//:: Like container definitions, recipes too can contain type parameters. :(scenario shape_shifting_recipe) def main [ 10:point <- merge 14, 15 11:point <- foo 10:point ] # non-matching variant def foo a:num -> result:num [ local-scope load-ingredients result <- copy 34 ] # matching shape-shifting variant def foo a:_t -> result:_t [ local-scope load-ingredients result <- copy a ] +mem: storing 14 in location 11 +mem: storing 15 in location 12 //: Before anything else, disable transforms for shape-shifting recipes and //: make sure we never try to actually run a shape-shifting recipe. We should //: be rewriting such instructions to *specializations* with the type //: ingredients filled in. //: One exception (and this makes things very ugly): we need to expand type //: abbreviations in shape-shifting recipes because we need them types for //: deciding which variant to specialize. :(before "End Transform Checks") r.transformed_until = t; if (Transform.at(t) != static_cast(expand_type_abbreviations) && any_type_ingredient_in_header(/*recipe_ordinal*/p->first)) continue; :(after "Running One Instruction") if (Current_routine->calls.front().running_step_index == 0 && any_type_ingredient_in_header(Current_routine->calls.front().running_recipe)) { //? DUMP(""); raise << "ran into unspecialized shape-shifting recipe " << current_recipe_name() << '\n' << end(); //? exit(0); } //: Make sure we don't match up literals with type ingredients without //: specialization. :(before "End Matching Types For Literal(to)") if (contains_type_ingredient_name(to)) return false; :(after "Static Dispatch Phase 3") candidates = strictly_matching_shape_shifting_variants(inst, variants); if (!candidates.empty()) { recipe_ordinal exemplar = best_shape_shifting_variant(inst, candidates); trace(9992, "transform") << "found variant to specialize: " << exemplar << ' ' << get(Recipe, exemplar).name << end(); string new_recipe_name = insert_new_variant(exemplar, inst, caller_recipe); if (new_recipe_name != "") { trace(9992, "transform") << "new specialization: " << new_recipe_name << end(); return new_recipe_name; } } //: before running Mu programs, make sure no unspecialized shape-shifting //: recipes can be called :(before "End Instruction Operation Checks") if (contains_key(Recipe, inst.operation) && !is_primitive(inst.operation) && any_type_ingredient_in_header(inst.operation)) { raise << maybe(caller.name) << "instruction '" << inst.name << "' has no valid specialization\n" << end(); return; } :(replace{} "Match Literal Zero Against Address") if (is_literal(from) && is_mu_address(to)) return from.name == "0" && !contains_type_ingredient_name(to); :(code) // phase 3 of static dispatch vector strictly_matching_shape_shifting_variants(const instruction& inst, const vector& variants) { vector result; for (int i = 0; i < SIZE(variants); ++i) { if (variants.at(i) == -1) continue; if (!any_type_ingredient_in_header(variants.at(i))) continue; if (!all_concrete_header_reagents_strictly_match(inst, get(Recipe, variants.at(i)))) continue; result.push_back(variants.at(i)); } return result; } bool all_concrete_header_reagents_strictly_match(const instruction& inst, const recipe& variant) { for (int i = 0; i < min(SIZE(inst.ingredients), SIZE(variant.ingredients)); ++i) { if (!concrete_type_names_strictly_match(variant.ingredients.at(i), inst.ingredients.at(i))) { trace(9993, "transform") << "concrete-type match failed: ingredient " << i << end(); return false; } } for (int i = 0; i < min(SIZE(inst.products), SIZE(variant.ingredients)); ++i) { if (is_dummy(inst.products.at(i))) continue; if (!concrete_type_names_strictly_match(variant.products.at(i), inst.products.at(i))) { trace(9993, "transform") << "concrete-type match failed: product " << i << end(); return false; } } return true; } // manual prototype vector keep_max(const instruction&, const vector&, int (*)(const instruction&, recipe_ordinal)); // tie-breaker for phase 3 recipe_ordinal best_shape_shifting_variant(const instruction& inst, const vector& candidates) { assert(!candidates.empty()); if (SIZE(candidates) == 1) return candidates.at(0); //? cerr << "A picking shape-shifting variant:\n"; vector result1 = keep_max(inst, candidates, number_of_concrete_type_names); assert(!result1.empty()); if (SIZE(result1) == 1) return result1.at(0); //? cerr << "B picking shape-shifting variant:\n"; vector result2 = keep_max(inst, result1, arity_fit); assert(!result2.empty()); if (SIZE(result2) == 1) return result2.at(0); //? cerr << "C picking shape-shifting variant:\n"; vector result3 = keep_max(inst, result2, number_of_type_ingredients); if (SIZE(result3) > 1) { raise << "\nCouldn't decide the best shape-shifting variant for instruction '" << to_original_string(inst) << "'\n" << end(); cerr << "This is a hole in Mu. Please copy the following candidates into an email to Kartik Agaram \n"; for (int i = 0; i < SIZE(candidates); ++i) cerr << " " << header_label(get(Recipe, candidates.at(i))) << '\n'; } return result3.at(0); } vector keep_max(const instruction& inst, const vector& in, int (*scorer)(const instruction&, recipe_ordinal)) { assert(!in.empty()); vector out; out.push_back(in.at(0)); int best_score = (*scorer)(inst, in.at(0)); //? cerr << best_score << " " << header_label(get(Recipe, in.at(0))) << '\n'; for (int i = 1; i < SIZE(in); ++i) { int score = (*scorer)(inst, in.at(i)); //? cerr << score << " " << header_label(get(Recipe, in.at(i))) << '\n'; if (score == best_score) { out.push_back(in.at(i)); } else if (score > best_score) { best_score = score; out.clear(); out.push_back(in.at(i)); } } return out; } int arity_fit(const instruction& inst, recipe_ordinal candidate) { const recipe& r = get(Recipe, candidate); return (SIZE(inst.products) - SIZE(r.products)) + (SIZE(r.ingredients) - SIZE(inst.ingredients)); } bool any_type_ingredient_in_header(recipe_ordinal variant) { const recipe& caller = get(Recipe, variant); for (int i = 0; i < SIZE(caller.ingredients); ++i) { if (contains_type_ingredient_name(caller.ingredients.at(i))) return true; } for (int i = 0; i < SIZE(caller.products); ++i) { if (contains_type_ingredient_name(caller.products.at(i))) return true; } return false; } bool concrete_type_names_strictly_match(reagent/*copy*/ to, reagent/*copy*/ from) { canonize_type(to); canonize_type(from); return concrete_type_names_strictly_match(to.type, from.type, from); } bool concrete_type_names_strictly_match(const type_tree* to, const type_tree* from, const reagent& rhs_reagent) { if (!to) return !from; if (!from) return !to; if (to->atom && is_type_ingredient_name(to->name)) return true; // type ingredient matches anything if (!to->atom && to->right == NULL && to->left != NULL && to->left->atom && is_type_ingredient_name(to->left->name)) return true; if (from->atom && is_mu_address(to)) return from->name == "literal" && rhs_reagent.name == "0"; if (!from->atom && !to->atom) return concrete_type_names_strictly_match(to->left, from->left, rhs_reagent) && concrete_type_names_strictly_match(to->right, from->right, rhs_reagent); if (from->atom != to->atom) return false; // both from and to are atoms if (from->name == "literal") return Literal_type_names.find(to->name) != Literal_type_names.end(); if (to->name == "literal") return Literal_type_names.find(from->name) != Literal_type_names.end(); return to->name == from->name; } bool contains_type_ingredient_name(const reagent& x) { return contains_type_ingredient_name(x.type); } bool contains_type_ingredient_name(const type_tree* type) { if (!type) return false; if (is_type_ingredient_name(type->name)) return true; return contains_type_ingredient_name(type->left) || contains_type_ingredient_name(type->right); } int number_of_concrete_type_names(unused const instruction& inst, recipe_ordinal r) { const recipe& caller = get(Recipe, r); int result = 0; for (int i = 0; i < SIZE(caller.ingredients); ++i) result += number_of_concrete_type_names(caller.ingredients.at(i).type); for (int i = 0; i < SIZE(caller.products); ++i) result += number_of_concrete_type_names(caller.products.at(i).type); return result; } int number_of_concrete_type_names(const type_tree* type) { if (!type) return 0; if (type->atom) return is_type_ingredient_name(type->name) ? 0 : 1; return number_of_concrete_type_names(type->left) + number_of_concrete_type_names(type->right); } int number_of_type_ingredients(unused const instruction& inst, recipe_ordinal r) { const recipe& caller = get(Recipe, r); int result = 0; for (int i = 0; i < SIZE(caller.ingredients); ++i) result += number_of_type_ingredients(caller.ingredients.at(i).type); for (int i = 0; i < SIZE(caller.products); ++i) result += number_of_type_ingredients(caller.products.at(i).type); return result; } int number_of_type_ingredients(const type_tree* type) { if (!type) return 0; if (type->atom) return is_type_ingredient_name(type->name) ? 1 : 0; return number_of_type_ingredients(type->left) + number_of_type_ingredients(type->right); } // returns name of new variant string insert_new_variant(recipe_ordinal exemplar, const instruction& inst, const recipe& caller_recipe) { string new_name = next_unused_recipe_name(inst.name); assert(!contains_key(Recipe_ordinal, new_name)); recipe_ordinal new_recipe_ordinal = put(Recipe_ordinal, new_name, Next_recipe_ordinal++); // make a copy assert(contains_key(Recipe, exemplar)); assert(!contains_key(Recipe, new_recipe_ordinal)); recipe new_recipe = get(Recipe, exemplar); new_recipe.name = new_name; new_recipe.is_autogenerated = true; trace(9993, "transform") << "switching " << inst.name << " to specialized " << header_label(new_recipe) << end(); // Replace type ingredients with concrete types in new_recipe. // // preprocessing: micro-manage a couple of transforms // a) perform tangle *before* replacing type ingredients, just in case // inserted code involves type ingredients insert_fragments(new_recipe); // b) do the work of check_or_set_types_by_name (and its prerequisites) // while supporting type-ingredients expand_type_abbreviations(new_recipe); compute_type_names(new_recipe); // that gives enough information to replace type-ingredients with concrete types { map mappings; bool error = false; compute_type_ingredient_mappings(get(Recipe, exemplar), inst, mappings, caller_recipe, &error); if (!error) error = (SIZE(mappings) != type_ingredient_count_in_header(exemplar)); if (!error) replace_type_ingredients(new_recipe, mappings); for (map::iterator p = mappings.begin(); p != mappings.end(); ++p) delete p->second; if (error) return ""; } ensure_all_concrete_types(new_recipe, get(Recipe, exemplar)); put(Recipe, new_recipe_ordinal, new_recipe); // record variant before performing transforms, just in case the recipe is recursive get(Recipe_variants, inst.name).push_back(new_recipe_ordinal); // perform all transforms on the new specialization if (!new_recipe.steps.empty()) { trace(9992, "transform") << "transforming new specialization: " << new_recipe.name << end(); for (int t = 0; t < SIZE(Transform); ++t) { // one exception: skip tangle, which has already occurred above if (Transform.at(t) == /*disambiguate overloading*/static_cast(insert_fragments)) continue; (*Transform.at(t))(new_recipe_ordinal); } } new_recipe.transformed_until = SIZE(Transform)-1; return new_recipe.name; } void compute_type_names(recipe& variant) { trace(9993, "transform") << "-- compute type names: " << variant.name << end(); map type_names; for (int i = 0; i < SIZE(variant.ingredients); ++i) save_or_deduce_type_name(variant.ingredients.at(i), type_names, variant, ""); for (int i = 0; i < SIZE(variant.products); ++i) save_or_deduce_type_name(variant.products.at(i), type_names, variant, ""); for (int i = 0; i < SIZE(variant.steps); ++i) { instruction& inst = variant.steps.at(i); trace(9993, "transform") << " instruction: " << to_string(inst) << end(); for (int in = 0; in < SIZE(inst.ingredients); ++in) save_or_deduce_type_name(inst.ingredients.at(in), type_names, variant, " in '" + to_original_string(inst) + "'"); for (int out = 0; out < SIZE(inst.products); ++out) save_or_deduce_type_name(inst.products.at(out), type_names, variant, " in '" + to_original_string(inst) + "'"); } } void save_or_deduce_type_name(reagent& x, map& type, const recipe& variant, const string& context) { trace(9994, "transform") << " checking " << to_string(x) << ": " << names_to_string(x.type) << end(); if (!x.type && contains_key(type, x.name)) { x.type = new type_tree(*get(type, x.name)); trace(9994, "transform") << " deducing type to " << names_to_string(x.type) << end(); return; } if (!x.type) { raise << maybe(variant.original_name) << "unknown type for '" << x.original_string << "'" << context << " (check the name for typos)\n" << end(); return; } if (contains_key(type, x.name)) return; if (x.type->name == "offset" || x.type->name == "variant") return; // special-case for container-access instructions put(type, x.name, x.type); trace(9993, "transform") << "type of '" << x.name << "' is " << names_to_string(x.type) << end(); } void compute_type_ingredient_mappings(const recipe& exemplar, const instruction& inst, map& mappings, const recipe& caller_recipe, bool* error) { int limit = min(SIZE(inst.ingredients), SIZE(exemplar.ingredients)); for (int i = 0; i < limit; ++i) { const reagent& exemplar_reagent = exemplar.ingredients.at(i); reagent/*copy*/ ingredient = inst.ingredients.at(i); canonize_type(ingredient); if (is_mu_address(exemplar_reagent) && ingredient.name == "0") continue; // assume it matches accumulate_type_ingredients(exemplar_reagent, ingredient, mappings, exemplar, inst, caller_recipe, error); } limit = min(SIZE(inst.products), SIZE(exemplar.products)); for (int i = 0; i < limit; ++i) { const reagent& exemplar_reagent = exemplar.products.at(i); reagent/*copy*/ product = inst.products.at(i); if (is_dummy(product)) continue; canonize_type(product); accumulate_type_ingredients(exemplar_reagent, product, mappings, exemplar, inst, caller_recipe, error); } } void accumulate_type_ingredients(const reagent& exemplar_reagent, reagent& refinement, map& mappings, const recipe& exemplar, const instruction& call_instruction, const recipe& caller_recipe, bool* error) { assert(refinement.type); accumulate_type_ingredients(exemplar_reagent.type, refinement.type, mappings, exemplar, exemplar_reagent, call_instruction, caller_recipe, error); } void accumulate_type_ingredients(const type_tree* exemplar_type, const type_tree* refinement_type, map& mappings, const recipe& exemplar, const reagent& exemplar_reagent, const instruction& call_instruction, const recipe& caller_recipe, bool* error) { if (!exemplar_type) return; if (!refinement_type) { // probably a bug in mu // todo: make this smarter; only flag an error if exemplar_type contains some *new* type ingredient raise << maybe(exemplar.name) << "missing type ingredient for " << exemplar_reagent.original_string << '\n' << end(); raise << " (called from '" << to_original_string(call_instruction) << "')\n" << end(); return; } if (!exemplar_type->atom && exemplar_type->right == NULL && !refinement_type->atom && refinement_type->right != NULL) { exemplar_type = exemplar_type->left; assert_for_now(exemplar_type->atom); } if (exemplar_type->atom) { if (is_type_ingredient_name(exemplar_type->name)) { const type_tree* curr_refinement_type = NULL; // temporary heap allocation; must always be deleted before it goes out of scope if (exemplar_type->atom) curr_refinement_type = new type_tree(*refinement_type); else { assert(!refinement_type->atom); curr_refinement_type = new type_tree(*refinement_type->left); } if (!contains_key(mappings, exemplar_type->name)) { trace(9993, "transform") << "adding mapping from " << exemplar_type->name << " to " << to_string(curr_refinement_type) << end(); put(mappings, exemplar_type->name, new type_tree(*curr_refinement_type)); } else { if (!deeply_equal_type_names(get(mappings, exemplar_type->name), curr_refinement_type)) { raise << maybe(caller_recipe.name) << "no call found for '" << to_original_string(call_instruction) << "'\n" << end(); *error = true; delete curr_refinement_type; return; } if (get(mappings, exemplar_type->name)->name == "literal") { delete get(mappings, exemplar_type->name); put(mappings, exemplar_type->name, new type_tree(*curr_refinement_type)); } } delete curr_refinement_type; } } else { accumulate_type_ingredients(exemplar_type->left, refinement_type->left, mappings, exemplar, exemplar_reagent, call_instruction, caller_recipe, error); accumulate_type_ingredients(exemplar_type->right, refinement_type->right, mappings, exemplar, exemplar_reagent, call_instruction, caller_recipe, error); } } void replace_type_ingredients(recipe& new_recipe, const map& mappings) { // update its header if (mappings.empty()) return; trace(9993, "transform") << "replacing in recipe header ingredients" << end(); for (int i = 0; i < SIZE(new_recipe.ingredients); ++i) replace_type_ingredients(new_recipe.ingredients.at(i), mappings, new_recipe); trace(9993, "transform") << "replacing in recipe header products" << end(); for (int i = 0; i < SIZE(new_recipe.products); ++i) replace_type_ingredients(new_recipe.products.at(i), mappings, new_recipe); // update its body for (int i = 0; i < SIZE(new_recipe.steps); ++i) { instruction& inst = new_recipe.steps.at(i); trace(9993, "transform") << "replacing in instruction '" << to_string(inst) << "'" << end(); for (int j = 0; j < SIZE(inst.ingredients); ++j) replace_type_ingredients(inst.ingredients.at(j), mappings, new_recipe); for (int j = 0; j < SIZE(inst.products); ++j) replace_type_ingredients(inst.products.at(j), mappings, new_recipe); // special-case for new: replace type ingredient in first ingredient *value* if (inst.name == "new" && inst.ingredients.at(0).type->name != "literal-string") { type_tree* type = parse_type_tree(inst.ingredients.at(0).name); replace_type_ingredients(type, mappings); inst.ingredients.at(0).name = inspect(type); delete type; } } } void replace_type_ingredients(reagent& x, const map& mappings, const recipe& caller) { string before = to_string(x); trace(9993, "transform") << "replacing in ingredient " << x.original_string << end(); if (!x.type) { raise << "specializing " << caller.original_name << ": missing type for '" << x.original_string << "'\n" << end(); return; } replace_type_ingredients(x.type, mappings); } void replace_type_ingredients(type_tree* type, const map& mappings) { if (!type) return; if (!type->atom) { if (type->right == NULL && type->left != NULL && type->left->atom && contains_key(mappings, type->left->name) && !get(mappings, type->left->name)->atom && get(mappings, type->left->name)->right != NULL) { *type = *get(mappings, type->left->name); return; } replace_type_ingredients(type->left, mappings); replace_type_ingredients(type->right, mappings); return; } if (contains_key(Type_ordinal, type->name)) // todo: ugly side effect type->value = get(Type_ordinal, type->name); if (!contains_key(mappings, type->name)) return; const type_tree* replacement = get(mappings, type->name); trace(9993, "transform") << type->name << " => " << names_to_string(replacement) << end(); if (replacement->atom) { if (!contains_key(Type_ordinal, replacement->name)) { // error in program; should be reported elsewhere return; } type->name = (replacement->name == "literal") ? "number" : replacement->name; type->value = get(Type_ordinal, type->name); } else { *type = *replacement; } } int type_ingredient_count_in_header(recipe_ordinal variant) { const recipe& caller = get(Recipe, variant); set type_ingredients; for (int i = 0; i < SIZE(caller.ingredients); ++i) accumulate_type_ingredients(caller.ingredients.at(i).type, type_ingredients); for (int i = 0; i < SIZE(caller.products); ++i) accumulate_type_ingredients(caller.products.at(i).type, type_ingredients); return SIZE(type_ingredients); } void accumulate_type_ingredients(const type_tree* type, set& out) { if (!type) return; if (is_type_ingredient_name(type->name)) out.insert(type->name); accumulate_type_ingredients(type->left, out); accumulate_type_ingredients(type->right, out); } type_tree* parse_type_tree(const string& s) { string_tree* s2 = parse_string_tree(s); type_tree* result = new_type_tree(s2); delete s2; return result; } string inspect(const type_tree* x) { ostringstream out; dump_inspect(x, out); return out.str(); } void dump_inspect(const type_tree* x, ostream& out) { if (!x->left && !x->right) { out << x->name; return; } out << '('; for (const type_tree* curr = x; curr; curr = curr->right) { if (curr != x) out << ' '; if (curr->left) dump_inspect(curr->left, out); else out << curr->name; } out << ')'; } void ensure_all_concrete_types(/*const*/ recipe& new_recipe, const recipe& exemplar) { trace(9993, "transform") << "-- ensure all concrete types in recipe " << new_recipe.name << end(); for (int i = 0; i < SIZE(new_recipe.ingredients); ++i) ensure_all_concrete_types(new_recipe.ingredients.at(i), exemplar); for (int i = 0; i < SIZE(new_recipe.products); ++i) ensure_all_concrete_types(new_recipe.products.at(i), exemplar); for (int i = 0; i < SIZE(new_recipe.steps); ++i) { instruction& inst = new_recipe.steps.at(i); for (int j = 0; j < SIZE(inst.ingredients); ++j) ensure_all_concrete_types(inst.ingredients.at(j), exemplar); for (int j = 0; j < SIZE(inst.products); ++j) ensure_all_concrete_types(inst.products.at(j), exemplar); } } void ensure_all_concrete_types(/*const*/ reagent& x, const recipe& exemplar) { if (!x.type || contains_type_ingredient_name(x.type)) { raise << maybe(exemplar.name) << "failed to map a type to " << x.original_string << '\n' << end(); if (!x.type) x.type = new type_tree("", 0); // just to prevent crashes later return; } if (x.type->value == -1) { raise << maybe(exemplar.name) << "failed to map a type to the unknown " << x.original_string << '\n' << end(); return; } } :(scenario shape_shifting_recipe_2) def main [ 10:point <- merge 14, 15 11:point <- foo 10:point ] # non-matching shape-shifting variant def foo a:_t, b:_t -> result:num [ local-scope load-ingredients result <- copy 34 ] # matching shape-shifting variant def foo a:_t -> result:_t [ local-scope load-ingredients result <- copy a ] +mem: storing 14 in location 11 +mem: storing 15 in location 12 :(scenario shape_shifting_recipe_nonroot) def main [ 10:foo:point <- merge 14, 15, 16 20:point/raw <- bar 10:foo:point ] # shape-shifting recipe with type ingredient following some other type def bar a:foo:_t -> result:_t [ local-scope load-ingredients result <- get a, x:offset ] container foo:_t [ x:_t y:num ] +mem: storing 14 in location 20 +mem: storing 15 in location 21 :(scenario shape_shifting_recipe_nested) container c:_a:_b [ a:_a b:_b ] def main [ s:text <- new [abc] {x: (c (address array character) number)} <- merge s, 34 foo x ] def foo x:c:_bar:_baz [ local-scope load-ingredients ] # no errors :(scenario shape_shifting_recipe_type_deduction_ignores_offsets) def main [ 10:foo:point <- merge 14, 15, 16 20:point/raw <- bar 10:foo:point ] def bar a:foo:_t -> result:_t [ local-scope load-ingredients x:num <- copy 1 result <- get a, x:offset # shouldn't collide with other variable ] container foo:_t [ x:_t y:num ] +mem: storing 14 in location 20 +mem: storing 15 in location 21 :(scenario shape_shifting_recipe_empty) def main [ foo 1 ] # shape-shifting recipe with no body def foo a:_t [ ] # shouldn't crash :(scenario shape_shifting_recipe_handles_shape_shifting_new_ingredient) def main [ 1:&:foo:point <- bar 3 11:foo:point <- copy *1:&:foo:point ] container foo:_t [ x:_t y:num ] def bar x:num -> result:&:foo:_t [ local-scope load-ingredients # new refers to _t in its ingredient *value* result <- new {(foo _t) : type} ] +mem: storing 0 in location 11 +mem: storing 0 in location 12 +mem: storing 0 in location 13 :(scenario shape_shifting_recipe_handles_shape_shifting_new_ingredient_2) def main [ 1:&:foo:point <- bar 3 11:foo:point <- copy *1:&:foo:point ] def bar x:num -> result:&:foo:_t [ local-scope load-ingredients # new refers to _t in its ingredient *value* result <- new {(foo _t) : type} ] # container defined after use container foo:_t [ x:_t y:num ] +mem: storing 0 in location 11 +mem: storing 0 in location 12 +mem: storing 0 in location 13 :(scenario shape_shifting_recipe_called_with_dummy) def main [ _ <- bar 34 ] def bar x:_t -> result:&:_t [ local-scope load-ingredients result <- copy 0 ] $error: 0 :(code) // this one needs a little more fine-grained control void test_shape_shifting_new_ingredient_does_not_pollute_global_namespace() { // if you specialize a shape-shifting recipe that allocates a type-ingredient.. transform("def barz x:_elem [\n" " local-scope\n" " load-ingredients\n" " y:&:num <- new _elem:type\n" "]\n" "def fooz [\n" " local-scope\n" " barz 34\n" "]\n"); // ..and if you then try to load a new shape-shifting container with that // type-ingredient run("container foo:_elem [\n" " x:_elem\n" " y:num\n" "]\n"); // then it should work as usual reagent callsite("x:foo:point"); reagent element = element_type(callsite.type, 0); CHECK_EQ(element.name, "x"); CHECK_EQ(element.type->name, "point"); CHECK(!element.type->right); } //: specializing a type ingredient with a compound type :(scenario shape_shifting_recipe_supports_compound_types) def main [ 1:&:point <- new point:type *1:&:point <- put *1:&:point, y:offset, 34 3:&:point <- bar 1:&:point # specialize _t to address:point 4:point <- copy *3:&:point ] def bar a:_t -> result:_t [ local-scope load-ingredients result <- copy a ] +mem: storing 34 in location 5 //: specializing a type ingredient with a compound type -- while *inside* another compound type :(scenario shape_shifting_recipe_supports_compound_types_2) container foo:_t [ value:_t ] def bar x:&:foo:_t -> result:_t [ local-scope load-ingredients result <- get *x, value:offset ] def main [ 1:&:foo:&:point <- new {(foo address point): type} 2:&:point <- bar 1:&:foo:&:point ] # no errors; call to 'bar' successfully specialized :(scenario shape_shifting_recipe_error) % Hide_errors = true; def main [ a:num <- copy 3 b:&:num <- foo a ] def foo a:_t -> b:_t [ load-ingredients b <- copy a ] +error: main: no call found for 'b:&:num <- foo a' :(scenario specialize_inside_recipe_without_header) def main [ foo 3 ] def foo [ local-scope x:num <- next-ingredient # ensure no header 1:num/raw <- bar x # call a shape-shifting recipe ] def bar x:_elem -> y:_elem [ local-scope load-ingredients y <- add x, 1 ] +mem: storing 4 in location 1 :(scenario specialize_with_literal) def main [ local-scope # permit literal to map to number 1:num/raw <- foo 3 ] def foo x:_elem -> y:_elem [ local-scope load-ingredients y <- add x, 1 ] +mem: storing 4 in location 1 :(scenario specialize_with_literal_2) def main [ local-scope # permit literal to map to character 1:char/raw <- foo 3 ] def foo x:_elem -> y:_elem [ local-scope load-ingredients y <- add x, 1 ] +mem: storing 4 in location 1 :(scenario specialize_with_literal_3) def main [ local-scope # permit '0' to map to address to shape-shifting type-ingredient 1:&:char/raw <- foo 0 ] def foo x:&:_elem -> y:&:_elem [ local-scope load-ingredients y <- copy x ] +mem: storing 0 in location 1 $error: 0 :(scenario specialize_with_literal_4) % Hide_errors = true; def main [ local-scope # ambiguous call: what's the type of its ingredient?! foo 0 ] def foo x:&:_elem -> y:&:_elem [ local-scope load-ingredients y <- copy x ] +error: main: instruction 'foo' has no valid specialization :(scenario specialize_with_literal_5) def main [ foo 3, 4 # recipe mapping two variables to literals ] def foo x:_elem, y:_elem [ local-scope load-ingredients 1:num/raw <- add x, y ] +mem: storing 7 in location 1 :(scenario multiple_shape_shifting_variants) # try to call two different shape-shifting recipes with the same name def main [ e1:d1:num <- merge 3 e2:d2:num <- merge 4, 5 1:num/raw <- foo e1 2:num/raw <- foo e2 ] # the two shape-shifting definitions def foo a:d1:_elem -> b:num [ local-scope load-ingredients return 34 ] def foo a:d2:_elem -> b:num [ local-scope load-ingredients return 35 ] # the shape-shifting containers they use container d1:_elem [ x:_elem ] container d2:_elem [ x:num y:_elem ] +mem: storing 34 in location 1 +mem: storing 35 in location 2 :(scenario multiple_shape_shifting_variants_2) # static dispatch between shape-shifting variants, _including pointer lookups_ def main [ e1:d1:num <- merge 3 e2:&:d2:num <- new {(d2 number): type} 1:num/raw <- foo e1 2:num/raw <- foo *e2 # different from previous scenario ] def foo a:d1:_elem -> b:num [ local-scope load-ingredients return 34 ] def foo a:d2:_elem -> b:num [ local-scope load-ingredients return 35 ] container d1:_elem [ x:_elem ] container d2:_elem [ x:num y:_elem ] +mem: storing 34 in location 1 +mem: storing 35 in location 2 :(scenario missing_type_in_shape_shifting_recipe) % Hide_errors = true; def main [ a:d1:num <- merge 3 foo a ] def foo a:d1:_elem -> b:num [ local-scope load-ingredients copy e # no such variable return 34 ] container d1:_elem [ x:_elem ] +error: foo: unknown type for 'e' in 'copy e' (check the name for typos) +error: specializing foo: missing type for 'e' # and it doesn't crash :(scenario missing_type_in_shape_shifting_recipe_2) % Hide_errors = true; def main [ a:d1:num <- merge 3 foo a ] def foo a:d1:_elem -> b:num [ local-scope load-ingredients get e, x:offset # unknown variable in a 'get', which does some extra checking return 34 ] container d1:_elem [ x:_elem ] +error: foo: unknown type for 'e' in 'get e, x:offset' (check the name for typos) +error: specializing foo: missing type for 'e' # and it doesn't crash :(scenarios transform) :(scenario specialize_recursive_shape_shifting_recipe) def main [ 1:num <- copy 34 2:num <- foo 1:num ] def foo x:_elem -> y:num [ local-scope load-ingredients { break y:num <- foo x } return y ] +transform: new specialization: foo_2 # transform terminates :(scenarios run) :(scenario specialize_most_similar_variant) def main [ 1:&:num <- new number:type 2:num <- foo 1:&:num ] def foo x:_elem -> y:num [ local-scope load-ingredients return 34 ] def foo x:&:_elem -> y:num [ local-scope load-ingredients return 35 ] +mem: storing 35 in location 2 :(scenario specialize_most_similar_variant_2) # version with headers padded with lots of unrelated concrete types def main [ 1:num <- copy 23 2:&:@:num <- copy 0 3:num <- foo 2:&:@:num, 1:num ] # variant with concrete type def foo dummy:&:@:num, x:num -> y:num, dummy:&:@:num [ local-scope load-ingredients return 34 ] # shape-shifting variant def foo dummy:&:@:num, x:_elem -> y:num, dummy:&:@:num [ local-scope load-ingredients return 35 ] # prefer the concrete variant +mem: storing 34 in location 3 :(scenario specialize_most_similar_variant_3) def main [ 1:text <- new [abc] foo 1:text ] def foo x:text [ 2:num <- copy 34 ] def foo x:&:_elem [ 2:num <- copy 35 ] # make sure the more precise version was used +mem: storing 34 in location 2 :(scenario specialize_literal_as_number) def main [ 1:num <- foo 23 ] def foo x:_elem -> y:num [ local-scope load-ingredients return 34 ] def foo x:char -> y:num [ local-scope load-ingredients return 35 ] +mem: storing 34 in location 1 :(scenario specialize_literal_as_number_2) # version calling with literal def main [ 1:num <- foo 0 ] # variant with concrete type def foo x:num -> y:num [ local-scope load-ingredients return 34 ] # shape-shifting variant def foo x:&:_elem -> y:num [ local-scope load-ingredients return 35 ] # prefer the concrete variant, ignore concrete types in scoring the shape-shifting variant +mem: storing 34 in location 1 :(scenario specialize_literal_as_address) def main [ 1:num <- foo 0 ] # variant with concrete address type def foo x:&:num -> y:num [ local-scope load-ingredients return 34 ] # shape-shifting variant def foo x:&:_elem -> y:num [ local-scope load-ingredients return 35 ] # prefer the concrete variant, ignore concrete types in scoring the shape-shifting variant +mem: storing 34 in location 1 :(scenario missing_type_during_specialization) % Hide_errors = true; # define a shape-shifting recipe def foo a:_elem [ ] # define a container with field 'z' container foo2 [ z:num ] def main [ local-scope x:foo2 <- merge 34 y:num <- get x, z:offse # typo in 'offset' # define a variable with the same name 'z' z:num <- copy 34 # trigger specialization of the shape-shifting recipe foo z ] # shouldn't crash :(scenario missing_type_during_specialization2) % Hide_errors = true; # define a shape-shifting recipe def foo a:_elem [ ] # define a container with field 'z' container foo2 [ z:num ] def main [ local-scope x:foo2 <- merge 34 y:num <- get x, z:offse # typo in 'offset' # define a variable with the same name 'z' z:&:num <- copy 34 # trigger specialization of the shape-shifting recipe foo *z ] # shouldn't crash :(scenario tangle_shape_shifting_recipe) # shape-shifting recipe def foo a:_elem [ local-scope load-ingredients ] # tangle some code that refers to the type ingredient after [ b:_elem <- copy a ] # trigger specialization def main [ local-scope foo 34 ] $error: 0 :(scenario tangle_shape_shifting_recipe_with_type_abbreviation) # shape-shifting recipe def foo a:_elem [ local-scope load-ingredients ] # tangle some code that refers to the type ingredient after [ b:bool <- copy 0 # type abbreviation ] # trigger specialization def main [ local-scope foo 34 ] $error: 0 :(scenario shape_shifting_recipe_coexists_with_primitive) # recipe overloading a primitive with a generic type def add a:&:foo:_elem [ assert 0, [should not get here] ] def main [ # call primitive add with literal 0 add 0, 0 ] $error: 0 :(scenario specialization_heuristic_test_1) # modeled on the 'buffer' container in text.mu container foo_buffer:_elem [ x:num ] def main [ append 1:&:foo_buffer:char/raw, 2:text/raw ] def append buf:&:foo_buffer:_elem, x:_elem -> buf:&:foo_buffer:_elem [ local-scope load-ingredients stash 34 ] def append buf:&:foo_buffer:char, x:_elem -> buf:&:foo_buffer:char [ local-scope load-ingredients stash 35 ] def append buf:&:foo_buffer:_elem, x:&:@:_elem -> buf:&:foo_buffer:_elem [ local-scope load-ingredients stash 36 ] +app: 36