Difference between revisions of "Tutorial Moodle VPL Tips & Tricks"
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; To remove comments from a '''Java''' program, including /* ... */, /** ... */, and //: | ; To remove comments from a '''Java''' program, including /* ... */, /** ... */, and //: | ||
| + | <br /> | ||
| + | ::<source lang="bash"> | ||
prog1=yourprogramname # the name of the java code, '''without''' the ".java" extension | prog1=yourprogramname # the name of the java code, '''without''' the ".java" extension | ||
cat $prog1.java | sed 's://.*$::g' | sed '/\/\*\*/,/\*\// {s/.*\*\/.*//p; d}' > _$prog1.java | cat $prog1.java | sed 's://.*$::g' | sed '/\/\*\*/,/\*\// {s/.*\*\/.*//p; d}' > _$prog1.java | ||
| − | + | </source> | |
| + | <br /> | ||
; To remove the comments from an assembly program (.asm): | ; To remove the comments from an assembly program (.asm): | ||
| − | + | <br /> | |
| + | ::<source lang="bash"> | ||
prog1=yourprogramname # then name of the asm code, '''without''' the ".asm" extension | prog1=yourprogramname # then name of the asm code, '''without''' the ".asm" extension | ||
cat ${prog1}.asm | sed 's:;.*$::g' > _${prog1}.asm | cat ${prog1}.asm | sed 's:;.*$::g' > _${prog1}.asm | ||
| − | + | </source> | |
| + | <br /> | ||
; To stop programs with endless loops: use '''timeout''' command. | ; To stop programs with endless loops: use '''timeout''' command. | ||
<br /> | <br /> | ||
| − | <source lang="bash"> | + | ::<source lang="bash"> |
| − | + | timeout 30 java \${prog1} < data\${i}.txt &> user.out | |
retcode=\$? | retcode=\$? | ||
Revision as of 11:01, 17 October 2014
--D. Thiebaut (talk) 20:31, 11 June 2014 (EDT)
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This is a collection of tips, tricks, observations, recommendations, and modifications related to using VPL with Moodle.
Tips & Tricks
Bash Quick Solutions
- To remove comments from a Java program, including /* ... */, /** ... */, and //
prog1=yourprogramname # the name of the java code, '''without''' the ".java" extension cat $prog1.java | sed 's://.*$::g' | sed '/\/\*\*/,/\*\// {s/.*\*\/.*//p; d}' > _$prog1.java
- To remove the comments from an assembly program (.asm)
prog1=yourprogramname # then name of the asm code, '''without''' the ".asm" extension cat ${prog1}.asm | sed 's:;.*$::g' > _${prog1}.asm
- To stop programs with endless loops
- use timeout command.
timeout 30 java \${prog1} < data\${i}.txt &> user.out retcode=\$? #--- if we killed the waiter, everything is good --- if [ \$retcode -eq 124 ]; then echo "Comment :=>>-Your program has stopped working." timeoutOutput \$i continue else echo "Comment :=>>-Your program ran to completion." fi
Output of Evaluate Step
- The output of the Evaluate action is a bit illogical:
+------------------------------+ | 3 tests run/ 0 tests failed | +------------------------------+
- To change it into something more intuitive, such as this:
+------------------------------+ | 3 tests run/ 3 tests passed | +------------------------------+
- we simply need to modify the code of vpl_evaluate.cpp on the moodle server, in /var/www/html/moodle/mod/vpl/jail/default_scripts (or whatever directory the vpl files reside).
- The diff of the modification is shown below:
1058,1059c1058,1060
< printf(">| %2d %s run/%2d %s failed |\n",
< nruns, nruns==1?stest[0]:stest[1], nerrors, nerrors==1?stest[0]:stest[1]);
---
> printf(">| %2d %s run/%2d %s passed |\n",
> nruns, nruns==1?stest[0]:stest[1], nruns-nerrors,
> (nruns-nerrors)==1?stest[0]:stest[1]);
Generating a vpl_evaluate.cases File Quickly
- Recommendations
- write a solution program first.
- run it on several cases you want to test your students' programs with.
- capture the outputs of the solution program on different cases. Copy paste into the vpl_evaluate.cases file. Don't worry yet about making it exactly correct.
- evaluate the solution program. You will get mismatches between the generated output and the expected output. Just copy/paste the generated output back into the vpl_evaluate.cases file. You will also be able to include the extra characters generated by the input statements.
- You should be ready to evaluate the solution program and get 100/100 as a grade.
Creating a vpl_execution script that measures the size of a program
Imagine that the assignment for the student is to create a program that solves a particular problem (which can be tested separately for the correctness of its output), but the requirement is to make the program executable as small as possible.
The grade given to the submitted program will be 100 if the size is equal to the size of the solution program, and some lower grade depending on how large the file is.
Here's a bash script that will do the trick
#! /bin/bash # $file contains the name of the executable. The executable # is created by assembling ${file}.asm, generating ${file}.o, # and linking ${file}.o. # The script outputs 0 if the executable crashes, or just # an integer that is the size of the executable, in bytes, if # it runs correctly. file="printStars" # whatever executable is to be tested # assemble and link the executable nasm -f elf -F stabs ${file}.asm ld -melf_i386 -o $file ${file}.o # run the executable in a subshell to catch any segmentation fault error # that may result. { ./$file &> /dev/null ; } &> log # if an error occured, automatically return 0 if [ $? -eq 139 ]; then echo "0"; exit 0; fi # print out the size of the file size=$(stat -c%s "$file") echo $size
The part of the script that reads { ./$file &> /dev/null ; } &> log is a bit complex. The reason for this is that we want to catch a potential crash by the program being tested, prevent it from outputting some segmentation fault message that would have come up, and automatically output 0 for it, and not its size.
If the program runs correctly, its output is discarded and the script simply outputs the size in bytes of the executable.
Creating a vpl_execution Script that Outputs the Grade a Program Based on its Size
This time we take the previous version of vpl_execution and make it output the grade (0 to 100) based on how small the program executable is. The smallest possible size is assumed to be known.
#! /bin/bash # $file contains the name of the executable. The executable # is created by assembling ${file}.asm, generating ${file}.o, # and linking ${file}.o. # The script outputs 0 if the executable crashes, or just # an integer that is the size of the executable, in bytes, if # it runs correctly. file="printStars" # whatever executable is to be tested bestSize=1065 # the size of the executable version of the solution program # in bytes. # assemble and link the executable nasm -f elf -F stabs ${file}.asm ld -melf_i386 -o $file ${file}.o # run the executable in a subshell to catch any segmentation fault error # that may result. { ./$file &> /dev/null ; } &> log # if an error occured, automatically return 0 if [ $? -eq 139 ]; then echo "0"; exit 0; fi # print out the size of the file size=$(stat -c%s "$file") #echo $size # compare size to best size recorded and output # grade based on size. increment=20 # size increment that takes away 10 more points # from the grade # possible grades grades=( 100 90 80 70 60 50 40 30 20 10 0 ) # find bin corresponding to size of executable, based on # $bestSize, and bins of width $increment for i in {0..10} ; do bestSize=$(($bestSize+$increment)) if [ $size -le $bestSize ] ; then echo ${grades[$i]} exit 0 fi done echo "0"
