Apache::TestSmoke(3) User Contributed Perl Documentation Apache::TestSmoke(3)
NAME
Apache::TestSmoke - Special Tests Sequence Failure Finder
SYNOPSIS
# get the usage and the default values
% t/SMOKE -help
# repeat all tests 5 times and try 20 random iterations
# and save the report into the file 'myreport'
% t/SMOKE -times=5 -iterations=20 -report=myreport
# run all tests default number of iterations, and repeat tests
# default number of times
% t/SMOKE
# same as above but work only the specified tests
% t/SMOKE foo/bar foo/tar
# run once a sequence of tests in a non-random mode
# e.g. when trying to reduce a known long sequence that fails
% t/SMOKE -order=rotate -times=1 foo/bar foo/tar
# show me each currently running test
# it's not the same as running the tests in the verbose mode
% t/SMOKE -verbose
# run t/TEST, but show any problems after *each* tests is run
# useful for bug reports (it actually runs t/TEST -start, then
# t/TEST -run for each test separately and finally t/TEST -stop
% t/SMOKE -bug_mode
# now read the created report file
DESCRIPTION
The Problem
When we try to test a stateless machine (i.e. all tests are independent), running all tests once
ensures that all tested things properly work. However when a state machine is tested (i.e. where a
run of one test may influence another test) it's not enough to run all the tests once to know that
the tested features actually work. It's quite possible that if the same tests are run in a different
order and/or repeated a few times, some tests may fail. This usually happens when some tests don't
restore the system under test to its pristine state at the end of the run, which may influence other
tests which rely on the fact that they start on pristine state, when in fact it's not true anymore.
In fact it's possible that a single test may fail when run twice or three times in a sequence.
The Solution
To reduce the possibility of such dependency errors, it's helpful to run random testing repeated many
times with many different srand seeds. Of course if no failures get spotted that doesn't mean that
there are no tests inter-dependencies, which may cause a failure in production. But random testing
definitely helps to spot many problems and can give better test coverage.
Resolving Sequence Problems
When this kind of testing is used and a failure is detected there are two problems:
1. First is to be able to reproduce the problem so if we think we fixed it, we could verify the fix.
This one is easy, just remember the sequence of tests run till the failed test and rerun the same
sequence once again after the problem has been fixed.
2. Second is to be able to understand the cause of the problem. If during the random test the
failure has happened after running 400 tests, how can we possibly know which previously running
tests has caused to the failure of the test 401. Chances are that most of the tests were clean
and don't have inter-dependency problem. Therefore it'd be very helpful if we could reduce the
long sequence to a minimum. Preferably 1 or 2 tests. That's when we can try to understand the
cause of the detected problem.
This utility attempts to solve both problems, and at the end of each iteration print a minimal
sequence of tests causing to a failure. This doesn't always succeed, but works in many cases.
This utility:
1. Runs the tests randomly until the first failure is detected. Or non-randomly if the option -order
is set to repeat or rotate.
2. Then it tries to reduce that sequence of tests to a minimum, and this sequence still causes to
the same failure.
3. (XXX: todo): then it reruns the minimal sequence in the verbose mode and saves the output.
4. It reports all the successful reductions as it goes to STDOUT and report file of the format:
smoke-report-<date>.txt.
In addition the systems build parameters are logged into the report file, so the detected
problems could be reproduced.
5. Goto 1 and run again using a new random seed, which potentially should detect different failures.
Reduction Algorithm
Currently for each reduction path, the following reduction algorithms get applied:
1. Binary search: first try the upper half then the lower.
2. Random window: randomize the left item, then the right item and return the items between these
two points.
t/SMOKE.PL
t/SMOKE.PL is driving this module, if you don't have it, create it:
#!perl
use strict;
use warnings FATAL => 'all';
use FindBin;
use lib "$FindBin::Bin/../Apache-Test/lib";
use lib "$FindBin::Bin/../lib";
use Apache::TestSmoke ();
Apache::TestSmoke->new(@ARGV)->run;
usually Makefile.PL converts it into t/SMOKE while adjusting the perl path, but you create t/SMOKE in
first place as well.
AUTHOR
Stas Bekman
perl v5.8.8 2005-10-20 Apache::TestSmoke(3)
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