//: A big convenience high-level languages provide is the ability to name memory //: locations. In mu, a transform called 'convert-names' provides this //: convenience. :(scenarios run) :(scenario "convert_names") recipe main [ x:integer <- copy 0:literal ] +name: assign x 1 +run: instruction main/0 +mem: storing 0 in location 1 :(scenario "convert_names_warns") hide warnings recipe main [ x:integer <- copy y:integer ] +warn: use before set: y in main :(after "int main") Transform.push_back(transform_names); :(before "End Globals") unordered_map > Name; :(after "Clear Other State For recently_added_recipes") for (size_t i = 0; i < recently_added_recipes.size(); ++i) { Name.erase(recently_added_recipes[i]); } :(code) void transform_names(const recipe_number r) { unordered_map& names = Name[r]; int curr_idx = 1; //? cout << "Recipe " << r << '\n'; //? 2 //? cout << Recipe[r].steps.size(); //? 1 for (size_t i = 0; i < Recipe[r].steps.size(); ++i) { //? cout << "instruction " << i << '\n'; //? 2 instruction& inst = Recipe[r].steps[i]; // Per-recipe Transforms // map names to addresses for (size_t in = 0; in < inst.ingredients.size(); ++in) { //? cout << "ingredients\n"; //? 2 if (is_raw(inst.ingredients[in])) continue; //? cout << "ingredient " << inst.ingredients[in].name << '\n'; //? 2 if (inst.ingredients[in].name == "default-space") inst.ingredients[in].initialized = true; assert(!inst.ingredients[in].types.empty()); if (inst.ingredients[in].types[0] // not a literal && !inst.ingredients[in].initialized && inst.ingredients[in].name.find_first_not_of("0123456789-.") != string::npos) { if (!already_transformed(inst.ingredients[in], names)) { raise << "use before set: " << inst.ingredients[in].name << " in " << Recipe[r].name << '\n'; } inst.ingredients[in].set_value(lookup_name(inst.ingredients[in], r)); //? cout << "lookup ingredient " << Recipe[r].name << "/" << i << ": " << inst.ingredients[in].to_string() << '\n'; //? 1 } } for (size_t out = 0; out < inst.products.size(); ++out) { //? cout << "products\n"; //? 1 if (is_raw(inst.products[out])) continue; //? cout << "product " << out << '/' << inst.products.size() << " " << inst.products[out].name << '\n'; //? 4 //? cout << inst.products[out].types[0] << '\n'; //? 1 if (inst.products[out].name == "default-space") inst.products[out].initialized = true; if (inst.products[out].types[0] // not a literal && !inst.products[out].initialized && inst.products[out].name.find_first_not_of("0123456789-.") != string::npos) { if (names.find(inst.products[out].name) == names.end()) { trace("name") << "assign " << inst.products[out].name << " " << curr_idx; names[inst.products[out].name] = curr_idx; curr_idx += size_of(inst.products[out]); } inst.products[out].set_value(lookup_name(inst.products[out], r)); //? cout << "lookup product " << Recipe[r].name << "/" << i << ": " << inst.products[out].to_string() << '\n'; //? 1 } } } } bool already_transformed(const reagent& r, const unordered_map& names) { return names.find(r.name) != names.end(); } size_t lookup_name(const reagent& r, const recipe_number default_recipe) { return Name[default_recipe][r.name]; } type_number skip_addresses(const vector& types) { for (size_t i = 0; i < types.size(); ++i) { if (types[i] != Type_number["address"]) return types[i]; } raise << "expected a container" << '\n' << die(); return -1; } int find_element_name(const type_number t, const string& name) { const type_info& container = Type[t]; //? cout << "looking for element " << name << " in type " << container.name << " with " << container.element_names.size() << " elements\n"; //? 1 for (size_t i = 0; i < container.element_names.size(); ++i) { if (container.element_names[i] == name) return i; } raise << "unknown element " << name << " in container " << t << '\n' << die(); return -1; } bool is_raw(const reagent& r) { for (size_t i = /*skip value+type*/1; i < r.properties.size(); ++i) { if (r.properties[i].first == "raw") return true; } return false; } :(scenario "convert_names_passes_dummy") # _ is just a dummy result that never gets consumed recipe main [ _, x:integer <- copy 0:literal ] +name: assign x 1 -name: assign _ 1 //: one reserved word that we'll need later :(scenario "convert_names_passes_default_space") recipe main [ default-space:integer, x:integer <- copy 0:literal ] +name: assign x 1 -name: assign default-space 1 //: an escape hatch to suppress name conversion that we'll use later :(scenario "convert_names_passes_raw") recipe main [ x:integer/raw <- copy 0:literal ] -name: assign x 1 //: update our running example container for the next test :(before "End Mu Types Initialization") Type[point].element_names.push_back("x"); Type[point].element_names.push_back("y"); :(scenario "convert_names_transforms_container_elements") recipe main [ a:integer <- get 0:point, y:offset b:integer <- get 0:point, x:offset ] +name: element y of type point is at offset 1 +name: element x of type point is at offset 0 :(after "Per-recipe Transforms") // replace element names of containers with offsets if (inst.operation == Recipe_number["get"] || inst.operation == Recipe_number["get-address"]) { // at least 2 args, and second arg is offset assert(inst.ingredients.size() >= 2); //? cout << inst.ingredients[1].to_string() << '\n'; //? 1 assert(isa_literal(inst.ingredients[1])); if (inst.ingredients[1].name.find_first_not_of("0123456789") == string::npos) continue; // since first non-address in base type must be a container, we don't have to canonize type_number container = skip_addresses(inst.ingredients[0].types); inst.ingredients[1].set_value(find_element_name(container, inst.ingredients[1].name)); trace("name") << "element " << inst.ingredients[1].name << " of type " << Type[container].name << " is at offset " << inst.ingredients[1].value; } //: this test is actually illegal so can't call run :(scenarios transform_test) :(scenario "convert_names_handles_containers") recipe main [ a:point <- copy 0:literal b:integer <- copy 0:literal ] +name: assign a 1 +name: assign b 3