/*************************************************************************/ /* variant_op.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/object/object.h" #include "core/object/object_rc.h" #include "core/object/script_language.h" #define CASE_TYPE_ALL(PREFIX, OP) \ CASE_TYPE(PREFIX, OP, INT) \ CASE_TYPE_ALL_BUT_INT(PREFIX, OP) #define CASE_TYPE_ALL_BUT_INT(PREFIX, OP) \ CASE_TYPE(PREFIX, OP, NIL) \ CASE_TYPE(PREFIX, OP, BOOL) \ CASE_TYPE(PREFIX, OP, REAL) \ CASE_TYPE(PREFIX, OP, STRING) \ CASE_TYPE(PREFIX, OP, RECT2) \ CASE_TYPE(PREFIX, OP, RECT2I) \ CASE_TYPE(PREFIX, OP, VECTOR2) \ CASE_TYPE(PREFIX, OP, VECTOR2I) \ CASE_TYPE(PREFIX, OP, VECTOR3) \ CASE_TYPE(PREFIX, OP, VECTOR3I) \ CASE_TYPE(PREFIX, OP, VECTOR4) \ CASE_TYPE(PREFIX, OP, VECTOR4I) \ CASE_TYPE(PREFIX, OP, PLANE) \ CASE_TYPE(PREFIX, OP, QUATERNION) \ CASE_TYPE(PREFIX, OP, AABB) \ CASE_TYPE(PREFIX, OP, BASIS) \ CASE_TYPE(PREFIX, OP, TRANSFORM) \ CASE_TYPE(PREFIX, OP, TRANSFORM2D) \ CASE_TYPE(PREFIX, OP, PROJECTION) \ CASE_TYPE(PREFIX, OP, COLOR) \ CASE_TYPE(PREFIX, OP, NODE_PATH) \ CASE_TYPE(PREFIX, OP, RID) \ CASE_TYPE(PREFIX, OP, OBJECT) \ CASE_TYPE(PREFIX, OP, STRING_NAME) \ CASE_TYPE(PREFIX, OP, DICTIONARY) \ CASE_TYPE(PREFIX, OP, ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_BYTE_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_INT_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_REAL_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_STRING_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_VECTOR2_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_VECTOR2I_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_VECTOR3_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_VECTOR3I_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_VECTOR4_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_VECTOR4I_ARRAY) \ CASE_TYPE(PREFIX, OP, POOL_COLOR_ARRAY) #ifdef __GNUC__ #define TYPE(PREFIX, OP, TYPE) &&PREFIX##_##OP##_##TYPE /* clang-format off */ #define TYPES(PREFIX, OP) { \ TYPE(PREFIX, OP, NIL), \ TYPE(PREFIX, OP, BOOL), \ TYPE(PREFIX, OP, INT), \ TYPE(PREFIX, OP, REAL), \ TYPE(PREFIX, OP, STRING), \ TYPE(PREFIX, OP, RECT2), \ TYPE(PREFIX, OP, RECT2I), \ TYPE(PREFIX, OP, VECTOR2), \ TYPE(PREFIX, OP, VECTOR2I), \ TYPE(PREFIX, OP, VECTOR3), \ TYPE(PREFIX, OP, VECTOR3I), \ TYPE(PREFIX, OP, VECTOR4), \ TYPE(PREFIX, OP, VECTOR4I), \ TYPE(PREFIX, OP, PLANE), \ TYPE(PREFIX, OP, QUATERNION), \ TYPE(PREFIX, OP, AABB), \ TYPE(PREFIX, OP, BASIS), \ TYPE(PREFIX, OP, TRANSFORM), \ TYPE(PREFIX, OP, TRANSFORM2D), \ TYPE(PREFIX, OP, PROJECTION), \ TYPE(PREFIX, OP, COLOR), \ TYPE(PREFIX, OP, NODE_PATH), \ TYPE(PREFIX, OP, RID), \ TYPE(PREFIX, OP, OBJECT), \ TYPE(PREFIX, OP, STRING_NAME), \ TYPE(PREFIX, OP, DICTIONARY), \ TYPE(PREFIX, OP, ARRAY), \ TYPE(PREFIX, OP, POOL_BYTE_ARRAY), \ TYPE(PREFIX, OP, POOL_INT_ARRAY), \ TYPE(PREFIX, OP, POOL_REAL_ARRAY), \ TYPE(PREFIX, OP, POOL_STRING_ARRAY), \ TYPE(PREFIX, OP, POOL_VECTOR2_ARRAY), \ TYPE(PREFIX, OP, POOL_VECTOR2I_ARRAY), \ TYPE(PREFIX, OP, POOL_VECTOR3_ARRAY), \ TYPE(PREFIX, OP, POOL_VECTOR3I_ARRAY), \ TYPE(PREFIX, OP, POOL_VECTOR4_ARRAY), \ TYPE(PREFIX, OP, POOL_VECTOR4I_ARRAY), \ TYPE(PREFIX, OP, POOL_COLOR_ARRAY), \ } /* clang-format on */ #define CASES(PREFIX) static const void *switch_table_##PREFIX[25][38] = { \ TYPES(PREFIX, OP_EQUAL), \ TYPES(PREFIX, OP_NOT_EQUAL), \ TYPES(PREFIX, OP_LESS), \ TYPES(PREFIX, OP_LESS_EQUAL), \ TYPES(PREFIX, OP_GREATER), \ TYPES(PREFIX, OP_GREATER_EQUAL), \ TYPES(PREFIX, OP_ADD), \ TYPES(PREFIX, OP_SUBTRACT), \ TYPES(PREFIX, OP_MULTIPLY), \ TYPES(PREFIX, OP_DIVIDE), \ TYPES(PREFIX, OP_NEGATE), \ TYPES(PREFIX, OP_POSITIVE), \ TYPES(PREFIX, OP_MODULE), \ TYPES(PREFIX, OP_STRING_CONCAT), \ TYPES(PREFIX, OP_SHIFT_LEFT), \ TYPES(PREFIX, OP_SHIFT_RIGHT), \ TYPES(PREFIX, OP_BIT_AND), \ TYPES(PREFIX, OP_BIT_OR), \ TYPES(PREFIX, OP_BIT_XOR), \ TYPES(PREFIX, OP_BIT_NEGATE), \ TYPES(PREFIX, OP_AND), \ TYPES(PREFIX, OP_OR), \ TYPES(PREFIX, OP_XOR), \ TYPES(PREFIX, OP_NOT), \ TYPES(PREFIX, OP_IN), \ } #define SWITCH(PREFIX, op, val) goto *switch_table_##PREFIX[op][val]; #define SWITCH_OP(PREFIX, OP, val) #define CASE_TYPE(PREFIX, OP, TYPE) PREFIX##_##OP##_##TYPE: #else #define CASES(PREFIX) #define SWITCH(PREFIX, op, val) switch (op) #define SWITCH_OP(PREFIX, OP, val) \ case OP: \ switch (val) #define CASE_TYPE(PREFIX, OP, TYPE) case TYPE: #endif Variant::operator bool() const { return booleanize(); } // We consider all uninitialized or empty types to be false based on the type's // zeroiness. bool Variant::booleanize() const { return !is_zero(); } #define _RETURN(m_what) \ { \ r_ret = m_what; \ return; \ } #define _RETURN_FAIL \ { \ r_valid = false; \ return; \ } #define DEFAULT_OP_NUM(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == INT) \ _RETURN(p_a._data.m_type m_op p_b._data._int); \ if (p_b.type == REAL) \ _RETURN(p_a._data.m_type m_op p_b._data._real); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_NUM_NULL(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == INT) \ _RETURN(p_a._data.m_type m_op p_b._data._int); \ if (p_b.type == REAL) \ _RETURN(p_a._data.m_type m_op p_b._data._real); \ if (p_b.type == NIL) \ _RETURN(!(p_b.type m_op NIL)); \ \ _RETURN_FAIL \ }; #ifdef DEBUG_ENABLED #define DEFAULT_OP_NUM_DIV(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == INT) { \ if (p_b._data._int == 0) { \ r_valid = false; \ _RETURN("Division By Zero"); \ } \ _RETURN(p_a._data.m_type / p_b._data._int); \ } \ if (p_b.type == REAL) { \ if (p_b._data._real == 0) { \ r_valid = false; \ _RETURN("Division By Zero"); \ } \ _RETURN(p_a._data.m_type / p_b._data._real); \ } \ \ _RETURN_FAIL \ }; #else #define DEFAULT_OP_NUM_DIV(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == INT) \ _RETURN(p_a._data.m_type / p_b._data._int); \ if (p_b.type == REAL) \ _RETURN(p_a._data.m_type / p_b._data._real); \ \ _RETURN_FAIL \ }; #endif #define DEFAULT_OP_NUM_NEG(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ _RETURN(-p_a._data.m_type); \ }; #define DEFAULT_OP_NUM_POS(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ _RETURN(p_a._data.m_type); \ }; #define DEFAULT_OP_NUM_VEC(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == INT) \ _RETURN(p_a._data.m_type m_op p_b._data._int); \ if (p_b.type == REAL) \ _RETURN(p_a._data.m_type m_op p_b._data._real); \ if (p_b.type == VECTOR2) \ _RETURN(p_a._data.m_type m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == VECTOR2I) \ _RETURN(p_a._data.m_type m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == VECTOR3) \ _RETURN(p_a._data.m_type m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == VECTOR3I) \ _RETURN(p_a._data.m_type m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == VECTOR4) \ _RETURN(p_a._data.m_type m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == VECTOR4I) \ _RETURN(p_a._data.m_type m_op *reinterpret_cast(p_b._data._mem)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_STR_REV(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == STRING) \ _RETURN(*reinterpret_cast(p_b._data._mem) m_op *reinterpret_cast(p_a._data._mem)); \ if (p_b.type == STRING_NAME) \ _RETURN(*reinterpret_cast(p_b._data._mem) m_op *reinterpret_cast(p_a._data._mem)); \ if (p_b.type == NODE_PATH) \ _RETURN(*reinterpret_cast(p_b._data._mem) m_op *reinterpret_cast(p_a._data._mem)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_STR(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == STRING) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == STRING_NAME) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NODE_PATH) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_STR_NULL(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == STRING) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == STRING_NAME) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NODE_PATH) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NIL) \ _RETURN(!(p_b.type m_op NIL)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_STR_NULL_NP(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == STRING) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NODE_PATH) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NIL) \ _RETURN(!(p_b.type m_op NIL)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_STR_NULL_SN(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == STRING) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == STRING_NAME) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NIL) \ _RETURN(!(p_b.type m_op NIL)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_LOCALMEM_REV(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(*reinterpret_cast(p_b._data._mem) m_op *reinterpret_cast(p_a._data._mem)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_LOCALMEM(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_LOCALMEM_NULL(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == NIL) \ _RETURN(!(p_b.type m_op NIL)); \ \ _RETURN_FAIL \ }; #define DEFAULT_OP_LOCALMEM_NEG(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ _RETURN(-*reinterpret_cast(p_a._data._mem)); \ } #define DEFAULT_OP_LOCALMEM_POS(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ _RETURN(*reinterpret_cast(p_a._data._mem)); \ } #define DEFAULT_OP_LOCALMEM_NUM(m_prefix, m_op_name, m_name, m_op, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op *reinterpret_cast(p_b._data._mem)); \ if (p_b.type == INT) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op p_b._data._int); \ if (p_b.type == REAL) \ _RETURN(*reinterpret_cast(p_a._data._mem) m_op p_b._data._real); \ \ _RETURN_FAIL \ } #define DEFAULT_OP_PTR(m_op, m_name, m_sub) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(p_a._data.m_sub m_op p_b._data.m_sub); \ \ _RETURN_FAIL \ } #define DEFAULT_OP_PTRREF(m_prefix, m_op_name, m_name, m_op, m_sub) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(*p_a._data.m_sub m_op *p_b._data.m_sub); \ \ _RETURN_FAIL \ } #define DEFAULT_OP_PTRREF_NULL(m_prefix, m_op_name, m_name, m_op, m_sub) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == m_name) \ _RETURN(*p_a._data.m_sub m_op *p_b._data.m_sub); \ if (p_b.type == NIL) \ _RETURN(!(p_b.type m_op NIL)); \ \ _RETURN_FAIL \ } #define DEFAULT_OP_ARRAY_EQ(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == NIL) \ _RETURN(false) \ DEFAULT_OP_ARRAY_OP_BODY(m_prefix, m_op_name, m_name, m_type, !=, !=, true, false, false) \ } #define DEFAULT_OP_ARRAY_NEQ(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_b.type == NIL) \ _RETURN(true) \ DEFAULT_OP_ARRAY_OP_BODY(m_prefix, m_op_name, m_name, m_type, !=, !=, false, true, true) \ } #define DEFAULT_OP_ARRAY_LT(m_prefix, m_op_name, m_name, m_type) \ DEFAULT_OP_ARRAY_OP(m_prefix, m_op_name, m_name, m_type, <, !=, false, a_len < array_b.size(), true) #define DEFAULT_OP_ARRAY_GT(m_prefix, m_op_name, m_name, m_type) \ DEFAULT_OP_ARRAY_OP(m_prefix, m_op_name, m_name, m_type, >, !=, false, a_len < array_b.size(), true) #define DEFAULT_OP_ARRAY_OP(m_prefix, m_op_name, m_name, m_type, m_opa, m_opb, m_ret_def, m_ret_s, m_ret_f) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ DEFAULT_OP_ARRAY_OP_BODY(m_prefix, m_op_name, m_name, m_type, m_opa, m_opb, m_ret_def, m_ret_s, m_ret_f) \ } #define DEFAULT_OP_ARRAY_OP_BODY(m_prefix, m_op_name, m_name, m_type, m_opa, m_opb, m_ret_def, m_ret_s, m_ret_f) \ if (p_a.type != p_b.type) \ _RETURN_FAIL \ \ const PoolVector &array_a = *reinterpret_cast *>(p_a._data._mem); \ const PoolVector &array_b = *reinterpret_cast *>(p_b._data._mem); \ \ int a_len = array_a.size(); \ if (a_len m_opa array_b.size()) { \ _RETURN(m_ret_s); \ } else { \ PoolVector::Read ra = array_a.read(); \ PoolVector::Read rb = array_b.read(); \ \ for (int i = 0; i < a_len; i++) { \ if (ra[i] m_opb rb[i]) \ _RETURN(m_ret_f); \ } \ \ _RETURN(m_ret_def); \ } #define DEFAULT_OP_ARRAY_ADD(m_prefix, m_op_name, m_name, m_type) \ CASE_TYPE(m_prefix, m_op_name, m_name) { \ if (p_a.type != p_b.type) \ _RETURN_FAIL; \ \ const PoolVector &array_a = *reinterpret_cast *>(p_a._data._mem); \ const PoolVector &array_b = *reinterpret_cast *>(p_b._data._mem); \ PoolVector sum = array_a; \ sum.append_array(array_b); \ _RETURN(sum); \ } void Variant::evaluate(const Operator &p_op, const Variant &p_a, const Variant &p_b, Variant &r_ret, bool &r_valid) { CASES(math); r_valid = true; SWITCH(math, p_op, p_a.type) { SWITCH_OP(math, OP_EQUAL, p_a.type) { CASE_TYPE(math, OP_EQUAL, NIL) { if (p_b.type == NIL) _RETURN(true); if (p_b.type == OBJECT) _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_b) == nullptr); _RETURN(false); } CASE_TYPE(math, OP_EQUAL, BOOL) { if (p_b.type != BOOL) { if (p_b.type == NIL) _RETURN(false); _RETURN_FAIL; } _RETURN(p_a._data._bool == p_b._data._bool); } CASE_TYPE(math, OP_EQUAL, OBJECT) { if (p_b.type == OBJECT) _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) == _UNSAFE_OBJ_PROXY_PTR(p_b)); if (p_b.type == NIL) _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) == nullptr); _RETURN_FAIL; } CASE_TYPE(math, OP_EQUAL, DICTIONARY) { if (p_b.type != DICTIONARY) { if (p_b.type == NIL) _RETURN(false); _RETURN_FAIL; } const Dictionary *arr_a = reinterpret_cast(p_a._data._mem); const Dictionary *arr_b = reinterpret_cast(p_b._data._mem); _RETURN(*arr_a == *arr_b); } CASE_TYPE(math, OP_EQUAL, ARRAY) { if (p_b.type != ARRAY) { if (p_b.type == NIL) _RETURN(false); _RETURN_FAIL; } const Array *arr_a = reinterpret_cast(p_a._data._mem); const Array *arr_b = reinterpret_cast(p_b._data._mem); int l = arr_a->size(); if (arr_b->size() != l) _RETURN(false); for (int i = 0; i < l; i++) { if (!((*arr_a)[i] == (*arr_b)[i])) { _RETURN(false); } } _RETURN(true); } DEFAULT_OP_NUM_NULL(math, OP_EQUAL, INT, ==, _int); DEFAULT_OP_NUM_NULL(math, OP_EQUAL, REAL, ==, _real); DEFAULT_OP_STR_NULL(math, OP_EQUAL, STRING, ==, String); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, RECT2, ==, Rect2); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, RECT2I, ==, Rect2i); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, VECTOR2, ==, Vector2); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, VECTOR2I, ==, Vector2i); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, VECTOR3, ==, Vector3); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, VECTOR3I, ==, Vector3i); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, VECTOR4, ==, Vector4); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, VECTOR4I, ==, Vector4i); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, PLANE, ==, Plane); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, QUATERNION, ==, Quaternion); DEFAULT_OP_PTRREF_NULL(math, OP_EQUAL, AABB, ==, _aabb); DEFAULT_OP_PTRREF_NULL(math, OP_EQUAL, BASIS, ==, _basis); DEFAULT_OP_PTRREF_NULL(math, OP_EQUAL, TRANSFORM, ==, _transform); DEFAULT_OP_PTRREF_NULL(math, OP_EQUAL, TRANSFORM2D, ==, _transform2d); DEFAULT_OP_PTRREF_NULL(math, OP_EQUAL, PROJECTION, ==, _projection); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, COLOR, ==, Color); DEFAULT_OP_STR_NULL_NP(math, OP_EQUAL, NODE_PATH, ==, NodePath); DEFAULT_OP_STR_NULL_SN(math, OP_EQUAL, STRING_NAME, ==, StringName); DEFAULT_OP_LOCALMEM_NULL(math, OP_EQUAL, RID, ==, ::RID); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_BYTE_ARRAY, uint8_t); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_INT_ARRAY, int); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_REAL_ARRAY, real_t); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_STRING_ARRAY, String); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_VECTOR2_ARRAY, Vector2); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_VECTOR2I_ARRAY, Vector2i); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_VECTOR3_ARRAY, Vector3); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_VECTOR3I_ARRAY, Vector3i); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_VECTOR4_ARRAY, Vector4); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_VECTOR4I_ARRAY, Vector4i); DEFAULT_OP_ARRAY_EQ(math, OP_EQUAL, POOL_COLOR_ARRAY, Color); } SWITCH_OP(math, OP_NOT_EQUAL, p_a.type) { CASE_TYPE(math, OP_NOT_EQUAL, NIL) { if (p_b.type == NIL) _RETURN(false); if (p_b.type == OBJECT) _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_b) != nullptr); _RETURN(true); } CASE_TYPE(math, OP_NOT_EQUAL, BOOL) { if (p_b.type != BOOL) { if (p_b.type == NIL) _RETURN(true); _RETURN_FAIL; } _RETURN(p_a._data._bool != p_b._data._bool); } CASE_TYPE(math, OP_NOT_EQUAL, OBJECT) { if (p_b.type == OBJECT) _RETURN((_UNSAFE_OBJ_PROXY_PTR(p_a) != _UNSAFE_OBJ_PROXY_PTR(p_b))); if (p_b.type == NIL) _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) != nullptr); _RETURN_FAIL; } CASE_TYPE(math, OP_NOT_EQUAL, DICTIONARY) { if (p_b.type != DICTIONARY) { if (p_b.type == NIL) _RETURN(true); _RETURN_FAIL; } const Dictionary *arr_a = reinterpret_cast(p_a._data._mem); const Dictionary *arr_b = reinterpret_cast(p_b._data._mem); _RETURN(*arr_a != *arr_b); } CASE_TYPE(math, OP_NOT_EQUAL, ARRAY) { if (p_b.type != ARRAY) { if (p_b.type == NIL) _RETURN(true); _RETURN_FAIL; } const Array *arr_a = reinterpret_cast(p_a._data._mem); const Array *arr_b = reinterpret_cast(p_b._data._mem); int l = arr_a->size(); if (arr_b->size() != l) _RETURN(true); for (int i = 0; i < l; i++) { if (((*arr_a)[i] != (*arr_b)[i])) { _RETURN(true); } } _RETURN(false); } DEFAULT_OP_NUM_NULL(math, OP_NOT_EQUAL, INT, !=, _int); DEFAULT_OP_NUM_NULL(math, OP_NOT_EQUAL, REAL, !=, _real); DEFAULT_OP_STR_NULL(math, OP_NOT_EQUAL, STRING, !=, String); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, RECT2, !=, Rect2); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, RECT2I, !=, Rect2i); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, VECTOR2, !=, Vector2); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, VECTOR2I, !=, Vector2i); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, VECTOR3, !=, Vector3); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, VECTOR3I, !=, Vector3i); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, VECTOR4, !=, Vector4); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, VECTOR4I, !=, Vector4i); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, PLANE, !=, Plane); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, QUATERNION, !=, Quaternion); DEFAULT_OP_PTRREF_NULL(math, OP_NOT_EQUAL, AABB, !=, _aabb); DEFAULT_OP_PTRREF_NULL(math, OP_NOT_EQUAL, BASIS, !=, _basis); DEFAULT_OP_PTRREF_NULL(math, OP_NOT_EQUAL, TRANSFORM, !=, _transform); DEFAULT_OP_PTRREF_NULL(math, OP_NOT_EQUAL, TRANSFORM2D, !=, _transform2d); DEFAULT_OP_PTRREF_NULL(math, OP_NOT_EQUAL, PROJECTION, !=, _projection); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, COLOR, !=, Color); DEFAULT_OP_STR_NULL_NP(math, OP_NOT_EQUAL, NODE_PATH, !=, NodePath); DEFAULT_OP_STR_NULL_SN(math, OP_NOT_EQUAL, STRING_NAME, !=, StringName); DEFAULT_OP_LOCALMEM_NULL(math, OP_NOT_EQUAL, RID, !=, ::RID); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_BYTE_ARRAY, uint8_t); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_INT_ARRAY, int); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_REAL_ARRAY, real_t); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_STRING_ARRAY, String); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_VECTOR2_ARRAY, Vector2); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_VECTOR2I_ARRAY, Vector2i); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_VECTOR3_ARRAY, Vector3); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_VECTOR3I_ARRAY, Vector3i); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_VECTOR4_ARRAY, Vector4); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_VECTOR4I_ARRAY, Vector4i); DEFAULT_OP_ARRAY_NEQ(math, OP_NOT_EQUAL, POOL_COLOR_ARRAY, Color); } SWITCH_OP(math, OP_LESS, p_a.type) { CASE_TYPE(math, OP_LESS, BOOL) { if (p_b.type != BOOL) _RETURN_FAIL; if (p_a._data._bool == p_b._data._bool) _RETURN(false); if (p_a._data._bool && !p_b._data._bool) _RETURN(false); _RETURN(true); } CASE_TYPE(math, OP_LESS, OBJECT) { if (p_b.type != OBJECT) _RETURN_FAIL; _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) < _UNSAFE_OBJ_PROXY_PTR(p_b)); } CASE_TYPE(math, OP_LESS, ARRAY) { if (p_b.type != ARRAY) _RETURN_FAIL; const Array *arr_a = reinterpret_cast(p_a._data._mem); const Array *arr_b = reinterpret_cast(p_b._data._mem); int l = arr_a->size(); if (arr_b->size() < l) _RETURN(false); for (int i = 0; i < l; i++) { if (!((*arr_a)[i] < (*arr_b)[i])) { _RETURN(true); } } _RETURN(false); } DEFAULT_OP_NUM(math, OP_LESS, INT, <, _int); DEFAULT_OP_NUM(math, OP_LESS, REAL, <, _real); DEFAULT_OP_STR(math, OP_LESS, STRING, <, String); DEFAULT_OP_LOCALMEM(math, OP_LESS, VECTOR2, <, Vector2); DEFAULT_OP_LOCALMEM(math, OP_LESS, VECTOR2I, <, Vector2i); DEFAULT_OP_LOCALMEM(math, OP_LESS, VECTOR3, <, Vector3); DEFAULT_OP_LOCALMEM(math, OP_LESS, VECTOR3I, <, Vector3i); DEFAULT_OP_LOCALMEM(math, OP_LESS, VECTOR4, <, Vector4); DEFAULT_OP_LOCALMEM(math, OP_LESS, VECTOR4I, <, Vector4i); DEFAULT_OP_LOCALMEM(math, OP_LESS, RID, <, ::RID); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_BYTE_ARRAY, uint8_t); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_INT_ARRAY, int); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_REAL_ARRAY, real_t); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_STRING_ARRAY, String); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_VECTOR2_ARRAY, Vector2); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_VECTOR2I_ARRAY, Vector2i); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_VECTOR3_ARRAY, Vector3); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_VECTOR3I_ARRAY, Vector3i); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_VECTOR4_ARRAY, Vector4); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_VECTOR4I_ARRAY, Vector4i); DEFAULT_OP_ARRAY_LT(math, OP_LESS, POOL_COLOR_ARRAY, Color); CASE_TYPE(math, OP_LESS, NIL) CASE_TYPE(math, OP_LESS, RECT2) CASE_TYPE(math, OP_LESS, RECT2I) CASE_TYPE(math, OP_LESS, PLANE) CASE_TYPE(math, OP_LESS, QUATERNION) CASE_TYPE(math, OP_LESS, AABB) CASE_TYPE(math, OP_LESS, BASIS) CASE_TYPE(math, OP_LESS, TRANSFORM) CASE_TYPE(math, OP_LESS, TRANSFORM2D) CASE_TYPE(math, OP_LESS, PROJECTION) CASE_TYPE(math, OP_LESS, STRING_NAME) CASE_TYPE(math, OP_LESS, COLOR) CASE_TYPE(math, OP_LESS, NODE_PATH) CASE_TYPE(math, OP_LESS, DICTIONARY) _RETURN_FAIL; } SWITCH_OP(math, OP_LESS_EQUAL, p_a.type) { CASE_TYPE(math, OP_LESS_EQUAL, OBJECT) { if (p_b.type != OBJECT) _RETURN_FAIL; _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) <= _UNSAFE_OBJ_PROXY_PTR(p_b)); } DEFAULT_OP_NUM(math, OP_LESS_EQUAL, INT, <=, _int); DEFAULT_OP_NUM(math, OP_LESS_EQUAL, REAL, <=, _real); DEFAULT_OP_STR(math, OP_LESS_EQUAL, STRING, <=, String); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, VECTOR2, <=, Vector2); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, VECTOR2I, <=, Vector2i); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, VECTOR3, <=, Vector3); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, VECTOR3I, <=, Vector3i); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, VECTOR4, <=, Vector4); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, VECTOR4I, <=, Vector4i); DEFAULT_OP_LOCALMEM(math, OP_LESS_EQUAL, RID, <=, ::RID); CASE_TYPE(math, OP_LESS_EQUAL, NIL) CASE_TYPE(math, OP_LESS_EQUAL, BOOL) CASE_TYPE(math, OP_LESS_EQUAL, RECT2) CASE_TYPE(math, OP_LESS_EQUAL, RECT2I) CASE_TYPE(math, OP_LESS_EQUAL, PLANE) CASE_TYPE(math, OP_LESS_EQUAL, QUATERNION) CASE_TYPE(math, OP_LESS_EQUAL, AABB) CASE_TYPE(math, OP_LESS_EQUAL, BASIS) CASE_TYPE(math, OP_LESS_EQUAL, TRANSFORM) CASE_TYPE(math, OP_LESS_EQUAL, TRANSFORM2D) CASE_TYPE(math, OP_LESS_EQUAL, PROJECTION) CASE_TYPE(math, OP_LESS_EQUAL, COLOR) CASE_TYPE(math, OP_LESS_EQUAL, NODE_PATH) CASE_TYPE(math, OP_LESS_EQUAL, STRING_NAME) CASE_TYPE(math, OP_LESS_EQUAL, DICTIONARY) CASE_TYPE(math, OP_LESS_EQUAL, ARRAY) CASE_TYPE(math, OP_LESS_EQUAL, POOL_BYTE_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_INT_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_REAL_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_STRING_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_VECTOR2_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_VECTOR2I_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_VECTOR3_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_VECTOR3I_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_VECTOR4_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_VECTOR4I_ARRAY); CASE_TYPE(math, OP_LESS_EQUAL, POOL_COLOR_ARRAY); _RETURN_FAIL; } SWITCH_OP(math, OP_GREATER, p_a.type) { CASE_TYPE(math, OP_GREATER, BOOL) { if (p_b.type != BOOL) _RETURN_FAIL; if (p_a._data._bool == p_b._data._bool) _RETURN(false); if (!p_a._data._bool && p_b._data._bool) _RETURN(false); _RETURN(true); } CASE_TYPE(math, OP_GREATER, OBJECT) { if (p_b.type != OBJECT) _RETURN_FAIL; _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) > _UNSAFE_OBJ_PROXY_PTR(p_b)); } CASE_TYPE(math, OP_GREATER, ARRAY) { if (p_b.type != ARRAY) _RETURN_FAIL; const Array *arr_a = reinterpret_cast(p_a._data._mem); const Array *arr_b = reinterpret_cast(p_b._data._mem); int l = arr_a->size(); if (arr_b->size() > l) _RETURN(false); for (int i = 0; i < l; i++) { if (((*arr_a)[i] < (*arr_b)[i])) { _RETURN(false); } } _RETURN(true); } DEFAULT_OP_NUM(math, OP_GREATER, INT, >, _int); DEFAULT_OP_NUM(math, OP_GREATER, REAL, >, _real); DEFAULT_OP_STR_REV(math, OP_GREATER, STRING, <, String); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, VECTOR2, <, Vector2); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, VECTOR2I, <, Vector2i); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, VECTOR3, <, Vector3); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, VECTOR3I, <, Vector3i); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, VECTOR4, <, Vector4); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, VECTOR4I, <, Vector4i); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER, RID, <, ::RID); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_BYTE_ARRAY, uint8_t); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_INT_ARRAY, int); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_REAL_ARRAY, real_t); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_STRING_ARRAY, String); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_VECTOR2_ARRAY, Vector2); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_VECTOR2I_ARRAY, Vector2i); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_VECTOR3_ARRAY, Vector3); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_VECTOR3I_ARRAY, Vector3i); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_VECTOR4_ARRAY, Vector4); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_VECTOR4I_ARRAY, Vector4i); DEFAULT_OP_ARRAY_GT(math, OP_GREATER, POOL_COLOR_ARRAY, Color); CASE_TYPE(math, OP_GREATER, NIL) CASE_TYPE(math, OP_GREATER, RECT2) CASE_TYPE(math, OP_GREATER, RECT2I) CASE_TYPE(math, OP_GREATER, PLANE) CASE_TYPE(math, OP_GREATER, QUATERNION) CASE_TYPE(math, OP_GREATER, AABB) CASE_TYPE(math, OP_GREATER, BASIS) CASE_TYPE(math, OP_GREATER, STRING_NAME) CASE_TYPE(math, OP_GREATER, TRANSFORM) CASE_TYPE(math, OP_GREATER, TRANSFORM2D) CASE_TYPE(math, OP_GREATER, PROJECTION) CASE_TYPE(math, OP_GREATER, COLOR) CASE_TYPE(math, OP_GREATER, NODE_PATH) CASE_TYPE(math, OP_GREATER, DICTIONARY) _RETURN_FAIL; } SWITCH_OP(math, OP_GREATER_EQUAL, p_a.type) { CASE_TYPE(math, OP_GREATER_EQUAL, OBJECT) { if (p_b.type != OBJECT) _RETURN_FAIL; _RETURN(_UNSAFE_OBJ_PROXY_PTR(p_a) >= _UNSAFE_OBJ_PROXY_PTR(p_b)); } DEFAULT_OP_NUM(math, OP_GREATER_EQUAL, INT, >=, _int); DEFAULT_OP_NUM(math, OP_GREATER_EQUAL, REAL, >=, _real); DEFAULT_OP_STR_REV(math, OP_GREATER_EQUAL, STRING, <=, String); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, VECTOR2, <=, Vector2); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, VECTOR2I, <=, Vector2i); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, VECTOR3, <=, Vector3); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, VECTOR3I, <=, Vector3i); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, VECTOR4, <=, Vector4); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, VECTOR4I, <=, Vector4i); DEFAULT_OP_LOCALMEM_REV(math, OP_GREATER_EQUAL, RID, <=, ::RID); CASE_TYPE(math, OP_GREATER_EQUAL, NIL) CASE_TYPE(math, OP_GREATER_EQUAL, BOOL) CASE_TYPE(math, OP_GREATER_EQUAL, RECT2) CASE_TYPE(math, OP_GREATER_EQUAL, RECT2I) CASE_TYPE(math, OP_GREATER_EQUAL, PLANE) CASE_TYPE(math, OP_GREATER_EQUAL, QUATERNION) CASE_TYPE(math, OP_GREATER_EQUAL, AABB) CASE_TYPE(math, OP_GREATER_EQUAL, BASIS) CASE_TYPE(math, OP_GREATER_EQUAL, TRANSFORM) CASE_TYPE(math, OP_GREATER_EQUAL, TRANSFORM2D) CASE_TYPE(math, OP_GREATER_EQUAL, PROJECTION) CASE_TYPE(math, OP_GREATER_EQUAL, COLOR) CASE_TYPE(math, OP_GREATER_EQUAL, NODE_PATH) CASE_TYPE(math, OP_GREATER_EQUAL, DICTIONARY) CASE_TYPE(math, OP_GREATER_EQUAL, STRING_NAME) CASE_TYPE(math, OP_GREATER_EQUAL, ARRAY) CASE_TYPE(math, OP_GREATER_EQUAL, POOL_BYTE_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_INT_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_REAL_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_STRING_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_VECTOR2_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_VECTOR2I_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_VECTOR3_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_VECTOR3I_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_VECTOR4_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_VECTOR4I_ARRAY); CASE_TYPE(math, OP_GREATER_EQUAL, POOL_COLOR_ARRAY); _RETURN_FAIL; } SWITCH_OP(math, OP_ADD, p_a.type) { CASE_TYPE(math, OP_ADD, ARRAY) { if (p_a.type != p_b.type) _RETURN_FAIL; const Array &array_a = *reinterpret_cast(p_a._data._mem); const Array &array_b = *reinterpret_cast(p_b._data._mem); Array sum; int asize = array_a.size(); int bsize = array_b.size(); sum.resize(asize + bsize); for (int i = 0; i < asize; i++) { sum[i] = array_a[i]; } for (int i = 0; i < bsize; i++) { sum[i + asize] = array_b[i]; } _RETURN(sum); } DEFAULT_OP_NUM(math, OP_ADD, INT, +, _int); DEFAULT_OP_NUM(math, OP_ADD, REAL, +, _real); DEFAULT_OP_STR(math, OP_ADD, STRING, +, String); DEFAULT_OP_LOCALMEM(math, OP_ADD, VECTOR2, +, Vector2); DEFAULT_OP_LOCALMEM(math, OP_ADD, VECTOR2I, +, Vector2i); DEFAULT_OP_LOCALMEM(math, OP_ADD, VECTOR3, +, Vector3); DEFAULT_OP_LOCALMEM(math, OP_ADD, VECTOR3I, +, Vector3i); DEFAULT_OP_LOCALMEM(math, OP_ADD, VECTOR4, +, Vector4); DEFAULT_OP_LOCALMEM(math, OP_ADD, VECTOR4I, +, Vector4i); DEFAULT_OP_LOCALMEM(math, OP_ADD, QUATERNION, +, Quaternion); DEFAULT_OP_LOCALMEM(math, OP_ADD, COLOR, +, Color); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_BYTE_ARRAY, uint8_t); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_INT_ARRAY, int); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_REAL_ARRAY, real_t); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_STRING_ARRAY, String); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_VECTOR2_ARRAY, Vector2); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_VECTOR2I_ARRAY, Vector2i); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_VECTOR3_ARRAY, Vector3); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_VECTOR3I_ARRAY, Vector3i); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_VECTOR4_ARRAY, Vector4); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_VECTOR4I_ARRAY, Vector4i); DEFAULT_OP_ARRAY_ADD(math, OP_ADD, POOL_COLOR_ARRAY, Color); CASE_TYPE(math, OP_ADD, NIL) CASE_TYPE(math, OP_ADD, BOOL) CASE_TYPE(math, OP_ADD, RECT2) CASE_TYPE(math, OP_ADD, RECT2I) CASE_TYPE(math, OP_ADD, PLANE) CASE_TYPE(math, OP_ADD, AABB) CASE_TYPE(math, OP_ADD, BASIS) CASE_TYPE(math, OP_ADD, TRANSFORM) CASE_TYPE(math, OP_ADD, TRANSFORM2D) CASE_TYPE(math, OP_ADD, PROJECTION) CASE_TYPE(math, OP_ADD, NODE_PATH) CASE_TYPE(math, OP_ADD, RID) CASE_TYPE(math, OP_ADD, OBJECT) CASE_TYPE(math, OP_ADD, DICTIONARY) CASE_TYPE(math, OP_ADD, STRING_NAME) _RETURN_FAIL; } SWITCH_OP(math, OP_SUBTRACT, p_a.type) { DEFAULT_OP_NUM(math, OP_SUBTRACT, INT, -, _int); DEFAULT_OP_NUM(math, OP_SUBTRACT, REAL, -, _real); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, VECTOR2, -, Vector2); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, VECTOR2I, -, Vector2i); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, VECTOR3, -, Vector3); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, VECTOR3I, -, Vector3i); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, VECTOR4, -, Vector4); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, VECTOR4I, -, Vector4i); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, QUATERNION, -, Quaternion); DEFAULT_OP_LOCALMEM(math, OP_SUBTRACT, COLOR, -, Color); CASE_TYPE(math, OP_SUBTRACT, NIL) CASE_TYPE(math, OP_SUBTRACT, BOOL) CASE_TYPE(math, OP_SUBTRACT, STRING) CASE_TYPE(math, OP_SUBTRACT, RECT2) CASE_TYPE(math, OP_SUBTRACT, RECT2I) CASE_TYPE(math, OP_SUBTRACT, PLANE) CASE_TYPE(math, OP_SUBTRACT, AABB) CASE_TYPE(math, OP_SUBTRACT, BASIS) CASE_TYPE(math, OP_SUBTRACT, TRANSFORM) CASE_TYPE(math, OP_SUBTRACT, TRANSFORM2D) CASE_TYPE(math, OP_SUBTRACT, PROJECTION) CASE_TYPE(math, OP_SUBTRACT, NODE_PATH) CASE_TYPE(math, OP_SUBTRACT, RID) CASE_TYPE(math, OP_SUBTRACT, OBJECT) CASE_TYPE(math, OP_SUBTRACT, STRING_NAME) CASE_TYPE(math, OP_SUBTRACT, DICTIONARY) CASE_TYPE(math, OP_SUBTRACT, ARRAY) CASE_TYPE(math, OP_SUBTRACT, POOL_BYTE_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_INT_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_REAL_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_STRING_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_VECTOR2_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_VECTOR2I_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_VECTOR3_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_VECTOR3I_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_VECTOR4_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_VECTOR4I_ARRAY); CASE_TYPE(math, OP_SUBTRACT, POOL_COLOR_ARRAY); _RETURN_FAIL; } SWITCH_OP(math, OP_MULTIPLY, p_a.type) { CASE_TYPE(math, OP_MULTIPLY, QUATERNION) { switch (p_b.type) { case VECTOR3: { _RETURN(reinterpret_cast(p_a._data._mem)->xform(*(const Vector3 *)p_b._data._mem)); } case VECTOR3I: { _RETURN(reinterpret_cast(p_a._data._mem)->xform(*(const Vector3i *)p_b._data._mem)); } case QUATERNION: { _RETURN(*reinterpret_cast(p_a._data._mem) * *reinterpret_cast(p_b._data._mem)); } case REAL: { _RETURN(*reinterpret_cast(p_a._data._mem) * p_b._data._real); } default: _RETURN_FAIL; } } CASE_TYPE(math, OP_MULTIPLY, BASIS) { switch (p_b.type) { case VECTOR3: { _RETURN(p_a._data._basis->xform(*(const Vector3 *)p_b._data._mem)); } case VECTOR3I: { _RETURN(p_a._data._basis->xform(*(const Vector3i *)p_b._data._mem)); } case BASIS: { _RETURN(*p_a._data._basis * *p_b._data._basis); } default: _RETURN_FAIL; } } CASE_TYPE(math, OP_MULTIPLY, TRANSFORM) { switch (p_b.type) { case VECTOR3: { _RETURN(p_a._data._transform->xform(*(const Vector3 *)p_b._data._mem)); } case VECTOR3I: { _RETURN(p_a._data._transform->xform(*(const Vector3i *)p_b._data._mem)); } case TRANSFORM: { _RETURN(*p_a._data._transform * *p_b._data._transform); } default: _RETURN_FAIL; } } CASE_TYPE(math, OP_MULTIPLY, TRANSFORM2D) { switch (p_b.type) { case TRANSFORM2D: { _RETURN(*p_a._data._transform2d * *p_b._data._transform2d); } case VECTOR2: { _RETURN(p_a._data._transform2d->xform(*(const Vector2 *)p_b._data._mem)); } case VECTOR2I: { _RETURN(p_a._data._transform2d->xform(*(const Vector2i *)p_b._data._mem)); } default: _RETURN_FAIL; } } CASE_TYPE(math, OP_MULTIPLY, PROJECTION) { switch (p_b.type) { case VECTOR4: { _RETURN(p_a._data._projection->xform(*(const Vector4 *)p_b._data._mem)); } case VECTOR3: { _RETURN(p_a._data._projection->xform(*(const Vector3 *)p_b._data._mem)); } case PLANE: { _RETURN(p_a._data._projection->xform(*(const Plane *)p_b._data._mem)); } case PROJECTION: { _RETURN(p_a._data._projection->operator*(*(const Projection *)p_b._data._mem)); } default: _RETURN_FAIL; } } DEFAULT_OP_NUM_VEC(math, OP_MULTIPLY, INT, *, _int); DEFAULT_OP_NUM_VEC(math, OP_MULTIPLY, REAL, *, _real); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, VECTOR2, *, Vector2); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, VECTOR2I, *, Vector2i); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, VECTOR3, *, Vector3); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, VECTOR3I, *, Vector3i); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, VECTOR4, *, Vector4); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, VECTOR4I, *, Vector4i); DEFAULT_OP_LOCALMEM_NUM(math, OP_MULTIPLY, COLOR, *, Color); CASE_TYPE(math, OP_MULTIPLY, NIL) CASE_TYPE(math, OP_MULTIPLY, BOOL) CASE_TYPE(math, OP_MULTIPLY, STRING) CASE_TYPE(math, OP_MULTIPLY, RECT2) CASE_TYPE(math, OP_MULTIPLY, RECT2I) CASE_TYPE(math, OP_MULTIPLY, PLANE) CASE_TYPE(math, OP_MULTIPLY, AABB) CASE_TYPE(math, OP_MULTIPLY, NODE_PATH) CASE_TYPE(math, OP_MULTIPLY, RID) CASE_TYPE(math, OP_MULTIPLY, OBJECT) CASE_TYPE(math, OP_MULTIPLY, STRING_NAME) CASE_TYPE(math, OP_MULTIPLY, DICTIONARY) CASE_TYPE(math, OP_MULTIPLY, ARRAY) CASE_TYPE(math, OP_MULTIPLY, POOL_BYTE_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_INT_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_REAL_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_STRING_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_VECTOR2_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_VECTOR2I_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_VECTOR3_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_VECTOR3I_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_VECTOR4_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_VECTOR4I_ARRAY); CASE_TYPE(math, OP_MULTIPLY, POOL_COLOR_ARRAY); _RETURN_FAIL; } SWITCH_OP(math, OP_DIVIDE, p_a.type) { CASE_TYPE(math, OP_DIVIDE, QUATERNION) { if (p_b.type != REAL) _RETURN_FAIL; #ifdef DEBUG_ENABLED if (p_b._data._real == 0) { r_valid = false; _RETURN("Division By Zero"); } #endif _RETURN(*reinterpret_cast(p_a._data._mem) / p_b._data._real); } DEFAULT_OP_NUM_DIV(math, OP_DIVIDE, INT, _int); DEFAULT_OP_NUM_DIV(math, OP_DIVIDE, REAL, _real); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, VECTOR2, /, Vector2); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, VECTOR2I, /, Vector2i); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, VECTOR3, /, Vector3); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, VECTOR3I, /, Vector3i); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, VECTOR4, /, Vector4); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, VECTOR4I, /, Vector4i); DEFAULT_OP_LOCALMEM_NUM(math, OP_DIVIDE, COLOR, /, Color); CASE_TYPE(math, OP_DIVIDE, NIL) CASE_TYPE(math, OP_DIVIDE, BOOL) CASE_TYPE(math, OP_DIVIDE, STRING) CASE_TYPE(math, OP_DIVIDE, RECT2) CASE_TYPE(math, OP_DIVIDE, RECT2I) CASE_TYPE(math, OP_DIVIDE, PLANE) CASE_TYPE(math, OP_DIVIDE, AABB) CASE_TYPE(math, OP_DIVIDE, BASIS) CASE_TYPE(math, OP_DIVIDE, TRANSFORM) CASE_TYPE(math, OP_DIVIDE, TRANSFORM2D) CASE_TYPE(math, OP_DIVIDE, PROJECTION) CASE_TYPE(math, OP_DIVIDE, NODE_PATH) CASE_TYPE(math, OP_DIVIDE, RID) CASE_TYPE(math, OP_DIVIDE, OBJECT) CASE_TYPE(math, OP_DIVIDE, STRING_NAME) CASE_TYPE(math, OP_DIVIDE, DICTIONARY) CASE_TYPE(math, OP_DIVIDE, ARRAY) CASE_TYPE(math, OP_DIVIDE, POOL_BYTE_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_INT_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_REAL_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_STRING_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_VECTOR2_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_VECTOR2I_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_VECTOR3_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_VECTOR3I_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_VECTOR4_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_VECTOR4I_ARRAY); CASE_TYPE(math, OP_DIVIDE, POOL_COLOR_ARRAY); _RETURN_FAIL; } SWITCH_OP(math, OP_POSITIVE, p_a.type) { DEFAULT_OP_NUM_POS(math, OP_POSITIVE, INT, _int); DEFAULT_OP_NUM_POS(math, OP_POSITIVE, REAL, _real); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, VECTOR2, Vector2); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, VECTOR2I, Vector2i); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, VECTOR3, Vector3); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, VECTOR3I, Vector3i); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, VECTOR4, Vector4); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, VECTOR4I, Vector4i); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, PLANE, Plane); DEFAULT_OP_LOCALMEM_POS(math, OP_POSITIVE, QUATERNION, Quaternion); CASE_TYPE(math, OP_POSITIVE, NIL) CASE_TYPE(math, OP_POSITIVE, BOOL) CASE_TYPE(math, OP_POSITIVE, STRING) CASE_TYPE(math, OP_POSITIVE, RECT2) CASE_TYPE(math, OP_POSITIVE, RECT2I) CASE_TYPE(math, OP_POSITIVE, AABB) CASE_TYPE(math, OP_POSITIVE, BASIS) CASE_TYPE(math, OP_POSITIVE, TRANSFORM) CASE_TYPE(math, OP_POSITIVE, TRANSFORM2D) CASE_TYPE(math, OP_POSITIVE, PROJECTION) CASE_TYPE(math, OP_POSITIVE, COLOR) CASE_TYPE(math, OP_POSITIVE, NODE_PATH) CASE_TYPE(math, OP_POSITIVE, RID) CASE_TYPE(math, OP_POSITIVE, OBJECT) CASE_TYPE(math, OP_POSITIVE, STRING_NAME) CASE_TYPE(math, OP_POSITIVE, DICTIONARY) CASE_TYPE(math, OP_POSITIVE, ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_BYTE_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_INT_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_REAL_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_STRING_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_VECTOR2_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_VECTOR2I_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_VECTOR3_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_VECTOR3I_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_VECTOR4_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_VECTOR4I_ARRAY) CASE_TYPE(math, OP_POSITIVE, POOL_COLOR_ARRAY) _RETURN_FAIL; } SWITCH_OP(math, OP_NEGATE, p_a.type) { DEFAULT_OP_NUM_NEG(math, OP_NEGATE, INT, _int); DEFAULT_OP_NUM_NEG(math, OP_NEGATE, REAL, _real); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, VECTOR2, Vector2); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, VECTOR2I, Vector2i); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, VECTOR3, Vector3); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, VECTOR3I, Vector3i); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, VECTOR4, Vector4); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, VECTOR4I, Vector4i); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, PLANE, Plane); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, QUATERNION, Quaternion); DEFAULT_OP_LOCALMEM_NEG(math, OP_NEGATE, COLOR, Color); CASE_TYPE(math, OP_NEGATE, NIL) CASE_TYPE(math, OP_NEGATE, BOOL) CASE_TYPE(math, OP_NEGATE, STRING) CASE_TYPE(math, OP_NEGATE, RECT2) CASE_TYPE(math, OP_NEGATE, RECT2I) CASE_TYPE(math, OP_NEGATE, AABB) CASE_TYPE(math, OP_NEGATE, BASIS) CASE_TYPE(math, OP_NEGATE, TRANSFORM) CASE_TYPE(math, OP_NEGATE, TRANSFORM2D) CASE_TYPE(math, OP_NEGATE, PROJECTION) CASE_TYPE(math, OP_NEGATE, NODE_PATH) CASE_TYPE(math, OP_NEGATE, RID) CASE_TYPE(math, OP_NEGATE, OBJECT) CASE_TYPE(math, OP_NEGATE, STRING_NAME) CASE_TYPE(math, OP_NEGATE, DICTIONARY) CASE_TYPE(math, OP_NEGATE, ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_BYTE_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_INT_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_REAL_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_STRING_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_VECTOR2_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_VECTOR2I_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_VECTOR3_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_VECTOR3I_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_VECTOR4_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_VECTOR4I_ARRAY) CASE_TYPE(math, OP_NEGATE, POOL_COLOR_ARRAY) _RETURN_FAIL; } SWITCH_OP(math, OP_MODULE, p_a.type) { CASE_TYPE(math, OP_MODULE, INT) { if (p_b.type != INT) _RETURN_FAIL; #ifdef DEBUG_ENABLED if (p_b._data._int == 0) { r_valid = false; _RETURN("Division By Zero"); } #endif _RETURN(p_a._data._int % p_b._data._int); } CASE_TYPE(math, OP_MODULE, STRING) { const String *format = reinterpret_cast(p_a._data._mem); String result; bool error; if (p_b.type == ARRAY) { // e.g. "frog %s %d" % ["fish", 12] const Array *args = reinterpret_cast(p_b._data._mem); result = format->sprintf(*args, &error); } else { // e.g. "frog %d" % 12 Array args; args.push_back(p_b); result = format->sprintf(args, &error); } r_valid = !error; _RETURN(result); } CASE_TYPE(math, OP_MODULE, NIL) CASE_TYPE(math, OP_MODULE, BOOL) CASE_TYPE(math, OP_MODULE, REAL) CASE_TYPE(math, OP_MODULE, RECT2) CASE_TYPE(math, OP_MODULE, RECT2I) CASE_TYPE(math, OP_MODULE, VECTOR2) CASE_TYPE(math, OP_MODULE, VECTOR2I) CASE_TYPE(math, OP_MODULE, VECTOR3) CASE_TYPE(math, OP_MODULE, VECTOR3I) CASE_TYPE(math, OP_MODULE, VECTOR4) CASE_TYPE(math, OP_MODULE, VECTOR4I) CASE_TYPE(math, OP_MODULE, PLANE) CASE_TYPE(math, OP_MODULE, QUATERNION) CASE_TYPE(math, OP_MODULE, AABB) CASE_TYPE(math, OP_MODULE, BASIS) CASE_TYPE(math, OP_MODULE, TRANSFORM) CASE_TYPE(math, OP_MODULE, TRANSFORM2D) CASE_TYPE(math, OP_MODULE, PROJECTION) CASE_TYPE(math, OP_MODULE, COLOR) CASE_TYPE(math, OP_MODULE, NODE_PATH) CASE_TYPE(math, OP_MODULE, RID) CASE_TYPE(math, OP_MODULE, OBJECT) CASE_TYPE(math, OP_MODULE, STRING_NAME) CASE_TYPE(math, OP_MODULE, DICTIONARY) CASE_TYPE(math, OP_MODULE, ARRAY) CASE_TYPE(math, OP_MODULE, POOL_BYTE_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_INT_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_REAL_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_STRING_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_VECTOR2_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_VECTOR2I_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_VECTOR3_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_VECTOR3I_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_VECTOR4_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_VECTOR4I_ARRAY) CASE_TYPE(math, OP_MODULE, POOL_COLOR_ARRAY) _RETURN_FAIL; } SWITCH_OP(math, OP_STRING_CONCAT, p_a.type) { CASE_TYPE_ALL(math, OP_STRING_CONCAT) _RETURN(p_a.operator String() + p_b.operator String()); } SWITCH_OP(math, OP_SHIFT_LEFT, p_a.type) { CASE_TYPE(math, OP_SHIFT_LEFT, INT) { if (p_b.type != INT) _RETURN_FAIL; if (p_b._data._int < 0 || p_b._data._int >= 64) _RETURN_FAIL; _RETURN(p_a._data._int << p_b._data._int); } CASE_TYPE_ALL_BUT_INT(math, OP_SHIFT_LEFT) _RETURN_FAIL; } SWITCH_OP(math, OP_SHIFT_RIGHT, p_a.type) { CASE_TYPE(math, OP_SHIFT_RIGHT, INT) { if (p_b.type != INT) _RETURN_FAIL; if (p_b._data._int < 0 || p_b._data._int >= 64) _RETURN_FAIL; _RETURN(p_a._data._int >> p_b._data._int); } CASE_TYPE_ALL_BUT_INT(math, OP_SHIFT_RIGHT) _RETURN_FAIL; } SWITCH_OP(math, OP_BIT_AND, p_a.type) { CASE_TYPE(math, OP_BIT_AND, INT) { if (p_b.type != INT) _RETURN_FAIL; _RETURN(p_a._data._int & p_b._data._int); } CASE_TYPE_ALL_BUT_INT(math, OP_BIT_AND) _RETURN_FAIL; } SWITCH_OP(math, OP_BIT_OR, p_a.type) { CASE_TYPE(math, OP_BIT_OR, INT) { if (p_b.type != INT) _RETURN_FAIL; _RETURN(p_a._data._int | p_b._data._int); } CASE_TYPE_ALL_BUT_INT(math, OP_BIT_OR) _RETURN_FAIL; } SWITCH_OP(math, OP_BIT_XOR, p_a.type) { CASE_TYPE(math, OP_BIT_XOR, INT) { if (p_b.type != INT) _RETURN_FAIL; _RETURN(p_a._data._int ^ p_b._data._int); } CASE_TYPE_ALL_BUT_INT(math, OP_BIT_XOR) _RETURN_FAIL; } SWITCH_OP(math, OP_BIT_NEGATE, p_a.type) { CASE_TYPE(math, OP_BIT_NEGATE, INT) { _RETURN(~p_a._data._int); } CASE_TYPE_ALL_BUT_INT(math, OP_BIT_NEGATE) _RETURN_FAIL; } SWITCH_OP(math, OP_AND, p_a.type) { CASE_TYPE_ALL(math, OP_AND) { bool l = p_a.booleanize(); bool r = p_b.booleanize(); _RETURN(l && r); } } SWITCH_OP(math, OP_OR, p_a.type) { CASE_TYPE_ALL(math, OP_OR) { bool l = p_a.booleanize(); bool r = p_b.booleanize(); _RETURN(l || r); } } SWITCH_OP(math, OP_XOR, p_a.type) { CASE_TYPE_ALL(math, OP_XOR) { bool l = p_a.booleanize(); bool r = p_b.booleanize(); _RETURN((l || r) && !(l && r)); } } SWITCH_OP(math, OP_NOT, p_a.type) { CASE_TYPE_ALL(math, OP_NOT) { bool l = p_a.booleanize(); _RETURN(!l); } } SWITCH_OP(math, OP_IN, p_a.type) { CASE_TYPE_ALL(math, OP_IN) _RETURN(p_b.in(p_a, &r_valid)); } } } void Variant::set_named(const StringName &p_index, const Variant &p_value, bool *r_valid) { bool valid = false; switch (type) { case RECT2: { if (p_value.type == Variant::VECTOR2) { Rect2 *v = reinterpret_cast(_data._mem); //scalar name if (p_index == CoreStringNames::singleton->position) { v->position = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->size) { v->size = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->end) { v->size = *reinterpret_cast(p_value._data._mem) - v->position; valid = true; } } else if (p_value.type == Variant::VECTOR2I) { Rect2 *v = reinterpret_cast(_data._mem); //scalar name if (p_index == CoreStringNames::singleton->position) { v->position = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->size) { v->size = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->end) { v->size = *reinterpret_cast(p_value._data._mem) - v->position; valid = true; } } } break; case RECT2I: { if (p_value.type == Variant::VECTOR2) { Rect2i *v = reinterpret_cast(_data._mem); //scalar name if (p_index == CoreStringNames::singleton->position) { v->position = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->size) { v->size = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->end) { v->size = *reinterpret_cast(p_value._data._mem) - v->position; valid = true; } } else if (p_value.type == Variant::VECTOR2I) { Rect2i *v = reinterpret_cast(_data._mem); //scalar name if (p_index == CoreStringNames::singleton->position) { v->position = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->size) { v->size = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->end) { v->size = *reinterpret_cast(p_value._data._mem) - v->position; valid = true; } } } break; case VECTOR2: { if (p_value.type == Variant::INT) { Vector2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Vector2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._real; valid = true; } } } break; case VECTOR2I: { if (p_value.type == Variant::INT) { Vector2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Vector2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = static_cast(p_value._data._real); valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = static_cast(p_value._data._real); valid = true; } } } break; case VECTOR3: { if (p_value.type == Variant::INT) { Vector3 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Vector3 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._real; valid = true; } } } break; case VECTOR3I: { if (p_value.type == Variant::INT) { Vector3i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Vector3i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._real; valid = true; } } } break; case VECTOR4: { if (p_value.type == Variant::INT) { Vector4 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->w = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Vector4 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->w = p_value._data._real; valid = true; } } } break; case VECTOR4I: { if (p_value.type == Variant::INT) { Vector4i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->w = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Vector4i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->w = p_value._data._real; valid = true; } } } break; case PLANE: { if (p_value.type == Variant::INT) { Plane *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->normal.x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->normal.y = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->normal.z = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->d) { v->d = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Plane *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->normal.x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->normal.y = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->normal.z = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->d) { v->d = p_value._data._real; valid = true; } } else if (p_value.type == Variant::VECTOR3) { Plane *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->normal) { v->normal = *reinterpret_cast(p_value._data._mem); valid = true; } } } break; case QUATERNION: { if (p_value.type == Variant::INT) { Quaternion *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->w = p_value._data._int; valid = true; } } else if (p_value.type == Variant::REAL) { Quaternion *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { v->x = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->y = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->z = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->w = p_value._data._real; valid = true; } } } break; // 10 case AABB: { if (p_value.type == Variant::VECTOR3) { ::AABB *v = _data._aabb; //scalar name if (p_index == CoreStringNames::singleton->position) { v->position = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->size) { v->size = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->end) { v->size = *reinterpret_cast(p_value._data._mem) - v->position; valid = true; } } else if (p_value.type == Variant::VECTOR3I) { ::AABB *v = _data._aabb; //scalar name if (p_index == CoreStringNames::singleton->position) { v->position = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->size) { v->size = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->end) { v->size = Vector3(*reinterpret_cast(p_value._data._mem)) - v->position; valid = true; } } } break; case BASIS: { if (p_value.type == Variant::VECTOR3) { Basis *v = _data._basis; //scalar name if (p_index == CoreStringNames::singleton->x) { v->set_axis(0, *reinterpret_cast(p_value._data._mem)); valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->set_axis(1, *reinterpret_cast(p_value._data._mem)); valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->set_axis(2, *reinterpret_cast(p_value._data._mem)); valid = true; } } else if (p_value.type == Variant::VECTOR3I) { Basis *v = _data._basis; //scalar name if (p_index == CoreStringNames::singleton->x) { v->set_axis(0, *reinterpret_cast(p_value._data._mem)); valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->set_axis(1, *reinterpret_cast(p_value._data._mem)); valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->set_axis(2, *reinterpret_cast(p_value._data._mem)); valid = true; } } } break; case TRANSFORM: { if (p_value.type == Variant::BASIS && p_index == CoreStringNames::singleton->basis) { _data._transform->basis = *p_value._data._basis; valid = true; } else if (p_value.type == Variant::VECTOR3 && p_index == CoreStringNames::singleton->origin) { _data._transform->origin = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_value.type == Variant::VECTOR3I && p_index == CoreStringNames::singleton->origin) { _data._transform->origin = *reinterpret_cast(p_value._data._mem); valid = true; } } break; case TRANSFORM2D: { if (p_value.type == Variant::VECTOR2) { Transform2D *v = _data._transform2d; if (p_index == CoreStringNames::singleton->x) { v->columns[0] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->columns[1] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->origin) { v->columns[2] = *reinterpret_cast(p_value._data._mem); valid = true; } } else if (p_value.type == Variant::VECTOR2I) { Transform2D *v = _data._transform2d; if (p_index == CoreStringNames::singleton->x) { v->columns[0] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->columns[1] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->origin) { v->columns[2] = *reinterpret_cast(p_value._data._mem); valid = true; } } } break; case PROJECTION: { if (p_value.type == Variant::VECTOR4) { Projection *v = _data._projection; if (p_index == CoreStringNames::singleton->x) { v->matrix[0] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->y) { v->matrix[1] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->z) { v->matrix[2] = *reinterpret_cast(p_value._data._mem); valid = true; } else if (p_index == CoreStringNames::singleton->w) { v->matrix[3] = *reinterpret_cast(p_value._data._mem); valid = true; } } } break; case COLOR: { if (p_value.type == Variant::INT) { Color *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->r) { v->r = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->g) { v->g = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->b) { v->b = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->a) { v->a = p_value._data._int; valid = true; } else if (p_index == CoreStringNames::singleton->r8) { v->r = p_value._data._int / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->g8) { v->g = p_value._data._int / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->b8) { v->b = p_value._data._int / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->a8) { v->a = p_value._data._int / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->h) { v->set_hsv(p_value._data._int, v->get_s(), v->get_v(), v->a); valid = true; } else if (p_index == CoreStringNames::singleton->s) { v->set_hsv(v->get_h(), p_value._data._int, v->get_v(), v->a); valid = true; } else if (p_index == CoreStringNames::singleton->v) { v->set_hsv(v->get_h(), v->get_s(), p_value._data._int, v->a); valid = true; } } else if (p_value.type == Variant::REAL) { Color *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->r) { v->r = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->g) { v->g = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->b) { v->b = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->a) { v->a = p_value._data._real; valid = true; } else if (p_index == CoreStringNames::singleton->r8) { v->r = p_value._data._real / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->g8) { v->g = p_value._data._real / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->b8) { v->b = p_value._data._real / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->a8) { v->a = p_value._data._real / 255.0; valid = true; } else if (p_index == CoreStringNames::singleton->h) { v->set_hsv(p_value._data._real, v->get_s(), v->get_v(), v->a); valid = true; } else if (p_index == CoreStringNames::singleton->s) { v->set_hsv(v->get_h(), p_value._data._real, v->get_v(), v->a); valid = true; } else if (p_index == CoreStringNames::singleton->v) { v->set_hsv(v->get_h(), v->get_s(), p_value._data._real, v->a); valid = true; } } } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted set on a deleted object."); } #endif break; } obj->set(p_index, p_value, &valid); } break; default: { set(p_index.operator String(), p_value, &valid); } break; } if (r_valid) { *r_valid = valid; } } Variant Variant::get_named(const StringName &p_index, bool *r_valid) const { if (r_valid) { *r_valid = true; } switch (type) { case RECT2: { const Rect2 *v = reinterpret_cast(_data._mem); //scalar name if (p_index == CoreStringNames::singleton->position) { return v->position; } else if (p_index == CoreStringNames::singleton->size) { return v->size; } else if (p_index == CoreStringNames::singleton->end) { return v->size + v->position; } } break; case RECT2I: { const Rect2i *v = reinterpret_cast(_data._mem); //scalar name if (p_index == CoreStringNames::singleton->position) { return v->position; } else if (p_index == CoreStringNames::singleton->size) { return v->size; } else if (p_index == CoreStringNames::singleton->end) { return v->size + v->position; } } break; case VECTOR2: { const Vector2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } } break; case VECTOR2I: { const Vector2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } } break; case VECTOR3: { const Vector3 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } else if (p_index == CoreStringNames::singleton->z) { return v->z; } } break; case VECTOR3I: { const Vector3i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } else if (p_index == CoreStringNames::singleton->z) { return v->z; } } break; case VECTOR4: { const Vector4 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } else if (p_index == CoreStringNames::singleton->z) { return v->z; } else if (p_index == CoreStringNames::singleton->w) { return v->w; } } break; case VECTOR4I: { const Vector4i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } else if (p_index == CoreStringNames::singleton->z) { return v->z; } else if (p_index == CoreStringNames::singleton->w) { return v->w; } } break; case PLANE: { const Plane *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->normal.x; } else if (p_index == CoreStringNames::singleton->y) { return v->normal.y; } else if (p_index == CoreStringNames::singleton->z) { return v->normal.z; } else if (p_index == CoreStringNames::singleton->d) { return v->d; } else if (p_index == CoreStringNames::singleton->normal) { return v->normal; } } break; case QUATERNION: { const Quaternion *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { return v->x; } else if (p_index == CoreStringNames::singleton->y) { return v->y; } else if (p_index == CoreStringNames::singleton->z) { return v->z; } else if (p_index == CoreStringNames::singleton->w) { return v->w; } } break; // 10 case AABB: { const ::AABB *v = _data._aabb; //scalar name if (p_index == CoreStringNames::singleton->position) { return v->position; } else if (p_index == CoreStringNames::singleton->size) { return v->size; } else if (p_index == CoreStringNames::singleton->end) { return v->size + v->position; } } break; case BASIS: { const Basis *v = _data._basis; //scalar name if (p_index == CoreStringNames::singleton->x) { return v->get_axis(0); } else if (p_index == CoreStringNames::singleton->y) { return v->get_axis(1); } else if (p_index == CoreStringNames::singleton->z) { return v->get_axis(2); } } break; case TRANSFORM: { if (p_index == CoreStringNames::singleton->basis) { return _data._transform->basis; } else if (p_index == CoreStringNames::singleton->origin) { return _data._transform->origin; } } break; case TRANSFORM2D: { const Transform2D *v = _data._transform2d; if (p_index == CoreStringNames::singleton->x) { return v->columns[0]; } else if (p_index == CoreStringNames::singleton->y) { return v->columns[1]; } else if (p_index == CoreStringNames::singleton->origin) { return v->columns[2]; } } break; case PROJECTION: { const Projection *v = _data._projection; if (p_index == CoreStringNames::singleton->x) { return v->matrix[0]; } else if (p_index == CoreStringNames::singleton->y) { return v->matrix[1]; } else if (p_index == CoreStringNames::singleton->z) { return v->matrix[2]; } else if (p_index == CoreStringNames::singleton->w) { return v->matrix[3]; } } break; case COLOR: { const Color *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->r) { return v->r; } else if (p_index == CoreStringNames::singleton->g) { return v->g; } else if (p_index == CoreStringNames::singleton->b) { return v->b; } else if (p_index == CoreStringNames::singleton->a) { return v->a; } else if (p_index == CoreStringNames::singleton->r8) { return int(Math::round(v->r * 255.0)); } else if (p_index == CoreStringNames::singleton->g8) { return int(Math::round(v->g * 255.0)); } else if (p_index == CoreStringNames::singleton->b8) { return int(Math::round(v->b * 255.0)); } else if (p_index == CoreStringNames::singleton->a8) { return int(Math::round(v->a * 255.0)); } else if (p_index == CoreStringNames::singleton->h) { return v->get_h(); } else if (p_index == CoreStringNames::singleton->s) { return v->get_s(); } else if (p_index == CoreStringNames::singleton->v) { return v->get_v(); } } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { if (r_valid) { *r_valid = false; } #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted get on a deleted object."); } #endif return Variant(); } return obj->get(p_index, r_valid); } break; case DICTIONARY: { const Dictionary *dic = reinterpret_cast(_data._mem); const Variant *res = dic->getptr(p_index); if (!res) { // Backwards compatibility for before variants supported stringnames. const Variant *res2 = dic->getptr(p_index.operator String()); if (res2) { if (r_valid) { *r_valid = true; } return *res2; } } else { if (r_valid) { *r_valid = true; } return *res; } } break; default: { return get(p_index.operator String(), r_valid); } } if (r_valid) { *r_valid = false; } return Variant(); } #define DEFAULT_OP_ARRAY_CMD(m_name, m_type, skip_test, cmd) \ case m_name: { \ skip_test; \ \ if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { \ int index = p_index; \ m_type *arr = reinterpret_cast(_data._mem); \ \ if (index < 0) \ index += arr->size(); \ if (index >= 0 && index < arr->size()) { \ valid = true; \ cmd; \ } \ } \ } break; #define DEFAULT_OP_DVECTOR_SET(m_name, dv_type, skip_cond) \ DEFAULT_OP_ARRAY_CMD(m_name, PoolVector, if (skip_cond) return;, arr->set(index, p_value); return ) #define DEFAULT_OP_DVECTOR_GET(m_name, dv_type) \ DEFAULT_OP_ARRAY_CMD(m_name, const PoolVector, ;, return arr->get(index)) void Variant::set(const Variant &p_index, const Variant &p_value, bool *r_valid) { static bool _dummy = false; bool &valid = r_valid ? *r_valid : _dummy; valid = false; switch (type) { case NIL: { return; } break; case BOOL: { return; } break; case INT: { return; } break; case REAL: { return; } break; case STRING: { if (p_index.type != Variant::INT && p_index.type != Variant::REAL) { return; } int idx = p_index; String *str = reinterpret_cast(_data._mem); int len = str->length(); if (idx < 0) { idx += len; } if (idx < 0 || idx >= len) { return; } String chr; if (p_value.type == Variant::INT || p_value.type == Variant::REAL) { chr = String::chr(p_value); } else if (p_value.type == Variant::STRING) { chr = p_value; } else { return; } *str = str->substr(0, idx) + chr + str->substr(idx + 1, len); valid = true; return; } break; case RECT2: { if (p_value.type == Variant::VECTOR2 || p_value.type == Variant::VECTOR2I) { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Rect2 *v = reinterpret_cast(_data._mem); if (*str == "position") { valid = true; v->position = p_value; return; } else if (*str == "size") { valid = true; v->size = p_value; return; } else if (*str == "end") { valid = true; v->size = Vector2(p_value) - v->position; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Rect2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->position) { valid = true; v->position = p_value; return; } else if (p_index == CoreStringNames::singleton->size) { valid = true; v->size = p_value; return; } else if (p_index == CoreStringNames::singleton->end) { valid = true; v->size = Vector2(p_value) - v->position; return; } } } else { return; } } break; //7 case RECT2I: { if (p_value.type == Variant::VECTOR2 || p_value.type == Variant::VECTOR2I) { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Rect2i *v = reinterpret_cast(_data._mem); if (*str == "position") { valid = true; v->position = p_value; return; } else if (*str == "size") { valid = true; v->size = p_value; return; } else if (*str == "end") { valid = true; //TODO fix v->size = Vector2i(Vector2(p_value)) - v->position; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Rect2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->position) { valid = true; v->position = p_value; return; } else if (p_index == CoreStringNames::singleton->size) { valid = true; v->size = p_value; return; } else if (p_index == CoreStringNames::singleton->end) { valid = true; v->size = Vector2(p_value) - v->position; return; } } } else { return; } } break; case VECTOR2: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { // scalar index int idx = p_index; if (idx < 0) { idx += 2; } if (idx >= 0 && idx < 2) { Vector2 *v = reinterpret_cast(_data._mem); valid = true; (*v)[idx] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Vector2 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Vector2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } } } break; // 5 case VECTOR2I: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { // scalar index int idx = p_index; if (idx < 0) { idx += 2; } if (idx >= 0 && idx < 2) { Vector2i *v = reinterpret_cast(_data._mem); valid = true; (*v)[idx] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Vector2i *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Vector2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } } } break; //6 case VECTOR3: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 3; } if (idx >= 0 && idx < 3) { Vector3 *v = reinterpret_cast(_data._mem); valid = true; (*v)[idx] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Vector3 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } else if (*str == "z") { valid = true; v->z = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Vector3 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->z = p_value; return; } } } break; case VECTOR3I: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 3; } if (idx >= 0 && idx < 3) { Vector3i *v = reinterpret_cast(_data._mem); valid = true; (*v)[idx] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Vector3 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } else if (*str == "z") { valid = true; v->z = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Vector3i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->z = p_value; return; } } } break; case VECTOR4: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 4; } if (idx >= 0 && idx < 4) { Vector4 *v = reinterpret_cast(_data._mem); valid = true; (*v)[idx] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Vector4 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } else if (*str == "z") { valid = true; v->z = p_value; return; } else if (*str == "w") { valid = true; v->w = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Vector4 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->z = p_value; return; } else if (p_index == CoreStringNames::singleton->w) { valid = true; v->w = p_value; return; } } } break; case VECTOR4I: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 4; } if (idx >= 0 && idx < 4) { Vector4i *v = reinterpret_cast(_data._mem); valid = true; (*v)[idx] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Vector4 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } else if (*str == "z") { valid = true; v->z = p_value; return; } else if (*str == "w") { valid = true; v->w = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Vector4i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->z = p_value; return; } else if (p_index == CoreStringNames::singleton->w) { valid = true; v->w = p_value; return; } } } break; case PLANE: { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Plane *v = reinterpret_cast(_data._mem); if (*str == "x") { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } valid = true; v->normal.x = p_value; return; } else if (*str == "y") { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } valid = true; v->normal.y = p_value; return; } else if (*str == "z") { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } valid = true; v->normal.z = p_value; return; } else if (*str == "normal") { if (p_value.type != Variant::VECTOR3) { return; } valid = true; v->normal = p_value; return; } else if (*str == "d") { valid = true; v->d = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Plane *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } valid = true; v->normal.x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } valid = true; v->normal.y = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } valid = true; v->normal.z = p_value; return; } else if (p_index == CoreStringNames::singleton->normal) { if (p_value.type != Variant::VECTOR3) { return; } valid = true; v->normal = p_value; return; } else if (p_index == CoreStringNames::singleton->d) { valid = true; v->d = p_value; return; } } } break; case QUATERNION: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::STRING) { const String *str = reinterpret_cast(p_index._data._mem); Quaternion *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; v->x = p_value; return; } else if (*str == "y") { valid = true; v->y = p_value; return; } else if (*str == "z") { valid = true; v->z = p_value; return; } else if (*str == "w") { valid = true; v->w = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { Quaternion *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; v->x = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->y = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->z = p_value; return; } else if (p_index == CoreStringNames::singleton->w) { valid = true; v->w = p_value; return; } } } break; // 10 case AABB: { if (p_value.type != Variant::VECTOR3) { return; } if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); ::AABB *v = _data._aabb; if (*str == "position") { valid = true; v->position = p_value; return; } else if (*str == "size") { valid = true; v->size = p_value; return; } else if (*str == "end") { valid = true; v->size = Vector3(p_value) - v->position; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name ::AABB *v = _data._aabb; if (p_index == CoreStringNames::singleton->position) { valid = true; v->position = p_value; return; } else if (p_index == CoreStringNames::singleton->size) { valid = true; v->size = p_value; return; } else if (p_index == CoreStringNames::singleton->end) { valid = true; v->size = Vector3(p_value) - v->position; return; } } } break; case BASIS: { if (p_value.type != Variant::VECTOR3) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; if (index < 0) { index += 3; } if (index >= 0 && index < 3) { Basis *v = _data._basis; valid = true; v->set_axis(index, p_value); return; } } else if (p_index.get_type() == Variant::STRING) { const String *str = reinterpret_cast(p_index._data._mem); Basis *v = _data._basis; if (*str == "x") { valid = true; v->set_axis(0, p_value); return; } else if (*str == "y") { valid = true; v->set_axis(1, p_value); return; } else if (*str == "z") { valid = true; v->set_axis(2, p_value); return; } } else if (p_index.get_type() == Variant::STRING_NAME) { Basis *v = _data._basis; if (p_index == CoreStringNames::singleton->x) { valid = true; v->set_axis(0, p_value); return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->set_axis(1, p_value); return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->set_axis(2, p_value); return; } } } break; case TRANSFORM: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { if (p_value.type != Variant::VECTOR3) { return; } int index = p_index; if (index < 0) { index += 4; } if (index >= 0 && index < 4) { Transform *v = _data._transform; valid = true; if (index == 3) { v->origin = p_value; } else { v->basis.set_axis(index, p_value); } return; } } else if (p_index.get_type() == Variant::STRING) { Transform *v = _data._transform; const String *str = reinterpret_cast(p_index._data._mem); if (*str == "basis") { if (p_value.type != Variant::BASIS) { return; } valid = true; v->basis = p_value; return; } if (*str == "origin") { if (p_value.type != Variant::VECTOR3) { return; } valid = true; v->origin = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { Transform *v = _data._transform; if (p_index == CoreStringNames::singleton->basis) { if (p_value.type != Variant::BASIS) { return; } valid = true; v->basis = p_value; return; } if (p_index == CoreStringNames::singleton->origin) { if (p_value.type != Variant::VECTOR3) { return; } valid = true; v->origin = p_value; return; } } } break; case TRANSFORM2D: { if (p_value.type != Variant::VECTOR2 || p_value.get_type() != Variant::VECTOR2I) { return; } if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; if (index < 0) { index += 3; } if (index >= 0 && index < 3) { Transform2D *v = _data._transform2d; valid = true; v->columns[index] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); Transform2D *v = _data._transform2d; if (*str == "x") { valid = true; v->columns[0] = p_value; return; } else if (*str == "y") { valid = true; v->columns[1] = p_value; return; } else if (*str == "origin") { valid = true; v->columns[2] = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name Transform2D *v = _data._transform2d; if (p_index == CoreStringNames::singleton->x) { valid = true; v->columns[0] = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->columns[1] = p_value; return; } else if (p_index == CoreStringNames::singleton->origin) { valid = true; v->columns[2] = p_value; return; } } } break; case PROJECTION: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { if (p_value.type != Variant::VECTOR4) { return; } int index = p_index; if (index < 0) { index += 4; } if (index >= 0 && index < 4) { Projection *v = _data._projection; valid = true; v->matrix[index] = p_value; return; } } else if (p_index.get_type() == Variant::STRING) { Projection *v = _data._projection; const String *str = reinterpret_cast(p_index._data._mem); if (p_value.type != Variant::VECTOR4) { return; } if (*str == "x") { valid = true; v->matrix[0] = p_value; return; } else if (*str == "y") { valid = true; v->matrix[1] = p_value; return; } else if (*str == "z") { valid = true; v->matrix[2] = p_value; return; } else if (*str == "w") { valid = true; v->matrix[3] = p_value; return; } } else if (p_index.get_type() == Variant::STRING_NAME) { Projection *v = _data._projection; if (p_value.type != Variant::VECTOR4) { return; } if (p_index == CoreStringNames::singleton->x) { valid = true; v->matrix[0] = p_value; return; } else if (p_index == CoreStringNames::singleton->y) { valid = true; v->matrix[1] = p_value; return; } else if (p_index == CoreStringNames::singleton->z) { valid = true; v->matrix[2] = p_value; return; } else if (p_index == CoreStringNames::singleton->w) { valid = true; v->matrix[3] = p_value; return; } } } break; case COLOR: { if (p_value.type != Variant::INT && p_value.type != Variant::REAL) { return; } if (p_index.get_type() == Variant::STRING) { const String *str = reinterpret_cast(p_index._data._mem); Color *v = reinterpret_cast(_data._mem); if (*str == "r") { valid = true; v->r = p_value; return; } else if (*str == "g") { valid = true; v->g = p_value; return; } else if (*str == "b") { valid = true; v->b = p_value; return; } else if (*str == "a") { valid = true; v->a = p_value; return; } else if (*str == "h") { valid = true; v->set_hsv(p_value, v->get_s(), v->get_v(), v->a); return; } else if (*str == "s") { valid = true; v->set_hsv(v->get_h(), p_value, v->get_v(), v->a); return; } else if (*str == "v") { valid = true; v->set_hsv(v->get_h(), v->get_s(), p_value, v->a); return; } else if (*str == "r8") { valid = true; v->r = float(p_value) / 255.0; return; } else if (*str == "g8") { valid = true; v->g = float(p_value) / 255.0; return; } else if (*str == "b8") { valid = true; v->b = float(p_value) / 255.0; return; } else if (*str == "a8") { valid = true; v->a = float(p_value) / 255.0; return; } } else if (p_index.get_type() == Variant::INT) { int idx = p_index; if (idx < 0) { idx += 4; } if (idx >= 0 && idx < 4) { Color *v = reinterpret_cast(_data._mem); (*v)[idx] = p_value; valid = true; } } else if (p_index.get_type() == Variant::STRING_NAME) { Color *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->r) { valid = true; v->r = p_value; return; } else if (p_index == CoreStringNames::singleton->g) { valid = true; v->g = p_value; return; } else if (p_index == CoreStringNames::singleton->b) { valid = true; v->b = p_value; return; } else if (p_index == CoreStringNames::singleton->a) { valid = true; v->a = p_value; return; } else if (p_index == CoreStringNames::singleton->h) { valid = true; v->set_hsv(p_value, v->get_s(), v->get_v(), v->a); return; } else if (p_index == CoreStringNames::singleton->s) { valid = true; v->set_hsv(v->get_h(), p_value, v->get_v(), v->a); return; } else if (p_index == CoreStringNames::singleton->v) { valid = true; v->set_hsv(v->get_h(), v->get_s(), p_value, v->a); return; } else if (p_index == CoreStringNames::singleton->r8) { valid = true; v->r = float(p_value) / 255.0; return; } else if (p_index == CoreStringNames::singleton->g8) { valid = true; v->g = float(p_value) / 255.0; return; } else if (p_index == CoreStringNames::singleton->b8) { valid = true; v->b = float(p_value) / 255.0; return; } else if (p_index == CoreStringNames::singleton->a8) { valid = true; v->a = float(p_value) / 255.0; return; } } } break; case NODE_PATH: { } break; // 15 case RID: { } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { valid = false; #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted set on a deleted object."); } #endif return; } if (p_index.get_type() != Variant::STRING_NAME && p_index.get_type() != Variant::STRING) { obj->setvar(p_index, p_value, r_valid); return; } obj->set(p_index, p_value, r_valid); return; } break; case STRING_NAME: { } break; case DICTIONARY: { Dictionary *dic = reinterpret_cast(_data._mem); dic->operator[](p_index) = p_value; valid = true; //always valid, i guess? should this really be ok? return; } break; DEFAULT_OP_ARRAY_CMD(ARRAY, Array, ;, (*arr)[index] = p_value; return ) // 20 DEFAULT_OP_DVECTOR_SET(POOL_BYTE_ARRAY, uint8_t, p_value.type != Variant::REAL && p_value.type != Variant::INT) DEFAULT_OP_DVECTOR_SET(POOL_INT_ARRAY, int, p_value.type != Variant::REAL && p_value.type != Variant::INT) DEFAULT_OP_DVECTOR_SET(POOL_REAL_ARRAY, real_t, p_value.type != Variant::REAL && p_value.type != Variant::INT) DEFAULT_OP_DVECTOR_SET(POOL_STRING_ARRAY, String, p_value.type != Variant::STRING) DEFAULT_OP_DVECTOR_SET(POOL_VECTOR2_ARRAY, Vector2, p_value.type != Variant::VECTOR2) // 25 DEFAULT_OP_DVECTOR_SET(POOL_VECTOR3_ARRAY, Vector3, p_value.type != Variant::VECTOR3) DEFAULT_OP_DVECTOR_SET(POOL_COLOR_ARRAY, Color, p_value.type != Variant::COLOR) default: return; } } Variant Variant::get(const Variant &p_index, bool *r_valid) const { static bool _dummy = false; bool &valid = r_valid ? *r_valid : _dummy; valid = false; switch (type) { case NIL: { return Variant(); } break; case BOOL: { return Variant(); } break; case INT: { return Variant(); } break; case REAL: { return Variant(); } break; case STRING: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //string index int idx = p_index; const String *str = reinterpret_cast(_data._mem); if (idx < 0) { idx += str->length(); } if (idx >= 0 && idx < str->length()) { valid = true; return str->substr(idx, 1); } } } break; case RECT2: { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Rect2 *v = reinterpret_cast(_data._mem); if (*str == "position") { valid = true; return v->position; } else if (*str == "size") { valid = true; return v->size; } else if (*str == "end") { valid = true; return v->size + v->position; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Rect2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->position) { valid = true; return v->position; } else if (p_index == CoreStringNames::singleton->size) { valid = true; return v->size; } else if (p_index == CoreStringNames::singleton->end) { valid = true; return v->size + v->position; } } } break; case RECT2I: { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Rect2i *v = reinterpret_cast(_data._mem); if (*str == "position") { valid = true; return v->position; } else if (*str == "size") { valid = true; return v->size; } else if (*str == "end") { valid = true; return v->size + v->position; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Rect2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->position) { valid = true; return v->position; } else if (p_index == CoreStringNames::singleton->size) { valid = true; return v->size; } else if (p_index == CoreStringNames::singleton->end) { valid = true; return v->size + v->position; } } } break; case VECTOR2: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { // scalar index int idx = p_index; if (idx < 0) { idx += 2; } if (idx >= 0 && idx < 2) { const Vector2 *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Vector2 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Vector2 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } } } break; // 5 case VECTOR2I: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { // scalar index int idx = p_index; if (idx < 0) { idx += 2; } if (idx >= 0 && idx < 2) { const Vector2i *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Vector2i *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Vector2i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } } } break; // 6 case VECTOR3: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 3; } if (idx >= 0 && idx < 3) { const Vector3 *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Vector3 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } else if (*str == "z") { valid = true; return v->z; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Vector3 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->z; } } } break; case VECTOR3I: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 3; } if (idx >= 0 && idx < 3) { const Vector3i *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Vector3i *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } else if (*str == "z") { valid = true; return v->z; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Vector3i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->z; } } } break; case VECTOR4: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 4; } if (idx >= 0 && idx < 4) { const Vector4 *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Vector4 *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } else if (*str == "z") { valid = true; return v->z; } else if (*str == "w") { valid = true; return v->w; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Vector4 *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->z; } else if (p_index == CoreStringNames::singleton->w) { valid = true; return v->w; } } } break; case VECTOR4I: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { //scalar index int idx = p_index; if (idx < 0) { idx += 4; } if (idx >= 0 && idx < 4) { const Vector4i *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Vector4i *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } else if (*str == "z") { valid = true; return v->z; } else if (*str == "w") { valid = true; return v->w; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Vector4i *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->z; } else if (p_index == CoreStringNames::singleton->w) { valid = true; return v->w; } } } break; case PLANE: { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Plane *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->normal.x; } else if (*str == "y") { valid = true; return v->normal.y; } else if (*str == "z") { valid = true; return v->normal.z; } else if (*str == "normal") { valid = true; return v->normal; } else if (*str == "d") { valid = true; return v->d; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Plane *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->normal.x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->normal.y; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->normal.z; } else if (p_index == CoreStringNames::singleton->normal) { valid = true; return v->normal; } else if (p_index == CoreStringNames::singleton->d) { valid = true; return v->d; } } } break; case QUATERNION: { if (p_index.get_type() == Variant::STRING) { const String *str = reinterpret_cast(p_index._data._mem); const Quaternion *v = reinterpret_cast(_data._mem); if (*str == "x") { valid = true; return v->x; } else if (*str == "y") { valid = true; return v->y; } else if (*str == "z") { valid = true; return v->z; } else if (*str == "w") { valid = true; return v->w; } } else if (p_index.get_type() == Variant::STRING_NAME) { const Quaternion *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->x) { valid = true; return v->x; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->y; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->z; } else if (p_index == CoreStringNames::singleton->w) { valid = true; return v->w; } } } break; // 10 case AABB: { if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const ::AABB *v = _data._aabb; if (*str == "position") { valid = true; return v->position; } else if (*str == "size") { valid = true; return v->size; } else if (*str == "end") { valid = true; return v->size + v->position; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const ::AABB *v = _data._aabb; if (p_index == CoreStringNames::singleton->position) { valid = true; return v->position; } else if (p_index == CoreStringNames::singleton->size) { valid = true; return v->size; } else if (p_index == CoreStringNames::singleton->end) { valid = true; return v->size + v->position; } } } break; case BASIS: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; if (index < 0) { index += 3; } if (index >= 0 && index < 3) { const Basis *v = _data._basis; valid = true; return v->get_axis(index); } } else if (p_index.get_type() == Variant::STRING) { const String *str = reinterpret_cast(p_index._data._mem); const Basis *v = _data._basis; if (*str == "x") { valid = true; return v->get_axis(0); } else if (*str == "y") { valid = true; return v->get_axis(1); } else if (*str == "z") { valid = true; return v->get_axis(2); } } else if (p_index.get_type() == Variant::STRING_NAME) { const Basis *v = _data._basis; if (p_index == CoreStringNames::singleton->x) { valid = true; return v->get_axis(0); } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->get_axis(1); } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->get_axis(2); } } } break; case TRANSFORM: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; if (index < 0) { index += 4; } if (index >= 0 && index < 4) { const Transform *v = _data._transform; valid = true; return index == 3 ? v->origin : v->basis.get_axis(index); } } else if (p_index.get_type() == Variant::STRING) { const Transform *v = _data._transform; const String *str = reinterpret_cast(p_index._data._mem); if (*str == "basis") { valid = true; return v->basis; } if (*str == "origin") { valid = true; return v->origin; } } else if (p_index.get_type() == Variant::STRING_NAME) { const Transform *v = _data._transform; if (p_index == CoreStringNames::singleton->basis) { valid = true; return v->basis; } if (p_index == CoreStringNames::singleton->origin) { valid = true; return v->origin; } } } break; case TRANSFORM2D: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; if (index < 0) { index += 3; } if (index >= 0 && index < 3) { const Transform2D *v = _data._transform2d; valid = true; return v->columns[index]; } } else if (p_index.get_type() == Variant::STRING) { //scalar name const String *str = reinterpret_cast(p_index._data._mem); const Transform2D *v = _data._transform2d; if (*str == "x") { valid = true; return v->columns[0]; } else if (*str == "y") { valid = true; return v->columns[1]; } else if (*str == "origin") { valid = true; return v->columns[2]; } } else if (p_index.get_type() == Variant::STRING_NAME) { //scalar name const Transform2D *v = _data._transform2d; if (p_index == CoreStringNames::singleton->x) { valid = true; return v->columns[0]; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->columns[1]; } else if (p_index == CoreStringNames::singleton->origin) { valid = true; return v->columns[2]; } } } break; case PROJECTION: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; if (index < 0) { index += 4; } if (index >= 0 && index < 4) { const Projection *v = _data._projection; valid = true; return v->matrix[index]; } } else if (p_index.get_type() == Variant::STRING) { const Projection *v = _data._projection; const String *str = reinterpret_cast(p_index._data._mem); if (*str == "x") { valid = true; return v->matrix[0]; } else if (*str == "y") { valid = true; return v->matrix[1]; } else if (*str == "z") { valid = true; return v->matrix[2]; } else if (*str == "w") { valid = true; return v->matrix[3]; } } else if (p_index.get_type() == Variant::STRING_NAME) { const Projection *v = _data._projection; if (p_index == CoreStringNames::singleton->x) { valid = true; return v->matrix[0]; } else if (p_index == CoreStringNames::singleton->y) { valid = true; return v->matrix[1]; } else if (p_index == CoreStringNames::singleton->z) { valid = true; return v->matrix[2]; } else if (p_index == CoreStringNames::singleton->w) { valid = true; return v->matrix[3]; } } } break; case COLOR: { if (p_index.get_type() == Variant::STRING) { const String *str = reinterpret_cast(p_index._data._mem); const Color *v = reinterpret_cast(_data._mem); if (*str == "r") { valid = true; return v->r; } else if (*str == "g") { valid = true; return v->g; } else if (*str == "b") { valid = true; return v->b; } else if (*str == "a") { valid = true; return v->a; } else if (*str == "h") { valid = true; return v->get_h(); } else if (*str == "s") { valid = true; return v->get_s(); } else if (*str == "v") { valid = true; return v->get_v(); } else if (*str == "r8") { valid = true; return (int)Math::round(v->r * 255.0); } else if (*str == "g8") { valid = true; return (int)Math::round(v->g * 255.0); } else if (*str == "b8") { valid = true; return (int)Math::round(v->b * 255.0); } else if (*str == "a8") { valid = true; return (int)Math::round(v->a * 255.0); } } else if (p_index.get_type() == Variant::INT) { int idx = p_index; if (idx < 0) { idx += 4; } if (idx >= 0 && idx < 4) { const Color *v = reinterpret_cast(_data._mem); valid = true; return (*v)[idx]; } } else if (p_index.get_type() == Variant::STRING) { const Color *v = reinterpret_cast(_data._mem); if (p_index == CoreStringNames::singleton->r) { valid = true; return v->r; } else if (p_index == CoreStringNames::singleton->g) { valid = true; return v->g; } else if (p_index == CoreStringNames::singleton->b) { valid = true; return v->b; } else if (p_index == CoreStringNames::singleton->a) { valid = true; return v->a; } else if (p_index == CoreStringNames::singleton->h) { valid = true; return v->get_h(); } else if (p_index == CoreStringNames::singleton->s) { valid = true; return v->get_s(); } else if (p_index == CoreStringNames::singleton->v) { valid = true; return v->get_v(); } else if (p_index == CoreStringNames::singleton->r8) { valid = true; return (int)Math::round(v->r * 255.0); } else if (p_index == CoreStringNames::singleton->g8) { valid = true; return (int)Math::round(v->g * 255.0); } else if (p_index == CoreStringNames::singleton->b8) { valid = true; return (int)Math::round(v->b * 255.0); } else if (p_index == CoreStringNames::singleton->a8) { valid = true; return (int)Math::round(v->a * 255.0); } } } break; case NODE_PATH: { } break; // 15 case RID: { } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { valid = false; #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted get on a deleted object."); } #endif return Variant(); } if (p_index.get_type() != Variant::STRING && p_index.get_type() != Variant::STRING_NAME) { return obj->getvar(p_index, r_valid); } else { return obj->get(p_index, r_valid); } } break; case STRING_NAME: { } break; case DICTIONARY: { const Dictionary *dic = reinterpret_cast(_data._mem); const Variant *res = dic->getptr(p_index); if (res) { valid = true; return *res; } } break; DEFAULT_OP_ARRAY_CMD(ARRAY, const Array, ;, return (*arr)[index]) // 20 DEFAULT_OP_DVECTOR_GET(POOL_BYTE_ARRAY, uint8_t) DEFAULT_OP_DVECTOR_GET(POOL_INT_ARRAY, int) DEFAULT_OP_DVECTOR_GET(POOL_REAL_ARRAY, real_t) DEFAULT_OP_DVECTOR_GET(POOL_STRING_ARRAY, String) DEFAULT_OP_DVECTOR_GET(POOL_VECTOR2_ARRAY, Vector2) DEFAULT_OP_DVECTOR_GET(POOL_VECTOR2I_ARRAY, Vector2i) DEFAULT_OP_DVECTOR_GET(POOL_VECTOR3_ARRAY, Vector3) DEFAULT_OP_DVECTOR_GET(POOL_VECTOR3I_ARRAY, Vector3i) DEFAULT_OP_DVECTOR_GET(POOL_VECTOR4_ARRAY, Vector4) DEFAULT_OP_DVECTOR_GET(POOL_VECTOR4I_ARRAY, Vector4i) DEFAULT_OP_DVECTOR_GET(POOL_COLOR_ARRAY, Color) default: return Variant(); } return Variant(); } bool Variant::in(const Variant &p_index, bool *r_valid) const { if (r_valid) { *r_valid = true; } switch (type) { case STRING: { if (p_index.get_type() == Variant::STRING) { //string index String idx = p_index; const String *str = reinterpret_cast(_data._mem); return str->find(idx) != -1; } } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { if (r_valid) { *r_valid = false; } #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted 'in' on a deleted object."); } #endif return false; } bool result; if (p_index.get_type() != Variant::STRING && p_index.get_type() != Variant::STRING_NAME) { obj->getvar(p_index, &result); } else { obj->get(p_index, &result); } return result; } break; case DICTIONARY: { const Dictionary *dic = reinterpret_cast(_data._mem); return dic->has(p_index); } break; // 20 case ARRAY: { const Array *arr = reinterpret_cast(_data._mem); int l = arr->size(); if (l) { for (int i = 0; i < l; i++) { if (evaluate(OP_EQUAL, (*arr)[i], p_index)) { return true; } } } return false; } break; case POOL_BYTE_ARRAY: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_INT_ARRAY: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { int index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_REAL_ARRAY: { if (p_index.get_type() == Variant::INT || p_index.get_type() == Variant::REAL) { real_t index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_STRING_ARRAY: { if (p_index.get_type() == Variant::STRING) { String index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; //25 case POOL_VECTOR2_ARRAY: { if (p_index.get_type() == Variant::VECTOR2) { Vector2 index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_VECTOR2I_ARRAY: { if (p_index.get_type() == Variant::VECTOR2I) { Vector2i index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_VECTOR3_ARRAY: { if (p_index.get_type() == Variant::VECTOR3) { Vector3 index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_VECTOR3I_ARRAY: { if (p_index.get_type() == Variant::VECTOR3I) { Vector3i index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_VECTOR4_ARRAY: { if (p_index.get_type() == Variant::VECTOR4) { Vector4 index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_VECTOR4I_ARRAY: { if (p_index.get_type() == Variant::VECTOR4I) { Vector4i index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; case POOL_COLOR_ARRAY: { if (p_index.get_type() == Variant::COLOR) { Color index = p_index; const PoolVector *arr = reinterpret_cast *>(_data._mem); int l = arr->size(); if (l) { PoolVector::Read r = arr->read(); for (int i = 0; i < l; i++) { if (r[i] == index) { return true; } } } return false; } } break; default: { } } if (r_valid) { *r_valid = false; } return false; } void Variant::get_property_list(List *p_list) const { switch (type) { case RECT2: { p_list->push_back(PropertyInfo(Variant::VECTOR2, "position")); p_list->push_back(PropertyInfo(Variant::VECTOR2, "size")); p_list->push_back(PropertyInfo(Variant::VECTOR2, "end")); } break; case RECT2I: { p_list->push_back(PropertyInfo(Variant::VECTOR2I, "position")); p_list->push_back(PropertyInfo(Variant::VECTOR2I, "size")); p_list->push_back(PropertyInfo(Variant::VECTOR2I, "end")); } break; case VECTOR2: { p_list->push_back(PropertyInfo(Variant::REAL, "x")); p_list->push_back(PropertyInfo(Variant::REAL, "y")); } break; case VECTOR2I: { p_list->push_back(PropertyInfo(Variant::INT, "x")); p_list->push_back(PropertyInfo(Variant::INT, "y")); } break; case VECTOR3: { p_list->push_back(PropertyInfo(Variant::REAL, "x")); p_list->push_back(PropertyInfo(Variant::REAL, "y")); p_list->push_back(PropertyInfo(Variant::REAL, "z")); } break; case VECTOR3I: { p_list->push_back(PropertyInfo(Variant::INT, "x")); p_list->push_back(PropertyInfo(Variant::INT, "y")); p_list->push_back(PropertyInfo(Variant::INT, "z")); } break; case VECTOR4: { p_list->push_back(PropertyInfo(Variant::REAL, "x")); p_list->push_back(PropertyInfo(Variant::REAL, "y")); p_list->push_back(PropertyInfo(Variant::REAL, "z")); p_list->push_back(PropertyInfo(Variant::REAL, "w")); } break; case VECTOR4I: { p_list->push_back(PropertyInfo(Variant::INT, "x")); p_list->push_back(PropertyInfo(Variant::INT, "y")); p_list->push_back(PropertyInfo(Variant::INT, "z")); p_list->push_back(PropertyInfo(Variant::INT, "w")); } break; case PLANE: { p_list->push_back(PropertyInfo(Variant::VECTOR3, "normal")); p_list->push_back(PropertyInfo(Variant::REAL, "x")); p_list->push_back(PropertyInfo(Variant::REAL, "y")); p_list->push_back(PropertyInfo(Variant::REAL, "z")); p_list->push_back(PropertyInfo(Variant::REAL, "d")); } break; case QUATERNION: { p_list->push_back(PropertyInfo(Variant::REAL, "x")); p_list->push_back(PropertyInfo(Variant::REAL, "y")); p_list->push_back(PropertyInfo(Variant::REAL, "z")); p_list->push_back(PropertyInfo(Variant::REAL, "w")); } break; case AABB: { p_list->push_back(PropertyInfo(Variant::VECTOR3, "position")); p_list->push_back(PropertyInfo(Variant::VECTOR3, "size")); p_list->push_back(PropertyInfo(Variant::VECTOR3, "end")); } break; case BASIS: { p_list->push_back(PropertyInfo(Variant::VECTOR3, "x")); p_list->push_back(PropertyInfo(Variant::VECTOR3, "y")); p_list->push_back(PropertyInfo(Variant::VECTOR3, "z")); } break; case TRANSFORM: { p_list->push_back(PropertyInfo(Variant::BASIS, "basis")); p_list->push_back(PropertyInfo(Variant::VECTOR3, "origin")); } break; case TRANSFORM2D: { p_list->push_back(PropertyInfo(Variant::VECTOR2, "x")); p_list->push_back(PropertyInfo(Variant::VECTOR2, "y")); p_list->push_back(PropertyInfo(Variant::VECTOR2, "origin")); } break; case PROJECTION: { p_list->push_back(PropertyInfo(Variant::VECTOR4, "x")); p_list->push_back(PropertyInfo(Variant::VECTOR4, "y")); p_list->push_back(PropertyInfo(Variant::VECTOR4, "z")); p_list->push_back(PropertyInfo(Variant::VECTOR4, "w")); } break; case COLOR: { p_list->push_back(PropertyInfo(Variant::REAL, "r")); p_list->push_back(PropertyInfo(Variant::REAL, "g")); p_list->push_back(PropertyInfo(Variant::REAL, "b")); p_list->push_back(PropertyInfo(Variant::REAL, "a")); p_list->push_back(PropertyInfo(Variant::REAL, "h")); p_list->push_back(PropertyInfo(Variant::REAL, "s")); p_list->push_back(PropertyInfo(Variant::REAL, "v")); p_list->push_back(PropertyInfo(Variant::INT, "r8")); p_list->push_back(PropertyInfo(Variant::INT, "g8")); p_list->push_back(PropertyInfo(Variant::INT, "b8")); p_list->push_back(PropertyInfo(Variant::INT, "a8")); } break; case NODE_PATH: { } break; case RID: { } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted get property list on a deleted object."); } #endif return; } obj->get_property_list(p_list); } break; case DICTIONARY: { const Dictionary *dic = reinterpret_cast(_data._mem); List keys; dic->get_key_list(&keys); for (List::Element *E = keys.front(); E; E = E->next()) { if (E->get().get_type() == Variant::STRING) { p_list->push_back(PropertyInfo(Variant::STRING, E->get())); } } } break; case ARRAY: // 20 case POOL_BYTE_ARRAY: case POOL_INT_ARRAY: case POOL_REAL_ARRAY: case POOL_STRING_ARRAY: case POOL_VECTOR2_ARRAY: case POOL_VECTOR2I_ARRAY: case POOL_VECTOR3_ARRAY: case POOL_VECTOR3I_ARRAY: case POOL_VECTOR4_ARRAY: case POOL_VECTOR4I_ARRAY: case POOL_COLOR_ARRAY: { //nothing } break; default: { } } } bool Variant::iter_init(Variant &r_iter, bool &valid) const { valid = true; switch (type) { case INT: { r_iter = 0; return _data._int > 0; } break; case REAL: { r_iter = 0; return _data._real > 0.0; } break; case VECTOR2: { int64_t from = reinterpret_cast(_data._mem)->x; int64_t to = reinterpret_cast(_data._mem)->y; r_iter = from; return from < to; } break; case VECTOR2I: { int64_t from = reinterpret_cast(_data._mem)->x; int64_t to = reinterpret_cast(_data._mem)->y; r_iter = from; return from < to; } break; case VECTOR3: { int64_t from = reinterpret_cast(_data._mem)->x; int64_t to = reinterpret_cast(_data._mem)->y; int64_t step = reinterpret_cast(_data._mem)->z; r_iter = from; if (from == to) { return false; } else if (from < to) { return step > 0; } else { return step < 0; } //return true; } break; case VECTOR3I: { int64_t from = reinterpret_cast(_data._mem)->x; int64_t to = reinterpret_cast(_data._mem)->y; int64_t step = reinterpret_cast(_data._mem)->z; r_iter = from; if (from == to) { return false; } else if (from < to) { return step > 0; } else { return step < 0; } //return true; } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { valid = false; #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted iteration start on a deleted object."); } #endif return false; } Variant::CallError ce; ce.error = Variant::CallError::CALL_OK; Array ref; ref.push_back(r_iter); Variant vref = ref; const Variant *refp[] = { &vref }; Variant ret = obj->call(CoreStringNames::get_singleton()->_iter_init, refp, 1, ce); if (ref.size() != 1 || ce.error != Variant::CallError::CALL_OK) { valid = false; return false; } r_iter = ref[0]; return ret; } break; case STRING: { const String *str = reinterpret_cast(_data._mem); if (str->empty()) { return false; } r_iter = 0; return true; } break; case DICTIONARY: { const Dictionary *dic = reinterpret_cast(_data._mem); if (dic->empty()) { return false; } const Variant *next = dic->next(nullptr); r_iter = *next; return true; } break; case ARRAY: { const Array *arr = reinterpret_cast(_data._mem); if (arr->empty()) { return false; } r_iter = 0; return true; } break; case POOL_BYTE_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_INT_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_REAL_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_STRING_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_VECTOR2_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_VECTOR2I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_VECTOR3_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_VECTOR3I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_VECTOR4_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_VECTOR4I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; case POOL_COLOR_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); if (arr->size() == 0) { return false; } r_iter = 0; return true; } break; default: { } } valid = false; return false; } bool Variant::iter_next(Variant &r_iter, bool &valid) const { valid = true; switch (type) { case INT: { int64_t idx = r_iter; idx++; if (idx >= _data._int) { return false; } r_iter = idx; return true; } break; case REAL: { int64_t idx = r_iter; idx++; if (idx >= _data._real) { return false; } r_iter = idx; return true; } break; case VECTOR2: { int64_t to = reinterpret_cast(_data._mem)->y; int64_t idx = r_iter; idx++; if (idx >= to) { return false; } r_iter = idx; return true; } break; case VECTOR2I: { int64_t to = reinterpret_cast(_data._mem)->y; int64_t idx = r_iter; idx++; if (idx >= to) { return false; } r_iter = idx; return true; } break; case VECTOR3: { int64_t to = reinterpret_cast(_data._mem)->y; int64_t step = reinterpret_cast(_data._mem)->z; int64_t idx = r_iter; idx += step; if (step < 0 && idx <= to) { return false; } if (step > 0 && idx >= to) { return false; } r_iter = idx; return true; } break; case VECTOR3I: { int64_t to = reinterpret_cast(_data._mem)->y; int64_t step = reinterpret_cast(_data._mem)->z; int64_t idx = r_iter; idx += step; if (step < 0 && idx <= to) { return false; } if (step > 0 && idx >= to) { return false; } r_iter = idx; return true; } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { valid = false; #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted iteration check next on a deleted object."); } #endif return false; } Variant::CallError ce; ce.error = Variant::CallError::CALL_OK; Array ref; ref.push_back(r_iter); Variant vref = ref; const Variant *refp[] = { &vref }; Variant ret = obj->call(CoreStringNames::get_singleton()->_iter_next, refp, 1, ce); if (ref.size() != 1 || ce.error != Variant::CallError::CALL_OK) { valid = false; return false; } r_iter = ref[0]; return ret; } break; case STRING: { const String *str = reinterpret_cast(_data._mem); int idx = r_iter; idx++; if (idx >= str->length()) { return false; } r_iter = idx; return true; } break; case DICTIONARY: { const Dictionary *dic = reinterpret_cast(_data._mem); const Variant *next = dic->next(&r_iter); if (!next) { return false; } r_iter = *next; return true; } break; case ARRAY: { const Array *arr = reinterpret_cast(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_BYTE_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_INT_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_REAL_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_STRING_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_VECTOR2_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_VECTOR2I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_VECTOR3_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_VECTOR3I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_VECTOR4_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_VECTOR4I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; case POOL_COLOR_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; idx++; if (idx >= arr->size()) { return false; } r_iter = idx; return true; } break; default: { } } valid = false; return false; } Variant Variant::iter_get(const Variant &r_iter, bool &r_valid) const { r_valid = true; switch (type) { case INT: { return r_iter; } break; case REAL: { return r_iter; } break; case VECTOR2: { return r_iter; } break; case VECTOR2I: { return r_iter; } break; case VECTOR3: { return r_iter; } break; case VECTOR3I: { return r_iter; } break; case OBJECT: { Object *obj = _OBJ_PTR(*this); if (unlikely(!obj)) { r_valid = false; #ifdef DEBUG_ENABLED if (_get_obj().rc) { ERR_PRINT("Attempted iteration get next on a deleted object."); } #endif return Variant(); } Variant::CallError ce; ce.error = Variant::CallError::CALL_OK; const Variant *refp[] = { &r_iter }; Variant ret = obj->call(CoreStringNames::get_singleton()->_iter_get, refp, 1, ce); if (ce.error != Variant::CallError::CALL_OK) { r_valid = false; return Variant(); } //r_iter=ref[0]; return ret; } break; case STRING: { const String *str = reinterpret_cast(_data._mem); return str->substr(r_iter, 1); } break; case DICTIONARY: { return r_iter; //iterator is the same as the key } break; case ARRAY: { const Array *arr = reinterpret_cast(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_BYTE_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_INT_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_REAL_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_STRING_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_VECTOR2_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_VECTOR2I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_VECTOR3_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_VECTOR3I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_VECTOR4_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_VECTOR4I_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; case POOL_COLOR_ARRAY: { const PoolVector *arr = reinterpret_cast *>(_data._mem); int idx = r_iter; #ifdef DEBUG_ENABLED if (idx < 0 || idx >= arr->size()) { r_valid = false; return Variant(); } #endif return arr->get(idx); } break; default: { } } r_valid = false; return Variant(); } Variant Variant::duplicate(bool deep) const { switch (type) { case OBJECT: { /* breaks stuff :( if (deep && !_get_obj().ref.is_null()) { Ref resource = _get_obj().ref; if (resource.is_valid()) { return resource->duplicate(true); } } */ return *this; } break; case DICTIONARY: return operator Dictionary().duplicate(deep); case ARRAY: return operator Array().duplicate(deep); default: return *this; } } void Variant::sub(const Variant &a, const Variant &b, Variant &r_dst) { if (a.type != b.type) { return; } switch (a.type) { case NIL: { r_dst = Variant(); } return; case INT: { int64_t va = a._data._int; int64_t vb = b._data._int; r_dst = int(va - vb); } return; case REAL: { real_t ra = a._data._real; real_t rb = b._data._real; r_dst = ra - rb; } return; case RECT2: { const Rect2 *ra = reinterpret_cast(a._data._mem); const Rect2 *rb = reinterpret_cast(b._data._mem); r_dst = Rect2(ra->position - rb->position, ra->size - rb->size); } return; case RECT2I: { const Rect2i *ra = reinterpret_cast(a._data._mem); const Rect2i *rb = reinterpret_cast(b._data._mem); int32_t vax = ra->position.x; int32_t vay = ra->position.y; int32_t vbx = ra->size.x; int32_t vby = ra->size.y; int32_t vcx = rb->position.x; int32_t vcy = rb->position.y; int32_t vdx = rb->size.x; int32_t vdy = rb->size.y; r_dst = Rect2i(int32_t(vax - vbx), int32_t(vay - vby), int32_t(vcx - vdx), int32_t(vcy - vdy)); } return; case VECTOR2: { r_dst = *reinterpret_cast(a._data._mem) - *reinterpret_cast(b._data._mem); } return; case VECTOR2I: { int32_t vax = reinterpret_cast(a._data._mem)->x; int32_t vbx = reinterpret_cast(b._data._mem)->x; int32_t vay = reinterpret_cast(a._data._mem)->y; int32_t vby = reinterpret_cast(b._data._mem)->y; r_dst = Vector2i(int32_t(vax - vbx), int32_t(vay - vby)); } return; case VECTOR3: { r_dst = *reinterpret_cast(a._data._mem) - *reinterpret_cast(b._data._mem); } return; case VECTOR3I: { int32_t vax = reinterpret_cast(a._data._mem)->x; int32_t vbx = reinterpret_cast(b._data._mem)->x; int32_t vay = reinterpret_cast(a._data._mem)->y; int32_t vby = reinterpret_cast(b._data._mem)->y; int32_t vaz = reinterpret_cast(a._data._mem)->z; int32_t vbz = reinterpret_cast(b._data._mem)->z; r_dst = Vector3i(int32_t(vax - vbx), int32_t(vay - vby), int32_t(vaz - vbz)); } return; case VECTOR4: { r_dst = *reinterpret_cast(a._data._mem) - *reinterpret_cast(b._data._mem); } return; case VECTOR4I: { int32_t vax = reinterpret_cast(a._data._mem)->x; int32_t vbx = reinterpret_cast(b._data._mem)->x; int32_t vay = reinterpret_cast(a._data._mem)->y; int32_t vaw = reinterpret_cast(a._data._mem)->w; int32_t vby = reinterpret_cast(b._data._mem)->y; int32_t vaz = reinterpret_cast(a._data._mem)->z; int32_t vbz = reinterpret_cast(b._data._mem)->z; int32_t vbw = reinterpret_cast(b._data._mem)->w; r_dst = Vector4i(int32_t(vax - vbx), int32_t(vay - vby), int32_t(vaz - vbz), int32_t(vaw - vbw)); } return; case AABB: { const ::AABB *ra = reinterpret_cast(a._data._mem); const ::AABB *rb = reinterpret_cast(b._data._mem); r_dst = ::AABB(ra->position - rb->position, ra->size - rb->size); } return; case QUATERNION: { Quaternion empty_rot; const Quaternion *qa = reinterpret_cast(a._data._mem); const Quaternion *qb = reinterpret_cast(b._data._mem); r_dst = (*qb).inverse() * *qa; } return; case COLOR: { const Color *ca = reinterpret_cast(a._data._mem); const Color *cb = reinterpret_cast(b._data._mem); float new_r = ca->r - cb->r; float new_g = ca->g - cb->g; float new_b = ca->b - cb->b; float new_a = ca->a - cb->a; new_r = new_r > 1.0 ? 1.0 : new_r; new_g = new_g > 1.0 ? 1.0 : new_g; new_b = new_b > 1.0 ? 1.0 : new_b; new_a = new_a > 1.0 ? 1.0 : new_a; r_dst = Color(new_r, new_g, new_b, new_a); } return; default: { r_dst = a; } return; } } void Variant::blend(const Variant &a, const Variant &b, float c, Variant &r_dst) { if (a.type != b.type) { if (a.is_num() && b.is_num()) { real_t va = a; real_t vb = b; r_dst = va + vb * c; } else { r_dst = a; } return; } switch (a.type) { case NIL: { r_dst = Variant(); } return; case INT: { int64_t va = a._data._int; int64_t vb = b._data._int; r_dst = int(va + vb * c + 0.5); } return; case REAL: { double ra = a._data._real; double rb = b._data._real; r_dst = ra + rb * c; } return; case RECT2: { const Rect2 *ra = reinterpret_cast(a._data._mem); const Rect2 *rb = reinterpret_cast(b._data._mem); r_dst = Rect2(ra->position + rb->position * c, ra->size + rb->size * c); } return; case RECT2I: { const Rect2i *ra = reinterpret_cast(a._data._mem); const Rect2i *rb = reinterpret_cast(b._data._mem); r_dst = Rect2(ra->position + rb->position * c, ra->size + rb->size * c); } return; case VECTOR2: { r_dst = *reinterpret_cast(a._data._mem) + *reinterpret_cast(b._data._mem) * c; } return; case VECTOR2I: { r_dst = *reinterpret_cast(a._data._mem) + *reinterpret_cast(b._data._mem) * c; } return; case VECTOR3: { r_dst = *reinterpret_cast(a._data._mem) + *reinterpret_cast(b._data._mem) * c; } return; case VECTOR3I: { r_dst = *reinterpret_cast(a._data._mem) + *reinterpret_cast(b._data._mem) * c; } return; case VECTOR4: { r_dst = *reinterpret_cast(a._data._mem) + *reinterpret_cast(b._data._mem) * c; } return; case VECTOR4I: { r_dst = *reinterpret_cast(a._data._mem) + *reinterpret_cast(b._data._mem) * c; } return; case AABB: { const ::AABB *ra = reinterpret_cast(a._data._mem); const ::AABB *rb = reinterpret_cast(b._data._mem); r_dst = ::AABB(ra->position + rb->position * c, ra->size + rb->size * c); } return; case QUATERNION: { Quaternion empty_rot; const Quaternion *qa = reinterpret_cast(a._data._mem); const Quaternion *qb = reinterpret_cast(b._data._mem); r_dst = *qa * empty_rot.slerp(*qb, c); } return; case COLOR: { const Color *ca = reinterpret_cast(a._data._mem); const Color *cb = reinterpret_cast(b._data._mem); float new_r = ca->r + cb->r * c; float new_g = ca->g + cb->g * c; float new_b = ca->b + cb->b * c; float new_a = ca->a + cb->a * c; new_r = new_r > 1.0 ? 1.0 : new_r; new_g = new_g > 1.0 ? 1.0 : new_g; new_b = new_b > 1.0 ? 1.0 : new_b; new_a = new_a > 1.0 ? 1.0 : new_a; r_dst = Color(new_r, new_g, new_b, new_a); } return; default: { r_dst = c < 0.5 ? a : b; } return; } } void Variant::interpolate(const Variant &a, const Variant &b, float c, Variant &r_dst) { if (a.type != b.type) { if (a.is_num() && b.is_num()) { //not as efficient but.. real_t va = a; real_t vb = b; r_dst = va + (vb - va) * c; } else { r_dst = a; } return; } switch (a.type) { case NIL: { r_dst = Variant(); } return; case BOOL: { r_dst = a; } return; case INT: { int64_t va = a._data._int; int64_t vb = b._data._int; r_dst = int(va + (vb - va) * c); } return; case REAL: { real_t va = a._data._real; real_t vb = b._data._real; r_dst = va + (vb - va) * c; } return; case STRING: { //this is pretty funny and bizarre, but artists like to use it for typewritter effects String sa = *reinterpret_cast(a._data._mem); String sb = *reinterpret_cast(b._data._mem); String dst; int sa_len = sa.length(); int sb_len = sb.length(); int csize = sa_len + (sb_len - sa_len) * c; if (csize == 0) { r_dst = ""; return; } dst.resize(csize + 1); dst[csize] = 0; int split = csize / 2; for (int i = 0; i < csize; i++) { CharType chr = ' '; if (i < split) { if (i < sa.length()) { chr = sa[i]; } else if (i < sb.length()) { chr = sb[i]; } } else { if (i < sb.length()) { chr = sb[i]; } else if (i < sa.length()) { chr = sa[i]; } } dst[i] = chr; } r_dst = dst; } return; case RECT2: { r_dst = Rect2(reinterpret_cast(a._data._mem)->position.linear_interpolate(reinterpret_cast(b._data._mem)->position, c), reinterpret_cast(a._data._mem)->size.linear_interpolate(reinterpret_cast(b._data._mem)->size, c)); } return; case RECT2I: { r_dst = Rect2(reinterpret_cast(a._data._mem)->position.linear_interpolate(reinterpret_cast(b._data._mem)->position, c), reinterpret_cast(a._data._mem)->size.linear_interpolate(reinterpret_cast(b._data._mem)->size, c)); } return; case VECTOR2: { r_dst = reinterpret_cast(a._data._mem)->linear_interpolate(*reinterpret_cast(b._data._mem), c); } return; case VECTOR2I: { r_dst = reinterpret_cast(a._data._mem)->linear_interpolate(*reinterpret_cast(b._data._mem), c); } return; case VECTOR3: { r_dst = reinterpret_cast(a._data._mem)->linear_interpolate(*reinterpret_cast(b._data._mem), c); } return; case VECTOR3I: { r_dst = reinterpret_cast(a._data._mem)->linear_interpolate(*reinterpret_cast(b._data._mem), c); } return; case VECTOR4: { r_dst = reinterpret_cast(a._data._mem)->lerp(*reinterpret_cast(b._data._mem), c); } return; case VECTOR4I: { //r_dst = reinterpret_cast(a._data._mem)->lerp(*reinterpret_cast(b._data._mem), c); r_dst = a; } return; case PLANE: { r_dst = a; } return; case QUATERNION: { r_dst = reinterpret_cast(a._data._mem)->slerp(*reinterpret_cast(b._data._mem), c); } return; case AABB: { r_dst = ::AABB(a._data._aabb->position.linear_interpolate(b._data._aabb->position, c), a._data._aabb->size.linear_interpolate(b._data._aabb->size, c)); } return; case BASIS: { r_dst = Transform(*a._data._basis).interpolate_with(Transform(*b._data._basis), c).basis; } return; case TRANSFORM: { r_dst = a._data._transform->interpolate_with(*b._data._transform, c); } return; case TRANSFORM2D: { r_dst = a._data._transform2d->interpolate_with(*b._data._transform2d, c); } return; case COLOR: { r_dst = reinterpret_cast(a._data._mem)->linear_interpolate(*reinterpret_cast(b._data._mem), c); } return; case NODE_PATH: { r_dst = a; } return; case RID: { r_dst = a; } return; case OBJECT: { r_dst = a; } return; case STRING_NAME: { r_dst = a; } return; case DICTIONARY: { } return; case ARRAY: { r_dst = a; } return; case POOL_BYTE_ARRAY: { r_dst = a; } return; case POOL_INT_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); Variant va; for (int i = 0; i < sz; i++) { Variant::interpolate(ar[i], br[i], c, va); vw[i] = va; } } r_dst = v; } } return; case POOL_REAL_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); Variant va; for (int i = 0; i < sz; i++) { Variant::interpolate(ar[i], br[i], c, va); vw[i] = va; } } r_dst = v; } } return; case POOL_STRING_ARRAY: { r_dst = a; } return; case POOL_VECTOR2_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].linear_interpolate(br[i], c); } } r_dst = v; } } return; case POOL_VECTOR2I_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].linear_interpolate(br[i], c); } } r_dst = v; } } return; case POOL_VECTOR3_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].linear_interpolate(br[i], c); } } r_dst = v; } } return; case POOL_VECTOR3I_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].linear_interpolate(br[i], c); } } r_dst = v; } } return; case POOL_VECTOR4_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].lerp(br[i], c); } } r_dst = v; } } return; case POOL_VECTOR4I_ARRAY: { /* const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].lerp(br[i], c); } } r_dst = v; } */ r_dst = a; } return; case POOL_COLOR_ARRAY: { const PoolVector *arr_a = reinterpret_cast *>(a._data._mem); const PoolVector *arr_b = reinterpret_cast *>(b._data._mem); int sz = arr_a->size(); if (sz == 0 || arr_b->size() != sz) { r_dst = a; } else { PoolVector v; v.resize(sz); { PoolVector::Write vw = v.write(); PoolVector::Read ar = arr_a->read(); PoolVector::Read br = arr_b->read(); for (int i = 0; i < sz; i++) { vw[i] = ar[i].linear_interpolate(br[i], c); } } r_dst = v; } } return; default: { r_dst = a; } } } static const char *_op_names[Variant::OP_MAX] = { "==", "!=", "<", "<=", ">", ">=", "+", "-", "*", "/", "- (negation)", "+ (positive)", "%", "+ (concatenation)", "<<", ">>", "&", "|", "^", "~", "and", "or", "xor", "not", "in" }; String Variant::get_operator_name(Operator p_op) { ERR_FAIL_INDEX_V(p_op, OP_MAX, ""); return _op_names[p_op]; }