#include "test/jemalloc_test.h"
#include "jemalloc/internal/fb.h"
#include "test/nbits.h"
static void
do_test_init(size_t nbits) {
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb = malloc(sz);
/* Junk fb's contents. */
memset(fb, 99, sz);
fb_init(fb, nbits);
for (size_t i = 0; i < nbits; i++) {
expect_false(fb_get(fb, nbits, i),
"bitmap should start empty");
}
free(fb);
}
TEST_BEGIN(test_fb_init) {
#define NB(nbits) \
do_test_init(nbits);
NBITS_TAB
#undef NB
}
TEST_END
static void
do_test_get_set_unset(size_t nbits) {
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb = malloc(sz);
fb_init(fb, nbits);
/* Set the bits divisible by 3. */
for (size_t i = 0; i < nbits; i++) {
if (i % 3 == 0) {
fb_set(fb, nbits, i);
}
}
/* Check them. */
for (size_t i = 0; i < nbits; i++) {
expect_b_eq(i % 3 == 0, fb_get(fb, nbits, i),
"Unexpected bit at position %zu", i);
}
/* Unset those divisible by 5. */
for (size_t i = 0; i < nbits; i++) {
if (i % 5 == 0) {
fb_unset(fb, nbits, i);
}
}
/* Check them. */
for (size_t i = 0; i < nbits; i++) {
expect_b_eq(i % 3 == 0 && i % 5 != 0, fb_get(fb, nbits, i),
"Unexpected bit at position %zu", i);
}
free(fb);
}
TEST_BEGIN(test_get_set_unset) {
#define NB(nbits) \
do_test_get_set_unset(nbits);
NBITS_TAB
#undef NB
}
TEST_END
static ssize_t
find_3_5_compute(ssize_t i, size_t nbits, bool bit, bool forward) {
for(; i < (ssize_t)nbits && i >= 0; i += (forward ? 1 : -1)) {
bool expected_bit = i % 3 == 0 || i % 5 == 0;
if (expected_bit == bit) {
return i;
}
}
return forward ? (ssize_t)nbits : (ssize_t)-1;
}
static void
do_test_search_simple(size_t nbits) {
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb = malloc(sz);
fb_init(fb, nbits);
/* We pick multiples of 3 or 5. */
for (size_t i = 0; i < nbits; i++) {
if (i % 3 == 0) {
fb_set(fb, nbits, i);
}
/* This tests double-setting a little, too. */
if (i % 5 == 0) {
fb_set(fb, nbits, i);
}
}
for (size_t i = 0; i < nbits; i++) {
size_t ffs_compute = find_3_5_compute(i, nbits, true, true);
size_t ffs_search = fb_ffs(fb, nbits, i);
expect_zu_eq(ffs_compute, ffs_search, "ffs mismatch at %zu", i);
ssize_t fls_compute = find_3_5_compute(i, nbits, true, false);
size_t fls_search = fb_fls(fb, nbits, i);
expect_zu_eq(fls_compute, fls_search, "fls mismatch at %zu", i);
size_t ffu_compute = find_3_5_compute(i, nbits, false, true);
size_t ffu_search = fb_ffu(fb, nbits, i);
expect_zu_eq(ffu_compute, ffu_search, "ffu mismatch at %zu", i);
size_t flu_compute = find_3_5_compute(i, nbits, false, false);
size_t flu_search = fb_flu(fb, nbits, i);
expect_zu_eq(flu_compute, flu_search, "flu mismatch at %zu", i);
}
free(fb);
}
TEST_BEGIN(test_search_simple) {
#define NB(nbits) \
do_test_search_simple(nbits);
NBITS_TAB
#undef NB
}
TEST_END
static void
expect_exhaustive_results(fb_group_t *mostly_full, fb_group_t *mostly_empty,
size_t nbits, size_t special_bit, size_t position) {
if (position < special_bit) {
expect_zu_eq(special_bit, fb_ffs(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(-1, fb_fls(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position, fb_ffu(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position, fb_flu(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position, fb_ffs(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position, fb_fls(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(special_bit, fb_ffu(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(-1, fb_flu(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
} else if (position == special_bit) {
expect_zu_eq(special_bit, fb_ffs(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(special_bit, fb_fls(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position + 1, fb_ffu(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position - 1, fb_flu(mostly_empty, nbits,
position), "mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position + 1, fb_ffs(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position - 1, fb_fls(mostly_full, nbits,
position), "mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position, fb_ffu(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position, fb_flu(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
} else {
/* position > special_bit. */
expect_zu_eq(nbits, fb_ffs(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(special_bit, fb_fls(mostly_empty, nbits,
position), "mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position, fb_ffu(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position, fb_flu(mostly_empty, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(position, fb_ffs(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(position, fb_fls(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zu_eq(nbits, fb_ffu(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
expect_zd_eq(special_bit, fb_flu(mostly_full, nbits, position),
"mismatch at %zu, %zu", position, special_bit);
}
}
static void
do_test_search_exhaustive(size_t nbits) {
/* This test is quadratic; let's not get too big. */
if (nbits > 1000) {
return;
}
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *empty = malloc(sz);
fb_init(empty, nbits);
fb_group_t *full = malloc(sz);
fb_init(full, nbits);
fb_set_range(full, nbits, 0, nbits);
for (size_t i = 0; i < nbits; i++) {
fb_set(empty, nbits, i);
fb_unset(full, nbits, i);
for (size_t j = 0; j < nbits; j++) {
expect_exhaustive_results(full, empty, nbits, i, j);
}
fb_unset(empty, nbits, i);
fb_set(full, nbits, i);
}
free(empty);
free(full);
}
TEST_BEGIN(test_search_exhaustive) {
#define NB(nbits) \
do_test_search_exhaustive(nbits);
NBITS_TAB
#undef NB
}
TEST_END
TEST_BEGIN(test_range_simple) {
/*
* Just pick a constant big enough to have nontrivial middle sizes, and
* big enough that usages of things like weirdnum (below) near the
* beginning fit comfortably into the beginning of the bitmap.
*/
size_t nbits = 64 * 10;
size_t ngroups = FB_NGROUPS(nbits);
fb_group_t *fb = malloc(sizeof(fb_group_t) * ngroups);
fb_init(fb, nbits);
for (size_t i = 0; i < nbits; i++) {
if (i % 2 == 0) {
fb_set_range(fb, nbits, i, 1);
}
}
for (size_t i = 0; i < nbits; i++) {
expect_b_eq(i % 2 == 0, fb_get(fb, nbits, i),
"mismatch at position %zu", i);
}
fb_set_range(fb, nbits, 0, nbits / 2);
fb_unset_range(fb, nbits, nbits / 2, nbits / 2);
for (size_t i = 0; i < nbits; i++) {
expect_b_eq(i < nbits / 2, fb_get(fb, nbits, i),
"mismatch at position %zu", i);
}
static const size_t weirdnum = 7;
fb_set_range(fb, nbits, 0, nbits);
fb_unset_range(fb, nbits, weirdnum, FB_GROUP_BITS + weirdnum);
for (size_t i = 0; i < nbits; i++) {
expect_b_eq(7 <= i && i <= 2 * weirdnum + FB_GROUP_BITS - 1,
!fb_get(fb, nbits, i), "mismatch at position %zu", i);
}
free(fb);
}
TEST_END
static void
do_test_empty_full_exhaustive(size_t nbits) {
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *empty = malloc(sz);
fb_init(empty, nbits);
fb_group_t *full = malloc(sz);
fb_init(full, nbits);
fb_set_range(full, nbits, 0, nbits);
expect_true(fb_full(full, nbits), "");
expect_false(fb_empty(full, nbits), "");
expect_false(fb_full(empty, nbits), "");
expect_true(fb_empty(empty, nbits), "");
for (size_t i = 0; i < nbits; i++) {
fb_set(empty, nbits, i);
fb_unset(full, nbits, i);
expect_false(fb_empty(empty, nbits), "error at bit %zu", i);
if (nbits != 1) {
expect_false(fb_full(empty, nbits),
"error at bit %zu", i);
expect_false(fb_empty(full, nbits),
"error at bit %zu", i);
} else {
expect_true(fb_full(empty, nbits),
"error at bit %zu", i);
expect_true(fb_empty(full, nbits),
"error at bit %zu", i);
}
expect_false(fb_full(full, nbits), "error at bit %zu", i);
fb_unset(empty, nbits, i);
fb_set(full, nbits, i);
}
free(empty);
free(full);
}
TEST_BEGIN(test_empty_full) {
#define NB(nbits) \
do_test_empty_full_exhaustive(nbits);
NBITS_TAB
#undef NB
}
TEST_END
/*
* This tests both iter_range and the longest range functionality, which is
* built closely on top of it.
*/
TEST_BEGIN(test_iter_range_simple) {
size_t set_limit = 30;
size_t nbits = 100;
fb_group_t fb[FB_NGROUPS(100)];
fb_init(fb, nbits);
/*
* Failing to initialize these can lead to build failures with -Wall;
* the compiler can't prove that they're set.
*/
size_t begin = (size_t)-1;
size_t len = (size_t)-1;
bool result;
/* A set of checks with only the first set_limit bits *set*. */
fb_set_range(fb, nbits, 0, set_limit);
expect_zu_eq(set_limit, fb_srange_longest(fb, nbits),
"Incorrect longest set range");
expect_zu_eq(nbits - set_limit, fb_urange_longest(fb, nbits),
"Incorrect longest unset range");
for (size_t i = 0; i < set_limit; i++) {
result = fb_srange_iter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(i, begin, "Incorrect begin at %zu", i);
expect_zu_eq(set_limit - i, len, "Incorrect len at %zu", i);
result = fb_urange_iter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(set_limit, begin, "Incorrect begin at %zu", i);
expect_zu_eq(nbits - set_limit, len, "Incorrect len at %zu", i);
result = fb_srange_riter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(0, begin, "Incorrect begin at %zu", i);
expect_zu_eq(i + 1, len, "Incorrect len at %zu", i);
result = fb_urange_riter(fb, nbits, i, &begin, &len);
expect_false(result, "Should not have found a range at %zu", i);
}
for (size_t i = set_limit; i < nbits; i++) {
result = fb_srange_iter(fb, nbits, i, &begin, &len);
expect_false(result, "Should not have found a range at %zu", i);
result = fb_urange_iter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(i, begin, "Incorrect begin at %zu", i);
expect_zu_eq(nbits - i, len, "Incorrect len at %zu", i);
result = fb_srange_riter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(0, begin, "Incorrect begin at %zu", i);
expect_zu_eq(set_limit, len, "Incorrect len at %zu", i);
result = fb_urange_riter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(set_limit, begin, "Incorrect begin at %zu", i);
expect_zu_eq(i - set_limit + 1, len, "Incorrect len at %zu", i);
}
/* A set of checks with only the first set_limit bits *unset*. */
fb_unset_range(fb, nbits, 0, set_limit);
fb_set_range(fb, nbits, set_limit, nbits - set_limit);
expect_zu_eq(nbits - set_limit, fb_srange_longest(fb, nbits),
"Incorrect longest set range");
expect_zu_eq(set_limit, fb_urange_longest(fb, nbits),
"Incorrect longest unset range");
for (size_t i = 0; i < set_limit; i++) {
result = fb_srange_iter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(set_limit, begin, "Incorrect begin at %zu", i);
expect_zu_eq(nbits - set_limit, len, "Incorrect len at %zu", i);
result = fb_urange_iter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(i, begin, "Incorrect begin at %zu", i);
expect_zu_eq(set_limit - i, len, "Incorrect len at %zu", i);
result = fb_srange_riter(fb, nbits, i, &begin, &len);
expect_false(result, "Should not have found a range at %zu", i);
result = fb_urange_riter(fb, nbits, i, &begin, &len);
expect_true(result, "Should not have found a range at %zu", i);
expect_zu_eq(0, begin, "Incorrect begin at %zu", i);
expect_zu_eq(i + 1, len, "Incorrect len at %zu", i);
}
for (size_t i = set_limit; i < nbits; i++) {
result = fb_srange_iter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(i, begin, "Incorrect begin at %zu", i);
expect_zu_eq(nbits - i, len, "Incorrect len at %zu", i);
result = fb_urange_iter(fb, nbits, i, &begin, &len);
expect_false(result, "Should not have found a range at %zu", i);
result = fb_srange_riter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(set_limit, begin, "Incorrect begin at %zu", i);
expect_zu_eq(i - set_limit + 1, len, "Incorrect len at %zu", i);
result = fb_urange_riter(fb, nbits, i, &begin, &len);
expect_true(result, "Should have found a range at %zu", i);
expect_zu_eq(0, begin, "Incorrect begin at %zu", i);
expect_zu_eq(set_limit, len, "Incorrect len at %zu", i);
}
}
TEST_END
/*
* Doing this bit-by-bit is too slow for a real implementation, but for testing
* code, it's easy to get right. In the exhaustive tests, we'll compare the
* (fast but tricky) real implementation against the (slow but simple) testing
* one.
*/
static bool
fb_iter_simple(fb_group_t *fb, size_t nbits, size_t start, size_t *r_begin,
size_t *r_len, bool val, bool forward) {
ssize_t stride = (forward ? (ssize_t)1 : (ssize_t)-1);
ssize_t range_begin = (ssize_t)start;
for (; range_begin != (ssize_t)nbits && range_begin != -1;
range_begin += stride) {
if (fb_get(fb, nbits, range_begin) == val) {
ssize_t range_end = range_begin;
for (; range_end != (ssize_t)nbits && range_end != -1;
range_end += stride) {
if (fb_get(fb, nbits, range_end) != val) {
break;
}
}
if (forward) {
*r_begin = range_begin;
*r_len = range_end - range_begin;
} else {
*r_begin = range_end + 1;
*r_len = range_begin - range_end;
}
return true;
}
}
return false;
}
/* Similar, but for finding longest ranges. */
static size_t
fb_range_longest_simple(fb_group_t *fb, size_t nbits, bool val) {
size_t longest_so_far = 0;
for (size_t begin = 0; begin < nbits; begin++) {
if (fb_get(fb, nbits, begin) != val) {
continue;
}
size_t end = begin + 1;
for (; end < nbits; end++) {
if (fb_get(fb, nbits, end) != val) {
break;
}
}
if (end - begin > longest_so_far) {
longest_so_far = end - begin;
}
}
return longest_so_far;
}
static void
expect_iter_results_at(fb_group_t *fb, size_t nbits, size_t pos,
bool val, bool forward) {
bool iter_res;
size_t iter_begin JEMALLOC_CC_SILENCE_INIT(0);
size_t iter_len JEMALLOC_CC_SILENCE_INIT(0);
if (val) {
if (forward) {
iter_res = fb_srange_iter(fb, nbits, pos,
&iter_begin, &iter_len);
} else {
iter_res = fb_srange_riter(fb, nbits, pos,
&iter_begin, &iter_len);
}
} else {
if (forward) {
iter_res = fb_urange_iter(fb, nbits, pos,
&iter_begin, &iter_len);
} else {
iter_res = fb_urange_riter(fb, nbits, pos,
&iter_begin, &iter_len);
}
}
bool simple_iter_res;
/*
* These are dead stores, but the compiler can't always figure that out
* statically, and warns on the uninitialized variable.
*/
size_t simple_iter_begin = 0;
size_t simple_iter_len = 0;
simple_iter_res = fb_iter_simple(fb, nbits, pos, &simple_iter_begin,
&simple_iter_len, val, forward);
expect_b_eq(iter_res, simple_iter_res, "Result mismatch at %zu", pos);
if (iter_res && simple_iter_res) {
assert_zu_eq(iter_begin, simple_iter_begin,
"Begin mismatch at %zu", pos);
expect_zu_eq(iter_len, simple_iter_len,
"Length mismatch at %zu", pos);
}
}
static void
expect_iter_results(fb_group_t *fb, size_t nbits) {
for (size_t i = 0; i < nbits; i++) {
expect_iter_results_at(fb, nbits, i, false, false);
expect_iter_results_at(fb, nbits, i, false, true);
expect_iter_results_at(fb, nbits, i, true, false);
expect_iter_results_at(fb, nbits, i, true, true);
}
expect_zu_eq(fb_range_longest_simple(fb, nbits, true),
fb_srange_longest(fb, nbits), "Longest range mismatch");
expect_zu_eq(fb_range_longest_simple(fb, nbits, false),
fb_urange_longest(fb, nbits), "Longest range mismatch");
}
static void
set_pattern_3(fb_group_t *fb, size_t nbits, bool zero_val) {
for (size_t i = 0; i < nbits; i++) {
if ((i % 6 < 3 && zero_val) || (i % 6 >= 3 && !zero_val)) {
fb_set(fb, nbits, i);
} else {
fb_unset(fb, nbits, i);
}
}
}
static void
do_test_iter_range_exhaustive(size_t nbits) {
/* This test is also pretty slow. */
if (nbits > 1000) {
return;
}
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb = malloc(sz);
fb_init(fb, nbits);
set_pattern_3(fb, nbits, /* zero_val */ true);
expect_iter_results(fb, nbits);
set_pattern_3(fb, nbits, /* zero_val */ false);
expect_iter_results(fb, nbits);
fb_set_range(fb, nbits, 0, nbits);
fb_unset_range(fb, nbits, 0, nbits / 2 == 0 ? 1 : nbits / 2);
expect_iter_results(fb, nbits);
fb_unset_range(fb, nbits, 0, nbits);
fb_set_range(fb, nbits, 0, nbits / 2 == 0 ? 1: nbits / 2);
expect_iter_results(fb, nbits);
free(fb);
}
/*
* Like test_iter_range_simple, this tests both iteration and longest-range
* computation.
*/
TEST_BEGIN(test_iter_range_exhaustive) {
#define NB(nbits) \
do_test_iter_range_exhaustive(nbits);
NBITS_TAB
#undef NB
}
TEST_END
/*
* If all set bits in the bitmap are contiguous, in [set_start, set_end),
* returns the number of set bits in [scount_start, scount_end).
*/
static size_t
scount_contiguous(size_t set_start, size_t set_end, size_t scount_start,
size_t scount_end) {
/* No overlap. */
if (set_end <= scount_start || scount_end <= set_start) {
return 0;
}
/* set range contains scount range */
if (set_start <= scount_start && set_end >= scount_end) {
return scount_end - scount_start;
}
/* scount range contains set range. */
if (scount_start <= set_start && scount_end >= set_end) {
return set_end - set_start;
}
/* Partial overlap, with set range starting first. */
if (set_start < scount_start && set_end < scount_end) {
return set_end - scount_start;
}
/* Partial overlap, with scount range starting first. */
if (scount_start < set_start && scount_end < set_end) {
return scount_end - set_start;
}
/*
* Trigger an assert failure; the above list should have been
* exhaustive.
*/
unreachable();
}
static size_t
ucount_contiguous(size_t set_start, size_t set_end, size_t ucount_start,
size_t ucount_end) {
/* No overlap. */
if (set_end <= ucount_start || ucount_end <= set_start) {
return ucount_end - ucount_start;
}
/* set range contains ucount range */
if (set_start <= ucount_start && set_end >= ucount_end) {
return 0;
}
/* ucount range contains set range. */
if (ucount_start <= set_start && ucount_end >= set_end) {
return (ucount_end - ucount_start) - (set_end - set_start);
}
/* Partial overlap, with set range starting first. */
if (set_start < ucount_start && set_end < ucount_end) {
return ucount_end - set_end;
}
/* Partial overlap, with ucount range starting first. */
if (ucount_start < set_start && ucount_end < set_end) {
return set_start - ucount_start;
}
/*
* Trigger an assert failure; the above list should have been
* exhaustive.
*/
unreachable();
}
static void
expect_count_match_contiguous(fb_group_t *fb, size_t nbits, size_t set_start,
size_t set_end) {
for (size_t i = 0; i < nbits; i++) {
for (size_t j = i + 1; j <= nbits; j++) {
size_t cnt = j - i;
size_t scount_expected = scount_contiguous(set_start,
set_end, i, j);
size_t scount_computed = fb_scount(fb, nbits, i, cnt);
expect_zu_eq(scount_expected, scount_computed,
"fb_scount error with nbits=%zu, start=%zu, "
"cnt=%zu, with bits set in [%zu, %zu)",
nbits, i, cnt, set_start, set_end);
size_t ucount_expected = ucount_contiguous(set_start,
set_end, i, j);
size_t ucount_computed = fb_ucount(fb, nbits, i, cnt);
assert_zu_eq(ucount_expected, ucount_computed,
"fb_ucount error with nbits=%zu, start=%zu, "
"cnt=%zu, with bits set in [%zu, %zu)",
nbits, i, cnt, set_start, set_end);
}
}
}
static void
do_test_count_contiguous(size_t nbits) {
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb = malloc(sz);
fb_init(fb, nbits);
expect_count_match_contiguous(fb, nbits, 0, 0);
for (size_t i = 0; i < nbits; i++) {
fb_set(fb, nbits, i);
expect_count_match_contiguous(fb, nbits, 0, i + 1);
}
for (size_t i = 0; i < nbits; i++) {
fb_unset(fb, nbits, i);
expect_count_match_contiguous(fb, nbits, i + 1, nbits);
}
free(fb);
}
TEST_BEGIN(test_count_contiguous_simple) {
enum {nbits = 300};
fb_group_t fb[FB_NGROUPS(nbits)];
fb_init(fb, nbits);
/* Just an arbitrary number. */
size_t start = 23;
fb_set_range(fb, nbits, start, 30 - start);
expect_count_match_contiguous(fb, nbits, start, 30);
fb_set_range(fb, nbits, start, 40 - start);
expect_count_match_contiguous(fb, nbits, start, 40);
fb_set_range(fb, nbits, start, 70 - start);
expect_count_match_contiguous(fb, nbits, start, 70);
fb_set_range(fb, nbits, start, 120 - start);
expect_count_match_contiguous(fb, nbits, start, 120);
fb_set_range(fb, nbits, start, 150 - start);
expect_count_match_contiguous(fb, nbits, start, 150);
fb_set_range(fb, nbits, start, 200 - start);
expect_count_match_contiguous(fb, nbits, start, 200);
fb_set_range(fb, nbits, start, 290 - start);
expect_count_match_contiguous(fb, nbits, start, 290);
}
TEST_END
TEST_BEGIN(test_count_contiguous) {
#define NB(nbits) \
/* This test is *particularly* slow in debug builds. */ \
if ((!config_debug && nbits < 300) || nbits < 150) { \
do_test_count_contiguous(nbits); \
}
NBITS_TAB
#undef NB
}
TEST_END
static void
expect_count_match_alternating(fb_group_t *fb_even, fb_group_t *fb_odd,
size_t nbits) {
for (size_t i = 0; i < nbits; i++) {
for (size_t j = i + 1; j <= nbits; j++) {
size_t cnt = j - i;
size_t odd_scount = cnt / 2
+ (size_t)(cnt % 2 == 1 && i % 2 == 1);
size_t odd_scount_computed = fb_scount(fb_odd, nbits,
i, j - i);
assert_zu_eq(odd_scount, odd_scount_computed,
"fb_scount error with nbits=%zu, start=%zu, "
"cnt=%zu, with alternating bits set.",
nbits, i, j - i);
size_t odd_ucount = cnt / 2
+ (size_t)(cnt % 2 == 1 && i % 2 == 0);
size_t odd_ucount_computed = fb_ucount(fb_odd, nbits,
i, j - i);
assert_zu_eq(odd_ucount, odd_ucount_computed,
"fb_ucount error with nbits=%zu, start=%zu, "
"cnt=%zu, with alternating bits set.",
nbits, i, j - i);
size_t even_scount = cnt / 2
+ (size_t)(cnt % 2 == 1 && i % 2 == 0);
size_t even_scount_computed = fb_scount(fb_even, nbits,
i, j - i);
assert_zu_eq(even_scount, even_scount_computed,
"fb_scount error with nbits=%zu, start=%zu, "
"cnt=%zu, with alternating bits set.",
nbits, i, j - i);
size_t even_ucount = cnt / 2
+ (size_t)(cnt % 2 == 1 && i % 2 == 1);
size_t even_ucount_computed = fb_ucount(fb_even, nbits,
i, j - i);
assert_zu_eq(even_ucount, even_ucount_computed,
"fb_ucount error with nbits=%zu, start=%zu, "
"cnt=%zu, with alternating bits set.",
nbits, i, j - i);
}
}
}
static void
do_test_count_alternating(size_t nbits) {
if (nbits > 1000) {
return;
}
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb_even = malloc(sz);
fb_group_t *fb_odd = malloc(sz);
fb_init(fb_even, nbits);
fb_init(fb_odd, nbits);
for (size_t i = 0; i < nbits; i++) {
if (i % 2 == 0) {
fb_set(fb_even, nbits, i);
} else {
fb_set(fb_odd, nbits, i);
}
}
expect_count_match_alternating(fb_even, fb_odd, nbits);
free(fb_even);
free(fb_odd);
}
TEST_BEGIN(test_count_alternating) {
#define NB(nbits) \
do_test_count_alternating(nbits);
NBITS_TAB
#undef NB
}
TEST_END
static void
do_test_bit_op(size_t nbits, bool (*op)(bool a, bool b),
void (*fb_op)(fb_group_t *dst, fb_group_t *src1, fb_group_t *src2, size_t nbits)) {
size_t sz = FB_NGROUPS(nbits) * sizeof(fb_group_t);
fb_group_t *fb1 = malloc(sz);
fb_group_t *fb2 = malloc(sz);
fb_group_t *fb_result = malloc(sz);
fb_init(fb1, nbits);
fb_init(fb2, nbits);
fb_init(fb_result, nbits);
/* Just two random numbers. */
const uint64_t prng_init1 = (uint64_t)0X4E9A9DE6A35691CDULL;
const uint64_t prng_init2 = (uint64_t)0X7856E396B063C36EULL;
uint64_t prng1 = prng_init1;
uint64_t prng2 = prng_init2;
for (size_t i = 0; i < nbits; i++) {
bool bit1 = ((prng1 & (1ULL << (i % 64))) != 0);
bool bit2 = ((prng2 & (1ULL << (i % 64))) != 0);
if (bit1) {
fb_set(fb1, nbits, i);
}
if (bit2) {
fb_set(fb2, nbits, i);
}
if (i % 64 == 0) {
prng1 = prng_state_next_u64(prng1);
prng2 = prng_state_next_u64(prng2);
}
}
fb_op(fb_result, fb1, fb2, nbits);
/* Reset the prngs to replay them. */
prng1 = prng_init1;
prng2 = prng_init2;
for (size_t i = 0; i < nbits; i++) {
bool bit1 = ((prng1 & (1ULL << (i % 64))) != 0);
bool bit2 = ((prng2 & (1ULL << (i % 64))) != 0);
/* Original bitmaps shouldn't change. */
expect_b_eq(bit1, fb_get(fb1, nbits, i), "difference at bit %zu", i);
expect_b_eq(bit2, fb_get(fb2, nbits, i), "difference at bit %zu", i);
/* New one should be bitwise and. */
expect_b_eq(op(bit1, bit2), fb_get(fb_result, nbits, i),
"difference at bit %zu", i);
/* Update the same way we did last time. */
if (i % 64 == 0) {
prng1 = prng_state_next_u64(prng1);
prng2 = prng_state_next_u64(prng2);
}
}
free(fb1);
free(fb2);
free(fb_result);
}
static bool
binary_and(bool a, bool b) {
return a & b;
}
static void
do_test_bit_and(size_t nbits) {
do_test_bit_op(nbits, &binary_and, &fb_bit_and);
}
TEST_BEGIN(test_bit_and) {
#define NB(nbits) \
do_test_bit_and(nbits);
NBITS_TAB
#undef NB
}
TEST_END
static bool
binary_or(bool a, bool b) {
return a | b;
}
static void
do_test_bit_or(size_t nbits) {
do_test_bit_op(nbits, &binary_or, &fb_bit_or);
}
TEST_BEGIN(test_bit_or) {
#define NB(nbits) \
do_test_bit_or(nbits);
NBITS_TAB
#undef NB
}
TEST_END
static bool
binary_not(bool a, bool b) {
(void)b;
return !a;
}
static void
fb_bit_not_shim(fb_group_t *dst, fb_group_t *src1, fb_group_t *src2,
size_t nbits) {
(void)src2;
fb_bit_not(dst, src1, nbits);
}
static void
do_test_bit_not(size_t nbits) {
do_test_bit_op(nbits, &binary_not, &fb_bit_not_shim);
}
TEST_BEGIN(test_bit_not) {
#define NB(nbits) \
do_test_bit_not(nbits);
NBITS_TAB
#undef NB
}
TEST_END
int
main(void) {
return test_no_reentrancy(
test_fb_init,
test_get_set_unset,
test_search_simple,
test_search_exhaustive,
test_range_simple,
test_empty_full,
test_iter_range_simple,
test_iter_range_exhaustive,
test_count_contiguous_simple,
test_count_contiguous,
test_count_alternating,
test_bit_and,
test_bit_or,
test_bit_not);
}