Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
02110-1301, USA.
- Bacula® is a registered trademark of John Walker.
+ Bacula® is a registered trademark of Kern Sibbald.
The licensor of Bacula is the Free Software Foundation Europe
(FSFE), Fiduciary Program, Sumatrastrasse 25, 8006 Zürich,
Switzerland, email:ftf@fsfeurope.org.
#include "htable.h"
+static const int dbglvl = 500;
+
/* ===================================================================
* htable
*/
/*
* This subroutine gets a big buffer.
*/
-void htable::malloc_buf(int size)
+void htable::malloc_big_buf(int size)
{
struct h_mem *hmem;
hmem = (struct h_mem *)malloc(size);
total_size += size;
blocks++;
- hmem->next = this->mem;
- this->mem = hmem;
- hmem->mem = mem->first;
+ hmem->next = mem_block;
+ mem_block = hmem;
+ hmem->mem = mem_block->first;
hmem->rem = (char *)hmem + size - hmem->mem;
- Dmsg2(200, "malloc buf size=%d rem=%d\n", size, hmem->rem);
+ Dmsg3(100, "malloc buf=%p size=%d rem=%d\n", hmem, size, hmem->rem);
}
-char *htable::hash_alloc(int size)
+/* This routine frees the whole tree */
+void htable::hash_big_free()
{
+ struct h_mem *hmem, *rel;
+
+ for (hmem=mem_block; hmem; ) {
+ rel = hmem;
+ hmem = hmem->next;
+ Dmsg1(100, "free malloc buf=%p\n", rel);
+ free(rel);
+ }
+}
+
+#endif
+
+/*
+ * Normal hash malloc routine that gets a
+ * "small" buffer from the big buffer
+ */
+char *htable::hash_malloc(int size)
+{
+#ifdef BIG_MALLOC
char *buf;
int asize = BALIGN(size);
- if (mem->rem < asize) {
+ if (mem_block->rem < asize) {
uint32_t mb_size;
if (total_size >= 1000000) {
mb_size = 1000000;
} else {
mb_size = 100000;
}
- malloc_buf(mb_size);
+ malloc_big_buf(mb_size);
}
- mem->rem -= asize;
- buf = mem->mem;
- mem->mem += asize;
+ mem_block->rem -= asize;
+ buf = mem_block->mem;
+ mem_block->mem += asize;
return buf;
+#else
+ total_size += size;
+ blocks++;
+ return (char *)malloc(size);
+#endif
}
-/* This routine frees the whole tree */
-void htable::hash_free()
-{
- struct h_mem *hmem, *rel;
-
- for (hmem=mem; hmem; ) {
- rel = hmem;
- hmem = hmem->next;
- free(rel);
- }
-}
-#endif
/*
{
hash = 0;
for (char *p=key; *p; p++) {
- hash += (hash << 3) + (uint32_t)*p;
+// hash += (hash << 3) + (uint32_t)*p;
+ hash += ((hash << 5) | (hash >> (sizeof(hash)*8-5))) + (uint32_t)*p;
}
/* Multiply by large prime number, take top bits, mask for remainder */
index = ((hash * 1103515249) >> rshift) & mask;
- Dmsg2(100, "Leave hash_index hash=0x%x index=%d\n", hash, index);
+ Dmsg2(dbglvl, "Leave hash_index hash=0x%x index=%d\n", hash, index);
}
+/*
+ * tsize is the estimated number of entries in the hash table
+ */
htable::htable(void *item, void *link, int tsize)
{
init(item, link, tsize);
void htable::init(void *item, void *link, int tsize)
{
int pwr;
+
+ memset(this, 0, sizeof(htable));
+ if (tsize < 31) {
+ tsize = 31;
+ }
tsize >>= 2;
for (pwr=0; tsize; pwr++) {
tsize >>= 1;
loffset = (char *)link - (char *)item;
mask = ~((~0)<<pwr); /* 3 bits => table size = 8 */
rshift = 30 - pwr; /* start using bits 28, 29, 30 */
- num_items = 0; /* number of entries in table */
buckets = 1<<pwr; /* hash table size -- power of two */
max_items = buckets * 4; /* allow average 4 entries per chain */
table = (hlink **)malloc(buckets * sizeof(hlink *));
memset(table, 0, buckets * sizeof(hlink *));
- walkptr = NULL;
- walk_index = 0;
#ifdef BIG_MALLOC
- mem = NULL;
- malloc_buf(1000000); /* ***FIXME*** base off of size */
+ malloc_big_buf(1000000); /* ***FIXME*** need variable or some estimate */
#endif
}
* Take each hash link and walk down the chain of items
* that hash there counting them (i.e. the hits),
* then report that number.
- * Obiously, the more hits in a chain, the more time
+ * Obiously, the more hits in a chain, the more time
* it takes to reference them. Empty chains are not so
* hot either -- as it means unused or wasted space.
*/
for (i=0; i < MAX_COUNT; i++) {
printf("%2d: %d\n",i, hits[i]);
}
+ printf("buckets=%d num_items=%d max_items=%d\n", buckets, num_items, max_items);
printf("max hits in a bucket = %d\n", max);
+#ifdef BIG_MALLOC
+ printf("total bytes malloced = %d\n", total_size);
+ printf("total blocks malloced = %d\n", blocks);
+#endif
}
void htable::grow_table()
Dmsg1(100, "Grow called old size = %d\n", buckets);
/* Setup a bigger table */
htable *big = (htable *)malloc(sizeof(htable));
+ memcpy(big, this, sizeof(htable)); /* start with original class data */
big->loffset = loffset;
big->mask = mask<<1 | 1;
big->rshift = rshift - 1;
big->num_items = 0;
big->buckets = buckets * 2;
big->max_items = big->buckets * 4;
+ /* Create a bigger hash table */
big->table = (hlink **)malloc(big->buckets * sizeof(hlink *));
memset(big->table, 0, big->buckets * sizeof(hlink *));
big->walkptr = NULL;
return false; /* already exists */
}
ASSERT(index < buckets);
- Dmsg2(100, "Insert: hash=%p index=%d\n", hash, index);
+ Dmsg2(dbglvl, "Insert: hash=%p index=%d\n", hash, index);
hp = (hlink *)(((char *)item)+loffset);
- Dmsg4(100, "Insert hp=%p index=%d item=%p offset=%u\n", hp,
+ Dmsg4(dbglvl, "Insert hp=%p index=%d item=%p offset=%u\n", hp,
index, item, loffset);
hp->next = table[index];
hp->hash = hash;
hp->key = key;
table[index] = hp;
- Dmsg3(100, "Insert hp->next=%p hp->hash=0x%x hp->key=%s\n",
+ Dmsg3(dbglvl, "Insert hp->next=%p hp->hash=0x%x hp->key=%s\n",
hp->next, hp->hash, hp->key);
if (++num_items >= max_items) {
- Dmsg2(100, "num_items=%d max_items=%d\n", num_items, max_items);
+ Dmsg2(dbglvl, "num_items=%d max_items=%d\n", num_items, max_items);
grow_table();
}
- Dmsg3(100, "Leave insert index=%d num_items=%d key=%s\n", index, num_items, key);
+ Dmsg3(dbglvl, "Leave insert index=%d num_items=%d key=%s\n", index, num_items, key);
return true;
}
for (hlink *hp=table[index]; hp; hp=(hlink *)hp->next) {
// Dmsg2(100, "hp=%p key=%s\n", hp, hp->key);
if (hash == hp->hash && strcmp(key, hp->key) == 0) {
- Dmsg1(100, "lookup return %p\n", ((char *)hp)-loffset);
+ Dmsg1(dbglvl, "lookup return %p\n", ((char *)hp)-loffset);
return ((char *)hp)-loffset;
}
}
void *htable::next()
{
- Dmsg1(100, "Enter next: walkptr=%p\n", walkptr);
+ Dmsg1(dbglvl, "Enter next: walkptr=%p\n", walkptr);
if (walkptr) {
walkptr = (hlink *)(walkptr->next);
}
while (!walkptr && walk_index < buckets) {
walkptr = table[walk_index++];
if (walkptr) {
- Dmsg3(100, "new walkptr=%p next=%p inx=%d\n", walkptr,
+ Dmsg3(dbglvl, "new walkptr=%p next=%p inx=%d\n", walkptr,
walkptr->next, walk_index-1);
}
}
if (walkptr) {
- Dmsg2(100, "next: rtn %p walk_index=%d\n",
+ Dmsg2(dbglvl, "next: rtn %p walk_index=%d\n",
((char *)walkptr)-loffset, walk_index);
return ((char *)walkptr)-loffset;
}
- Dmsg0(100, "next: return NULL\n");
+ Dmsg0(dbglvl, "next: return NULL\n");
return NULL;
}
void *htable::first()
{
- Dmsg0(100, "Enter first\n");
+ Dmsg0(dbglvl, "Enter first\n");
walkptr = table[0]; /* get first bucket */
walk_index = 1; /* Point to next index */
while (!walkptr && walk_index < buckets) {
walkptr = table[walk_index++]; /* go to next bucket */
if (walkptr) {
- Dmsg3(100, "first new walkptr=%p next=%p inx=%d\n", walkptr,
+ Dmsg3(dbglvl, "first new walkptr=%p next=%p inx=%d\n", walkptr,
walkptr->next, walk_index-1);
}
}
if (walkptr) {
- Dmsg1(100, "Leave first walkptr=%p\n", walkptr);
+ Dmsg1(dbglvl, "Leave first walkptr=%p\n", walkptr);
return ((char *)walkptr)-loffset;
}
- Dmsg0(100, "Leave first walkptr=NULL\n");
+ Dmsg0(dbglvl, "Leave first walkptr=NULL\n");
return NULL;
}
/* Destroy the table and its contents */
void htable::destroy()
{
+#ifdef BIG_MALLOC
+ hash_big_free();
+#else
void *ni;
void *li = first();
free(li);
li=ni;
}
+#endif
free(table);
table = NULL;
hlink link;
};
-#define NITEMS 1000000
+#define NITEMS 5000000
int main()
{
int len;
len = sprintf(mkey, "This is htable item %d", i) + 1;
-#ifdef BIG_MALLOC
- jcr = (MYJCR *)jcrtbl->hash_alloc(sizeof(MYJCR));
- jcr->key = (char *)jcrtbl->hash_alloc(len);
-#else
- jcr = (MYJCR *)malloc(sizeof(MYJCR));
- jcr->key = (char *)malloc(len);
-#endif
+ jcr = (MYJCR *)jcrtbl->hash_malloc(sizeof(MYJCR));
+ jcr->key = (char *)jcrtbl->hash_malloc(len);
memcpy(jcr->key, mkey, len);
Dmsg2(100, "link=%p jcr=%p\n", jcr->link, jcr);