Apply a binary fixing heuristic to an unpresolved MIP problem
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| Type: | Programming |
| Rating: | 4 (medium-difficult) |
| Description: | We take a production plan model and solve its LP relaxation. This heuristic will speed up solution - though may fail to optimse the problem. The results are displayed on screen and the problem statistics stored in a log file. |
| File(s): | FixBV.cs |
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| FixBV.cs |
using System;
using System.IO;
using Optimizer;
namespace XPRSExamples
{
class FixBV
{
public static void Main(string[] args)
{
FixBV example = new FixBV();
example.Run();
}
private const double TOL=0.0005; // Tolerance on binary variables
private void Run()
{
try
{
string sProblem=@"..\..\..\Data\coco"; // Problem name
string sLogFile="fixbv.log"; // Log file name
int nCol; // Number of columns
// Global problem information
int nGlEnt; // Number of global entities: binary, integer, semi-continuous and partial integer variables
int nSet; // Number of S1 and S2 sets
int[] pGlInd; // Column indices of the global entities
char[] pGlType; // Global entity types
// Bound changes
int[] pBndInd; // Column indices of the bounds to be changed
char[] pBndType; // New bound type
double[] pBndVal; // New bound values
int nBnd; // Bound counter
int i; // Loop counter
int j; // Holder for the bound indices
// Solution information
double[] x; // LP solution values
int nGlStatus; // Global status
int nNodes; // Number of nodes solved so far in the global search
double dObjVal; // Objective value of the best integer solution
// Initialise Optimizer
XPRS.Init("");
Console.Write(XPRS.GetBanner());
prob = new XPRSprob();
// Delete and define log file
// Delete the file if it exists.
if (File.Exists(sLogFile))
{
File.Delete(sLogFile);
}
prob.SetLogFile(sLogFile);
// Tell Optimizer to call optimizermsg whenever a message is output
prob.MessageCallbacks += new MessageCallback(this.OptimizerMsg);
// Get and display the Optimizer version number
Console.WriteLine("\nXpress Optimiser Subroutine Library Release {0}\n\n", prob.Version/100);
// Turn off presolve and permit no cuts - to slow down solution and allow
// the effect of the heuristic to be be seen
prob.Presolve = 0;
prob.CutStrategy = 0;
// Read the problem file
prob.MPSFormat = -1;
prob.ReadProb(sProblem,"");
// Solve the LP relaxation
// Get the number of columns
nCol = prob.Cols;
// Allocate memory for solution array and check for memory shortage
x= new double[nCol];
// Solve the LP
prob.Maxim("");
// Get LP solution values
prob.GetSol(x,null,null,null);
// Fix the binary variables that are at their bounds
// Allocate memory for global entity arrays
pGlInd = new int[nCol];
pGlType = new char[nCol];
// Get global entity information
prob.GetGlobal(out nGlEnt, out nSet, pGlType, pGlInd, null, null, (int[])null, null, null);
// Allocate memory for bound arrays
pBndInd = new int[nGlEnt];
pBndVal = new double[nGlEnt];
pBndType = new char[nGlEnt];
// Initialise bound counter
nBnd=0;
// Go through the global entities
for(i=0; i<nGlEnt; i++)
{
// Test whether each is a binary variable
if (pGlType[i] == 'B')
{
// Hold the index of the BV
j=pGlInd[i];
// If the value of the BV is within TOL of zero, store its index,
// set its upper bound to 0, and increment the bound counter
if (x[j]<=TOL)
{
pBndInd[nBnd]=j;
pBndType[nBnd]='U';
pBndVal[nBnd]=0.0;
nBnd++;
// If the value of the BV is within TOL of one,store its index,
// set its lower bound to 1, and increment the bound counter
}
else if ((1-x[j])<=TOL)
{
pBndInd[nBnd]=j;
pBndType[nBnd]='L';
pBndVal[nBnd]=1.0;
nBnd++;
}
}
}
// Instruct Optimizer to change the bounds of the appropriate BVs,
// and tell the user how many have been fixed
prob.ChgBounds(nBnd,pBndInd,pBndType,pBndVal);
Console.WriteLine("Solving problem {0} with a binary fixing heuristic:\n\n",sProblem);
Console.WriteLine(" After the LP optimisation {0} binary variables were fixed\n\n",nBnd);
// Solve the modified problem as a MIP
// Search for an integer solution
prob.Global();
// Get the number of nodes solved in the global search
nNodes = prob.Nodes;
// Get the objective value of the best integer solution
dObjVal = prob.MIPObjVal;
// Check the global status and display the results of the global search
nGlStatus = (int)prob.MIPStatus;
switch (nGlStatus)
{
case 0:
Console.WriteLine(" Problem has not been loaded");
break;
case 1:
Console.WriteLine(" Search has not begun - LP has not been optimised");
break;
case 2:
Console.WriteLine(" Search has not begun - LP has been optimised");
break;
case 3:
Console.WriteLine(" Search interrupted - No integer solution was found");
break;
case 4:
Console.WriteLine(" Search interrupted - Integer solution found: %g",dObjVal);
break;
case 5:
Console.WriteLine(" No integer solution was found");
break;
case 6:
Console.WriteLine(" Integer solution found: {0}",dObjVal);
break;
}
Console.WriteLine("\n\n The MIP optimisation took {0} nodes\n\n",nNodes);
}
catch (XPRSException e)
{
Console.WriteLine(e.ToString());
throw e;
}
finally
{
prob.Destroy();
XPRS.Free();
}
}
public void OptimizerMsg (XPRSprob prob, object data, string message, int len, int msglvl)
{
switch(msglvl)
{
case 3:
case 4:
Console.WriteLine ("{0}" + message, data);
break;
}
}
private XPRSprob prob;
}
}
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