//: Support for arrays. :(before "End Mu Types Initialization") //: We'll use this array as a running example: int integer_array = Type_number["integer-array"] = Next_type_number++; Type[integer_array].is_array = true; Type[integer_array].element.push_back(integer); Type[integer_array].name = "integer-array"; //: Arrays can be copied around with a single instruction just like integers, //: no matter how large they are. :(scenario copy_array) recipe main [ 1:integer <- copy 3:literal 2:integer <- copy 14:literal 3:integer <- copy 15:literal 4:integer <- copy 16:literal 5:integer-array <- copy 1:integer-array ] +run: instruction main/4 +run: ingredient 0 is 1 +mem: location 1 is 3 +mem: location 2 is 14 +mem: location 3 is 15 +mem: location 4 is 16 +mem: storing in location 5 +mem: storing in location 6 +mem: storing in location 7 +mem: storing in location 8 :(before "End size_of Cases") if (t.is_array) { int base = r.value; if (Memory[base] == 0) return 0; reagent x(t.element[0]); x.set_value(base+1); return 1 + Memory[base]*size_of(x); } :(before "End Globals") // Operator to look at elements of arrays. const int INDEX = 20; :(before "End Primitive Recipe Numbers") Recipe_number["index"] = INDEX; assert(Next_recipe_number == INDEX); Next_recipe_number++; :(before "End Primitive Recipe Implementations") case INDEX: { trace("run") << "ingredient 0 is " << instructions[pc].ingredients[0].name; reagent base = canonize(instructions[pc].ingredients[0]); int base_address = base.value; int base_type = base.types[0]; assert(Type[base_type].is_array); trace("run") << "ingredient 1 is " << instructions[pc].ingredients[1].name; size_t offset = instructions[pc].ingredients[1].value; int src = base_address + 1 + offset*size_of(reagent(Type[base_type].element[0])); trace("run") << "address to copy is " << src; int src_type = Type[base_type].element[0]; trace("run") << "its type is " << src_type; reagent tmp(src_type); tmp.set_value(src); vector result(read_memory(tmp)); trace("run") << "product 0 is " << result[0]; write_memory(instructions[pc].products[0], result); break; } :(scenario "index") recipe main [ 1:integer <- copy 3:literal 2:integer <- copy 14:literal 3:integer <- copy 15:literal 4:integer <- copy 16:literal 5:integer <- index 1:integer-array, 0:literal ] +run: instruction main/4 +run: ingredient 0 is 1 +run: ingredient 1 is 0 +run: address to copy is 2 +run: its type is 1 +mem: location 2 is 14 +run: product 0 is 14 +mem: storing in location 5 :(before "End Globals") // To write to fields of records, you need their address. const int INDEX_ADDRESS = 21; :(before "End Primitive Recipe Numbers") Recipe_number["index-address"] = INDEX_ADDRESS; assert(Next_recipe_number == INDEX_ADDRESS); Next_recipe_number++; :(before "End Primitive Recipe Implementations") case INDEX_ADDRESS: { trace("run") << "ingredient 0 is " << instructions[pc].ingredients[0].name; reagent base = canonize(instructions[pc].ingredients[0]); int base_address = base.value; int base_type = base.types[0]; assert(Type[base_type].is_array); trace("run") << "ingredient 1 is " << instructions[pc].ingredients[1].name; size_t offset = instructions[pc].ingredients[1].value; int src = base_address + 1 + offset*size_of(reagent(Type[base_type].element[0])); trace("run") << "address to copy is " << src; vector result; result.push_back(src); trace("run") << "product 0 is " << result[0]; write_memory(instructions[pc].products[0], result); break; } :(scenario "index_address") recipe main [ 1:integer <- copy 3:literal 2:integer <- copy 14:literal 3:integer <- copy 15:literal 4:integer <- copy 16:literal 5:integer <- index-address 1:integer-array, 0:literal ] +run: instruction main/4 +run: ingredient 0 is 1 +run: ingredient 1 is 0 +run: address to copy is 2 +mem: storing in location 5