500 lines
14 KiB
C
500 lines
14 KiB
C
/*
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* testcode/unitlruhash.c - unit test for lruhash table.
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*
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* Copyright (c) 2007, NLnet Labs. All rights reserved.
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*
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* This software is open source.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions
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* are met:
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*
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* Redistributions of source code must retain the above copyright notice,
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* this list of conditions and the following disclaimer.
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*
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* Redistributions in binary form must reproduce the above copyright notice,
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* this list of conditions and the following disclaimer in the documentation
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* and/or other materials provided with the distribution.
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*
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* Neither the name of the NLNET LABS nor the names of its contributors may
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* be used to endorse or promote products derived from this software without
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* specific prior written permission.
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*
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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* HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
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* TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
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* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
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* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
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* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
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* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*
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*/
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/**
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* \file
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* Tests the locking LRU keeping hash table implementation.
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*/
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#include "config.h"
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#include "testcode/unitmain.h"
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#include "util/log.h"
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#include "util/storage/lruhash.h"
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#include "util/storage/slabhash.h" /* for the test structures */
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/** use this type for the lruhash test key */
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typedef struct slabhash_testkey testkey_type;
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/** use this type for the lruhash test data */
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typedef struct slabhash_testdata testdata_type;
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/** delete key */
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static void delkey(struct slabhash_testkey* k) {
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lock_rw_destroy(&k->entry.lock); free(k);}
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/** delete data */
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static void deldata(struct slabhash_testdata* d) {free(d);}
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/** hash func, very bad to improve collisions */
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static hashvalue_type myhash(int id) {return (hashvalue_type)id & 0x0f;}
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/** allocate new key, fill in hash */
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static testkey_type* newkey(int id) {
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testkey_type* k = (testkey_type*)calloc(1, sizeof(testkey_type));
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if(!k) fatal_exit("out of memory");
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k->id = id;
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k->entry.hash = myhash(id);
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k->entry.key = k;
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lock_rw_init(&k->entry.lock);
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return k;
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}
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/** new data el */
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static testdata_type* newdata(int val) {
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testdata_type* d = (testdata_type*)calloc(1,
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sizeof(testdata_type));
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if(!d) fatal_exit("out of memory");
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d->data = val;
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return d;
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}
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/** test bin_find_entry function and bin_overflow_remove */
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static void
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test_bin_find_entry(struct lruhash* table)
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{
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testkey_type* k = newkey(12);
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testdata_type* d = newdata(128);
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testkey_type* k2 = newkey(12 + 1024);
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testkey_type* k3 = newkey(14);
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testkey_type* k4 = newkey(12 + 1024*2);
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hashvalue_type h = myhash(12);
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struct lruhash_bin bin;
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memset(&bin, 0, sizeof(bin));
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bin_init(&bin, 1);
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/* remove from empty list */
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bin_overflow_remove(&bin, &k->entry);
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/* find in empty list */
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unit_assert( bin_find_entry(table, &bin, h, k) == NULL );
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/* insert */
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lock_quick_lock(&bin.lock);
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bin.overflow_list = &k->entry;
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lock_quick_unlock(&bin.lock);
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/* find, hash not OK. */
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unit_assert( bin_find_entry(table, &bin, myhash(13), k) == NULL );
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/* find, hash OK, but cmp not */
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unit_assert( k->entry.hash == k2->entry.hash );
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unit_assert( bin_find_entry(table, &bin, h, k2) == NULL );
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/* find, hash OK, and cmp too */
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unit_assert( bin_find_entry(table, &bin, h, k) == &k->entry );
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/* remove the element */
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lock_quick_lock(&bin.lock);
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bin_overflow_remove(&bin, &k->entry);
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lock_quick_unlock(&bin.lock);
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unit_assert( bin_find_entry(table, &bin, h, k) == NULL );
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/* prepend two different elements; so the list is long */
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/* one has the same hash, but different cmp */
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lock_quick_lock(&bin.lock);
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unit_assert( k->entry.hash == k4->entry.hash );
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k4->entry.overflow_next = &k->entry;
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k3->entry.overflow_next = &k4->entry;
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bin.overflow_list = &k3->entry;
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lock_quick_unlock(&bin.lock);
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/* find, hash not OK. */
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unit_assert( bin_find_entry(table, &bin, myhash(13), k) == NULL );
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/* find, hash OK, but cmp not */
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unit_assert( k->entry.hash == k2->entry.hash );
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unit_assert( bin_find_entry(table, &bin, h, k2) == NULL );
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/* find, hash OK, and cmp too */
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unit_assert( bin_find_entry(table, &bin, h, k) == &k->entry );
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/* remove middle element */
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unit_assert( bin_find_entry(table, &bin, k4->entry.hash, k4)
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== &k4->entry );
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lock_quick_lock(&bin.lock);
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bin_overflow_remove(&bin, &k4->entry);
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lock_quick_unlock(&bin.lock);
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unit_assert( bin_find_entry(table, &bin, k4->entry.hash, k4) == NULL);
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/* remove last element */
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lock_quick_lock(&bin.lock);
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bin_overflow_remove(&bin, &k->entry);
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lock_quick_unlock(&bin.lock);
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unit_assert( bin_find_entry(table, &bin, h, k) == NULL );
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lock_quick_destroy(&bin.lock);
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delkey(k);
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delkey(k2);
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delkey(k3);
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delkey(k4);
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deldata(d);
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}
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/** test lru_front lru_remove */
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static void test_lru(struct lruhash* table)
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{
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testkey_type* k = newkey(12);
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testkey_type* k2 = newkey(14);
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lock_quick_lock(&table->lock);
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unit_assert( table->lru_start == NULL && table->lru_end == NULL);
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lru_remove(table, &k->entry);
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unit_assert( table->lru_start == NULL && table->lru_end == NULL);
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/* add one */
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lru_front(table, &k->entry);
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unit_assert( table->lru_start == &k->entry &&
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table->lru_end == &k->entry);
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/* remove it */
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lru_remove(table, &k->entry);
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unit_assert( table->lru_start == NULL && table->lru_end == NULL);
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/* add two */
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lru_front(table, &k->entry);
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unit_assert( table->lru_start == &k->entry &&
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table->lru_end == &k->entry);
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lru_front(table, &k2->entry);
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unit_assert( table->lru_start == &k2->entry &&
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table->lru_end == &k->entry);
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/* remove first in list */
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lru_remove(table, &k2->entry);
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unit_assert( table->lru_start == &k->entry &&
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table->lru_end == &k->entry);
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lru_front(table, &k2->entry);
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unit_assert( table->lru_start == &k2->entry &&
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table->lru_end == &k->entry);
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/* remove last in list */
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lru_remove(table, &k->entry);
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unit_assert( table->lru_start == &k2->entry &&
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table->lru_end == &k2->entry);
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/* empty the list */
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lru_remove(table, &k2->entry);
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unit_assert( table->lru_start == NULL && table->lru_end == NULL);
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lock_quick_unlock(&table->lock);
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delkey(k);
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delkey(k2);
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}
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/** test hashtable using short sequence */
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static void
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test_short_table(struct lruhash* table)
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{
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testkey_type* k = newkey(12);
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testkey_type* k2 = newkey(14);
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testdata_type* d = newdata(128);
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testdata_type* d2 = newdata(129);
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k->entry.data = d;
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k2->entry.data = d2;
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lruhash_insert(table, myhash(12), &k->entry, d, NULL);
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lruhash_insert(table, myhash(14), &k2->entry, d2, NULL);
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unit_assert( lruhash_lookup(table, myhash(12), k, 0) == &k->entry);
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lock_rw_unlock( &k->entry.lock );
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unit_assert( lruhash_lookup(table, myhash(14), k2, 0) == &k2->entry);
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lock_rw_unlock( &k2->entry.lock );
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lruhash_remove(table, myhash(12), k);
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lruhash_remove(table, myhash(14), k2);
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}
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/** number of hash test max */
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#define HASHTESTMAX 25
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/** test adding a random element */
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static void
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testadd(struct lruhash* table, testdata_type* ref[])
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{
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int numtoadd = random() % HASHTESTMAX;
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testdata_type* data = newdata(numtoadd);
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testkey_type* key = newkey(numtoadd);
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key->entry.data = data;
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lruhash_insert(table, myhash(numtoadd), &key->entry, data, NULL);
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ref[numtoadd] = data;
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}
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/** test adding a random element */
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static void
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testremove(struct lruhash* table, testdata_type* ref[])
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{
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int num = random() % HASHTESTMAX;
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testkey_type* key = newkey(num);
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lruhash_remove(table, myhash(num), key);
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ref[num] = NULL;
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delkey(key);
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}
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/** test adding a random element */
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static void
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testlookup(struct lruhash* table, testdata_type* ref[])
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{
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int num = random() % HASHTESTMAX;
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testkey_type* key = newkey(num);
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struct lruhash_entry* en = lruhash_lookup(table, myhash(num), key, 0);
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testdata_type* data = en? (testdata_type*)en->data : NULL;
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if(en) {
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unit_assert(en->key);
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unit_assert(en->data);
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}
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if(0) log_info("lookup %d got %d, expect %d", num, en? data->data :-1,
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ref[num]? ref[num]->data : -1);
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unit_assert( data == ref[num] );
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if(en) { lock_rw_unlock(&en->lock); }
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delkey(key);
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}
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/** check integrity of hash table */
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static void
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check_table(struct lruhash* table)
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{
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struct lruhash_entry* p;
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size_t c = 0;
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lock_quick_lock(&table->lock);
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unit_assert( table->num <= table->size);
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unit_assert( table->size_mask == (int)table->size-1 );
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unit_assert( (table->lru_start && table->lru_end) ||
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(!table->lru_start && !table->lru_end) );
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unit_assert( table->space_used <= table->space_max );
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/* check lru list integrity */
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if(table->lru_start)
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unit_assert(table->lru_start->lru_prev == NULL);
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if(table->lru_end)
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unit_assert(table->lru_end->lru_next == NULL);
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p = table->lru_start;
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while(p) {
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if(p->lru_prev) {
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unit_assert(p->lru_prev->lru_next == p);
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}
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if(p->lru_next) {
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unit_assert(p->lru_next->lru_prev == p);
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}
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c++;
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p = p->lru_next;
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}
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unit_assert(c == table->num);
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/* this assertion is specific to the unit test */
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unit_assert( table->space_used ==
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table->num * test_slabhash_sizefunc(NULL, NULL) );
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lock_quick_unlock(&table->lock);
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}
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/** test adding a random element (unlimited range) */
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static void
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testadd_unlim(struct lruhash* table, testdata_type** ref)
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{
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int numtoadd = random() % (HASHTESTMAX * 10);
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testdata_type* data = newdata(numtoadd);
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testkey_type* key = newkey(numtoadd);
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key->entry.data = data;
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lruhash_insert(table, myhash(numtoadd), &key->entry, data, NULL);
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if(ref)
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ref[numtoadd] = data;
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}
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/** test adding a random element (unlimited range) */
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static void
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testremove_unlim(struct lruhash* table, testdata_type** ref)
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{
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int num = random() % (HASHTESTMAX*10);
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testkey_type* key = newkey(num);
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lruhash_remove(table, myhash(num), key);
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if(ref)
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ref[num] = NULL;
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delkey(key);
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}
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/** test adding a random element (unlimited range) */
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static void
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testlookup_unlim(struct lruhash* table, testdata_type** ref)
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{
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int num = random() % (HASHTESTMAX*10);
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testkey_type* key = newkey(num);
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struct lruhash_entry* en = lruhash_lookup(table, myhash(num), key, 0);
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testdata_type* data = en? (testdata_type*)en->data : NULL;
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if(en) {
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unit_assert(en->key);
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unit_assert(en->data);
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}
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if(0 && ref) log_info("lookup unlim %d got %d, expect %d", num, en ?
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data->data :-1, ref[num] ? ref[num]->data : -1);
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if(data && ref) {
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/* its okay for !data, it fell off the lru */
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unit_assert( data == ref[num] );
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}
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if(en) { lock_rw_unlock(&en->lock); }
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delkey(key);
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}
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/** test with long sequence of adds, removes and updates, and lookups */
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static void
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test_long_table(struct lruhash* table)
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{
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/* assuming it all fits in the hashtable, this check will work */
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testdata_type* ref[HASHTESTMAX * 100];
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size_t i;
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memset(ref, 0, sizeof(ref));
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/* test assumption */
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if(0) log_info(" size %d x %d < %d", (int)test_slabhash_sizefunc(NULL, NULL),
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(int)HASHTESTMAX, (int)table->space_max);
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unit_assert( test_slabhash_sizefunc(NULL, NULL)*HASHTESTMAX < table->space_max);
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if(0) lruhash_status(table, "unit test", 1);
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srandom(48);
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for(i=0; i<1000; i++) {
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/* what to do? */
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if(i == 500) {
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lruhash_clear(table);
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memset(ref, 0, sizeof(ref));
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continue;
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}
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switch(random() % 4) {
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case 0:
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case 3:
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testadd(table, ref);
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break;
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case 1:
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testremove(table, ref);
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break;
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case 2:
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testlookup(table, ref);
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break;
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default:
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unit_assert(0);
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}
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if(0) lruhash_status(table, "unit test", 1);
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check_table(table);
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unit_assert( table->num <= HASHTESTMAX );
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}
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/* test more, but 'ref' assumption does not hold anymore */
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for(i=0; i<1000; i++) {
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/* what to do? */
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switch(random() % 4) {
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case 0:
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case 3:
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testadd_unlim(table, ref);
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break;
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case 1:
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testremove_unlim(table, ref);
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break;
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case 2:
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testlookup_unlim(table, ref);
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break;
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default:
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unit_assert(0);
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}
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if(0) lruhash_status(table, "unlim", 1);
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check_table(table);
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}
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}
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/** structure to threaded test the lru hash table */
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struct test_thr {
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/** thread num, first entry. */
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int num;
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/** id */
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ub_thread_type id;
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/** hash table */
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struct lruhash* table;
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};
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/** main routine for threaded hash table test */
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static void*
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test_thr_main(void* arg)
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{
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struct test_thr* t = (struct test_thr*)arg;
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int i;
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log_thread_set(&t->num);
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for(i=0; i<1000; i++) {
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switch(random() % 4) {
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case 0:
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case 3:
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testadd_unlim(t->table, NULL);
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break;
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case 1:
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testremove_unlim(t->table, NULL);
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break;
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case 2:
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testlookup_unlim(t->table, NULL);
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break;
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default:
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unit_assert(0);
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}
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if(0) lruhash_status(t->table, "hashtest", 1);
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if(i % 100 == 0) /* because of locking, not all the time */
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check_table(t->table);
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}
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check_table(t->table);
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return NULL;
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}
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/** test hash table access by multiple threads */
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static void
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test_threaded_table(struct lruhash* table)
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{
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int numth = 10;
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struct test_thr t[100];
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int i;
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for(i=1; i<numth; i++) {
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t[i].num = i;
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t[i].table = table;
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ub_thread_create(&t[i].id, test_thr_main, &t[i]);
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}
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for(i=1; i<numth; i++) {
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ub_thread_join(t[i].id);
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}
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if(0) lruhash_status(table, "hashtest", 1);
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}
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void lruhash_test(void)
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{
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/* start very very small array, so it can do lots of table_grow() */
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/* also small in size so that reclaim has to be done quickly. */
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struct lruhash* table ;
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unit_show_feature("lruhash");
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table = lruhash_create(2, 8192,
|
|
test_slabhash_sizefunc, test_slabhash_compfunc,
|
|
test_slabhash_delkey, test_slabhash_deldata, NULL);
|
|
test_bin_find_entry(table);
|
|
test_lru(table);
|
|
test_short_table(table);
|
|
test_long_table(table);
|
|
lruhash_delete(table);
|
|
table = lruhash_create(2, 8192,
|
|
test_slabhash_sizefunc, test_slabhash_compfunc,
|
|
test_slabhash_delkey, test_slabhash_deldata, NULL);
|
|
test_threaded_table(table);
|
|
lruhash_delete(table);
|
|
}
|