//: A simple memory allocator to create space for new variables at runtime. :(scenarios run) :(scenario new) # call new two times with identical arguments; you should get back different results recipe main [ 1:address:number/raw <- new number:type 2:address:number/raw <- new number:type 3:boolean/raw <- equal 1:address:number/raw, 2:address:number/raw ] +mem: storing 0 in location 3 :(before "End Globals") long long int Memory_allocated_until = Reserved_for_tests; long long int Initial_memory_per_routine = 100000; :(before "End Setup") Memory_allocated_until = Reserved_for_tests; Initial_memory_per_routine = 100000; :(before "End routine Fields") long long int alloc, alloc_max; :(before "End routine Constructor") alloc = Memory_allocated_until; Memory_allocated_until += Initial_memory_per_routine; alloc_max = Memory_allocated_until; trace(9999, "new") << "routine allocated memory from " << alloc << " to " << alloc_max << end(); //:: 'new' takes a weird 'type' as its first ingredient; don't error on it :(before "End Mu Types Initialization") put(Type_ordinal, "type", 0); //:: typecheck 'new' instructions :(before "End Primitive Recipe Declarations") NEW, :(before "End Primitive Recipe Numbers") put(Recipe_ordinal, "new", NEW); :(before "End Primitive Recipe Checks") case NEW: { if (inst.ingredients.empty() || SIZE(inst.ingredients) > 2) { raise_error << maybe(get(Recipe, r).name) << "'new' requires one or two ingredients, but got " << inst.to_string() << '\n' << end(); break; } // End NEW Check Special-cases reagent type = inst.ingredients.at(0); if (!is_mu_type_literal(type)) { raise_error << maybe(get(Recipe, r).name) << "first ingredient of 'new' should be a type, but got " << type.original_string << '\n' << end(); break; } break; } //:: translate 'new' to 'allocate' instructions that take a size instead of a type :(after "Transform.push_back(check_instruction)") // check_instruction will guard against direct 'allocate' instructions below Transform.push_back(transform_new_to_allocate); // idempotent :(code) void transform_new_to_allocate(const recipe_ordinal r) { trace(9991, "transform") << "--- convert 'new' to 'allocate' for recipe " << get(Recipe, r).name << end(); //? cerr << "--- convert 'new' to 'allocate' for recipe " << get(Recipe, r).name << '\n'; for (long long int i = 0; i < SIZE(get(Recipe, r).steps); ++i) { instruction& inst = get(Recipe, r).steps.at(i); // Convert 'new' To 'allocate' if (inst.name == "new") { inst.operation = ALLOCATE; string_tree* type_name = new string_tree(inst.ingredients.at(0).name); // End Post-processing(type_name) When Converting 'new' type_tree* type = new_type_tree(type_name); inst.ingredients.at(0).set_value(size_of(type)); ostringstream out; dump_property(type_name, out); trace(9992, "new") << "size of " << out.str() << " is " << inst.ingredients.at(0).value << end(); delete type; delete type_name; } } } //:: implement 'allocate' based on size :(before "End Primitive Recipe Declarations") ALLOCATE, :(before "End Primitive Recipe Numbers") put(Recipe_ordinal, "allocate", ALLOCATE); :(before "End Primitive Recipe Implementations") case ALLOCATE: { // compute the space we need long long int size = ingredients.at(0).at(0); if (SIZE(ingredients) > 1) { // array trace(9999, "mem") << "array size is " << ingredients.at(1).at(0) << end(); size = /*space for length*/1 + size*ingredients.at(1).at(0); } //? Total_alloc += size; //? Num_alloc++; // compute the region of memory to return // really crappy at the moment ensure_space(size); const long long int result = Current_routine->alloc; trace(9999, "mem") << "new alloc: " << result << end(); // save result products.resize(1); products.at(0).push_back(result); // initialize allocated space for (long long int address = result; address < result+size; ++address) { put(Memory, address, 0); } if (SIZE(current_instruction().ingredients) > 1) { put(Memory, result, ingredients.at(1).at(0)); // array length } // bump Current_routine->alloc += size; // no support for reclaiming memory assert(Current_routine->alloc <= Current_routine->alloc_max); break; } //:: ensure we never call 'allocate' directly; its types are not checked :(before "End Primitive Recipe Checks") case ALLOCATE: { raise << "never call 'allocate' directly'; always use 'new'\n" << end(); break; } //:: ensure we never call 'new' without translating it (unless we add special-cases later) :(before "End Primitive Recipe Implementations") case NEW: { raise << "no implementation for 'new'; why wasn't it translated to 'allocate'?\n" << end(); break; } //? :(before "End Globals") //? long long int Total_alloc = 0; //? long long int Num_alloc = 0; //? long long int Total_free = 0; //? long long int Num_free = 0; //? :(before "End Setup") //? Total_alloc = Num_alloc = Total_free = Num_free = 0; //? :(before "End Teardown") //? cerr << Total_alloc << "/" << Num_alloc //? << " vs " << Total_free << "/" << Num_free << '\n'; //? cerr << SIZE(Memory) << '\n'; :(code) void ensure_space(long long int size) { if (size > Initial_memory_per_routine) { tb_shutdown(); cerr << "can't allocate " << size << " locations, that's too much.\n"; exit(0); } if (Current_routine->alloc + size > Current_routine->alloc_max) { // waste the remaining space and create a new chunk Current_routine->alloc = Memory_allocated_until; Memory_allocated_until += Initial_memory_per_routine; Current_routine->alloc_max = Memory_allocated_until; trace(9999, "new") << "routine allocated memory from " << Current_routine->alloc << " to " << Current_routine->alloc_max << end(); } } :(scenario new_initializes) % Memory_allocated_until = 10; % put(Memory, Memory_allocated_until, 1); recipe main [ 1:address:number <- new number:type 2:number <- copy *1:address:number ] +mem: storing 0 in location 2 :(scenario new_array) recipe main [ 1:address:array:number/raw <- new number:type, 5 2:address:number/raw <- new number:type 3:number/raw <- subtract 2:address:number/raw, 1:address:array:number/raw ] +run: 1:address:array:number/raw <- new number:type, 5 +mem: array size is 5 # don't forget the extra location for array size +mem: storing 6 in location 3 :(scenario new_empty_array) recipe main [ 1:address:array:number/raw <- new number:type, 0 2:address:number/raw <- new number:type 3:number/raw <- subtract 2:address:number/raw, 1:address:array:number/raw ] +run: 1:address:array:number/raw <- new number:type, 0 +mem: array size is 0 +mem: storing 1 in location 3 //: Make sure that each routine gets a different alloc to start. :(scenario new_concurrent) recipe f1 [ start-running f2:recipe 1:address:number/raw <- new number:type # wait for f2 to complete { loop-unless 4:number/raw } ] recipe f2 [ 2:address:number/raw <- new number:type # hack: assumes scheduler implementation 3:boolean/raw <- equal 1:address:number/raw, 2:address:number/raw # signal f2 complete 4:number/raw <- copy 1 ] +mem: storing 0 in location 3 //: If a routine runs out of its initial allocation, it should allocate more. :(scenario new_overflow) % Initial_memory_per_routine = 2; recipe main [ 1:address:number/raw <- new number:type 2:address:point/raw <- new point:type # not enough room in initial page ] +new: routine allocated memory from 1000 to 1002 +new: routine allocated memory from 1002 to 1004 //: We also provide a way to return memory, and to reuse reclaimed memory. //: todo: custodians, etc. Following malloc/free is a temporary hack. :(scenario new_reclaim) recipe main [ 1:address:number <- new number:type abandon 1:address:number 2:address:number <- new number:type # must be same size as abandoned memory to reuse 3:boolean <- equal 1:address:number, 2:address:number ] # both allocations should have returned the same address +mem: storing 1 in location 3 :(before "End Globals") map Free_list; :(before "End Setup") Free_list.clear(); :(before "End Primitive Recipe Declarations") ABANDON, :(before "End Primitive Recipe Numbers") put(Recipe_ordinal, "abandon", ABANDON); :(before "End Primitive Recipe Checks") case ABANDON: { if (SIZE(inst.ingredients) != 1) { raise_error << maybe(get(Recipe, r).name) << "'abandon' requires one ingredient, but got '" << inst.to_string() << "'\n" << end(); break; } reagent types = inst.ingredients.at(0); canonize_type(types); if (!types.type || types.type->value != get(Type_ordinal, "address")) { raise_error << maybe(get(Recipe, r).name) << "first ingredient of 'abandon' should be an address, but got " << inst.ingredients.at(0).original_string << '\n' << end(); break; } break; } :(before "End Primitive Recipe Implementations") case ABANDON: { long long int address = ingredients.at(0).at(0); reagent types = current_instruction().ingredients.at(0); canonize(types); // lookup_memory without drop_one_lookup { types.set_value(get_or_insert(Memory, types.value)); drop_address_from_type(types); // } abandon(address, size_of(types)); break; } :(code) void abandon(long long int address, long long int size) { //? Total_free += size; //? Num_free++; //? cerr << "abandon: " << size << '\n'; // clear memory for (long long int curr = address; curr < address+size; ++curr) put(Memory, curr, 0); // append existing free list to address put(Memory, address, Free_list[size]); Free_list[size] = address; } :(before "ensure_space(size)" following "case ALLOCATE") if (Free_list[size]) { long long int result = Free_list[size]; Free_list[size] = get_or_insert(Memory, result); for (long long int curr = result+1; curr < result+size; ++curr) { if (get_or_insert(Memory, curr) != 0) { raise_error << maybe(current_recipe_name()) << "memory in free list was not zeroed out: " << curr << '/' << result << "; somebody wrote to us after free!!!\n" << end(); break; // always fatal } } if (SIZE(current_instruction().ingredients) > 1) put(Memory, result, ingredients.at(1).at(0)); else put(Memory, result, 0); products.resize(1); products.at(0).push_back(result); break; } :(scenario new_differing_size_no_reclaim) recipe main [ 1:address:number <- new number:type abandon 1:address:number 2:address:number <- new number:type, 2 # different size 3:boolean <- equal 1:address:number, 2:address:number ] # no reuse +mem: storing 0 in location 3 :(scenario new_reclaim_array) recipe main [ 1:address:array:number <- new number:type, 2 abandon 1:address:array:number 2:address:array:number <- new number:type, 2 3:boolean <- equal 1:address:array:number, 2:address:array:number ] # reuse +mem: storing 1 in location 3 //:: Next, extend 'new' to handle a unicode string literal argument. :(scenario new_string) recipe main [ 1:address:array:character <- new [abc def] 2:character <- index *1:address:array:character, 5 ] # number code for 'e' +mem: storing 101 in location 2 :(scenario new_string_handles_unicode) recipe main [ 1:address:array:character <- new [a«c] 2:number <- length *1:address:array:character 3:character <- index *1:address:array:character, 1 ] +mem: storing 3 in location 2 # unicode for '«' +mem: storing 171 in location 3 :(before "End NEW Check Special-cases") if (is_literal_string(inst.ingredients.at(0))) break; :(before "Convert 'new' To 'allocate'") if (inst.name == "new" && is_literal_string(inst.ingredients.at(0))) continue; :(after "case NEW" following "Primitive Recipe Implementations") if (is_literal_string(current_instruction().ingredients.at(0))) { products.resize(1); products.at(0).push_back(new_mu_string(current_instruction().ingredients.at(0).name)); break; } :(code) long long int new_mu_string(const string& contents) { // allocate an array just large enough for it long long int string_length = unicode_length(contents); //? Total_alloc += string_length+1; //? Num_alloc++; ensure_space(string_length+1); // don't forget the extra location for array size // initialize string long long int result = Current_routine->alloc; put(Memory, Current_routine->alloc++, string_length); long long int curr = 0; const char* raw_contents = contents.c_str(); for (long long int i = 0; i < string_length; ++i) { uint32_t curr_character; assert(curr < SIZE(contents)); tb_utf8_char_to_unicode(&curr_character, &raw_contents[curr]); put(Memory, Current_routine->alloc, curr_character); curr += tb_utf8_char_length(raw_contents[curr]); ++Current_routine->alloc; } // mu strings are not null-terminated in memory return result; } //: pass in commandline args as ingredients to main //: todo: test this :(after "Update main_routine") Current_routine = main_routine; for (long long int i = 1; i < argc; ++i) { vector arg; arg.push_back(new_mu_string(argv[i])); current_call().ingredient_atoms.push_back(arg); } //: stash recognizes strings :(scenario stash_string) recipe main [ x:address:array:character <- new [abc] stash [foo:], x:address:array:character ] +app: foo: abc :(before "End print Special-cases(reagent r, data)") if (is_mu_string(r)) { assert(scalar(data)); return read_mu_string(data.at(0)); } :(scenario unicode_string) recipe main [ x:address:array:character <- new [♠] stash [foo:], x:address:array:character ] +app: foo: ♠ //: Allocate more to routine when initializing a literal string :(scenario new_string_overflow) % Initial_memory_per_routine = 2; recipe main [ 1:address:number/raw <- new number:type 2:address:array:character/raw <- new [a] # not enough room in initial page, if you take the array size into account ] +new: routine allocated memory from 1000 to 1002 +new: routine allocated memory from 1002 to 1004 //: helpers :(code) long long int unicode_length(const string& s) { const char* in = s.c_str(); long long int result = 0; long long int curr = 0; while (curr < SIZE(s)) { // carefully bounds-check on the string // before accessing its raw pointer ++result; curr += tb_utf8_char_length(in[curr]); } return result; } bool is_mu_string(const reagent& x) { return x.type && x.type->value == get(Type_ordinal, "address") && x.type->right && x.type->right->value == get(Type_ordinal, "array") && x.type->right->right && x.type->right->right->value == get(Type_ordinal, "character") && x.type->right->right->right == NULL; } string read_mu_string(long long int address) { long long int size = get_or_insert(Memory, address); if (size == 0) return ""; ostringstream tmp; for (long long int curr = address+1; curr <= address+size; ++curr) { tmp << to_unicode(static_cast(get_or_insert(Memory, curr))); } return tmp.str(); } bool is_mu_type_literal(reagent r) { //? if (!r.properties.empty()) //? dump_property(r.properties.at(0).second, cerr); return is_literal(r) && !r.properties.empty() && r.properties.at(0).second && r.properties.at(0).second->value == "type"; }