY;
_data.packed_array = PackedArrayRef<uint8_t>::create(p_byte_array);
}
Variant::Variant(const Vector<int32_t> &p_int32_array) {
type = PACKED_INT32_ARRAY;
_data.packed_array = PackedArrayRef<int32_t>::create(p_int32_array);
}
Variant::Variant(const Vector<int64_t> &p_int64_array) {
type = PACKED_INT64_ARRAY;
_data.packed_array = PackedArrayRef<int64_t>::create(p_int64_array);
}
Variant::Variant(const Vector<float> &p_float32_array) {
type = PACKED_FLOAT32_ARRAY;
_data.packed_array = PackedArrayRef<float>::create(p_float32_array);
}
Variant::Variant(const Vector<double> &p_float64_array) {
type = PACKED_FLOAT64_ARRAY;
_data.packed_array = PackedArrayRef<double>::create(p_float64_array);
}
Variant::Variant(const Vector<String> &p_string_array) {
type = PACKED_STRING_ARRAY;
_data.packed_array = PackedArrayRef<String>::create(p_string_array);
}
Variant::Variant(const Vector<Vector3> &p_vector3_array) {
type = PACKED_VECTOR3_ARRAY;
_data.packed_array = PackedArrayRef<Vector3>::create(p_vector3_array);
}
Variant::Variant(const Vector<Vector2> &p_vector2_array) {
type = PACKED_VECTOR2_ARRAY;
_data.packed_array = PackedArrayRef<Vector2>::create(p_vector2_array);
}
Variant::Variant(const Vector<Color> &p_color_array) {
type = PACKED_COLOR_ARRAY;
_data.packed_array = PackedArrayRef<Color>::create(p_color_array);
}
Variant::Variant(const Vector<Face3> &p_face_array) {
Vector<Vector3> vertices;
int face_count = p_face_array.size();
vertices.resize(face_count * 3);
if (face_count) {
const Face3 *r = p_face_array.ptr();
Vector3 *w = vertices.ptrw();
for (int i = 0; i < face_count; i++) {
for (int j = 0; j < 3; j++) {
w[i * 3 + j] = r[i].vertex[j];
}
}
}
type = NIL;
*this = vertices;
}
/* helpers */
Variant::Variant(const Vector<Variant> &p_array) {
type = NIL;
Array arr;
arr.resize(p_array.size());
for (int i = 0; i < p_array.size(); i++) {
arr[i] = p_array[i];
}
*this = arr;
}
Variant::Variant(const Vector<StringName> &p_array) {
type = NIL;
Vector<String> v;
int len = p_array.size();
v.resize(len);
for (int i = 0; i < len; i++) {
v.set(i, p_array[i]);
}
*this = v;
}
void Variant::operator=(const Variant &p_variant) {
if (unlikely(this == &p_variant)) {
return;
}
if (unlikely(type != p_variant.type)) {
reference(p_variant);
return;
}
switch (p_variant.type) {
case NIL: {
// none
} break;
// atomic types
case BOOL: {
_data._bool = p_variant._data._bool;
} break;
case INT: {
_data._int = p_variant._data._int;
} break;
case FLOAT: {
_data._float = p_variant._data._float;
} break;
case STRING: {
*reinterpret_cast<String *>(_data._mem) = *reinterpret_cast<const String *>(p_variant._data._mem);
} break;
// math types
case VECTOR2: {
*reinterpret_cast<Vector2 *>(_data._mem) = *reinterpret_cast<const Vector2 *>(p_variant._data._mem);
} break;
case VECTOR2I: {
*reinterpret_cast<Vector2i *>(_data._mem) = *reinterpret_cast<const Vector2i *>(p_variant._data._mem);
} break;
case RECT2: {
*reinterpret_cast<Rect2 *>(_data._mem) = *reinterpret_cast<const Rect2 *>(p_variant._data._mem);
} break;
case RECT2I: {
*reinterpret_cast<Rect2i *>(_data._mem) = *reinterpret_cast<const Rect2i *>(p_variant._data._mem);
} break;
case TRANSFORM2D: {
*_data._transform2d = *(p_variant._data._transform2d);
} break;
case VECTOR3: {
*reinterpret_cast<Vector3 *>(_data._mem) = *reinterpret_cast<const Vector3 *>(p_variant._data._mem);
} break;
case VECTOR3I: {
*reinterpret_cast<Vector3i *>(_data._mem) = *reinterpret_cast<const Vector3i *>(p_variant._data._mem);
} break;
case PLANE: {
*reinterpret_cast<Plane *>(_data._mem) = *reinterpret_cast<const Plane *>(p_variant._data._mem);
} break;
case AABB: {
*_data._aabb = *(p_variant._data._aabb);
} break;
case QUATERNION: {
*reinterpret_cast<Quaternion *>(_data._mem) = *reinterpret_cast<const Quaternion *>(p_variant._data._mem);
} break;
case BASIS: {
*_data._basis = *(p_variant._data._basis);
} break;
case TRANSFORM3D: {
*_data._transform3d = *(p_variant._data._transform3d);
} break;
// misc types
case COLOR: {
*reinterpret_cast<Color *>(_data._mem) = *reinterpret_cast<const Color *>(p_variant._data._mem);
} break;
case RID: {
*reinterpret_cast<::RID *>(_data._mem) = *reinterpret_cast<const ::RID *>(p_variant._data._mem);
} break;
case OBJECT: {
if (_get_obj().id.is_ref_counted()) {
//we are safe that there is a reference here
RefCounted *ref_counted = static_cast<RefCounted *>(_get_obj().obj);
if (ref_counted->unreference()) {
memdelete(ref_counted);
}
}
if (p_variant._get_obj().obj && p_variant._get_obj().id.is_ref_counted()) {
RefCounted *ref_counted = static_cast<RefCounted *>(p_variant._get_obj().obj);
if (!ref_counted->reference()) {
_get_obj().obj = nullptr;
_get_obj().id = ObjectID();
break;
}
}
_get_obj().obj = const_cast<Object *>(p_variant._get_obj().obj);
_get_obj().id = p_variant._get_obj().id;
} break;
case CALLABLE: {
*reinterpret_cast<Callable *>(_data._mem) = *reinterpret_cast<const Callable *>(p_variant._data._mem);
} break;
case SIGNAL: {
*reinterpret_cast<Signal *>(_data._mem) = *reinterpret_cast<const Signal *>(p_variant._data._mem);
} break;
case STRING_NAME: {
*reinterpret_cast<StringName *>(_data._mem) = *reinterpret_cast<const StringName *>(p_variant._data._mem);
} break;
case NODE_PATH: {
*reinterpret_cast<NodePath *>(_data._mem) = *reinterpret_cast<const NodePath *>(p_variant._data._mem);
} break;
case DICTIONARY: {
*reinterpret_cast<Dictionary *>(_data._mem) = *reinterpret_cast<const Dictionary *>(p_variant._data._mem);
} break;
case ARRAY: {
*reinterpret_cast<Array *>(_data._mem) = *reinterpret_cast<const Array *>(p_variant._data._mem);
} break;
// arrays
case PACKED_BYTE_ARRAY: {
_data.packed_array = PackedArrayRef<uint8_t>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_INT32_ARRAY: {
_data.packed_array = PackedArrayRef<int32_t>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_INT64_ARRAY: {
_data.packed_array = PackedArrayRef<int64_t>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_FLOAT32_ARRAY: {
_data.packed_array = PackedArrayRef<float>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_FLOAT64_ARRAY: {
_data.packed_array = PackedArrayRef<double>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_STRING_ARRAY: {
_data.packed_array = PackedArrayRef<String>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_VECTOR2_ARRAY: {
_data.packed_array = PackedArrayRef<Vector2>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_VECTOR3_ARRAY: {
_data.packed_array = PackedArrayRef<Vector3>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
case PACKED_COLOR_ARRAY: {
_data.packed_array = PackedArrayRef<Color>::reference_from(_data.packed_array, p_variant._data.packed_array);
} break;
default: {
}
}
}
Variant::Variant(const IPAddress &p_address) {
type = STRING;
memnew_placement(_data._mem, String(p_address));
}
Variant::Variant(const Variant &p_variant) {
reference(p_variant);
}
uint32_t Variant::hash() const {
return recursive_hash(0);
}
uint32_t Variant::recursive_hash(int recursion_count) const {
switch (type) {
case NIL: {
return 0;
} break;
case BOOL: {
return _data._bool ? 1 : 0;
} break;
case INT: {
return hash_one_uint64((uint64_t)_data._int);
} break;
case FLOAT: {
return hash_murmur3_one_float(_data._float);
} break;
case STRING: {
return reinterpret_cast<const String *>(_data._mem)->hash();
} break;
// math types
case VECTOR2: {
return HashMapHasherDefault::hash(*reinterpret_cast<const Vector2 *>(_data._mem));
} break;
case VECTOR2I: {
return HashMapHasherDefault::hash(*reinterpret_cast<const Vector2i *>(_data._mem));
} break;
case RECT2: {
return HashMapHasherDefault::hash(*reinterpret_cast<const Rect2 *>(_data._mem));
} break;
case RECT2I: {
return HashMapHasherDefault::hash(*reinterpret_cast<const Rect2i *>(_data._mem));
} break;
case TRANSFORM2D: {
uint32_t h = HASH_MURMUR3_SEED;
const Transform2D &t = *_data._transform2d;
h = hash_murmur3_one_real(t[0].x, h);
h = hash_murmur3_one_real(t[0].y, h);
h = hash_murmur3_one_real(t[1].x, h);
h = hash_murmur3_one_real(t[1].y, h);
h = hash_murmur3_one_real(t[2].x, h);
h = hash_murmur3_one_real(t[2].y, h);
return hash_fmix32(h);
} break;
case VECTOR3: {
return HashMapHasherDefault::hash(*reinterpret_cast<const Vector3 *>(_data._mem));
} break;
case VECTOR3I: {
return HashMapHasherDefault::hash(*reinterpret_cast<const Vector3i *>(_data._mem));
} break;
case PLANE: {
uint32_t h = HASH_MURMUR3_SEED;
const Plane &p = *reinterpret_cast<const Plane *>(_data._mem);
h = hash_murmur3_one_real(p.normal.x, h);
h = hash_murmur3_one_real(p.normal.y, h);
h = hash_murmur3_one_real(p.normal.z, h);
h = hash_murmur3_one_real(p.d, h);
return hash_fmix32(h);
} break;
case AABB: {
return HashMapHasherDefault::hash(*_data._aabb);
} break;
case QUATERNION: {
uint32_t h = HASH_MURMUR3_SEED;
const Quaternion &q = *reinterpret_cast<const Quaternion *>(_data._mem);
h = hash_murmur3_one_real(q.x, h);
h = hash_murmur3_one_real(q.y, h);
h = hash_murmur3_one_real(q.z, h);
h = hash_murmur3_one_real(q.w, h);
return hash_fmix32(h);
} break;
case BASIS: {
uint32_t h = HASH_MURMUR3_SEED;
const Basis &b = *_data._basis;
h = hash_murmur3_one_real(b[0].x, h);
h = hash_murmur3_one_real(b[0].y, h);
h = hash_murmur3_one_real(b[0].z, h);
h = hash_murmur3_one_real(b[1].x, h);
h = hash_murmur3_one_real(b[1].y, h);
h = hash_murmur3_one_real(b[1].z, h);
h = hash_murmur3_one_real(b[2].x, h);
h = hash_murmur3_one_real(b[2].y, h);
h = hash_murmur3_one_real(b[2].z, h);
return hash_fmix32(h);
} break;
case TRANSFORM3D: {
uint32_t h = HASH_MURMUR3_SEED;
const Transform3D &t = *_data._transform3d;
h = hash_murmur3_one_real(t.basis[0].x, h);
h = hash_murmur3_one_real(t.basis[0].y, h);
h = hash_murmur3_one_real(t.basis[0].z, h);
h = hash_murmur3_one_real(t.basis[1].x, h);
h = hash_murmur3_one_real(t.basis[1].y, h);
h = hash_murmur3_one_real(t.basis[1].z, h);
h = hash_murmur3_one_real(t.basis[2].x, h);
h = hash_murmur3_one_real(t.basis[2].y, h);
h = hash_murmur3_one_real(t.basis[2].z, h);
h = hash_murmur3_one_real(t.origin.x, h);
h = hash_murmur3_one_real(t.origin.y, h);
h = hash_murmur3_one_real(t.origin.z, h);
return hash_fmix32(h);
} break;
// misc types
case COLOR: {
uint32_t h = HASH_MURMUR3_SEED;
const Color &c = *reinterpret_cast<const Color *>(_data._mem);
h = hash_murmur3_one_float(c.r, h);
h = hash_murmur3_one_float(c.g, h);
h = hash_murmur3_one_float(c.b, h);
h = hash_murmur3_one_float(c.a, h);
return hash_fmix32(h);
} break;
case RID: {
return hash_one_uint64(reinterpret_cast<const ::RID *>(_data._mem)->get_id());
} break;
case OBJECT: {
return hash_one_uint64(hash_make_uint64_t(_get_obj().obj));
} break;
case STRING_NAME: {
return reinterpret_cast<const StringName *>(_data._mem)->hash();
} break;
case NODE_PATH: {
return reinterpret_cast<const NodePath *>(_data._mem)->hash();
} break;
case DICTIONARY: {
return reinterpret_cast<const Dictionary *>(_data._mem)->recursive_hash(recursion_count);
} break;
case CALLABLE: {
return reinterpret_cast<const Callable *>(_data._mem)->hash();
} break;
case SIGNAL: {
const Signal &s = *reinterpret_cast<const Signal *>(_data._mem);
uint32_t hash = s.get_name().hash();
return hash_murmur3_one_64(s.get_object_id(), hash);
} break;
case ARRAY: {
const Array &arr = *reinterpret_cast<const Array *>(_data._mem);
return arr.recursive_hash(recursion_count);
} break;
case PACKED_BYTE_ARRAY: {
const Vector<uint8_t> &arr = PackedArrayRef<uint8_t>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const uint8_t *r = arr.ptr();
return hash_murmur3_buffer((uint8_t *)&r[0], len);
} else {
return hash_murmur3_one_64(0);
}
} break;
case PACKED_INT32_ARRAY: {
const Vector<int32_t> &arr = PackedArrayRef<int32_t>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const int32_t *r = arr.ptr();
return hash_murmur3_buffer((uint8_t *)&r[0], len * sizeof(int32_t));
} else {
return hash_murmur3_one_64(0);
}
} break;
case PACKED_INT64_ARRAY: {
const Vector<int64_t> &arr = PackedArrayRef<int64_t>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const int64_t *r = arr.ptr();
return hash_murmur3_buffer((uint8_t *)&r[0], len * sizeof(int64_t));
} else {
return hash_murmur3_one_64(0);
}
} break;
case PACKED_FLOAT32_ARRAY: {
const Vector<float> &arr = PackedArrayRef<float>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const float *r = arr.ptr();
uint32_t h = HASH_MURMUR3_SEED;
for (int32_t i = 0; i < len; i++) {
h = hash_murmur3_one_float(r[i], h);
}
return hash_fmix32(h);
} else {
return hash_murmur3_one_float(0.0);
}
} break;
case PACKED_FLOAT64_ARRAY: {
const Vector<double> &arr = PackedArrayRef<double>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const double *r = arr.ptr();
uint32_t h = HASH_MURMUR3_SEED;
for (int32_t i = 0; i < len; i++) {
h = hash_murmur3_one_double(r[i], h);
}
return hash_fmix32(h);
} else {
return hash_murmur3_one_float(0.0);
}
} break;
case PACKED_STRING_ARRAY: {
uint32_t hash = HASH_MURMUR3_SEED;
const Vector<String> &arr = PackedArrayRef<String>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const String *r = arr.ptr();
for (int i = 0; i < len; i++) {
hash = hash_murmur3_one_32(r[i].hash(), hash);
}
hash = hash_fmix32(hash);
}
return hash;
} break;
case PACKED_VECTOR2_ARRAY: {
uint32_t hash = HASH_MURMUR3_SEED;
const Vector<Vector2> &arr = PackedArrayRef<Vector2>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const Vector2 *r = arr.ptr();
for (int i = 0; i < len; i++) {
hash = hash_murmur3_one_real(r[i].x, hash);
hash = hash_murmur3_one_real(r[i].y, hash);
}
hash = hash_fmix32(hash);
}
return hash;
} break;
case PACKED_VECTOR3_ARRAY: {
uint32_t hash = HASH_MURMUR3_SEED;
const Vector<Vector3> &arr = PackedArrayRef<Vector3>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const Vector3 *r = arr.ptr();
for (int i = 0; i < len; i++) {
hash = hash_murmur3_one_real(r[i].x, hash);
hash = hash_murmur3_one_real(r[i].y, hash);
hash = hash_murmur3_one_real(r[i].z, hash);
}
hash = hash_fmix32(hash);
}
return hash;
} break;
case PACKED_COLOR_ARRAY: {
uint32_t hash = HASH_MURMUR3_SEED;
const Vector<Color> &arr = PackedArrayRef<Color>::get_array(_data.packed_array);
int len = arr.size();
if (likely(len)) {
const Color *r = arr.ptr();
for (int i = 0; i < len; i++) {
hash = hash_murmur3_one_float(r[i].r, hash);
hash = hash_murmur3_one_float(r[i].g, hash);
hash = hash_murmur3_one_float(r[i].b, hash);
hash = hash_murmur3_one_float(r[i].a, hash);
}
hash = hash_fmix32(hash);
}
return hash;
} break;
default: {
}
}
return 0;
}
#define hash_compare_scalar(p_lhs, p_rhs) \
((p_lhs) == (p_rhs)) || (Math::is_nan(p_lhs) && Math::is_nan(p_rhs))
#define hash_compare_vector2(p_lhs, p_rhs) \
(hash_compare_scalar((p_lhs).x, (p_rhs).x)) && \
(hash_compare_scalar((p_lhs).y, (p_rhs).y))
#define hash_compare_vector3(p_lhs, p_rhs) \
(hash_compare_scalar((p_lhs).x, (p_rhs).x)) && \
(hash_compare_scalar((p_lhs).y, (p_rhs).y)) && \
(hash_compare_scalar((p_lhs).z, (p_rhs).z))
#define hash_compare_quaternion(p_lhs, p_rhs) \
(hash_compare_scalar((p_lhs).x, (p_rhs).x)) && \
(hash_compare_scalar((p_lhs).y, (p_rhs).y)) && \
(hash_compare_scalar((p_lhs).z, (p_rhs).z)) && \
(hash_compare_scalar((p_lhs).w, (p_rhs).w))
#define hash_compare_color(p_lhs, p_rhs) \
(hash_compare_scalar((p_lhs).r, (p_rhs).r)) && \
(hash_compare_scalar((p_lhs).g, (p_rhs).g)) && \
(hash_compare_scalar((p_lhs).b, (p_rhs).b)) && \
(hash_compare_scalar((p_lhs).a, (p_rhs).a))
#define hash_compare_packed_array(p_lhs, p_rhs, p_type, p_compare_func) \
const Vector<p_type> &l = PackedArrayRef<p_type>::get_array(p_lhs); \
const Vector<p_type> &r = PackedArrayRef<p_type>::get_array(p_rhs); \
\
if (l.size() != r.size()) \
return false; \
\
const p_type *lr = l.ptr(); \
const p_type *rr = r.ptr(); \
\
for (int i = 0; i < l.size(); ++i) { \
if (!p_compare_func((lr[i]), (rr[i]))) \
return false; \
} \
\
return true
bool Variant::hash_compare(const Variant &p_variant, int recursion_count) const {
if (type != p_variant.type) {
return false;
}
switch (type) {
case INT: {
return _data._int == p_variant._data._int;
} break;
case FLOAT: {
return hash_compare_scalar(_data._float, p_variant._data._float);
} break;
case STRING: {
return *reinterpret_cast<const String *>(_data._mem) == *reinterpret_cast<const String *>(p_variant._data._mem);
} break;
case STRING_NAME: {
return *reinterpret_cast<const StringName *>(_data._mem) == *reinterpret_cast<const StringName *>(p_variant._data._mem);
} break;
case VECTOR2: {
const Vector2 *l = reinterpret_cast<const Vector2 *>(_data._mem);
const Vector2 *r = reinterpret_cast<const Vector2 *>(p_variant._data._mem);
return hash_compare_vector2(*l, *r);
} break;
case VECTOR2I: {
const Vector2i *l = reinterpret_cast<const Vector2i *>(_data._mem);
const Vector2i *r = reinterpret_cast<const Vector2i *>(p_variant._data._mem);
return *l == *r;
} break;
case RECT2: {
const Rect2 *l = reinterpret_cast<const Rect2 *>(_data._mem);
const Rect2 *r = reinterpret_cast<const Rect2 *>(p_variant._data._mem);
return (hash_compare_vector2(l->position, r->position)) &&
(hash_compare_vector2(l->size, r->size));
} break;
case RECT2I: {
const Rect2i *l = reinterpret_cast<const Rect2i *>(_data._mem);
const Rect2i *r = reinterpret_cast<const Rect2i *>(p_variant._data._mem);
return *l == *r;
} break;
case TRANSFORM2D: {
Transform2D *l = _data._transform2d;
Transform2D *r = p_variant._data._transform2d;
for (int i = 0; i < 3; i++) {
if (!(hash_compare_vector2(l->columns[i], r->columns[i]))) {
return false;
}
}
return true;
} break;
case VECTOR3: {
const Vector3 *l = reinterpret_cast<const Vector3 *>(_data._mem);
const Vector3 *r = reinterpret_cast<const Vector3 *>(p_variant._data._mem);
return hash_compare_vector3(*l, *r);
} break;
case VECTOR3I: {
const Vector3i *l = reinterpret_cast<const Vector3i *>(_data._mem);
const Vector3i *r = reinterpret_cast<const Vector3i *>(p_variant._data._mem);
return *l == *r;
} break;
case PLANE: {
const Plane *l = reinterpret_cast<const Plane *>(_data._mem);
const Plane *r = reinterpret_cast<const Plane *>(p_variant._data._mem);
return (hash_compare_vector3(l->normal, r->normal)) &&
(hash_compare_scalar(l->d, r->d));
} break;
case AABB: {
const ::AABB *l = _data._aabb;
const ::AABB *r = p_variant._data._aabb;
return (hash_compare_vector3(l->position, r->position) &&
(hash_compare_vector3(l->size, r->size)));
} break;
case QUATERNION: {
const Quaternion *l = reinterpret_cast<const Quaternion *>(_data._mem);
const Quaternion *r = reinterpret_cast<const Quaternion *>(p_variant._data._mem);
return hash_compare_quaternion(*l, *r);
} break;
case BASIS: {
const Basis *l = _data._basis;
const Basis *r = p_variant._data._basis;
for (int i = 0; i < 3; i++) {
if (!(hash_compare_vector3(l->rows[i], r->rows[i]))) {
return false;
}
}
return true;
} break;
case TRANSFORM3D: {
const Transform3D *l = _data._transform3d;
const Transform3D *r = p_variant._data._transform3d;
for (int i = 0; i < 3; i++) {
if (!(hash_compare_vector3(l->basis.rows[i], r->basis.rows[i]))) {
return false;
}
}
return hash_compare_vector3(l->origin, r->origin);
} break;
case COLOR: {
const Color *l = reinterpret_cast<const Color *>(_data._mem);
const Color *r = reinterpret_cast<const Color *>(p_variant._data._mem);
return hash_compare_color(*l, *r);
} break;
case ARRAY: {
const Array &l = *(reinterpret_cast<const Array *>(_data._mem));
const Array &r = *(reinterpret_cast<const Array *>(p_variant._data._mem));
if (!l.recursive_equal(r, recursion_count + 1)) {
return false;
}
return true;
} break;
case DICTIONARY: {
const Dictionary &l = *(reinterpret_cast<const Dictionary *>(_data._mem));
const Dictionary &r = *(reinterpret_cast<const Dictionary *>(p_variant._data._mem));
if (!l.recursive_equal(r, recursion_count + 1)) {
return false;
}
return true;
} break;
// This is for floating point comparisons only.
case PACKED_FLOAT32_ARRAY: {
hash_compare_packed_array(_data.packed_array, p_variant._data.packed_array, float, hash_compare_scalar);
} break;
case PACKED_FLOAT64_ARRAY: {
hash_compare_packed_array(_data.packed_array, p_variant._data.packed_array, double, hash_compare_scalar);
} break;
case PACKED_VECTOR2_ARRAY: {
hash_compare_packed_array(_data.packed_array, p_variant._data.packed_array, Vector2, hash_compare_vector2);
} break;
case PACKED_VECTOR3_ARRAY: {
hash_compare_packed_array(_data.packed_array, p_variant._data.packed_array, Vector3, hash_compare_vector3);
} break;
case PACKED_COLOR_ARRAY: {
hash_compare_packed_array(_data.packed_array, p_variant._data.packed_array, Color, hash_compare_color);
} break;
default:
bool v;
Variant r;
evaluate(OP_EQUAL, *this, p_variant, r, v);
return r;
}
return false;
}
bool Variant::is_ref_counted() const {
return type == OBJECT && _get_obj().id.is_ref_counted();
}
Vector<Variant> varray() {
return Vector<Variant>();
}
Vector<Variant> varray(const Variant &p_arg1) {
Vector<Variant> v;
v.push_back(p_arg1);
return v;
}
Vector<Variant> varray(const Variant &p_arg1, const Variant &p_arg2) {
Vector<Variant> v;
v.push_back(p_arg1);
v.push_back(p_arg2);
return v;
}
Vector<Variant> varray(const Variant &p_arg1, const Variant &p_arg2, const Variant &p_arg3) {
Vector<Variant> v;
v.push_back(p_arg1);
v.push_back(p_arg2);
v.push_back(p_arg3);
return v;
}
Vector<Variant> varray(const Variant &p_arg1, const Variant &p_arg2, const Variant &p_arg3, const Variant &p_arg4) {
Vector<Variant> v;
v.push_back(p_arg1);
v.push_back(p_arg2);
v.push_back(p_arg3);
v.push_back(p_arg4);
return v;
}
Vector<Variant> varray(const Variant &p_arg1, const Variant &p_arg2, const Variant &p_arg3, const Variant &p_arg4, const Variant &p_arg5) {
Vector<Variant> v;
v.push_back(p_arg1);
v.push_back(p_arg2);
v.push_back(p_arg3);
v.push_back(p_arg4);
v.push_back(p_arg5);
return v;
}
void Variant::static_assign(const Variant &p_variant) {
}
bool Variant::is_type_shared(Variant::Type p_type) {
switch (p_type) {
case OBJECT:
case ARRAY:
case DICTIONARY:
case PACKED_BYTE_ARRAY:
case PACKED_INT32_ARRAY:
case PACKED_INT64_ARRAY:
case PACKED_FLOAT32_ARRAY:
case PACKED_FLOAT64_ARRAY:
case PACKED_STRING_ARRAY:
case PACKED_VECTOR2_ARRAY:
case PACKED_VECTOR3_ARRAY:
case PACKED_COLOR_ARRAY:
return true;
default: {
}
}
return false;
}
bool Variant::is_shared() const {
return is_type_shared(type);
}
void Variant::_variant_call_error(const String &p_method, Callable::CallError &error) {
switch (error.error) {
case Callable::CallError::CALL_ERROR_INVALID_ARGUMENT: {
String err = "Invalid type for argument #" + itos(error.argument) + ", expected '" + Variant::get_type_name(Variant::Type(error.expected)) + "'.";
ERR_PRINT(err.utf8().get_data());
} break;
case Callable::CallError::CALL_ERROR_INVALID_METHOD: {
String err = "Invalid method '" + p_method + "' for type '" + Variant::get_type_name(type) + "'.";
ERR_PRINT(err.utf8().get_data());
} break;
case Callable::CallError::CALL_ERROR_TOO_MANY_ARGUMENTS: {
String err = "Too many arguments for method '" + p_method + "'";
ERR_PRINT(err.utf8().get_data());
} break;
default: {
}
}
}
void Variant::construct_from_string(const String &p_string, Variant &r_value, ObjectConstruct p_obj_construct, void *p_construct_ud) {
r_value = Variant();
}
String Variant::get_construct_string() const {
String vars;
VariantWriter::write_to_string(*this, vars);
return vars;
}
String Variant::get_call_error_text(const StringName &p_method, const Variant **p_argptrs, int p_argcount, const Callable::CallError &ce) {
return get_call_error_text(nullptr, p_method, p_argptrs, p_argcount, ce);
}
String Variant::get_call_error_text(Object *p_base, const StringName &p_method, const Variant **p_argptrs, int p_argcount, const Callable::CallError &ce) {
String err_text;
if (ce.error == Callable::CallError::CALL_ERROR_INVALID_ARGUMENT) {
int errorarg = ce.argument;
if (p_argptrs) {
err_text = "Cannot convert argument " + itos(errorarg + 1) + " from " + Variant::get_type_name(p_argptrs[errorarg]->get_type()) + " to " + Variant::get_type_name(Variant::Type(ce.expected)) + ".";
} else {
err_text = "Cannot convert argument " + itos(errorarg + 1) + " from [missing argptr, type unknown] to " + Variant::get_type_name(Variant::Type(ce.expected)) + ".";
}
} else if (ce.error == Callable::CallError::CALL_ERROR_TOO_MANY_ARGUMENTS) {
err_text = "Method expected " + itos(ce.argument) + " arguments, but called with " + itos(p_argcount) + ".";
} else if (ce.error == Callable::CallError::CALL_ERROR_TOO_FEW_ARGUMENTS) {
err_text = "Method expected " + itos(ce.argument) + " arguments, but called with " + itos(p_argcount) + ".";
} else if (ce.error == Callable::CallError::CALL_ERROR_INVALID_METHOD) {
err_text = "Method not found.";
} else if (ce.error == Callable::CallError::CALL_ERROR_INSTANCE_IS_NULL) {
err_text = "Instance is null";
} else if (ce.error == Callable::CallError::CALL_OK) {
return "Call OK";
}
String base_text;
if (p_base) {
base_text = p_base->get_class();
Ref<Resource> script = p_base->get_script();
if (script.is_valid() && script->get_path().is_resource_file()) {
base_text += "(" + script->get_path().get_file() + ")";
}
base_text += "::";
}
return "'" + base_text + String(p_method) + "': " + err_text;
}
String Variant::get_callable_error_text(const Callable &p_callable, const Variant **p_argptrs, int p_argcount, const Callable::CallError &ce) {
return get_call_error_text(p_callable.get_object(), p_callable.get_method(), p_argptrs, p_argcount, ce);
}
String vformat(const String &p_text, const Variant &p1, const Variant &p2, const Variant &p3, const Variant &p4, const Variant &p5) {
Array args;
if (p1.get_type() != Variant::NIL) {
args.push_back(p1);
if (p2.get_type() != Variant::NIL) {
args.push_back(p2);
if (p3.get_type() != Variant::NIL) {
args.push_back(p3);
if (p4.get_type() != Variant::NIL) {
args.push_back(p4);
if (p5.get_type() != Variant::NIL) {
args.push_back(p5);
}
}
}
}
}
bool error = false;
String fmt = p_text.sprintf(args, &error);
ERR_FAIL_COND_V_MSG(error, String(), fmt);
return fmt;
}
void Variant::register_types() {
_register_variant_operators();
_register_variant_methods();
_register_variant_setters_getters();
_register_variant_constructors();
_register_variant_destructors();
_register_variant_utility_functions();
}
void Variant::unregister_types() {
_unregister_variant_operators();
_unregister_variant_methods();
_unregister_variant_setters_getters();
_unregister_variant_destructors();
_unregister_variant_utility_functions();
}