ClickHouse/utils/compressor/decompress_perf.cpp

#include <lz4.h>
#include <string.h>
#include <optional>
#include <common/types.h>

#include <IO/ReadBuffer.h>
#include <IO/ReadBufferFromFileDescriptor.h>
#include <IO/WriteBufferFromFileDescriptor.h>
#include <IO/MMapReadBufferFromFileDescriptor.h>
#include <IO/HashingWriteBuffer.h>
#include <IO/BufferWithOwnMemory.h>
#include <Compression/CompressionInfo.h>
#include <IO/WriteHelpers.h>
#include <Compression/LZ4_decompress_faster.h>
#include <IO/copyData.h>
#include <Common/PODArray.h>
#include <Common/Stopwatch.h>
#include <Common/formatReadable.h>
#include <Common/memcpySmall.h>
#include <common/unaligned.h>


/** for i in *.bin; do ./decompress_perf < $i > /dev/null; done
  */

namespace DB
{

namespace ErrorCodes
{
    extern const int UNKNOWN_COMPRESSION_METHOD;
    extern const int TOO_LARGE_SIZE_COMPRESSED;
    extern const int CANNOT_DECOMPRESS;
}

class FasterCompressedReadBufferBase
{
protected:
    ReadBuffer * compressed_in;

    /// If 'compressed_in' buffer has whole compressed block - then use it. Otherwise copy parts of data to 'own_compressed_buffer'.
    PODArray<char> own_compressed_buffer;
    /// Points to memory, holding compressed block.
    char * compressed_buffer = nullptr;

    ssize_t variant;

    /// Variant for reference implementation of LZ4.
    static constexpr ssize_t LZ4_REFERENCE = -3;

    LZ4::StreamStatistics stream_stat;
    LZ4::PerformanceStatistics perf_stat;

    size_t readCompressedData(size_t & size_decompressed, size_t & size_compressed_without_checksum)
    {
        if (compressed_in->eof())
            return 0;

        CityHash_v1_0_2::uint128 checksum;
        compressed_in->readStrict(reinterpret_cast<char *>(&checksum), sizeof(checksum));

        own_compressed_buffer.resize(COMPRESSED_BLOCK_HEADER_SIZE);
        compressed_in->readStrict(&own_compressed_buffer[0], COMPRESSED_BLOCK_HEADER_SIZE);

        UInt8 method = own_compressed_buffer[0];    /// See CompressedWriteBuffer.h

        size_t & size_compressed = size_compressed_without_checksum;

        if (method == static_cast<UInt8>(CompressionMethodByte::LZ4) ||
            method == static_cast<UInt8>(CompressionMethodByte::ZSTD) ||
            method == static_cast<UInt8>(CompressionMethodByte::NONE))
        {
            size_compressed = unalignedLoad<UInt32>(&own_compressed_buffer[1]);
            size_decompressed = unalignedLoad<UInt32>(&own_compressed_buffer[5]);
        }
        else
            throw Exception("Unknown compression method: " + toString(method), ErrorCodes::UNKNOWN_COMPRESSION_METHOD);

        if (size_compressed > DBMS_MAX_COMPRESSED_SIZE)
            throw Exception("Too large size_compressed. Most likely corrupted data.", ErrorCodes::TOO_LARGE_SIZE_COMPRESSED);

        /// Is whole compressed block located in 'compressed_in' buffer?
        if (compressed_in->offset() >= COMPRESSED_BLOCK_HEADER_SIZE &&
            compressed_in->position() + size_compressed - COMPRESSED_BLOCK_HEADER_SIZE <= compressed_in->buffer().end())
        {
            compressed_in->position() -= COMPRESSED_BLOCK_HEADER_SIZE;
            compressed_buffer = compressed_in->position();
            compressed_in->position() += size_compressed;
        }
        else
        {
            own_compressed_buffer.resize(size_compressed + (variant == LZ4_REFERENCE ? 0 : LZ4::ADDITIONAL_BYTES_AT_END_OF_BUFFER));
            compressed_buffer = &own_compressed_buffer[0];
            compressed_in->readStrict(compressed_buffer + COMPRESSED_BLOCK_HEADER_SIZE, size_compressed - COMPRESSED_BLOCK_HEADER_SIZE);
        }

        return size_compressed + sizeof(checksum);
    }

    void decompress(char * to, size_t size_decompressed, size_t size_compressed_without_checksum)
    {
        UInt8 method = compressed_buffer[0];    /// See CompressedWriteBuffer.h

        if (method == static_cast<UInt8>(CompressionMethodByte::LZ4))
        {
            //LZ4::statistics(compressed_buffer + COMPRESSED_BLOCK_HEADER_SIZE, to, size_decompressed, stat);

            if (variant == LZ4_REFERENCE)
            {
                if (LZ4_decompress_fast(compressed_buffer + COMPRESSED_BLOCK_HEADER_SIZE, to, size_decompressed) < 0)
                    throw Exception("Cannot LZ4_decompress_fast", ErrorCodes::CANNOT_DECOMPRESS);
            }
            else
                LZ4::decompress(compressed_buffer + COMPRESSED_BLOCK_HEADER_SIZE, to, size_compressed_without_checksum, size_decompressed, perf_stat);
        }
        else
            throw Exception("Unknown compression method: " + toString(method), ErrorCodes::UNKNOWN_COMPRESSION_METHOD);
    }

public:
    /// 'compressed_in' could be initialized lazily, but before first call of 'readCompressedData'.
    FasterCompressedReadBufferBase(ReadBuffer * in, ssize_t variant)
        : compressed_in(in), own_compressed_buffer(COMPRESSED_BLOCK_HEADER_SIZE), variant(variant), perf_stat(variant)
    {
    }

    LZ4::StreamStatistics getStreamStatistics() const { return stream_stat; }
    LZ4::PerformanceStatistics getPerformanceStatistics() const { return perf_stat; }
};


class FasterCompressedReadBuffer : public FasterCompressedReadBufferBase, public BufferWithOwnMemory<ReadBuffer>
{
private:
    size_t size_compressed = 0;

    bool nextImpl() override
    {
        size_t size_decompressed;
        size_t size_compressed_without_checksum;
        size_compressed = readCompressedData(size_decompressed, size_compressed_without_checksum);
        if (!size_compressed)
            return false;

        memory.resize(size_decompressed + LZ4::ADDITIONAL_BYTES_AT_END_OF_BUFFER);
        working_buffer = Buffer(&memory[0], &memory[size_decompressed]);

        decompress(working_buffer.begin(), size_decompressed, size_compressed_without_checksum);

        return true;
    }

public:
    FasterCompressedReadBuffer(ReadBuffer & in_, ssize_t method)
        : FasterCompressedReadBufferBase(&in_, method), BufferWithOwnMemory<ReadBuffer>(0)
    {
    }
};

}


int main(int argc, char ** argv)
try
{
    using namespace DB;

    /** -3 - use reference implementation of LZ4
      * -2 - run all algorithms in round robin fashion
      * -1 - automatically detect best algorithm based on statistics
      * 0..3 - run specified algorithm
      */
    ssize_t variant = argc < 2 ? -1 : parse<ssize_t>(argv[1]);

    MMapReadBufferFromFileDescriptor in(STDIN_FILENO, 0);
//    ReadBufferFromFileDescriptor in(STDIN_FILENO);
    FasterCompressedReadBuffer decompressing_in(in, variant);
//    WriteBufferFromFileDescriptor out(STDOUT_FILENO);
//    HashingWriteBuffer hashing_out(out);

    Stopwatch watch;
//    copyData(decompressing_in, /*hashing_*/out);
    while (!decompressing_in.eof())
    {
        decompressing_in.position() = decompressing_in.buffer().end();
        decompressing_in.next();
    }
    watch.stop();

    std::cout << std::fixed << std::setprecision(3)
        << watch.elapsed() * 1000 / decompressing_in.count()
        << '\n';

/*
//    auto hash = hashing_out.getHash();

    double seconds = watch.elapsedSeconds();
    std::cerr << std::fixed << std::setprecision(3)
        << "Elapsed: " << seconds
        << ", " << formatReadableSizeWithBinarySuffix(in.count()) << " compressed"
        << ", " << formatReadableSizeWithBinarySuffix(decompressing_in.count()) << " decompressed"
        << ", ratio: " << static_cast<double>(decompressing_in.count()) / in.count()
        << ", " << formatReadableSizeWithBinarySuffix(in.count() / seconds) << "/sec. compressed"
        << ", " << formatReadableSizeWithBinarySuffix(decompressing_in.count() / seconds) << "/sec. decompressed"
//        << ", checksum: " << hash.first << "_" << hash.second
        << "\n";

//    decompressing_in.getStatistics().print();

    LZ4::PerformanceStatistics perf_stat = decompressing_in.getPerformanceStatistics();

    std::optional<size_t> best_variant;
    double best_variant_mean = 0;

    for (size_t i = 0; i < LZ4::PerformanceStatistics::NUM_ELEMENTS; ++i)
    {
        const LZ4::PerformanceStatistics::Element & elem = perf_stat.data[i];

        if (elem.count)
        {
            double mean = elem.mean();

            std::cerr << "Variant " << i << ": "
                << "count: " << elem.count
                << ", mean ns/b: " << 1000000000.0 * mean << " (" << formatReadableSizeWithBinarySuffix(1 / mean) << "/sec.)"
                << ", sigma ns/b: " << 1000000000.0 * elem.sigma()
                << "\n";

            if (!best_variant || mean < best_variant_mean)
            {
                best_variant_mean = mean;
                best_variant = i;
            }
        }
    }

    if (best_variant)
        std::cerr << "Best variant: " << *best_variant << "\n";
*/

    return 0;
}
catch (...)
{
    std::cerr << DB::getCurrentExceptionMessage(true);
    return DB::getCurrentExceptionCode();
}