# Julia - Iterating over combinations of keys in a dictionary

Is there a nifty way to iterate over combinations of keys in a dictionary?

my dictionary has values like:

``````[1] => [1,2], [2,3] => [15], [3] => [6,7,8], [4,9,11] => [3], ...
``````

what I need to do is fetch all combinations of keys that are of length `1:n` where `n` might be fx 3

So as in the example above, I would want to iterate over

``````[[1], [3], [2,3], [[1],[1,2]], [[3],[2,3]], [4,9,11]]
``````

I know I could just collect the keys, but my dictionary is rather large and I am in the middle of redesigning the entire algorithm because it starts swapping insanely when `n > 3`, reducing efficiency terribly

tl;dr is there a way to create a combinatoric iterator from a dictionary without `collect`-ing the dictionary?

The following is a straight forward implementation, which tries to minimize a bit on going through the dictionary. Additionally it uses OrderedDict so holding key indices makes sense (since Dicts don't promise consistent key iteration each time and thus meaningful key indexing).

``````using Iterators
using DataStructures

od = OrderedDict([1] => [1,2], [2,3] => [15], [3] => [6,7,8], [4,9,11] => [3])

sv = map(length,keys(od))        # store length of keys for quicker calculations
maxmaxlen = sum(sv)              # maximum total elements in good key
for maxlen=1:maxmaxlen           # replace maxmaxlen with lower value if too slow
@show maxlen
gsets = Vector{Vector{Int}}()  # hold good sets of key _indices_
for curlen=1:maxlen
foreach(x->push!(gsets,x),
(x for x in subsets(collect(1:n),curlen) if sum(sv[x])==maxlen))
end
# indmatrix is necessary to run through keys once in next loop
indmatrix = zeros(Bool,length(od),length(gsets))
for i=1:length(gsets)              for e in gsets[i]
indmatrix[e,i] = true
end
end
# gkeys is the vector of vecotrs of keys i.e. what we wanted to calculate
gkeys = [Vector{Vector{Int}}() for i=1:length(gsets)]
for (i,k) in enumerate(keys(od))
for j=1:length(gsets)
if indmatrix[i,j]
push!(gkeys[j],k)
end
end
end
# do something with each set of good keys
foreach(x->println(x),gkeys)
end
``````

Is this more efficient that what you currently have? It would also be better to put the code in a function or turn it into a Julia task which produces the next keys set each iteration.

--- UPDATE ---

An improved iterator-ified version is:

``````function keysubsets(n,d)
od = OrderedDict(d)
sv = map(length,keys(od))        # store length of keys for quicker calculations
maxmaxlen = sum(sv)              # maximum total elements in good key
for maxlen=1:min(n,maxmaxlen)    # replace maxmaxlen with lower value if too slow
gsets = Vector{Vector{Int}}()  # hold good sets of key _indices_
for curlen=1:maxlen
foreach(x->push!(gsets,x),(x for x in subsets(collect(1:n),curlen) if sum(sv[x])==maxlen))
end
# indmatrix is necessary to run through keys once in next loop
indmatrix = zeros(Bool,length(od),length(gsets))
for i=1:length(gsets)              for e in gsets[i]
indmatrix[e,i] = true
end
end
# gkeys is the vector of vecotrs of keys i.e. what we wanted to calculate
gkeys = [Vector{Vector{Int}}() for i=1:length(gsets)]
for (i,k) in enumerate(keys(od))
for j=1:length(gsets)
if indmatrix[i,j]
push!(gkeys[j],k)
end
end
end
# do something with each set of good keys
foreach(x->produce(x),gkeys)
end
end
end
``````

Which now enables iterating over all keysubsets up to combined size 4 in this way (after running the code from the other StackOverflow answer):

``````julia> nt2 = NewTask(keysubsets(4,od))
julia> collect(nt2)
10-element Array{Array{Array{Int64,1},1},1}:
Array{Int64,1}[[1]]
Array{Int64,1}[[3]]
Array{Int64,1}[[2,3]]
Array{Int64,1}[[1],[3]]
Array{Int64,1}[[4,9,11]]
Array{Int64,1}[[1],[2,3]]
Array{Int64,1}[[2,3],[3]]
Array{Int64,1}[[1],[4,9,11]]
Array{Int64,1}[[3],[4,9,11]]
Array{Int64,1}[[1],[2,3],[3]]
``````