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  • Les autorisations surchargées par les plugins

    27 avril 2010, par

    Mediaspip core
    autoriser_auteur_modifier() afin que les visiteurs soient capables de modifier leurs informations sur la page d’auteurs

  • Support audio et vidéo HTML5

    10 avril 2011

    MediaSPIP utilise les balises HTML5 video et audio pour la lecture de documents multimedia en profitant des dernières innovations du W3C supportées par les navigateurs modernes.
    Pour les navigateurs plus anciens, le lecteur flash Flowplayer est utilisé.
    Le lecteur HTML5 utilisé a été spécifiquement créé pour MediaSPIP : il est complètement modifiable graphiquement pour correspondre à un thème choisi.
    Ces technologies permettent de distribuer vidéo et son à la fois sur des ordinateurs conventionnels (...)

  • HTML5 audio and video support

    13 avril 2011, par

    MediaSPIP uses HTML5 video and audio tags to play multimedia files, taking advantage of the latest W3C innovations supported by modern browsers.
    The MediaSPIP player used has been created specifically for MediaSPIP and can be easily adapted to fit in with a specific theme.
    For older browsers the Flowplayer flash fallback is used.
    MediaSPIP allows for media playback on major mobile platforms with the above (...)

Sur d’autres sites (5657)

  • ffmpeg ecplise debugging

    27 février 2012, par NadavRub

    I am using ffmpeg with my application ( Ubuntu ), to be able to better understand the way things work I want to be able to debug through it, for that, while compiling I am using the following './configure' options :

    • —disable-stripping
    • —enable-debug=3
    • —extra-cflags="-gstabs+"

    Having that set, I am able to step through 'ffmpeg' with the debugger ( gdb ), however, I am not able to evaluate any of the variables, only the code position is resolvable...

    What am I doing wrong ? why can't I evaluate the variables ?

    Any help will be appreciated.

  • Tour of Part of the VP8 Process

    18 novembre 2010, par Multimedia Mike — VP8

    My toy VP8 encoder outputs a lot of textual data to illustrate exactly what it’s doing. For those who may not be exactly clear on how this or related algorithms operate, this may prove illuminating.

    Let’s look at subblock 0 of macroblock 0 of a luma plane :

     subblock 0 (original)
  92  91  89  86
  91  90  88  86
  89  89  89  88
  89  87  88  93

    Since it’s in the top-left corner of the image to be encoded, the phantom samples above and to the left are implicitly 128 for the purpose of intra prediction (in the VP8 algorithm).

     subblock 0 (original)
     128 128 128 128
 128  92  91  89  86
 128  91  90  88  86
 128  89  89  89  88
 128  89  87  88  93


    Using the 4×4 DC prediction mode means averaging the 4 top predictors and 4 left predictors. So, the predictor is 128. Subtract this from each element of the subblock :

     subblock 0, predictor removed
 -36 -37 -39 -42
 -37 -38 -40 -42
 -39 -39 -39 -40
 -39 -41 -40 -35

    Next, run the subblock through the forward transform :

     subblock 0, transformed
 -312   7   1   0
    1  12  -5   2
    2  -3   3  -1
    1   0  -2   1

    Quantize (integer divide) each element ; the DC (first element) and AC (rest of the elements) quantizers are both 4 :

     subblock 0, quantized
 -78   1   0   0
   0   3  -1   0
   0   0   0   0
   0   0   0   0

    The above block contains the coefficients that are actually transmitted (zigzagged and entropy-encoded) through the bitstream and decoded on the other end.

    The decoding process looks something like this– after the same coefficients are decoded and rearranged, they are dequantized (multiplied) by the original quantizers :

     subblock 0, dequantized
 -312   4   0   0
    0  12  -4   0
    0   0   0   0
    0   0   0   0

    Note that these coefficients are not exactly the same as the original, pre-quantized coefficients. This is a large part of where the “lossy” in “lossy video compression” comes from.

    Next, the decoder generates a base predictor subblock. In this case, it’s all 128 (DC prediction for top-left subblock) :

     subblock 0, predictor
  128 128 128 128
  128 128 128 128
  128 128 128 128
  128 128 128 128

    Finally, the dequantized coefficients are shoved through the inverse transform and added to the base predictor block :

     subblock 0, reconstructed
  91  91  89  85
  90  90  89  87
  89  88  89  90
  88  88  89  92

    Again, not exactly the same as the original block, but an incredible facsimile thereof.

    Note that this decoding-after-encoding demonstration is not merely pedagogical– the encoder has to decode the subblock because the encoding of successive subblocks may depend on this subblock. The encoder can’t rely on the original representation of the subblock because the decoder won’t have that– it will have the reconstructed block.

    For example, here’s the next subblock :

     subblock 1 (original)
  84  84  87  90
  85  85  86  93
  86  83  83  89
  91  85  84  87

    Let’s assume DC prediction once more. The 4 top predictors are still all 128 since this subblock lies along the top row. However, the 4 left predictors are the right edge of the subblock reconstructed in the previous example :

     subblock 1 (original)
    128 128 128 128
 85  84  84  87  90
 87  85  85  86  93
 90  86  83  83  89
 92  91  85  84  87

    The DC predictor is computed as (128 + 128 + 128 + 128 + 85 + 87 + 90 + 92 + 4) / 8 = 108 (the extra +4 is for rounding considerations). (Note that in this case, using the original subblock’s right edge would also have resulted in 108, but that’s beside the point.)

    Continuing through the same process as in subblock 0 :

     subblock 1, predictor removed
 -24 -24 -21 -18
 -23 -23 -22 -15
 -22 -25 -25 -19
 -17 -23 -24 -21

     subblock 1, transformed
    
 -173  -9  14  -1
    
    2 -11  -4   0
    
    1   6  -2   3
    
   -5   1   0   1
    

     subblock 1, quantized
    
 -43  -2   3   0
    
   0  -2  -1   0
    
   0   1   0   0
    
  -1   0   0   0
    

     subblock 1, dequantized
    
 -172  -8  12   0
    
    0  -8  -4   0
    
    0   4   0   0
    
   -4   0   0   0
    

     subblock 1, predictor
    
  108 108 108 108
    
  108 108 108 108
    
  108 108 108 108
    
  108 108 108 108
    

     subblock 1, reconstructed
    
  84  84  87  89
    
  86  85  87  91
    
  86  83  84  89
    
  90  85  84  88

    I hope this concrete example (straight from a working codec) clarifies this part of the VP8 process.

  • Where is the documentation for the Mjpeg codec used in mencoder, VLC and FFMpeg ?

    18 août 2011, par Sugrue

    Mencoder has a lovely option for converting a mjpeg file into an avi file with an 'MJPG' codec that plays in VLC.

    The command line to do this is :

    mencoder filename.mjpeg -oac copy -ovc copy -o outputfile.avi -speed 0.3

    where 0.3 is the ratio of the desired play framerate to the default 25 fps. All this does is make a copy of the mjpeg file, put an avi header on top and at the end, what seems to be an index of the frame positions in the file.

    I want to replicate this in my own code, but I can't find documentation anywhere. What is the exact format of the index section ? The header has extra filler bytes in it for some reason - whats this about ?

    Anyone know where I can find documentation ? Both mencoder and vlc seem to have this codec built in.

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