Using regression tests
Overview
Teaching: 40 min
Exercises: 10 minQuestions
Test-driven development
Objectives
Be able to create and run test files
Understand how test discrepancies and runtime regressions can be identified and interpreted
Understand how to adjust tests to check randomised algorithms
Learn the ‘Make it right, then make it fast’ concept
The code of AvgOrdOfGroup is very simple, and nothing could possibly go wrong
with it. By iterating over the group instead of creating a list of its elements,
it avoids running out of memory
(calling AsList(SymmetricGroup(11)) already results in exceeding the permitted
memory). That said, the computation still takes time, with several minutes
needed to calculate the average order of an
element of SymmetricGroup(11). But at least we are confident that it is
correct.
Now we would like to write a better version of this function using some
theoretical facts we know from Group Theory. We may put
avgord.g under version control to revert changes if need be;
we may create a new function to keep the old one around and compare the
results of both; but this could be made even more efficient if we
use regression testing: this is the term for testing based on
rerunning previously completed tests to check that new changes do not
impact their correctness or worsen their performance.
To start with, we need to create a test file. The test file looks
exactly like a GAP session, so it is easy to create it by copying and
pasting a GAP session with all GAP prompts, inputs and outputs into a
text file (a test file could be also created from a log file with a
GAP session recorded with the help of LogTo). During the test, GAP will
run all inputs from the test file, compare the outputs with those in the test
file and report any differences.
GAP test files are just text files, but the common practice is to name
them with the extension .tst. Now create the file avgord.tst in the current directory (to
avoid typing the full path) with the following content:
# tests for average order of a group element
# permutation group
gap> S:=SymmetricGroup(9);
Sym( [ 1 .. 9 ] )
gap> AvgOrdOfGroup(S);
3291487/362880
As you see, the test file may include comments, with certain rules specifying
where they may be placed, because one should be able to distinguish comments
in the test file from GAP output started with #. For that purpose,
lines at the beginning of the test file that start with #, and one empty line
together with one or more lines starting with #, are considered as comments.
All other lines are interpreted as GAP output from the preceding GAP input.
To run the test, one should use the function Test, as documented
here.
For example (assuming that the function AvgOrdOfGroup is already loaded):
Test("avgord.tst");
true
In this case, Test reported no discrepancies and returned true, so we
conclude that the test has passed.
We will not cover the topic of writing a good and comprehensive test suite here,
nor will we cover the various options of the Test function, allowing us, for
example, to ignore differences in the output formatting, or to display the progress
of the test, as these are described in its documentation.
Instead, we will now add more groups to avgord.tst, to demonstrate that the
code also works with other kinds of groups, and to show various ways of
combining commands in the test file:
# tests for average order of a group element
# permutation group
gap> S:=SymmetricGroup(9);
Sym( [ 1 .. 9 ] )
gap> AvgOrdOfGroup(S);
3291487/362880
# pc group
gap> D:=DihedralGroup(512);
<pc group of size 512 with 9 generators>
gap> AvgOrdOfGroup(D);
44203/512
gap> G:=TrivialGroup();; # suppress output
gap> AvgOrdOfGroup(G);
1
# fp group
gap> F:=FreeGroup("a","b");
<free group on the generators [ a, b ]>
gap> G:=F/ParseRelators(GeneratorsOfGroup(F),"a^8=b^2=1, b^-1ab=a^-1");
<fp group on the generators [ a, b ]>
gap> IsFinite(G);
true
gap> AvgOrdOfGroup(G);
59/16
# finite matrix group over integers
gap> AvgOrdOfGroup( Group( [[0,-1],[1,0]] ) );
11/4
# matrix group over a finite field
gap> AvgOrdOfGroup(SL(2,5));
221/40
Let us test the extended version of the test again and check that it works:
Test("avgord.tst");
true
Now we will work on a better implementation. Of course, the order of an element
is an invariant of a conjugacy class of elements of a group, so we need only to
know the orders of conjugacy classes of elements and their representatives. The
following code, which we add into avgord.g, reads into GAP and redefines
AvgOrdOfGroup without any syntax errors:
AvgOrdOfGroup := function(G)
local cc, sum, c;
cc:=ConjugacyClasses(G);
sum:=0;
for c in cc do
sum := sum + Order( Representative(c) ) * Size(cc);
od;
return sum/Size(G);
end;
but when we run the test, here comes a surprise!
Read("avgord.g");
Test("avgord.tst");
########> Diff in avgord.tst, line 6:
# Input is:
AvgOrdOfGroup(S);
# Expected output:
3291487/362880
# But found:
11/672
########
########> Diff in avgord.tst, line 12:
# Input is:
AvgOrdOfGroup(D);
# Expected output:
44203/512
# But found:
2862481/512
########
########> Diff in avgord.tst, line 23:
# Input is:
AvgOrdOfGroup(G);
# Expected output:
59/16
# But found:
189/16
########
########> Diff in avgord.tst, line 29:
# Input is:
AvgOrdOfGroup(SL(2,5));
# Expected output:
221/40
# But found:
69/20
########
false
Indeed, we made a typo (deliberately) and replaced Size(c) by Size(cc).
The correct version of course should look as follows:
AvgOrdOfGroup := function(G)
local cc, sum, c;
cc:=ConjugacyClasses(G);
sum:=0;
for c in cc do
sum := sum + Order( Representative(c) ) * Size(c);
od;
return sum/Size(G);
end;
Now we will fix this in avgord.g, and read and test it again to check that
the tests run correctly.
Read("avgord.g");
Test("avgord.tst");
true
Thus, the approach ‘Make it right, then make it fast’ helped detect a bug immediately after it has been introduced.
Key Points
It is easy to create a test file by copying and pasting a GAP session.
Writing a good and comprehensive test suite requires some effort.
Make it right, then make it fast!