void BlockHierarchyResolver::enter(Block &block)
{
+ r_any_resolved |= (current_block!=block.parent);
block.parent = current_block;
}
TypeResolver::TypeResolver():
- stage(0)
+ stage(0),
+ r_any_resolved(false)
{ }
-void TypeResolver::apply(Stage &s)
+bool TypeResolver::apply(Stage &s)
{
stage = &s;
s.types.clear();
+ r_any_resolved = false;
s.content.visit(*this);
+ return r_any_resolved;
+}
+
+TypeDeclaration *TypeResolver::get_or_create_array_type(TypeDeclaration &type)
+{
+ map<TypeDeclaration *, TypeDeclaration *>::iterator i = array_types.find(&type);
+ if(i!=array_types.end())
+ return i->second;
+
+ BasicTypeDeclaration *array = new BasicTypeDeclaration;
+ array->source = BUILTIN_SOURCE;
+ array->name = type.name+"[]";
+ array->kind = BasicTypeDeclaration::ARRAY;
+ array->base = type.name;
+ array->base_type = &type;
+ stage->content.body.insert(type_insert_point, array);
+ array_types[&type] = array;
+ return array;
}
-TypeDeclaration *TypeResolver::resolve_type(const string &name)
+void TypeResolver::resolve_type(TypeDeclaration *&type, const string &name, bool array)
{
+ TypeDeclaration *resolved = 0;
map<string, TypeDeclaration *>::iterator i = stage->types.find(name);
if(i!=stage->types.end())
{
map<TypeDeclaration *, TypeDeclaration *>::iterator j = alias_map.find(i->second);
- return (j!=alias_map.end() ? j->second : i->second);
+ resolved = (j!=alias_map.end() ? j->second : i->second);
}
- else
- return 0;
+
+ if(resolved && array)
+ resolved = get_or_create_array_type(*resolved);
+
+ r_any_resolved |= (resolved!=type);
+ type=resolved;
}
void TypeResolver::visit(Block &block)
void TypeResolver::visit(BasicTypeDeclaration &type)
{
- type.base_type = resolve_type(type.base);
+ resolve_type(type.base_type, type.base, false);
if(type.kind==BasicTypeDeclaration::VECTOR && type.base_type)
if(BasicTypeDeclaration *basic_base = dynamic_cast<BasicTypeDeclaration *>(type.base_type))
void TypeResolver::visit(ImageTypeDeclaration &type)
{
- type.base_type = resolve_type(type.base);
+ resolve_type(type.base_type, type.base, false);
stage->types.insert(make_pair(type.name, &type));
}
void TypeResolver::visit(VariableDeclaration &var)
{
- TypeDeclaration *type = resolve_type(var.type);
- if(var.array && type)
- {
- map<TypeDeclaration *, TypeDeclaration *>::iterator i = array_types.find(type);
- if(i==array_types.end())
- {
- BasicTypeDeclaration *array = new BasicTypeDeclaration;
- array->source = BUILTIN_SOURCE;
- array->name = type->name+"[]";
- array->kind = BasicTypeDeclaration::ARRAY;
- array->base = type->name;
- array->base_type = type;
- stage->content.body.insert(type_insert_point, array);
- array->visit(*this);
- type = array;
- }
- else
- type = i->second;
- }
- var.type_declaration = type;
+ resolve_type(var.type_declaration, var.type, var.array);
}
void TypeResolver::visit(FunctionDeclaration &func)
{
- func.return_type_declaration = resolve_type(func.return_type);
+ resolve_type(func.return_type_declaration, func.return_type, false);
TraversingVisitor::visit(func);
}
VariableResolver::VariableResolver():
stage(0),
- r_members(0),
+ r_any_resolved(false),
record_target(false),
r_self_referencing(false),
r_assignment_target(0)
{ }
-void VariableResolver::apply(Stage &s)
+bool VariableResolver::apply(Stage &s)
{
stage = &s;
s.interface_blocks.clear();
+ r_any_resolved = false;
s.content.visit(*this);
+ return r_any_resolved;
}
void VariableResolver::enter(Block &block)
block.variables.clear();
}
+void VariableResolver::visit_and_replace(RefPtr<Expression> &expr)
+{
+ r_replacement_expr = 0;
+ expr->visit(*this);
+ if(r_replacement_expr)
+ expr = r_replacement_expr;
+ r_replacement_expr = 0;
+}
+
void VariableResolver::visit(VariableReference &var)
{
- var.declaration = 0;
- r_members = 0;
+ VariableDeclaration *declaration = 0;
+
/* Look for variable declarations in the block hierarchy first. Interface
blocks are always defined in the top level so we can't accidentally skip
one. */
- for(Block *block=current_block; (!var.declaration && block); block=block->parent)
+ for(Block *block=current_block; (!declaration && block); block=block->parent)
{
map<string, VariableDeclaration *>::iterator i = block->variables.find(var.name);
if(i!=block->variables.end())
- var.declaration = i->second;
+ declaration = i->second;
}
- if(!var.declaration)
+ if(!declaration)
{
const map<string, InterfaceBlock *> &blocks = stage->interface_blocks;
map<string, InterfaceBlock *>::const_iterator i = blocks.find("_"+var.name);
{
/* The name refers to an interface block with an instance name rather
than a variable. Prepare a new syntax tree node accordingly. */
- r_iface_ref = new InterfaceBlockReference;
- r_iface_ref->source = var.source;
- r_iface_ref->line = var.line;
- r_iface_ref->name = var.name;
- r_iface_ref->declaration = i->second;
- r_members = &i->second->members.variables;
+ InterfaceBlockReference *iface_ref = new InterfaceBlockReference;
+ iface_ref->source = var.source;
+ iface_ref->line = var.line;
+ iface_ref->name = var.name;
+ iface_ref->declaration = i->second;
+ r_replacement_expr = iface_ref;
}
else
{
// Look for the variable in anonymous interface blocks.
- for(i=blocks.begin(); (!var.declaration && i!=blocks.end()); ++i)
+ for(i=blocks.begin(); (!declaration && i!=blocks.end()); ++i)
if(i->second->instance_name.empty())
{
map<string, VariableDeclaration *>::iterator j = i->second->members.variables.find(var.name);
if(j!=i->second->members.variables.end())
- var.declaration = j->second;
+ declaration = j->second;
}
}
}
- if(var.declaration)
- if(StructDeclaration *strct = dynamic_cast<StructDeclaration *>(var.declaration->type_declaration))
- r_members = &strct->members.variables;
+ r_any_resolved |= (declaration!=var.declaration);
+ var.declaration = declaration;
if(record_target)
{
void VariableResolver::visit(InterfaceBlockReference &iface)
{
- iface.declaration = 0;
- for(Block *block=current_block; block; block=block->parent)
- {
- map<string, InterfaceBlock *>::iterator i = stage->interface_blocks.find("_"+iface.name);
- if(i!=stage->interface_blocks.end())
- {
- iface.declaration = i->second;
- r_members = &i->second->members.variables;
- break;
- }
- }
+ map<string, InterfaceBlock *>::iterator i = stage->interface_blocks.find("_"+iface.name);
+ InterfaceBlock *declaration = (i!=stage->interface_blocks.end() ? i->second : 0);
+ r_any_resolved |= (declaration!=iface.declaration);
+ iface.declaration = declaration;
}
void VariableResolver::visit(MemberAccess &memacc)
{
- r_members = 0;
- r_iface_ref = 0;
- memacc.left->visit(*this);
+ visit_and_replace(memacc.left);
- if(r_iface_ref)
- memacc.left = r_iface_ref;
- r_iface_ref = 0;
+ map<string, VariableDeclaration *> *members = 0;
+ if(StructDeclaration *strct = dynamic_cast<StructDeclaration *>(memacc.left->type))
+ members = &strct->members.variables;
+ else if(InterfaceBlockReference *iface_ref = dynamic_cast<InterfaceBlockReference *>(memacc.left.get()))
+ {
+ if(iface_ref->declaration)
+ members = &iface_ref->declaration->members.variables;
+ }
- memacc.declaration = 0;
- if(r_members)
+ VariableDeclaration *declaration = 0;
+ if(members)
{
- map<string, VariableDeclaration *>::iterator i = r_members->find(memacc.member);
- if(i!=r_members->end())
- {
- memacc.declaration = i->second;
- if(StructDeclaration *strct = dynamic_cast<StructDeclaration *>(i->second->type_declaration))
- r_members = &strct->members.variables;
- }
- else
- r_members = 0;
+ map<string, VariableDeclaration *>::iterator i = members->find(memacc.member);
+ if(i!=members->end())
+ declaration = i->second;
}
+
+ r_any_resolved |= (declaration!=memacc.declaration);
+ memacc.declaration = declaration;
}
void VariableResolver::visit(UnaryExpression &unary)
{
- TraversingVisitor::visit(unary);
- r_members = 0;
- r_iface_ref = 0;
+ visit_and_replace(unary.expression);
}
void VariableResolver::visit(BinaryExpression &binary)
/* The subscript expression is not a part of the primary assignment
target. */
SetFlag set(record_target, false);
- binary.right->visit(*this);
+ visit_and_replace(binary.right);
}
- r_members = 0;
- r_iface_ref = 0;
- binary.left->visit(*this);
- if(r_iface_ref)
- binary.left = r_iface_ref;
+ visit_and_replace(binary.left);
}
else
{
- TraversingVisitor::visit(binary);
- r_members = 0;
+ visit_and_replace(binary.left);
+ visit_and_replace(binary.right);
}
-
- r_iface_ref = 0;
}
void VariableResolver::visit(Assignment &assign)
{
SetFlag set(record_target);
r_assignment_target = 0;
- assign.left->visit(*this);
+ visit_and_replace(assign.left);
+ r_any_resolved |= (r_assignment_target!=assign.target_declaration);
assign.target_declaration = r_assignment_target;
}
r_self_referencing = false;
- assign.right->visit(*this);
+ visit_and_replace(assign.right);
assign.self_referencing = (r_self_referencing || assign.oper->token[0]!='=');
-
- r_members = 0;
- r_iface_ref = 0;
}
void VariableResolver::visit(FunctionCall &call)
{
- TraversingVisitor::visit(call);
- r_members = 0;
- r_iface_ref = 0;
+ for(NodeArray<Expression>::iterator i=call.arguments.begin(); i!=call.arguments.end(); ++i)
+ visit_and_replace(*i);
}
void VariableResolver::visit(VariableDeclaration &var)
}
-void FunctionResolver::apply(Stage &s)
+ExpressionResolver::ExpressionResolver():
+ stage(0),
+ r_any_resolved(false)
+{ }
+
+bool ExpressionResolver::apply(Stage &s)
+{
+ stage = &s;
+ r_any_resolved = false;
+ s.content.visit(*this);
+ return r_any_resolved;
+}
+
+bool ExpressionResolver::is_scalar(BasicTypeDeclaration &type)
+{
+ return (type.kind==BasicTypeDeclaration::INT || type.kind==BasicTypeDeclaration::FLOAT);
+}
+
+bool ExpressionResolver::is_vector_or_matrix(BasicTypeDeclaration &type)
+{
+ return (type.kind==BasicTypeDeclaration::VECTOR || type.kind==BasicTypeDeclaration::MATRIX);
+}
+
+BasicTypeDeclaration *ExpressionResolver::get_element_type(BasicTypeDeclaration &type)
+{
+ if(is_vector_or_matrix(type) || type.kind==BasicTypeDeclaration::ARRAY)
+ {
+ BasicTypeDeclaration *basic_base = dynamic_cast<BasicTypeDeclaration *>(type.base_type);
+ return (basic_base ? get_element_type(*basic_base) : 0);
+ }
+ else
+ return &type;
+}
+
+bool ExpressionResolver::can_convert(BasicTypeDeclaration &from, BasicTypeDeclaration &to)
+{
+ if(from.kind==BasicTypeDeclaration::INT && to.kind==BasicTypeDeclaration::FLOAT)
+ return from.size<=to.size;
+ else if(from.kind!=to.kind)
+ return false;
+ else if((from.kind==BasicTypeDeclaration::VECTOR || from.kind==BasicTypeDeclaration::MATRIX) && from.size==to.size)
+ {
+ BasicTypeDeclaration *from_base = dynamic_cast<BasicTypeDeclaration *>(from.base_type);
+ BasicTypeDeclaration *to_base = dynamic_cast<BasicTypeDeclaration *>(to.base_type);
+ return (from_base && to_base && can_convert(*from_base, *to_base));
+ }
+ else
+ return false;
+}
+
+ExpressionResolver::Compatibility ExpressionResolver::get_compatibility(BasicTypeDeclaration &left, BasicTypeDeclaration &right)
+{
+ if(&left==&right)
+ return SAME_TYPE;
+ else if(can_convert(left, right))
+ return LEFT_CONVERTIBLE;
+ else if(can_convert(right, left))
+ return RIGHT_CONVERTIBLE;
+ else
+ return NOT_COMPATIBLE;
+}
+
+BasicTypeDeclaration *ExpressionResolver::find_type(BasicTypeDeclaration::Kind kind, unsigned size)
+{
+ for(vector<BasicTypeDeclaration *>::const_iterator i=basic_types.begin(); i!=basic_types.end(); ++i)
+ if((*i)->kind==kind && (*i)->size==size)
+ return *i;
+ return 0;
+}
+
+BasicTypeDeclaration *ExpressionResolver::find_type(BasicTypeDeclaration &elem_type, BasicTypeDeclaration::Kind kind, unsigned size)
+{
+ for(vector<BasicTypeDeclaration *>::const_iterator i=basic_types.begin(); i!=basic_types.end(); ++i)
+ if(get_element_type(**i)==&elem_type && (*i)->kind==kind && (*i)->size==size)
+ return *i;
+ return 0;
+}
+
+void ExpressionResolver::convert_to(RefPtr<Expression> &expr, BasicTypeDeclaration &type)
+{
+ RefPtr<FunctionCall> call = new FunctionCall;
+ call->name = type.name;
+ call->constructor = true;
+ call->arguments.push_back(0);
+ call->arguments.back() = expr;
+ call->type = &type;
+ expr = call;
+}
+
+bool ExpressionResolver::convert_to_element(RefPtr<Expression> &expr, BasicTypeDeclaration &elem_type)
+{
+ if(BasicTypeDeclaration *expr_type = dynamic_cast<BasicTypeDeclaration *>(expr->type))
+ {
+ BasicTypeDeclaration *to_type = &elem_type;
+ if(is_vector_or_matrix(*expr_type))
+ to_type = find_type(elem_type, expr_type->kind, expr_type->size);
+ if(to_type)
+ {
+ convert_to(expr, *to_type);
+ return true;
+ }
+ }
+
+ return false;
+}
+
+void ExpressionResolver::resolve(Expression &expr, TypeDeclaration *type, bool lvalue)
+{
+ r_any_resolved |= (type!=expr.type || lvalue!=expr.lvalue);
+ expr.type = type;
+ expr.lvalue = lvalue;
+}
+
+void ExpressionResolver::visit(Literal &literal)
+{
+ if(literal.value.check_type<bool>())
+ resolve(literal, find_type(BasicTypeDeclaration::BOOL, 1), false);
+ else if(literal.value.check_type<int>())
+ resolve(literal, find_type(BasicTypeDeclaration::INT, 32), false);
+ else if(literal.value.check_type<float>())
+ resolve(literal, find_type(BasicTypeDeclaration::FLOAT, 32), false);
+}
+
+void ExpressionResolver::visit(ParenthesizedExpression &parexpr)
+{
+ TraversingVisitor::visit(parexpr);
+ resolve(parexpr, parexpr.expression->type, parexpr.expression->lvalue);
+}
+
+void ExpressionResolver::visit(VariableReference &var)
+{
+ if(var.declaration)
+ resolve(var, var.declaration->type_declaration, true);
+}
+
+void ExpressionResolver::visit(InterfaceBlockReference &iface)
+{
+ resolve(iface, 0, true);
+}
+
+void ExpressionResolver::visit(MemberAccess &memacc)
+{
+ TraversingVisitor::visit(memacc);
+
+ if(memacc.declaration)
+ resolve(memacc, memacc.declaration->type_declaration, memacc.left->lvalue);
+}
+
+void ExpressionResolver::visit(UnaryExpression &unary)
+{
+ TraversingVisitor::visit(unary);
+
+ BasicTypeDeclaration *basic = dynamic_cast<BasicTypeDeclaration *>(unary.expression->type);
+ if(!basic)
+ return;
+
+ char oper = unary.oper->token[0];
+ if(oper=='!')
+ {
+ if(basic->kind!=BasicTypeDeclaration::BOOL)
+ return;
+ }
+ else if(oper=='~')
+ {
+ if(basic->kind!=BasicTypeDeclaration::INT)
+ return;
+ }
+ else if(oper=='+' || oper=='-')
+ {
+ BasicTypeDeclaration *elem = get_element_type(*basic);
+ if(!elem || !is_scalar(*elem))
+ return;
+ }
+ resolve(unary, basic, unary.expression->lvalue);
+}
+
+void ExpressionResolver::visit(BinaryExpression &binary, bool assign)
+{
+ /* Binary operators are only defined for basic types (not for image or
+ structure types). */
+ BasicTypeDeclaration *basic_left = dynamic_cast<BasicTypeDeclaration *>(binary.left->type);
+ BasicTypeDeclaration *basic_right = dynamic_cast<BasicTypeDeclaration *>(binary.right->type);
+ if(!basic_left || !basic_right)
+ return;
+
+ char oper = binary.oper->token[0];
+ if(oper=='[')
+ {
+ /* Subscripting operates on vectors, matrices and arrays, and the right
+ operand must be an integer. */
+ if((!is_vector_or_matrix(*basic_left) && basic_left->kind!=BasicTypeDeclaration::ARRAY) || basic_right->kind!=BasicTypeDeclaration::INT)
+ return;
+
+ resolve(binary, basic_left->base_type, binary.left->lvalue);
+ return;
+ }
+ else if(basic_left->kind==BasicTypeDeclaration::ARRAY || basic_right->kind==BasicTypeDeclaration::ARRAY)
+ // No other binary operator can be used with arrays.
+ return;
+
+ BasicTypeDeclaration *elem_left = get_element_type(*basic_left);
+ BasicTypeDeclaration *elem_right = get_element_type(*basic_right);
+ if(!elem_left || !elem_right)
+ return;
+
+ Compatibility compat = get_compatibility(*basic_left, *basic_right);
+ Compatibility elem_compat = get_compatibility(*elem_left, *elem_right);
+ if(elem_compat==NOT_COMPATIBLE)
+ return;
+ if(assign && (compat==LEFT_CONVERTIBLE || elem_compat==LEFT_CONVERTIBLE))
+ return;
+
+ TypeDeclaration *type = 0;
+ char oper2 = binary.oper->token[1];
+ if((oper=='<' && oper2!='<') || (oper=='>' && oper2!='>'))
+ {
+ /* Relational operators compare two scalar integer or floating-point
+ values. */
+ if(!is_scalar(*elem_left) || !is_scalar(*elem_right) || compat==NOT_COMPATIBLE)
+ return;
+
+ type = find_type(BasicTypeDeclaration::BOOL, 1);
+ }
+ else if((oper=='=' || oper=='!') && oper2=='=')
+ {
+ // Equality comparison can be done on any compatible types.
+ if(compat==NOT_COMPATIBLE)
+ return;
+
+ type = find_type(BasicTypeDeclaration::BOOL, 1);
+ }
+ else if(oper2=='&' || oper2=='|' || oper2=='^')
+ {
+ // Logical operators can only be applied to booleans.
+ if(basic_left->kind!=BasicTypeDeclaration::BOOL || basic_right->kind!=BasicTypeDeclaration::BOOL)
+ return;
+
+ type = basic_left;
+ }
+ else if((oper=='&' || oper=='|' || oper=='^' || oper=='%') && !oper2)
+ {
+ // Bitwise operators and modulo can only be applied to integers.
+ if(basic_left->kind!=BasicTypeDeclaration::INT || basic_right->kind!=BasicTypeDeclaration::INT)
+ return;
+
+ type = (compat==LEFT_CONVERTIBLE ? basic_right : basic_left);
+ }
+ else if((oper=='<' || oper=='>') && oper2==oper)
+ {
+ // Shifts apply to integer scalars and vectors, with some restrictions.
+ if(elem_left->kind!=BasicTypeDeclaration::INT || elem_right->kind!=BasicTypeDeclaration::INT)
+ return;
+ unsigned left_size = (basic_left->kind==BasicTypeDeclaration::INT ? 1 : basic_left->kind==BasicTypeDeclaration::VECTOR ? basic_left->size : 0);
+ unsigned right_size = (basic_right->kind==BasicTypeDeclaration::INT ? 1 : basic_right->kind==BasicTypeDeclaration::VECTOR ? basic_right->size : 0);
+ if(!left_size || (left_size==1 && right_size!=1) || (left_size>1 && right_size!=1 && right_size!=left_size))
+ return;
+
+ type = basic_left;
+ // Don't perform conversion even if the operands are of different sizes.
+ compat = SAME_TYPE;
+ }
+ else if(oper=='+' || oper=='-' || oper=='*' || oper=='/')
+ {
+ // Arithmetic operators require scalar elements.
+ if(!is_scalar(*elem_left) || !is_scalar(*elem_right))
+ return;
+
+ if(oper=='*' && is_vector_or_matrix(*basic_left) && is_vector_or_matrix(*basic_right) &&
+ (basic_left->kind==BasicTypeDeclaration::MATRIX || basic_right->kind==BasicTypeDeclaration::MATRIX))
+ {
+ /* Multiplication has special rules when at least one operand is a
+ matrix and the other is a vector or a matrix. */
+ unsigned left_columns = basic_left->size&0xFFFF;
+ unsigned right_rows = basic_right->size;
+ if(basic_right->kind==BasicTypeDeclaration::MATRIX)
+ right_rows >>= 16;
+ if(left_columns!=right_rows)
+ return;
+
+ BasicTypeDeclaration *elem_result = (elem_compat==LEFT_CONVERTIBLE ? elem_right : elem_left);
+
+ if(basic_left->kind==BasicTypeDeclaration::VECTOR)
+ type = find_type(*elem_result, BasicTypeDeclaration::VECTOR, basic_right->size&0xFFFF);
+ else if(basic_right->kind==BasicTypeDeclaration::VECTOR)
+ type = find_type(*elem_result, BasicTypeDeclaration::VECTOR, basic_left->size>>16);
+ else
+ type = find_type(*elem_result, BasicTypeDeclaration::MATRIX, (basic_left->size&0xFFFF0000)|(basic_right->size&0xFFFF));
+ }
+ else if(compat==NOT_COMPATIBLE)
+ {
+ // Arithmetic between scalars and matrices or vectors is supported.
+ if(is_scalar(*basic_left) && is_vector_or_matrix(*basic_right))
+ type = (elem_compat==RIGHT_CONVERTIBLE ? find_type(*elem_left, basic_right->kind, basic_right->size) : basic_right);
+ else if(is_vector_or_matrix(*basic_left) && is_scalar(*basic_right))
+ type = (elem_compat==LEFT_CONVERTIBLE ? find_type(*elem_right, basic_left->kind, basic_left->size) : basic_left);
+ else
+ return;
+ }
+ else if(compat==LEFT_CONVERTIBLE)
+ type = basic_right;
+ else
+ type = basic_left;
+ }
+ else
+ return;
+
+ if(assign && type!=basic_left)
+ return;
+
+ bool converted = true;
+ if(compat==LEFT_CONVERTIBLE)
+ convert_to(binary.left, *basic_right);
+ else if(compat==RIGHT_CONVERTIBLE)
+ convert_to(binary.right, *basic_left);
+ else if(elem_compat==LEFT_CONVERTIBLE)
+ converted = convert_to_element(binary.left, *elem_right);
+ else if(elem_compat==RIGHT_CONVERTIBLE)
+ converted = convert_to_element(binary.right, *elem_left);
+
+ if(!converted)
+ type = 0;
+
+ resolve(binary, type, assign);
+}
+
+void ExpressionResolver::visit(BinaryExpression &binary)
+{
+ TraversingVisitor::visit(binary);
+ visit(binary, false);
+}
+
+void ExpressionResolver::visit(Assignment &assign)
+{
+ TraversingVisitor::visit(assign);
+
+ if(assign.oper->token[0]!='=')
+ return visit(assign, true);
+ else if(assign.left->type!=assign.right->type)
+ {
+ BasicTypeDeclaration *basic_left = dynamic_cast<BasicTypeDeclaration *>(assign.left->type);
+ BasicTypeDeclaration *basic_right = dynamic_cast<BasicTypeDeclaration *>(assign.right->type);
+ if(!basic_left || !basic_right)
+ return;
+
+ Compatibility compat = get_compatibility(*basic_left, *basic_right);
+ if(compat==RIGHT_CONVERTIBLE)
+ convert_to(assign.right, *basic_left);
+ else if(compat!=SAME_TYPE)
+ return;
+ }
+
+ resolve(assign, assign.left->type, true);
+}
+
+void ExpressionResolver::visit(FunctionCall &call)
+{
+ TraversingVisitor::visit(call);
+
+ TypeDeclaration *type = 0;
+ if(call.declaration)
+ type = call.declaration->return_type_declaration;
+ else if(call.constructor)
+ {
+ map<string, TypeDeclaration *>::const_iterator i=stage->types.find(call.name);
+ type = (i!=stage->types.end() ? i->second : 0);
+ }
+ resolve(call, type, false);
+}
+
+void ExpressionResolver::visit(BasicTypeDeclaration &type)
+{
+ basic_types.push_back(&type);
+}
+
+void ExpressionResolver::visit(VariableDeclaration &var)
+{
+ TraversingVisitor::visit(var);
+ if(!var.init_expression)
+ return;
+
+ BasicTypeDeclaration *var_basic = dynamic_cast<BasicTypeDeclaration *>(var.type_declaration);
+ BasicTypeDeclaration *init_basic = dynamic_cast<BasicTypeDeclaration *>(var.init_expression->type);
+ if(!var_basic || !init_basic)
+ return;
+
+ Compatibility compat = get_compatibility(*var_basic, *init_basic);
+ if(compat==RIGHT_CONVERTIBLE)
+ convert_to(var.init_expression, *var_basic);
+}
+
+
+bool FunctionResolver::apply(Stage &s)
{
stage = &s;
s.functions.clear();
+ r_any_resolved = false;
s.content.visit(*this);
+ return r_any_resolved;
}
void FunctionResolver::visit(FunctionCall &call)