Provided by: libtest-memorygrowth-perl_0.04-1_all 
NAME
"Test::MemoryGrowth" - assert that code does not cause growth in memory usage
SYNOPSIS
use Test::More;
use Test::MemoryGrowth;
use Some::Class;
no_growth {
my $obj = Some::Class->new;
} 'Constructing Some::Class does not grow memory';
my $obj = Some::Class->new;
no_growth {
$obj->do_thing;
} 'Some::Class->do_thing does not grow memory';
#### This test will fail ####
my @list;
no_growth {
push @list, "Hello world";
} 'pushing to an array does not grow memory';
done_testing;
DESCRIPTION
This module provides a function to check that a given block of code does not result in the
process consuming extra memory once it has finished. Despite the name of this module it
does not, in the strictest sense of the word, test for a memory leak: that term is
specifically applied to cases where memory has been allocated but all record of it has
been lost, so it cannot possibly be reclaimed. While the method employed by this module
can detect such bugs, it can also detect cases where memory is still referenced and
reachable, but the usage has grown more than would be expected or necessary.
The block of code will be run a large number of times (by default 10,000), and the
difference in memory usage by the process before and after is compared. If the memory
usage has now increased by more than one byte per call, then the test fails.
In order to give the code a chance to load initial resources it needs, it will be run a
few times first (by default 10); giving it a chance to load files, AUTOLOADs, caches, or
any other information that it requires. Any extra memory usage here will not count against
it.
This simple method is not a guaranteed indicator of the absence of memory resource bugs
from a piece of code; it has the possibility to fail in both a false-negative and a false-
positive way.
False Negative
It is possible that a piece of code causes memory usage growth that this module does
not detect. Because it only detects memory growth of at least one byte per call, it
cannot detect cases of linear memory growth at lower rates than this. Most memory
usage growth comes either from Perl-level or C-level bugs where memory objects are
created at every call and not reclaimed again. (These are either genuine memory
leaks, or needless allocations of objects that are stored somewhere and never
reclaimed). It is unlikely such a bug would result in a growth rate smaller than one
byte per call.
A second failure case comes from the fact that memory usage is taken from the
Operating System's measure of the process's Virtual Memory size, so as to be able to
detect memory usage growth in C libraries or XS-level wrapping code, as well as Perl
functions. Because Perl does not aggressively return unused memory to the Operating
System, it is possible that a piece of code could use un-allocated but un-reclaimed
memory to grow into; resulting in an increase in its requirements despite not
requesting extra memory from the Operating System.
False Positive
It is possible that the test will claim that a function grows in memory, when the
behaviour is in fact perfectly normal for the code in question. For example, the code
could simply be some function whose behaviour is required to store extra state; for
example, adding a new item into a list. In this case it is in fact expected that the
memory usage of the process will increase.
By careful use of this test module, false indications can be minimised. By splitting tests
across many test scripts, each one can be started in a new process state, where most of
the memory assigned from the Operating System is in use by Perl, so anything extra that
the code requires will have to request more. This should reduce the false negative
indications.
By keeping in mind that the module simply measures the change in allocated memory size,
false positives can be minimised, by not attempting to assert that certain pieces of code
do not grow in memory, when in fact it would be expected that they do.
Devel::Gladiator Integration
Since version 0.04.
If Devel::Gladiator is installed, this test module will use it as a second potential
source of detecting memory growth. A walk of the Perl memory heap is taken before running
the code, in order to count the number of every kind of object present. This is then
compared to a second count taken afterwards. Any object types that have increased by at
least one per call are reported.
For example, the output might contain the following extra lines of diagnostic output:
# Growths in arena object counts:
# ARRAY 1735 -> 11735 (1.00 per call)
# HASH 459 -> 10459 (1.00 per call)
# REF 1387 -> 21387 (2.00 per call)
# REF-ARRAY 163 -> 10163 (1.00 per call)
# REF-HASH 66 -> 10066 (1.00 per call)
# WithContainerSlots 10 -> 10010 (1.00 per call)
Devel::MAT Integration
If Devel::MAT is installed, this test module will use it to dump the state of the memory
after a failure. It will create a .pmat file named the same as the unit test, but with the
trailing .t suffix replaced with -TEST.pmat where "TEST" is the number of the test that
failed (in case there was more than one). It will then run the code under test one more
time, before writing another file whose name is suffixed with -TEST-after.pmat. This pair
of files may be useful for differential analysis.
FUNCTIONS
no_growth
no_growth { CODE } %opts, $name
Assert that the code block does not consume extra memory.
Takes the following named arguments:
calls => INT
The number of times to call the code during growth testing.
burn_in => INT
The number of times to call the code initially, before watching for memory usage.
TODO
• Don't be Linux Specific
Currently, this module uses a very Linux-specific method of determining process
memory usage (namely, by inspecting /proc/self/status). This should really be
fixed to some OS-neutral abstraction. Currently I am unaware of a simple portable
mechanism to query this. Patches very much welcome. :)
AUTHOR
Paul Evans <leonerd@leonerd.org.uk>