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1460719153
Signed-off-by: Ganesh Ajjanagadde <gajjanagadde@gmail.com>
424 lines
16 KiB
Plaintext
424 lines
16 KiB
Plaintext
This document is a tutorial/initiation for writing simple filters in
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libavfilter.
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Foreword: just like everything else in FFmpeg, libavfilter is monolithic, which
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means that it is highly recommended that you submit your filters to the FFmpeg
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development mailing-list and make sure that they are applied. Otherwise, your filters
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are likely to have a very short lifetime due to more or less regular internal API
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changes, and a limited distribution, review, and testing.
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Bootstrap
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=========
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Let's say you want to write a new simple video filter called "foobar" which
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takes one frame in input, changes the pixels in whatever fashion you fancy, and
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outputs the modified frame. The most simple way of doing this is to take a
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similar filter. We'll pick edgedetect, but any other should do. You can look
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for others using the `./ffmpeg -v 0 -filters|grep ' V->V '` command.
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- sed 's/edgedetect/foobar/g;s/EdgeDetect/Foobar/g' libavfilter/vf_edgedetect.c > libavfilter/vf_foobar.c
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- edit libavfilter/Makefile, and add an entry for "foobar" following the
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pattern of the other filters.
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- edit libavfilter/allfilters.c, and add an entry for "foobar" following the
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pattern of the other filters.
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- ./configure ...
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- make -j<whatever> ffmpeg
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- ./ffmpeg -i http://samples.ffmpeg.org/image-samples/lena.pnm -vf foobar foobar.png
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Note here: you can obviously use a random local image instead of a remote URL.
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If everything went right, you should get a foobar.png with Lena edge-detected.
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That's it, your new playground is ready.
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Some little details about what's going on:
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libavfilter/allfilters.c:avfilter_register_all() is called at runtime to create
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a list of the available filters, but it's important to know that this file is
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also parsed by the configure script, which in turn will define variables for
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the build system and the C:
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--- after running configure ---
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$ grep FOOBAR config.mak
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CONFIG_FOOBAR_FILTER=yes
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$ grep FOOBAR config.h
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#define CONFIG_FOOBAR_FILTER 1
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CONFIG_FOOBAR_FILTER=yes from the config.mak is later used to enable the filter in
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libavfilter/Makefile and CONFIG_FOOBAR_FILTER=1 from the config.h will be used
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for registering the filter in libavfilter/allfilters.c.
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Filter code layout
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==================
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You now need some theory about the general code layout of a filter. Open your
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libavfilter/vf_foobar.c. This section will detail the important parts of the
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code you need to understand before messing with it.
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Copyright
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---------
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First chunk is the copyright. Most filters are LGPL, and we are assuming
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vf_foobar is as well. We are also assuming vf_foobar is not an edge detector
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filter, so you can update the boilerplate with your credits.
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Doxy
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----
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Next chunk is the Doxygen about the file. See https://ffmpeg.org/doxygen/trunk/.
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Detail here what the filter is, does, and add some references if you feel like
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it.
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Context
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-------
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Skip the headers and scroll down to the definition of FoobarContext. This is
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your local state context. It is already filled with 0 when you get it so do not
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worry about uninitialized reads into this context. This is where you put all
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"global" information that you need; typically the variables storing the user options.
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You'll notice the first field "const AVClass *class"; it's the only field you
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need to keep assuming you have a context. There is some magic you don't need to
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care about around this field, just let it be (in the first position) for now.
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Options
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-------
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Then comes the options array. This is what will define the user accessible
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options. For example, -vf foobar=mode=colormix:high=0.4:low=0.1. Most options
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have the following pattern:
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name, description, offset, type, default value, minimum value, maximum value, flags
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- name is the option name, keep it simple and lowercase
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- description are short, in lowercase, without period, and describe what they
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do, for example "set the foo of the bar"
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- offset is the offset of the field in your local context, see the OFFSET()
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macro; the option parser will use that information to fill the fields
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according to the user input
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- type is any of AV_OPT_TYPE_* defined in libavutil/opt.h
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- default value is an union where you pick the appropriate type; "{.dbl=0.3}",
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"{.i64=0x234}", "{.str=NULL}", ...
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- min and max values define the range of available values, inclusive
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- flags are AVOption generic flags. See AV_OPT_FLAG_* definitions
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When in doubt, just look at the other AVOption definitions all around the codebase,
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there are tons of examples.
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Class
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-----
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AVFILTER_DEFINE_CLASS(foobar) will define a unique foobar_class with some kind
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of signature referencing the options, etc. which will be referenced in the
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definition of the AVFilter.
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Filter definition
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-----------------
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At the end of the file, you will find foobar_inputs, foobar_outputs and
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the AVFilter ff_vf_foobar. Don't forget to update the AVFilter.description with
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a description of what the filter does, starting with a capitalized letter and
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ending with a period. You'd better drop the AVFilter.flags entry for now, and
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re-add them later depending on the capabilities of your filter.
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Callbacks
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---------
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Let's now study the common callbacks. Before going into details, note that all
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these callbacks are explained in details in libavfilter/avfilter.h, so in
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doubt, refer to the doxy in that file.
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init()
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~~~~~~
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First one to be called is init(). It's flagged as cold because not called
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often. Look for "cold" on
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http://gcc.gnu.org/onlinedocs/gcc/Function-Attributes.html for more
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information.
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As the name suggests, init() is where you eventually initialize and allocate
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your buffers, pre-compute your data, etc. Note that at this point, your local
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context already has the user options initialized, but you still haven't any
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clue about the kind of data input you will get, so this function is often
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mainly used to sanitize the user options.
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Some init()s will also define the number of inputs or outputs dynamically
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according to the user options. A good example of this is the split filter, but
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we won't cover this here since vf_foobar is just a simple 1:1 filter.
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uninit()
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~~~~~~~~
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Similarly, there is the uninit() callback, doing what the name suggests. Free
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everything you allocated here.
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query_formats()
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~~~~~~~~~~~~~~~
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This follows the init() and is used for the format negotiation. Basically
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you specify here what pixel format(s) (gray, rgb 32, yuv 4:2:0, ...) you accept
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for your inputs, and what you can output. All pixel formats are defined in
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libavutil/pixfmt.h. If you don't change the pixel format between the input and
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the output, you just have to define a pixel formats array and call
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ff_set_common_formats(). For more complex negotiation, you can refer to other
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filters such as vf_scale.
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config_props()
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~~~~~~~~~~~~~~
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This callback is not necessary, but you will probably have one or more
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config_props() anyway. It's not a callback for the filter itself but for its
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inputs or outputs (they're called "pads" - AVFilterPad - in libavfilter's
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lexicon).
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Inside the input config_props(), you are at a point where you know which pixel
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format has been picked after query_formats(), and more information such as the
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video width and height (inlink->{w,h}). So if you need to update your internal
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context state depending on your input you can do it here. In edgedetect you can
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see that this callback is used to allocate buffers depending on these
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information. They will be destroyed in uninit().
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Inside the output config_props(), you can define what you want to change in the
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output. Typically, if your filter is going to double the size of the video, you
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will update outlink->w and outlink->h.
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filter_frame()
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~~~~~~~~~~~~~~
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This is the callback you are waiting for from the beginning: it is where you
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process the received frames. Along with the frame, you get the input link from
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where the frame comes from.
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static int filter_frame(AVFilterLink *inlink, AVFrame *in) { ... }
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You can get the filter context through that input link:
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AVFilterContext *ctx = inlink->dst;
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Then access your internal state context:
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FoobarContext *foobar = ctx->priv;
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And also the output link where you will send your frame when you are done:
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AVFilterLink *outlink = ctx->outputs[0];
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Here, we are picking the first output. You can have several, but in our case we
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only have one since we are in a 1:1 input-output situation.
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If you want to define a simple pass-through filter, you can just do:
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return ff_filter_frame(outlink, in);
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But of course, you probably want to change the data of that frame.
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This can be done by accessing frame->data[] and frame->linesize[]. Important
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note here: the width does NOT match the linesize. The linesize is always
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greater or equal to the width. The padding created should not be changed or
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even read. Typically, keep in mind that a previous filter in your chain might
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have altered the frame dimension but not the linesize. Imagine a crop filter
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that halves the video size: the linesizes won't be changed, just the width.
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<-------------- linesize ------------------------>
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+-------------------------------+----------------+ ^
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| picture | padding | | height
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+-------------------------------+----------------+ v
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<----------- width ------------->
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Before modifying the "in" frame, you have to make sure it is writable, or get a
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new one. Multiple scenarios are possible here depending on the kind of
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processing you are doing.
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Let's say you want to change one pixel depending on multiple pixels (typically
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the surrounding ones) of the input. In that case, you can't do an in-place
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processing of the input so you will need to allocate a new frame, with the same
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properties as the input one, and send that new frame to the next filter:
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AVFrame *out = ff_get_video_buffer(outlink, outlink->w, outlink->h);
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if (!out) {
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av_frame_free(&in);
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return AVERROR(ENOMEM);
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}
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av_frame_copy_props(out, in);
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// out->data[...] = foobar(in->data[...])
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av_frame_free(&in);
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return ff_filter_frame(outlink, out);
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In-place processing
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~~~~~~~~~~~~~~~~~~~
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If you can just alter the input frame, you probably just want to do that
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instead:
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av_frame_make_writable(in);
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// in->data[...] = foobar(in->data[...])
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return ff_filter_frame(outlink, in);
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You may wonder why a frame might not be writable. The answer is that for
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example a previous filter might still own the frame data: imagine a filter
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prior to yours in the filtergraph that needs to cache the frame. You must not
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alter that frame, otherwise it will make that previous filter buggy. This is
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where av_frame_make_writable() helps (it won't have any effect if the frame
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already is writable).
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The problem with using av_frame_make_writable() is that in the worst case it
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will copy the whole input frame before you change it all over again with your
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filter: if the frame is not writable, av_frame_make_writable() will allocate
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new buffers, and copy the input frame data. You don't want that, and you can
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avoid it by just allocating a new buffer if necessary, and process from in to
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out in your filter, saving the memcpy. Generally, this is done following this
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scheme:
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int direct = 0;
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AVFrame *out;
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if (av_frame_is_writable(in)) {
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direct = 1;
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out = in;
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} else {
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out = ff_get_video_buffer(outlink, outlink->w, outlink->h);
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if (!out) {
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av_frame_free(&in);
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return AVERROR(ENOMEM);
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}
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av_frame_copy_props(out, in);
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}
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// out->data[...] = foobar(in->data[...])
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if (!direct)
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av_frame_free(&in);
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return ff_filter_frame(outlink, out);
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Of course, this will only work if you can do in-place processing. To test if
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your filter handles well the permissions, you can use the perms filter. For
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example with:
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-vf perms=random,foobar
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Make sure no automatic pixel conversion is inserted between perms and foobar,
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otherwise the frames permissions might change again and the test will be
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meaningless: add av_log(0,0,"direct=%d\n",direct) in your code to check that.
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You can avoid the issue with something like:
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-vf format=rgb24,perms=random,foobar
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...assuming your filter accepts rgb24 of course. This will make sure the
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necessary conversion is inserted before the perms filter.
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Timeline
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~~~~~~~~
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Adding timeline support
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(http://ffmpeg.org/ffmpeg-filters.html#Timeline-editing) is often an easy
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feature to add. In the most simple case, you just have to add
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AVFILTER_FLAG_SUPPORT_TIMELINE_GENERIC to the AVFilter.flags. You can typically
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do this when your filter does not need to save the previous context frames, or
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basically if your filter just alters whatever goes in and doesn't need
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previous/future information. See for instance commit 86cb986ce that adds
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timeline support to the fieldorder filter.
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In some cases, you might need to reset your context somehow. This is handled by
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the AVFILTER_FLAG_SUPPORT_TIMELINE_INTERNAL flag which is used if the filter
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must not process the frames but still wants to keep track of the frames going
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through (to keep them in cache for when it's enabled again). See for example
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commit 69d72140a that adds timeline support to the phase filter.
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Threading
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~~~~~~~~~
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libavfilter does not yet support frame threading, but you can add slice
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threading to your filters.
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Let's say the foobar filter has the following frame processing function:
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dst = out->data[0];
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src = in ->data[0];
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for (y = 0; y < inlink->h; y++) {
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for (x = 0; x < inlink->w; x++)
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dst[x] = foobar(src[x]);
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dst += out->linesize[0];
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src += in ->linesize[0];
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}
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The first thing is to make this function work into slices. The new code will
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look like this:
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for (y = slice_start; y < slice_end; y++) {
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for (x = 0; x < inlink->w; x++)
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dst[x] = foobar(src[x]);
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dst += out->linesize[0];
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src += in ->linesize[0];
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}
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The source and destination pointers, and slice_start/slice_end will be defined
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according to the number of jobs. Generally, it looks like this:
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const int slice_start = (in->height * jobnr ) / nb_jobs;
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const int slice_end = (in->height * (jobnr+1)) / nb_jobs;
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uint8_t *dst = out->data[0] + slice_start * out->linesize[0];
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const uint8_t *src = in->data[0] + slice_start * in->linesize[0];
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This new code will be isolated in a new filter_slice():
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static int filter_slice(AVFilterContext *ctx, void *arg, int jobnr, int nb_jobs) { ... }
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Note that we need our input and output frame to define slice_{start,end} and
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dst/src, which are not available in that callback. They will be transmitted
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through the opaque void *arg. You have to define a structure which contains
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everything you need:
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typedef struct ThreadData {
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AVFrame *in, *out;
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} ThreadData;
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If you need some more information from your local context, put them here.
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In you filter_slice function, you access it like that:
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const ThreadData *td = arg;
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Then in your filter_frame() callback, you need to call the threading
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distributor with something like this:
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ThreadData td;
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// ...
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td.in = in;
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td.out = out;
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ctx->internal->execute(ctx, filter_slice, &td, NULL, FFMIN(outlink->h, ctx->graph->nb_threads));
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// ...
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return ff_filter_frame(outlink, out);
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Last step is to add AVFILTER_FLAG_SLICE_THREADS flag to AVFilter.flags.
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For more example of slice threading additions, you can try to run git log -p
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--grep 'slice threading' libavfilter/
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Finalization
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~~~~~~~~~~~~
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When your awesome filter is finished, you have a few more steps before you're
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done:
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- write its documentation in doc/filters.texi, and test the output with make
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doc/ffmpeg-filters.html.
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- add a FATE test, generally by adding an entry in
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tests/fate/filter-video.mak, add running make fate-filter-foobar GEN=1 to
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generate the data.
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- add an entry in the Changelog
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- edit libavfilter/version.h and increase LIBAVFILTER_VERSION_MINOR by one
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(and reset LIBAVFILTER_VERSION_MICRO to 100)
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- git add ... && git commit -m "avfilter: add foobar filter." && git format-patch -1
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When all of this is done, you can submit your patch to the ffmpeg-devel
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mailing-list for review. If you need any help, feel free to come on our IRC
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channel, #ffmpeg-devel on irc.freenode.net.
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