# Numpy how to use np.cumprod to rewrite python for i in range function

I have two python functions. The first one:

``````mt = np.array([1, 2, 3, 4, 5, 6, 7])
age, interest = 3, 0.5

def getnpx(mt, age, interest):
val = 1
initval = 1
for i in range(age, 6):
val = val * mt[i]
intval = val / (1 + interest) ** (i + 1 - age)
initval = initval + intval
return initval
``````

The output is:

``````48.111111111111114
``````

In order to make it faster, I used numpy to vectorize it:

``````def getnpx_(mt, age, interest):
print(np.cumprod(mt[age:6]) / (1 + interest)**np.arange(1, 7 - age))
return 1 + (np.cumprod(mt[age:6]) / (1 + interest)**np.arange(1, 7 - age)).sum()

getnpx_(mt, age, interest)
``````

It works and the output is still:

``````48.111111111111114
``````

However I have no idea how to rewrite my second function by numpy:

``````pt1 = np.array([1, 2, 3, 4, 5, 6, 7])
pt2 = np.array([2, 4, 3, 4, 7, 4, 8])
pvaltable = np.array([0, 0, 0, 0, 0, 0, 0])

def jointpval(pt1, pt2, age1, age2):
j = age1
for i in range(age2, 6):
k = min(j, 135)
pvaltable[i] = pt1[k] * pt2[i]
j = j + 1
return pvaltable

jointpval(pt1, pt2, 3, 4)
``````

Output:

``````array([ 0,  0,  0,  0, 28, 20,  0])
``````

I expect to be able to convert the loop

``````for i in range(age2, 6):
``````

To something like:

``````np.cumprod(pt1[age:6])
``````

The final output should be the same as:

``````array([ 0,  0,  0,  0, 28, 20,  0])
``````
• Do you mind to add the expected output? How is `pandas` involved here? Commented Oct 5, 2021 at 19:10
• Hi @rpanai thank you for your reply I have updated my question please check! Commented Oct 5, 2021 at 19:18
• Does 135 need to be hardcoded? Commented Oct 5, 2021 at 19:26
• yes,but 135 can be smaller as 7 Commented Oct 5, 2021 at 19:27

I found this solution:

``````import numpy as np
pt1 = np.array([1, 2, 3, 4, 5, 6, 7])
pt2 = np.array([2, 4, 3, 4, 7, 4, 8])

def jointpval(pt1, pt2, age1, age2):
pvaltable = np.zeros(len(pt1))
idx2 = np.arange(age2, 6)
idx1 = np.arange(len(idx2)) + age1
idx1 = np.where(idx1 > 135, 135, idx1)
pvaltable[idx2] = pt1[idx1] * pt2[idx2]
return pvaltable
``````

Where `jointpval(pt1, pt2, 3, 4)` returns

``````array([ 0.,  0.,  0.,  0., 28., 20.,  0.])
``````

I would recommend not hard coding your array sizes. For example:

``````def getnpx_(mt, age, interest):
return 1 + (np.cumprod(mt[age:-1]) / (1 + interest)**np.arange(1, len(mt) - age)).sum()
``````

Notice that the index `age:-1` agnostic to the size of `mt`, and `mt.size - age` saves you the trouble of recoding the function every time you have a different `mt`.

Your solution for the second case is pretty much on-point. I might recommend using `np.clip` rather than where to also set the lower bound to zero:

``````def jointpval(pt1, pt2, age1, age2):
pvaltable = np.zeros(len(pt1))
idx = np.arange(len(pt2) - age2 - 1)
idx1 = np.clip(idx + age1, 0, len(pt1) - 1)
idx2 = idx + age2
pvaltable[idx2] = pt1[idx1] * pt2[idx2]
return pvaltable
``````

You could also use `np.minimum` to implement vectorized `min` directly:

``````idx1 = np.minimum(idx + age1, len(pt1) - 1)
``````

Keep in mind that ranges are exclusive on the upper bound. Both of your functions are truncating the computation of the last element for this reason. It is likely that `idx = np.arange(len(pt2) - age2 - 1)` should really be `idx = np.arange(len(pt2) - age2)` in `jointpval`, while `mt[age:-1]` should be `mt[age:]`, and `np.arange(1, len(mt) - age)` should be `np.arange(len(mt) - age)` in `genpx_`.