*I indicate matrices by capital letters, and vectors by small letters.*

I need to solve the following system of linear inequalities for vector `v`

:

```
min(rv - (u + Av), v - s) = 0
```

where `0`

is a vector of zeros.

where `r`

is a scalar, `u`

and `s`

are vectors, and `A`

is a matrix.

Defining `z = v-s`

, `B=rI - A`

, `q=-u + Bs`

, I can rewrite the previous problem as a linear complementarity problem and hope to use an LCP solver, for example from `openopt`

:

```
LCP(M, z): min(Bz+q, z) = 0
```

or, in matrix notation:

```
z'(Bz+q) = 0
z >= 0
Bz + q >= 0
```

The problem is that my system of equations is huge. To create `A`

, I

- Create four matrices
`A11`

,`A12`

,`A21`

,`A22`

using`scipy.sparse.diags`

- And stack them together as
`A = scipy.sparse.bmat([[A11, A12], [A21, A22]])`

- (This also means that
`A`

is not symmetric, and hence some efficient translations into`QP`

problems won't work)

`openopt.LCP`

apparently cannot deal with sparse matrices: When I ran this, my computer crashed. Generally, `A.todense()`

will lead to a memory error. Similarly, `compecon-python`

is not able to solve `LCP`

problems with sparse matrices.

What alternative `LCP`

implementations are fit for this problem?

I really did not think *sample data* was required for a general "which tools to solve LCP" question were required, but anyways, here we go

```
from numpy.random import rand
from scipy import sparse
n = 3000
r = 0.03
A = sparse.diags([-rand(n)], [0])
s = rand(n,).reshape((-1, 1))
u = rand(n,).reshape((-1, 1))
B = sparse.eye(n)*r - A
q = -u + B.dot(s)
q.shape
Out[37]: (3000, 1)
B
Out[38]:
<3000x3000 sparse matrix of type '<class 'numpy.float64'>'
with 3000 stored elements in Compressed Sparse Row format>
```

Some more pointers:

`openopt.LCP`

crashes with my matrices, I assume it converts the matrices to dense before continuing`compecon-python`

outright fails with some error, it apparently requires dense matrices and has no fallback for sparsity`B`

is not positive semi-definite, so I cannot rephrase the linear complementarity problem (LCP) as a convex quadratic problem (QP)- All QP sparse solvers from this exposition require the problem to be convex, which mine is not
- In Julia, PATHSolver can solve my problem (given a license). However, there are problems calling it from Python with PyJulia (my issue report here)
- Also Matlab has an LCP solver that apparently can handle sparse matrices, but there implementation is even more wacky (and I really do not want to fallback on Matlab for this)

`scipy.sparse`

. They are built around the idea of linear operator, something with a matrix vector product,`A*v`

. Anything that assumes more about the matrix is likely to have problems with a sparse matrix. It has to explicitly say it works with`scipy.sparse`

(and which format).`LCP`

methods I found at`openopt`

appeared not to work - what exactly can I do with`nonOptMisc`

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