namespace factor {
-void factor_vm::init_card_decks() {
- cards_offset = (cell) data->cards - addr_to_card(data->start);
- decks_offset = (cell) data->decks - addr_to_deck(data->start);
-}
+data_heap::data_heap(bump_allocator* vm_nursery,
+ cell young_size_,
+ cell aging_size_,
+ cell tenured_size_) {
-data_heap::data_heap(cell young_size_, cell aging_size_, cell tenured_size_) {
young_size_ = align(young_size_, deck_size);
aging_size_ = align(aging_size_, deck_size);
tenured_size_ = align(tenured_size_, deck_size);
cell total_size = young_size + 2 * aging_size + tenured_size + deck_size;
seg = new segment(total_size, false);
- cell cards_size = addr_to_card(total_size);
+ cell cards_size = total_size / card_size;
cards = new card[cards_size];
cards_end = cards + cards_size;
memset(cards, 0, cards_size);
- cell decks_size = addr_to_deck(total_size);
+ cell decks_size = total_size / deck_size;
decks = new card_deck[decks_size];
decks_end = decks + decks_size;
memset(decks, 0, decks_size);
aging = new aging_space(aging_size, tenured->end);
aging_semispace = new aging_space(aging_size, aging->end);
- nursery = new nursery_space(young_size, aging_semispace->end);
+ // Initialize vm nursery
+ vm_nursery->here = aging_semispace->end;
+ vm_nursery->start = aging_semispace->end;
+ vm_nursery->end = vm_nursery->start + young_size;
+ vm_nursery->size = young_size;
+ nursery = vm_nursery;
FACTOR_ASSERT(seg->end - nursery->end <= deck_size);
}
data_heap::~data_heap() {
delete seg;
- delete nursery;
delete aging;
delete aging_semispace;
delete tenured;
delete[] decks;
}
-data_heap* data_heap::grow(cell requested_bytes) {
- cell new_tenured_size = (tenured_size * 2) + requested_bytes;
- return new data_heap(young_size, aging_size, new_tenured_size);
+data_heap* data_heap::grow(bump_allocator* vm_nursery, cell requested_bytes) {
+ FACTOR_ASSERT(vm_nursery->occupied_space() == 0);
+ cell new_tenured_size = 2 * tenured_size + requested_bytes;
+ return new data_heap(vm_nursery, young_size, aging_size, new_tenured_size);
}
template <typename Generation> void data_heap::clear_cards(Generation* gen) {
memset(&decks[first_deck], 0, last_deck - first_deck);
}
-void data_heap::reset_generation(nursery_space* gen) { gen->here = gen->start; }
+void data_heap::reset_nursery() {
+ nursery->flush();
+}
-void data_heap::reset_generation(aging_space* gen) {
- gen->here = gen->start;
- clear_cards(gen);
- clear_decks(gen);
- gen->starts.clear_object_start_offsets();
+void data_heap::reset_aging() {
+ aging->flush();
+ clear_cards(aging);
+ clear_decks(aging);
+ aging->starts.clear_object_start_offsets();
}
-void data_heap::reset_generation(tenured_space* gen) {
- clear_cards(gen);
- clear_decks(gen);
+void data_heap::reset_tenured() {
+ clear_cards(tenured);
+ clear_decks(tenured);
}
bool data_heap::high_fragmentation_p() {
- return (tenured->largest_free_block() <= high_water_mark());
+ return tenured->largest_free_block() <= high_water_mark();
}
bool data_heap::low_memory_p() {
- return (tenured->free_space() <= high_water_mark());
+ return tenured->free_space <= high_water_mark();
}
void data_heap::mark_all_cards() {
- memset(cards, -1, cards_end - cards);
- memset(decks, -1, decks_end - decks);
+ memset(cards, 0xff, cards_end - cards);
+ memset(decks, 0xff, decks_end - decks);
}
void factor_vm::set_data_heap(data_heap* data_) {
data = data_;
- nursery = *data->nursery;
- init_card_decks();
-}
-
-void factor_vm::init_data_heap(cell young_size, cell aging_size,
- cell tenured_size) {
- set_data_heap(new data_heap(young_size, aging_size, tenured_size));
+ cards_offset = (cell)data->cards - addr_to_card(data->start);
+ decks_offset = (cell)data->decks - addr_to_deck(data->start);
}
data_heap_room factor_vm::data_room() {
data_heap_room room;
- room.nursery_size = nursery.size;
- room.nursery_occupied = nursery.occupied_space();
- room.nursery_free = nursery.free_space();
+ room.nursery_size = data->nursery->size;
+ room.nursery_occupied = data->nursery->occupied_space();
+ room.nursery_free = data->nursery->free_space();
room.aging_size = data->aging->size;
room.aging_occupied = data->aging->occupied_space();
room.aging_free = data->aging->free_space();
room.tenured_size = data->tenured->size;
room.tenured_occupied = data->tenured->occupied_space();
- room.tenured_total_free = data->tenured->free_space();
+ room.tenured_total_free = data->tenured->free_space;
room.tenured_contiguous_free = data->tenured->largest_free_block();
- room.tenured_free_block_count = data->tenured->free_block_count();
+ room.tenured_free_block_count = data->tenured->free_block_count;
room.cards = data->cards_end - data->cards;
room.decks = data->decks_end - data->decks;
room.mark_stack = mark_stack.capacity() * sizeof(cell);
return room;
}
-/* Allocates memory */
+// Allocates memory
void factor_vm::primitive_data_room() {
data_heap_room room = data_room();
ctx->push(tag<byte_array>(byte_array_from_value(&room)));
}
-struct object_accumulator {
- cell type;
- std::vector<cell> objects;
-
- explicit object_accumulator(cell type) : type(type) {}
+// Allocates memory
+cell factor_vm::instances(cell type) {
+ primitive_full_gc();
- void operator()(object* obj) {
+ std::vector<cell> objects;
+ auto object_accumulator = [&](object* obj) {
if (type == TYPE_COUNT || obj->type() == type)
objects.push_back(tag_dynamic(obj));
- }
-};
-
-/* Allocates memory */
-cell factor_vm::instances(cell type) {
- object_accumulator accum(type);
- each_object(accum);
- return std_vector_to_array(accum.objects);
+ };
+ each_object(object_accumulator);
+ return std_vector_to_array(objects);
}
-/* Allocates memory */
+// Allocates memory
void factor_vm::primitive_all_instances() {
- primitive_full_gc();
ctx->push(instances(TYPE_COUNT));
}