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53007b5d83
1) add stride align fields in allocation.md 2) add stride align fields in gstvideometa.h Part-of: <https://gitlab.freedesktop.org/gstreamer/gstreamer/-/merge_requests/7201>
745 lines
25 KiB
Markdown
745 lines
25 KiB
Markdown
---
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title: Memory allocation
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...
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# Memory allocation
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Memory allocation and management are very important topics in
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multimedia. High definition video uses many megabytes to store one
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single image frame. It is important to reuse memory when possible
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instead of constantly allocating and freeing it.
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Multimedia systems usually use special-purpose chips, such as DSPs or
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GPUs to perform the heavy lifting (especially for video). These
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special-purpose chips usually have strict requirements for the memory
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they operate on and how it is accessed.
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This chapter talks about the memory-management features available to
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GStreamer plugins. We will first talk about the lowlevel `GstMemory`
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object that manages access to a piece of memory and then continue with
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one of it's main users, the `GstBuffer`, which is used to exchange data
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between elements and with the application. We will also discuss the `GstMeta`.
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This object can be placed on buffers to provide extra info about them and
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their memory. We will also discuss the `GstBufferPool`, which allows to
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more-efficiently manage buffers of the same size.
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To conclude this chapter we will take a look at the `GST_QUERY_ALLOCATION`
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query, which is used to negotiate memory management options between
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elements.
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## GstMemory
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`GstMemory` is an object that manages a region of memory. This memory
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object points to a region of memory of “maxsize”. The area in this
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memory starting at “offset” and size “size” bytes is the accessible
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memory region. After a `GstMemory` is created its maxsize can no longer
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be changed, however, its "offset" and "size" can.
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### GstAllocator
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`GstMemory` objects are created by a `GstAllocator` object. Most
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allocators implement the default `gst_allocator_alloc()` method but some
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might implement different ones, for example, when additional parameters
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are needed to allocate the specific memory.
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Different allocators exist for system memory, shared memory and memory
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backed by a DMAbuf file descriptor. To implement support for a new kind
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of memory type, you must implement a new allocator object.
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### GstMemory API example
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Data access to the memory wrapped by the `GstMemory` object is always
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protected with a `gst_memory_map()` and `gst_memory_unmap()` pair. An
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access mode (read/write) must be given when mapping memory. The map
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function returns a pointer to the valid memory region that can then be
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accessed according to the requested access mode.
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Below is an example on creating a `GstMemory` object and using the
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`gst_memory_map()` to access the memory region.
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``` c
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[...]
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GstMemory *mem;
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GstMapInfo info;
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gint i;
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/* allocate 100 bytes */
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mem = gst_allocator_alloc (NULL, 100, NULL);
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/* get access to the memory in write mode */
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gst_memory_map (mem, &info, GST_MAP_WRITE);
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/* fill with pattern */
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for (i = 0; i < info.size; i++)
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info.data[i] = i;
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/* release memory */
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gst_memory_unmap (mem, &info);
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[...]
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```
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### Implementing a GstAllocator
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WRITEME
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## GstBuffer
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A `GstBuffer` is a lightweight object that is passed from an upstream
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to a downstream element and contains memory and metadata. It represents
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the multimedia content that is pushed to or pulled by downstream elements.
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A `GstBuffer` contains one or more `GstMemory` objects. These objects hold
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the buffer's data.
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Metadata in the buffer consists of:
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- DTS and PTS timestamps. These represent the decoding and
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presentation timestamps of the buffer content and are used by
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synchronizing elements to schedule buffers. These timestamps
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can be `GST_CLOCK_TIME_NONE` when unknown/undefined.
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- The duration of the buffer contents. This duration can be
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`GST_CLOCK_TIME_NONE` when unknown/undefined.
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- Media-specific `offset` and `offset_end` values. For video this is the
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frame number in the stream, for audio, the sample number. Other media
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might use different definitions.
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- Arbitrary structures via `GstMeta`, see below.
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### Writability
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A `GstBuffer` is writable when the refcount of the object is exactly 1,
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meaning that only one object is holding a ref to the buffer. You can
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only modify the buffer when it is writable. This means that you need to
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call `gst_buffer_make_writable()` before changing the timestamps,
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offsets, metadata or adding and removing memory blocks.
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### API examples
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You can create a `GstBuffer` with `gst_buffer_new ()` and then you can
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add memory objects to it. You can alternatively use the convenience function
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`gst_buffer_new_allocate ()` to perform both operations at once. It's also possible
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to wrap existing memory with `gst_buffer_new_wrapped_full ()` and specify the
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function to call when the memory should be freed.
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You can access the memory of a `GstBuffer` by getting and mapping the
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`GstMemory` objects individually or by using `gst_buffer_map ()`. The
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latter merges all the memory into one big block and then gives you a
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pointer to it.
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Below is an example of how to create a buffer and access its memory.
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``` c
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[...]
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GstBuffer *buffer;
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GstMemory *mem;
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GstMapInfo info;
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/* make empty buffer */
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buffer = gst_buffer_new ();
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/* make memory holding 100 bytes */
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mem = gst_allocator_alloc (NULL, 100, NULL);
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/* add the buffer */
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gst_buffer_append_memory (buffer, mem);
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[...]
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/* get WRITE access to the memory and fill with 0xff */
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gst_buffer_map (buffer, &info, GST_MAP_WRITE);
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memset (info.data, 0xff, info.size);
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gst_buffer_unmap (buffer, &info);
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[...]
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/* free the buffer */
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gst_buffer_unref (buffer);
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[...]
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```
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## GstMeta
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With the `GstMeta` system you can add arbitrary structures to buffers.
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These structures describe extra properties of the buffer such as
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cropping, stride, region of interest, etc.
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The metadata system separates API specification (what the metadata and
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its API look like) and its implementation (how it works). This makes it
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possible to have different implementations of the same API, for example,
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depending on the hardware you are running on.
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### API example
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After allocating a new `GstBuffer`, you can add metadata to it with
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the metadata-specific API. This means that you will need to link to the
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header file where the metadata is defined to use its API.
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By convention, a metadata API with name `FooBar` should provide two
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methods, a `gst_buffer_add_foo_bar_meta ()` and a
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`gst_buffer_get_foo_bar_meta ()`. Both functions should return a pointer
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to a `FooBarMeta` structure that contains the metadata fields. Some of
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the `_add_*_meta ()` can have extra parameters that will usually be used
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to configure the metadata structure for you.
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Let's have a look at the metadata that is used to specify a cropping
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region for video frames.
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``` c
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#include <gst/video/gstvideometa.h>
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[...]
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GstVideoCropMeta *meta;
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/* buffer points to a video frame, add some cropping metadata */
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meta = gst_buffer_add_video_crop_meta (buffer);
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/* configure the cropping metadata */
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meta->x = 8;
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meta->y = 8;
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meta->width = 120;
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meta->height = 80;
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[...]
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```
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An element can then use the metadata on the buffer when rendering the
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frame like this:
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``` c
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#include <gst/video/gstvideometa.h>
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[...]
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GstVideoCropMeta *meta;
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/* buffer points to a video frame, get the cropping metadata */
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meta = gst_buffer_get_video_crop_meta (buffer);
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if (meta) {
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/* render frame with cropping */
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_render_frame_cropped (buffer, meta->x, meta->y, meta->width, meta->height);
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} else {
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/* render frame */
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_render_frame (buffer);
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}
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[...]
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```
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### Implementing new GstMeta
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In the next sections we show how you can add new metadata to the system
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and use it on buffers.
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#### Define the metadata API
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First we need to define what our API will look like and we have to
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register this API to the system. This is important because the API
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definition will be used when elements negotiate what kind of metadata
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they will exchange. The API definition also contains arbitrary tags that
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give hints about what the metadata contains. This is important when we
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see how metadata is preserved as buffers pass through the pipeline.
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If you are making a new implementation of an existing API, you can skip
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this step and move directly to the implementation.
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First we start with making the `my-example-meta.h` header file that will
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contain the definition of the API and structure for our metadata.
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``` c
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#include <gst/gst.h>
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typedef struct _MyExampleMeta MyExampleMeta;
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struct _MyExampleMeta {
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GstMeta meta;
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gint age;
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gchar *name;
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};
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GType my_example_meta_api_get_type (void);
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#define MY_EXAMPLE_META_API_TYPE (my_example_meta_api_get_type())
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#define gst_buffer_get_my_example_meta(b) \
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((MyExampleMeta*)gst_buffer_get_meta((b),MY_EXAMPLE_META_API_TYPE))
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```
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The metadata API definition consists of the definition of the structure
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that holds a `gint` and a string. The first field in the structure must be
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a `GstMeta`.
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We also define a `my_example_meta_api_get_type ()` function that will
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register our metadata API definition and a convenience
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`gst_buffer_get_my_example_meta ()` macro that simply finds and returns the
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metadata with our new API.
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Let's have a look at how the `my_example_meta_api_get_type ()`
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function is implemented in the `my-example-meta.c` file:
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``` c
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#include "my-example-meta.h"
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GType
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my_example_meta_api_get_type (void)
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{
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static GType type;
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static const gchar *tags[] = { "foo", "bar", NULL };
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if (g_once_init_enter (&type)) {
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GType _type = gst_meta_api_type_register ("MyExampleMetaAPI", tags);
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g_once_init_leave (&type, _type);
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}
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return type;
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}
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```
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As you can see, it simply uses the `gst_meta_api_type_register ()`
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function to register a name and some tags for the API. The result is a
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new `GType` pointer that defines the newly registered API.
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#### Implementing a metadata API
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Next we can make an implementation for a registered metadata API `GType`.
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The implementation details of a metadata API are kept in a `GstMetaInfo`
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structure that you make available to the users of your metadata API
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implementation with a `my_example_meta_get_info ()` function and a
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convenience `MY_EXAMPLE_META_INFO` macro. You also provide a method to
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add your metadata implementation to a `GstBuffer`. Your
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`my-example-meta.h` header file will need these additions:
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``` c
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[...]
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/* implementation */
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const GstMetaInfo *my_example_meta_get_info (void);
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#define MY_EXAMPLE_META_INFO (my_example_meta_get_info())
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MyExampleMeta * gst_buffer_add_my_example_meta (GstBuffer *buffer,
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gint age,
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const gchar *name);
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```
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Let's have a look at how these functions are implemented in the
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`my-example-meta.c` file.
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``` c
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[...]
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static gboolean
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my_example_meta_init (GstMeta * meta, gpointer params, GstBuffer * buffer)
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{
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MyExampleMeta *emeta = (MyExampleMeta *) meta;
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emeta->age = 0;
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emeta->name = NULL;
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return TRUE;
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}
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static gboolean
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my_example_meta_transform (GstBuffer * transbuf, GstMeta * meta,
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GstBuffer * buffer, GQuark type, gpointer data)
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{
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MyExampleMeta *emeta = (MyExampleMeta *) meta;
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/* we always copy no matter what transform */
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gst_buffer_add_my_example_meta (transbuf, emeta->age, emeta->name);
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return TRUE;
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}
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static void
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my_example_meta_free (GstMeta * meta, GstBuffer * buffer)
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{
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MyExampleMeta *emeta = (MyExampleMeta *) meta;
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g_free (emeta->name);
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emeta->name = NULL;
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}
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const GstMetaInfo *
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my_example_meta_get_info (void)
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{
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static const GstMetaInfo *meta_info = NULL;
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if (g_once_init_enter (&meta_info)) {
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const GstMetaInfo *mi = gst_meta_register (MY_EXAMPLE_META_API_TYPE,
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"MyExampleMeta",
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sizeof (MyExampleMeta),
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my_example_meta_init,
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my_example_meta_free,
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my_example_meta_transform);
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g_once_init_leave (&meta_info, mi);
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}
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return meta_info;
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}
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MyExampleMeta *
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gst_buffer_add_my_example_meta (GstBuffer *buffer,
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gint age,
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const gchar *name)
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{
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MyExampleMeta *meta;
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g_return_val_if_fail (GST_IS_BUFFER (buffer), NULL);
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meta = (MyExampleMeta *) gst_buffer_add_meta (buffer,
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MY_EXAMPLE_META_INFO, NULL);
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meta->age = age;
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meta->name = g_strdup (name);
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return meta;
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}
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```
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`gst_meta_register ()` registers the implementation details, like the
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API that you implement and the size of the metadata structure, alongside
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methods to initialize and free the memory area. You can also implement a
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transform function that will be called when a certain transformation
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(identified by the quark and quark specific data) is performed on a
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buffer.
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Lastly, you implement a `gst_buffer_add_*_meta()` that adds the metadata
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implementation to a buffer and sets the values of the metadata.
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## GstBufferPool
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The `GstBufferPool` object provides a convenient base class for managing
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lists of reusable buffers. Essential for this object is that all the
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buffers have the same properties such as size, padding, metadata and
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alignment.
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A `GstBufferPool` can be configured to manage a minimum and maximum
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amount of buffers of a specific size. It can also be configured to use a
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specific `GstAllocator` for the memory of the buffers. There is also
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support in the bufferpool to enable bufferpool specific options, such as
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adding `GstMeta` to the pool's buffers or enabling specific padding on the
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buffers' memory.
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A `GstBufferPool` can be either inactivate or active. In the inactive state, you
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can configure the pool. In the active state, you can't change the
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configuration anymore but you can acquire and release buffers from/to
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the pool.
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In the following sections we take a look at how you can use a `GstBufferPool`.
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### API example
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There can be many different `GstBufferPool` implementations; they are all
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subclasses of the `GstBufferPool` base class. For this example, we will
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assume we somehow have access to a buffer pool, either because we created
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it ourselves or because we were given one as a result of the `ALLOCATION`
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query, as we will see below.
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The `GstBufferPool` is initially in the inactive state so that we can
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configure it. Trying to configure a `GstBufferPool` that is not in the
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inactive state will fail. Likewise, trying to activate a bufferpool that
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is not configured will also fail.
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``` c
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GstStructure *config;
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[...]
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/* get config structure */
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config = gst_buffer_pool_get_config (pool);
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/* set caps, size, minimum and maximum buffers in the pool */
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gst_buffer_pool_config_set_params (config, caps, size, min, max);
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/* configure allocator and parameters */
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gst_buffer_pool_config_set_allocator (config, allocator, ¶ms);
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/* store the updated configuration again */
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gst_buffer_pool_set_config (pool, config);
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[...]
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```
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The configuration of a `GstBufferPool` is maintained in a generic
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`GstStructure` that can be obtained with `gst_buffer_pool_get_config()`.
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Convenience methods exist to get and set the configuration options in
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this structure. After updating the structure, it is set as the current
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configuration in the `GstBufferPool` again with
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`gst_buffer_pool_set_config()`.
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The following options can be configured on a `GstBufferPool`:
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- The caps of the buffers to allocate.
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- The size of the buffers. This is the suggested size of the buffers
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in the pool. The pool might decide to allocate larger buffers to add
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padding.
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- The minimum and maximum amount of buffers in the pool. When minimum
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is set to `\> 0`, the bufferpool will pre-allocate this amount of
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buffers. When maximum is not 0, the bufferpool will allocate up to
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maximum amount of buffers.
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- The allocator and parameters to use. Some bufferpools might ignore
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the allocator and use its internal one.
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- Other arbitrary bufferpool options identified with a string. a
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bufferpool lists the supported options with
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`gst_buffer_pool_get_options()` and you can ask if an option is
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supported with `gst_buffer_pool_has_option()`. The option can be
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enabled by adding it to the configuration structure with
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`gst_buffer_pool_config_add_option ()`. These options are used to
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enable things like letting the pool set metadata on the buffers or
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to add extra configuration options for padding, for example.
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After the configuration is set on the bufferpool, the pool can be
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activated with `gst_buffer_pool_set_active (pool, TRUE)`. From that
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point on you can use `gst_buffer_pool_acquire_buffer ()` to retrieve a
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buffer from the pool, like this:
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``` c
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[...]
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GstFlowReturn ret;
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GstBuffer *buffer;
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ret = gst_buffer_pool_acquire_buffer (pool, &buffer, NULL);
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if (G_UNLIKELY (ret != GST_FLOW_OK))
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goto pool_failed;
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[...]
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```
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It is important to check the return value of the acquire function
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because it is possible that it fails: When your element shuts down, it
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will deactivate the bufferpool and then all calls to acquire will return
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`GST_FLOW_FLUSHING`.
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All buffers that are acquired from the pool will have their pool member
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set to the original pool. When the last ref is decremented on the
|
|
buffer, GStreamer will automatically call
|
|
`gst_buffer_pool_release_buffer()` to release the buffer back to the
|
|
pool. You (or any other downstream element) don't need to know if a
|
|
buffer came from a pool, you can just unref it.
|
|
|
|
### Implementing a new GstBufferPool
|
|
|
|
WRITEME
|
|
|
|
## GST\_QUERY\_ALLOCATION
|
|
|
|
The `ALLOCATION` query is used to negotiate `GstMeta`, `GstBufferPool` and
|
|
`GstAllocator` between elements. Negotiation of the allocation strategy
|
|
is always initiated and decided by a srcpad after it has negotiated a
|
|
format and before it decides to push buffers. A sinkpad can suggest an
|
|
allocation strategy but it is ultimately the source pad that will decide
|
|
based on the suggestions of the downstream sink pad.
|
|
|
|
The source pad will do a `GST_QUERY_ALLOCATION` with the negotiated caps
|
|
as a parameter. This is needed so that the downstream element knows what
|
|
media type is being handled. A downstream sink pad can answer the
|
|
allocation query with the following results:
|
|
|
|
- An array of possible `GstBufferPool` suggestions with suggested
|
|
size, minimum and maximum amount of buffers.
|
|
|
|
- An array of `GstAllocator` objects along with suggested allocation
|
|
parameters such as flags, prefix, alignment and padding. These
|
|
allocators can also be configured in a bufferpool when this is
|
|
supported by the bufferpool.
|
|
|
|
- An array of supported `GstMeta` implementations along with metadata
|
|
specific parameters. It is important that the upstream element knows
|
|
what kind of metadata is supported downstream before it places that
|
|
metadata on buffers.
|
|
|
|
When the `GST_QUERY_ALLOCATION` returns, the source pad will select from
|
|
the available bufferpools, allocators and metadata how it will allocate
|
|
buffers.
|
|
|
|
### ALLOCATION query example
|
|
|
|
Below is an example of the `ALLOCATION` query.
|
|
|
|
``` c
|
|
#include <gst/video/video.h>
|
|
#include <gst/video/gstvideometa.h>
|
|
#include <gst/video/gstvideopool.h>
|
|
|
|
GstCaps *caps;
|
|
GstQuery *query;
|
|
GstStructure *structure;
|
|
GstBufferPool *pool;
|
|
GstStructure *config;
|
|
guint size, min, max;
|
|
|
|
[...]
|
|
|
|
/* find a pool for the negotiated caps now */
|
|
query = gst_query_new_allocation (caps, TRUE);
|
|
|
|
if (!gst_pad_peer_query (scope->srcpad, query)) {
|
|
/* query failed, not a problem, we use the query defaults */
|
|
}
|
|
|
|
if (gst_query_get_n_allocation_pools (query) > 0) {
|
|
/* we got configuration from our peer, parse them */
|
|
gst_query_parse_nth_allocation_pool (query, 0, &pool, &size, &min, &max);
|
|
} else {
|
|
pool = NULL;
|
|
size = 0;
|
|
min = max = 0;
|
|
}
|
|
|
|
if (pool == NULL) {
|
|
/* we did not get a pool, make one ourselves then */
|
|
pool = gst_video_buffer_pool_new ();
|
|
}
|
|
|
|
config = gst_buffer_pool_get_config (pool);
|
|
gst_buffer_pool_config_add_option (config, GST_BUFFER_POOL_OPTION_VIDEO_META);
|
|
gst_buffer_pool_config_set_params (config, caps, size, min, max);
|
|
gst_buffer_pool_set_config (pool, config);
|
|
|
|
/* and activate */
|
|
gst_buffer_pool_set_active (pool, TRUE);
|
|
|
|
[...]
|
|
```
|
|
|
|
This particular implementation will make a custom `GstVideoBufferPool`
|
|
object that is specialized in allocating video buffers. You can also
|
|
enable the pool to put `GstVideoMeta` metadata on the buffers from the
|
|
pool doing:
|
|
|
|
``` c
|
|
gst_buffer_pool_config_add_option (config, GST_BUFFER_POOL_OPTION_VIDEO_META)
|
|
```
|
|
|
|
### The ALLOCATION query in base classes
|
|
|
|
In many base classes you will see the following virtual methods for
|
|
influencing the allocation strategy:
|
|
|
|
- `propose_allocation ()` should suggest allocation parameters for the
|
|
upstream element.
|
|
|
|
- `decide_allocation ()` should decide the allocation parameters from
|
|
the suggestions received from downstream.
|
|
|
|
Implementors of these methods should modify the given `GstQuery` object
|
|
by updating the pool options and allocation options.
|
|
|
|
### Negotiating the exact layout of video buffers
|
|
|
|
Hardware elements may have specific constraints on the layout
|
|
of their input buffers, requiring to add vertical and/or horizontal paddings
|
|
to their planes.
|
|
If the producer is able to create buffers fulfilling these requirements,
|
|
we can ensure zero-copy by configuring its driver accordingly before starting to produce
|
|
buffers.
|
|
|
|
In such setup on Linux we'll generally use dmabuf to exchange buffers in order
|
|
to reduce memory copies. The producer can either export its buffers
|
|
to the consumer (dmabuf export) or import them from it (dmabuf import).
|
|
|
|
In this section we'll outline the steps for how the consumer can inform the
|
|
producer of its expected buffer layout for import and export use cases.
|
|
Let's consider `v4l2src` (the producer) feeding buffers to
|
|
`v4l2h264enc` (the consumer) for encoding.
|
|
|
|
#### v4l2src importing buffers from v4l2h264enc
|
|
|
|
1. *v4l2h264enc*: query the hardware for its requirements and create a
|
|
`GstVideoAlignment` accordingly.
|
|
2. *v4l2h264enc*: in its buffer pool `alloc_buffer` implementation, call
|
|
`gst_buffer_add_video_meta_full()` and then
|
|
`gst_video_meta_set_alignment()` on the returned meta with the
|
|
requested alignment. The alignment will be added to the meta, allowing
|
|
`v4l2src` to configure its driver before trying to import buffers.
|
|
``` c
|
|
meta = gst_buffer_add_video_meta_full (buf, GST_VIDEO_FRAME_FLAG_NONE,
|
|
GST_VIDEO_INFO_FORMAT (&pool->video_info),
|
|
GST_VIDEO_INFO_WIDTH (&pool->video_info),
|
|
GST_VIDEO_INFO_HEIGHT (&pool->video_info),
|
|
GST_VIDEO_INFO_N_PLANES (&pool->video_info), offset, stride);
|
|
|
|
gst_video_meta_set_alignment (meta, align);
|
|
```
|
|
3. *v4l2h264enc*: propose its pool to the producer when replying to the
|
|
`ALLOCATION` query (`propose_allocation()`).
|
|
4. *v4l2src*: when receiving the reply from the `ALLOCATION` query
|
|
(`decide_allocation()`) acquire
|
|
a single buffer from the suggested pool and retrieve its layout
|
|
using `GstVideoMeta.stride` and `gst_video_meta_get_plane_height()`.
|
|
5. *v4l2src*: configure its driver to produce data matching those requirements,
|
|
if possible, then try to import the buffer.
|
|
If not, `v4l2src` won't be able to import from `v4l2h264enc` and so will
|
|
fallback to sending its own buffers to `v4l2h264enc` which will
|
|
have to copy each input buffer to fit its requirements.
|
|
|
|
#### v4l2src exporting buffers to v4l2h264enc
|
|
|
|
1. *v4l2h264enc*: query the hardware for its requirements and create a
|
|
`GstVideoAlignment` accordingly.
|
|
2. *v4l2h264enc*: create a `GstStructure` named `video-meta` serializing the alignment:
|
|
``` c
|
|
params = gst_structure_new ("video-meta",
|
|
"padding-top", G_TYPE_UINT, align.padding_top,
|
|
"padding-bottom", G_TYPE_UINT, align.padding_bottom,
|
|
"padding-left", G_TYPE_UINT, align.padding_left,
|
|
"padding-right", G_TYPE_UINT, align.padding_right,
|
|
"stride-align0", G_TYPE_UINT, align->stride_align[0],
|
|
"stride-align1", G_TYPE_UINT, align->stride_align[1],
|
|
"stride-align2", G_TYPE_UINT, align->stride_align[2],
|
|
"stride-align3", G_TYPE_UINT, align->stride_align[3],
|
|
NULL);
|
|
```
|
|
3. *v4l2h264enc*: when handling the `ALLOCATION` query (`propose_allocation()`),
|
|
pass this structure as parameter when adding the `GST_VIDEO_META_API_TYPE`
|
|
meta:
|
|
``` c
|
|
gst_query_add_allocation_meta (query, GST_VIDEO_META_API_TYPE, params);
|
|
```
|
|
4. *v4l2src*: when receiving the reply from the `ALLOCATION` query
|
|
(`decide_allocation()`) retrieve the `GST_VIDEO_META_API_TYPE` parameters
|
|
to compute the expected buffers layout:
|
|
``` c
|
|
guint video_idx;
|
|
GstStructure *params;
|
|
|
|
if (gst_query_find_allocation_meta (query, GST_VIDEO_META_API_TYPE, &video_idx)) {
|
|
gst_query_parse_nth_allocation_meta (query, video_idx, ¶ms);
|
|
|
|
if (params) {
|
|
GstVideoAlignment align;
|
|
GstVideoInfo info;
|
|
gsize plane_size[GST_VIDEO_MAX_PLANES];
|
|
|
|
gst_video_alignment_reset (&align);
|
|
|
|
gst_structure_get_uint (s, "padding-top", &align.padding_top);
|
|
gst_structure_get_uint (s, "padding-bottom", &align.padding_bottom);
|
|
gst_structure_get_uint (s, "padding-left", &align.padding_left);
|
|
gst_structure_get_uint (s, "padding-right", &align.padding_right);
|
|
gst_structure_get_uint (s, "stride-align0", &align.stride_align[0]);
|
|
gst_structure_get_uint (s, "stride-align1", &align.stride_align[1]);
|
|
gst_structure_get_uint (s, "stride-align2", &align.stride_align[2]);
|
|
gst_structure_get_uint (s, "stride-align3", &align.stride_align[3]);
|
|
|
|
gst_video_info_from_caps (&info, caps);
|
|
|
|
gst_video_info_align_full (&info, align, plane_size);
|
|
}
|
|
}
|
|
```
|
|
5. *v4l2src*: retrieve the requested buffers layout using
|
|
`GstVideoInfo.stride` and `GST_VIDEO_INFO_PLANE_HEIGHT()`.
|
|
6. *v4l2src*: configure its driver to produce data matching those requirements,
|
|
if possible.
|
|
If not, driver will produce buffers using its own layout but `v4l2h264enc` will
|
|
have to copy each input buffer to fit its requirements.
|