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#include <string.h>
#include <stdio.h>
#include <math.h>
#include "hashtable.h"
HashTable::HashTable( HashFunction *hNewFunc, unsigned long int nInitSize, bool bAllowDupes )
{
hFunc = hNewFunc;
nTableSize = nextPrime( nInitSize );
aTable = new HashNode[nTableSize];
//for( int j = 0; j < nTableSize; j++ ) if( aTable[j].id || aTable[j].data || aTable[j].bDeleted ) printf("Unclean entry\n");
nSize = 0;
nFilled = 0;
this->bAllowDupes = bAllowDupes;
}
HashTable::~HashTable()
{
delete[] aTable;
delete hFunc;
}
void HashTable::set( int j, const void *newID, const void *newData )
{
if( newData == NULL )
{
printf("Inserting NULL data is indestinguishable from uninserted data!\n");
}
aTable[j].id = newID;
aTable[j].data = newData;
}
void HashTable::clear()
{
memset( aTable, 0, sizeof(HashNode) * nTableSize );
}
bool HashTable::isFilled( int j )
{
return (aTable[j].id != NULL)||(aTable[j].bDeleted);
}
bool HashTable::reHash( unsigned long int nNewSize )
{
HashNode *aOldTable = aTable;
unsigned long int oldSize = nTableSize;
// If the table can still be used if we just get rid of deleted items, don't
// change the size of the table, otherwise, go ahead and use the number
// passed in.
if( nSize > nTableSize>>1 )
{
nTableSize = nextPrime( nNewSize );
}
aTable = newTable( nTableSize );
//for( int j = 0; j < nTableSize; j++ ) if( aTable[j].id || aTable[j].data || aTable[j].bDeleted ) printf("Unclean entry\n");
nSize = 0;
nFilled = 0;
for( unsigned long int j = 0; j < oldSize; j++ )
{
if( aOldTable[j].id != NULL && aOldTable[j].bDeleted == false )
{
insert( aOldTable[j].id, aOldTable[j].data );
}
}
delete[] aOldTable;
}
unsigned long int HashTable::probe( unsigned long int nStart, const void *id )
{
int nHash = nStart;
nStart = nStart%nTableSize;
if( bAllowDupes == true )
{
for(
unsigned long int j=0;
isFilled( nStart ) && j < 32;
nStart = (nStart+(1<<j))%nTableSize, j++
);
/**
* This is an ugly little hack. If the hash table is too full in allow-
* dups mode we have to fall back on a linear search, otherwise you can
* only get up to 32 entries with the same name.
*/
if( isFilled( nStart ) )
{
int nOldStart = nStart;
for(
nStart++;
isFilled( nStart ) && nStart != nOldStart;
nStart = (nStart+1)%nTableSize
);
}
}
else
{
for(
unsigned long int j=0;
isFilled( nStart ) && j < 32;
nStart = (nStart+(1<<j))%nTableSize, j++
)
{
if( isFilled( nStart ) )
{
if( hFunc->cmpIDs( aTable[nStart].id, id ) == true &&
aTable[nStart].bDeleted == false )
{
return nStart;
}
}
}
}
// This is our insurance, if the table is full, then go ahead and rehash,
// then try again.
if( isFilled( nStart ) )
{
reHash( getCapacity()*2 );
return probe( nHash, id );
}
return nStart;
}
HashTable::HashNode *HashTable::newTable( unsigned long int nNewSize )
{
return new HashNode[nNewSize];
}
#ifdef HASH_DEBUG_VIS
void HashTable::printDebugLine( const char *exData )
{
char *buf = new char[getCapacity()+3];
int j;
buf[0] = '[';
for( j = 0; j < getCapacity(); j++ )
{
buf[j+1] = (aTable[j].bDeleted)?('X'):((isFilled( j ))?('#'):('-'));
}
buf[j+1] = ']';
buf[j+2] = '\0';
printf("%s %s\n", buf, exData );
delete[] buf;
}
#endif
bool HashTable::insert( const void *id, const void *data )
{
unsigned long int nPos = probe( hFunc->hash( id ), id )%nTableSize;
if( bAllowDupes == true )
{
if( aTable[nPos].id == NULL && aTable[nPos].bDeleted == false )
{
set( nPos, id, data );
#ifdef HASH_DEBUG_VIS
printDebugLine( (const char *)id );
#endif
nSize++;
nFilled++;
return true;
}
else
{
return false;
}
}
else
{
if( aTable[nPos].id == NULL && aTable[nPos].bDeleted == false )
{
set( nPos, id, data );
#ifdef HASH_DEBUG_VIS
printDebugLine( (const char *)id );
#endif
nSize++;
nFilled++;
return true;
}
else if( hFunc->cmpIDs( aTable[nPos].id, id ) == true )
{
set( nPos, id, data );
#ifdef HASH_DEBUG_VIS
printDebugLine( (const char *)id );
#endif
return true;
}
else
{
return false;
}
}
}
const void *HashTable::get( const void *id, unsigned long int nSkip )
{
unsigned long int nPos = hFunc->hash( id )%nTableSize;
for( unsigned long int j=0; j < 32; nPos = (nPos+(1<<j))%nTableSize, j++ )
{
if( !isFilled( nPos ) ) return NULL;
if( aTable[nPos].bDeleted == false )
{
if( hFunc->cmpIDs( id, aTable[nPos].id ) )
{
if( nSkip == 0 )
{
return aTable[nPos].data;
}
else
{
nSkip--;
}
}
}
}
if( bAllowDupes )
{
int nOldPos = nPos;
for( nPos++; nPos != nOldPos; nPos=(nPos+1)%nTableSize )
{
if( !isFilled( nPos ) ) return NULL;
if( aTable[nPos].bDeleted == false )
{
if( hFunc->cmpIDs( id, aTable[nPos].id ) )
{
if( nSkip == 0 )
{
return aTable[nPos].data;
}
else
{
nSkip--;
}
}
}
}
}
return NULL;
}
const void *HashTable::getKey( const void *id, unsigned long int nSkip )
{
unsigned long int nPos = hFunc->hash( id )%nTableSize;
for( unsigned long int j=0; j < 32; nPos = (nPos+(1<<j))%nTableSize, j++ )
{
if( !isFilled( nPos ) ) return NULL;
if( aTable[nPos].bDeleted == false )
{
if( hFunc->cmpIDs( id, aTable[nPos].id ) )
{
if( nSkip == 0 )
{
return aTable[nPos].id;
}
else
{
nSkip--;
}
}
}
}
if( bAllowDupes )
{
int nOldPos = nPos;
for( nPos++; nPos != nOldPos; nPos=(nPos+1)%nTableSize )
{
if( !isFilled( nPos ) ) return NULL;
if( aTable[nPos].bDeleted == false )
{
if( hFunc->cmpIDs( id, aTable[nPos].id ) )
{
if( nSkip == 0 )
{
return aTable[nPos].id;
}
else
{
nSkip--;
}
}
}
}
}
return NULL;
}
void *HashTable::getFirstItemPos()
{
HashPos *pos = new HashPos;
return pos;
}
const void *HashTable::getItemData( void *xPos )
{
return aTable[((HashPos *)xPos)->nPos].data;
}
const void *HashTable::getItemID( void *xPos )
{
return aTable[((HashPos *)xPos)->nPos].id;
}
void *HashTable::getNextItemPos( void *xPos )
{
HashPos *pos = (HashPos *)xPos;
if( pos->bStarted == false )
{
pos->bStarted = true;
pos->nPos = 0;
}
else
{
pos->nPos++;
}
if( pos->nPos < nTableSize )
{
for( ; pos->nPos < nTableSize; pos->nPos++ )
{
if( isFilled( pos->nPos ) &&
aTable[pos->nPos].bDeleted == false )
{
return xPos;
}
}
}
delete pos;
return NULL;
}
// Big-O sqrt(n)
// Change this to be erethpothynies table with a storage
// lookup later on.
bool HashTable::isPrime (int num)
{
if (num == 2) // the only even prime
return true;
else if (num % 2 == 0) // other even numbers are composite
return false;
else
{
//bool prime = true;
int divisor = 3;
int upperLimit = static_cast<int>(sqrt(num) + 1);
while (divisor <= upperLimit)
{
if (num % divisor == 0)
return false;
// prime = false;
divisor +=2;
}
return true;
}
}
// Big-O n^(3/2)
int HashTable::nextPrime( int base )
{
int nPrime;
for( nPrime = base; isPrime( nPrime ) == false; nPrime++ );
return nPrime;
}
unsigned long int HashTable::getCapacity()
{
return nTableSize;
}
unsigned long int HashTable::getSize()
{
return nSize;
}
double HashTable::getLoad()
{
return (double)(nFilled)/(double)(nTableSize);
}
const void *HashTable::operator[](const void *id)
{
return get( id );
}
bool HashTable::del( const void *id, int nSkip )
{
unsigned long int nPos = hFunc->hash( id )%nTableSize;
for( unsigned long int j=0; j < 32; nPos = (nPos+(1<<j))%nTableSize, j++ )
{
if( !isFilled( nPos ) ) return false;
//printf("0x%08X \"%s\" == 0x%08X \"%s\" (%d)\n", id, id, aTable[nPos].id, aTable[nPos].id, nPos );
if( hFunc->cmpIDs( id, aTable[nPos].id ) &&
aTable[nPos].bDeleted == false )
{
if( nSkip == 0 )
{
aTable[nPos].bDeleted = true;
nSize--;
#ifdef HASH_DEBUG_VIS
printDebugLine( (const char *)id );
#endif
return true;
}
else
{
nSkip--;
}
}
}
return false;
}
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