@ -35,33 +35,69 @@ class CacheTest {
}
}
static const int kCacheSize = 1000 ;
static const int kCacheSize = 1000 ;
static const int kNumShardBits = 4 ;
static const int kRemoveScanCountLimit = 16 ;
static const int kCacheSize2 = 100 ;
static const int kNumShardBits2 = 2 ;
static const int kRemoveScanCountLimit2 = 200 ;
std : : vector < int > deleted_keys_ ;
std : : vector < int > deleted_keys_ ;
std : : vector < int > deleted_values_ ;
std : : vector < int > deleted_values_ ;
shared_ptr < Cache > cache_ ;
shared_ptr < Cache > cache_ ;
shared_ptr < Cache > cache2_ ;
CacheTest ( ) : cache_ ( NewLRUCache ( kCacheSize ) ) {
CacheTest ( ) :
cache_ ( NewLRUCache ( kCacheSize , kNumShardBits , kRemoveScanCountLimit ) ) ,
cache2_ ( NewLRUCache ( kCacheSize2 , kNumShardBits2 ,
kRemoveScanCountLimit2 ) ) {
current_ = this ;
current_ = this ;
}
}
~ CacheTest ( ) {
~ CacheTest ( ) {
}
}
int Lookup ( int key ) {
int Lookup ( shared_ptr < Cache > cache , int key ) {
Cache : : Handle * handle = cache_ - > Lookup ( EncodeKey ( key ) ) ;
Cache : : Handle * handle = cache - > Lookup ( EncodeKey ( key ) ) ;
const int r = ( handle = = nullptr ) ? - 1 : DecodeValue ( cache_ - > Value ( handle ) ) ;
const int r = ( handle = = nullptr ) ? - 1 : DecodeValue ( cache - > Value ( handle ) ) ;
if ( handle ! = nullptr ) {
if ( handle ! = nullptr ) {
cache_ - > Release ( handle ) ;
cache - > Release ( handle ) ;
}
}
return r ;
return r ;
}
}
void Insert ( shared_ptr < Cache > cache , int key , int value , int charge = 1 ) {
cache - > Release ( cache - > Insert ( EncodeKey ( key ) , EncodeValue ( value ) , charge ,
& CacheTest : : Deleter ) ) ;
}
void Erase ( shared_ptr < Cache > cache , int key ) {
cache - > Erase ( EncodeKey ( key ) ) ;
}
int Lookup ( int key ) {
return Lookup ( cache_ , key ) ;
}
void Insert ( int key , int value , int charge = 1 ) {
void Insert ( int key , int value , int charge = 1 ) {
cache_ - > Release ( cache_ - > Insert ( EncodeKey ( key ) , EncodeValue ( value ) , charge ,
Insert ( cache_ , key , value , charge ) ;
& CacheTest : : Deleter ) ) ;
}
}
void Erase ( int key ) {
void Erase ( int key ) {
cache_ - > Erase ( EncodeKey ( key ) ) ;
Erase ( cache_ , key ) ;
}
int Lookup2 ( int key ) {
return Lookup ( cache2_ , key ) ;
}
void Insert2 ( int key , int value , int charge = 1 ) {
Insert ( cache2_ , key , value , charge ) ;
}
void Erase2 ( int key ) {
Erase ( cache2_ , key ) ;
}
}
} ;
} ;
CacheTest * CacheTest : : current_ ;
CacheTest * CacheTest : : current_ ;
@ -147,6 +183,124 @@ TEST(CacheTest, EvictionPolicy) {
ASSERT_EQ ( - 1 , Lookup ( 200 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 200 ) ) ;
}
}
TEST ( CacheTest , EvictionPolicyRef ) {
Insert ( 100 , 101 ) ;
Insert ( 101 , 102 ) ;
Insert ( 102 , 103 ) ;
Insert ( 103 , 104 ) ;
Insert ( 200 , 101 ) ;
Insert ( 201 , 102 ) ;
Insert ( 202 , 103 ) ;
Insert ( 203 , 104 ) ;
Cache : : Handle * h201 = cache_ - > Lookup ( EncodeKey ( 200 ) ) ;
Cache : : Handle * h202 = cache_ - > Lookup ( EncodeKey ( 201 ) ) ;
Cache : : Handle * h203 = cache_ - > Lookup ( EncodeKey ( 202 ) ) ;
Cache : : Handle * h204 = cache_ - > Lookup ( EncodeKey ( 203 ) ) ;
Insert ( 300 , 101 ) ;
Insert ( 301 , 102 ) ;
Insert ( 302 , 103 ) ;
Insert ( 303 , 104 ) ;
// Insert entries much more than Cache capacity
for ( int i = 0 ; i < kCacheSize + 100 ; i + + ) {
Insert ( 1000 + i , 2000 + i ) ;
}
// Check whether the entries inserted in the beginning
// are evicted. Ones without extra ref are evicted and
// those with are not.
ASSERT_EQ ( - 1 , Lookup ( 100 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 101 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 102 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 103 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 300 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 301 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 302 ) ) ;
ASSERT_EQ ( - 1 , Lookup ( 303 ) ) ;
ASSERT_EQ ( 101 , Lookup ( 200 ) ) ;
ASSERT_EQ ( 102 , Lookup ( 201 ) ) ;
ASSERT_EQ ( 103 , Lookup ( 202 ) ) ;
ASSERT_EQ ( 104 , Lookup ( 203 ) ) ;
// Cleaning up all the handles
cache_ - > Release ( h201 ) ;
cache_ - > Release ( h202 ) ;
cache_ - > Release ( h203 ) ;
cache_ - > Release ( h204 ) ;
}
TEST ( CacheTest , EvictionPolicyRef2 ) {
std : : vector < Cache : : Handle * > handles ;
Insert ( 100 , 101 ) ;
// Insert entries much more than Cache capacity
for ( int i = 0 ; i < kCacheSize + 100 ; i + + ) {
Insert ( 1000 + i , 2000 + i ) ;
if ( i < kCacheSize ) {
handles . push_back ( cache_ - > Lookup ( EncodeKey ( 1000 + i ) ) ) ;
}
}
// Make sure referenced keys are also possible to be deleted
// if there are not sufficient non-referenced keys
for ( int i = 0 ; i < 5 ; i + + ) {
ASSERT_EQ ( - 1 , Lookup ( 1000 + i ) ) ;
}
for ( int i = kCacheSize ; i < kCacheSize + 100 ; i + + ) {
ASSERT_EQ ( 2000 + i , Lookup ( 1000 + i ) ) ;
}
ASSERT_EQ ( - 1 , Lookup ( 100 ) ) ;
// Cleaning up all the handles
while ( handles . size ( ) > 0 ) {
cache_ - > Release ( handles . back ( ) ) ;
handles . pop_back ( ) ;
}
}
TEST ( CacheTest , EvictionPolicyRefLargeScanLimit ) {
std : : vector < Cache : : Handle * > handles2 ;
// Cache2 has a cache RemoveScanCountLimit higher than cache size
// so it would trigger a boundary condition.
// Populate the cache with 10 more keys than its size.
// Reference all keys except one close to the end.
for ( int i = 0 ; i < kCacheSize2 + 10 ; i + + ) {
Insert2 ( 1000 + i , 2000 + i ) ;
if ( i ! = kCacheSize2 ) {
handles2 . push_back ( cache2_ - > Lookup ( EncodeKey ( 1000 + i ) ) ) ;
}
}
// Make sure referenced keys are also possible to be deleted
// if there are not sufficient non-referenced keys
for ( int i = 0 ; i < 3 ; i + + ) {
ASSERT_EQ ( - 1 , Lookup2 ( 1000 + i ) ) ;
}
// The non-referenced value is deleted even if it's accessed
// recently.
ASSERT_EQ ( - 1 , Lookup2 ( 1000 + kCacheSize2 ) ) ;
// Other values recently accessed are not deleted since they
// are referenced.
for ( int i = kCacheSize2 - 10 ; i < kCacheSize2 + 10 ; i + + ) {
if ( i ! = kCacheSize2 ) {
ASSERT_EQ ( 2000 + i , Lookup2 ( 1000 + i ) ) ;
}
}
// Cleaning up all the handles
while ( handles2 . size ( ) > 0 ) {
cache2_ - > Release ( handles2 . back ( ) ) ;
handles2 . pop_back ( ) ;
}
}
TEST ( CacheTest , HeavyEntries ) {
TEST ( CacheTest , HeavyEntries ) {
// Add a bunch of light and heavy entries and then count the combined
// Add a bunch of light and heavy entries and then count the combined
// size of items still in the cache, which must be approximately the
// size of items still in the cache, which must be approximately the