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assignmentoptimal.m
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assignmentoptimal.m
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function [assignment, cost] = assignmentoptimal(distMatrix)
%ASSIGNMENTOPTIMAL Compute optimal assignment by Munkres algorithm
% ASSIGNMENTOPTIMAL(DISTMATRIX) computes the optimal assignment (minimum
% overall costs) for the given rectangular distance or cost matrix, for
% example the assignment of tracks (in rows) to observations (in
% columns). The result is a column vector containing the assigned column
% number in each row (or 0 if no assignment could be done).
%
% [ASSIGNMENT, COST] = ASSIGNMENTOPTIMAL(DISTMATRIX) returns the
% assignment vector and the overall cost.
%
% The distance matrix may contain infinite values (forbidden
% assignments). Internally, the infinite values are set to a very large
% finite number, so that the Munkres algorithm itself works on
% finite-number matrices. Before returning the assignment, all
% assignments with infinite distance are deleted (i.e. set to zero).
%
% A description of Munkres algorithm (also called Hungarian algorithm)
% can easily be found on the web.
%
% <a href="assignment.html">assignment.html</a> <a href="http://www.mathworks.com/matlabcentral/fileexchange/6543">File Exchange</a> <a href="https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=EVW2A4G2HBVAU">Donate via PayPal</a>
%
% Markus Buehren
% Last modified 05.07.2011
% Copyright (c) 2004, Markus Buehren
% All rights reserved.
%
% Redistribution and use in source and binary forms, with or without
% modification, are permitted provided that the following conditions are
% met:
%
% * Redistributions of source code must retain the above copyright
% notice, this list of conditions and the following disclaimer.
% * Redistributions in binary form must reproduce the above copyright
% notice, this list of conditions and the following disclaimer in
% the documentation and/or other materials provided with the distribution
%
% THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
% AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
% IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
% ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
% LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
% CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
% SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
% INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
% CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
% ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
% POSSIBILITY OF SUCH DAMAGE.
% save original distMatrix for cost computation
originalDistMatrix = distMatrix;
% check for negative elements
if any(distMatrix(:) < 0)
error('All matrix elements have to be non-negative.');
end
% get matrix dimensions
[nOfRows, nOfColumns] = size(distMatrix);
% check for infinite values
finiteIndex = isfinite(distMatrix);
infiniteIndex = find(~finiteIndex);
if ~isempty(infiniteIndex)
% set infinite values to large finite value
maxFiniteValue = max(max(distMatrix(finiteIndex)));
if maxFiniteValue > 0
infValue = abs(10 * maxFiniteValue * nOfRows * nOfColumns);
else
infValue = 10;
end
if isempty(infValue)
% all elements are infinite
assignment = zeros(nOfRows, 1);
cost = 0;
return
end
distMatrix(infiniteIndex) = infValue;
end
% memory allocation
coveredColumns = zeros(1, nOfColumns);
coveredRows = zeros(nOfRows, 1);
starMatrix = zeros(nOfRows, nOfColumns);
primeMatrix = zeros(nOfRows, nOfColumns);
% preliminary steps
if nOfRows <= nOfColumns
minDim = nOfRows;
% find the smallest element of each row
minVector = min(distMatrix, [], 2);
% subtract the smallest element of each row from the row
distMatrix = distMatrix - repmat(minVector, 1, nOfColumns);
% Steps 1 and 2
for row = 1:nOfRows
for col = find(distMatrix(row,:)==0)
if ~coveredColumns(col)%~any(starMatrix(:,col))
starMatrix(row, col) = 1;
coveredColumns(col) = 1;
break
end
end
end
else % nOfRows > nOfColumns
minDim = nOfColumns;
% find the smallest element of each column
minVector = min(distMatrix);
% subtract the smallest element of each column from the column
distMatrix = distMatrix - repmat(minVector, nOfRows, 1);
% Steps 1 and 2
for col = 1:nOfColumns
for row = find(distMatrix(:,col)==0)'
if ~coveredRows(row)
starMatrix(row, col) = 1;
coveredColumns(col) = 1;
coveredRows(row) = 1;
break
end
end
end
coveredRows(:) = 0; % was used auxiliary above
end
if sum(coveredColumns) == minDim
% algorithm finished
assignment = buildassignmentvector__(starMatrix);
else
% move to step 3
[assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step3__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim); %#ok
end
% compute cost and remove invalid assignments
[assignment, cost] = computeassignmentcost__(assignment, originalDistMatrix, nOfRows);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function assignment = buildassignmentvector__(starMatrix)
[maxValue, assignment] = max(starMatrix, [], 2);
assignment(maxValue == 0) = 0;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [assignment, cost] = computeassignmentcost__(assignment, distMatrix, nOfRows)
rowIndex = find(assignment);
costVector = distMatrix(rowIndex + nOfRows * (assignment(rowIndex)-1));
finiteIndex = isfinite(costVector);
cost = sum(costVector(finiteIndex));
assignment(rowIndex(~finiteIndex)) = 0;
% Step 2: %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step2__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim)
% cover every column containing a starred zero
maxValue = max(starMatrix);
coveredColumns(maxValue == 1) = 1;
if sum(coveredColumns) == minDim
% algorithm finished
assignment = buildassignmentvector__(starMatrix);
else
% move to step 3
[assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step3__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim);
end
% Step 3: %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step3__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim)
zerosFound = 1;
while zerosFound
zerosFound = 0;
for col = find(~coveredColumns)
for row = find(~coveredRows')
if distMatrix(row,col) == 0
primeMatrix(row, col) = 1;
starCol = find(starMatrix(row,:));
if isempty(starCol)
% move to step 4
[assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step4__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, row, col, minDim);
return
else
coveredRows(row) = 1;
coveredColumns(starCol) = 0;
zerosFound = 1;
break % go on in next column
end
end
end
end
end
% move to step 5
[assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step5__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim);
% Step 4: %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step4__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, row, col, minDim)
newStarMatrix = starMatrix;
newStarMatrix(row,col) = 1;
starCol = col;
starRow = find(starMatrix(:, starCol));
while ~isempty(starRow)
% unstar the starred zero
newStarMatrix(starRow, starCol) = 0;
% find primed zero in row
primeRow = starRow;
primeCol = find(primeMatrix(primeRow, :));
% star the primed zero
newStarMatrix(primeRow, primeCol) = 1;
% find starred zero in column
starCol = primeCol;
starRow = find(starMatrix(:, starCol));
end
starMatrix = newStarMatrix;
primeMatrix(:) = 0;
coveredRows(:) = 0;
% move to step 2
[assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step2__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim);
% Step 5: %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function [assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step5__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim)
% find smallest uncovered element
uncoveredRowsIndex = find(~coveredRows');
uncoveredColumnsIndex = find(~coveredColumns);
[s, index1] = min(distMatrix(uncoveredRowsIndex,uncoveredColumnsIndex));
[s, index2] = min(s); %#ok
h = distMatrix(uncoveredRowsIndex(index1(index2)), uncoveredColumnsIndex(index2));
% add h to each covered row
index = find(coveredRows);
distMatrix(index, :) = distMatrix(index, :) + h;
% subtract h from each uncovered column
distMatrix(:, uncoveredColumnsIndex) = distMatrix(:, uncoveredColumnsIndex) - h;
% move to step 3
[assignment, distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows] = step3__(distMatrix, starMatrix, primeMatrix, coveredColumns, coveredRows, minDim);