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Merge branch 'haugesund-to-2.0' into HEAD

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This commit is contained in:
Maria Matejka 2022-03-14 17:38:25 +01:00
commit b4336b0880
3 changed files with 179 additions and 2 deletions
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2
lib/Makefile
View File

@ -2,6 +2,6 @@ src := bitmap.c bitops.c blake2s.c blake2b.c checksum.c event.c flowspec.c idm.c
obj := $(src-o-files) obj := $(src-o-files)
$(all-daemon) $(all-daemon)
tests_src := bitmap_test.c heap_test.c buffer_test.c event_test.c flowspec_test.c bitops_test.c patmatch_test.c fletcher16_test.c slist_test.c checksum_test.c lists_test.c mac_test.c ip_test.c hash_test.c printf_test.c tests_src := bitmap_test.c heap_test.c buffer_test.c event_test.c flowspec_test.c bitops_test.c patmatch_test.c fletcher16_test.c slist_test.c checksum_test.c lists_test.c mac_test.c ip_test.c hash_test.c printf_test.c slab_test.c
tests_targets := $(tests_targets) $(tests-target-files) tests_targets := $(tests_targets) $(tests-target-files)
tests_objs := $(tests_objs) $(src-o-files) tests_objs := $(tests_objs) $(src-o-files)

2
lib/slab.c
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@ -394,7 +394,7 @@ slab_memsize(resource *r)
WALK_LIST(h, s->empty_heads) WALK_LIST(h, s->empty_heads)
heads++; heads++;
size_t eff = items * s->obj_size; size_t eff = items * s->data_size;
return (struct resmem) { return (struct resmem) {
.effective = eff, .effective = eff,

177
lib/slab_test.c Normal file
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@ -0,0 +1,177 @@
/*
* BIRD Library -- Slab Alloc / Dealloc Tests
*
* (c) 2022 Maria Matejka <mq@jmq.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#include "test/birdtest.h"
#include "lib/resource.h"
#include "lib/bitops.h"
static const int sizes[] = {
8, 12, 18, 27, 41, 75, 131, 269,
};
#define TEST_SIZE 1024 * 128
#define ITEMS(sz) TEST_SIZE / ( (sz) >> u32_log2((sz))/2 )
static inline byte *test_alloc(slab *s, int sz, struct resmem *sliz)
{
byte *out = sl_alloc(s);
for (int p=0; p < sz; p++)
out[p] = p & 0xff;
struct resmem ns = rmemsize((resource *) s);
bt_assert(sliz->effective + sz == ns.effective);
bt_assert((sliz->overhead - sz - ns.overhead) % page_size == 0);
*sliz = ns;
return out;
}
static inline void test_free(slab *s, byte *block, int sz, struct resmem *sliz)
{
for (int p=0; p < sz; p++)
{
bt_assert(block[p] == (p & 0xff));
block[p]++;
}
sl_free(s, block);
struct resmem ns = rmemsize((resource *) s);
bt_assert(sliz->effective - sz == ns.effective);
bt_assert((sliz->overhead + sz - ns.overhead) % page_size == 0);
*sliz = ns;
}
static inline struct resmem get_memsize(slab *s)
{
struct resmem sz = rmemsize((resource *) s);
bt_assert(sz.effective == 0);
return sz;
}
static int
t_slab_forwards(const void *data)
{
int sz = (intptr_t) data;
slab *s = sl_new(&root_pool, sz);
struct resmem sliz = get_memsize(s);
int n = ITEMS(sz);
byte **block = mb_alloc(&root_pool, n * sizeof(*block));
for (int i = 0; i < n; i++)
block[i] = test_alloc(s, sz, &sliz);
for (int i = 0; i < n; i++)
test_free(s, block[i], sz, &sliz);
mb_free(block);
return 1;
}
static int
t_slab_backwards(const void *data)
{
int sz = (intptr_t) data;
slab *s = sl_new(&root_pool, sz);
struct resmem sliz = get_memsize(s);
int n = ITEMS(sz);
byte **block = mb_alloc(&root_pool, n * sizeof(*block));
for (int i = 0; i < n; i++)
block[i] = test_alloc(s, sz, &sliz);
for (int i = n - 1; i >= 0; i--)
test_free(s, block[i], sz, &sliz);
mb_free(block);
return 1;
}
static int
t_slab_random(const void *data)
{
int sz = (intptr_t) data;
slab *s = sl_new(&root_pool, sz);
struct resmem sliz = get_memsize(s);
int n = ITEMS(sz);
byte **block = mb_alloc(&root_pool, n * sizeof(*block));
for (int i = 0; i < n; i++)
block[i] = test_alloc(s, sz, &sliz);
for (int i = 0; i < n; i++)
{
int pos = bt_random() % (n - i);
test_free(s, block[pos], sz, &sliz);
if (pos != n - i - 1)
block[pos] = block[n - i - 1];
}
mb_free(block);
return 1;
}
static int
t_slab_mixed(const void *data)
{
int sz = (intptr_t) data;
slab *s = sl_new(&root_pool, sz);
struct resmem sliz = get_memsize(s);
int n = ITEMS(sz);
byte **block = mb_alloc(&root_pool, n * sizeof(*block));
int cur = 0;
int pending = n;
while (cur + pending > 0) {
int action = bt_random() % (cur + pending);
if (action < cur) {
test_free(s, block[action], sz, &sliz);
if (action != --cur)
block[action] = block[cur];
} else {
block[cur++] = test_alloc(s, sz, &sliz);
pending--;
}
}
mb_free(block);
return 1;
}
int main(int argc, char *argv[])
{
bt_init(argc, argv);
for (uint i = 0; i < sizeof(sizes) / sizeof(*sizes); i++)
{
bt_test_suite_arg(t_slab_forwards, (void *) (intptr_t) sizes[i], "Slab deallocation from beginning to end, size=%d", sizes[i]);
bt_test_suite_arg(t_slab_backwards, (void *) (intptr_t) sizes[i], "Slab deallocation from end to beginning, size=%d", sizes[i]);
bt_test_suite_arg(t_slab_random, (void *) (intptr_t) sizes[i], "Slab deallocation in random order, size=%d", sizes[i]);
bt_test_suite_arg(t_slab_mixed, (void *) (intptr_t) sizes[i], "Slab deallocation in mixed order, size=%d", sizes[i]);
}
return bt_exit_value();
}