@ -15,6 +15,7 @@
# include "rocksdb/filter_policy.h"
# include "rocksdb/filter_policy.h"
# include "rocksdb/options.h"
# include "rocksdb/options.h"
# include "rocksdb/statistics.h"
# include "rocksdb/statistics.h"
# include "rocksdb/plain_table_factory.h"
# include "table/block.h"
# include "table/block.h"
# include "table/filter_block.h"
# include "table/filter_block.h"
@ -23,6 +24,7 @@
# include "table/two_level_iterator.h"
# include "table/two_level_iterator.h"
# include "util/coding.h"
# include "util/coding.h"
# include "util/dynamic_bloom.h"
# include "util/hash.h"
# include "util/hash.h"
# include "util/histogram.h"
# include "util/histogram.h"
# include "util/murmurhash.h"
# include "util/murmurhash.h"
@ -30,46 +32,36 @@
# include "util/stop_watch.h"
# include "util/stop_watch.h"
namespace std {
template < >
struct hash < rocksdb : : Slice > {
public :
std : : size_t operator ( ) ( rocksdb : : Slice const & s ) const {
return MurmurHash ( s . data ( ) , s . size ( ) , 397 ) ;
}
} ;
}
namespace rocksdb {
namespace rocksdb {
extern const uint64_t kPlainTableMagicNumber ;
extern const uint64_t kPlainTableMagicNumber ;
static uint32_t getBucketId ( Slice const & s , size_t prefix_len ,
uint32_t num_buckets ) {
static uint32_t GetSliceHash ( Slice const & s ) {
return MurmurHash ( s . data ( ) , prefix_len , 397 ) % num_buckets ;
return Hash ( s . data ( ) , s . size ( ) , 397 ) ;
}
static uint32_t getBucketIdFromHash ( uint32_t hash , uint32_t num_buckets ) {
return hash % num_buckets ;
}
}
PlainTableReader : : PlainTableReader ( const EnvOptions & storage_options ,
PlainTableReader : : PlainTableReader ( const EnvOptions & storage_options ,
uint64_t file_size , int user_key_size ,
uint64_t file_size , int bloom_bits_per_key ,
int key_prefix_len , int bloom_bits_per_key ,
double hash_table_ratio ,
double hash_table_ratio ,
const TableProperties & table_properties ) :
const TableProperties & table_properties ) :
hash_table_size_ ( 0 ) , soptions_ ( storage_options ) , file_size_ ( file_size ) ,
hash_table_size_ ( 0 ) , soptions_ ( storage_options ) , file_size_ ( file_size ) ,
user_key_size_ ( user_key_size ) , key_prefix_len_ ( key_prefix_len ) ,
hash_table_ratio_ ( hash_table_ratio ) ,
hash_table_ratio_ ( hash_table_ratio ) ,
filter_policy_ ( bloom_bits_per_key > 0 ?
bloom_bits_per_key_ ( bloom_bits_per_key ) ,
NewBloomFilterPolicy ( bloom_bits_per_key ) : nullptr ) ,
table_properties_ ( table_properties ) , data_start_offset_ ( 0 ) ,
table_properties_ ( table_properties ) ,
data_end_offset_ ( table_properties_ . data_size ) ,
data_start_offset_ ( 0 ) ,
user_key_len_ ( table_properties . fixed_key_len ) {
data_end_offset_ ( table_properties_ . data_size ) {
hash_table_ = nullptr ;
bloom_ = nullptr ;
sub_index_ = nullptr ;
}
}
PlainTableReader : : ~ PlainTableReader ( ) {
PlainTableReader : : ~ PlainTableReader ( ) {
if ( hash_table_ ! = nullptr ) {
delete [ ] hash_table_ ;
delete [ ] hash_table_ ;
delete [ ] sub_index_ ;
}
delete bloom_ ;
if ( filter_policy_ ! = nullptr ) {
delete filter_policy_ ;
}
}
}
Status PlainTableReader : : Open ( const Options & options ,
Status PlainTableReader : : Open ( const Options & options ,
@ -77,8 +69,6 @@ Status PlainTableReader::Open(const Options& options,
unique_ptr < RandomAccessFile > & & file ,
unique_ptr < RandomAccessFile > & & file ,
uint64_t file_size ,
uint64_t file_size ,
unique_ptr < TableReader > * table_reader ,
unique_ptr < TableReader > * table_reader ,
const int user_key_size ,
const int key_prefix_len ,
const int bloom_num_bits ,
const int bloom_num_bits ,
double hash_table_ratio ) {
double hash_table_ratio ) {
assert ( options . allow_mmap_reads ) ;
assert ( options . allow_mmap_reads ) ;
@ -103,8 +93,6 @@ Status PlainTableReader::Open(const Options& options,
std : : unique_ptr < PlainTableReader > new_reader ( new PlainTableReader (
std : : unique_ptr < PlainTableReader > new_reader ( new PlainTableReader (
soptions ,
soptions ,
file_size ,
file_size ,
user_key_size ,
key_prefix_len ,
bloom_num_bits ,
bloom_num_bits ,
hash_table_ratio ,
hash_table_ratio ,
table_properties
table_properties
@ -133,22 +121,69 @@ Iterator* PlainTableReader::NewIterator(const ReadOptions& options) {
return new PlainTableIterator ( this ) ;
return new PlainTableIterator ( this ) ;
}
}
Status PlainTableReader : : PopulateIndex ( ) {
struct PlainTableReader : : IndexRecord {
// Get mmapped memory to file_data_.
uint32_t hash ; // hash of the prefix
Status s = file_ - > Read ( 0 , file_size_ , & file_data_ , nullptr ) ;
uint32_t offset ; // offset of a row
if ( ! s . ok ( ) ) {
IndexRecord * next ;
return s ;
} ;
// Helper class to track all the index records
class PlainTableReader : : IndexRecordList {
public :
explicit IndexRecordList ( size_t num_records_per_group ) :
num_records_per_group_ ( num_records_per_group ) ,
current_group_ ( nullptr ) ,
num_records_in_current_group_ ( num_records_per_group ) {
}
~ IndexRecordList ( ) {
for ( size_t i = 0 ; i < groups_ . size ( ) ; i + + ) {
delete [ ] groups_ [ i ] ;
}
}
void AddRecord ( murmur_t hash , uint32_t offset ) {
if ( num_records_in_current_group_ = = num_records_per_group_ ) {
current_group_ = AllocateNewGroup ( ) ;
num_records_in_current_group_ = 0 ;
}
auto & new_record = current_group_ [ num_records_in_current_group_ ] ;
new_record . hash = hash ;
new_record . offset = offset ;
new_record . next = nullptr ;
num_records_in_current_group_ + + ;
}
size_t GetNumRecords ( ) {
return ( groups_ . size ( ) - 1 ) * num_records_per_group_
+ num_records_in_current_group_ ;
}
IndexRecord * At ( size_t index ) {
return & ( groups_ [ index / num_records_per_group_ ]
[ index % num_records_per_group_ ] ) ;
}
IndexRecord * AllocateNewGroup ( ) {
IndexRecord * result = new IndexRecord [ num_records_per_group_ ] ;
groups_ . push_back ( result ) ;
return result ;
}
}
version_ = DecodeFixed32 ( file_data_ . data ( ) ) ;
private :
version_ ^ = 0x80000000 ;
const size_t num_records_per_group_ ;
assert ( version_ = = 1 ) ;
IndexRecord * current_group_ ;
data_start_offset_ = 4 ;
// List of arrays allocated
std : : vector < IndexRecord * > groups_ ;
size_t num_records_in_current_group_ ;
} ;
int PlainTableReader : : PopulateIndexRecordList (
IndexRecordList & record_list ) {
Slice key_slice ;
Slice key_slice ;
Slice key_prefix_slice ;
Slice key_prefix_slice ;
Slice key_suffix_slice ;
Slice key_suffix_slice ;
Slice value_slice ;
Slice value_slice ;
Slice prev_key_prefix_slice ;
Slice prev_key_prefix_slice ;
uint32_t prev_key_prefix_hash = 0 ;
uint32_t pos = data_start_offset_ ;
uint32_t pos = data_start_offset_ ;
int key_index_within_prefix = 0 ;
int key_index_within_prefix = 0 ;
bool first = true ;
bool first = true ;
@ -156,72 +191,104 @@ Status PlainTableReader::PopulateIndex() {
HistogramImpl keys_per_prefix_hist ;
HistogramImpl keys_per_prefix_hist ;
// Need map to be ordered to make sure sub indexes generated
// Need map to be ordered to make sure sub indexes generated
// are in order.
// are in order.
std : : vector < std : : pair < Slice , std : : string > > prefix_index_pairs ;
std : : string current_prefix_index ;
int num_prefixes = 0 ;
while ( pos < data_end_offset_ ) {
while ( pos < data_end_offset_ ) {
uint32_t key_offset = pos ;
uint32_t key_offset = pos ;
status_ = Next ( pos , & key_slice , & value_slice , pos ) ;
status_ = Next ( pos , & key_slice , & value_slice , pos ) ;
key_prefix_slice = Slice ( key_slice . data ( ) , key_prefix_len_ ) ;
key_prefix_slice = GetPrefix ( key_slice ) ;
if ( first | | prev_key_prefix_slice ! = key_prefix_slice ) {
if ( first | | prev_key_prefix_slice ! = key_prefix_slice ) {
num_prefixes + + ;
if ( ! first ) {
if ( ! first ) {
keys_per_prefix_hist . Add ( key_index_within_prefix ) ;
keys_per_prefix_hist . Add ( key_index_within_prefix ) ;
prefix_index_pairs . push_back (
std : : make_pair < Slice , std : : string > (
std : : move ( prev_key_prefix_slice ) ,
std : : move ( current_prefix_index ) ) ) ;
current_prefix_index . clear ( ) ;
}
}
key_index_within_prefix = 0 ;
key_index_within_prefix = 0 ;
prev_key_prefix_slice = key_prefix_slice ;
prev_key_prefix_slice = key_prefix_slice ;
prev_key_prefix_hash = GetSliceHash ( key_prefix_slice ) ;
}
}
if ( key_index_within_prefix + + % 8 = = 0 ) {
if ( key_index_within_prefix + + % 16 = = 0 ) {
// Add an index key for every 8 keys
// Add an index key for every 16 keys
PutFixed32 ( & current_prefix_index , key_offset ) ;
record_list . AddRecord ( prev_key_prefix_hash , key_offset ) ;
}
}
first = false ;
first = false ;
}
}
prefix_index_pairs . push_back (
std : : make_pair < Slice , std : : string > ( std : : move ( prev_key_prefix_slice ) ,
std : : move ( current_prefix_index ) ) ) ;
keys_per_prefix_hist . Add ( key_index_within_prefix ) ;
keys_per_prefix_hist . Add ( key_index_within_prefix ) ;
Log ( options_ . info_log , " Number of Keys per prefix Histogram: %s " ,
keys_per_prefix_hist . ToString ( ) . c_str ( ) ) ;
return num_prefixes ;
}
void PlainTableReader : : Allocate ( int num_prefixes ) {
if ( hash_table_ ! = nullptr ) {
if ( hash_table_ ! = nullptr ) {
delete [ ] hash_table_ ;
delete [ ] hash_table_ ;
}
}
std : : vector < Slice > filter_entries ( 0 ) ; // for creating bloom filter;
if ( bloom_bits_per_key_ > 0 ) {
if ( filter_policy_ ! = nullptr ) {
bloom_ = new DynamicBloom ( num_prefixes * bloom_bits_per_key_ ) ;
filter_entries . reserve ( prefix_index_pairs . size ( ) ) ;
}
}
double hash_table_size_multipier =
double hash_table_size_multipier =
( hash_table_ratio_ > 1.0 ) ? 1.0 : 1.0 / hash_table_ratio_ ;
( hash_table_ratio_ > 1.0 ) ? 1.0 : 1.0 / hash_table_ratio_ ;
hash_table_size_ = prefix_ind ex_pair s . size ( ) * hash_table_size_multipier + 1 ;
hash_table_size_ = num_ prefixes * hash_table_size_multipier + 1 ;
hash_table_ = new uint32_t [ hash_table_size_ ] ;
hash_table_ = new uint32_t [ hash_table_size_ ] ;
std : : vector < std : : string > hash2map ( hash_table_size_ ) ;
}
size_t PlainTableReader : : BucketizeIndexesAndFillBloom (
IndexRecordList & record_list , int num_prefixes ,
std : : vector < IndexRecord * > & hash2offsets ,
std : : vector < uint32_t > & bucket_count ) {
size_t sub_index_size_needed = 0 ;
size_t sub_index_size_needed = 0 ;
for ( auto & p : prefix_index_pairs ) {
bool first = true ;
auto & sub_index = hash2map [ getBucketId ( p . first , key_prefix_len_ ,
uint32_t prev_hash = 0 ;
hash_table_size_ ) ] ;
size_t num_records = record_list . GetNumRecords ( ) ;
if ( sub_index . length ( ) > 0 | | p . second . length ( ) > kOffsetLen ) {
for ( size_t i = 0 ; i < num_records ; i + + ) {
if ( sub_index . length ( ) < = kOffsetLen ) {
IndexRecord * index_record = record_list . At ( i ) ;
sub_index_size_needed + = sub_index . length ( ) + 4 ;
uint32_t cur_hash = index_record - > hash ;
if ( first | | prev_hash ! = cur_hash ) {
prev_hash = cur_hash ;
first = false ;
if ( bloom_ ) {
bloom_ - > AddHash ( cur_hash ) ;
}
}
sub_index_size_needed + = p . second . length ( ) ;
}
}
sub_index . append ( p . second ) ;
uint32_t bucket = getBucketIdFromHash ( cur_hash , hash_table_size_ ) ;
if ( filter_policy_ ! = nullptr ) {
IndexRecord * prev_bucket_head = hash2offsets [ bucket ] ;
filter_entries . push_back ( p . first ) ;
index_record - > next = prev_bucket_head ;
hash2offsets [ bucket ] = index_record ;
if ( bucket_count [ bucket ] > 0 ) {
if ( bucket_count [ bucket ] = = 1 ) {
sub_index_size_needed + = kOffsetLen + 1 ;
}
if ( bucket_count [ bucket ] = = 127 ) {
// Need more than one byte for length
sub_index_size_needed + + ;
}
sub_index_size_needed + = kOffsetLen ;
}
}
bucket_count [ bucket ] + + ;
}
}
return sub_index_size_needed ;
}
sub_index_ . clear ( ) ;
void PlainTableReader : : FillIndexes ( size_t sub_index_size_needed ,
std : : vector < IndexRecord * > & hash2offsets ,
std : : vector < uint32_t > & bucket_count ) {
Log ( options_ . info_log , " Reserving %zu bytes for sub index " ,
Log ( options_ . info_log , " Reserving %zu bytes for sub index " ,
sub_index_size_needed ) ;
sub_index_size_needed ) ;
sub_index_ . reserve ( sub_index_size_needed ) ;
// 4 bytes buffer for variable length size
size_t buffer_size = 64 ;
size_t buffer_used = 0 ;
sub_index_size_needed + = buffer_size ;
sub_index_ = new char [ sub_index_size_needed ] ;
size_t sub_index_offset = 0 ;
char * prev_ptr ;
char * cur_ptr ;
uint32_t * sub_index_ptr ;
IndexRecord * record ;
for ( int i = 0 ; i < hash_table_size_ ; i + + ) {
for ( int i = 0 ; i < hash_table_size_ ; i + + ) {
uint32_t num_keys_for_bucket = hash2map [ i ] . length ( ) / kOffsetLen ;
uint32_t num_keys_for_bucket = bucket_count [ i ] ;
switch ( num_keys_for_bucket ) {
switch ( num_keys_for_bucket ) {
case 0 :
case 0 :
// No key for bucket
// No key for bucket
@ -229,58 +296,131 @@ Status PlainTableReader::PopulateIndex() {
break ;
break ;
case 1 :
case 1 :
// point directly to the file offset
// point directly to the file offset
hash_table_ [ i ] = DecodeFixed32 ( hash2map [ i ] . data ( ) ) ;
hash_table_ [ i ] = hash2offsets [ i ] - > offset ;
break ;
break ;
default :
default :
// point to index block
// point to second level indexes.
hash_table_ [ i ] = sub_index_ . length ( ) | kSubIndexMask ;
hash_table_ [ i ] = sub_index_offset | kSubIndexMask ;
PutFixed32 ( & sub_index_ , num_keys_for_bucket ) ;
prev_ptr = sub_index_ + sub_index_offset ;
sub_index_ . append ( hash2map [ i ] ) ;
cur_ptr = EncodeVarint32 ( prev_ptr , num_keys_for_bucket ) ;
sub_index_offset + = cur_ptr - prev_ptr ;
if ( cur_ptr - prev_ptr > 2
| | ( cur_ptr - prev_ptr = = 2 & & num_keys_for_bucket < = 127 ) ) {
// Need to resize sub_index. Exponentially grow buffer.
buffer_used + = cur_ptr - prev_ptr - 1 ;
if ( buffer_used + 4 > buffer_size ) {
Log ( options_ . info_log , " Recalculate suffix_map length to %zu " ,
sub_index_size_needed ) ;
sub_index_size_needed + = buffer_size ;
buffer_size * = 2 ;
char * new_sub_index = new char [ sub_index_size_needed ] ;
memcpy ( new_sub_index , sub_index_ , sub_index_offset ) ;
delete [ ] sub_index_ ;
sub_index_ = new_sub_index ;
}
}
sub_index_ptr = ( uint32_t * ) ( sub_index_ + sub_index_offset ) ;
record = hash2offsets [ i ] ;
int j ;
for ( j = num_keys_for_bucket - 1 ;
j > = 0 & & record ; j - - , record = record - > next ) {
sub_index_ptr [ j ] = record - > offset ;
}
assert ( j = = - 1 & & record = = nullptr ) ;
sub_index_offset + = kOffsetLen * num_keys_for_bucket ;
break ;
}
}
}
}
if ( filter_policy_ ! = nullptr ) {
filter_str_ . clear ( ) ;
filter_policy_ - > CreateFilter ( & filter_entries [ 0 ] , filter_entries . size ( ) ,
& filter_str_ ) ;
filter_slice_ = Slice ( filter_str_ . data ( ) , filter_str_ . size ( ) ) ;
}
Log ( options_ . info_log , " hash table size: %d, suffix_map length %zu " ,
Log ( options_ . info_log , " hash table size: %d, suffix_map length %zu " ,
hash_table_size_ , sub_index_ . length ( ) ) ;
hash_table_size_ , sub_index_size_needed ) ;
Log ( options_ . info_log , " Number of Keys per prefix Histogram: %s " ,
}
keys_per_prefix_hist . ToString ( ) . c_str ( ) ) ;
// PopulateIndex() builds index of keys.
// hash_table_ contains buckets size of hash_table_size_, each is a 32-bit
// integer. The lower 31 bits contain an offset value (explained below) and
// the first bit of the integer indicates type of the offset:
//
// 0 indicates that the bucket contains only one prefix (no conflict when
// hashing this prefix), whose first row starts from this offset of the file.
// 1 indicates that the bucket contains more than one prefixes, or there
// are too many rows for one prefix so we need a binary search for it. In
// this case, the offset indicates the offset of sub_index_ holding the
// binary search indexes of keys for those rows. Those binary search indexes
// are organized in this way:
//
// The first 4 bytes, indicates how many indexes (N) are stored after it. After
// it, there are N 32-bit integers, each points of an offset of the file, which
// points to starting of a row. Those offsets need to be guaranteed to be in
// ascending order so the keys they are pointing to are also in ascending order
// to make sure we can use them to do binary searches.
Status PlainTableReader : : PopulateIndex ( ) {
// Get mmapped memory to file_data_.
Status s = file_ - > Read ( 0 , file_size_ , & file_data_ , nullptr ) ;
if ( ! s . ok ( ) ) {
return s ;
}
IndexRecordList record_list ( 256 ) ;
// First, read the whole file, for every 16 rows for a prefix (starting from
// the first one), generate a record of (hash, offset) and append it to
// IndexRecordList, which is a data structure created to store them.
int num_prefixes = PopulateIndexRecordList ( record_list ) ;
// Calculated hash table and bloom filter size and allocate memory for indexes
// and bloom filter based on the number of prefixes.
Allocate ( num_prefixes ) ;
// Bucketize all the index records to a temp data structure, in which for
// each bucket, we generate a linked list of IndexRecord, in reversed order.
std : : vector < IndexRecord * > hash2offsets ( hash_table_size_ , nullptr ) ;
std : : vector < uint32_t > bucket_count ( hash_table_size_ , 0 ) ;
size_t sub_index_size_needed = BucketizeIndexesAndFillBloom ( record_list ,
num_prefixes ,
hash2offsets ,
bucket_count ) ;
// From the temp data structure, populate indexes.
FillIndexes ( sub_index_size_needed , hash2offsets , bucket_count ) ;
return Status : : OK ( ) ;
return Status : : OK ( ) ;
}
}
uint32_t PlainTableReader : : GetOffset ( const Slice & target ,
Status PlainTableReader : : GetOffset ( const Slice & target , const Slice & prefix ,
bool & prefix_matched ) {
uint32_t prefix_hash , bool & prefix_matched ,
uint32_t & ret_offset ) {
prefix_matched = false ;
prefix_matched = false ;
int bucket = getBucketId ( target , key_prefix_len_ , hash_table_size_ ) ;
int bucket = getBucketIdFromHash ( prefix_hash , hash_table_size_ ) ;
uint32_t bucket_value = hash_table_ [ bucket ] ;
uint32_t bucket_value = hash_table_ [ bucket ] ;
if ( bucket_value = = data_end_offset_ ) {
if ( bucket_value = = data_end_offset_ ) {
return data_end_offset_ ;
ret_offset = data_end_offset_ ;
return Status : : OK ( ) ;
} else if ( ( bucket_value & kSubIndexMask ) = = 0 ) {
} else if ( ( bucket_value & kSubIndexMask ) = = 0 ) {
// point directly to the file
// point directly to the file
return bucket_value ;
ret_offset = bucket_value ;
return Status : : OK ( ) ;
}
}
// point to sub-index, need to do a binary search
// point to sub-index, need to do a binary search
uint32_t low = 0 ;
uint32_t low = 0 ;
uint64_t prefix_index_offset = bucket_value ^ kSubIndexMask ;
uint64_t prefix_index_offset = bucket_value ^ kSubIndexMask ;
uint32_t upper_bound = DecodeFixed32 ( sub_index_ . data ( ) + prefix_index_offset ) ;
const char * index_ptr = sub_index_ + prefix_index_offset ;
uint32_t upper_bound ;
const uint32_t * base_ptr = ( const uint32_t * ) GetVarint32Ptr ( index_ptr ,
index_ptr + 4 ,
& upper_bound ) ;
uint32_t high = upper_bound ;
uint32_t high = upper_bound ;
uint64_t base_offset = prefix_index_offset + 4 ;
Slice mid_key ;
Slice mid_key ;
// The key is between [low, high). Do a binary search between it.
// The key is between [low, high). Do a binary search between it.
while ( high - low > 1 ) {
while ( high - low > 1 ) {
uint32_t mid = ( high + low ) / 2 ;
uint32_t mid = ( high + low ) / 2 ;
const char * index_offset = sub_index_ . data ( ) + base_offset
uint32_t file_offset = base_ptr [ mid ] ;
+ kOffsetLen * mid ;
size_t tmp ;
uint32_t file_offset = DecodeFixed32 ( index_offset ) ;
Status s = ReadKey ( file_data_ . data ( ) + file_offset , & mid_key , tmp ) ;
mid_key = Slice ( file_data_ . data ( ) + file_offset , GetInternalKeyLength ( ) ) ;
if ( ! s . ok ( ) ) {
return s ;
}
int cmp_result = options_ . comparator - > Compare ( target , mid_key ) ;
int cmp_result = options_ . comparator - > Compare ( target , mid_key ) ;
if ( cmp_result > 0 ) {
if ( cmp_result > 0 ) {
low = mid ;
low = mid ;
@ -289,38 +429,61 @@ uint32_t PlainTableReader::GetOffset(const Slice& target,
// Happen to have found the exact key or target is smaller than the
// Happen to have found the exact key or target is smaller than the
// first key after base_offset.
// first key after base_offset.
prefix_matched = true ;
prefix_matched = true ;
return file_offset ;
ret_offset = file_offset ;
return Status : : OK ( ) ;
} else {
} else {
high = mid ;
high = mid ;
}
}
}
}
}
}
// Both of the key at the position low or low+1 could share the same
// The key is between low and low+1 (if exists). Both of them can have the
// prefix as target. We need to rule out one of them to avoid to go
// correct prefix. Need to rule out at least one, to avoid to miss the
// to the wrong prefix.
// correct one.
Slice low_key ;
uint32_t low_key_offset = DecodeFixed32 (
size_t tmp ;
sub_index_ . data ( ) + base_offset + kOffsetLen * low ) ;
uint32_t low_key_offset = base_ptr [ low ] ;
if ( low + 1 < upper_bound ) {
Status s = ReadKey ( file_data_ . data ( ) + low_key_offset , & low_key , tmp ) ;
if ( Slice ( file_data_ . data ( ) + low_key_offset , key_prefix_len_ )
if ( GetPrefix ( low_key ) = = prefix ) {
= = Slice ( target . data ( ) , key_prefix_len_ ) ) {
prefix_matched = true ;
prefix_matched = true ;
ret_offset = low_key_offset ;
} else {
} else if ( low + 1 < upper_bound ) {
prefix_matched = false ;
// There is possible a next prefix, return it
return DecodeFixed32 (
sub_index_ . data ( ) + base_offset + kOffsetLen * ( low + 1 ) ) ;
}
} else {
prefix_matched = false ;
prefix_matched = false ;
ret_offset = base_ptr [ low + 1 ] ;
} else {
// target is larger than a key of the last prefix in this bucket
// but with a different prefix. Key does not exist.
ret_offset = data_end_offset_ ;
}
}
return low_key_offset ;
return Status : : OK ( ) ;
}
}
bool PlainTableReader : : MayHavePrefix ( const Slice & target_prefix ) {
bool PlainTableReader : : MayHavePrefix ( uint32_t hash ) {
return filter_policy_ = = nullptr
return bloom_ = = nullptr | | bloom_ - > MayContainHash ( hash ) ;
| | filter_policy_ - > KeyMayMatch ( target_prefix , filter_slice_ ) ;
}
}
Status PlainTableReader : : ReadKey ( const char * row_ptr , Slice * key ,
size_t & bytes_read ) {
const char * key_ptr ;
bytes_read = 0 ;
size_t internal_key_size ;
if ( IsFixedLength ( ) ) {
internal_key_size = GetFixedInternalKeyLength ( ) ;
key_ptr = row_ptr ;
} else {
uint32_t key_size ;
key_ptr = GetVarint32Ptr ( row_ptr , file_data_ . data ( ) + data_end_offset_ ,
& key_size ) ;
internal_key_size = ( size_t ) key_size ;
bytes_read = key_ptr - row_ptr ;
}
if ( row_ptr + internal_key_size > = file_data_ . data ( ) + data_end_offset_ ) {
return Status : : Corruption ( " Unable to read the next key " ) ;
}
* key = Slice ( key_ptr , internal_key_size ) ;
bytes_read + = internal_key_size ;
return Status : : OK ( ) ;
}
Status PlainTableReader : : Next ( uint32_t offset , Slice * key , Slice * value ,
Status PlainTableReader : : Next ( uint32_t offset , Slice * key , Slice * value ,
uint32_t & next_offset ) {
uint32_t & next_offset ) {
@ -333,22 +496,17 @@ Status PlainTableReader::Next(uint32_t offset, Slice* key, Slice* value,
return Status : : Corruption ( " Offset is out of file size " ) ;
return Status : : Corruption ( " Offset is out of file size " ) ;
}
}
int internal_key_size = GetInternalKeyLength ( ) ;
const char * row_ptr = file_data_ . data ( ) + offset ;
if ( offset + internal_key_size > = data_end_offset_ ) {
size_t bytes_for_key ;
return Status : : Corruption ( " Un able to read the next key " ) ;
Status s = ReadKey ( row_ptr , key , bytes_for_key ) ;
}
const char * key_ptr = file_data_ . data ( ) + offset ;
* key = Slice ( key_ptr , internal_key_size ) ;
uint32_t value_size ;
uint32_t value_size ;
const char * value_ptr = GetVarint32Ptr ( key_ptr + internal_key_size ,
const char * value_ptr = GetVarint32Ptr ( row_ptr + bytes_for_key ,
file_data_ . data ( ) + data_end_offset_ ,
file_data_ . data ( ) + data_end_offset_ ,
& value_size ) ;
& value_size ) ;
if ( value_ptr = = nullptr ) {
if ( value_ptr = = nullptr ) {
return Status : : Corruption ( " Error reading value length. " ) ;
return Status : : Corruption ( " Error reading value length. " ) ;
}
}
next_offset = offset + ( value_ptr - key _ptr) + value_size ;
next_offset = offset + ( value_ptr - row _ptr) + value_size ;
if ( next_offset > data_end_offset_ ) {
if ( next_offset > data_end_offset_ ) {
return Status : : Corruption ( " Reach end of file when reading value " ) ;
return Status : : Corruption ( " Reach end of file when reading value " ) ;
}
}
@ -362,13 +520,17 @@ Status PlainTableReader::Get(
bool ( * saver ) ( void * , const Slice & , const Slice & , bool ) ,
bool ( * saver ) ( void * , const Slice & , const Slice & , bool ) ,
void ( * mark_key_may_exist ) ( void * ) ) {
void ( * mark_key_may_exist ) ( void * ) ) {
// Check bloom filter first.
// Check bloom filter first.
if ( ! MayHavePrefix ( Slice ( target . data ( ) , key_prefix_len_ ) ) ) {
Slice prefix_slice = GetPrefix ( target ) ;
uint32_t prefix_hash = GetSliceHash ( prefix_slice ) ;
if ( ! MayHavePrefix ( prefix_hash ) ) {
return Status : : OK ( ) ;
return Status : : OK ( ) ;
}
}
uint32_t offset ;
uint32_t offset ;
bool prefix_match ;
bool prefix_match ;
offset = GetOffset ( target , prefix_match ) ;
Status s = GetOffset ( target , prefix_slice , prefix_hash , prefix_match , offset ) ;
if ( ! s . ok ( ) ) {
return s ;
}
Slice found_key ;
Slice found_key ;
Slice found_value ;
Slice found_value ;
while ( offset < data_end_offset_ ) {
while ( offset < data_end_offset_ ) {
@ -379,8 +541,8 @@ Status PlainTableReader::Get(
if ( ! prefix_match ) {
if ( ! prefix_match ) {
// Need to verify prefix for the first key found if it is not yet
// Need to verify prefix for the first key found if it is not yet
// checked.
// checked.
if ( ! target . starts_with ( Slice ( found_key . data ( ) , key_prefix_len_ ) ) ) {
if ( GetPrefix ( found_key ) ! = prefix_slice ) {
break ;
return Status : : OK ( ) ;
}
}
prefix_match = true ;
prefix_match = true ;
}
}
@ -403,7 +565,7 @@ uint64_t PlainTableReader::ApproximateOffsetOf(const Slice& key) {
PlainTableIterator : : PlainTableIterator ( PlainTableReader * table ) :
PlainTableIterator : : PlainTableIterator ( PlainTableReader * table ) :
table_ ( table ) {
table_ ( table ) {
SeekToFirst ( ) ;
next_offset_ = offset_ = table_ - > data_end_offset_ ;
}
}
PlainTableIterator : : ~ PlainTableIterator ( ) {
PlainTableIterator : : ~ PlainTableIterator ( ) {
@ -416,7 +578,11 @@ bool PlainTableIterator::Valid() const {
void PlainTableIterator : : SeekToFirst ( ) {
void PlainTableIterator : : SeekToFirst ( ) {
next_offset_ = table_ - > data_start_offset_ ;
next_offset_ = table_ - > data_start_offset_ ;
Next ( ) ;
if ( next_offset_ > = table_ - > data_end_offset_ ) {
next_offset_ = offset_ = table_ - > data_end_offset_ ;
} else {
Next ( ) ;
}
}
}
void PlainTableIterator : : SeekToLast ( ) {
void PlainTableIterator : : SeekToLast ( ) {
@ -424,18 +590,25 @@ void PlainTableIterator::SeekToLast() {
}
}
void PlainTableIterator : : Seek ( const Slice & target ) {
void PlainTableIterator : : Seek ( const Slice & target ) {
if ( ! table_ - > MayHavePrefix ( Slice ( target . data ( ) , table_ - > key_prefix_len_ ) ) ) {
Slice prefix_slice = table_ - > GetPrefix ( target ) ;
uint32_t prefix_hash = GetSliceHash ( prefix_slice ) ;
if ( ! table_ - > MayHavePrefix ( prefix_hash ) ) {
offset_ = next_offset_ = table_ - > data_end_offset_ ;
offset_ = next_offset_ = table_ - > data_end_offset_ ;
return ;
return ;
}
}
bool prefix_match ;
bool prefix_match ;
next_offset_ = table_ - > GetOffset ( target , prefix_match ) ;
status_ = table_ - > GetOffset ( target , prefix_slice , prefix_hash , prefix_match ,
next_offset_ ) ;
if ( ! status_ . ok ( ) ) {
offset_ = next_offset_ = table_ - > data_end_offset_ ;
return ;
}
if ( next_offset_ < table_ - > data_end_offset_ ) {
if ( next_offset_ < table_ - > data_end_offset_ ) {
for ( Next ( ) ; status_ . ok ( ) & & Valid ( ) ; Next ( ) ) {
for ( Next ( ) ; status_ . ok ( ) & & Valid ( ) ; Next ( ) ) {
if ( ! prefix_match ) {
if ( ! prefix_match ) {
// Need to verify the first key's prefix
// Need to verify the first key's prefix
if ( ! target . starts_with ( Slice ( key ( ) . data ( ) , table_ - > key_prefix_len_ ) ) ) {
if ( table_ - > GetPrefix ( key ( ) ) ! = prefix_slice ) {
offset_ = next_offset_ = table_ - > data_end_offset_ ;
offset_ = next_offset_ = table_ - > data_end_offset_ ;
break ;
break ;
}
}