Shell scripting: Difference between revisions
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=== What is this? === | |||
This page contains information about Shell scripting for GRASS GIS. | This page contains information about Shell scripting for GRASS GIS. | ||
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''Note, content below transfered here from the page [http://grasswiki.osgeo.org/wiki/GRASS_and_Shell GRASS and Shell]'' | ''Note, content below transfered here from the page [http://grasswiki.osgeo.org/wiki/GRASS_and_Shell GRASS and Shell].'' | ||
=== Scripting for GRASS === | |||
It is fairly easy to write a GRASS job as Shell script which launches GRASS, does the operation and cleans up the temporary files. | |||
Often, it is convenient to automate repeated jobs. GRASS can be controlled via user scripts to facilitate daily work. How to start? Using the command line is a kind of writing scripts without saving them - so, you may start to write '''your first script''' by saving the executed commands in a text file (use your preferred editor to do so, ideally save the script file in ASCII format). | |||
'''Important Note''': if you don't know shell programming and consider to learn it, | |||
better look at Python (e.g. [[GRASS and Python]]) to not waste time... | |||
Line 164: | Line 176: | ||
== Best practice shell programming == | == Best practice shell programming == | ||
There are many books on the subject, and the subject will be subjective to personal preference, but here are some tips from fellow wiki users. For patches submitted to GRASS, please follow the code guidelines set out in the SUBMITTING files in the main dir of the source code. | There are many books on the subject, and the subject will be subjective to personal preference, but here are some tips from fellow wiki users. For patches submitted to GRASS, please follow the code guidelines set out in the <source lang="bash" enclose="none">SUBMITTING</source> files in the main dir of the source code. | ||
* try to reach 50% of comments, started with # character (see above). Then you will understand your script even after years | * try to reach 50% of comments, started with # character (see above). Then you will understand your script even after years | ||
Line 173: | Line 185: | ||
Error management: | Error management: | ||
A module which terminates with a fatal error will return a non-zero exit status, so you can use the command with | A module which terminates with a fatal error will return a non-zero exit status, so you can use the command with <code>if</code>, <code>||</code>, <code>&&</code> etc, or test the value of <code>$?</code>. | ||
== Inserting coordinates in a raster module from a vector points map == | |||
Some raster modules have an option <code>coordinates=</code>, but don't have the option for selecting them from a vector points map. The following example refers to the module {{cmd|r.viewshed}}. | |||
First, you must have a vector map with the coordinates in the attribute table; if not, add it with {{cmd|v.db.addcolumn}} and {{cmd|v.to.db}}. | |||
=== Example 1: r.viewshed - selecting a single point from vector map === | |||
<source lang="bash"> | |||
#!/bin/bash | |||
# Author: Marco Curreli | |||
# Usage: sh myviewshed.sh cat | |||
# "cat" is the category of the point from the vector map | |||
VECT=myvector | |||
ARG=1 | |||
E_ERR_ARG=65 | |||
if [ $# -ne "$ARG" ] | |||
### Verifies the number of arguments ### | |||
then | |||
echo "Usage: $0 cat" | |||
exit $E_ERR_ARG | |||
fi | |||
# point coordinates | |||
COR=$(v.db.select -c map=$VECT columns=x,y separator=, where="cat = $1") | |||
r.viewshed --verbose -c in=dtm out=visib_$1 coordinate=$COR obs_elev=2.75 memory=3000 stream_dir=tmp | |||
</source> | |||
=== Example 2: r.viewshed - batch process by selecting points from vector map === | |||
<source lang="bash"> | |||
#!/bin/bash | |||
# Author: Marco Curreli | |||
# Usage: sh myviewshed_batch.sh cat1,cat2[,cat3,...] [cat3..catN] | |||
# "cat" is the category of the point from the vector map | |||
# example: to selecting cats 1 3 5 6 7 | |||
# sh myviewshed_batch.sh 1,3 5..7 | |||
VECT=myvector | |||
CAT1=$( | |||
for index in $(eval echo {$1}) | |||
do | |||
echo -n "$index " | |||
done | |||
echo | |||
) | |||
CAT2=$( | |||
for index in $(eval echo {$2}) | |||
do | |||
echo -n "$index " | |||
done | |||
echo | |||
) | |||
ARG=1 | |||
E_ERR_ARG=65 | |||
if [ $# -lt "$ARG" ] | |||
then | |||
echo "Usage: $0 cat1,cat2[,cat3,...] [cat3..catN] | |||
you must specify at least one argument" | |||
exit $E_ERR_ARG | |||
fi | |||
# to working with one or two arguments | |||
if [[ -n $2 ]] | |||
then | |||
CATS=$(echo $CAT1 $CAT2) | |||
else | |||
CATS=$(echo $CAT1) | |||
fi | |||
echo categories: $CATS | |||
# list of categories with their coordinates | |||
for i in $CATS | |||
do | |||
v.db.select -c map=$VECT columns=cat,x,y separator=, where="cat = $i" >> ${VECT}_coord.csv | |||
done | |||
PTI=$(echo $(cat ${VECT}_coord.csv)) | |||
for p in $PTI | |||
do | |||
set -- $p | |||
#coordinates | |||
CORD=$( echo $p | gawk -F "," '{print $2","$3}') | |||
#category | |||
CAT=$( echo $p | gawk -F "," '{print $1}') | |||
r.viewshed --verbose --overwrite in=dtm out=visib_$CAT coordinate=$CORD obs_elev=2.75 memory=1500 stream_dir=tmp | |||
done | |||
rm ${VECT}_coord.csv | |||
</source> | |||
[[Category:FAQ]] | [[Category:FAQ]] |
Latest revision as of 23:16, 19 May 2013
What is this?
This page contains information about Shell scripting for GRASS GIS.
The shell for the Unix and Unix-like operating systems, is essentially a command(-line) interpreter or processor, a text-based user interface through which one can instruct the operating system of a computer. One or more commands can be written in a script (usually a simple text file) which, in turn, can be read and executed by the shell. The most widespread shell is probably bash.
Scripting is the act of designing, writing, testing, debugging, and maintaining a set of commands which perform specific, from simple to complex, tasks.
Note, content below transfered here from the page GRASS and Shell.
Scripting for GRASS
It is fairly easy to write a GRASS job as Shell script which launches GRASS, does the operation and cleans up the temporary files.
Often, it is convenient to automate repeated jobs. GRASS can be controlled via user scripts to facilitate daily work. How to start? Using the command line is a kind of writing scripts without saving them - so, you may start to write your first script by saving the executed commands in a text file (use your preferred editor to do so, ideally save the script file in ASCII format).
Important Note: if you don't know shell programming and consider to learn it, better look at Python (e.g. GRASS and Python) to not waste time...
A first GRASS shell script
Comments should be started with a '#' character. The first line indicates the shell interpreter to be used, here "sh" which is always in the /bin/ directory.
Silly example, run within a GRASS session:
#!/bin/sh
# my first script,
# copyright, year, Author
# plot current region settings
g.region -p
# leave with exit status 0 which means "ok":
exit 0
Save this in a file "myscript.sh" and run it within GRASS GIS from the command line:
sh myscript.sh
It should print the current region settings, finish, and return to the command line.
For shell debugging, run instead:
sh -x myscript.sh
It will echo every line which helps to identify errors.
Example 1: d.rast.region (simple)
Script to set computational region to a raster map ($1 is the parameter given to the script, here map name):
#!/bin/sh
# Author: me, today; copyright: GPL >= 2
# Purpose: Script to set computational region to a raster map
# Usage: d.rast.region rastermap
g.region rast=$1
d.erase
d.rast $1
exit 0
Using the script in a "North Carolina" location GRASS 6 session:
d.mon x0
sh d.rast.region elev_state_500m
sh d.rast.region lsat7_2002_40
Example 2: d.rast.region (improved)
In this example, we assign the first parameter ($1) given to the script (here map name) to a new variable which is easier to understand in the script. Again, the script is setting the computational region to a raster map, but now it says what happens:
#!/bin/sh
# Author: me, today; copyright: GPL >= 2
# Purpose: Script to set computational region to a raster map
# Usage: d.rast.region rastermap
# be careful to not have white space in the next line:
map=$1
g.message message="Setting computational region to map <$map>"
g.region rast=$map
d.erase
d.rast $map
exit 0
Using the script in a "North Carolina" location GRASS 6 session: see Example 1 above.
Example 3: d.rast.region (improved again)
Here we introduce the variable $0 which contains the program name as well as a test to see if the user specified the map to be shown:
#!/bin/sh
# Author: me, today; copyright: GPL >= 2
# Purpose: Script to set computational region to a raster map
# Usage: d.rast.region rastermap
if [ $# -lt 1 ] ; then
echo "Parameter not defined. Usage"
echo " $0 rastermap"
exit 1
fi
map=$1
g.message message="Setting computational region to map <$map>"
g.region rast=$map
d.erase
d.rast $map
exit 0
To see how it works, it is interesting to use shell debugging:
d.mon x0
sh -x d.rast.region elev_state_500m
Example 4: Parameter handling
Assume you want to create a shell script for GRASS that has two parameters (x and y coordinates) in order to calculate the watershed related to this outlet point (r.water.outlet). In shell, the variables $1 $2 and so on are the parameters you pass on to the script. So, if you have a script called basin.sh and you type
sh basin.sh -23.3 -47.7
the variable $1 will be -23.3 and $2 will be -47.6. So in your script basin.sh you could use the line
r.water.outlet drainage="your_map" basin="basin_map" easting=$2 northing=$1
Likewise, you could also pass a third parameter for the basin map name, etc.
However, it is highly recommended to use g.parser for the parameter handling. It is much easier and then even the graphical user interface will be autocreated and standard messages appear already translated! You can clone from existing scripts, see here for a series of examples.
Using output from GRASS modules in the script
Sometimes you need to use the output of a module for the next step in a script. Most of the GRASS modules which produce numeric output offer a "-g" flag to facilitate the parsing of the results. Along with the "eval" shell function you can reduce the effort of using printed output in the next step to a minimum. The trick is that the equal sign is considered as variable assignment in shell:
# North Carolina example inmap=elevation outmap=some_result
Example for common module output:
g.region rast=$inmap r.info -r $inmap min=55.57879 max=156.3299
Using this in a script:
eval `r.info -r $inmap` r.mapcalc "$outmap = float($inmap) / $max"
Verify:
r.info -r $outmap min=0.355522472489405 max=0.999999772928615
Best practice shell programming
There are many books on the subject, and the subject will be subjective to personal preference, but here are some tips from fellow wiki users. For patches submitted to GRASS, please follow the code guidelines set out in the SUBMITTING
files in the main dir of the source code.
- try to reach 50% of comments, started with # character (see above). Then you will understand your script even after years
- add an initial comment about what the script does
- study existing scripts, see here for a series of scripts
Error management:
A module which terminates with a fatal error will return a non-zero exit status, so you can use the command with if
, ||
, &&
etc, or test the value of $?
.
Inserting coordinates in a raster module from a vector points map
Some raster modules have an option coordinates=
, but don't have the option for selecting them from a vector points map. The following example refers to the module r.viewshed.
First, you must have a vector map with the coordinates in the attribute table; if not, add it with v.db.addcolumn and v.to.db.
Example 1: r.viewshed - selecting a single point from vector map
#!/bin/bash
# Author: Marco Curreli
# Usage: sh myviewshed.sh cat
# "cat" is the category of the point from the vector map
VECT=myvector
ARG=1
E_ERR_ARG=65
if [ $# -ne "$ARG" ]
### Verifies the number of arguments ###
then
echo "Usage: $0 cat"
exit $E_ERR_ARG
fi
# point coordinates
COR=$(v.db.select -c map=$VECT columns=x,y separator=, where="cat = $1")
r.viewshed --verbose -c in=dtm out=visib_$1 coordinate=$COR obs_elev=2.75 memory=3000 stream_dir=tmp
Example 2: r.viewshed - batch process by selecting points from vector map
#!/bin/bash
# Author: Marco Curreli
# Usage: sh myviewshed_batch.sh cat1,cat2[,cat3,...] [cat3..catN]
# "cat" is the category of the point from the vector map
# example: to selecting cats 1 3 5 6 7
# sh myviewshed_batch.sh 1,3 5..7
VECT=myvector
CAT1=$(
for index in $(eval echo {$1})
do
echo -n "$index "
done
echo
)
CAT2=$(
for index in $(eval echo {$2})
do
echo -n "$index "
done
echo
)
ARG=1
E_ERR_ARG=65
if [ $# -lt "$ARG" ]
then
echo "Usage: $0 cat1,cat2[,cat3,...] [cat3..catN]
you must specify at least one argument"
exit $E_ERR_ARG
fi
# to working with one or two arguments
if [[ -n $2 ]]
then
CATS=$(echo $CAT1 $CAT2)
else
CATS=$(echo $CAT1)
fi
echo categories: $CATS
# list of categories with their coordinates
for i in $CATS
do
v.db.select -c map=$VECT columns=cat,x,y separator=, where="cat = $i" >> ${VECT}_coord.csv
done
PTI=$(echo $(cat ${VECT}_coord.csv))
for p in $PTI
do
set -- $p
#coordinates
CORD=$( echo $p | gawk -F "," '{print $2","$3}')
#category
CAT=$( echo $p | gawk -F "," '{print $1}')
r.viewshed --verbose --overwrite in=dtm out=visib_$CAT coordinate=$CORD obs_elev=2.75 memory=1500 stream_dir=tmp
done
rm ${VECT}_coord.csv