/* Complexity: O(n log n), worst-case if data is located
* at the right-most leaf node on the lowest level of the
* tree.
*/
int heap_remove(Heap *heap, const void *data)
{
unsigned long i;
assert(heap != NULL);
if(heap_is_empty(heap)) {
return -1;
}
for(i = 0; i < heap_size(heap); i++) {
if(darray_index(heap->h, i) == data) {
if(darray_swap(heap->h, i, darray_size(heap->h) - 1) < 0) {
return -1;
}
/* Don't care about the return value */
darray_remove(heap->h, darray_size(heap->h) - 1);
heapify_down(heap, i);
return 0;
}
}
return -1;
}
void graph_free_all(Graph *g, FreeFn vertex_data_freefn)
{
unsigned long index;
Vertex *v;
assert(g != NULL);
if(NULL == vertex_data_freefn) {
/* Default to stdlib free */
vertex_data_freefn = free;
}
/* Free edge lists and vertex data */
for(index = 0; index < darray_size(g->vertices); index++) {
v = (Vertex *)darray_index(g->vertices, index);
vertex_data_freefn(v->data);
darray_free_all(v->edges, NULL);
}
/* Free vertex list */
darray_free_all(g->vertices, NULL);
/* Free graph container */
free(g);
}
DArray* graph_get_edges(const Graph *g)
{
unsigned long index;
DArray *edges;
Vertex *v;
assert(g != NULL);
edges = darray_create();
if(NULL == edges) {
fprintf(stderr, "Cannot create edge list (%s:%d)\n",
__FUNCTION__, __LINE__);
return NULL;
}
for(index = 0; index < darray_size(g->vertices); index++) {
v = (Vertex *)darray_index(g->vertices, index);
if(darray_concat(edges, v->edges) < 0) {
fprintf(stderr, "Cannot construct edge list (%s:%d)\n",
__FUNCTION__, __LINE__);
darray_free(edges);
return NULL;
}
}
return edges;
}
DArray* graph_vertex_get_out_edges(const Graph *g, const Vertex *v)
{
unsigned long index;
DArray *out_edges;
Edge *e;
assert(g != NULL);
assert(v != NULL);
out_edges = darray_create();
if(NULL == out_edges) {
fprintf(stderr, "Cannot create out-edge list (%s:%d)\n",
__FUNCTION__, __LINE__);
return NULL;
}
for(index = 0; index < darray_size(v->edges); index++) {
e = (Edge *)darray_index(v->edges, index);
if(v == e->source) {
if(darray_append(out_edges, e) < 0) {
fprintf(stderr, "Cannot construct out-edge list (%s:%d)\n",
__FUNCTION__, __LINE__);
darray_free(out_edges);
return NULL;
}
}
}
return out_edges;
}
/* Complexity: O(log n), worst-case */
int heap_push(Heap *heap, void *data)
{
assert(heap != NULL);
darray_append(heap->h, data);
heapify_up(heap, darray_size(heap->h) - 1);
return 0;
}
int graph_vertex_add(Graph *g, Vertex *v)
{
assert(g != NULL);
assert(v != NULL);
v->idx = darray_size(g->vertices);
return darray_append(g->vertices, v);
}
/* Complexity: O(log n) */
void* heap_pop(Heap *heap)
{
void *ret = NULL;
assert(heap != NULL);
if(heap_is_empty(heap)) {
return NULL;
}
if(darray_swap(heap->h, 0, darray_size(heap->h) - 1) < 0) {
return NULL;
}
ret = darray_remove(heap->h, darray_size(heap->h) - 1);
heapify_down(heap, 0);
return ret;
}
int main(int argc, char *argv[])
{
dyn_array_t arr = darray_make(4);
// Store 1,2,3,4 in array
for (int i = 0; i < darray_size(arr); ++i) darray_set(arr, i, i);
// Print arr[i] = i for i=[1,4]
for (int i = 0; i < darray_size(arr); ++i) printf("arr[%d] = %d\n", i, *darray_get(arr, i));
darray_append(&arr, 5);
darray_append(&arr, 6);
darray_prepend(&arr, 7);
darray_prepend(&arr, 8);
// Print arr[i] = j for i=[1,8]
for (int i = 0; i < darray_size(arr); ++i) printf("arr[%d] = %d\n", i, *darray_get(arr, i));
darray_free(&arr);
arr = NULL;
return 0;
}
Vertex* graph_vertex_find(const Graph *g, const void *data)
{
unsigned long index;
Vertex *v;
assert(g != NULL);
assert(data != NULL);
for(index = 0; index < darray_size(g->vertices); index++) {
v = (Vertex *)darray_index(g->vertices, index);
if(v->data == data) {
return v;
}
}
return NULL;
}
int graph_edge_add(Graph *g, Edge *e)
{
unsigned long index;
Vertex *v;
assert(g != NULL);
assert(e != NULL);
for(index = 0; index < darray_size(g->vertices); index++) {
v = (Vertex *)darray_index(g->vertices, index);
if(v == e->source) {
v->out_degree++;
darray_append(v->edges, e);
g->edge_count++;
}
if((v == e->target)) {
/* For undirected graphs, insert an extra edge to allow
* traversal from the target vertex back to the source
* vertex, except in the case where an edge is a loop.
*/
if(graph_is_undirected(g)) {
v->out_degree++;
if(e->target != e->source) {
darray_append(v->edges,
edge_create(e->target, e->source, e->weight));
} else {
/* Loops are counted twice */
v->out_degree++;
}
} else {
/* Keep track of the number of edges directed
* toward this vertex, but not which edges
*
* TODO Keep a separate in-edge list for each
* node?
*/
v->in_degree++;
}
}
}
return 0;
}
/* Complexity: O(size(heap1) + 2 * size(heap2)) => O(n) */
int heap_merge(Heap *heap1, Heap* heap2)
{
unsigned long i;
assert(heap1 != NULL);
assert(heap2 != NULL);
if(heap_is_empty(heap1) && heap_is_empty(heap2)) {
return -1;
}
/* O(size(heap2)) */
if(darray_concat(heap1->h, heap2->h) < 0) {
return -1;
}
/* O(size(heap1) + size(heap2)) */
for(i = (darray_size(heap1->h) - 1) / 2; i > 0; i--) {
heapify_down(heap1, i);
}
heapify_down(heap1, 0); /* Edge-case for loop 0 index */
return 0;
}
/**
* Returns the number of entries in the context's include path.
*/
XKB_EXPORT unsigned int
xkb_context_num_include_paths(struct xkb_context *ctx)
{
return darray_size(ctx->includes);
}
unsigned long graph_vertex_count(const Graph *g)
{
assert(g != NULL);
return darray_size(g->vertices);
}
/* Complexity: O(1) */
unsigned long heap_size(Heap *heap)
{
assert(heap != NULL);
return darray_size(heap->h);
}
/*
* Bucket sort algorithm.
*/
void integer_sort(int *array, int n)
{
int max, _max; /* Max number in array. */
int range; /* Bucket range. */
int i, j, k; /* Loop indexes. */
int *indexes; /* Index for buckets. */
struct darray **buckets; /* Buckets. */
indexes = smalloc(NUM_BUCKETS*sizeof(int));
/* Create buckets. */
buckets = smalloc(NUM_BUCKETS*sizeof(struct darray *));
for (i = 0; i < NUM_BUCKETS; i++)
buckets[i] = darray_create(n/NUM_BUCKETS);
max = INT_MIN;
#pragma omp parallel private(i, j, k, _max)
{
_max = INT_MIN;
/* Find max number in the array. */
#pragma omp for schedule(static)
for (i = 0; i < n; i++)
{
/* Found. */
if (array[i] > _max)
_max = array[i];
}
#pragma omp critical
{
if (_max > max) {
max = _max;
}
}
#pragma omp master
range = max/NUM_BUCKETS;
#pragma omp barrier
/* Distribute numbers into buckets. */
#pragma omp master
for (i = 0; i < n; i++)
{
j = array[i]/range;
if (j >= NUM_BUCKETS)
j = NUM_BUCKETS - 1;
darray_append(buckets[j], array[i]);
}
/* Sort Each bucket. */
#pragma omp for schedule(dynamic)
for (i = 0; i < NUM_BUCKETS; i++)
{
if (darray_size(buckets[i]) > 0)
sort(buckets[i]);
}
#pragma omp master
{
/* Build indexes. */
indexes[0] = 0;
for (i = 1; i < NUM_BUCKETS; i++)
indexes[i] = indexes[i - 1] + darray_size(buckets[i]);
/* Rebuild array. */
for (i = 0; i < NUM_BUCKETS; i++)
{
k = indexes[i];
for (j = 0; j < darray_size(buckets[i]); j++)
array[k + j] = darray_get(buckets[i], j);
}
}
}
/* House keeping. */
for (i = 0; i < NUM_BUCKETS; i++)
darray_destroy(buckets[i]);
free(buckets);
free(indexes);
}
unsigned long vertex_edge_count(const Vertex *v)
{
assert(v != NULL);
return darray_size(v->edges);
}
int main(void) {
darray(long) arr = darray_new();
darray_char str = darray_new();
darray(long*) arrp = darray_new();
arrp.onFree = _arr_free_handler;
#define reset(arr) do {darray_free(arr); darray_init(arr);} while(0)
size_t i;
trace("Generating amalgams (internal)");
generateAmalgams();
plan_tests(54);
testLits();
testing(darray_pushptr);
{
int vMaxCount = 10;//ARRAY_SIZE(lotsOfNumbers);
for (int k=0; k < vMaxCount; k++) {
long* p = malloc(sizeof(long));
*p = lotsOfNumbers[k];
darray_push(arrp, p);
}
ok1(darray_size(arrp) == vMaxCount);
ok1(darray_alloc(arrp) >= darray_size(arrp));
long **i;
size_t j = 0;
darray_foreach(i, arrp) {
if (i - arrp.item != j)
break;
if (**i != (long)lotsOfNumbers[j])
break;
j++;
};
ok1(j == vMaxCount);
darray_free_all(arrp);
ok1(_free_count == vMaxCount);
}
testing(darray_push);
{
for (i=0; i < ARRAY_SIZE(lotsOfNumbers); i++)
darray_push(arr, lotsOfNumbers[i]);
ok1(darray_size(arr) == ARRAY_SIZE(lotsOfNumbers));
ok1(darray_alloc(arr) >= darray_size(arr));
ok1(!memcmp(arr.item, lotsOfNumbers, sizeof(lotsOfNumbers)));
}
testing(darray_insert);
{
darray_insert(arr, 0, 123456);
ok1(darray_size(arr) == ARRAY_SIZE(lotsOfNumbers)+1);
ok1(!memcmp(arr.item+1, lotsOfNumbers, sizeof(lotsOfNumbers)));
ok1(darray_item(arr, 0) == 123456);
darray_insert(arr, 15, 0x112233);
ok1(darray_size(arr) == ARRAY_SIZE(lotsOfNumbers)+2);
ok1(darray_item(arr, 15) == 0x112233);
ok1(!memcmp(arr.item+1, lotsOfNumbers, 14*sizeof(long)));
ok1(!memcmp(arr.item+16, &lotsOfNumbers[14], ARRAY_SIZE(lotsOfNumbers)-(15*sizeof(long))));
}
testing(darray_del);
{
darray_del(arr, 15);
darray_del(arr, 0);
ok1(darray_size(arr) == ARRAY_SIZE(lotsOfNumbers));
ok1(!memcmp(arr.item, lotsOfNumbers, sizeof(lotsOfNumbers)));
}
reset(arr);
testing(darray_prepend, darray_pop);
{
for (i = ARRAY_SIZE(lotsOfNumbers); i;)
darray_prepend(arr, lotsOfNumbers[--i]);
ok1(darray_size(arr) == ARRAY_SIZE(lotsOfNumbers));
ok1(darray_alloc(arr) >= darray_size(arr));
ok1(!memcmp(arr.item, lotsOfNumbers, sizeof(lotsOfNumbers)));
for (i = ARRAY_SIZE(lotsOfNumbers); i;) {
if (darray_pop(arr) != (long)lotsOfNumbers[--i]) {
i++;
break;
}
}
ok1(i==0);
ok1(darray_size(arr) == 0);
}
reset(arr);
testing(darray_from_c, darray_foreach, darray_foreach_reverse);
{
long *i;
size_t j;
darray_from_c(arr, lotsOfNumbers);
ok1(darray_size(arr) == ARRAY_SIZE(lotsOfNumbers));
ok1(darray_alloc(arr) >= darray_size(arr));
ok1(memcmp(arr.item, lotsOfNumbers, sizeof(lotsOfNumbers)) == 0);
j = 0;
darray_foreach(i, arr) {
if (i - arr.item != j)
break;
if (*i != (long)lotsOfNumbers[j])
break;
j++;
};
ok1(j == ARRAY_SIZE(lotsOfNumbers));
j = 0;
darray_foreach_reverse(i, arr) {
if (i - arr.item != darray_size(arr)-j-1)
break;
if (*i != (long)lotsOfNumbers[darray_size(arr)-j-1])
break;
j++;
};
ok1(j == ARRAY_SIZE(lotsOfNumbers));
}
reset(arr);
testing(darray_append_string);
{
for (i=0; i < ARRAY_SIZE(lotsOfStrings); i++)
darray_append_string(str, lotsOfStrings[i]);
ok1(str.size == amalgams.stringsSize);
ok1(str.alloc > str.size);
ok1(str.item[str.size] == 0);
ok1(!strcmp(str.item, amalgams.stringsF));
}
reset(str);
testing(darray_prepend_string);
{
for (i=0; i < ARRAY_SIZE(lotsOfStrings); i++)
darray_prepend_string(str, lotsOfStrings[i]);
ok1(str.size == amalgams.stringsSize);
ok1(str.alloc > str.size);
ok1(str.item[str.size] == 0);
ok1(!strcmp(str.item, amalgams.stringsB));
}
reset(str);
testing(darray_from_string);
{
for (i=0; i < ARRAY_SIZE(lotsOfStrings); i++) {
darray_from_string(str, lotsOfStrings[i]);
if (str.size != strlen(lotsOfStrings[i]))
break;
if (str.alloc < strlen(lotsOfStrings[i])+1)
break;
if (strcmp(str.item, lotsOfStrings[i]))
break;
}
ok1(i == ARRAY_SIZE(lotsOfStrings));
}
reset(str);
testing(darray_resize0);
{
size_t prevSize=0, size;
for (i=0; i < ARRAY_SIZE(lotsOfNumbers); i++, prevSize=size) {
size = lotsOfNumbers[i] & 0xFFFF;
darray_resize0(arr, size);
if (darray_size(arr) != size)
break;
if (darray_alloc(arr) < size)
break;
if (size>prevSize) {
if (!isZeros(arr.item+prevSize, (size-prevSize)*sizeof(*arr.item)))
break;
}
//fill the darray with lotsOfNumbers garbage
memtile(arr.item, darray_size(arr)*sizeof(*arr.item), lotsOfNumbers, sizeof(lotsOfNumbers));
}
ok1(i == ARRAY_SIZE(lotsOfNumbers));
}
reset(arr);
testing(darray_realloc);
{
size_t s,a;
for (i=0; i < ARRAY_SIZE(lotsOfNumbers); i++) {
arr.size = (s = lotsOfNumbers[i] >> 16);
//give size a nonsense value to make sure darray_realloc doesn't care about it
a = amalgams.stringsSize/sizeof(*arr.item)+2;
darray_realloc(arr, a = lotsOfNumbers[i] % ((amalgams.stringsSize/sizeof(*arr.item))+1));
if (a*sizeof(*arr.item) > amalgams.stringsSize)
break;
if (darray_alloc(arr) != a)
break;
if (darray_size(arr) != s)
break;
memtile(arr.item, a*sizeof(*arr.item), amalgams.stringsF, a*sizeof(*arr.item));
if (memcmp(arr.item, amalgams.stringsF, a*sizeof(*arr.item)))
break;
}
ok1(i == ARRAY_SIZE(lotsOfNumbers));
}
reset(arr);
testing(darray_growalloc);
{
size_t prevA, s, a;
for (i=0; i < ARRAY_SIZE(lotsOfNumbers); i++) {
arr.size = (s = lotsOfNumbers[i] >> 16);
//give size a nonsense value to make sure darray_growalloc doesn't care about it
a = amalgams.stringsSize/sizeof(*arr.item)+2;
prevA = darray_alloc(arr);
darray_growalloc(arr, a = lotsOfNumbers[i] % ((amalgams.stringsSize/sizeof(*arr.item))+1));
if (a*sizeof(*arr.item) > amalgams.stringsSize)
break;
if (darray_alloc(arr) < a)
break;
if (darray_alloc(arr) < prevA)
break;
if (darray_size(arr) != s)
break;
memtile(arr.item, a*sizeof(*arr.item), amalgams.stringsF, a*sizeof(*arr.item));
if (memcmp(arr.item, amalgams.stringsF, a*sizeof(*arr.item)))
break;
//clear the darray every now and then
if (!(lotsOfNumbers[i] & 15)) {
reset(arr);
}
}
ok1(i == ARRAY_SIZE(lotsOfNumbers));
}
reset(arr);
testing(darray_make_room);
{
for (i=0; i < ARRAY_SIZE(lotsOfStrings); i++) {
char *dest = darray_make_room(str, strlen(lotsOfStrings[i]));
if (str.alloc < str.size+strlen(lotsOfStrings[i]))
break;
if (dest != str.item+str.size)
break;
memcpy(dest, lotsOfStrings[i], strlen(lotsOfStrings[i]));
str.size += strlen(lotsOfStrings[i]);
}
ok1(i == ARRAY_SIZE(lotsOfStrings));
ok1(str.size == amalgams.stringsSize);
darray_append(str, 0);
ok1(!strcmp(str.item, amalgams.stringsF));
}
reset(str);
testing(darray_appends, darray_prepends, darray_pop_check);
{
darray(const char*) arr = darray_new();
const char *n[9] = {"zero", "one", "two", "three", "four", "five", "six", "seven", "eight"};
#if HAVE_TYPEOF
darray_appends(arr, n[5], n[6], n[7], n[8]);
#else
darray_appends_t(arr, const char *, n[5], n[6], n[7], n[8]);
#endif
ok1(darray_size(arr)==4 && darray_alloc(arr)>=4);
#if HAVE_TYPEOF
darray_prepends(arr, n[0], n[1], n[2], n[3], n[4]);
#else
darray_prepends_t(arr, const char *, n[0], n[1], n[2], n[3], n[4]);
#endif
ok1(darray_size(arr)==9 && darray_alloc(arr)>=9);
ok1(arr.item[0]==n[0] &&
arr.item[1]==n[1] &&
arr.item[2]==n[2] &&
arr.item[3]==n[3] &&
arr.item[4]==n[4] &&
arr.item[5]==n[5] &&
arr.item[6]==n[6] &&
arr.item[7]==n[7] &&
arr.item[8]==n[8]);
ok1(darray_pop_check(arr)==n[8] &&
darray_pop_check(arr)==n[7] &&
darray_pop_check(arr)==n[6] &&
darray_pop_check(arr)==n[5] &&
darray_pop_check(arr)==n[4] &&
darray_pop_check(arr)==n[3] &&
darray_pop_check(arr)==n[2] &&
darray_pop_check(arr)==n[1] &&
darray_pop_check(arr)==n[0]);
ok1(darray_size(arr)==0);
ok1(darray_pop_check(arr)==NULL && darray_pop_check(arr)==NULL && darray_pop_check(arr)==NULL);
darray_free(arr);
}
trace("Freeing amalgams (internal)");
freeAmalgams();
return exit_status();
}
struct type *type_function_get_rettype(const struct type *t)
{
RF_ASSERT(type_is_function(t) && darray_size(t->operator.operands) == 2,
"Non function type detected");
return darray_item(t->operator.operands, 1);
}
unsigned int
xkb_context_num_failed_include_paths(struct xkb_context *ctx)
{
return darray_size(ctx->failed_includes);
}
static inline void analyzer_traversal_ctx_prev_parent(struct analyzer_traversal_ctx *ctx)
{
RF_ASSERT(darray_size(ctx->parent_nodes) != 0, "Tried to go beyond the root");
(void)darray_pop(ctx->parent_nodes);
}
