gb_internal isize lb_type_info_index(CheckerInfo *info, Type *type, bool err_on_not_found=true) { auto *set = &info->minimum_dependency_type_info_set; isize index = type_info_index(info, type, err_on_not_found); if (index >= 0) { auto *found = map_get(set, index); if (found) { GB_ASSERT(*found >= 0); return *found + 1; } } if (err_on_not_found) { gb_printf_err("NOT FOUND lb_type_info_index:\n\t%s\n\t@ index %td\n\tmax count: %u\nFound:\n", type_to_string(type), index, set->count); for (auto const &entry : *set) { isize type_info_index = entry.key; gb_printf_err("\t%s\n", type_to_string(info->type_info_types[type_info_index])); } GB_PANIC("NOT FOUND"); } return -1; } gb_internal u64 lb_typeid_kind(lbModule *m, Type *type, u64 id=0) { GB_ASSERT(!build_context.no_rtti); type = default_type(type); if (id == 0) { id = cast(u64)lb_type_info_index(m->info, type); } u64 kind = Typeid_Invalid; Type *bt = base_type(type); TypeKind tk = bt->kind; switch (tk) { case Type_Basic: { u32 flags = bt->Basic.flags; if (flags & BasicFlag_Boolean) kind = Typeid_Boolean; if (flags & BasicFlag_Integer) kind = Typeid_Integer; if (flags & BasicFlag_Unsigned) kind = Typeid_Integer; if (flags & BasicFlag_Float) kind = Typeid_Float; if (flags & BasicFlag_Complex) kind = Typeid_Complex; if (flags & BasicFlag_Pointer) kind = Typeid_Pointer; if (flags & BasicFlag_String) kind = Typeid_String; if (flags & BasicFlag_Rune) kind = Typeid_Rune; } break; case Type_Pointer: kind = Typeid_Pointer; break; case Type_MultiPointer: kind = Typeid_Multi_Pointer; break; case Type_Array: kind = Typeid_Array; break; case Type_Matrix: kind = Typeid_Matrix; break; case Type_EnumeratedArray: kind = Typeid_Enumerated_Array; break; case Type_Slice: kind = Typeid_Slice; break; case Type_DynamicArray: kind = Typeid_Dynamic_Array; break; case Type_Map: kind = Typeid_Map; break; case Type_Struct: kind = Typeid_Struct; break; case Type_Enum: kind = Typeid_Enum; break; case Type_Union: kind = Typeid_Union; break; case Type_Tuple: kind = Typeid_Tuple; break; case Type_Proc: kind = Typeid_Procedure; break; case Type_BitSet: kind = Typeid_Bit_Set; break; case Type_SimdVector: kind = Typeid_Simd_Vector; break; case Type_RelativePointer: kind = Typeid_Relative_Pointer; break; case Type_RelativeMultiPointer: kind = Typeid_Relative_Multi_Pointer; break; case Type_SoaPointer: kind = Typeid_SoaPointer; break; case Type_BitField: kind = Typeid_Bit_Field; break; } return kind; } gb_internal lbValue lb_typeid(lbModule *m, Type *type) { GB_ASSERT(!build_context.no_rtti); type = default_type(type); u64 id = cast(u64)lb_type_info_index(m->info, type); GB_ASSERT(id >= 0); u64 kind = lb_typeid_kind(m, type, id); u64 named = is_type_named(type) && type->kind != Type_Basic; u64 special = 0; u64 reserved = 0; if (is_type_cstring(type)) { special = 1; } else if (is_type_integer(type) && !is_type_unsigned(type)) { special = 1; } u64 data = 0; if (build_context.ptr_size == 4) { GB_ASSERT(id <= (1u<<24u)); data |= (id &~ (1u<<24)) << 0u; // index data |= (kind &~ (1u<<5)) << 24u; // kind data |= (named &~ (1u<<1)) << 29u; // named data |= (special &~ (1u<<1)) << 30u; // special data |= (reserved &~ (1u<<1)) << 31u; // reserved } else { GB_ASSERT(build_context.ptr_size == 8); GB_ASSERT(id <= (1ull<<56u)); data |= (id &~ (1ull<<56)) << 0ul; // index data |= (kind &~ (1ull<<5)) << 56ull; // kind data |= (named &~ (1ull<<1)) << 61ull; // named data |= (special &~ (1ull<<1)) << 62ull; // special data |= (reserved &~ (1ull<<1)) << 63ull; // reserved } lbValue res = {}; res.value = LLVMConstInt(lb_type(m, t_typeid), data, false); res.type = t_typeid; return res; } gb_internal lbValue lb_type_info(lbProcedure *p, Type *type) { GB_ASSERT(!build_context.no_rtti); type = default_type(type); lbModule *m = p->module; isize index = lb_type_info_index(m->info, type); GB_ASSERT(index >= 0); lbValue global = lb_global_type_info_data_ptr(m); lbValue ptr = lb_emit_array_epi(p, global, index); return lb_emit_load(p, ptr); } gb_internal LLVMTypeRef lb_get_procedure_raw_type(lbModule *m, Type *type) { return lb_type_internal_for_procedures_raw(m, type); } gb_internal lbValue lb_const_array_epi(lbModule *m, lbValue value, isize index) { GB_ASSERT(is_type_pointer(value.type)); Type *type = type_deref(value.type); LLVMValueRef indices[2] = { LLVMConstInt(lb_type(m, t_int), 0, false), LLVMConstInt(lb_type(m, t_int), cast(unsigned long long)index, false), }; LLVMTypeRef llvm_type = lb_type(m, type); lbValue res = {}; Type *ptr = base_array_type(type); res.type = alloc_type_pointer(ptr); GB_ASSERT(LLVMIsConstant(value.value)); res.value = LLVMConstGEP2(llvm_type, value.value, indices, gb_count_of(indices)); return res; } gb_internal lbValue lb_type_info_member_types_offset(lbModule *m, isize count, i64 *offset_=nullptr) { GB_ASSERT(m == &m->gen->default_module); if (offset_) *offset_ = lb_global_type_info_member_types_index; lbValue offset = lb_const_array_epi(m, lb_global_type_info_member_types.addr, lb_global_type_info_member_types_index); lb_global_type_info_member_types_index += cast(i32)count; return offset; } gb_internal lbValue lb_type_info_member_names_offset(lbModule *m, isize count, i64 *offset_=nullptr) { GB_ASSERT(m == &m->gen->default_module); if (offset_) *offset_ = lb_global_type_info_member_names_index; lbValue offset = lb_const_array_epi(m, lb_global_type_info_member_names.addr, lb_global_type_info_member_names_index); lb_global_type_info_member_names_index += cast(i32)count; return offset; } gb_internal lbValue lb_type_info_member_offsets_offset(lbModule *m, isize count, i64 *offset_=nullptr) { GB_ASSERT(m == &m->gen->default_module); if (offset_) *offset_ = lb_global_type_info_member_offsets_index; lbValue offset = lb_const_array_epi(m, lb_global_type_info_member_offsets.addr, lb_global_type_info_member_offsets_index); lb_global_type_info_member_offsets_index += cast(i32)count; return offset; } gb_internal lbValue lb_type_info_member_usings_offset(lbModule *m, isize count, i64 *offset_=nullptr) { GB_ASSERT(m == &m->gen->default_module); if (offset_) *offset_ = lb_global_type_info_member_usings_index; lbValue offset = lb_const_array_epi(m, lb_global_type_info_member_usings.addr, lb_global_type_info_member_usings_index); lb_global_type_info_member_usings_index += cast(i32)count; return offset; } gb_internal lbValue lb_type_info_member_tags_offset(lbModule *m, isize count, i64 *offset_=nullptr) { GB_ASSERT(m == &m->gen->default_module); if (offset_) *offset_ = lb_global_type_info_member_tags_index; lbValue offset = lb_const_array_epi(m, lb_global_type_info_member_tags.addr, lb_global_type_info_member_tags_index); lb_global_type_info_member_tags_index += cast(i32)count; return offset; } gb_internal LLVMTypeRef *lb_setup_modified_types_for_type_info(lbModule *m, isize max_type_info_count) { LLVMTypeRef *element_types = gb_alloc_array(heap_allocator(), LLVMTypeRef, max_type_info_count); defer (gb_free(heap_allocator(), element_types)); auto entries_handled = slice_make(heap_allocator(), max_type_info_count); defer (gb_free(heap_allocator(), entries_handled.data)); entries_handled[0] = true; element_types[0] = lb_type(m, t_type_info); Type *tibt = base_type(t_type_info); GB_ASSERT(tibt->kind == Type_Struct); Type *ut = base_type(tibt->Struct.fields[tibt->Struct.fields.count-1]->type); GB_ASSERT(ut->kind == Type_Union); GB_ASSERT(tibt->Struct.fields.count == 5); LLVMTypeRef stypes[6] = {}; stypes[0] = lb_type(m, tibt->Struct.fields[0]->type); stypes[1] = lb_type(m, tibt->Struct.fields[1]->type); stypes[2] = lb_type(m, tibt->Struct.fields[2]->type); isize variant_index = 0; if (build_context.int_size == 8) { stypes[3] = lb_type(m, t_i32); // padding stypes[4] = lb_type(m, tibt->Struct.fields[3]->type); variant_index = 5; } else { stypes[3] = lb_type(m, tibt->Struct.fields[3]->type); variant_index = 4; } LLVMTypeRef *modified_types = gb_alloc_array(heap_allocator(), LLVMTypeRef, Typeid__COUNT); GB_ASSERT(Typeid__COUNT == ut->Union.variants.count); modified_types[0] = element_types[0]; i64 tag_offset = ut->Union.variant_block_size; LLVMTypeRef tag = lb_type(m, union_tag_type(ut)); for_array(i, ut->Union.variants) { Type *t = ut->Union.variants[i]; LLVMTypeRef padding = llvm_array_type(lb_type(m, t_u8), tag_offset-type_size_of(t)); LLVMTypeRef vtypes[3] = {}; vtypes[0] = lb_type(m, t); vtypes[1] = padding; vtypes[2] = tag; LLVMTypeRef variant_type = LLVMStructType(vtypes, gb_count_of(vtypes), true); stypes[variant_index] = variant_type; LLVMTypeRef modified_type = LLVMStructType(stypes, cast(unsigned)(variant_index+1), false); modified_types[i] = modified_type; } for (isize i = 0; i < Typeid__COUNT; i++) { GB_ASSERT_MSG(modified_types[i] != nullptr, "%td", ut->Union.variants.count); } return modified_types; } gb_internal void lb_setup_type_info_data_giant_array(lbModule *m, i64 global_type_info_data_entity_count) { // NOTE(bill): Setup type_info data auto const &ADD_GLOBAL_TYPE_INFO_ENTRY = [](lbModule *m, LLVMTypeRef type, isize index) -> LLVMValueRef { char name[64] = {}; gb_snprintf(name, 63, "__$ti-%lld", cast(long long)index); LLVMValueRef g = LLVMAddGlobal(m->mod, type, name); LLVMSetLinkage(g, LLVMInternalLinkage); LLVMSetUnnamedAddress(g, LLVMGlobalUnnamedAddr); LLVMSetGlobalConstant(g, true); return g; }; CheckerInfo *info = m->info; // Useful types Entity *type_info_flags_entity = find_core_entity(info->checker, str_lit("Type_Info_Flags")); Type *t_type_info_flags = type_info_flags_entity->type; gb_unused(t_type_info_flags); Type *ut = base_type(t_type_info); GB_ASSERT(ut->kind == Type_Struct); ut = base_type(ut->Struct.fields[ut->Struct.fields.count-1]->type); GB_ASSERT(ut->kind == Type_Union); auto entries_handled = slice_make(heap_allocator(), cast(isize)global_type_info_data_entity_count); defer (gb_free(heap_allocator(), entries_handled.data)); entries_handled[0] = true; LLVMValueRef *giant_const_values = gb_alloc_array(heap_allocator(), LLVMValueRef, global_type_info_data_entity_count); defer (gb_free(heap_allocator(), giant_const_values)); // zero value is just zero data giant_const_values[0] = ADD_GLOBAL_TYPE_INFO_ENTRY(m, lb_type(m, t_type_info), 0); LLVMSetInitializer(giant_const_values[0], LLVMConstNull(lb_type(m, t_type_info))); LLVMTypeRef *modified_types = lb_setup_modified_types_for_type_info(m, global_type_info_data_entity_count); defer (gb_free(heap_allocator(), modified_types)); for_array(type_info_type_index, info->type_info_types) { Type *t = info->type_info_types[type_info_type_index]; if (t == nullptr || t == t_invalid) { continue; } isize entry_index = lb_type_info_index(info, t, false); if (entry_index <= 0) { continue; } if (entries_handled[entry_index]) { continue; } entries_handled[entry_index] = true; LLVMTypeRef stype = nullptr; if (t->kind == Type_Named) { stype = modified_types[0]; } else { stype = modified_types[lb_typeid_kind(m, t)]; } giant_const_values[entry_index] = ADD_GLOBAL_TYPE_INFO_ENTRY(m, stype, entry_index); } for (isize i = 1; i < global_type_info_data_entity_count; i++) { entries_handled[i] = false; } LLVMValueRef *small_const_values = gb_alloc_array(heap_allocator(), LLVMValueRef, 6); defer (gb_free(heap_allocator(), small_const_values)); #define type_info_allocate_values(name) \ LLVMValueRef *name##_values = gb_alloc_array(heap_allocator(), LLVMValueRef, type_deref(name.addr.type)->Array.count); \ defer (gb_free(heap_allocator(), name##_values)); \ defer ({ \ Type *at = type_deref(name.addr.type); \ LLVMTypeRef elem = lb_type(m, at->Array.elem); \ for (i64 i = 0; i < at->Array.count; i++) { \ if ((name##_values)[i] == nullptr) { \ (name##_values)[i] = LLVMConstNull(elem); \ } \ } \ LLVMSetInitializer(name.addr.value, llvm_const_array(elem, name##_values, at->Array.count)); \ }) type_info_allocate_values(lb_global_type_info_member_types); type_info_allocate_values(lb_global_type_info_member_names); type_info_allocate_values(lb_global_type_info_member_offsets); type_info_allocate_values(lb_global_type_info_member_usings); type_info_allocate_values(lb_global_type_info_member_tags); auto const get_type_info_ptr = [&](lbModule *m, Type *type) -> LLVMValueRef { type = default_type(type); isize index = lb_type_info_index(m->info, type); GB_ASSERT(index >= 0); return giant_const_values[index]; }; for_array(type_info_type_index, info->type_info_types) { Type *t = info->type_info_types[type_info_type_index]; if (t == nullptr || t == t_invalid) { continue; } isize entry_index = lb_type_info_index(info, t, false); if (entry_index <= 0) { continue; } if (entries_handled[entry_index]) { continue; } entries_handled[entry_index] = true; LLVMTypeRef stype = nullptr; if (t->kind == Type_Named) { stype = modified_types[0]; } else { stype = modified_types[lb_typeid_kind(m, t)]; } i64 size = type_size_of(t); i64 align = type_align_of(t); u32 flags = type_info_flags_of_type(t); lbValue id = lb_typeid(m, t); GB_ASSERT_MSG(align != 0, "%lld %s", align, type_to_string(t)); lbValue type_info_flags = lb_const_int(m, t_type_info_flags, flags); for (isize i = 0; i < 6; i++) { small_const_values[i] = nullptr; } small_const_values[0] = LLVMConstInt(lb_type(m, t_int), size, true); small_const_values[1] = LLVMConstInt(lb_type(m, t_int), align, true); small_const_values[2] = type_info_flags.value; unsigned variant_index = 0; if (build_context.int_size == 8) { small_const_values[3] = LLVMConstNull(LLVMStructGetTypeAtIndex(stype, 3)); small_const_values[4] = id.value; variant_index = 5; } else { small_const_values[3] = id.value; variant_index = 4; } LLVMTypeRef full_variant_type = LLVMStructGetTypeAtIndex(stype, variant_index); unsigned full_variant_elem_count = LLVMCountStructElementTypes(full_variant_type); if (full_variant_elem_count != 2) { GB_ASSERT_MSG(LLVMCountStructElementTypes(full_variant_type) == 3, "%lld %s", entry_index, type_to_string(t)); // blob, padding, tag } LLVMValueRef variant_value = nullptr; Type *tag_type = nullptr; switch (t->kind) { case Type_Named: { tag_type = t_type_info_named; LLVMValueRef pkg_name = nullptr; if (t->Named.type_name->pkg) { pkg_name = lb_const_string(m, t->Named.type_name->pkg->name).value; } else { pkg_name = LLVMConstNull(lb_type(m, t_string)); } String proc_name = {}; if (t->Named.type_name->parent_proc_decl) { DeclInfo *decl = t->Named.type_name->parent_proc_decl; if (decl->entity && decl->entity->kind == Entity_Procedure) { proc_name = decl->entity->token.string; } } TokenPos pos = t->Named.type_name->token.pos; lbValue loc = lb_const_source_code_location_const(m, proc_name, pos); LLVMValueRef vals[4] = { lb_const_string(m, t->Named.type_name->token.string).value, get_type_info_ptr(m, t->Named.base), pkg_name, loc.value }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Basic: switch (t->Basic.kind) { case Basic_bool: case Basic_b8: case Basic_b16: case Basic_b32: case Basic_b64: tag_type = t_type_info_boolean; break; case Basic_i8: case Basic_u8: case Basic_i16: case Basic_u16: case Basic_i32: case Basic_u32: case Basic_i64: case Basic_u64: case Basic_i128: case Basic_u128: case Basic_i16le: case Basic_u16le: case Basic_i32le: case Basic_u32le: case Basic_i64le: case Basic_u64le: case Basic_i128le: case Basic_u128le: case Basic_i16be: case Basic_u16be: case Basic_i32be: case Basic_u32be: case Basic_i64be: case Basic_u64be: case Basic_i128be: case Basic_u128be: case Basic_int: case Basic_uint: case Basic_uintptr: { tag_type = t_type_info_integer; lbValue is_signed = lb_const_bool(m, t_bool, (t->Basic.flags & BasicFlag_Unsigned) == 0); // NOTE(bill): This is matches the runtime layout u8 endianness_value = 0; if (t->Basic.flags & BasicFlag_EndianLittle) { endianness_value = 1; } else if (t->Basic.flags & BasicFlag_EndianBig) { endianness_value = 2; } lbValue endianness = lb_const_int(m, t_u8, endianness_value); LLVMValueRef vals[2] = { is_signed.value, endianness.value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Basic_rune: tag_type = t_type_info_rune; break; case Basic_f16: case Basic_f32: case Basic_f64: case Basic_f16le: case Basic_f32le: case Basic_f64le: case Basic_f16be: case Basic_f32be: case Basic_f64be: { tag_type = t_type_info_float; // NOTE(bill): This is matches the runtime layout u8 endianness_value = 0; if (t->Basic.flags & BasicFlag_EndianLittle) { endianness_value = 1; } else if (t->Basic.flags & BasicFlag_EndianBig) { endianness_value = 2; } lbValue endianness = lb_const_int(m, t_u8, endianness_value); LLVMValueRef vals[1] = { endianness.value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Basic_complex32: case Basic_complex64: case Basic_complex128: tag_type = t_type_info_complex; break; case Basic_quaternion64: case Basic_quaternion128: case Basic_quaternion256: tag_type = t_type_info_quaternion; break; case Basic_rawptr: tag_type = t_type_info_pointer; break; case Basic_string: tag_type = t_type_info_string; break; case Basic_cstring: { tag_type = t_type_info_string; LLVMValueRef vals[1] = { lb_const_bool(m, t_bool, true).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Basic_any: tag_type = t_type_info_any; break; case Basic_typeid: tag_type = t_type_info_typeid; break; } break; case Type_Pointer: { tag_type = t_type_info_pointer; LLVMValueRef vals[1] = { get_type_info_ptr(m, t->Pointer.elem), }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_MultiPointer: { tag_type = t_type_info_multi_pointer; LLVMValueRef vals[1] = { get_type_info_ptr(m, t->MultiPointer.elem), }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_SoaPointer: { tag_type = t_type_info_soa_pointer; LLVMValueRef vals[1] = { get_type_info_ptr(m, t->SoaPointer.elem), }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Array: { tag_type = t_type_info_array; i64 ez = type_size_of(t->Array.elem); LLVMValueRef vals[3] = { get_type_info_ptr(m, t->Array.elem), lb_const_int(m, t_int, ez).value, lb_const_int(m, t_int, t->Array.count).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_EnumeratedArray: { tag_type = t_type_info_enumerated_array; LLVMValueRef vals[7] = { get_type_info_ptr(m, t->EnumeratedArray.elem), get_type_info_ptr(m, t->EnumeratedArray.index), lb_const_int(m, t_int, type_size_of(t->EnumeratedArray.elem)).value, lb_const_int(m, t_int, t->EnumeratedArray.count).value, // Unions lb_const_value(m, t_type_info_enum_value, *t->EnumeratedArray.min_value).value, lb_const_value(m, t_type_info_enum_value, *t->EnumeratedArray.max_value).value, lb_const_bool(m, t_bool, t->EnumeratedArray.is_sparse).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_DynamicArray: { tag_type = t_type_info_dynamic_array; LLVMValueRef vals[2] = { get_type_info_ptr(m, t->DynamicArray.elem), lb_const_int(m, t_int, type_size_of(t->DynamicArray.elem)).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Slice: { tag_type = t_type_info_slice; LLVMValueRef vals[2] = { get_type_info_ptr(m, t->Slice.elem), lb_const_int(m, t_int, type_size_of(t->Slice.elem)).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Proc: { tag_type = t_type_info_procedure; LLVMValueRef params = LLVMConstNull(lb_type(m, t_type_info_ptr)); LLVMValueRef results = LLVMConstNull(lb_type(m, t_type_info_ptr)); if (t->Proc.params != nullptr) { params = get_type_info_ptr(m, t->Proc.params); } if (t->Proc.results != nullptr) { results = get_type_info_ptr(m, t->Proc.results); } LLVMValueRef vals[4] = { params, results, lb_const_bool(m, t_bool, t->Proc.variadic).value, lb_const_int(m, t_u8, t->Proc.calling_convention).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Tuple: { tag_type = t_type_info_parameters; i64 type_offset = 0; i64 name_offset = 0; lbValue memory_types = lb_type_info_member_types_offset(m, t->Tuple.variables.count, &type_offset); lbValue memory_names = lb_type_info_member_names_offset(m, t->Tuple.variables.count, &name_offset); for_array(i, t->Tuple.variables) { // NOTE(bill): offset is not used for tuples Entity *f = t->Tuple.variables[i]; lbValue index = lb_const_int(m, t_int, i); lbValue type_info = lb_const_ptr_offset(m, memory_types, index); lb_global_type_info_member_types_values[type_offset+i] = get_type_info_ptr(m, f->type); if (f->token.string.len > 0) { lb_global_type_info_member_names_values[name_offset+i] = lb_const_string(m, f->token.string).value; } } lbValue count = lb_const_int(m, t_int, t->Tuple.variables.count); LLVMValueRef types_slice = llvm_const_slice(m, memory_types, count); LLVMValueRef names_slice = llvm_const_slice(m, memory_names, count); LLVMValueRef vals[2] = { types_slice, names_slice, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Enum: tag_type = t_type_info_enum; { GB_ASSERT(t->Enum.base_type != nullptr); // GB_ASSERT_MSG(type_size_of(t_type_info_enum_value) == 16, "%lld == 16", cast(long long)type_size_of(t_type_info_enum_value)); LLVMValueRef vals[3] = {}; vals[0] = get_type_info_ptr(m, t->Enum.base_type); if (t->Enum.fields.count > 0) { auto fields = t->Enum.fields; lbValue name_array = lb_generate_global_array(m, t_string, fields.count, str_lit("$enum_names"), cast(i64)entry_index); lbValue value_array = lb_generate_global_array(m, t_type_info_enum_value, fields.count, str_lit("$enum_values"), cast(i64)entry_index); LLVMValueRef *name_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, fields.count); LLVMValueRef *value_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, fields.count); GB_ASSERT(is_type_integer(t->Enum.base_type)); for_array(i, fields) { name_values[i] = lb_const_string(m, fields[i]->token.string).value; value_values[i] = lb_const_value(m, t_i64, fields[i]->Constant.value).value; } LLVMValueRef name_init = llvm_const_array(lb_type(m, t_string), name_values, cast(unsigned)fields.count); LLVMValueRef value_init = llvm_const_array(lb_type(m, t_type_info_enum_value), value_values, cast(unsigned)fields.count); LLVMSetInitializer(name_array.value, name_init); LLVMSetInitializer(value_array.value, value_init); LLVMSetGlobalConstant(name_array.value, true); LLVMSetGlobalConstant(value_array.value, true); lbValue v_count = lb_const_int(m, t_int, fields.count); vals[1] = llvm_const_slice(m, lbValue{name_array.value, alloc_type_pointer(t_string)}, v_count); vals[2] = llvm_const_slice(m, lbValue{value_array.value, alloc_type_pointer(t_type_info_enum_value)}, v_count); } else { vals[1] = LLVMConstNull(lb_type(m, base_type(t_type_info_enum)->Struct.fields[1]->type)); vals[2] = LLVMConstNull(lb_type(m, base_type(t_type_info_enum)->Struct.fields[2]->type)); } variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Type_Union: { tag_type = t_type_info_union; { LLVMValueRef vals[7] = {}; isize variant_count = gb_max(0, t->Union.variants.count); i64 variant_offset = 0; lbValue memory_types = lb_type_info_member_types_offset(m, variant_count, &variant_offset); for (isize variant_index = 0; variant_index < variant_count; variant_index++) { Type *vt = t->Union.variants[variant_index]; lb_global_type_info_member_types_values[variant_offset+variant_index] = get_type_info_ptr(m, vt); } lbValue count = lb_const_int(m, t_int, variant_count); vals[0] = llvm_const_slice(m, memory_types, count); i64 tag_size = union_tag_size(t); if (tag_size > 0) { i64 tag_offset = align_formula(t->Union.variant_block_size, tag_size); vals[1] = lb_const_int(m, t_uintptr, tag_offset).value; vals[2] = get_type_info_ptr(m, union_tag_type(t)); } else { vals[1] = lb_const_int(m, t_uintptr, 0).value; vals[2] = LLVMConstNull(lb_type(m, t_type_info_ptr)); } if (is_type_comparable(t) && !is_type_simple_compare(t)) { vals[3] = lb_equal_proc_for_type(m, t).value; } vals[4] = lb_const_bool(m, t_bool, t->Union.custom_align != 0).value; vals[5] = lb_const_bool(m, t_bool, t->Union.kind == UnionType_no_nil).value; vals[6] = lb_const_bool(m, t_bool, t->Union.kind == UnionType_shared_nil).value; for (isize i = 0; i < gb_count_of(vals); i++) { if (vals[i] == nullptr) { vals[i] = LLVMConstNull(lb_type(m, get_struct_field_type(tag_type, i))); } } variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; } case Type_Struct: { tag_type = t_type_info_struct; LLVMValueRef vals[13] = {}; { lbValue is_packed = lb_const_bool(m, t_bool, t->Struct.is_packed); lbValue is_raw_union = lb_const_bool(m, t_bool, t->Struct.is_raw_union); lbValue is_no_copy = lb_const_bool(m, t_bool, t->Struct.is_no_copy); lbValue is_custom_align = lb_const_bool(m, t_bool, t->Struct.custom_align != 0); vals[5] = is_packed.value; vals[6] = is_raw_union.value; vals[7] = is_no_copy.value; vals[8] = is_custom_align.value; if (is_type_comparable(t) && !is_type_simple_compare(t)) { vals[9] = lb_equal_proc_for_type(m, t).value; } if (t->Struct.soa_kind != StructSoa_None) { Type *kind_type = get_struct_field_type(tag_type, 10); lbValue soa_kind = lb_const_value(m, kind_type, exact_value_i64(t->Struct.soa_kind)); LLVMValueRef soa_type = get_type_info_ptr(m, t->Struct.soa_elem); lbValue soa_len = lb_const_int(m, t_int, t->Struct.soa_count); vals[10] = soa_kind.value; vals[11] = soa_type; vals[12] = soa_len.value; } } isize count = t->Struct.fields.count; if (count > 0) { i64 types_offset = 0; i64 names_offset = 0; i64 offsets_offset = 0; i64 usings_offset = 0; i64 tags_offset = 0; lbValue memory_types = lb_type_info_member_types_offset (m, count, &types_offset); lbValue memory_names = lb_type_info_member_names_offset (m, count, &names_offset); lbValue memory_offsets = lb_type_info_member_offsets_offset(m, count, &offsets_offset); lbValue memory_usings = lb_type_info_member_usings_offset (m, count, &usings_offset); lbValue memory_tags = lb_type_info_member_tags_offset (m, count, &tags_offset); type_set_offsets(t); // NOTE(bill): Just incase the offsets have not been set yet for (isize source_index = 0; source_index < count; source_index++) { Entity *f = t->Struct.fields[source_index]; i64 foffset = 0; if (!t->Struct.is_raw_union) { GB_ASSERT(t->Struct.offsets != nullptr); GB_ASSERT(0 <= f->Variable.field_index && f->Variable.field_index < count); foffset = t->Struct.offsets[source_index]; } GB_ASSERT(f->kind == Entity_Variable && f->flags & EntityFlag_Field); lb_global_type_info_member_types_values[types_offset+source_index] = get_type_info_ptr(m, f->type); lb_global_type_info_member_offsets_values[offsets_offset+source_index] = lb_const_int(m, t_uintptr, foffset).value; lb_global_type_info_member_usings_values[usings_offset+source_index] = lb_const_bool(m, t_bool, (f->flags&EntityFlag_Using) != 0).value; if (f->token.string.len > 0) { lb_global_type_info_member_names_values[names_offset+source_index] = lb_const_string(m, f->token.string).value; } if (t->Struct.tags != nullptr) { String tag_string = t->Struct.tags[source_index]; if (tag_string.len > 0) { lb_global_type_info_member_tags_values[tags_offset+source_index] = lb_const_string(m, tag_string).value; } } } lbValue cv = lb_const_int(m, t_int, count); vals[0] = llvm_const_slice(m, memory_types, cv); vals[1] = llvm_const_slice(m, memory_names, cv); vals[2] = llvm_const_slice(m, memory_offsets, cv); vals[3] = llvm_const_slice(m, memory_usings, cv); vals[4] = llvm_const_slice(m, memory_tags, cv); } for (isize i = 0; i < gb_count_of(vals); i++) { if (vals[i] == nullptr) { vals[i] = LLVMConstNull(lb_type(m, get_struct_field_type(tag_type, i))); } } variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_Map: { tag_type = t_type_info_map; init_map_internal_types(t); LLVMValueRef vals[3] = { get_type_info_ptr(m, t->Map.key), get_type_info_ptr(m, t->Map.value), lb_gen_map_info_ptr(m, t).value }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } case Type_BitSet: { tag_type = t_type_info_bit_set; GB_ASSERT(is_type_typed(t->BitSet.elem)); LLVMValueRef vals[4] = { get_type_info_ptr(m, t->BitSet.elem), LLVMConstNull(lb_type(m, t_type_info_ptr)), lb_const_int(m, t_i64, t->BitSet.lower).value, lb_const_int(m, t_i64, t->BitSet.upper).value, }; if (t->BitSet.underlying != nullptr) { vals[1] = get_type_info_ptr(m, t->BitSet.underlying); } variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Type_SimdVector: { tag_type = t_type_info_simd_vector; LLVMValueRef vals[3] = {}; vals[0] = get_type_info_ptr(m, t->SimdVector.elem); vals[1] = lb_const_int(m, t_int, type_size_of(t->SimdVector.elem)).value; vals[2] = lb_const_int(m, t_int, t->SimdVector.count).value; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Type_RelativePointer: { tag_type = t_type_info_relative_pointer; LLVMValueRef vals[2] = { get_type_info_ptr(m, t->RelativePointer.pointer_type), get_type_info_ptr(m, t->RelativePointer.base_integer), }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Type_RelativeMultiPointer: { tag_type = t_type_info_relative_multi_pointer; LLVMValueRef vals[2] = { get_type_info_ptr(m, t->RelativeMultiPointer.pointer_type), get_type_info_ptr(m, t->RelativeMultiPointer.base_integer), }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Type_Matrix: { tag_type = t_type_info_matrix; i64 ez = type_size_of(t->Matrix.elem); LLVMValueRef vals[5] = { get_type_info_ptr(m, t->Matrix.elem), lb_const_int(m, t_int, ez).value, lb_const_int(m, t_int, matrix_type_stride_in_elems(t)).value, lb_const_int(m, t_int, t->Matrix.row_count).value, lb_const_int(m, t_int, t->Matrix.column_count).value, }; variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); } break; case Type_BitField: { tag_type = t_type_info_bit_field; LLVMValueRef vals[6] = {}; vals[0] = get_type_info_ptr(m, t->BitField.backing_type); isize count = t->BitField.fields.count; if (count > 0) { i64 names_offset = 0; i64 types_offset = 0; i64 bit_sizes_offset = 0; i64 bit_offsets_offset = 0; i64 tags_offset = 0; lbValue memory_names = lb_type_info_member_names_offset (m, count, &names_offset); lbValue memory_types = lb_type_info_member_types_offset (m, count, &types_offset); lbValue memory_bit_sizes = lb_type_info_member_offsets_offset(m, count, &bit_sizes_offset); lbValue memory_bit_offsets = lb_type_info_member_offsets_offset(m, count, &bit_offsets_offset); lbValue memory_tags = lb_type_info_member_tags_offset (m, count, &tags_offset); u64 bit_offset = 0; for (isize source_index = 0; source_index < count; source_index++) { Entity *f = t->BitField.fields[source_index]; u64 bit_size = cast(u64)t->BitField.bit_sizes[source_index]; lbValue index = lb_const_int(m, t_int, source_index); if (f->token.string.len > 0) { lb_global_type_info_member_names_values[names_offset+source_index] = lb_const_string(m, f->token.string).value; } lb_global_type_info_member_types_values[types_offset+source_index] = get_type_info_ptr(m, f->type); lb_global_type_info_member_offsets_values[bit_sizes_offset+source_index] = lb_const_int(m, t_uintptr, bit_size).value; lb_global_type_info_member_offsets_values[bit_offsets_offset+source_index] = lb_const_int(m, t_uintptr, bit_offset).value; if (t->BitField.tags) { String tag = t->BitField.tags[source_index]; if (tag.len > 0) { lb_global_type_info_member_tags_values[tags_offset+source_index] = lb_const_string(m, tag).value; } } bit_offset += bit_size; } lbValue cv = lb_const_int(m, t_int, count); vals[1] = llvm_const_slice(m, memory_names, cv); vals[2] = llvm_const_slice(m, memory_types, cv); vals[3] = llvm_const_slice(m, memory_bit_sizes, cv); vals[4] = llvm_const_slice(m, memory_bit_offsets, cv); vals[5] = llvm_const_slice(m, memory_tags, cv); } for (isize i = 0; i < gb_count_of(vals); i++) { if (vals[i] == nullptr) { vals[i] = LLVMConstNull(lb_type(m, get_struct_field_type(tag_type, i))); } } variant_value = llvm_const_named_struct(m, tag_type, vals, gb_count_of(vals)); break; } } i64 tag_index = 0; if (tag_type != nullptr) { tag_index = union_variant_index(ut, tag_type); } GB_ASSERT(tag_index <= Typeid__COUNT); LLVMValueRef full_variant_values[3] = {}; if (full_variant_elem_count == 2) { if (variant_value == nullptr) { full_variant_values[0] = LLVMConstNull(LLVMStructGetTypeAtIndex(full_variant_type, 0)); full_variant_values[1] = LLVMConstInt(LLVMStructGetTypeAtIndex(full_variant_type, 1), tag_index, false); } else { full_variant_values[0] = variant_value; full_variant_values[1] = LLVMConstInt(LLVMStructGetTypeAtIndex(full_variant_type, 1), tag_index, false); } } else { if (variant_value == nullptr) { variant_value = LLVMConstNull(LLVMStructGetTypeAtIndex(full_variant_type, 0)); } else { GB_ASSERT_MSG(LLVMStructGetTypeAtIndex(full_variant_type, 0) == LLVMTypeOf(variant_value), "\n%s -> %s\n%s vs %s\n", type_to_string(t), LLVMPrintValueToString(variant_value), LLVMPrintTypeToString(LLVMStructGetTypeAtIndex(full_variant_type, 0)), LLVMPrintTypeToString(LLVMTypeOf(variant_value)) ); } full_variant_values[0] = variant_value; full_variant_values[1] = LLVMConstNull(LLVMStructGetTypeAtIndex(full_variant_type, 1)); full_variant_values[2] = LLVMConstInt(LLVMStructGetTypeAtIndex(full_variant_type, 2), tag_index, false); } LLVMValueRef full_variant_value = LLVMConstNamedStruct(full_variant_type, full_variant_values, full_variant_elem_count); small_const_values[variant_index] = full_variant_value; LLVMSetInitializer(giant_const_values[entry_index], LLVMConstNamedStruct(stype, small_const_values, variant_index+1)); } for (isize i = 0; i < global_type_info_data_entity_count; i++) { giant_const_values[i] = LLVMConstPointerCast(giant_const_values[i], lb_type(m, t_type_info_ptr)); } LLVMValueRef giant_const = LLVMConstArray(lb_type(m, t_type_info_ptr), giant_const_values, cast(unsigned)global_type_info_data_entity_count); LLVMValueRef giant_array = lb_global_type_info_data_ptr(m).value; LLVMSetInitializer(giant_array, giant_const); } gb_internal void lb_setup_type_info_data(lbModule *m) { // NOTE(bill): Setup type_info data if (build_context.no_rtti) { return; } i64 global_type_info_data_entity_count = 0; // NOTE(bill): Set the type_table slice with the global backing array lbValue global_type_table = lb_find_runtime_value(m, str_lit("type_table")); Type *type = base_type(lb_global_type_info_data_entity->type); GB_ASSERT(type->kind == Type_Array); global_type_info_data_entity_count = type->Array.count; if (true) { lb_setup_type_info_data_giant_array(m, global_type_info_data_entity_count); } LLVMValueRef data = lb_global_type_info_data_ptr(m).value; data = LLVMConstPointerCast(data, lb_type(m, alloc_type_pointer(type->Array.elem))); LLVMValueRef len = LLVMConstInt(lb_type(m, t_int), type->Array.count, true); Type *t = type_deref(global_type_table.type); GB_ASSERT(is_type_slice(t)); LLVMValueRef slice = llvm_const_slice_internal(m, data, len); LLVMSetInitializer(global_type_table.value, slice); }