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mutter/deps/glib/gdataset.c

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build: Allow to build cogl without an external glib dependency This commit pushes --disable-glib to the extreme of embedding the par of glib cogl depends on in tree to be able to generate a DSO that does not depend on an external glib. To do so, it: - keeps a lot of glib's configure.ac in as-glibconfig.m4 - pulls the code cogl depends on and the necessary dependencies Reviewed-by: Robert Bragg <robert@linux.intel.com>
2012-09-16 21:20:10 -04:00
/* GLIB - Library of useful routines for C programming
* Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
*
* gdataset.c: Generic dataset mechanism, similar to GtkObject data.
* Copyright (C) 1998 Tim Janik
*
* 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 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, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA.
*/
/*
* 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 ; except for g_data*_foreach()
*/
#include "config.h"
#include <string.h>
#include "gdataset.h"
#include "gbitlock.h"
#include "gdatasetprivate.h"
#include "ghash.h"
#include "gquark.h"
#include "gstrfuncs.h"
#include "gtestutils.h"
#include "gthread.h"
#include "glib_trace.h"
/**
* SECTION:datasets
* @title: Datasets
* @short_description: associate groups of data elements with
* particular memory locations
*
* Datasets associate groups of data elements with particular memory
* locations. These are useful if you need to associate data with a
* structure returned from an external library. Since you cannot modify
* the structure, you use its location in memory as the key into a
* dataset, where you can associate any number of data elements with it.
*
* There are two forms of most of the dataset functions. The first form
* uses strings to identify the data elements associated with a
* location. The second form uses #GQuark identifiers, which are
* created with a call to g_quark_from_string() or
* g_quark_from_static_string(). The second form is quicker, since it
* does not require looking up the string in the hash table of #GQuark
* identifiers.
*
* There is no function to create a dataset. It is automatically
* created as soon as you add elements to it.
*
* To add data elements to a dataset use g_dataset_id_set_data(),
* g_dataset_id_set_data_full(), g_dataset_set_data() and
* g_dataset_set_data_full().
*
* To get data elements from a dataset use g_dataset_id_get_data() and
* g_dataset_get_data().
*
* To iterate over all data elements in a dataset use
* g_dataset_foreach() (not thread-safe).
*
* To remove data elements from a dataset use
* g_dataset_id_remove_data() and g_dataset_remove_data().
*
* To destroy a dataset, use g_dataset_destroy().
**/
/**
* SECTION:datalist
* @title: Keyed Data Lists
* @short_description: lists of data elements which are accessible by a
* string or GQuark identifier
*
* Keyed data lists provide lists of arbitrary data elements which can
* be accessed either with a string or with a #GQuark corresponding to
* the string.
*
* The #GQuark methods are quicker, since the strings have to be
* converted to #GQuarks anyway.
*
* Data lists are used for associating arbitrary data with #GObjects,
* using g_object_set_data() and related functions.
*
* To create a datalist, use g_datalist_init().
*
* To add data elements to a datalist use g_datalist_id_set_data(),
* g_datalist_id_set_data_full(), g_datalist_set_data() and
* g_datalist_set_data_full().
*
* To get data elements from a datalist use g_datalist_id_get_data()
* and g_datalist_get_data().
*
* To iterate over all data elements in a datalist use
* g_datalist_foreach() (not thread-safe).
*
* To remove data elements from a datalist use
* g_datalist_id_remove_data() and g_datalist_remove_data().
*
* To remove all data elements from a datalist, use g_datalist_clear().
**/
/**
* GData:
*
* The #GData struct is an opaque data structure to represent a <link
* linkend="glib-Keyed-Data-Lists">Keyed Data List</link>. It should
* only be accessed via the following functions.
**/
/**
* GDestroyNotify:
* @data: the data element.
*
* Specifies the type of function which is called when a data element
* is destroyed. It is passed the pointer to the data element and
* should free any memory and resources allocated for it.
**/
/* --- defines --- */
#define G_QUARK_BLOCK_SIZE (2048)
#define G_DATALIST_FLAGS_MASK_INTERNAL 0x7
/* datalist pointer accesses have to be carried out atomically */
#define G_DATALIST_GET_POINTER(datalist) \
((GData*) ((gsize) g_atomic_pointer_get (datalist) & ~(gsize) G_DATALIST_FLAGS_MASK_INTERNAL))
#define G_DATALIST_SET_POINTER(datalist, pointer) G_STMT_START { \
gpointer _oldv, _newv; \
do { \
_oldv = g_atomic_pointer_get (datalist); \
_newv = (gpointer) (((gsize) _oldv & G_DATALIST_FLAGS_MASK_INTERNAL) | (gsize) pointer); \
} while (!g_atomic_pointer_compare_and_exchange ((void**) datalist, _oldv, _newv)); \
} G_STMT_END
/* --- structures --- */
typedef struct {
GQuark key;
gpointer data;
GDestroyNotify destroy;
} GDataElt;
typedef struct _GDataset GDataset;
struct _GData
{
guint32 len; /* Number of elements */
guint32 alloc; /* Number of allocated elements */
GDataElt data[1]; /* Flexible array */
};
struct _GDataset
{
gconstpointer location;
GData *datalist;
};
/* --- prototypes --- */
static inline GDataset* g_dataset_lookup (gconstpointer dataset_location);
static inline void g_datalist_clear_i (GData **datalist);
static void g_dataset_destroy_internal (GDataset *dataset);
static inline gpointer g_data_set_internal (GData **datalist,
GQuark key_id,
gpointer data,
GDestroyNotify destroy_func,
GDataset *dataset);
static void g_data_initialize (void);
static inline GQuark g_quark_new (gchar *string);
/* Locking model:
* Each standalone GDataList is protected by a bitlock in the datalist pointer,
* which protects that modification of the non-flags part of the datalist pointer
* and the contents of the datalist.
*
* For GDataSet we have a global lock g_dataset_global that protects
* the global dataset hash and cache, and additionally it protects the
* datalist such that we can avoid to use the bit lock in a few places
* where it is easy.
*/
/* --- variables --- */
G_LOCK_DEFINE_STATIC (g_dataset_global);
static GHashTable *g_dataset_location_ht = NULL;
static GDataset *g_dataset_cached = NULL; /* should this be
threadspecific? */
G_LOCK_DEFINE_STATIC (g_quark_global);
static GHashTable *g_quark_ht = NULL;
static gchar **g_quarks = NULL;
static int g_quark_seq_id = 0;
/* --- functions --- */
#define DATALIST_LOCK_BIT 2
static void
g_datalist_lock (GData **datalist)
{
g_pointer_bit_lock ((void **)datalist, DATALIST_LOCK_BIT);
}
static void
g_datalist_unlock (GData **datalist)
{
g_pointer_bit_unlock ((void **)datalist, DATALIST_LOCK_BIT);
}
/* Called with the datalist lock held, or the dataset global
* lock for dataset lists
*/
static void
g_datalist_clear_i (GData **datalist)
{
GData *data;
gint i;
data = G_DATALIST_GET_POINTER (datalist);
G_DATALIST_SET_POINTER (datalist, NULL);
if (data)
{
G_UNLOCK (g_dataset_global);
for (i = 0; i < data->len; i++)
{
if (data->data[i].data && data->data[i].destroy)
data->data[i].destroy (data->data[i].data);
}
G_LOCK (g_dataset_global);
g_free (data);
}
}
/**
* g_datalist_clear:
* @datalist: a datalist.
*
* Frees all the data elements of the datalist.
* The data elements' destroy functions are called
* if they have been set.
**/
void
g_datalist_clear (GData **datalist)
{
GData *data;
gint i;
g_return_if_fail (datalist != NULL);
g_datalist_lock (datalist);
data = G_DATALIST_GET_POINTER (datalist);
G_DATALIST_SET_POINTER (datalist, NULL);
g_datalist_unlock (datalist);
if (data)
{
for (i = 0; i < data->len; i++)
{
if (data->data[i].data && data->data[i].destroy)
data->data[i].destroy (data->data[i].data);
}
g_free (data);
}
}
/* HOLDS: g_dataset_global_lock */
static inline GDataset*
g_dataset_lookup (gconstpointer dataset_location)
{
register GDataset *dataset;
if (g_dataset_cached && g_dataset_cached->location == dataset_location)
return g_dataset_cached;
dataset = g_hash_table_lookup (g_dataset_location_ht, dataset_location);
if (dataset)
g_dataset_cached = dataset;
return dataset;
}
/* HOLDS: g_dataset_global_lock */
static void
g_dataset_destroy_internal (GDataset *dataset)
{
register gconstpointer dataset_location;
dataset_location = dataset->location;
while (dataset)
{
if (G_DATALIST_GET_POINTER(&dataset->datalist) == NULL)
{
if (dataset == g_dataset_cached)
g_dataset_cached = NULL;
g_hash_table_remove (g_dataset_location_ht, dataset_location);
g_slice_free (GDataset, dataset);
break;
}
g_datalist_clear_i (&dataset->datalist);
dataset = g_dataset_lookup (dataset_location);
}
}
/**
* g_dataset_destroy:
* @dataset_location: the location identifying the dataset.
*
* Destroys the dataset, freeing all memory allocated, and calling any
* destroy functions set for data elements.
*/
void
g_dataset_destroy (gconstpointer dataset_location)
{
g_return_if_fail (dataset_location != NULL);
G_LOCK (g_dataset_global);
if (g_dataset_location_ht)
{
register GDataset *dataset;
dataset = g_dataset_lookup (dataset_location);
if (dataset)
g_dataset_destroy_internal (dataset);
}
G_UNLOCK (g_dataset_global);
}
/* HOLDS: g_dataset_global_lock if dataset != null */
static inline gpointer
g_data_set_internal (GData **datalist,
GQuark key_id,
gpointer new_data,
GDestroyNotify new_destroy_func,
GDataset *dataset)
{
GData *d, *old_d;
GDataElt old, *data, *data_last, *data_end;
g_datalist_lock (datalist);
d = G_DATALIST_GET_POINTER (datalist);
if (new_data == NULL) /* remove */
{
if (d)
{
data = d->data;
data_last = data + d->len - 1;
while (data <= data_last)
{
if (data->key == key_id)
{
old = *data;
if (data != data_last)
*data = *data_last;
d->len--;
/* We don't bother to shrink, but if all data are now gone
* we at least free the memory
*/
if (d->len == 0)
{
G_DATALIST_SET_POINTER (datalist, NULL);
g_free (d);
/* datalist may be situated in dataset, so must not be
* unlocked after we free it
*/
g_datalist_unlock (datalist);
/* the dataset destruction *must* be done
* prior to invocation of the data destroy function
*/
if (dataset)
g_dataset_destroy_internal (dataset);
}
else
{
g_datalist_unlock (datalist);
}
/* We found and removed an old value
* the GData struct *must* already be unlinked
* when invoking the destroy function.
* we use (new_data==NULL && new_destroy_func!=NULL) as
* a special hint combination to "steal"
* data without destroy notification
*/
if (old.destroy && !new_destroy_func)
{
if (dataset)
G_UNLOCK (g_dataset_global);
old.destroy (old.data);
if (dataset)
G_LOCK (g_dataset_global);
old.data = NULL;
}
return old.data;
}
data++;
}
}
}
else
{
old.data = NULL;
if (d)
{
data = d->data;
data_end = data + d->len;
while (data < data_end)
{
if (data->key == key_id)
{
if (!data->destroy)
{
data->data = new_data;
data->destroy = new_destroy_func;
g_datalist_unlock (datalist);
}
else
{
old = *data;
data->data = new_data;
data->destroy = new_destroy_func;
g_datalist_unlock (datalist);
/* We found and replaced an old value
* the GData struct *must* already be unlinked
* when invoking the destroy function.
*/
if (dataset)
G_UNLOCK (g_dataset_global);
old.destroy (old.data);
if (dataset)
G_LOCK (g_dataset_global);
}
return NULL;
}
data++;
}
}
/* The key was not found, insert it */
old_d = d;
if (d == NULL)
{
d = g_malloc (sizeof (GData));
d->len = 0;
d->alloc = 1;
}
else if (d->len == d->alloc)
{
d->alloc = d->alloc * 2;
d = g_realloc (d, sizeof (GData) + (d->alloc - 1) * sizeof (GDataElt));
}
if (old_d != d)
G_DATALIST_SET_POINTER (datalist, d);
d->data[d->len].key = key_id;
d->data[d->len].data = new_data;
d->data[d->len].destroy = new_destroy_func;
d->len++;
}
g_datalist_unlock (datalist);
return NULL;
}
/**
* g_dataset_id_set_data_full:
* @dataset_location: the location identifying the dataset.
* @key_id: the #GQuark id to identify the data element.
* @data: the data element.
* @destroy_func: the function to call when the data element is
* removed. This function will be called with the data
* element and can be used to free any memory allocated
* for it.
*
* Sets the data element associated with the given #GQuark id, and also
* the function to call when the data element is destroyed. Any
* previous data with the same key is removed, and its destroy function
* is called.
**/
/**
* g_dataset_set_data_full:
* @l: the location identifying the dataset.
* @k: the string to identify the data element.
* @d: the data element.
* @f: the function to call when the data element is removed. This
* function will be called with the data element and can be used to
* free any memory allocated for it.
*
* Sets the data corresponding to the given string identifier, and the
* function to call when the data element is destroyed.
**/
/**
* g_dataset_id_set_data:
* @l: the location identifying the dataset.
* @k: the #GQuark id to identify the data element.
* @d: the data element.
*
* Sets the data element associated with the given #GQuark id. Any
* previous data with the same key is removed, and its destroy function
* is called.
**/
/**
* g_dataset_set_data:
* @l: the location identifying the dataset.
* @k: the string to identify the data element.
* @d: the data element.
*
* Sets the data corresponding to the given string identifier.
**/
/**
* g_dataset_id_remove_data:
* @l: the location identifying the dataset.
* @k: the #GQuark id identifying the data element.
*
* Removes a data element from a dataset. The data element's destroy
* function is called if it has been set.
**/
/**
* g_dataset_remove_data:
* @l: the location identifying the dataset.
* @k: the string identifying the data element.
*
* Removes a data element corresponding to a string. Its destroy
* function is called if it has been set.
**/
void
g_dataset_id_set_data_full (gconstpointer dataset_location,
GQuark key_id,
gpointer data,
GDestroyNotify destroy_func)
{
register GDataset *dataset;
g_return_if_fail (dataset_location != NULL);
if (!data)
g_return_if_fail (destroy_func == NULL);
if (!key_id)
{
if (data)
g_return_if_fail (key_id > 0);
else
return;
}
G_LOCK (g_dataset_global);
if (!g_dataset_location_ht)
g_data_initialize ();
dataset = g_dataset_lookup (dataset_location);
if (!dataset)
{
dataset = g_slice_new (GDataset);
dataset->location = dataset_location;
g_datalist_init (&dataset->datalist);
g_hash_table_insert (g_dataset_location_ht,
(gpointer) dataset->location,
dataset);
}
g_data_set_internal (&dataset->datalist, key_id, data, destroy_func, dataset);
G_UNLOCK (g_dataset_global);
}
/**
* g_datalist_id_set_data_full:
* @datalist: a datalist.
* @key_id: the #GQuark to identify the data element.
* @data: the data element or %NULL to remove any previous element
* corresponding to @key_id.
* @destroy_func: the function to call when the data element is
* removed. This function will be called with the data
* element and can be used to free any memory allocated
* for it. If @data is %NULL, then @destroy_func must
* also be %NULL.
*
* Sets the data corresponding to the given #GQuark id, and the
* function to be called when the element is removed from the datalist.
* Any previous data with the same key is removed, and its destroy
* function is called.
**/
/**
* g_datalist_set_data_full:
* @dl: a datalist.
* @k: the string to identify the data element.
* @d: the data element, or %NULL to remove any previous element
* corresponding to @k.
* @f: the function to call when the data element is removed. This
* function will be called with the data element and can be used to
* free any memory allocated for it. If @d is %NULL, then @f must
* also be %NULL.
*
* Sets the data element corresponding to the given string identifier,
* and the function to be called when the data element is removed.
**/
/**
* g_datalist_id_set_data:
* @dl: a datalist.
* @q: the #GQuark to identify the data element.
* @d: the data element, or %NULL to remove any previous element
* corresponding to @q.
*
* Sets the data corresponding to the given #GQuark id. Any previous
* data with the same key is removed, and its destroy function is
* called.
**/
/**
* g_datalist_set_data:
* @dl: a datalist.
* @k: the string to identify the data element.
* @d: the data element, or %NULL to remove any previous element
* corresponding to @k.
*
* Sets the data element corresponding to the given string identifier.
**/
/**
* g_datalist_id_remove_data:
* @dl: a datalist.
* @q: the #GQuark identifying the data element.
*
* Removes an element, using its #GQuark identifier.
**/
/**
* g_datalist_remove_data:
* @dl: a datalist.
* @k: the string identifying the data element.
*
* Removes an element using its string identifier. The data element's
* destroy function is called if it has been set.
**/
void
g_datalist_id_set_data_full (GData **datalist,
GQuark key_id,
gpointer data,
GDestroyNotify destroy_func)
{
g_return_if_fail (datalist != NULL);
if (!data)
g_return_if_fail (destroy_func == NULL);
if (!key_id)
{
if (data)
g_return_if_fail (key_id > 0);
else
return;
}
g_data_set_internal (datalist, key_id, data, destroy_func, NULL);
}
/**
* g_dataset_id_remove_no_notify:
* @dataset_location: the location identifying the dataset.
* @key_id: the #GQuark ID identifying the data element.
* @Returns: the data previously stored at @key_id, or %NULL if none.
*
* Removes an element, without calling its destroy notification
* function.
**/
/**
* g_dataset_remove_no_notify:
* @l: the location identifying the dataset.
* @k: the string identifying the data element.
*
* Removes an element, without calling its destroy notifier.
**/
gpointer
g_dataset_id_remove_no_notify (gconstpointer dataset_location,
GQuark key_id)
{
gpointer ret_data = NULL;
g_return_val_if_fail (dataset_location != NULL, NULL);
G_LOCK (g_dataset_global);
if (key_id && g_dataset_location_ht)
{
GDataset *dataset;
dataset = g_dataset_lookup (dataset_location);
if (dataset)
ret_data = g_data_set_internal (&dataset->datalist, key_id, NULL, (GDestroyNotify) 42, dataset);
}
G_UNLOCK (g_dataset_global);
return ret_data;
}
/**
* g_datalist_id_remove_no_notify:
* @datalist: a datalist.
* @key_id: the #GQuark identifying a data element.
* @Returns: the data previously stored at @key_id, or %NULL if none.
*
* Removes an element, without calling its destroy notification
* function.
**/
/**
* g_datalist_remove_no_notify:
* @dl: a datalist.
* @k: the string identifying the data element.
*
* Removes an element, without calling its destroy notifier.
**/
gpointer
g_datalist_id_remove_no_notify (GData **datalist,
GQuark key_id)
{
gpointer ret_data = NULL;
g_return_val_if_fail (datalist != NULL, NULL);
if (key_id)
ret_data = g_data_set_internal (datalist, key_id, NULL, (GDestroyNotify) 42, NULL);
return ret_data;
}
/**
* g_dataset_id_get_data:
* @dataset_location: the location identifying the dataset.
* @key_id: the #GQuark id to identify the data element.
* @Returns: the data element corresponding to the #GQuark, or %NULL if
* it is not found.
*
* Gets the data element corresponding to a #GQuark.
**/
/**
* g_dataset_get_data:
* @l: the location identifying the dataset.
* @k: the string identifying the data element.
* @Returns: the data element corresponding to the string, or %NULL if
* it is not found.
*
* Gets the data element corresponding to a string.
**/
gpointer
g_dataset_id_get_data (gconstpointer dataset_location,
GQuark key_id)
{
gpointer retval = NULL;
g_return_val_if_fail (dataset_location != NULL, NULL);
G_LOCK (g_dataset_global);
if (key_id && g_dataset_location_ht)
{
GDataset *dataset;
dataset = g_dataset_lookup (dataset_location);
if (dataset)
retval = g_datalist_id_get_data (&dataset->datalist, key_id);
}
G_UNLOCK (g_dataset_global);
return retval;
}
/**
* g_datalist_id_get_data:
* @datalist: a datalist.
* @key_id: the #GQuark identifying a data element.
* @Returns: the data element, or %NULL if it is not found.
*
* Retrieves the data element corresponding to @key_id.
**/
gpointer
g_datalist_id_get_data (GData **datalist,
GQuark key_id)
{
gpointer res = NULL;
g_return_val_if_fail (datalist != NULL, NULL);
if (key_id)
{
GData *d;
GDataElt *data, *data_end;
g_datalist_lock (datalist);
d = G_DATALIST_GET_POINTER (datalist);
if (d)
{
data = d->data;
data_end = data + d->len;
while (data < data_end)
{
if (data->key == key_id)
{
res = data->data;
break;
}
data++;
}
}
g_datalist_unlock (datalist);
}
return res;
}
/**
* g_datalist_get_data:
* @datalist: a datalist.
* @key: the string identifying a data element.
* @Returns: the data element, or %NULL if it is not found.
*
* Gets a data element, using its string identifer. This is slower than
* g_datalist_id_get_data() because it compares strings.
**/
gpointer
g_datalist_get_data (GData **datalist,
const gchar *key)
{
gpointer res = NULL;
GData *d;
GDataElt *data, *data_end;
g_return_val_if_fail (datalist != NULL, NULL);
g_datalist_lock (datalist);
d = G_DATALIST_GET_POINTER (datalist);
if (d)
{
data = d->data;
data_end = data + d->len;
while (data < data_end)
{
if (strcmp (g_quark_to_string (data->key), key) == 0)
{
res = data->data;
break;
}
data++;
}
}
g_datalist_unlock (datalist);
return res;
}
/**
* GDataForeachFunc:
* @key_id: the #GQuark id to identifying the data element.
* @data: the data element.
* @user_data: user data passed to g_dataset_foreach().
*
* Specifies the type of function passed to g_dataset_foreach(). It is
* called with each #GQuark id and associated data element, together
* with the @user_data parameter supplied to g_dataset_foreach().
**/
/**
* g_dataset_foreach:
* @dataset_location: the location identifying the dataset.
* @func: the function to call for each data element.
* @user_data: user data to pass to the function.
*
* Calls the given function for each data element which is associated
* with the given location. Note that this function is NOT thread-safe.
* So unless @datalist can be protected from any modifications during
* invocation of this function, it should not be called.
**/
void
g_dataset_foreach (gconstpointer dataset_location,
GDataForeachFunc func,
gpointer user_data)
{
register GDataset *dataset;
g_return_if_fail (dataset_location != NULL);
g_return_if_fail (func != NULL);
G_LOCK (g_dataset_global);
if (g_dataset_location_ht)
{
dataset = g_dataset_lookup (dataset_location);
G_UNLOCK (g_dataset_global);
if (dataset)
g_datalist_foreach (&dataset->datalist, func, user_data);
}
else
{
G_UNLOCK (g_dataset_global);
}
}
/**
* g_datalist_foreach:
* @datalist: a datalist.
* @func: the function to call for each data element.
* @user_data: user data to pass to the function.
*
* Calls the given function for each data element of the datalist. The
* function is called with each data element's #GQuark id and data,
* together with the given @user_data parameter. Note that this
* function is NOT thread-safe. So unless @datalist can be protected
* from any modifications during invocation of this function, it should
* not be called.
**/
void
g_datalist_foreach (GData **datalist,
GDataForeachFunc func,
gpointer user_data)
{
GData *d;
int i, j, len;
GQuark *keys;
g_return_if_fail (datalist != NULL);
g_return_if_fail (func != NULL);
d = G_DATALIST_GET_POINTER (datalist);
if (d == NULL)
return;
/* We make a copy of the keys so that we can handle it changing
in the callback */
len = d->len;
keys = g_new (GQuark, len);
for (i = 0; i < len; i++)
keys[i] = d->data[i].key;
for (i = 0; i < len; i++)
{
/* A previous callback might have removed a later item, so always check that
it still exists before calling */
d = G_DATALIST_GET_POINTER (datalist);
if (d == NULL)
break;
for (j = 0; j < d->len; j++)
{
if (d->data[j].key == keys[i]) {
func (d->data[i].key, d->data[i].data, user_data);
break;
}
}
}
g_free (keys);
}
/**
* g_datalist_init:
* @datalist: a pointer to a pointer to a datalist.
*
* Resets the datalist to %NULL. It does not free any memory or call
* any destroy functions.
**/
void
g_datalist_init (GData **datalist)
{
g_return_if_fail (datalist != NULL);
g_atomic_pointer_set (datalist, NULL);
}
/**
* g_datalist_set_flags:
* @datalist: pointer to the location that holds a list
* @flags: the flags to turn on. The values of the flags are
* restricted by %G_DATALIST_FLAGS_MASK (currently
* 3; giving two possible boolean flags).
* A value for @flags that doesn't fit within the mask is
* an error.
*
* Turns on flag values for a data list. This function is used
* to keep a small number of boolean flags in an object with
* a data list without using any additional space. It is
* not generally useful except in circumstances where space
* is very tight. (It is used in the base #GObject type, for
* example.)
*
* Since: 2.8
**/
void
g_datalist_set_flags (GData **datalist,
guint flags)
{
g_return_if_fail (datalist != NULL);
g_return_if_fail ((flags & ~G_DATALIST_FLAGS_MASK) == 0);
g_atomic_pointer_or (datalist, (gsize)flags);
}
/**
* g_datalist_unset_flags:
* @datalist: pointer to the location that holds a list
* @flags: the flags to turn off. The values of the flags are
* restricted by %G_DATALIST_FLAGS_MASK (currently
* 3: giving two possible boolean flags).
* A value for @flags that doesn't fit within the mask is
* an error.
*
* Turns off flag values for a data list. See g_datalist_unset_flags()
*
* Since: 2.8
**/
void
g_datalist_unset_flags (GData **datalist,
guint flags)
{
g_return_if_fail (datalist != NULL);
g_return_if_fail ((flags & ~G_DATALIST_FLAGS_MASK) == 0);
g_atomic_pointer_and (datalist, ~(gsize)flags);
}
/**
* g_datalist_get_flags:
* @datalist: pointer to the location that holds a list
*
* Gets flags values packed in together with the datalist.
* See g_datalist_set_flags().
*
* Return value: the flags of the datalist
*
* Since: 2.8
**/
guint
g_datalist_get_flags (GData **datalist)
{
g_return_val_if_fail (datalist != NULL, 0);
return G_DATALIST_GET_FLAGS (datalist); /* atomic macro */
}
/* HOLDS: g_dataset_global_lock */
static void
g_data_initialize (void)
{
g_return_if_fail (g_dataset_location_ht == NULL);
g_dataset_location_ht = g_hash_table_new (g_direct_hash, NULL);
g_dataset_cached = NULL;
}
/**
* SECTION:quarks
* @title: Quarks
* @short_description: a 2-way association between a string and a
* unique integer identifier
*
* Quarks are associations between strings and integer identifiers.
* Given either the string or the #GQuark identifier it is possible to
* retrieve the other.
*
* Quarks are used for both <link
* linkend="glib-Datasets">Datasets</link> and <link
* linkend="glib-Keyed-Data-Lists">Keyed Data Lists</link>.
*
* To create a new quark from a string, use g_quark_from_string() or
* g_quark_from_static_string().
*
* To find the string corresponding to a given #GQuark, use
* g_quark_to_string().
*
* To find the #GQuark corresponding to a given string, use
* g_quark_try_string().
*
* Another use for the string pool maintained for the quark functions
* is string interning, using g_intern_string() or
* g_intern_static_string(). An interned string is a canonical
* representation for a string. One important advantage of interned
* strings is that they can be compared for equality by a simple
* pointer comparison, rather than using strcmp().
**/
/**
* GQuark:
*
* A GQuark is a non-zero integer which uniquely identifies a
* particular string. A GQuark value of zero is associated to %NULL.
**/
/**
* g_quark_try_string:
* @string: (allow-none): a string.
* @Returns: the #GQuark associated with the string, or 0 if @string is
* %NULL or there is no #GQuark associated with it.
*
* Gets the #GQuark associated with the given string, or 0 if string is
* %NULL or it has no associated #GQuark.
*
* If you want the GQuark to be created if it doesn't already exist,
* use g_quark_from_string() or g_quark_from_static_string().
**/
GQuark
g_quark_try_string (const gchar *string)
{
GQuark quark = 0;
if (string == NULL)
return 0;
G_LOCK (g_quark_global);
if (g_quark_ht)
quark = GPOINTER_TO_UINT (g_hash_table_lookup (g_quark_ht, string));
G_UNLOCK (g_quark_global);
return quark;
}
#define QUARK_STRING_BLOCK_SIZE (4096 - sizeof (gsize))
static char *quark_block = NULL;
static int quark_block_offset = 0;
/* HOLDS: g_quark_global_lock */
static char *
quark_strdup(const gchar *string)
{
gchar *copy;
gsize len;
len = strlen (string) + 1;
/* For strings longer than half the block size, fall back
to strdup so that we fill our blocks at least 50%. */
if (len > QUARK_STRING_BLOCK_SIZE / 2)
return g_strdup (string);
if (quark_block == NULL ||
QUARK_STRING_BLOCK_SIZE - quark_block_offset < len)
{
quark_block = g_malloc (QUARK_STRING_BLOCK_SIZE);
quark_block_offset = 0;
}
copy = quark_block + quark_block_offset;
memcpy (copy, string, len);
quark_block_offset += len;
return copy;
}
/* HOLDS: g_quark_global_lock */
static inline GQuark
g_quark_from_string_internal (const gchar *string,
gboolean duplicate)
{
GQuark quark = 0;
if (g_quark_ht)
quark = GPOINTER_TO_UINT (g_hash_table_lookup (g_quark_ht, string));
if (!quark)
{
quark = g_quark_new (duplicate ? quark_strdup (string) : (gchar *)string);
TRACE(GLIB_QUARK_NEW(string, quark));
}
return quark;
}
/**
* g_quark_from_string:
* @string: (allow-none): a string.
* @Returns: the #GQuark identifying the string, or 0 if @string is
* %NULL.
*
* Gets the #GQuark identifying the given string. If the string does
* not currently have an associated #GQuark, a new #GQuark is created,
* using a copy of the string.
**/
GQuark
g_quark_from_string (const gchar *string)
{
GQuark quark;
if (!string)
return 0;
G_LOCK (g_quark_global);
quark = g_quark_from_string_internal (string, TRUE);
G_UNLOCK (g_quark_global);
return quark;
}
/**
* g_quark_from_static_string:
* @string: (allow-none): a string.
* @Returns: the #GQuark identifying the string, or 0 if @string is
* %NULL.
*
* Gets the #GQuark identifying the given (static) string. If the
* string does not currently have an associated #GQuark, a new #GQuark
* is created, linked to the given string.
*
* Note that this function is identical to g_quark_from_string() except
* that if a new #GQuark is created the string itself is used rather
* than a copy. This saves memory, but can only be used if the string
* will <emphasis>always</emphasis> exist. It can be used with
* statically allocated strings in the main program, but not with
* statically allocated memory in dynamically loaded modules, if you
* expect to ever unload the module again (e.g. do not use this
* function in GTK+ theme engines).
**/
GQuark
g_quark_from_static_string (const gchar *string)
{
GQuark quark;
if (!string)
return 0;
G_LOCK (g_quark_global);
quark = g_quark_from_string_internal (string, FALSE);
G_UNLOCK (g_quark_global);
return quark;
}
/**
* g_quark_to_string:
* @quark: a #GQuark.
* @Returns: the string associated with the #GQuark.
*
* Gets the string associated with the given #GQuark.
**/
const gchar *
g_quark_to_string (GQuark quark)
{
gchar* result = NULL;
gchar **quarks;
gint quark_seq_id;
quark_seq_id = g_atomic_int_get (&g_quark_seq_id);
quarks = g_atomic_pointer_get (&g_quarks);
if (quark < quark_seq_id)
result = quarks[quark];
return result;
}
/* HOLDS: g_quark_global_lock */
static inline GQuark
g_quark_new (gchar *string)
{
GQuark quark;
gchar **g_quarks_new;
if (g_quark_seq_id % G_QUARK_BLOCK_SIZE == 0)
{
g_quarks_new = g_new (gchar*, g_quark_seq_id + G_QUARK_BLOCK_SIZE);
if (g_quark_seq_id != 0)
memcpy (g_quarks_new, g_quarks, sizeof (char *) * g_quark_seq_id);
memset (g_quarks_new + g_quark_seq_id, 0, sizeof (char *) * G_QUARK_BLOCK_SIZE);
/* This leaks the old quarks array. Its unfortunate, but it allows
us to do lockless lookup of the arrays, and there shouldn't be that
many quarks in an app */
g_atomic_pointer_set (&g_quarks, g_quarks_new);
}
if (!g_quark_ht)
{
g_assert (g_quark_seq_id == 0);
g_quark_ht = g_hash_table_new (g_str_hash, g_str_equal);
g_quarks[g_quark_seq_id] = NULL;
g_atomic_int_inc (&g_quark_seq_id);
}
quark = g_quark_seq_id;
g_atomic_pointer_set (&g_quarks[quark], string);
g_hash_table_insert (g_quark_ht, string, GUINT_TO_POINTER (quark));
g_atomic_int_inc (&g_quark_seq_id);
return quark;
}
/**
* g_intern_string:
* @string: (allow-none): a string
*
* Returns a canonical representation for @string. Interned strings can
* be compared for equality by comparing the pointers, instead of using strcmp().
*
* Returns: a canonical representation for the string
*
* Since: 2.10
*/
const gchar *
g_intern_string (const gchar *string)
{
const gchar *result;
GQuark quark;
if (!string)
return NULL;
G_LOCK (g_quark_global);
quark = g_quark_from_string_internal (string, TRUE);
result = g_quarks[quark];
G_UNLOCK (g_quark_global);
return result;
}
/**
* g_intern_static_string:
* @string: (allow-none): a static string
*
* Returns a canonical representation for @string. Interned strings can
* be compared for equality by comparing the pointers, instead of using strcmp().
* g_intern_static_string() does not copy the string, therefore @string must
* not be freed or modified.
*
* Returns: a canonical representation for the string
*
* Since: 2.10
*/
const gchar *
g_intern_static_string (const gchar *string)
{
GQuark quark;
const gchar *result;
if (!string)
return NULL;
G_LOCK (g_quark_global);
quark = g_quark_from_string_internal (string, FALSE);
result = g_quarks[quark];
G_UNLOCK (g_quark_global);
return result;
}
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