Popularity
5.5
Growing
Activity
0.0
Stable
11
3
3

Code Quality Rank: L1
Monthly Downloads: 21
Programming language: C++
License: MIT License
Tags: Numeric     Limp    

limp-cbc alternatives and similar packages

Based on the "limp" category.
Alternatively, view limp-cbc alternatives based on common mentions on social networks and blogs.

  • limp

    6.7 0.0 limp-cbc VS limp
    ideally, this will become a pure Haskell library for Linear Integer/Mixed Programming

Do you think we are missing an alternative of limp-cbc or a related project?

Add another 'limp' Package
InfluxDB - Power Real-Time Data Analytics at Scale
sponsored www.influxdata.com

Popular Comparisons

WorkOS - The modern identity platform for B2B SaaS
sponsored workos.com

README

limp-cbc

Solve your integer linear programming problems with CBC. This library uses the constructors in limp to define integer linear programming problems, then passes them to the CBC solver to find solutions.

Build Status

Example usage

You can define an integer linear program using the Program type. This type is parameterised over three type parameters: Program z r c, where z is the type of integer-valued variables; r is the type of real-valued variables, and c is a description of how to represent results. This solver only supports the IntDouble representation type – that is, integers are represented as machine Ints and reals as double-precision floating point values.

You can define a program with an integer variable "a" and a real variable "b" as follows:

import Numeric.Limp.Rep
import Numeric.Limp.Program

-- Minimise     a + b
-- Subject to   a + 2b >= 3
-- Where        0 <= a <= 10 :: Z
--              0 <= b <= 10 :: R
problem1 :: Direction -> Program String String IntDouble
problem1 dir
 = program dir
           (z1 "a" .+. r1 "b" )
           (z1 "a" .+. r "b" 2 :>= con 3)
           [ lowerUpperZ 0 "a" 10
           , lowerUpperR 0 "b" 10 ]

You can then use Numeric.Limp.Solvers.Cbc.solve to find a solution using CBC. This gives you an Assignment z r IntDouble for the variables, which is a mapping from z to Int and a mapping from r to Double:

import Numeric.Limp.Solvers.Cbc

solve_problem :: (Show z, Show r, Ord z, Ord r) => (Direction -> Program z r IntDouble) -> IO ()
solve_problem problem
 = do   let a1 = solve $ problem Minimise
        putStrLn "*** Minimise *** "
        show_result a1

        let a2 = solve $ problem Maximise
        putStrLn "*** Maximise *** "
        show_result a2

show_result :: (Show z, Show r, Ord z, Ord r) => Either Error (Assignment z r IntDouble) -> IO ()
show_result as
 = case as of
    Left e
     -> do putStrLn "Error:"
           print e
    Right a
     -> do putStrLn "Success:"
           print a

Further examples are available in the examples directory.