/* Exit with a failure code.
(Place a breakpoint on this function while debugging.) */
static void
-check_die (void)
+check_die (void)
{
- exit (EXIT_FAILURE);
+ exit (EXIT_FAILURE);
}
/* If OK is not true, prints a message about failure on the
current source file and the given LINE and terminates. */
static void
-check_func (bool ok, int line)
+check_func (bool ok, int line)
{
- if (!ok)
+ if (!ok)
{
printf ("Check failed in %s test at %s, line %d\n",
test_name, __FILE__, line);
/* Swaps *A and *B. */
static void
-swap (int *a, int *b)
+swap (int *a, int *b)
{
int t = *a;
*a = *b;
if (cnt > 0)
{
size_t i = cnt - 1;
- while (i != 0)
+ while (i != 0)
{
i--;
if (values[i] < values[i + 1])
swap (values + i, values + j);
reverse (values + (i + 1), cnt - (i + 1));
return true;
- }
+ }
}
-
+
reverse (values, cnt);
}
-
+
return false;
}
/* Returns N!. */
static unsigned int
-factorial (unsigned int n)
+factorial (unsigned int n)
{
unsigned int value = 1;
/* Disallow N values that overflow on 32-bit machines. */
/* Returns C(n, k), the number of ways that K choices can be made
from N items when order is unimportant. */
static unsigned int
-binomial_cofficient (unsigned int n, unsigned int k)
+binomial_cofficient (unsigned int n, unsigned int k)
{
assert (n >= k);
return factorial (n) / factorial (k) / factorial (n - k);
/* Tests whether PARTS is a K-part integer composition of N.
Returns true if so, false otherwise. */
static bool UNUSED
-is_k_composition (int n, int k, const int parts[])
+is_k_composition (int n, int k, const int parts[])
{
int sum;
int i;
already the greatest K-part composition of N (in which case
PARTS is unaltered). */
static bool
-next_k_composition (int n UNUSED, int k, int parts[])
+next_k_composition (int n UNUSED, int k, int parts[])
{
int x, i;
/* Sets the K integers in PARTS to the lexicographically first
K-part composition of N. */
static void
-first_k_composition (int n, int k, int parts[])
+first_k_composition (int n, int k, int parts[])
{
int i;
Returns true if successful, false if the set of compositions
has been exhausted. */
static bool
-next_composition (int n, int *k, int parts[])
+next_composition (int n, int *k, int parts[])
{
if (*k >= 1 && next_k_composition (n, *k, parts))
return true;
}
/* A block expected to be found in a tower. */
-struct expected_block
+struct expected_block
{
int height; /* Expected height of bottom of block. */
int x; /* Expected value for `x' member. */
BLOCKS[]. */
static void
check_tower (struct tower *t,
- struct expected_block blocks[], size_t block_cnt)
+ struct expected_block blocks[], size_t block_cnt)
{
int total_height;
struct tower_node *node;
size_t i;
-
+
check (tower_is_empty (t) == (block_cnt == 0));
total_height = 0;
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
{
unsigned long int level;
for (level = total_height;
level < total_height + blocks[i].height;
- level++)
+ level++)
{
struct tower_node *found;
unsigned long int block_start;
check (tower_node_to_block (found)->x == blocks[i].x);
check (block_start == total_height);
}
- total_height += blocks[i].height;
+ total_height += blocks[i].height;
}
check (tower_height (t) == total_height);
for (node = tower_first (t), i = 0;
node != NULL;
- node = tower_next (t, node), i++)
+ node = tower_next (t, node), i++)
{
check (tower_node_get_height (node) == blocks[i].height);
check (tower_node_to_block (node)->x == blocks[i].x);
for (node = tower_last (t), i = block_cnt - 1;
node != NULL;
- node = tower_prev (t, node), i--)
+ node = tower_prev (t, node), i--)
{
check (tower_node_get_height (node) == blocks[i].height);
check (tower_node_to_block (node)->x == blocks[i].x);
tower in all possible orders, up to a specified maximum tower
height. */
static void
-test_insert (void)
+test_insert (void)
{
const int max_height = 7;
int cnt;
- for (cnt = 1; cnt <= max_height; cnt++)
+ for (cnt = 1; cnt <= max_height; cnt++)
{
unsigned int composition_cnt;
struct expected_block *expected;
int block_cnt;
int *order;
struct block *blocks;
-
+
expected = xnmalloc (cnt, sizeof *expected);
heights = xnmalloc (cnt, sizeof *heights);
order = xnmalloc (cnt, sizeof *order);
block_cnt = 0;
composition_cnt = 0;
- while (next_composition (cnt, &block_cnt, heights))
+ while (next_composition (cnt, &block_cnt, heights))
{
int i, j;
unsigned int permutation_cnt;
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
order[i] = i;
permutation_cnt = 0;
- while (permutation_cnt == 0 || next_permutation (order, block_cnt))
+ while (permutation_cnt == 0 || next_permutation (order, block_cnt))
{
struct tower t;
/* Inserts the block_cnt blocks with the given
heights[] into T in the order given by order[]. */
tower_init (&t);
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
{
struct block *under;
int idx;
permutation_cnt++;
}
check (permutation_cnt == factorial (block_cnt));
-
+
composition_cnt++;
}
check (composition_cnt == 1 << (cnt - 1));
possible sets of block heights into a tower in all possible
orders, up to a specified maximum tower height. */
static void
-test_delete (void)
+test_delete (void)
{
const int max_height = 7;
int cnt;
- for (cnt = 1; cnt <= max_height; cnt++)
+ for (cnt = 1; cnt <= max_height; cnt++)
{
unsigned int composition_cnt;
struct expected_block *expected;
int block_cnt;
int *order;
struct block *blocks;
-
+
expected = xnmalloc (cnt, sizeof *expected);
heights = xnmalloc (cnt, sizeof *heights);
order = xnmalloc (cnt, sizeof *order);
block_cnt = 0;
composition_cnt = 0;
- while (next_composition (cnt, &block_cnt, heights))
+ while (next_composition (cnt, &block_cnt, heights))
{
int i;
unsigned int permutation_cnt;
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
order[i] = i;
permutation_cnt = 0;
- while (permutation_cnt == 0 || next_permutation (order, block_cnt))
+ while (permutation_cnt == 0 || next_permutation (order, block_cnt))
{
struct tower t;
/* Insert blocks into tower in ascending order. */
tower_init (&t);
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
{
blocks[i].x = i;
tower_insert (&t, heights[i], &blocks[i].node, NULL);
expected[i].height = heights[i];
}
check_tower (&t, expected, block_cnt);
-
+
/* Delete blocks from tower in the order of
order[]. */
for (i = 0; i < block_cnt; i++)
int idx = order[i];
int j;
tower_delete (&t, &blocks[idx].node);
- for (j = 0; ; j++)
+ for (j = 0; ; j++)
{
assert (j < block_cnt - i);
if (expected[j].x == idx)
permutation_cnt++;
}
check (permutation_cnt == factorial (block_cnt));
-
+
composition_cnt++;
}
check (composition_cnt == 1 << (cnt - 1));
the blocks to all possible heights that conserve the total
tower height, up to a maximum total tower height. */
static void
-test_resize (void)
+test_resize (void)
{
const int max_height = 9;
int cnt;
- for (cnt = 1; cnt <= max_height; cnt++)
+ for (cnt = 1; cnt <= max_height; cnt++)
{
unsigned int composition_cnt;
struct expected_block *expected;
int block_cnt;
int *order;
struct block *blocks;
-
+
expected = xnmalloc (cnt, sizeof *expected);
heights = xnmalloc (cnt, sizeof *heights);
new_heights = xnmalloc (cnt, sizeof *new_heights);
block_cnt = 0;
composition_cnt = 0;
- while (next_composition (cnt, &block_cnt, heights))
+ while (next_composition (cnt, &block_cnt, heights))
{
int i;
unsigned int resizes = 0;
/* Insert blocks into tower in ascending order. */
tower_init (&t);
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
{
blocks[i].x = i;
tower_insert (&t, heights[i], &blocks[i].node, NULL);
check_tower (&t, expected, block_cnt);
/* Resize all the blocks. */
- for (i = 0; i < block_cnt; i++)
+ for (i = 0; i < block_cnt; i++)
{
if (expected[i].height != new_heights[i] || rand () % 2)
tower_resize (&t, &blocks[i].node, new_heights[i]);
check_tower (&t, expected, block_cnt);
}
check (resizes == binomial_cofficient (cnt - 1, block_cnt - 1));
-
+
composition_cnt++;
}
check (composition_cnt == 1 << (cnt - 1));
/* Tests splicing all possible contiguous sets of blocks out of one
tower into a second, initially empty tower. */
static void
-test_splice_out (void)
+test_splice_out (void)
{
const int max_height = 9;
int cnt;
- for (cnt = 1; cnt <= max_height; cnt++)
+ for (cnt = 1; cnt <= max_height; cnt++)
{
unsigned int composition_cnt;
struct expected_block *expected;
int block_cnt;
int *order;
struct block *blocks;
-
+
expected = xnmalloc (cnt, sizeof *expected);
heights = xnmalloc (cnt, sizeof *heights);
new_heights = xnmalloc (cnt, sizeof *new_heights);
block_cnt = 0;
composition_cnt = 0;
- while (next_composition (cnt, &block_cnt, heights))
+ while (next_composition (cnt, &block_cnt, heights))
{
int i, j;
tower_init (&dst);
/* Insert blocks into SRC and DST in ascending order. */
- for (k = 0; k < block_cnt; k++)
+ for (k = 0; k < block_cnt; k++)
{
blocks[k].x = k;
tower_insert (&src, heights[k], &blocks[k].node, NULL);
/* Tests splicing all of the contents of a tower into all
possible positions in a second tower. */
static void
-test_splice_in (void)
+test_splice_in (void)
{
const int max_height = 9;
int cnt;
- for (cnt = 1; cnt <= max_height; cnt++)
+ for (cnt = 1; cnt <= max_height; cnt++)
{
unsigned int composition_cnt;
struct expected_block *expected;
int block_cnt;
int *order;
struct block *blocks;
-
+
expected = xnmalloc (cnt, sizeof *expected);
heights = xnmalloc (cnt, sizeof *heights);
new_heights = xnmalloc (cnt, sizeof *new_heights);
block_cnt = 0;
composition_cnt = 0;
- while (next_composition (cnt, &block_cnt, heights))
+ while (next_composition (cnt, &block_cnt, heights))
{
int i, j;
tower_init (&dst);
/* Insert blocks into SRC and DST in ascending order. */
- for (k = 0; k < block_cnt; k++)
+ for (k = 0; k < block_cnt; k++)
{
blocks[k].x = k;
- tower_insert (k >= i && k < j ? &src : &dst,
+ tower_insert (k >= i && k < j ? &src : &dst,
heights[k], &blocks[k].node, NULL);
expected[k].x = k;
expected[k].height = heights[k];
/* Runs TEST_FUNCTION and prints a message about NAME. */
static void
-run_test (void (*test_function) (void), const char *name)
+run_test (void (*test_function) (void), const char *name)
{
test_name = name;
putchar ('.');
}
int
-main (void)
+main (void)
{
run_test (test_insert, "insert");
run_test (test_delete, "delete");