blob: 5b71c887a27ab1956356f677847b6af373eee130 [file] [log] [blame]
/* GLIB - Library of useful routines for C programming
* Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
/*
* Modified by the GLib Team and others 1997-2000. See the AUTHORS
* file for a list of people on the GLib Team. See the ChangeLog
* files for a list of changes. These files are distributed with
* GLib at ftp://ftp.gtk.org/pub/gtk/.
*/
/*
* MT safe
*/
#include "config.h"
#include <string.h>
#include <stdlib.h>
#include "garray.h"
#include "gbytes.h"
#include "ghash.h"
#include "gslice.h"
#include "gmem.h"
#include "gtestutils.h"
#include "gthread.h"
#include "gmessages.h"
#include "gqsort.h"
#include "grefcount.h"
/**
* SECTION:arrays
* @title: Arrays
* @short_description: arrays of arbitrary elements which grow
* automatically as elements are added
*
* Arrays are similar to standard C arrays, except that they grow
* automatically as elements are added.
*
* Array elements can be of any size (though all elements of one array
* are the same size), and the array can be automatically cleared to
* '0's and zero-terminated.
*
* To create a new array use g_array_new().
*
* To add elements to an array, use g_array_append_val(),
* g_array_append_vals(), g_array_prepend_val(), and
* g_array_prepend_vals().
*
* To access an element of an array, use g_array_index().
*
* To set the size of an array, use g_array_set_size().
*
* To free an array, use g_array_free().
*
* Here is an example that stores integers in a #GArray:
* |[<!-- language="C" -->
* GArray *garray;
* gint i;
* // We create a new array to store gint values.
* // We don't want it zero-terminated or cleared to 0's.
* garray = g_array_new (FALSE, FALSE, sizeof (gint));
* for (i = 0; i < 10000; i++)
* g_array_append_val (garray, i);
* for (i = 0; i < 10000; i++)
* if (g_array_index (garray, gint, i) != i)
* g_print ("ERROR: got %d instead of %d\n",
* g_array_index (garray, gint, i), i);
* g_array_free (garray, TRUE);
* ]|
*/
#define MIN_ARRAY_SIZE 16
typedef struct _GRealArray GRealArray;
/**
* GArray:
* @data: a pointer to the element data. The data may be moved as
* elements are added to the #GArray.
* @len: the number of elements in the #GArray not including the
* possible terminating zero element.
*
* Contains the public fields of a GArray.
*/
struct _GRealArray
{
guint8 *data;
guint len;
guint alloc;
guint elt_size;
guint zero_terminated : 1;
guint clear : 1;
gatomicrefcount ref_count;
GDestroyNotify clear_func;
};
/**
* g_array_index:
* @a: a #GArray
* @t: the type of the elements
* @i: the index of the element to return
*
* Returns the element of a #GArray at the given index. The return
* value is cast to the given type.
*
* This example gets a pointer to an element in a #GArray:
* |[<!-- language="C" -->
* EDayViewEvent *event;
* // This gets a pointer to the 4th element in the array of
* // EDayViewEvent structs.
* event = &g_array_index (events, EDayViewEvent, 3);
* ]|
*
* Returns: the element of the #GArray at the index given by @i
*/
#define g_array_elt_len(array,i) ((array)->elt_size * (i))
#define g_array_elt_pos(array,i) ((array)->data + g_array_elt_len((array),(i)))
#define g_array_elt_zero(array, pos, len) \
(memset (g_array_elt_pos ((array), pos), 0, g_array_elt_len ((array), len)))
#define g_array_zero_terminate(array) G_STMT_START{ \
if ((array)->zero_terminated) \
g_array_elt_zero ((array), (array)->len, 1); \
}G_STMT_END
static guint g_nearest_pow (guint num) G_GNUC_CONST;
static void g_array_maybe_expand (GRealArray *array,
guint len);
/**
* g_array_new:
* @zero_terminated: %TRUE if the array should have an extra element at
* the end which is set to 0
* @clear_: %TRUE if #GArray elements should be automatically cleared
* to 0 when they are allocated
* @element_size: the size of each element in bytes
*
* Creates a new #GArray with a reference count of 1.
*
* Returns: the new #GArray
*/
GArray*
g_array_new (gboolean zero_terminated,
gboolean clear,
guint elt_size)
{
g_return_val_if_fail (elt_size > 0, NULL);
return g_array_sized_new (zero_terminated, clear, elt_size, 0);
}
/**
* g_array_sized_new:
* @zero_terminated: %TRUE if the array should have an extra element at
* the end with all bits cleared
* @clear_: %TRUE if all bits in the array should be cleared to 0 on
* allocation
* @element_size: size of each element in the array
* @reserved_size: number of elements preallocated
*
* Creates a new #GArray with @reserved_size elements preallocated and
* a reference count of 1. This avoids frequent reallocation, if you
* are going to add many elements to the array. Note however that the
* size of the array is still 0.
*
* Returns: the new #GArray
*/
GArray*
g_array_sized_new (gboolean zero_terminated,
gboolean clear,
guint elt_size,
guint reserved_size)
{
GRealArray *array;
g_return_val_if_fail (elt_size > 0, NULL);
array = g_slice_new (GRealArray);
array->data = NULL;
array->len = 0;
array->alloc = 0;
array->zero_terminated = (zero_terminated ? 1 : 0);
array->clear = (clear ? 1 : 0);
array->elt_size = elt_size;
array->clear_func = NULL;
g_atomic_ref_count_init (&array->ref_count);
if (array->zero_terminated || reserved_size != 0)
{
g_array_maybe_expand (array, reserved_size);
g_array_zero_terminate(array);
}
return (GArray*) array;
}
/**
* g_array_set_clear_func:
* @array: A #GArray
* @clear_func: a function to clear an element of @array
*
* Sets a function to clear an element of @array.
*
* The @clear_func will be called when an element in the array
* data segment is removed and when the array is freed and data
* segment is deallocated as well. @clear_func will be passed a
* pointer to the element to clear, rather than the element itself.
*
* Note that in contrast with other uses of #GDestroyNotify
* functions, @clear_func is expected to clear the contents of
* the array element it is given, but not free the element itself.
*
* Since: 2.32
*/
void
g_array_set_clear_func (GArray *array,
GDestroyNotify clear_func)
{
GRealArray *rarray = (GRealArray *) array;
g_return_if_fail (array != NULL);
rarray->clear_func = clear_func;
}
/**
* g_array_ref:
* @array: A #GArray
*
* Atomically increments the reference count of @array by one.
* This function is thread-safe and may be called from any thread.
*
* Returns: The passed in #GArray
*
* Since: 2.22
*/
GArray *
g_array_ref (GArray *array)
{
GRealArray *rarray = (GRealArray*) array;
g_return_val_if_fail (array, NULL);
g_atomic_ref_count_inc (&rarray->ref_count);
return array;
}
typedef enum
{
FREE_SEGMENT = 1 << 0,
PRESERVE_WRAPPER = 1 << 1
} ArrayFreeFlags;
static gchar *array_free (GRealArray *, ArrayFreeFlags);
/**
* g_array_unref:
* @array: A #GArray
*
* Atomically decrements the reference count of @array by one. If the
* reference count drops to 0, all memory allocated by the array is
* released. This function is thread-safe and may be called from any
* thread.
*
* Since: 2.22
*/
void
g_array_unref (GArray *array)
{
GRealArray *rarray = (GRealArray*) array;
g_return_if_fail (array);
if (g_atomic_ref_count_dec (&rarray->ref_count))
array_free (rarray, FREE_SEGMENT);
}
/**
* g_array_get_element_size:
* @array: A #GArray
*
* Gets the size of the elements in @array.
*
* Returns: Size of each element, in bytes
*
* Since: 2.22
*/
guint
g_array_get_element_size (GArray *array)
{
GRealArray *rarray = (GRealArray*) array;
g_return_val_if_fail (array, 0);
return rarray->elt_size;
}
/**
* g_array_free:
* @array: a #GArray
* @free_segment: if %TRUE the actual element data is freed as well
*
* Frees the memory allocated for the #GArray. If @free_segment is
* %TRUE it frees the memory block holding the elements as well and
* also each element if @array has a @element_free_func set. Pass
* %FALSE if you want to free the #GArray wrapper but preserve the
* underlying array for use elsewhere. If the reference count of @array
* is greater than one, the #GArray wrapper is preserved but the size
* of @array will be set to zero.
*
* If array elements contain dynamically-allocated memory, they should
* be freed separately.
*
* This function is not thread-safe. If using a #GArray from multiple
* threads, use only the atomic g_array_ref() and g_array_unref()
* functions.
*
* Returns: the element data if @free_segment is %FALSE, otherwise
* %NULL. The element data should be freed using g_free().
*/
gchar*
g_array_free (GArray *farray,
gboolean free_segment)
{
GRealArray *array = (GRealArray*) farray;
ArrayFreeFlags flags;
g_return_val_if_fail (array, NULL);
flags = (free_segment ? FREE_SEGMENT : 0);
/* if others are holding a reference, preserve the wrapper but do free/return the data */
if (!g_atomic_ref_count_dec (&array->ref_count))
flags |= PRESERVE_WRAPPER;
return array_free (array, flags);
}
static gchar *
array_free (GRealArray *array,
ArrayFreeFlags flags)
{
gchar *segment;
if (flags & FREE_SEGMENT)
{
if (array->clear_func != NULL)
{
guint i;
for (i = 0; i < array->len; i++)
array->clear_func (g_array_elt_pos (array, i));
}
g_free (array->data);
segment = NULL;
}
else
segment = (gchar*) array->data;
if (flags & PRESERVE_WRAPPER)
{
array->data = NULL;
array->len = 0;
array->alloc = 0;
}
else
{
g_slice_free1 (sizeof (GRealArray), array);
}
return segment;
}
/**
* g_array_append_vals:
* @array: a #GArray
* @data: (not nullable): a pointer to the elements to append to the end of the array
* @len: the number of elements to append
*
* Adds @len elements onto the end of the array.
*
* Returns: the #GArray
*/
/**
* g_array_append_val:
* @a: a #GArray
* @v: the value to append to the #GArray
*
* Adds the value on to the end of the array. The array will grow in
* size automatically if necessary.
*
* g_array_append_val() is a macro which uses a reference to the value
* parameter @v. This means that you cannot use it with literal values
* such as "27". You must use variables.
*
* Returns: the #GArray
*/
GArray*
g_array_append_vals (GArray *farray,
gconstpointer data,
guint len)
{
GRealArray *array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
if (len == 0)
return farray;
g_array_maybe_expand (array, len);
memcpy (g_array_elt_pos (array, array->len), data,
g_array_elt_len (array, len));
array->len += len;
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_prepend_vals:
* @array: a #GArray
* @data: (nullable): a pointer to the elements to prepend to the start of the array
* @len: the number of elements to prepend, which may be zero
*
* Adds @len elements onto the start of the array.
*
* @data may be %NULL if (and only if) @len is zero. If @len is zero, this
* function is a no-op.
*
* This operation is slower than g_array_append_vals() since the
* existing elements in the array have to be moved to make space for
* the new elements.
*
* Returns: the #GArray
*/
/**
* g_array_prepend_val:
* @a: a #GArray
* @v: the value to prepend to the #GArray
*
* Adds the value on to the start of the array. The array will grow in
* size automatically if necessary.
*
* This operation is slower than g_array_append_val() since the
* existing elements in the array have to be moved to make space for
* the new element.
*
* g_array_prepend_val() is a macro which uses a reference to the value
* parameter @v. This means that you cannot use it with literal values
* such as "27". You must use variables.
*
* Returns: the #GArray
*/
GArray*
g_array_prepend_vals (GArray *farray,
gconstpointer data,
guint len)
{
GRealArray *array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
if (len == 0)
return farray;
g_array_maybe_expand (array, len);
memmove (g_array_elt_pos (array, len), g_array_elt_pos (array, 0),
g_array_elt_len (array, array->len));
memcpy (g_array_elt_pos (array, 0), data, g_array_elt_len (array, len));
array->len += len;
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_insert_vals:
* @array: a #GArray
* @index_: the index to place the elements at
* @data: (nullable): a pointer to the elements to insert
* @len: the number of elements to insert
*
* Inserts @len elements into a #GArray at the given index.
*
* If @index_ is greater than the array’s current length, the array is expanded.
* The elements between the old end of the array and the newly inserted elements
* will be initialised to zero if the array was configured to clear elements;
* otherwise their values will be undefined.
*
* @data may be %NULL if (and only if) @len is zero. If @len is zero, this
* function is a no-op.
*
* Returns: the #GArray
*/
/**
* g_array_insert_val:
* @a: a #GArray
* @i: the index to place the element at
* @v: the value to insert into the array
*
* Inserts an element into an array at the given index.
*
* g_array_insert_val() is a macro which uses a reference to the value
* parameter @v. This means that you cannot use it with literal values
* such as "27". You must use variables.
*
* Returns: the #GArray
*/
GArray*
g_array_insert_vals (GArray *farray,
guint index_,
gconstpointer data,
guint len)
{
GRealArray *array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
if (len == 0)
return farray;
/* Is the index off the end of the array, and hence do we need to over-allocate
* and clear some elements? */
if (index_ >= array->len)
{
g_array_maybe_expand (array, index_ - array->len + len);
return g_array_append_vals (g_array_set_size (farray, index_), data, len);
}
g_array_maybe_expand (array, len);
memmove (g_array_elt_pos (array, len + index_),
g_array_elt_pos (array, index_),
g_array_elt_len (array, array->len - index_));
memcpy (g_array_elt_pos (array, index_), data, g_array_elt_len (array, len));
array->len += len;
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_set_size:
* @array: a #GArray
* @length: the new size of the #GArray
*
* Sets the size of the array, expanding it if necessary. If the array
* was created with @clear_ set to %TRUE, the new elements are set to 0.
*
* Returns: the #GArray
*/
GArray*
g_array_set_size (GArray *farray,
guint length)
{
GRealArray *array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
if (length > array->len)
{
g_array_maybe_expand (array, length - array->len);
if (array->clear)
g_array_elt_zero (array, array->len, length - array->len);
}
else if (length < array->len)
g_array_remove_range (farray, length, array->len - length);
array->len = length;
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_remove_index:
* @array: a #GArray
* @index_: the index of the element to remove
*
* Removes the element at the given index from a #GArray. The following
* elements are moved down one place.
*
* Returns: the #GArray
*/
GArray*
g_array_remove_index (GArray *farray,
guint index_)
{
GRealArray* array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
g_return_val_if_fail (index_ < array->len, NULL);
if (array->clear_func != NULL)
array->clear_func (g_array_elt_pos (array, index_));
if (index_ != array->len - 1)
memmove (g_array_elt_pos (array, index_),
g_array_elt_pos (array, index_ + 1),
g_array_elt_len (array, array->len - index_ - 1));
array->len -= 1;
if (G_UNLIKELY (g_mem_gc_friendly))
g_array_elt_zero (array, array->len, 1);
else
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_remove_index_fast:
* @array: a @GArray
* @index_: the index of the element to remove
*
* Removes the element at the given index from a #GArray. The last
* element in the array is used to fill in the space, so this function
* does not preserve the order of the #GArray. But it is faster than
* g_array_remove_index().
*
* Returns: the #GArray
*/
GArray*
g_array_remove_index_fast (GArray *farray,
guint index_)
{
GRealArray* array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
g_return_val_if_fail (index_ < array->len, NULL);
if (array->clear_func != NULL)
array->clear_func (g_array_elt_pos (array, index_));
if (index_ != array->len - 1)
memcpy (g_array_elt_pos (array, index_),
g_array_elt_pos (array, array->len - 1),
g_array_elt_len (array, 1));
array->len -= 1;
if (G_UNLIKELY (g_mem_gc_friendly))
g_array_elt_zero (array, array->len, 1);
else
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_remove_range:
* @array: a @GArray
* @index_: the index of the first element to remove
* @length: the number of elements to remove
*
* Removes the given number of elements starting at the given index
* from a #GArray. The following elements are moved to close the gap.
*
* Returns: the #GArray
*
* Since: 2.4
*/
GArray*
g_array_remove_range (GArray *farray,
guint index_,
guint length)
{
GRealArray *array = (GRealArray*) farray;
g_return_val_if_fail (array, NULL);
g_return_val_if_fail (index_ <= array->len, NULL);
g_return_val_if_fail (index_ + length <= array->len, NULL);
if (array->clear_func != NULL)
{
guint i;
for (i = 0; i < length; i++)
array->clear_func (g_array_elt_pos (array, index_ + i));
}
if (index_ + length != array->len)
memmove (g_array_elt_pos (array, index_),
g_array_elt_pos (array, index_ + length),
(array->len - (index_ + length)) * array->elt_size);
array->len -= length;
if (G_UNLIKELY (g_mem_gc_friendly))
g_array_elt_zero (array, array->len, length);
else
g_array_zero_terminate (array);
return farray;
}
/**
* g_array_sort:
* @array: a #GArray
* @compare_func: comparison function
*
* Sorts a #GArray using @compare_func which should be a qsort()-style
* comparison function (returns less than zero for first arg is less
* than second arg, zero for equal, greater zero if first arg is
* greater than second arg).
*
* This is guaranteed to be a stable sort since version 2.32.
*/
void
g_array_sort (GArray *farray,
GCompareFunc compare_func)
{
GRealArray *array = (GRealArray*) farray;
g_return_if_fail (array != NULL);
/* Don't use qsort as we want a guaranteed stable sort */
g_qsort_with_data (array->data,
array->len,
array->elt_size,
(GCompareDataFunc)compare_func,
NULL);
}
/**
* g_array_sort_with_data:
* @array: a #GArray
* @compare_func: comparison function
* @user_data: data to pass to @compare_func
*
* Like g_array_sort(), but the comparison function receives an extra
* user data argument.
*
* This is guaranteed to be a stable sort since version 2.32.
*
* There used to be a comment here about making the sort stable by
* using the addresses of the elements in the comparison function.
* This did not actually work, so any such code should be removed.
*/
void
g_array_sort_with_data (GArray *farray,
GCompareDataFunc compare_func,
gpointer user_data)
{
GRealArray *array = (GRealArray*) farray;
g_return_if_fail (array != NULL);
g_qsort_with_data (array->data,
array->len,
array->elt_size,
compare_func,
user_data);
}
/* Returns the smallest power of 2 greater than n, or n if
* such power does not fit in a guint
*/
static guint
g_nearest_pow (guint num)
{
guint n = 1;
while (n < num && n > 0)
n <<= 1;
return n ? n : num;
}
static void
g_array_maybe_expand (GRealArray *array,
guint len)
{
guint want_alloc = g_array_elt_len (array, array->len + len +
array->zero_terminated);
if (want_alloc > array->alloc)
{
want_alloc = g_nearest_pow (want_alloc);
want_alloc = MAX (want_alloc, MIN_ARRAY_SIZE);
array->data = g_realloc (array->data, want_alloc);
if (G_UNLIKELY (g_mem_gc_friendly))
memset (array->data + array->alloc, 0, want_alloc - array->alloc);
array->alloc = want_alloc;
}
}
/**
* SECTION:arrays_pointer
* @title: Pointer Arrays
* @short_description: arrays of pointers to any type of data, which
* grow automatically as new elements are added
*
* Pointer Arrays are similar to Arrays but are used only for storing
* pointers.
*
* If you remove elements from the array, elements at the end of the
* array are moved into the space previously occupied by the removed
* element. This means that you should not rely on the index of particular
* elements remaining the same. You should also be careful when deleting
* elements while iterating over the array.
*
* To create a pointer array, use g_ptr_array_new().
*
* To add elements to a pointer array, use g_ptr_array_add().
*
* To remove elements from a pointer array, use g_ptr_array_remove(),
* g_ptr_array_remove_index() or g_ptr_array_remove_index_fast().
*
* To access an element of a pointer array, use g_ptr_array_index().
*
* To set the size of a pointer array, use g_ptr_array_set_size().
*
* To free a pointer array, use g_ptr_array_free().
*
* An example using a #GPtrArray:
* |[<!-- language="C" -->
* GPtrArray *array;
* gchar *string1 = "one";
* gchar *string2 = "two";
* gchar *string3 = "three";
*
* array = g_ptr_array_new ();
* g_ptr_array_add (array, (gpointer) string1);
* g_ptr_array_add (array, (gpointer) string2);
* g_ptr_array_add (array, (gpointer) string3);
*
* if (g_ptr_array_index (array, 0) != (gpointer) string1)
* g_print ("ERROR: got %p instead of %p\n",
* g_ptr_array_index (array, 0), string1);
*
* g_ptr_array_free (array, TRUE);
* ]|
*/
typedef struct _GRealPtrArray GRealPtrArray;
/**
* GPtrArray:
* @pdata: points to the array of pointers, which may be moved when the
* array grows
* @len: number of pointers in the array
*
* Contains the public fields of a pointer array.
*/
struct _GRealPtrArray
{
gpointer *pdata;
guint len;
guint alloc;
gatomicrefcount ref_count;
GDestroyNotify element_free_func;
};
/**
* g_ptr_array_index:
* @array: a #GPtrArray
* @index_: the index of the pointer to return
*
* Returns the pointer at the given index of the pointer array.
*
* This does not perform bounds checking on the given @index_,
* so you are responsible for checking it against the array length.
*
* Returns: the pointer at the given index
*/
static void g_ptr_array_maybe_expand (GRealPtrArray *array,
gint len);
/**
* g_ptr_array_new:
*
* Creates a new #GPtrArray with a reference count of 1.
*
* Returns: the new #GPtrArray
*/
GPtrArray*
g_ptr_array_new (void)
{
return g_ptr_array_sized_new (0);
}
/**
* g_ptr_array_sized_new:
* @reserved_size: number of pointers preallocated
*
* Creates a new #GPtrArray with @reserved_size pointers preallocated
* and a reference count of 1. This avoids frequent reallocation, if
* you are going to add many pointers to the array. Note however that
* the size of the array is still 0.
*
* Returns: the new #GPtrArray
*/
GPtrArray*
g_ptr_array_sized_new (guint reserved_size)
{
GRealPtrArray *array;
array = g_slice_new (GRealPtrArray);
array->pdata = NULL;
array->len = 0;
array->alloc = 0;
array->element_free_func = NULL;
g_atomic_ref_count_init (&array->ref_count);
if (reserved_size != 0)
g_ptr_array_maybe_expand (array, reserved_size);
return (GPtrArray*) array;
}
/**
* g_ptr_array_new_with_free_func:
* @element_free_func: (nullable): A function to free elements with
* destroy @array or %NULL
*
* Creates a new #GPtrArray with a reference count of 1 and use
* @element_free_func for freeing each element when the array is destroyed
* either via g_ptr_array_unref(), when g_ptr_array_free() is called with
* @free_segment set to %TRUE or when removing elements.
*
* Returns: A new #GPtrArray
*
* Since: 2.22
*/
GPtrArray*
g_ptr_array_new_with_free_func (GDestroyNotify element_free_func)
{
GPtrArray *array;
array = g_ptr_array_new ();
g_ptr_array_set_free_func (array, element_free_func);
return array;
}
/**
* g_ptr_array_new_full:
* @reserved_size: number of pointers preallocated
* @element_free_func: (nullable): A function to free elements with
* destroy @array or %NULL
*
* Creates a new #GPtrArray with @reserved_size pointers preallocated
* and a reference count of 1. This avoids frequent reallocation, if
* you are going to add many pointers to the array. Note however that
* the size of the array is still 0. It also set @element_free_func
* for freeing each element when the array is destroyed either via
* g_ptr_array_unref(), when g_ptr_array_free() is called with
* @free_segment set to %TRUE or when removing elements.
*
* Returns: A new #GPtrArray
*
* Since: 2.30
*/
GPtrArray*
g_ptr_array_new_full (guint reserved_size,
GDestroyNotify element_free_func)
{
GPtrArray *array;
array = g_ptr_array_sized_new (reserved_size);
g_ptr_array_set_free_func (array, element_free_func);
return array;
}
/**
* g_ptr_array_set_free_func:
* @array: A #GPtrArray
* @element_free_func: (nullable): A function to free elements with
* destroy @array or %NULL
*
* Sets a function for freeing each element when @array is destroyed
* either via g_ptr_array_unref(), when g_ptr_array_free() is called
* with @free_segment set to %TRUE or when removing elements.
*
* Since: 2.22
*/
void
g_ptr_array_set_free_func (GPtrArray *array,
GDestroyNotify element_free_func)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
g_return_if_fail (array);
rarray->element_free_func = element_free_func;
}
/**
* g_ptr_array_ref:
* @array: a #GPtrArray
*
* Atomically increments the reference count of @array by one.
* This function is thread-safe and may be called from any thread.
*
* Returns: The passed in #GPtrArray
*
* Since: 2.22
*/
GPtrArray*
g_ptr_array_ref (GPtrArray *array)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
g_return_val_if_fail (array, NULL);
g_atomic_ref_count_inc (&rarray->ref_count);
return array;
}
static gpointer *ptr_array_free (GPtrArray *, ArrayFreeFlags);
/**
* g_ptr_array_unref:
* @array: A #GPtrArray
*
* Atomically decrements the reference count of @array by one. If the
* reference count drops to 0, the effect is the same as calling
* g_ptr_array_free() with @free_segment set to %TRUE. This function
* is thread-safe and may be called from any thread.
*
* Since: 2.22
*/
void
g_ptr_array_unref (GPtrArray *array)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
g_return_if_fail (array);
if (g_atomic_ref_count_dec (&rarray->ref_count))
ptr_array_free (array, FREE_SEGMENT);
}
/**
* g_ptr_array_free:
* @array: a #GPtrArray
* @free_seg: if %TRUE the actual pointer array is freed as well
*
* Frees the memory allocated for the #GPtrArray. If @free_seg is %TRUE
* it frees the memory block holding the elements as well. Pass %FALSE
* if you want to free the #GPtrArray wrapper but preserve the
* underlying array for use elsewhere. If the reference count of @array
* is greater than one, the #GPtrArray wrapper is preserved but the
* size of @array will be set to zero.
*
* If array contents point to dynamically-allocated memory, they should
* be freed separately if @free_seg is %TRUE and no #GDestroyNotify
* function has been set for @array.
*
* This function is not thread-safe. If using a #GPtrArray from multiple
* threads, use only the atomic g_ptr_array_ref() and g_ptr_array_unref()
* functions.
*
* Returns: the pointer array if @free_seg is %FALSE, otherwise %NULL.
* The pointer array should be freed using g_free().
*/
gpointer*
g_ptr_array_free (GPtrArray *array,
gboolean free_segment)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
ArrayFreeFlags flags;
g_return_val_if_fail (rarray, NULL);
flags = (free_segment ? FREE_SEGMENT : 0);
/* if others are holding a reference, preserve the wrapper but
* do free/return the data
*/
if (!g_atomic_ref_count_dec (&rarray->ref_count))
flags |= PRESERVE_WRAPPER;
return ptr_array_free (array, flags);
}
static gpointer *
ptr_array_free (GPtrArray *array,
ArrayFreeFlags flags)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
gpointer *segment;
if (flags & FREE_SEGMENT)
{
/* Data here is stolen and freed manually. It is an
* error to attempt to access the array data (including
* mutating the array bounds) during destruction).
*
* https://bugzilla.gnome.org/show_bug.cgi?id=769064
*/
gpointer *stolen_pdata = g_steal_pointer (&rarray->pdata);
if (rarray->element_free_func != NULL)
{
gsize i;
for (i = 0; i < rarray->len; ++i)
rarray->element_free_func (stolen_pdata[i]);
}
g_free (stolen_pdata);
segment = NULL;
}
else
segment = rarray->pdata;
if (flags & PRESERVE_WRAPPER)
{
rarray->pdata = NULL;
rarray->len = 0;
rarray->alloc = 0;
}
else
{
g_slice_free1 (sizeof (GRealPtrArray), rarray);
}
return segment;
}
static void
g_ptr_array_maybe_expand (GRealPtrArray *array,
gint len)
{
if ((array->len + len) > array->alloc)
{
guint old_alloc = array->alloc;
array->alloc = g_nearest_pow (array->len + len);
array->alloc = MAX (array->alloc, MIN_ARRAY_SIZE);
array->pdata = g_realloc (array->pdata, sizeof (gpointer) * array->alloc);
if (G_UNLIKELY (g_mem_gc_friendly))
for ( ; old_alloc < array->alloc; old_alloc++)
array->pdata [old_alloc] = NULL;
}
}
/**
* g_ptr_array_set_size:
* @array: a #GPtrArray
* @length: the new length of the pointer array
*
* Sets the size of the array. When making the array larger,
* newly-added elements will be set to %NULL. When making it smaller,
* if @array has a non-%NULL #GDestroyNotify function then it will be
* called for the removed elements.
*/
void
g_ptr_array_set_size (GPtrArray *array,
gint length)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
guint length_unsigned;
g_return_if_fail (rarray);
g_return_if_fail (rarray->len == 0 || (rarray->len != 0 && rarray->pdata != NULL));
g_return_if_fail (length >= 0);
length_unsigned = (guint) length;
if (length_unsigned > rarray->len)
{
guint i;
g_ptr_array_maybe_expand (rarray, (length_unsigned - rarray->len));
/* This is not
* memset (array->pdata + array->len, 0,
* sizeof (gpointer) * (length_unsigned - array->len));
* to make it really portable. Remember (void*)NULL needn't be
* bitwise zero. It of course is silly not to use memset (..,0,..).
*/
for (i = rarray->len; i < length_unsigned; i++)
rarray->pdata[i] = NULL;
}
else if (length_unsigned < rarray->len)
g_ptr_array_remove_range (array, length_unsigned, rarray->len - length_unsigned);
rarray->len = length_unsigned;
}
static gpointer
ptr_array_remove_index (GPtrArray *array,
guint index_,
gboolean fast,
gboolean free_element)
{
GRealPtrArray *rarray = (GRealPtrArray *) array;
gpointer result;
g_return_val_if_fail (rarray, NULL);
g_return_val_if_fail (rarray->len == 0 || (rarray->len != 0 && rarray->pdata != NULL), NULL);
g_return_val_if_fail (index_ < rarray->len, NULL);
result = rarray->pdata[index_];
if (rarray->element_free_func != NULL && free_element)
rarray->element_free_func (rarray->pdata[index_]);
if (index_ != rarray->len - 1 && !fast)
memmove (rarray->pdata + index_, rarray->pdata + index_ + 1,
sizeof (gpointer) * (rarray->len - index_ - 1));
else if (index_ != rarray->len - 1)
rarray->pdata[index_] = rarray->pdata[rarray->len - 1];
rarray->len -= 1;
if (G_UNLIKELY (g_mem_gc_friendly))
rarray->pdata[rarray->len] = NULL;
return result;
}
/**
* g_ptr_array_remove_index:
* @array: a #GPtrArray
* @index_: the index of the pointer to remove
*
* Removes the pointer at the given index from the pointer array.
* The following elements are moved down one place. If @array has
* a non-%NULL #GDestroyNotify function it is called for the removed
* element. If so, the return value from this function will potentially point
* to freed memory (depending on the #GDestroyNotify implementation).
*
* Returns: (nullable): the pointer which was removed
*/
gpointer
g_ptr_array_remove_index (GPtrArray *array,
guint index_)
{
return ptr_array_remove_index (array, index_, FALSE, TRUE);
}
/**
* g_ptr_array_remove_index_fast:
* @array: a #GPtrArray
* @index_: the index of the pointer to remove
*
* Removes the pointer at the given index from the pointer array.
* The last element in the array is used to fill in the space, so
* this function does not preserve the order of the array. But it
* is faster than g_ptr_array_remove_index(). If @array has a non-%NULL
* #GDestroyNotify function it is called for the removed element. If so, the
* return value from this function will potentially point to freed memory
* (depending on the #GDestroyNotify implementation).
*
* Returns: (nullable): the pointer which was removed
*/
gpointer
g_ptr_array_remove_index_fast (GPtrArray *array,
guint index_)
{
return ptr_array_remove_index (array, index_, TRUE, TRUE);
}
/**
* g_ptr_array_steal_index:
* @array: a #GPtrArray
* @index_: the index of the pointer to steal
*
* Removes the pointer at the given index from the pointer array.
* The following elements are moved down one place. The #GDestroyNotify for
* @array is *not* called on the removed element; ownership is transferred to
* the caller of this function.
*
* Returns: (transfer full) (nullable): the pointer which was removed
* Since: 2.58
*/
gpointer
g_ptr_array_steal_index (GPtrArray *array,
guint index_)
{
return ptr_array_remove_index (array, index_, FALSE, FALSE);
}
/**
* g_ptr_array_steal_index_fast:
* @array: a #GPtrArray
* @index_: the index of the pointer to steal
*
* Removes the pointer at the given index from the pointer array.
* The last element in the array is used to fill in the space, so
* this function does not preserve the order of the array. But it
* is faster than g_ptr_array_steal_index(). The #GDestroyNotify for @array is
* *not* called on the removed element; ownership is transferred to the caller
* of this function.
*
* Returns: (transfer full) (nullable): the pointer which was removed
* Since: 2.58
*/
gpointer
g_ptr_array_steal_index_fast (GPtrArray *array,
guint index_)
{
return ptr_array_remove_index (array, index_, TRUE, FALSE);
}
/**
* g_ptr_array_remove_range:
* @array: a @GPtrArray
* @index_: the index of the first pointer to remove
* @length: the number of pointers to remove
*
* Removes the given number of pointers starting at the given index
* from a #GPtrArray. The following elements are moved to close the
* gap. If @array has a non-%NULL #GDestroyNotify function it is
* called for the removed elements.
*
* Returns: the @array
*
* Since: 2.4
*/
GPtrArray*
g_ptr_array_remove_range (GPtrArray *array,
guint index_,
guint length)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
guint n;
g_return_val_if_fail (rarray != NULL, NULL);
g_return_val_if_fail (rarray->len == 0 || (rarray->len != 0 && rarray->pdata != NULL), NULL);
g_return_val_if_fail (index_ <= rarray->len, NULL);
g_return_val_if_fail (index_ + length <= rarray->len, NULL);
if (rarray->element_free_func != NULL)
{
for (n = index_; n < index_ + length; n++)
rarray->element_free_func (rarray->pdata[n]);
}
if (index_ + length != rarray->len)
{
memmove (&rarray->pdata[index_],
&rarray->pdata[index_ + length],
(rarray->len - (index_ + length)) * sizeof (gpointer));
}
rarray->len -= length;
if (G_UNLIKELY (g_mem_gc_friendly))
{
guint i;
for (i = 0; i < length; i++)
rarray->pdata[rarray->len + i] = NULL;
}
return array;
}
/**
* g_ptr_array_remove:
* @array: a #GPtrArray
* @data: the pointer to remove
*
* Removes the first occurrence of the given pointer from the pointer
* array. The following elements are moved down one place. If @array
* has a non-%NULL #GDestroyNotify function it is called for the
* removed element.
*
* It returns %TRUE if the pointer was removed, or %FALSE if the
* pointer was not found.
*
* Returns: %TRUE if the pointer is removed, %FALSE if the pointer
* is not found in the array
*/
gboolean
g_ptr_array_remove (GPtrArray *array,
gpointer data)
{
guint i;
g_return_val_if_fail (array, FALSE);
g_return_val_if_fail (array->len == 0 || (array->len != 0 && array->pdata != NULL), FALSE);
for (i = 0; i < array->len; i += 1)
{
if (array->pdata[i] == data)
{
g_ptr_array_remove_index (array, i);
return TRUE;
}
}
return FALSE;
}
/**
* g_ptr_array_remove_fast:
* @array: a #GPtrArray
* @data: the pointer to remove
*
* Removes the first occurrence of the given pointer from the pointer
* array. The last element in the array is used to fill in the space,
* so this function does not preserve the order of the array. But it
* is faster than g_ptr_array_remove(). If @array has a non-%NULL
* #GDestroyNotify function it is called for the removed element.
*
* It returns %TRUE if the pointer was removed, or %FALSE if the
* pointer was not found.
*
* Returns: %TRUE if the pointer was found in the array
*/
gboolean
g_ptr_array_remove_fast (GPtrArray *array,
gpointer data)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
guint i;
g_return_val_if_fail (rarray, FALSE);
g_return_val_if_fail (rarray->len == 0 || (rarray->len != 0 && rarray->pdata != NULL), FALSE);
for (i = 0; i < rarray->len; i += 1)
{
if (rarray->pdata[i] == data)
{
g_ptr_array_remove_index_fast (array, i);
return TRUE;
}
}
return FALSE;
}
/**
* g_ptr_array_add:
* @array: a #GPtrArray
* @data: the pointer to add
*
* Adds a pointer to the end of the pointer array. The array will grow
* in size automatically if necessary.
*/
void
g_ptr_array_add (GPtrArray *array,
gpointer data)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
g_return_if_fail (rarray);
g_return_if_fail (rarray->len == 0 || (rarray->len != 0 && rarray->pdata != NULL));
g_ptr_array_maybe_expand (rarray, 1);
rarray->pdata[rarray->len++] = data;
}
/**
* g_ptr_array_insert:
* @array: a #GPtrArray
* @index_: the index to place the new element at, or -1 to append
* @data: the pointer to add.
*
* Inserts an element into the pointer array at the given index. The
* array will grow in size automatically if necessary.
*
* Since: 2.40
*/
void
g_ptr_array_insert (GPtrArray *array,
gint index_,
gpointer data)
{
GRealPtrArray *rarray = (GRealPtrArray *)array;
g_return_if_fail (rarray);
g_return_if_fail (index_ >= -1);
g_return_if_fail (index_ <= (gint)rarray->len);
g_ptr_array_maybe_expand (rarray, 1);
if (index_ < 0)
index_ = rarray->len;
if (index_ < rarray->len)
memmove (&(rarray->pdata[index_ + 1]),
&(rarray->pdata[index_]),
(rarray->len - index_) * sizeof (gpointer));
rarray->len++;
rarray->pdata[index_] = data;
}
/**
* g_ptr_array_sort:
* @array: a #GPtrArray
* @compare_func: comparison function
*
* Sorts the array, using @compare_func which should be a qsort()-style
* comparison function (returns less than zero for first arg is less
* than second arg, zero for equal, greater than zero if irst arg is
* greater than second arg).
*
* Note that the comparison function for g_ptr_array_sort() doesn't
* take the pointers from the array as arguments, it takes pointers to
* the pointers in the array.
*
* This is guaranteed to be a stable sort since version 2.32.
*/
void
g_ptr_array_sort (GPtrArray *array,
GCompareFunc compare_func)
{
g_return_if_fail (array != NULL);
/* Don't use qsort as we want a guaranteed stable sort */
g_qsort_with_data (array->pdata,
array->len,
sizeof (gpointer),
(GCompareDataFunc)compare_func,
NULL);
}
/**
* g_ptr_array_sort_with_data:
* @array: a #GPtrArray
* @compare_func: comparison function
* @user_data: data to pass to @compare_func
*
* Like g_ptr_array_sort(), but the comparison function has an extra
* user data argument.
*
* Note that the comparison function for g_ptr_array_sort_with_data()
* doesn't take the pointers from the array as arguments, it takes
* pointers to the pointers in the array.
*
* This is guaranteed to be a stable sort since version 2.32.
*/
void
g_ptr_array_sort_with_data (GPtrArray *array,
GCompareDataFunc compare_func,
gpointer user_data)
{
g_return_if_fail (array != NULL);
g_qsort_with_data (array->pdata,
array->len,
sizeof (gpointer),
compare_func,
user_data);
}
/**
* g_ptr_array_foreach:
* @array: a #GPtrArray
* @func: the function to call for each array element
* @user_data: user data to pass to the function
*
* Calls a function for each element of a #GPtrArray. @func must not
* add elements to or remove elements from the array.
*
* Since: 2.4
*/
void
g_ptr_array_foreach (GPtrArray *array,
GFunc func,
gpointer user_data)
{
guint i;
g_return_if_fail (array);
for (i = 0; i < array->len; i++)
(*func) (array->pdata[i], user_data);
}
/**
* g_ptr_array_find: (skip)
* @haystack: pointer array to be searched
* @needle: pointer to look for
* @index_: (optional) (out caller-allocates): return location for the index of
* the element, if found
*
* Checks whether @needle exists in @haystack. If the element is found, %TRUE is
* returned and the element’s index is returned in @index_ (if non-%NULL).
* Otherwise, %FALSE is returned and @index_ is undefined. If @needle exists
* multiple times in @haystack, the index of the first instance is returned.
*
* This does pointer comparisons only. If you want to use more complex equality
* checks, such as string comparisons, use g_ptr_array_find_with_equal_func().
*
* Returns: %TRUE if @needle is one of the elements of @haystack
* Since: 2.54
*/
gboolean
g_ptr_array_find (GPtrArray *haystack,
gconstpointer needle,
guint *index_)
{
return g_ptr_array_find_with_equal_func (haystack, needle, NULL, index_);
}
/**
* g_ptr_array_find_with_equal_func: (skip)
* @haystack: pointer array to be searched
* @needle: pointer to look for
* @equal_func: (nullable): the function to call for each element, which should
* return %TRUE when the desired element is found; or %NULL to use pointer
* equality
* @index_: (optional) (out caller-allocates): return location for the index of
* the element, if found
*
* Checks whether @needle exists in @haystack, using the given @equal_func.
* If the element is found, %TRUE is returned and the element’s index is
* returned in @index_ (if non-%NULL). Otherwise, %FALSE is returned and @index_
* is undefined. If @needle exists multiple times in @haystack, the index of
* the first instance is returned.
*
* @equal_func is called with the element from the array as its first parameter,
* and @needle as its second parameter. If @equal_func is %NULL, pointer
* equality is used.
*
* Returns: %TRUE if @needle is one of the elements of @haystack
* Since: 2.54
*/
gboolean
g_ptr_array_find_with_equal_func (GPtrArray *haystack,
gconstpointer needle,
GEqualFunc equal_func,
guint *index_)
{
guint i;
g_return_val_if_fail (haystack != NULL, FALSE);
if (equal_func == NULL)
equal_func = g_direct_equal;
for (i = 0; i < haystack->len; i++)
{
if (equal_func (g_ptr_array_index (haystack, i), needle))
{
if (index_ != NULL)
*index_ = i;
return TRUE;
}
}
return FALSE;
}
/**
* SECTION:arrays_byte
* @title: Byte Arrays
* @short_description: arrays of bytes
*
* #GByteArray is a mutable array of bytes based on #GArray, to provide arrays
* of bytes which grow automatically as elements are added.
*
* To create a new #GByteArray use g_byte_array_new(). To add elements to a
* #GByteArray, use g_byte_array_append(), and g_byte_array_prepend().
*
* To set the size of a #GByteArray, use g_byte_array_set_size().
*
* To free a #GByteArray, use g_byte_array_free().
*
* An example for using a #GByteArray:
* |[<!-- language="C" -->
* GByteArray *gbarray;
* gint i;
*
* gbarray = g_byte_array_new ();
* for (i = 0; i < 10000; i++)
* g_byte_array_append (gbarray, (guint8*) "abcd", 4);
*
* for (i = 0; i < 10000; i++)
* {
* g_assert (gbarray->data[4*i] == 'a');
* g_assert (gbarray->data[4*i+1] == 'b');
* g_assert (gbarray->data[4*i+2] == 'c');
* g_assert (gbarray->data[4*i+3] == 'd');
* }
*
* g_byte_array_free (gbarray, TRUE);
* ]|
*
* See #GBytes if you are interested in an immutable object representing a
* sequence of bytes.
*/
/**
* GByteArray:
* @data: a pointer to the element data. The data may be moved as
* elements are added to the #GByteArray
* @len: the number of elements in the #GByteArray
*
* Contains the public fields of a GByteArray.
*/
/**
* g_byte_array_new:
*
* Creates a new #GByteArray with a reference count of 1.
*
* Returns: (transfer full): the new #GByteArray
*/
GByteArray*
g_byte_array_new (void)
{
return (GByteArray *)g_array_sized_new (FALSE, FALSE, 1, 0);
}
/**
* g_byte_array_new_take:
* @data: (transfer full) (array length=len): byte data for the array
* @len: length of @data
*
* Create byte array containing the data. The data will be owned by the array
* and will be freed with g_free(), i.e. it could be allocated using g_strdup().
*
* Since: 2.32
*
* Returns: (transfer full): a new #GByteArray
*/
GByteArray*
g_byte_array_new_take (guint8 *data,
gsize len)
{
GByteArray *array;
GRealArray *real;
array = g_byte_array_new ();
real = (GRealArray *)array;
g_assert (real->data == NULL);
g_assert (real->len == 0);
real->data = data;
real->len = len;
real->alloc = len;
return array;
}
/**
* g_byte_array_sized_new:
* @reserved_size: number of bytes preallocated
*
* Creates a new #GByteArray with @reserved_size bytes preallocated.
* This avoids frequent reallocation, if you are going to add many
* bytes to the array. Note however that the size of the array is still
* 0.
*
* Returns: the new #GByteArray
*/
GByteArray*
g_byte_array_sized_new (guint reserved_size)
{
return (GByteArray *)g_array_sized_new (FALSE, FALSE, 1, reserved_size);
}
/**
* g_byte_array_free:
* @array: a #GByteArray
* @free_segment: if %TRUE the actual byte data is freed as well
*
* Frees the memory allocated by the #GByteArray. If @free_segment is
* %TRUE it frees the actual byte data. If the reference count of
* @array is greater than one, the #GByteArray wrapper is preserved but
* the size of @array will be set to zero.
*
* Returns: the element data if @free_segment is %FALSE, otherwise
* %NULL. The element data should be freed using g_free().
*/
guint8*
g_byte_array_free (GByteArray *array,
gboolean free_segment)
{
return (guint8 *)g_array_free ((GArray *)array, free_segment);
}
/**
* g_byte_array_free_to_bytes:
* @array: (transfer full): a #GByteArray
*
* Transfers the data from the #GByteArray into a new immutable #GBytes.
*
* The #GByteArray is freed unless the reference count of @array is greater
* than one, the #GByteArray wrapper is preserved but the size of @array
* will be set to zero.
*
* This is identical to using g_bytes_new_take() and g_byte_array_free()
* together.
*
* Since: 2.32
*
* Returns: (transfer full): a new immutable #GBytes representing same
* byte data that was in the array
*/
GBytes*
g_byte_array_free_to_bytes (GByteArray *array)
{
gsize length;
g_return_val_if_fail (array != NULL, NULL);
length = array->len;
return g_bytes_new_take (g_byte_array_free (array, FALSE), length);
}
/**
* g_byte_array_ref:
* @array: A #GByteArray
*
* Atomically increments the reference count of @array by one.
* This function is thread-safe and may be called from any thread.
*
* Returns: The passed in #GByteArray
*
* Since: 2.22
*/
GByteArray*
g_byte_array_ref (GByteArray *array)
{
return (GByteArray *)g_array_ref ((GArray *)array);
}
/**
* g_byte_array_unref:
* @array: A #GByteArray
*
* Atomically decrements the reference count of @array by one. If the
* reference count drops to 0, all memory allocated by the array is
* released. This function is thread-safe and may be called from any
* thread.
*
* Since: 2.22
*/
void
g_byte_array_unref (GByteArray *array)
{
g_array_unref ((GArray *)array);
}
/**
* g_byte_array_append:
* @array: a #GByteArray
* @data: the byte data to be added
* @len: the number of bytes to add
*
* Adds the given bytes to the end of the #GByteArray.
* The array will grow in size automatically if necessary.
*
* Returns: the #GByteArray
*/
GByteArray*
g_byte_array_append (GByteArray *array,
const guint8 *data,
guint len)
{
g_array_append_vals ((GArray *)array, (guint8 *)data, len);
return array;
}
/**
* g_byte_array_prepend:
* @array: a #GByteArray
* @data: the byte data to be added
* @len: the number of bytes to add
*
* Adds the given data to the start of the #GByteArray.
* The array will grow in size automatically if necessary.
*
* Returns: the #GByteArray
*/
GByteArray*
g_byte_array_prepend (GByteArray *array,
const guint8 *data,
guint len)
{
g_array_prepend_vals ((GArray *)array, (guint8 *)data, len);
return array;
}
/**
* g_byte_array_set_size:
* @array: a #GByteArray
* @length: the new size of the #GByteArray
*
* Sets the size of the #GByteArray, expanding it if necessary.
*
* Returns: the #GByteArray
*/
GByteArray*
g_byte_array_set_size (GByteArray *array,
guint length)
{
g_array_set_size ((GArray *)array, length);
return array;
}
/**
* g_byte_array_remove_index:
* @array: a #GByteArray
* @index_: the index of the byte to remove
*
* Removes the byte at the given index from a #GByteArray.
* The following bytes are moved down one place.
*
* Returns: the #GByteArray
**/
GByteArray*
g_byte_array_remove_index (GByteArray *array,
guint index_)
{
g_array_remove_index ((GArray *)array, index_);
return array;
}
/**
* g_byte_array_remove_index_fast:
* @array: a #GByteArray
* @index_: the index of the byte to remove
*
* Removes the byte at the given index from a #GByteArray. The last
* element in the array is used to fill in the space, so this function
* does not preserve the order of the #GByteArray. But it is faster
* than g_byte_array_remove_index().
*
* Returns: the #GByteArray
*/
GByteArray*
g_byte_array_remove_index_fast (GByteArray *array,
guint index_)
{
g_array_remove_index_fast ((GArray *)array, index_);
return array;
}
/**
* g_byte_array_remove_range:
* @array: a @GByteArray
* @index_: the index of the first byte to remove
* @length: the number of bytes to remove
*
* Removes the given number of bytes starting at the given index from a
* #GByteArray. The following elements are moved to close the gap.
*
* Returns: the #GByteArray
*
* Since: 2.4
*/
GByteArray*
g_byte_array_remove_range (GByteArray *array,
guint index_,
guint length)
{
g_return_val_if_fail (array, NULL);
g_return_val_if_fail (index_ <= array->len, NULL);
g_return_val_if_fail (index_ + length <= array->len, NULL);
return (GByteArray *)g_array_remove_range ((GArray *)array, index_, length);
}
/**
* g_byte_array_sort:
* @array: a #GByteArray
* @compare_func: comparison function
*
* Sorts a byte array, using @compare_func which should be a
* qsort()-style comparison function (returns less than zero for first
* arg is less than second arg, zero for equal, greater than zero if
* first arg is greater than second arg).
*
* If two array elements compare equal, their order in the sorted array
* is undefined. If you want equal elements to keep their order (i.e.
* you want a stable sort) you can write a comparison function that,
* if two elements would otherwise compare equal, compares them by
* their addresses.
*/
void
g_byte_array_sort (GByteArray *array,
GCompareFunc compare_func)
{
g_array_sort ((GArray *)array, compare_func);
}
/**
* g_byte_array_sort_with_data:
* @array: a #GByteArray
* @compare_func: comparison function
* @user_data: data to pass to @compare_func
*
* Like g_byte_array_sort(), but the comparison function takes an extra
* user data argument.
*/
void
g_byte_array_sort_with_data (GByteArray *array,
GCompareDataFunc compare_func,
gpointer user_data)
{
g_array_sort_with_data ((GArray *)array, compare_func, user_data);
}