// This source code is licensed under the BSD-style license found in the // LICENSE file in the root directory of this source tree. An additional grant // of patent rights can be found in the PATENTS file in the same directory. // // Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include "db/internal_stats.h" #ifndef __STDC_FORMAT_MACROS #define __STDC_FORMAT_MACROS #endif #include #include #include #include "db/column_family.h" #include "db/db_impl.h" #include "util/string_util.h" namespace rocksdb { #ifndef ROCKSDB_LITE namespace { const double kMB = 1048576.0; const double kGB = kMB * 1024; void PrintLevelStatsHeader(char* buf, size_t len, const std::string& cf_name) { snprintf( buf, len, "\n** Compaction Stats [%s] **\n" "Level Files Size(MB) Score Read(GB) Rn(GB) Rnp1(GB) " "Write(GB) Wnew(GB) Moved(GB) W-Amp Rd(MB/s) Wr(MB/s) " "Comp(sec) Comp(cnt) Avg(sec) " "Stall(cnt) KeyIn KeyDrop\n" "--------------------------------------------------------------------" "-----------------------------------------------------------" "--------------------------------------\n", cf_name.c_str()); } void PrintLevelStats(char* buf, size_t len, const std::string& name, int num_files, int being_compacted, double total_file_size, double score, double w_amp, uint64_t stalls, const InternalStats::CompactionStats& stats) { uint64_t bytes_read = stats.bytes_read_non_output_levels + stats.bytes_read_output_level; int64_t bytes_new = stats.bytes_written - stats.bytes_read_output_level; double elapsed = (stats.micros + 1) / 1000000.0; std::string num_input_records = NumberToHumanString(stats.num_input_records); std::string num_dropped_records = NumberToHumanString(stats.num_dropped_records); snprintf(buf, len, "%4s %6d/%-3d %8.0f %5.1f " /* Level, Files, Size(MB), Score */ "%8.1f " /* Read(GB) */ "%7.1f " /* Rn(GB) */ "%8.1f " /* Rnp1(GB) */ "%9.1f " /* Write(GB) */ "%8.1f " /* Wnew(GB) */ "%9.1f " /* Moved(GB) */ "%5.1f " /* W-Amp */ "%8.1f " /* Rd(MB/s) */ "%8.1f " /* Wr(MB/s) */ "%9.0f " /* Comp(sec) */ "%9d " /* Comp(cnt) */ "%8.3f " /* Avg(sec) */ "%10" PRIu64 " " /* Stall(cnt) */ "%7s " /* KeyIn */ "%6s\n", /* KeyDrop */ name.c_str(), num_files, being_compacted, total_file_size / kMB, score, bytes_read / kGB, stats.bytes_read_non_output_levels / kGB, stats.bytes_read_output_level / kGB, stats.bytes_written / kGB, bytes_new / kGB, stats.bytes_moved / kGB, w_amp, bytes_read / kMB / elapsed, stats.bytes_written / kMB / elapsed, stats.micros / 1000000.0, stats.count, stats.count == 0 ? 0 : stats.micros / 1000000.0 / stats.count, stalls, num_input_records.c_str(), num_dropped_records.c_str()); } } static const std::string rocksdb_prefix = "rocksdb."; static const std::string num_files_at_level_prefix = "num-files-at-level"; static const std::string allstats = "stats"; static const std::string sstables = "sstables"; static const std::string cfstats = "cfstats"; static const std::string dbstats = "dbstats"; static const std::string levelstats = "levelstats"; static const std::string num_immutable_mem_table = "num-immutable-mem-table"; static const std::string num_immutable_mem_table_flushed = "num-immutable-mem-table-flushed"; static const std::string mem_table_flush_pending = "mem-table-flush-pending"; static const std::string compaction_pending = "compaction-pending"; static const std::string background_errors = "background-errors"; static const std::string cur_size_active_mem_table = "cur-size-active-mem-table"; static const std::string cur_size_unflushed_mem_tables = "cur-size-all-mem-tabless"; static const std::string cur_size_all_mem_tables = "size-all-mem-tables"; static const std::string num_entries_active_mem_table = "num-entries-active-mem-table"; static const std::string num_entries_imm_mem_tables = "num-entries-imm-mem-tables"; static const std::string num_deletes_active_mem_table = "num-deletes-active-mem-table"; static const std::string num_deletes_imm_mem_tables = "num-deletes-imm-mem-tables"; static const std::string estimate_num_keys = "estimate-num-keys"; static const std::string estimate_table_readers_mem = "estimate-table-readers-mem"; static const std::string is_file_deletions_enabled = "is-file-deletions-enabled"; static const std::string num_snapshots = "num-snapshots"; static const std::string oldest_snapshot_time = "oldest-snapshot-time"; static const std::string num_live_versions = "num-live-versions"; static const std::string estimate_live_data_size = "estimate-live-data-size"; static const std::string base_level = "base-level"; const std::string DB::Properties::kNumFilesAtLevelPrefix = rocksdb_prefix + num_files_at_level_prefix; const std::string DB::Properties::kStats = rocksdb_prefix + allstats; const std::string DB::Properties::kSSTables = rocksdb_prefix + sstables; const std::string DB::Properties::kCFStats = rocksdb_prefix + cfstats; const std::string DB::Properties::kDBStats = rocksdb_prefix + dbstats; const std::string DB::Properties::kNumImmutableMemTable = rocksdb_prefix + num_immutable_mem_table; const std::string DB::Properties::kMemTableFlushPending = rocksdb_prefix + mem_table_flush_pending; const std::string DB::Properties::kCompactionPending = rocksdb_prefix + compaction_pending; const std::string DB::Properties::kBackgroundErrors = rocksdb_prefix + background_errors; const std::string DB::Properties::kCurSizeActiveMemTable = rocksdb_prefix + cur_size_active_mem_table; const std::string DB::Properties::kCurSizeAllMemTables = rocksdb_prefix + cur_size_unflushed_mem_tables; const std::string DB::Properties::kSizeAllMemTables = rocksdb_prefix + cur_size_all_mem_tables; const std::string DB::Properties::kNumEntriesActiveMemTable = rocksdb_prefix + num_entries_active_mem_table; const std::string DB::Properties::kNumEntriesImmMemTables = rocksdb_prefix + num_entries_imm_mem_tables; const std::string DB::Properties::kNumDeletesActiveMemTable = rocksdb_prefix + num_deletes_active_mem_table; const std::string DB::Properties::kNumDeletesImmMemTables = rocksdb_prefix + num_deletes_imm_mem_tables; const std::string DB::Properties::kEstimateNumKeys = rocksdb_prefix + estimate_num_keys; const std::string DB::Properties::kEstimateTableReadersMem = rocksdb_prefix + estimate_table_readers_mem; const std::string DB::Properties::kIsFileDeletionsEnabled = rocksdb_prefix + is_file_deletions_enabled; const std::string DB::Properties::kNumSnapshots = rocksdb_prefix + num_snapshots; const std::string DB::Properties::kOldestSnapshotTime = rocksdb_prefix + oldest_snapshot_time; const std::string DB::Properties::kNumLiveVersions = rocksdb_prefix + num_live_versions; const std::string DB::Properties::kEstimateLiveDataSize = rocksdb_prefix + estimate_live_data_size; DBPropertyType GetPropertyType(const Slice& property, bool* is_int_property, bool* need_out_of_mutex) { assert(is_int_property != nullptr); assert(need_out_of_mutex != nullptr); Slice in = property; Slice prefix(rocksdb_prefix); *need_out_of_mutex = false; *is_int_property = false; if (!in.starts_with(prefix)) { return kUnknown; } in.remove_prefix(prefix.size()); if (in.starts_with(num_files_at_level_prefix)) { return kNumFilesAtLevel; } else if (in == levelstats) { return kLevelStats; } else if (in == allstats) { return kStats; } else if (in == cfstats) { return kCFStats; } else if (in == dbstats) { return kDBStats; } else if (in == sstables) { return kSsTables; } *is_int_property = true; if (in == num_immutable_mem_table) { return kNumImmutableMemTable; } else if (in == num_immutable_mem_table_flushed) { return kNumImmutableMemTableFlushed; } else if (in == mem_table_flush_pending) { return kMemtableFlushPending; } else if (in == compaction_pending) { return kCompactionPending; } else if (in == background_errors) { return kBackgroundErrors; } else if (in == cur_size_active_mem_table) { return kCurSizeActiveMemTable; } else if (in == cur_size_unflushed_mem_tables) { return kCurSizeAllMemTables; } else if (in == cur_size_all_mem_tables) { return kSizeAllMemTables; } else if (in == num_entries_active_mem_table) { return kNumEntriesInMutableMemtable; } else if (in == num_entries_imm_mem_tables) { return kNumEntriesInImmutableMemtable; } else if (in == num_deletes_active_mem_table) { return kNumDeletesInMutableMemtable; } else if (in == num_deletes_imm_mem_tables) { return kNumDeletesInImmutableMemtable; } else if (in == estimate_num_keys) { return kEstimatedNumKeys; } else if (in == estimate_table_readers_mem) { *need_out_of_mutex = true; return kEstimatedUsageByTableReaders; } else if (in == is_file_deletions_enabled) { return kIsFileDeletionEnabled; } else if (in == num_snapshots) { return kNumSnapshots; } else if (in == oldest_snapshot_time) { return kOldestSnapshotTime; } else if (in == num_live_versions) { return kNumLiveVersions; } else if (in == estimate_live_data_size) { *need_out_of_mutex = true; return kEstimateLiveDataSize; } else if (in == base_level) { return kBaseLevel; } return kUnknown; } bool InternalStats::GetIntPropertyOutOfMutex(DBPropertyType property_type, Version* version, uint64_t* value) const { assert(value != nullptr); const auto* vstorage = cfd_->current()->storage_info(); switch (property_type) { case kEstimatedUsageByTableReaders: *value = (version == nullptr) ? 0 : version->GetMemoryUsageByTableReaders(); return true; case kEstimateLiveDataSize: *value = vstorage->EstimateLiveDataSize(); return true; default: return false; } } bool InternalStats::GetStringProperty(DBPropertyType property_type, const Slice& property, std::string* value) { assert(value != nullptr); auto* current = cfd_->current(); const auto* vstorage = current->storage_info(); Slice in = property; switch (property_type) { case kNumFilesAtLevel: { in.remove_prefix(strlen("rocksdb.num-files-at-level")); uint64_t level; bool ok = ConsumeDecimalNumber(&in, &level) && in.empty(); if (!ok || (int)level >= number_levels_) { return false; } else { char buf[100]; snprintf(buf, sizeof(buf), "%d", vstorage->NumLevelFiles(static_cast(level))); *value = buf; return true; } } case kLevelStats: { char buf[1000]; snprintf(buf, sizeof(buf), "Level Files Size(MB)\n" "--------------------\n"); value->append(buf); for (int level = 0; level < number_levels_; level++) { snprintf(buf, sizeof(buf), "%3d %8d %8.0f\n", level, vstorage->NumLevelFiles(level), vstorage->NumLevelBytes(level) / kMB); value->append(buf); } return true; } case kStats: { if (!GetStringProperty(kCFStats, DB::Properties::kCFStats, value)) { return false; } if (!GetStringProperty(kDBStats, DB::Properties::kDBStats, value)) { return false; } return true; } case kCFStats: { DumpCFStats(value); return true; } case kDBStats: { DumpDBStats(value); return true; } case kSsTables: *value = current->DebugString(); return true; default: return false; } } bool InternalStats::GetIntProperty(DBPropertyType property_type, uint64_t* value, DBImpl* db) const { db->mutex_.AssertHeld(); const auto* vstorage = cfd_->current()->storage_info(); switch (property_type) { case kNumImmutableMemTable: *value = cfd_->imm()->NumNotFlushed(); return true; case kNumImmutableMemTableFlushed: *value = cfd_->imm()->NumFlushed(); return true; case kMemtableFlushPending: // Return number of mem tables that are ready to flush (made immutable) *value = (cfd_->imm()->IsFlushPending() ? 1 : 0); return true; case kCompactionPending: // 1 if the system already determines at least one compaction is needed. // 0 otherwise, *value = (cfd_->compaction_picker()->NeedsCompaction(vstorage) ? 1 : 0); return true; case kBackgroundErrors: // Accumulated number of errors in background flushes or compactions. *value = GetBackgroundErrorCount(); return true; case kCurSizeActiveMemTable: // Current size of the active memtable *value = cfd_->mem()->ApproximateMemoryUsage(); return true; case kCurSizeAllMemTables: // Current size of the active memtable + immutable memtables *value = cfd_->mem()->ApproximateMemoryUsage() + cfd_->imm()->ApproximateUnflushedMemTablesMemoryUsage(); return true; case kSizeAllMemTables: *value = cfd_->mem()->ApproximateMemoryUsage() + cfd_->imm()->ApproximateMemoryUsage(); return true; case kNumEntriesInMutableMemtable: // Current number of entires in the active memtable *value = cfd_->mem()->num_entries(); return true; case kNumEntriesInImmutableMemtable: // Current number of entries in the immutable memtables *value = cfd_->imm()->current()->GetTotalNumEntries(); return true; case kNumDeletesInMutableMemtable: // Current number of entires in the active memtable *value = cfd_->mem()->num_deletes(); return true; case kNumDeletesInImmutableMemtable: // Current number of entries in the immutable memtables *value = cfd_->imm()->current()->GetTotalNumDeletes(); return true; case kEstimatedNumKeys: // Estimate number of entries in the column family: // Use estimated entries in tables + total entries in memtables. *value = cfd_->mem()->num_entries() + cfd_->imm()->current()->GetTotalNumEntries() - (cfd_->mem()->num_deletes() + cfd_->imm()->current()->GetTotalNumDeletes()) * 2 + vstorage->GetEstimatedActiveKeys(); return true; case kNumSnapshots: *value = db->snapshots().count(); return true; case kOldestSnapshotTime: *value = static_cast(db->snapshots().GetOldestSnapshotTime()); return true; case kNumLiveVersions: *value = cfd_->GetNumLiveVersions(); return true; case kIsFileDeletionEnabled: *value = db->IsFileDeletionsEnabled(); return true; case kBaseLevel: *value = vstorage->base_level(); return true; default: return false; } } void InternalStats::DumpDBStats(std::string* value) { char buf[1000]; // DB-level stats, only available from default column family double seconds_up = (env_->NowMicros() - started_at_ + 1) / 1000000.0; double interval_seconds_up = seconds_up - db_stats_snapshot_.seconds_up; snprintf(buf, sizeof(buf), "\n** DB Stats **\nUptime(secs): %.1f total, %.1f interval\n", seconds_up, interval_seconds_up); value->append(buf); // Cumulative uint64_t user_bytes_written = db_stats_[InternalStats::BYTES_WRITTEN]; uint64_t num_keys_written = db_stats_[InternalStats::NUMBER_KEYS_WRITTEN]; uint64_t write_other = db_stats_[InternalStats::WRITE_DONE_BY_OTHER]; uint64_t write_self = db_stats_[InternalStats::WRITE_DONE_BY_SELF]; uint64_t wal_bytes = db_stats_[InternalStats::WAL_FILE_BYTES]; uint64_t wal_synced = db_stats_[InternalStats::WAL_FILE_SYNCED]; uint64_t write_with_wal = db_stats_[InternalStats::WRITE_WITH_WAL]; uint64_t write_stall_micros = db_stats_[InternalStats::WRITE_STALL_MICROS]; uint64_t compact_bytes_read = 0; uint64_t compact_bytes_write = 0; uint64_t compact_micros = 0; const int kHumanMicrosLen = 32; char human_micros[kHumanMicrosLen]; // Data // writes: total number of write requests. // keys: total number of key updates issued by all the write requests // batches: number of group commits issued to the DB. Each group can contain // one or more writes. // so writes/keys is the average number of put in multi-put or put // writes/batches is the average group commit size. // // The format is the same for interval stats. snprintf(buf, sizeof(buf), "Cumulative writes: %s writes, %s keys, %s batches, " "%.1f writes per batch, ingest: %.2f GB, %.2f MB/s\n", NumberToHumanString(write_other + write_self).c_str(), NumberToHumanString(num_keys_written).c_str(), NumberToHumanString(write_self).c_str(), (write_other + write_self) / static_cast(write_self + 1), user_bytes_written / kGB, user_bytes_written / kMB / seconds_up); value->append(buf); // WAL snprintf(buf, sizeof(buf), "Cumulative WAL: %s writes, %s syncs, " "%.2f writes per sync, written: %.2f GB, %.2f MB/s\n", NumberToHumanString(write_with_wal).c_str(), NumberToHumanString(wal_synced).c_str(), write_with_wal / static_cast(wal_synced + 1), wal_bytes / kGB, wal_bytes / kMB / seconds_up); value->append(buf); // Compact for (int level = 0; level < number_levels_; level++) { compact_bytes_read += comp_stats_[level].bytes_read_output_level + comp_stats_[level].bytes_read_non_output_levels; compact_bytes_write += comp_stats_[level].bytes_written; compact_micros += comp_stats_[level].micros; } snprintf(buf, sizeof(buf), "Cumulative compaction: %.2f GB write, %.2f MB/s write, " "%.2f GB read, %.2f MB/s read, %.1f seconds\n", compact_bytes_write / kGB, compact_bytes_write / kMB / seconds_up, compact_bytes_read / kGB, compact_bytes_read / kMB / seconds_up, compact_micros / 1000000.0); value->append(buf); // Stall AppendHumanMicros(write_stall_micros, human_micros, kHumanMicrosLen, true); snprintf(buf, sizeof(buf), "Cumulative stall: %s, %.1f percent\n", human_micros, // 10000 = divide by 1M to get secs, then multiply by 100 for pct write_stall_micros / 10000.0 / std::max(seconds_up, 0.001)); value->append(buf); // Interval uint64_t interval_write_other = write_other - db_stats_snapshot_.write_other; uint64_t interval_write_self = write_self - db_stats_snapshot_.write_self; uint64_t interval_num_keys_written = num_keys_written - db_stats_snapshot_.num_keys_written; snprintf(buf, sizeof(buf), "Interval writes: %s writes, %s keys, %s batches, " "%.1f writes per batch, ingest: %.2f MB, %.2f MB/s\n", NumberToHumanString( interval_write_other + interval_write_self).c_str(), NumberToHumanString(interval_num_keys_written).c_str(), NumberToHumanString(interval_write_self).c_str(), static_cast(interval_write_other + interval_write_self) / (interval_write_self + 1), (user_bytes_written - db_stats_snapshot_.ingest_bytes) / kMB, (user_bytes_written - db_stats_snapshot_.ingest_bytes) / kMB / std::max(interval_seconds_up, 0.001)), value->append(buf); uint64_t interval_write_with_wal = write_with_wal - db_stats_snapshot_.write_with_wal; uint64_t interval_wal_synced = wal_synced - db_stats_snapshot_.wal_synced; uint64_t interval_wal_bytes = wal_bytes - db_stats_snapshot_.wal_bytes; snprintf(buf, sizeof(buf), "Interval WAL: %s writes, %s syncs, " "%.2f writes per sync, written: %.2f MB, %.2f MB/s\n", NumberToHumanString(interval_write_with_wal).c_str(), NumberToHumanString(interval_wal_synced).c_str(), interval_write_with_wal / static_cast(interval_wal_synced + 1), interval_wal_bytes / kGB, interval_wal_bytes / kMB / std::max(interval_seconds_up, 0.001)); value->append(buf); // Compaction uint64_t interval_compact_bytes_write = compact_bytes_write - db_stats_snapshot_.compact_bytes_write; uint64_t interval_compact_bytes_read = compact_bytes_read - db_stats_snapshot_.compact_bytes_read; uint64_t interval_compact_micros = compact_micros - db_stats_snapshot_.compact_micros; snprintf(buf, sizeof(buf), "Interval compaction: %.2f GB write, %.2f MB/s write, " "%.2f GB read, %.2f MB/s read, %.1f seconds\n", interval_compact_bytes_write / kGB, interval_compact_bytes_write / kMB / std::max(interval_seconds_up, 0.001), interval_compact_bytes_read / kGB, interval_compact_bytes_read / kMB / std::max(interval_seconds_up, 0.001), interval_compact_micros / 1000000.0); value->append(buf); // Stall AppendHumanMicros( write_stall_micros - db_stats_snapshot_.write_stall_micros, human_micros, kHumanMicrosLen, true); snprintf(buf, sizeof(buf), "Interval stall: %s, %.1f percent\n", human_micros, // 10000 = divide by 1M to get secs, then multiply by 100 for pct (write_stall_micros - db_stats_snapshot_.write_stall_micros) / 10000.0 / std::max(interval_seconds_up, 0.001)); value->append(buf); for (int level = 0; level < number_levels_; level++) { if (!file_read_latency_[level].Empty()) { char buf2[5000]; snprintf(buf2, sizeof(buf2), "** Level %d read latency histogram (micros):\n%s\n", level, file_read_latency_[level].ToString().c_str()); value->append(buf2); } } db_stats_snapshot_.seconds_up = seconds_up; db_stats_snapshot_.ingest_bytes = user_bytes_written; db_stats_snapshot_.write_other = write_other; db_stats_snapshot_.write_self = write_self; db_stats_snapshot_.num_keys_written = num_keys_written; db_stats_snapshot_.wal_bytes = wal_bytes; db_stats_snapshot_.wal_synced = wal_synced; db_stats_snapshot_.write_with_wal = write_with_wal; db_stats_snapshot_.write_stall_micros = write_stall_micros; db_stats_snapshot_.compact_bytes_write = compact_bytes_write; db_stats_snapshot_.compact_bytes_read = compact_bytes_read; db_stats_snapshot_.compact_micros = compact_micros; } void InternalStats::DumpCFStats(std::string* value) { const VersionStorageInfo* vstorage = cfd_->current()->storage_info(); int num_levels_to_check = (cfd_->ioptions()->compaction_style != kCompactionStyleFIFO) ? vstorage->num_levels() - 1 : 1; // Compaction scores are sorted base on its value. Restore them to the // level order std::vector compaction_score(number_levels_, 0); for (int i = 0; i < num_levels_to_check; ++i) { compaction_score[vstorage->CompactionScoreLevel(i)] = vstorage->CompactionScore(i); } // Count # of files being compacted for each level std::vector files_being_compacted(number_levels_, 0); for (int level = 0; level < number_levels_; ++level) { for (auto* f : vstorage->LevelFiles(level)) { if (f->being_compacted) { ++files_being_compacted[level]; } } } char buf[1000]; // Per-ColumnFamily stats PrintLevelStatsHeader(buf, sizeof(buf), cfd_->GetName()); value->append(buf); CompactionStats stats_sum(0); int total_files = 0; int total_files_being_compacted = 0; double total_file_size = 0; uint64_t total_slowdown_count_soft = 0; uint64_t total_slowdown_count_hard = 0; uint64_t total_stall_count = 0; for (int level = 0; level < number_levels_; level++) { int files = vstorage->NumLevelFiles(level); total_files += files; total_files_being_compacted += files_being_compacted[level]; if (comp_stats_[level].micros > 0 || files > 0) { uint64_t stalls = level == 0 ? (cf_stats_count_[LEVEL0_SLOWDOWN] + cf_stats_count_[LEVEL0_NUM_FILES] + cf_stats_count_[MEMTABLE_COMPACTION]) : (stall_leveln_slowdown_count_soft_[level] + stall_leveln_slowdown_count_hard_[level]); stats_sum.Add(comp_stats_[level]); total_file_size += vstorage->NumLevelBytes(level); total_stall_count += stalls; total_slowdown_count_soft += stall_leveln_slowdown_count_soft_[level]; total_slowdown_count_hard += stall_leveln_slowdown_count_hard_[level]; double w_amp = (comp_stats_[level].bytes_read_non_output_levels == 0) ? 0.0 : static_cast(comp_stats_[level].bytes_written) / comp_stats_[level].bytes_read_non_output_levels; PrintLevelStats(buf, sizeof(buf), "L" + ToString(level), files, files_being_compacted[level], vstorage->NumLevelBytes(level), compaction_score[level], w_amp, stalls, comp_stats_[level]); value->append(buf); } } uint64_t curr_ingest = cf_stats_value_[BYTES_FLUSHED]; // Cumulative summary double w_amp = stats_sum.bytes_written / static_cast(curr_ingest + 1); // Stats summary across levels PrintLevelStats(buf, sizeof(buf), "Sum", total_files, total_files_being_compacted, total_file_size, 0, w_amp, total_stall_count, stats_sum); value->append(buf); // Interval summary uint64_t interval_ingest = curr_ingest - cf_stats_snapshot_.ingest_bytes + 1; CompactionStats interval_stats(stats_sum); interval_stats.Subtract(cf_stats_snapshot_.comp_stats); w_amp = interval_stats.bytes_written / static_cast(interval_ingest); PrintLevelStats(buf, sizeof(buf), "Int", 0, 0, 0, 0, w_amp, total_stall_count - cf_stats_snapshot_.stall_count, interval_stats); value->append(buf); snprintf(buf, sizeof(buf), "Flush(GB): cumulative %.3f, interval %.3f\n", curr_ingest / kGB, interval_ingest / kGB); value->append(buf); snprintf(buf, sizeof(buf), "Stalls(count): %" PRIu64 " level0_slowdown, " "%" PRIu64 " level0_numfiles, %" PRIu64 " memtable_compaction, " "%" PRIu64 " leveln_slowdown_soft, " "%" PRIu64 " leveln_slowdown_hard\n", cf_stats_count_[LEVEL0_SLOWDOWN], cf_stats_count_[LEVEL0_NUM_FILES], cf_stats_count_[MEMTABLE_COMPACTION], total_slowdown_count_soft, total_slowdown_count_hard); value->append(buf); cf_stats_snapshot_.ingest_bytes = curr_ingest; cf_stats_snapshot_.comp_stats = stats_sum; cf_stats_snapshot_.stall_count = total_stall_count; } #else DBPropertyType GetPropertyType(const Slice& property, bool* is_int_property, bool* need_out_of_mutex) { return kUnknown; } #endif // !ROCKSDB_LITE } // namespace rocksdb