# Fastest way to create a sparse matrix of the form A.T * diag(b) * A + C?

I'm trying to optimize a piece of code that solves a large sparse nonlinear system using an interior point method. During the update step, this involves computing the Hessian matrix `H`, the gradient `g`, then solving for `d` in `H * d = -g` to get the new search direction.

The Hessian matrix has a symmetric tridiagonal structure of the form:

A.T * diag(b) * A + C

I've run `line_profiler` on the particular function in question:

``````Line # Hits     Time  Per Hit % Time Line Contents
==================================================
386                               def _direction(n, res, M, Hsig, scale_var, grad_lnprior, z, fac):
387
389   44  1241715  28220.8    3.7     g = 2 * scale_var * res - grad_lnprior + z * np.dot(M.T, 1. / n)
390
391                                   # hessian
392   44  3103117  70525.4    9.3     N = sparse.diags(1. / n ** 2, 0, format=FMT, dtype=DTYPE)
393   44 18814307 427597.9   56.2     H = - Hsig - z * np.dot(M.T, np.dot(N, M))    # slow!
394
395                                   # update direction
396   44 10329556 234762.6   30.8     d, fac = my_solver(H, -g, fac)
397
398   44      111      2.5    0.0     return d, fac
``````

Looking at the output it's clear that constructing `H` is by far the most costly step - it takes considerably longer than actually solving for the new direction.

`Hsig` and `M` are both CSC sparse matrices, `n` is a dense vector and `z` is a scalar. The solver I'm using requires `H` to be either a CSC or CSR sparse matrix.

Here's a function that produces some toy data with the same formats, dimensions and sparseness as my real matrices:

``````import numpy as np
from scipy import sparse

def make_toy_data(nt=200000, nc=10):

d0 = np.random.randn(nc * (nt - 1))
d1 = np.random.randn(nc * (nt - 1))
M = sparse.diags((d0, d1), (0, nc), shape=(nc * (nt - 1), nc * nt),
format='csc', dtype=np.float64)

d0 = np.random.randn(nc * nt)
Hsig = sparse.diags(d0, 0, shape=(nc * nt, nc * nt), format='csc',
dtype=np.float64)

n = np.random.randn(nc * (nt - 1))
z = np.random.randn()

return Hsig, M, n, z
``````

And here's my original approach for constructing `H`:

``````def original(Hsig, M, n, z):
N = sparse.diags(1. / n ** 2, 0, format='csc')
H = - Hsig - z * np.dot(M.T, np.dot(N, M))    # slow!
return H
``````

Timing:

``````%timeit original(Hsig, M, n, z)
# 1 loops, best of 3: 483 ms per loop
``````

Is there a faster way to construct this matrix?

• My NumPy won't let me do `np.dot(M.T, np.dot(N, M))`. Does it definitely run on your machine? Do you want to do `N.dot(M)`? – YXD Apr 17 '14 at 22:02
• @MrE I suspect it's probably a version issue - `numpy.dot()` is overridden for sparse matrices as of this commit 8 months ago. – ali_m Apr 17 '14 at 22:28
• You don't need `dot`, just `Hsig - z * M.T * (N * M)`, but I don't know whether it's faster. – HYRY Apr 18 '14 at 2:12
• @HYRY Yeah, I know - I almost always work with ndarrays rather than matrices, so the `np.dot()` syntax feels more natural to me than `*`. There's no real performance difference, since both just call the `.__mul__()` method of the sparse matrix. – ali_m Apr 18 '14 at 2:54

I get close to a 4x speed-up in computing the product `M.T * D * M` out of the three diagonal arrays. If `d0` and `d1` are the main and upper diagonal of `M`, and `d` is the main diagonal of `D`, then the following code creates `M.T * D * M` directly:

``````def make_tridi_bis(d0, d1, d, nc=10):
d00 = d0*d0*d
d11 = d1*d1*d
d01 = d0*d1*d
len_ = d0.size
data = np.empty((3*len_ + nc,))
indices = np.empty((3*len_ + nc,), dtype=np.int)
# Fill main diagonal
data[:2*nc:2] = d00[:nc]
indices[:2*nc:2] = np.arange(nc)
data[2*nc+1:-2*nc:3] = d00[nc:] + d11[:-nc]
indices[2*nc+1:-2*nc:3] = np.arange(nc, len_)
data[-2*nc+1::2] = d11[-nc:]
indices[-2*nc+1::2] = np.arange(len_, len_ + nc)
# Fill top diagonal
data[1:2*nc:2] = d01[:nc]
indices[1:2*nc:2] = np.arange(nc, 2*nc)
data[2*nc+2:-2*nc:3] = d01[nc:]
indices[2*nc+2:-2*nc:3] = np.arange(2*nc, len_+nc)
# Fill bottom diagonal
data[2*nc:-2*nc:3] = d01[:-nc]
indices[2*nc:-2*nc:3] = np.arange(len_ - nc)
data[-2*nc::2] = d01[-nc:]
indices[-2*nc::2] = np.arange(len_ - nc ,len_)

indptr = np.empty((len_ + nc + 1,), dtype=np.int)
indptr = 0
indptr[1:nc+1] = 2
indptr[nc+1:len_+1] = 3
indptr[-nc:] = 2
np.cumsum(indptr, out=indptr)

return sparse.csr_matrix((data, indices, indptr), shape=(len_+nc, len_+nc))
``````

If your matrix `M` were in CSR format, you can extract `d0` and `d1` as `d0 = M.data[::2]` and `d1 = M.data[1::2]`, I modified you toy data making routine to return those arrays as well, and here's what I get:

``````In : np.allclose((M.T * sparse.diags(d, 0) * M).A, make_tridi_bis(d0, d1, d).A)
Out: True

In : %timeit make_tridi_bis(d0, d1, d)
10 loops, best of 3: 124 ms per loop

In : %timeit M.T * sparse.diags(d, 0) * M
1 loops, best of 3: 501 ms per loop
``````

The whole purpose of the above code is to take advantage of the structure of the non-zero entries. If you draw a diagram of the matrices you are multiplying together, it is relatively easy to convince yourself that the main (`d_0`) and top and bottom (`d_1`) diagonals of the resulting tridiagonal matrix are simply:

``````d_0 = np.zeros((len_ + nc,))
d_0[:len_] = d00
d_0[-len_:] += d11

d_1 = d01
``````

The rest of the code in that function is simply building the tridiagonal matrix directly, as calling `sparse.diags` with the above data is several times slower.

• That is impressively quick. I'm still trying to wrap my head around how it works. If I wanted to construct just the main and upper/lower diagonals of `M.T * D * M` as dense vectors, how would I obtain these? – ali_m Apr 18 '14 at 14:56
• See my edit on what the diagonals are. – Jaime Apr 18 '14 at 16:50
• Fantastic, that's very useful! – ali_m Apr 18 '14 at 16:59

I tried running your test case and had problems with the `np.dot(N, M)`. I didn't dig into it, but I think my numpy/sparse combo (both pretty new) had problems using `np.dot` on sparse arrays.

But `H = -Hsig - z*M.T.dot(N.dot(M))` runs just fine. This uses the `sparse dot`.

I haven't run a profile, but here are Ipython timings for several parts. It takes longer to generate the data than to do that double dot.

``````In : timeit Hsig,M,n,z=make_toy_data()
1 loops, best of 3: 2 s per loop

In : timeit N = sparse.diags(1. / n ** 2, 0, format='csc')
1 loops, best of 3: 377 ms per loop

In : timeit H = -Hsig - z*M.T.dot(N.dot(M))
1 loops, best of 3: 1.55 s per loop
``````

`H` is a

``````<2000000x2000000 sparse matrix of type '<type 'numpy.float64'>'
with 5999980 stored elements in Compressed Sparse Column format>
``````
• As I mentioned above, the issues with `np.dot(N, M)` are version-related - in recent versions of scipy, the `.dot()` method of sparse arrays overrides `np.dot()`, so in my case the two are equivalent (and for some reason the `np.dot(A, B)` syntax feels more comfortable to me :-)). Regarding the timings, I only construct `Hsig` and `M` once but the `_direction()` function is called 1000s of times, so I really do care about the overhead involved in constructing `H`. – ali_m Apr 17 '14 at 22:39
• The sparse .dot is just matrix multiplication, so you could write `M.T*(N*M)` or even `M.T*N*M`. Not that there's any speed difference. The sparsetools.csr.h file references this SMMP paper: mgnet.org/~douglas/Preprints/pub0034.pdf – hpaulj Apr 18 '14 at 2:35