# Partition Equivalent in Julia

What is an equivalent for Mathematica's `Partition` function in Julia?

Mathematica's `Partition[list,n]` takes an array and partitions it into non-overlapping sub-list of length `n`. On the other hand, the partition function in Julia takes an array and gives all the partitions of that array into `n` sub-sets.

Maybe I'm missing something, but doesn't this do what you want?

``````x = [:a,:b,:c,:d,:e,:f]
n = 2
reshape(x, (n, div(length(x), n)))
``````
• This is exactly what I was looking for. Thanks. – Ali Nov 16 '14 at 3:55
• This answer won't work if the length doesn't cleanly divide into subarrays of length `n`, e.g. `x = [:a,:b,:c,:d,:e,:f,:g]`, `n=2` will fail. You also get a matrix, instead of an array-of-arrays. – IainDunning Nov 16 '14 at 16:43
• @IainDunning, I agree, it doesn't mimic the `Partition` function in Mathematica. Given @Ali's use, however, it might be what is needed. – cd98 Nov 16 '14 at 23:09

So in Mathematica:

``````In[1]:= Partition[{a, b, c, d, e, f}, 2]
Out[1]= {{a,b},{c,d},{e,f}}
``````

but in Julia the `partitions` function has a very different meaning:

``````x = [:a,:b,:c,:d,:e,:f]
first(partitions(x,2))
#2-element Array{Array{Symbol,1},1}:
# [:a,:b,:c,:d,:e]
# [:f]
``````

Its the set of all 2-partitions of the set. To get what you want you could do something like

``````yourpart(x,n) = {{x[i:min(i+n-1,length(x))]} for i in 1:n:length(x)}
``````

and

``````julia> yourpart([:a,:b,:c,:d,:e,:f], 2)
3-element Array{Any,1}:
{:a,:b}
{:c,:d}
{:e,:f}

julia> yourpart(x,4)
2-element Array{Any,1}:
{[:a,:b,:c,:d]}
{[:e,:f]}
``````
• To avoid deprecated warnings (as of Julia 0.4.5), you can write this as `yourpart(x, n) = [x[i:min(i+n-1,length(x))] for i in 1:n:length(x)]` – Jeff Ames Apr 13 '16 at 15:31

In case others also run across the need for the related task of breaking an array into n parts:

``````function nfolds(x::AbstractArray, n::Int)
s = length(x) / n
[x[round(Int64, (i-1)*s)+1:min(length(x),round(Int64, i*s))] for i=1:n]
end

julia> map(length, npartition(1:21, 6))
6-element Array{Int64,1}:
4
3
3
4
4
3
``````

This also works

``````partitioneddata=[data[n:n+pfac] for n=1:offset:length(data)-pfac];
``````

where:

• pfac is how "long" you want your new arrays to each be

and

• offset is by how many positions you want each new array to be offset by

This can be seen in the following example:

We want to partition [1,2,3,4,5,6,7,8,9,10] into new arrays of length=2 with each array shifted by offset=1.

``````pfac=2
offset=1
partitioneddata=[data[n:n+pfac] for n=1:offset:length(data)-pfac]
8-element Array{Array{Int64,1},1}:
[1,2,3]
[2,3,4]
[3,4,5]
[4,5,6]
[5,6,7]
[6,7,8]
[7,8,9]
[8,9,10]
``````

I know I'm a bit late to the party but hopefully this helps!

This approach should (i) be more memory efficient and (ii) allow e.g. 53 data points to be split into groups of 10.

``````"""
returns ranges (i.e. indices to split the data).
"""
function partition_array_indices(nb_data::Int, nb_data_per_chunk::Int)
nb_chunks = ceil(Int, nb_data / nb_data_per_chunk)
ids = UnitRange{Int}[]
for which_chunk = 1:nb_chunks
id_start::Int = 1 + nb_data_per_chunk * (which_chunk - 1)
id_end::Int = id_start - 1 + nb_data_per_chunk
if id_end > nb_data
id_end = nb_data
end
push!(ids, id_start:id_end)
end
return ids
end
``````

Example use:

``````x = collect(linspace(0, 1, 53))
nb_data_per_chunk = 10
ids = partition_array_indices(length(x), nb_data_per_chunk)

# get first chunk, 10 elements
x[ids[1]]
# get last chunk, just 3 elements
x[ids[end]]
``````