serenity/AK/CircularBuffer.cpp

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/*
* Copyright (c) 2022, Lucas Chollet <lucas.chollet@free.fr>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/CircularBuffer.h>
#include <AK/MemMem.h>
#include <AK/Stream.h>
namespace AK {
CircularBuffer::CircularBuffer(ByteBuffer buffer)
: m_buffer(move(buffer))
{
}
ErrorOr<CircularBuffer> CircularBuffer::create_empty(size_t size)
{
auto temporary_buffer = TRY(ByteBuffer::create_uninitialized(size));
CircularBuffer circular_buffer { move(temporary_buffer) };
return circular_buffer;
}
ErrorOr<CircularBuffer> CircularBuffer::create_initialized(ByteBuffer buffer)
{
CircularBuffer circular_buffer { move(buffer) };
circular_buffer.m_used_space = circular_buffer.m_buffer.size();
return circular_buffer;
}
size_t CircularBuffer::empty_space() const
{
return capacity() - m_used_space;
}
size_t CircularBuffer::used_space() const
{
return m_used_space;
}
size_t CircularBuffer::capacity() const
{
return m_buffer.size();
}
size_t CircularBuffer::seekback_limit() const
{
return m_seekback_limit;
}
size_t SearchableCircularBuffer::search_limit() const
{
return m_seekback_limit - m_used_space;
}
bool CircularBuffer::is_wrapping_around() const
{
return capacity() <= m_reading_head + m_used_space;
}
Optional<size_t> CircularBuffer::offset_of(StringView needle, Optional<size_t> from, Optional<size_t> until) const
{
auto const read_from = from.value_or(0);
auto const read_until = until.value_or(m_used_space);
VERIFY(read_from <= read_until);
Array<ReadonlyBytes, 2> spans {};
spans[0] = next_read_span();
auto const original_span_0_size = spans[0].size();
if (read_from > 0)
spans[0] = spans[0].slice(min(spans[0].size(), read_from));
if (spans[0].size() + read_from > read_until)
spans[0] = spans[0].trim(read_until - read_from);
else if (is_wrapping_around())
spans[1] = m_buffer.span().slice(max(original_span_0_size, read_from) - original_span_0_size, min(read_until, m_used_space) - original_span_0_size);
auto maybe_found = AK::memmem(spans.begin(), spans.end(), needle.bytes());
if (maybe_found.has_value())
*maybe_found += read_from;
return maybe_found;
}
void CircularBuffer::clear()
{
m_reading_head = 0;
m_used_space = 0;
m_seekback_limit = 0;
}
Bytes CircularBuffer::next_write_span()
{
if (is_wrapping_around())
return m_buffer.span().slice(m_reading_head + m_used_space - capacity(), capacity() - m_used_space);
return m_buffer.span().slice(m_reading_head + m_used_space, capacity() - (m_reading_head + m_used_space));
}
ReadonlyBytes CircularBuffer::next_read_span(size_t offset) const
{
auto reading_head = m_reading_head;
auto used_space = m_used_space;
if (offset > 0) {
if (offset >= used_space)
return Bytes {};
reading_head = (reading_head + offset) % capacity();
used_space -= offset;
}
return m_buffer.span().slice(reading_head, min(capacity() - reading_head, used_space));
}
ReadonlyBytes CircularBuffer::next_seekback_span(size_t distance) const
{
VERIFY(m_seekback_limit <= capacity());
VERIFY(distance <= m_seekback_limit);
// Note: We are adding the capacity once here to ensure that we can wrap around the negative space by using modulo.
auto read_offset = (capacity() + m_reading_head + m_used_space - distance) % capacity();
return m_buffer.span().slice(read_offset, min(capacity() - read_offset, distance));
}
ReadonlyBytes SearchableCircularBuffer::next_search_span(size_t distance) const
{
VERIFY(search_limit() <= capacity());
VERIFY(distance <= search_limit());
// Note: We are adding the capacity once here to ensure that we can wrap around the negative space by using modulo.
auto read_offset = (capacity() + m_reading_head - distance) % capacity();
return m_buffer.span().slice(read_offset, min(capacity() - read_offset, distance));
}
size_t CircularBuffer::write(ReadonlyBytes bytes)
{
auto remaining = bytes.size();
while (remaining > 0) {
auto const next_span = next_write_span();
if (next_span.size() == 0)
break;
auto const written_bytes = bytes.slice(bytes.size() - remaining).copy_trimmed_to(next_span);
m_used_space += written_bytes;
m_seekback_limit += written_bytes;
if (m_seekback_limit > capacity())
m_seekback_limit = capacity();
remaining -= written_bytes;
}
return bytes.size() - remaining;
}
Bytes CircularBuffer::read(Bytes bytes)
{
auto remaining = bytes.size();
while (remaining > 0) {
auto const next_span = next_read_span();
if (next_span.size() == 0)
break;
auto written_bytes = next_span.copy_trimmed_to(bytes.slice(bytes.size() - remaining));
m_used_space -= written_bytes;
m_reading_head += written_bytes;
if (m_reading_head >= capacity())
m_reading_head -= capacity();
remaining -= written_bytes;
}
return bytes.trim(bytes.size() - remaining);
}
ErrorOr<Bytes> CircularBuffer::read_with_seekback(Bytes bytes, size_t distance) const
{
if (distance > m_seekback_limit)
return Error::from_string_literal("Tried a seekback read beyond the seekback limit");
auto remaining = bytes.size();
while (remaining > 0) {
auto const next_span = next_seekback_span(distance);
if (next_span.size() == 0)
break;
auto written_bytes = next_span.copy_trimmed_to(bytes.slice(bytes.size() - remaining));
distance -= written_bytes;
remaining -= written_bytes;
}
return bytes.trim(bytes.size() - remaining);
}
ErrorOr<void> CircularBuffer::discard(size_t discarding_size)
{
if (m_used_space < discarding_size)
return Error::from_string_literal("Can not discard more data than what the buffer contains");
m_used_space -= discarding_size;
m_reading_head = (m_reading_head + discarding_size) % capacity();
return {};
}
ErrorOr<size_t> CircularBuffer::fill_from_stream(Stream& stream)
{
auto next_span = next_write_span();
if (next_span.size() == 0)
return 0;
auto bytes = TRY(stream.read_some(next_span));
m_used_space += bytes.size();
m_seekback_limit += bytes.size();
if (m_seekback_limit > capacity())
m_seekback_limit = capacity();
return bytes.size();
}
ErrorOr<size_t> CircularBuffer::flush_to_stream(Stream& stream)
{
auto next_span = next_read_span();
if (next_span.size() == 0)
return 0;
auto written_bytes = TRY(stream.write_some(next_span));
m_used_space -= written_bytes;
m_reading_head += written_bytes;
if (m_reading_head >= capacity())
m_reading_head -= capacity();
return written_bytes;
}
ErrorOr<size_t> CircularBuffer::copy_from_seekback(size_t distance, size_t length)
{
if (distance > m_seekback_limit)
return Error::from_string_literal("Tried a seekback copy beyond the seekback limit");
auto remaining_length = length;
while (remaining_length > 0) {
if (empty_space() == 0)
break;
auto next_span = next_seekback_span(distance);
if (next_span.size() == 0)
break;
auto length_written = write(next_span.trim(remaining_length));
remaining_length -= length_written;
// If we copied right from the end of the seekback area (i.e. our length is larger than the distance)
// and the last copy was one complete "chunk", we can now double the distance to copy twice as much data in one go.
if (remaining_length > distance && length_written == distance)
distance *= 2;
}
return length - remaining_length;
}
SearchableCircularBuffer::SearchableCircularBuffer(ByteBuffer buffer)
: CircularBuffer(move(buffer))
{
}
ErrorOr<SearchableCircularBuffer> SearchableCircularBuffer::create_empty(size_t size)
{
auto temporary_buffer = TRY(ByteBuffer::create_uninitialized(size));
SearchableCircularBuffer circular_buffer { move(temporary_buffer) };
return circular_buffer;
}
ErrorOr<SearchableCircularBuffer> SearchableCircularBuffer::create_initialized(ByteBuffer buffer)
{
SearchableCircularBuffer circular_buffer { move(buffer) };
circular_buffer.m_used_space = circular_buffer.m_buffer.size();
for (size_t i = 0; i + HASH_CHUNK_SIZE <= circular_buffer.m_buffer.size(); i++)
TRY(circular_buffer.insert_location_hash(circular_buffer.m_buffer.span().slice(i, HASH_CHUNK_SIZE), i));
return circular_buffer;
}
ErrorOr<Bytes> SearchableCircularBuffer::read(Bytes bytes)
{
auto read_bytes_span = CircularBuffer::read(bytes);
TRY(hash_last_bytes(read_bytes_span.size()));
return read_bytes_span;
}
ErrorOr<void> SearchableCircularBuffer::discard(size_t discarded_bytes)
{
TRY(CircularBuffer::discard(discarded_bytes));
TRY(hash_last_bytes(discarded_bytes));
return {};
}
ErrorOr<size_t> SearchableCircularBuffer::flush_to_stream(Stream& stream)
{
auto flushed_byte_count = TRY(CircularBuffer::flush_to_stream(stream));
TRY(hash_last_bytes(flushed_byte_count));
return flushed_byte_count;
}
Optional<SearchableCircularBuffer::Match> SearchableCircularBuffer::find_copy_in_seekback(size_t maximum_length, size_t minimum_length)
{
VERIFY(minimum_length > 0);
// Clip the maximum length to the amount of data that we actually store.
if (maximum_length > m_used_space)
maximum_length = m_used_space;
if (maximum_length < minimum_length)
return {};
Optional<Match> best_match;
Array<u8, HASH_CHUNK_SIZE> needle_storage;
auto needle = needle_storage.span().trim(min(HASH_CHUNK_SIZE, maximum_length));
{
auto needle_read_bytes = MUST(read_with_seekback(needle, used_space()));
VERIFY(needle_read_bytes.size() == needle.size());
}
// Try an efficient hash-based search first.
if (needle.size() >= HASH_CHUNK_SIZE) {
auto needle_hash = StringView { needle }.hash();
auto maybe_starting_offset = m_hash_location_map.get(needle_hash);
if (maybe_starting_offset.has_value()) {
Optional<size_t> previous_buffer_offset;
auto current_buffer_offset = maybe_starting_offset.value();
while (true) {
auto current_search_offset = (capacity() + m_reading_head - current_buffer_offset) % capacity();
// Validate the hash. In case it is invalid, we can discard the rest of the chain, as the data (and everything older) got updated.
Array<u8, HASH_CHUNK_SIZE> hash_chunk_at_offset;
auto hash_chunk_at_offset_span = MUST(read_with_seekback(hash_chunk_at_offset, current_search_offset + used_space()));
VERIFY(hash_chunk_at_offset_span.size() == HASH_CHUNK_SIZE);
auto found_chunk_hash = StringView { hash_chunk_at_offset }.hash();
if (needle_hash != found_chunk_hash) {
if (!previous_buffer_offset.has_value())
m_hash_location_map.remove(needle_hash);
else
m_location_chain_map.remove(*previous_buffer_offset);
break;
}
// Validate the match through the set-distance-based implementation.
auto maybe_new_match = find_copy_in_seekback(Array { current_search_offset }, maximum_length, HASH_CHUNK_SIZE);
// If we found a match, record it.
// If we haven't found a match, we simply got a hash collision, so skip.
if (maybe_new_match.has_value()) {
auto new_match = maybe_new_match.release_value();
if (!best_match.has_value() || best_match->length < new_match.length) {
best_match = new_match;
// If we already found a result with the best possible length, then stop searching.
if (best_match->length >= maximum_length)
break;
}
}
// Get the next location with the same hash from the location chain.
auto maybe_next_buffer_offset = m_location_chain_map.get(current_buffer_offset);
// End of the chain, nothing more to check.
if (!maybe_next_buffer_offset.has_value())
break;
previous_buffer_offset = current_buffer_offset;
current_buffer_offset = maybe_next_buffer_offset.release_value();
}
// If we found a match, return it now.
if (best_match.has_value())
return best_match;
}
}
// Try a plain memory search for smaller values.
// Note: This overlaps with the hash search for chunks of size HASH_CHUNK_SIZE for the purpose of validation.
if (minimum_length <= HASH_CHUNK_SIZE) {
size_t haystack_offset_from_start = 0;
Vector<ReadonlyBytes, 2> haystack;
haystack.append(next_search_span(search_limit()));
if (haystack[0].size() < search_limit())
haystack.append(next_search_span(search_limit() - haystack[0].size()));
// TODO: `memmem` searches the memory in "natural" order, which means that it finds matches with a greater distance first.
// Hash-based searching finds the shortest distances first, which is most likely better for encoding and memory efficiency.
// Look into creating a `memmem_reverse`, which starts searching from the end.
auto memmem_match = AK::memmem(haystack.begin(), haystack.end(), needle);
while (memmem_match.has_value()) {
auto match_offset = memmem_match.release_value();
auto corrected_match_distance = search_limit() - haystack_offset_from_start - match_offset;
// Validate the match through the set-distance-based implementation and extend it to the largest size possible.
auto maybe_new_match = find_copy_in_seekback(Array { corrected_match_distance }, min(maximum_length, HASH_CHUNK_SIZE), minimum_length);
// If we weren't able to validate the match at all, either our memmem search returned garbage or our validation function is incorrect. Investigate.
VERIFY(maybe_new_match.has_value());
auto new_match = maybe_new_match.release_value();
if (!best_match.has_value() || best_match->length < new_match.length) {
best_match = new_match;
// If we already found a result with the best possible length, then stop searching.
if (best_match->length >= maximum_length)
break;
}
auto size_to_discard = match_offset + 1;
// Trim away the already processed bytes from the haystack.
haystack_offset_from_start += size_to_discard;
while (size_to_discard > 0) {
if (haystack[0].size() < size_to_discard) {
size_to_discard -= haystack[0].size();
haystack.remove(0);
} else {
haystack[0] = haystack[0].slice(size_to_discard);
break;
}
}
if (haystack.size() == 0)
break;
// Try and find the next match.
memmem_match = AK::memmem(haystack.begin(), haystack.end(), needle);
}
// If we found a match of size HASH_CHUNK_SIZE, we should have already found that using the hash search. Investigate.
VERIFY(!best_match.has_value() || best_match->length < HASH_CHUNK_SIZE);
}
return best_match;
}
Optional<SearchableCircularBuffer::Match> SearchableCircularBuffer::find_copy_in_seekback(ReadonlySpan<size_t> distances, size_t maximum_length, size_t minimum_length) const
{
VERIFY(minimum_length > 0);
// Clip the maximum length to the amount of data that we actually store.
if (maximum_length > m_used_space)
maximum_length = m_used_space;
if (maximum_length < minimum_length)
return Optional<Match> {};
Optional<Match> best_match;
for (auto distance : distances) {
// Discard distances outside the valid range.
if (distance > search_limit() || distance <= 0)
continue;
// TODO: This does not yet support looping repetitions.
if (distance < minimum_length)
continue;
auto current_match_length = 0ul;
while (current_match_length < maximum_length) {
auto haystack = next_search_span(distance - current_match_length).trim(maximum_length - current_match_length);
auto needle = next_read_span(current_match_length).trim(maximum_length - current_match_length);
auto submatch_length = haystack.matching_prefix_length(needle);
if (submatch_length == 0)
break;
current_match_length += submatch_length;
}
// Discard matches that don't reach the minimum length.
if (current_match_length < minimum_length)
continue;
if (!best_match.has_value() || best_match->length < current_match_length)
best_match = Match { distance, current_match_length };
}
return best_match;
}
ErrorOr<void> SearchableCircularBuffer::insert_location_hash(ReadonlyBytes value, size_t raw_offset)
{
VERIFY(value.size() == HASH_CHUNK_SIZE);
auto value_hash = StringView { value }.hash();
// Discard any old entries for this offset first. This should eliminate accidental loops by breaking the chain.
// The actual cleanup is done on access, since we can only remove invalid references when actually walking the chain.
m_location_chain_map.remove(raw_offset);
// Check if we have any existing entries for this hash.
// If so, we need to add it to the location chain map instead, as we will soon replace the entry in the hash location map.
auto existing_entry = m_hash_location_map.get(value_hash);
if (existing_entry.has_value())
TRY(m_location_chain_map.try_set(raw_offset, existing_entry.value()));
TRY(m_hash_location_map.try_set(value_hash, raw_offset));
return {};
}
ErrorOr<void> SearchableCircularBuffer::hash_last_bytes(size_t count)
{
// Stop early if we don't have enough data overall to hash a full chunk.
if (search_limit() < HASH_CHUNK_SIZE)
return {};
auto remaining_recalculations = count;
while (remaining_recalculations > 0) {
// Note: We offset everything by HASH_CHUNK_SIZE because we have up to HASH_CHUNK_SIZE - 1 bytes that we couldn't hash before (as we had missing data).
// The number of recalculations stays the same, since we now have up to HASH_CHUNK_SIZE - 1 bytes that we can't hash now.
auto recalculation_span = next_search_span(min(remaining_recalculations + HASH_CHUNK_SIZE - 1, search_limit()));
// If the span is smaller than a hash chunk, we need to manually craft some consecutive data to do the hashing.
if (recalculation_span.size() < HASH_CHUNK_SIZE) {
auto auxiliary_span = next_seekback_span(remaining_recalculations);
// Ensure that our math is correct and that both spans are "adjacent".
VERIFY(recalculation_span.data() + recalculation_span.size() == m_buffer.data() + m_buffer.size());
VERIFY(auxiliary_span.data() == m_buffer.data());
while (recalculation_span.size() > 0 && recalculation_span.size() + auxiliary_span.size() >= HASH_CHUNK_SIZE) {
Array<u8, HASH_CHUNK_SIZE> temporary_hash_chunk;
auto copied_from_recalculation_span = recalculation_span.copy_to(temporary_hash_chunk);
VERIFY(copied_from_recalculation_span == recalculation_span.size());
auto copied_from_auxiliary_span = auxiliary_span.copy_to(temporary_hash_chunk.span().slice(copied_from_recalculation_span));
VERIFY(copied_from_recalculation_span + copied_from_auxiliary_span == HASH_CHUNK_SIZE);
TRY(insert_location_hash(temporary_hash_chunk, recalculation_span.data() - m_buffer.data()));
recalculation_span = recalculation_span.slice(1);
remaining_recalculations--;
}
continue;
}
for (size_t i = 0; i + HASH_CHUNK_SIZE <= recalculation_span.size(); i++) {
auto value = recalculation_span.slice(i, HASH_CHUNK_SIZE);
auto raw_offset = value.data() - m_buffer.data();
TRY(insert_location_hash(value, raw_offset));
remaining_recalculations--;
}
}
return {};
}
}