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author | Richard Burhans <burhans@bx.psu.edu> |
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date | Fri, 28 Feb 2014 12:15:32 -0500 |
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#!/usr/bin/env python # -*- coding: iso-8859-1 -*- # Documentation is intended to be processed by Epydoc. """ Introduction ============ The Munkres module provides an implementation of the Munkres algorithm (also called the Hungarian algorithm or the Kuhn-Munkres algorithm), useful for solving the Assignment Problem. Assignment Problem ================== Let *C* be an *n*\ x\ *n* matrix representing the costs of each of *n* workers to perform any of *n* jobs. The assignment problem is to assign jobs to workers in a way that minimizes the total cost. Since each worker can perform only one job and each job can be assigned to only one worker the assignments represent an independent set of the matrix *C*. One way to generate the optimal set is to create all permutations of the indexes necessary to traverse the matrix so that no row and column are used more than once. For instance, given this matrix (expressed in Python):: matrix = [[5, 9, 1], [10, 3, 2], [8, 7, 4]] You could use this code to generate the traversal indexes:: def permute(a, results): if len(a) == 1: results.insert(len(results), a) else: for i in range(0, len(a)): element = a[i] a_copy = [a[j] for j in range(0, len(a)) if j != i] subresults = [] permute(a_copy, subresults) for subresult in subresults: result = [element] + subresult results.insert(len(results), result) results = [] permute(range(len(matrix)), results) # [0, 1, 2] for a 3x3 matrix After the call to permute(), the results matrix would look like this:: [[0, 1, 2], [0, 2, 1], [1, 0, 2], [1, 2, 0], [2, 0, 1], [2, 1, 0]] You could then use that index matrix to loop over the original cost matrix and calculate the smallest cost of the combinations:: n = len(matrix) minval = sys.maxint for row in range(n): cost = 0 for col in range(n): cost += matrix[row][col] minval = min(cost, minval) print minval While this approach works fine for small matrices, it does not scale. It executes in O(*n*!) time: Calculating the permutations for an *n*\ x\ *n* matrix requires *n*! operations. For a 12x12 matrix, that's 479,001,600 traversals. Even if you could manage to perform each traversal in just one millisecond, it would still take more than 133 hours to perform the entire traversal. A 20x20 matrix would take 2,432,902,008,176,640,000 operations. At an optimistic millisecond per operation, that's more than 77 million years. The Munkres algorithm runs in O(*n*\ ^3) time, rather than O(*n*!). This package provides an implementation of that algorithm. This version is based on http://www.public.iastate.edu/~ddoty/HungarianAlgorithm.html. This version was written for Python by Brian Clapper from the (Ada) algorithm at the above web site. (The ``Algorithm::Munkres`` Perl version, in CPAN, was clearly adapted from the same web site.) Usage ===== Construct a Munkres object:: from munkres import Munkres m = Munkres() Then use it to compute the lowest cost assignment from a cost matrix. Here's a sample program:: from munkres import Munkres, print_matrix matrix = [[5, 9, 1], [10, 3, 2], [8, 7, 4]] m = Munkres() indexes = m.compute(matrix) print_matrix(matrix, msg='Lowest cost through this matrix:') total = 0 for row, column in indexes: value = matrix[row][column] total += value print '(%d, %d) -> %d' % (row, column, value) print 'total cost: %d' % total Running that program produces:: Lowest cost through this matrix: [5, 9, 1] [10, 3, 2] [8, 7, 4] (0, 0) -> 5 (1, 1) -> 3 (2, 2) -> 4 total cost=12 The instantiated Munkres object can be used multiple times on different matrices. Non-square Cost Matrices ======================== The Munkres algorithm assumes that the cost matrix is square. However, it's possible to use a rectangular matrix if you first pad it with 0 values to make it square. This module automatically pads rectangular cost matrices to make them square. Notes: - The module operates on a *copy* of the caller's matrix, so any padding will not be seen by the caller. - The cost matrix must be rectangular or square. An irregular matrix will *not* work. Calculating Profit, Rather than Cost ==================================== The cost matrix is just that: A cost matrix. The Munkres algorithm finds the combination of elements (one from each row and column) that results in the smallest cost. It's also possible to use the algorithm to maximize profit. To do that, however, you have to convert your profit matrix to a cost matrix. The simplest way to do that is to subtract all elements from a large value. For example:: from munkres import Munkres, print_matrix matrix = [[5, 9, 1], [10, 3, 2], [8, 7, 4]] cost_matrix = [] for row in matrix: cost_row = [] for col in row: cost_row += [sys.maxint - col] cost_matrix += [cost_row] m = Munkres() indexes = m.compute(cost_matrix) print_matrix(matrix, msg='Highest profit through this matrix:') total = 0 for row, column in indexes: value = matrix[row][column] total += value print '(%d, %d) -> %d' % (row, column, value) print 'total profit=%d' % total Running that program produces:: Highest profit through this matrix: [5, 9, 1] [10, 3, 2] [8, 7, 4] (0, 1) -> 9 (1, 0) -> 10 (2, 2) -> 4 total profit=23 The ``munkres`` module provides a convenience method for creating a cost matrix from a profit matrix. Since it doesn't know whether the matrix contains floating point numbers, decimals, or integers, you have to provide the conversion function; but the convenience method takes care of the actual creation of the cost matrix:: import munkres cost_matrix = munkres.make_cost_matrix(matrix, lambda cost: sys.maxint - cost) So, the above profit-calculation program can be recast as:: from munkres import Munkres, print_matrix, make_cost_matrix matrix = [[5, 9, 1], [10, 3, 2], [8, 7, 4]] cost_matrix = make_cost_matrix(matrix, lambda cost: sys.maxint - cost) m = Munkres() indexes = m.compute(cost_matrix) print_matrix(matrix, msg='Lowest cost through this matrix:') total = 0 for row, column in indexes: value = matrix[row][column] total += value print '(%d, %d) -> %d' % (row, column, value) print 'total profit=%d' % total References ========== 1. http://www.public.iastate.edu/~ddoty/HungarianAlgorithm.html 2. Harold W. Kuhn. The Hungarian Method for the assignment problem. *Naval Research Logistics Quarterly*, 2:83-97, 1955. 3. Harold W. Kuhn. Variants of the Hungarian method for assignment problems. *Naval Research Logistics Quarterly*, 3: 253-258, 1956. 4. Munkres, J. Algorithms for the Assignment and Transportation Problems. *Journal of the Society of Industrial and Applied Mathematics*, 5(1):32-38, March, 1957. 5. http://en.wikipedia.org/wiki/Hungarian_algorithm Copyright and License ===================== This software is released under a BSD license, adapted from <http://opensource.org/licenses/bsd-license.php> Copyright (c) 2008 Brian M. Clapper 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. * Neither the name "clapper.org" nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. 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 HOLDER 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. """ __docformat__ = 'restructuredtext' # --------------------------------------------------------------------------- # Imports # --------------------------------------------------------------------------- import sys # --------------------------------------------------------------------------- # Exports # --------------------------------------------------------------------------- __all__ = ['Munkres', 'make_cost_matrix'] # --------------------------------------------------------------------------- # Globals # --------------------------------------------------------------------------- # Info about the module __version__ = "1.0.5.4" __author__ = "Brian Clapper, bmc@clapper.org" __url__ = "http://bmc.github.com/munkres/" __copyright__ = "(c) 2008 Brian M. Clapper" __license__ = "BSD-style license" # --------------------------------------------------------------------------- # Classes # --------------------------------------------------------------------------- class Munkres: """ Calculate the Munkres solution to the classical assignment problem. See the module documentation for usage. """ def __init__(self): """Create a new instance""" self.C = None self.row_covered = [] self.col_covered = [] self.n = 0 self.Z0_r = 0 self.Z0_c = 0 self.marked = None self.path = None def make_cost_matrix(profit_matrix, inversion_function): """ **DEPRECATED** Please use the module function ``make_cost_matrix()``. """ import munkres return munkres.make_cost_matrix(profit_matrix, inversion_function) make_cost_matrix = staticmethod(make_cost_matrix) def pad_matrix(self, matrix, pad_value=0): """ Pad a possibly non-square matrix to make it square. :Parameters: matrix : list of lists matrix to pad pad_value : int value to use to pad the matrix :rtype: list of lists :return: a new, possibly padded, matrix """ max_columns = 0 total_rows = len(matrix) for row in matrix: max_columns = max(max_columns, len(row)) total_rows = max(max_columns, total_rows) new_matrix = [] for row in matrix: row_len = len(row) new_row = row[:] if total_rows > row_len: # Row too short. Pad it. new_row += [0] * (total_rows - row_len) new_matrix += [new_row] while len(new_matrix) < total_rows: new_matrix += [[0] * total_rows] return new_matrix def compute(self, cost_matrix): """ Compute the indexes for the lowest-cost pairings between rows and columns in the database. Returns a list of (row, column) tuples that can be used to traverse the matrix. :Parameters: cost_matrix : list of lists The cost matrix. If this cost matrix is not square, it will be padded with zeros, via a call to ``pad_matrix()``. (This method does *not* modify the caller's matrix. It operates on a copy of the matrix.) **WARNING**: This code handles square and rectangular matrices. It does *not* handle irregular matrices. :rtype: list :return: A list of ``(row, column)`` tuples that describe the lowest cost path through the matrix """ self.C = self.pad_matrix(cost_matrix) self.n = len(self.C) self.original_length = len(cost_matrix) self.original_width = len(cost_matrix[0]) self.row_covered = [False for i in range(self.n)] self.col_covered = [False for i in range(self.n)] self.Z0_r = 0 self.Z0_c = 0 self.path = self.__make_matrix(self.n * 2, 0) self.marked = self.__make_matrix(self.n, 0) done = False step = 1 steps = { 1 : self.__step1, 2 : self.__step2, 3 : self.__step3, 4 : self.__step4, 5 : self.__step5, 6 : self.__step6 } while not done: try: func = steps[step] step = func() except KeyError: done = True # Look for the starred columns results = [] for i in range(self.original_length): for j in range(self.original_width): if self.marked[i][j] == 1: results += [(i, j)] return results def __copy_matrix(self, matrix): """Return an exact copy of the supplied matrix""" return copy.deepcopy(matrix) def __make_matrix(self, n, val): """Create an *n*x*n* matrix, populating it with the specific value.""" matrix = [] for i in range(n): matrix += [[val for j in range(n)]] return matrix def __step1(self): """ For each row of the matrix, find the smallest element and subtract it from every element in its row. Go to Step 2. """ C = self.C n = self.n for i in range(n): minval = min(self.C[i]) # Find the minimum value for this row and subtract that minimum # from every element in the row. for j in range(n): self.C[i][j] -= minval return 2 def __step2(self): """ Find a zero (Z) in the resulting matrix. If there is no starred zero in its row or column, star Z. Repeat for each element in the matrix. Go to Step 3. """ n = self.n for i in range(n): for j in range(n): if (self.C[i][j] == 0) and \ (not self.col_covered[j]) and \ (not self.row_covered[i]): self.marked[i][j] = 1 self.col_covered[j] = True self.row_covered[i] = True self.__clear_covers() return 3 def __step3(self): """ Cover each column containing a starred zero. If K columns are covered, the starred zeros describe a complete set of unique assignments. In this case, Go to DONE, otherwise, Go to Step 4. """ n = self.n count = 0 for i in range(n): for j in range(n): if self.marked[i][j] == 1: self.col_covered[j] = True count += 1 if count >= n: step = 7 # done else: step = 4 return step def __step4(self): """ Find a noncovered zero and prime it. If there is no starred zero in the row containing this primed zero, Go to Step 5. Otherwise, cover this row and uncover the column containing the starred zero. Continue in this manner until there are no uncovered zeros left. Save the smallest uncovered value and Go to Step 6. """ step = 0 done = False row = -1 col = -1 star_col = -1 while not done: (row, col) = self.__find_a_zero() if row < 0: done = True step = 6 else: self.marked[row][col] = 2 star_col = self.__find_star_in_row(row) if star_col >= 0: col = star_col self.row_covered[row] = True self.col_covered[col] = False else: done = True self.Z0_r = row self.Z0_c = col step = 5 return step def __step5(self): """ Construct a series of alternating primed and starred zeros as follows. Let Z0 represent the uncovered primed zero found in Step 4. Let Z1 denote the starred zero in the column of Z0 (if any). Let Z2 denote the primed zero in the row of Z1 (there will always be one). Continue until the series terminates at a primed zero that has no starred zero in its column. Unstar each starred zero of the series, star each primed zero of the series, erase all primes and uncover every line in the matrix. Return to Step 3 """ count = 0 path = self.path path[count][0] = self.Z0_r path[count][1] = self.Z0_c done = False while not done: row = self.__find_star_in_col(path[count][1]) if row >= 0: count += 1 path[count][0] = row path[count][1] = path[count-1][1] else: done = True if not done: col = self.__find_prime_in_row(path[count][0]) count += 1 path[count][0] = path[count-1][0] path[count][1] = col self.__convert_path(path, count) self.__clear_covers() self.__erase_primes() return 3 def __step6(self): """ Add the value found in Step 4 to every element of each covered row, and subtract it from every element of each uncovered column. Return to Step 4 without altering any stars, primes, or covered lines. """ minval = self.__find_smallest() for i in range(self.n): for j in range(self.n): if self.row_covered[i]: self.C[i][j] += minval if not self.col_covered[j]: self.C[i][j] -= minval return 4 def __find_smallest(self): """Find the smallest uncovered value in the matrix.""" minval = sys.maxint for i in range(self.n): for j in range(self.n): if (not self.row_covered[i]) and (not self.col_covered[j]): if minval > self.C[i][j]: minval = self.C[i][j] return minval def __find_a_zero(self): """Find the first uncovered element with value 0""" row = -1 col = -1 i = 0 n = self.n done = False while not done: j = 0 while True: if (self.C[i][j] == 0) and \ (not self.row_covered[i]) and \ (not self.col_covered[j]): row = i col = j done = True j += 1 if j >= n: break i += 1 if i >= n: done = True return (row, col) def __find_star_in_row(self, row): """ Find the first starred element in the specified row. Returns the column index, or -1 if no starred element was found. """ col = -1 for j in range(self.n): if self.marked[row][j] == 1: col = j break return col def __find_star_in_col(self, col): """ Find the first starred element in the specified row. Returns the row index, or -1 if no starred element was found. """ row = -1 for i in range(self.n): if self.marked[i][col] == 1: row = i break return row def __find_prime_in_row(self, row): """ Find the first prime element in the specified row. Returns the column index, or -1 if no starred element was found. """ col = -1 for j in range(self.n): if self.marked[row][j] == 2: col = j break return col def __convert_path(self, path, count): for i in range(count+1): if self.marked[path[i][0]][path[i][1]] == 1: self.marked[path[i][0]][path[i][1]] = 0 else: self.marked[path[i][0]][path[i][1]] = 1 def __clear_covers(self): """Clear all covered matrix cells""" for i in range(self.n): self.row_covered[i] = False self.col_covered[i] = False def __erase_primes(self): """Erase all prime markings""" for i in range(self.n): for j in range(self.n): if self.marked[i][j] == 2: self.marked[i][j] = 0 # --------------------------------------------------------------------------- # Functions # --------------------------------------------------------------------------- def make_cost_matrix(profit_matrix, inversion_function): """ Create a cost matrix from a profit matrix by calling 'inversion_function' to invert each value. The inversion function must take one numeric argument (of any type) and return another numeric argument which is presumed to be the cost inverse of the original profit. This is a static method. Call it like this: .. python:: cost_matrix = Munkres.make_cost_matrix(matrix, inversion_func) For example: .. python:: cost_matrix = Munkres.make_cost_matrix(matrix, lambda x : sys.maxint - x) :Parameters: profit_matrix : list of lists The matrix to convert from a profit to a cost matrix inversion_function : function The function to use to invert each entry in the profit matrix :rtype: list of lists :return: The converted matrix """ cost_matrix = [] for row in profit_matrix: cost_matrix.append([inversion_function(value) for value in row]) return cost_matrix def print_matrix(matrix, msg=None): """ Convenience function: Displays the contents of a matrix of integers. :Parameters: matrix : list of lists Matrix to print msg : str Optional message to print before displaying the matrix """ import math if msg is not None: print msg # Calculate the appropriate format width. width = 0 for row in matrix: for val in row: width = max(width, int(math.log10(val)) + 1) # Make the format string format = '%%%dd' % width # Print the matrix for row in matrix: sep = '[' for val in row: sys.stdout.write(sep + format % val) sep = ', ' sys.stdout.write(']\n') # --------------------------------------------------------------------------- # Main # --------------------------------------------------------------------------- if __name__ == '__main__': matrices = [ # Square ([[400, 150, 400], [400, 450, 600], [300, 225, 300]], 850 # expected cost ), # Rectangular variant ([[400, 150, 400, 1], [400, 450, 600, 2], [300, 225, 300, 3]], 452 # expected cost ), # Square ([[10, 10, 8], [ 9, 8, 1], [ 9, 7, 4]], 18 ), # Rectangular variant ([[10, 10, 8, 11], [ 9, 8, 1, 1], [ 9, 7, 4, 10]], 15 ), ] m = Munkres() for cost_matrix, expected_total in matrices: print_matrix(cost_matrix, msg='cost matrix') indexes = m.compute(cost_matrix) total_cost = 0 for r, c in indexes: x = cost_matrix[r][c] total_cost += x print '(%d, %d) -> %d' % (r, c, x) print 'lowest cost=%d' % total_cost assert expected_total == total_cost