# How to apply a function on every row on a dataframe?

I am new to Python and I am not sure how to solve the following problem.

I have a function:

``````def EOQ(D,p,ck,ch):
Q = math.sqrt((2*D*ck)/(ch*p))
return Q
``````

Say I have the dataframe

``````df = pd.DataFrame({"D": [10,20,30], "p": [20, 30, 10]})

D   p
0   10  20
1   20  30
2   30  10

ch=0.2
ck=5
``````

And `ch` and `ck` are float types. Now I want to apply the formula to every row on the dataframe and return it as an extra row 'Q'. An example (that does not work) would be:

``````df['Q']= map(lambda p, D: EOQ(D,p,ck,ch),df['p'], df['D'])
``````

(returns only 'map' types)

I will need this type of processing more in my project and I hope to find something that works.

• You can look through this function that applies functions to rows: docs.scipy.org/doc/numpy/reference/generated/numpy.apply_along_axis.html Nov 4, 2015 at 9:35
• Do you mean Now I want to apply the formula to every row on the dataframe and return it as an extra COLUMN 'Q'. Jan 8, 2020 at 21:57

The following should work:

``````def EOQ(D,p,ck,ch):
Q = math.sqrt((2*D*ck)/(ch*p))
return Q
ch=0.2
ck=5
df['Q'] = df.apply(lambda row: EOQ(row['D'], row['p'], ck, ch), axis=1)
df
``````

If all you're doing is calculating the square root of some result then use the `np.sqrt` method this is vectorised and will be significantly faster:

``````In [80]:
df['Q'] = np.sqrt((2*df['D']*ck)/(ch*df['p']))

df
Out[80]:
D   p          Q
0  10  20   5.000000
1  20  30   5.773503
2  30  10  12.247449
``````

Timings

For a 30k row df:

``````In [92]:

import math
ch=0.2
ck=5
def EOQ(D,p,ck,ch):
Q = math.sqrt((2*D*ck)/(ch*p))
return Q

%timeit np.sqrt((2*df['D']*ck)/(ch*df['p']))
%timeit df.apply(lambda row: EOQ(row['D'], row['p'], ck, ch), axis=1)
1000 loops, best of 3: 622 µs per loop
1 loops, best of 3: 1.19 s per loop
``````

You can see that the np method is ~1900 X faster

There are few more ways to apply a function on every row of a DataFrame.

(1) You could modify `EOQ` a bit by letting it accept a row (a Series object) as argument and access the relevant elements using the column names inside the function. Moreover, you can pass arguments to `apply` using its keyword, e.g. `ch` or `ck`:

``````def EOQ1(row, ck, ch):
Q = math.sqrt((2*row['D']*ck)/(ch*row['p']))
return Q

df['Q1'] = df.apply(EOQ1, ck=ck, ch=ch, axis=1)
``````

(2) It turns out that `apply` is often slower than a list comprehension (in the benchmark below, it's 20x slower). To use a list comprehension, you could modify `EOQ` still further so that you access elements by its index. Then call the function in a loop over `df` rows that are converted to lists:

``````def EOQ2(row, ck, ch):
Q = math.sqrt((2*row[0]*ck)/(ch*row[1]))
return Q

df['Q2a'] = [EOQ2(x, ck, ch) for x in df[['D','p']].to_numpy().tolist()]
``````

(3) As it happens, if the goal is to call a function iteratively, `map` is usually faster than a list comprehension. So you could convert `df` into a list, `map` the function to it; then unpack the result in a list:

``````df['Q2b'] = [*map(EOQ2, df[['D','p']].to_numpy().tolist(), [ck]*len(df), [ch]*len(df))]
``````

(4) As @EdChum notes, it's always better to use vectorized methods if it's possible to do so, instead of applying a function row by row. Pandas offers vectorized methods that rival that of numpy's. In the case of `EOQ` for example, instead of `math.sqrt`, you could use pandas' `pow` method (in the benchmark below, using pandas vectorized methods is ~20% faster than using numpy):

``````df['Q_pd'] = df['D'].mul(2*ck).div(ch*df['p']).pow(0.5)
``````

Output:

``````    D   p          Q       Q_np         Q1        Q2a        Q2b       Q_pd
0  10  20   5.000000   5.000000   5.000000   5.000000   5.000000   5.000000
1  20  30   5.773503   5.773503   5.773503   5.773503   5.773503   5.773503
2  30  10  12.247449  12.247449  12.247449  12.247449  12.247449  12.247449
``````

Timings:

``````df = pd.DataFrame({"D": [10,20,30], "p": [20, 30, 10]})
df = pd.concat([df]*10000)

>>> %timeit df['Q'] = df.apply(lambda row: EOQ(row['D'], row['p'], ck, ch), axis=1)
623 ms ± 22.7 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

>>> %timeit df['Q1'] = df.apply(EOQ1, ck=ck, ch=ch, axis=1)
615 ms ± 39.9 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

>>> %timeit df['Q2a'] = [EOQ2(x, ck, ch) for x in df[['D','p']].to_numpy().tolist()]
31.3 ms ± 479 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

>>> %timeit df['Q2b'] = [*map(EOQ2, df[['D','p']].to_numpy().tolist(), [ck]*len(df), [ch]*len(df))]
26.9 ms ± 306 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
``````

``````>>> %timeit df['Q_np'] = np.sqrt((2*df['D']*ck)/(ch*df['p']))
1.19 ms ± 53.7 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)

>>> %timeit df['Q_pd'] = df['D'].mul(2*ck).div(ch*df['p']).pow(0.5)
966 µs ± 27 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
``````