base64: fix for unsigned chars (e.g. ARM).

[ccan] / ccan / antithread / alloc / test / run.c

#include <ccan/antithread/alloc/alloc.h>
#include <ccan/tap/tap.h>
#include <ccan/antithread/alloc/alloc.c>
#include <ccan/antithread/alloc/bitops.c>
#include <ccan/antithread/alloc/tiny.c>
#include <stdlib.h>
#include <err.h>

#define sort(p, num, cmp) \
        qsort((p), (num), sizeof(*p), (int(*)(const void *, const void *))cmp)

static int addr_cmp(void **a, void **b)
{
        return (char *)(*a) - (char *)(*b);
}

static bool unique(void *p[], unsigned int num)
{
        unsigned int i;

        for (i = 1; i < num; i++)
                if (p[i] == p[i-1])
                        return false;
        return true;
}

static bool free_every_second_one(void *mem, unsigned int num,
                                  unsigned long pool_size, void *p[])
{
        unsigned int i;

        /* Free every second one. */
        for (i = 0; i < num; i += 2) {
                alloc_free(mem, pool_size, p[i]);
        }
        if (!alloc_check(mem, pool_size))
                return false;
        for (i = 1; i < num; i += 2) {
                alloc_free(mem, pool_size, p[i]);
        }
        if (!alloc_check(mem, pool_size))
                return false;
        return true;
}

static void test(unsigned int pool_size)
{
        void *mem;
        unsigned int i, num, max_size;
        void **p = calloc(pool_size, sizeof(*p));
        unsigned alloc_limit = pool_size / 2;

        mem = malloc(pool_size);

        /* Small pool, all allocs fail, even 0-length. */
        alloc_init(mem, 0);
        ok1(alloc_check(mem, 0));
        ok1(alloc_get(mem, 0, 1, 1) == NULL);
        ok1(alloc_get(mem, 0, 128, 1) == NULL);
        ok1(alloc_get(mem, 0, 0, 1) == NULL);

        /* Free of NULL should work. */
        alloc_free(mem, 0, NULL);

        alloc_init(mem, pool_size);
        ok1(alloc_check(mem, pool_size));
        /* Find largest allocation which works. */
        for (max_size = pool_size + 1; max_size; max_size--) {
                p[0] = alloc_get(mem, pool_size, max_size, 1);
                if (p[0])
                        break;
        }
        ok1(max_size < pool_size);
        ok1(max_size > 0);
        ok1(alloc_check(mem, pool_size));
        ok1(alloc_size(mem, pool_size, p[0]) >= max_size);

        /* Free it, should be able to reallocate it. */
        alloc_free(mem, pool_size, p[0]);
        ok1(alloc_check(mem, pool_size));

        p[0] = alloc_get(mem, pool_size, max_size, 1);
        ok1(p[0]);
        ok1(alloc_size(mem, pool_size, p[0]) >= max_size);
        ok1(alloc_check(mem, pool_size));
        alloc_free(mem, pool_size, p[0]);
        ok1(alloc_check(mem, pool_size));

        /* Allocate a whole heap. */
        for (i = 0; i < pool_size; i++) {
                p[i] = alloc_get(mem, pool_size, 1, 1);
                if (!p[i])
                        break;
        }

        /* Uncomment this for a more intuitive view of what the
         * allocator looks like after all these 1 byte allocs. */
#if 0
        alloc_visualize(stderr, mem, pool_size);
#endif

        num = i;
        /* Can't allocate this many. */
        ok1(num != pool_size);
        ok1(alloc_check(mem, pool_size));

        /* Sort them. */
        sort(p, num, addr_cmp);

        /* Uniqueness check */
        ok1(unique(p, num));

        ok1(free_every_second_one(mem, num, pool_size, p));
        ok1(alloc_check(mem, pool_size));

        /* Should be able to reallocate max size. */
        p[0] = alloc_get(mem, pool_size, max_size, 1);
        ok1(p[0]);
        ok1(alloc_check(mem, pool_size));
        ok1(alloc_size(mem, pool_size, p[0]) >= max_size);

        /* Re-initializing should be the same as freeing everything */
        alloc_init(mem, pool_size);
        ok1(alloc_check(mem, pool_size));
        p[0] = alloc_get(mem, pool_size, max_size, 1);
        ok1(p[0]);
        ok1(alloc_size(mem, pool_size, p[0]) >= max_size);
        ok1(alloc_check(mem, pool_size));
        alloc_free(mem, pool_size, p[0]);
        ok1(alloc_check(mem, pool_size));

        /* Alignment constraints should be met, as long as powers of two */
        for (i = 0; (1 << i) < alloc_limit; i++) {
                p[i] = alloc_get(mem, pool_size, i, 1 << i);
                ok1(p[i]);
                ok1(((char *)p[i] - (char *)mem) % (1 << i) == 0);
                ok1(alloc_check(mem, pool_size));
                ok1(alloc_size(mem, pool_size, p[i]) >= i);
        }

        for (i = 0; (1 << i) < alloc_limit; i++) {
                alloc_free(mem, pool_size, p[i]);
                ok1(alloc_check(mem, pool_size));
        }

        /* Alignment constraints for a single-byte allocation. */
        for (i = 0; (1 << i) < alloc_limit; i++) {
                p[0] = alloc_get(mem, pool_size, 1, 1 << i);
                ok1(p[0]);
                ok1(((char *)p[0] - (char *)mem) % (1 << i) == 0);
                ok1(alloc_check(mem, pool_size));
                ok1(alloc_size(mem, pool_size, p[0]) >= 1);
                alloc_free(mem, pool_size, p[0]);
                ok1(alloc_check(mem, pool_size));
        }

        /* Alignment check for a 0-byte allocation.  Corner case. */
        p[0] = alloc_get(mem, pool_size, 0, alloc_limit);
        ok1(alloc_check(mem, pool_size));
        ok1(alloc_size(mem, pool_size, p[0]) < pool_size);
        alloc_free(mem, pool_size, p[0]);
        ok1(alloc_check(mem, pool_size));

        free(mem);
        free(p);
}

int main(int argc, char *argv[])
{
        plan_tests(440);

        /* Large test. */
        test(MIN_USEFUL_SIZE * 2);

        /* Small test. */
        test(MIN_USEFUL_SIZE / 2);

        return exit_status();
}