gstreamer/docs/design/part-element-transform.txt
Sebastian Dröge 43538e2e75 Merge branch 'master' into 0.11
Conflicts:
	docs/design/draft-buffer2.txt
	docs/design/part-TODO.txt
	docs/design/part-block.txt
	docs/design/part-bufferlist.txt
	docs/design/part-caps.txt
	docs/design/part-element-transform.txt
	docs/design/part-events.txt
	docs/design/part-negotiation.txt
	gst/gstcaps.c
	gst/gstevent.h
	gst/gstghostpad.c
	gst/gstinterface.c
	gst/gstpad.c
	gst/gstpad.h
	gst/gstutils.c
	libs/gst/base/gstbasesink.c
	libs/gst/base/gstbasesrc.c
	libs/gst/base/gstbasetransform.c
	libs/gst/base/gsttypefindhelper.c
	plugins/elements/gstcapsfilter.c
	plugins/elements/gsttee.c
	tests/check/generic/sinks.c
	tools/gst-launch.1.in
2011-09-08 14:28:23 +02:00

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Transform elements
------------------
Transform elements transform input buffers to output buffers based
on the sink and source caps.
An important requirement for a transform is that the ouput caps are completely
defined by the input caps and vice versa. This means that a typical decoder
element can NOT be implemented with a transform element, this is because the
output caps like width and height of the decompessed video frame, for example,
are endcoded in the stream and thus not defined by the input caps.
Typical transform elements include:
- audio convertors (audioconvert, audioresample,...)
- video convertors (colorspace, videoscale, ...)
- filters (capfilter, volume, colorbalance, ...)
The implementation of the transform element has to take care of
the following things:
- efficient negotiation both up and downstream
- efficient buffer alloc and other buffer management
Some transform elements can operate in different modes:
- passthrough (no changes are done on the input buffers)
- in-place (changes made directly to the incoming buffers without requiring a
copy or new buffer allocation)
- metadata changes only
Depending on the mode of operation the buffer allocation strategy might change.
The transform element should at any point be able to renegotiate sink and src
caps as well as change the operation mode.
In addition, the transform element will typically take care of the following
things as well:
- flushing, seeking
- state changes
- timestamping, this is typically done by copying the input timestamps to the
output buffers but subclasses should be able to override this.
- QoS, avoiding calls to the subclass transform function
- handle scheduling issues such as push and pull based operation.
In the next sections, we will describe the behaviour of the transform element in
each of the above use cases. We focus mostly on the buffer allocation strategies
and caps negotiation.
Processing
~~~~~~~~~~
A transform has 2 main processing functions:
- transform():
Transform the input buffer to the output buffer. The output buffer is
guaranteed to be writable and different from the input buffer.
- transform_ip():
Transform the input buffer in-place. The input buffer is writable and of
bigger or equal size than the output buffer.
A transform can operate in the following modes:
- passthrough:
The element will not make changes to the buffers, buffers are pushed straight
through, caps on both sides need to be the same. The element can optionally
implement a transform_ip() function to take a look at the data, the buffer
does not have to be writable.
- in-place:
Changes can be made to the input buffer directly to obtain the output buffer.
The transform must implement a transform_ip() function.
- copy-transform
The transform is performed by copying and transforming the input buffer to a
new output buffer. The transform must implement a transform() function.
When no transform() function is provided, only in-place and passthrough
operation is allowed, this means that source and destination caps must be equal
or that the source buffer size is bigger or equal than the destination buffer.
When no transform_ip() function is provided, only passthrough and
copy-transforms are supported. Providing this function is an optimisation that
can avoid a buffer copy.
When no functions are provided, we can only process in passthrough mode.
Negotiation
~~~~~~~~~~~
Typical (re)negotiation of the transform element in push mode always goes from
sink to src, this means triggers the following sequence:
- the sinkpad receives a new caps event.
- the transform function figures out what it can convert these caps to.
- try to see if we can configure the caps unmodified on the peer. We need to
do this because we prefer to not do anything.
- the transform configures itself to transform from the new sink caps to the
target src caps
- the transform processes and sets the output caps on the src pad
We call this downstream negotiation (DN) and it goes roughly like this:
sinkpad transform srcpad
CAPS event | | |
------------>| find_transform() | |
|------------------->| |
| | CAPS event |
| |--------------------->|
| <configure caps> <-| |
These steps configure the element for a transformation from the input caps to
the output caps.
The transform has 3 function to perform the negotiation:
- transform_caps():
Transform the caps on a certain pad to all the possible supported caps on
the other pad. The input caps are guaranteed to be a simple caps with just
one structure. The caps do not have to be fixed.
- fixate_caps():
Given a caps on one pad, fixate the caps on the other pad. The target caps
are writable.
- set_caps():
Configure the transform for a transformation between src caps and dest
caps. Both caps are guaranteed to be fixed caps.
If no transform_caps() is defined, we can only perform the identity transform,
by default.
If no set_caps() is defined, we don't care about caps. In that case we also
assume nothing is going to write to the buffer and we don't enforce a writable
buffer for the transform_ip function, when present.
One common function that we need for the transform element is to find the best
transform from one format (src) to another (dest). Some requirements of this
function are:
- has a fixed src caps
- finds a fixed dest caps that the transform element can transform to
- the dest caps are compatible and can be accepted by peer elements
- the transform function prefers to make src caps == dest caps
- the transform function can optionally fixate dest caps.
The find_transform() function goes like this:
- start from src aps, these caps are fixed.
- check if the caps are acceptable for us as src caps. This is usually
enforced by the padtemplate of the element.
- calculate all caps we can transform too with transform_caps()
- if the original caps are a subset of the transforms, try to see if the
the caps are acceptable for the peer. If this is possible, we can
perform passthrough and make src == dest. This is performed by simply
calling gst_pad_peer_accept_caps().
- if the caps are not fixed, we need to fixate it, start by taking the peer
caps and intersect with them.
- for each of the transformed caps retrieved with transform_caps():
- try to fixate the caps with fixate_caps()
- if the caps are fixated, check if the peer accepts them with
_peer_accept_caps(), if the peer accepts, we have found a dest caps.
- if we run out of caps, we fail to find a transform.
- if we found a destination caps, configure the transform with set_caps().
After this negotiation process, the transform element is usually in a steady
state. We can identify these steady states:
- src and sink pads both have the same caps. Note that when the caps are equal
on both pads, the input and output buffers automatically have the same size.
The element can operate on the buffers in the following ways: (Same caps, SC)
- passthrough: buffers are inspected but no metadata or buffer data
is changed. The input buffers don't need to be writable. The input
buffer is simply pushed out again without modifications. (SCP)
sinkpad transform srcpad
chain() | | |
------------>| handle_buffer() | |
|------------------->| pad_push() |
| |--------------------->|
| | |
- in-place: buffers are modified in-place, this means that the input
buffer is modified to produce a new output buffer. This requires the
input buffer to be writable. If the input buffer is not writable, a new
buffer has to be allocated from the bufferpool. (SCI)
sinkpad transform srcpad
chain() | | |
------------>| handle_buffer() | |
|------------------->| |
| | [!writable] |
| | alloc buffer |
| .-| |
| <transform_ip> | | |
| '>| |
| | pad_push() |
| |--------------------->|
| | |
- copy transform: a new output buffer is allocate from the bufferpool
and data from the input buffer is transformed into the output buffer.
(SCC)
sinkpad transform srcpad
chain() | | |
------------>| handle_buffer() | |
|------------------->| |
| | alloc buffer |
| .-| |
| <transform> | | |
| '>| |
| | pad_push() |
| |--------------------->|
| | |
- src and sink pads have different caps. The element can operate on the
buffers in the following way: (Different Caps, DC)
- in-place: input buffers are modified in-place. This means that the input
buffer has a size that is larger or equal to the output size. The input
buffer will be resized to the size of the output buffer. If the input
buffer is not writable or the output size is bigger than the input size,
we need to pad-alloc a new buffer. (DCI)
sinkpad transform srcpad
chain() | | |
------------>| handle_buffer() | |
|------------------->| |
| | [!writable || !size] |
| | alloc buffer |
| .-| |
| <transform_ip> | | |
| '>| |
| | pad_push() |
| |--------------------->|
| | |
- copy transform: a new output buffer is allocated and the data from the
input buffer is transformed into the output buffer. The flow is exactly
the same as the case with the same-caps negotiation. (DCC)
We can immediately observe that the copy transform states will need to
allocate a new buffer from the bufferpool. When the transform element is
receiving a non-writable buffer in the in-place state, it will also
need to perform an allocation. There is no reason why the passthrough state would
perform an allocation.
This steady state changes when one of the following actions occur:
- the sink pad receives new caps, this triggers the above downstream
renegotation process, see above for the flow.
- the transform element wants to renegotiate (because of changed properties,
for example). This essentially clears the current steady state and
triggers the downstream and upstream renegotiation process. This situation
also happens when a RECONFIGURE event was received on the transform srcpad.
Allocation
~~~~~~~~~~
After the transform element is configured with caps, a bufferpool needs to be
negotiated to perform the allocation of buffers. We habe 2 cases:
- The element is operating in passthrough we don't need to allocate a buffer
in the transform element.
- The element is not operating in passthrough and needs to allocation an
output buffer.
In case 1, we don't query and configure a pool. We let upstream decide if it
wants to use a bufferpool and then we will proxy the bufferpool from downstream
to upstream.
In case 2, we query and set a bufferpool on the srcpad that will be used for
doing the allocations.
In order to perform allocation, we need to be able to get the size of the
output buffer after the transform. We need additional function to
retrieve the size. There are two functions:
- transform_size()
Given a caps and a size on one pad, and a caps on the other pad, calculate
the size of the other buffer. This function is able to perform all size
transforms and is the preferred method of transforming a size.
- get_unit_size()
When the input size and output size are always a multiple of eachother
(audio conversion, ..) we can define a more simple get_unit_size() function.
The transform will use this function to get the same amount of units in the
source and destination buffers.
For performance reasons, the mapping between caps and size is kept in a cache.