It is VERY recommended to check if the MTRR registers are set up properly, because they can give a big performance boost.
Do a cat /proc/mtrr:
--($:~)-- cat /proc/mtrr reg00: base=0xe4000000 (3648MB), size= 16MB: write-combining, count=9 reg01: base=0xd8000000 (3456MB), size= 128MB: write-combining, count=1
It's right, shows my Matrox G400 with 16MB memory. I did this from XFree 4.x.x , which sets up MTRR registers automatically.
If nothing worked, you have to do it manually. First, you have to find the base address. You have 3 ways to find it:
from X11 startup messages, for example:
(--) SVGA: PCI: Matrox MGA G400 AGP rev 4, Memory @ 0xd8000000, 0xd4000000 (--) SVGA: Linear framebuffer at 0xD8000000
from /proc/pci (use lspci -v command):
01:00.0 VGA compatible controller: Matrox Graphics, Inc.: Unknown device 0525 Memory at d8000000 (32-bit, prefetchable)
from mga_vid kernel driver messages (use dmesg):
mga_mem_base = d8000000
Then let's find the memory size. This is very easy, just convert video RAM size to hexadecimal, or use this table:
You know base address and memory size, let's setup MTRR registers! For example, for the Matrox card above (base=0xd8000000) with 32MB ram (size=0x2000000) just execute:
echo "base=0xd8000000 size=0x2000000 type=write-combining" >| /proc/mtrr
Not all CPUs have MTRRs. For example older K6-2 (around 266MHz, stepping 0) CPUs don't have MTRRs, but stepping 12 does (execute cat /proc/cpuinfo to check it).
Under XFree86 4.0.2 or newer, you can use your card's hardware YUV routines using the XVideo extension. This is what the option '-vo xv' uses. Also, this driver supports adjusting brightness/contrast/hue/etc (unless you use the old, slow DirectShow DivX codec, which supports it everywhere), see the man page.
In order to make this work, be sure to check the following:
You have to use XFree86 4.0.2 or newer (former versions don't have XVideo)
Your card actually supports hardware acceleration (modern cards do)
X loads the XVideo extension, it's something like this:
(II) Loading extension XVideoin /var/log/XFree86.0.log
This loads only the XFree86's extension. In a good install, this is always loaded, and doesn't mean that the card's XVideo support is loaded!
Your card has Xv support under Linux. To check, try xvinfo, it is the part of the XFree86 distribution. It should display a long text, similar to this:
X-Video Extension version 2.2 screen #0 Adaptor #0: "Savage Streams Engine" number of ports: 1 port base: 43 operations supported: PutImage supported visuals: depth 16, visualID 0x22 depth 16, visualID 0x23 number of attributes: 5 (...) Number of image formats: 7 id: 0x32595559 (YUY2) guid: 59555932-0000-0010-8000-00aa00389b71 bits per pixel: 16 number of planes: 1 type: YUV (packed) id: 0x32315659 (YV12) guid: 59563132-0000-0010-8000-00aa00389b71 bits per pixel: 12 number of planes: 3 type: YUV (planar) (...etc...)It must support YUY2 packed, and YV12 planar pixel formats to be usable with MPlayer.
And finally, check if MPlayer was compiled with 'xv' support. Do a mplayer -vo help | grep xv . If 'xv' support was built a line similar to this should appear:
Older 3dfx drivers were known to have problems with XVideo acceleration, it didn't support either YUY2 or YV12, and so. Verify that you have XFree86 version 4.2.0 or greater, it works OK with YV12 and YUY2. Previous versions, including 4.1.0, crashes with YV12. If you experience strange effects using -vo xv, try SDL (it has XVideo, too) and see if it helps. Check the SDL section for details.
OR, try the NEW -vo tdfxfb driver! See the tdfxfb section.
S3 Savage3D's should work fine, but for Savage4, use XFree86 version 4.0.3 or greater (in case of image problems, try 16bpp). As for S3 Virge: there is xv support, but the card itself is very slow, so you better sell it.
It's currently unclear which Savage models lack YV12 support, and convert by driver (slow). If you suspect your card, get a newer driver, or ask politely on the MPlayer-users mailing list for an MMX/3DNow! enabled driver.
nVidia isn't always a very good choice under Linux (according to nVidia, this is not true)... XFree86's open-source driver supports most of these cards, but for some cases, you'll have to use the binary closed-source nVidia driver, available at nVidia's web site. You'll always need this driver if you want 3D acceleration, too.
Riva128 cards don't have XVideo support with XFree86's nVidia driver :( Complain to nVidia.
The GATOS driver (which you should use, unless you have Rage128 or Radeon) has VSYNC enabled by default. It means that decoding speed (!) is synced to the monitor's refresh rate. If playing seems to be slow, try disabling VSYNC somehow, or set refresh rate to a n*(fps of the movie) Hz.
Radeon VE - if you need X, use XFree86 4.2.0 or greater for this card. No TV out support. Of course with MPlayer you can happily get accelerated display, with or without TV output, and no libraries or X are needed. Read the VIDIX section.
These cards can be found in many laptops. You must use XFree86 4.3.0 or above, or else use Stefan Seyfried's Xv-capable drivers. Just choose the one that applies to your version of XFree86.
XFree86 4.3.0 includes Xv support, yet Bohdan Horst sent a small patch against the XFree86 sources that speeds up framebuffer operations (so XVideo) up to four times. The patch has been included in XFree86 CVS and should be in the next release after 4.3.0.
To allow playback of DVD sized content change your XF86Config like this:
Section "Device" [...] Driver "neomagic" Option "OverlayMem" "829440" [...] EndSection
If you want to use Xv with a Trident card, provided that it doesn't work with 4.1.0, install XFree 4.2.0. 4.2.0 adds support for fullscreen Xv support with the Cyberblade XP card.
Alternatively, MPlayer contains a VIDIX driver for the Cyberblade/i1 card.
If you want to use Xv with a Kyro based card (for example Hercules Prophet 4000XT), you should download the drivers from the PowerVR site
PREAMBLE. This document tries to explain in some words what DGA is in general and what the DGA video output driver for MPlayer can do (and what it can't).
WHAT IS DGA. DGA is short for Direct Graphics Access and is a means for a program to bypass the X server and directly modifying the framebuffer memory. Technically spoken this happens by mapping the framebuffer memory into the memory range of your process. This is allowed by the kernel only if you have superuser privileges. You can get these either by logging in as root or by setting the SUID bit on the MPlayer executable (not recommended).
There are two versions of DGA: DGA1 is used by XFree 3.x.x and DGA2 was introduced with XFree 4.0.1.
DGA1 provides only direct framebuffer access as described above. For switching the resolution of the video signal you have to rely on the XVidMode extension.
DGA2 incorporates the features of XVidMode extension and also allows switching the depth of the display. So you may, although basically running a 32 bit depth X server, switch to a depth of 15 bits and vice versa.
However DGA has some drawbacks. It seems it is somewhat dependent on the graphics chip you use and on the implementation of the X server's video driver that controls this chip. So it does not work on every system...
INSTALLING DGA SUPPORT FOR MPLAYER. First make sure X loads the DGA extension, see in /var/log/XFree86.0.log:
(II) Loading extension XFree86-DGASee, XFree86 4.0.x or greater is highly recommended! MPlayer's DGA driver is autodetected by ./configure, or you can force it with --enable-dga.
If the driver couldn't switch to a smaller resolution, experiment with options -vm (only with X 3.3.x), -fs, -bpp, -zoom to find a video mode that the movie fits in. There is no converter right now :(
Become root. DGA needs root access to be able to write directly video memory. If you want to run it as user, then install MPlayer SUID root:
chown root /usr/local/bin/mplayer chmod 750 /usr/local/bin/mplayer chmod +s /usr/local/bin/mplayerNow it works as a simple user, too.
This is a big security risk! Never do this on a server or on a computer that can be accessed by other people because they can gain root privileges through SUID root MPlayer.
Now use -vo dga option, and there you go! (hope so:) You should also try if the -vo sdl:dga option works for you! It's much faster!
RESOLUTION SWITCHING. The DGA driver allows for switching the resolution of the output signal. This avoids the need for doing (slow) software scaling and at the same time provides a fullscreen image. Ideally it would switch to the exact resolution (except for honoring aspect ratio) of the video data, but the X server only allows switching to resolutions predefined in /etc/X11/XF86Config (/etc/X11/XF86Config-4 for XFree 4.X.X respectively). Those are defined by so-called modelines and depend on the capabilities of your video hardware. The X server scans this config file on startup and disables the modelines not suitable for your hardware. You can find out which modes survive with the X11 log file. It can be found at: /var/log/XFree86.0.log.
These entries are known to work fine with a Riva128 chip, using the nv.o X server driver module.
Section "Modes" Identifier "Modes" Modeline "800x600" 40 800 840 968 1056 600 601 605 628 Modeline "712x600" 35.0 712 740 850 900 400 410 412 425 Modeline "640x480" 25.175 640 664 760 800 480 491 493 525 Modeline "400x300" 20 400 416 480 528 300 301 303 314 Doublescan Modeline "352x288" 25.10 352 368 416 432 288 296 290 310 Modeline "352x240" 15.750 352 368 416 432 240 244 246 262 Doublescan Modeline "320x240" 12.588 320 336 384 400 240 245 246 262 Doublescan EndSection
DGA & MPLAYER. DGA is used in two places with MPlayer: The SDL driver can be made to make use of it (-vo sdl:dga) and within the DGA driver (-vo dga). The above said is true for both; in the following sections I'll explain how the DGA driver for MPlayer works.
FEATURES. The DGA driver is invoked by specifying -vo dga at the command line. The default behavior is to switch to a resolution matching the original resolution of the video as close as possible. It deliberately ignores the -vm and -fs options (enabling of video mode switching and fullscreen) - it always tries to cover as much area of your screen as possible by switching the video mode, thus refraining from using additional cycles of your CPU to scale the image. If you don't like the mode it chooses you may force it to choose the mode matching closest the resolution you specify by -x and -y. By providing the -v option, the DGA driver will print, among a lot of other things, a list of all resolutions supported by your current XF86Config file. Having DGA2 you may also force it to use a certain depth by using the -bpp option. Valid depths are 15, 16, 24 and 32. It depends on your hardware whether these depths are natively supported or if a (possibly slow) conversion has to be done.
If you should be lucky enough to have enough offscreen memory left to put a whole image there, the DGA driver will use double buffering, which results in much smoother movie playback. It will tell you whether double buffering is enabled or not.
Double buffering means that the next frame of your video is being drawn in some offscreen memory while the current frame is being displayed. When the next frame is ready, the graphics chip is just told the location in memory of the new frame and simply fetches the data to be displayed from there. In the meantime the other buffer in memory will be filled again with new video data.
Double buffering may be switched on by using the option -double and may be disabled with -nodouble. Current default option is to disable double buffering. When using the DGA driver, onscreen display (OSD) only works with double buffering enabled. However, enabling double buffering may result in a big speed penalty (on my K6-II+ 525 it used an additional 20% of CPU time!) depending on the implementation of DGA for your hardware.
SPEED ISSUES. Generally spoken, DGA framebuffer access should be at least as fast as using the X11 driver with the additional benefit of getting a fullscreen image. The percentage speed values printed by MPlayer have to be interpreted with some care, as for example, with the X11 driver they do not include the time used by the X server needed for the actual drawing. Hook a terminal to a serial line of your box and start top to see what is really going on in your box.
Generally spoken, the speedup done by using DGA against 'normal' use of X11 highly depends on your graphics card and how well the X server module for it is optimized.
If you have a slow system, better use 15 or 16 bit depth since they require only half the memory bandwidth of a 32 bit display.
Using a depth of 24 bit is even a good idea if your card natively just supports 32 bit depth since it transfers 25% less data compared to the 32/32 mode.
I've seen some AVI files be played back on a Pentium MMX 266. AMD K6-2 CPUs might work at 400 MHZ and above.
KNOWN BUGS. Well, according to some developers of XFree, DGA is quite a beast. They tell you better not to use it. Its implementation is not always flawless with every chipset driver for XFree out there.
SDL (Simple Directmedia Layer) is basically a unified video/audio interface. Programs that use it know only about SDL, and not about what video or audio driver does SDL actually use. For example a Doom port using SDL can run on svgalib, aalib, X, fbdev, and others, you only have to specify the (for example) video driver to use with the SDL_VIDEODRIVER environment variable. Well, in theory.
With MPlayer, we used its X11 driver's software scaler ability for cards/drivers that doesn't support XVideo, until we made our own (faster, nicer) software scaler. Also we used its aalib output, but now we have ours which is more comfortable. Its DGA mode was better than ours, until recently. Get it now? :)
It also helps with some buggy drivers/cards if the video is jerky (not slow system problem), or audio is lagging.
SDL video output supports displaying subtitles under the movie, on the (if present) black bar.
There are several command line switches for SDL:
Table 2.1. SDL only keys
|c||cycles available fullscreen modes|
|n||changes back to normal mode|
INSTALLATION. You'll have to install svgalib and its development package in order for MPlayer build its SVGAlib driver (autodetected, but can be forced), and don't forget to edit /etc/vga/libvga.config to suit your card and monitor.
Be sure not to use the -fs switch, since it toggles the usage of the software scaler, and it's slow. If you really need it, use the -sws 4 option which will produce bad quality, but is somewhat faster.
EGA (4BPP) SUPPORT. SVGAlib incorporates EGAlib, and MPlayer has the possibility to display any movie in 16 colors, thus usable in the following sets:
The bpp (bits per pixel) value must be set to 4 by hand: -bpp 4
The movie probably must be scaled down to fit in EGA mode:
For that we need fast but bad quality scaling routine:
Maybe automatic aspect correction has to be shut off:
According to my experience the best image quality on EGA screens can be achieved by decreasing the brightness a bit: -vf eq=-20:0. I also needed to lower the audio samplerate on my box, because the sound was broken on 44kHz: -srate 22050.
You can turn on OSD and subtitles only with the expand filter, see the man page for exact parameters.
Whether to build the FBdev target is autodetected during ./configure. Read the framebuffer documentation in the kernel sources (Documentation/fb/*) for more information.
If your card doesn't support VBE 2.0 standard (older ISA/PCI cards, such as S3 Trio64), only VBE 1.2 (or older?): Well, VESAfb is still available, but you'll have to load SciTech Display Doctor (formerly UniVBE) before booting Linux. Use a DOS boot disk or whatever. And don't forget to register your UniVBE ;))
The FBdev output takes some additional parameters above the others:
If you want to change to a specific mode, then use
mplayer -vm -fbmode name_of_mode filename
-vm alone will choose the most suitable mode from /etc/fb.modes. Can be used together with -x and -y options too. The -flip option is supported only if the movie's pixel format matches the video mode's pixel format. Pay attention to the bpp value, fbdev driver tries to use the current, or if you specify the -bpp option, then that.
-zoom option isn't supported (use -vf scale). You can't use 8bpp (or less) modes.
You possibly want to turn the cursor off:
echo -e '\033[?25l'or
setterm -cursor offand the screen saver:
setterm -blank 0To turn the cursor back on:
echo -e '\033[?25h'or
setterm -cursor on
FBdev video mode changing does not work with the VESA framebuffer, and don't ask for it, since it's not an MPlayer limitation.
This section is about the Matrox G200/G400/G450/G550 BES (Back-End Scaler) support, the mga_vid kernel driver. It's actively developed by A'rpi, and it has hardware VSYNC support with triple buffering. It works on both framebuffer console and under X.
This is Linux only! On non-Linux (tested on FreeBSD) systems, you can use VIDIX instead!
To use it, you first have to compile mga_vid.o:
cd drivers make
Then create /dev/mga_vid device:
mknod /dev/mga_vid c 178 0and load the driver with
You should verify the memory size detection using the dmesg command. If it's bad, use the mga_ram_size option (rmmod mga_vid first), specify card's memory size in MB:
insmod mga_vid.o mga_ram_size=16
To make it load/unload automatically when needed, first insert the following line at the end of /etc/modules.conf:
alias char-major-178 mga_vidThen copy the mga_vid.o module to the appropriate place under /lib/modules/kernel version/somewhere.
Now you have to (re)compile MPlayer, ./configure will detect /dev/mga_vid and build the 'mga' driver. Using it from MPlayer goes by -vo mga if you have matroxfb console, or -vo xmga under XFree86 3.x.x or 4.x.x.
The mga_vid driver cooperates with Xv.
The /dev/mga_vid device file can be read for some info, for example by
cat /dev/mga_vidand can be written for brightness change:
echo "brightness=120" > /dev/mga_vid
This driver uses the kernel's tdfx framebuffer driver to play movies with YUV acceleration. You'll need a kernel with tdfxfb support, and recompile with
MPlayer supports displaying movies using OpenGL, but if your platform/driver supports xv as should be the case on a PC with Linux, use xv instead, OpenGL performance is considerably worse. If you have an X11 implementation without xv support, OpenGL is a viable alternative.
Unfortunately not all drivers support this feature. The Utah-GLX drivers (for XFree86 3.3.6) support it for all cards. See http://utah-glx.sf.net for details about how to install it.
XFree86(DRI) 4.0.3 or later supports OpenGL with Matrox and Radeon cards, 4.2.0 or later supports Rage128. See http://dri.sf.net for download and installation instructions.
A hint from one of our users: the GL video output can be used to get vsynced TV output. You'll have to set an environment variable (at least on nVidia):
AAlib is a library for displaying graphics in text mode, using powerful ASCII renderer. There are lots of programs already supporting it, like Doom, Quake, etc. MPlayer contains a very usable driver for it. If ./configure detects aalib installed, the aalib libvo driver will be built.
You can use some keys in the AA Window to change rendering options:
|5||switch fast rendering on/off|
|6||set dithering mode (none, error distribution, Floyd Steinberg)|
|8||toggles between aa and MPlayer control|
The following command line options can be used:
change OSD color
change subtitle color
where V can be: 0 (normal), 1 (dark), 2 (bold), 3 (bold font), 4 (reverse), 5 (special).
AAlib itself provides a large sum of options. Here are some important:
The rendering is very CPU intensive, especially when using AA-on-X (using aalib on X), and it's least CPU intensive on standard, non-framebuffer console. Use SVGATextMode to set up a big textmode, then enjoy! (secondary head Hercules cards rock :)) (but IMHO you can use -vf 1bpp option to get graphics on hgafb:)
Use the -framedrop option if your computer isn't fast enough to render all frames!
Playing on terminal you'll get better speed and quality using the Linux driver, not curses (-aadriver linux). But therefore you need write access on /dev/vcsa<terminal>! That isn't autodetected by aalib, but vo_aa tries to find the best mode. See http://aa-project.sf.net/tune for further tuning issues.
The libcaca library is a graphics library that outputs text instead of pixels, so that it can work on older video cards or text terminals. It is not unlike the famous AAlib library. libcaca needs a terminal to work, thus it should work on all Unix systems (including Mac OS X) using either the slang library or the ncurses library, on DOS using the conio.h library, and on Windows systems using either slang or ncurses (through Cygwin emulation) or conio.h. If ./configure detects libcaca, the caca libvo driver will be built.
The differences with AAlib are the following:
But libcaca also has the following limitations:
You can use some keys in the caca window to change rendering options:
|d||Toggle libcaca dithering methods.|
|a||Toggle libcaca antialiasing.|
|b||Toggle libcaca background.|
libcaca will also look for certain environment variables:
Use the -framedrop option if your computer is not fast enough to render all frames.
This driver was designed and introduced as a generic driver for any video card which has VESA VBE 2.0 compatible BIOS. Another advantage of this driver is that it tries to force TV output on. VESA BIOS EXTENSION (VBE) Version 3.0 Date: September 16, 1998 (Page 70) says:
Dual-Controller Designs. VBE 3.0 supports the dual-controller design by assuming that since both controllers are typically provided by the same OEM, under control of a single BIOS ROM on the same graphics card, it is possible to hide the fact that two controllers are indeed present from the application. This has the limitation of preventing simultaneous use of the independent controllers, but allows applications released before VBE 3.0 to operate normally. The VBE Function 00h (Return Controller Information) returns the combined information of both controllers, including the combined list of available modes. When the application selects a mode, the appropriate controller is activated. Each of the remaining VBE functions then operates on the active controller.
So you have chances to get working TV-out by using this driver. (I guess that TV-out frequently is standalone head or standalone output at least.)
Don't use this driver with GCC 2.96! It won't work!
COMMAND LINE OPTIONS AVAILABLE FOR VESA
KNOWN PROBLEMS AND WORKAROUNDS
Avoid if possible. Outputs to X11 (uses shared memory extension), with no hardware acceleration at all. Supports (MMX/3DNow/SSE accelerated, but still slow) software scaling, use the options -fs -zoom. Most cards have hardware scaling support, use the -vo xv output for them, or -vo xmga for Matrox cards.
The problem is that most cards' driver doesn't support hardware acceleration on the second head/TV. In those cases, you see green/blue colored window instead of the movie. This is where this driver comes in handy, but you need powerful CPU to use software scaling. Don't use the SDL driver's software output+scaler, it has worse image quality!
Software scaling is very slow, you better try changing video modes instead. It's very simple. See the DGA section's modelines, and insert them into your XF86Config.
If you can't find the modes you inserted, browse XFree86's output. Some drivers can't use low pixelclocks that are needed for low resolution video modes.
PREAMBLE. VIDIX is the abbreviation for VIDeo Interface for *niX. VIDIX was designed and introduced as an interface for fast user-space drivers providing such video performance as mga_vid does for Matrox cards. It's also very portable.
This interface was designed as an attempt to fit existing video acceleration interfaces (known as mga_vid, rage128_vid, radeon_vid, pm3_vid) into a fixed scheme. It provides a high level interface to chips which are known as BES (BackEnd scalers) or OV (Video Overlays). It doesn't provide low level interface to things which are known as graphics servers. (I don't want to compete with X11 team in graphics mode switching). I.e. main goal of this interface is to maximize the speed of video playback.
Indeed it doesn't matter which video output driver is used with VIDIX.
USAGE METHODS. When VIDIX is used as subdevice (-vo vesa:vidix) then video mode configuration is performed by video output device (vo_server in short). Therefore you can pass into command line of MPlayer the same keys as for vo_server. In addition it understands -double key as globally visible parameter. (I recommend using this key with VIDIX at least for ATI's card). As for -vo xvidix, currently it recognizes the following options: -fs -zoom -x -y -double.
Also you can specify VIDIX's driver directly as third subargument in command line:
mplayer -vo xvidix:mga_vid.so -fs -zoom -double file.avior
mplayer -vo vesa:vidix:radeon_vid.so -fs -zoom -double -bpp 32 file.aviBut it's dangerous, and you shouldn't do that. In this case given driver will be forced and result is unpredictable (it may freeze your computer). You should do that ONLY if you are absolutely sure it will work, and MPlayer doesn't do it automatically. Please tell about it to the developers. The right way is to use VIDIX without arguments to enable driver autodetection.
VIDIX is new technology and it's extremely possible that on your system it won't work. In this case only solution for you it's port it (mainly libdha). But there is hope that it will work on those systems where X11 does.
Since VIDIX requires direct hardware access you can either run it as root or set the SUID bit on the MPlayer binary (Warning: This is a security risk!). Alternatively, you can use a special kernel module, like this:
Compile the module in the svgalib_helper directory (it can be found inside the svgalib-1.9.17/kernel/ directory if you've downloaded the source from the svgalib site) and insmod it.
To create the necessary devices in the /dev directory, do a
make devicein the svgalib_helper dir, as root.
Move the svgalib_helper directory to mplayer/main/libdha/svgalib_helper.
Required if you download the source from the svgalib site: Remove the comment before the CFLAGS line containing "svgalib_helper" string from the libdha/Makefile.
Recompile and install libdha.
Currently most ATI cards are supported natively, from Mach64 to the newest Radeons.
There are two compiled binaries: radeon_vid for Radeon and rage128_vid for Rage 128 cards. You may force one or let the VIDIX system autoprobe all available drivers.
Matrox G200, G400, G450 and G550 have been reported to work.
The driver supports video equalizers and should be nearly as fast as the Matrox framebuffer
There is a driver available for the Trident Cyberblade/i1 chipset, which can be found on VIA Epia motherboards.
The driver was written and is maintained by Alastair M. Robinson
Although there is a driver for the 3DLabs GLINT R3 and Permedia3 chips, no one has tested it, so reports are welcome.
There's a relatively new nVidia driver out there, it's known to work on Riva 128, TNT and GeForce2 chipsets, also others have been reported working.
It's recommended to use the binary nVidia drivers for X before using this VIDIX driver, because some of the registers which need to be initialized haven't been discovered yet, so it will probably fail with the Open Source XFree86 nv.o driver.
Currently only codecs capable of UYVY colorspace output can work in conjunction with this driver. Unfortunately, this excludes every single decoder from the libavcodec family. This leaves us with the following usable popular codecs: cvid, divxds, xvid, divx4, wmv7, wmv8 and some others. Please note that this is only a temporal inconvenience. The usage syntax is as follows:
mplayer -vf format=uyvy -vc divxds divx3file.avi
An unique feature of the nvidia_vid driver is its ability to display video on plain, pure, text-only console - with no framebuffer or X magic whatsoever. For this purpose, we'll have to use the cvidix video output, as the following example shows:
mplayer -vf format=uyvy -vc divxds -vo cvidix example.avi
"DirectFB is a graphics library which was designed with embedded systems in mind. It offers maximum hardware accelerated performance at a minimum of resource usage and overhead." - quoted from http://www.directfb.org
I'll exclude DirectFB features from this section.
Though MPlayer is not supported as a "video provider" in DirectFB, this output driver will enable video playback through DirectFB. It will - of course - be accelerated, on my Matrox G400 DirectFB's speed was the same as XVideo.
Always try to use the newest version of DirectFB. You can use DirectFB options on the command line, using the -dfbopts option. Layer selection can be done by the subdevice method, e.g.: -vo directfb:2 (layer -1 is default: autodetect)
Please read the main DirectFB section for general information.
This video output driver will enable CRTC2 (on the second head) on Matrox G400/G450/G550 cards, displaying video independent of the first head.
MPlayer supports cards with the Siemens DVB chipset from vendors like Siemens, Technotrend, Galaxis or Hauppauge. The latest DVB drivers are available from the Linux TV site. If you want to do software transcoding you should have at least a 1GHz CPU.
Configure should detect your DVB card. If it did not, force detection with
If you have ost headers at a non-standard path, set the path with
./configure --with-extraincdir=DVB source directory/ost/include
Then compile and install as usual.
USAGE. Hardware decoding (playing standard MPEG-1/2 files) can be done with this command:
mplayer -ao mpegpes -vo mpegpes file.mpg|vob
Software decoding or transcoding different formats to MPEG-1 can be achieved using a command like this:
mplayer -ao mpegpes -vo mpegpes yourfile.ext mplayer -ao mpegpes -vo mpegpes -vf expand yourfile.ext
Note that DVB cards only support heights 288 and 576 for PAL or 240 and 480 for NTSC. You must rescale for other heights by adding scale=width:height with the width and height you want to the -vf option. DVB cards accept various widths, like 720, 704, 640, 512, 480, 352 etc and do hardware scaling in horizontal direction, so you do not need to scale horizontally in most cases. For a 512x384 (aspect 4:3) MPEG-4 (DivX) try:
mplayer -ao mpegpes -vo mpegpes -vf scale=512:576
If you have a widescreen movie and you do not want to scale it to full height, you can use the expand=w:h filter to add black bands. To view a 640x384 MPEG-4 (DivX), try:
mplayer -ao mpegpes -vo mpegpes -vf expand=640:576 file.avi
If your CPU is too slow for a full size 720x576 MPEG-4 (DivX), try downscaling:
mplayer -ao mpegpes -vo mpegpes -vf scale=352:576 file.avi
If speed does not improve, try vertical downscaling, too:
mplayer -ao mpegpes -vo mpegpes -vf scale=352:288 file.avi
For OSD and subtitles use the OSD feature of the expand filter. So, instead of expand=w:h or expand=w:h:x:y, use expand=w:h:x:y:1 (the 5th parameter :1 at the end will enable OSD rendering). You may want to move the image up a bit to get a bigger black zone for subtitles. You may also want to move subtitles up, if they are outside your TV screen, use the -subpos <0-100> option to adjust this (-subpos 80 is a good choice).
In order to play non-25fps movies on a PAL TV or with a slow CPU, add the -framedrop option.
To keep the aspect ratio of MPEG-4 (DivX) files and get the optimal scaling parameters (hardware horizontal scaling and software vertical scaling while keeping the right aspect ratio), use the new dvbscale filter:
for a 4:3 TV: -vf dvbscale,scale=-1:0,expand=-1:576:-1:-1:1 for a 16:9 TV: -vf dvbscale=1024,scale=-1:0,expand=-1:576:-1:-1:1
Digital TV (DVB input module). You can use your DVB card for watching Digital TV.
You should have the programs scan and szap/tzap/czap/azap installed; they are all included in the drivers package.
Verify that your drivers are working properly with a program such as dvbstream (that is the base of the DVB input module).
Now you should compile a ~/.mplayer/channels.conf file, with the syntax accepted by szap/tzap/czap/azap, or have scan compile it for you.
If you have more than one card type (e.g. Satellitar, Terrestrial, Cable and ATSC) you can save your channels files as ~/.mplayer/channels.conf.sat, ~/.mplayer/channels.conf.ter, ~/.mplayer/channels.conf.cbl, and ~/.mplayer/channels.conf.atsc, respectively, so as to implicitly hint MPlayer to use these files rather than ~/.mplayer/channels.conf, and you only need to specify which card to use.
Make sure that you have have only Free to Air channels in your channels.conf file, or MPlayer will try to skip to the next visible one, but it may take long if there are many consecutive encrypted channels.
In your audio and video fields you can use an extended syntax: ...:pid[+pid]:... (for a maximum of 6 pids each); in this case MPlayer will include in the stream all the indicated pids, plus pid 0 (that contains the PAT). You are encouraged to include in each row the PMT pid for the corresponding channel (if you know it). Other possible uses are: televideo pid, second audio track, etc.
To show the first of the channels present in your list, run
If you want to watch a specific channel, such as R1, run
If you have more than one card you also need to specify the number of the card where the channel is visible (e.g. 2) with the syntax:
To change channels press the h (next) and k (previous) keys, or use the OSD menu (requires a working OSD subsystem).
If your ~/.mplayer/menu.conf contains a <dvbsel> entry, such as the one in the example file etc/dvb-menu.conf (that you can use to overwrite ~/.mplayer/menu.conf), the main menu will show a sub-menu entry that will permit you to choose one of the channels present in your channels.conf, possibly preceded by a menu with the list of cards available if more than one is usable by MPlayer.
If you want to save a program to disk you can use
mplayer -dumpfile r1.ts -dumpstream dvb://R1
If you want to record it in a different format (re-encoding it) instead you can run a command such as
mencoder -o r1.avi -ovc xvid -xvidencopts bitrate=800 -oac mp3lame -lameopts cbr:br=128 -pp=ci dvb://R1
Read the man page for a list of options that you can pass to the DVB input module.
FUTURE. If you have questions or want to hear feature announcements and take part in discussions on this subject, join our MPlayer-DVB mailing list. Please remember that the list language is English.
In the future you may expect the ability to display OSD and subtitles using the native OSD feature of DVB cards, as well as more fluent playback of non-25fps movies and realtime transcoding between MPEG-2 and MPEG-4 (partial decompression).
MPlayer supports hardware accelerated playback with the Creative DXR2 card.
First of all you will need properly installed DXR2 drivers. You can find the drivers and installation instructions at the DXR2 Resource Center site.
enable TV output
enable Overlay output in X11
This option is used to control the DXR2 driver.
The overlay chipset used on the DXR2 is of pretty bad quality but the default settings should work for everybody. The OSD may be usable with the overlay (not on TV) by drawing it in the colorkey. With the default colorkey settings you may get variable results, usually you will see the colorkey around the characters or some other funny effect. But if you properly adjust the colorkey settings you should be able to get acceptable results.
Please see the man page for available options.
MPlayer supports hardware accelerated playback with the Creative DXR3 and Sigma Designs Hollywood Plus cards. These cards both use the em8300 MPEG decoder chip from Sigma Designs.
First of all you will need properly installed DXR3/H+ drivers, version 0.12.0 or later. You can find the drivers and installation instructions at the DXR3 & Hollywood Plus for Linux site. configure should detect your card automatically, compilation should go without problems.
overlay activates the overlay instead of TVOut. It requires that you have a properly configured overlay setup to work right. The easiest way to configure the overlay is to first run autocal. Then run mplayer with dxr3 output and without overlay turned on, run dxr3view. In dxr3view you can tweak the overlay settings and see the effects in realtime, perhaps this feature will be supported by the MPlayer GUI in the future. When overlay is properly set up you will no longer need to use dxr3view. prebuf turns on prebuffering. Prebuffering is a feature of the em8300 chip that enables it to hold more than one frame of video at a time. This means that when you are running with prebuffering MPlayer will try to keep the video buffer filled with data at all times. If you are on a slow machine MPlayer will probably use close to, or precisely 100% of CPU. This is especially common if you play pure MPEG streams (like DVDs, SVCDs a.s.o.) since MPlayer will not have to reencode it to MPEG it will fill the buffer very fast. With prebuffering video playback is much less sensitive to other programs hogging the CPU, it will not drop frames unless applications hog the CPU for a long time. When running without prebuffering the em8300 is much more sensitive to CPU load, so it is highly suggested that you turn on MPlayer's -framedrop option to avoid further loss of sync. sync will turn on the new sync-engine. This is currently an experimental feature. With the sync feature turned on the em8300's internal clock will be monitored at all times, if it starts to deviate from MPlayer's clock it will be reset causing the em8300 to drop any frames that are lagging behind. norm=x will set the TV norm of the DXR3 card without the need for external tools like em8300setup. Valid norms are 5 = NTSC, 4 = PAL-60, 3 = PAL. Special norms are 2 (auto-adjust using PAL/PAL-60) and 1 (auto-adjust using PAL/NTSC) because they decide which norm to use by looking at the frame rate of the movie. norm = 0 (default) does not change the current norm. device = device number to use if you have more than one em8300 card. Any of these options may be left out. :prebuf:sync seems to work great when playing MPEG-4 (DivX) movies. People have reported problems using the prebuf option when playing MPEG-1/2 files. You might want to try running without any options first, if you have sync problems, or DVD subtitle problems, give :sync a try.
For audio output, where X is the device number (0 if one card).
The em8300 cannot play back samplerates lower than 44100Hz. If the sample rate is below 44100Hz select either 44100Hz or 48000Hz depending on which one matches closest. I.e. if the movie uses 22050Hz use 44100Hz as 44100 / 2 = 22050, if it is 24000Hz use 48000Hz as 48000 / 2 = 24000 and so on. This does not work with digital audio output (-ac hwac3).
To watch non-MPEG content on the em8300 (i.e. MPEG-4 (DivX) or RealVideo) you have to specify an MPEG-1 video filter such as libavcodec (lavc) or libfame (fame). At the moment lavc is both faster and gives better image quality, it is suggested that you use that unless you have problems with it. See the man page for further info about -vf lavc/fame. Using lavc is highly recommended. Currently there is no way of setting the fps of the em8300 which means that it is fixed to 30000/1001 fps. Because of this it is highly recommended that you use -vf lavc=quality:25 especially if you are using prebuffering. Then why 25 and not 30000/1001? Well, the thing is that when you use 30000/1001 the picture becomes a bit jumpy. The reason for this is unknown to us. If you set it to somewhere between 25 and 27 the picture becomes stable. For now all we can do is accept this for a fact.
Although the DXR3 driver can put some OSD onto the MPEG-1/2/4 video, it has much lower quality than MPlayer's traditional OSD, and has several refresh problems as well. The command line above will firstly convert the input video to MPEG-4 (this is mandatory, sorry), then apply an expand filter which won't expand anything (-1: default), but apply the normal OSD onto the picture (that's what the "1" at the end does).
The em8300 supports playing back AC3 audio (surround sound) through the digital audio output of the card. See the -ao oss option above, it must be used to specify the DXR3's output instead of a sound card.
This is a display-driver (-vo zr) for a number of MJPEG capture/playback cards (tested for DC10+ and Buz, and it should work for the LML33, the DC10). The driver works by encoding the frame to JPEG and then sending it to the card. For the JPEG encoding libavcodec is used, and required. With the special cinerama mode, you can watch movies in true wide screen provided that you have two beamers and two MJPEG cards. Depending on resolution and quality settings, this driver may require a lot of CPU power, remember to specify -framedrop if your machine is too slow. Note: My AMD K6-2 350MHz is (with -framedrop) quite adequate for watching VCD sized material and downscaled movies.
This driver talks to the kernel driver available at http://mjpeg.sf.net, so you must get it working first. The presence of an MJPEG card is autodetected by the configure script, if autodetection fails, force detection with
The output can be controlled by several options, a long description of the options can be found in the man page, a short list of options can be viewed by running
Things like scaling and the OSD (on screen display) are not handled by this driver but can be done using the video filters. For example, suppose that you have a movie with a resolution of 512x272 and you want to view it fullscreen on your DC10+. There are three main possibilities, you may scale the movie to a width of 768, 384 or 192. For performance and quality reasons, I would choose to scale the movie to 384x204 using the fast bilinear software scaler. The command line is
mplayer -vo zr -sws 0 -vf scale=384:204 movie.avi
Cropping can be done by the crop filter and by this driver itself. Suppose that a movie is too wide for display on your Buz and that you want to use -zrcrop to make the movie less wide, then you would issue the following command
mplayer -vo zr -zrcrop 720x320+80+0 benhur.avi
if you want to use the crop filter, you would do
mplayer -vo zr -vf crop=720:320:80:0 benhur.avi
Extra occurrences of -zrcrop invoke cinerama mode, i.e. you can distribute the movie over several TV's or beamers to create a larger screen. Suppose you have two beamers. The left one is connected to your Buz at /dev/video1 and the right one is connected to your DC10+ at /dev/video0. The movie has a resolution of 704x288. Suppose also that you want the right beamer in black and white and that the left beamer should have JPEG frames at quality 10, then you would issue the following command
mplayer -vo zr -zrdev /dev/video0 -zrcrop 352x288+352+0 -zrxdoff 0 -zrbw \ -zrcrop 352x288+0+0 -zrdev /dev/video1 -zrquality 10 \ movie.avi
You see that the options appearing before the second -zrcrop only apply to the DC10+ and that the options after the second -zrcrop apply to the Buz. The maximum number of MJPEG cards participating in cinerama is four, so you can build a 2x2 vidiwall.
Finally an important remark: Do not start or stop XawTV on the playback device during playback, it will crash your computer. It is, however, fine to FIRST start XawTV, THEN start MPlayer, wait for MPlayer to finish and THEN stop XawTV.
This driver is capable of playback using the Blinkenlights UDP protocol. If you don't know what Blinkenlights or its successor Arcade are, find it out. Although this is most probably the least used video output driver, without a doubt it is the coolest MPlayer has to offer. Just watch some of the Blinkenlights documentation videos. On the Arcade video you can see the Blinkenlights output driver in action at 00:07:50.
Under Linux you have two methods to get G400 TV out working:
for Matrox G450/G550 TV-out instructions, please see the next section!
Using the driver and the HAL module, available from the Matrox site. This will give you X on the TV.
This method doesn't give you accelerated playback as under Windows! The second head has only YUV framebuffer, the BES (Back End Scaler, the YUV scaler on G200/G400/G450/G550 cards) doesn't work on it! The windows driver somehow workarounds this, probably by using the 3D engine to zoom, and the YUV framebuffer to display the zoomed image. If you really want to use X, use the -vo x11 -fs -zoom options, but it will be SLOW, and has Macrovision copy protection enabled (you can "workaround" Macrovision using this perl script).
Using the matroxfb modules in the 2.4 kernels. 2.2 kernels don't have the TVout feature in them, thus unusable for this. You have to enable ALL matroxfb-specific feature during compilation (except MultiHead), and compile them into modules! You'll also need I2C enabled.
Enter TVout and type ./compile.sh. Install TVout/matroxset/matroxset somewhere into your PATH.
If you don't have fbset installed, put TVout/fbset/fbset somewhere into your PATH.
If you don't have con2fb installed, put TVout/con2fb/con2fb somewhere into your PATH.
Then enter into the TVout/ directory in the MPlayer source, and execute ./modules as root. Your text-mode console will enter into framebuffer mode (no way back!).
Next, EDIT and run the ./matroxtv script. This will present you to a very simple menu. Press 2 and Enter. Now you should have the same picture on your monitor, and TV. If the TV (PAL by default) picture has some weird stripes on it, the script wasn't able to set the resolution correctly (to 640x512 by default). Try other resolutions from the menu and/or experiment with fbset.
Yoh. Next task is to make the cursor on tty1 (or whatever) to disappear, and turn off screen blanking. Execute the following commands:
echo -e '\033[?25l' setterm -blank 0or
setterm -cursor off setterm -blank 0You possibly want to put the above into a script, and also clear the screen. To turn the cursor back:
echo -e '\033[?25h'or
setterm -cursor on
Yeah kewl. Start movie playing with
mplayer -vo mga -fs -screenw 640 -screenh 512 filename(If you use X, now change to matroxfb with for example Ctrl+Alt+F1.) Change 640 and 512 if you set the resolution to other...
Enjoy the ultra-fast ultra-featured Matrox TV output (better than Xv)!
Building a Matrox TV-out cable. No one takes any responsibility, nor guarantee for any damage caused by this documentation.
Cable for G400. The CRTC2 connector's fourth pin is the composite video signal. The ground are the sixth, seventh and eighth pins. (info contributed from Balázs Rácz)
Cable for G450. The CRTC2 connector's first pin is the composite video signal. The ground are the fifth, sixth, seventh, and fifteenth (5, 6, 7, 15) pins. (info contributed from Balázs Kerekes)
TV output support for these cards has only been recently introduced, and is not yet in the mainstream kernel. Currently the mga_vid module can't be used AFAIK, because the G450/G550 driver works only in one configuration: the first CRTC chip (with much more features) on the first display (on monitor), and the second CRTC (no BES - for explanation on BES, please see the G400 section above) on TV. So you can only use MPlayer's fbdev output driver at the present.
The first CRTC can't be routed to the second head currently. The author of the kernel matroxfb driver - Petr Vandrovec - will maybe make support for this, by displaying the first CRTC's output onto both of the heads at once, as currently recommended for G400, see the section above.
The necessary kernel patch and the detailed HOWTO is downloadable from http://www.bglug.ca/matrox_tvout/
PREAMBLE. Currently ATI doesn't want to support any of its TV-out chips under Linux, because of their licensed Macrovision technology.
ATI CARDS TV-OUT STATUS ON LINUX
On other cards, just use the VESA driver, without VIDIX. Powerful CPU is needed, though.
Only thing you need to do - Have the TV connector plugged in before booting your PC since video BIOS initializes itself only once during POST procedure.
Check this URL.
First, you MUST download the closed-source drivers from http://nvidia.com. I will not describe the installation and configuration process because it does not cover the scope of this documentation.
After XFree86, XVideo, and 3D acceleration is properly working, edit your card's Device section in the XF86Config file, according to the following example (adapt for your card/TV):
Section "Device" Identifier "GeForce" VendorName "ASUS" BoardName "nVidia GeForce2/MX 400" Driver "nvidia" #Option "NvAGP" "1" Option "NoLogo" Option "CursorShadow" "on" Option "TwinView" Option "TwinViewOrientation" "Clone" Option "MetaModes" "1024x768,640x480" Option "ConnectedMonitor" "CRT, TV" Option "TVStandard" "PAL-B" Option "TVOutFormat" "Composite" EndSection
Of course the important thing is the TwinView part.
The NeoMagic chip is found in a variety of laptops, some of them are equipped with a simple analog TV encoder, some have a more advanced one.
Analog encoder chip: Tested on a Toshiba Tecra 8000. Its TV output chip is miserable crap. Avoid if possible.
You must use -vo vesa. The tested chip was capable of 1.333333 aspect ratio only, so be sure to use the -x, -y options and/or the -vf scale,crop,expand filters if the box doesn't let you enable TV output. Maximum resolution was 720*576 at 16bpp.
Known issues: VESA-only, 1.33333 limitation, image isn't always centered, movie becomes 4bpp in every 10 minutes, and stays that way. Frequent hard freezes, LCD display problems.
Chrontel 70xx encoder chip: Found in IBM Thinkpad 390E and possibly other Thinkpads or notebooks.
You must use -vo vesa:neotv_pal for PAL or -vo vesa:neotv_ntsc for NTSC. It will provide TV output function in the following 16 bpp and 8 bpp modes:
Mode 512x384 is not supported in BIOS. You must scale the image to a different resolution to activate TV out. If you can see an image on the screen in 640x480 or in 800x600 but not in 320x240 or other smaller resolution you need to replace two tables in vbelib.c. See the vbeSetTV function for details. Please contact the author in this case.
Known issues: VESA-only, no other controls such as brightness, contrast, blacklevel, flickfilter are implemented.