// // Copyright Aliaksei Levin (levlam@telegram.org), Arseny Smirnov (arseny30@gmail.com) 2014-2024 // // 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/utils/algorithm.h" #include "td/utils/buffer.h" #include "td/utils/ByteFlow.h" #include "td/utils/common.h" #include "td/utils/Gzip.h" #include "td/utils/GzipByteFlow.h" #include "td/utils/logging.h" #include "td/utils/port/thread_local.h" #include "td/utils/Slice.h" #include "td/utils/Status.h" #include "td/utils/tests.h" #include "td/utils/Time.h" static void encode_decode(const td::string &s) { auto r = td::gzencode(s, 2); ASSERT_TRUE(!r.empty()); ASSERT_EQ(s, td::gzdecode(r.as_slice())); } TEST(Gzip, gzencode_gzdecode) { encode_decode(td::rand_string(0, 255, 1000)); encode_decode(td::rand_string('a', 'z', 1000000)); encode_decode(td::string(1000000, 'a')); } static void test_gzencode(const td::string &s) { auto begin_time = td::Time::now(); auto r = td::gzencode(s, td::max(2, static_cast(100 / s.size()))); ASSERT_TRUE(!r.empty()); LOG(INFO) << "Encoded string of size " << s.size() << " in " << (td::Time::now() - begin_time) << " seconds with compression ratio " << static_cast(r.size()) / static_cast(s.size()); } TEST(Gzip, gzencode) { for (size_t len = 1; len <= 10000000; len *= 10) { test_gzencode(td::rand_string('a', 'a', len)); test_gzencode(td::rand_string('a', 'z', len)); test_gzencode(td::rand_string(0, 255, len)); } } TEST(Gzip, flow) { auto str = td::rand_string('a', 'z', 1000000); auto parts = td::rand_split(str); td::ChainBufferWriter input_writer; auto input = input_writer.extract_reader(); td::ByteFlowSource source(&input); td::GzipByteFlow gzip_flow(td::Gzip::Mode::Encode); gzip_flow = td::GzipByteFlow(td::Gzip::Mode::Encode); td::ByteFlowSink sink; source >> gzip_flow >> sink; ASSERT_TRUE(!sink.is_ready()); for (auto &part : parts) { input_writer.append(part); source.wakeup(); } ASSERT_TRUE(!sink.is_ready()); source.close_input(td::Status::OK()); ASSERT_TRUE(sink.is_ready()); ASSERT_TRUE(sink.status().is_ok()); auto res = sink.result()->move_as_buffer_slice().as_slice().str(); ASSERT_TRUE(!res.empty()); ASSERT_EQ(td::gzencode(str, 2).as_slice().str(), res); } TEST(Gzip, flow_error) { auto str = td::rand_string('a', 'z', 1000000); auto zip = td::gzencode(str, 0.9).as_slice().str(); ASSERT_TRUE(!zip.empty()); zip.resize(zip.size() - 1); auto parts = td::rand_split(zip); auto input_writer = td::ChainBufferWriter(); auto input = input_writer.extract_reader(); td::ByteFlowSource source(&input); td::GzipByteFlow gzip_flow(td::Gzip::Mode::Decode); td::ByteFlowSink sink; source >> gzip_flow >> sink; ASSERT_TRUE(!sink.is_ready()); for (auto &part : parts) { input_writer.append(part); source.wakeup(); } ASSERT_TRUE(!sink.is_ready()); source.close_input(td::Status::OK()); ASSERT_TRUE(sink.is_ready()); ASSERT_TRUE(!sink.status().is_ok()); } TEST(Gzip, encode_decode_flow) { auto str = td::rand_string('a', 'z', 1000000); auto parts = td::rand_split(str); td::ChainBufferWriter input_writer; auto input = input_writer.extract_reader(); td::ByteFlowSource source(&input); td::GzipByteFlow gzip_encode_flow(td::Gzip::Mode::Encode); td::GzipByteFlow gzip_decode_flow(td::Gzip::Mode::Decode); td::GzipByteFlow gzip_encode_flow2(td::Gzip::Mode::Encode); td::GzipByteFlow gzip_decode_flow2(td::Gzip::Mode::Decode); td::ByteFlowSink sink; source >> gzip_encode_flow >> gzip_decode_flow >> gzip_encode_flow2 >> gzip_decode_flow2 >> sink; ASSERT_TRUE(!sink.is_ready()); for (auto &part : parts) { input_writer.append(part); source.wakeup(); } ASSERT_TRUE(!sink.is_ready()); source.close_input(td::Status::OK()); ASSERT_TRUE(sink.is_ready()); LOG_IF(ERROR, sink.status().is_error()) << sink.status(); ASSERT_TRUE(sink.status().is_ok()); ASSERT_EQ(str, sink.result()->move_as_buffer_slice().as_slice().str()); } TEST(Gzip, encode_decode_flow_big) { td::clear_thread_locals(); auto start_mem = td::BufferAllocator::get_buffer_mem(); { auto str = td::string(200000, 'a'); td::ChainBufferWriter input_writer; auto input = input_writer.extract_reader(); td::ByteFlowSource source(&input); td::GzipByteFlow gzip_encode_flow(td::Gzip::Mode::Encode); td::GzipByteFlow gzip_decode_flow(td::Gzip::Mode::Decode); td::GzipByteFlow gzip_encode_flow2(td::Gzip::Mode::Encode); td::GzipByteFlow gzip_decode_flow2(td::Gzip::Mode::Decode); td::ByteFlowSink sink; source >> gzip_encode_flow >> gzip_decode_flow >> gzip_encode_flow2 >> gzip_decode_flow2 >> sink; ASSERT_TRUE(!sink.is_ready()); size_t n = 200; size_t left_size = n * str.size(); auto validate = [&](td::Slice chunk) { CHECK(chunk.size() <= left_size); left_size -= chunk.size(); ASSERT_TRUE(td::all_of(chunk, [](auto c) { return c == 'a'; })); }; for (size_t i = 0; i < n; i++) { input_writer.append(str); source.wakeup(); auto extra_mem = td::BufferAllocator::get_buffer_mem() - start_mem; // limit means nothing. just check that we do not use 200Mb or so CHECK(extra_mem < (10 << 20)); auto size = sink.get_output()->size(); validate(sink.get_output()->cut_head(size).move_as_buffer_slice().as_slice()); } ASSERT_TRUE(!sink.is_ready()); source.close_input(td::Status::OK()); ASSERT_TRUE(sink.is_ready()); LOG_IF(ERROR, sink.status().is_error()) << sink.status(); ASSERT_TRUE(sink.status().is_ok()); validate(sink.result()->move_as_buffer_slice().as_slice()); ASSERT_EQ(0u, left_size); } td::clear_thread_locals(); ASSERT_EQ(start_mem, td::BufferAllocator::get_buffer_mem()); } TEST(Gzip, decode_encode_flow_bomb) { td::string gzip_bomb_str; size_t N = 200; { td::ChainBufferWriter input_writer; auto input = input_writer.extract_reader(); td::GzipByteFlow gzip_flow(td::Gzip::Mode::Encode); td::ByteFlowSource source(&input); td::ByteFlowSink sink; source >> gzip_flow >> sink; td::string s(1 << 16, 'a'); for (size_t i = 0; i < N; i++) { input_writer.append(s); source.wakeup(); } source.close_input(td::Status::OK()); ASSERT_TRUE(sink.is_ready()); LOG_IF(ERROR, sink.status().is_error()) << sink.status(); ASSERT_TRUE(sink.status().is_ok()); gzip_bomb_str = sink.result()->move_as_buffer_slice().as_slice().str(); } td::clear_thread_locals(); auto start_mem = td::BufferAllocator::get_buffer_mem(); { td::ChainBufferWriter input_writer; auto input = input_writer.extract_reader(); td::ByteFlowSource source(&input); td::GzipByteFlow::Options decode_options; decode_options.write_watermark.low = 2 << 20; decode_options.write_watermark.high = 4 << 20; td::GzipByteFlow::Options encode_options; encode_options.read_watermark.low = 2 << 20; encode_options.read_watermark.high = 4 << 20; td::GzipByteFlow gzip_decode_flow(td::Gzip::Mode::Decode); gzip_decode_flow.set_options(decode_options); td::GzipByteFlow gzip_encode_flow(td::Gzip::Mode::Encode); gzip_encode_flow.set_options(encode_options); td::GzipByteFlow gzip_decode_flow2(td::Gzip::Mode::Decode); gzip_decode_flow2.set_options(decode_options); td::GzipByteFlow gzip_encode_flow2(td::Gzip::Mode::Encode); gzip_encode_flow2.set_options(encode_options); td::GzipByteFlow gzip_decode_flow3(td::Gzip::Mode::Decode); gzip_decode_flow3.set_options(decode_options); td::ByteFlowSink sink; source >> gzip_decode_flow >> gzip_encode_flow >> gzip_decode_flow2 >> gzip_encode_flow2 >> gzip_decode_flow3 >> sink; ASSERT_TRUE(!sink.is_ready()); size_t left_size = N * (1 << 16); auto validate = [&](td::Slice chunk) { CHECK(chunk.size() <= left_size); left_size -= chunk.size(); ASSERT_TRUE(td::all_of(chunk, [](auto c) { return c == 'a'; })); }; input_writer.append(gzip_bomb_str); source.close_input(td::Status::OK()); do { gzip_decode_flow3.wakeup(); gzip_decode_flow2.wakeup(); gzip_decode_flow.wakeup(); source.wakeup(); auto extra_mem = td::BufferAllocator::get_buffer_mem() - start_mem; // limit means nothing. just check that we do not use 15Mb or so CHECK(extra_mem < (5 << 20)); auto size = sink.get_output()->size(); validate(sink.get_output()->cut_head(size).move_as_buffer_slice().as_slice()); } while (!sink.is_ready()); ASSERT_EQ(0u, left_size); } td::clear_thread_locals(); ASSERT_EQ(start_mem, td::BufferAllocator::get_buffer_mem()); }