# STL thrust multiple vector transform?

I was wondering if there was a more efficient way of writing a = a + b + c?

`````` thrust::transform(b.begin(), b.end(), c.begin(), b.begin(), thrust::plus<int>());
thrust::transform(a.begin(), a.end(), b.begin(), a.begin(), thrust::plus<int>());
``````

This works but is there a way to get the same effect using just one line of code? I looked at the saxpy implementation in the examples, however this uses 2 vectors and a constant value;

Is this more efficient?

``````struct arbitrary_functor
{
template <typename Tuple>
__host__ __device__
void operator()(Tuple t)
{
// D[i] = A[i] + B[i] + C[i];
thrust::get<3>(t) = thrust::get<0>(t) + thrust::get<1>(t) + thrust::get<2>(t);
}
};

int main(){

// allocate storage
thrust::host_vector<int> A;
thrust::host_vector<int> B;
thrust::host_vector<int> C;

// initialize input vectors
A.push_back(10);
B.push_back(10);
C.push_back(10);

// apply the transformation
thrust::for_each(thrust::make_zip_iterator(thrust::make_tuple(A.begin(), B.begin(), C.begin(), A.begin())),
thrust::make_zip_iterator(thrust::make_tuple(A.end(),   B.end(),   C.end(),   A.end())),
arbitrary_functor());

// print the output
std::cout << A[0] << std::endl;

return 0;
}
``````
-
This looks pretty good to me. –  Lightness Races in Orbit Sep 22 '11 at 10:48

`a = a + b + c` has low arithmetic intensity (only two arithmetic operations for every 4 memory operations), so the computation is going to be memory bandwidth bound. To compare the efficiency of your proposed solutions, we need to measure their bandwidth demands.
Each call to `transform` in the first solution requires two loads and one store for each call to `plus`. So we can model the cost of each `transform` call as `3N`, where `N` is the size of the vectors `a`, `b`, and `c`. Since there are two invocations of `transform`, the cost of this solution is `6N`.
We can model the cost of the second solution in the same way. Each invocation of `arbitrary_functor` requires three loads and one store. So a cost model for this solution would be `4N`, which implies that the `for_each` solution should be more efficient than calling `transform` twice. When `N` is large, the second solution should perform `6N/4N = 1.5x` faster than the first.
Of course, you could always combine `zip_iterator` with `transform` in a similar way to avoid two separate calls to `transform`.