@ -40,6 +40,263 @@
namespace rocksdb {
namespace {
// Find File in FileLevel data structure
// Within an index range defined by left and right
int FindFileInRange ( const InternalKeyComparator & icmp ,
const FileLevel & file_level ,
const Slice & key ,
uint32_t left ,
uint32_t right ) {
while ( left < right ) {
uint32_t mid = ( left + right ) / 2 ;
const FdWithKeyRange & f = file_level . files [ mid ] ;
if ( icmp . InternalKeyComparator : : Compare ( f . largest_key , key ) < 0 ) {
// Key at "mid.largest" is < "target". Therefore all
// files at or before "mid" are uninteresting.
left = mid + 1 ;
} else {
// Key at "mid.largest" is >= "target". Therefore all files
// after "mid" are uninteresting.
right = mid ;
}
}
return right ;
}
bool NewestFirstBySeqNo ( FileMetaData * a , FileMetaData * b ) {
if ( a - > smallest_seqno ! = b - > smallest_seqno ) {
return a - > smallest_seqno > b - > smallest_seqno ;
}
if ( a - > largest_seqno ! = b - > largest_seqno ) {
return a - > largest_seqno > b - > largest_seqno ;
}
// Break ties by file number
return a - > fd . GetNumber ( ) > b - > fd . GetNumber ( ) ;
}
bool BySmallestKey ( FileMetaData * a , FileMetaData * b ,
const InternalKeyComparator * cmp ) {
int r = cmp - > Compare ( a - > smallest , b - > smallest ) ;
if ( r ! = 0 ) {
return ( r < 0 ) ;
}
// Break ties by file number
return ( a - > fd . GetNumber ( ) < b - > fd . GetNumber ( ) ) ;
}
// Class to help choose the next file to search for the particular key.
// Searches and returns files level by level.
// We can search level-by-level since entries never hop across
// levels. Therefore we are guaranteed that if we find data
// in a smaller level, later levels are irrelevant (unless we
// are MergeInProgress).
class FilePicker {
public :
FilePicker (
std : : vector < FileMetaData * > * files ,
const Slice & user_key ,
const Slice & ikey ,
autovector < FileLevel > * file_levels ,
unsigned int num_levels ,
FileIndexer * file_indexer ,
const Comparator * user_comparator ,
const InternalKeyComparator * internal_comparator )
: num_levels_ ( num_levels ) ,
curr_level_ ( - 1 ) ,
search_left_bound_ ( 0 ) ,
search_right_bound_ ( FileIndexer : : kLevelMaxIndex ) ,
files_ ( files ) ,
file_levels_ ( file_levels ) ,
user_key_ ( user_key ) ,
ikey_ ( ikey ) ,
file_indexer_ ( file_indexer ) ,
user_comparator_ ( user_comparator ) ,
internal_comparator_ ( internal_comparator ) {
// Setup member variables to search first level.
search_ended_ = ! PrepareNextLevel ( ) ;
if ( ! search_ended_ ) {
// Prefetch Level 0 table data to avoid cache miss if possible.
for ( unsigned int i = 0 ; i < ( * file_levels_ ) [ 0 ] . num_files ; + + i ) {
auto * r = ( * file_levels_ ) [ 0 ] . files [ i ] . fd . table_reader ;
if ( r ) {
r - > Prepare ( ikey ) ;
}
}
}
}
FdWithKeyRange * GetNextFile ( ) {
while ( ! search_ended_ ) { // Loops over different levels.
while ( curr_index_in_curr_level_ < curr_file_level_ - > num_files ) {
// Loops over all files in current level.
FdWithKeyRange * f = & curr_file_level_ - > files [ curr_index_in_curr_level_ ] ;
int cmp_largest = - 1 ;
// Do key range filtering of files or/and fractional cascading if:
// (1) not all the files are in level 0, or
// (2) there are more than 3 Level 0 files
// If there are only 3 or less level 0 files in the system, we skip
// the key range filtering. In this case, more likely, the system is
// highly tuned to minimize number of tables queried by each query,
// so it is unlikely that key range filtering is more efficient than
// querying the files.
if ( num_levels_ > 1 | | curr_file_level_ - > num_files > 3 ) {
// Check if key is within a file's range. If search left bound and
// right bound point to the same find, we are sure key falls in
// range.
assert (
curr_level_ = = 0 | |
curr_index_in_curr_level_ = = start_index_in_curr_level_ | |
user_comparator_ - > Compare ( user_key_ ,
ExtractUserKey ( f - > smallest_key ) ) < = 0 ) ;
int cmp_smallest = user_comparator_ - > Compare ( user_key_ ,
ExtractUserKey ( f - > smallest_key ) ) ;
if ( cmp_smallest > = 0 ) {
cmp_largest = user_comparator_ - > Compare ( user_key_ ,
ExtractUserKey ( f - > largest_key ) ) ;
}
// Setup file search bound for the next level based on the
// comparison results
if ( curr_level_ > 0 ) {
file_indexer_ - > GetNextLevelIndex ( curr_level_ ,
curr_index_in_curr_level_ ,
cmp_smallest , cmp_largest ,
& search_left_bound_ ,
& search_right_bound_ ) ;
}
// Key falls out of current file's range
if ( cmp_smallest < 0 | | cmp_largest > 0 ) {
if ( curr_level_ = = 0 ) {
+ + curr_index_in_curr_level_ ;
continue ;
} else {
// Search next level.
break ;
}
}
}
# ifndef NDEBUG
// Sanity check to make sure that the files are correctly sorted
if ( prev_file_ ) {
if ( curr_level_ ! = 0 ) {
int comp_sign = internal_comparator_ - > Compare (
prev_file_ - > largest_key , f - > smallest_key ) ;
assert ( comp_sign < 0 ) ;
} else {
// level == 0, the current file cannot be newer than the previous
// one. Use compressed data structure, has no attribute seqNo
assert ( curr_index_in_curr_level_ > 0 ) ;
assert ( ! NewestFirstBySeqNo ( files_ [ 0 ] [ curr_index_in_curr_level_ ] ,
files_ [ 0 ] [ curr_index_in_curr_level_ - 1 ] ) ) ;
}
}
prev_file_ = f ;
# endif
if ( curr_level_ > 0 & & cmp_largest < 0 ) {
// No more files to search in this level.
search_ended_ = ! PrepareNextLevel ( ) ;
} else {
+ + curr_index_in_curr_level_ ;
}
return f ;
}
// Start searching next level.
search_ended_ = ! PrepareNextLevel ( ) ;
}
// Search ended.
return nullptr ;
}
private :
unsigned int num_levels_ ;
unsigned int curr_level_ ;
int search_left_bound_ ;
int search_right_bound_ ;
std : : vector < FileMetaData * > * files_ ;
autovector < FileLevel > * file_levels_ ;
bool search_ended_ ;
FileLevel * curr_file_level_ ;
unsigned int curr_index_in_curr_level_ ;
unsigned int start_index_in_curr_level_ ;
Slice user_key_ ;
Slice ikey_ ;
FileIndexer * file_indexer_ ;
const Comparator * user_comparator_ ;
const InternalKeyComparator * internal_comparator_ ;
# ifndef NDEBUG
FdWithKeyRange * prev_file_ ;
# endif
// Setup local variables to search next level.
// Returns false if there are no more levels to search.
bool PrepareNextLevel ( ) {
curr_level_ + + ;
while ( curr_level_ < num_levels_ ) {
curr_file_level_ = & ( * file_levels_ ) [ curr_level_ ] ;
if ( curr_file_level_ - > num_files = = 0 ) {
// When current level is empty, the search bound generated from upper
// level must be [0, -1] or [0, FileIndexer::kLevelMaxIndex] if it is
// also empty.
assert ( search_left_bound_ = = 0 ) ;
assert ( search_right_bound_ = = - 1 | |
search_right_bound_ = = FileIndexer : : kLevelMaxIndex ) ;
// Since current level is empty, it will need to search all files in
// the next level
search_left_bound_ = 0 ;
search_right_bound_ = FileIndexer : : kLevelMaxIndex ;
curr_level_ + + ;
continue ;
}
// Some files may overlap each other. We find
// all files that overlap user_key and process them in order from
// newest to oldest. In the context of merge-operator, this can occur at
// any level. Otherwise, it only occurs at Level-0 (since Put/Deletes
// are always compacted into a single entry).
int32_t start_index ;
if ( curr_level_ = = 0 ) {
// On Level-0, we read through all files to check for overlap.
start_index = 0 ;
} else {
// On Level-n (n>=1), files are sorted. Binary search to find the
// earliest file whose largest key >= ikey. Search left bound and
// right bound are used to narrow the range.
if ( search_left_bound_ = = search_right_bound_ ) {
start_index = search_left_bound_ ;
} else if ( search_left_bound_ < search_right_bound_ ) {
if ( search_right_bound_ = = FileIndexer : : kLevelMaxIndex ) {
search_right_bound_ = curr_file_level_ - > num_files - 1 ;
}
start_index = FindFileInRange ( * internal_comparator_ ,
* curr_file_level_ , ikey_ ,
search_left_bound_ , search_right_bound_ ) ;
} else {
// search_left_bound > search_right_bound, key does not exist in
// this level. Since no comparision is done in this level, it will
// need to search all files in the next level.
search_left_bound_ = 0 ;
search_right_bound_ = FileIndexer : : kLevelMaxIndex ;
curr_level_ + + ;
continue ;
}
}
start_index_in_curr_level_ = start_index ;
curr_index_in_curr_level_ = start_index ;
# ifndef NDEBUG
prev_file_ = nullptr ;
# endif
return true ;
}
// curr_level_ = num_levels_. So, no more levels to search.
return false ;
}
} ;
} // anonymous namespace
static uint64_t TotalFileSize ( const std : : vector < FileMetaData * > & files ) {
uint64_t sum = 0 ;
for ( size_t i = 0 ; i < files . size ( ) & & files [ i ] ; i + + ) {
@ -82,29 +339,6 @@ Version::~Version() {
delete [ ] files_ ;
}
// Find File in FileLevel data structure
// Within an index range defined by left and right
int FindFileInRange ( const InternalKeyComparator & icmp ,
const FileLevel & file_level ,
const Slice & key ,
uint32_t left ,
uint32_t right ) {
while ( left < right ) {
uint32_t mid = ( left + right ) / 2 ;
const FdWithKeyRange & f = file_level . files [ mid ] ;
if ( icmp . InternalKeyComparator : : Compare ( f . largest_key , key ) < 0 ) {
// Key at "mid.largest" is < "target". Therefore all
// files at or before "mid" are uninteresting.
left = mid + 1 ;
} else {
// Key at "mid.largest" is >= "target". Therefore all files
// after "mid" are uninteresting.
right = mid ;
}
}
return right ;
}
int FindFile ( const InternalKeyComparator & icmp ,
const FileLevel & file_level ,
const Slice & key ) {
@ -507,28 +741,6 @@ static bool SaveValue(void* arg, const ParsedInternalKey& parsed_key,
return false ;
}
namespace {
bool NewestFirstBySeqNo ( FileMetaData * a , FileMetaData * b ) {
if ( a - > smallest_seqno ! = b - > smallest_seqno ) {
return a - > smallest_seqno > b - > smallest_seqno ;
}
if ( a - > largest_seqno ! = b - > largest_seqno ) {
return a - > largest_seqno > b - > largest_seqno ;
}
// Break ties by file number
return a - > fd . GetNumber ( ) > b - > fd . GetNumber ( ) ;
}
bool BySmallestKey ( FileMetaData * a , FileMetaData * b ,
const InternalKeyComparator * cmp ) {
int r = cmp - > Compare ( a - > smallest , b - > smallest ) ;
if ( r ! = 0 ) {
return ( r < 0 ) ;
}
// Break ties by file number
return ( a - > fd . GetNumber ( ) < b - > fd . GetNumber ( ) ) ;
}
} // anonymous namespace
Version : : Version ( ColumnFamilyData * cfd , VersionSet * vset ,
uint64_t version_number )
: cfd_ ( cfd ) ,
@ -591,139 +803,10 @@ void Version::Get(const ReadOptions& options,
saver . logger = info_log_ ;
saver . statistics = db_statistics_ ;
// We can search level-by-level since entries never hop across
// levels. Therefore we are guaranteed that if we find data
// in an smaller level, later levels are irrelevant (unless we
// are MergeInProgress).
int32_t search_left_bound = 0 ;
int32_t search_right_bound = FileIndexer : : kLevelMaxIndex ;
for ( int level = 0 ; level < num_non_empty_levels_ ; + + level ) {
int num_files = file_levels_ [ level ] . num_files ;
if ( num_files = = 0 ) {
// When current level is empty, the search bound generated from upper
// level must be [0, -1] or [0, FileIndexer::kLevelMaxIndex] if it is
// also empty.
assert ( search_left_bound = = 0 ) ;
assert ( search_right_bound = = - 1 | |
search_right_bound = = FileIndexer : : kLevelMaxIndex ) ;
// Since current level is empty, it will need to search all files in the
// next level
search_left_bound = 0 ;
search_right_bound = FileIndexer : : kLevelMaxIndex ;
continue ;
}
// Prefetch table data to avoid cache miss if possible
if ( level = = 0 ) {
for ( int i = 0 ; i < num_files ; + + i ) {
auto * r = file_levels_ [ 0 ] . files [ i ] . fd . table_reader ;
if ( r ) {
r - > Prepare ( ikey ) ;
}
}
}
// Get the list of files to search in this level
FdWithKeyRange * files = file_levels_ [ level ] . files ;
// Some files may overlap each other. We find
// all files that overlap user_key and process them in order from
// newest to oldest. In the context of merge-operator,
// this can occur at any level. Otherwise, it only occurs
// at Level-0 (since Put/Deletes are always compacted into a single entry).
int32_t start_index ;
if ( level = = 0 ) {
// On Level-0, we read through all files to check for overlap.
start_index = 0 ;
} else {
// On Level-n (n>=1), files are sorted. Binary search to find the earliest
// file whose largest key >= ikey. Search left bound and right bound are
// used to narrow the range.
if ( search_left_bound = = search_right_bound ) {
start_index = search_left_bound ;
} else if ( search_left_bound < search_right_bound ) {
if ( search_right_bound = = FileIndexer : : kLevelMaxIndex ) {
search_right_bound = num_files - 1 ;
}
start_index = FindFileInRange ( cfd_ - > internal_comparator ( ) ,
file_levels_ [ level ] , ikey ,
search_left_bound , search_right_bound ) ;
} else {
// search_left_bound > search_right_bound, key does not exist in this
// level. Since no comparision is done in this level, it will need to
// search all files in the next level.
search_left_bound = 0 ;
search_right_bound = FileIndexer : : kLevelMaxIndex ;
continue ;
}
}
// Traverse each relevant file to find the desired key
# ifndef NDEBUG
FdWithKeyRange * prev_file = nullptr ;
# endif
for ( int32_t i = start_index ; i < num_files ; ) {
FdWithKeyRange * f = & files [ i ] ;
assert ( f - > fd . GetNumber ( ) = = files_ [ level ] [ i ] - > fd . GetNumber ( ) ) ;
int cmp_largest = - 1 ;
// Do key range filtering of files or/and fractional cascading if:
// (1) not all the files are in level 0, or
// (2) there are more than 3 Level 0 files
// If there are only 3 or less level 0 files in the system, we skip the
// key range filtering. In this case, more likely, the system is highly
// tuned to minimize number of tables queried by each query, so it is
// unlikely that key range filtering is more efficient than querying the
// files.
if ( num_non_empty_levels_ > 1 | | num_files > 3 ) {
// Check if key is within a file's range. If search left bound and right
// bound point to the same find, we are sure key falls in range.
assert (
level = = 0 | | i = = start_index | | user_comparator_ - > Compare (
user_key , ExtractUserKey ( f - > smallest_key ) ) < = 0 ) ;
int cmp_smallest = user_comparator_ - > Compare ( user_key ,
ExtractUserKey ( f - > smallest_key ) ) ;
if ( cmp_smallest > = 0 ) {
cmp_largest = user_comparator_ - > Compare ( user_key ,
ExtractUserKey ( f - > largest_key ) ) ;
}
// Setup file search bound for the next level based on the comparison
// results
if ( level > 0 ) {
file_indexer_ . GetNextLevelIndex ( level , i , cmp_smallest , cmp_largest ,
& search_left_bound ,
& search_right_bound ) ;
}
// Key falls out of current file's range
if ( cmp_smallest < 0 | | cmp_largest > 0 ) {
if ( level = = 0 ) {
+ + i ;
continue ;
} else {
break ;
}
}
}
# ifndef NDEBUG
// Sanity check to make sure that the files are correctly sorted
if ( prev_file ) {
if ( level ! = 0 ) {
int comp_sign = internal_comparator_ - > Compare ( prev_file - > largest_key ,
f - > smallest_key ) ;
assert ( comp_sign < 0 ) ;
} else {
// level == 0, the current file cannot be newer than the previous one.
// Use compressed data structure, has no attribute seqNo
assert ( i > 0 ) ;
assert ( ! NewestFirstBySeqNo ( files_ [ 0 ] [ i ] , files_ [ 0 ] [ i - 1 ] ) ) ;
}
}
prev_file = f ;
# endif
FilePicker fp ( files_ , user_key , ikey , & file_levels_ , num_non_empty_levels_ ,
& file_indexer_ , user_comparator_ , internal_comparator_ ) ;
FdWithKeyRange * f = fp . GetNextFile ( ) ;
while ( f ! = nullptr ) {
* status = table_cache_ - > Get ( options , * internal_comparator_ , f - > fd , ikey ,
& saver , SaveValue , MarkKeyMayExist ) ;
// TODO: examine the behavior for corrupted key
@ -745,12 +828,7 @@ void Version::Get(const ReadOptions& options,
case kMerge :
break ;
}
if ( level > 0 & & cmp_largest < 0 ) {
break ;
} else {
+ + i ;
}
}
f = fp . GetNextFile ( ) ;
}
if ( kMerge = = saver . state ) {