Drain unnecessary levels when `level_compaction_dynamic_level_bytes=true` (#11340)

Summary:
When a user migrates to level compaction + `level_compaction_dynamic_level_bytes=true`, or when a DB shrinks, there can be unnecessary levels in the DB. Before this PR, this is no way to remove these levels except a manual compaction. These extra unnecessary levels make it harder to guarantee max_bytes_for_level_multiplier and can cause extra space amp. This PR boosts compaction score for these levels to allow RocksDB to automatically drain these levels. Together with https://github.com/facebook/rocksdb/issues/11321, this makes migration to `level_compaction_dynamic_level_bytes=true` automatic without needing user to do a one time full manual compaction. Credit: this PR is modified from https://github.com/facebook/rocksdb/issues/3921.

Pull Request resolved: https://github.com/facebook/rocksdb/pull/11340

Test Plan:
- New unit tests
- `python3 tools/db_crashtest.py whitebox --simple` which randomly sets level_compaction_dynamic_level_bytes in each run.

Reviewed By: ajkr

Differential Revision: D44563884

Pulled By: cbi42

fbshipit-source-id: e20d3620bd73dff22be18c5a91a07f340740bcc8
oxigraph-8.3.2
Changyu Bi 2 years ago committed by Facebook GitHub Bot
parent 0623c5b903
commit b3c43a5b99
  1. 3
      HISTORY.md
  2. 5
      db/compact_files_test.cc
  3. 13
      db/compaction/compaction.h
  4. 21
      db/compaction/compaction_iterator.cc
  5. 1
      db/compaction/tiered_compaction_test.cc
  6. 202
      db/db_compaction_test.cc
  7. 3
      db/db_impl/db_impl_open.cc
  8. 4
      db/db_test.cc
  9. 69
      db/version_set.cc
  10. 6
      db/version_set.h
  11. 31
      db/version_set_test.cc
  12. 6
      include/rocksdb/advanced_options.h

@ -6,8 +6,9 @@
### Behavior changes
* Changed default block cache size from an 8MB to 32MB LRUCache, which increases the default number of cache shards from 16 to 64. This change is intended to minimize cache mutex contention under stress conditions. See https://github.com/facebook/rocksdb/wiki/Block-Cache for more information.
* For level compaction with `level_compaction_dynamic_level_bytes=true`, RocksDB now trivially moves levels down to fill LSM starting from bottommost level during DB open. See more in comments for option `level_compaction_dynamic_level_bytes`.
* For level compaction with `level_compaction_dynamic_level_bytes=true`, RocksDB now trivially moves levels down to fill LSM starting from bottommost level during DB open. See more in comments for option `level_compaction_dynamic_level_bytes` (#11321).
* User-provided `ReadOptions` take effect for more reads of non-`CacheEntryRole::kDataBlock` blocks.
* For level compaction with `level_compaction_dynamic_level_bytes=true`, RocksDB now drains unnecessary levels through background compaction automatically (#11340). This together with #11321 makes it automatic to migrate other compaction settings to level compaction with `level_compaction_dynamic_level_bytes=true`. In addition, a live DB that becomes smaller will now have unnecessary levels drained which can help to reduce read and space amp.
### Bug Fixes
* In the DB::VerifyFileChecksums API, ensure that file system reads of SST files are equal to the readahead_size in ReadOptions, if specified. Previously, each read was 2x the readahead_size.

@ -120,7 +120,9 @@ TEST_F(CompactFilesTest, L0ConflictsFiles) {
TEST_F(CompactFilesTest, MultipleLevel) {
Options options;
options.create_if_missing = true;
options.level_compaction_dynamic_level_bytes = true;
// Otherwise background compaction can happen to
// drain unnecessary level
options.level_compaction_dynamic_level_bytes = false;
options.num_levels = 6;
// Add listener
FlushedFileCollector* collector = new FlushedFileCollector();
@ -181,7 +183,6 @@ TEST_F(CompactFilesTest, MultipleLevel) {
for (int invalid_output_level = 0; invalid_output_level < 5;
invalid_output_level++) {
s = db->CompactFiles(CompactionOptions(), files, invalid_output_level);
std::cout << s.ToString() << std::endl;
ASSERT_TRUE(s.IsInvalidArgument());
}

@ -546,13 +546,16 @@ struct PerKeyPlacementContext {
const Slice value;
const SequenceNumber seq_num;
bool output_to_penultimate_level;
bool& output_to_penultimate_level;
PerKeyPlacementContext(int _level, Slice _key, Slice _value,
SequenceNumber _seq_num)
: level(_level), key(_key), value(_value), seq_num(_seq_num) {
output_to_penultimate_level = false;
}
SequenceNumber _seq_num,
bool& _output_to_penultimate_level)
: level(_level),
key(_key),
value(_value),
seq_num(_seq_num),
output_to_penultimate_level(_output_to_penultimate_level) {}
};
#endif /* !NDEBUG */

@ -1201,17 +1201,7 @@ void CompactionIterator::GarbageCollectBlobIfNeeded() {
void CompactionIterator::DecideOutputLevel() {
assert(compaction_->SupportsPerKeyPlacement());
#ifndef NDEBUG
// Could be overridden by unittest
PerKeyPlacementContext context(level_, ikey_.user_key, value_,
ikey_.sequence);
TEST_SYNC_POINT_CALLBACK("CompactionIterator::PrepareOutput.context",
&context);
output_to_penultimate_level_ = context.output_to_penultimate_level;
#else
output_to_penultimate_level_ = false;
#endif // NDEBUG
// if the key is newer than the cutoff sequence or within the earliest
// snapshot, it should output to the penultimate level.
if (ikey_.sequence > preclude_last_level_min_seqno_ ||
@ -1219,6 +1209,17 @@ void CompactionIterator::DecideOutputLevel() {
output_to_penultimate_level_ = true;
}
#ifndef NDEBUG
// Could be overridden by unittest
PerKeyPlacementContext context(level_, ikey_.user_key, value_, ikey_.sequence,
output_to_penultimate_level_);
TEST_SYNC_POINT_CALLBACK("CompactionIterator::PrepareOutput.context",
&context);
if (ikey_.sequence > earliest_snapshot_) {
output_to_penultimate_level_ = true;
}
#endif // NDEBUG
if (output_to_penultimate_level_) {
// If it's decided to output to the penultimate level, but unsafe to do so,
// still output to the last level. For example, moving the data from a lower

@ -1111,6 +1111,7 @@ TEST_P(TieredCompactionTest, RangeBasedTieredStorageLevel) {
options.num_levels = kNumLevels;
options.statistics = CreateDBStatistics();
options.max_subcompactions = 10;
options.preclude_last_level_data_seconds = 10000;
DestroyAndReopen(options);
auto cmp = options.comparator;

@ -9118,11 +9118,19 @@ TEST_F(DBCompactionTest, TurnOnLevelCompactionDynamicLevelBytes) {
options.level_compaction_dynamic_level_bytes = false;
options.num_levels = 6;
options.compression = kNoCompression;
options.max_bytes_for_level_base = 1 << 20;
options.max_bytes_for_level_multiplier = 10;
DestroyAndReopen(options);
// put files in L0, L1 and L2
WriteOptions write_opts;
ASSERT_OK(db_->Put(write_opts, Key(1), "val1"));
Random rnd(33);
// Fill L2 with size larger than max_bytes_for_level_base,
// so the level above it won't be drained.
for (int i = 2; i <= (1 << 10); ++i) {
ASSERT_OK(db_->Put(write_opts, Key(i), rnd.RandomString(2 << 10)));
}
ASSERT_OK(Flush());
MoveFilesToLevel(2);
ASSERT_OK(db_->Put(write_opts, Key(2), "val2"));
@ -9157,63 +9165,11 @@ TEST_F(DBCompactionTest, TurnOnLevelCompactionDynamicLevelBytes) {
// newly flushed file is also pushed down
options.level_compaction_dynamic_level_bytes = true;
Reopen(options);
ASSERT_EQ("0,0,0,1,1,2", FilesPerLevel());
verify_db();
}
TEST_F(DBCompactionTest, TurnOnLevelCompactionDynamicLevelBytesIngestBehind) {
Options options = CurrentOptions();
options.compaction_style = kCompactionStyleLevel;
options.allow_ingest_behind = true;
options.level_compaction_dynamic_level_bytes = false;
options.num_levels = 6;
options.compression = kNoCompression;
DestroyAndReopen(options);
// put files in L0, L1 and L2
WriteOptions write_opts;
ASSERT_OK(db_->Put(write_opts, Key(1), "val1"));
ASSERT_OK(Flush());
MoveFilesToLevel(2);
ASSERT_OK(db_->Put(write_opts, Key(2), "val2"));
ASSERT_OK(Flush());
MoveFilesToLevel(2);
ASSERT_OK(db_->Put(write_opts, Key(1), "new_val1"));
ASSERT_OK(Flush());
MoveFilesToLevel(1);
ASSERT_OK(db_->Put(write_opts, Key(3), "val3"));
ASSERT_OK(Flush());
ASSERT_EQ("1,1,2", FilesPerLevel());
auto verify_db = [&]() {
ASSERT_EQ(Get(Key(1)), "new_val1");
ASSERT_EQ(Get(Key(2)), "val2");
ASSERT_EQ(Get(Key(3)), "val3");
};
verify_db();
options.level_compaction_dynamic_level_bytes = true;
Reopen(options);
// note that last level (L6) should be empty
ASSERT_EQ("1,0,0,1,2", FilesPerLevel());
verify_db();
// turning the options on and off should both be safe
options.level_compaction_dynamic_level_bytes = false;
Reopen(options);
MoveFilesToLevel(1);
ASSERT_EQ("0,1,0,1,2", FilesPerLevel());
verify_db();
// newly flushed file is also pushed down
options.level_compaction_dynamic_level_bytes = true;
Reopen(options);
ASSERT_EQ("0,0,1,1,2", FilesPerLevel());
verify_db();
// files will be pushed down to last level (L6)
options.allow_ingest_behind = false;
Reopen(options);
ASSERT_EQ("0,0,0,1,1,2", FilesPerLevel());
// Files in L1 should be trivially moved down during DB opening.
// The file should be moved to L3, and then may be drained and compacted to
// L4. So we just check L1 and L2 here.
ASSERT_EQ(0, NumTableFilesAtLevel(1));
ASSERT_EQ(0, NumTableFilesAtLevel(2));
verify_db();
}
@ -9253,6 +9209,138 @@ TEST_F(DBCompactionTest, TurnOnLevelCompactionDynamicLevelBytesUCToLC) {
ASSERT_EQ(expected_lsm, FilesPerLevel(1));
}
TEST_F(DBCompactionTest, DrainUnnecessaryLevelsAfterMultiplierChanged) {
// When the level size multiplier increases such that fewer levels become
// necessary, unnecessary levels should to be drained.
const int kBaseLevelBytes = 256 << 10; // 256KB
const int kFileBytes = 64 << 10; // 64KB
const int kInitMultiplier = 2, kChangedMultiplier = 10;
const int kNumFiles = 32;
const int kNumLevels = 5;
const int kValueBytes = 1 << 10; // 1KB
Options options = CurrentOptions();
options.compression = kNoCompression;
options.level_compaction_dynamic_level_bytes = true;
options.max_bytes_for_level_base = kBaseLevelBytes;
options.max_bytes_for_level_multiplier = kInitMultiplier;
options.num_levels = kNumLevels;
Reopen(options);
// Initially we setup the LSM to look roughly as follows:
//
// L0: empty
// L1: 256KB
// ...
// L4: 1MB
Random rnd(301);
for (int file = 0; file < kNumFiles; ++file) {
for (int i = 0; i < kFileBytes / kValueBytes; ++i) {
ASSERT_OK(Put(Key(file * kFileBytes / kValueBytes + i),
rnd.RandomString(kValueBytes)));
}
ASSERT_OK(Flush());
}
int init_num_nonempty = 0;
ASSERT_OK(dbfull()->TEST_WaitForCompact());
for (int level = 1; level < kNumLevels; ++level) {
if (NumTableFilesAtLevel(level) > 0) {
++init_num_nonempty;
}
}
// After increasing the multiplier and running compaction fewer levels are
// needed to hold all the data. Unnecessary levels should be drained.
ASSERT_OK(db_->SetOptions({{"max_bytes_for_level_multiplier",
std::to_string(kChangedMultiplier)}}));
ASSERT_OK(dbfull()->TEST_WaitForCompact());
int final_num_nonempty = 0;
for (int level = 1; level < kNumLevels; ++level) {
if (NumTableFilesAtLevel(level) > 0) {
++final_num_nonempty;
}
}
ASSERT_GT(init_num_nonempty, final_num_nonempty);
}
TEST_F(DBCompactionTest, DrainUnnecessaryLevelsAfterDBBecomesSmall) {
// When the DB size is smaller, e.g., large chunk of data deleted by
// DeleteRange(), unnecessary levels should to be drained.
const int kBaseLevelBytes = 256 << 10; // 256KB
const int kFileBytes = 64 << 10; // 64KB
const int kMultiplier = 2;
const int kNumFiles = 32;
const int kNumLevels = 5;
const int kValueBytes = 1 << 10; // 1KB
const int kDeleteFileNum = 8;
Options options = CurrentOptions();
options.compression = kNoCompression;
options.level_compaction_dynamic_level_bytes = true;
options.max_bytes_for_level_base = kBaseLevelBytes;
options.max_bytes_for_level_multiplier = kMultiplier;
options.num_levels = kNumLevels;
Reopen(options);
// Initially we setup the LSM to look roughly as follows:
//
// L0: empty
// L1: 256KB
// ...
// L4: 1MB
Random rnd(301);
for (int file = 0; file < kNumFiles; ++file) {
for (int i = 0; i < kFileBytes / kValueBytes; ++i) {
ASSERT_OK(Put(Key(file * kFileBytes / kValueBytes + i),
rnd.RandomString(kValueBytes)));
}
ASSERT_OK(Flush());
if (file == kDeleteFileNum) {
// Ensure the DeleteRange() call below only delete data from last level
ASSERT_OK(db_->CompactRange(CompactRangeOptions(), nullptr, nullptr));
ASSERT_EQ(NumTableFilesAtLevel(kNumLevels - 1), kDeleteFileNum + 1);
}
}
int init_num_nonempty = 0;
ASSERT_OK(dbfull()->TEST_WaitForCompact());
for (int level = 1; level < kNumLevels; ++level) {
if (NumTableFilesAtLevel(level) > 0) {
++init_num_nonempty;
}
}
// Disable auto compaction CompactRange() below
ASSERT_OK(dbfull()->SetOptions({{"disable_auto_compactions", "true"}}));
// Delete keys within first (kDeleteFileNum + 1) files' key ranges.
// This should reduce DB size enough such that there is now
// an unneeded level.
std::string begin = Key(0);
std::string end = Key(kDeleteFileNum * kFileBytes / kValueBytes);
ASSERT_OK(
db_->DeleteRange(WriteOptions(), db_->DefaultColumnFamily(), begin, end));
Slice begin_slice = begin;
Slice end_slice = end;
ASSERT_OK(db_->CompactRange(CompactRangeOptions(), &begin_slice, &end_slice));
int after_delete_range_nonempty = 0;
for (int level = 1; level < kNumLevels; ++level) {
if (NumTableFilesAtLevel(level) > 0) {
++after_delete_range_nonempty;
}
}
ASSERT_OK(dbfull()->SetOptions({{"disable_auto_compactions", "false"}}));
ASSERT_OK(dbfull()->TEST_WaitForCompact());
int final_num_nonempty = 0;
for (int level = 1; level < kNumLevels; ++level) {
if (NumTableFilesAtLevel(level) > 0) {
++final_num_nonempty;
}
}
ASSERT_GE(init_num_nonempty, after_delete_range_nonempty);
ASSERT_GT(after_delete_range_nonempty, final_num_nonempty);
}
} // namespace ROCKSDB_NAMESPACE
int main(int argc, char** argv) {

@ -555,6 +555,9 @@ Status DBImpl::Recover(
!cfd->GetLatestMutableCFOptions()->disable_auto_compactions) {
int to_level = cfd->ioptions()->num_levels - 1;
// last level is reserved
// allow_ingest_behind does not support Level Compaction,
// and per_key_placement can have infinite compaction loop for Level
// Compaction. Adjust to_level here just to be safe.
if (cfd->ioptions()->allow_ingest_behind ||
cfd->ioptions()->preclude_last_level_data_seconds > 0) {
to_level -= 1;

@ -353,7 +353,7 @@ TEST_F(DBTest, MixedSlowdownOptionsInQueue) {
for (int i = 0; i < 2; ++i) {
threads.emplace_back(write_no_slowdown_func);
}
// Sleep for 2s to allow the threads to insert themselves into the
// Sleep for 3s to allow the threads to insert themselves into the
// write queue
env_->SleepForMicroseconds(3000000ULL);
}
@ -424,7 +424,7 @@ TEST_F(DBTest, MixedSlowdownOptionsStop) {
for (int i = 0; i < 2; ++i) {
threads.emplace_back(write_no_slowdown_func);
}
// Sleep for 2s to allow the threads to insert themselves into the
// Sleep for 3s to allow the threads to insert themselves into the
// write queue
env_->SleepForMicroseconds(3000000ULL);
}

@ -3373,7 +3373,7 @@ void VersionStorageInfo::ComputeCompactionScore(
}
}
}
} else {
} else { // level > 0
// Compute the ratio of current size to size limit.
uint64_t level_bytes_no_compacting = 0;
uint64_t level_total_bytes = 0;
@ -3383,21 +3383,36 @@ void VersionStorageInfo::ComputeCompactionScore(
level_bytes_no_compacting += f->compensated_file_size;
}
}
if (!immutable_options.level_compaction_dynamic_level_bytes ||
level_bytes_no_compacting < MaxBytesForLevel(level)) {
if (!immutable_options.level_compaction_dynamic_level_bytes) {
score = static_cast<double>(level_bytes_no_compacting) /
MaxBytesForLevel(level);
} else {
// If there are a large mount of data being compacted down to the
// current level soon, we would de-prioritize compaction from
// a level where the incoming data would be a large ratio. We do
// it by dividing level size not by target level size, but
// the target size and the incoming compaction bytes.
score = static_cast<double>(level_bytes_no_compacting) /
(MaxBytesForLevel(level) + total_downcompact_bytes) *
kScoreScale;
if (level_bytes_no_compacting < MaxBytesForLevel(level)) {
score = static_cast<double>(level_bytes_no_compacting) /
MaxBytesForLevel(level);
} else {
// If there are a large mount of data being compacted down to the
// current level soon, we would de-prioritize compaction from
// a level where the incoming data would be a large ratio. We do
// it by dividing level size not by target level size, but
// the target size and the incoming compaction bytes.
score = static_cast<double>(level_bytes_no_compacting) /
(MaxBytesForLevel(level) + total_downcompact_bytes) *
kScoreScale;
}
// Drain unnecessary levels, but with lower priority compared to
// when L0 is eligible. Only non-empty levels can be unnecessary.
// If there is no unnecessary levels, lowest_unnecessary_level_ = -1.
if (level_bytes_no_compacting > 0 &&
level <= lowest_unnecessary_level_) {
score = std::max(
score, kScoreScale *
(1.001 + 0.001 * (lowest_unnecessary_level_ - level)));
}
}
if (level_total_bytes > MaxBytesForLevel(level)) {
if (level <= lowest_unnecessary_level_) {
total_downcompact_bytes += level_total_bytes;
} else if (level_total_bytes > MaxBytesForLevel(level)) {
total_downcompact_bytes +=
static_cast<double>(level_total_bytes - MaxBytesForLevel(level));
}
@ -4470,6 +4485,7 @@ void VersionStorageInfo::CalculateBaseBytes(const ImmutableOptions& ioptions,
}
}
} else {
assert(ioptions.compaction_style == kCompactionStyleLevel);
uint64_t max_level_size = 0;
int first_non_empty_level = -1;
@ -4494,11 +4510,13 @@ void VersionStorageInfo::CalculateBaseBytes(const ImmutableOptions& ioptions,
level_max_bytes_[i] = std::numeric_limits<uint64_t>::max();
}
lowest_unnecessary_level_ = -1;
if (max_level_size == 0) {
// No data for L1 and up. L0 compacts to last level directly.
// No compaction from L1+ needs to be scheduled.
base_level_ = num_levels_ - 1;
} else {
assert(first_non_empty_level >= 1);
uint64_t base_bytes_max = options.max_bytes_for_level_base;
uint64_t base_bytes_min = static_cast<uint64_t>(
base_bytes_max / options.max_bytes_for_level_multiplier);
@ -4509,20 +4527,41 @@ void VersionStorageInfo::CalculateBaseBytes(const ImmutableOptions& ioptions,
// Round up after dividing
cur_level_size = static_cast<uint64_t>(
cur_level_size / options.max_bytes_for_level_multiplier);
if (lowest_unnecessary_level_ == -1 &&
cur_level_size <= base_bytes_min &&
(ioptions.preclude_last_level_data_seconds == 0 ||
i < num_levels_ - 2)) {
// When per_key_placement is enabled, the penultimate level is
// necessary.
lowest_unnecessary_level_ = i;
}
}
// Calculate base level and its size.
uint64_t base_level_size;
if (cur_level_size <= base_bytes_min) {
// If per_key_placement is not enabled,
// either there is only one non-empty level after level 0,
// which can less than base_bytes_min AND necessary,
// or there is some unnecessary level.
assert(first_non_empty_level == num_levels_ - 1 ||
ioptions.preclude_last_level_data_seconds > 0 ||
lowest_unnecessary_level_ != -1);
// Case 1. If we make target size of last level to be max_level_size,
// target size of the first non-empty level would be smaller than
// base_bytes_min. We set it be base_bytes_min.
base_level_size = base_bytes_min + 1U;
base_level_ = first_non_empty_level;
ROCKS_LOG_INFO(ioptions.logger,
"More existing levels in DB than needed. "
"max_bytes_for_level_multiplier may not be guaranteed.");
if (base_level_ < num_levels_ - 1) {
ROCKS_LOG_INFO(
ioptions.logger,
"More existing levels in DB than needed: all non-zero "
"levels <= level %d are unnecessary. "
"max_bytes_for_level_multiplier may not be guaranteed.",
lowest_unnecessary_level_);
}
} else {
assert(lowest_unnecessary_level_ == -1);
// Find base level (where L0 data is compacted to).
base_level_ = first_non_empty_level;
while (base_level_ > 1 && cur_level_size > base_bytes_max) {

@ -650,6 +650,12 @@ class VersionStorageInfo {
// be empty. -1 if it is not level-compaction so it's not applicable.
int base_level_;
// Applies to level compaction when
// `level_compaction_dynamic_level_bytes=true`. All non-empty levels <=
// lowest_unnecessary_level_ are not needed and will be drained automatically.
// -1 if there is no unnecessary level,
int lowest_unnecessary_level_;
double level_multiplier_;
// A list for the same set of files that are stored in files_,

@ -454,6 +454,37 @@ TEST_F(VersionStorageInfoTest, MaxBytesForLevelDynamicWithLargeL0_3) {
ASSERT_EQ(4, vstorage_.CompactionScoreLevel(2));
}
TEST_F(VersionStorageInfoTest, DrainUnnecessaryLevel) {
ioptions_.level_compaction_dynamic_level_bytes = true;
mutable_cf_options_.max_bytes_for_level_base = 1000;
mutable_cf_options_.max_bytes_for_level_multiplier = 10;
// Create a few unnecessary levels.
// See if score is calculated correctly.
Add(5, 1U, "1", "2", 2000U); // target size 1010000
Add(4, 2U, "1", "2", 200U); // target size 101000
// Unnecessary levels
Add(3, 3U, "1", "2", 100U); // target size 10100
// Level 2: target size 1010
Add(1, 4U, "1", "2",
10U); // target size 1000 = max(base_bytes_min + 1, base_bytes_max)
UpdateVersionStorageInfo();
ASSERT_EQ(1, vstorage_.base_level());
ASSERT_EQ(1000, vstorage_.MaxBytesForLevel(1));
ASSERT_EQ(10100, vstorage_.MaxBytesForLevel(3));
vstorage_.ComputeCompactionScore(ioptions_, mutable_cf_options_);
// Tests that levels 1 and 3 are eligible for compaction.
// Levels 1 and 3 are much smaller than target size,
// so size does not contribute to a high compaction score.
ASSERT_EQ(1, vstorage_.CompactionScoreLevel(0));
ASSERT_GT(vstorage_.CompactionScore(0), 10);
ASSERT_EQ(3, vstorage_.CompactionScoreLevel(1));
ASSERT_GT(vstorage_.CompactionScore(1), 10);
}
TEST_F(VersionStorageInfoTest, EstimateLiveDataSize) {
// Test whether the overlaps are detected as expected
Add(1, 1U, "4", "7", 1U); // Perfect overlap with last level

@ -592,7 +592,7 @@ struct AdvancedColumnFamilyOptions {
// and max_bytes_for_level_base=10MB.
// Target sizes of level 1 to 5 starts with:
// [- - - - 10MB]
// with base level is level. Target sizes of level 1 to 4 are not applicable
// with base level is level 5. Target sizes of level 1 to 4 are not applicable
// because they will not be used.
// Until the size of Level 5 grows to more than 10MB, say 11MB, we make
// base target to level 4 and now the targets looks like:
@ -665,8 +665,8 @@ struct AdvancedColumnFamilyOptions {
// computed based on this feature) in the LSM after a user migrates to turn
// this feature on. This is especially likely when a user migrates from
// leveled compaction with a smaller multiplier or from universal compaction.
// A full manual compaction is needed to drain these levels explicitly.
//
// RocksDB will gradually drain these unnecessary levels by compacting files
// down the LSM.
//
// Default: false
bool level_compaction_dynamic_level_bytes = false;

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