| Current File : //usr/local/apps/dovecot/include/dovecot/array.h |
#ifndef ARRAY_H
#define ARRAY_H
/* Array is a buffer accessible using fixed size elements. As long as the
compiler provides a typeof() operator, the array provides type safety. If
a wrong type is tried to be added to the array, or if the array's contents
are tried to be used using a wrong type, the compiler will give a warning.
Example usage:
struct foo {
ARRAY(struct bar) bars;
...
};
i_array_init(&foo->bars, 10);
struct bar *bar = array_idx(&foo->bars, 5);
struct baz *baz = array_idx(&foo->bars, 5); // compiler warning
If you want to pass an array as a parameter to a function, you'll need to
create a type for the array using ARRAY_DEFINE_TYPE() and use the type in
the parameter using ARRAY_TYPE(). Any arrays that you want to be passing
around, such as structure members as in the above example, must also be
defined using ARRAY_TYPE() too, rather than ARRAY().
Example:
ARRAY_DEFINE_TYPE(foo, struct foo);
void do_foo(ARRAY_TYPE(foo) *foos) {
struct foo *foo = array_idx(foos, 0);
}
struct foo_manager {
ARRAY_TYPE(foo) foos; // pedantically, ARRAY(struct foo) is a different type
};
// ...
do_foo(&my_foo_manager->foos); // No compiler warning about mismatched types
*/
#include "array-decl.h"
#include "buffer.h"
#define p_array_init(array, pool, init_count) \
array_create(array, pool, sizeof(**(array)->v), init_count)
#define i_array_init(array, init_count) \
p_array_init(array, default_pool, init_count)
#define t_array_init(array, init_count) \
p_array_init(array, pool_datastack_create(), init_count)
#ifdef HAVE_TYPEOF
# define ARRAY_TYPE_CAST_CONST(array) \
(typeof(*(array)->v))
# define ARRAY_TYPE_CAST_MODIFIABLE(array) \
(typeof(*(array)->v_modifiable))
# define ARRAY_TYPE_CHECK(array, data) \
COMPILE_ERROR_IF_TYPES_NOT_COMPATIBLE( \
**(array)->v_modifiable, *(data))
# define ARRAY_TYPES_CHECK(array1, array2) \
COMPILE_ERROR_IF_TYPES_NOT_COMPATIBLE( \
**(array1)->v_modifiable, **(array2)->v_modifiable)
#else
# define ARRAY_TYPE_CAST_CONST(array)
# define ARRAY_TYPE_CAST_MODIFIABLE(array)
# define ARRAY_TYPE_CHECK(array, data) 0
# define ARRAY_TYPES_CHECK(array1, array2) 0
#endif
/* Usage:
ARRAY(struct foo) foo_arr;
struct foo *foo;
array_foreach(&foo_arr, foo) {
..
}
Note that deleting an element while iterating will cause the iteration to
skip over the next element. So deleting a single element and breaking out
of the loop is fine, but continuing the loop is likely a bug. Use
array_foreach_reverse() instead when deleting multiple elements.
*/
#define array_foreach(array, elem) \
for (const void *elem ## __foreach_end = \
(const char *)(elem = *(array)->v) + (array)->arr.buffer->used; \
elem != elem ## __foreach_end; (elem)++)
#define array_foreach_modifiable(array, elem) \
for (const void *elem ## _end = \
(const char *)(elem = ARRAY_TYPE_CAST_MODIFIABLE(array) \
buffer_get_modifiable_data((array)->arr.buffer, NULL)) + \
(array)->arr.buffer->used; \
elem != elem ## _end; (elem)++)
/* Iterate the array in reverse order. */
#define array_foreach_reverse(array, elem) \
for (elem = CONST_PTR_OFFSET(*(array)->v, (array)->arr.buffer->used); \
(const char *)(elem--) > (const char *)*(array)->v; )
#define array_foreach_reverse_modifiable(array, elem) \
for (elem = ARRAY_TYPE_CAST_MODIFIABLE(array) \
((char *)buffer_get_modifiable_data((array)->arr.buffer, NULL) + \
(array)->arr.buffer->used); \
(const char *)(elem--) > (const char *)*(array)->v; )
/* Usage:
ARRAY(struct foo *) foo_ptrs_arr;
struct foo *foo;
array_foreach_elem(&foo_ptrs_arr, foo) {
..
} */
#define array_foreach_elem(array, elem) \
for (const void *_foreach_end = \
CONST_PTR_OFFSET(*(array)->v, (array)->arr.buffer->used), \
*_foreach_ptr = CONST_PTR_OFFSET(*(array)->v, ARRAY_TYPE_CHECK(array, &elem) + \
COMPILE_ERROR_IF_TRUE(sizeof(elem) > sizeof(void *))) \
; \
(_foreach_ptr != _foreach_end && \
(memcpy(&elem, _foreach_ptr, sizeof(elem)), TRUE)) \
; \
_foreach_ptr = CONST_PTR_OFFSET(_foreach_ptr, sizeof(elem)))
#define array_ptr_to_idx(array, elem) \
((elem) - (array)->v[0])
/* Return index of iterated element inside array_foreach() or
array_foreach_modifiable() loop. Note that this doesn't work inside
array_foreach_elem() loop. */
#define array_foreach_idx(array, elem) \
array_ptr_to_idx(array, elem)
static inline void
array_create_from_buffer_i(struct array *array, buffer_t *buffer,
size_t element_size)
{
array->buffer = buffer;
array->element_size = element_size;
}
#define array_create_from_buffer(array, buffer, element_size) \
array_create_from_buffer_i(&(array)->arr, buffer, element_size)
static inline void
array_create_i(struct array *array, pool_t pool,
size_t element_size, unsigned int init_count)
{
buffer_t *buffer;
buffer = buffer_create_dynamic_max(pool, init_count * element_size,
SIZE_MAX / element_size < UINT_MAX ? SIZE_MAX :
UINT_MAX * element_size);
array_create_from_buffer_i(array, buffer, element_size);
}
#define array_create(array, pool, element_size, init_count) \
array_create_i(&(array)->arr, pool, element_size, init_count)
static inline void
array_free_i(struct array *array)
{
buffer_free(&array->buffer);
}
#define array_free(array) \
array_free_i(&(array)->arr)
static inline void * ATTR_WARN_UNUSED_RESULT
array_free_without_data_i(struct array *array)
{
return buffer_free_without_data(&array->buffer);
}
#define array_free_without_data(array) \
ARRAY_TYPE_CAST_MODIFIABLE(array)array_free_without_data_i(&(array)->arr)
static inline bool
array_is_created_i(const struct array *array)
{
return array->buffer != NULL;
}
#define array_is_created(array) \
array_is_created_i(&(array)->arr)
static inline pool_t ATTR_PURE
array_get_pool_i(struct array *array)
{
return buffer_get_pool(array->buffer);
}
#define array_get_pool(array) \
array_get_pool_i(&(array)->arr)
static inline void
array_clear_i(struct array *array)
{
buffer_set_used_size(array->buffer, 0);
}
#define array_clear(array) \
array_clear_i(&(array)->arr)
static inline unsigned int ATTR_PURE
array_count_i(const struct array *array)
{
return array->buffer->used / array->element_size;
}
#define array_count(array) \
array_count_i(&(array)->arr)
/* No need for the real count if all we're doing is comparing against 0 */
#define array_is_empty(array) \
((array)->arr.buffer->used == 0)
#define array_not_empty(array) \
((array)->arr.buffer->used > 0)
static inline void
array_append_i(struct array *array, const void *data, unsigned int count)
{
buffer_append(array->buffer, data, count * array->element_size);
}
#define array_append(array, data, count) \
TYPE_CHECKS(void, ARRAY_TYPE_CHECK(array, data), \
array_append_i(&(array)->arr, data, count))
static inline void
array_append_array_i(struct array *dest_array, const struct array *src_array)
{
i_assert(dest_array->element_size == src_array->element_size);
buffer_append_buf(dest_array->buffer, src_array->buffer, 0, SIZE_MAX);
}
#define array_append_array(dest_array, src_array) \
TYPE_CHECKS(void, ARRAY_TYPES_CHECK(dest_array, src_array), \
array_append_array_i(&(dest_array)->arr, &(src_array)->arr))
static inline void
array_insert_i(struct array *array, unsigned int idx,
const void *data, unsigned int count)
{
buffer_insert(array->buffer, idx * array->element_size,
data, count * array->element_size);
}
#define array_insert(array, idx, data, count) \
TYPE_CHECKS(void, ARRAY_TYPE_CHECK(array, data), \
array_insert_i(&(array)->arr, idx, data, count))
static inline void
array_delete_i(struct array *array, unsigned int idx, unsigned int count)
{
buffer_delete(array->buffer, idx * array->element_size,
count * array->element_size);
}
#define array_delete(array, idx, count) \
array_delete_i(&(array)->arr, idx, count)
static inline const void *
array_get_i(const struct array *array, unsigned int *count_r)
{
*count_r = array_count_i(array);
return array->buffer->data;
}
#define array_get(array, count) \
ARRAY_TYPE_CAST_CONST(array)array_get_i(&(array)->arr, count)
/* Re: i_assert() vs. pure: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=51971#c1 */
static inline const void * ATTR_PURE
array_idx_i(const struct array *array, unsigned int idx)
{
i_assert(idx < array->buffer->used / array->element_size);
return CONST_PTR_OFFSET(array->buffer->data, idx * array->element_size);
}
#define array_front(array) array_idx(array, 0)
#define array_front_modifiable(array) array_idx_modifiable(array, 0)
#define array_back(array) array_idx(array, array_count(array)-1)
#define array_back_modifiable(array) array_idx_modifiable(array, array_count(array)-1)
#define array_pop_back(array) array_delete(array, array_count(array)-1, 1);
#define array_push_back(array, item) array_append(array, (item), 1)
#define array_pop_front(array) array_delete(array, 0, 1)
#define array_push_front(array, item) array_insert(array, 0, (item), 1)
#define array_idx(array, idx) \
ARRAY_TYPE_CAST_CONST(array)array_idx_i(&(array)->arr, idx)
/* Using *array_idx() will fail if the compiler doesn't support typeof().
The same can be done with array_idx_elem() for arrays that have pointers. */
#ifdef HAVE_TYPEOF
# define array_idx_elem(array, idx) \
(TRUE ? *array_idx(array, idx) : \
COMPILE_ERROR_IF_TRUE(sizeof(**(array)->v) != sizeof(void *)))
#else
# define array_idx_elem(array, idx) \
(*(void **)array_idx_i(&(array)->arr, idx))
#endif
static inline void *
array_get_modifiable_i(struct array *array, unsigned int *count_r)
{
*count_r = array_count_i(array);
return buffer_get_modifiable_data(array->buffer, NULL);
}
#define array_get_modifiable(array, count) \
ARRAY_TYPE_CAST_MODIFIABLE(array) \
array_get_modifiable_i(&(array)->arr, count)
void *
array_idx_modifiable_i(const struct array *array, unsigned int idx) ATTR_PURE;
#define array_idx_modifiable(array, idx) \
ARRAY_TYPE_CAST_MODIFIABLE(array) \
array_idx_modifiable_i(&(array)->arr, idx)
void *array_idx_get_space_i(struct array *array, unsigned int idx);
#define array_idx_get_space(array, idx) \
ARRAY_TYPE_CAST_MODIFIABLE(array) \
array_idx_get_space_i(&(array)->arr, idx)
void array_idx_set_i(struct array *array, unsigned int idx, const void *data);
#define array_idx_set(array, idx, data) \
TYPE_CHECKS(void, ARRAY_TYPE_CHECK(array, data), \
array_idx_set_i(&(array)->arr, idx, data))
void array_idx_clear_i(struct array *array, unsigned int idx);
#define array_idx_clear(array, idx) \
array_idx_clear_i(&(array)->arr, idx)
static inline void *
array_append_space_i(struct array *array)
{
void *data;
data = buffer_append_space_unsafe(array->buffer, array->element_size);
memset(data, 0, array->element_size);
return data;
}
#define array_append_space(array) \
ARRAY_TYPE_CAST_MODIFIABLE(array)array_append_space_i(&(array)->arr)
#define array_append_zero(array) \
(void)array_append_space_i(&(array)->arr)
void *array_insert_space_i(struct array *array, unsigned int idx);
#define array_insert_space(array, idx) \
ARRAY_TYPE_CAST_MODIFIABLE(array) \
array_insert_space_i(&(array)->arr, idx)
static inline void
array_copy(struct array *dest, unsigned int dest_idx,
const struct array *src, unsigned int src_idx, unsigned int count)
{
i_assert(dest->element_size == src->element_size);
buffer_copy(dest->buffer, dest_idx * dest->element_size,
src->buffer, src_idx * src->element_size,
count * dest->element_size);
}
bool array_cmp_i(const struct array *array1,
const struct array *array2) ATTR_PURE;
#define array_cmp(array1, array2) \
array_cmp_i(&(array1)->arr, &(array2)->arr)
/* Test equality via a comparator */
bool array_equal_fn_i(const struct array *array1,
const struct array *array2,
int (*cmp)(const void*, const void *)) ATTR_PURE;
#define array_equal_fn(array1, array2, cmp) \
TYPE_CHECKS(bool, \
ARRAY_TYPES_CHECK(array1, array2) || \
CALLBACK_TYPECHECK(cmp, int (*)(typeof(*(array1)->v), \
typeof(*(array2)->v))), \
array_equal_fn_i(&(array1)->arr, &(array2)->arr, \
(int (*)(const void *, const void *))cmp))
bool array_equal_fn_ctx_i(const struct array *array1,
const struct array *array2,
int (*cmp)(const void*, const void *, const void *),
const void *context) ATTR_PURE;
/* Same, but with a context pointer.
context can't be void* as ``const typeof(context)'' won't compile,
so ``const typeof(*context)*'' is required instead, and that requires a
complete type. */
#define array_equal_fn_ctx(array1, array2, cmp, ctx) \
TYPE_CHECKS(bool, \
ARRAY_TYPES_CHECK(array1, array2) || \
CALLBACK_TYPECHECK(cmp, int (*)(typeof(*(array1)->v), \
typeof(*(array2)->v), \
const typeof(*ctx)*)), \
array_equal_fn_ctx_i(&(array1)->arr, &(array2)->arr, \
(int (*)(const void *, const void *, const void *))cmp, ctx))
void array_reverse_i(struct array *array);
#define array_reverse(array) \
array_reverse_i(&(array)->arr)
void array_sort_i(struct array *array, int (*cmp)(const void *, const void *));
#define array_sort(array, cmp) \
TYPE_CHECKS(void, \
CALLBACK_TYPECHECK(cmp, int (*)(typeof(*(array)->v), \
typeof(*(array)->v))), \
array_sort_i(&(array)->arr, (int (*)(const void *, const void *))cmp))
void *array_bsearch_i(struct array *array, const void *key,
int (*cmp)(const void *, const void *));
#define array_bsearch(array, key, cmp) \
TYPE_CHECKS(void *, \
CALLBACK_TYPECHECK(cmp, int (*)(typeof(const typeof(*key) *), \
typeof(*(array)->v))), \
ARRAY_TYPE_CAST_MODIFIABLE(array)array_bsearch_i(&(array)->arr, \
(const void *)key, (int (*)(const void *, const void *))cmp))
/* Returns pointer to first element for which cmp(key,elem)==0, or NULL */
const void *array_lsearch_i(const struct array *array, const void *key,
int (*cmp)(const void *, const void *));
static inline void *array_lsearch_modifiable_i(struct array *array, const void *key,
int (*cmp)(const void *, const void *))
{
return (void *)array_lsearch_i(array, key, cmp);
}
#define ARRAY_LSEARCH_CALL(modifiable, array, key, cmp) \
TYPE_CHECKS(void *, \
CALLBACK_TYPECHECK(cmp, int (*)(typeof(const typeof(*key) *), \
typeof(*(array)->v))), \
array_lsearch##modifiable##i( \
&(array)->arr, (const void *)key, \
(int (*)(const void *, const void *))cmp))
#define array_lsearch(array, key, cmp) \
ARRAY_TYPE_CAST_CONST(array)ARRAY_LSEARCH_CALL(_, array, key, cmp)
#define array_lsearch_modifiable(array, key, cmp) \
ARRAY_TYPE_CAST_MODIFIABLE(array)ARRAY_LSEARCH_CALL(_modifiable_, array, key, cmp)
#endif