Source code of Windows XP (NT5)
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287 lines
5.6 KiB

/*++
Copyright (c) 1992-1996 Microsoft Corporation
Module Name:
hash.c
Abstract:
Hash Table and support functions.
Environment:
User Mode - Win32
Revision History:
10-May-1996 DonRyan
Removed banner from Technology Dynamics, Inc.
--*/
//--------------------------- WINDOWS DEPENDENCIES --------------------------
//--------------------------- STANDARD DEPENDENCIES -- #include<xxxxx.h> ----
#include <stdio.h>
//--------------------------- MODULE DEPENDENCIES -- #include"xxxxx.h" ------
#include <snmp.h>
#include "mib.h"
//--------------------------- SELF-DEPENDENCY -- ONE #include"module.h" -----
#include "hash.h"
//--------------------------- PUBLIC VARIABLES --(same as in module.h file)--
//--------------------------- PRIVATE CONSTANTS -----------------------------
#define HT_SIZE 101
#define HT_RADIX 18
//--------------------------- PRIVATE STRUCTS -------------------------------
//--------------------------- PRIVATE VARIABLES -----------------------------
// Structure of one node in the hash table
typedef struct hash_node
{
MIB_ENTRY *MibEntry;
struct hash_node *Next;
} HASH_NODE;
// Hash table definition
HASH_NODE *MIB_HashTable[HT_SIZE];
//--------------------------- PRIVATE PROTOTYPES ----------------------------
//--------------------------- PRIVATE PROCEDURES ----------------------------
//--------------------------- PUBLIC PROCEDURES -----------------------------
//
// MIB_HashInit
// Initializes hash table.
//
// Notes:
//
// Return Codes:
// SNMPAPI_NOERROR
// SNMPAPI_ERROR
//
// Error Codes:
// None.
//
SNMPAPI MIB_HashInit()
{
UINT I;
UINT HashRes;
HASH_NODE *ht_ptr;
SNMPAPI nResult;
// Initialize hash table
for ( I=0;I < HT_SIZE;I++ )
{
MIB_HashTable[I] = NULL;
}
// Loop MIB hashing the OID's to find position in Hash Table
for ( I=0;I < MIB_num_variables;I++ )
{
HashRes = MIB_Hash( &Mib[I].Oid );
// Check for empty bucket
if ( MIB_HashTable[HashRes] == NULL )
{
// Allocate first node in bucket
MIB_HashTable[HashRes] = SnmpUtilMemAlloc( sizeof(HASH_NODE) );
if ( MIB_HashTable[HashRes] == NULL )
{
SetLastError( SNMP_MEM_ALLOC_ERROR );
nResult = SNMPAPI_ERROR;
goto Exit;
}
// Make copy of position in hash table to save MIB entry
ht_ptr = MIB_HashTable[HashRes];
}
else
{
// Find end of bucket
ht_ptr = MIB_HashTable[HashRes];
while ( ht_ptr->Next != NULL )
{
ht_ptr = ht_ptr->Next;
}
// Alloc space for next node
ht_ptr->Next = SnmpUtilMemAlloc( sizeof(HASH_NODE) );
if ( ht_ptr->Next == NULL )
{
SetLastError( SNMP_MEM_ALLOC_ERROR );
nResult = SNMPAPI_ERROR;
goto Exit;
}
// Make copy of position in hash table to save MIB entry
ht_ptr = ht_ptr->Next;
}
// Save MIB Entry pointer
ht_ptr->MibEntry = &Mib[I];
ht_ptr->Next = NULL;
}
Exit:
return nResult;
} // MIB_HashInit
//
// MIB_Hash
// Hash an Object Identifier to find its position in the Hash Table.
//
// Notes:
//
// Return Codes:
// None.
//
// Error Codes:
// None.
//
UINT MIB_Hash(
IN AsnObjectIdentifier *Oid // OID to hash
)
{
long I;
UINT Sum;
Sum = 0;
for ( I=0;I < (long)Oid->idLength-1;I++ )
{
Sum = Sum * HT_RADIX + Oid->ids[I+1];
}
return Sum % HT_SIZE;
} // MIB_Hash
//
// MIB_HashLookup
// Lookup OID in Hash Table and return pointer to MIB Entry.
//
// Notes:
//
// Return Codes:
// NULL - OID not present in Hash Table.
//
// Error Codes:
// None.
//
MIB_ENTRY *MIB_HashLookup(
IN AsnObjectIdentifier *Oid // OID to lookup
)
{
HASH_NODE *ht_ptr;
MIB_ENTRY *pResult;
UINT HashPos;
// Hash OID to find position in Hash Table
HashPos = MIB_Hash( Oid );
// Search hash bucket for match
ht_ptr = MIB_HashTable[HashPos];
while ( ht_ptr != NULL )
{
if ( !SnmpUtilOidCmp(Oid, &ht_ptr->MibEntry->Oid) )
{
pResult = ht_ptr->MibEntry;
goto Exit;
}
ht_ptr = ht_ptr->Next;
}
// Check for not found error
if ( ht_ptr == NULL )
{
pResult = NULL;
}
Exit:
return pResult;
} // MIB_HashLookup
#if 0 // Left in in case of more testing on hash performance
//
//
// Debugging Code
//
//
void MIB_HashPerformance()
{
UINT I;
UINT LargestBucket;
UINT BucketSize;
HASH_NODE *ht_ptr;
ULONG Sum;
ULONG Count;
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Hash Performance Report\n" );
LargestBucket = 0;
Count = 0;
Sum = 0;
for ( I=0;I < HT_SIZE;I++ )
{
BucketSize = 0;
ht_ptr = MIB_HashTable[I];
// Count nodes in bucket
while ( ht_ptr != NULL )
{
BucketSize++;
ht_ptr = ht_ptr->Next;
}
if ( BucketSize )
{
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: %d -- Bucket Size: %d\n", I, BucketSize ));
Sum += BucketSize;
Count ++;
LargestBucket = max( LargestBucket, BucketSize );
}
}
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Number of Buckets: %d\n", HT_SIZE ));
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Number of MIB Var: %d\n", MIB_num_variables ));
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Hashing Radix : %d\n", HashRadix ));
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Used bucket Count: %d\n", Count ));
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Avg. Bucket Size : %d\n", Sum / Count ));
SNMPDBG(( SNMP_LOG_TRACE, "LMMIB2: Larg. bucket Size: %d\n", LargestBucket ));
} // MIB_HashPerformance
#endif
//-------------------------------- END --------------------------------------