I'm new to the concept of concurrent and parallel programing in general. I'm trying to calculate Pi using Monte Carlo method in C. Here is my source code:
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>
int main(void)
{
long points;
long m = 0;
double coord...
@dreamcrash With all due respect, if your claim were correct ( obtaining a 4x speedup ), Dr. Gene AMDAHL's arguments would have gone ( which they never can ). No matter how short the initial (principally SERIAL, non-PARALLEL-isable) processing setup efforts take, these can never get avoided and the speedup can never reach 4.00 x. The higher the loop-count, the smaller the SERIAL fraction will remain and still bearing all the add-on overhead costs makes the limit of 4.00 x speedup principally not achievable :o) The Math ...
@user3666197 You can speedups with more than 4x for a 4 cores, with an improving on cache locality. If you have less miss in the parallel version than in the sequential.
@user3666197 the actually speedup was 3.96x, and I can provide it very easily if you want.
@user3666197 "These can never get avoided and the speedup can never reach 4.00 x." you clearly never worked in HPC before
@dreamcrash - well, this is not an argument. HPC practitioners often present a SUPER-LINEAR speedup figures, yet these never get a level playfield - as the "baseline" for the comparison has never been run at a very same playfield as the "claimed" super-linear instruction-mix. Not my fault, yet if one starts to compare apples-to-oranges, may we live with claims that oranges are super-linear spead-up apples ( because having been grown in other biotop ) -- grow the oranges in the exactly the same eco-system -- ( i.e.same mem-I/O bottlenecks (non-free channels due to NUMA-colocated ) )
This question was about the overheads, I was the only one point out the overheads besides the obvious rand. None have provided a solution actually using openMP. I compare the same sequential version with correspond parallel version. For some reason you start to pick on myself with comments like :"Proposing timed-sections is left to @dreamcrash for having a level plainfield for re-testing with meaningful comparisons:" I have better to do. Obviously, if you optimized the seq. code as much as possible you will likely have less speedups on the parallel version. Did I claim otherwise?
If one inspects the assembly code for the claimed super-linear speedups, soon you realise that original apples can never get fair compared with oranges, the less with oranges-on-transformed-code-on-steroids. ( Code works faster, no doubts about that, yet the code is, for many reasons, way different than was the pure-[SERIAL] version one started with, so shan't be promoted as a fair baseline for such super-linearity skewed comparisons --- or, provide the same footprint of non-blocking, non-cross-QPI / NUMA-equalised L1data access, and there we go to compare a "same" code under fair conditions )
@user3666197 "way different than was the pure-[SERIAL] version one started with?" I used the same code with 4 threads and without any threads. One could claim that it is unfair for the sequential version because one could try to optimized further with SIMD instructions and so on.
@user3666197 I added some results testing against you optimized version. So your optimized sequential version compared with my non optimized parallel version. The speedup was 2.27 for 4 cores.
@Jean-BaptisteYunès no need to say sorry, you were just trying to help, everyone makes mistakes :)
@Amirreza A. Do you mind testing the parallel version?
@user3666197 Btw you have a race conditions in your code, namely coordinates[0] = rand_r( &aThreadSpecificSEED_x ); and coordinates[1] = rand_r( &aThreadSpecificSEED_y ); since double coordinates[2]; is shared among threads.
Nice speeds up, this is with the first or second version? The second version contains some of the optimizations that @user3666197 did, which made the sequential code faster, I added the parallelism there you probably will even get a better execution time
