Status FTDCFileWriter::writeArchiveFileBuffer(ConstDataRange buf) { _archiveStream.write(buf.data(), buf.length()); if (_archiveStream.fail()) { return { ErrorCodes::FileStreamFailed, str::stream() << "Failed to write to archive file buffer for full-time diagnostic data capture: " << _archiveFile.generic_string()}; } // Flush the stream explictly, this is preferred over "pubsetbuf(0,0)" which has implementation // defined behavior of "before any I/O has occurred". _archiveStream.flush(); if (_archiveStream.fail()) { return { ErrorCodes::FileStreamFailed, str::stream() << "Failed to flush to archive file buffer for full-time diagnostic data capture: " << _archiveFile.generic_string()}; } _size += buf.length(); return Status::OK(); }
StatusWith<std::size_t> SnappyMessageCompressor::compressData(ConstDataRange input, DataRange output) { size_t outLength = output.length(); if (output.length() < getMaxCompressedSize(input.length())) { return {ErrorCodes::BadValue, "Output too small for max size of compressed input"}; } snappy::RawCompress(input.data(), input.length(), const_cast<char*>(output.data()), &outLength); counterHitCompress(input.length(), outLength); return {outLength}; }
StatusWith<std::size_t> SnappyMessageCompressor::decompressData(ConstDataRange input, DataRange output) { size_t expectedLength = 0; if (!snappy::GetUncompressedLength(input.data(), input.length(), &expectedLength) || expectedLength != output.length()) { return {ErrorCodes::BadValue, "Compressed message was invalid or corrupted"}; } if (!snappy::RawUncompress(input.data(), input.length(), const_cast<char*>(output.data()))) { return Status{ErrorCodes::BadValue, "Compressed message was invalid or corrupted"}; } counterHitDecompress(input.length(), output.length()); return output.length(); }
Status FTDCFileWriter::writeArchiveFileBuffer(ConstDataRange buf) { _archiveStream.write(buf.data(), buf.length()); if (_archiveStream.fail()) { return { ErrorCodes::FileStreamFailed, str::stream() << "Failed to write to archive file buffer for full-time diagnostic data capture: " << _archiveFile.generic_string()}; } _size += buf.length(); return Status::OK(); }
void BinDataInfo::Functions::UUID::call(JSContext* cx, JS::CallArgs args) { boost::optional<mongo::UUID> uuid; if (args.length() == 0) { uuid = mongo::UUID::gen(); } else { uassert(ErrorCodes::BadValue, "UUID needs 0 or 1 arguments", args.length() == 1); auto arg = args.get(0); std::string str = ValueWriter(cx, arg).toString(); // For backward compatibility quietly accept and convert 32-character hex strings to // BinData(3, ...) as used for the deprecated UUID v3 BSON type. if (str.length() == 32) { hexToBinData(cx, bdtUUID, arg, args.rval()); return; } uuid = uassertStatusOK(mongo::UUID::parse(str)); }; ConstDataRange cdr = uuid->toCDR(); std::string encoded = mongo::base64::encode(cdr.data(), cdr.length()); JS::AutoValueArray<2> newArgs(cx); newArgs[0].setInt32(newUUID); ValueReader(cx, newArgs[1]).fromStringData(encoded); getScope(cx)->getProto<BinDataInfo>().newInstance(newArgs, args.rval()); }
BSONObj createBSONMetricChunkDocument(ConstDataRange buf, Date_t date) { BSONObjBuilder builder; builder.appendDate(kFTDCIdField, date); builder.appendNumber(kFTDCTypeField, static_cast<int>(FTDCType::kMetricChunk)); builder.appendBinData(kFTDCDataField, buf.length(), BinDataType::BinDataGeneral, buf.data()); return builder.obj(); }
StatusWith<ConstDataRange> BlockCompressor::compress(ConstDataRange source) { z_stream stream; int level = Z_DEFAULT_COMPRESSION; stream.next_in = reinterpret_cast<unsigned char*>(const_cast<char*>(source.data())); stream.avail_in = source.length(); // In compress.c in the zlib source, they recommend that the compression buffer be // at least 0.1% larger + 12 bytes then the source length. // We make the buffer 1% larger then the source length buffer to be on the safe side. If we are // too small, deflate returns an error. _buffer.resize(source.length() * 1.01 + 12); stream.next_out = _buffer.data(); stream.avail_out = _buffer.size(); stream.zalloc = nullptr; stream.zfree = nullptr; stream.opaque = nullptr; int err = deflateInit(&stream, level); if (err != Z_OK) { return {ErrorCodes::ZLibError, str::stream() << "deflateInit failed with " << err}; } err = deflate(&stream, Z_FINISH); if (err != Z_STREAM_END) { (void)deflateEnd(&stream); if (err != Z_OK) { return {ErrorCodes::ZLibError, str::stream() << "deflate failed with " << err}; } } err = deflateEnd(&stream); if (err != Z_OK) { return {ErrorCodes::ZLibError, str::stream() << "deflateEnd failed with " << err}; } return ConstDataRange(reinterpret_cast<char*>(_buffer.data()), stream.total_out); }
Status FTDCFileWriter::writeInterimFileBuffer(ConstDataRange buf) { // Fixed size interim stream std::ofstream interimStream; // Disable file buffering interimStream.rdbuf()->pubsetbuf(0, 0); // Open up a temporary interim file interimStream.open(_interimTempFile.c_str(), std::ios_base::out | std::ios_base::binary | std::ios_base::trunc); if (!interimStream.is_open()) { return Status(ErrorCodes::FileNotOpen, "Failed to open interim file " + _interimTempFile.generic_string()); } interimStream.write(buf.data(), buf.length()); if (interimStream.fail()) { return { ErrorCodes::FileStreamFailed, str::stream() << "Failed to write to interim file buffer for full-time diagnostic data capture: " << _interimTempFile.generic_string()}; } interimStream.close(); // Now that the temp interim file is closed, rename the temp interim file to the real one. boost::system::error_code ec; boost::filesystem::rename(_interimTempFile, _interimFile, ec); if (ec) { return Status(ErrorCodes::FileRenameFailed, ec.message()); } _sizeInterim = buf.length(); return Status::OK(); }
StatusWith<ConstDataRange> BlockCompressor::uncompress(ConstDataRange source, size_t uncompressedLength) { z_stream stream; stream.next_in = reinterpret_cast<unsigned char*>(const_cast<char*>(source.data())); stream.avail_in = source.length(); _buffer.resize(uncompressedLength); stream.next_out = _buffer.data(); stream.avail_out = _buffer.size(); stream.zalloc = nullptr; stream.zfree = nullptr; stream.opaque = nullptr; int err = inflateInit(&stream); if (err != Z_OK) { return {ErrorCodes::ZLibError, str::stream() << "inflateInit failed with " << err}; } err = inflate(&stream, Z_FINISH); if (err != Z_STREAM_END) { (void)inflateEnd(&stream); if (err != Z_OK) { return {ErrorCodes::ZLibError, str::stream() << "inflate failed with " << err}; } } err = inflateEnd(&stream); if (err != Z_OK) { return {ErrorCodes::ZLibError, str::stream() << "inflateEnd failed with " << err}; } return ConstDataRange(reinterpret_cast<char*>(_buffer.data()), stream.total_out); }
StatusWith<std::tuple<ConstDataRange, Date_t>> FTDCCompressor::getCompressedSamples() { _uncompressedChunkBuffer.setlen(0); // Append reference document - BSON Object _uncompressedChunkBuffer.appendBuf(_referenceDoc.objdata(), _referenceDoc.objsize()); // Append count of metrics - uint32 little endian _uncompressedChunkBuffer.appendNum(static_cast<std::uint32_t>(_metricsCount)); // Append count of samples - uint32 little endian _uncompressedChunkBuffer.appendNum(static_cast<std::uint32_t>(_deltaCount)); if (_metricsCount != 0 && _deltaCount != 0) { // On average, we do not need all 10 bytes for every sample, worst case, we grow the buffer DataBuilder db(_metricsCount * _deltaCount * FTDCVarInt::kMaxSizeBytes64 / 2); std::uint32_t zeroesCount = 0; // For each set of samples for a particular metric, // we think of it is simple array of 64-bit integers we try to compress into a byte array. // This is done in three steps for each metric // 1. Delta Compression // - i.e., we store the difference between pairs of samples, not their absolute values // - this is done in addSamples // 2. Run Length Encoding of zeros // - We find consecutive sets of zeros and represent them as a tuple of (0, count - 1). // - Each memeber is stored as VarInt packed integer // 3. Finally, for non-zero members, we store these as VarInt packed // // These byte arrays are added to a buffer which is then concatenated with other chunks and // compressed with ZLIB. for (std::uint32_t i = 0; i < _metricsCount; i++) { for (std::uint32_t j = 0; j < _deltaCount; j++) { std::uint64_t delta = _deltas[getArrayOffset(_maxDeltas, j, i)]; if (delta == 0) { ++zeroesCount; continue; } // If we have a non-zero sample, then write out all the accumulated zero samples. if (zeroesCount > 0) { auto s1 = db.writeAndAdvance(FTDCVarInt(0)); if (!s1.isOK()) { return s1; } auto s2 = db.writeAndAdvance(FTDCVarInt(zeroesCount - 1)); if (!s2.isOK()) { return s2; } zeroesCount = 0; } auto s3 = db.writeAndAdvance(FTDCVarInt(delta)); if (!s3.isOK()) { return s3; } } // If we are on the last metric, and the previous loop ended in a zero, write out the // RLE // pair of zero information. if ((i == (_metricsCount - 1)) && zeroesCount) { auto s1 = db.writeAndAdvance(FTDCVarInt(0)); if (!s1.isOK()) { return s1; } auto s2 = db.writeAndAdvance(FTDCVarInt(zeroesCount - 1)); if (!s2.isOK()) { return s2; } } } // Append the entire compacted metric chunk into the uncompressed buffer ConstDataRange cdr = db.getCursor(); _uncompressedChunkBuffer.appendBuf(cdr.data(), cdr.length()); } auto swDest = _compressor.compress( ConstDataRange(_uncompressedChunkBuffer.buf(), _uncompressedChunkBuffer.len())); // The only way for compression to fail is if the buffer size calculations are wrong if (!swDest.isOK()) { return swDest.getStatus(); } _compressedChunkBuffer.setlen(0); _compressedChunkBuffer.appendNum(static_cast<std::uint32_t>(_uncompressedChunkBuffer.len())); _compressedChunkBuffer.appendBuf(swDest.getValue().data(), swDest.getValue().length()); return std::tuple<ConstDataRange, Date_t>( ConstDataRange(_compressedChunkBuffer.buf(), static_cast<size_t>(_compressedChunkBuffer.len())), _referenceDocDate); }