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-/*! \page usage_decode Decoding
-
-    The aom_codec_decode() function is at the core of the decode loop. It
-    processes packets of compressed data passed by the application, producing
-    decoded images. The decoder expects packets to comprise exactly one image
-    frame of data. Packets \ref MUST be passed in decode order. If the
-    application wishes to associate some data with the frame, the
-    <code>user_priv</code> member may be set.
-
-    \ref samples
-
-
-    \section usage_cb Callback Based Decoding
-    There are two methods for the application to access decoded frame data. Some
-    codecs support asynchronous (callback-based) decoding \ref usage_features
-    that allow the application to register a callback to be invoked by the
-    decoder when decoded data becomes available. Decoders are not required to
-    support this feature, however. Like all \ref usage_features, support can be
-    determined by calling aom_codec_get_caps(). Callbacks are available in both
-    frame-based and slice-based variants. Frame based callbacks conform to the
-    signature of #aom_codec_put_frame_cb_fn_t and are invoked once the entire
-    frame has been decoded. Slice based callbacks conform to the signature of
-    #aom_codec_put_slice_cb_fn_t and are invoked after a subsection of the frame
-    is decoded. For example, a slice callback could be issued for each
-    macroblock row. However, the number and size of slices to return is
-    implementation specific. Also, the image data passed in a slice callback is
-    not necessarily in the same memory segment as the data will be when it is
-    assembled into a full frame. For this reason, the application \ref MUST
-    examine the rectangles that describe what data is valid to access and what
-    data has been updated in this call. For all their additional complexity,
-    slice based decoding callbacks provide substantial speed gains to the
-    overall application in some cases, due to improved cache behavior.
-
-
-    \section usage_frame_iter Frame Iterator Based Decoding
-    If the codec does not support callback based decoding, or the application
-    chooses not to make use of that feature, decoded frames are made available
-    through the aom_codec_get_frame() iterator. The application initializes the
-    iterator storage (of type #aom_codec_iter_t) to NULL, then calls
-    aom_codec_get_frame repeatedly until it returns NULL, indicating that all
-    images have been returned. This process may result in zero, one, or many
-    frames that are ready for display, depending on the codec.
-
-
-    \section usage_postproc Postprocessing
-    Postprocessing is a process that is applied after a frame is decoded to
-    enhance the image's appearance by removing artifacts introduced in the
-    compression process. It is not required to properly decode the frame, and
-    is generally done only when there is enough spare CPU time to execute
-    the required filters. Codecs may support a number of different
-    postprocessing filters, and the available filters may differ from platform
-    to platform. Embedded devices often do not have enough CPU to implement
-    postprocessing in software. The filter selection is generally handled
-    automatically by the codec.
-
-
-*/