Task::MemManager - A memory allocated and manager for low level code in Perl.
version 0.01
use Task::MemManager;
my $mem_manager = Task::MemManager->new(10, 1, { allocator => 'PerlAlloc' });
my $buffer = $mem_manager->get_buffer();
my $buffer_size = $mem_manager->get_buffer_size();
my $element_size = $mem_manager->get_element_size();
my $num_of_elements = $mem_manager->get_num_of_elements();
my $region = $mem_manager->extract_buffer_region($pos_start, $pos_end);
my $delayed_gc_objects = $mem_manager->get_delayed_gc_objects();
Task::MemManager is a memory allocator and manager designed for low level code in Perl. It provides functionalities to allocate, manage, and manipulate memory buffers.
Purpose : Allocates a buffer using a specified allocator.
Returns : A reference to the buffer.
Parameters :
- $num_of_items: Number of items in the buffer.
- $size_of_each_item: Size of each item in the buffer.
- \%opts: Reference to a hash of options. These are:
- allocator: Name of the allocator to use.
- delayed_gc: Should garbage collection be delayed?
- init_value: Value to initialize the buffer with (byte, non UTF!).
- death_stub: Function to call upon object destruction (if any).
Throws : Croaks if the buffer allocation fails.
Comments : Default allocator is PerlAlloc, which uses Perl's string functions.
Default init_value is undef ('zero' zeroes out memory,
any other byte value will initialize memory with that value).
Default delayed_gc is 0 (garbage collection is immediate).
Usage : my $region = Task::MemManager->extract_buffer_region($pos_start, $pos_end);
Purpose : Extracts a region of the buffer.
Returns : A Perl string (null terminated) containing the region.
Parameters :
- $pos_start: The starting position of the region.
- $pos_end: The ending position of the region.
Throws : n/a
Comments : Returns undef if attempt to overrun buffer, or if $pos_start > $pos_end.
Usage : my $buffer = Task::MemManager->get_buffer();
Purpose : Returns the memory address of the buffer.
Returns : The memory address of the buffer as an unsigned integer.
Parameters : n/a
Throws : n/a
Comments : None.
Usage : my $buffer_size = Task::MemManager->get_buffer_size();
Purpose : Returns the size of the buffer.
Returns : The size of the buffer in bytes.
Parameters : n/a
Throws : n/a
Comments : None.
Usage : my $element_size = Task::MemManager->get_element_size();
Purpose : Returns the size of each element in the buffer.
Returns : The size of each element in bytes.
Parameters : n/a
Throws : n/a
Comments : None.
Usage : my $num_of_elements = Task::MemManager->get_num_of_elements();
Purpose : Returns the number of elements in the buffer.
Returns : The number of elements in the buffer.
Parameters : n/a
Throws : n/a
Comments : None.
Usage : my $delayed_gc_objects = Task::MemManager->get_delayed_gc_objects();
Purpose : Obtains a list of objects that have delayed garbage collection.
Returns : A reference to an array of objects with delayed GC.
Parameters : n/a
Throws : n/a
Comments : None.
We will illustrate the use of these methods with multiple examples. These will cover issues like the allocation of memory, the extraction of regions from the buffer, constant (to the eyes of Perl) memory allocation, delayed garbage collection, and the use of a death stub, which is a function that is called upon object destruction and may be used to perform e.g. logging or cleanup , operations other than freeing the memory buffer itself. The examples are best run sequentially in a single Perl script.
use Task::MemManager;
## uses the default allocator PerlAlloc
my $memdeath = Task::MemManager->new(
40, 1,
{
init_value => 'zero',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
}
);
my $mem = Task::MemManager->new(
20, 1,
{
init_value => 'A',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
allocator => 'CMalloc',
}
);
my $mem = Task::MemManager->new(
20, 1,
{
init_value => 'A',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
allocator => 'CMalloc',
}
);
Print the buffer objects
printf( "%10s object is %s\n", ' memdeath', $memdeath );
printf( "%10s object is %s\n", ' mem', $mem );
Killing the buffer should give you a message from the death stub
undef $memdeath;
Attempting to under (or in general modify a constant or a Readonly) memory buffer will kill the script. Note that these buffers can be modified outside of Perl (including the Perl API) but not inside the main Perl script. Such buffers are useful for keeping a constant (in space) buffer throughout the lifetime of the script. Attempt to modify them from within Perl, will kill the script at *runtime* uncovering the modification attempt.
use Const::Fast; ## may also use Readonly mutatis mutandis
const my $mem_cp2 => Task::MemManager->new(
20, 1,
{
init_value => 'D',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
allocator => 'CMalloc',
}
);
undef $mem_cp2; # This will kill the script
First we will define a subroutine that will print the extracted region in a nicely formated hexadecimal format.
sub print_hex_values {
my ( $string, $bytes_per_line ) = @_;
$bytes_per_line //= 8; # Default to 8 bytes per line if not provided
my @bytes = unpack( 'C*', $string ); # Unpack the string into a list of bytes
for ( my $i = 0 ; $i < @bytes ; $i++ ) {
printf( "%02X ", $bytes[$i] ); # Print each byte in hexadecimal format
print "\n"
if ( ( $i + 1 ) % $bytes_per_line == 0 )
; # Print a newline after every $bytes_per_line bytes
}
print "\n"
if ( @bytes % $bytes_per_line != 0 )
; # Print a final newline if the last line wasn't complete
}
Now let's extract the region and print it
my $region = $mem->extract_buffer_region(5, 10);
print_hex_values( $region, 8 );
Making a shallow copy of the buffer:
my $mem_cp = $mem;
printf( "%10s object is %s\n", ' mem_cp', $mem_cp );
printf "Buffer %10s with buffer address %s\n",
'Alpha', $mem->get_buffer();
printf "Buffer %10s with buffer address %s\n",
'Alpha_copy', $mem_cp->get_buffer();
Killing the original buffer in Perl. Trying to access it after death will lead to an error (but we intercept it in the code below)
undef $mem;
say "mem : ", ( $mem ? $mem->get_buffer() : "does not exist anymore" );
The shallow copy continues to exist, and so does the buffer region:
printf "Buffer %10s with buffer address %s\n",
'Alpha_copy', $mem_cp->get_buffer();
print_hex_values( $mem_cp->extract_buffer_region, 10 );
Attempting to modify an existing buffer object, e.g. by reassiging it to a new buffer object, will instantly free the old memory buffer, and allocate a new buffer with new contents (this Example continues at the end of Example 3)
$mem_cp = Task::MemManager->new(
20, 1,
{
init_value => 'D',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
allocator => 'CMalloc',
}
);
printf( "%10s object is %s\n", ' mem_cp', $mem_cp );
printf "Buffer %10s with buffer address %s\n",
'Alpha_copy after modification', $mem_cp->get_buffer();
print_hex_values( $mem_cp->extract_buffer_region, 10 );
Delayed garbage collection is useful when you want to keep a buffer alive
for a while after it goes out of scope. This is useful when you want to
transfer ownership of the memory space to an interfacing code (e.g. C code),
and don't want Perl to free the memory buffer (e.g when a lexical variable
is reassigned to a new buffer object in a loop).
In this example we will create two buffers, one without and one with delayed
garbage collection and will track when they die relative to the end of the
script. This example is entirely self-contained.
use Task::MemManager;
use strict;
use warnings;
$mem_cp = Task::MemManager->new(
20, 1,
{
init_value => 'D',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
allocator => 'PerlAlloc',
}
);
$mem_cp2 = Task::MemManager->new(
20, 1,
{
init_value => 'D',
death_stub => sub {
my ($obj_ref) = @_;
printf "Killing 0x%8x \n", $obj_ref->{identifier};
},
delayed_gc => 1,
allocator => 'CMalloc',
}
);
List the objects with delayed garbage collection
printf "Objects with delayed GC : "
. ("0x%8x " x @$delayed_gc_objects)
. "\n", @$delayed_gc_objects;
Time the precise moment of death:
undef $mem_cp2;
say "End of the program - see how Perl's destroying all "
. "delayed GC objects along with the rest of the objects";
There are no diagnostics that one can use. The module will croak if the allocation fails, so you don't have to worry about error handling.
The module depends on the Inline::C module to access the memory buffer
of the Perl scalar using the PerlAPI. In addition it depends implicitly
on all the dependencies of the memory allocators it uses
Open to suggestions. A few foolish ideas of my own include: adding further allocators and providing facilities that will *trigger* the delayed garbage collection for a specific object, at specific time points in a script (emulating for example Go's garbage collector).
-
https://metacpan.org/pod/Inline::C
Inline::C is a module that allows you to write Perl subroutines in C.
-
https://perldoc.perl.org/perlguts
Introduction to the Perl API.
-
https://perldoc.perl.org/perlapi
Autogenerated documentation for the perl public API.
Christos Argyropoulos, <chrisarg at cpan.org>
This software is copyright (c) 2024 by Christos Argyropoulos.
This is free software; you can redistribute it and/or modify it under the MIT license. The full text of the license can be found in the LICENSE file See https://en.wikipedia.org/wiki/MIT_License for more information.