_dynar_unlock(dynar);
}
+/** @brief Merge dynar d2 into d1
+ *
+ * \param d1 dynar to keep
+ * \param d2 dynar to merge into d1. This dynar is free at end.
+ */
+void xbt_dynar_merge(xbt_dynar_t *d1, xbt_dynar_t *d2)
+{
+ if((*d1)->elmsize != (*d2)->elmsize)
+ xbt_die("Element size must are not equal");
+
+ const unsigned long elmsize = (*d1)->elmsize;
+
+ void *ptr = _xbt_dynar_elm((*d2), 0);
+ _xbt_dynar_resize(*d1, (*d1)->size + (*d2)->size);
+ void *elm = _xbt_dynar_elm((*d1), (*d1)->used);
+
+ memcpy(elm, ptr, ((*d2)->size)*elmsize);
+ (*d1)->used += (*d2)->used;
+ (*d2)->used = 0;
+ xbt_dynar_free(d2);
+}
+
/**
* \brief Shrink the dynar by removing empty slots at the end of the internal array
* \param dynar a dynar
/** @brief Returns the position of the element in the dynar
*
- * Raises not_found_error if not found.
+ * Raises not_found_error if not found. If you have less than 2 millions elements,
+ * you probably want to use #xbt_dynar_search_or_negative() instead, so that you
+ * don't have to TRY/CATCH on element not found.
*/
unsigned int xbt_dynar_search(xbt_dynar_t const dynar, void *const elem)
{
dynar);
}
+/** @brief Returns the position of the element in the dynar (or -1 if not found)
+ *
+ * Note that usually, the dynar indices are unsigned integers. If you have more
+ * than 2 million elements in your dynar, this very function will not work (but the other will).
+ */
+signed int xbt_dynar_search_or_negative(xbt_dynar_t const dynar, void *const elem)
+{
+ unsigned long it;
+
+ _dynar_lock(dynar);
+ for (it = 0; it < dynar->used; it++)
+ if (!memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
+ _dynar_unlock(dynar);
+ return it;
+ }
+
+ _dynar_unlock(dynar);
+ return -1;
+}
+
/** @brief Returns a boolean indicating whether the element is part of the dynar */
int xbt_dynar_member(xbt_dynar_t const dynar, void *const elem)
{
_dynar_unlock(dynar);
}
+/** @brief Sorts a dynar according to their color assuming elements can have only three colors.
+ * Since there are only three colors, it is linear and much faster than a classical sort.
+ * See for example http://en.wikipedia.org/wiki/Dutch_national_flag_problem
+ *
+ * \param dynar the dynar to sort
+ * \param color the color function of type (int (compar_fn*) (void*) (void*)). The return value of color is assumed to be 0, 1, or 2.
+ *
+ * At the end of the call, elements with color 0 are at the beginning of the dynar, elements with color 2 are at the end and elements with color 1 are in the middle.
+ *
+ * Remark: if the elements stored in the dynar are structures, the color
+ * function has to retrieve the field to sort first.
+ */
+XBT_PUBLIC(void) xbt_dynar_three_way_partition(xbt_dynar_t const dynar,
+ int_f_pvoid_t color)
+{
+ _dynar_lock(dynar);
+ unsigned long int i;
+ unsigned long int p = -1;
+ unsigned long int q = dynar->used;
+ const unsigned long elmsize = dynar->elmsize;
+ void *tmp = xbt_malloc(elmsize);
+ void *elm;
+
+ for (i = 0; i < q;) {
+ void *elmi = _xbt_dynar_elm(dynar, i);
+ int colori = color(elmi);
+
+ if (colori == 1) {
+ ++i;
+ } else {
+ if (colori == 0) {
+ elm = _xbt_dynar_elm(dynar, ++p);
+ ++i;
+ } else { /* colori == 2 */
+ elm = _xbt_dynar_elm(dynar, --q);
+ }
+ if (elm != elmi) {
+ memcpy(tmp, elm, elmsize);
+ memcpy(elm, elmi, elmsize);
+ memcpy(elmi, tmp, elmsize);
+ }
+ }
+ }
+ _dynar_unlock(dynar);
+ xbt_free(tmp);
+}
+
/** @brief Transform a dynar into a NULL terminated array
*
* \param dynar the dynar to transform
* Return 0 if d1 and d2 are equal and 1 if not equal
*/
XBT_INLINE int xbt_dynar_compare(xbt_dynar_t d1, xbt_dynar_t d2,
- int(*compar)(const void *, const void *))
+ int(*compar)(const void *, const void *))
{
- int i ;
- int size;
- if((!d1) && (!d2)) return 0;
- if((!d1) || (!d2))
- {
- XBT_DEBUG("NULL dynar d1=%p d2=%p",d1,d2);
- xbt_dynar_free(&d2);
- return 1;
- }
- if((d1->elmsize)!=(d2->elmsize))
- {
- XBT_DEBUG("Size of elmsize d1=%ld d2=%ld",d1->elmsize,d2->elmsize);
- xbt_dynar_free(&d2);
- return 1; // xbt_die
- }
- if(xbt_dynar_length(d1) != xbt_dynar_length(d2))
- {
- XBT_DEBUG("Size of dynar d1=%ld d2=%ld",xbt_dynar_length(d1),xbt_dynar_length(d2));
- xbt_dynar_free(&d2);
- return 1;
- }
-
- size = xbt_dynar_length(d1);
- for(i=0;i<size;i++)
- {
- void *data1 = xbt_dynar_get_as(d1, i, void *);
- void *data2 = xbt_dynar_get_as(d2, i, void *);
- XBT_DEBUG("link[%d] d1=%p d2=%p",i,data1,data2);
- if(compar(data1,data2)){
- xbt_dynar_free(&d2);
- return 1;
- }
- }
- xbt_dynar_free(&d2);
- return 0;
+ int i ;
+ int size;
+ if((!d1) && (!d2)) return 0;
+ if((!d1) || (!d2))
+ {
+ XBT_DEBUG("NULL dynar d1=%p d2=%p",d1,d2);
+ xbt_dynar_free(&d2);
+ return 1;
+ }
+ if((d1->elmsize)!=(d2->elmsize))
+ {
+ XBT_DEBUG("Size of elmsize d1=%lu d2=%lu",d1->elmsize,d2->elmsize);
+ xbt_dynar_free(&d2);
+ return 1; // xbt_die
+ }
+ if(xbt_dynar_length(d1) != xbt_dynar_length(d2))
+ {
+ XBT_DEBUG("Size of dynar d1=%lu d2=%lu",xbt_dynar_length(d1),xbt_dynar_length(d2));
+ xbt_dynar_free(&d2);
+ return 1;
+ }
+
+ size = xbt_dynar_length(d1);
+ for(i=0;i<size;i++)
+ {
+ void *data1 = xbt_dynar_get_as(d1, i, void *);
+ void *data2 = xbt_dynar_get_as(d2, i, void *);
+ XBT_DEBUG("link[%d] d1=%p d2=%p",i,data1,data2);
+ if(compar(data1,data2)){
+ xbt_dynar_free(&d2);
+ return 1;
+ }
+ }
+ xbt_dynar_free(&d2);
+ return 0;
}
#ifdef SIMGRID_TEST
#define NB_ELEM 5000
XBT_TEST_SUITE("dynar", "Dynar data container");
-XBT_LOG_EXTERNAL_CATEGORY(xbt_dyn);
-XBT_LOG_DEFAULT_CATEGORY(xbt_dyn);
+XBT_LOG_EXTERNAL_DEFAULT_CATEGORY(xbt_dyn);
XBT_TEST_UNIT("int", test_dynar_int, "Dynars of integers")
{
for (cursor = 0; cursor < NB_ELEM; cursor++) {
iptr = xbt_dynar_get_ptr(d, cursor);
xbt_test_assert(cursor == *iptr,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
}
/* 3. Traverse the dynar using the neat macro to that extend */
xbt_dynar_foreach(d, cursor, cpt) {
xbt_test_assert(cursor == cpt,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
}
/* end_of_traversal */
/* 3. Traverse the dynar */
xbt_dynar_foreach(d, cursor, cpt) {
xbt_test_assert(cursor == cpt,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
}
/* end_of_traversal */
xbt_dynar_set_as(d, cpt, int, cpt);
xbt_dynar_foreach(d, cursor, cpt)
xbt_test_assert(cursor == cpt,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
for (cpt = 0; cpt < NB_ELEM; cpt++) {
int val;
xbt_dynar_remove_at(d,0,&val);
xbt_test_assert(cpt == val,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
}
xbt_test_assert(xbt_dynar_is_empty(d),
/* 3. Traverse the dynar */
xbt_dynar_foreach(d, cursor, cpt) {
xbt_test_assert(cursor == cpt,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
}
/* end_of_traversal */
int val;
xbt_dynar_remove_at(d,xbt_dynar_length(d)-1,&val);
xbt_test_assert(cpt == val,
- "The retrieved value is not the same than the injected one (%d!=%d)",
+ "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, cpt);
}
xbt_test_assert(xbt_dynar_is_empty(d),
}
/* 2. Traverse the dynar with the macro */
xbt_dynar_foreach(d, iter, s1) {
- sprintf(buf, "%d", NB_ELEM - iter - 1);
+ sprintf(buf, "%u", NB_ELEM - iter - 1);
xbt_test_assert(!strcmp(buf, s1),
"The retrieved value is not the same than the injected one (%s!=%s)",
buf, s1);