// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). #include "trace_replay/trace_replay.h" #include #include #include #include "db/db_impl/db_impl.h" #include "rocksdb/env.h" #include "rocksdb/iterator.h" #include "rocksdb/options.h" #include "rocksdb/slice.h" #include "rocksdb/system_clock.h" #include "rocksdb/trace_reader_writer.h" #include "rocksdb/write_batch.h" #include "util/coding.h" #include "util/string_util.h" namespace ROCKSDB_NAMESPACE { const std::string kTraceMagic = "feedcafedeadbeef"; namespace { void DecodeCFAndKey(std::string& buffer, uint32_t* cf_id, Slice* key) { Slice buf(buffer); GetFixed32(&buf, cf_id); GetLengthPrefixedSlice(&buf, key); } } // namespace Status TracerHelper::ParseVersionStr(std::string& v_string, int* v_num) { if (v_string.find_first_of('.') == std::string::npos || v_string.find_first_of('.') != v_string.find_last_of('.')) { return Status::Corruption( "Corrupted trace file. Incorrect version format."); } int tmp_num = 0; for (int i = 0; i < static_cast(v_string.size()); i++) { if (v_string[i] == '.') { continue; } else if (isdigit(v_string[i])) { tmp_num = tmp_num * 10 + (v_string[i] - '0'); } else { return Status::Corruption( "Corrupted trace file. Incorrect version format"); } } *v_num = tmp_num; return Status::OK(); } Status TracerHelper::ParseTraceHeader(const Trace& header, int* trace_version, int* db_version) { std::vector s_vec; int begin = 0, end; for (int i = 0; i < 3; i++) { assert(header.payload.find("\t", begin) != std::string::npos); end = static_cast(header.payload.find("\t", begin)); s_vec.push_back(header.payload.substr(begin, end - begin)); begin = end + 1; } std::string t_v_str, db_v_str; assert(s_vec.size() == 3); assert(s_vec[1].find("Trace Version: ") != std::string::npos); t_v_str = s_vec[1].substr(15); assert(s_vec[2].find("RocksDB Version: ") != std::string::npos); db_v_str = s_vec[2].substr(17); Status s; s = ParseVersionStr(t_v_str, trace_version); if (s != Status::OK()) { return s; } s = ParseVersionStr(db_v_str, db_version); return s; } void TracerHelper::EncodeTrace(const Trace& trace, std::string* encoded_trace) { assert(encoded_trace); PutFixed64(encoded_trace, trace.ts); encoded_trace->push_back(trace.type); PutFixed32(encoded_trace, static_cast(trace.payload.size())); encoded_trace->append(trace.payload); } Status TracerHelper::DecodeTrace(const std::string& encoded_trace, Trace* trace) { assert(trace != nullptr); Slice enc_slice = Slice(encoded_trace); if (!GetFixed64(&enc_slice, &trace->ts)) { return Status::Incomplete("Decode trace string failed"); } if (enc_slice.size() < kTraceTypeSize + kTracePayloadLengthSize) { return Status::Incomplete("Decode trace string failed"); } trace->type = static_cast(enc_slice[0]); enc_slice.remove_prefix(kTraceTypeSize + kTracePayloadLengthSize); trace->payload = enc_slice.ToString(); return Status::OK(); } Status TracerHelper::DecodeHeader(const std::string& encoded_trace, Trace* header) { Status s = TracerHelper::DecodeTrace(encoded_trace, header); if (header->type != kTraceBegin) { return Status::Corruption("Corrupted trace file. Incorrect header."); } if (header->payload.substr(0, kTraceMagic.length()) != kTraceMagic) { return Status::Corruption("Corrupted trace file. Incorrect magic."); } return s; } bool TracerHelper::SetPayloadMap(uint64_t& payload_map, const TracePayloadType payload_type) { uint64_t old_state = payload_map; uint64_t tmp = 1; payload_map |= (tmp << payload_type); return old_state != payload_map; } Status TracerHelper::DecodeWriteRecord(Trace* trace, int trace_file_version, std::unique_ptr* record) { assert(trace != nullptr); assert(trace->type == kTraceWrite); PinnableSlice rep; if (trace_file_version < 2) { rep.PinSelf(trace->payload); } else { Slice buf(trace->payload); GetFixed64(&buf, &trace->payload_map); int64_t payload_map = static_cast(trace->payload_map); Slice write_batch_data; while (payload_map) { // Find the rightmost set bit. uint32_t set_pos = static_cast(log2(payload_map & -payload_map)); switch (set_pos) { case TracePayloadType::kWriteBatchData: GetLengthPrefixedSlice(&buf, &write_batch_data); break; default: assert(false); } // unset the rightmost bit. payload_map &= (payload_map - 1); } rep.PinSelf(write_batch_data); } if (record != nullptr) { record->reset(new WriteQueryTraceRecord(std::move(rep), trace->ts)); } return Status::OK(); } Status TracerHelper::DecodeGetRecord(Trace* trace, int trace_file_version, std::unique_ptr* record) { assert(trace != nullptr); assert(trace->type == kTraceGet); uint32_t cf_id = 0; Slice get_key; if (trace_file_version < 2) { DecodeCFAndKey(trace->payload, &cf_id, &get_key); } else { Slice buf(trace->payload); GetFixed64(&buf, &trace->payload_map); int64_t payload_map = static_cast(trace->payload_map); while (payload_map) { // Find the rightmost set bit. uint32_t set_pos = static_cast(log2(payload_map & -payload_map)); switch (set_pos) { case TracePayloadType::kGetCFID: GetFixed32(&buf, &cf_id); break; case TracePayloadType::kGetKey: GetLengthPrefixedSlice(&buf, &get_key); break; default: assert(false); } // unset the rightmost bit. payload_map &= (payload_map - 1); } } if (record != nullptr) { PinnableSlice ps; ps.PinSelf(get_key); record->reset(new GetQueryTraceRecord(cf_id, std::move(ps), trace->ts)); } return Status::OK(); } Status TracerHelper::DecodeIterRecord(Trace* trace, int trace_file_version, std::unique_ptr* record) { assert(trace != nullptr); assert(trace->type == kTraceIteratorSeek || trace->type == kTraceIteratorSeekForPrev); uint32_t cf_id = 0; Slice iter_key; if (trace_file_version < 2) { DecodeCFAndKey(trace->payload, &cf_id, &iter_key); } else { // Are these two used anywhere? Slice lower_bound; Slice upper_bound; Slice buf(trace->payload); GetFixed64(&buf, &trace->payload_map); int64_t payload_map = static_cast(trace->payload_map); while (payload_map) { // Find the rightmost set bit. uint32_t set_pos = static_cast(log2(payload_map & -payload_map)); switch (set_pos) { case TracePayloadType::kIterCFID: GetFixed32(&buf, &cf_id); break; case TracePayloadType::kIterKey: GetLengthPrefixedSlice(&buf, &iter_key); break; case TracePayloadType::kIterLowerBound: GetLengthPrefixedSlice(&buf, &lower_bound); break; case TracePayloadType::kIterUpperBound: GetLengthPrefixedSlice(&buf, &upper_bound); break; default: assert(false); } // unset the rightmost bit. payload_map &= (payload_map - 1); } } if (record != nullptr) { PinnableSlice ps_key; ps_key.PinSelf(iter_key); record->reset(new IteratorSeekQueryTraceRecord( static_cast(trace->type), cf_id, std::move(ps_key), trace->ts)); } return Status::OK(); } Status TracerHelper::DecodeMultiGetRecord( Trace* trace, int trace_file_version, std::unique_ptr* record) { assert(trace != nullptr); assert(trace->type == kTraceMultiGet); if (trace_file_version < 2) { return Status::Corruption("MultiGet is not supported."); } uint32_t multiget_size = 0; std::vector cf_ids; std::vector multiget_keys; Slice cfids_payload; Slice keys_payload; Slice buf(trace->payload); GetFixed64(&buf, &trace->payload_map); int64_t payload_map = static_cast(trace->payload_map); while (payload_map) { // Find the rightmost set bit. uint32_t set_pos = static_cast(log2(payload_map & -payload_map)); switch (set_pos) { case TracePayloadType::kMultiGetSize: GetFixed32(&buf, &multiget_size); break; case TracePayloadType::kMultiGetCFIDs: GetLengthPrefixedSlice(&buf, &cfids_payload); break; case TracePayloadType::kMultiGetKeys: GetLengthPrefixedSlice(&buf, &keys_payload); break; default: assert(false); } // unset the rightmost bit. payload_map &= (payload_map - 1); } if (multiget_size == 0) { return Status::InvalidArgument("Empty MultiGet cf_ids or keys."); } // Decode the cfids_payload and keys_payload cf_ids.reserve(multiget_size); multiget_keys.reserve(multiget_size); for (uint32_t i = 0; i < multiget_size; i++) { uint32_t tmp_cfid; Slice tmp_key; GetFixed32(&cfids_payload, &tmp_cfid); GetLengthPrefixedSlice(&keys_payload, &tmp_key); cf_ids.push_back(tmp_cfid); Slice s(tmp_key); PinnableSlice ps; ps.PinSelf(s); multiget_keys.push_back(std::move(ps)); } if (record != nullptr) { record->reset(new MultiGetQueryTraceRecord( std::move(cf_ids), std::move(multiget_keys), trace->ts)); } return Status::OK(); } Tracer::Tracer(SystemClock* clock, const TraceOptions& trace_options, std::unique_ptr&& trace_writer) : clock_(clock), trace_options_(trace_options), trace_writer_(std::move(trace_writer)), trace_request_count_(0) { // TODO: What if this fails? WriteHeader().PermitUncheckedError(); } Tracer::~Tracer() { trace_writer_.reset(); } Status Tracer::Write(WriteBatch* write_batch) { TraceType trace_type = kTraceWrite; if (ShouldSkipTrace(trace_type)) { return Status::OK(); } Trace trace; trace.ts = clock_->NowMicros(); trace.type = trace_type; TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kWriteBatchData); PutFixed64(&trace.payload, trace.payload_map); PutLengthPrefixedSlice(&trace.payload, Slice(write_batch->Data())); return WriteTrace(trace); } Status Tracer::Get(ColumnFamilyHandle* column_family, const Slice& key) { TraceType trace_type = kTraceGet; if (ShouldSkipTrace(trace_type)) { return Status::OK(); } Trace trace; trace.ts = clock_->NowMicros(); trace.type = trace_type; // Set the payloadmap of the struct member that will be encoded in the // payload. TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kGetCFID); TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kGetKey); // Encode the Get struct members into payload. Make sure add them in order. PutFixed64(&trace.payload, trace.payload_map); PutFixed32(&trace.payload, column_family->GetID()); PutLengthPrefixedSlice(&trace.payload, key); return WriteTrace(trace); } Status Tracer::IteratorSeek(const uint32_t& cf_id, const Slice& key, const Slice& lower_bound, const Slice upper_bound) { TraceType trace_type = kTraceIteratorSeek; if (ShouldSkipTrace(trace_type)) { return Status::OK(); } Trace trace; trace.ts = clock_->NowMicros(); trace.type = trace_type; // Set the payloadmap of the struct member that will be encoded in the // payload. TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterCFID); TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterKey); if (lower_bound.size() > 0) { TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterLowerBound); } if (upper_bound.size() > 0) { TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterUpperBound); } // Encode the Iterator struct members into payload. Make sure add them in // order. PutFixed64(&trace.payload, trace.payload_map); PutFixed32(&trace.payload, cf_id); PutLengthPrefixedSlice(&trace.payload, key); if (lower_bound.size() > 0) { PutLengthPrefixedSlice(&trace.payload, lower_bound); } if (upper_bound.size() > 0) { PutLengthPrefixedSlice(&trace.payload, upper_bound); } return WriteTrace(trace); } Status Tracer::IteratorSeekForPrev(const uint32_t& cf_id, const Slice& key, const Slice& lower_bound, const Slice upper_bound) { TraceType trace_type = kTraceIteratorSeekForPrev; if (ShouldSkipTrace(trace_type)) { return Status::OK(); } Trace trace; trace.ts = clock_->NowMicros(); trace.type = trace_type; // Set the payloadmap of the struct member that will be encoded in the // payload. TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterCFID); TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterKey); if (lower_bound.size() > 0) { TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterLowerBound); } if (upper_bound.size() > 0) { TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kIterUpperBound); } // Encode the Iterator struct members into payload. Make sure add them in // order. PutFixed64(&trace.payload, trace.payload_map); PutFixed32(&trace.payload, cf_id); PutLengthPrefixedSlice(&trace.payload, key); if (lower_bound.size() > 0) { PutLengthPrefixedSlice(&trace.payload, lower_bound); } if (upper_bound.size() > 0) { PutLengthPrefixedSlice(&trace.payload, upper_bound); } return WriteTrace(trace); } Status Tracer::MultiGet(const size_t num_keys, ColumnFamilyHandle** column_families, const Slice* keys) { if (num_keys == 0) { return Status::OK(); } std::vector v_column_families; std::vector v_keys; v_column_families.resize(num_keys); v_keys.resize(num_keys); for (size_t i = 0; i < num_keys; i++) { v_column_families[i] = column_families[i]; v_keys[i] = keys[i]; } return MultiGet(v_column_families, v_keys); } Status Tracer::MultiGet(const size_t num_keys, ColumnFamilyHandle* column_family, const Slice* keys) { if (num_keys == 0) { return Status::OK(); } std::vector column_families; std::vector v_keys; column_families.resize(num_keys); v_keys.resize(num_keys); for (size_t i = 0; i < num_keys; i++) { column_families[i] = column_family; v_keys[i] = keys[i]; } return MultiGet(column_families, v_keys); } Status Tracer::MultiGet(const std::vector& column_families, const std::vector& keys) { if (column_families.size() != keys.size()) { return Status::Corruption("the CFs size and keys size does not match!"); } TraceType trace_type = kTraceMultiGet; if (ShouldSkipTrace(trace_type)) { return Status::OK(); } uint32_t multiget_size = static_cast(keys.size()); Trace trace; trace.ts = clock_->NowMicros(); trace.type = trace_type; // Set the payloadmap of the struct member that will be encoded in the // payload. TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kMultiGetSize); TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kMultiGetCFIDs); TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kMultiGetKeys); // Encode the CFIDs inorder std::string cfids_payload; std::string keys_payload; for (uint32_t i = 0; i < multiget_size; i++) { assert(i < column_families.size()); assert(i < keys.size()); PutFixed32(&cfids_payload, column_families[i]->GetID()); PutLengthPrefixedSlice(&keys_payload, keys[i]); } // Encode the Get struct members into payload. Make sure add them in order. PutFixed64(&trace.payload, trace.payload_map); PutFixed32(&trace.payload, multiget_size); PutLengthPrefixedSlice(&trace.payload, cfids_payload); PutLengthPrefixedSlice(&trace.payload, keys_payload); return WriteTrace(trace); } bool Tracer::ShouldSkipTrace(const TraceType& trace_type) { if (IsTraceFileOverMax()) { return true; } if ((trace_options_.filter & kTraceFilterGet && trace_type == kTraceGet) || (trace_options_.filter & kTraceFilterWrite && trace_type == kTraceWrite)) { return true; } ++trace_request_count_; if (trace_request_count_ < trace_options_.sampling_frequency) { return true; } trace_request_count_ = 0; return false; } bool Tracer::IsTraceFileOverMax() { uint64_t trace_file_size = trace_writer_->GetFileSize(); return (trace_file_size > trace_options_.max_trace_file_size); } Status Tracer::WriteHeader() { std::ostringstream s; s << kTraceMagic << "\t" << "Trace Version: " << kTraceFileMajorVersion << "." << kTraceFileMinorVersion << "\t" << "RocksDB Version: " << kMajorVersion << "." << kMinorVersion << "\t" << "Format: Timestamp OpType Payload\n"; std::string header(s.str()); Trace trace; trace.ts = clock_->NowMicros(); trace.type = kTraceBegin; trace.payload = header; return WriteTrace(trace); } Status Tracer::WriteFooter() { Trace trace; trace.ts = clock_->NowMicros(); trace.type = kTraceEnd; TracerHelper::SetPayloadMap(trace.payload_map, TracePayloadType::kEmptyPayload); trace.payload = ""; return WriteTrace(trace); } Status Tracer::WriteTrace(const Trace& trace) { std::string encoded_trace; TracerHelper::EncodeTrace(trace, &encoded_trace); return trace_writer_->Write(Slice(encoded_trace)); } Status Tracer::Close() { return WriteFooter(); } } // namespace ROCKSDB_NAMESPACE