I'm using the Anaconda distribution of Python, together with Numba, and I've written the following Python function that multiplies a sparse matrix ** A** (stored in a CSR format) by a dense vector

**:**

`x`

```
@jit
def csrMult( x, Adata, Aindices, Aindptr, Ashape ):
numRowsA = Ashape[0]
Ax = numpy.zeros( numRowsA )
for i in range( numRowsA ):
Ax_i = 0.0
for dataIdx in range( Aindptr[i], Aindptr[i+1] ):
j = Aindices[dataIdx]
Ax_i += Adata[dataIdx] * x[j]
Ax[i] = Ax_i
return Ax
```

Here ** A** is a large

`scipy`

sparse matrix,```
>>> A.shape
( 56469, 39279 )
# having ~ 142,258,302 nonzero entries (so about 6.4% )
>>> type( A[0,0] )
dtype( 'float32' )
```

and ** x** is a

`numpy`

array. Here is a snippet of code that calls the above function:```
x = numpy.random.randn( A.shape[1] )
Ax = A.dot( x )
AxCheck = csrMult( x, A.data, A.indices, A.indptr, A.shape )
```

Notice the ** @jit**-decorator that tells Numba to do a just-in-time compilation for the

**function.**

`csrMult()`

In my experiments, my function `csrMult()`

is about **twice as fast** as the `scipy`

** .dot()** method. That is a pretty impressive result for Numba.

However, MATLAB still performs this matrix-vector multiplication about **6 times faster** than `csrMult()`

. I believe that is because MATLAB uses multithreading when performing sparse matrix-vector multiplication.

**Question:**

How can I parallelize the outer `for`

-loop when using Numba?

Numba used to have a ** prange()** function, that made it simple to parallelize embarassingly parallel

**-loops. Unfortunately, Numba no longer has**

`for`

`prange()`

[**actually, that is false, see the edit below**].

**So what is the correct way to parallelize this**

`for`

-loop now, that Numba's `prange()`

function is gone?When `prange()`

was removed from Numba, what alternative did the developers of Numba have in mind?

Edit 1:

I updated to the latest version of Numba, which is .35, and`prange()`

is back! It was not included in version .33, the version I had been using.

That is good news, but unfortunately I am getting an error message when I attempt to parallelize my for loop using`prange()`

. Here is a parallel for loop example from the Numba documentation (see section 1.9.2 "Explicit Parallel Loops"), and below is my new code:

```
from numba import njit, prange
@njit( parallel=True )
def csrMult_numba( x, Adata, Aindices, Aindptr, Ashape):
numRowsA = Ashape[0]
Ax = np.zeros( numRowsA )
for i in prange( numRowsA ):
Ax_i = 0.0
for dataIdx in range( Aindptr[i],Aindptr[i+1] ):
j = Aindices[dataIdx]
Ax_i += Adata[dataIdx] * x[j]
Ax[i] = Ax_i
return Ax
```

When I call this function, using the code snippet given above, I receive the following error:

AttributeError: Failed at nopython (convert to parfors) 'SetItem' object has no attribute 'get_targets'

## Given

the above attempt to use `prange`

crashes, my question stands:

**What is the correct way** ( using `prange`

or an alternative method ) **to parallelize this Python for-loop?**

As noted below, it was trivial to parallelize a similar for loop in C++ and obtain an **8x** speedup, having been run on **20**-omp-threads. There must be a way to do it using Numba, since the for loop is embarrassingly parallel (and since sparse matrix-vector multiplication is a fundamental operation in scientific computing).

Edit 2:

Here is my C++ version of`csrMult()`

. Parallelizing the`for()`

loop in the C++ version makes the code about 8x faster in my tests. This suggests to me that a similar speedup should be possible for the Python version when using Numba.

```
void csrMult(VectorXd& Ax, VectorXd& x, vector<double>& Adata, vector<int>& Aindices, vector<int>& Aindptr)
{
// This code assumes that the size of Ax is numRowsA.
#pragma omp parallel num_threads(20)
{
#pragma omp for schedule(dynamic,590)
for (int i = 0; i < Ax.size(); i++)
{
double Ax_i = 0.0;
for (int dataIdx = Aindptr[i]; dataIdx < Aindptr[i + 1]; dataIdx++)
{
Ax_i += Adata[dataIdx] * x[Aindices[dataIdx]];
}
Ax[i] = Ax_i;
}
}
}
```

`parallel=True`

keyword argument to the`jit`

decorator? I mean annotating it with`@jit(parallel=True)`

?`@jit`

with`@jit(parallel=True)`

, and when I ran my test code snippet I received the following error message: KeyError: "<class 'numba.targets.cpu.CPUTargetOptions'> does not support option: 'parallel'"`@vectorize`

or`@guvectorize`

(to generate ufuncs). Maybe you even have to roll out the inner loop into another function for that.How large and how sparseis thematrix ( rows, cols, dtype ) + a ( sparse / dense ) occupancy ratio? N.b.: Trying to compare a MATLAB code-execution with Py3/Numba ecosystem tooling may be a lot misleading.`A`

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