static inline void _sanity_check_idx(int idx)
{
- xbt_assert(idx >= 0, "dynar idx(=%d) < 0", (int) (idx));
+ xbt_assert(idx >= 0, "dynar idx(=%d) < 0", idx);
}
static inline void _check_inbound_idx(xbt_dynar_t dynar, int idx)
{
- if (idx < 0 || idx >= (int)dynar->used) {
+ if (idx < 0 || idx >= static_cast<int>(dynar->used)) {
THROWF(bound_error, idx, "dynar is not that long. You asked %d, but it's only %lu long",
- (int) (idx), (unsigned long) dynar->used);
+ idx, static_cast<unsigned long>(dynar->used));
}
}
memcpy(dst, elm, dynar->elmsize);
}
-void xbt_dynar_dump(xbt_dynar_t dynar)
+extern "C" void xbt_dynar_dump(xbt_dynar_t dynar)
{
XBT_INFO("Dynar dump: size=%lu; used=%lu; elmsize=%lu; data=%p; free_f=%p",
dynar->size, dynar->used, dynar->elmsize, dynar->data, dynar->free_f);
* Creates a new dynar. If a free_func is provided, the elements have to be pointer of pointer. That is to say that
* dynars can contain either base types (int, char, double, etc) or pointer of pointers (struct **).
*/
-xbt_dynar_t xbt_dynar_new(const unsigned long elmsize, void_f_pvoid_t const free_f)
+extern "C" xbt_dynar_t xbt_dynar_new(const unsigned long elmsize, void_f_pvoid_t const free_f)
{
xbt_dynar_t dynar = xbt_new0(s_xbt_dynar_t, 1);
return dynar;
}
+/** @brief Initialize a dynar structure that was not malloc'ed
+ * This can be useful to keep temporary dynars on the stack
+ */
+extern "C" void xbt_dynar_init(xbt_dynar_t dynar, const unsigned long elmsize, void_f_pvoid_t const free_f)
+{
+ dynar->size = 0;
+ dynar->used = 0;
+ dynar->elmsize = elmsize;
+ dynar->data = nullptr;
+ dynar->free_f = free_f;
+}
+
+/** @brief Destroy a dynar that was created with xbt_dynar_init */
+extern "C" void xbt_dynar_free_data(xbt_dynar_t dynar)
+{
+ xbt_dynar_reset(dynar);
+ if (dynar)
+ free(dynar->data);
+}
+
/** @brief Destructor of the structure not touching to the content
*
* \param dynar poor victim
* kilkil a dynar BUT NOT its content. Ie, the array is freed, but the content is not touched (the \a free_f function
* is not used)
*/
-void xbt_dynar_free_container(xbt_dynar_t * dynar)
+extern "C" void xbt_dynar_free_container(xbt_dynar_t* dynar)
{
if (dynar && *dynar) {
xbt_dynar_t d = *dynar;
*
* \param dynar who to squeeze
*/
-void xbt_dynar_reset(xbt_dynar_t const dynar)
+extern "C" void xbt_dynar_reset(xbt_dynar_t const dynar)
{
_sanity_check_dynar(dynar);
* \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)
+extern "C" 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");
* Set \a empty_slots_wanted to zero to reduce the dynar internal array as much as possible.
* Note that if \a empty_slots_wanted is greater than the array size, the internal array is expanded instead of shrunk.
*/
-void xbt_dynar_shrink(xbt_dynar_t dynar, int empty_slots_wanted)
+extern "C" void xbt_dynar_shrink(xbt_dynar_t dynar, int empty_slots_wanted)
{
_xbt_dynar_resize(dynar, dynar->used + empty_slots_wanted);
}
*
* kilkil a dynar and its content
*/
-void xbt_dynar_free(xbt_dynar_t * dynar)
+extern "C" void xbt_dynar_free(xbt_dynar_t* dynar)
{
if (dynar && *dynar) {
xbt_dynar_reset(*dynar);
}
/** \brief free a dynar passed as void* (handy to store dynar in dynars or dict) */
-void xbt_dynar_free_voidp(void *d)
+extern "C" void xbt_dynar_free_voidp(void* d)
{
xbt_dynar_t dynar = (xbt_dynar_t)d;
xbt_dynar_free(&dynar);
*
* \param dynar the dynar we want to mesure
*/
-unsigned long xbt_dynar_length(const xbt_dynar_t dynar)
+extern "C" unsigned long xbt_dynar_length(const xbt_dynar_t dynar)
{
return (dynar ? (unsigned long) dynar->used : (unsigned long) 0);
}
*
*\param dynar the dynat we want to check
*/
-
-int xbt_dynar_is_empty(const xbt_dynar_t dynar)
+extern "C" int xbt_dynar_is_empty(const xbt_dynar_t dynar)
{
return (xbt_dynar_length(dynar) == 0);
}
* \param idx index of the slot we want to retrieve
* \param[out] dst where to put the result to.
*/
-void xbt_dynar_get_cpy(const xbt_dynar_t dynar, const unsigned long idx, void *const dst)
+extern "C" void xbt_dynar_get_cpy(const xbt_dynar_t dynar, const unsigned long idx, void* const dst)
{
_sanity_check_dynar(dynar);
_check_inbound_idx(dynar, idx);
* \warning The returned value is the actual content of the dynar.
* Make a copy before fooling with it.
*/
-void *xbt_dynar_get_ptr(const xbt_dynar_t dynar, const unsigned long idx)
+extern "C" void* xbt_dynar_get_ptr(const xbt_dynar_t dynar, const unsigned long idx)
{
void *res;
_sanity_check_dynar(dynar);
return res;
}
-void *xbt_dynar_set_at_ptr(const xbt_dynar_t dynar, const unsigned long idx)
+extern "C" void* xbt_dynar_set_at_ptr(const xbt_dynar_t dynar, const unsigned long idx)
{
_sanity_check_dynar(dynar);
*
* If you want to free the previous content, use xbt_dynar_replace().
*/
-void xbt_dynar_set(xbt_dynar_t dynar, const int idx, const void *const src)
+extern "C" void xbt_dynar_set(xbt_dynar_t dynar, const int idx, const void* const src)
{
memcpy(xbt_dynar_set_at_ptr(dynar, idx), src, dynar->elmsize);
}
* Set the Nth element of a dynar, expanding the dynar if needed, AND DO free the previous value at this position. If
* you don't want to free the previous content, use xbt_dynar_set().
*/
-void xbt_dynar_replace(xbt_dynar_t dynar, const unsigned long idx, const void *const object)
+extern "C" void xbt_dynar_replace(xbt_dynar_t dynar, const unsigned long idx, const void* const object)
{
_sanity_check_dynar(dynar);
* You can then use regular affectation to set its value instead of relying on the slow memcpy. This is what
* xbt_dynar_insert_at_as() does.
*/
-void *xbt_dynar_insert_at_ptr(xbt_dynar_t const dynar, const int idx)
+extern "C" void* xbt_dynar_insert_at_ptr(xbt_dynar_t const dynar, const int idx)
{
void *res;
unsigned long old_used;
* Set the Nth element of a dynar, expanding the dynar if needed, and moving the previously existing value and all
* subsequent ones to one position right in the dynar.
*/
-void xbt_dynar_insert_at(xbt_dynar_t const dynar, const int idx, const void *const src)
+extern "C" void xbt_dynar_insert_at(xbt_dynar_t const dynar, const int idx, const void* const src)
{
/* checks done in xbt_dynar_insert_at_ptr */
memcpy(xbt_dynar_insert_at_ptr(dynar, idx), src, dynar->elmsize);
* If the object argument of this function is a non-null pointer, the removed element is copied to this address. If not,
* the element is freed using the free_f function passed at dynar creation.
*/
-void xbt_dynar_remove_at(xbt_dynar_t const dynar, const int idx, void *const object)
+extern "C" void xbt_dynar_remove_at(xbt_dynar_t const dynar, const int idx, void* const object)
{
- unsigned long nb_shift;
- unsigned long offset;
-
_sanity_check_dynar(dynar);
_check_inbound_idx(dynar, idx);
dynar->free_f(_xbt_dynar_elm(dynar, idx));
}
- nb_shift = dynar->used - 1 - idx;
+ unsigned long nb_shift = dynar->used - 1 - idx;
if (nb_shift) {
- offset = nb_shift * dynar->elmsize;
+ unsigned long offset = nb_shift * dynar->elmsize;
memmove(_xbt_dynar_elm(dynar, idx), _xbt_dynar_elm(dynar, idx + 1), offset);
}
*
* Each of the removed elements is freed using the free_f function passed at dynar creation.
*/
-void xbt_dynar_remove_n_at(xbt_dynar_t const dynar, const unsigned int n, const int idx)
+extern "C" void xbt_dynar_remove_n_at(xbt_dynar_t const dynar, const unsigned int n, const int idx)
{
- unsigned long nb_shift;
- unsigned long offset;
- unsigned long cur;
-
- if (!n) return;
+ if (not n)
+ return;
_sanity_check_dynar(dynar);
_check_inbound_idx(dynar, idx);
_check_inbound_idx(dynar, idx + n - 1);
if (dynar->free_f) {
- for (cur = idx; cur < idx + n; cur++) {
+ for (unsigned long cur = idx; cur < idx + n; cur++) {
dynar->free_f(_xbt_dynar_elm(dynar, cur));
}
}
- nb_shift = dynar->used - n - idx;
+ unsigned long nb_shift = dynar->used - n - idx;
if (nb_shift) {
- offset = nb_shift * dynar->elmsize;
+ unsigned long offset = nb_shift * dynar->elmsize;
memmove(_xbt_dynar_elm(dynar, idx), _xbt_dynar_elm(dynar, idx + n), offset);
}
* \code
* signed int position = -1;
* xbt_dynar_foreach(dynar, iter, elem) {
- * if (!memcmp(elem, searched_element, sizeof(*elem))) {
+ * if (not memcmp(elem, searched_element, sizeof(*elem))) {
* position = iter;
* break;
* }
* }
* \endcode
- *
+ *
* 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)
+extern "C" unsigned int xbt_dynar_search(xbt_dynar_t const dynar, void* const elem)
{
unsigned long it;
for (it = 0; it < dynar->used; it++)
- if (!memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
+ if (not memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
return it;
}
*
* Beware that if your dynar contains pointed values (such as strings) instead of scalar, this function is probably not
* what you want. Check the documentation of xbt_dynar_search() for more info.
- *
+ *
* 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)
+extern "C" signed int xbt_dynar_search_or_negative(xbt_dynar_t const dynar, void* const elem)
{
unsigned long it;
for (it = 0; it < dynar->used; it++)
- if (!memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
+ if (not memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
return it;
}
return -1;
}
-/** @brief Returns a boolean indicating whether the element is part of the dynar
+/** @brief Returns a boolean indicating whether the element is part of the dynar
*
* Beware that if your dynar contains pointed values (such as strings) instead of scalar, this function is probably not
* what you want. Check the documentation of xbt_dynar_search() for more info.
*/
-int xbt_dynar_member(xbt_dynar_t const dynar, void *const elem)
+extern "C" int xbt_dynar_member(xbt_dynar_t const dynar, void* const elem)
{
unsigned long it;
for (it = 0; it < dynar->used; it++)
- if (!memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
+ if (not memcmp(_xbt_dynar_elm(dynar, it), elem, dynar->elmsize)) {
return 1;
}
* You can then use regular affectation to set its value instead of relying on the slow memcpy. This is what
* xbt_dynar_push_as() does.
*/
-void *xbt_dynar_push_ptr(xbt_dynar_t const dynar)
+extern "C" void* xbt_dynar_push_ptr(xbt_dynar_t const dynar)
{
return xbt_dynar_insert_at_ptr(dynar, dynar->used);
}
/** @brief Add an element at the end of the dynar */
-void xbt_dynar_push(xbt_dynar_t const dynar, const void *const src)
+extern "C" void xbt_dynar_push(xbt_dynar_t const dynar, const void* const src)
{
/* checks done in xbt_dynar_insert_at_ptr */
memcpy(xbt_dynar_insert_at_ptr(dynar, dynar->used), src, dynar->elmsize);
* You can then use regular affectation to set its value instead of relying on the slow memcpy. This is what
* xbt_dynar_pop_as() does.
*/
-void *xbt_dynar_pop_ptr(xbt_dynar_t const dynar)
+extern "C" void* xbt_dynar_pop_ptr(xbt_dynar_t const dynar)
{
_check_populated_dynar(dynar);
XBT_CDEBUG(xbt_dyn, "Pop %p", (void *) dynar);
}
/** @brief Get and remove the last element of the dynar */
-void xbt_dynar_pop(xbt_dynar_t const dynar, void *const dst)
+extern "C" void xbt_dynar_pop(xbt_dynar_t const dynar, void* const dst)
{
/* sanity checks done by remove_at */
XBT_CDEBUG(xbt_dyn, "Pop %p", (void *) dynar);
*
* This is less efficient than xbt_dynar_push()
*/
-void xbt_dynar_unshift(xbt_dynar_t const dynar, const void *const src)
+extern "C" void xbt_dynar_unshift(xbt_dynar_t const dynar, const void* const src)
{
/* sanity checks done by insert_at */
xbt_dynar_insert_at(dynar, 0, src);
*
* This is less efficient than xbt_dynar_pop()
*/
-void xbt_dynar_shift(xbt_dynar_t const dynar, void *const dst)
+extern "C" void xbt_dynar_shift(xbt_dynar_t const dynar, void* const dst)
{
/* sanity checks done by remove_at */
xbt_dynar_remove_at(dynar, 0, dst);
*
* The mapped function may change the value of the element itself, but should not mess with the structure of the dynar.
*/
-void xbt_dynar_map(const xbt_dynar_t dynar, void_f_pvoid_t const op)
+extern "C" void xbt_dynar_map(const xbt_dynar_t dynar, void_f_pvoid_t const op)
{
char *const data = (char *) dynar->data;
const unsigned long elmsize = dynar->elmsize;
*
* This function can be used while traversing without problem.
*/
-void xbt_dynar_cursor_rm(xbt_dynar_t dynar, unsigned int *const cursor)
+extern "C" void xbt_dynar_cursor_rm(xbt_dynar_t dynar, unsigned int* const cursor)
{
- xbt_dynar_remove_at(dynar, (*cursor)--, nullptr);
+ xbt_dynar_remove_at(dynar, *cursor, nullptr);
+ *cursor -= 1;
}
/** @brief Sorts a dynar according to the function <tt>compar_fn</tt>
* \param dynar the dynar to sort
* \param compar_fn comparison function of type (int (compar_fn*) (const void*) (const void*)).
*/
-void xbt_dynar_sort(xbt_dynar_t dynar, int_f_cpvoid_cpvoid_t compar_fn)
+extern "C" void xbt_dynar_sort(xbt_dynar_t dynar, int_f_cpvoid_cpvoid_t compar_fn)
{
if (dynar->data != nullptr)
qsort(dynar->data, dynar->used, dynar->elmsize, compar_fn);
}
/** @brief Sorts a dynar of strings (ie, char* data) */
-xbt_dynar_t xbt_dynar_sort_strings(xbt_dynar_t dynar)
+extern "C" xbt_dynar_t xbt_dynar_sort_strings(xbt_dynar_t dynar)
{
xbt_dynar_sort(dynar, strcmp_voidp);
return dynar; // to enable functional uses
* 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)
+extern "C" void xbt_dynar_three_way_partition(xbt_dynar_t const dynar, int_f_pvoid_t color)
{
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);
+ char* tmp[elmsize];
void *elm;
for (i = 0; i < q;) {
++i;
} else {
if (colori == 0) {
- elm = _xbt_dynar_elm(dynar, ++p);
+ ++p;
+ elm = _xbt_dynar_elm(dynar, p);
++i;
} else { /* colori == 2 */
- elm = _xbt_dynar_elm(dynar, --q);
+ --q;
+ elm = _xbt_dynar_elm(dynar, q);
}
if (elm != elmi) {
memcpy(tmp, elm, elmsize);
}
}
}
- xbt_free(tmp);
}
-/** @brief Transform a dynar into a nullptr terminated array.
+/** @brief Transform a dynar into a nullptr terminated array.
*
* \param dynar the dynar to transform
* \return pointer to the first element of the array
*
* Note: The dynar won't be usable afterwards.
*/
-void *xbt_dynar_to_array(xbt_dynar_t dynar)
+extern "C" void* xbt_dynar_to_array(xbt_dynar_t dynar)
{
void *res;
xbt_dynar_shrink(dynar, 1);
* considered equal, and a value different of zero when they are considered different. Finally, d2 is destroyed
* afterwards.
*/
-int xbt_dynar_compare(xbt_dynar_t d1, xbt_dynar_t d2, int(*compar)(const void *, const void *))
+extern "C" int xbt_dynar_compare(xbt_dynar_t d1, xbt_dynar_t d2, int (*compar)(const void*, const void*))
{
int i ;
int size;
- if((!d1) && (!d2)) return 0;
- if((!d1) || (!d2))
- {
+ if ((not d1) && (not d2))
+ return 0;
+ if ((not d1) || (not d2)) {
XBT_DEBUG("nullptr dynar d1=%p d2=%p",d1,d2);
xbt_dynar_free(&d2);
return 1;
/* Vars_decl [doxygen cruft] */
int i;
unsigned int cursor;
- int *iptr;
xbt_test_add("==== Traverse the empty dynar");
xbt_dynar_t d = xbt_dynar_new(sizeof(int), nullptr);
/* 2. Traverse manually the dynar */
for (cursor = 0; cursor < NB_ELEM; cursor++) {
- iptr = (int*) xbt_dynar_get_ptr(d, cursor);
+ int* iptr = (int*)xbt_dynar_get_ptr(d, cursor);
xbt_test_assert(cursor == (unsigned int)*iptr, "The retrieved value is not the same than the injected one (%u!=%d)",
cursor, *iptr);
}
s1 = xbt_strdup(buf);
xbt_dynar_push(d, &s1);
}
- for (int cpt = 0; cpt < NB_ELEM; cpt++) {
- snprintf(buf,1023, "%d", cpt);
- s1 = xbt_strdup(buf);
- xbt_dynar_replace(d, cpt, &s1);
- }
- for (int cpt = 0; cpt < NB_ELEM; cpt++) {
- snprintf(buf,1023, "%d", cpt);
- s1 = xbt_strdup(buf);
- xbt_dynar_replace(d, cpt, &s1);
- }
- for (int cpt = 0; cpt < NB_ELEM; cpt++) {
- snprintf(buf,1023, "%d", cpt);
- s1 = xbt_strdup(buf);
- xbt_dynar_replace(d, cpt, &s1);
+ for (int i = 0 ; i < 3 ; i++) {
+ for (int cpt = 0; cpt < NB_ELEM; cpt++) {
+ snprintf(buf,1023, "%d", cpt);
+ s1 = xbt_strdup(buf);
+ xbt_dynar_replace(d, cpt, &s1);
+ }
}
for (int cpt = 0; cpt < NB_ELEM; cpt++) {
snprintf(buf,1023, "%d", cpt);
xbt_dynar_shift(d, &s2);
- xbt_test_assert(!strcmp(buf, s2), "The retrieved value is not the same than the injected one (%s!=%s)", buf, s2);
+ xbt_test_assert(not strcmp(buf, s2), "The retrieved value is not the same than the injected one (%s!=%s)", buf, s2);
free(s2);
}
xbt_dynar_free(&d); /* This code is used both as example and as regression test, so we try to */
/* 2. Traverse the dynar with the macro */
xbt_dynar_foreach(d, iter, s1) {
snprintf(buf,1023, "%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);
+ xbt_test_assert(not strcmp(buf, s1), "The retrieved value is not the same than the injected one (%s!=%s)", buf, s1);
}
/* 3. Traverse the dynar with the macro */
for (int cpt = 0; cpt < NB_ELEM; cpt++) {
snprintf(buf,1023, "%d", cpt);
xbt_dynar_pop(d, &s2);
- xbt_test_assert(!strcmp(buf, s2), "The retrieved value is not the same than the injected one (%s!=%s)", buf, s2);
+ xbt_test_assert(not strcmp(buf, s2), "The retrieved value is not the same than the injected one (%s!=%s)", buf, s2);
free(s2);
}
/* 4. Free the resources */
for (int cpt = 0; cpt < NB_ELEM / 2; cpt++) {
snprintf(buf,1023, "%d", cpt);
xbt_dynar_shift(d, &s2);
- xbt_test_assert(!strcmp(buf, s2),
- "The retrieved value is not the same than the injected one at the begining (%s!=%s)", buf, s2);
+ xbt_test_assert(not strcmp(buf, s2),
+ "The retrieved value is not the same than the injected one at the begining (%s!=%s)", buf, s2);
free(s2);
}
for (int cpt = (NB_ELEM / 5) - 1; cpt >= 0; cpt--) {
snprintf(buf,1023, "%d", cpt);
xbt_dynar_shift(d, &s2);
- xbt_test_assert(!strcmp(buf, s2),
- "The retrieved value is not the same than the injected one in the middle (%s!=%s)", buf, s2);
+ xbt_test_assert(not strcmp(buf, s2),
+ "The retrieved value is not the same than the injected one in the middle (%s!=%s)", buf, s2);
free(s2);
}
for (int cpt = NB_ELEM / 2; cpt < NB_ELEM; cpt++) {
snprintf(buf,1023, "%d", cpt);
xbt_dynar_shift(d, &s2);
- xbt_test_assert(!strcmp(buf, s2), "The retrieved value is not the same than the injected one at the end (%s!=%s)",
- buf, s2);
+ xbt_test_assert(not strcmp(buf, s2),
+ "The retrieved value is not the same than the injected one at the end (%s!=%s)", buf, s2);
free(s2);
}
xbt_dynar_free(&d); /* This code is used both as example and as regression test, so we try to */
for (int cpt = 2 * (NB_ELEM / 5); cpt < 4 * (NB_ELEM / 5); cpt++) {
snprintf(buf,1023, "%d", cpt);
xbt_dynar_remove_at(d, 2 * (NB_ELEM / 5), &s2);
- xbt_test_assert(!strcmp(buf, s2), "Remove a bad value. Got %s, expected %s", s2, buf);
+ xbt_test_assert(not strcmp(buf, s2), "Remove a bad value. Got %s, expected %s", s2, buf);
free(s2);
}
xbt_dynar_free(&d); /* end_of_doxygen */