I have a data set where each samples has a structure similar to this

```
X=[ [[],[],[],[]], [[],[]] , [[],[],[]] ,[[][]]]
```

for example:

```
X=np.array([ [ [1,2,3], [2,4,5] ,[2,3,4] ] , [ [5,6], [6,6] ] , [[2,3,1],[2,3,10],[23,1,2],[1,4,5]] ] ,"object")
Y=np.array([ [ [12,14,15] ,[12,13,14] ] , [ [15,16], [16,16] ] , [[22,23,21],[32,33,11],[12,44,55]] ] ,"object")
```

so for **every sample** I need to calculate the dot product between every element of x with corresponding element of y of same index and sum the result. i.e:

```
result=0
for i in range(3):
for n,m in itertools.product(X[i],Y[i]):
print "%s, %s" % (n,m)
result+=np.dot(n,m)
.....:
[1, 2, 3], [12, 14, 15]
[1, 2, 3], [12, 13, 14]
[2, 4, 5], [12, 14, 15]
[2, 4, 5], [12, 13, 14]
[2, 3, 4], [12, 14, 15]
[2, 3, 4], [12, 13, 14]
[5, 6], [15, 16]
[5, 6], [16, 16]
[6, 6], [15, 16]
[6, 6], [16, 16]
[2, 3, 1], [22, 23, 21]
[2, 3, 1], [32, 33, 11]
[2, 3, 1], [12, 44, 55]
[2, 3, 10], [22, 23, 21]
[2, 3, 10], [32, 33, 11]
[2, 3, 10], [12, 44, 55]
[23, 1, 2], [22, 23, 21]
[23, 1, 2], [32, 33, 11]
[23, 1, 2], [12, 44, 55]
[1, 4, 5], [22, 23, 21]
[1, 4, 5], [32, 33, 11]
[1, 4, 5], [12, 44, 55]
```

This is my whole code:

```
print "***build kernel***"
K = np.zeros((n_samples, n_samples))
for i in range(n_samples):
for j in range(n_samples):
K[i,j] = self.kernel(X[i], X[j])
def kernel(x1,x2):
N=8 #number of objects
result=0
for i in xrange(N):
for n,m in itertools.product(x1[i],x2[i]):
result+=np.dot(n,m)
return result
```

as you can see the complexity of this algorithm is too high and also my samples are much bigger than this. so for even a small data set, i.e. contains 400 samples, I have to wait 4 hours to get the result. I am looking for a better way to implement this algorithm. P.S: I was thinking about multithreading or multiproccessing but I am not sure if it helps?!

I appreciate any suggestion!

`X[i]`

and`Y[i]`

both have 200 vectors? – Claudiu Mar 18 '13 at 14:57`Y`

. – Janne Karila Mar 18 '13 at 14:58