I have written the following codes in R and C++ which perform the same algorithm:

a) To simulate the random variable X 500 times. (X has value 0.9 with prob 0.5 and 1.1 with prob 0.5)

b) Multiply these 500 simulated values together to get a value. Save that value in a container

c) Repeat 10000000 times such that the container has 10000000 values

R:

```
ptm <- proc.time()
steps <- 500
MCsize <- 10000000
a <- rbinom(MCsize,steps,0.5)
b <- rep(500,times=MCsize) - a
result <- rep(1.1,times=MCsize)^a*rep(0.9,times=MCsize)^b
proc.time()-ptm
```

C++

```
#include <numeric>
#include <vector>
#include <iostream>
#include <random>
#include <thread>
#include <mutex>
#include <cmath>
#include <algorithm>
#include <chrono>
const size_t MCsize = 10000000;
std::mutex mutex1;
std::mutex mutex2;
unsigned seed_;
std::vector<double> cache;
void generatereturns(size_t steps, int RUNS){
mutex2.lock();
// setting seed
try{
std::mt19937 tmpgenerator(seed_);
seed_ = tmpgenerator();
std::cout << "SEED : " << seed_ << std::endl;
}catch(int exception){
mutex2.unlock();
}
mutex2.unlock();
// Creating generator
std::binomial_distribution<int> distribution(steps,0.5);
std::mt19937 generator(seed_);
for(int i = 0; i!= RUNS; ++i){
double power;
double returns;
power = distribution(generator);
returns = pow(0.9,power) * pow(1.1,(double)steps - power);
std::lock_guard<std::mutex> guard(mutex1);
cache.push_back(returns);
}
}
int main(){
std::chrono::steady_clock::time_point start = std::chrono::steady_clock::now();
size_t steps = 500;
seed_ = 777;
unsigned concurentThreadsSupported = std::max(std::thread::hardware_concurrency(),(unsigned)1);
int remainder = MCsize % concurentThreadsSupported;
std::vector<std::thread> threads;
// starting sub-thread simulations
if(concurentThreadsSupported != 1){
for(int i = 0 ; i != concurentThreadsSupported - 1; ++i){
if(remainder != 0){
threads.push_back(std::thread(generatereturns,steps,MCsize / concurentThreadsSupported + 1));
remainder--;
}else{
threads.push_back(std::thread(generatereturns,steps,MCsize / concurentThreadsSupported));
}
}
}
//starting main thread simulation
if(remainder != 0){
generatereturns(steps, MCsize / concurentThreadsSupported + 1);
remainder--;
}else{
generatereturns(steps, MCsize / concurentThreadsSupported);
}
for (auto& th : threads) th.join();
std::chrono::steady_clock::time_point end = std::chrono::steady_clock::now() ;
typedef std::chrono::duration<int,std::milli> millisecs_t ;
millisecs_t duration( std::chrono::duration_cast<millisecs_t>(end-start) ) ;
std::cout << "Time elapsed : " << duration.count() << " milliseconds.\n" ;
return 0;
}
```

I can't understand why my R code is so much faster than my C++ code (3.29s vs 12s) even though I have used four threads in the C++ code? Can anyone enlighten me please? How should I improve my C++ code to make it run faster?

EDIT:

Thanks for all the advice! I reserved capacity for my vectors and reduced the amount of locking in my code. The crucial update in the generatereturns() function is :

```
std::vector<double> cache(MCsize);
std::vector<double>::iterator currit = cache.begin();
//.....
// Creating generator
std::binomial_distribution<int> distribution(steps,0.5);
std::mt19937 generator(seed_);
std::vector<double> tmpvec(RUNS);
for(int i = 0; i!= RUNS; ++i){
double power;
double returns;
power = distribution(generator);
returns = pow(0.9,power) * pow(1.1,(double)steps - power);
tmpvec[i] = returns;
}
std::lock_guard<std::mutex> guard(mutex1);
std::move(tmpvec.begin(),tmpvec.end(),currit);
currit += RUNS;
```

Instead of locking every time, I created a temporary vector and then used std::move to shift the elements in that tempvec into cache. Now the elapsed time has reduced to 1.9seconds.

`rep`

is a primitive, meaning that it calls C code directly and it contains no R code. That speeds it up quite a bit. – Rich Scriven May 2 '14 at 8:59