To add another point to Ralf Stubner's solution, then you can use the following C++ version to

- do multiple columns at the same time to avoid re-reading the output vector many times.
- add
`__restrict__`

to potentially allow for vector operations (likely does not matter here as it is only reads I guess).

```
#include <Rcpp.h>
using namespace Rcpp;
inline void mat_vec_mult_vanilla
(double const * __restrict__ m,
double const * __restrict__ v,
double * __restrict__ const res,
size_t const dn, size_t const dm) noexcept {
for(size_t j = 0; j < dm; ++j, ++v){
double * r = res;
for(size_t i = 0; i < dn; ++i, ++r, ++m)
*r += *m * *v;
}
}
inline void mat_vec_mult
(double const * __restrict__ const m,
double const * __restrict__ const v,
double * __restrict__ const res,
size_t const dn, size_t const dm) noexcept {
size_t j(0L);
double const * vj = v,
* mi = m;
constexpr size_t const ncl(8L);
{
double const * mvals[ncl];
size_t const end_j = dm - (dm % ncl),
inc = ncl * dn;
for(; j < end_j; j += ncl, vj += ncl, mi += inc){
double *r = res;
mvals[0] = mi;
for(size_t i = 1; i < ncl; ++i)
mvals[i] = mvals[i - 1L] + dn;
for(size_t i = 0; i < dn; ++i, ++r)
for(size_t ii = 0; ii < ncl; ++ii)
*r += *(vj + ii) * *mvals[ii]++;
}
}
mat_vec_mult_vanilla(mi, vj, res, dn, dm - j);
}
// [[Rcpp::export("mat_vec_mult", rng = false)]]
NumericVector mat_vec_mult_cpp(NumericMatrix m, NumericVector v){
size_t const dn = m.nrow(),
dm = m.ncol();
NumericVector res(dn);
mat_vec_mult(&m[0], &v[0], &res[0], dn, dm);
return res;
}
// [[Rcpp::export("mat_vec_mult_vanilla", rng = false)]]
NumericVector mat_vec_mult_vanilla_cpp(NumericMatrix m, NumericVector v){
size_t const dn = m.nrow(),
dm = m.ncol();
NumericVector res(dn);
mat_vec_mult_vanilla(&m[0], &v[0], &res[0], dn, dm);
return res;
}
```

The result with `-O3`

in my Makevars file and gcc-8.3 is

```
set.seed(1)
dn <- 10001L
dm <- 10001L
m <- matrix(rnorm(dn * dm), dn, dm)
lv <- rnorm(dm)
all.equal(drop(m %*% lv), mat_vec_mult(m = m, v = lv))
#R> [1] TRUE
all.equal(drop(m %*% lv), mat_vec_mult_vanilla(m = m, v = lv))
#R> [1] TRUE
bench::mark(
R = m %*% lv,
`OP's version` = my_mm(m = m, v = lv),
`BLAS` = blas_mm(m = m, v = lv),
`C++ vanilla` = mat_vec_mult_vanilla(m = m, v = lv),
`C++` = mat_vec_mult(m = m, v = lv), check = FALSE)
#R> # A tibble: 5 x 13
#R> expression min median `itr/sec` mem_alloc `gc/sec` n_itr n_gc total_time result memory time gc
#R> <bch:expr> <bch:tm> <bch:tm> <dbl> <bch:byt> <dbl> <int> <dbl> <bch:tm> <list> <list> <list> <list>
#R> 1 R 147.9ms 151ms 6.57 78.2KB 0 4 0 609ms <NULL> <Rprofmem[,3] [2 × 3]> <bch:tm [4]> <tibble [4 × 3]>
#R> 2 OP's version 56.9ms 57.1ms 17.4 78.2KB 0 9 0 516ms <NULL> <Rprofmem[,3] [2 × 3]> <bch:tm [9]> <tibble [9 × 3]>
#R> 3 BLAS 90.1ms 90.7ms 11.0 78.2KB 0 6 0 545ms <NULL> <Rprofmem[,3] [2 × 3]> <bch:tm [6]> <tibble [6 × 3]>
#R> 4 C++ vanilla 57.2ms 57.4ms 17.4 78.2KB 0 9 0 518ms <NULL> <Rprofmem[,3] [2 × 3]> <bch:tm [9]> <tibble [9 × 3]>
#R> 5 C++ 51ms 51.4ms 19.3 78.2KB 0 10 0 519ms <NULL> <Rprofmem[,3] [2 × 3]> <bch:tm [10]> <tibble [10 × 3]>
```

So a slight improvement. The result may though be very dependent on the BLAS version. The version I used is

```
sessionInfo()
#R> #...
#R> Matrix products: default
#R> BLAS: /usr/lib/x86_64-linux-gnu/blas/libblas.so.3.7.1
#R> LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.7.1
#R> ...
```

The whole file I `Rcpp::sourceCpp()`

ed is

```
#include <Rcpp.h>
#include <R_ext/BLAS.h>
using namespace Rcpp;
inline void mat_vec_mult_vanilla
(double const * __restrict__ m,
double const * __restrict__ v,
double * __restrict__ const res,
size_t const dn, size_t const dm) noexcept {
for(size_t j = 0; j < dm; ++j, ++v){
double * r = res;
for(size_t i = 0; i < dn; ++i, ++r, ++m)
*r += *m * *v;
}
}
inline void mat_vec_mult
(double const * __restrict__ const m,
double const * __restrict__ const v,
double * __restrict__ const res,
size_t const dn, size_t const dm) noexcept {
size_t j(0L);
double const * vj = v,
* mi = m;
constexpr size_t const ncl(8L);
{
double const * mvals[ncl];
size_t const end_j = dm - (dm % ncl),
inc = ncl * dn;
for(; j < end_j; j += ncl, vj += ncl, mi += inc){
double *r = res;
mvals[0] = mi;
for(size_t i = 1; i < ncl; ++i)
mvals[i] = mvals[i - 1L] + dn;
for(size_t i = 0; i < dn; ++i, ++r)
for(size_t ii = 0; ii < ncl; ++ii)
*r += *(vj + ii) * *mvals[ii]++;
}
}
mat_vec_mult_vanilla(mi, vj, res, dn, dm - j);
}
// [[Rcpp::export("mat_vec_mult", rng = false)]]
NumericVector mat_vec_mult_cpp(NumericMatrix m, NumericVector v){
size_t const dn = m.nrow(),
dm = m.ncol();
NumericVector res(dn);
mat_vec_mult(&m[0], &v[0], &res[0], dn, dm);
return res;
}
// [[Rcpp::export("mat_vec_mult_vanilla", rng = false)]]
NumericVector mat_vec_mult_vanilla_cpp(NumericMatrix m, NumericVector v){
size_t const dn = m.nrow(),
dm = m.ncol();
NumericVector res(dn);
mat_vec_mult_vanilla(&m[0], &v[0], &res[0], dn, dm);
return res;
}
// [[Rcpp::export(rng = false)]]
NumericVector my_mm(NumericMatrix m, NumericVector v){
int nRow = m.rows();
int nCol = m.cols();
NumericVector ans(nRow);
double v_j;
for(int j = 0; j < nCol; j++){
v_j = v[j];
for(int i = 0; i < nRow; i++){
ans[i] += m(i,j) * v_j;
}
}
return(ans);
}
// [[Rcpp::export(rng = false)]]
NumericVector blas_mm(NumericMatrix m, NumericVector v){
int nRow = m.rows();
int nCol = m.cols();
NumericVector ans(nRow);
char trans = 'N';
double one = 1.0, zero = 0.0;
int ione = 1;
F77_CALL(dgemv)(&trans, &nRow, &nCol, &one, m.begin(), &nRow, v.begin(),
&ione, &zero, ans.begin(), &ione);
return ans;
}
/*** R
set.seed(1)
dn <- 10001L
dm <- 10001L
m <- matrix(rnorm(dn * dm), dn, dm)
lv <- rnorm(dm)
all.equal(drop(m %*% lv), mat_vec_mult(m = m, v = lv))
all.equal(drop(m %*% lv), mat_vec_mult_vanilla(m = m, v = lv))
bench::mark(
R = m %*% lv,
`OP's version` = my_mm(m = m, v = lv),
`BLAS` = blas_mm(m = m, v = lv),
`C++ vanilla` = mat_vec_mult_vanilla(m = m, v = lv),
`C++` = mat_vec_mult(m = m, v = lv), check = FALSE)
*/
```

`getAnywhere(`

%*%`)`

, we have:`function (x, y) .Primitive("%*%")`

. So, this is interfacing with aClibrary but as @joran points out, you are not factoring in`NA`

handling.`NA`

's properly. The only difference I can see is that this results in a vector not a matrix.1more comment