highs-sys 1.14.0

Rust binding for the HiGHS linear programming solver. See http://highs.dev.
Documentation 
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# Parallelism

## Generally

HiGHS currently has limited opportunities for exploiting parallel
computing. When using a CPU, these are currently restricted to the
dual simplex solver for LP, and the MIP solver. Details of these and
future plans are set out below. HiGHS has an implementation of a first
order method (PDLP) for solving LPs that can exploit the availability of a
[GPU](@ref gpu).

By default, when running in parallel, HiGHS will use half the
available threads on a machine. This number can be modified by setting
the value of the [threads](@ref) option.

## Dual simplex

By default, the HiGHS dual simplex solver runs in serial. However, it
has a variant allowing concurrent processing. This variant is used
when the
[parallel](@ref)
option is set "on", by specifying `--parallel` when running the
[executable](@ref executable) via
the command line, or by setting it via a library call in an
application.

The concurrency used will be the value of
[simplex\_max\_concurrency](@ref). If
this is fewer than the number of threads available, parallel
performance may be less than anticipated.

The speed-up achieved using the dual simplex solver is normally
bounded by the number of memory channels in the architecture, and
typically less than the values achieved by [Huangfu and
Hall](https://link.springer.com/article/10.1007/s12532-017-0130-5). This
is because enhancements to the serial dual simplex solver in recent
years have not been propagated to the parallel solver.

Unless an LP has significantly more variables than constraints, the
parallel dual simplex solver is unlikely to be worth using.

## MIP

The only parallel computation currently implemented in the MIP solver
occurs when performing symmetry detection on the model, when querying
clique tables, and when the interior point solver is used to compute
the analytic centre. This parallelism is always advantageous, so is
performed regardless of the value of the [parallel](@ref) option.

## Future plans

The MIP solver has been written with parallel tree search in mind. Some
work has started (Feb 2025), and it is hoped that a prototype solver
will be available during 2025.

Development of a new parallel interior point solver began 2023, and a
prototype solver is expected to be be available during 2025.

First-order solvers for LP are still very much in their infancy, and
are not robust. Hence the availability of a PDLP solver for LP is
unlikely to be used to enhance other solvers in HiGHS in the short or
medium term.