summaryrefslogtreecommitdiffstats
path: root/DOCS/tech-overview.txt
blob: 0fb20e7e81ca6c3e852a012ab77eab0f940d5f58 (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
NOTE: DOCS/OUTDATED-tech/* may contain more detailed information, but most of it
      is possibly or definitely outdated. This file intends to give a big
      picture of how mplayer/mpv is structured.

core/mplayer.c:
    This contains the main play loop, anything related to mplayer and playback
    related initializations. It also contains the main function. Generally, it
    accesses all other subsystems, initializes them, and pushes data between
    them during playback.

    The structure is as follows (as of commit e13c05366557cb):
    * main():
        * basic initializations (e.g. init_libav() and more)
        * pre-parse command line (verbosity level, config file locations)
        * load config files (parse_cfgfiles())
        * parse command line, add files from the command line to playlist
          (m_config_parse_mp_command_line())
        * check help options etc. (call handle_help_options()), possibly exit
        * call play_files() function that works down the playlist:
            * run idle loop (idle_loop()), until there are files in the
                playlist or an exit command was given (slave mode only)
            * actually load and play a file in play_current_file():
                * run all the dozens of functions to load the file and
                  initialize playback
                * run a small loop that does normal playback, until the file is
                  done or a slave command terminates playback
                  (on each iteration, run_playloop() is called, which is rather
                   big and complicated - it decodes some audio and video on
                   each frame, waits for input, etc.)
                * uninitialize playback
            * determine next entry on the playlist to play
            * loop, or exit if no next file or quit is requested
              (see enum stop_play_reason)
        * call exit_player_with_rc()

    Things worth saying about the playback core:
    - the currently played tracks are in sh_video and sh_audio
    - the timeline stuff is used only with MKV ordered chapters (and some other
      minor features: cue, edl)
    - most state is in MPContext (mp_core.h), which is not available to the
      subsystems
    - the other subsystems rarely call back into the frontend, and the frontend
      polls them instead (probably a good thing)

    I like to call mplayer.c (and some other files) the "frontend".

talloc.h & talloc.c:
    Hierarchical memory manager copied from Samba. It's like a malloc() with
    more features. Most importantly, each talloc allocation can have a parent,
    and if the parent is free'd, all children will be free'd as well. The
    parent is an arbitrary talloc allocation. It's either set by the allocation
    call by passing a talloc parent, usually as first argument to the allocation
    function. It can also be set or reset later by other calls (at least
    talloc_steal()). A talloc allocation that is used as parent is often called
    a talloc context.

    Lots of code still uses malloc() proper, and you should be careful what
    type of allocation you're dealing with when returning or free'ing an
    allocation. (Needless to say, talloc_free() and free() are completely
    different things.)

    The copy in mplayer has been modified to abort on OOM conditions. An
    allocation call will never return NULL.

    One very useful feature of talloc is fast tracking of memory leaks. ("Fast"
    as in it doesn't require valgrind.) You can enable it by passing the option
    --leak-report as first parameter, or better, setting the
    MPV_LEAK_REPORT environment variable to "1":
        export MPV_LEAK_REPORT=1
    This will list all unfree'd allocations on exit.

    Documentation can be found here:
        http://git.samba.org/?p=samba.git;a=blob;f=lib/talloc/talloc.h;hb=HEAD

core/mp_core.h:
    Data structures for mplayer.c and command.c. They are usually not accessed
    by other parts of mplayer for the sake of modularization.

    Note that there are lots of global variables floating around everywhere
    else. This is an ongoing transition, and eventually there should be no
    global variables anymore.

    options.h contains the global option struct MPOpts, and its default values
    are in defaultopts.c for some reason.

core/input/input.c:
    This translates keyboard input comming from libvo and other sources (such
    as remote control devices like Apple IR or slave mode commands) to the
    key bindings listed in the user's (or the builtin) input.conf and turns
    them into items of type struct mp_cmd. These commands are queued, and read
    by mplayer.c. They get pushed with run_command() to command.c.

    Note that keyboard input and slave mode input are essentially the same
    things. Just looking at input.conf should make this clear. (The other
    direction of slave mode communication, mplayer to application, consists of
    random mp_msg() calls all over the code in all parts of the player.)

core/command.c:
    This contains the implementation for slave commands and properties.
    Properties are essentially dynamic variables changed by certain commands.
    This is basically responsible for all user commands, like initiating
    seeking, switching tracks, etc. It calls into mplayer.c, where most of the
    work is done, but also into other parts of mplayer.

core/mp_msg.h:
    All terminal output should go though mp_msg().

stream/*:
    File input is implemented here. stream.h/.c provides a simple stream based
    interface (like reading a number of bytes at a given offset). mplayer can
    also play from http streams and such, which is implemented here.

    E.g. if mplayer sees "http://something" on the command line, it will pick
    stream_http.c based on the prefix, and pass the rest of the filename to it.

    Some stream inputs are quite special: stream_dvd.c turns DVDs into mpeg
    streams (DVDs are actually a bunch of vob files etc. on a filesystem),
    stream_tv.c provides TV input including channel switching.

    Some stream inputs are just there to invoke special demuxers, like
    stream_mf.c. (Basically to make the prefix "mf://" do something special.)

    cache2.c is a horrible little thing which provides a caching wrapper around
    stream implementations, needed for smooth network playback.

demux/:
    Demuxers split data streams into audio/video/sub streams, which in turn
    yield packets. Packets (see demux_packet.h) are mostly byte chunks tagged
    with a playback time (PTS). These packets are passed to the decoders.

    Most demuxers have been removed from this fork, and the only important and
    "actual" demuxers left are demux_mkv.c and demux_lavf.c (uses libavformat).
    There are some pseudo demuxers like demux_cue.c, which exist only to invoke
    other frontend code (tl_cue.c in this case).

    The main interface is in demux.h. A demuxer provides a list of available
    streams. Also, for each type of stream (video/audio/sub) there is a
    demux_stream. This contains the current packet stream coming from the
    demuxer as a linked list of demux_packets.

video/:
    This contains several things related to audio/video encoding, as well as
    video filters.

    mp_image.h and img_format.h define how mplayer stores video frames
    internally.

video/decode/:
    vd_*.c are video decoders. (There's only vd_ffmpeg.c left.) dec_video.c/vd.c
    handle most of connecting the frontend with the actual decoder.

video/filter/:
    vf_*.c and vf.c form the video filter chain. They are fed by the video
    decoder, and output the filtered images to the VOs though vf_vo.c. By
    default, no video filters (except vf_vo) are used.

video/out/:
    Video output. They also create GUI windows and handle user input. In most
    cases, the windowing code is shared among VOs, like x11_common.c for X11 and
    w32_common.c for Windows. The VOs stand between frontend and windowing code.
    vo_opengl can pick a windowing system at runtime, e.g. the same binary can
    provide both X11 and Cocoa support on OSX.

    VOs can be reconfigured at runtime. A config() call can change the video
    resolution and format, without destroying the window.

    vo_vdpau and vo_opengl should be taken as reference.

audio/:
    format.h/format.c define the audio formats.

audio/decode/:
    ad_*.c and dec_audio.c/ad.c handle audio decoding.

audio/filter/:
    Audio filter chain.

audio/out/:
    Audio outputs.

    Unlike VOs, AOs can't be reconfigured on a format change. Without
    --gapless-audio, even playing a new file will close and re-open the audio
    device.

    Note that mplayer synchronizes the video to the audio. That's the reason
    why buggy audio drivers can have a bad influence on playback quality.

sub/:
    A big mess. Contains subtitle rendering (parts of it), OSD rendering,
    subtitle loading.

    There are about 3 types of subtitles: image subs, ASS subs, text subs. Also,
    there are 3 rendering methods: image subs, libass, internal subtitle
    renderer. Also, subtitles can come from demuxers or external files. All the
    possible combinations create weird special cases, e.g. taking a text
    subtitle event from the demuxer and converting it to ass for display is
    different from loading a text subtitle and converting it to ass.

core/timeline/:
    A timeline is the abstraction used by mplayer.c to combine several files
    into one seemingly linear video. It's mainly used for ordered chapters
    playback. The high level code to find and load other files containing the
    segments for playing an ordered chapters file is in tl_matroska.c.

etc/:
    The files codecs.conf and input.conf are actually integrated into the
    mplayer binary by the build system. These files define the default settings.
    codecs.conf maps video/audio formats to decoders. input.conf contains
    the default keybindings.