ladybird/AK/MemoryStream.cpp

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/*
* Copyright (c) 2021, kleines Filmröllchen <filmroellchen@serenityos.org>.
* Copyright (c) 2022, Tim Schumacher <timschumi@gmx.de>.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
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#include <AK/ByteBuffer.h>
#include <AK/FixedArray.h>
#include <AK/MemMem.h>
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#include <AK/MemoryStream.h>
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namespace AK {
FixedMemoryStream::FixedMemoryStream(Bytes bytes, bool writing_enabled)
: m_bytes(bytes)
, m_writing_enabled(writing_enabled)
{
}
FixedMemoryStream::FixedMemoryStream(ReadonlyBytes bytes)
: m_bytes({ const_cast<u8*>(bytes.data()), bytes.size() })
, m_writing_enabled(false)
{
}
bool FixedMemoryStream::is_eof() const
{
return m_offset >= m_bytes.size();
}
bool FixedMemoryStream::is_open() const
{
return true;
}
void FixedMemoryStream::close()
{
// FIXME: It doesn't make sense to close a memory stream. Therefore, we don't do anything here. Is that fine?
}
ErrorOr<void> FixedMemoryStream::truncate(size_t)
{
return Error::from_errno(EBADF);
}
ErrorOr<Bytes> FixedMemoryStream::read_some(Bytes bytes)
{
auto to_read = min(remaining(), bytes.size());
if (to_read == 0)
return Bytes {};
m_bytes.slice(m_offset, to_read).copy_to(bytes);
m_offset += to_read;
return bytes.trim(to_read);
}
ErrorOr<void> FixedMemoryStream::read_until_filled(AK::Bytes bytes)
{
if (remaining() < bytes.size())
return Error::from_string_view_or_print_error_and_return_errno("Can't read past the end of the stream memory"sv, EINVAL);
m_bytes.slice(m_offset).copy_trimmed_to(bytes);
m_offset += bytes.size();
return {};
}
ErrorOr<size_t> FixedMemoryStream::seek(i64 offset, SeekMode seek_mode)
{
switch (seek_mode) {
case SeekMode::SetPosition:
if (offset > static_cast<i64>(m_bytes.size()))
return Error::from_string_view_or_print_error_and_return_errno("Offset past the end of the stream memory"sv, EINVAL);
m_offset = offset;
break;
case SeekMode::FromCurrentPosition:
if (offset + static_cast<i64>(m_offset) > static_cast<i64>(m_bytes.size()))
return Error::from_string_view_or_print_error_and_return_errno("Offset past the end of the stream memory"sv, EINVAL);
m_offset += offset;
break;
case SeekMode::FromEndPosition:
if (-offset > static_cast<i64>(m_bytes.size()))
return Error::from_string_view_or_print_error_and_return_errno("Offset past the start of the stream memory"sv, EINVAL);
m_offset = m_bytes.size() + offset;
break;
}
return m_offset;
}
ErrorOr<size_t> FixedMemoryStream::write_some(ReadonlyBytes bytes)
{
VERIFY(m_writing_enabled);
// FIXME: Can this not error?
auto const nwritten = bytes.copy_trimmed_to(m_bytes.slice(m_offset));
m_offset += nwritten;
return nwritten;
}
ErrorOr<void> FixedMemoryStream::write_until_depleted(ReadonlyBytes bytes)
{
if (remaining() < bytes.size())
return Error::from_string_view_or_print_error_and_return_errno("Write of entire buffer ends past the memory area"sv, EINVAL);
TRY(write_some(bytes));
return {};
}
size_t FixedMemoryStream::offset() const
{
return m_offset;
}
size_t FixedMemoryStream::remaining() const
{
return m_bytes.size() - m_offset;
}
ErrorOr<Bytes> AllocatingMemoryStream::read_some(Bytes bytes)
{
size_t read_bytes = 0;
while (read_bytes < bytes.size()) {
VERIFY(m_write_offset >= m_read_offset);
auto range = TRY(next_read_range());
if (range.size() == 0)
break;
auto copied_bytes = range.copy_trimmed_to(bytes.slice(read_bytes));
read_bytes += copied_bytes;
m_read_offset += copied_bytes;
}
cleanup_unused_chunks();
return bytes.trim(read_bytes);
}
ErrorOr<size_t> AllocatingMemoryStream::write_some(ReadonlyBytes bytes)
{
size_t written_bytes = 0;
while (written_bytes < bytes.size()) {
VERIFY(m_write_offset >= m_read_offset);
auto range = TRY(next_write_range());
auto copied_bytes = bytes.slice(written_bytes).copy_trimmed_to(range);
written_bytes += copied_bytes;
m_write_offset += copied_bytes;
}
return written_bytes;
}
ErrorOr<void> AllocatingMemoryStream::discard(size_t count)
{
VERIFY(m_write_offset >= m_read_offset);
if (count > used_buffer_size())
return Error::from_string_view_or_print_error_and_return_errno("Number of discarded bytes is higher than the number of allocated bytes"sv, EINVAL);
m_read_offset += count;
cleanup_unused_chunks();
return {};
}
bool AllocatingMemoryStream::is_eof() const
{
return used_buffer_size() == 0;
}
bool AllocatingMemoryStream::is_open() const
{
return true;
}
void AllocatingMemoryStream::close()
{
}
size_t AllocatingMemoryStream::used_buffer_size() const
{
return m_write_offset - m_read_offset;
}
ErrorOr<Optional<size_t>> AllocatingMemoryStream::offset_of(ReadonlyBytes needle) const
{
VERIFY(m_write_offset >= m_read_offset);
if (m_chunks.size() == 0)
return Optional<size_t> {};
// Ensure that we don't have empty chunks at the beginning of the stream. Our trimming implementation
// assumes this to be the case, since this should be held up by `cleanup_unused_chunks()` at all times.
VERIFY(m_read_offset < CHUNK_SIZE);
auto empty_chunks_at_end = ((m_chunks.size() * CHUNK_SIZE - m_write_offset) / CHUNK_SIZE);
auto chunk_count = m_chunks.size() - empty_chunks_at_end;
auto search_spans = TRY(FixedArray<ReadonlyBytes>::create(chunk_count));
for (size_t i = 0; i < chunk_count; i++) {
search_spans[i] = m_chunks[i].span();
}
auto used_size_of_last_chunk = m_write_offset % CHUNK_SIZE;
// The case where the stored write offset is actually the used space is the only case where a result of zero
// actually is zero. In other cases (i.e. our write offset is beyond the size of a chunk) the write offset
// already points to the beginning of the next chunk, in that case a result of zero indicates "use the last chunk in full".
if (m_write_offset >= CHUNK_SIZE && used_size_of_last_chunk == 0)
used_size_of_last_chunk = CHUNK_SIZE;
// Trimming is done first to ensure that we don't unintentionally shift around if the first and last chunks are the same.
search_spans[chunk_count - 1] = search_spans[chunk_count - 1].trim(used_size_of_last_chunk);
search_spans[0] = search_spans[0].slice(m_read_offset);
return AK::memmem(search_spans.begin(), search_spans.end(), needle);
}
ErrorOr<ReadonlyBytes> AllocatingMemoryStream::next_read_range()
{
VERIFY(m_write_offset >= m_read_offset);
size_t const chunk_index = m_read_offset / CHUNK_SIZE;
size_t const chunk_offset = m_read_offset % CHUNK_SIZE;
size_t const read_size = min(CHUNK_SIZE - m_read_offset % CHUNK_SIZE, m_write_offset - m_read_offset);
if (read_size == 0)
return ReadonlyBytes { static_cast<u8*>(nullptr), 0 };
VERIFY(chunk_index < m_chunks.size());
return ReadonlyBytes { m_chunks[chunk_index].data() + chunk_offset, read_size };
}
ErrorOr<Bytes> AllocatingMemoryStream::next_write_range()
{
VERIFY(m_write_offset >= m_read_offset);
size_t const chunk_index = m_write_offset / CHUNK_SIZE;
size_t const chunk_offset = m_write_offset % CHUNK_SIZE;
size_t const write_size = CHUNK_SIZE - m_write_offset % CHUNK_SIZE;
if (chunk_index >= m_chunks.size())
TRY(m_chunks.try_append(TRY(Chunk::create_uninitialized(CHUNK_SIZE))));
VERIFY(chunk_index < m_chunks.size());
return Bytes { m_chunks[chunk_index].data() + chunk_offset, write_size };
}
void AllocatingMemoryStream::cleanup_unused_chunks()
{
VERIFY(m_write_offset >= m_read_offset);
auto const chunks_to_remove = m_read_offset / CHUNK_SIZE;
m_chunks.remove(0, chunks_to_remove);
m_read_offset -= CHUNK_SIZE * chunks_to_remove;
m_write_offset -= CHUNK_SIZE * chunks_to_remove;
}
}