//: Transform to maintain multiple variants of a recipe depending on the //: number and types of the ingredients and products. Allows us to use nice //: names like 'print' or 'length' in many mutually extensible ways. :(scenario static_dispatch) recipe main [ 7:number/raw <- test 3 ] recipe test a:number -> z:number [ z <- copy 1 ] recipe test a:number, b:number -> z:number [ z <- copy 2 ] +mem: storing 1 in location 7 //: When loading recipes, accumulate variants if headers don't collide, and //: flag an error if headers collide. :(before "End Globals") map > Recipe_variants; :(before "End One-time Setup") put(Recipe_variants, "main", vector()); // since we manually added main to Recipe_ordinal :(before "Clear Other State For Recently_added_recipes") for (map >::iterator p = Recipe_variants.begin(); p != Recipe_variants.end(); ++p) { for (long long int i = 0; i < SIZE(p->second); ++i) { if (find(Recently_added_recipes.begin(), Recently_added_recipes.end(), p->second.at(i)) != Recently_added_recipes.end()) p->second.at(i) = -1; // just leave a ghost } } :(before "End Load Recipe Header(result)") // there can only ever be one variant for main if (result.name != "main" && contains_key(Recipe_ordinal, result.name)) { const recipe_ordinal r = get(Recipe_ordinal, result.name); //? cerr << result.name << ": " << contains_key(Recipe, r) << (contains_key(Recipe, r) ? get(Recipe, r).has_header : 0) << matching_variant_name(result) << '\n'; if (!contains_key(Recipe, r) || get(Recipe, r).has_header) { string new_name = matching_variant_name(result); if (new_name.empty()) { // variant doesn't already exist new_name = next_unused_recipe_name(result.name); put(Recipe_ordinal, new_name, Next_recipe_ordinal++); get_or_insert(Recipe_variants, result.name).push_back(get(Recipe_ordinal, new_name)); } trace(9999, "load") << "switching " << result.name << " to " << new_name << end(); result.name = new_name; //? cerr << "=> " << new_name << '\n'; } } else { // save first variant put(Recipe_ordinal, result.name, Next_recipe_ordinal++); get_or_insert(Recipe_variants, result.name).push_back(get(Recipe_ordinal, result.name)); } :(code) string matching_variant_name(const recipe& rr) { const vector& variants = get_or_insert(Recipe_variants, rr.name); for (long long int i = 0; i < SIZE(variants); ++i) { if (!contains_key(Recipe, variants.at(i))) continue; const recipe& candidate = get(Recipe, variants.at(i)); if (!all_reagents_match(rr, candidate)) continue; return candidate.name; } return ""; } bool all_reagents_match(const recipe& r1, const recipe& r2) { if (SIZE(r1.ingredients) != SIZE(r2.ingredients)) return false; if (SIZE(r1.products) != SIZE(r2.products)) return false; for (long long int i = 0; i < SIZE(r1.ingredients); ++i) { if (!deeply_equal_type_names(r1.ingredients.at(i), r2.ingredients.at(i))) { return false; } } for (long long int i = 0; i < SIZE(r1.products); ++i) { if (!deeply_equal_type_names(r1.products.at(i), r2.products.at(i))) { return false; } } return true; } :(before "End Globals") set Literal_type_names; :(before "End One-time Setup") Literal_type_names.insert("number"); Literal_type_names.insert("character"); :(code) bool deeply_equal_type_names(const reagent& a, const reagent& b) { return deeply_equal_type_names(a.type, b.type); } bool deeply_equal_type_names(const type_tree* a, const type_tree* b) { if (!a) return !b; if (!b) return !a; if (a->name == "literal" && b->name == "literal") return true; if (a->name == "literal") return Literal_type_names.find(b->name) != Literal_type_names.end(); if (b->name == "literal") return Literal_type_names.find(a->name) != Literal_type_names.end(); return a->name == b->name && deeply_equal_type_names(a->left, b->left) && deeply_equal_type_names(a->right, b->right); } string next_unused_recipe_name(const string& recipe_name) { for (long long int i = 2; ; ++i) { ostringstream out; out << recipe_name << '_' << i; if (!contains_key(Recipe_ordinal, out.str())) return out.str(); } } //: Once all the recipes are loaded, transform their bodies to replace each //: call with the most suitable variant. :(scenario static_dispatch_picks_most_similar_variant) recipe main [ 7:number/raw <- test 3, 4, 5 ] recipe test a:number -> z:number [ z <- copy 1 ] recipe test a:number, b:number -> z:number [ z <- copy 2 ] +mem: storing 2 in location 7 //: support recipe headers in a previous transform to fill in missing types :(before "End check_or_set_invalid_types") for (long long int i = 0; i < SIZE(caller.ingredients); ++i) check_or_set_invalid_types(caller.ingredients.at(i).type, maybe(caller.name), "recipe header ingredient"); for (long long int i = 0; i < SIZE(caller.products); ++i) check_or_set_invalid_types(caller.products.at(i).type, maybe(caller.name), "recipe header product"); //: after filling in all missing types (because we'll be introducing 'blank' types in this transform in a later layer, for shape-shifting recipes) :(after "Transform.push_back(transform_names)") Transform.push_back(resolve_ambiguous_calls); // idempotent //: In a later layer we'll introduce recursion in resolve_ambiguous_calls, by //: having it generate code for shape-shifting recipes and then transform such //: code. This data structure will help error messages be more useful. //: //: We're punning the 'call' data structure just because it has slots for //: calling recipe and calling instruction. :(before "End Globals") list resolve_stack; :(code) void resolve_ambiguous_calls(recipe_ordinal r) { recipe& caller_recipe = get(Recipe, r); trace(9991, "transform") << "--- resolve ambiguous calls for recipe " << caller_recipe.name << end(); for (long long int index = 0; index < SIZE(caller_recipe.steps); ++index) { instruction& inst = caller_recipe.steps.at(index); if (inst.is_label) continue; if (non_ghost_size(get_or_insert(Recipe_variants, inst.name)) == 0) continue; trace(9992, "transform") << "instruction " << inst.original_string << end(); resolve_stack.push_front(call(r)); resolve_stack.front().running_step_index = index; string new_name = best_variant(inst, caller_recipe); if (!new_name.empty()) inst.name = new_name; assert(resolve_stack.front().running_recipe == r); assert(resolve_stack.front().running_step_index == index); resolve_stack.pop_front(); } } string best_variant(instruction& inst, const recipe& caller_recipe) { vector& variants = get(Recipe_variants, inst.name); vector candidates; // Static Dispatch Phase 1 candidates = strictly_matching_variants(inst, variants); if (!candidates.empty()) return best_variant(inst, candidates).name; // Static Dispatch Phase 2 (shape-shifting recipes in a later layer) // End Static Dispatch Phase 2 // Static Dispatch Phase 3 candidates = strictly_matching_variants_except_literal_against_boolean(inst, variants); if (!candidates.empty()) return best_variant(inst, candidates).name; // Static Dispatch Phase 4 candidates = matching_variants(inst, variants); if (!candidates.empty()) return best_variant(inst, candidates).name; // error messages if (get(Recipe_ordinal, inst.name) >= MAX_PRIMITIVE_RECIPES) { // we currently don't check types for primitive variants raise_error << maybe(caller_recipe.name) << "failed to find a matching call for '" << to_string(inst) << "'\n" << end(); for (list::iterator p = /*skip*/++resolve_stack.begin(); p != resolve_stack.end(); ++p) { const recipe& specializer_recipe = get(Recipe, p->running_recipe); const instruction& specializer_inst = specializer_recipe.steps.at(p->running_step_index); if (specializer_recipe.name != "interactive") raise_error << " (from '" << to_string(specializer_inst) << "' in " << specializer_recipe.name << ")\n" << end(); else raise_error << " (from '" << to_string(specializer_inst) << "')\n" << end(); // One special-case to help with the rewrite_stash transform. (cross-layer) if (specializer_inst.products.at(0).name.find("stash_") == 0) { instruction stash_inst; if (next_stash(*p, &stash_inst)) { if (specializer_recipe.name != "interactive") raise_error << " (part of '" << stash_inst.original_string << "' in " << specializer_recipe.name << ")\n" << end(); else raise_error << " (part of '" << stash_inst.original_string << "')\n" << end(); } } } } return ""; } // phase 1 vector strictly_matching_variants(const instruction& inst, vector& variants) { vector result; for (long long int i = 0; i < SIZE(variants); ++i) { if (variants.at(i) == -1) continue; trace(9992, "transform") << "checking variant (strict) " << i << ": " << header_label(variants.at(i)) << end(); if (all_header_reagents_strictly_match(inst, get(Recipe, variants.at(i)))) result.push_back(variants.at(i)); } return result; } bool all_header_reagents_strictly_match(const instruction& inst, const recipe& variant) { for (long long int i = 0; i < min(SIZE(inst.ingredients), SIZE(variant.ingredients)); ++i) { if (!types_strictly_match(variant.ingredients.at(i), inst.ingredients.at(i))) { trace(9993, "transform") << "strict match failed: ingredient " << i << end(); return false; } } for (long long int i = 0; i < min(SIZE(inst.products), SIZE(variant.products)); ++i) { if (is_dummy(inst.products.at(i))) continue; if (!types_strictly_match(variant.products.at(i), inst.products.at(i))) { trace(9993, "transform") << "strict match failed: product " << i << end(); return false; } } return true; } // phase 3 vector strictly_matching_variants_except_literal_against_boolean(const instruction& inst, vector& variants) { vector result; for (long long int i = 0; i < SIZE(variants); ++i) { if (variants.at(i) == -1) continue; trace(9992, "transform") << "checking variant (strict except literals-against-booleans) " << i << ": " << header_label(variants.at(i)) << end(); if (all_header_reagents_strictly_match_except_literal_against_boolean(inst, get(Recipe, variants.at(i)))) result.push_back(variants.at(i)); } return result; } bool all_header_reagents_strictly_match_except_literal_against_boolean(const instruction& inst, const recipe& variant) { for (long long int i = 0; i < min(SIZE(inst.ingredients), SIZE(variant.ingredients)); ++i) { if (!types_strictly_match_except_literal_against_boolean(variant.ingredients.at(i), inst.ingredients.at(i))) { trace(9993, "transform") << "strict match failed: ingredient " << i << end(); return false; } } for (long long int i = 0; i < min(SIZE(variant.products), SIZE(inst.products)); ++i) { if (is_dummy(inst.products.at(i))) continue; if (!types_strictly_match_except_literal_against_boolean(variant.products.at(i), inst.products.at(i))) { trace(9993, "transform") << "strict match failed: product " << i << end(); return false; } } return true; } // phase 4 vector matching_variants(const instruction& inst, vector& variants) { vector result; for (long long int i = 0; i < SIZE(variants); ++i) { if (variants.at(i) == -1) continue; trace(9992, "transform") << "checking variant " << i << ": " << header_label(variants.at(i)) << end(); if (all_header_reagents_match(inst, get(Recipe, variants.at(i)))) result.push_back(variants.at(i)); } return result; } bool all_header_reagents_match(const instruction& inst, const recipe& variant) { for (long long int i = 0; i < min(SIZE(inst.ingredients), SIZE(variant.ingredients)); ++i) { if (!types_match(variant.ingredients.at(i), inst.ingredients.at(i))) { trace(9993, "transform") << "strict match failed: ingredient " << i << end(); return false; } } for (long long int i = 0; i < min(SIZE(variant.products), SIZE(inst.products)); ++i) { if (is_dummy(inst.products.at(i))) continue; if (!types_match(variant.products.at(i), inst.products.at(i))) { trace(9993, "transform") << "strict match failed: product " << i << end(); return false; } } return true; } // tie-breaker for each phase const recipe& best_variant(const instruction& inst, vector& candidates) { assert(!candidates.empty()); long long int min_score = 999; long long int min_index = 0; for (long long int i = 0; i < SIZE(candidates); ++i) { const recipe& candidate = get(Recipe, candidates.at(i)); long long int score = abs(SIZE(candidate.products)-SIZE(inst.products)) + abs(SIZE(candidate.ingredients)-SIZE(inst.ingredients)); assert(score < 999); if (score < min_score) { min_score = score; min_index = i; } } return get(Recipe, candidates.at(min_index)); } long long int non_ghost_size(vector& variants) { long long int result = 0; for (long long int i = 0; i < SIZE(variants); ++i) if (variants.at(i) != -1) ++result; return result; } bool next_stash(const call& c, instruction* stash_inst) { const recipe& specializer_recipe = get(Recipe, c.running_recipe); long long int index = c.running_step_index; for (++index; index < SIZE(specializer_recipe.steps); ++index) { const instruction& inst = specializer_recipe.steps.at(index); if (inst.name == "stash") { *stash_inst = inst; return true; } } return false; } :(scenario static_dispatch_disabled_in_recipe_without_variants) recipe main [ 1:number <- test 3 ] recipe test [ 2:number <- next-ingredient # ensure no header reply 34 ] +mem: storing 34 in location 1 :(scenario static_dispatch_disabled_on_headerless_definition) % Hide_errors = true; recipe test a:number -> z:number [ z <- copy 1 ] recipe test [ reply 34 ] +error: redefining recipe test :(scenario static_dispatch_disabled_on_headerless_definition_2) % Hide_errors = true; recipe test [ reply 34 ] recipe test a:number -> z:number [ z <- copy 1 ] +error: redefining recipe test :(scenario static_dispatch_on_primitive_names) recipe main [ 1:number <- copy 34 2:number <- copy 34 3:boolean <- equal 1:number, 2:number 4:boolean <- copy 0/false 5:boolean <- copy 0/false 6:boolean <- equal 4:boolean, 5:boolean ] # temporarily hardcode number equality to always fail recipe equal x:number, y:number -> z:boolean [ local-scope load-ingredients z <- copy 0/false ] # comparing numbers used overload +mem: storing 0 in location 3 # comparing booleans continues to use primitive +mem: storing 1 in location 6 :(scenario static_dispatch_works_with_dummy_results_for_containers) % Hide_errors = true; recipe main [ _ <- test 3, 4 ] recipe test a:number -> z:point [ local-scope load-ingredients z <- merge a, 0 ] recipe test a:number, b:number -> z:point [ local-scope load-ingredients z <- merge a, b ] $error: 0 :(scenario static_dispatch_works_with_compound_type_containing_container_defined_after_first_use) % Hide_errors = true; recipe main [ x:address:shared:foo <- new foo:type test x ] container foo [ x:number ] recipe test a:address:shared:foo -> z:number [ local-scope load-ingredients z:number <- get *a, x:offset ] $error: 0 :(scenario static_dispatch_works_with_compound_type_containing_container_defined_after_second_use) % Hide_errors = true; recipe main [ x:address:shared:foo <- new foo:type test x ] recipe test a:address:shared:foo -> z:number [ local-scope load-ingredients z:number <- get *a, x:offset ] container foo [ x:number ] $error: 0 :(scenario static_dispatch_prefers_literals_to_be_numbers_rather_than_addresses) recipe main [ 1:number <- foo 0 ] recipe foo x:address:number -> y:number [ reply 34 ] recipe foo x:number -> y:number [ reply 35 ] +mem: storing 35 in location 1 :(scenario static_dispatch_on_non_literal_character_ignores_variant_with_numbers) % Hide_errors = true; recipe main [ local-scope x:character <- copy 10/newline 1:number/raw <- foo x ] recipe foo x:number -> y:number [ load-ingredients reply 34 ] +error: main: ingredient 0 has the wrong type at '1:number/raw <- foo x' -mem: storing 34 in location 1 :(scenario static_dispatch_dispatches_literal_to_boolean_before_character) recipe main [ 1:number/raw <- foo 0 # valid literal for boolean ] recipe foo x:character -> y:number [ local-scope load-ingredients reply 34 ] recipe foo x:boolean -> y:number [ local-scope load-ingredients reply 35 ] # boolean variant is preferred +mem: storing 35 in location 1 :(scenario static_dispatch_dispatches_literal_to_character_when_out_of_boolean_range) recipe main [ 1:number/raw <- foo 97 # not a valid literal for boolean ] recipe foo x:character -> y:number [ local-scope load-ingredients reply 34 ] recipe foo x:boolean -> y:number [ local-scope load-ingredients reply 35 ] # character variant is preferred +mem: storing 34 in location 1 :(scenario static_dispatch_dispatches_literal_to_number_if_at_all_possible) recipe main [ 1:number/raw <- foo 97 ] recipe foo x:character -> y:number [ local-scope load-ingredients reply 34 ] recipe foo x:number -> y:number [ local-scope load-ingredients reply 35 ] # number variant is preferred +mem: storing 35 in location 1 :(code) string header_label(recipe_ordinal r) { const recipe& caller = get(Recipe, r); ostringstream out; out << "recipe " << caller.name; for (long long int i = 0; i < SIZE(caller.ingredients); ++i) out << ' ' << to_string(caller.ingredients.at(i)); if (!caller.products.empty()) out << " ->"; for (long long int i = 0; i < SIZE(caller.products); ++i) out << ' ' << to_string(caller.products.at(i)); return out.str(); } :(scenario reload_variant_retains_other_variants) recipe main [ 1:number <- copy 34 2:number <- foo 1:number ] recipe foo x:number -> y:number [ local-scope load-ingredients reply 34 ] recipe foo x:address:number -> y:number [ local-scope load-ingredients reply 35 ] recipe! foo x:address:number -> y:number [ local-scope load-ingredients reply 36 ] +mem: storing 34 in location 2 $error: 0 :(scenario dispatch_errors_come_after_unknown_name_errors) % Hide_errors = true; recipe main [ y:number <- foo x ] recipe foo a:number -> b:number [ local-scope load-ingredients reply 34 ] recipe foo a:boolean -> b:number [ local-scope load-ingredients reply 35 ] +error: main: missing type for x in 'y:number <- foo x' +error: main: failed to find a matching call for 'y:number <- foo x' :(before "End Includes") using std::abs;