/*************************************************************************/ /* gd_compiler.cpp */ /*************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /*************************************************************************/ /* Copyright (c) 2007-2018 Juan Linietsky, Ariel Manzur. */ /* Copyright (c) 2014-2018 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 "gd_compiler.h" #include "gd_script.h" void GDCompiler::_set_error(const String &p_error, const GDParser::Node *p_node) { if (error != "") return; error = p_error; if (p_node) { err_line = p_node->line; err_column = p_node->column; } else { err_line = 0; err_column = 0; } } bool GDCompiler::_create_unary_operator(CodeGen &codegen, const GDParser::OperatorNode *on, Variant::Operator op, int p_stack_level) { ERR_FAIL_COND_V(on->arguments.size() != 1, false); int src_address_a = _parse_expression(codegen, on->arguments[0], p_stack_level); if (src_address_a < 0) return false; codegen.opcodes.push_back(GDFunction::OPCODE_OPERATOR); // perform operator codegen.opcodes.push_back(op); //which operator codegen.opcodes.push_back(src_address_a); // argument 1 codegen.opcodes.push_back(src_address_a); // argument 2 (repeated) //codegen.opcodes.push_back(GDFunction::ADDR_TYPE_NIL); // argument 2 (unary only takes one parameter) return true; } bool GDCompiler::_create_binary_operator(CodeGen &codegen, const GDParser::OperatorNode *on, Variant::Operator op, int p_stack_level, bool p_initializer) { ERR_FAIL_COND_V(on->arguments.size() != 2, false); int src_address_a = _parse_expression(codegen, on->arguments[0], p_stack_level, false, p_initializer); if (src_address_a < 0) return false; if (src_address_a & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) p_stack_level++; //uses stack for return, increase stack int src_address_b = _parse_expression(codegen, on->arguments[1], p_stack_level, false, p_initializer); if (src_address_b < 0) return false; codegen.opcodes.push_back(GDFunction::OPCODE_OPERATOR); // perform operator codegen.opcodes.push_back(op); //which operator codegen.opcodes.push_back(src_address_a); // argument 1 codegen.opcodes.push_back(src_address_b); // argument 2 (unary only takes one parameter) return true; } /* int GDCompiler::_parse_subexpression(CodeGen& codegen,const GDParser::Node *p_expression) { int ret = _parse_expression(codegen,p_expression); if (ret<0) return ret; if (ret&(GDFunction::ADDR_TYPE_STACK<op) { case GDParser::OperatorNode::OP_ASSIGN_ADD: var_op = Variant::OP_ADD; break; case GDParser::OperatorNode::OP_ASSIGN_SUB: var_op = Variant::OP_SUBSTRACT; break; case GDParser::OperatorNode::OP_ASSIGN_MUL: var_op = Variant::OP_MULTIPLY; break; case GDParser::OperatorNode::OP_ASSIGN_DIV: var_op = Variant::OP_DIVIDE; break; case GDParser::OperatorNode::OP_ASSIGN_MOD: var_op = Variant::OP_MODULE; break; case GDParser::OperatorNode::OP_ASSIGN_SHIFT_LEFT: var_op = Variant::OP_SHIFT_LEFT; break; case GDParser::OperatorNode::OP_ASSIGN_SHIFT_RIGHT: var_op = Variant::OP_SHIFT_RIGHT; break; case GDParser::OperatorNode::OP_ASSIGN_BIT_AND: var_op = Variant::OP_BIT_AND; break; case GDParser::OperatorNode::OP_ASSIGN_BIT_OR: var_op = Variant::OP_BIT_OR; break; case GDParser::OperatorNode::OP_ASSIGN_BIT_XOR: var_op = Variant::OP_BIT_XOR; break; case GDParser::OperatorNode::OP_INIT_ASSIGN: case GDParser::OperatorNode::OP_ASSIGN: { //none } break; default: { ERR_FAIL_V(-1); } } bool initializer = p_expression->op == GDParser::OperatorNode::OP_INIT_ASSIGN; if (var_op == Variant::OP_MAX) { return _parse_expression(codegen, p_expression->arguments[1], p_stack_level, false, initializer); } if (!_create_binary_operator(codegen, p_expression, var_op, p_stack_level, initializer)) return -1; int dst_addr = (p_stack_level) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(dst_addr); // append the stack level as destination address of the opcode codegen.alloc_stack(p_stack_level); return dst_addr; } int GDCompiler::_parse_expression(CodeGen &codegen, const GDParser::Node *p_expression, int p_stack_level, bool p_root, bool p_initializer) { switch (p_expression->type) { //should parse variable declaration and adjust stack accordingly... case GDParser::Node::TYPE_IDENTIFIER: { //return identifier //wait, identifier could be a local variable or something else... careful here, must reference properly //as stack may be more interesting to work with //This could be made much simpler by just indexing "self", but done this way (with custom self-addressing modes) increases peformance a lot. const GDParser::IdentifierNode *in = static_cast(p_expression); StringName identifier = in->name; // TRY STACK! if (!p_initializer && codegen.stack_identifiers.has(identifier)) { int pos = codegen.stack_identifiers[identifier]; return pos | (GDFunction::ADDR_TYPE_STACK_VARIABLE << GDFunction::ADDR_BITS); } //TRY MEMBERS! if (!codegen.function_node || !codegen.function_node->_static) { // TRY MEMBER VARIABLES! //static function if (codegen.script->member_indices.has(identifier)) { int idx = codegen.script->member_indices[identifier].index; return idx | (GDFunction::ADDR_TYPE_MEMBER << GDFunction::ADDR_BITS); //argument (stack root) } } //TRY CLASS CONSTANTS GDScript *owner = codegen.script; while (owner) { GDScript *scr = owner; GDNativeClass *nc = NULL; while (scr) { if (scr->constants.has(identifier)) { //int idx=scr->constants[identifier]; int idx = codegen.get_name_map_pos(identifier); return idx | (GDFunction::ADDR_TYPE_CLASS_CONSTANT << GDFunction::ADDR_BITS); //argument (stack root) } if (scr->native.is_valid()) nc = scr->native.ptr(); scr = scr->_base; } // CLASS C++ Integer Constant if (nc) { bool success = false; int constant = ObjectTypeDB::get_integer_constant(nc->get_name(), identifier, &success); if (success) { Variant key = constant; int idx; if (!codegen.constant_map.has(key)) { idx = codegen.constant_map.size(); codegen.constant_map[key] = idx; } else { idx = codegen.constant_map[key]; } return idx | (GDFunction::ADDR_TYPE_LOCAL_CONSTANT << GDFunction::ADDR_BITS); //make it a local constant (faster access) } } owner = owner->_owner; } /* handled in constants now if (codegen.script->subclasses.has(identifier)) { //same with a subclass, make it a local constant. int idx = codegen.get_constant_pos(codegen.script->subclasses[identifier]); return idx|(GDFunction::ADDR_TYPE_LOCAL_CONSTANT<get_global_map().has(identifier)) { int idx = GDScriptLanguage::get_singleton()->get_global_map()[identifier]; return idx | (GDFunction::ADDR_TYPE_GLOBAL << GDFunction::ADDR_BITS); //argument (stack root) } //not found, error _set_error("Identifier not found: " + String(identifier), p_expression); return -1; } break; case GDParser::Node::TYPE_CONSTANT: { //return constant const GDParser::ConstantNode *cn = static_cast(p_expression); int idx; if (!codegen.constant_map.has(cn->value)) { idx = codegen.constant_map.size(); codegen.constant_map[cn->value] = idx; } else { idx = codegen.constant_map[cn->value]; } return idx | (GDFunction::ADDR_TYPE_LOCAL_CONSTANT << GDFunction::ADDR_BITS); //argument (stack root) } break; case GDParser::Node::TYPE_SELF: { //return constant if (codegen.function_node && codegen.function_node->_static) { _set_error("'self' not present in static function!", p_expression); return -1; } return (GDFunction::ADDR_TYPE_SELF << GDFunction::ADDR_BITS); } break; case GDParser::Node::TYPE_ARRAY: { const GDParser::ArrayNode *an = static_cast(p_expression); Vector values; int slevel = p_stack_level; for (int i = 0; i < an->elements.size(); i++) { int ret = _parse_expression(codegen, an->elements[i], slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } values.push_back(ret); } codegen.opcodes.push_back(GDFunction::OPCODE_CONSTRUCT_ARRAY); codegen.opcodes.push_back(values.size()); for (int i = 0; i < values.size(); i++) codegen.opcodes.push_back(values[i]); int dst_addr = (p_stack_level) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(dst_addr); // append the stack level as destination address of the opcode codegen.alloc_stack(p_stack_level); return dst_addr; } break; case GDParser::Node::TYPE_DICTIONARY: { const GDParser::DictionaryNode *dn = static_cast(p_expression); Vector values; int slevel = p_stack_level; for (int i = 0; i < dn->elements.size(); i++) { int ret = _parse_expression(codegen, dn->elements[i].key, slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } values.push_back(ret); ret = _parse_expression(codegen, dn->elements[i].value, slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } values.push_back(ret); } codegen.opcodes.push_back(GDFunction::OPCODE_CONSTRUCT_DICTIONARY); codegen.opcodes.push_back(dn->elements.size()); for (int i = 0; i < values.size(); i++) codegen.opcodes.push_back(values[i]); int dst_addr = (p_stack_level) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(dst_addr); // append the stack level as destination address of the opcode codegen.alloc_stack(p_stack_level); return dst_addr; } break; case GDParser::Node::TYPE_OPERATOR: { //hell breaks loose const GDParser::OperatorNode *on = static_cast(p_expression); switch (on->op) { //call/constructor operator case GDParser::OperatorNode::OP_PARENT_CALL: { ERR_FAIL_COND_V(on->arguments.size() < 1, -1); const GDParser::IdentifierNode *in = (const GDParser::IdentifierNode *)on->arguments[0]; Vector arguments; int slevel = p_stack_level; for (int i = 1; i < on->arguments.size(); i++) { int ret = _parse_expression(codegen, on->arguments[i], slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } arguments.push_back(ret); } //push call bytecode codegen.opcodes.push_back(GDFunction::OPCODE_CALL_SELF_BASE); // basic type constructor codegen.opcodes.push_back(codegen.get_name_map_pos(in->name)); //instance codegen.opcodes.push_back(arguments.size()); //argument count codegen.alloc_call(arguments.size()); for (int i = 0; i < arguments.size(); i++) codegen.opcodes.push_back(arguments[i]); //arguments } break; case GDParser::OperatorNode::OP_CALL: { if (on->arguments[0]->type == GDParser::Node::TYPE_TYPE) { //construct a basic type ERR_FAIL_COND_V(on->arguments.size() < 1, -1); const GDParser::TypeNode *tn = (const GDParser::TypeNode *)on->arguments[0]; int vtype = tn->vtype; Vector arguments; int slevel = p_stack_level; for (int i = 1; i < on->arguments.size(); i++) { int ret = _parse_expression(codegen, on->arguments[i], slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } arguments.push_back(ret); } //push call bytecode codegen.opcodes.push_back(GDFunction::OPCODE_CONSTRUCT); // basic type constructor codegen.opcodes.push_back(vtype); //instance codegen.opcodes.push_back(arguments.size()); //argument count codegen.alloc_call(arguments.size()); for (int i = 0; i < arguments.size(); i++) codegen.opcodes.push_back(arguments[i]); //arguments } else if (on->arguments[0]->type == GDParser::Node::TYPE_BUILT_IN_FUNCTION) { //built in function ERR_FAIL_COND_V(on->arguments.size() < 1, -1); Vector arguments; int slevel = p_stack_level; for (int i = 1; i < on->arguments.size(); i++) { int ret = _parse_expression(codegen, on->arguments[i], slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } arguments.push_back(ret); } codegen.opcodes.push_back(GDFunction::OPCODE_CALL_BUILT_IN); codegen.opcodes.push_back(static_cast(on->arguments[0])->function); codegen.opcodes.push_back(on->arguments.size() - 1); codegen.alloc_call(on->arguments.size() - 1); for (int i = 0; i < arguments.size(); i++) codegen.opcodes.push_back(arguments[i]); } else { //regular function ERR_FAIL_COND_V(on->arguments.size() < 2, -1); const GDParser::Node *instance = on->arguments[0]; if (instance->type == GDParser::Node::TYPE_SELF) { //room for optimization } Vector arguments; int slevel = p_stack_level; for (int i = 0; i < on->arguments.size(); i++) { int ret; if (i == 0 && on->arguments[i]->type == GDParser::Node::TYPE_SELF && codegen.function_node && codegen.function_node->_static) { //static call to self ret = (GDFunction::ADDR_TYPE_CLASS << GDFunction::ADDR_BITS); } else if (i == 1) { if (on->arguments[i]->type != GDParser::Node::TYPE_IDENTIFIER) { _set_error("Attempt to call a non-identifier.", on); return -1; } GDParser::IdentifierNode *id = static_cast(on->arguments[i]); ret = codegen.get_name_map_pos(id->name); } else { ret = _parse_expression(codegen, on->arguments[i], slevel); if (ret < 0) return ret; if (ret & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } } arguments.push_back(ret); } codegen.opcodes.push_back(p_root ? GDFunction::OPCODE_CALL : GDFunction::OPCODE_CALL_RETURN); // perform operator codegen.opcodes.push_back(on->arguments.size() - 2); codegen.alloc_call(on->arguments.size() - 2); for (int i = 0; i < arguments.size(); i++) codegen.opcodes.push_back(arguments[i]); } } break; case GDParser::OperatorNode::OP_YIELD: { ERR_FAIL_COND_V(on->arguments.size() && on->arguments.size() != 2, -1); Vector arguments; int slevel = p_stack_level; for (int i = 0; i < on->arguments.size(); i++) { int ret = _parse_expression(codegen, on->arguments[i], slevel); if (ret < 0) return ret; if (ret & (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS)) { slevel++; codegen.alloc_stack(slevel); } arguments.push_back(ret); } //push call bytecode codegen.opcodes.push_back(arguments.size() == 0 ? GDFunction::OPCODE_YIELD : GDFunction::OPCODE_YIELD_SIGNAL); // basic type constructor for (int i = 0; i < arguments.size(); i++) codegen.opcodes.push_back(arguments[i]); //arguments codegen.opcodes.push_back(GDFunction::OPCODE_YIELD_RESUME); //next will be where to place the result :) } break; //indexing operator case GDParser::OperatorNode::OP_INDEX: case GDParser::OperatorNode::OP_INDEX_NAMED: { ERR_FAIL_COND_V(on->arguments.size() != 2, -1); int slevel = p_stack_level; bool named = (on->op == GDParser::OperatorNode::OP_INDEX_NAMED); int from = _parse_expression(codegen, on->arguments[0], slevel); if (from < 0) return from; int index; if (named) { if (on->arguments[0]->type == GDParser::Node::TYPE_SELF && codegen.script && codegen.function_node && !codegen.function_node->_static) { GDParser::IdentifierNode *identifier = static_cast(on->arguments[1]); const Map::Element *MI = codegen.script->member_indices.find(identifier->name); #ifdef DEBUG_ENABLED if (MI && MI->get().getter == codegen.function_node->name) { String n = static_cast(on->arguments[1])->name; _set_error("Must use '" + n + "' instead of 'self." + n + "' in getter.", on); return -1; } #endif if (MI && MI->get().getter == "") { // Faster than indexing self (as if no self. had been used) return (MI->get().index) | (GDFunction::ADDR_TYPE_MEMBER << GDFunction::ADDR_BITS); } } index = codegen.get_name_map_pos(static_cast(on->arguments[1])->name); } else { if (on->arguments[1]->type == GDParser::Node::TYPE_CONSTANT && static_cast(on->arguments[1])->value.get_type() == Variant::STRING) { //also, somehow, named (speed up anyway) StringName name = static_cast(on->arguments[1])->value; index = codegen.get_name_map_pos(name); named = true; } else { //regular indexing if (from & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } index = _parse_expression(codegen, on->arguments[1], slevel); if (index < 0) return index; } } codegen.opcodes.push_back(named ? GDFunction::OPCODE_GET_NAMED : GDFunction::OPCODE_GET); // perform operator codegen.opcodes.push_back(from); // argument 1 codegen.opcodes.push_back(index); // argument 2 (unary only takes one parameter) } break; case GDParser::OperatorNode::OP_AND: { // AND operator with early out on failure int res = _parse_expression(codegen, on->arguments[0], p_stack_level); if (res < 0) return res; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF_NOT); codegen.opcodes.push_back(res); int jump_fail_pos = codegen.opcodes.size(); codegen.opcodes.push_back(0); res = _parse_expression(codegen, on->arguments[1], p_stack_level); if (res < 0) return res; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF_NOT); codegen.opcodes.push_back(res); int jump_fail_pos2 = codegen.opcodes.size(); codegen.opcodes.push_back(0); codegen.alloc_stack(p_stack_level); //it will be used.. codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN_TRUE); codegen.opcodes.push_back(p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(codegen.opcodes.size() + 3); codegen.opcodes[jump_fail_pos] = codegen.opcodes.size(); codegen.opcodes[jump_fail_pos2] = codegen.opcodes.size(); codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN_FALSE); codegen.opcodes.push_back(p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); return p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS; } break; case GDParser::OperatorNode::OP_OR: { // OR operator with early out on success int res = _parse_expression(codegen, on->arguments[0], p_stack_level); if (res < 0) return res; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF); codegen.opcodes.push_back(res); int jump_success_pos = codegen.opcodes.size(); codegen.opcodes.push_back(0); res = _parse_expression(codegen, on->arguments[1], p_stack_level); if (res < 0) return res; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF); codegen.opcodes.push_back(res); int jump_success_pos2 = codegen.opcodes.size(); codegen.opcodes.push_back(0); codegen.alloc_stack(p_stack_level); //it will be used.. codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN_FALSE); codegen.opcodes.push_back(p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(codegen.opcodes.size() + 3); codegen.opcodes[jump_success_pos] = codegen.opcodes.size(); codegen.opcodes[jump_success_pos2] = codegen.opcodes.size(); codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN_TRUE); codegen.opcodes.push_back(p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); return p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS; } break; // ternary operators case GDParser::OperatorNode::OP_TERNARY_IF: { // x IF a ELSE y operator with early out on failure int res = _parse_expression(codegen, on->arguments[0], p_stack_level); if (res < 0) return res; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF_NOT); codegen.opcodes.push_back(res); int jump_fail_pos = codegen.opcodes.size(); codegen.opcodes.push_back(0); res = _parse_expression(codegen, on->arguments[1], p_stack_level); if (res < 0) return res; codegen.alloc_stack(p_stack_level); //it will be used.. codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN); codegen.opcodes.push_back(p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(res); codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); int jump_past_pos = codegen.opcodes.size(); codegen.opcodes.push_back(0); codegen.opcodes[jump_fail_pos] = codegen.opcodes.size(); res = _parse_expression(codegen, on->arguments[2], p_stack_level); if (res < 0) return res; codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN); codegen.opcodes.push_back(p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(res); codegen.opcodes[jump_past_pos] = codegen.opcodes.size(); return p_stack_level | GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS; } break; //unary operators case GDParser::OperatorNode::OP_NEG: { if (!_create_unary_operator(codegen, on, Variant::OP_NEGATE, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_NOT: { if (!_create_unary_operator(codegen, on, Variant::OP_NOT, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_BIT_INVERT: { if (!_create_unary_operator(codegen, on, Variant::OP_BIT_NEGATE, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_PREINC: { } break; //? case GDParser::OperatorNode::OP_PREDEC: { } break; case GDParser::OperatorNode::OP_INC: { } break; case GDParser::OperatorNode::OP_DEC: { } break; //binary operators (in precedence order) case GDParser::OperatorNode::OP_IN: { if (!_create_binary_operator(codegen, on, Variant::OP_IN, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_EQUAL: { if (!_create_binary_operator(codegen, on, Variant::OP_EQUAL, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_NOT_EQUAL: { if (!_create_binary_operator(codegen, on, Variant::OP_NOT_EQUAL, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_LESS: { if (!_create_binary_operator(codegen, on, Variant::OP_LESS, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_LESS_EQUAL: { if (!_create_binary_operator(codegen, on, Variant::OP_LESS_EQUAL, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_GREATER: { if (!_create_binary_operator(codegen, on, Variant::OP_GREATER, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_GREATER_EQUAL: { if (!_create_binary_operator(codegen, on, Variant::OP_GREATER_EQUAL, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_ADD: { if (!_create_binary_operator(codegen, on, Variant::OP_ADD, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_SUB: { if (!_create_binary_operator(codegen, on, Variant::OP_SUBSTRACT, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_MUL: { if (!_create_binary_operator(codegen, on, Variant::OP_MULTIPLY, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_DIV: { if (!_create_binary_operator(codegen, on, Variant::OP_DIVIDE, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_MOD: { if (!_create_binary_operator(codegen, on, Variant::OP_MODULE, p_stack_level)) return -1; } break; //case GDParser::OperatorNode::OP_SHIFT_LEFT: { if (!_create_binary_operator(codegen,on,Variant::OP_SHIFT_LEFT,p_stack_level)) return -1;} break; //case GDParser::OperatorNode::OP_SHIFT_RIGHT: { if (!_create_binary_operator(codegen,on,Variant::OP_SHIFT_RIGHT,p_stack_level)) return -1;} break; case GDParser::OperatorNode::OP_BIT_AND: { if (!_create_binary_operator(codegen, on, Variant::OP_BIT_AND, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_BIT_OR: { if (!_create_binary_operator(codegen, on, Variant::OP_BIT_OR, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_BIT_XOR: { if (!_create_binary_operator(codegen, on, Variant::OP_BIT_XOR, p_stack_level)) return -1; } break; //shift case GDParser::OperatorNode::OP_SHIFT_LEFT: { if (!_create_binary_operator(codegen, on, Variant::OP_SHIFT_LEFT, p_stack_level)) return -1; } break; case GDParser::OperatorNode::OP_SHIFT_RIGHT: { if (!_create_binary_operator(codegen, on, Variant::OP_SHIFT_RIGHT, p_stack_level)) return -1; } break; //assignment operators case GDParser::OperatorNode::OP_ASSIGN_ADD: case GDParser::OperatorNode::OP_ASSIGN_SUB: case GDParser::OperatorNode::OP_ASSIGN_MUL: case GDParser::OperatorNode::OP_ASSIGN_DIV: case GDParser::OperatorNode::OP_ASSIGN_MOD: case GDParser::OperatorNode::OP_ASSIGN_SHIFT_LEFT: case GDParser::OperatorNode::OP_ASSIGN_SHIFT_RIGHT: case GDParser::OperatorNode::OP_ASSIGN_BIT_AND: case GDParser::OperatorNode::OP_ASSIGN_BIT_OR: case GDParser::OperatorNode::OP_ASSIGN_BIT_XOR: case GDParser::OperatorNode::OP_INIT_ASSIGN: case GDParser::OperatorNode::OP_ASSIGN: { ERR_FAIL_COND_V(on->arguments.size() != 2, -1); if (on->arguments[0]->type == GDParser::Node::TYPE_OPERATOR && (static_cast(on->arguments[0])->op == GDParser::OperatorNode::OP_INDEX || static_cast(on->arguments[0])->op == GDParser::OperatorNode::OP_INDEX_NAMED)) { //SET (chained) MODE!! #ifdef DEBUG_ENABLED if (static_cast(on->arguments[0])->op == GDParser::OperatorNode::OP_INDEX_NAMED) { const GDParser::OperatorNode *inon = static_cast(on->arguments[0]); if (inon->arguments[0]->type == GDParser::Node::TYPE_SELF && codegen.script && codegen.function_node && !codegen.function_node->_static) { const Map::Element *MI = codegen.script->member_indices.find(static_cast(inon->arguments[1])->name); if (MI && MI->get().setter == codegen.function_node->name) { String n = static_cast(inon->arguments[1])->name; _set_error("Must use '" + n + "' instead of 'self." + n + "' in setter.", inon); return -1; } } } #endif int slevel = p_stack_level; GDParser::OperatorNode *op = static_cast(on->arguments[0]); /* Find chain of sets */ List chain; { //create get/set chain GDParser::OperatorNode *n = op; while (true) { chain.push_back(n); if (n->arguments[0]->type != GDParser::Node::TYPE_OPERATOR) break; n = static_cast(n->arguments[0]); if (n->op != GDParser::OperatorNode::OP_INDEX && n->op != GDParser::OperatorNode::OP_INDEX_NAMED) break; } } /* Chain of gets */ //get at (potential) root stack pos, so it can be returned int prev_pos = _parse_expression(codegen, chain.back()->get()->arguments[0], slevel); if (prev_pos < 0) return prev_pos; int retval = prev_pos; //print_line("retval: "+itos(retval)); if (retval & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } Vector setchain; for (List::Element *E = chain.back(); E; E = E->prev()) { if (E == chain.front()) //ignore first break; bool named = E->get()->op == GDParser::OperatorNode::OP_INDEX_NAMED; int key_idx; if (named) { key_idx = codegen.get_name_map_pos(static_cast(E->get()->arguments[1])->name); //printf("named key %x\n",key_idx); } else { if (prev_pos & (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS)) { slevel++; codegen.alloc_stack(slevel); } GDParser::Node *key = E->get()->arguments[1]; key_idx = _parse_expression(codegen, key, slevel); //printf("expr key %x\n",key_idx); //stack was raised here if retval was stack but.. } if (key_idx < 0) return key_idx; codegen.opcodes.push_back(named ? GDFunction::OPCODE_GET_NAMED : GDFunction::OPCODE_GET); codegen.opcodes.push_back(prev_pos); codegen.opcodes.push_back(key_idx); slevel++; codegen.alloc_stack(slevel); int dst_pos = (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) | slevel; codegen.opcodes.push_back(dst_pos); //add in reverse order, since it will be reverted setchain.push_back(dst_pos); setchain.push_back(key_idx); setchain.push_back(prev_pos); setchain.push_back(named ? GDFunction::OPCODE_SET_NAMED : GDFunction::OPCODE_SET); prev_pos = dst_pos; } setchain.invert(); int set_index; bool named = false; if (static_cast(op)->op == GDParser::OperatorNode::OP_INDEX_NAMED) { set_index = codegen.get_name_map_pos(static_cast(op->arguments[1])->name); named = true; } else { set_index = _parse_expression(codegen, op->arguments[1], slevel + 1); named = false; } if (set_index < 0) return set_index; if (set_index & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } int set_value = _parse_assign_right_expression(codegen, on, slevel + 1); if (set_value < 0) return set_value; codegen.opcodes.push_back(named ? GDFunction::OPCODE_SET_NAMED : GDFunction::OPCODE_SET); codegen.opcodes.push_back(prev_pos); codegen.opcodes.push_back(set_index); codegen.opcodes.push_back(set_value); for (int i = 0; i < setchain.size(); i += 4) { codegen.opcodes.push_back(setchain[i + 0]); codegen.opcodes.push_back(setchain[i + 1]); codegen.opcodes.push_back(setchain[i + 2]); codegen.opcodes.push_back(setchain[i + 3]); } return retval; } else { //ASSIGNMENT MODE!! int slevel = p_stack_level; int dst_address_a = _parse_expression(codegen, on->arguments[0], slevel, false, on->op == GDParser::OperatorNode::OP_INIT_ASSIGN); if (dst_address_a < 0) return -1; if (dst_address_a & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) { slevel++; codegen.alloc_stack(slevel); } int src_address_b = _parse_assign_right_expression(codegen, on, slevel); if (src_address_b < 0) return -1; codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN); // perform operator codegen.opcodes.push_back(dst_address_a); // argument 1 codegen.opcodes.push_back(src_address_b); // argument 2 (unary only takes one parameter) return dst_address_a; //if anything, returns wathever was assigned or correct stack position } } break; case GDParser::OperatorNode::OP_EXTENDS: { ERR_FAIL_COND_V(on->arguments.size() != 2, false); int slevel = p_stack_level; int src_address_a = _parse_expression(codegen, on->arguments[0], slevel); if (src_address_a < 0) return -1; if (src_address_a & GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) slevel++; //uses stack for return, increase stack int src_address_b = _parse_expression(codegen, on->arguments[1], slevel); if (src_address_b < 0) return -1; codegen.opcodes.push_back(GDFunction::OPCODE_EXTENDS_TEST); // perform operator codegen.opcodes.push_back(src_address_a); // argument 1 codegen.opcodes.push_back(src_address_b); // argument 2 (unary only takes one parameter) } break; default: { ERR_EXPLAIN("Bug in bytecode compiler, unexpected operator #" + itos(on->op) + " in parse tree while parsing expression."); ERR_FAIL_V(0); //unreachable code } break; } int dst_addr = (p_stack_level) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.opcodes.push_back(dst_addr); // append the stack level as destination address of the opcode codegen.alloc_stack(p_stack_level); return dst_addr; } break; //TYPE_TYPE, default: { ERR_EXPLAIN("Bug in bytecode compiler, unexpected node in parse tree while parsing expression."); ERR_FAIL_V(-1); //unreachable code } break; } ERR_FAIL_V(-1); //unreachable code } Error GDCompiler::_parse_block(CodeGen &codegen, const GDParser::BlockNode *p_block, int p_stack_level, int p_break_addr, int p_continue_addr) { codegen.push_stack_identifiers(); int new_identifiers = 0; codegen.current_line = p_block->line; for (int i = 0; i < p_block->statements.size(); i++) { const GDParser::Node *s = p_block->statements[i]; switch (s->type) { case GDParser::Node::TYPE_NEWLINE: { #ifdef DEBUG_ENABLED const GDParser::NewLineNode *nl = static_cast(s); codegen.opcodes.push_back(GDFunction::OPCODE_LINE); codegen.opcodes.push_back(nl->line); codegen.current_line = nl->line; #endif } break; case GDParser::Node::TYPE_CONTROL_FLOW: { // try subblocks const GDParser::ControlFlowNode *cf = static_cast(s); switch (cf->cf_type) { case GDParser::ControlFlowNode::CF_IF: { #ifdef DEBUG_ENABLED codegen.opcodes.push_back(GDFunction::OPCODE_LINE); codegen.opcodes.push_back(cf->line); codegen.current_line = cf->line; #endif int ret = _parse_expression(codegen, cf->arguments[0], p_stack_level, false); if (ret < 0) return ERR_PARSE_ERROR; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF_NOT); codegen.opcodes.push_back(ret); int else_addr = codegen.opcodes.size(); codegen.opcodes.push_back(0); //temporary Error err = _parse_block(codegen, cf->body, p_stack_level, p_break_addr, p_continue_addr); if (err) return err; if (cf->body_else) { codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); int end_addr = codegen.opcodes.size(); codegen.opcodes.push_back(0); codegen.opcodes[else_addr] = codegen.opcodes.size(); Error err = _parse_block(codegen, cf->body_else, p_stack_level, p_break_addr, p_continue_addr); if (err) return err; codegen.opcodes[end_addr] = codegen.opcodes.size(); } else { //end without else codegen.opcodes[else_addr] = codegen.opcodes.size(); } } break; case GDParser::ControlFlowNode::CF_FOR: { int slevel = p_stack_level; int iter_stack_pos = slevel; int iterator_pos = (slevel++) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); int counter_pos = (slevel++) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); int container_pos = (slevel++) | (GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS); codegen.alloc_stack(slevel); codegen.push_stack_identifiers(); codegen.add_stack_identifier(static_cast(cf->arguments[0])->name, iter_stack_pos); int ret = _parse_expression(codegen, cf->arguments[1], slevel, false); if (ret < 0) return ERR_COMPILATION_FAILED; //assign container codegen.opcodes.push_back(GDFunction::OPCODE_ASSIGN); codegen.opcodes.push_back(container_pos); codegen.opcodes.push_back(ret); //begin loop codegen.opcodes.push_back(GDFunction::OPCODE_ITERATE_BEGIN); codegen.opcodes.push_back(counter_pos); codegen.opcodes.push_back(container_pos); codegen.opcodes.push_back(codegen.opcodes.size() + 4); codegen.opcodes.push_back(iterator_pos); codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); //skip code for next codegen.opcodes.push_back(codegen.opcodes.size() + 8); //break loop int break_pos = codegen.opcodes.size(); codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); //skip code for next codegen.opcodes.push_back(0); //skip code for next //next loop int continue_pos = codegen.opcodes.size(); codegen.opcodes.push_back(GDFunction::OPCODE_ITERATE); codegen.opcodes.push_back(counter_pos); codegen.opcodes.push_back(container_pos); codegen.opcodes.push_back(break_pos); codegen.opcodes.push_back(iterator_pos); Error err = _parse_block(codegen, cf->body, slevel, break_pos, continue_pos); if (err) return err; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(continue_pos); codegen.opcodes[break_pos + 1] = codegen.opcodes.size(); codegen.pop_stack_identifiers(); } break; case GDParser::ControlFlowNode::CF_WHILE: { codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(codegen.opcodes.size() + 3); int break_addr = codegen.opcodes.size(); codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(0); int continue_addr = codegen.opcodes.size(); int ret = _parse_expression(codegen, cf->arguments[0], p_stack_level, false); if (ret < 0) return ERR_PARSE_ERROR; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_IF_NOT); codegen.opcodes.push_back(ret); codegen.opcodes.push_back(break_addr); Error err = _parse_block(codegen, cf->body, p_stack_level, break_addr, continue_addr); if (err) return err; codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(continue_addr); codegen.opcodes[break_addr + 1] = codegen.opcodes.size(); } break; case GDParser::ControlFlowNode::CF_SWITCH: { } break; case GDParser::ControlFlowNode::CF_BREAK: { if (p_break_addr < 0) { _set_error("'break'' not within loop", cf); return ERR_COMPILATION_FAILED; } codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(p_break_addr); } break; case GDParser::ControlFlowNode::CF_CONTINUE: { if (p_continue_addr < 0) { _set_error("'continue' not within loop", cf); return ERR_COMPILATION_FAILED; } codegen.opcodes.push_back(GDFunction::OPCODE_JUMP); codegen.opcodes.push_back(p_continue_addr); } break; case GDParser::ControlFlowNode::CF_RETURN: { int ret; if (cf->arguments.size()) { ret = _parse_expression(codegen, cf->arguments[0], p_stack_level, false); if (ret < 0) return ERR_PARSE_ERROR; } else { ret = GDFunction::ADDR_TYPE_NIL << GDFunction::ADDR_BITS; } codegen.opcodes.push_back(GDFunction::OPCODE_RETURN); codegen.opcodes.push_back(ret); } break; } } break; case GDParser::Node::TYPE_ASSERT: { #ifdef DEBUG_ENABLED // try subblocks const GDParser::AssertNode *as = static_cast(s); int ret = _parse_expression(codegen, as->condition, p_stack_level, false); if (ret < 0) return ERR_PARSE_ERROR; codegen.opcodes.push_back(GDFunction::OPCODE_ASSERT); codegen.opcodes.push_back(ret); #endif } break; case GDParser::Node::TYPE_BREAKPOINT: { #ifdef DEBUG_ENABLED // try subblocks codegen.opcodes.push_back(GDFunction::OPCODE_BREAKPOINT); #endif } break; case GDParser::Node::TYPE_LOCAL_VAR: { const GDParser::LocalVarNode *lv = static_cast(s); codegen.add_stack_identifier(lv->name, p_stack_level++); codegen.alloc_stack(p_stack_level); new_identifiers++; } break; default: { //expression int ret = _parse_expression(codegen, s, p_stack_level, true); if (ret < 0) return ERR_PARSE_ERROR; } break; } } codegen.pop_stack_identifiers(); return OK; } Error GDCompiler::_parse_function(GDScript *p_script, const GDParser::ClassNode *p_class, const GDParser::FunctionNode *p_func, bool p_for_ready) { Vector bytecode; CodeGen codegen; codegen.class_node = p_class; codegen.script = p_script; codegen.function_node = p_func; codegen.stack_max = 0; codegen.current_line = 0; codegen.call_max = 0; codegen.debug_stack = ScriptDebugger::get_singleton() != NULL; Vector argnames; int stack_level = 0; if (p_func) { for (int i = 0; i < p_func->arguments.size(); i++) { codegen.add_stack_identifier(p_func->arguments[i], i); #ifdef TOOLS_ENABLED argnames.push_back(p_func->arguments[i]); #endif } stack_level = p_func->arguments.size(); } codegen.alloc_stack(stack_level); /* Parse initializer -if applies- */ bool is_initializer = !p_for_ready && !p_func; if (is_initializer || (p_func && String(p_func->name) == "_init")) { //parse initializer for class members if (!p_func && p_class->extends_used && p_script->native.is_null()) { //call implicit parent constructor codegen.opcodes.push_back(GDFunction::OPCODE_CALL_SELF_BASE); codegen.opcodes.push_back(codegen.get_name_map_pos("_init")); codegen.opcodes.push_back(0); codegen.opcodes.push_back((GDFunction::ADDR_TYPE_STACK << GDFunction::ADDR_BITS) | 0); } Error err = _parse_block(codegen, p_class->initializer, stack_level); if (err) return err; is_initializer = true; } if (p_for_ready || (p_func && String(p_func->name) == "_ready")) { //parse initializer for class members if (p_class->ready->statements.size()) { Error err = _parse_block(codegen, p_class->ready, stack_level); if (err) return err; } } /* Parse default argument code -if applies- */ Vector defarg_addr; StringName func_name; if (p_func) { if (p_func->default_values.size()) { codegen.opcodes.push_back(GDFunction::OPCODE_JUMP_TO_DEF_ARGUMENT); defarg_addr.push_back(codegen.opcodes.size()); for (int i = 0; i < p_func->default_values.size(); i++) { _parse_expression(codegen, p_func->default_values[i], stack_level, true); defarg_addr.push_back(codegen.opcodes.size()); } defarg_addr.invert(); } Error err = _parse_block(codegen, p_func->body, stack_level); if (err) return err; func_name = p_func->name; } else { if (p_for_ready) func_name = "_ready"; else func_name = "_init"; } codegen.opcodes.push_back(GDFunction::OPCODE_END); GDFunction *gdfunc = NULL; //if (String(p_func->name)=="") { //initializer func // gdfunc = &p_script->initializer; //} else { //regular func p_script->member_functions[func_name] = memnew(GDFunction); gdfunc = p_script->member_functions[func_name]; //} if (p_func) gdfunc->_static = p_func->_static; #ifdef TOOLS_ENABLED gdfunc->arg_names = argnames; #endif //constants if (codegen.constant_map.size()) { gdfunc->_constant_count = codegen.constant_map.size(); gdfunc->constants.resize(codegen.constant_map.size()); gdfunc->_constants_ptr = &gdfunc->constants[0]; const Variant *K = NULL; while ((K = codegen.constant_map.next(K))) { int idx = codegen.constant_map[*K]; gdfunc->constants[idx] = *K; } } else { gdfunc->_constants_ptr = NULL; gdfunc->_constant_count = 0; } //global names if (codegen.name_map.size()) { gdfunc->global_names.resize(codegen.name_map.size()); gdfunc->_global_names_ptr = &gdfunc->global_names[0]; for (Map::Element *E = codegen.name_map.front(); E; E = E->next()) { gdfunc->global_names[E->get()] = E->key(); } gdfunc->_global_names_count = gdfunc->global_names.size(); } else { gdfunc->_global_names_ptr = NULL; gdfunc->_global_names_count = 0; } if (codegen.opcodes.size()) { gdfunc->code = codegen.opcodes; gdfunc->_code_ptr = &gdfunc->code[0]; gdfunc->_code_size = codegen.opcodes.size(); } else { gdfunc->_code_ptr = NULL; gdfunc->_code_size = 0; } if (defarg_addr.size()) { gdfunc->default_arguments = defarg_addr; gdfunc->_default_arg_count = defarg_addr.size() - 1; gdfunc->_default_arg_ptr = &gdfunc->default_arguments[0]; } else { gdfunc->_default_arg_count = 0; gdfunc->_default_arg_ptr = NULL; } gdfunc->_argument_count = p_func ? p_func->arguments.size() : 0; gdfunc->_stack_size = codegen.stack_max; gdfunc->_call_size = codegen.call_max; gdfunc->name = func_name; #ifdef DEBUG_ENABLED if (ScriptDebugger::get_singleton()) { String signature; //path if (p_script->get_path() != String()) signature += p_script->get_path(); //loc if (p_func) { signature += "::" + itos(p_func->body->line); } else { signature += "::0"; } //funciton and class if (p_class->name) { signature += "::" + String(p_class->name) + "." + String(func_name); } else { signature += "::" + String(func_name); } gdfunc->profile.signature = signature; } #endif gdfunc->_script = p_script; gdfunc->source = source; #ifdef DEBUG_ENABLED { gdfunc->func_cname = (String(source) + " - " + String(func_name)).utf8(); gdfunc->_func_cname = gdfunc->func_cname.get_data(); } #endif if (p_func) { gdfunc->_initial_line = p_func->line; } else { gdfunc->_initial_line = 0; } if (codegen.debug_stack) gdfunc->stack_debug = codegen.stack_debug; if (is_initializer) p_script->initializer = gdfunc; return OK; } Error GDCompiler::_parse_class(GDScript *p_script, GDScript *p_owner, const GDParser::ClassNode *p_class, bool p_keep_state) { Map > old_subclasses; if (p_keep_state) { old_subclasses = p_script->subclasses; } p_script->native = Ref(); p_script->base = Ref(); p_script->_base = NULL; p_script->members.clear(); p_script->constants.clear(); for (Map::Element *E = p_script->member_functions.front(); E; E = E->next()) { memdelete(E->get()); } p_script->member_functions.clear(); p_script->member_indices.clear(); p_script->member_info.clear(); p_script->_signals.clear(); p_script->initializer = NULL; p_script->subclasses.clear(); p_script->_owner = p_owner; p_script->tool = p_class->tool; p_script->name = p_class->name; Ref native; if (p_class->extends_used) { //do inheritance String path = p_class->extends_file; Ref script; if (path != "") { //path (and optionally subclasses) if (path.is_rel_path()) { String base; if (p_owner) { GDScript *current_class = p_owner; while (current_class != NULL) { base = current_class->get_path(); if (base == "") current_class = current_class->_owner; else break; } } else { base = p_script->get_path(); } if (base == "" || base.is_rel_path()) { _set_error("Could not resolve relative path for parent class: " + path, p_class); return ERR_FILE_NOT_FOUND; } path = base.get_base_dir().plus_file(path).simplify_path(); } script = ResourceLoader::load(path); if (script.is_null()) { _set_error("Could not load base class: " + path, p_class); return ERR_FILE_NOT_FOUND; } if (!script->valid) { _set_error("Script not fully loaded (cyclic preload?): " + path, p_class); return ERR_BUSY; } //print_line("EXTENDS PATH: "+path+" script is "+itos(script.is_valid())+" indices is "+itos(script->member_indices.size())+" valid? "+itos(script->valid)); if (p_class->extends_class.size()) { for (int i = 0; i < p_class->extends_class.size(); i++) { String sub = p_class->extends_class[i]; if (script->subclasses.has(sub)) { Ref