I have a code where a shared resource is changed by a function call. So far, for each input vector (the input matrix of dimension rxc), I'm running it serially.

I want to change a shared resource (say R) with each function call. I've so far tried using Python Multiprocessing and Pathos Multiprocessing to speed this up. I even tried np.apply_along_axis to try and speed it up.

So far what I've noticed was that the serial processing is the fastest way. I'm lost as to why this is happening.

I've tried the following approaches

- np.apply_along_axis : Only slight delay (constant time shift)
- Pathos.multiprocessing.ProcessingPool.Map : up to 10x delay
- multiprocessing.Process (manual split): up to 5x delay
- multiprocessing.Pool : in line with Pathos results.

I am new to python parallel programming and may be doing something wrong. What is a good way to do it?

**Update : Self Organizing Map code attached**

I'm quoting what I'm doing.

```
class SOM(object):
def __init__(self, X):
pool = Pool()
pool.ncpus=4
self.map = pool.map
def train_single( self, x, lr, r):
b = np.argmin(np.linalg.norm(self.W-x, axis=1))
N = np.where(np.linalg.norm(self.Y-self.Y[b],axis=1)<r)[0]
d = np.linalg.norm(self.Y[N]-self.Y[b],axis=1)
H = np.array([np.exp(-d**2/np.max(d)**2*0.5)]).T
H/=H.max()
gradients = - (self.W[N] - x) * H * lr
if np.isnan(gradients).any():
return
#
self.W[N] += gradients
def train_batch_parallel(self, X):
self.W = np.random.random(size=(100, X.shape[1]))
self.Y = np.array([[i, j] for i in range(10) for j in range(10)])
self.X = X
r = 10
lr = .5
self.rs = np.repeat(r, X.shape[0]).astype(float)
self.lrs = np.repeat(lr, X.shape[0])
for k in range(1, 100):
self.rs *=0.8# np.append(self.rs, np.repeat(r * 0.8 ** k, X.shape[0]), axis=0)
self.lrs *=0.9# np.append(self.rs, np.repeat(lr * 0.9 ** k, X.shape[0]), axis=0)
#parallel execution using the pool.map
self.map(self.train_single, X, self.lrs, self.rs)
```