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7130230ddb
There are gstmemory's available that operate in two memory domains and need to ensure consistent access between these domains. Imagine a scenario where e.g. the GLMemory is mapped twice in both the GPU and the CPU domain. On unmap or a subsequent map, it would like to ensure that the most recent data is available in the memory domain requested. Either by flushing the writes and/or initiating a DMA transfer. Without knowing which domain is being unmapped, the memory does not know where the most recent data is to transfer to the other memory domain. Note: this still does not allow downgrading a memory map. https://bugzilla.gnome.org/show_bug.cgi?id=750319
459 lines
13 KiB
C
459 lines
13 KiB
C
/* GStreamer
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* Copyright (C) 2011 Wim Taymans <wim.taymans@gmail.be>
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*
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* gstmemory.c: memory block handling
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*
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Library General Public
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* License as published by the Free Software Foundation; either
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* version 2 of the License, or (at your option) any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Library General Public License for more details.
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*
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* You should have received a copy of the GNU Library General Public
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* License along with this library; if not, write to the
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* Free Software Foundation, Inc., 51 Franklin St, Fifth Floor,
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* Boston, MA 02110-1301, USA.
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*/
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/**
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* SECTION:gstmemory
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* @short_description: refcounted wrapper for memory blocks
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* @see_also: #GstBuffer
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*
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* GstMemory is a lightweight refcounted object that wraps a region of memory.
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* They are typically used to manage the data of a #GstBuffer.
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*
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* A GstMemory object has an allocated region of memory of maxsize. The maximum
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* size does not change during the lifetime of the memory object. The memory
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* also has an offset and size property that specifies the valid range of memory
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* in the allocated region.
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*
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* Memory is usually created by allocators with a gst_allocator_alloc()
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* method call. When %NULL is used as the allocator, the default allocator will
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* be used.
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*
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* New allocators can be registered with gst_allocator_register().
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* Allocators are identified by name and can be retrieved with
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* gst_allocator_find(). gst_allocator_set_default() can be used to change the
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* default allocator.
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*
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* New memory can be created with gst_memory_new_wrapped() that wraps the memory
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* allocated elsewhere.
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*
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* Refcounting of the memory block is performed with gst_memory_ref() and
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* gst_memory_unref().
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*
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* The size of the memory can be retrieved and changed with
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* gst_memory_get_sizes() and gst_memory_resize() respectively.
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*
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* Getting access to the data of the memory is performed with gst_memory_map().
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* The call will return a pointer to offset bytes into the region of memory.
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* After the memory access is completed, gst_memory_unmap() should be called.
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*
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* Memory can be copied with gst_memory_copy(), which will return a writable
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* copy. gst_memory_share() will create a new memory block that shares the
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* memory with an existing memory block at a custom offset and with a custom
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* size.
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*
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* Memory can be efficiently merged when gst_memory_is_span() returns %TRUE.
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*/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include "gst_private.h"
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#include "gstmemory.h"
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GType _gst_memory_type = 0;
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GST_DEFINE_MINI_OBJECT_TYPE (GstMemory, gst_memory);
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static GstMemory *
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_gst_memory_copy (GstMemory * mem)
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{
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GST_CAT_DEBUG (GST_CAT_MEMORY, "copy memory %p", mem);
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return gst_memory_copy (mem, 0, -1);
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}
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static void
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_gst_memory_free (GstMemory * mem)
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{
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GstAllocator *allocator;
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GST_CAT_DEBUG (GST_CAT_MEMORY, "free memory %p", mem);
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if (mem->parent) {
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gst_memory_unlock (mem->parent, GST_LOCK_FLAG_EXCLUSIVE);
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gst_memory_unref (mem->parent);
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}
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allocator = mem->allocator;
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gst_allocator_free (allocator, mem);
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gst_object_unref (allocator);
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}
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/**
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* gst_memory_init: (skip)
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* @mem: a #GstMemory
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* @flags: #GstMemoryFlags
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* @allocator: the #GstAllocator
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* @parent: the parent of @mem
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* @maxsize: the total size of the memory
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* @align: the alignment of the memory
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* @offset: The offset in the memory
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* @size: the size of valid data in the memory
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* Initializes a newly allocated @mem with the given parameters. This function
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* will call gst_mini_object_init() with the default memory parameters.
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*/
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void
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gst_memory_init (GstMemory * mem, GstMemoryFlags flags,
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GstAllocator * allocator, GstMemory * parent, gsize maxsize, gsize align,
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gsize offset, gsize size)
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{
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gst_mini_object_init (GST_MINI_OBJECT_CAST (mem),
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flags | GST_MINI_OBJECT_FLAG_LOCKABLE, GST_TYPE_MEMORY,
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(GstMiniObjectCopyFunction) _gst_memory_copy, NULL,
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(GstMiniObjectFreeFunction) _gst_memory_free);
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mem->allocator = gst_object_ref (allocator);
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if (parent) {
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/* FIXME 2.0: this can fail if the memory is already write locked */
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gst_memory_lock (parent, GST_LOCK_FLAG_EXCLUSIVE);
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gst_memory_ref (parent);
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}
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mem->parent = parent;
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mem->maxsize = maxsize;
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mem->align = align;
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mem->offset = offset;
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mem->size = size;
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GST_CAT_DEBUG (GST_CAT_MEMORY, "new memory %p, maxsize:%" G_GSIZE_FORMAT
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" offset:%" G_GSIZE_FORMAT " size:%" G_GSIZE_FORMAT, mem, maxsize,
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offset, size);
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}
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/**
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* gst_memory_is_type:
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* @mem: a #GstMemory
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* @mem_type: a memory type
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*
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* Check if @mem if allocated with an allocator for @mem_type.
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*
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* Returns: %TRUE if @mem was allocated from an allocator for @mem_type.
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*
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* Since: 1.2
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*/
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gboolean
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gst_memory_is_type (GstMemory * mem, const gchar * mem_type)
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{
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g_return_val_if_fail (mem != NULL, FALSE);
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g_return_val_if_fail (mem->allocator != NULL, FALSE);
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g_return_val_if_fail (mem_type != NULL, FALSE);
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return (g_strcmp0 (mem->allocator->mem_type, mem_type) == 0);
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}
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/**
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* gst_memory_get_sizes:
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* @mem: a #GstMemory
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* @offset: pointer to offset
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* @maxsize: pointer to maxsize
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*
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* Get the current @size, @offset and @maxsize of @mem.
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*
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* Returns: the current sizes of @mem
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*/
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gsize
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gst_memory_get_sizes (GstMemory * mem, gsize * offset, gsize * maxsize)
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{
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g_return_val_if_fail (mem != NULL, 0);
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if (offset)
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*offset = mem->offset;
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if (maxsize)
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*maxsize = mem->maxsize;
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return mem->size;
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}
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/**
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* gst_memory_resize:
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* @mem: a #GstMemory
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* @offset: a new offset
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* @size: a new size
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*
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* Resize the memory region. @mem should be writable and offset + size should be
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* less than the maxsize of @mem.
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*
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* #GST_MEMORY_FLAG_ZERO_PREFIXED and #GST_MEMORY_FLAG_ZERO_PADDED will be
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* cleared when offset or padding is increased respectively.
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*/
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void
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gst_memory_resize (GstMemory * mem, gssize offset, gsize size)
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{
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g_return_if_fail (mem != NULL);
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g_return_if_fail (gst_memory_is_writable (mem));
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g_return_if_fail (offset >= 0 || mem->offset >= -offset);
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g_return_if_fail (size + mem->offset + offset <= mem->maxsize);
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/* if we increase the prefix, we can't guarantee it is still 0 filled */
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if ((offset > 0) && GST_MEMORY_IS_ZERO_PREFIXED (mem))
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GST_MEMORY_FLAG_UNSET (mem, GST_MEMORY_FLAG_ZERO_PREFIXED);
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/* if we increase the padding, we can't guarantee it is still 0 filled */
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if ((offset + size < mem->size) && GST_MEMORY_IS_ZERO_PADDED (mem))
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GST_MEMORY_FLAG_UNSET (mem, GST_MEMORY_FLAG_ZERO_PADDED);
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mem->offset += offset;
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mem->size = size;
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}
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/**
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* gst_memory_make_mapped:
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* @mem: (transfer full): a #GstMemory
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* @info: (out): pointer for info
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* @flags: mapping flags
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*
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* Create a #GstMemory object that is mapped with @flags. If @mem is mappable
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* with @flags, this function returns the mapped @mem directly. Otherwise a
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* mapped copy of @mem is returned.
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*
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* This function takes ownership of old @mem and returns a reference to a new
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* #GstMemory.
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*
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* Returns: (transfer full) (nullable): a #GstMemory object mapped
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* with @flags or %NULL when a mapping is not possible.
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*/
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GstMemory *
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gst_memory_make_mapped (GstMemory * mem, GstMapInfo * info, GstMapFlags flags)
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{
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GstMemory *result;
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if (gst_memory_map (mem, info, flags)) {
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result = mem;
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} else {
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result = gst_memory_copy (mem, 0, -1);
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gst_memory_unref (mem);
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if (result == NULL)
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goto cannot_copy;
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if (!gst_memory_map (result, info, flags))
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goto cannot_map;
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}
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return result;
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/* ERRORS */
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cannot_copy:
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{
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GST_CAT_DEBUG (GST_CAT_MEMORY, "cannot copy memory %p", mem);
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return NULL;
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}
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cannot_map:
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{
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GST_CAT_DEBUG (GST_CAT_MEMORY, "cannot map memory %p with flags %d", mem,
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flags);
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gst_memory_unref (result);
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return NULL;
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}
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}
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/**
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* gst_memory_map:
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* @mem: a #GstMemory
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* @info: (out): pointer for info
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* @flags: mapping flags
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*
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* Fill @info with the pointer and sizes of the memory in @mem that can be
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* accessed according to @flags.
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*
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* This function can return %FALSE for various reasons:
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* - the memory backed by @mem is not accessible with the given @flags.
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* - the memory was already mapped with a different mapping.
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*
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* @info and its contents remain valid for as long as @mem is valid and
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* until gst_memory_unmap() is called.
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*
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* For each gst_memory_map() call, a corresponding gst_memory_unmap() call
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* should be done.
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*
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* Returns: %TRUE if the map operation was successful.
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*/
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gboolean
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gst_memory_map (GstMemory * mem, GstMapInfo * info, GstMapFlags flags)
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{
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g_return_val_if_fail (mem != NULL, FALSE);
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g_return_val_if_fail (info != NULL, FALSE);
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if (!gst_memory_lock (mem, (GstLockFlags) flags))
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goto lock_failed;
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info->data = mem->allocator->mem_map (mem, mem->maxsize, flags);
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if (G_UNLIKELY (info->data == NULL))
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goto error;
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info->memory = mem;
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info->flags = flags;
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info->size = mem->size;
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info->maxsize = mem->maxsize - mem->offset;
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info->data = info->data + mem->offset;
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return TRUE;
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/* ERRORS */
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lock_failed:
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{
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GST_CAT_DEBUG (GST_CAT_MEMORY, "mem %p: lock %d failed", mem, flags);
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memset (info, 0, sizeof (GstMapInfo));
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return FALSE;
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}
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error:
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{
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/* something went wrong, restore the orginal state again */
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GST_CAT_ERROR (GST_CAT_MEMORY, "mem %p: subclass map failed", mem);
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gst_memory_unlock (mem, (GstLockFlags) flags);
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memset (info, 0, sizeof (GstMapInfo));
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return FALSE;
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}
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}
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/**
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* gst_memory_unmap:
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* @mem: a #GstMemory
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* @info: a #GstMapInfo
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*
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* Release the memory obtained with gst_memory_map()
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*/
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void
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gst_memory_unmap (GstMemory * mem, GstMapInfo * info)
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{
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g_return_if_fail (mem != NULL);
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g_return_if_fail (info != NULL);
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g_return_if_fail (info->memory == mem);
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if (mem->allocator->mem_unmap_full)
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mem->allocator->mem_unmap_full (mem, info->flags);
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else
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mem->allocator->mem_unmap (mem);
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gst_memory_unlock (mem, (GstLockFlags) info->flags);
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}
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/**
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* gst_memory_copy:
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* @mem: a #GstMemory
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* @offset: offset to copy from
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* @size: size to copy, or -1 to copy to the end of the memory region
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*
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* Return a copy of @size bytes from @mem starting from @offset. This copy is
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* guaranteed to be writable. @size can be set to -1 to return a copy
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* from @offset to the end of the memory region.
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*
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* Returns: a new #GstMemory.
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*/
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GstMemory *
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gst_memory_copy (GstMemory * mem, gssize offset, gssize size)
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{
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GstMemory *copy;
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g_return_val_if_fail (mem != NULL, NULL);
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copy = mem->allocator->mem_copy (mem, offset, size);
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return copy;
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}
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/**
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* gst_memory_share:
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* @mem: a #GstMemory
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* @offset: offset to share from
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* @size: size to share, or -1 to share to the end of the memory region
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*
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* Return a shared copy of @size bytes from @mem starting from @offset. No
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* memory copy is performed and the memory region is simply shared. The result
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* is guaranteed to be non-writable. @size can be set to -1 to return a shared
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* copy from @offset to the end of the memory region.
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*
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* Returns: a new #GstMemory.
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*/
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GstMemory *
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gst_memory_share (GstMemory * mem, gssize offset, gssize size)
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{
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GstMemory *shared;
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g_return_val_if_fail (mem != NULL, NULL);
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g_return_val_if_fail (!GST_MEMORY_FLAG_IS_SET (mem, GST_MEMORY_FLAG_NO_SHARE),
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NULL);
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/* whether we can lock the memory exclusively */
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/* in order to maintain backwards compatibility by not requiring subclasses
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* to lock the memory themselves and propagate the possible failure in their
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* mem_share implementation */
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/* FIXME 2.0: remove and fix gst_memory_init() and/or all memory subclasses
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* to propagate this failure case */
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if (!gst_memory_lock (mem, GST_LOCK_FLAG_EXCLUSIVE))
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return NULL;
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/* double lock to ensure we are not mapped writable without an
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* exclusive lock. */
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if (!gst_memory_lock (mem, GST_LOCK_FLAG_EXCLUSIVE)) {
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gst_memory_unlock (mem, GST_LOCK_FLAG_EXCLUSIVE);
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return NULL;
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}
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shared = mem->allocator->mem_share (mem, offset, size);
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/* unlocking before calling the subclass would be racy */
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gst_memory_unlock (mem, GST_LOCK_FLAG_EXCLUSIVE);
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gst_memory_unlock (mem, GST_LOCK_FLAG_EXCLUSIVE);
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return shared;
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}
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/**
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* gst_memory_is_span:
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* @mem1: a #GstMemory
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* @mem2: a #GstMemory
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* @offset: a pointer to a result offset
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*
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* Check if @mem1 and mem2 share the memory with a common parent memory object
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* and that the memory is contiguous.
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*
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* If this is the case, the memory of @mem1 and @mem2 can be merged
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* efficiently by performing gst_memory_share() on the parent object from
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* the returned @offset.
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*
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* Returns: %TRUE if the memory is contiguous and of a common parent.
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*/
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gboolean
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gst_memory_is_span (GstMemory * mem1, GstMemory * mem2, gsize * offset)
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{
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g_return_val_if_fail (mem1 != NULL, FALSE);
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g_return_val_if_fail (mem2 != NULL, FALSE);
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/* need to have the same allocators */
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if (mem1->allocator != mem2->allocator)
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return FALSE;
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/* need to have the same parent */
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if (mem1->parent == NULL || mem1->parent != mem2->parent)
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return FALSE;
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/* and memory is contiguous */
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if (!mem1->allocator->mem_is_span (mem1, mem2, offset))
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return FALSE;
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return TRUE;
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}
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void
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_priv_gst_memory_initialize (void)
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{
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_gst_memory_type = gst_memory_get_type ();
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}
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