// // Copyright Aliaksei Levin (levlam@telegram.org), Arseny Smirnov (arseny30@gmail.com) 2014-2019 // // Distributed under the Boost Software License, Version 1.0. (See accompanying // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) // #include "td/telegram/files/PartsManager.h" #include "td/utils/format.h" #include "td/utils/logging.h" #include "td/utils/misc.h" #include #include namespace td { /*** PartsManager ***/ namespace { int64 calc_part_count(int64 size, int64 part_size) { CHECK(part_size != 0); return (size + part_size - 1) / part_size; } } // namespace Status PartsManager::init_known_prefix(int64 known_prefix, size_t part_size, const std::vector &ready_parts) { known_prefix_flag_ = true; known_prefix_size_ = known_prefix; return init_no_size(part_size, ready_parts); } void PartsManager::set_streaming_offset(int64 offset) { if (offset < 0 || need_check_ || (!unknown_size_flag_ && get_size() < offset)) { streaming_offset_ = 0; return; } auto part_i = offset / part_size_; if (part_i >= MAX_PART_COUNT) { streaming_offset_ = 0; // error? return; } streaming_offset_ = offset; first_streaming_empty_part_ = narrow_cast(part_i); first_streaming_not_ready_part_ = narrow_cast(part_i); if (part_count_ < first_streaming_empty_part_) { part_count_ = first_streaming_empty_part_; part_status_.resize(part_count_, PartStatus::Empty); } } void PartsManager::set_streaming_limit(int64 limit) { streaming_limit_ = limit; streaming_ready_size_ = 0; if (streaming_limit_ == 0) { return; } for (int part_i = 0; part_i < part_count_; part_i++) { if (is_part_in_streaming_limit(part_i) && part_status_[part_i] == PartStatus::Ready) { streaming_ready_size_ += get_part(part_i).size; } } } Status PartsManager::init_no_size(size_t part_size, const std::vector &ready_parts) { unknown_size_flag_ = true; size_ = 0; min_size_ = 0; max_size_ = std::numeric_limits::max(); if (part_size != 0) { part_size_ = part_size; } else { part_size_ = 32 * (1 << 10); while (use_part_count_limit_ && calc_part_count(expected_size_, part_size_) > MAX_PART_COUNT) { part_size_ *= 2; CHECK(part_size_ <= MAX_PART_SIZE); } // just in case if expected_size_ is wrong if (part_size_ < MAX_PART_SIZE) { part_size_ *= 2; } } part_count_ = std::accumulate(ready_parts.begin(), ready_parts.end(), 0, [](auto a, auto b) { return max(a, b + 1); }); init_common(ready_parts); return Status::OK(); } Status PartsManager::init(int64 size, int64 expected_size, bool is_size_final, size_t part_size, const std::vector &ready_parts, bool use_part_count_limit) { CHECK(expected_size >= size); use_part_count_limit_ = use_part_count_limit; expected_size_ = expected_size; if (expected_size_ > MAX_FILE_SIZE) { return Status::Error("Too big file"); } if (!is_size_final) { return init_known_prefix(size, part_size, ready_parts); } if (size == 0) { return init_no_size(part_size, ready_parts); } LOG_CHECK(size > 0) << tag("size", size); unknown_size_flag_ = false; size_ = size; if (part_size != 0) { part_size_ = part_size; if (use_part_count_limit_ && calc_part_count(expected_size_, part_size_) > MAX_PART_COUNT) { return Status::Error("FILE_UPLOAD_RESTART"); } } else { // TODO choose part_size_ depending on size part_size_ = 64 * (1 << 10); while (use_part_count_limit && calc_part_count(expected_size_, part_size_) > MAX_PART_COUNT) { part_size_ *= 2; CHECK(part_size_ <= MAX_PART_SIZE); } } LOG_CHECK(1 <= size_) << tag("size_", size_); LOG_CHECK(!use_part_count_limit || calc_part_count(expected_size_, part_size_) <= MAX_PART_COUNT) << tag("size_", size_) << tag("expected_size", size_) << tag("is_size_final", is_size_final) << tag("part_size_", part_size_) << tag("ready_parts", ready_parts.size()); part_count_ = static_cast(calc_part_count(size_, part_size_)); init_common(ready_parts); return Status::OK(); } bool PartsManager::unchecked_ready() { VLOG(files) << "Check readiness. Ready size is " << ready_size_ << ", total size is " << size_ << ", unknown_size_flag = " << unknown_size_flag_ << ", need_check = " << need_check_ << ", checked_prefix_size = " << checked_prefix_size_; return !unknown_size_flag_ && ready_size_ == size_; } bool PartsManager::may_finish() { if (is_streaming_limit_reached()) { return true; } return ready(); } bool PartsManager::ready() { return unchecked_ready() && (!need_check_ || checked_prefix_size_ == size_); } Status PartsManager::finish() { if (ready()) { return Status::OK(); } if (is_streaming_limit_reached()) { return Status::Error("FILE_DOWNLOAD_LIMIT"); } return Status::Error("File transferring not finished"); } void PartsManager::update_first_empty_part() { while (first_empty_part_ < part_count_ && part_status_[first_empty_part_] != PartStatus::Empty) { first_empty_part_++; } if (streaming_offset_ == 0) { first_streaming_empty_part_ = first_empty_part_; return; } while (first_streaming_empty_part_ < part_count_ && part_status_[first_streaming_empty_part_] != PartStatus::Empty) { first_streaming_empty_part_++; } } void PartsManager::update_first_not_ready_part() { while (first_not_ready_part_ < part_count_ && part_status_[first_not_ready_part_] == PartStatus::Ready) { first_not_ready_part_++; } if (streaming_offset_ == 0) { first_streaming_not_ready_part_ = first_not_ready_part_; return; } while (first_streaming_not_ready_part_ < part_count_ && part_status_[first_streaming_not_ready_part_] == PartStatus::Ready) { first_streaming_not_ready_part_++; } } int32 PartsManager::get_unchecked_ready_prefix_count() { update_first_not_ready_part(); return first_not_ready_part_; } int32 PartsManager::get_ready_prefix_count() { auto res = get_unchecked_ready_prefix_count(); if (need_check_) { auto checked_parts = narrow_cast(checked_prefix_size_ / part_size_); if (checked_parts < res) { return checked_parts; } } return res; } string PartsManager::get_bitmask() { int32 prefix_count = -1; if (need_check_) { prefix_count = narrow_cast(checked_prefix_size_ / part_size_); } return bitmask_.encode(prefix_count); } bool PartsManager::is_part_in_streaming_limit(int part_i) const { auto offset_begin = static_cast(part_i * get_part_size()); auto offset_end = static_cast(offset_begin + get_part(part_i).size); if (offset_begin >= get_expected_size()) { return false; } if (streaming_limit_ == 0) { return true; } auto is_intersect_with = [&](int64 begin, int64 end) { return std::max(begin, offset_begin) < std::min(end, offset_end); }; auto streaming_begin = streaming_offset_; auto streaming_end = streaming_offset_ + streaming_limit_; if (is_intersect_with(streaming_begin, streaming_end)) { return true; } // wrap limit if (!unknown_size_flag_ && streaming_end > get_size() && is_intersect_with(0, streaming_end - get_size())) { return true; } return false; } bool PartsManager::is_streaming_limit_reached() { if (streaming_limit_ == 0) { return false; } update_first_not_ready_part(); auto part_i = first_streaming_not_ready_part_; // wrap if (!unknown_size_flag_ && part_i == part_count_) { part_i = first_not_ready_part_; } return !is_part_in_streaming_limit(part_i); } Result PartsManager::start_part() { update_first_empty_part(); auto part_i = first_streaming_empty_part_; if (known_prefix_flag_ && part_i >= static_cast(known_prefix_size_ / part_size_)) { return Status::Error(1, "Wait for prefix to be known"); } if (part_i == part_count_) { if (unknown_size_flag_) { part_count_++; if (part_count_ > MAX_PART_COUNT) { return Status::Error("Too big file with unknown size"); } part_status_.push_back(PartStatus::Empty); } else { if (first_empty_part_ < part_count_) { part_i = first_empty_part_; } else { return get_empty_part(); } } } if (!is_part_in_streaming_limit(part_i)) { return get_empty_part(); } CHECK(part_status_[part_i] == PartStatus::Empty); on_part_start(part_i); return get_part(part_i); } Status PartsManager::set_known_prefix(size_t size, bool is_ready) { if (!known_prefix_flag_ || size < static_cast(known_prefix_size_)) { return Status::Error("FILE_UPLOAD_RESTART"); } known_prefix_size_ = narrow_cast(size); expected_size_ = max(known_prefix_size_, expected_size_); CHECK(static_cast(part_count_) == part_status_.size()); if (is_ready) { part_count_ = static_cast(calc_part_count(size, part_size_)); size_ = narrow_cast(size); unknown_size_flag_ = false; known_prefix_flag_ = false; } else { part_count_ = static_cast(size / part_size_); } LOG_CHECK(static_cast(part_count_) >= part_status_.size()) << size << " " << is_ready << " " << part_count_ << " " << part_size_ << " " << part_status_.size(); part_status_.resize(part_count_); if (use_part_count_limit_ && calc_part_count(expected_size_, part_size_) > MAX_PART_COUNT) { return Status::Error("FILE_UPLOAD_RESTART"); } return Status::OK(); } Status PartsManager::on_part_ok(int32 id, size_t part_size, size_t actual_size) { CHECK(part_status_[id] == PartStatus::Pending); pending_count_--; part_status_[id] = PartStatus::Ready; if (actual_size != 0) { bitmask_.set(id); } ready_size_ += narrow_cast(actual_size); if (streaming_limit_ > 0 && is_part_in_streaming_limit(id)) { streaming_ready_size_ += narrow_cast(actual_size); } VLOG(files) << "Transferred part " << id << " of size " << part_size << ", total ready size = " << ready_size_; int64 offset = narrow_cast(part_size_) * id; int64 end_offset = offset + narrow_cast(actual_size); if (unknown_size_flag_) { CHECK(part_size == part_size_); if (actual_size < part_size_) { max_size_ = min(max_size_, end_offset); } if (actual_size) { min_size_ = max(min_size_, end_offset); } if (min_size_ > max_size_) { auto status = Status::Error(PSLICE() << "Failed to transfer file: " << tag("min_size", min_size_) << tag("max_size", max_size_)); LOG(ERROR) << status; return status; } else if (min_size_ == max_size_) { unknown_size_flag_ = false; size_ = min_size_; } } else { if ((actual_size < part_size && offset < size_) || (offset >= size_ && actual_size > 0)) { auto status = Status::Error(PSLICE() << "Failed to transfer file: " << tag("size", size_) << tag("offset", offset) << tag("transferred size", actual_size) << tag("part size", part_size)); LOG(ERROR) << status; return status; } } return Status::OK(); } void PartsManager::on_part_failed(int32 id) { CHECK(part_status_[id] == PartStatus::Pending); pending_count_--; part_status_[id] = PartStatus::Empty; if (id < first_empty_part_) { first_empty_part_ = id; } if (streaming_offset_ == 0) { first_streaming_empty_part_ = id; return; } auto part_i = narrow_cast(streaming_offset_ / part_size_); if (id >= part_i && id < first_streaming_empty_part_) { first_streaming_empty_part_ = id; } } int64 PartsManager::get_size() const { CHECK(!unknown_size_flag_); return size_; } int64 PartsManager::get_size_or_zero() const { return size_; } int64 PartsManager::get_estimated_extra() const { auto total_estimated_extra = get_expected_size() - get_ready_size(); if (streaming_limit_ != 0) { int64 expected_size = get_expected_size(); int64 streaming_begin = streaming_offset_ / get_part_size() * get_part_size(); int64 streaming_end = (streaming_offset_ + streaming_limit_ + get_part_size() - 1) / get_part_size() * get_part_size(); int64 streaming_size = streaming_end - streaming_begin; if (unknown_size_flag_) { if (streaming_begin < expected_size) { streaming_size = min(expected_size - streaming_begin, streaming_size); } else { streaming_size = 0; } } else { if (streaming_end > expected_size) { int64 total = streaming_limit_; int64 suffix = 0; if (streaming_offset_ < expected_size_) { suffix = expected_size_ - streaming_begin; total -= expected_size_ - streaming_offset_; } int64 prefix = (total + get_part_size() - 1) / get_part_size() * get_part_size(); streaming_size = min(expected_size, prefix + suffix); } } int64 res = streaming_size; //TODO: delete this block if CHECK won't fail int64 sub = 0; for (int part_i = 0; part_i < part_count_; part_i++) { if (is_part_in_streaming_limit(part_i) && part_status_[part_i] == PartStatus::Ready) { sub += get_part(part_i).size; } } CHECK(sub == streaming_ready_size_); res -= streaming_ready_size_; CHECK(res >= 0); return res; } return total_estimated_extra; } int64 PartsManager::get_ready_size() const { return ready_size_; } int64 PartsManager::get_expected_size() const { if (unknown_size_flag_) { return max(static_cast(512 * (1 << 10)), get_ready_size() * 2); } return get_size(); } size_t PartsManager::get_part_size() const { return part_size_; } int32 PartsManager::get_part_count() const { return part_count_; } void PartsManager::init_common(const std::vector &ready_parts) { ready_size_ = 0; streaming_ready_size_ = 0; pending_count_ = 0; first_empty_part_ = 0; first_not_ready_part_ = 0; part_status_ = vector(part_count_); for (auto i : ready_parts) { LOG_CHECK(0 <= i && i < part_count_) << tag("i", i) << tag("part_count", part_count_); part_status_[i] = PartStatus::Ready; bitmask_.set(i); auto part = get_part(i); ready_size_ += narrow_cast(part.size); } checked_prefix_size_ = get_ready_prefix_count() * narrow_cast(part_size_); } void PartsManager::set_need_check() { need_check_ = true; set_streaming_offset(0); } void PartsManager::set_checked_prefix_size(int64 size) { checked_prefix_size_ = size; } int64 PartsManager::get_checked_prefix_size() const { return checked_prefix_size_; } int64 PartsManager::get_unchecked_ready_prefix_size() { update_first_not_ready_part(); auto count = first_not_ready_part_; if (count == 0) { return 0; } auto part = get_part(count - 1); int64 res = part.offset; if (!unknown_size_flag_) { res += narrow_cast(part.size); res = min(res, get_size()); } return res; } Part PartsManager::get_part(int id) const { int64 offset = narrow_cast(part_size_) * id; int64 size = narrow_cast(part_size_); auto total_size = unknown_size_flag_ ? max_size_ : get_size(); if (total_size < offset) { size = 0; } else { size = min(size, total_size - offset); } return Part{id, offset, static_cast(size)}; } Part PartsManager::get_empty_part() { return Part{-1, 0, 0}; } void PartsManager::on_part_start(int32 id) { CHECK(part_status_[id] == PartStatus::Empty); part_status_[id] = PartStatus::Pending; pending_count_++; } } // namespace td