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factor/vm/free_list.hpp

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6.1 KiB
C++
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namespace factor {
static const cell free_list_count = 32;
static const cell allocation_page_size = 1024;
struct free_heap_block {
cell header;
bool free_p() const { return (header & 1) == 1; }
cell size() const {
cell size = header & ~7;
FACTOR_ASSERT(size > 0);
return size;
}
void make_free(cell size) {
FACTOR_ASSERT(size > 0);
header = size | 1;
}
};
struct block_size_compare {
bool operator()(free_heap_block* a, free_heap_block* b) const {
return a->size() < b->size();
}
};
typedef std::multiset<free_heap_block*, block_size_compare> large_block_set;
struct free_list {
std::vector<free_heap_block*> small_blocks[free_list_count];
large_block_set large_blocks;
cell free_block_count;
cell free_space;
void clear_free_list();
void initial_free_list(cell start, cell end, cell occupied);
void add_to_free_list(free_heap_block* block);
free_heap_block* find_free_block(cell size);
free_heap_block* split_free_block(free_heap_block* block, cell size);
bool can_allot_p(cell size);
cell largest_free_block();
};
struct allocator_room {
cell size;
cell occupied_space;
cell total_free;
cell contiguous_free;
cell free_block_count;
};
template <typename Block> struct free_list_allocator {
cell size;
cell start;
cell end;
free_list free_blocks;
mark_bits state;
free_list_allocator(cell size, cell start);
void initial_free_list(cell occupied);
bool contains_p(Block* block);
bool can_allot_p(cell size);
Block* allot(cell size);
void free(Block* block);
cell occupied_space();
cell free_space();
cell largest_free_block();
cell free_block_count();
void sweep();
template <typename Iterator> void sweep(Iterator& iter);
template <typename Iterator, typename Fixup>
void compact(Iterator& iter, Fixup fixup, const Block** finger);
template <typename Iterator, typename Fixup>
void iterate(Iterator& iter, Fixup fixup);
template <typename Iterator> void iterate(Iterator& iter);
allocator_room as_allocator_room();
};
template <typename Block>
free_list_allocator<Block>::free_list_allocator(cell size, cell start)
: size(size),
start(start),
end(start + size),
state(mark_bits(size, start)) {
initial_free_list(0);
}
template <typename Block>
void free_list_allocator<Block>::initial_free_list(cell occupied) {
free_blocks.initial_free_list(start, end, occupied);
}
template <typename Block>
bool free_list_allocator<Block>::contains_p(Block* block) {
return ((cell)block - start) < size;
}
template <typename Block>
bool free_list_allocator<Block>::can_allot_p(cell size) {
return free_blocks.can_allot_p(size);
}
template <typename Block> Block* free_list_allocator<Block>::allot(cell size) {
size = align(size, data_alignment);
free_heap_block* block = free_blocks.find_free_block(size);
if (block) {
block = free_blocks.split_free_block(block, size);
return (Block*)block;
} else
return NULL;
}
template <typename Block> void free_list_allocator<Block>::free(Block* block) {
free_heap_block* free_block = (free_heap_block*)block;
free_block->make_free(block->size());
free_blocks.add_to_free_list(free_block);
}
template <typename Block> cell free_list_allocator<Block>::free_space() {
return free_blocks.free_space;
}
template <typename Block> cell free_list_allocator<Block>::occupied_space() {
return size - free_blocks.free_space;
}
template <typename Block>
cell free_list_allocator<Block>::largest_free_block() {
return free_blocks.largest_free_block();
}
template <typename Block> cell free_list_allocator<Block>::free_block_count() {
return free_blocks.free_block_count;
}
template <typename Block>
template <typename Iterator>
void free_list_allocator<Block>::sweep(Iterator& iter) {
free_blocks.clear_free_list();
cell start = this->start;
cell end = this->end;
while (start != end) {
/* find next unmarked block */
start = state.next_unmarked_block_after(start);
if (start != end) {
/* find size */
cell size = state.unmarked_block_size(start);
FACTOR_ASSERT(size > 0);
free_heap_block* free_block = (free_heap_block*)start;
free_block->make_free(size);
free_blocks.add_to_free_list(free_block);
iter((Block*)start, size);
start = start + size;
}
}
}
template <typename Block> void free_list_allocator<Block>::sweep() {
auto null_sweep = [](Block* free_block, cell size) { };
sweep(null_sweep);
}
/* The forwarding map must be computed first by calling
state.compute_forwarding(). */
template <typename Block>
template <typename Iterator, typename Fixup>
void free_list_allocator<Block>::compact(Iterator& iter, Fixup fixup,
const Block** finger) {
cell dest_addr = start;
auto compact_block_func = [&](Block* block, cell size) {
cell block_addr = (cell)block;
if (!state.marked_p(block_addr))
return;
*finger = (Block*)(block_addr + size);
memmove((Block*)dest_addr, block, size);
iter(block, (Block*)dest_addr, size);
dest_addr += size;
};
iterate(compact_block_func, fixup);
/* Now update the free list; there will be a single free block at
the end */
free_blocks.initial_free_list(start, end, dest_addr - start);
}
/* During compaction we have to be careful and measure object sizes
differently */
template <typename Block>
template <typename Iterator, typename Fixup>
void free_list_allocator<Block>::iterate(Iterator& iter, Fixup fixup) {
cell scan = this->start;
while (scan != this->end) {
Block* block = (Block*)scan;
cell size = fixup.size(block);
if (!block->free_p())
iter(block, size);
scan += size;
}
}
template <typename Block>
template <typename Iterator>
void free_list_allocator<Block>::iterate(Iterator& iter) {
iterate(iter, no_fixup());
}
template <typename Block>
allocator_room free_list_allocator<Block>::as_allocator_room() {
allocator_room room;
room.size = size;
room.occupied_space = occupied_space();
room.total_free = free_space();
room.contiguous_free = largest_free_block();
room.free_block_count = free_block_count();
return room;
}
}
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