Here is some less mathematical pseudo-code. I don't know if this will explain what's happening, but it may help you read it. This isn't a functional algorithm (lots of `:=`

all over), so I'm going to use Python pseudo-code.

```
# I have no idea where 'i' comes from. It's not defined anywhere
for k in range(2,n):
C[set(i,k), k] = d(1,k)
shortest_path = VERY_LARGE_NUMBER
# I have to assume that n is the number of nodes in the graph G
# other things that are not defined:
# d_i,j -- I will assume it's the distance from i to j in G
for subset_size in range(3,n):
for index_subset in subsets_of_size(subset_size, range(1,n)):
for k in index_subset:
C[S,k] = argmin(lambda m: C[S-k,m] + d(G,m,k), S - k)
shortest_path = argmin(lambda k: C[set(range(1,n)),k] + d(G,1,k), range(2,n))
return shortest_path
# also needed....
def d(G, i, j):
return G[i][j]
def subsets_of_size(n, s): # returns a list of sets
# complicated code goes here
pass
def argmin(f, l):
best = l[0]
bestVal = f(best)
for x in l[1:]:
newVal = f(x)
if newVal < bestVal:
best = x
bestVal = newVal
return best
```

Some notes:

- The source algorithm is not complete. At least, its formatting is weird in the inner loop, and it rebinds
*k* in the second argmin. So the whole thing is probably wrong; I've not tried to run this code.
- arguments to
`range`

should probably all be increased by 1 since Python counts from 0, not 1. (and in general counting from 1 is a bad idea).
- I assume that G is a dictionary of type { from : { to : length } }. In other words, an adjacency list representation.
- I inferred that C is a dictionary of type { (set(int),int) : int }. I could be wrong.
- I use a
`set`

as keys to `C`

. In real Python, you must convert to a `frozen_set`

first. The conversion is just busywork so I left it out.
- I can't remember the set operators in Python. I seem to remember it uses
`|`

and `&`

instead of `+`

and `-`

.
- I didn't write
`subsets_of_size`

. It's fairly complicated.