# Code a linear programming exercise by hand

I have been doing linear programming problems in my class by graphing them but I would like to know how to write a program for a particular problem to solve it for me. If there are too many variables or constraints I could never do this by graphing.

Example problem, maximize 5x + 3y with constraints:

• 5x - 2y >= 0
• x + y <= 7
• x <= 5
• x >= 0
• y >= 0

I graphed this and got a visible region with 3 corners. x=5 y=2 is the optimal point.

How do I turn this into code? I know of the simplex method. And very importantly, will all LP problems be coded in the same structure? Would brute force work?

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The simplex method is what you want. – Vaughn Cato Dec 5 '12 at 6:28
The answer is different if you are looking for Integer Linear Programming or Fractional Linear Programming (since the complexity of the problems is different) – amit Dec 5 '12 at 6:29
In Numerical Recipes for C online, section 10.8, you can find a straightforward implementation of the Simplex algorithm written in C. – Anders Gustafsson Dec 5 '12 at 9:29
According to Wikipedia, the algorithm mentioned in Numerical Recipes for C section 10.8 is NOT the simplex algorithm about linear programming as in OP. Instead, it is a non-linear optimization heuristic, namely, the Nelder–Mead method. – tinlyx Jan 2 at 23:15

There are quite a number of Simplex Implementations that you will find if you search.

In addition to the one mentioned in the comment (Numerical Recipes in C), you can also find:

2. Then there's COIN-OR
3. GNU has its own GLPK
4. If you want a C++ implementation, this one in Google Code is actually accessible.
5. There are many implementations in R including the boot package. (In R, you can see the implementation of a function by typing it without the parenthesis.)

1. Will all LPs be coded the same way? Yes, a generic LP solver can be written to load and solve any LP. (There are industry standard formats for reading LP's like `mps` and `.lp`

2. Would brute force work? Keep in mind that many companies and big organizations spend a long time on fine tuning the solvers. There are LP's that have interesting properties that many solvers will try to exploit. Also, certain computations can be solved in parallel. The algorithm is exponential, so at some large number of variables/constraints, brute force won't work.

Hope that helps.

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I wrote this is matlab yesterday, which could be easily transcribed to C++ if you use Eigen library or write your own matrix class using a std::vector of a std::vector

``````function [x, fval] = mySimplex(fun, A, B, lb, up)

%Examples paramters to show that the function actually works

% sample set 1 (works for this data set)

% fun = [8 10 7];
% A = [1 3 2; 1 5 1];
% B = [10; 8];
% lb = [0; 0; 0];
% ub = [inf; inf; inf];

% sample set 2 (works for this data set)

fun = [7 8 10];
A = [2 3 2; 1 1 2];
B = [1000; 800];
lb = [0; 0; 0];
ub = [inf; inf; inf];

% generate a new slack variable for every row of A

numSlackVars = size(A,1); % need a new slack variables for every row of A

% Set up tableau to store algorithm data
tableau = [A; -fun];

tableau = [tableau, eye(numSlackVars + 1)];

lastCol = [B;0];

tableau = [tableau, lastCol];

% for convienience sake, assign the following:

numRows = size(tableau,1);
numCols = size(tableau,2);

% do simplex algorithm

% step 0: find num of negative entries in bottom row of tableau

numNeg = 0; % the number of negative entries in bottom row

for i=1:numCols
if(tableau(numRows,i) < 0)
numNeg = numNeg + 1;
end
end

% Remark: the number of negatives is exactly the number of iterations needed in the
% simplex algorithm

for iterations = 1:numNeg
% step 1: find minimum value in last row
minVal = 10000; % some big number
minCol = 1; % start by assuming min value is the first element
for i=1:numCols
if(tableau(numRows, i) < minVal)
minVal = tableau(size(tableau,1), i);
minCol = i; % update the index corresponding to the min element
end
end

% step 2: Find corresponding ratio vector in pivot column
vectorRatio = zeros(numRows -1, 1);
for i=1:(numRows-1) % the size of ratio vector is numCols - 1
vectorRatio(i, 1) = tableau(i, numCols) ./ tableau(i, minCol);
end

% step 3: Determine pivot element by finding minimum element in vector
% ratio

minVal = 10000; % some big number
minRatio = 1; % holds the element with the minimum ratio

for i=1:numRows-1
if(vectorRatio(i,1) < minVal)
minVal = vectorRatio(i,1);
minRatio = i;
end
end

% step 4: assign pivot element

pivotElement = tableau(minRatio, minCol);

% step 5: perform pivot operation on tableau around the pivot element

tableau(minRatio, :) = tableau(minRatio, :) * (1/pivotElement);

% step 6: perform pivot operation on rows (not including last row)

for i=1:size(vectorRatio,1)+1 % do last row last
if(i ~= minRatio) % we skip over the minRatio'th element of the tableau here
tableau(i, :) = -tableau(i,minCol)*tableau(minRatio, :) +  tableau(i,:);
end
end
end

% Now we can interpret the algo tableau

numVars = size(A,2); % the number of cols of A is the number of variables

x = zeros(size(size(tableau,1), 1)); % for efficiency

% Check for basicity
for col=1:numVars
count_zero = 0;
count_one = 0;
for row = 1:size(tableau,1)
if(tableau(row,col) < 1e-2)
count_zero = count_zero + 1;
elseif(tableau(row,col) - 1 < 1e-2)
count_one = count_one + 1;
stored_row = row; % we store this (like in memory) column for later use
end
end
if(count_zero == (size(tableau,1) -1) && count_one == 1) % this is the case where it is basic
x(col,1) = tableau(stored_row, numCols);
else
x(col,1) = 0; % this is the base where it is not basic
end
end

% find function optimal value at optimal solution
fval = x(1,1) * fun(1,1); % just needed for logic to work here
for i=2:numVars
fval = fval + x(i,1) * fun(1,i);
end

end
``````
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