# Shopping route optimization algorithm?

There are number of shops `s` which offer articles `a` for different prices. It is possible for a shop to not offer a specific product. Shops can be connected to each other (streets).

The task is to find an optimal route (cycle) from (and back to) some home location, so that the total price is minimal. The total prices is the sum of prices of the articles and the sum of the distances between the shops.

The prices of articles are known for each shop. A shop does not need to be visited for this information.

The constraits are:

• The buyer/traveller wants to purchase a list of articles, potentially all articles
• Every article is available at least in one shop
• The distances between shops are expressed as cost, so it may be simply added to the cost of the purchased articles, when calculating the total cost of a route
• Shops can be visited more than once, but that would increase the travelling an therefore the total cost of a route

I did the initial modeling with networkx, modeling the shops (and the home) as a directed graph (with the distance/cost as weight), where each node (shop) holds a list of all prices for the products it offers.

My first attempt was to create a brute-force solution, and I succeeded by iterating over all simple cycles. Then, for each cycle I calculate the travelling costs and the costs of the articles (that is, the minimum prices, as they appear in the shops of the cycle).

Now the above works, but doesn't scale: The time complexity for enumerating all cycles is `O((n+e)(c+1))` for n nodes, e edges and c elementary circuits (Finding all the elementary circuits of a directed graph. D. B. Johnson, SIAM Journal on Computing 4, no. 1, 77-84, 1975). And the number of cycles (circuits) grows quite rapidly:

``````# random 'streetlike' shop-graphs

number of shops: 3, cycles: 2
number of shops: 4, cycles: 11
number of shops: 5, cycles: 11
number of shops: 6, cycles: 60
number of shops: 7, cycles: 229
number of shops: 8, cycles: 868
number of shops: 9, cycles: 1399
number of shops: 10, cycles: 61139
number of shops: 11, cycles: 60066
number of shops: 12, cycles: 1246579
number of shops: 13, cycles: 7993420
``````

Any suggestions for a more scalable problem description? I'm thinking about dynamic or linear programming solutions, but I'd love to hear ideas.

update: Found a whole PhD thesis on the topic: ftp://tesis.bbtk.ull.es/ccppytec/cp181.pdf

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Nice question. But does Python have anything to do with it? –  Steven Rumbalski Jan 11 '12 at 20:35
Sounds easy -- just don't go anywhere, and don't buy anything. Total price is minimized :) –  Ian Clelland Jan 11 '12 at 20:38
Are the article availability and price available for lookup, or does one have to visit a store to know the availability and price? –  Benoit Jan 11 '12 at 20:41
@BenS All prices are known. A shop does not need to be visited for this information. –  miku Jan 11 '12 at 20:42
In seriousness, though -- what are the constraints? Do you have to visit every shop? Do you have to purchase one of every article? If you visit a shop, do you have to purchase whatever is in it? Can you re-visit shops on the way back to minimize travel cost? And are you saying that the distance between shops is also expressed in a cost, on the same scale as the cost of the articles? –  Ian Clelland Jan 11 '12 at 20:43

There was a comment here a minute ago which linked to the Wikipedia entry on what looks like this exact problem: http://en.wikipedia.org/wiki/Traveling_purchaser_problem

From that page, there are some links to papers describing various solution methods:

Dynamic Programming: http://www.di.unipi.it/optimize/Events/proceedings/T/C/4/TC4-1.pdf

Tabu Search -- http://infos2008.fci.cu.edu.eg/infos/DSS_04_P024-030.pdf (This might only find a 'pretty good' solution, not necessarily the absolute best, but it could be much faster)

Edit: Thank you, @soulcheck -- your comment disappeared for a while, but it's back now.

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Thanks for the links, I'll try to see if the algorithms are applicable. –  miku Jan 11 '12 at 21:00
no problem ;) i deleted it cause there could be actually some constraints that made this problem a different one, but then posted it again when constraints were clarified –  soulcheck Jan 11 '12 at 21:14