# What is the meaning of “from distinct vertex chains” in this nearest neighbor algorithm?

The following pseudo-code is from the first chapter of an online preview version of The Algorithm Design Manual (page 7 from this PDF).

The example is of a flawed algorithm, but I still really want to understand it:

[...] A diﬀerent idea might be to repeatedly connect the closest pair of endpoints whose connection will not create a problem, such as premature termination of the cycle. Each vertex begins as its own single vertex chain. After merging everything together, we will end up with a single chain containing all the points in it. Connecting the ﬁnal two endpoints gives us a cycle. At any step during the execution of this closest-pair heuristic, we will have a set of single vertices and vertex-disjoint chains available to merge. In pseudocode:

``````ClosestPair(P)
Let n be the number of points in set P.
For i = 1  to n − 1 do
d = ∞
For each pair of endpoints (s, t) from distinct vertex chains
if dist(s, t) ≤ d then sm = s, tm = t, and d = dist(s, t)
Connect (sm, tm) by an edge
Connect the two endpoints by an edge
``````

Please note that `sm` and `tm` should be `s``m` and `t``m`.

First of all, I don't understand what "from distinct vertex chains" would mean. Second, `i` is used as a counter in the outer loop, but `i` itself is never actually used anywhere! Could someone smarter than me please explain what's really going on here?

• Interesting, I was about to come up with the same questions! – TigrouMeow Sep 5 '11 at 1:21
• Exactly the same questions! Word for word. I was actually depressed that I'm not smart enough for the book - well at least alone :-P thanks for posting! – Aditya M P Dec 7 '17 at 1:55

1) The description states that every vertex always belongs either to a "single-vertex chain" (i.e., it's alone) or it belongs to one other chain; a vertex can only belong to one chain. The algorithm says at each step you select every possible pair of two vertices which are each an endpoint of the respective chain they belong to, and don't already belong to the same chain. Sometimes they'll be singletons; sometimes one or both will already belong to a non-trivial chain, so you'll join two chains.

2) You repeat the loop n times, so that you eventually select every vertex; but yes, the actual iteration count isn't used for anything. All that matters is that you run the loop enough times.

• a bit of clarification for 1): they enumerate only the endpoints of the chains. It's not some kind of Kruskal's algorithm, it's a TSP heuristic, the chains grow only at the endpoints. – unkulunkulu Aug 27 '11 at 19:40
• Edited, thanks. – Ernest Friedman-Hill Aug 27 '11 at 19:56
• Eh, still don't get it. – dhblah Jul 12 '12 at 13:19
• I get the overall idea, what I am missing is the first iteration. In the first iteration there are no endpoints so how are the single vertices enumerated upon? ex: -5, -1, 0, 2. – ChrisOdney Apr 8 '14 at 9:22
• A Singleton is a chain with one endpoint. At the beginning each point is a Singleton. – Ernest Friedman-Hill Apr 8 '14 at 10:55

This is how I see it, after explanation of Ernest Friedman-Hill (accepted answer):

So the example from the same book (Figure 1.4). I've added names to the vertices to make it clear So at first step all the vertices are single vertex chains, so we connect A-D, B-E and C-F pairs, b/c distance between them is the smallest.

At the second step we have 3 chains and distance between A-D and B-E is the same as between B-E and C-F, so we connect let's say A-D with B-E and we left with two chains - A-D-E-B and C-F

At the third step there is the only way to connect them is through B and C, b/c B-C is shorter then B-F, A-F and A-C (remember we consider only endpoints of chains). So we have one chain now A-D-E-B-C-F.

At the last step we connect two endpoints (A and F) to get a cycle.

• I wasn't understanding that B-E prevents A-B and E-F because only vertexes in different chains are chosen. This completed my understanding – ricab Nov 23 '14 at 20:38
• A picture tells a thousand words, thank you! But this part I didn't understand: "b/c distance between them is the smallest". To know that, it seems to me that you would have to iterate through all other points to figure out which of the respective distances are the smallest. – stifin Jun 30 '18 at 13:52
• @stifin A-D has distance 1-e and D-E has 1+e and afaiu it's already known – Eugene Platonov Jun 30 '18 at 14:56
• It's stated in the text of the book, but the book does not explain how that is known. – stifin Jul 2 '18 at 10:52

Though question is already answered, here's a python implementation for closest pair heuristic. It starts with every point as a chain, then successively extending chains to build one long chain containing all points. This algorithm does build a path yet it's not a sequence of robot arm movements for that arm starting point is unknown.

``````import matplotlib.pyplot as plot
import math
import random

def draw_arrow(axis, p1, p2, rad):
"""draw an arrow connecting point 1 to point 2"""
axis.annotate("",
xy=p2,
xytext=p1,

def closest_pair(points):
distance = lambda c1p, c2p:  math.hypot(c1p - c2p, c1p - c2p)
chains = [[points[i]] for i in range(len(points))]
edges = []
for i in range(len(points)-1):
dmin = float("inf")  # infinitely big distance
# test each chain against each other chain
for chain1 in chains:
for chain2 in [item for item in chains if item is not chain1]:
# test each chain1 endpoint against each of chain2 endpoints
for c1ind in [0, len(chain1) - 1]:
for c2ind in [0, len(chain2) - 1]:
dist = distance(chain1[c1ind], chain2[c2ind])
if dist < dmin:
dmin = dist
# remember endpoints as closest pair
point1, point2 = chain1[c1ind], chain2[c2ind]
# connect two closest points
edges.append((point1, point2))
if len(chain2link1) > 1:
if len(chain2link2) > 1:
# connect first endpoint to the last one
edges.append((chains, chains[len(chains)-1]))
return edges

data = [(0.3, 0.2), (0.3, 0.4), (0.501, 0.4), (0.501, 0.2), (0.702, 0.4), (0.702, 0.2)]
# random.seed()
# data = [(random.uniform(0.01, 0.99), 0.2) for i in range(60)]
edges = closest_pair(data)
# draw path
figure = plot.figure()