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In some computations on the GPU I need to scale the rows in a matrix so that all the elements in a given row sum to 1.

| a1,1 a1,2 ... a1,N |    | alpha1*a1,1 alpha1*a1,2 ... alpha1*a1,N |
| a2,1 a2,2 ... a2,N | => | alpha2*a2,1 alpha2*a2,2 ... alpha2*a2,N |
| .            .  |    | .                                .  |
| aN,1 aN,2 ... aN,N |    | alphaN*aN,1 alphaN*aN,2 ... alphaN*aN,N |

where

alphai =  1.0/(ai,1 + ai,2 + ... + ai,N)

I need the vector of alpha's, and the scaled matrix

and I would like to do this in as few blas calls as posible.

The code is going to run on nvidia CUDA hardware.

Does anyone know of anysmart way to do this?

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2 Answers 2

up vote 1 down vote accepted

If you use BLAS gemv with a unit vector, the result will a vector of the reciprocal of scaling factors (1/alpha) you need. That is the easy part.

Applying the factors row wise is a bit harder, because standard BLAS doesn't have anything like a Hadamard product operator you could use. Also because you are mentioning BLAS, I presume you are using column major order storage for your matrices, which is not so straightforward for row wise operations. The really slow way to do it would be to BLAS scal on each row with a pitch, but that would require one BLAS call per row and the pitched memory access will kill performance because of the effect on coalescing and L1 cache coherency.

My suggestion would be to use your own kernel for the second operation. It doesn't have to be all that complex, perhaps only something like this:

template<typename T>
__global__ void rowscale(T * X, const int M, const int N, const int LDA,
                             const T * ralpha)
{
    for(int row=threadIdx.x; row<M; row+=gridDim.x) {
        const T rscale = 1./ralpha[row]; 
        for(int col=blockIdx.x; col<N; col+=blockDim.x) 
            X[row+col*LDA] *= rscale;
    }
}

That just has a bunch of blocks stepping through the rows columnwise, scaling as they go along. Should work for any sized column major ordered matrix. Memory access should be coalesced, but depending on how worried about performance you are, there are a number of optimization you could try. It at least gives a general idea of what to do.

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That was what I had concluded on my own, (as for the whole row vs col, if one is better than the other I will just rearrange my data -- transpose here I come:) –  Martin Kristiansen Feb 15 '12 at 13:29
    
@MartinKristiansen: There isn't really a "better" order for this, except that a naïve, purely row oriented scaling operation (ie row by row scal) won't perform well on column major order data because of the stride of the row entries (at least the height of the matrix). But a sensibly designed scheme will do just as well on column major as on row major data. –  talonmies Feb 15 '12 at 13:48

Cublas 5.0 introduced a blas-like routine called cublas(Type)dgmm which is the multiplication of a matrix by a diagonal matrix (represented by a vector).

There is a left option ( which will scale the rows) or a right option that will scale the column.

Please refer to CUBLAS 5.0 documentation for details.

So in your problem, you need to create a vector containing all the alpha on the GPU and use cublasdgmm with the left option.

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Dammit, I handed in my thesis 20 days ago.. perhaps I will mention it in the defence :-) Thank you. –  Martin Kristiansen Sep 28 '12 at 9:27

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