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44ea82f8452876c4890884506111e243b8b2a541
Odin/src/check_type.cpp
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gingerBill 44ea82f845 Clean up usage of using throughout core and vendor
2023-07-31 11:46:40 +01:00

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gb_internal ParameterValue handle_parameter_value(CheckerContext *ctx, Type *in_type, Type **out_type_, Ast *expr, bool allow_caller_location);
gb_internal void populate_using_array_index(CheckerContext *ctx, Ast *node, AstField *field, Type *t, String name, i32 idx) {
t = base_type(t);
GB_ASSERT(t->kind == Type_Array);
Entity *e = scope_lookup_current(ctx->scope, name);
if (e != nullptr) {
gbString str = nullptr;
defer (gb_string_free(str));
if (node != nullptr) {
str = expr_to_string(node);
}
if (str != nullptr) {
error(e->token, "'%.*s' is already declared in '%s'", LIT(name), str);
} else {
error(e->token, "'%.*s' is already declared", LIT(name));
}
} else {
Token tok = make_token_ident(name);
if (field->names.count > 0) {
tok.pos = ast_token(field->names[0]).pos;
} else {
tok.pos = ast_token(field->type).pos;
}
Entity *f = alloc_entity_array_elem(nullptr, tok, t->Array.elem, idx);
add_entity(ctx, ctx->scope, nullptr, f);
}
}
gb_internal void populate_using_entity_scope(CheckerContext *ctx, Ast *node, AstField *field, Type *t) {
if (t == nullptr) {
return;
}
t = base_type(type_deref(t));
gbString str = nullptr;
defer (gb_string_free(str));
if (node != nullptr) {
str = expr_to_string(node);
}
if (t->kind == Type_Struct) {
for (Entity *f : t->Struct.fields) {
GB_ASSERT(f->kind == Entity_Variable);
String name = f->token.string;
Entity *e = scope_lookup_current(ctx->scope, name);
if (e != nullptr && name != "_") {
// TODO(bill): Better type error
if (str != nullptr) {
error(e->token, "'%.*s' is already declared in '%s'", LIT(name), str);
} else {
error(e->token, "'%.*s' is already declared", LIT(name));
}
} else {
add_entity(ctx, ctx->scope, nullptr, f);
if (f->flags & EntityFlag_Using) {
populate_using_entity_scope(ctx, node, field, f->type);
}
}
}
} else if (t->kind == Type_Array && t->Array.count <= 4) {
switch (t->Array.count) {
case 4:
populate_using_array_index(ctx, node, field, t, str_lit("w"), 3);
populate_using_array_index(ctx, node, field, t, str_lit("a"), 3);
/*fallthrough*/
case 3:
populate_using_array_index(ctx, node, field, t, str_lit("z"), 2);
populate_using_array_index(ctx, node, field, t, str_lit("b"), 2);
/*fallthrough*/
case 2:
populate_using_array_index(ctx, node, field, t, str_lit("y"), 1);
populate_using_array_index(ctx, node, field, t, str_lit("g"), 1);
/*fallthrough*/
case 1:
populate_using_array_index(ctx, node, field, t, str_lit("x"), 0);
populate_using_array_index(ctx, node, field, t, str_lit("r"), 0);
/*fallthrough*/
default:
break;
}
}
}
gb_internal bool does_field_type_allow_using(Type *t) {
t = base_type(t);
if (is_type_struct(t)) {
return true;
} else if (is_type_array(t)) {
return t->Array.count <= 4;
}
return false;
}
gb_internal void check_struct_fields(CheckerContext *ctx, Ast *node, Slice<Entity *> *fields, String **tags, Slice<Ast *> const &params,
isize init_field_capacity, Type *struct_type, String context) {
auto fields_array = array_make<Entity *>(heap_allocator(), 0, init_field_capacity);
auto tags_array = array_make<String>(heap_allocator(), 0, init_field_capacity);
GB_ASSERT(node->kind == Ast_StructType);
GB_ASSERT(struct_type->kind == Type_Struct);
isize variable_count = 0;
for_array(i, params) {
Ast *field = params[i];
if (ast_node_expect(field, Ast_Field)) {
ast_node(f, Field, field);
variable_count += gb_max(f->names.count, 1);
}
}
i32 field_src_index = 0;
i32 field_group_index = -1;
for_array(i, params) {
Ast *param = params[i];
if (param->kind != Ast_Field) {
continue;
}
field_group_index += 1;
ast_node(p, Field, param);
Ast *type_expr = p->type;
Type *type = nullptr;
CommentGroup *docs = p->docs;
CommentGroup *comment = p->comment;
if (type_expr != nullptr) {
type = check_type_expr(ctx, type_expr, nullptr);
if (is_type_polymorphic(type)) {
struct_type->Struct.is_polymorphic = true;
type = nullptr;
}
}
if (type == nullptr) {
error(params[i], "Invalid parameter type");
type = t_invalid;
}
if (is_type_untyped(type)) {
if (is_type_untyped_uninit(type)) {
error(params[i], "Cannot determine parameter type from ---");
} else {
error(params[i], "Cannot determine parameter type from a nil");
}
type = t_invalid;
}
bool is_using = (p->flags&FieldFlag_using) != 0;
bool is_subtype = (p->flags&FieldFlag_subtype) != 0;
for_array(j, p->names) {
Ast *name = p->names[j];
if (!ast_node_expect2(name, Ast_Ident, Ast_PolyType)) {
continue;
}
if (name->kind == Ast_PolyType) {
name = name->PolyType.type;
}
Token name_token = name->Ident.token;
Entity *field = alloc_entity_field(ctx->scope, name_token, type, is_using, field_src_index);
add_entity(ctx, ctx->scope, name, field);
field->Variable.field_group_index = field_group_index;
if (is_subtype) {
field->flags |= EntityFlag_Subtype;
}
if (j == 0) {
field->Variable.docs = docs;
}
if (j+1 == p->names.count) {
field->Variable.comment = comment;
}
array_add(&fields_array, field);
String tag = p->tag.string;
if (tag.len != 0 && !unquote_string(permanent_allocator(), &tag, 0, tag.text[0] == '`')) {
error(p->tag, "Invalid string literal");
tag = {};
}
array_add(&tags_array, tag);
field_src_index += 1;
}
if (is_using && p->names.count > 0) {
Type *first_type = fields_array[fields_array.count-1]->type;
Type *t = base_type(type_deref(first_type));
if (!does_field_type_allow_using(t) &&
p->names.count >= 1 &&
p->names[0]->kind == Ast_Ident) {
Token name_token = p->names[0]->Ident.token;
gbString type_str = type_to_string(first_type);
error(name_token, "'using' cannot be applied to the field '%.*s' of type '%s'", LIT(name_token.string), type_str);
gb_string_free(type_str);
continue;
}
populate_using_entity_scope(ctx, node, p, type);
}
if (is_subtype && p->names.count > 0) {
Type *first_type = fields_array[fields_array.count-1]->type;
Type *t = base_type(type_deref(first_type));
if (!does_field_type_allow_using(t) &&
p->names.count >= 1 &&
p->names[0]->kind == Ast_Ident) {
Token name_token = p->names[0]->Ident.token;
gbString type_str = type_to_string(first_type);
error(name_token, "'subtype' cannot be applied to the field '%.*s' of type '%s'", LIT(name_token.string), type_str);
gb_string_free(type_str);
}
}
}
*fields = slice_from_array(fields_array);
*tags = tags_array.data;
}
gb_internal bool check_custom_align(CheckerContext *ctx, Ast *node, i64 *align_) {
GB_ASSERT(align_ != nullptr);
Operand o = {};
check_expr(ctx, &o, node);
if (o.mode != Addressing_Constant) {
if (o.mode != Addressing_Invalid) {
error(node, "#align must be a constant");
}
return false;
}
Type *type = base_type(o.type);
if (is_type_untyped(type) || is_type_integer(type)) {
if (o.value.kind == ExactValue_Integer) {
BigInt v = o.value.value_integer;
if (v.used > 1) {
gbAllocator a = heap_allocator();
String str = big_int_to_string(a, &v);
error(node, "#align too large, %.*s", LIT(str));
gb_free(a, str.text);
return false;
}
i64 align = big_int_to_i64(&v);
if (align < 1 || !gb_is_power_of_two(cast(isize)align)) {
error(node, "#align must be a power of 2, got %lld", align);
return false;
}
*align_ = align;
return true;
}
}
error(node, "#align must be an integer");
return false;
}
gb_internal Entity *find_polymorphic_record_entity(CheckerContext *ctx, Type *original_type, isize param_count, Array<Operand> const &ordered_operands, bool *failure) {
rw_mutex_shared_lock(&ctx->info->gen_types_mutex); // @@global
auto *found_gen_types = map_get(&ctx->info->gen_types, original_type);
if (found_gen_types == nullptr) {
rw_mutex_shared_unlock(&ctx->info->gen_types_mutex); // @@global
return nullptr;
}
rw_mutex_shared_lock(&found_gen_types->mutex); // @@local
defer (rw_mutex_shared_unlock(&found_gen_types->mutex)); // @@local
rw_mutex_shared_unlock(&ctx->info->gen_types_mutex); // @@global
for (Entity *e : found_gen_types->types) {
Type *t = base_type(e->type);
TypeTuple *tuple = nullptr;
switch (t->kind) {
case Type_Struct:
if (t->Struct.polymorphic_params) {
tuple = &t->Struct.polymorphic_params->Tuple;
}
break;
case Type_Union:
if (t->Union.polymorphic_params) {
tuple = &t->Union.polymorphic_params->Tuple;
}
break;
}
GB_ASSERT_MSG(tuple != nullptr, "%s :: %s", type_to_string(e->type), type_to_string(t));
GB_ASSERT(param_count == tuple->variables.count);
bool skip = false;
for (isize j = 0; j < param_count; j++) {
Entity *p = tuple->variables[j];
Operand o = {};
if (j < ordered_operands.count) {
o = ordered_operands[j];
}
if (o.expr == nullptr) {
continue;
}
Entity *oe = entity_of_node(o.expr);
if (p == oe) {
// NOTE(bill): This is the same type, make sure that it will be be same thing and use that
// Saves on a lot of checking too below
continue;
}
if (p->kind == Entity_TypeName) {
if (is_type_polymorphic(o.type)) {
// NOTE(bill): Do not add polymorphic version to the gen_types
skip = true;
break;
}
if (!are_types_identical(o.type, p->type)) {
skip = true;
break;
}
} else if (p->kind == Entity_Constant) {
if (!compare_exact_values(Token_CmpEq, o.value, p->Constant.value)) {
skip = true;
break;
}
if (!are_types_identical(o.type, p->type)) {
skip = true;
break;
}
} else {
GB_PANIC("Unknown entity kind");
}
}
if (!skip) {
return e;
}
}
return nullptr;
}
gb_internal void add_polymorphic_record_entity(CheckerContext *ctx, Ast *node, Type *named_type, Type *original_type) {
GB_ASSERT(is_type_named(named_type));
gbAllocator a = heap_allocator();
Scope *s = ctx->scope->parent;
Entity *e = nullptr;
{
Token token = ast_token(node);
token.kind = Token_String;
token.string = named_type->Named.name;
Ast *node = ast_ident(nullptr, token);
e = alloc_entity_type_name(s, token, named_type);
e->state = EntityState_Resolved;
e->file = ctx->file;
e->pkg = ctx->pkg;
add_entity_use(ctx, node, e);
}
named_type->Named.type_name = e;
GB_ASSERT(original_type->kind == Type_Named);
e->TypeName.objc_class_name = original_type->Named.type_name->TypeName.objc_class_name;
// TODO(bill): Is this even correct? Or should the metadata be copied?
e->TypeName.objc_metadata = original_type->Named.type_name->TypeName.objc_metadata;
rw_mutex_lock(&ctx->info->gen_types_mutex);
auto *found_gen_types = map_get(&ctx->info->gen_types, original_type);
if (found_gen_types) {
rw_mutex_lock(&found_gen_types->mutex);
array_add(&found_gen_types->types, e);
rw_mutex_unlock(&found_gen_types->mutex);
} else {
GenTypesData gen_types = {};
gen_types.types = array_make<Entity *>(heap_allocator());
array_add(&gen_types.types, e);
map_set(&ctx->info->gen_types, original_type, gen_types);
}
rw_mutex_unlock(&ctx->info->gen_types_mutex);
}
bool check_constant_parameter_value(Type *type, Ast *expr) {
if (!is_type_constant_type(type)) {
gbString str = type_to_string(type);
defer (gb_string_free(str));
error(expr, "A parameter must be a valid constant type, got %s", str);
return true;
}
return false;
}
gb_internal Type *check_record_polymorphic_params(CheckerContext *ctx, Ast *polymorphic_params,
bool *is_polymorphic_,
Ast *node, Array<Operand> *poly_operands) {
Type *polymorphic_params_type = nullptr;
bool can_check_fields = true;
GB_ASSERT(is_polymorphic_ != nullptr);
if (polymorphic_params == nullptr) {
if (!*is_polymorphic_) {
*is_polymorphic_ = polymorphic_params != nullptr && poly_operands == nullptr;
}
return polymorphic_params_type;
}
ast_node(field_list, FieldList, polymorphic_params);
Slice<Ast *> params = field_list->list;
if (params.count != 0) {
isize variable_count = 0;
for_array(i, params) {
Ast *field = params[i];
if (ast_node_expect(field, Ast_Field)) {
ast_node(f, Field, field);
variable_count += gb_max(f->names.count, 1);
}
}
auto entities = array_make<Entity *>(permanent_allocator(), 0, variable_count);
for_array(i, params) {
Ast *param = params[i];
if (param->kind != Ast_Field) {
continue;
}
ast_node(p, Field, param);
Ast *type_expr = p->type;
Ast *default_value = unparen_expr(p->default_value);
Type *type = nullptr;
bool is_type_param = false;
bool is_type_polymorphic_type = false;
if (type_expr == nullptr && default_value == nullptr) {
error(param, "Expected a type for this parameter");
continue;
}
if (type_expr != nullptr) {
if (type_expr->kind == Ast_Ellipsis) {
type_expr = type_expr->Ellipsis.expr;
error(param, "A polymorphic parameter cannot be variadic");
}
if (type_expr->kind == Ast_TypeidType) {
is_type_param = true;
Type *specialization = nullptr;
if (type_expr->TypeidType.specialization != nullptr) {
Ast *s = type_expr->TypeidType.specialization;
specialization = check_type(ctx, s);
}
type = alloc_type_generic(ctx->scope, 0, str_lit(""), specialization);
} else {
type = check_type(ctx, type_expr);
if (is_type_polymorphic(type)) {
is_type_polymorphic_type = true;
}
}
}
ParameterValue param_value = {};
if (default_value != nullptr) {
Type *out_type = nullptr;
param_value = handle_parameter_value(ctx, type, &out_type, default_value, false);
if (type == nullptr && out_type != nullptr) {
type = out_type;
}
if (param_value.kind != ParameterValue_Constant && param_value.kind != ParameterValue_Nil) {
error(default_value, "Invalid parameter value");
param_value = {};
}
}
if (type == nullptr) {
error(params[i], "Invalid parameter type");
type = t_invalid;
}
if (is_type_untyped(type)) {
if (is_type_untyped_uninit(type)) {
error(params[i], "Cannot determine parameter type from ---");
} else {
error(params[i], "Cannot determine parameter type from a nil");
}
type = t_invalid;
}
if (is_type_polymorphic_type) {
gbString str = type_to_string(type);
error(params[i], "Parameter types cannot be polymorphic, got %s", str);
gb_string_free(str);
type = t_invalid;
}
if (!is_type_param && check_constant_parameter_value(type, params[i])) {
// failed
}
Scope *scope = ctx->scope;
for_array(j, p->names) {
Ast *name = p->names[j];
if (!ast_node_expect2(name, Ast_Ident, Ast_PolyType)) {
continue;
}
if (name->kind == Ast_PolyType) {
name = name->PolyType.type;
}
Entity *e = nullptr;
Token token = name->Ident.token;
if (poly_operands != nullptr) {
Operand operand = {};
operand.type = t_invalid;
if (entities.count < poly_operands->count) {
operand = (*poly_operands)[entities.count];
} else if (param_value.kind != ParameterValue_Invalid) {
operand.mode = Addressing_Constant;
operand.value = param_value.value;
}
if (is_type_param) {
if (is_type_polymorphic(base_type(operand.type))) {
*is_polymorphic_ = true;
can_check_fields = false;
}
e = alloc_entity_type_name(scope, token, operand.type);
e->TypeName.is_type_alias = true;
e->flags |= EntityFlag_PolyConst;
} else {
if (is_type_polymorphic(base_type(operand.type))) {
*is_polymorphic_ = true;
can_check_fields = false;
}
if (e == nullptr) {
e = alloc_entity_constant(scope, token, operand.type, operand.value);
e->Constant.param_value = param_value;
}
}
} else {
if (is_type_param) {
e = alloc_entity_type_name(scope, token, type);
e->TypeName.is_type_alias = true;
e->flags |= EntityFlag_PolyConst;
} else {
e = alloc_entity_constant(scope, token, type, param_value.value);
e->Constant.param_value = param_value;
}
}
e->state = EntityState_Resolved;
add_entity(ctx, scope, name, e);
array_add(&entities, e);
}
}
if (entities.count > 0) {
Type *tuple = alloc_type_tuple();
tuple->Tuple.variables = slice_from_array(entities);
polymorphic_params_type = tuple;
}
}
if (!*is_polymorphic_) {
*is_polymorphic_ = polymorphic_params != nullptr && poly_operands == nullptr;
}
return polymorphic_params_type;
}
gb_internal bool check_record_poly_operand_specialization(CheckerContext *ctx, Type *record_type, Array<Operand> *poly_operands, bool *is_polymorphic_) {
if (poly_operands == nullptr) {
return false;
}
for (isize i = 0; i < poly_operands->count; i++) {
Operand o = (*poly_operands)[i];
if (is_type_polymorphic(o.type)) {
return false;
}
if (record_type == o.type) {
// NOTE(bill): Cycle
return false;
}
if (o.mode == Addressing_Type) {
// NOTE(bill): ANNOYING EDGE CASE FOR `where` clauses
// TODO(bill, 2021-03-27): Is this even a valid HACK?!
Entity *entity = entity_of_node(o.expr);
if (entity != nullptr &&
entity->kind == Entity_TypeName &&
entity->type == t_typeid) {
*is_polymorphic_ = true;
return false;
}
}
}
return true;
}
gb_internal void check_struct_type(CheckerContext *ctx, Type *struct_type, Ast *node, Array<Operand> *poly_operands, Type *named_type, Type *original_type_for_poly) {
GB_ASSERT(is_type_struct(struct_type));
ast_node(st, StructType, node);
String context = str_lit("struct");
isize min_field_count = 0;
for_array(field_index, st->fields) {
Ast *field = st->fields[field_index];
switch (field->kind) {
case_ast_node(f, ValueDecl, field);
min_field_count += f->names.count;
case_end;
case_ast_node(f, Field, field);
min_field_count += f->names.count;
case_end;
}
}
scope_reserve(ctx->scope, min_field_count);
if (st->is_raw_union && min_field_count > 1) {
struct_type->Struct.is_raw_union = true;
context = str_lit("struct #raw_union");
}
struct_type->Struct.scope = ctx->scope;
struct_type->Struct.is_packed = st->is_packed;
struct_type->Struct.is_no_copy = st->is_no_copy;
struct_type->Struct.polymorphic_params = check_record_polymorphic_params(
ctx, st->polymorphic_params,
&struct_type->Struct.is_polymorphic,
node, poly_operands
);
struct_type->Struct.is_poly_specialized = check_record_poly_operand_specialization(ctx, struct_type, poly_operands, &struct_type->Struct.is_polymorphic);
if (original_type_for_poly) {
GB_ASSERT(named_type != nullptr);
add_polymorphic_record_entity(ctx, node, named_type, original_type_for_poly);
}
if (!struct_type->Struct.is_polymorphic) {
if (st->where_clauses.count > 0 && st->polymorphic_params == nullptr) {
error(st->where_clauses[0], "'where' clauses can only be used on structures with polymorphic parameters");
} else {
bool where_clause_ok = evaluate_where_clauses(ctx, node, ctx->scope, &st->where_clauses, true);
gb_unused(where_clause_ok);
}
check_struct_fields(ctx, node, &struct_type->Struct.fields, &struct_type->Struct.tags, st->fields, min_field_count, struct_type, context);
}
if (st->align != nullptr) {
if (st->is_packed) {
syntax_error(st->align, "'#align' cannot be applied with '#packed'");
return;
}
i64 custom_align = 1;
if (check_custom_align(ctx, st->align, &custom_align)) {
struct_type->Struct.custom_align = custom_align;
}
}
}
gb_internal void check_union_type(CheckerContext *ctx, Type *union_type, Ast *node, Array<Operand> *poly_operands, Type *named_type, Type *original_type_for_poly) {
GB_ASSERT(is_type_union(union_type));
ast_node(ut, UnionType, node);
union_type->Union.scope = ctx->scope;
union_type->Union.polymorphic_params = check_record_polymorphic_params(
ctx, ut->polymorphic_params,
&union_type->Union.is_polymorphic,
node, poly_operands
);
union_type->Union.is_poly_specialized = check_record_poly_operand_specialization(ctx, union_type, poly_operands, &union_type->Union.is_polymorphic);
if (original_type_for_poly) {
GB_ASSERT(named_type != nullptr);
add_polymorphic_record_entity(ctx, node, named_type, original_type_for_poly);
}
if (!union_type->Union.is_polymorphic) {
if (ut->where_clauses.count > 0 && ut->polymorphic_params == nullptr) {
error(ut->where_clauses[0], "'where' clauses can only be used on unions with polymorphic parameters");
} else {
bool where_clause_ok = evaluate_where_clauses(ctx, node, ctx->scope, &ut->where_clauses, true);
gb_unused(where_clause_ok);
}
}
auto variants = array_make<Type *>(permanent_allocator(), 0, ut->variants.count);
for_array(i, ut->variants) {
Ast *node = ut->variants[i];
Type *t = check_type_expr(ctx, node, nullptr);
if (union_type->Union.is_polymorphic && poly_operands == nullptr) {
// NOTE(bill): don't add any variants if this is this is an unspecialized polymorphic record
continue;
}
if (t != nullptr && t != t_invalid) {
bool ok = true;
t = default_type(t);
if (is_type_untyped(t) || is_type_empty_union(t)) {
ok = false;
gbString str = type_to_string(t);
error(node, "Invalid variant type in union '%s'", str);
gb_string_free(str);
} else {
for_array(j, variants) {
if (are_types_identical(t, variants[j])) {
ok = false;
ERROR_BLOCK();
gbString str = type_to_string(t);
error(node, "Duplicate variant type '%s'", str);
if (j < ut->variants.count) {
error_line("\tPrevious found at %s\n", token_pos_to_string(ast_token(ut->variants[j]).pos));
}
gb_string_free(str);
break;
}
}
}
if (ok) {
array_add(&variants, t);
if (ut->kind == UnionType_shared_nil) {
if (!type_has_nil(t)) {
gbString s = type_to_string(t);
error(node, "Each variant of a union with #shared_nil must have a 'nil' value, got %s", s);
gb_string_free(s);
}
}
}
}
}
union_type->Union.variants = slice_from_array(variants);
union_type->Union.kind = ut->kind;
switch (ut->kind) {
case UnionType_no_nil:
if (union_type->Union.is_polymorphic && poly_operands == nullptr) {
GB_ASSERT(variants.count == 0);
if (ut->variants.count != 1) {
break;
}
}
if (variants.count < 2) {
error(ut->align, "A union with #no_nil must have at least 2 variants");
}
break;
}
if (ut->align != nullptr) {
i64 custom_align = 1;
if (check_custom_align(ctx, ut->align, &custom_align)) {
if (variants.count == 0) {
error(ut->align, "An empty union cannot have a custom alignment");
} else {
union_type->Union.custom_align = custom_align;
}
}
}
}
gb_internal void check_enum_type(CheckerContext *ctx, Type *enum_type, Type *named_type, Ast *node) {
ast_node(et, EnumType, node);
GB_ASSERT(is_type_enum(enum_type));
Type *base_type = t_int;
if (et->base_type != nullptr) {
base_type = check_type(ctx, et->base_type);
}
if (base_type == nullptr || !is_type_integer(base_type)) {
error(node, "Base type for enumeration must be an integer");
return;
}
if (is_type_enum(base_type)) {
error(node, "Base type for enumeration cannot be another enumeration");
return;
}
if (is_type_integer_128bit(base_type)) {
error(node, "Base type for enumeration cannot be a 128-bit integer");
return;
}
// NOTE(bill): Must be up here for the 'check_init_constant' system
enum_type->Enum.base_type = base_type;
enum_type->Enum.scope = ctx->scope;
auto fields = array_make<Entity *>(permanent_allocator(), 0, et->fields.count);
Type *constant_type = enum_type;
if (named_type != nullptr) {
constant_type = named_type;
}
ExactValue iota = exact_value_i64(-1);
ExactValue min_value = exact_value_i64(0);
ExactValue max_value = exact_value_i64(0);
isize min_value_index = 0;
isize max_value_index = 0;
bool min_value_set = false;
bool max_value_set = false;
scope_reserve(ctx->scope, et->fields.count);
for_array(i, et->fields) {
Ast *field = et->fields[i];
Ast *ident = nullptr;
Ast *init = nullptr;
u32 entity_flags = 0;
if (field->kind != Ast_EnumFieldValue) {
error(field, "An enum field's name must be an identifier");
continue;
}
ident = field->EnumFieldValue.name;
init = field->EnumFieldValue.value;
if (ident == nullptr || ident->kind != Ast_Ident) {
error(field, "An enum field's name must be an identifier");
continue;
}
CommentGroup *docs = field->EnumFieldValue.docs;
CommentGroup *comment = field->EnumFieldValue.comment;
String name = ident->Ident.token.string;
if (init != nullptr) {
Operand o = {};
check_expr(ctx, &o, init);
if (o.mode != Addressing_Constant) {
error(init, "Enumeration value must be a constant");
o.mode = Addressing_Invalid;
}
if (o.mode != Addressing_Invalid) {
check_assignment(ctx, &o, constant_type, str_lit("enumeration"));
}
if (o.mode != Addressing_Invalid) {
iota = o.value;
} else {
iota = exact_binary_operator_value(Token_Add, iota, exact_value_i64(1));
}
} else {
iota = exact_binary_operator_value(Token_Add, iota, exact_value_i64(1));
entity_flags |= EntityConstantFlag_ImplicitEnumValue;
}
// NOTE(bill): Skip blank identifiers
if (is_blank_ident(name)) {
continue;
} else if (name == "names") {
error(field, "'names' is a reserved identifier for enumerations");
continue;
}
if (min_value_set) {
if (compare_exact_values(Token_Gt, min_value, iota)) {
min_value_index = i;
min_value = iota;
}
} else {
min_value_index = i;
min_value = iota;
min_value_set = true;
}
if (max_value_set) {
if (compare_exact_values(Token_Lt, max_value, iota)) {
max_value_index = i;
max_value = iota;
}
} else {
max_value_index = i;
max_value = iota;
max_value_set = true;
}
Entity *e = alloc_entity_constant(ctx->scope, ident->Ident.token, constant_type, iota);
e->identifier = ident;
e->flags |= EntityFlag_Visited;
e->state = EntityState_Resolved;
e->Constant.flags |= entity_flags;
e->Constant.docs = docs;
e->Constant.comment = comment;
if (scope_lookup_current(ctx->scope, name) != nullptr) {
error(ident, "'%.*s' is already declared in this enumeration", LIT(name));
} else {
add_entity(ctx, ctx->scope, nullptr, e);
array_add(&fields, e);
// TODO(bill): Should I add a use for the enum value?
add_entity_use(ctx, field, e);
}
}
GB_ASSERT(fields.count <= et->fields.count);
enum_type->Enum.fields = fields;
*enum_type->Enum.min_value = min_value;
*enum_type->Enum.max_value = max_value;
enum_type->Enum.min_value_index = min_value_index;
enum_type->Enum.max_value_index = max_value_index;
}
gb_internal bool is_type_valid_bit_set_range(Type *t) {
if (is_type_integer(t)) {
return true;
}
if (is_type_rune(t)) {
return true;
}
return false;
}
gb_internal void check_bit_set_type(CheckerContext *c, Type *type, Type *named_type, Ast *node) {
ast_node(bs, BitSetType, node);
GB_ASSERT(type->kind == Type_BitSet);
type->BitSet.node = node;
/* i64 const DEFAULT_BITS = cast(i64)(8*build_context.word_size); */
i64 const MAX_BITS = 128;
Ast *base = unparen_expr(bs->elem);
if (is_ast_range(base)) {
ast_node(be, BinaryExpr, base);
Operand lhs = {};
Operand rhs = {};
check_expr(c, &lhs, be->left);
check_expr(c, &rhs, be->right);
if (lhs.mode == Addressing_Invalid || rhs.mode == Addressing_Invalid) {
return;
}
convert_to_typed(c, &lhs, rhs.type);
if (lhs.mode == Addressing_Invalid) {
return;
}
convert_to_typed(c, &rhs, lhs.type);
if (rhs.mode == Addressing_Invalid) {
return;
}
if (!are_types_identical(lhs.type, rhs.type)) {
if (lhs.type != t_invalid &&
rhs.type != t_invalid) {
gbString xt = type_to_string(lhs.type);
gbString yt = type_to_string(rhs.type);
gbString expr_str = expr_to_string(bs->elem);
error(bs->elem, "Mismatched types in range '%s' : '%s' vs '%s'", expr_str, xt, yt);
gb_string_free(expr_str);
gb_string_free(yt);
gb_string_free(xt);
}
return;
}
if (!is_type_valid_bit_set_range(lhs.type)) {
gbString str = type_to_string(lhs.type);
error(bs->elem, "'%s' is invalid for an interval expression, expected an integer or rune", str);
gb_string_free(str);
return;
}
if (lhs.mode != Addressing_Constant || rhs.mode != Addressing_Constant) {
error(bs->elem, "Intervals must be constant values");
return;
}
ExactValue iv = exact_value_to_integer(lhs.value);
ExactValue jv = exact_value_to_integer(rhs.value);
GB_ASSERT(iv.kind == ExactValue_Integer);
GB_ASSERT(jv.kind == ExactValue_Integer);
BigInt i = iv.value_integer;
BigInt j = jv.value_integer;
if (big_int_cmp(&i, &j) > 0) {
gbAllocator a = heap_allocator();
String si = big_int_to_string(a, &i);
String sj = big_int_to_string(a, &j);
error(bs->elem, "Lower interval bound larger than upper bound, %.*s .. %.*s", LIT(si), LIT(sj));
gb_free(a, si.text);
gb_free(a, sj.text);
return;
}
Type *t = default_type(lhs.type);
if (bs->underlying != nullptr) {
Type *u = check_type(c, bs->underlying);
if (!is_type_integer(u)) {
gbString ts = type_to_string(u);
error(bs->underlying, "Expected an underlying integer for the bit set, got %s", ts);
gb_string_free(ts);
return;
}
type->BitSet.underlying = u;
}
if (!check_representable_as_constant(c, iv, t, nullptr)) {
gbAllocator a = heap_allocator();
String s = big_int_to_string(a, &i);
gbString ts = type_to_string(t);
error(bs->elem, "%.*s is not representable by %s", LIT(s), ts);
gb_string_free(ts);
gb_free(a, s.text);
return;
}
if (!check_representable_as_constant(c, iv, t, nullptr)) {
gbAllocator a = heap_allocator();
String s = big_int_to_string(a, &j);
gbString ts = type_to_string(t);
error(bs->elem, "%.*s is not representable by %s", LIT(s), ts);
gb_string_free(ts);
gb_free(a, s.text);
return;
}
i64 lower = big_int_to_i64(&i);
i64 upper = big_int_to_i64(&j);
i64 actual_lower = lower;
i64 bits = MAX_BITS;
if (type->BitSet.underlying != nullptr) {
bits = 8*type_size_of(type->BitSet.underlying);
if (lower > 0) {
actual_lower = 0;
} else if (lower < 0) {
error(bs->elem, "bit_set does not allow a negative lower bound (%lld) when an underlying type is set", lower);
}
}
i64 bits_required = upper-actual_lower;
switch (be->op.kind) {
case Token_Ellipsis:
case Token_RangeFull:
bits_required += 1;
break;
}
bool is_valid = true;
switch (be->op.kind) {
case Token_Ellipsis:
case Token_RangeFull:
if (upper - lower >= bits) {
is_valid = false;
}
break;
case Token_RangeHalf:
if (upper - lower > bits) {
is_valid = false;
}
upper -= 1;
break;
}
if (!is_valid) {
if (actual_lower != lower) {
error(bs->elem, "bit_set range is greater than %lld bits, %lld bits are required (internal the lower changed was changed 0 as an underlying type was set)", bits, bits_required);
} else {
error(bs->elem, "bit_set range is greater than %lld bits, %lld bits are required", bits, bits_required);
}
}
type->BitSet.elem = t;
type->BitSet.lower = lower;
type->BitSet.upper = upper;
} else {
Type *elem = check_type_expr(c, bs->elem, nullptr);
#if 0
if (named_type != nullptr && named_type->kind == Type_Named &&
elem->kind == Type_Enum) {
// NOTE(bill): Anonymous enumeration
String prefix = named_type->Named.name;
String enum_name = concatenate_strings(heap_allocator(), prefix, str_lit(".enum"));
Token token = make_token_ident(enum_name);
Entity *e = alloc_entity_type_name(nullptr, token, nullptr, EntityState_Resolved);
Type *named = alloc_type_named(enum_name, elem, e);
e->type = named;
e->TypeName.is_type_alias = true;
elem = named;
}
#endif
type->BitSet.elem = elem;
if (!is_type_valid_bit_set_elem(elem)) {
error(bs->elem, "Expected an enum type for a bit_set");
} else {
Type *et = base_type(elem);
if (et->kind == Type_Enum) {
if (!is_type_integer(et->Enum.base_type)) {
error(bs->elem, "Enum type for bit_set must be an integer");
return;
}
i64 lower = I64_MAX;
i64 upper = I64_MIN;
for_array(i, et->Enum.fields) {
Entity *e = et->Enum.fields[i];
if (e->kind != Entity_Constant) {
continue;
}
ExactValue value = exact_value_to_integer(e->Constant.value);
GB_ASSERT(value.kind == ExactValue_Integer);
// NOTE(bill): enum types should be able to store i64 values
i64 x = big_int_to_i64(&value.value_integer);
lower = gb_min(lower, x);
upper = gb_max(upper, x);
}
if (et->Enum.fields.count == 0) {
lower = 0;
upper = 0;
}
GB_ASSERT(lower <= upper);
bool lower_changed = false;
i64 bits = MAX_BITS
; if (bs->underlying != nullptr) {
Type *u = check_type(c, bs->underlying);
if (!is_type_integer(u)) {
gbString ts = type_to_string(u);
error(bs->underlying, "Expected an underlying integer for the bit set, got %s", ts);
gb_string_free(ts);
return;
}
type->BitSet.underlying = u;
bits = 8*type_size_of(u);
if (lower > 0) {
lower = 0;
lower_changed = true;
} else if (lower < 0) {
gbString s = type_to_string(elem);
error(bs->elem, "bit_set does not allow a negative lower bound (%lld) of the element type '%s' when an underlying type is set", lower, s);
gb_string_free(s);
}
}
if (upper - lower >= bits) {
i64 bits_required = upper-lower+1;
if (lower_changed) {
error(bs->elem, "bit_set range is greater than %lld bits, %lld bits are required (internal the lower changed was changed 0 as an underlying type was set)", bits, bits_required);
} else {
error(bs->elem, "bit_set range is greater than %lld bits, %lld bits are required", bits, bits_required);
}
}
type->BitSet.lower = lower;
type->BitSet.upper = upper;
}
}
}
}
gb_internal bool check_type_specialization_to(CheckerContext *ctx, Type *specialization, Type *type, bool compound, bool modify_type) {
if (type == nullptr ||
type == t_invalid) {
return true;
}
Type *t = base_type(type);
Type *s = base_type(specialization);
if (t->kind != s->kind) {
if (t->kind == Type_EnumeratedArray && s->kind == Type_Array) {
// Might be okay, check later
} else {
return false;
}
}
if (is_type_untyped(t)) {
Operand o = {Addressing_Value};
o.type = default_type(type);
bool can_convert = check_cast_internal(ctx, &o, specialization);
return can_convert;
} else if (t->kind == Type_Struct) {
if (t->Struct.polymorphic_parent == specialization) {
return true;
}
if (t->Struct.polymorphic_parent == s->Struct.polymorphic_parent &&
s->Struct.polymorphic_params != nullptr &&
t->Struct.polymorphic_params != nullptr) {
TypeTuple *s_tuple = &s->Struct.polymorphic_params->Tuple;
TypeTuple *t_tuple = &t->Struct.polymorphic_params->Tuple;
GB_ASSERT(t_tuple->variables.count == s_tuple->variables.count);
for_array(i, s_tuple->variables) {
Entity *s_e = s_tuple->variables[i];
Entity *t_e = t_tuple->variables[i];
Type *st = s_e->type;
Type *tt = t_e->type;
// NOTE(bill, 2018-12-14): This is needed to override polymorphic named constants in types
if (st->kind == Type_Generic && t_e->kind == Entity_Constant) {
Entity *e = scope_lookup(st->Generic.scope, st->Generic.name);
GB_ASSERT(e != nullptr);
if (modify_type) {
e->kind = Entity_Constant;
e->Constant.value = t_e->Constant.value;
e->type = t_e->type;
}
} else {
if (st->kind == Type_Basic && tt->kind == Type_Basic &&
s_e->kind == Entity_Constant && t_e->kind == Entity_Constant) {
if (!compare_exact_values(Token_CmpEq, s_e->Constant.value, t_e->Constant.value))
return false;
} else {
bool ok = is_polymorphic_type_assignable(ctx, st, tt, true, modify_type);
if (!ok) {
// TODO(bill, 2021-08-19): is this logic correct?
return false;
}
}
}
}
if (modify_type) {
// NOTE(bill): This is needed in order to change the actual type but still have the types defined within it
gb_memmove(specialization, type, gb_size_of(Type));
}
return true;
}
} else if (t->kind == Type_Union) {
if (t->Union.polymorphic_parent == specialization) {
return true;
}
if (t->Union.polymorphic_parent == s->Union.polymorphic_parent &&
s->Union.polymorphic_params != nullptr &&
t->Union.polymorphic_params != nullptr) {
TypeTuple *s_tuple = &s->Union.polymorphic_params->Tuple;
TypeTuple *t_tuple = &t->Union.polymorphic_params->Tuple;
GB_ASSERT(t_tuple->variables.count == s_tuple->variables.count);
for_array(i, s_tuple->variables) {
Entity *s_e = s_tuple->variables[i];
Entity *t_e = t_tuple->variables[i];
Type *st = s_e->type;
Type *tt = t_e->type;
// NOTE(bill, 2018-12-14): This is needed to override polymorphic named constants in types
if (st->kind == Type_Generic && t_e->kind == Entity_Constant) {
Entity *e = scope_lookup(st->Generic.scope, st->Generic.name);
GB_ASSERT(e != nullptr);
if (modify_type) {
e->kind = Entity_Constant;
e->Constant.value = t_e->Constant.value;
e->type = t_e->type;
}
} else {
bool ok = is_polymorphic_type_assignable(ctx, st, tt, true, modify_type);
if (!ok) {
// TODO(bill, 2021-08-19): is this logic correct?
return false;
}
}
}
if (modify_type) {
// NOTE(bill): This is needed in order to change the actual type but still have the types defined within it
gb_memmove(specialization, type, gb_size_of(Type));
}
return true;
}
}
if (specialization->kind == Type_Named &&
type->kind != Type_Named) {
return false;
}
if (is_polymorphic_type_assignable(ctx, base_type(specialization), base_type(type), compound, modify_type)) {
return true;
}
return false;
}
gb_internal Type *determine_type_from_polymorphic(CheckerContext *ctx, Type *poly_type, Operand const &operand) {
bool modify_type = !ctx->no_polymorphic_errors;
bool show_error = modify_type && !ctx->hide_polymorphic_errors;
if (!is_operand_value(operand)) {
if (show_error) {
gbString pts = type_to_string(poly_type);
gbString ots = type_to_string(operand.type, true);
defer (gb_string_free(pts));
defer (gb_string_free(ots));
error(operand.expr, "Cannot determine polymorphic type from parameter: '%s' to '%s'", ots, pts);
}
return t_invalid;
}
if (is_polymorphic_type_assignable(ctx, poly_type, operand.type, false, modify_type)) {
return poly_type;
}
if (show_error) {
gbString pts = type_to_string(poly_type);
gbString ots = type_to_string(operand.type, true);
defer (gb_string_free(pts));
defer (gb_string_free(ots));
error(operand.expr, "Cannot determine polymorphic type from parameter: '%s' to '%s'", ots, pts);
}
return t_invalid;
}
gb_internal bool is_expr_from_a_parameter(CheckerContext *ctx, Ast *expr) {
if (expr == nullptr) {
return false;
}
expr = unparen_expr(expr);
if (expr->kind == Ast_SelectorExpr) {
Ast *lhs = expr->SelectorExpr.expr;
return is_expr_from_a_parameter(ctx, lhs);
} else if (expr->kind == Ast_Ident) {
Operand x= {};
Entity *e = check_ident(ctx, &x, expr, nullptr, nullptr, false);
if (e->flags & EntityFlag_Param) {
return true;
}
}
return false;
}
gb_internal ParameterValue handle_parameter_value(CheckerContext *ctx, Type *in_type, Type **out_type_, Ast *expr, bool allow_caller_location) {
ParameterValue param_value = {};
param_value.original_ast_expr = expr;
if (expr == nullptr) {
return param_value;
}
Operand o = {};
if (allow_caller_location &&
expr->kind == Ast_BasicDirective &&
expr->BasicDirective.name.string == "caller_location") {
init_core_source_code_location(ctx->checker);
param_value.kind = ParameterValue_Location;
o.type = t_source_code_location;
o.mode = Addressing_Value;
o.expr = expr;
if (in_type) {
check_assignment(ctx, &o, in_type, str_lit("parameter value"));
}
} else {
if (in_type) {
check_expr_with_type_hint(ctx, &o, expr, in_type);
} else {
check_expr(ctx, &o, expr);
}
if (in_type) {
check_assignment(ctx, &o, in_type, str_lit("parameter value"));
}
if (is_operand_nil(o)) {
param_value.kind = ParameterValue_Nil;
} else if (o.mode != Addressing_Constant) {
if (expr->kind == Ast_ProcLit) {
param_value.kind = ParameterValue_Constant;
param_value.value = exact_value_procedure(expr);
} else {
Entity *e = entity_from_expr(o.expr);
if (e != nullptr) {
if (e->kind == Entity_Procedure) {
param_value.kind = ParameterValue_Constant;
param_value.value = exact_value_procedure(e->identifier);
add_entity_use(ctx, e->identifier, e);
} else {
if (e->flags & EntityFlag_Param) {
error(expr, "Default parameter cannot be another parameter");
} else {
if (is_expr_from_a_parameter(ctx, expr)) {
error(expr, "Default parameter cannot be another parameter");
} else {
param_value.kind = ParameterValue_Value;
param_value.ast_value = expr;
add_entity_use(ctx, e->identifier, e);
}
}
}
} else if (allow_caller_location && o.mode == Addressing_Context) {
param_value.kind = ParameterValue_Value;
param_value.ast_value = expr;
} else if (o.value.kind != ExactValue_Invalid) {
param_value.kind = ParameterValue_Constant;
param_value.value = o.value;
} else {
gbString s = expr_to_string(o.expr);
error(expr, "Default parameter must be a constant, got %s", s);
gb_string_free(s);
}
}
} else {
if (o.value.kind != ExactValue_Invalid) {
param_value.kind = ParameterValue_Constant;
param_value.value = o.value;
} else {
gbString s = expr_to_string(o.expr);
error(o.expr, "Invalid constant parameter, got '%s'", s);
// error(o.expr, "Invalid constant parameter, got '%s' %d %d", s, o.mode, o.value.kind);
gb_string_free(s);
}
}
}
if (out_type_) {
if (in_type != nullptr) {
*out_type_ = in_type;
} else {
*out_type_ = default_type(o.type);
}
}
return param_value;
}
gb_internal Type *check_get_params(CheckerContext *ctx, Scope *scope, Ast *_params, bool *is_variadic_, isize *variadic_index_, bool *success_, isize *specialization_count_, Array<Operand> const *operands) {
if (_params == nullptr) {
return nullptr;
}
bool success = true;
ast_node(field_list, FieldList, _params);
Slice<Ast *> params = field_list->list;
if (params.count == 0) {
if (success_) *success_ = success;
return nullptr;
}
isize variable_count = 0;
for_array(i, params) {
Ast *field = params[i];
if (ast_node_expect(field, Ast_Field)) {
ast_node(f, Field, field);
variable_count += gb_max(f->names.count, 1);
}
}
isize min_variable_count = variable_count;
for (isize i = params.count-1; i >= 0; i--) {
Ast *field = params[i];
if (field->kind == Ast_Field) {
ast_node(f, Field, field);
if (f->default_value == nullptr) {
break;
}
min_variable_count--;
}
}
bool is_variadic = false;
isize variadic_index = -1;
bool is_c_vararg = false;
auto variables = array_make<Entity *>(permanent_allocator(), 0, variable_count);
i32 field_group_index = -1;
for_array(i, params) {
Ast *param = params[i];
if (param->kind != Ast_Field) {
continue;
}
field_group_index += 1;
ast_node(p, Field, param);
Ast *type_expr = unparen_expr(p->type);
Type *type = nullptr;
Ast *default_value = unparen_expr(p->default_value);
ParameterValue param_value = {};
bool is_type_param = false;
bool is_type_polymorphic_type = false;
bool detemine_type_from_operand = false;
Type *specialization = nullptr;
bool is_using = (p->flags&FieldFlag_using) != 0;
if ((check_vet_flags(param) & VetFlag_UsingParam) && is_using) {
ERROR_BLOCK();
error(param, "'using' on a procedure parameter is now allowed when '-vet' or '-vet-using-param' is applied");
error_line("\t'using' is considered bad practice to use as a statement/procedure parameter outside of immediate refactoring\n");
}
if (type_expr == nullptr) {
param_value = handle_parameter_value(ctx, nullptr, &type, default_value, true);
} else {
if (type_expr->kind == Ast_Ellipsis) {
type_expr = type_expr->Ellipsis.expr;
is_variadic = true;
variadic_index = variables.count;
if (p->names.count != 1) {
error(param, "Invalid AST: Invalid variadic parameter with multiple names");
success = false;
}
}
if (type_expr->kind == Ast_TypeidType) {
ast_node(tt, TypeidType, type_expr);
if (tt->specialization) {
specialization = check_type(ctx, tt->specialization);
if (specialization == t_invalid){
specialization = nullptr;
}
if (operands != nullptr) {
detemine_type_from_operand = true;
type = t_invalid;
} else {
type = alloc_type_generic(ctx->scope, 0, str_lit(""), specialization);
}
} else {
type = t_typeid;
}
} else {
bool prev = ctx->allow_polymorphic_types;
if (operands != nullptr) {
ctx->allow_polymorphic_types = true;
}
type = check_type(ctx, type_expr);
ctx->allow_polymorphic_types = prev;
if (is_type_polymorphic(type)) {
is_type_polymorphic_type = true;
}
}
if (default_value != nullptr) {
if (type_expr != nullptr && type_expr->kind == Ast_TypeidType) {
error(type_expr, "A type parameter may not have a default value");
} else {
param_value = handle_parameter_value(ctx, type, nullptr, default_value, true);
}
}
}
if (type == nullptr) {
error(param, "Invalid parameter type");
type = t_invalid;
}
if (is_type_untyped(type)) {
if (is_type_untyped_uninit(type)) {
error(param, "Cannot determine parameter type from ---");
} else {
error(param, "Cannot determine parameter type from a nil");
}
type = t_invalid;
}
if (is_type_empty_union(type)) {
gbString str = type_to_string(type);
error(param, "Invalid use of an empty union '%s'", str);
gb_string_free(str);
type = t_invalid;
}
if (is_type_polymorphic(type)) {
switch (param_value.kind) {
case ParameterValue_Invalid:
case ParameterValue_Constant:
case ParameterValue_Nil:
break;
case ParameterValue_Location:
case ParameterValue_Value:
gbString str = type_to_string(type);
error(params[i], "A default value for a parameter must not be a polymorphic constant type, got %s", str);
gb_string_free(str);
break;
}
}
if (p->flags&FieldFlag_c_vararg) {
if (p->type == nullptr ||
p->type->kind != Ast_Ellipsis) {
error(param, "'#c_vararg' can only be applied to variadic type fields");
p->flags &= ~FieldFlag_c_vararg; // Remove the flag
} else {
is_c_vararg = true;
}
}
for_array(j, p->names) {
Ast *name = p->names[j];
bool is_poly_name = false;
switch (name->kind) {
case Ast_Ident:
break;
case Ast_PolyType:
GB_ASSERT(name->PolyType.specialization == nullptr);
is_poly_name = true;
name = name->PolyType.type;
break;
}
if (!ast_node_expect(name, Ast_Ident)) {
continue;
}
if (is_poly_name) {
if (type_expr != nullptr && type_expr->kind == Ast_TypeidType) {
is_type_param = true;
} else {
if (param_value.kind != ParameterValue_Invalid) {
error(default_value, "Constant parameters cannot have a default value");
param_value.kind = ParameterValue_Invalid;
}
}
}
Entity *param = nullptr;
if (is_type_param) {
if (operands != nullptr) {
Operand o = (*operands)[variables.count];
if (o.mode == Addressing_Type) {
type = o.type;
} else {
if (!ctx->no_polymorphic_errors) {
error(o.expr, "Expected a type to assign to the type parameter");
}
success = false;
type = t_invalid;
}
if (is_type_polymorphic(type)) {
gbString str = type_to_string(type);
error(o.expr, "Cannot pass polymorphic type as a parameter, got '%s'", str);
gb_string_free(str);
success = false;
type = t_invalid;
}
if (is_type_untyped(default_type(type))) {
gbString str = type_to_string(type);
error(o.expr, "Cannot determine type from the parameter, got '%s'", str);
gb_string_free(str);
success = false;
type = t_invalid;
}
bool modify_type = !ctx->no_polymorphic_errors;
if (specialization != nullptr && !check_type_specialization_to(ctx, specialization, type, false, modify_type)) {
if (!ctx->no_polymorphic_errors) {
gbString t = type_to_string(type);
gbString s = type_to_string(specialization);
error(o.expr, "Cannot convert type '%s' to the specialization '%s'", t, s);
gb_string_free(s);
gb_string_free(t);
}
success = false;
type = t_invalid;
}
}
if (p->flags&FieldFlag_const) {
error(name, "'#const' can only be applied to variable fields");
p->flags &= ~FieldFlag_const;
}
if (p->flags&FieldFlag_any_int) {
error(name, "'#any_int' can only be applied to variable fields");
p->flags &= ~FieldFlag_any_int;
}
if (p->flags&FieldFlag_by_ptr) {
error(name, "'#by_ptr' can only be applied to variable fields");
p->flags &= ~FieldFlag_by_ptr;
}
param = alloc_entity_type_name(scope, name->Ident.token, type, EntityState_Resolved);
param->TypeName.is_type_alias = true;
} else {
ExactValue poly_const = {};
if (operands != nullptr && variables.count < operands->count) {
Operand op = (*operands)[variables.count];
if (op.expr == nullptr) {
// NOTE(bill): 2019-03-30
// This is just to add the error message to determine_type_from_polymorphic which
// depends on valid position information
op.expr = _params;
op.mode = Addressing_Invalid;
op.type = t_invalid;
}
if (is_type_polymorphic_type) {
type = determine_type_from_polymorphic(ctx, type, op);
if (type == t_invalid) {
success = false;
} else if (!ctx->no_polymorphic_errors) {
// NOTE(bill): The type should be determined now and thus, no need to determine the type any more
is_type_polymorphic_type = false;
Entity *proc_entity = entity_from_expr(op.expr);
if ((proc_entity != nullptr) && (op.value.kind == ExactValue_Procedure)) {
if (is_type_polymorphic(proc_entity->type, false)) {
error(op.expr, "Cannot determine complete type of partial polymorphic procedure");
}
}
}
}
if (is_poly_name) {
bool valid = false;
if (is_type_proc(op.type)) {
Ast *expr = unparen_expr(op.expr);
Entity *proc_entity = entity_from_expr(expr);
if (proc_entity) {
poly_const = exact_value_procedure(proc_entity->identifier.load() ? proc_entity->identifier.load() : op.expr);
valid = true;
} else if (expr->kind == Ast_ProcLit) {
poly_const = exact_value_procedure(expr);
valid = true;
}
}
if (!valid) {
if (op.mode == Addressing_Constant) {
poly_const = op.value;
} else {
error(op.expr, "Expected a constant value for this polymorphic name parameter, got %s", expr_to_string(op.expr));
success = false;
}
}
}
if (type != t_invalid && !check_is_assignable_to(ctx, &op, type)) {
bool ok = true;
if (p->flags&FieldFlag_any_int) {
if ((!is_type_integer(op.type) && !is_type_enum(op.type)) || (!is_type_integer(type) && !is_type_enum(type))) {
ok = false;
} else if (!check_is_castable_to(ctx, &op, type)) {
ok = false;
}
}
if (!ok) {
success = false;
#if 0
gbString got = type_to_string(op.type);
gbString expected = type_to_string(type);
error(op.expr, "Cannot assigned type to parameter, got type '%s', expected '%s'", got, expected);
gb_string_free(expected);
gb_string_free(got);
#endif
}
}
if (is_type_untyped(default_type(type))) {
gbString str = type_to_string(type);
error(op.expr, "Cannot determine type from the parameter, got '%s'", str);
gb_string_free(str);
success = false;
type = t_invalid;
}
}
if (p->flags&FieldFlag_no_alias) {
if (!is_type_pointer(type)) {
error(name, "'#no_alias' can only be applied pointer typed parameters");
p->flags &= ~FieldFlag_no_alias; // Remove the flag
}
}
if (p->flags&FieldFlag_by_ptr) {
if (is_type_internally_pointer_like(type)) {
error(name, "'#by_ptr' can only be applied to non-pointer-like parameters");
p->flags &= ~FieldFlag_by_ptr; // Remove the flag
}
}
if (is_poly_name) {
if (p->flags&FieldFlag_no_alias) {
error(name, "'#no_alias' can only be applied to non constant values");
p->flags &= ~FieldFlag_no_alias; // Remove the flag
}
if (p->flags&FieldFlag_any_int) {
error(name, "'#any_int' can only be applied to variable fields");
p->flags &= ~FieldFlag_any_int;
}
if (p->flags&FieldFlag_const) {
error(name, "'#const' can only be applied to variable fields");
p->flags &= ~FieldFlag_const;
}
if (p->flags&FieldFlag_by_ptr) {
error(name, "'#by_ptr' can only be applied to variable fields");
p->flags &= ~FieldFlag_by_ptr;
}
if (!is_type_polymorphic(type) && check_constant_parameter_value(type, params[i])) {
// failed
}
param = alloc_entity_const_param(scope, name->Ident.token, type, poly_const, is_type_polymorphic(type));
param->Constant.field_group_index = field_group_index;
} else {
param = alloc_entity_param(scope, name->Ident.token, type, is_using, true);
param->Variable.param_value = param_value;
param->Variable.field_group_index = field_group_index;
}
}
if (p->flags&FieldFlag_no_alias) {
param->flags |= EntityFlag_NoAlias;
}
if (p->flags&FieldFlag_any_int) {
if (!is_type_integer(param->type) && !is_type_enum(param->type)) {
gbString str = type_to_string(param->type);
error(name, "A parameter with '#any_int' must be an integer, got %s", str);
gb_string_free(str);
}
param->flags |= EntityFlag_AnyInt;
}
if (p->flags&FieldFlag_const) {
param->flags |= EntityFlag_ConstInput;
}
if (p->flags&FieldFlag_by_ptr) {
param->flags |= EntityFlag_ByPtr;
}
param->state = EntityState_Resolved; // NOTE(bill): This should have be resolved whilst determining it
add_entity(ctx, scope, name, param);
if (is_using) {
add_entity_use(ctx, name, param);
}
array_add(&variables, param);
}
}
if (is_variadic) {
GB_ASSERT(variadic_index >= 0);
}
if (is_variadic) {
GB_ASSERT(params.count > 0);
// NOTE(bill): Change last variadic parameter to be a slice
// Custom Calling convention for variadic parameters
Entity *end = variables[variadic_index];
end->type = alloc_type_slice(end->type);
end->flags |= EntityFlag_Ellipsis;
if (is_c_vararg) {
end->flags |= EntityFlag_CVarArg;
}
}
isize specialization_count = 0;
if (scope != nullptr) {
for (auto const &entry : scope->elements) {
Entity *e = entry.value;
if (e->kind == Entity_TypeName) {
Type *t = e->type;
if (t->kind == Type_Generic &&
t->Generic.specialized != nullptr) {
specialization_count += 1;
}
}
}
}
Type *tuple = alloc_type_tuple();
tuple->Tuple.variables = slice_from_array(variables);
if (success_) *success_ = success;
if (specialization_count_) *specialization_count_ = specialization_count;
if (is_variadic_) *is_variadic_ = is_variadic;
if (variadic_index_) *variadic_index_ = variadic_index;
return tuple;
}
gb_internal Type *check_get_results(CheckerContext *ctx, Scope *scope, Ast *_results) {
if (_results == nullptr) {
return nullptr;
}
ast_node(field_list, FieldList, _results);
Slice<Ast *> results = field_list->list;
if (results.count == 0) {
return nullptr;
}
Type *tuple = alloc_type_tuple();
isize variable_count = 0;
for_array(i, results) {
Ast *field = results[i];
if (ast_node_expect(field, Ast_Field)) {
ast_node(f, Field, field);
variable_count += gb_max(f->names.count, 1);
}
}
auto variables = array_make<Entity *>(permanent_allocator(), 0, variable_count);
i32 field_group_index = -1;
for_array(i, results) {
field_group_index += 1;
ast_node(field, Field, results[i]);
Ast *default_value = unparen_expr(field->default_value);
ParameterValue param_value = {};
Type *type = nullptr;
if (field->type == nullptr) {
param_value = handle_parameter_value(ctx, nullptr, &type, default_value, false);
} else {
type = check_type(ctx, field->type);
if (default_value != nullptr) {
param_value = handle_parameter_value(ctx, type, nullptr, default_value, false);
}
}
if (type == nullptr) {
error(results[i], "Invalid parameter type");
type = t_invalid;
}
if (is_type_untyped(type)) {
error(results[i], "Cannot determine parameter type from a nil");
type = t_invalid;
}
if (field->names.count == 0) {
Token token = ast_token(field->type);
token.string = str_lit("");
Entity *param = alloc_entity_param(scope, token, type, false, false);
param->Variable.param_value = param_value;
param->Variable.field_group_index = -1;
array_add(&variables, param);
} else {
for_array(j, field->names) {
Token token = ast_token(results[i]);
if (field->type != nullptr) {
token = ast_token(field->type);
}
token.string = str_lit("");
Ast *name = field->names[j];
if (name->kind != Ast_Ident) {
error(name, "Expected an identifer for as the field name");
} else {
token = name->Ident.token;
}
if (is_blank_ident(token)) {
error(name, "Result value cannot be a blank identifer `_`");
}
Entity *param = alloc_entity_param(scope, token, type, false, false);
param->flags |= EntityFlag_Result;
param->Variable.param_value = param_value;
param->Variable.field_group_index = field_group_index;
array_add(&variables, param);
add_entity(ctx, scope, name, param);
// NOTE(bill): Removes `declared but not used` when using -vet
add_entity_use(ctx, name, param);
}
}
}
for_array(i, variables) {
String x = variables[i]->token.string;
if (x.len == 0 || is_blank_ident(x)) {
continue;
}
for (isize j = i+1; j < variables.count; j++) {
String y = variables[j]->token.string;
if (y.len == 0 || is_blank_ident(y)) {
continue;
}
if (x == y) {
error(variables[j]->token, "Duplicate return value name '%.*s'", LIT(y));
}
}
}
tuple->Tuple.variables = slice_from_array(variables);
return tuple;
}
// NOTE(bill): 'operands' is for generating non generic procedure type
gb_internal bool check_procedure_type(CheckerContext *ctx, Type *type, Ast *proc_type_node, Array<Operand> const *operands) {
ast_node(pt, ProcType, proc_type_node);
if (ctx->polymorphic_scope == nullptr && ctx->allow_polymorphic_types) {
ctx->polymorphic_scope = ctx->scope;
}
CheckerContext c_ = *ctx;
CheckerContext *c = &c_;
c->curr_proc_sig = type;
c->in_proc_sig = true;
ProcCallingConvention cc = pt->calling_convention;
if (cc == ProcCC_ForeignBlockDefault) {
cc = ProcCC_CDecl;
if (c->foreign_context.default_cc > 0) {
cc = c->foreign_context.default_cc;
}
}
GB_ASSERT(cc > 0);
if (cc == ProcCC_Odin) {
c->scope->flags |= ScopeFlag_ContextDefined;
} else {
c->scope->flags &= ~ScopeFlag_ContextDefined;
}
TargetArchKind arch = build_context.metrics.arch;
switch (cc) {
case ProcCC_StdCall:
case ProcCC_FastCall:
if (arch != TargetArch_i386 && arch != TargetArch_amd64) {
error(proc_type_node, "Invalid procedure calling convention \"%s\" for target architecture, expected either i386 or amd64, got %.*s",
proc_calling_convention_strings[cc], LIT(target_arch_names[arch]));
}
break;
case ProcCC_Win64:
case ProcCC_SysV:
if (arch != TargetArch_amd64) {
error(proc_type_node, "Invalid procedure calling convention \"%s\" for target architecture, expected amd64, got %.*s",
proc_calling_convention_strings[cc], LIT(target_arch_names[arch]));
}
break;
}
bool variadic = false;
isize variadic_index = -1;
bool success = true;
isize specialization_count = 0;
Type *params = check_get_params(c, c->scope, pt->params, &variadic, &variadic_index, &success, &specialization_count, operands);
Type *results = check_get_results(c, c->scope, pt->results);
isize param_count = 0;
isize result_count = 0;
if (params) param_count = params ->Tuple.variables.count;
if (results) result_count = results->Tuple.variables.count;
if (result_count > 0) {
Entity *first = results->Tuple.variables[0];
type->Proc.has_named_results = first->token.string != "";
}
bool optional_ok = (pt->tags & ProcTag_optional_ok) != 0;
if (optional_ok) {
if (result_count != 2) {
error(proc_type_node, "A procedure type with the #optional_ok tag requires 2 return values, got %td", result_count);
} else {
Entity *second = results->Tuple.variables[1];
if (is_type_polymorphic(second->type)) {
// ignore
} else if (is_type_boolean(second->type)) {
// GOOD
} else {
error(second->token, "Second return value of an #optional_ok procedure must be a boolean, got %s", type_to_string(second->type));
}
}
}
if (pt->tags & ProcTag_optional_allocator_error) {
if (optional_ok) {
error(proc_type_node, "A procedure type cannot have both an #optional_ok tag and #optional_allocator_error");
}
optional_ok = true;
if (result_count != 2) {
error(proc_type_node, "A procedure type with the #optional_allocator_error tag requires 2 return values, got %td", result_count);
} else {
init_mem_allocator(c->checker);
Type *type = results->Tuple.variables[1]->type;
if (!are_types_identical(type, t_allocator_error)) {
gbString t = type_to_string(type);
error(proc_type_node, "A procedure type with the #optional_allocator_error expects a `runtime.Allocator_Error`, got '%s'", t);
gb_string_free(t);
}
}
}
type->Proc.node = proc_type_node;
type->Proc.scope = c->scope;
type->Proc.params = params;
type->Proc.param_count = cast(i32)param_count;
type->Proc.results = results;
type->Proc.result_count = cast(i32)result_count;
type->Proc.variadic = variadic;
type->Proc.variadic_index = cast(i32)variadic_index;
type->Proc.calling_convention = cc;
type->Proc.is_polymorphic = pt->generic;
type->Proc.specialization_count = specialization_count;
type->Proc.diverging = pt->diverging;
type->Proc.optional_ok = optional_ok;
if (param_count > 0) {
Entity *end = params->Tuple.variables[param_count-1];
if (end->flags&EntityFlag_CVarArg) {
switch (cc) {
default:
type->Proc.c_vararg = true;
break;
case ProcCC_Odin:
case ProcCC_Contextless:
error(end->token, "Calling convention does not support #c_vararg");
break;
}
}
}
bool is_polymorphic = false;
for (isize i = 0; i < param_count; i++) {
Entity *e = params->Tuple.variables[i];
if (e->kind != Entity_Variable) {
is_polymorphic = true;
break;
} else if (is_type_polymorphic(e->type)) {
is_polymorphic = true;
break;
}
}
for (isize i = 0; i < result_count; i++) {
Entity *e = results->Tuple.variables[i];
if (e->kind != Entity_Variable) {
is_polymorphic = true;
break;
} else if (is_type_polymorphic(e->type)) {
is_polymorphic = true;
break;
}
}
type->Proc.is_polymorphic = is_polymorphic;
return success;
}
gb_internal i64 check_array_count(CheckerContext *ctx, Operand *o, Ast *e) {
if (e == nullptr) {
return 0;
}
if (e->kind == Ast_UnaryExpr &&
e->UnaryExpr.op.kind == Token_Question) {
return -1;
}
check_expr_or_type(ctx, o, e);
if (o->mode == Addressing_Type) {
Type *ot = base_type(o->type);
if (ot->kind == Type_Generic) {
if (ctx->allow_polymorphic_types) {
if (ot->Generic.specialized) {
ot->Generic.specialized = nullptr;
error(o->expr, "Polymorphic array length cannot have a specialization");
}
return 0;
}
}
if (is_type_enum(ot)) {
return -1;
}
}
if (o->mode != Addressing_Constant) {
if (o->mode != Addressing_Invalid) {
Entity *entity = entity_of_node(o->expr);
bool is_poly_type = false;
if (entity != nullptr) {
is_poly_type = \
entity->kind == Entity_TypeName &&
entity->type == t_typeid &&
entity->flags&EntityFlag_PolyConst;
}
// NOTE(bill, 2021-03-27): Improve error message for parametric polymorphic parameters which want to generate
// and enumerated array but cannot determine what it ought to be yet
if (ctx->allow_polymorphic_types && is_poly_type) {
return 0;
}
gbString s = expr_to_string(o->expr);
error(e, "Array count must be a constant integer, got %s", s);
gb_string_free(s);
if (is_poly_type) {
error_line("\tSuggestion: 'where' clause may be required to restrict the enumerated array index type to an enum\n");
error_line("\t 'where intrinsics.type_is_enum(%.*s)'\n", LIT(entity->token.string));
}
o->mode = Addressing_Invalid;
o->type = t_invalid;
}
return 0;
}
Type *type = core_type(o->type);
if (is_type_untyped(type) || is_type_integer(type)) {
if (o->value.kind == ExactValue_Integer) {
BigInt count = o->value.value_integer;
if (big_int_is_neg(&o->value.value_integer)) {
gbAllocator a = heap_allocator();
String str = big_int_to_string(a, &count);
error(e, "Invalid negative array count, %.*s", LIT(str));
gb_free(a, str.text);
return 0;
}
switch (count.used) {
case 0: return 0;
case 1: return big_int_to_u64(&count);
}
gbAllocator a = heap_allocator();
String str = big_int_to_string(a, &count);
error(e, "Array count too large, %.*s", LIT(str));
gb_free(a, str.text);
return 0;
}
}
error(e, "Array count must be a constant integer");
return 0;
}
gb_internal Type *make_optional_ok_type(Type *value, bool typed) {
gbAllocator a = permanent_allocator();
Type *t = alloc_type_tuple();
slice_init(&t->Tuple.variables, a, 2);
t->Tuple.variables[0] = alloc_entity_field(nullptr, blank_token, value, false, 0);
t->Tuple.variables[1] = alloc_entity_field(nullptr, blank_token, typed ? t_bool : t_untyped_bool, false, 1);
return t;
}
// IMPORTANT NOTE(bill): This must match the definition in dynamic_map_internal.odin
enum : i64 {
MAP_CELL_CACHE_LINE_LOG2 = 6,
MAP_CELL_CACHE_LINE_SIZE = 1 << MAP_CELL_CACHE_LINE_LOG2,
};
GB_STATIC_ASSERT(MAP_CELL_CACHE_LINE_SIZE >= 64);
gb_internal void map_cell_size_and_len(Type *type, i64 *size_, i64 *len_) {
i64 elem_sz = type_size_of(type);
i64 len = 1;
if (0 < elem_sz && elem_sz < MAP_CELL_CACHE_LINE_SIZE) {
len = MAP_CELL_CACHE_LINE_SIZE / elem_sz;
}
i64 size = align_formula(elem_sz * len, MAP_CELL_CACHE_LINE_SIZE);
if (size_) *size_ = size;
if (len_) *len_ = len;
}
gb_internal void init_map_internal_types(Type *type) {
GB_ASSERT(type->kind == Type_Map);
GB_ASSERT(t_allocator != nullptr);
if (type->Map.lookup_result_type != nullptr) return;
Type *key = type->Map.key;
Type *value = type->Map.value;
GB_ASSERT(key != nullptr);
GB_ASSERT(value != nullptr);
type->Map.lookup_result_type = make_optional_ok_type(value);
}
gb_internal void add_map_key_type_dependencies(CheckerContext *ctx, Type *key) {
key = core_type(key);
if (is_type_cstring(key)) {
add_package_dependency(ctx, "runtime", "default_hasher_cstring");
} else if (is_type_string(key)) {
add_package_dependency(ctx, "runtime", "default_hasher_string");
} else if (!is_type_polymorphic(key)) {
if (!is_type_comparable(key)) {
return;
}
if (is_type_simple_compare(key)) {
add_package_dependency(ctx, "runtime", "default_hasher");
return;
}
if (key->kind == Type_Struct) {
add_package_dependency(ctx, "runtime", "default_hasher");
for_array(i, key->Struct.fields) {
Entity *field = key->Struct.fields[i];
add_map_key_type_dependencies(ctx, field->type);
}
} else if (key->kind == Type_Union) {
add_package_dependency(ctx, "runtime", "default_hasher");
for_array(i, key->Union.variants) {
Type *v = key->Union.variants[i];
add_map_key_type_dependencies(ctx, v);
}
} else if (key->kind == Type_EnumeratedArray) {
add_package_dependency(ctx, "runtime", "default_hasher");
add_map_key_type_dependencies(ctx, key->EnumeratedArray.elem);
} else if (key->kind == Type_Array) {
add_package_dependency(ctx, "runtime", "default_hasher");
add_map_key_type_dependencies(ctx, key->Array.elem);
}
}
}
gb_internal void check_map_type(CheckerContext *ctx, Type *type, Ast *node) {
GB_ASSERT(type->kind == Type_Map);
ast_node(mt, MapType, node);
Type *key = check_type(ctx, mt->key);
Type *value = check_type(ctx, mt->value);
if (!is_type_valid_for_keys(key)) {
if (is_type_boolean(key)) {
error(node, "A boolean cannot be used as a key for a map, use an array instead for this case");
} else {
gbString str = type_to_string(key);
error(node, "Invalid type of a key for a map, got '%s'", str);
gb_string_free(str);
}
}
if (type_size_of(key) == 0) {
gbString str = type_to_string(key);
error(node, "Invalid type of a key for a map of size 0, got '%s'", str);
gb_string_free(str);
}
type->Map.key = key;
type->Map.value = value;
add_map_key_type_dependencies(ctx, key);
init_core_map_type(ctx->checker);
init_map_internal_types(type);
// error(node, "'map' types are not yet implemented");
}
gb_internal void check_matrix_type(CheckerContext *ctx, Type **type, Ast *node) {
ast_node(mt, MatrixType, node);
Operand row = {};
Operand column = {};
i64 row_count = check_array_count(ctx, &row, mt->row_count);
i64 column_count = check_array_count(ctx, &column, mt->column_count);
Type *generic_row = nullptr;
Type *generic_column = nullptr;
if (row.mode == Addressing_Type && row.type->kind == Type_Generic) {
generic_row = row.type;
}
if (column.mode == Addressing_Type && column.type->kind == Type_Generic) {
generic_column = column.type;
}
if (generic_row == nullptr && row_count < MATRIX_ELEMENT_COUNT_MIN) {
gbString s = expr_to_string(row.expr);
error(row.expr, "Invalid matrix row count, expected %d+ rows, got %s", MATRIX_ELEMENT_COUNT_MIN, s);
gb_string_free(s);
}
if (generic_column == nullptr && column_count < MATRIX_ELEMENT_COUNT_MIN) {
gbString s = expr_to_string(column.expr);
error(column.expr, "Invalid matrix column count, expected %d+ rows, got %s", MATRIX_ELEMENT_COUNT_MIN, s);
gb_string_free(s);
}
if ((generic_row == nullptr && generic_column == nullptr) && row_count*column_count > MATRIX_ELEMENT_COUNT_MAX) {
i64 element_count = row_count*column_count;
error(column.expr, "Matrix types are limited to a maximum of %d elements, got %lld", MATRIX_ELEMENT_COUNT_MAX, cast(long long)element_count);
}
Type *elem = check_type_expr(ctx, mt->elem, nullptr);
if (!is_type_valid_for_matrix_elems(elem)) {
if (elem == t_typeid) {
Entity *e = entity_of_node(mt->elem);
if (e && e->kind == Entity_TypeName && e->TypeName.is_type_alias) {
// HACK TODO(bill): This is to allow polymorphic parameters for matrix elements
// proc($T: typeid) -> matrix[2, 2]T
//
// THIS IS NEEDS TO BE FIXED AND NOT USE THIS HACK
goto type_assign;
}
}
gbString s = type_to_string(elem);
error(column.expr, "Matrix elements types are limited to integers, floats, and complex, got %s", s);
gb_string_free(s);
}
type_assign:;
*type = alloc_type_matrix(elem, row_count, column_count, generic_row, generic_column);
return;
}
gb_internal Type *make_soa_struct_internal(CheckerContext *ctx, Ast *array_typ_expr, Ast *elem_expr, Type *elem, i64 count, Type *generic_type, StructSoaKind soa_kind) {
Type *bt_elem = base_type(elem);
bool is_polymorphic = is_type_polymorphic(elem);
if ((!is_polymorphic || soa_kind == StructSoa_Fixed) && !is_type_struct(elem) && !is_type_raw_union(elem) && !(is_type_array(elem) && bt_elem->Array.count <= 4)) {
gbString str = type_to_string(elem);
error(elem_expr, "Invalid type for an #soa array, expected a struct or array of length 4 or below, got '%s'", str);
gb_string_free(str);
return alloc_type_array(elem, count, generic_type);
}
Type *soa_struct = nullptr;
Scope *scope = nullptr;
isize field_count = 0;
i32 extra_field_count = 0;
switch (soa_kind) {
case StructSoa_Fixed: extra_field_count = 0; break;
case StructSoa_Slice: extra_field_count = 1; break;
case StructSoa_Dynamic: extra_field_count = 3; break;
}
if (is_polymorphic && soa_kind != StructSoa_Fixed) {
field_count = 0;
soa_struct = alloc_type_struct();
soa_struct->Struct.fields = slice_make<Entity *>(permanent_allocator(), field_count+extra_field_count);
soa_struct->Struct.tags = gb_alloc_array(permanent_allocator(), String, field_count+extra_field_count);
soa_struct->Struct.node = array_typ_expr;
soa_struct->Struct.soa_kind = soa_kind;
soa_struct->Struct.soa_elem = elem;
soa_struct->Struct.soa_count = 0;
soa_struct->Struct.is_polymorphic = true;
scope = create_scope(ctx->info, ctx->scope);
soa_struct->Struct.scope = scope;
} else if (is_type_array(elem)) {
Type *old_array = base_type(elem);
field_count = cast(isize)old_array->Array.count;
soa_struct = alloc_type_struct();
soa_struct->Struct.fields = slice_make<Entity *>(permanent_allocator(), field_count+extra_field_count);
soa_struct->Struct.tags = gb_alloc_array(permanent_allocator(), String, field_count+extra_field_count);
soa_struct->Struct.node = array_typ_expr;
soa_struct->Struct.soa_kind = soa_kind;
soa_struct->Struct.soa_elem = elem;
if (count > I32_MAX) {
count = I32_MAX;
error(array_typ_expr, "Array count too large for an #soa struct, got %lld", cast(long long)count);
}
soa_struct->Struct.soa_count = cast(i32)count;
scope = create_scope(ctx->info, ctx->scope);
string_map_init(&scope->elements, 8);
soa_struct->Struct.scope = scope;
String params_xyzw[4] = {
str_lit("x"),
str_lit("y"),
str_lit("z"),
str_lit("w")
};
for (isize i = 0; i < cast(isize)old_array->Array.count; i++) {
Type *field_type = nullptr;
if (soa_kind == StructSoa_Fixed) {
GB_ASSERT(count >= 0);
field_type = alloc_type_array(old_array->Array.elem, count);
} else {
field_type = alloc_type_pointer(old_array->Array.elem);
}
Token token = {};
token.string = params_xyzw[i];
Entity *new_field = alloc_entity_field(scope, token, field_type, false, cast(i32)i);
soa_struct->Struct.fields[i] = new_field;
add_entity(ctx, scope, nullptr, new_field);
add_entity_use(ctx, nullptr, new_field);
}
} else {
GB_ASSERT(is_type_struct(elem));
Type *old_struct = base_type(elem);
field_count = old_struct->Struct.fields.count;
soa_struct = alloc_type_struct();
soa_struct->Struct.fields = slice_make<Entity *>(permanent_allocator(), field_count+extra_field_count);
soa_struct->Struct.tags = gb_alloc_array(permanent_allocator(), String, field_count+extra_field_count);
soa_struct->Struct.node = array_typ_expr;
soa_struct->Struct.soa_kind = soa_kind;
soa_struct->Struct.soa_elem = elem;
if (count > I32_MAX) {
count = I32_MAX;
error(array_typ_expr, "Array count too large for an #soa struct, got %lld", cast(long long)count);
}
soa_struct->Struct.soa_count = cast(i32)count;
scope = create_scope(ctx->info, old_struct->Struct.scope->parent);
soa_struct->Struct.scope = scope;
for_array(i, old_struct->Struct.fields) {
Entity *old_field = old_struct->Struct.fields[i];
if (old_field->kind == Entity_Variable) {
Type *field_type = nullptr;
if (soa_kind == StructSoa_Fixed) {
GB_ASSERT(count >= 0);
field_type = alloc_type_array(old_field->type, count);
} else {
field_type = alloc_type_pointer(old_field->type);
}
Entity *new_field = alloc_entity_field(scope, old_field->token, field_type, false, old_field->Variable.field_index);
soa_struct->Struct.fields[i] = new_field;
add_entity(ctx, scope, nullptr, new_field);
add_entity_use(ctx, nullptr, new_field);
} else {
soa_struct->Struct.fields[i] = old_field;
}
soa_struct->Struct.tags[i] = old_struct->Struct.tags[i];
}
}
if (soa_kind != StructSoa_Fixed) {
Entity *len_field = alloc_entity_field(scope, empty_token, t_int, false, cast(i32)field_count+0);
soa_struct->Struct.fields[field_count+0] = len_field;
add_entity(ctx, scope, nullptr, len_field);
add_entity_use(ctx, nullptr, len_field);
if (soa_kind == StructSoa_Dynamic) {
Entity *cap_field = alloc_entity_field(scope, empty_token, t_int, false, cast(i32)field_count+1);
soa_struct->Struct.fields[field_count+1] = cap_field;
add_entity(ctx, scope, nullptr, cap_field);
add_entity_use(ctx, nullptr, cap_field);
Token token = {};
token.string = str_lit("allocator");
init_mem_allocator(ctx->checker);
Entity *allocator_field = alloc_entity_field(scope, token, t_allocator, false, cast(i32)field_count+2);
soa_struct->Struct.fields[field_count+2] = allocator_field;
add_entity(ctx, scope, nullptr, allocator_field);
add_entity_use(ctx, nullptr, allocator_field);
}
}
Token token = {};
token.string = str_lit("Base_Type");
Entity *base_type_entity = alloc_entity_type_name(scope, token, elem, EntityState_Resolved);
add_entity(ctx, scope, nullptr, base_type_entity);
add_type_info_type(ctx, soa_struct);
return soa_struct;
}
gb_internal Type *make_soa_struct_fixed(CheckerContext *ctx, Ast *array_typ_expr, Ast *elem_expr, Type *elem, i64 count, Type *generic_type) {
return make_soa_struct_internal(ctx, array_typ_expr, elem_expr, elem, count, generic_type, StructSoa_Fixed);
}
gb_internal Type *make_soa_struct_slice(CheckerContext *ctx, Ast *array_typ_expr, Ast *elem_expr, Type *elem) {
return make_soa_struct_internal(ctx, array_typ_expr, elem_expr, elem, -1, nullptr, StructSoa_Slice);
}
gb_internal Type *make_soa_struct_dynamic_array(CheckerContext *ctx, Ast *array_typ_expr, Ast *elem_expr, Type *elem) {
return make_soa_struct_internal(ctx, array_typ_expr, elem_expr, elem, -1, nullptr, StructSoa_Dynamic);
}
gb_internal bool check_type_internal(CheckerContext *ctx, Ast *e, Type **type, Type *named_type) {
GB_ASSERT_NOT_NULL(type);
if (e == nullptr) {
*type = t_invalid;
return true;
}
switch (e->kind) {
case_ast_node(i, Ident, e);
Operand o = {};
Entity *entity = check_ident(ctx, &o, e, named_type, nullptr, false);
gb_unused(entity);
gbString err_str = nullptr;
defer (gb_string_free(err_str));
switch (o.mode) {
case Addressing_Invalid:
break;
case Addressing_Type: {
*type = o.type;
if (!ctx->in_polymorphic_specialization) {
Type *t = base_type(o.type);
if (t != nullptr && is_type_polymorphic_record_unspecialized(t)) {
err_str = expr_to_string(e);
error(e, "Invalid use of a non-specialized polymorphic type '%s'", err_str);
return true;
}
}
return true;
}
case Addressing_NoValue:
err_str = expr_to_string(e);
error(e, "'%s' used as a type", err_str);
break;
default:
err_str = expr_to_string(e);
error(e, "'%s' used as a type when not a type", err_str);
break;
}
case_end;
case_ast_node(ht, HelperType, e);
return check_type_internal(ctx, ht->type, type, named_type);
case_end;
case_ast_node(dt, DistinctType, e);
error(e, "Invalid use of a distinct type");
// NOTE(bill): Treat it as a HelperType to remove errors
return check_type_internal(ctx, dt->type, type, named_type);
case_end;
case_ast_node(tt, TypeidType, e);
e->tav.mode = Addressing_Type;
e->tav.type = t_typeid;
*type = t_typeid;
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(pt, PolyType, e);
Ast *ident = pt->type;
if (ident->kind != Ast_Ident) {
error(ident, "Expected an identifier after the $");
*type = t_invalid;
return false;
}
Token token = ident->Ident.token;
Type *specific = nullptr;
if (pt->specialization != nullptr) {
CheckerContext c = *ctx;
c.in_polymorphic_specialization = true;
Ast *s = pt->specialization;
specific = check_type(&c, s);
}
Type *t = alloc_type_generic(ctx->scope, 0, token.string, specific);
if (ctx->allow_polymorphic_types) {
Scope *ps = ctx->polymorphic_scope;
Scope *s = ctx->scope;
Scope *entity_scope = s;
if (ps != nullptr && ps != s) {
// TODO(bill): Is this check needed?
// GB_ASSERT_MSG(is_scope_an_ancestor(ps, s) >= 0);
entity_scope = ps;
}
Entity *e = alloc_entity_type_name(entity_scope, token, t);
t->Generic.entity = e;
e->TypeName.is_type_alias = true;
e->state = EntityState_Resolved;
add_entity(ctx, ps, ident, e);
add_entity(ctx, s, ident, e);
} else {
error(ident, "Invalid use of a polymorphic parameter '$%.*s'", LIT(token.string));
*type = t_invalid;
return false;
}
*type = t;
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(se, SelectorExpr, e);
Operand o = {};
check_selector(ctx, &o, e, nullptr);
gbString err_str;
switch (o.mode) {
case Addressing_Invalid:
break;
case Addressing_Type:
GB_ASSERT(o.type != nullptr);
*type = o.type;
return true;
case Addressing_NoValue:
err_str = expr_to_string(e);
error(e, "'%s' used as a type", err_str);
gb_string_free(err_str);
break;
default:
err_str = expr_to_string(e);
error(e, "'%s' is not a type", err_str);
gb_string_free(err_str);
break;
}
case_end;
case_ast_node(pe, ParenExpr, e);
*type = check_type_expr(ctx, pe->expr, named_type);
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(ue, UnaryExpr, e);
switch (ue->op.kind) {
case Token_Pointer:
{
Type *elem = check_type(ctx, ue->expr);
*type = alloc_type_pointer(elem);
set_base_type(named_type, *type);
return true;
}
}
case_end;
case_ast_node(pt, PointerType, e);
CheckerContext c = *ctx;
c.type_path = new_checker_type_path();
defer (destroy_checker_type_path(c.type_path));
Type *elem = t_invalid;
Operand o = {};
check_expr_or_type(&c, &o, pt->type);
if (o.mode != Addressing_Invalid && o.mode != Addressing_Type) {
// NOTE(bill): call check_type_expr again to get a consistent error message
begin_error_block();
elem = check_type_expr(&c, pt->type, nullptr);
if (o.mode == Addressing_Variable) {
gbString s = expr_to_string(pt->type);
error_line("\tSuggestion: ^ is used for pointer types, did you mean '&%s'?\n", s);
gb_string_free(s);
}
end_error_block();
} else {
elem = o.type;
}
if (pt->tag != nullptr) {
GB_ASSERT(pt->tag->kind == Ast_BasicDirective);
String name = pt->tag->BasicDirective.name.string;
if (name == "soa") {
// TODO(bill): generic #soa pointers
if (is_type_soa_struct(elem)) {
*type = alloc_type_soa_pointer(elem);
} else {
error(pt->tag, "#soa pointers require an #soa record type as the element");
*type = alloc_type_pointer(elem);
}
} else {
error(pt->tag, "Invalid tag applied to pointer, got #%.*s", LIT(name));
*type = alloc_type_pointer(elem);
}
} else {
*type = alloc_type_pointer(elem);
}
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(pt, MultiPointerType, e);
*type = alloc_type_multi_pointer(check_type(ctx, pt->type));
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(rt, RelativeType, e);
GB_ASSERT(rt->tag->kind == Ast_CallExpr);
ast_node(ce, CallExpr, rt->tag);
Type *base_integer = nullptr;
if (ce->args.count != 1) {
error(rt->type, "#relative expected 1 type argument, got %td", ce->args.count);
} else {
base_integer = check_type(ctx, ce->args[0]);
if (!is_type_integer(base_integer)) {
error(rt->type, "#relative base types must be an integer");
base_integer = nullptr;
} else if (type_size_of(base_integer) > 64) {
error(rt->type, "#relative base integer types be less than or equal to 64-bits");
base_integer = nullptr;
}
}
Type *relative_type = nullptr;
Type *base_type = check_type(ctx, rt->type);
if (!is_type_pointer(base_type) && !is_type_slice(base_type)) {
error(rt->type, "#relative types can only be a pointer or slice");
relative_type = base_type;
} else if (base_integer == nullptr) {
relative_type = base_type;
} else {
if (is_type_pointer(base_type)) {
relative_type = alloc_type_relative_pointer(base_type, base_integer);
} else if (is_type_slice(base_type)) {
relative_type = alloc_type_relative_slice(base_type, base_integer);
}
}
GB_ASSERT(relative_type != nullptr);
*type = relative_type;
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(at, ArrayType, e);
if (at->count != nullptr) {
Operand o = {};
i64 count = check_array_count(ctx, &o, at->count);
Type *generic_type = nullptr;
Type *elem = check_type_expr(ctx, at->elem, nullptr);
if (o.mode == Addressing_Type && o.type->kind == Type_Generic) {
generic_type = o.type;
} else if (o.mode == Addressing_Type && is_type_enum(o.type)) {
Type *index = o.type;
Type *bt = base_type(index);
GB_ASSERT(bt->kind == Type_Enum);
Type *t = alloc_type_enumerated_array(elem, index, bt->Enum.min_value, bt->Enum.max_value, Token_Invalid);
bool is_sparse = false;
if (at->tag != nullptr) {
GB_ASSERT(at->tag->kind == Ast_BasicDirective);
String name = at->tag->BasicDirective.name.string;
if (name == "sparse") {
is_sparse = true;
} else {
error(at->tag, "Invalid tag applied to an enumerated array, got #%.*s", LIT(name));
}
}
if (!is_sparse && t->EnumeratedArray.count > bt->Enum.fields.count) {
error(e, "Non-contiguous enumeration used as an index in an enumerated array");
long long ea_count = cast(long long)t->EnumeratedArray.count;
long long enum_count = cast(long long)bt->Enum.fields.count;
error_line("\tenumerated array length: %lld\n", ea_count);
error_line("\tenum field count: %lld\n", enum_count);
error_line("\tSuggestion: prepend #sparse to the enumerated array to allow for non-contiguous elements\n");
if (2*enum_count < ea_count) {
error_line("\tWarning: the number of named elements is much smaller than the length of the array, are you sure this is what you want?\n");
error_line("\t this warning will be removed if #sparse is applied\n");
}
}
t->EnumeratedArray.is_sparse = is_sparse;
*type = t;
goto array_end;
}
if (count < 0) {
error(at->count, "? can only be used in conjuction with compound literals");
count = 0;
}
if (at->tag != nullptr) {
GB_ASSERT(at->tag->kind == Ast_BasicDirective);
String name = at->tag->BasicDirective.name.string;
if (name == "soa") {
*type = make_soa_struct_fixed(ctx, e, at->elem, elem, count, generic_type);
} else if (name == "simd") {
if (!is_type_valid_vector_elem(elem) && !is_type_polymorphic(elem)) {
gbString str = type_to_string(elem);
error(at->elem, "Invalid element type for #simd, expected an integer, float, or boolean with no specific endianness, got '%s'", str);
gb_string_free(str);
*type = alloc_type_array(elem, count, generic_type);
goto array_end;
}
if (generic_type != nullptr) {
// Ignore
} else if (count < 1 || !is_power_of_two(count)) {
error(at->count, "Invalid length for #simd, expected a power of two length, got '%lld'", cast(long long)count);
*type = alloc_type_array(elem, count, generic_type);
goto array_end;
}
*type = alloc_type_simd_vector(count, elem, generic_type);
if (count > SIMD_ELEMENT_COUNT_MAX) {
error(at->count, "#simd support a maximum element count of %d, got %lld", SIMD_ELEMENT_COUNT_MAX, cast(long long)count);
}
} else {
error(at->tag, "Invalid tag applied to array, got #%.*s", LIT(name));
*type = alloc_type_array(elem, count, generic_type);
}
} else {
*type = alloc_type_array(elem, count, generic_type);
}
} else {
Type *elem = check_type(ctx, at->elem);
if (at->tag != nullptr) {
GB_ASSERT(at->tag->kind == Ast_BasicDirective);
String name = at->tag->BasicDirective.name.string;
if (name == "soa") {
*type = make_soa_struct_slice(ctx, e, at->elem, elem);
} else {
error(at->tag, "Invalid tag applied to array, got #%.*s", LIT(name));
*type = alloc_type_slice(elem);
}
} else {
*type = alloc_type_slice(elem);
}
}
array_end:
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(dat, DynamicArrayType, e);
Type *elem = check_type(ctx, dat->elem);
if (dat->tag != nullptr) {
GB_ASSERT(dat->tag->kind == Ast_BasicDirective);
String name = dat->tag->BasicDirective.name.string;
if (name == "soa") {
*type = make_soa_struct_dynamic_array(ctx, e, dat->elem, elem);
} else {
error(dat->tag, "Invalid tag applied to dynamic array, got #%.*s", LIT(name));
*type = alloc_type_dynamic_array(elem);
}
} else {
*type = alloc_type_dynamic_array(elem);
}
set_base_type(named_type, *type);
return true;
case_end;
case_ast_node(st, StructType, e);
CheckerContext c = *ctx;
c.in_polymorphic_specialization = false;
c.type_level += 1;
*type = alloc_type_struct();
set_base_type(named_type, *type);
check_open_scope(&c, e);
check_struct_type(&c, *type, e, nullptr, named_type);
check_close_scope(&c);
(*type)->Struct.node = e;
return true;
case_end;
case_ast_node(ut, UnionType, e);
CheckerContext c = *ctx;
c.in_polymorphic_specialization = false;
c.type_level += 1;
*type = alloc_type_union();
set_base_type(named_type, *type);
check_open_scope(&c, e);
check_union_type(&c, *type, e, nullptr, named_type);
check_close_scope(&c);
(*type)->Union.node = e;
return true;
case_end;
case_ast_node(et, EnumType, e);
bool ips = ctx->in_polymorphic_specialization;
defer (ctx->in_polymorphic_specialization = ips);
ctx->in_polymorphic_specialization = false;
ctx->in_enum_type = true;
*type = alloc_type_enum();
set_base_type(named_type, *type);
check_open_scope(ctx, e);
check_enum_type(ctx, *type, named_type, e);
check_close_scope(ctx);
(*type)->Enum.node = e;
ctx->in_enum_type = false;
return true;
case_end;
case_ast_node(bs, BitSetType, e);
*type = alloc_type_bit_set();
set_base_type(named_type, *type);
check_bit_set_type(ctx, *type, named_type, e);
return true;
case_end;
case_ast_node(pt, ProcType, e);
bool ips = ctx->in_polymorphic_specialization;
defer (ctx->in_polymorphic_specialization = ips);
ctx->in_polymorphic_specialization = false;
*type = alloc_type(Type_Proc);
set_base_type(named_type, *type);
check_open_scope(ctx, e);
check_procedure_type(ctx, *type, e);
check_close_scope(ctx);
return true;
case_end;
case_ast_node(mt, MapType, e);
bool ips = ctx->in_polymorphic_specialization;
defer (ctx->in_polymorphic_specialization = ips);
ctx->in_polymorphic_specialization = false;
*type = alloc_type(Type_Map);
set_base_type(named_type, *type);
check_map_type(ctx, *type, e);
return true;
case_end;
case_ast_node(ce, CallExpr, e);
Operand o = {};
check_expr_or_type(ctx, &o, e);
if (o.mode == Addressing_Type) {
*type = o.type;
set_base_type(named_type, *type);
return true;
}
case_end;
case_ast_node(te, TernaryIfExpr, e);
Operand o = {};
check_expr_or_type(ctx, &o, e);
if (o.mode == Addressing_Type) {
*type = o.type;
set_base_type(named_type, *type);
return true;
}
case_end;
case_ast_node(te, TernaryWhenExpr, e);
Operand o = {};
check_expr_or_type(ctx, &o, e);
if (o.mode == Addressing_Type) {
*type = o.type;
set_base_type(named_type, *type);
return true;
}
case_end;
case_ast_node(mt, MatrixType, e);
check_matrix_type(ctx, type, e);
set_base_type(named_type, *type);
return true;
case_end;
}
*type = t_invalid;
return false;
}
gb_internal Type *check_type(CheckerContext *ctx, Ast *e) {
CheckerContext c = *ctx;
c.type_path = new_checker_type_path();
defer (destroy_checker_type_path(c.type_path));
return check_type_expr(&c, e, nullptr);
}
gb_internal Type *check_type_expr(CheckerContext *ctx, Ast *e, Type *named_type) {
Type *type = nullptr;
bool ok = check_type_internal(ctx, e, &type, named_type);
if (!ok) {
gbString err_str = expr_to_string(e);
error(e, "'%s' is not a type", err_str);
gb_string_free(err_str);
type = t_invalid;
}
if (type == nullptr) {
type = t_invalid;
}
if (type->kind == Type_Named &&
type->Named.base == nullptr) {
// IMPORTANT TODO(bill): Is this a serious error?!
#if 0
error(e, "Invalid type definition of '%.*s'", LIT(type->Named.name));
#endif
type->Named.base = t_invalid;
}
if (is_type_polymorphic(type)) {
type->flags |= TypeFlag_Polymorphic;
} else if (is_type_polymorphic(type, true)) {
type->flags |= TypeFlag_PolySpecialized;
}
#if 0
if (!ctx->allow_polymorphic_types && is_type_polymorphic(type)) {
gbString str = type_to_string(type);
error(e, "Invalid use of a polymorphic type '%s'", str);
gb_string_free(str);
type = t_invalid;
}
#endif
if (is_type_typed(type)) {
add_type_and_value(ctx, e, Addressing_Type, type, empty_exact_value);
} else {
gbString name = type_to_string(type);
error(e, "Invalid type definition of %s", name);
gb_string_free(name);
type = t_invalid;
}
set_base_type(named_type, type);
check_rtti_type_disallowed(e, type, "Use of a type, %s, which has been disallowed");
return type;
}
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