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485 lines
22 KiB
Text
485 lines
22 KiB
Text
Transform elements
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------------------
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Transform elements transform input buffers to output buffers based
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on the sink and source caps.
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An important requirement for a transform is that the ouput caps are completely
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defined by the input caps and vice versa. This means that a typical decoder
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element can NOT be implemented with a transform element, this is because the
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output caps like width and height of the decompessed video frame, for example,
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are endcoded in the stream and thus not defined by the input caps.
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Typical transform elements include:
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- audio convertors (audioconvert, audioresample,...)
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- video convertors (colorspace, videoscale, ...)
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- filters (capfilter, volume, colorbalance, ...)
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The implementation of the transform element has to take care of
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the following things:
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- efficient negotiation both up and downstream
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- efficient buffer alloc and other buffer management
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Some transform elements can operate in different modes:
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- passthrough (no changes are done on the input buffers)
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- in-place (changes made directly to the incomming buffers without requiring a
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copy or new buffer allocation)
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- metadata changes only
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Depending on the mode of operation the buffer allocation strategy might change.
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The transform element should at any point be able to renegotiate sink and src
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caps as well as change the operation mode.
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In addition, the transform element will typically take care of the following
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things as well:
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- flushing, seeking
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- state changes
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- timestamping, this is typically done by copying the input timestamps to the
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output buffers but subclasses should be able to override this.
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- QoS, avoiding calls to the subclass transform function
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- handle scheduling issues such as push and pull based operation.
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In the next sections, we will describe the behaviour of the transform element in
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each of the above use cases. We focus mostly on the buffer allocation strategies
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and caps negotiation.
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Processing
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~~~~~~~~~~
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A transform has 2 main processing functions:
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- transform():
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Transform the input buffer to the output buffer. The output buffer is
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guaranteed to be writable and different from the input buffer.
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- transform_ip():
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Transform the input buffer in-place. The input buffer is writable and of
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bigger or equal size than the output buffer.
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A transform can operate in the following modes:
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- passthrough:
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The element will not make changes to the buffers, buffers are pushed straight
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through, caps on both sides need to be the same. The element can optionally
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implement a transform_ip() function to take a look at the data, the buffer
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does not have to be writable.
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- in-place:
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Changes can be made to the input buffer directly to obtain the output buffer.
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The transform must implement a transform_ip() function.
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- copy-transform
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The transform is performed by copying and transforming the input buffer to a
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new output buffer. The transform must implement a transform() function.
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When no transform() function is provided, only in-place and passthrough
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operation is allowed, this means that source and destination caps must be equal
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or that the source buffer size is bigger or equal than the destination buffer.
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When no transform_ip() function is provided, only passthrough and
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copy-transforms are supported. Providing this function is an optimisation that
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can avoid a buffer copy.
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When no functions are provided, we can only process in passthrough mode.
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Negotiation
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~~~~~~~~~~~
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Typical (re)negotiation of the transform element in push mode always goes from
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sink to src, this means triggers the following sequence:
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- the sinkpad receives a buffer with new caps, this triggers the setcaps
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function on the sinkpad before handing the buffer to transform.
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- the transform function figures out what it can convert these caps to.
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- try to see if we can configure the caps unmodified on the peer. We need to
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do this because we prefer to not do anything.
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- the transform configures itself to transform from the new sink caps to the
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target src caps
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- the transform processes and sets the output caps on the src pad
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We call this downstream negotiation (DN) and it goes roughly like this:
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sinkpad transform srcpad
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setcaps() | | |
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------------>| find_transform() | |
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|------------------->| |
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| | setcaps() |
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| |--------------------->|
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| <configure caps> <-| |
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These steps configure the element for a transformation from the input caps to
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the output caps.
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The transform has 3 function to perform the negotiation:
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- transform_caps():
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Transform the caps on a certain pad to all the possible supported caps on
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the other pad. The input caps are guaranteed to be a simple caps with just
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one structure. The caps do not have to be fixed.
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- fixate_caps():
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Given a caps on one pad, fixate the caps on the other pad. The target caps
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are writable.
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- set_caps():
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Configure the transform for a transformation between src caps and dest
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caps. Both caps are guaranteed to be fixed caps.
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If no transform_caps() is defined, we can only perform the identity transform,
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by default.
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If no set_caps() is defined, we don't care about caps. In that case we also
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assume nothing is going to write to the buffer and we don't enforce a writable
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buffer for the transform_ip function, when present.
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One common function that we need for the transform element is to find the best
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transform from one format (src) to another (dest). Since the function is
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bidirectional, we will use the src->dest negotiation. Some requirements of this
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function are:
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- has a fixed src caps
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- finds a fixed dest caps that the transform element can transform to
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- the dest caps are compatible and can be accepted by peer elements
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- the transform function prefers to make src caps == dest caps
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- the transform function can optionally fixate dest caps.
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The find_transform() function goes like this:
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- start from src aps, these caps are fixed.
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- check if the caps are acceptable for us as src caps. This is usually
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enforced by the padtemplate of the element.
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- calculate all caps we can transform too with transform_caps()
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- if the original caps are a subset of the transforms, try to see if the
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the caps are acceptable for the peer. If this is possible, we can
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perform passthrough and make src == dest. This is performed by simply
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calling gst_pad_peer_accept_caps().
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- if the caps are not fixed, we need to fixate it, start by taking the peer
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caps and intersect with them.
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- for each of the transformed caps retrieved with transform_caps():
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- try to fixate the caps with fixate_caps()
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- if the caps are fixated, check if the peer accepts them with
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_peer_accept_caps(), if the peer accepts, we have found a dest caps.
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- if we run out of caps, we fail to find a transform.
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- if we found a destination caps, configure the transform with set_caps().
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After this negotiation process, the transform element is usually in a steady
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state. We can identify these steady states:
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- src and sink pads both have the same caps. Note that when the caps are equal
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on both pads, the input and output buffers automatically have the same size.
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The element can operate on the buffers in the following ways: (Same caps, SC)
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- passthrough: buffers are inspected but no metadata or buffer data
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is changed. The input buffers don't need to be writable. The input
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buffer is simply pushed out again without modifications. (SCP)
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sinkpad transform srcpad
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chain() | | |
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------------>| handle_buffer() | |
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|------------------->| pad_push() |
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| |--------------------->|
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- in-place: buffers are modified in-place, this means that the input
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buffer is modified to produce a new output buffer. This requires the
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input buffer to be writable. If the input buffer is not writable, a new
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buffer has to be allocated with pad-alloc. (SCI)
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sinkpad transform srcpad
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chain() | | |
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------------>| handle_buffer() | |
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|------------------->| |
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| | [!writable] |
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| | pad-alloc() |
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| |--------------------->|
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| [caps-changed] .-| [caps-changed] |
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| <reconfigure> | | setcaps() |
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| '>|--------------------->|
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| .-| |
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| <transform_ip> | | |
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| '>| |
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| | pad_push() |
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| |--------------------->|
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- copy transform: a new output buffer is allocated with pad-alloc and data
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from the input buffer is transformed into the output buffer. (SCC)
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sinkpad transform srcpad
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chain() | | |
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------------>| handle_buffer() | |
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|------------------->| |
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| | pad_alloc() |
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| |--------------------->|
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| [caps-changed] .-| [caps-changed] |
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| <reconfigure> | | setcaps() |
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| '>|--------------------->|
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| .-| |
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| <transform> | | |
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| '>| |
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| | pad_push() |
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| |--------------------->|
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- src and sink pads have different caps. The element can operate on the
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buffers in the following way: (Different Caps, DC)
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- in-place: input buffers are modified in-place. This means that the input
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buffer has a size that is larger or equal to the output size. The input
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buffer will be resized to the size of the output buffer. If the input
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buffer is not writable or the output size is bigger than the input size,
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we need to pad-alloc a new buffer. (DCI)
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sinkpad transform srcpad
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chain() | | |
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------------>| handle_buffer() | |
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|------------------->| |
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| | [!writable || !size] |
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| | pad-alloc |
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| |--------------------->|
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| [caps-changed] .-| [caps-changed] |
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| <reconfigure> | | setcaps() |
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| '>|--------------------->|
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| .-| |
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| <transform_ip> | | |
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| '>| |
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| | pad_push() |
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| |--------------------->|
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- copy transform: a new output buffer is allocated and the data from the
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input buffer is transformed into the output buffer. The flow is exactly
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the same as the case with the same-caps negotiation. (DCC)
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We can immeditatly observe that the copy transform states will need to
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allocate a buffer from a downstream element using pad-alloc. When the transform
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element is receiving a non-writable buffer in the in-place state, it will also
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need to perform a pad-alloc. There is no reason why the passthrough state would
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perform a pad-alloc. This is important because upstream re-negotiation can only
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happen when the transform uses pad-alloc for all outgoing buffers.
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This steady state changes when one of the following actions occur:
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- the sink pad receives new caps, this triggers the above downstream
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renegotation process, see above for the flow.
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- the src pad is instructed to produce new caps because of new caps from
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pad-alloc, this only happens when the transform calls pad-alloc on the
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srcpad in order to produce a new output buffer.
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- the transform element wants to renegotiate (because of changed properties,
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for example). This essentially clears the current steady state and
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triggers the downstream and upstream renegotiation process.
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Parallel to the downstream negotiation process there is an upstream negotiation
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process. The handling and proxy of buffer-alloc is the most comple part of the
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transform element. This upstream negotiation process has 3 cases: (UN)
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- upstream calls the buffer-alloc function of the transform sinkpad and this
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call is proxied downstream (UNP)
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- upstream calls the buffer-alloc function of the transform sinkpad, the
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transform does not proxy the call but returns a buffer itself (UNU)
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- the transform calls the pad-alloc function downstream to allocate a new
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output buffer (but not because of a proxied buffer-alloc) (UNA)
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The case where the pad-alloc is called because an output buffer must be
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generated in the chain function is handled above in the copy-transform and the
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in-place transform when the input buffer is not writable or the input buffer
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size is smaller than the output size.
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We are left with the last case (proxy an incomming pad-alloc or not). We have 2
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possibilities here:
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- pad-alloc is called with the same caps as are currently being handled by
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the transform on the sinkcaps. Note that this will only be true when the
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transform element is completely negotiated because of data processing, see
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above. Then the element is not yet negotiated, we proceed with the case
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where sinkcaps are different from thos in the buffer-alloc.
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* If the transform is using copy-transform, we don't need to proxy because
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we will call pad-alloc when generating an output buffer.
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sinkpad transform srcpad
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buffer_alloc() | | |
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--------------->| | |
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|-. [same caps && | |
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return default | | copy-trans] | |
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<------------|<' | |
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* If the transform is using in-place and insize < outsize, we proxy
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the pad-alloc with the srccaps. If the caps are unmodified, we proxy
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the buffer after changing the caps and size.
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sinkpad transform srcpad
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buffer_alloc() | | |
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--------------->| | |
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| [same caps && | |
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| in-place] | |
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|------------------->| pad_alloc() |
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| |--------------------->|
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| [caps unchanged] | |
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return | adjust_buffer | |
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<----------------------------------| |
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* If the transform is using in-place and insize < outsize, we proxy
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the pad-alloc with the srccaps. If the caps are modified find the best
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transform from these new caps and return a buffer of this size/caps
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instead.
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sinkpad transform srcpad
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buffer_alloc() | | |
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--------------->| | |
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| [same caps && | |
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| in-place] | pad-alloc() |
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|------------------------------------------>|
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| [caps changed] .-| |
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| find_transform() | | |
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return | '>| |
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<----------------------------------| |
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* If the transform is using in-place and insize >= outsize, we cannot proxy
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the pad-alloc because the resulting buffer would be too small to return
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anyway.
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* If the transform is using passthrough, we can proxy the pad-alloc to the
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source pad. If the caps change, find the best transform and return a
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buffer of those caps and size instead.
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sinkpad transform srcpad
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buffer_alloc() | | |
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--------------->| [same caps && | |
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| passtrough] | pad-alloc() |
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|------------------------------------------>|
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| [caps changed] .-| |
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| find_transform() | | |
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return | '>| |
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<----------------------------------| |
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- pad-alloc is called with different caps than are currently being handled by
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the transform on the sinkcaps we have to try to negotiate a new
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configuration for the transform element.
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* we perform the standard way to finding a best transform using
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find_transform() and we call the pad-alloc function with these caps.
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If we get different caps from pad-alloc, we find the best format to
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transform these to and return those caps instead.
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sinkpad transform srcpad
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buffer_alloc() | | |
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--------------->| | |
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| find_transform() | |
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|------------------->| |
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| | pad-alloc() |
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| |--------------------->|
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return | [caps unchanged] | |
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<----------------------------------| |
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| [caps changed] .-| |
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| find_transform() | | |
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return | '>| |
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<----------------------------------| |
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In order to perform passthrough buffer-alloc or pad-alloc, we need to be able
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to get the size of the output buffer after the transform.
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For passthrough buffer-alloc, this is trivial: the input size equals the output
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size.
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For the copy transform or the in-place transform we need additional function to
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retrieve the size. There are two functions:
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- transform_size()
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Given a caps and a size on one pad, and a caps on the other pad, calculate
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the size of the other buffer. This function is able to perform all size
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transforms and is the prefered method of transforming a size.
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- get_unit_size()
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When the input size and output size are always a multiple of eachother
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(audio conversion, ..) we can define a more simple get_unit_size() function.
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The transform will use this function to get the same amount of units in the
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source and destination buffers.
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For performance reasons, the mapping between caps and size is kept in a cache.
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Issues
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~~~~~~
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passthrough and in-place transforms (with writable buffers) never need to
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perform a pad-alloc on the srcpad. This means that if upstream negotiation
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happens, the transform element will never know about it.
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The transform element will keep therefore track of the allocation pattern of
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the peer elements. We can see the following cases:
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- upstream peer calls buffer-alloc on the sinkpad of the transform. In some
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cases (see above) this call gets proxied or not.
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- upstream peer does never call buffer-alloc.
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We will keeps state about this allocation pattern and perform the following in
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each case respectively:
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- Upstream calls buffer-alloc: In passthrough and (some) in-place we proxy
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this call onto the downstream element. If the caps are changed, we mark
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a flag that we will require a new pad-alloc for the output of the next
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output buffer.
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- upstream peer does not call buffer-alloc: We always perform a pad-alloc
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when processing buffers. We can further optimize by only looking at the
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returned caps instead of doing a full, needless buffer copy.
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Use cases
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~~~~~~~~~
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videotestsrc ! ximagesink
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- resizing happens because videotestsrc performs pad-alloc.
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videotestsrc peer-alloc=0 ! ximagesink
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- resizing cannot happen because videotestsrc never performs pad-alloc.
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videotestsrc ! videoscale ! ximagesink
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- videoscale is initially configured in passthrough mode, pad-alloc from
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videotestsrc is proxied through videoscale.
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- pad-alloc will renegotiate a new size in videotestsrc.
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videotestsrc peer-alloc=0 ! videoscale ! ximagesink
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- videoscale is initially configured in passthrough mode.
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- videoscale performs pad-alloc because no buffer-alloc is called on the
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sinkpad
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- resizing the videosink makes videoscale perform the scaling.
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Problematic
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~~~~~~~~~~~
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filesrc location=~/media/moveyourfeet.mov ! decodebin !
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ffmpegcolorspace ! videoscale ! ffmpegcolorspace ! ximagesink -v
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