transmission/libtransmission/completion.cc

263 lines
6.0 KiB
C++

// This file Copyright 2021-2022 Mnemosyne LLC.
// It may be used under GPLv2 (SPDX: GPL-2.0-only), GPLv3 (SPDX: GPL-3.0-only),
// or any future license endorsed by Mnemosyne LLC.
// License text can be found in the licenses/ folder.
#include <algorithm>
#include <memory>
#include <vector>
#include "transmission.h"
#include "completion.h"
#include "torrent.h"
#include "tr-assert.h"
uint64_t tr_completion::leftUntilDone() const
{
auto const size_when_done = sizeWhenDone();
auto const has_total = hasTotal();
return size_when_done - has_total;
}
uint64_t tr_completion::computeHasValid() const
{
uint64_t size = 0;
for (tr_piece_index_t piece = 0, n = block_info_->n_pieces; piece < n; ++piece)
{
if (hasPiece(piece))
{
size += block_info_->pieceSize(piece);
}
}
return size;
}
uint64_t tr_completion::hasValid() const
{
if (!has_valid_)
{
has_valid_ = computeHasValid();
}
return *has_valid_;
}
uint64_t tr_completion::computeSizeWhenDone() const
{
if (hasAll())
{
return block_info_->total_size;
}
// count bytes that we want or that we already have
auto size = uint64_t{ 0 };
for (tr_piece_index_t piece = 0; piece < block_info_->n_pieces; ++piece)
{
if (tor_->pieceIsWanted(piece))
{
size += block_info_->pieceSize(piece);
}
else
{
size += countHasBytesInBlocks(block_info_->blockSpanForPiece(piece));
}
}
return size;
}
uint64_t tr_completion::sizeWhenDone() const
{
if (!size_when_done_)
{
size_when_done_ = computeSizeWhenDone();
}
return *size_when_done_;
}
void tr_completion::amountDone(float* tab, size_t n_tabs) const
{
if (n_tabs < 1)
{
return;
}
auto const blocks_per_tab = std::size(blocks_) / n_tabs;
for (size_t i = 0; i < n_tabs; ++i)
{
auto const begin = i * blocks_per_tab;
auto const end = std::min(begin + blocks_per_tab, std::size(blocks_));
auto const numerator = blocks_.count(begin, end);
tab[i] = float(numerator) / (end - begin);
}
}
size_t tr_completion::countMissingBlocksInPiece(tr_piece_index_t piece) const
{
auto const [begin, end] = block_info_->blockSpanForPiece(piece);
return (end - begin) - blocks_.count(begin, end);
}
size_t tr_completion::countMissingBytesInPiece(tr_piece_index_t piece) const
{
return block_info_->pieceSize(piece) - countHasBytesInBlocks(block_info_->blockSpanForPiece(piece));
}
tr_completeness tr_completion::status() const
{
if (!hasMetainfo())
{
return TR_LEECH;
}
if (hasAll())
{
return TR_SEED;
}
if (size_now_ == sizeWhenDone())
{
return TR_PARTIAL_SEED;
}
return TR_LEECH;
}
std::vector<uint8_t> tr_completion::createPieceBitfield() const
{
size_t const n = block_info_->n_pieces;
auto pieces = tr_bitfield{ n };
auto flags = std::make_unique<bool[]>(n);
for (tr_piece_index_t piece = 0; piece < n; ++piece)
{
flags[piece] = hasPiece(piece);
}
pieces.setFromBools(flags.get(), n);
return pieces.raw();
}
/// mutators
void tr_completion::addBlock(tr_block_index_t block)
{
if (hasBlock(block))
{
return; // already had it
}
blocks_.set(block);
size_now_ += block_info_->blockSize(block);
has_valid_.reset();
}
void tr_completion::setBlocks(tr_bitfield blocks)
{
TR_ASSERT(std::size(blocks_) == std::size(blocks));
blocks_ = std::move(blocks);
size_now_ = countHasBytesInBlocks({ 0, tr_block_index_t(std::size(blocks_)) });
size_when_done_.reset();
has_valid_.reset();
}
void tr_completion::setHasAll()
{
auto const total_size = block_info_->totalSize();
blocks_.setHasAll();
size_now_ = total_size;
size_when_done_ = total_size;
has_valid_ = total_size;
}
void tr_completion::addPiece(tr_piece_index_t piece)
{
auto const [begin, end] = block_info_->blockSpanForPiece(piece);
for (tr_block_index_t block = begin; block < end; ++block)
{
addBlock(block);
}
}
void tr_completion::removePiece(tr_piece_index_t piece)
{
auto const [begin, end] = block_info_->blockSpanForPiece(piece);
size_now_ -= countHasBytesInBlocks(block_info_->blockSpanForPiece(piece));
has_valid_.reset();
blocks_.unsetSpan(begin, end);
}
uint64_t tr_completion::countHasBytesInBlocks(tr_block_span_t span) const
{
auto const [begin, end] = span;
uint64_t n = blocks_.count(begin, end);
n *= block_info_->block_size;
if (end == block_info_->n_blocks && blocks_.test(end - 1))
{
n -= block_info_->block_size - block_info_->final_block_size;
}
return n;
}
uint64_t tr_completion::countHasBytesInSpan(tr_byte_span_t span) const
{
// confirm the span is valid
span.begin = std::clamp(span.begin, uint64_t{ 0 }, block_info_->total_size);
span.end = std::clamp(span.end, uint64_t{ 0 }, block_info_->total_size);
auto const [begin_byte, end_byte] = span;
if (begin_byte >= end_byte)
{
return 0;
}
// get the block span of the byte span
auto const begin_block = block_info_->byteLoc(begin_byte).block;
auto const final_block = block_info_->byteLoc(end_byte - 1).block;
// if the entire span is in a single block
if (begin_block == final_block)
{
return hasBlock(begin_block) ? end_byte - begin_byte : 0;
}
auto total = uint64_t{};
// the first block
if (hasBlock(begin_block))
{
uint64_t u = begin_block + 1;
u *= block_info_->block_size;
u -= begin_byte;
total += u;
}
// the middle blocks
if (begin_block + 1 < final_block)
{
uint64_t u = blocks_.count(begin_block + 1, final_block);
u *= block_info_->block_size;
total += u;
}
// the last block
if (hasBlock(final_block))
{
uint64_t u = final_block;
u *= block_info_->block_size;
total += end_byte - u;
}
return total;
}