811 lines
36 KiB
Plaintext
811 lines
36 KiB
Plaintext
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GKrellM - GNU (or Gtk) Krell Monitors (or Meters)
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=======================================================================
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Author: Bill Wilson
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Email: billw--at--gkrellm.net
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Homepage: http://gkrellm.net
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Copyright (c) 1999-2006 by Bill Wilson. This program is free software
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which I release under the GNU General Public License.
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Read the COPYRIGHT file for more info.
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Description
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===========
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With a single process, GKrellM manages multiple stacked monitors and supports
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applying themes to match the monitors appearance to your window manager,
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Gtk, or any other theme.
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GKrellM Features
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================
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* SMP CPU, Disk, Proc, and active net interface monitors with LEDs.
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* Internet monitor that displays current and charts historical port hits.
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* Memory and swap space usage meters and a system uptime monitor.
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* File system meters show capacity/free space and can mount/umount.
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* A mbox/maildir/MH/POP3/IMAP mail monitor which can launch a mail reader
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or remote mail fetch program.
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* Clock/calendar and hostname display.
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* Battery laptop battery monitor.
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* CPU/motherboard temperature/fan/voltages display with warnings and
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alarms. Linux requires a sensor configured sysfs, lm_sensors modules or
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a running mbmon daemon. FreeBSD can also read the mbmon daemon.
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Windows requires MBM or SpeedFan.
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* Disk temperatures if there's a running hddtemp daemon.
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* Multiple monitors managed by a single process to reduce system load.
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* A timer button that can execute PPP or ISDN logon/logoff scripts.
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* Charts are autoscaling with configurable grid line resolution, or
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can be set to a fixed scale mode.
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* Separate colors for "in" and "out" data. The in color is used for
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CPU user time, disk read, forks, and net receive data. The out color
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is used for CPU sys time, disk write, load, and net transmit data.
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* Commands can be configured to run when monitor labels are clicked.
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* GKrellM is plugin capable so special interest monitors can be created.
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* Data can be collected from a gkrellmd server running on a remote machine.
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* Many themes are available.
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User Interface
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==============
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* Top frame:
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Btn 1 - Press and drag to move gkrellm window.
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Btn 3 - Popup main menu.
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* Side frames:
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Btn 2 - Slide gkrellm window shut (Btn1 if -m2 option).
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Btn 3 - Popup main menu.
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* All charts
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Btn 1 - Toggle draw of extra info on the chart.
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Btn 3 - Brings up a chart configuration window.
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* Inet charts
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Btn 2 - toggle between port hits per minute and hour.
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* Most panels
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Btn 3 - Opens the configuration window directly to a monitor's
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configuration page.
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* File System meter panels:
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Btn 1,2 - Toggle display of label and fs capacity scrolling display.
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The mount button runs mount/umount commands. If ejectable,
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left click the eject button to open tray, right click closes.
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* Mem and Swap meter panels:
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Btn 1,2 - Toggle display of label and memory or swap capacity
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scrolling display.
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* Mailbox monitor message count button:
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Btn 1 - Launch a mail reader program. If options permit, also
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stop animations and reset remote message counts.
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Btn 2 - Toggle mail check mute mode which inhibits the sound
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notify progra, and optionally inhibits all mail checking.
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* Mailbox monitor envelope decal:
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Btn 1 - Force a mail check regardless of mute or timeout state.
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* Battery monitor panel:
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Btn 1 - On the charging state decal toggles battery minutes left,
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percent level, and charge rate display.
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Btn 2 - Anywhere on the panel also toggles the display.
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Keyboard shortcuts:
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* F1 = popup the user config window.
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* F2 = popup the main menu.
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* Page_Up - previous theme or theme alternative.
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* Page_Down - next theme or theme alternative.
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* <Ctl>Page_Up - previous theme, skipping any theme alternatives.
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* <Ctl>Page_Down - next theme, skipping any theme alternatives.
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If a command has been configured to be launched for a monitor, then
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a button will appear when the mouse enters the panel of that monitor.
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Clicking the button will launch the command.
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Requirements
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============
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To use or compile GKrellM, you need:
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* Gtk+-2.0
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To compile, you additionally need the development libs.
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Installation
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============
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See the INSTALL file. BSD systems will need to use GNU gmake.
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Running GKrellM
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===============
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To get a list of options:
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gkrellm --help
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Some of the options are:
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-t, --theme theme_dir
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GKrellM will load all theme image files it finds in theme_dir
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and parse the gkrellmrc file if one exists. This option overrides
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the loading of the last theme you configured to be loaded in
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the Themes configuration window. Theme changes are not saved
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when GKrellM is run with this option.
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-g, --geometry +x+y
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Or -g +x+y. Makes GKrellM move to an x y postition on the screen
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at startup. Standard X window geometry position (not size) formats
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are parsed, ie +x+y -x+y +x-y -x-y. Except, negative geometry
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positions are not recognized (ie +-x--y )
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-wm
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Forces GKrellM to start up with window manager decorations. The
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default is no decorations because there are themed borders.
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-w, --withdrawn
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GKrellM starts up in withdrawn mode so it can go into a window
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manager's slit. This should work with the Blackbox, Fluxbox, Kahakai,
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Waimea, and maybe other window managers with the slit feature.
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-c, --config suffix
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Use alternate config files generated by appending "suffix" to config
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file names. This overrides any previous host config which may have
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been setup with the below option.
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-f, --force-host-config
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If GKrellM is run once with this option and then the configuration
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or theme is changed, the config files that are written will have
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a -hostname appended to them. Subsequent runs will detect the
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user-config-hostname and gkrellm_theme.cfg-hostname files and use
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them instead of the normal configuration files (unless the --config
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option is specified). This is a convenience for allowing
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remote GKrellMs independent config files in a shared home directory,
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and for the hostname to show up in the X title for window management.
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-s, --server hostname
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Run in client mode by connecting to and collecting data from a gkrellmd
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server running on "hostname".
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-P, --port server_port
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Use "server_port" for the gkrellmd server connection.
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-nc
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No config mode. The config menu is blocked so no config changes
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can be made. Useful in certain environments, or maybe for running
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on a gdm login screen or during a screensaver mode?
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-demo
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Force enabling of many monitors so themers can see everything. All
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config saving is inhibited.
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-p, --plugin plugin_under_test.so
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For plugin development, load the command line specified plugin so you
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can avoid repeated install steps in the development cycle.
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Configuring GKrellM
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===================
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A right button mouse click on the side or top frames of the GKrellM
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window will pop up a user configuration window where you can configure
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all the builtin and plugin monitors. Chart appearance may be configured
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by right clicking on a chart, and right clicking on many panels will open
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the configuration window directly to the corresponding monitor's
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configuration page.
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Using GKrellM - keeping an eye on your computers Id.
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====================================================
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Charts
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======
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The default for most charts is to automatically adjust the number of
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grid lines drawn and the resolution per grid so drawn data will be
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nicely visible. You may change this to fixed grids of 1-5 and/or
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fixed grid resolutions in the chart configuration windows. However,
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some combination of the auto scaling modes may give best results.
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Auto grid resolution has the following behavior.
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If "Auto mode sticks at peak value" is not set:
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1) If using auto number of grids, set the resolution per grid and the
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number of grids to optimize the visibility of data drawn on the chart.
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Try to keep the number of grids between 1 and 7.
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2) If using a fixed number of grids, set the resolution per grid to the
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smallest value that draws data without clipping.
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If "Auto mode sticks at peak value" is set:
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1) If using auto number of grids, set the resolution per grid such that
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drawing the peak value encountered would require at least 5 grids.
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2) If using a fixed number of grids, set the resolution per grid such
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that the peak value encountered could be drawn without clipping.
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This means the resolution per grid never decreases.
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All resolution per grid values are constrained to a set of values in
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either a 1, 2, 5 sequence or a 1, 1.5, 2, 3, 5, 7 sequence. If you set
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"Auto mode sticks at peak value" a manual "Auto mode recalibrate" may
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occasionally be required if the chart data has a wide dynamic range.
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CPU Monitor
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-----------
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Data is plotted as a percentage. In auto number of grids
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mode, resolution is a fixed 20% per grid. In fixed number of grids
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mode, grid resolution is 100% divided by the number of grids.
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Proc Monitor
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------------
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The krell shows process forks with a full scale value
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of 10 forks. The chart has a resolution of 10 forks/sec per grid
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in auto number of grids mode and 50 forks/second maximum on the
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chart in fixed number of grids mode.
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The process load resolution per grid is best left at 1.0 for auto
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number of grids, but can be set as high as 5 if you configure the
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chart to have only 1 or 2 fixed grids.
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Net Monitor
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------------
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GKrellM is designed to display a chart for net interfaces which are
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up, which means they are listed in the routing table (however, it is
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possible in some cases to monitor unrouted interfaces).
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One net interface may be linked to a timer button which can be used
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to connect and disconnect from an ISP.
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The timer button shows an off, standby, or on state by a distinctive
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(color or shape) icon.
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ppp: Standby state is while the modem phone line is locked while
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ppp is connecting, and the on state is the ppp link connected.
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The phone line lock is determined by the existence of the modem
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lock file /var/lock/LCK..modem which assumes pppd is using
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/dev/modem. However, if your pppd setup does not
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use /dev/modem, then you can configure an alternative with:
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ln -s /var/lock/LCK..ttySx ~/.gkrellm2/LCK..modem
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where ttySx is the tty device your modem does use. The ppp on
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state is detected by the existence of /var/run/pppX.pid and
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the time stamp of this file is the base for the on line time.
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ippp: The timer button standby state is not applicable to isdn
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interfaces that are always routed. The on state is isdn on line
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while the ippp interface is routed. The on line timer is reset
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at transitions from isdn hangup state to on line state.
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For both ppp and ippp timer button links, the panel area of the
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interface is always shown and the chart appears when the interface
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is routed with the phone link connected or on line.
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If the timer button is not linked to a net interface, then it can
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be used as a push on / push off timer
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Net monitors can have a label so that the interface can be
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associated with the identity of the other end of the connection.
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This is useful if you have several net connections or run multiple
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remote gkrellms. It can be easier to keep track of who is connected
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to who.
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Mem and Swap Monitor
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--------------------
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Here you are reading a ratio of total used to total available.
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The amount of memory used indicated by the memory monitor is
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actually a calculated "used" memory. If you enter the
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"free" command, you will see that most of your memory is almost
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always used because the kernel uses large amounts for buffers
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and cache. Since the kernel can free a lot of this memory
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as user process demand for memory goes up, a more realistic reading
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of memory in use is obtained by subtracting the buffers and cached
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memory from the kernel reported used. This is shown in the free
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command output in the "-/+ buffers/cache" line where a calculated
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used amount has buffers and cached memory subtracted from the kernel
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reported used memory, and a calculated free amount has the buffers
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and cached memory added in.
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While the memory meter always shows the calculated "used" memory,
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the raw memory values total, shared, buffered, and cached may be
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optionally displayed in the memory panel by entering an appropriate
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format display string in the config.
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Units: All memory values have units of binary megabytes (MiB).
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Memory sizes have historically been reported in these units because
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memory arrays on silicon have always increased in size by multiples
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of 2. Add an address line to a memory chip and you double or quadruple
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(a multiplexed address) the memory size. A binary megabyte is
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2^20 or 1048576. Contrast this with units for other stats such
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as disk capacities or net transfer rates where the proper units
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are decimal megabytes or kilobytes. Disk drive capacities do not
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increase by powers of 2 and manufacturers do not use binary
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units when reporting their sizes. However, some of you may prefer
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to see a binary disk drive capacity reported, so it is available
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as an option.
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Internet Monitor
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----------------
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Displays TCP port connections and records historical port hits on a
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minute or hourly chart. Middle button click on an inet chart to
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toggle between the minute and hourly displays. There is a strip
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below the minute or hour charts where marks are drawn for port
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hits in second intervals. Each inet krell also shows port hits
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with a full scale range of 5 hits. The left button toggle of extra
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info displays current port connections.
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For each internet monitor you can specify two labeled datasets with
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one or two ports for each dataset. There are two ports because some
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internet ports are related and you might want to group them - for
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example, the standard http port is 80, but there is also a www web
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caching service on port 8080. So it makes sense to have a http
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monitor which combines data from both ports. A possible common
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configuration would be to create one inet monitor that monitors
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http hits plotted in the one color and ftp hits in another.
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To do this, setup in the Internet configuration tab:
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http 80 8080 ftp 21
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Or you could create separate monitors for http and ftp. Other
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monitors might be smtp on port 25 or nntp on port 119.
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If you check the "Port0 - Port1 is a range" button, then all of the
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ports between the two entries will be monitored. Clicking the
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small button on the Inet panels will pop up a window listing the
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currently connected port numbers and the host that is connected
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to it.
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GKrellM samples TCP port activity once per second, so it is possible
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for port hits lasting less than a second to be missed.
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File System Monitor
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-------------------
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File system mount points can be selected to be monitored with a meter
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that shows the ratio of blocks used to total blocks available. Mounting
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commands can be enabled for mount points in one of two ways:
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1) If a mount point is in your /etc/fstab and you have mount permission
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then mount and umount commands can be enabled and executed for that
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mount point simply by checking the "Enable /etc/fstab mounting" option.
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Mount table entries in /etc/fstab must have the "user" or "owner" option set
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to grant this permission unless GKrellM is run as root.
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For example, if you run GKrellM as a normal user and you want to be
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able to mount your floppy, your /etc/fstab could have either of:
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/dev/fd0 /mnt/floppy ext2 user,noauto,rw,exec 0 0
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or
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/dev/fd0 /mnt/floppy ext2 user,defaults 0 0
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2) If GKrellM is run as root or if you have sudo permission to run the
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mount commands, then a custom mount command can be entered into the
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"mount command" entry box. A umount command must also be entered if you
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choose this method. Example mount and umount entries using sudo:
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sudo /bin/mount -t msdos /dev/fd0 /mnt/A
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sudo /bin/umount /mnt/A
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Notes: the mount point specified in a custom mount command (/mnt/A in
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this example) must be the same as entered in the "Mount Point" entry.
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Also, you should have the NOPASSWD option set in /etc/sudoers for this.
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File system monitors can be created as primary (always visible)
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or secondary which can be hidden and then shown when they are of
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interest. For example, you might make primary file system monitors
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for root, home, or user so they will be always visible, but make
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secondary monitors for less frequently used mount points such as
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floppy, zip, backup partitions, foreign file system types, etc.
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Secondary FS monitors can also be configured to always be visible if they
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are mounted by checking the "Show if mounted" option. Using this
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feature you can show the secondary group, mount a file system, and have
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that FS monitor remain visible even when the secondary group is hidden.
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A standard cdrom mount will show as 100% full but a monitor for it
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could be created with mounting enabled just to have the
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mount/umount convenience.
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When the "Ejectable" option is selected for a file system, an eject
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button will appear when the mouse enters the file system panel. If you
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are not using /etc/fstab mounting, a device file to eject will also need
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to be entered. Systems may have varying levels of support for this feature
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ranging from none or basic using an ioctl() to full support using an eject
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command to eject all its supported devices. Linux and NetBSD use the
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"eject" command while FreeBSD uses the "cdcontrol" command, so be sure
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these commands are installed.
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Most eject commands will also support closing a CDROM tray. If they do,
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you will be able to access this function by right clicking the eject button.
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Mail Monitor
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------------
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Checks your mailboxes for unread mail. A mail reading program (MUA) can be
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executed with a left mouse click on the mail monitor panel button, and
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a mail notify (play a sound) program such as esdplay or artsplay can be
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executed whenever the new mail count increases. The mail panel envelope
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||
|
decal may also be clicked to force an immediate mail check at any time.
|
||
|
|
||
|
GKrellM is capable of checking mail from local mailbox types mbox, MH, and
|
||
|
maildir, and from remote mailbox types POP3 and IMAP.
|
||
|
|
||
|
POP3 and IMAP checking can use non-standard port numbers and password
|
||
|
authentication protocols APOP (for POP3 only) or CRAM-MD5. If supported
|
||
|
by the mail server, emote checking may be done over an SSL connection if
|
||
|
the "Use SSL" option is selected.
|
||
|
|
||
|
Before internal POP3 and IMAP checking was added, an external mail
|
||
|
fetch/check program could be set up to be executed periodically to
|
||
|
download or check remote POP3 or IMAP mail. This method is still
|
||
|
available and must be used if you want GKrellM to be able to
|
||
|
download remote mail to local mailboxes because the builtin checking
|
||
|
functions cannot download.
|
||
|
|
||
|
|
||
|
Battery Monitor
|
||
|
--------------------------
|
||
|
This meter will be available if a battery exists and will show battery
|
||
|
percentage life remaining. A decal indicates if AC line is connected
|
||
|
or if the battery is in use. If the data is available, time remaining
|
||
|
may be displayed as well as the percentage battery level. If the time
|
||
|
remaining is not available or is inaccurate, the Estimate Time option
|
||
|
may be selected to display a battery time to run or time to charge which
|
||
|
is calculated based on the current battery percent level, user supplied
|
||
|
typical battery times, and a default linear extrapolation model.
|
||
|
For charging, an exponential charge model may be selected.
|
||
|
|
||
|
A battery low level warning and alarm alert may be set. If battery time
|
||
|
is not available from the OS and the estimate time mode is not set, the
|
||
|
alert units will be battery percent level. Otherwise the alert units will
|
||
|
be battery time left in minutes. If OS battery time is not available and the
|
||
|
estimate time mode is set when the alert is created, the alert will have
|
||
|
units of time left in minutes and the alert will automatically be destroyed
|
||
|
if the estimate time option is subsequently turned off.
|
||
|
|
||
|
If the OS reports multiple batteries, the alert will be a master alert
|
||
|
which is duplicated for each battery.
|
||
|
|
||
|
CPU/Motherboard Sensors - Temperature, Voltages, and Fan RPM
|
||
|
------------------------------------------------------------
|
||
|
Linux:
|
||
|
-----
|
||
|
Sensor monitoring requires that either lm_sensors modules are
|
||
|
installed in your running kernel, that you run a kernel >= 2.6 with sysfs
|
||
|
sensors configured, or, for i386 architectures, that you have the mbmon
|
||
|
daemon running when gkrellm is started. If the mbmon daemon is used, it
|
||
|
must be started before gkrellm like so:
|
||
|
|
||
|
mbmon -r -P port-number
|
||
|
|
||
|
where the given "port-number" must be configured to match in the gkrellm
|
||
|
Sensors->Options config. Sensor temperatures can also be read from
|
||
|
/proc/acpi/thermal_zone, /proc/acpi/thermal, /proc/acpi/ibm. the
|
||
|
PowerMac Windfarm /sysfs interface, and PowerMac PMU /sysfs based
|
||
|
sensors.
|
||
|
|
||
|
When using lm_sensors, libsensors will be used if available, but if
|
||
|
libsensors is not linked into the program, the sensor data will be
|
||
|
read directly from the /sysfs or /proc file systems. If running a newer
|
||
|
Linux kernel sensor module not yet supported by libsensors and libsensors
|
||
|
is linked, there will also be an automaitc fallback to using /sysfs as
|
||
|
long as libsensors doesn't detect any sensors. But if it does detect some
|
||
|
sensors which does not include the new sensors you need, you can force
|
||
|
getting /sysfs sensor data either by running:
|
||
|
|
||
|
gkrellm --without-libsensors
|
||
|
|
||
|
or by rebuilding with:
|
||
|
|
||
|
make without-libsensors=yes
|
||
|
|
||
|
|
||
|
Disk temperatures may also be monitored if you have the hddtemp daemon
|
||
|
running when gkrellm is started. Gkrellm uses the default hddtemp port
|
||
|
of 7634. Both hddtemp and mbmon are best started in a boot rc script to
|
||
|
guarantee they will be running when gkrellm is started.
|
||
|
|
||
|
Nvidia graphics card GPU temperatures may also be monitored if
|
||
|
the nvidia-settings command is installed and your Nvidia card supports
|
||
|
the temperature reporting. If nvidia-settings is not installed or does
|
||
|
not report temperatures for your card, an option for using the nvclock
|
||
|
program will appear in the Sensors config. Nvclock use is not
|
||
|
automatically enabled as is nvidia-settings because nvclock can add
|
||
|
seconds of gkrellm startup time when used on a NVIDIA GPU chipset it
|
||
|
does not support. GKrellM must be restarted to recognize changes for
|
||
|
the nvclock option.
|
||
|
|
||
|
Windows
|
||
|
-------
|
||
|
Requires on of:
|
||
|
- MBM: http://mbm.livewiredev.com/
|
||
|
- SpeedFan: http://www.almico.com/speedfan.php
|
||
|
|
||
|
FreeBSD
|
||
|
------------------
|
||
|
Builtin sensor reporting is available for some sensor chips.
|
||
|
FreeBSD systems can also read sensor data from the mbmon daemon as described
|
||
|
in the Linux section above.
|
||
|
|
||
|
NetBSD
|
||
|
------------------
|
||
|
Builtin sensor reporting is available for some sensor chips.
|
||
|
NetBSD uses the envsys(4) interface and sensors reading is automatically
|
||
|
enabled if you have either a lm(4) or viaenv(4) chip configured in your kernel.
|
||
|
|
||
|
General Setup:
|
||
|
--------------
|
||
|
Temperature and fan sensor displays may be optionally located on the CPU or
|
||
|
Proc panels to save some vertical space while voltages are always displayed
|
||
|
on their own panel. If you set up to monitor both a temperature and a fan
|
||
|
on a single CPU or Proc panel, they can be displayed optionally as an
|
||
|
alternating single display or as separate displays. If separate, the fan
|
||
|
display will replace the panel label. The configuration for this is under
|
||
|
the CPU and Proc config pages.
|
||
|
|
||
|
If not using libsensors, in the Setup page for the Sensors config enter
|
||
|
any correction factors and offsets for each of the sensors you are monitoring
|
||
|
(see below and lm_sensor documentation). For Linux, default values are
|
||
|
automatically provided for many sensor chips.
|
||
|
|
||
|
But if using libsenors, it is not possible to enter correction factors and
|
||
|
offsets on the Sensors config page because libsensors configuration is
|
||
|
done in the /etc/sensors.conf file. To get sensor debug output and to find
|
||
|
out the sensor data source, run:
|
||
|
|
||
|
gkrellm -d 0x80
|
||
|
|
||
|
Note for NetBSD users:
|
||
|
The current implementation of the sensor reading under NetBSD opens
|
||
|
/dev/sysmon and never closes it. Since that device does not support
|
||
|
concurrent accesses, you won't be able to run other apps such as
|
||
|
envstat(8) while GKrellM is running. This might change if this happens
|
||
|
to be an issue.
|
||
|
The reasons for this choice are a) efficiency (though it might be possible
|
||
|
to open/close /dev/sysmon each time a reading is needed without major
|
||
|
performance issue) and b) as of october 2001, there's a bug in the
|
||
|
envsys(4) driver which sometimes causes deadlocks when processes try to
|
||
|
access simultaneoulsy /dev/sysmon (see NetBSD PR#14368). A (quick and
|
||
|
dirty) workaround for this is to monopolize the driver :)
|
||
|
|
||
|
|
||
|
CPU/Motherboard Temperatures
|
||
|
----------------------------
|
||
|
Most modern motherboards will not require setting temperature correction
|
||
|
factors and offsets other than the defaults. However, for lm_sensors it
|
||
|
is necessary to have a correct "set sensor" line in /etc/sensors.conf
|
||
|
if the temperature sensor type is other than the default thermistor.
|
||
|
If using Linux sysfs sensors, this sensor type is set by writing to
|
||
|
a sysfs file. For example, you might at boot set a sysfs temperature sensor
|
||
|
type with:
|
||
|
|
||
|
echo "2" > /sys/bus/i2c/devices/0-0290/sensor2
|
||
|
|
||
|
On the other hand, some older motherboards may need temperature calibration
|
||
|
by setting a correction factor and offset for each temperature sensor
|
||
|
because of factors such as variations in physical thermistor contact
|
||
|
with the CPU. Unfortunately, this calibration may not be practical or
|
||
|
physically possible because it requires that somehow you can get a real
|
||
|
CPU temperature reading. So, the calibration discussion which follows
|
||
|
should probably be considered an academic exercise that might give you
|
||
|
some good (or bad) ideas. If you have a recent motherboard, skip the
|
||
|
following.
|
||
|
|
||
|
Anyway, to do this calibration, take two real CPU temperature readings
|
||
|
corresponding to two sensor reported readings. To get the real
|
||
|
readings, you can trust that your motherboard manufacturer has done
|
||
|
this calibration and is reporting accurate temperatures in the bios,
|
||
|
or you can put a temperature probe directly on your CPU case (and this
|
||
|
is where things get impractical).
|
||
|
|
||
|
Here is a hypothetical CPU calibration procedure. Make sure GKrellM is
|
||
|
configured with default factors of 1.0 and offsets of 0 and is reporting
|
||
|
temperatures in centigrade:
|
||
|
|
||
|
1) Power on the machine and read a real temperature T1 from the bios or
|
||
|
a temperature probe. If reading from the bios, proceed with booting
|
||
|
the OS. Now record a sensor temperature S1 as reported by GKrellM.
|
||
|
2) Change the room temperature environment (turn off your AC or change
|
||
|
computer fan exhaust speed). Now repeat step 1, this time recording
|
||
|
a real temperature T2 and GKrellM reported sensor temperature S2.
|
||
|
3) Now you can calculate the correction factor and offset you need
|
||
|
to enter into the Sensor configuration tab:
|
||
|
From:
|
||
|
s - S1 t - T1
|
||
|
------ = ------
|
||
|
S2 - S1 T2 - T1
|
||
|
|
||
|
T2 - T1 S2*T1 - S1*T2
|
||
|
t = s * ------- + -------------
|
||
|
S2 - S1 S2 - S1
|
||
|
|
||
|
So:
|
||
|
T2 - T1 S2*T1 - S1*T2
|
||
|
factor = ------- offset = -------------
|
||
|
S2 - S1 S2 - S1
|
||
|
|
||
|
|
||
|
Voltage Sensor Corrections
|
||
|
--------------------------
|
||
|
You need to read this section only if you think the default voltage correction
|
||
|
factors and offsets are incorrect. For Linux and lm_sensors and sysfs sensors
|
||
|
this would be if GKrellM does not know about your particular sensor chip.
|
||
|
For MBM/SpeedFan with Windows, the default values should be correct.
|
||
|
|
||
|
Motherboard voltage measurements are made by a variety of sensor
|
||
|
chips which are capable of measuring a small positive voltage.
|
||
|
GKrellM can display these voltage values and can apply a correction
|
||
|
factor, offset, and for the negative voltages of some chips (lm80), a
|
||
|
level shifting reference voltage to the displayed voltage. There are
|
||
|
four cases to consider:
|
||
|
|
||
|
1) Low valued positive voltages may be directly connected to the input
|
||
|
pins of the sensor chip and therefore need no correction. For these,
|
||
|
the correction factor should be 1.0 and the offset should be 0.
|
||
|
|
||
|
2) Higher valued positive voltages will be connected to the input pins
|
||
|
of the sensor chip through a 2 resistor attenuation circuit. For these,
|
||
|
the correction factor will be a ratio of the resistor values and the
|
||
|
offset will be 0.
|
||
|
|
||
|
3) Negative voltages will be connected to the input pins of the sensor
|
||
|
through a 2 resistor attenuation circuit with one of the resistors
|
||
|
connected to a positive voltage to effect a voltage level shift.
|
||
|
For these (lm80), the correction factor and offset will be ratios of the
|
||
|
resistor values, and a reference voltage must be used.
|
||
|
|
||
|
4) Some sensor chips (w83782, lm78) are designed to handle negative inputs
|
||
|
without requiring an input resistor connected to a voltage reference.
|
||
|
For these, there will be a correction factor and a possible offset.
|
||
|
|
||
|
For cases 2 and 3, the sensor chip input network looks like:
|
||
|
|
||
|
Vs o----/\/\/---o-------------o Vin
|
||
|
R1 |
|
||
|
o--/\/\--o Vref
|
||
|
R2
|
||
|
where,
|
||
|
Vs is the motherboard voltage under measurment
|
||
|
Vin is the voltage at the input pin of the sensor chip and therefore is
|
||
|
the voltage reading that will need correction.
|
||
|
Vref is a level shifting voltage reference. For case 2, Vref is ground
|
||
|
or zero. For case 3, Vref will be one of the positive motherboard
|
||
|
voltages.
|
||
|
|
||
|
The problem then is to compute correction factors and offsets as a function
|
||
|
of R1 and R2 so that GKrellM can display a computed motherboard voltage Vs
|
||
|
as a function of a measured voltage Vin.
|
||
|
|
||
|
Since sensor chip input pins are high impedance, current into the pins may
|
||
|
be assumed to be zero. In that case, the current through R1 equals current
|
||
|
through R2, and we have:
|
||
|
|
||
|
(Vs - Vin)/R1 = (Vin - Vref)/R2
|
||
|
|
||
|
Solving for Vs as a function of Vin:
|
||
|
|
||
|
Vs = Vin * (1 + R1/R2) - (R1/R2) * Vref
|
||
|
|
||
|
So, the correction factor is: 1 + R1/R2
|
||
|
the correction offset is: - (R1/R2)
|
||
|
Vref is specified in the config separately from the offset (for
|
||
|
chips that need it).
|
||
|
|
||
|
Fortunately there seems to be a standard set of resistor values used
|
||
|
for the various sensor chips which are documented in the lm_sensor
|
||
|
documentation. The GKrellM sensor corrections are similar to the compute
|
||
|
lines you find with lm_sensors, with the difference that lm_sensors has an
|
||
|
expression evaluator which does not require that compute lines be simplified
|
||
|
to the single factor and offset required by GKrellM. But you can easily
|
||
|
calculate the factor and offset. For example, this lm_sensor compute line
|
||
|
for a case 2 voltage:
|
||
|
|
||
|
compute in3 ((6.8/10)+1)*@ , @/((6.8/10)+1)
|
||
|
|
||
|
yields a correction factor of ((6.8/10)+1) = 1.68
|
||
|
and an offset of zero.
|
||
|
|
||
|
Note that the second compute line expression is not relevant in GKrellM
|
||
|
because there is never any need to invert the voltage reading calculation.
|
||
|
Also, the compute line '@' symbol represents the Vin voltage.
|
||
|
|
||
|
A more complicated compute line for a case 3 voltage:
|
||
|
|
||
|
compute in5 (160/35.7)*(@ - in0) + @, ...
|
||
|
|
||
|
can be rewritten:
|
||
|
|
||
|
compute in5 (1 + 160/35.7)*@ - (160/35.7)*in0, ...
|
||
|
|
||
|
so the correction factor is (1 + 160/35.7) = 5.48
|
||
|
and the correction offset is -(160/35.7) = -4.48
|
||
|
and the voltage reference Vref is in0
|
||
|
|
||
|
Here is a table of correction factors and offsets based on some typical
|
||
|
compute line entries from /etc/sensors.conf:
|
||
|
|
||
|
Compute line Factor Offset Vref
|
||
|
-----------------------------------------------------
|
||
|
lm80 in0 (24/14.7 + 1) * @ 2.633 0 -
|
||
|
in2 (22.1/30 + 1) * @ 1.737 0 -
|
||
|
in3 (2.8/1.9) * @ 1.474 0 -
|
||
|
in4 (160/30.1 + 1) * @ 6.316 0 -
|
||
|
in5 (160/35.7)*(@ - in0) + @ 5.482 -4.482 in0
|
||
|
in6 (36/16.2)*(@ - in0) + @ 3.222 -2.222 in0
|
||
|
|
||
|
LM78 in3 ((6.8/10)+1)*@ 1.68 0 -
|
||
|
in4 ((28/10)+1)*@ 3.8 0 -
|
||
|
in5 -(210/60.4)*@ -3.477 0 -
|
||
|
in6 -(90.9/60.4)*@ -1.505 0 -
|
||
|
|
||
|
w83782 in5 (5.14 * @) - 14.91 5.14 -14.91 -
|
||
|
in6 (3.14 * @) - 7.71 3.14 -7.71 -
|
||
|
|
||
|
|
||
|
|
||
|
Command launching
|
||
|
=================
|
||
|
Many monitors can be set up to launch a command when you click on
|
||
|
the monitor label. When a command is configured for a monitor, its
|
||
|
label is converted into a button which becomes visible when the mouse
|
||
|
enters the panel or meter area of the label. If the command is a
|
||
|
console command (doesn't have a graphical user interface), then
|
||
|
the command must be run in a terminal window such as xterm, eterm,
|
||
|
or Gnome terminal. For example running the "top" command would take:
|
||
|
|
||
|
xterm -e top
|
||
|
|
||
|
You can use the command launching feature to run commands related to
|
||
|
monitoring functions, or you may use it to have a convenient launch
|
||
|
for any command. Since GKrellM is usually made sticky, you can have
|
||
|
easy access to several frequently used commands from any desktop.
|
||
|
This is intended to be a convenience and a way to maximize utilization
|
||
|
of screen real estate and not a replacement for more full featured
|
||
|
command launching from desktops such as Gnome or KDE or others.
|
||
|
Some launch ideas for some monitors could be:
|
||
|
|
||
|
calendar: gnomecal, evolution, or ical
|
||
|
CPU: xterm -e top or gps or gtop
|
||
|
inet: gftp or xterm -e ftpwho
|
||
|
net: mozilla, galeon, skipstone, or xterm -e slrn -C-
|
||
|
and so on...
|
||
|
|
||
|
Tooltips can be set up for these commands.
|
||
|
|
||
|
|
||
|
Alerts
|
||
|
======
|
||
|
Most monitors can have alerts configured to give warnings and alarms
|
||
|
for data readings which range outside of configurable limits. Where
|
||
|
useful, a delay of the alert trigger can be configured. A warning or
|
||
|
alarm consists of an attention grabbing decal appearing and an optional
|
||
|
command being executed. For most monitors the command may contain the
|
||
|
same substitution variables which are available for display in the
|
||
|
chart or panel label format strings and are documented on configuration
|
||
|
Info pages. Additionally, the hostname may be embedded in the command
|
||
|
with the $H substitution variable.
|
||
|
|
||
|
If you have festival installed, either a warn or alarm command
|
||
|
could be configured to speak something. For example a CPU temperature
|
||
|
alert warn command could just speak the current temperature with:
|
||
|
|
||
|
sh -c "echo warning C P U is at $s degrees | esddsp festival --tts"
|
||
|
|
||
|
Assuming you have esd running.
|
||
|
|
||
|
|
||
|
Installing a Theme for GKrellM
|
||
|
==============================
|
||
|
|
||
|
A theme is a directory containing image files and a gkrellmrc
|
||
|
configuration file. The theme directory may be installed in
|
||
|
several locations:
|
||
|
|
||
|
~/.gkrellm2/themes
|
||
|
/usr/local/share/gkrellm2/themes
|
||
|
/usr/share/gkrellm2/themes
|
||
|
|
||
|
For compatibility with Gtk themes, a GKrellM theme may also be installed
|
||
|
as:
|
||
|
~/.themes/THEME_NAME/gkrellm2
|
||
|
/usr/share/themes/THEME_NAME/gkrellm2
|
||
|
|
||
|
Finally, a theme you simply want to check out can be untarred anywhere
|
||
|
and used by running:
|
||
|
|
||
|
gkrellm -t path_to_theme
|
||
|
|
||
|
Read the Themes file if you want more information or are interested in
|
||
|
making a new theme for GKrellM.
|
||
|
|
||
|
|
||
|
Plugins
|
||
|
=======
|
||
|
|
||
|
GKrellM tries to load all plugins (shared object files ending in .so)
|
||
|
it finds in your plugin directory ~/.gkrellm2/plugins. The directories
|
||
|
/usr/local/lib/gkrellm2/plugins and /usr/lib/gkrellm2/plugins are
|
||
|
also searched for plugins to install.
|
||
|
|
||
|
Some plugins may be available only as source files and they will
|
||
|
have to be compiled before installation. There should be instructions
|
||
|
for doing this with each plugin that comes in source form.
|
||
|
|
||
|
If you are interested in writing a plugin, go to the Plugins page
|
||
|
at http://gkrellm.net and there you will find a Plugin programmers
|
||
|
reference and Plugins-changelog.
|
||
|
|
||
|
|
||
|
Client/Server
|
||
|
=============
|
||
|
When gkrellm connects to a gkrellmd server all builtin monitors collect
|
||
|
their data from the server. However, the gkrellm process is running
|
||
|
on the local machine, so any enabled plugins will run in the local
|
||
|
context (Flynn is an example exception to this since it derives its data
|
||
|
from the builtin CPU monitor). Also, any command launching will run
|
||
|
commands on the local machine.
|