### Posting more utility code

see github: https://gist.github.com/1233012#file_new.cpp

This is basically an much better approach to generating all possible permutations based on much simpler approach (therefore I had no real reason to post it before: As it stands right now, it doesn't *do* anything more than the python code).

I decided to share it anyways, as you might be able to get some profit out of this as the basis for an eventual solution.

### Pro:

- much faster
- smarter algorithm (leverages STL and maths :))
- instruction optimization
- storage optimization

- generic problem model
- model and algorithmic ideas can be used as basis for proper algorithm
- basis for a good OpenMP parallelization (
*n*-way, for *n* rows) designed-in (but not fleshed out)

### Contra:

- The code is much more efficient at the cost of flexibility: adapting the code to build in logic about the constraints and cost heuristics would be much easier with the more step-by-step Python approach

All in all I feel that my C++ code could be a *big win* *IFF* it turns out that Simulated Annealing is appropriate given the cost function(s); The approach taken in the code would give

- a highly efficient storage model
- a highly efficient way to generate
*random* / closely related new grid configurations
- convenient display functions

Mandatory (abritrary...) benchmark data point (comparison to the python version:)

```
a b c d e
f g h i j
k l m n o
p q r s t
Result: 207360000
real 0m13.016s
user 0m13.000s
sys 0m0.010s
```

Here is what we got up till now:

From the description I glean the suggestion that you have a basic graph like

a path has to be constructed that visits all nodes in the grid (*Hamiltonian cycle*).

The extra constraint is that subsequent nodes **have to be taken from the next ***rank* (a-d, e-h, i-l being the three *ranks*; once a node from the last *rank* was visited, the path has to continue with any unvisited node from the first *rank*

The edges are weighted, in that they have a cost associated. However, the weight function is not traditional for graph algorithms in that the cost depends on the full path, not just the end-points of each edge.

In the light of this I believe we are in the realm of 'Full Cover' problems (requiring A* algorithm, most famous from Knuths Dancing Links paper).

**Specifically** Without further information (equivalence of paths, specific properties of the cost function) the best known algorithm to get the 'cheapest' hamiltonian path that satisfies the constraints will be to

- generate
*all possible* such paths
- calculate the actual cost function for each
- choose the minimum cost path

Which is why I have set off and wrote a really dumb brute force generator that generates all the unique paths possible in a generic grid of NxM.

### The End Of The Universe

Output for the 3×4 sample grid is 4!^{3} = 13824 possible paths... Extrapolating that to 6×48 columns, leads to 6!^{48} = 1.4×10^{137} possibilities. It is very clear *that without further optimization the problem is untractible* (NP Hard or something -- I never remember quite the subtle definitions).

The explosion of runtime is deafening:

- 3×4 (measured) takes about 0.175s
- 4×5 (measured) took about 6m5s (running without output and under PyPy 1.6 on a fast machine)
- 5×6 would take roughly 10 years and 9+ months...

At 48x6 we would be looking at... what... 8.3x10^{107} *lightyears* (read that closely)

Anyways, here is the python code (all preset for 2×3 grid)

```
#!/usr/bin/python
ROWS = 2
COLS = 3
## different cell representations
def cell(r,c):
## exercise for the reader: _gues_ which of the following is the fastest
## ...
## then profile it :)
index = COLS*(r) + c
# return [ r,c ]
# return ( r,c )
# return index
# return "(%i,%i)" % (r,c)
def baseN(num,b,numerals="abcdefghijklmnopqrstuvwxyz"):
return ((num == 0) and numerals[0]) or (baseN(num // b, b, numerals).lstrip(numerals[0]) + numerals[num % b])
return baseN(index, 26)
ORIGIN = cell(0,0)
def debug(t): pass; #print t
def dump(grid): print("\n".join(map(str, grid)))
def print_path(path):
## Note: to 'normalize' to start at (1,1) node:
# while ORIGIN != path[0]: path = path[1:] + path[:1]
print " -> ".join(map(str, path))
def bruteforce_hamiltonians(grid, whenfound):
def inner(grid, whenfound, partial):
cols = len(grid[-1]) # number of columns remaining in last rank
if cols<1:
# assert 1 == len(set([ len(r) for r in grid ])) # for debug only
whenfound(partial) # disable when benchmarking
pass
else:
#debug(" ------ cols: %i ------- " % cols)
for i,rank in enumerate(grid):
if len(rank)<cols: continue
#debug("debug: %i, %s (partial: %s%s)" % (i,rank, "... " if len(partial)>3 else "", partial[-3:]))
for ci,cell in enumerate(rank):
partial.append(cell)
grid[i] = rank[:ci]+rank[ci+1:] # modify grid in-place, keeps rank
inner(grid, whenfound, partial)
grid[i] = rank # restore in-place
partial.pop()
break
pass
# start of recursion
inner(grid, whenfound, [])
grid = [ [ cell(c,r) for r in range(COLS) ] for c in range(ROWS) ]
dump(grid)
bruteforce_hamiltonians(grid, print_path)
```

`C`

tag is probably not appropriate – TBohne Sep 12 '11 at 17:22