PWC 281 Task 2: Knight's Move

A Knight in chess can move from its current position to any square two rows or columns plus one column or row away. Write a script which takes a starting position and an ending position and calculates the least number of moves required.

Example 1

• Input: $start = 'g2', $end = 'a8'
• Output: 4
• g2 -> e3 -> d5 -> c7 -> a8

Example 2

• Input: $start = 'g2', $end = 'h2'
• Output: 3
• g2 -> e3 -> f1 -> h2

Strategize

If you didn't immediately start humming "Night Moves" by Bob Seger, well, then you, uh, probably aren't as old as I am. "... How far off, I sat and wondered ... Ain't it funny how the night moves ..."

It's a shortest-path problem. The classic computer science solution is a breadth-first search, mildly complicated by the weird L-shaped moves of the knight and the chess notation. As early answers trickled in, I saw that everyone appeared to be going down this path, and I sighed and thought about all the ways I was going to mess this up until I beat it into submission with the debugger.

But here's a different way to approach the problem. Let's place a knight in the bottom left corner (a1) and label that corner 0. From here, there are two possible knight moves; let's label them with 1. Then, for each of the 1s, let's label the possible knight moves from there with a 2.

If we continue doing this until the 8x8 grid fills up, the board will look like this:

We have a lookup table. If we place the start point at a1, then we can read the move count directly out of the table at the end point. Well, mostly, assuming the end point is above and to the right of the start point.

There are symmetries we can exploit. Knight moves are the same forward and backward, so we can interchange start and end. If we think of the start and end as being the ends of a line segment, we can rotate by 90 degrees or reflect horizontally or vertically, and the move distance will remain the same.

So, given this table, we can slide or reflect the start/end pair over the grid until one of the points is at a1 and the other point is somewhere on the grid.

It took all of five minutes to generate the grid on a piece of graph paper, and the easy move here would be to hard-code the grid into a two-dimensional array. To make it more fun, we could write the code to generate the grid. That might be useful if the problem were generalized to board sizes other than 8x8, which I am not going to do, just to be clear.

For even more Perl fun, let's use the class feature to build an object around the board.

So, let's start laying out a program.

• Chess notation is annoying. We're quickly going to convert to using 0 to 7 as row and column indexes.

sub chessToGrid($chess)
{
    return ( substr($chess,1,1) - 1, ord(substr($chess, 0, 1)) - ord('a') )
}

Our board is going to be a class, because I want it to be. I use v5.40, which has class features, but it still gives "experimental" warnings. The attributes of a Board are its size, and the two-dimensional grid. The only public methods we really need are a constructor, and a method to retrieve a value from the grid.

use v5.40;
use feature 'class'; no warnings "experimental::class";

class Board
{
    field $row :param //= 8;
    field $col :param //= 8;
    field $lastRow = $row - 1;
    field $lastCol = $col - 1;
    field @board;
    ADJUST {
        # The board starts out as 8x8 undef values
        push @board, [ (undef) x $col ] for ( 1 .. $row );
        $self->_init();
    }

    method at($r, $c) { ... }

    # Private methods
    method _init() { ... }
    method _knightMoveFrom($r, $c) { ... }
}

Some Perl points:

• field $row :param //= 8 -- The :param declares that this is a parameter that could be passed to the constructor, but the //=8 declares that it will default to 8 if not given.
• field $lastRow = $row - 1 -- This is a convenience variable, which will be set up in the constructor. It's not a parameter to the constructor.
• ADJUST -- This is a Perl class convention for adding code to the constructor. In this case, we're going to initialize @board to be a two-dimensional array, and then we're going to call a private method to fill in the distance values.
• method at() -- This is an accessor to a square on the board, helping us keep @board private to the class.
• method _init() -- I'm using the ancient venerable convention that private methods have an underscore prefix.

Let's tackle the sub-problem of figuring out possible knight moves. For a square in the middle of the board, there are 8 possible moves:

• go right 2, then up or down;
• go left 2, then up or down.
• go up 2, then left or right;
• go down 2, then left or right;

These possibilities can be represented in a list of (row,column) delta pairs.

( [-1, 2], [1,2], [-1,-2], [1,-2], [2,1], [2, -1], [-2, 1], [-2, -1 ] )

Now we can find our possible moves by adding our given row and column to each of these deltas:

map { [ $r + $_->[0], $c + $_->[1] ] } ( [-1,2]... )

That yields a list of [row,column] pairs, but some of those pairs might now be off the grid. Let's prune the list:

grep { 0 <= $_->[0] <= $lastRow  &&  0 <= $_->[1] <= $lastCol }

Since this is a class method, it has access to the fields, so $lastRow and $lastCol are available for the bounds check. The whole thing together is a terse couple of lines:

method knightMoveFrom($r, $c)
{
    grep { 0 <= $_->[0] <= $lastRow  &&  0 <= $_->[1] <= $lastCol }
    map { [ $r + $_->[0], $c + $_->[1] ] }
        ( [-1, 2], [1,2], [-1,-2], [1,-2], [2,1], [2, -1], [-2, 1], [-2, -1 ] )
}

Having this function available, it becomes possible to write the _init() private method. I'm going to omit the code for it, in an already-lost quest for brevity; it's on GitHub

Let's return to the main function of the program. We're given a start and end square in chess notation. We want to convert that to Cartesian coordinates, and then figure out how to translate the points to the origin.

We're going to check the slope of the line between the two points. If it's positive, then one of the points is up and to the right of the other, and all we have to do is slide the points down and to the left until one reaches (0,0).

If the slope is negative, that means that if we slide the two points towards the origin, one of them is going to fall outside of the grid. Fortunately, we can use symmetry to flip the line over and make the slope positive. For example, suppose our start and end points look like this:

|  .  .  .  .  .  .
|  .  S  .  .  .  .
|  .  .  .  .  .  .
|  .  .  .  .  .  .
|  .  .  .  .  E  .
|  .  .  .  .  .  .
+------------------

As far as the knight-move distance between the points is concerned, this is equivalent to flipping the points:

|  .  .  .  .  .  .
|  .  S------->s' .
|  .  .  .  .  .  .
|  .  .  .  .  .  .
|  .  e'<------E  .
|  .  .  .  .  .  .
+------------------

The reflection means that for S, keep its row, but move it over to E's column; and for E, keep its row, but move it over to S's column. That is, (in programming terms), swap the column coordinates.

Once we've adjusted the points so that they form a positive slope, then we have to slide the one closest to the origin to (0,0), and slide the other point by the same amount. If the end is closer than the start, then we swap the points (again, as far as knight-move distance is concerned, it's going to be the same).

The translation to (0,0) happens by subtracting the start point from the end point. Finally, the number of moves is just a table lookup from our carefully constructed Board object.

sub km($start, $end)
{
    my @start = chessToGrid($start);
    my @end   = chessToGrid($end);

    # If the slope is negative, reflect the line so that the slope is positive. 
    my $dy = $end[1] - $start[1];
    my $dx = $end[0] - $start[0];
    my $slope = ( $dx == 0 ? 0 : $dy / $dx );
    if ( $slope < 0 )
    {
        ( $start[1], $end[1] ) = ( $end[1], $start[1] );
    }

    # If the end is closer to the origin, swap ends
    if ( $end[0] < $start[0] || $end[1] < $start[1] )
    {
        ( $start[0], $start[1], $end[0], $end[1] ) = ( @end, @start);
    }

    # Shift the end point as if the start is at 0,0
    $end[0] -= $start[0];
    $end[1] -= $start[1];

    return $Board->at(@end);
}

Originally published at Perl Weekly 680

Hi there,

I know we still have 4 months before the Advent Calendar season kicks in but I noticed the ground work has already started by Olaf Alders with the announcement of The Call for Papers for the 2024 Perl Advent Calendar. The CFP is open until midnight on Friday September 30th EST. I would like to request all Perl fans to share their fun encounter with Perl as an article for the upcoming Perl Advent Calendar 2024. I have already submitted my proposal and keeping my fingers crossed. While talking about, Advent Calendar, I would love to see Dancer2 Advent Calendar to come back with full force. If I remember correctly, we didn't have the complete calendar last year. Being Dancer2 fan, I would really want it to get back to its peak. Dave Cross is one of those who uses Dancer2 for building applications. In the recent post, he shared his experience about deploying Dancer Apps. Even my personal website is a Dancer2 REST API application.

It's a bit late to share but better late than never. We have the monthly post about What's new on CPAN - June 2024 by Mathew Korica. Kudos for the effort and thanks for keeping the tradition alive.

Enjoy rest of the newsletter.

--
Your editor: Mohammad Sajid Anwar.

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Articles

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Deploying Dancer Apps (Addendum)

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This week in PSC (154)

Regular updates from Perl Steering Council. Happy to see the progress report. Thank you all for your time and efforts.

Why Perl Remains Indispensable in the Age of Modern Programming Languages

An honest opinion and view about Perl. What do you think?

The Weekly Challenge

The Weekly Challenge by Mohammad Sajid Anwar will help you step out of your comfort-zone. You can even win prize money of $50 by participating in the weekly challenge. We pick one champion at the end of the month from among all of the contributors during the month, thanks to the sponsor Lance Wicks.

The Weekly Challenge - 281

Welcome to a new week with a couple of fun tasks "Check Color" and "Knight's Move". If you are new to the weekly challenge then why not join us and have fun every week. For more information, please read the FAQ.

RECAP - The Weekly Challenge - 280

Enjoy a quick recap of last week's contributions by Team PWC dealing with the "Twice Appearance" and "Count Asterisks" tasks in Perl and Raku. You will find plenty of solutions to keep you busy.

Asterisks Appear Twice

Welcome back to blogging. Suprise to see do { } for loop construct. Highly recommended.

TWC280

Time for some clever regex in Perl and you end up with one-line. Cool work, thanks for sharing.

Count Twice

Powerful one-liner in Raku is on demand every week. Keep it up great work.

Why Is This Interesting?

See how to keep the logic simple and still get the elegant solution. Incredible, keep it up great work.

Perl Weekly Challenge: Week 280

Simply use split and hash, you end up with nice easy to follow solution. Smart and clever approach.

Regular Pairs

Well documented extended regex solutions, very brave indeed. Thanks for sharing knowledge with us.

Perl Weekly Challenge 280: Twice Appearance

Straight forward and to the point without any gimmicks. Short little discussion is very handy too. Great work.

Perl Weekly Challenge 280: Count Asterisks

Great show of regex in Perl and Raku. Thanks for sharing knowledge with us.

grepping everything!

Mix of Raku, Python, Java and PostgreSQL will keep you busy as always every week. Pleasure to see how implementation differs. Thanks for sharing.

Perl Weekly Challenge 280

Ideal use case for one-liner in Perl this week by master of one-liners. You really don't want to skip it.

There Is More Than One Way To Regex

Love the journey to get the desired output. Plenty to learn from the experience. Great work, keep it up.

Appear Twice, Count Once

I liked the Approach section where we get to see the finer details then implementation in varieties of languages. Highly recommended.

Counting the stars

Interesting use of regex and we have pretty cool solutions in Perl. Thanks for sharing knowledge with us.

The Weekly Challenge - 280

Simple use of hash in Perl is good enough for Twice Appearance task. Smart approach, well done.

The Weekly Challenge #280

Interesting use of finite state machine with detailed discussion. Loved the use of Unicode character. Keep it up great work.

The Sudden Appearance of Asterisks

Line by line discussion is very handy even if the language is alien. This week choice of languages for post are Raku and Rust. Thanks for your contributions.

Rakudo

2024.31 Mondrianally

Weekly collections

NICEPERL's lists

Great CPAN modules released last week.

Events

Boston.pm monthly meeting

August 13, 2024, Virtual event

GitHub Pages for Perl developers

August 15, 2024, in Zoom

Purdue Perl Mongers

August 14, 2024, Virtual event

London Perl and Raku Workshop

October 26, 2024, in London, UK

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(C) Copyright Gabor Szabo
The articles are copyright the respective authors.

Ah, Perl. The programming language that refuses to die. In a world flooded with shiny new toys like Go, Kotlin, and Python, Perl remains the wise (and slightly eccentric) grandparent at the family reunion, clutching its cherished regular expressions and muttering about the good old days. But before you roll your eyes and dismiss Perl as a relic, let’s dive into why this ancient language is still relevant. Spoiler alert: It involves some serious magic and a whole lot of text processing.

The Power of Text Processing

Perl’s text processing capabilities are legendary. No, seriously, they are. Imagine a Swiss Army knife, but instead of blades and screwdrivers, it has regex patterns and string manipulation functions. While other languages are busy with their fancy syntax and clean code, Perl is out there in the trenches, getting the job done with a regex pattern that looks like someone’s cat walked across the keyboard.

Example: Log File Analysis

System admins rejoice! Perl can plow through log files like a hot knife through butter. Need to find all the error messages in a 10GB log file? Perl’s got your back.

#!/usr/bin/env perl
use strict;
use warnings;

my $log_file = 'system.log';
open my $fh, '<', $log_file or die "Cannot open $log_file: $!";
while (my $line = <$fh>) {
    if ($line =~ /ERROR/) {
        print $line;
    }
}
close $fh;

See? Easy peasy. While Python is off doing yoga and Go is busy with its minimalism, Perl is here, elbows deep in your log files, pulling out the gory details.

DevOps and Automation

In the age of DevOps, automation is king. And who better to automate your mundane, soul-crushing tasks than Perl? Forget spending hours on deployment. With Perl, you can sit back, relax, and watch the magic happen.

Example: Automated Deployment

Perl can automate deployments like a boss. Git pull? Check. Server configuration? Check. Deploy script? Double-check.

#!/usr/bin/env perl
use strict;
use warnings;
use Net::SSH::Perl;

my $host = 'example.com';
my $user = 'deploy';
my $password = 'secret';

my $ssh = Net::SSH::Perl->new($host);
$ssh->login($user, $password);

my $output = $ssh->cmd('cd /var/www/myapp && git pull origin master && ./deploy.sh');
print $output;

While Kotlin is busy figuring out its coroutines, Perl is out there making your life easier, one deployment at a time.

Web Development

Web development, you say? Surely, Perl can’t compete with the likes of JavaScript and Python, right? Wrong. Enter Mojolicious, the web framework that lets you whip up web apps faster than you can say “Node.js”.

Example: Rapid Prototyping with Mojolicious

With Mojolicious, you can have a web app up and running in no time. Minimal boilerplate, maximum fun.

#!/usr/bin/env perl
use Mojolicious::Lite;

get '/' => {text => 'Hello, World!'};

app->start;

Take that, React! While you’re setting up your endless dependencies, Perl just launched a web app. Boom.

Data Science and AI

Sure, Python has pandas, and R has... well, R. But did you know Perl has the Perl Data Language (PDL)? It’s like Perl decided to dabble in data science and accidentally became pretty good at it.

Example: Data Analysis with PDL

PDL handles large datasets with the grace of a ballerina on a sugar rush. Need to calculate the mean? Perl’s got you covered.

use PDL;
use PDL::NiceSlice;

my $data = pdl [1, 2, 3, 4, 5];
my $mean = $data->average;
print "Mean: $mean\n";

While Python is off publishing papers, Perl is quietly crunching numbers in the corner, getting stuff done.

System Administration

System administration is where Perl truly shines. It’s like Perl was born for this stuff. Need to manage user accounts or automate backups? Perl’s your guy.

Example: User Management Script

Perl scripts can handle system admin tasks with the finesse of a ninja.

#!/usr/bin/env perl
use strict;
use warnings;

my @users = qw(user1 user2 user3);

foreach my $user (@users) {
    system("useradd $user");
}

While Go is busy being statically typed, Perl is out there making your sysadmin tasks look easy.

Conclusion

In a world obsessed with the latest and greatest, Perl stands as a testament to the power of simplicity and raw functionality. It may not have the flashiest syntax or the trendiest features, but it gets the job done. Whether it’s text processing, automation, web development, data science, or system administration, Perl is the unsung hero, quietly working behind the scenes. So, next time you’re faced with a daunting task, remember: Perl is still here, and it’s ready to help.

Thank You

And let’s not forget to extend a heartfelt thank you to Larry Wall, the genius behind Perl, and all the alpha nerds and sysadmin ninjas who’ve kept this language not just alive, but thriving. Your dedication and wit have made the tech world a better (and funnier) place. Here’s to many more years of Perl wizardry!

At this point one may wonder how numba, the Python compiler around numpy Python code, delivers a performance premium over numpy. To do so, let's inspect timings individually for all trigonometric functions (and yes, the exponential and the logarithm are trigonometric functions if you recall your complex analysis lessons from high school!). But the test is not relevant only for those who want to do high school trigonometry: physics engines e.g. in games will use these function, and machine learning and statistical calculations heavily use log and exp. So getting the trigonometric functions right is one small, but important step, towards implementing a variety of applications. The table below shows the timings for 50M in place transformations:

The table holds the first hold to the performance benefits: the square root, a function that has a dedicated SIMD instruction for vectorization takes exactly the same time to execute in numba and numpy, while all the other functions are speed up by 2-2.5 time, indicating either that the code auto-vectorizes using SIMD or auto-threads. A second clue is provided by examining the difference in results between the numba and numpy, using the ULP (Unit in the Last Place). ULP is a measure of accuracy in numerical calculations and can easily be computed for numpy arrays using the following Python function:

def compute_ulp_error(array1, array2):
## maxulp set up to a very high number to avoid throwing an exception in the code
    return np.testing.assert_array_max_ulp(array1, array2, maxulp=100000)

These numerical benchmarks indicate that the square root function utilizes pretty much equivalent code in numpy and numba, while for all the other trigonometric functions the mean, median, 99.9th percentile and maximum ULP value over all 50M numbers differ. This is a subtle hint that SIMD is at play: vectorization changes slightly the semantics of floating point code to make use of associative math, and floating point numerical operations are not associative.

Finally, we can inspect the code of the numba generated functions for vectorized assembly instructions as detailed here, using the code below:

@njit(nogil=True, fastmath=False, cache=True)
def compute_sqrt_with_numba(array):
    np.sqrt(array, array)


@njit(nogil=True, fastmath=False, cache=True)
def compute_sin_with_numba(array):
    np.sin(array, array)


@njit(nogil=True, fastmath=False, cache=True)
def compute_cos_with_numba(array):
    np.cos(array, array)


@njit(nogil=True, fastmath=False, cache=True)
def compute_exp_with_numba(array):
    np.exp(array, array)


@njit(nogil=True, fastmath=False, cache=True)
def compute_log_with_numba(array):
    np.log(array, array)

## check for vectorization
## code lifted from https://tbetcke.github.io/hpc_lecture_notes/simd.html
def find_instr(func, keyword, sig, limit=5):
    count = 0
    for l in func.inspect_asm(func.signatures[sig]).split("\n"):
        if keyword in l:
            count += 1
            print(l)
            if count >= limit:
                break
    if count == 0:
        print("No instructions found")

# Compile the function to avoid the overhead of the first call
compute_sqrt_with_numba(np.array([np.random.rand() for _ in range(1, 6)]))
compute_sin_with_numba(np.array([np.random.rand() for _ in range(1, 6)]))
compute_exp_with_numba(np.array([np.random.rand() for _ in range(1, 6)]))
compute_cos_with_numba(np.array([np.random.rand() for _ in range(1, 6)]))
compute_exp_with_numba(np.array([np.random.rand() for _ in range(1, 6)]))

And this is how we probe for the presence f the vmovups instruction indicating that the YMM AVX2 registers are being used in calculations

print("sqrt")
find_instr(compute_sqrt_with_numba, keyword="vsqrtsd", sig=0)
print("\n\n")
print("sin")
find_instr(compute_sin_with_numba, keyword="vmovups", sig=0)

As we can see in the output below the square root function uses the x86 SIMD vectorized square root instruction vsqrtsd , and the sin (but also all trigonometric functions) use SIMD instructions to access memory.

sqrt
        vsqrtsd %xmm0, %xmm0, %xmm0
        vsqrtsd %xmm0, %xmm0, %xmm0


sin
        vmovups (%r12,%rsi,8), %ymm0
        vmovups 32(%r12,%rsi,8), %ymm8
        vmovups 64(%r12,%rsi,8), %ymm9
        vmovups 96(%r12,%rsi,8), %ymm10
        vmovups %ymm11, (%r12,%rsi,8)

Let's shift attention to Perl and C now (after all this is a Perl blog!). In Part I
we saw that PDL and C gave similar performance when evaluating the nested function cos(sin(sqrt(x))), and in Part II that the single-threaded Perl code was as fast as numba. But what about the individual trigonometric functions in PDL and C without the Inline module? The C code block that will be evaluated in this case is:

#pragma omp for simd
  for (int i = 0; i < array_size; i++) {
    double x = array[i];
    array[i] = foo(x);
  }

where foo is one of sqrt, sin, cos, log, exp. We will use the simd omp pragma in conjunction with the following compilation flags and the gcc compiler to see if we can get the code to pick up the hint and auto-vectorize the machine code generated using the SIMD instructions.

CC = gcc
CFLAGS = -O3 -ftree-vectorize  -march=native -mtune=native -Wall -std=gnu11 -fopenmp -fstrict-aliasing -fopt-info-vec-optimized -fopt-info-vec-missed
LDFLAGS = -fPIE -fopenmp 
LIBS =  -lm

During compilation, gcc informs us about all the wonderful missed opportunities to optimize the loop. The performance table below also demonstrates this; note that the standard C implementation and PDL are equivalent and equal in performance to numba. Perl through PDL can deliver performance in our data science world.

To get the compiler to use SIMD, we replace the flag -O3 by -Ofast and all these wonderful opportunities for performance are no longer missed, and the C code now delivers (but with the usual caveats that apply to the -Ofast flag).

With these benchmarks, let's return to our initial Perl benchmarks and contrast the timings obtained with the non-SIMD aware invokation of the Inline C code:

use Inline (
    C    => 'DATA',
    build_noisy => 1,
    with => qw/Alien::OpenMP/,
    optimize => '-O3 -march=native -mtune=native',
    libs => '-lm'
);

and the SIMD aware one (in the code below, one has to incluce the vectorized version of the mathematics library for the code to compile):

use Inline (
    C    => 'DATA',
    build_noisy => 1,
    with => qw/Alien::OpenMP/,
    optimize => '-Ofast -march=native -mtune=native',
    libs => '-lmvec'
);

The non-vectorized version of the code yield the following table

Inplace  in  base Python took 11.9 seconds
Inplace  in PythonJoblib took 4.42 seconds
Inplace  in         Perl took 2.88 seconds
Inplace  in Perl/mapCseq took 1.60 seconds
Inplace  in    Perl/mapC took 1.50 seconds
C array  in            C took 1.42 seconds
Vector   in       Base R took 1.30 seconds
C array  in   Perl/C/seq took 1.17 seconds
Inplace  in     PDL - ST took 0.94 seconds
Inplace in  Python Numpy took 0.93 seconds
Inplace  in Python Numba took 0.49 seconds
Inplace  in   Perl/C/OMP took 0.24 seconds
C array  in   C with OMP took 0.22 seconds
C array  in    C/OMP/seq took 0.18 seconds
Inplace  in     PDL - MT took 0.16 seconds

while the vectorized ones this one:

Inplace  in  base Python took 11.9 seconds
Inplace  in PythonJoblib took 4.42 seconds
Inplace  in         Perl took 2.94 seconds
Inplace  in Perl/mapCseq took 1.59 seconds
Inplace  in    Perl/mapC took 1.48 seconds
Vector   in       Base R took 1.30 seconds
Inplace  in     PDL - ST took 0.96 seconds
Inplace in  Python Numpy took 0.93 seconds
Inplace  in Python Numba took 0.49 seconds
C array  in   Perl/C/seq took 0.30 seconds
C array  in            C took 0.26 seconds
Inplace  in   Perl/C/OMP took 0.24 seconds
C array  in   C with OMP took 0.23 seconds
C array  in    C/OMP/seq took 0.19 seconds
Inplace  in     PDL - MT took 0.17 seconds

To facilitate comparisons against the various flavors of Python and R, we inserted the results we presented previously in these 2 tables.

The take home points (some of which may be somewhat surprising are):

1. Performance of base Python was horrendous - nearly 4 times slower than base Perl. Even under parallel processing (Joblib) the 8 threaded Python code was slower than Perl
2. R performed the best out of the 3 dynamically typed languages considered : nearly 9 times faster than base Python and 2.3 times faster than base Perl.
3. Inplace modification of Perl arrays by accessing the array containers in C (Perl/mapC) narrowed the gap between Perl and R
4. Considering variability in timings, the three codes, base R, Perl/mapC and an equivalent inplace modification of a C array are roughly equivalent
5. The uni-threaded PDL code delivered the same performance as numpy
6. SIMD aware code, e.g. through numba or (for the case of native C code compiler pragmas, e.g. cntract C array in C timings between the vectorized and the non-vectorized versions of the table) delivered the best single thread performance.
7. OpenMP pragmas can really speed up operations (such as map) of Perl containers.
8. Adding threads (OMP code) or the multi-threaded versions of the PDL delivered the best performance.

These observations generate the following big picture questions:

• Observations 1 and 2 make it quite surprising that base Python earned a reputation for a data science language. In fact, with these performance characteristics of a rather simple numerical code, one should approach the replacement of R (or Perl for those of us who use it) by base Python in data analysis codes.
• Since hybrid implementations that involve C and Perl can deliver real performance benefits using SIMD aware code, even if a single thread is used, should we be upgrading our Inline::C codes to use SIMD friendly compiler flags? Or (for those who are are afraid of -Ofast, perhaps a carefully prepared mixology of intrinsics, and even assembly?
• Should we be looking into upgrading various C/XS modules for Perl, so that they use OpenMP?
• Why are not more people using the jewel of software that is PDL? The auto-threading property alone should make people think about using it for demanding, data intensive tasks.
• Is it possible to create hybrid applications that rely on both PDL and OpenMP/Inline::C for different computations?
• Should we look into special builds for PDL that leverage the SIMD properties and compiler pragmas to allow users to have their cake (SIMD vectorization) and eat it (autothreading) too?

In the two prior installments of this series, we considered the performance of floating operations in Perl,
Python and R in a toy example that computed the function cos(sin(sqrt(x))), where x was a very large array of 50M double precision floating numbers.
Hybrid implementations that delegated the arithmetic intensive part to C were among the most performant implementations. In this installment, we will digress slightly and look at the performance of a pure C code implementation of the toy example.
The C code will provide further insights about the importance of memory locality for performance (by default elements in a C array are stored in sequential addresses in memory, and numerical APIs such as PDL or numpy interface with such containers) vis-a-vis containers,
e.g. Perl arrays which do not store their values in sequential addresses in memory. Last, but certainly not least, the C code implementations will allow us to assess whether flags related to floating point operations for the low level compiler (in this case gcc) can affect performance.
This point is worth emphasizing: common mortals are entirely dependent on the choice of compiler flags when "piping" their "install" or building their Inline file. If one does not touch these flags, then one will be blissfully unaware of what they may missing, or pitfalls they may be avoiding.
The humble C file makefile allows one to make such performance evaluations explicitly.

The C code for our toy example is listed in its entirety below. The code is rather self-explanatory, so will not spend time explaining other than pointing out that it contains four functions for

• Non-sequential calculation of the expensive function : all three floating pointing operations take place inside a single loop using one thread
• Sequential calculations of the expensive function : each of the 3 floating point function evaluations takes inside a separate loop using one thread
• Non-sequential OpenMP code : threaded version of the non-sequential code
• Sequential OpenMP code: threaded of the sequential code

In this case, one may hope that the compiler is smart enough to recognize that the square root maps to packed (vectorized) floating pointing operations in assembly, so that one function can be vectorized using the appropriate SIMD instructions (note we did not use the simd program for the OpenMP codes).
Perhaps the speedup from the vectorization may offset the loss of performance from repeatedly accessing the same memory locations (or not).

#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <stdio.h>
#include <omp.h>

// simulates a large array of random numbers
double*  simulate_array(int num_of_elements,int seed);
// OMP environment functions
void _set_openmp_schedule_from_env();
void _set_num_threads_from_env();



// functions to modify C arrays 
void map_c_array(double* array, int len);
void map_c_array_sequential(double* array, int len);
void map_C_array_using_OMP(double* array, int len);
void map_C_array_sequential_using_OMP(double* array, int len);

int main(int argc, char *argv[]) {
    if (argc != 2) {
        printf("Usage: %s <array_size>\n", argv[0]);
        return 1;
    }

    int array_size = atoi(argv[1]);
    // printf the array size
    printf("Array size: %d\n", array_size);
    double *array = simulate_array(array_size, 1234);

    // Set OMP environment
    _set_openmp_schedule_from_env();
    _set_num_threads_from_env();

    // Perform calculations and collect timing data
    double start_time, end_time, elapsed_time;
    // Non-Sequential calculation
    start_time = omp_get_wtime();
    map_c_array(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Non-sequential calculation time: %f seconds\n", elapsed_time);
    free(array);

    // Sequential calculation
    array = simulate_array(array_size, 1234);
    start_time = omp_get_wtime();
    map_c_array_sequential(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Sequential calculation time: %f seconds\n", elapsed_time);
    free(array);

    array = simulate_array(array_size, 1234);
    // Parallel calculation using OMP
    start_time = omp_get_wtime();
    map_C_array_using_OMP(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Parallel calculation using OMP time: %f seconds\n", elapsed_time);
    free(array);

    // Sequential calculation using OMP
    array = simulate_array(array_size, 1234);
    start_time = omp_get_wtime();
    map_C_array_sequential_using_OMP(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Sequential calculation using OMP time: %f seconds\n", elapsed_time);

    free(array);
    return 0;
}



/*
*******************************************************************************
* OMP environment functions
*******************************************************************************
*/
void _set_openmp_schedule_from_env() {
  char *schedule_env = getenv("OMP_SCHEDULE");
  printf("Schedule from env %s\n", getenv("OMP_SCHEDULE"));
  if (schedule_env != NULL) {
    char *kind_str = strtok(schedule_env, ",");
    char *chunk_size_str = strtok(NULL, ",");

    omp_sched_t kind;
    if (strcmp(kind_str, "static") == 0) {
      kind = omp_sched_static;
    } else if (strcmp(kind_str, "dynamic") == 0) {
      kind = omp_sched_dynamic;
    } else if (strcmp(kind_str, "guided") == 0) {
      kind = omp_sched_guided;
    } else {
      kind = omp_sched_auto;
    }
    int chunk_size = atoi(chunk_size_str);
    omp_set_schedule(kind, chunk_size);
  }
}

void _set_num_threads_from_env() {
  char *num = getenv("OMP_NUM_THREADS");
  printf("Number of threads = %s from within C\n", num);
  omp_set_num_threads(atoi(num));
}
/*
*******************************************************************************
* Functions that modify C arrays whose address is passed from Perl in C
*******************************************************************************
*/

double*  simulate_array(int num_of_elements, int seed) {
  srand(seed); // Seed the random number generator
  double *array = (double *)malloc(num_of_elements * sizeof(double));
  for (int i = 0; i < num_of_elements; i++) {
    array[i] =
        (double)rand() / RAND_MAX; // Generate a random double between 0 and 1
  }
  return array;
}

void map_c_array(double *array, int len) {
  for (int i = 0; i < len; i++) {
    array[i] = cos(sin(sqrt(array[i])));
  }
}

void map_c_array_sequential(double* array, int len) {
  for (int i = 0; i < len; i++) {
    array[i] = sqrt(array[i]);
  }
  for (int i = 0; i < len; i++) {
    array[i] = sin(array[i]);
  }
  for (int i = 0; i < len; i++) {
    array[i] = cos(array[i]);
  }
}

void map_C_array_using_OMP(double* array, int len) {
#pragma omp parallel
  {
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = cos(sin(sqrt(array[i])));
    }
  }
}

void map_C_array_sequential_using_OMP(double* array, int len) {
#pragma omp parallel
  {
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = sqrt(array[i]);
    }
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = sin(array[i]);
    }
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = cos(array[i]);
    }
  }
}

A critical question is whether the use of fast floating compiler flags, a trick that trades speed for accuracy of the code, can affect performance.
Here is the makefile withut this compiler flag

CC = gcc
CFLAGS = -O3 -ftree-vectorize  -march=native  -Wall -std=gnu11 -fopenmp -fstrict-aliasing 
LDFLAGS = -fPIE -fopenmp
LIBS =  -lm

SOURCES = inplace_array_mod_with_OpenMP.c
OBJECTS = $(SOURCES:.c=_noffmath_gcc.o)
EXECUTABLE = inplace_array_mod_with_OpenMP_noffmath_gcc

all: $(SOURCES) $(EXECUTABLE)

clean:
    rm -f $(OBJECTS) $(EXECUTABLE)

$(EXECUTABLE): $(OBJECTS)
    $(CC) $(LDFLAGS) $(OBJECTS) $(LIBS) -o $@

%_noffmath_gcc.o : %.c 
    $(CC) $(CFLAGS) -c $< -o $@

and here is the one with this flag:

CC = gcc
CFLAGS = -O3 -ftree-vectorize  -march=native -Wall -std=gnu11 -fopenmp -fstrict-aliasing -ffast-math
LDFLAGS = -fPIE -fopenmp
LIBS =  -lm

SOURCES = inplace_array_mod_with_OpenMP.c
OBJECTS = $(SOURCES:.c=_gcc.o)
EXECUTABLE = inplace_array_mod_with_OpenMP_gcc

all: $(SOURCES) $(EXECUTABLE)

clean:
    rm -f $(OBJECTS) $(EXECUTABLE)

$(EXECUTABLE): $(OBJECTS)
    $(CC) $(LDFLAGS) $(OBJECTS) $(LIBS) -o $@

%_gcc.o : %.c 
    $(CC) $(CFLAGS) -c $< -o $@

And here are the results of running these two programs

• Without -ffast-math

OMP_SCHEDULE=guided,1 OMP_NUM_THREADS=8 ./inplace_array_mod_with_OpenMP_noffmath_gcc 50000000
Array size: 50000000
Schedule from env guided,1
Number of threads = 8 from within C
Non-sequential calculation time: 1.12 seconds
Sequential calculation time: 0.95 seconds
Parallel calculation using OMP time: 0.17 seconds
Sequential calculation using OMP time: 0.15 seconds

• With -ffast-math

OMP_SCHEDULE=guided,1 OMP_NUM_THREADS=8 ./inplace_array_mod_with_OpenMP_gcc 50000000
Array size: 50000000
Schedule from env guided,1
Number of threads = 8 from within C
Non-sequential calculation time: 0.27 seconds
Sequential calculation time: 0.28 seconds
Parallel calculation using OMP time: 0.05 seconds
Sequential calculation using OMP time: 0.06 seconds

Note that one can use the fastmath in Numba code as follows (the default is fastmath=False):

@njit(nogil=True,fastmath=True)
def compute_inplace_with_numba(array):
    np.sqrt(array,array)
    np.sin(array,array)
    np.cos(array,array)

A few points that are worth noting:

• The -ffast-math gives major boost in performance (about 300% for both the single threaded and the multi-threaded code), but it can generate erroneous results
• Fastmath also works in Numba, but should be avoided for the same reasons it should be avoided in any application that strives for accuracy
• The sequential C single threaded code gives performance similar to the single threaded PDL and Numpy
• Somewhat surprisingly, the sequential code is about 20% faster than the non-sequential code when the correct (non-fast) math is used.
• Unsurprisingly, multi-threaded code is faster than single threaded code :)
• I still cannot explain how numbas delivers a 50% performance premium over the C code of this rather simple function.

title: " The Quest for Performance Part III : C Force "

date: 2024-07-07

In the two prior installments of this series, we considered the performance of floating operations in Perl,
Python and R in a toy example that computed the function cos(sin(sqrt(x))), where x was a very large array of 50M double precision floating numbers.
Hybrid implementations that delegated the arithmetic intensive part to C were among the most performant implementations. In this installment, we will digress slightly and look at the performance of a pure C code implementation of the toy example.
The C code will provide further insights about the importance of memory locality for performance (by default elements in a C array are stored in sequential addresses in memory, and numerical APIs such as PDL or numpy interface with such containers) vis-a-vis containers,
e.g. Perl arrays which do not store their values in sequential addresses in memory. Last, but certainly not least, the C code implementations will allow us to assess whether flags related to floating point operations for the low level compiler (in this case gcc) can affect performance.
This point is worth emphasizing: common mortals are entirely dependent on the choice of compiler flags when "piping" their "install" or building their Inline file. If one does not touch these flags, then one will be blissfully unaware of what they may missing, or pitfalls they may be avoiding.
The humble C file makefile allows one to make such performance evaluations explicitly.

The C code for our toy example is listed in its entirety below. The code is rather self-explanatory, so will not spend time explaining other than pointing out that it contains four functions for

• Non-sequential calculation of the expensive function : all three floating pointing operations take place inside a single loop using one thread
• Sequential calculations of the expensive function : each of the 3 floating point function evaluations takes inside a separate loop using one thread
• Non-sequential OpenMP code : threaded version of the non-sequential code
• Sequential OpenMP code: threaded of the sequential code

In this case, one may hope that the compiler is smart enough to recognize that the square root maps to packed (vectorized) floating pointing operations in assembly, so that one function can be vectorized using the appropriate SIMD instructions (note we did not use the simd program for the OpenMP codes).
Perhaps the speedup from the vectorization may offset the loss of performance from repeatedly accessing the same memory locations (or not).

#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <stdio.h>
#include <omp.h>

// simulates a large array of random numbers
double*  simulate_array(int num_of_elements,int seed);
// OMP environment functions
void _set_openmp_schedule_from_env();
void _set_num_threads_from_env();



// functions to modify C arrays 
void map_c_array(double* array, int len);
void map_c_array_sequential(double* array, int len);
void map_C_array_using_OMP(double* array, int len);
void map_C_array_sequential_using_OMP(double* array, int len);

int main(int argc, char *argv[]) {
    if (argc != 2) {
        printf("Usage: %s <array_size>\n", argv[0]);
        return 1;
    }

    int array_size = atoi(argv[1]);
    // printf the array size
    printf("Array size: %d\n", array_size);
    double *array = simulate_array(array_size, 1234);

    // Set OMP environment
    _set_openmp_schedule_from_env();
    _set_num_threads_from_env();

    // Perform calculations and collect timing data
    double start_time, end_time, elapsed_time;
    // Non-Sequential calculation
    start_time = omp_get_wtime();
    map_c_array(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Non-sequential calculation time: %f seconds\n", elapsed_time);
    free(array);

    // Sequential calculation
    array = simulate_array(array_size, 1234);
    start_time = omp_get_wtime();
    map_c_array_sequential(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Sequential calculation time: %f seconds\n", elapsed_time);
    free(array);

    array = simulate_array(array_size, 1234);
    // Parallel calculation using OMP
    start_time = omp_get_wtime();
    map_C_array_using_OMP(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Parallel calculation using OMP time: %f seconds\n", elapsed_time);
    free(array);

    // Sequential calculation using OMP
    array = simulate_array(array_size, 1234);
    start_time = omp_get_wtime();
    map_C_array_sequential_using_OMP(array, array_size);
    end_time = omp_get_wtime();
    elapsed_time = end_time - start_time;
    printf("Sequential calculation using OMP time: %f seconds\n", elapsed_time);

    free(array);
    return 0;
}



/*
*******************************************************************************
* OMP environment functions
*******************************************************************************
*/
void _set_openmp_schedule_from_env() {
  char *schedule_env = getenv("OMP_SCHEDULE");
  printf("Schedule from env %s\n", getenv("OMP_SCHEDULE"));
  if (schedule_env != NULL) {
    char *kind_str = strtok(schedule_env, ",");
    char *chunk_size_str = strtok(NULL, ",");

    omp_sched_t kind;
    if (strcmp(kind_str, "static") == 0) {
      kind = omp_sched_static;
    } else if (strcmp(kind_str, "dynamic") == 0) {
      kind = omp_sched_dynamic;
    } else if (strcmp(kind_str, "guided") == 0) {
      kind = omp_sched_guided;
    } else {
      kind = omp_sched_auto;
    }
    int chunk_size = atoi(chunk_size_str);
    omp_set_schedule(kind, chunk_size);
  }
}

void _set_num_threads_from_env() {
  char *num = getenv("OMP_NUM_THREADS");
  printf("Number of threads = %s from within C\n", num);
  omp_set_num_threads(atoi(num));
}
/*
*******************************************************************************
* Functions that modify C arrays whose address is passed from Perl in C
*******************************************************************************
*/

double*  simulate_array(int num_of_elements, int seed) {
  srand(seed); // Seed the random number generator
  double *array = (double *)malloc(num_of_elements * sizeof(double));
  for (int i = 0; i < num_of_elements; i++) {
    array[i] =
        (double)rand() / RAND_MAX; // Generate a random double between 0 and 1
  }
  return array;
}

void map_c_array(double *array, int len) {
  for (int i = 0; i < len; i++) {
    array[i] = cos(sin(sqrt(array[i])));
  }
}

void map_c_array_sequential(double* array, int len) {
  for (int i = 0; i < len; i++) {
    array[i] = sqrt(array[i]);
  }
  for (int i = 0; i < len; i++) {
    array[i] = sin(array[i]);
  }
  for (int i = 0; i < len; i++) {
    array[i] = cos(array[i]);
  }
}

void map_C_array_using_OMP(double* array, int len) {
#pragma omp parallel
  {
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = cos(sin(sqrt(array[i])));
    }
  }
}

void map_C_array_sequential_using_OMP(double* array, int len) {
#pragma omp parallel
  {
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = sqrt(array[i]);
    }
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = sin(array[i]);
    }
#pragma omp for schedule(runtime) nowait
    for (int i = 0; i < len; i++) {
      array[i] = cos(array[i]);
    }
  }
}

A critical question is whether the use of fast floating compiler flags, a trick that trades speed for accuracy of the code, can affect performance.
Here is the makefile withut this compiler flag

CC = gcc
CFLAGS = -O3 -ftree-vectorize  -march=native  -Wall -std=gnu11 -fopenmp -fstrict-aliasing 
LDFLAGS = -fPIE -fopenmp
LIBS =  -lm

SOURCES = inplace_array_mod_with_OpenMP.c
OBJECTS = $(SOURCES:.c=_noffmath_gcc.o)
EXECUTABLE = inplace_array_mod_with_OpenMP_noffmath_gcc

all: $(SOURCES) $(EXECUTABLE)

clean:
    rm -f $(OBJECTS) $(EXECUTABLE)

$(EXECUTABLE): $(OBJECTS)
    $(CC) $(LDFLAGS) $(OBJECTS) $(LIBS) -o $@

%_noffmath_gcc.o : %.c 
    $(CC) $(CFLAGS) -c $< -o $@

and here is the one with this flag:

CC = gcc
CFLAGS = -O3 -ftree-vectorize  -march=native -Wall -std=gnu11 -fopenmp -fstrict-aliasing -ffast-math
LDFLAGS = -fPIE -fopenmp
LIBS =  -lm

SOURCES = inplace_array_mod_with_OpenMP.c
OBJECTS = $(SOURCES:.c=_gcc.o)
EXECUTABLE = inplace_array_mod_with_OpenMP_gcc

all: $(SOURCES) $(EXECUTABLE)

clean:
    rm -f $(OBJECTS) $(EXECUTABLE)

$(EXECUTABLE): $(OBJECTS)
    $(CC) $(LDFLAGS) $(OBJECTS) $(LIBS) -o $@

%_gcc.o : %.c 
    $(CC) $(CFLAGS) -c $< -o $@

And here are the results of running these two programs

• Without -ffast-math

OMP_SCHEDULE=guided,1 OMP_NUM_THREADS=8 ./inplace_array_mod_with_OpenMP_noffmath_gcc 50000000
Array size: 50000000
Schedule from env guided,1
Number of threads = 8 from within C
Non-sequential calculation time: 1.12 seconds
Sequential calculation time: 0.95 seconds
Parallel calculation using OMP time: 0.17 seconds
Sequential calculation using OMP time: 0.15 seconds

• With -ffast-math

OMP_SCHEDULE=guided,1 OMP_NUM_THREADS=8 ./inplace_array_mod_with_OpenMP_gcc 50000000
Array size: 50000000
Schedule from env guided,1
Number of threads = 8 from within C
Non-sequential calculation time: 0.27 seconds
Sequential calculation time: 0.28 seconds
Parallel calculation using OMP time: 0.05 seconds
Sequential calculation using OMP time: 0.06 seconds

Note that one can use the fastmath in Numba code as follows (the default is fastmath=False):

@njit(nogil=True,fastmath=True)
def compute_inplace_with_numba(array):
    np.sqrt(array,array)
    np.sin(array,array)
    np.cos(array,array)

A few points that are worth noting:

• The -ffast-math gives major boost in performance (about 300% for both the single threaded and the multi-threaded code), but it can generate erroneous results
• Fastmath also works in Numba, but should be avoided for the same reasons it should be avoided in any application that strives for accuracy
• The sequential C single threaded code gives performance similar to the single threaded PDL and Numpy
• Somewhat surprisingly, the sequential code is about 20% faster than the non-sequential code when the correct (non-fast) math is used.
• Unsurprisingly, multi-threaded code is faster than single threaded code :)
• I still cannot explain how numbas delivers a 50% performance premium over the C code of this rather simple function.