So I have created a sort for my traveling salesman problem and I con sort by the x-coordinates and the y-coordinates.

I am trying to implement a greedy search, but am unable to.

Also, each point is instantiated in the matrix city such as [0,3,4] where 0 is the header, 3 is the x coordinate, and 4 is the y coordinate.

Here is my program which you should be able to run. The main problem is that my algorithm isn't working and I need help fixing it to a working greedy algorithm. You can find the algorithm near the end of the code.


This is the text file you will need which it takes the input from.


closed as off-topic by Paul Hankin, CRABOLO, Shankar Damodaran, greg-449, Mark Rotteveel May 31 '15 at 8:35

This question appears to be off-topic. The users who voted to close gave this specific reason:

  • "Questions seeking debugging help ("why isn't this code working?") must include the desired behavior, a specific problem or error and the shortest code necessary to reproduce it in the question itself. Questions without a clear problem statement are not useful to other readers. See: How to create a Minimal, Reproducible Example." – Paul Hankin, CRABOLO, Shankar Damodaran, greg-449, Mark Rotteveel
If this question can be reworded to fit the rules in the help center, please edit the question.

  • It's best if you post some problematic code, what you expect, and what you're getting. – Ryan May 31 '15 at 0:27
  • Is this homework? It sure sounds like homework. – Plasma May 31 '15 at 0:30

The Traveling Salesman Problem (TSP) is a combinatorial optimization problem, where given a map (a set of cities and their positions), one wants to find an order for visiting all the cities in such a way that the travel distance is minimal.

I would suggest solving the tsp and then solve the visual stuff.

Following code contains a set of functions to illustrate: - construction heuristics for the TSP - improvement heuristics for a previously constructed solution - local search, and random-start local search.

import math
import random

def distL2((x1,y1), (x2,y2)):
    """Compute the L2-norm (Euclidean) distance between two points.

    The distance is rounded to the closest integer, for compatibility
    with the TSPLIB convention.

    The two points are located on coordinates (x1,y1) and (x2,y2),
    sent as parameters"""
    xdiff = x2 - x1
    ydiff = y2 - y1
    return int(math.sqrt(xdiff*xdiff + ydiff*ydiff) + .5)

def distL1((x1,y1), (x2,y2)):
    """Compute the L1-norm (Manhattan) distance between two points.

    The distance is rounded to the closest integer, for compatibility
    with the TSPLIB convention.

    The two points are located on coordinates (x1,y1) and (x2,y2),
    sent as parameters"""
    return int(abs(x2-x1) + abs(y2-y1)+.5)

def mk_matrix(coord, dist):
    """Compute a distance matrix for a set of points.

    Uses function 'dist' to calculate distance between
    any two points.  Parameters:
    -coord -- list of tuples with coordinates of all points, [(x1,y1),...,(xn,yn)]
    -dist -- distance function
    n = len(coord)
    D = {}      # dictionary to hold n times n matrix
    for i in range(n-1):
        for j in range(i+1,n):
            (x1,y1) = coord[i]
            (x2,y2) = coord[j]
            D[i,j] = dist((x1,y1), (x2,y2))
            D[j,i] = D[i,j]
    return n,D

def read_tsplib(filename):
    "basic function for reading a TSP problem on the TSPLIB format"
    "NOTE: only works for 2D euclidean or manhattan distances"
    f = open(filename, 'r');

    line = f.readline()
    while line.find("EDGE_WEIGHT_TYPE") == -1:
        line = f.readline()

    if line.find("EUC_2D") != -1:
        dist = distL2
    elif line.find("MAN_2D") != -1:
        dist = distL1
        print "cannot deal with non-euclidean or non-manhattan distances"
        raise Exception

    while line.find("NODE_COORD_SECTION") == -1:
        line = f.readline()

    xy_positions = []
    while 1:
        line = f.readline()
        if line.find("EOF") != -1: break
        (i,x,y) = line.split()
        x = float(x)
        y = float(y)

    n,D = mk_matrix(xy_positions, dist)
    return n, xy_positions, D

def mk_closest(D, n):
    """Compute a sorted list of the distances for each of the nodes.

    For each node, the entry is in the form [(d1,i1), (d2,i2), ...]
    where each tuple is a pair (distance,node).
    C = []
    for i in range(n):
        dlist = [(D[i,j], j) for j in range(n) if j != i]
    return C

def length(tour, D):
    """Calculate the length of a tour according to distance matrix 'D'."""
    z = D[tour[-1], tour[0]]    # edge from last to first city of the tour
    for i in range(1,len(tour)):
        z += D[tour[i], tour[i-1]]      # add length of edge from city i-1 to i
    return z

def randtour(n):
    """Construct a random tour of size 'n'."""
    sol = range(n)      # set solution equal to [0,1,...,n-1]
    random.shuffle(sol) # place it in a random order
    return sol

def nearest(last, unvisited, D):
    """Return the index of the node which is closest to 'last'."""
    near = unvisited[0]
    min_dist = D[last, near]
    for i in unvisited[1:]:
        if D[last,i] < min_dist:
            near = i
            min_dist = D[last, near]
    return near

def nearest_neighbor(n, i, D):
    """Return tour starting from city 'i', using the Nearest Neighbor.

    Uses the Nearest Neighbor heuristic to construct a solution:
    - start visiting city i
    - while there are unvisited cities, follow to the closest one
    - return to city i
    unvisited = range(n)
    last = i
    tour = [i]
    while unvisited != []:
        next = nearest(last, unvisited, D)
        last = next
    return tour

def exchange_cost(tour, i, j, D):
    """Calculate the cost of exchanging two arcs in a tour.

    Determine the variation in the tour length if
    arcs (i,i+1) and (j,j+1) are removed,
    and replaced by (i,j) and (i+1,j+1)
    (note the exception for the last arc).

    -t -- a tour
    -i -- position of the first arc
    -j>i -- position of the second arc
    n = len(tour)
    a,b = tour[i],tour[(i+1)%n]
    c,d = tour[j],tour[(j+1)%n]
    return (D[a,c] + D[b,d]) - (D[a,b] + D[c,d])

def exchange(tour, tinv, i, j):
    """Exchange arcs (i,i+1) and (j,j+1) with (i,j) and (i+1,j+1).

    For the given tour 't', remove the arcs (i,i+1) and (j,j+1) and
    insert (i,j) and (i+1,j+1).

    This is done by inverting the sublist of cities between i and j.
    n = len(tour)
    if i>j:
        i,j = j,i
    assert i>=0 and i<j-1 and j<n
    path = tour[i+1:j+1]
    tour[i+1:j+1] = path
    for k in range(i+1,j+1):
        tinv[tour[k]] = k

def improve(tour, z, D, C):
    """Try to improve tour 't' by exchanging arcs; return improved tour length.

    If possible, make a series of local improvements on the solution 'tour',
    using a breadth first strategy, until reaching a local optimum.
    n = len(tour)
    tinv = [0 for i in tour]
    for k in range(n):
        tinv[tour[k]] = k  # position of each city in 't'
    for i in range(n):
        a,b = tour[i],tour[(i+1)%n]
        dist_ab = D[a,b]
        improved = False
        for dist_ac,c in C[a]:
            if dist_ac >= dist_ab:
            j = tinv[c]
            d = tour[(j+1)%n]
            dist_cd = D[c,d]
            dist_bd = D[b,d]
            delta = (dist_ac + dist_bd) - (dist_ab + dist_cd)
            if delta < 0:       # exchange decreases length
                exchange(tour, tinv, i, j);
                z += delta
                improved = True
        if improved:
        for dist_bd,d in C[b]:
            if dist_bd >= dist_ab:
            j = tinv[d]-1
            if j==-1:
            c = tour[j]
            dist_cd = D[c,d]
            dist_ac = D[a,c]
            delta = (dist_ac + dist_bd) - (dist_ab + dist_cd)
            if delta < 0:       # exchange decreases length
                exchange(tour, tinv, i, j);
                z += delta
    return z

def localsearch(tour, z, D, C=None):
    """Obtain a local optimum starting from solution t; return solution length.

      tour -- initial tour
      z -- length of the initial tour
      D -- distance matrix
    n = len(tour)
    if C == None:
        C = mk_closest(D, n)     # create a sorted list of distances to each node
    while 1:
        newz = improve(tour, z, D, C)
        if newz < z:
            z = newz
    return z

def multistart_localsearch(k, n, D, report=None):
    """Do k iterations of local search, starting from random solutions.

    -k -- number of iterations
    -D -- distance matrix
    -report -- if not None, call it to print verbose output

    Returns best solution and its cost.
    C = mk_closest(D, n) # create a sorted list of distances to each node
    for i in range(0,k):
        tour = randtour(n)
        z = length(tour, D)
        z = localsearch(tour, z, D, C)
        if z < bestz or bestz == None:
            bestz = z
            bestt = list(tour)
            if report:
                report(z, tour)

    return bestt, bestz

if __name__ == "__main__":
    """Local search for the Travelling Saleman Problem: sample usage."""

    # test the functions:

    # random.seed(1)    # uncomment for having always the same behavior
    import sys
    if len(sys.argv) == 1:
        # create a graph with several cities' coordinates
        coord = [(4,0),(5,6),(8,3),(4,4),(4,1),(4,10),(4,7),(6,8),(8,1)]
        n, D = mk_matrix(coord, distL2) # create the distance matrix
        instance = "toy problem"
        instance = sys.argv[1]
        n, coord, D = read_tsplib(instance)     # create the distance matrix
        # n, coord, D = read_tsplib('INSTANCES/TSP/eil51.tsp')  # create the distance matrix

    # function for printing best found solution when it is found
    from time import clock
    init = clock()
    def report_sol(obj, s=""):
        print "cpu:%g\tobj:%g\ttour:%s" % \
              (clock(), obj, s)

    print "*** travelling salesman problem ***"

    # random construction
    print "random construction + local search:"
    tour = randtour(n)     # create a random tour
    z = length(tour, D)     # calculate its length
    print "random:", tour, z, '  -->  ',   
    z = localsearch(tour, z, D)      # local search starting from the random tour
    print tour, z

    # greedy construction
    print "greedy construction with nearest neighbor + local search:"
    for i in range(n):
        tour = nearest_neighbor(n, i, D)     # create a greedy tour, visiting city 'i' first
        z = length(tour, D)
        print "nneigh:", tour, z, '  -->  ',
        z = localsearch(tour, z, D)
        print tour, z

    # multi-start local search
    print "random start local search:"
    niter = 100
    tour,z = multistart_localsearch(niter, n, D, report_sol)
    assert z == length(tour, D)
    print "best found solution (%d iterations): z = %g" % (niter, z)
    print tour

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