I just gave a talk about this at SCaLE 17x. Here are the video of the talk and the "slides".
feedgnuplot - General purpose pipe-oriented plotting tool
Simple plotting of piped data:
$ seq 5 | awk '{print 2*$1, $1*$1}'
2 1
4 4
6 9
8 16
10 25
$ seq 5 | awk '{print 2*$1, $1*$1}' |
feedgnuplot \
--lines \
--points \
--title "Test plot" \
--y2 1 \
--unset key \
--unset grid
Simple real-time plotting example: plot how much data is received on the wlan0 network interface in bytes/second. This plot updates at 1Hz, and shows the last 10sec of history. The plot shown here is the final state of a sample run
$ while true; do
sleep 1;
cat /proc/net/dev;
done \
| gawk '/wlan0/ {if(b) {print $2-b; N++; fflush()} b=$2} N==15 {exit}' \
| feedgnuplot \
--lines \
--title "wlan0 throughput" \
--stream \
--xlen 10 \
--ylabel 'Bytes/sec' \
--xlabel seconds \
--unset key \
--unset grid
This is a flexible, command-line-oriented frontend to Gnuplot. It creates plots from data coming in on STDIN or given in a filename passed on the commandline. Various data representations are supported, as is hardcopy output and streaming display of live data. For a tutorial and a gallery please see the guide at https://github.com/dkogan/feedgnuplot/blob/master/guide/guide.org
A simple example:
$ seq 5 | awk '{print 2*$1, $1*$1}' | feedgnuplot
You should see a plot with two curves. The awk
command generates some data to plot and the feedgnuplot
reads it in from STDIN and generates the plot. The awk
invocation is just an example; more interesting things would be plotted in normal usage. No commandline-options are required for the most basic plotting. Input parsing is flexible; every line need not have the same number of points. New curves will be created as needed.
The most commonly used functionality of gnuplot is supported directly by the script. Anything not directly supported can still be done with options such as --set
, --cmds
--style
, etc. Arbitrary gnuplot commands can be passed in with --cmds
. For example, to turn off the grid, you can pass in --cmds 'unset grid'
. Commands --set
and --unset
exists to provide nicer syntax, so this is equivalent to passing --unset grid
. As many of these options as needed can be passed in. To add arbitrary curve styles, use --style curveID extrastyle
. Pass these more than once to affect more than one curve.
To apply an extra style to all the curves that lack an explicit --style
, pass in --styleall extrastyle
. In the most common case, the extra style is with something
. To support this more simply, you can pass in --with something
instead of --styleall 'with something'
. --styleall
and --with
are mutually exclusive. Furthermore any curve-specific --style
overrides the global --styleall
or --with
setting.
By default, each value present in the incoming data represents a distinct data point, as demonstrated in the original example above (we had 10 numbers in the input and 10 points in the plot). If requested, the script supports more sophisticated interpretation of input data
If --domain
is passed in, the first value on each line of input is interpreted as the X-value for the rest of the data on that line. Without --domain
the X-value is the line number, and the first value on a line is a plain data point like the others. Default is --nodomain
. Thus the original example above produces 2 curves, with 1,2,3,4,5 as the X-values. If we run the same command with --domain
:
$ seq 5 | awk '{print 2*$1, $1*$1}' | feedgnuplot --domain
we get only 1 curve, with 2,4,6,8,10 as the X-values. As many points as desired can appear on a single line, but all points on a line are associated with the X-value at the start of that line.
We index the curves in one of 3 ways: sequentially, explicitly with a --dataid
or by --vnlog
headers.
By default, each column represents a separate curve. The first column (after any domain) is curve 0
. The next one is curve 1
and so on. This is fine unless sparse data is to be plotted. With the --dataid
option, each point is represented by 2 values: a string identifying the curve, and the value itself. If we add --dataid
to the original example:
$ seq 5 | awk '{print 2*$1, $1*$1}' | feedgnuplot --dataid --autolegend
we get 5 different curves with one point in each. The first column, as produced by awk
, is 2,4,6,8,10. These are interpreted as the IDs of the curves to be plotted.
If we're plotting vnlog
data (https://www.github.com/dkogan/vnlog) then we can get the curve IDs from the vnlog header. Vnlog is a trivial data format where lines starting with #
are comments and the first comment contains column labels. If we have such data, feedgnuplot --vnlog
can interpret these column labels if the vnlog
perl modules are available.
The --autolegend
option adds a legend using the given IDs to label the curves. The IDs need not be numbers; generic strings are accepted. As many points as desired can appear on a single line. --domain
can be used in conjunction with --dataid
or --vnlog
.
Depending on how gnuplot is plotting the data, more than one value may be needed to represent the range of a single point. Basic 2D plots have 2 numbers representing each point: 1 domain and 1 range. But if plotting with --circles
, for instance, then there's an extra range value: the radius. Many other gnuplot styles require more data: errorbars, variable colors (with points palette
), variable sizes (with points ps variable
), labels and so on. The feedgnuplot tool itself does not know about all these intricacies, but they can still be used, by specifying the specific style with --style
, and specifying how many values are needed for each point with any of --rangesizeall
, --tuplesizeall
, --rangesize
, --tuplesize
. These options are required only for styles not explicitly supported by feedgnuplot; supported styles do the right thing automatically.
Specific example: if making a 2d plot of y error bars, the exact format can be queried by running gnuplot
and invoking help yerrorbars
. This tells us that there's a 3-column form: x y ydelta
and a 4-column form: x y ylow yhigh
. With 2d plots feedgnuplot will always output the 1-value domain x
, so the rangesize is 2 and 3 respectively. Thus the following are equivalent:
$ echo '1 2 0.3
2 3 0.4
3 4 0.5' | feedgnuplot --domain --rangesizeall 2 --with 'yerrorbars'
$ echo '1 2 0.3
2 3 0.4
3 4 0.5' | feedgnuplot --domain --tuplesizeall 3 --with 'yerrorbars'
$ echo '1 2 1.7 2.3
2 3 2.6 3.4
3 4 3.5 4.5' | feedgnuplot --domain --rangesizeall 3 --with 'yerrorbars'
To plot 3D data, pass in --3d
. --domain
MUST be given when plotting 3D data to avoid domain ambiguity. If 3D data is being plotted, there are by definition 2 domain values instead of one (Z as a function of X and Y instead of Y as a function of X). Thus the first 2 values on each line are interpreted as the domain instead of just 1. The rest of the processing happens the same way as before.
If the input data domain is a time/date, this can be interpreted with --timefmt
. This option takes a single argument: the format to use to parse the data. The format is documented in 'set timefmt' in gnuplot, although the common flags that strftime
understands are generally supported. The backslash sequences in the format are not supported, so if you want a tab, put in a tab instead of \t. Whitespace in the format is supported. When this flag is given, some other options act a little bit differently:
--xlen
and--binwidth
are integers in seconds--xmin
and--xmax
must use the format passed in to--timefmt
Using this option changes both the way the input is parsed and the way the x-axis tics are labelled. Gnuplot tries to be intelligent in this labelling, but it doesn't always do what the user wants. The labelling can be controlled with the gnuplot set format
command, which takes the same type of format string as --timefmt
. Example:
$ sar 1 -1 |
awk '$1 ~ /..:..:../ && $8 ~/^[0-9\.]*$/ {print $1,$8; fflush()}' |
feedgnuplot --stream --domain
--lines --timefmt '%H:%M:%S'
--set 'format x "%H:%M:%S"'
This plots the 'idle' CPU consumption against time.
Note that while gnuplot supports the time/date on any axis, feedgnuplot currently supports it only as the x-axis domain. This may change in the future.
We just described how feedgnuplot parses its input data. When passing this data to gnuplot, each curve is sent independently. The domain appears in the leading columns followed by --rangesize
columns to complete each row. Without --domain
, feedgnuplot explicitly writes out sequential integers. gnuplot then knows how many values it has for each point, and it knows which style we're using, so it's able to interpret the data appropriately, and to make the correct plot.
As an example, if gnuplot is passed 2 columns of data, and it is plotting with points
, it will use column 1 for the x coordinate and column 2 for the y coordinate. This is the default behavior, but the meaning of each column can be controlled via a using
expression in gnuplot (not feedgnuplot; keep reading). The default is sequential integers, so this example uses using 1:2
by default. We can flip the meaning of the columns by passing using 2:1
. Arbitrary expressions may be specified by enclosing each field in ()
, and using $
to denote each data column. So to use the 2nd column as the x coordinate and the sum of the two columns as the y coordinate, using 2:($1+$2)
is passed. Furthermore, the number of columns can vary. For instance gnuplot can read the same two columns of data, but produce a plot with the extra column encoding the sum as the color: using 1:2:($1+$2) with points palette
. Please see the gnuplot documentation for lots of detail.
That's how gnuplot works. Most of the time, feedgnuplot doesn't pass any using
expressions at all, and gnuplot does the default thing. But if we want to do something fancy, feedgnuplot supports --using curveID expression
and --usingall expression
. So we can plot a parabola:
seq 100 | feedgnuplot --lines --usingall '1:($2*$2)'
This is powerful, but there are some things to keep in mind:
--using
overrides whateverusing
expression feedgnuplot was going to pass. feedgnuplot passes ausing
expression only if--histogram
or--timefmt
or--xticlabels
are given. So if--using
is given together with any of these, the user must take care to do the right thing (whatever that means at that time).The
--tuplesize
controls the data passed to feedgnuplot and the data then passed to gnuplot. It does not directly control how gnuplot eventually interprets the data:--using
does that. So for instance we can plot color-coded points:seq 10 | feedgnuplot --with 'points pt 7 palette' --usingall '1:2:2'
Here feedgnuplot read 1 column of data. It defauled to
--tuplesize 2
, so it passed 2 columns of data to gnuplot. gnuplot then produced 3 values for each point, and plotted them as indicated with thepoints palette
style.You always need a column of data to generate a curve. You might want to use a
using
expression to plot a time series and its cumulative integral. Theusing
expression can compute the integral, but you must pass in the data twice; once for each curve to plot:seq 100 | \ awk '{print $1,$1}' | \ feedgnuplot \ --cmds 'sum=0' \ --cmds 'accum(x) = (sum=sum+x)' \ --using 1 '1:(accum($2))' \ --lines --y2 1
To plot real-time data, pass in the --stream [refreshperiod]
option. Data will then be plotted as it is received. The plot will be updated every refreshperiod
seconds. If the period isn't specified, a 1Hz refresh rate is used. To refresh at specific intervals indicated by the data, set the refreshperiod to 0 or to 'trigger'. The plot will then only be refreshed when a data line 'replot' is received. This 'replot' command works in both triggered and timed modes, but in triggered mode, it's the only way to replot. Look in "Special data commands" for more information.
To plot only the most recent data (instead of all the data), --xlen windowsize
can be given. This will create an constantly-updating, scrolling view of the recent past. windowsize
should be replaced by the desired length of the domain window to plot, in domain units (passed-in values if --domain
or line numbers otherwise). If the domain is a time/date via --timefmt
, then windowsize
is and integer in seconds. If we're plotting a histogram, then --xlen
causes a histogram over a moving window to be computed. The subtlely here is that with a histogram you don't actually see the domain since only the range is analyzed. But the domain is still there, and can be utilized with --xlen
. With --xlen
we can plot only histograms or only non-histograms.
If we are reading streaming data, the input stream can contain special commands in addition to the raw data. Feedgnuplot looks for these at the start of every input line. If a command is detected, the rest of the line is discarded. These commands are
replot
-
This command refreshes the plot right now, instead of waiting for the next refresh time indicated by the timer. This command works in addition to the timed refresh, as indicated by
--stream [refreshperiod]
. clear
-
This command clears out the current data in the plot. The plotting process continues, however, to any data following the
clear
. exit
-
This command causes feedgnuplot to exit.
The script is able to produce hardcopy output with --hardcopy outputfile
. The output type can be inferred from the filename, if .ps, .eps, .pdf, .svg, .png or .gp is requested. If any other file type is requested, --terminal
must be passed in to tell gnuplot how to make the plot. If --terminal
is passed in, then the --hardcopy
argument only provides the output filename.
The .gp output is special. Instead of asking gnuplot to plot to a particular terminal, writing to a .gp simply dumps a self-executable gnuplot script into the given file. This is similar to what --dump
does, but writes to a file, and makes sure that the file can be self-executing.
This script can be used to enable self-plotting data files. There are several ways of doing this: with a shebang (#!) or with inline perl data.
A self-plotting, executable data file data
is formatted as
$ cat data
#!/usr/bin/feedgnuplot --lines --points
2 1
4 4
6 9
8 16
10 25
12 36
14 49
16 64
18 81
20 100
22 121
24 144
26 169
28 196
30 225
This is the shebang (#!) line followed by the data, formatted as before. The data file can be plotted simply with
$ ./data
The caveats here are that on Linux the whole #! line is limited to 127 characters and that the full path to feedgnuplot must be given. The 127 character limit is a serious limitation, but this can likely be resolved with a kernel patch. I have only tried on Linux 2.6.
Running feedgnuplot --hardcopy plotdata.gp ....
will create a self-executable gnuplot script in plotdata.gp
Perl supports storing data and code in the same file. This can also be used to create self-plotting files:
$ cat plotdata.pl
#!/usr/bin/perl
use strict;
use warnings;
open PLOT, "| feedgnuplot --lines --points" or die "Couldn't open plotting pipe";
while( <DATA> )
{
my @xy = split;
print PLOT "@xy\n";
}
__DATA__
2 1
4 4
6 9
8 16
10 25
12 36
14 49
16 64
18 81
20 100
22 121
24 144
26 169
28 196
30 225
This is especially useful if the logged data is not in a format directly supported by feedgnuplot. Raw data can be stored after the __DATA__ directive, with a small perl script to manipulate the data into a useable format and send it to the plotter.
--
[no]domain
If enabled, the first element of each line is the domain variable. If not, the point index is used
--
[no]dataid
If enabled, each data point is preceded by the ID of the data set that point corresponds to. This ID is interpreted as a string, NOT as just a number. If not enabled, the order of the point is used.
As an example, if line 3 of the input is "0 9 1 20" then
--nodomain --nodataid
would parse the 4 numbers as points in 4 different curves at x=3--domain --nodataid
would parse the 4 numbers as points in 3 different curves at x=0. Here, 0 is the x-variable and 9,1,20 are the data values--nodomain --dataid
would parse the 4 numbers as points in 2 different curves at x=3. Here 0 and 1 are the data IDs and 9 and 20 are the data values--domain --dataid
would parse the 4 numbers as a single point at x=0. Here 9 is the data ID and 1 is the data value. 20 is an extra value, so it is ignored. If another value followed 20, we'd get another point in curve ID 20
--vnlog
Vnlog is a trivial data format where lines starting with
#
are comments and the first comment contains column labels. Some tools for working with such data are available from thevnlog
project: https://www.github.com/dkogan/vnlog. With thevnlog
perl modules installed, we can read the vnlog column headers withfeedgnuplot --vnlog
. This replaces--dataid
, and we can do all the normal things with these headers. For instancefeedgnuplot --vnlog --autolegend
will generate plot legends for each column in the vnlog, using the vnlog column label in the legend.--[no]3d
Do [not] plot in 3D. This only makes sense with
--domain
. Each domain here is an (x,y) tuple--
timefmt [format]
Interpret the X data as a time/date, parsed with the given format
--colormap
This is a legacy option used to who a colormapped xy plot. It does:
- Adds
palette
to--curvestyleall
- Adds 1 to the default
--tuplesize
(if--tuplesizeall
is not given- Uses
--zmin
,--zmax
to set the colorbar rangeIt's clearer to set the relevant options explicitly, but
--colormap
still exists for compatibility--stream [period]
Plot the data as it comes in, in realtime. If period is given, replot every period seconds. If no period is given, replot at 1Hz. If the period is given as 0 or 'trigger', replot only when the incoming data dictates this. See the "Real-time streaming data" section of the man page.
--[no]lines
Do [not] draw lines to connect consecutive points
--[no]points
Do [not] draw points
--circles
Plot with circles. This requires a radius be specified for each point. Automatically sets the
--rangesize
/--tuplesize
.Not
supported for 3d plots.--title xxx
Set the title of the plot
--legend curveID legend
Set the label for a curve plot. Use this option multiple times for multiple curves. With
--dataid
, curveID is the ID. Otherwise, it's the index of the curve, starting at 0--autolegend
Use the curve IDs for the legend. Titles given with
--legend
override these--xlen xxx
When using
--stream
, sets the size of the x-window to plot. Omit this or set it to 0 to plot ALL the data. Does not make sense with 3d plots. Implies--monotonic
. If we're plotting a histogram, then--xlen
causes a histogram over a moving window to be computed. The subtlely here is that with a histogram you don't actually see the domain since only the range is analyzed. But the domain is still there, and can be utilized with--xlen
. With--xlen
we can plot only histograms or only non-histograms.--xmin/xmax/x2min/x2max/ymin/ymax/y2min/y2max/zmin/zmax xxx
Set the range for the given axis. These x-axis bounds are ignored in a streaming plot. The x2/y2-axis bounds do not apply in 3d plots. The z-axis bounds apply only to 3d plots or colormaps. Note that there is no
--xrange
to set both sides at once or--xinv
to flip the axis around: anything more than the basics supported in this option is clearly obtainable by talking to gnuplot, for instance--set 'xrange [20:10]'
to set the given inverted bounds.--xlabel/x2label/ylabel/y2label/zlabel/cblabel xxx
Label the given axis. The x2/y2-axis labels do not apply to 3d plots while the z-axis label applies only to 3d plots. The "cblabel" applies to the colorbar, if there is one.
--x2/--y2/--x1y2/--x2y1/--x2y2 xxx
By default data is plotted against the x1 and y1 axes (the left and bottom one respectively). If we want a particular curve plotted against a different axis, we can specify that with these options. You pass
--AXIS ID
whereAXIS
defines the axis (x2
ory2
orx1y2
orx2y1
orx2y2
) and theID
is the curve ID.--x2
is a synonym for--x2y1
and--y2
is a synonym for--x1y2
. The curve ID is an ordered 0-based index or a specific ID if--dataid
or--vnlog
. None of these apply to 3d plots. Can be passed multiple times for different curve IDs, multiple IDs can be passed in as a comma-separated list. By default the curves plotted against the various axes aren not drawn in any differentiated way: the viewer of the resulting plot has to be told which is which via an axes label, legend, colors, etc. Prior to version 1.25 offeedgnuplot
the curves plotted on the y2 axis were drawn with a thicker line. This is no longer the case, but that behavior can be brought back by passing something like--y2 curveid --style curveid 'linewidth 3'
--histogram curveID
Set up a this specific curve to plot a histogram. The bin width is given with the
--binwidth
option (assumed 1.0 if omitted). If a drawing style is not specified for this curve (--curvestyle
) or all curves (--with
,--curvestyleall
) then the default histogram style is set: filled boxes with borders. This is what the user generally wants. This works with--domain
and/or--stream
, but in those cases the x-value is used only to cull old data because of--xlen
or--monotonic
. I.e. the domain values are not drawn in any way. Can be passed multiple times, or passed a comma- separated list--xticlabels
If given, the x-axis tic labels are not numerical, but are read from the data. This changes the interpretation of the input data: with
--domain
, each line begins withx label ....
. Without--domain
, each line begins withlabel ...
. Clearly, the labels may not contain whitespace. This does not affect the tuple size. This makes sense only without--3d
. Please see the guide (https://github.com/dkogan/feedgnuplot/blob/master/guide/guide.org) for usage examples.--binwidth width
The width of bins when making histograms. This setting applies to ALL histograms in the plot. Defaults to 1.0 if not given.
--histstyle style
Normally, histograms are generated with the 'smooth frequency' gnuplot style.
--histstyle
can be used to select differentsmooth
settings (see the gnuplothelp smooth
page for more info). Allowed values are 'frequency' (the default), 'fnormal' (available in very recent gnuplots), 'unique', 'cumulative' and 'cnormal'. 'fnormal' is a normalized histogram. 'unique' indicates whether a bin has at least one item in it: instead of counting the items, it'll always report 0 or 1. 'cumulative' is the integral of the 'frequency' histogram. 'cnormal' is like 'cumulative', but rescaled to end up at 1.0.--style curveID style
Additional styles per curve. With
--dataid
, curveID is the ID. Otherwise, it's the index of the curve, starting at 0. curveID can be a comma-separated list of IDs to which the given style should apply. Use this option multiple times for multiple curves.--styleall
does not apply to curves that have a--style
.--curvestyle curveID
Synonym for
--style
--styleall xxx
Additional styles for all curves that have no
--style
. This is overridden by any applicable--style
. Exclusive with--with
.--curvestyleall xxx
Synonym for
--styleall
--with xxx
Same as
--styleall
, but prefixed with "with". Thus--with boxes
is equivalent to
--styleall 'with boxes'
Exclusive with
--styleall
.--every curveID factor
Decimates the input. Instead of plotting every point in the given curve, plot one point per factor. This is useful to quickly process huge datasets. For instance, to plot 1% of the data, pass a factor of 100.
--everyall factor
Decimates the input. This works exactly like
--every
, except it applies to all the curves.--using curveID expression
Specifies a
using
expression to micromanage the plot. This is a powerful option that allows gnuplot to interpret the input data in arbitrary ways. Ausing
expression tells gnuplot how to map the input columns of data to tuples expected by the plotting style. Please see the "'using' expressions" section above for more detail.--usingall expression
Global "using" expressions. This works exactly like
--using
, except it applies to all the curves.--cmds xxx
Additional commands to pass on to gnuplot verbatim. These could contain extra global styles for instance. Can be passed multiple times.
--extracmds xxx
Synonym for
--cmds xxx
--set xxx
Additional 'set' commands to pass on to gnuplot verbatim.
--set 'a b c'
will result in gnuplot seeing aset a b c
command. Can be passed multiple times.--unset xxx
Additional 'unset' commands to pass on to gnuplot verbatim.
--unset 'a b c'
will result in gnuplot seeing aunset a b c
command. Can be passed multiple times.--image filename
Overlays the data on top of a raster image given in
filename
. This is passed through to gnuplot via--equation
, and is not interpreted byfeedgnuplot
other than checking for existence. Usually images have their origin at the top-left corner, while plots have it in the bottom-left corner instead. Thus if the y-axis extents are not specified (--ymin
,--ymax
,--set 'yrange ...'
) this option will also flip around the y axis to make the image appear properly. Since this option is just a passthrough to gnuplot, finer control can be achieved by passing in--equation
and--set yrange ...
directly.--equation xxx
Gnuplot can plot both data and symbolic equations.
feedgnuplot
generally plots data, but with this option can plot symbolic equations also. This is generally intended to augment data plots, since for equation-only plots you don't needfeedgnuplot
.--equation
can be passed multiple times for multiple equations. The given strings are passed to gnuplot directly without anything added or removed, so styling and such should be applied in the string. A basic example:seq 100 | awk '{print $1/10, $1/100}' | feedgnuplot --with 'lines lw 3' --domain --ymax 1 --equation 'sin(x)/x' --equation 'cos(x)/x with lines lw 4'
Here I plot the incoming data (points along a line) with the given style (a line with thickness 3), and I plot two damped sinusoids on the same plot. The sinusoids are not affected by
feedgnuplot
styling, so their styles are set separately, as in this example. More complicated example:seq 360 | perl -nE '$th=$_/360 * 3.14*2; $c=cos($th); $s=sin($th); say "$c $s"' | feedgnuplot --domain --square --set parametric --set "trange [0:2*3.14]" --equation "sin(t),cos(t)"
Here the data I generate is points along the unit circle. I plot these as points, and I also plot a true circle as a parametric equation.
--equation-below xxx
Synonym for
--equation
. These are rendered below all the other data.--equation-above xxx
Like
--equation
, but is rendered on top of all the other data.--square
Plot data with aspect ratio 1. For 3D plots, this controls the aspect ratio for all 3 axes
--square-xy
For 3D plots, set square aspect ratio for ONLY the x,y axes
--hardcopy xxx
If not streaming, output to a file specified here. Format inferred from filename, unless specified by
--terminal
. If--terminal
is given,--hardcopy
sets only the output filename.--terminal xxx
String passed to 'set terminal'. No attempts are made to validate this.
--hardcopy
sets this to some sensible defaults if--hardcopy
is set to a filename ending in.png
,.pdf
,.ps
,.eps
or.svg
. If any other file type is desired, use both--hardcopy
and--terminal
--maxcurves N
The maximum allowed number of curves. This is 100 by default, but can be reset with this option. This exists purely to prevent perl from allocating all of the system's memory when reading bogus data
--monotonic
If
--domain
is given, checks to make sure that the x-coordinate in the input data is monotonically increasing. If a given x-variable is in the past, all data currently cached for this curve is purged. Without--monotonic
, all data is kept. Does not make sense with 3d plots. No--monotonic
by default. The data is replotted before being purged. This is useful in streaming plots where the incoming data represents multiple iterations of the same process (repeated simulations of the same period in time, for instance).--rangesize curveID N
The options
--rangesizeall
and--rangesize
set the number of values are needed to represent each point being plotted (see "Multi-value style support" above). These options are only needed if unknown styles are used, with--styleall
or--with
for instance.--rangesize
is used to set how many values are needed to represent the range of a point for a particular curve. This overrides any defaults that may exist for this curve only.With
--dataid
, curveID is the ID. Otherwise, it's the index of the curve, starting at 0. curveID can be a comma-separated list of IDs to which the given rangesize should apply.--tuplesize curveID N
Very similar to
--rangesize
, but instead of specifying the range only, this specifies the whole tuple. For instance if we're plotting circles, the tuplesize is 3:x,y,radius
. In a 2D plot there's a 1-dimensional domain:x
, so the rangesize is 2:y,radius
. This dimensionality can be given either way.--rangesizeall N
Like
--rangesize
, but applies to all the curves.--tuplesizeall N
Like
--tuplesize
, but applies to all the curves.--dump
Instead of printing to gnuplot, print to STDOUT. Very useful for debugging. It is possible to send the output produced this way to gnuplot directly.
--exit
This controls what happens when the input data is exhausted, or when some part of the
feedgnuplot
pipeline is killed. This option does different things depending on whether--stream
is active, so read this closely.With interactive gnuplot terminals (qt, x11, wxt), the plot windows live in a separate process from the main
gnuplot
process. It is thus possible for the maingnuplot
process to exit, while leaving the plot windows up (a caveat is that such decapitated windows aren't interactive). There are 3 possible states of the polotting pipeline:- Alive:
feedgnuplot
,gnuplot
alive, plot window process alive, no shell prompt (shell busy withfeedgnuplot
) - Half-alive:
feedgnuplot
,gnuplot
dead, plot window process alive (but non-interactive), shell prompt available - Dead:
feedgnuplot
,gnuplot
dead, plot window process dead, shell prompt available
The possibilities are:
- No
--stream
, all data read in -
- no
--exit
(default) -
Alive. Need to Ctrl-C to get back into the shell
--exit
-
Half-alive. Non-interactive prompt up, and the shell accepts new commands. Without
--stream
the goal is to show a plot, so a Dead state would not be useful.
- no
--stream
, all data read in or thefeedgnuplot
process terminated-
- no
--exit
(default) -
Alive. Need to Ctrl-C to get back into the shell. This means that when making live plots, the first Ctrl-C kills the data feeding process, but leaves the final plot up for inspection. A second Ctrl-C kills feedgnuplot as well.
--exit
-
Dead. No plot is shown, and the shell accepts new commands. With
--stream
the goal is to show a plot as the data comes in, which we have been doing. Now that we're done, we can clean up everything.
- no
Note that one usually invokes
feedgnuplot
as a part of a shell pipeline:$ write_data | feedgnuplot
If the user terminates this pipeline with ^C, then all the processes in the pipeline receive SIGINT. This normally kills
feedgnuplot
and all itsgnuplot
children, and we let this happen unless--stream
and no--exit
. If--stream
and no--exit
, then we ignore the first ^C. The data feeder dies, and we behave as if the input data was exhausted. A second ^C kills us also.- Alive:
--geometry
Specifies the size, position of the plot window. This applies only to the
x11
gnuplot terminal, and has no effect otherwise. To control the window size for any other terminal, ask for the terminal explicitly, with the options specifying the size. For instance--terminal 'qt size 1024,768'
--version
Print the version and exit
For a tutorial and a gallery please see the guide at https://github.com/dkogan/feedgnuplot/blob/master/guide/guide.org
$ seq 5 | awk '{print 2*$1, $1*$1}'
2 1
4 4
6 9
8 16
10 25
$ seq 5 | awk '{print 2*$1, $1*$1}' |
feedgnuplot --lines --points --legend 0 "data 0" --title "Test plot" --y2 1
Looks at wlan0 on Linux.
$ while true; do sleep 1; cat /proc/net/dev; done |
gawk '/wlan0/ {if(b) {print $2-b; fflush()} b=$2}' |
feedgnuplot --lines --stream --xlen 10 --ylabel 'Bytes/sec' --xlabel seconds
Uses the result of the acpi
command.
$ while true; do acpi; sleep 15; done |
perl -nE 'BEGIN{ $| = 1; } /([0-9]*)%/; say join(" ", time(), $1);' |
feedgnuplot --stream --ymin 0 --ymax 100 --lines --domain --xlabel 'Time' --timefmt '%s' --ylabel "Battery charge (%)"
Uses /proc/acpi/ibm/thermal
, which reports temperatures at various locations in a Thinkpad.
$ while true; do cat /proc/acpi/ibm/thermal | awk '{$1=""; print}' ; sleep 1; done |
feedgnuplot --stream --xlen 100 --lines --autolegend --ymax 100 --ymin 20 --ylabel 'Temperature (deg C)'
$ ls -l | awk '{print $5/1e6}' |
feedgnuplot --histogram 0
--binwidth 10
--ymin 0 --xlabel 'File size (MB)' --ylabel Frequency
$ ping -D 8.8.8.8 |
perl -anE 'BEGIN { $| = 1; }
$F[0] =~ s/[\[\]]//g or next;
$F[7] =~ s/.*=//g or next;
say "$F[0] $F[7]"' |
feedgnuplot --stream --domain --histogram 0 --binwidth 10 \
--xlabel 'Ping round-trip time (s)' \
--ylabel Frequency --xlen 20
This can be done with --image
:
$ < features_xy.data
feedgnuplot --points --domain --image "image.png"
or with --equation
:
$ < features_xy.data
feedgnuplot --points --domain
--equation '"image.png" binary filetype=auto flipy with rgbimage'
--set 'yrange [:] reverse'
The --image
invocation is a convenience wrapper for the --equation
version. Finer control is available with --equation
.
Here an existing image is given to gnuplot verbatim, and data to plot on top of it is interpreted by feedgnuplot as usual. flipy
is useful here because usually the y axis points up, but when looking at images, this is usually reversed: the origin is the top-left pixel.
This program is originally based on the driveGnuPlots.pl script from Thanassis Tsiodras. It is available from his site at http://users.softlab.ece.ntua.gr/~ttsiod/gnuplotStreaming.html
https://github.com/dkogan/feedgnuplot
Dima Kogan, <dima@secretsauce.net>
Copyright 2011-2021 Dima Kogan.
This program is free software; you can redistribute it and/or modify it under the terms of either: the GNU General Public License as published by the Free Software Foundation; or the Artistic License.
See http://dev.perl.org/licenses/ for more information.