#acl FriedemannBunjes:read,write,delete,revert YuminZhou:read,write,delete,revert All:read,write #format wiki #language en #pragma section-numbers 2 = HowTo setup a new nrec development system = <> == Installing the operating system == 1. Make sure, that you have got linux compatible hardware. 2. Get a current [[http://cdimage.debian.org/debian-cd/7.2.0/i386/iso-cd/debian-7.2.0-i386-netinst.iso]] from debian.org and burn it on a CD. 3. Boot from this CD and install debian (desktop system). * If the installer is not able to detect your network hardware, insert an old standard PCI network card and use this one. * Choosing one partition for all data is fine. If you feel expertic, you can create different partitions. * Type in the administrator password and login data for your first default user (e.g. devel). * Use a network mirror from your country (e.g. ftp://ftp.de.debian.org/). * Choose the "Desktop environment" and "Standard system" software installation profiles. 4. Install sux, kde and openssh, if you want to access the machine from remote: {{{ aptitude -y install sux kde openssh-server }}} == Building a Linux Kernel with RTAI realtime extensions == 1. Get latest stable linux kernel source from http://www.kernel.org/pub/linux/kernel/ (e.g. http://www.kernel.org/pub/linux/kernel/v2.6/linux-2.6.38.8.tar.gz) {{{ cd /usr/local/src && wget http://www.kernel.org/pub/linux/kernel/v2.6/linux-2.6.38.8.tar.gz }}} 2. get rtai from https://www.rtai.org/RTAI/ (e.g.: https://www.rtai.org/RTAI/rtai-3.9.tar.bz2) {{{ wget --no-check-certificate https://www.rtai.org/RTAI/rtai-3.9.tar.bz2 }}} 3. Unpack kernel-sources and rtai-sources to /usr/local/src (after downloading or moving the packages to /tmp): {{{ cd /usr/local/src && tar xzvf linux-2.6.38.8.tar.gz && tar xjvf rtai-3.9.tar.bz2 }}} 4. Change into the build dir {{{ cd linux-2.6.38.8 }}} 5. Download the config file of your running kernel config-2.6.38.8 (http://nrec.neurologie.uni-tuebingen.de/nrec/SetupHowto?action=AttachFile) and copy it into the build dir (for a reasonable default config) {{{ cp /home/$useraccount$/Downloads/config-2.6.38.8 .config }}} 6. Get packages for kernel-compilation: {{{ aptitude -y install kernel-package libncurses5-dev }}} 7. Apply rtai patch suitable for your kernel version: {{{ patch -p1 --dry-run < ../rtai-3.9/base/arch/x86/patches/hal-linux-2.6.38.8-x86-2.11-02.patch patch -p1 < ../rtai-3.9/base/arch/x86/patches/hal-linux-2.6.38.8-x86-2.11-02.patch }}} 8. Configure and build kernel: {{{ make-kpkg --initrd --append-to-version rtai --config menuconfig kernel-image }}} When the kernel menuconfig menu pops up, make sure * Loadable module support ---> Module versioning support is '''disabled''' * Bus options (PCI etc.) ---> * PCI support ---> PCI Express support is enabled * Processor type and features ---> * Processor family: Set to right processor type for your system. You might want to find it out by {{{ cat /proc/cpuinfo }}} * General setup ---> IRQ subsystem ---> Support sparse irq numbering is enabled * Symmetric multi-processing support is enabled * Multi-core scheduler support is enabled * Preemption Model ---> Voluntary Kernel Preemtion (Desktop) is enabled * Virtualization is '''disabled''' Important for rtai compatibility (see http://wiki.linuxcnc.org/emcinfo.pl?Ubuntu10.04Notes): * Processor type and features ---> HPET Timer Support ---> disabled * Processor type and features ---> Interrupt pipeline ---> enabled [*] * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> enabled [*] * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Deprecated /proc/acpi files ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Deprecated power /proc/acpi directories ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Future power /sys interface ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Deprecated /proc/acpi/event support ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> AC Adapter ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Battery ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Button ---> enabled[*] * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Video ---> module [M] * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Fan ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Dock ---> enabled [*] * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Processor ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Disable ACPI for systems before Jan 1st this year ---> 0 * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Debug Statements ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> PCI slot detection driver ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Container and Module Devices ---> disabled * Power management and ACPI options ---> ACPI (Advanced Configuration and Power Interface) Support ---> Smart Battery System ---> disabled * Power management and ACPI options ---> APM (Advanced Power Management) BIOS support ---> disabled * Power management and ACPI options ---> CPU Frequency scaling ---> disabled * If you are using an older RTAI patch you may get the following error: include/linux/ipipe.h:76:2: error: #error "CONFIG_NR_CPUS is too large, please lower it." To fix this disable sparse irq numbering (CONFIG_SPARSE_IRQ=n): Processor type and features ---> Support sparse irq numbering ---> disabled * If you have a multi cores CPU or SMP system, don't choose a processor family which has no TSC (time stamp counter). This means that for example you can not choose 586/K5/5x86/6x86/6x86MX as Processor family if you have a dual cores CPU. In conclusion, choose the most suitable processor family for your machine. * NOTE: No need to disable High Memory Support for RTAI 3.7.1 and newer * NOTE: No need to disable Symmetric multi-processing support for the uniproccesor machine for RTAI 3.7.1 and newer. But if you don't have a multi cores CPU or SMP system, you can disable it to improve the performance * NOTE: There was supposedly no need to disable Module Versioning Support for RTAI 3.7.1, but it seems to be needed for the latest RTAI (3.8.1 or magma). I don't know if this is an RTAI problem or emc2, since I could run the RTAI latency test but not the emc2 stuff. * NOTE: No need to turn off debugging if building packages with the ubuntu debian/rules system. Otherwise remember to turn off debugging info to vastly reduce kernel size! Then "Exit", Answer question "Save kernel config?" with "Yes" and wait for the kernel to compile (Take a break). 8. If you get a compile error saying {{{"error: conflicting types for 'syscall_trace_enter'"}}} you are probably using the latest gcc-4.7. Try to switch back to an older compiler version, e.g. gcc-4.4. After {{{aptitude install gcc-4.4}}} you have to link /usr/bin/gcc-4.4 to /usr/bin/gcc: {{{ln -s /usr/bin/gcc-4.4 /usr/bin/gcc}}}. 9. Leave kernel source dir and install the built kernel {{{ cd /usr/local/src && dpkg -i linux-image-3.8.13rtai_3.8.13rtai-10.00.Custom_amd64.deb }}} 10. If you want, check and update "GRUB_DEFAULT" value for grub boot manager entry: {{{ less /boot/grub/grub.cfg nano /etc/default/grub update-grub }}} 11. Reboot: {{{ reboot }}} 12. After booting the new Kernel, you might have to rebuild the graphic card driver module: {{{ sh NVIDIA-Linux-x86-173.14.12-pkg1.run }}} and verify the display settings: {{{ nvidia-settings }}} 13. It might also be necessary to reinstall your network card driver. == Installing the graphic card driver == Here are the instructions for nVidia cards. For ATI cards the process is similar. Please check for instructions on the web. 1. Check what graphic card you have. If {{{lspci}}} does not help you, you will have to open the case and have a look. 2. For nvidia cards you might want to get your driver here: http://www.nvidia.de/Download/index.aspx 3. Save it to e.g. /usr/local/src. 7. Install the packages necessary for the graphics kernel module build: {{{ aptitude install binutils gcc make linux-headers-$(uname -r) }}} 4. Now you have to shut down X11 by switching to a console (Alt-Ctrl-F1), logging in as root and executing {{{ /etc/init.d/gdm3 stop }}} 5. Go to the directory, where you stored the installer into: {{{ cd /usr/local/src sh NVIDIA... }}} 6. When an error message about the Nouveau kernel driver appears, let the installer create a file in modprobe.d to disable it and reboot, switch to the shell, stop gdm3 and restart the installer 12. Ignore messages about the gcc version (e.g. let the installer use the installed gcc 4.4. instead of 4.3) and let the installer do all modifications it wants to. 13. restart gdm3: {{{ /etc/init.d/gdm3 start }}} 15. Adjust your display settings: {{{ nvidia-settings }}} Set the appropriate resolutions for your screens and set up a separate screen for the second monitor (if you have one). In the OpenGL Settings of the stimulus X Screen make sure, that the "Sync to VBlank" option is '''enabled''' and the "Allow Flipping" option is '''disabled'''. If you are using a high speed (e.g. 120 Hz) screen, you may have to '''disable''' (uncheck) the option "GPU 0 - DFP-0 - Information - Flat Panel Scaling - Force Full GPU Scaling" to enable the correct hight framerate for your screen. == Building the RTAI modules == 1. Go to the rtai source directory: {{{ # cd /usr/local/src/rtai-3.9 }}} 2. Make it: {{{ # make menuconfig }}} * In the menu "General" set the rtai-path (/usr/lib/realtime) and the path to the kernel sources (/usr/local/src/linux-2.6.38.8). * Choose "Exit", "Exit" and "Yes". {{{ # make install }}} 3. If you want to test rtai, do: {{{ # export PATH=/usr/lib/realtime/bin:$PATH # cd /usr/lib/realtime/testsuite/kern/latency # ./run }}} In short: {{{ export PATH=/usr/lib/realtime/bin:$PATH && cd /usr/lib/realtime/testsuite/kern/latency && ./run cd /usr/local/src }}} 4. It is useful to link the rtai modules to /lib/modules/$(uname -a)/ because they can then be loaded automatically if e.g. a comedi module needs them: {{{ ln -s /usr/lib/realtime/modules /lib/modules/2.6.38.8rtai/rtai depmod -a }}} == Comedi == 0. Install the autoconf package: {{{ aptitude -y install autoconf }}} 1. Download current comedi git snapshot from http://www.comedi.org/download.html, move it to /usr/local/src and unpack it: {{{ cd /usr/local/src tar -xvzf comedi-HEAD-6f425c7.tar.gz }}} 3. Configure it with the rtai package: {{{ cd comedi-HEAD-6f425c7 ./autogen.sh ./configure --with-rtaidir=/usr/lib/realtime }}} If you want to use a PCMCIA card in a notebook, add the PCMCIA drivers: {{{ ./configure --enable-pcmcia --with-rtaidir=/usr/lib/realtime }}} 4. Make and install it and create the devices: {{{ make && make install && depmod -a && make dev }}} 6. If you want to use a PCMCIA card in a notebook, some more steps are necessary (do this '''after''' installing comedilib): Assuming you installed comedilib into /usr/local - this is true if you didn't 'configure' it with a prefix other than that: {{{ cd /etc/pcmcia ln -s /usr/local/etc/pcmcia/* . }}} These steps install (link) the comedi-specific pcmcia scripts into the system's standard location for pcmcia scripts. After this the PCMCIA service of your laptop should attempt to load the needed modules for your card and configure it with comedi_configure as soon as you insert the card. To quickly check if it worked then: {{{ cat /proc/comedi }}} When the modules have been loaded and comedi_config has been executed, a line containing '0: ni_mio_cs' should appear (among others). If that's the case your DAQCard is properly configured. If not (especially, if comedy_config produces the error "comedi.o not loaded"), a modification in /etc/modprobe.d will be necessary (http://groups.google.com/group/comedi_list/browse_thread/thread/c24e52bb196abe61): If you are using the current CVS version of comedi, then by default, all comedi devices are reserved for autoconfigured PCI and USB devices, so if you want to configure ISA or PCMCIA devices you need to tell Comedi to reserve some or all comedi devices with a module option when the comedi.ko module is loaded. The easiest way to do that is to create and edit /etc/modprobe.d/comedi.conf and add one of the following lines: {{{ options comedi comedi_num_legacy_minors=4 }}} (you can change the number 4 if you want), or: {{{ options comedi comedi_autoconfig=0 }}} The first option, {{{comedi_num_legacy_minors=4}}} reserves 4 comedi devices for use by non-autoconfigured devices. The second option {{{comedi_autoconfig=0}}} disables auto-configuration completely. Take your pick! You'll have to run 'sudo depmod -a' and reload all the comedi modules for the change to take effect, or just reboot. 7. We need some packages for comedilib: {{{ aptitude install libtool flex bison }}} 7. Now is a good time to download (http://www.comedi.org/download/, e.g. http://www.comedi.org/download/comedilib-0.8.1.tar.gz), compile and install comedilib: {{{ cd /usr/local/src wget http://www.comedi.org/download/comedilib-HEAD-54712cb.tar.gz tar -xvzf comedilib-HEAD-54712cb.tar.gz cd comedilib-HEAD-54712cb ./autogen.sh ./configure -prefix=/usr make make install }}} 7. Add /usr/local/lib to the ldconfig config file /etc/ld.so.conf.d/i486-linux-gnu.conf: {{{ pico /etc/ld.so.conf.d/i486-linux-gnu.conf }}} The file should look similar to this: {{{ # Multiarch support /lib/i486-linux-gnu /usr/lib/i486-linux-gnu /usr/local/lib }}} 7. Run ldconfig to make the new libraries visible: {{{ ldconfig }}} 8. Load modules and associate comedi-driver of your card to comedi-device (find appropriate driver at http://www.comedi.org/hardware.html): {{{ # RTAI modules modprobe rtai_hal modprobe rtai_fifos # Comedi modules # For National Instruments cards: # modprobe ni_pcimio # modprobe ni_mio_cs # For measurement computing cards: # modprobe cb_pcidas64 modprobe comedi_rt_timer modprobe kcomedilib }}} Modules can be specified in /etc/modules (don't forget to uncomment the line for your card): {{{ # /etc/modules: kernel modules to load at boot time. # # This file contains the names of kernel modules that should be loaded # at boot time, one per line. Lines beginning with "#" are ignored. loop # RTAI modules rtai_hal rtai_fifos # Comedi modules # For National Instruments cards: ni_pcimio # ni_mio_cs # For measurement computing cards: # cb_pcidas64 comedi_rt_timer kcomedilib }}} 9. Find appropriate driver for your card at http://www.comedi.org/hardware.html. 10. Test comedi installation: {{{ comedi_test }}} 12. After calling comedi_config it is time, to check for interrupt conflicts. The nvidia card or a SATA controller should not share the same interrupt with the daq card. Use these commands to find out: {{{ dmesg cat /proc/interrupts lspci -v lspci -vb }}} If a conflict occurs, you can try to put the daq card into a different PCI slot. A conflict with the SATA controller might be solved by setting the SATA mode from "Enhanced" to "Compatible" in the BIOS. == Qwt == 1. Make sure you have qt4 and the g++ compiler installed: {{{ aptitude -y install qt4-dev-tools qt4-designer qt4-doc build-essential }}} 3. Download the latest Qwt from http://sourceforge.net/projects/qwt -> "Download" -> "Download" -> "qwt-6.1.zip" (currently: http://downloads.sourceforge.net/project/qwt/qwt/6.1.2/qwt-6.1.2.tar.bz2?r=http%3A%2F%2Fsourceforge.net%2Fprojects%2Fqwt%2F&ts=1424082627&use_mirror=cznic) {{{ cd /usr/local/src && wget http://downloads.sourceforge.net/project/qwt/qwt/6.1.2/qwt-6.1.2.tar.bz2?r=http%3A%2F%2Fsourceforge.net%2Fprojects%2Fqwt%2F&ts=1424082627&use_mirror=cznic }}} 4. Unpack the archive: {{{ tar -xvjf qwt-6.1.2.tar.bz2 }}} 5. Build the library: {{{ cd qwt-6.1.2/src/ && qmake && make && make install }}} 6. To use the library you have to * EITHER install Qwt by * copying the *.h files in src/ to /usr/local/include/: {{{ cp *.h /usr/local/include }}} * copying those in lib/ to /usr/local/lib/. {{{ cd /usr/local/src/qwt-6.1.2/lib && tar -cf l.tar * mv l.tar /usr/local/lib cd /usr/local/lib tar xf l.tar rm l.tar }}} * For the impatient people: All the above to copy & paste: {{{ cp /usr/local/src/qwt-6.1.2/src/*.h /usr/local/include cd /usr/local/src/qwt-6.1.2/lib && tar -cf l.tar * && mv l.tar /usr/local/lib && cd /usr/local/lib && tar xf l.tar && rm l.tar cd /usr/local/src/qwt-6.1.2 }}} * verifying, that /usr/local/lib is in the ldconfig config file /etc/ld.so.conf.d/i486-linux-gnu.conf: {{{ cat /etc/ld.so.conf.d/i486-linux-gnu.conf }}} should show something like: {{{ # Multiarch support /lib/i486-linux-gnu /usr/lib/i486-linux-gnu /usr/local/lib }}} * running ldconfig: {{{ ldconfig }}} * OR make sure the Qwt files are found by * adding the path to include/ to the INCLUDEPATH line in the nrec *.pro file. * adding the path to lib/ to the LIBS line in the nrec *.pro file (prefixed with '-L'). * adding the path to lib/ to the LD_LIBRARY_PATH environment variable. 7. If you want to test qwt by taking a look at the examples, build them: {{{ cd examples && qmake && make && bin/radio }}} == Development tools and libraries == Install subversion client, kdevelop, the HDF5 library (required) and tools (optional), the movie libraries, the gnu scientific library, the debuggers ddd and kdbg ntp and the ssh server (if needed): {{{ aptitude -y install subversion kdesvn kompare kdevelop libhdf5-serial-1.8.4 libhdf5-serial-dev hdf5-tools libpng12-0 libpng12-dev libfreetype6 libfreetype6-dev libavformat-dev libavcodec-dev libpostproc-dev libswscale-dev libswscale0 gsl-bin libgsl0ldbl libgsl0-dev ddd kdbg ntp ntpdate openssh-server }}} == nrec == 1. Checkout module "nrec" from the subversion server {{{ cd /usr/local/src svn co https://user@134.2.114.63/svn/nrec }}} 2. Install the vicon library: {{{ cp nrec/src/test/vicon/libViconDataStreamSDK_CPP.so /usr/local/lib ldconfig }}} 3. Generate Makefile from qmake project file {{{ cd nrec/src && qmake-qt4 -o Makefile nrec.pro }}} To generate the debug resp. release binaries nrec_debug resp. nrec that contain the debug information (that e.g. ddd or kdbg need) resp. not: {{{ qmake CONFIG-="release" CONFIG+="debug" nrec.pro && make clean && make qmake CONFIG-="debug" CONFIG+="release" nrec.pro && make clean && make qmake CONFIG+="debug_and_release" nrec.pro && make clean && make }}} 4. Change the owner and group of the of nrec/ folder : {{{ cd /usr/local/src chown -R devel:devel nrec/ }}} 4. Import nrec project into KDevelop (optional) * Run kdevelop * "Project" -> "Import Existing Project" * Directory: Browse to nrec/branches/qt4/src you have just checked out. * Fetch from: Ignore this. * Project Name: "nrec" * Build System: "Generic Project Manager" * Author: Your Name * Email: Your Email address 5. Compile nrec: Either in KDevelop "Build" -> "Build Project" or on the command line type {{{ make }}} <> == xoscope == The xoscope (http://xoscope.sourceforge.net/) is a nice little oscilloscope program that can be used to check analog inputs of the daq card via the comedi interface. To install it, type {{{ aptitude install xoscope }}} <> == Setting up the multiuser-environment == This is probably not the most secure way to do it, but it is working: 1. Install the sudo package: {{{ aptitude install sudo }}} 2. Put the call of the startscript in a file in /usr/local/bin {{{ echo -e "sudo /usr/bin/nvidia-settings -l\nsudo /Usr/local/src/nrec/run/nrec.sh $1" > /usr/local/bin/nr }}} 3. Make it executable: {{{ chmod a+x /usr/local/bin/nr }}} 4. Modify the sudo settings via visudo, so that a user can execute the startscipt: {{{ # /etc/sudoers # # This file MUST be edited with the 'visudo' command as root. # # See the man page for details on how to write a sudoers file. # Defaults env_reset Defaults mail_badpass Defaults secure_path="/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin" # Host alias specification # User alias specification User_Alias ALLE = devel, user # Cmnd alias specification # User privilege specification root ALL=(ALL) ALL ALLE ALL=NOPASSWD: /usr/local/src/nrec/run/nrec.sh, /usr/local/bin/nr, /usr/local/src/nrec/src/nrec, /usr/local/src/nrec/branches/squeeze-qt3/src/nrec, /usr/bin/nvidia-settings # Allow members of group sudo to execute any command %sudo ALL=(ALL:ALL) ALL # See sudoers(5) for more information on "#include" directives: #includedir /etc/sudoers.d }}} 5. Add xhost command to kde Autostart folder: {{{ echo "xhost localhost" > ~/.kde/Autostart/xhost_localhost && chmod a+x ~/.kde/Autostart/xhost_localhost }}} 5. now any user that is added by visudo can start nrec via: {{{ nr }}} <> == Creating screencasts == Install recordmydesktop and the frontend gtk-recordmydesktop: {{{ aptitude install recordmydesktop gtk-recordmydesktop }}} RECORDMYDESKTOP(1): RECORDMYDESKTOP(1) NAME recordMyDesktop - record desktop sessions to an Ogg-Theora-Vorbis file. SYNOPSIS recordmydesktop [ Options ]^ filename DESCRIPTION recordMyDesktop produces a file(default out.ogv) that contains a video and audio recording of a linux desktop session. The default behavior of recording is to mark areas that have changed(through libxdamage) and update the frame. This behavior can be changed (option --full-shots ) to produce a more accurate result or capture windows that do not generate events on change(windows with accelerated 3d context) but this will notably increase the workload. GTK-RECORDMYDESKTOP(1): GTK-RECORDMYDESKTOP(1) NAME gtk-recordMyDesktop - graphical gtk frontend for recordMyDestkop SYNOPSIS recordmydesktop [ Options ]^ filename DESCRIPTION gtk-recordMyDesktop is a graphical frontend for recordMyDesktop There are no options for the program, just execute it and use it from the Desktop panel