Related
Suppose I have a df which has columns of 'ID', 'col_1', 'col_2'. And I define a function :
f = lambda x, y : my_function_expression.
Now I want to apply the f to df's two columns 'col_1', 'col_2' to element-wise calculate a new column 'col_3' , somewhat like :
df['col_3'] = df[['col_1','col_2']].apply(f)
# Pandas gives : TypeError: ('<lambda>() takes exactly 2 arguments (1 given)'
How to do ?
** Add detail sample as below ***
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
#df['col_3'] = df[['col_1','col_2']].apply(get_sublist,axis=1)
# expect above to output df as below
ID col_1 col_2 col_3
0 1 0 1 ['a', 'b']
1 2 2 4 ['c', 'd', 'e']
2 3 3 5 ['d', 'e', 'f']
There is a clean, one-line way of doing this in Pandas:
df['col_3'] = df.apply(lambda x: f(x.col_1, x.col_2), axis=1)
This allows f to be a user-defined function with multiple input values, and uses (safe) column names rather than (unsafe) numeric indices to access the columns.
Example with data (based on original question):
import pandas as pd
df = pd.DataFrame({'ID':['1', '2', '3'], 'col_1': [0, 2, 3], 'col_2':[1, 4, 5]})
mylist = ['a', 'b', 'c', 'd', 'e', 'f']
def get_sublist(sta,end):
return mylist[sta:end+1]
df['col_3'] = df.apply(lambda x: get_sublist(x.col_1, x.col_2), axis=1)
Output of print(df):
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
If your column names contain spaces or share a name with an existing dataframe attribute, you can index with square brackets:
df['col_3'] = df.apply(lambda x: f(x['col 1'], x['col 2']), axis=1)
Here's an example using apply on the dataframe, which I am calling with axis = 1.
Note the difference is that instead of trying to pass two values to the function f, rewrite the function to accept a pandas Series object, and then index the Series to get the values needed.
In [49]: df
Out[49]:
0 1
0 1.000000 0.000000
1 -0.494375 0.570994
2 1.000000 0.000000
3 1.876360 -0.229738
4 1.000000 0.000000
In [50]: def f(x):
....: return x[0] + x[1]
....:
In [51]: df.apply(f, axis=1) #passes a Series object, row-wise
Out[51]:
0 1.000000
1 0.076619
2 1.000000
3 1.646622
4 1.000000
Depending on your use case, it is sometimes helpful to create a pandas group object, and then use apply on the group.
A simple solution is:
df['col_3'] = df[['col_1','col_2']].apply(lambda x: f(*x), axis=1)
A interesting question! my answer as below:
import pandas as pd
def sublst(row):
return lst[row['J1']:row['J2']]
df = pd.DataFrame({'ID':['1','2','3'], 'J1': [0,2,3], 'J2':[1,4,5]})
print df
lst = ['a','b','c','d','e','f']
df['J3'] = df.apply(sublst,axis=1)
print df
Output:
ID J1 J2
0 1 0 1
1 2 2 4
2 3 3 5
ID J1 J2 J3
0 1 0 1 [a]
1 2 2 4 [c, d]
2 3 3 5 [d, e]
I changed the column name to ID,J1,J2,J3 to ensure ID < J1 < J2 < J3, so the column display in right sequence.
One more brief version:
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'J1': [0,2,3], 'J2':[1,4,5]})
print df
lst = ['a','b','c','d','e','f']
df['J3'] = df.apply(lambda row:lst[row['J1']:row['J2']],axis=1)
print df
The method you are looking for is Series.combine.
However, it seems some care has to be taken around datatypes.
In your example, you would (as I did when testing the answer) naively call
df['col_3'] = df.col_1.combine(df.col_2, func=get_sublist)
However, this throws the error:
ValueError: setting an array element with a sequence.
My best guess is that it seems to expect the result to be of the same type as the series calling the method (df.col_1 here). However, the following works:
df['col_3'] = df.col_1.astype(object).combine(df.col_2, func=get_sublist)
df
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
Returning a list from apply is a dangerous operation as the resulting object is not guaranteed to be either a Series or a DataFrame. And exceptions might be raised in certain cases. Let's walk through a simple example:
df = pd.DataFrame(data=np.random.randint(0, 5, (5,3)),
columns=['a', 'b', 'c'])
df
a b c
0 4 0 0
1 2 0 1
2 2 2 2
3 1 2 2
4 3 0 0
There are three possible outcomes with returning a list from apply
1) If the length of the returned list is not equal to the number of columns, then a Series of lists is returned.
df.apply(lambda x: list(range(2)), axis=1) # returns a Series
0 [0, 1]
1 [0, 1]
2 [0, 1]
3 [0, 1]
4 [0, 1]
dtype: object
2) When the length of the returned list is equal to the number of
columns then a DataFrame is returned and each column gets the
corresponding value in the list.
df.apply(lambda x: list(range(3)), axis=1) # returns a DataFrame
a b c
0 0 1 2
1 0 1 2
2 0 1 2
3 0 1 2
4 0 1 2
3) If the length of the returned list equals the number of columns for the first row but has at least one row where the list has a different number of elements than number of columns a ValueError is raised.
i = 0
def f(x):
global i
if i == 0:
i += 1
return list(range(3))
return list(range(4))
df.apply(f, axis=1)
ValueError: Shape of passed values is (5, 4), indices imply (5, 3)
Answering the problem without apply
Using apply with axis=1 is very slow. It is possible to get much better performance (especially on larger datasets) with basic iterative methods.
Create larger dataframe
df1 = df.sample(100000, replace=True).reset_index(drop=True)
Timings
# apply is slow with axis=1
%timeit df1.apply(lambda x: mylist[x['col_1']: x['col_2']+1], axis=1)
2.59 s ± 76.8 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
# zip - similar to #Thomas
%timeit [mylist[v1:v2+1] for v1, v2 in zip(df1.col_1, df1.col_2)]
29.5 ms ± 534 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
#Thomas answer
%timeit list(map(get_sublist, df1['col_1'],df1['col_2']))
34 ms ± 459 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
I'm sure this isn't as fast as the solutions using Pandas or Numpy operations, but if you don't want to rewrite your function you can use map. Using the original example data -
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
df['col_3'] = list(map(get_sublist,df['col_1'],df['col_2']))
#In Python 2 don't convert above to list
We could pass as many arguments as we wanted into the function this way. The output is what we wanted
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
I'm going to put in a vote for np.vectorize. It allows you to just shoot over x number of columns and not deal with the dataframe in the function, so it's great for functions you don't control or doing something like sending 2 columns and a constant into a function (i.e. col_1, col_2, 'foo').
import numpy as np
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
#df['col_3'] = df[['col_1','col_2']].apply(get_sublist,axis=1)
# expect above to output df as below
df.loc[:,'col_3'] = np.vectorize(get_sublist, otypes=["O"]) (df['col_1'], df['col_2'])
df
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
Here is a faster solution:
def func_1(a,b):
return a + b
df["C"] = func_1(df["A"].to_numpy(),df["B"].to_numpy())
This is 380 times faster than df.apply(f, axis=1) from #Aman and 310 times faster than df['col_3'] = df.apply(lambda x: f(x.col_1, x.col_2), axis=1) from #ajrwhite.
I add some benchmarks too:
Results:
FUNCTIONS TIMINGS GAIN
apply lambda 0.7 x 1
apply 0.56 x 1.25
map 0.3 x 2.3
np.vectorize 0.01 x 70
f3 on Series 0.0026 x 270
f3 on np arrays 0.0018 x 380
f3 numba 0.0018 x 380
In short:
Using apply is slow. We can speed up things very simply, just by using a function that will operate directly on Pandas Series (or better on numpy arrays). And because we will operate on Pandas Series or numpy arrays, we will be able to vectorize the operations. The function will return a Pandas Series or numpy array that we will assign as a new column.
And here is the benchmark code:
import timeit
timeit_setup = """
import pandas as pd
import numpy as np
import numba
np.random.seed(0)
# Create a DataFrame of 10000 rows with 2 columns "A" and "B"
# containing integers between 0 and 100
df = pd.DataFrame(np.random.randint(0,10,size=(10000, 2)), columns=["A", "B"])
def f1(a,b):
# Here a and b are the values of column A and B for a specific row: integers
return a + b
def f2(x):
# Here, x is pandas Series, and corresponds to a specific row of the DataFrame
# 0 and 1 are the indexes of columns A and B
return x[0] + x[1]
def f3(a,b):
# Same as f1 but we will pass parameters that will allow vectorization
# Here, A and B will be Pandas Series or numpy arrays
# with df["C"] = f3(df["A"],df["B"]): Pandas Series
# with df["C"] = f3(df["A"].to_numpy(),df["B"].to_numpy()): numpy arrays
return a + b
#numba.njit('int64[:](int64[:], int64[:])')
def f3_numba_vectorize(a,b):
# Here a and b are 2 numpy arrays with dtype int64
# This function must return a numpy array whith dtype int64
return a + b
"""
test_functions = [
'df["C"] = df.apply(lambda row: f1(row["A"], row["B"]), axis=1)',
'df["C"] = df.apply(f2, axis=1)',
'df["C"] = list(map(f3,df["A"],df["B"]))',
'df["C"] = np.vectorize(f3) (df["A"].to_numpy(),df["B"].to_numpy())',
'df["C"] = f3(df["A"],df["B"])',
'df["C"] = f3(df["A"].to_numpy(),df["B"].to_numpy())',
'df["C"] = f3_numba_vectorize(df["A"].to_numpy(),df["B"].to_numpy())'
]
for test_function in test_functions:
print(min(timeit.repeat(setup=timeit_setup, stmt=test_function, repeat=7, number=10)))
Output:
0.7
0.56
0.3
0.01
0.0026
0.0018
0.0018
Final note: things could be optimzed with Cython and other numba tricks too.
The way you have written f it needs two inputs. If you look at the error message it says you are not providing two inputs to f, just one. The error message is correct.
The mismatch is because df[['col1','col2']] returns a single dataframe with two columns, not two separate columns.
You need to change your f so that it takes a single input, keep the above data frame as input, then break it up into x,y inside the function body. Then do whatever you need and return a single value.
You need this function signature because the syntax is .apply(f)
So f needs to take the single thing = dataframe and not two things which is what your current f expects.
Since you haven't provided the body of f I can't help in anymore detail - but this should provide the way out without fundamentally changing your code or using some other methods rather than apply
Another option is df.itertuples() (generally faster and recommended over df.iterrows() by docs and user testing):
import pandas as pd
df = pd.DataFrame([range(4) for _ in range(4)], columns=list("abcd"))
df
a b c d
0 0 1 2 3
1 0 1 2 3
2 0 1 2 3
3 0 1 2 3
df["e"] = [sum(row) for row in df[["b", "d"]].itertuples(index=False)]
df
a b c d e
0 0 1 2 3 4
1 0 1 2 3 4
2 0 1 2 3 4
3 0 1 2 3 4
Since itertuples returns an Iterable of namedtuples, you can access tuple elements both as attributes by column name (aka dot notation) and by index:
b, d = row
b = row.b
d = row[1]
My example to your questions:
def get_sublist(row, col1, col2):
return mylist[row[col1]:row[col2]+1]
df.apply(get_sublist, axis=1, col1='col_1', col2='col_2')
It can be done in two simple ways:
Let's say, we want sum of col1 and col2 in output column named col_sum
Method 1
f = lambda x : x.col1 + x.col2
df['col_sum'] = df.apply(f, axis=1)
Method 2
def f(x):
x['col_sum'] = x.col_1 + col_2
return x
df = df.apply(f, axis=1)
Method 2 should be used when some complex function has to applied to the dataframe. Method 2 can also be used when output in multiple columns is required.
I suppose you don't want to change get_sublist function, and just want to use DataFrame's apply method to do the job. To get the result you want, I've wrote two help functions: get_sublist_list and unlist. As the function name suggest, first get the list of sublist, second extract that sublist from that list. Finally, We need to call apply function to apply those two functions to the df[['col_1','col_2']] DataFrame subsequently.
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
def get_sublist_list(cols):
return [get_sublist(cols[0],cols[1])]
def unlist(list_of_lists):
return list_of_lists[0]
df['col_3'] = df[['col_1','col_2']].apply(get_sublist_list,axis=1).apply(unlist)
df
If you don't use [] to enclose the get_sublist function, then the get_sublist_list function will return a plain list, it'll raise ValueError: could not broadcast input array from shape (3) into shape (2), as #Ted Petrou had mentioned.
If you have a huge data-set, then you can use an easy but faster(execution time) way of doing this using swifter:
import pandas as pd
import swifter
def fnc(m,x,c):
return m*x+c
df = pd.DataFrame({"m": [1,2,3,4,5,6], "c": [1,1,1,1,1,1], "x":[5,3,6,2,6,1]})
df["y"] = df.swifter.apply(lambda x: fnc(x.m, x.x, x.c), axis=1)
Suppose I have a df which has columns of 'ID', 'col_1', 'col_2'. And I define a function :
f = lambda x, y : my_function_expression.
Now I want to apply the f to df's two columns 'col_1', 'col_2' to element-wise calculate a new column 'col_3' , somewhat like :
df['col_3'] = df[['col_1','col_2']].apply(f)
# Pandas gives : TypeError: ('<lambda>() takes exactly 2 arguments (1 given)'
How to do ?
** Add detail sample as below ***
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
#df['col_3'] = df[['col_1','col_2']].apply(get_sublist,axis=1)
# expect above to output df as below
ID col_1 col_2 col_3
0 1 0 1 ['a', 'b']
1 2 2 4 ['c', 'd', 'e']
2 3 3 5 ['d', 'e', 'f']
There is a clean, one-line way of doing this in Pandas:
df['col_3'] = df.apply(lambda x: f(x.col_1, x.col_2), axis=1)
This allows f to be a user-defined function with multiple input values, and uses (safe) column names rather than (unsafe) numeric indices to access the columns.
Example with data (based on original question):
import pandas as pd
df = pd.DataFrame({'ID':['1', '2', '3'], 'col_1': [0, 2, 3], 'col_2':[1, 4, 5]})
mylist = ['a', 'b', 'c', 'd', 'e', 'f']
def get_sublist(sta,end):
return mylist[sta:end+1]
df['col_3'] = df.apply(lambda x: get_sublist(x.col_1, x.col_2), axis=1)
Output of print(df):
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
If your column names contain spaces or share a name with an existing dataframe attribute, you can index with square brackets:
df['col_3'] = df.apply(lambda x: f(x['col 1'], x['col 2']), axis=1)
Here's an example using apply on the dataframe, which I am calling with axis = 1.
Note the difference is that instead of trying to pass two values to the function f, rewrite the function to accept a pandas Series object, and then index the Series to get the values needed.
In [49]: df
Out[49]:
0 1
0 1.000000 0.000000
1 -0.494375 0.570994
2 1.000000 0.000000
3 1.876360 -0.229738
4 1.000000 0.000000
In [50]: def f(x):
....: return x[0] + x[1]
....:
In [51]: df.apply(f, axis=1) #passes a Series object, row-wise
Out[51]:
0 1.000000
1 0.076619
2 1.000000
3 1.646622
4 1.000000
Depending on your use case, it is sometimes helpful to create a pandas group object, and then use apply on the group.
A simple solution is:
df['col_3'] = df[['col_1','col_2']].apply(lambda x: f(*x), axis=1)
A interesting question! my answer as below:
import pandas as pd
def sublst(row):
return lst[row['J1']:row['J2']]
df = pd.DataFrame({'ID':['1','2','3'], 'J1': [0,2,3], 'J2':[1,4,5]})
print df
lst = ['a','b','c','d','e','f']
df['J3'] = df.apply(sublst,axis=1)
print df
Output:
ID J1 J2
0 1 0 1
1 2 2 4
2 3 3 5
ID J1 J2 J3
0 1 0 1 [a]
1 2 2 4 [c, d]
2 3 3 5 [d, e]
I changed the column name to ID,J1,J2,J3 to ensure ID < J1 < J2 < J3, so the column display in right sequence.
One more brief version:
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'J1': [0,2,3], 'J2':[1,4,5]})
print df
lst = ['a','b','c','d','e','f']
df['J3'] = df.apply(lambda row:lst[row['J1']:row['J2']],axis=1)
print df
The method you are looking for is Series.combine.
However, it seems some care has to be taken around datatypes.
In your example, you would (as I did when testing the answer) naively call
df['col_3'] = df.col_1.combine(df.col_2, func=get_sublist)
However, this throws the error:
ValueError: setting an array element with a sequence.
My best guess is that it seems to expect the result to be of the same type as the series calling the method (df.col_1 here). However, the following works:
df['col_3'] = df.col_1.astype(object).combine(df.col_2, func=get_sublist)
df
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
Returning a list from apply is a dangerous operation as the resulting object is not guaranteed to be either a Series or a DataFrame. And exceptions might be raised in certain cases. Let's walk through a simple example:
df = pd.DataFrame(data=np.random.randint(0, 5, (5,3)),
columns=['a', 'b', 'c'])
df
a b c
0 4 0 0
1 2 0 1
2 2 2 2
3 1 2 2
4 3 0 0
There are three possible outcomes with returning a list from apply
1) If the length of the returned list is not equal to the number of columns, then a Series of lists is returned.
df.apply(lambda x: list(range(2)), axis=1) # returns a Series
0 [0, 1]
1 [0, 1]
2 [0, 1]
3 [0, 1]
4 [0, 1]
dtype: object
2) When the length of the returned list is equal to the number of
columns then a DataFrame is returned and each column gets the
corresponding value in the list.
df.apply(lambda x: list(range(3)), axis=1) # returns a DataFrame
a b c
0 0 1 2
1 0 1 2
2 0 1 2
3 0 1 2
4 0 1 2
3) If the length of the returned list equals the number of columns for the first row but has at least one row where the list has a different number of elements than number of columns a ValueError is raised.
i = 0
def f(x):
global i
if i == 0:
i += 1
return list(range(3))
return list(range(4))
df.apply(f, axis=1)
ValueError: Shape of passed values is (5, 4), indices imply (5, 3)
Answering the problem without apply
Using apply with axis=1 is very slow. It is possible to get much better performance (especially on larger datasets) with basic iterative methods.
Create larger dataframe
df1 = df.sample(100000, replace=True).reset_index(drop=True)
Timings
# apply is slow with axis=1
%timeit df1.apply(lambda x: mylist[x['col_1']: x['col_2']+1], axis=1)
2.59 s ± 76.8 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
# zip - similar to #Thomas
%timeit [mylist[v1:v2+1] for v1, v2 in zip(df1.col_1, df1.col_2)]
29.5 ms ± 534 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
#Thomas answer
%timeit list(map(get_sublist, df1['col_1'],df1['col_2']))
34 ms ± 459 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
I'm sure this isn't as fast as the solutions using Pandas or Numpy operations, but if you don't want to rewrite your function you can use map. Using the original example data -
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
df['col_3'] = list(map(get_sublist,df['col_1'],df['col_2']))
#In Python 2 don't convert above to list
We could pass as many arguments as we wanted into the function this way. The output is what we wanted
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
I'm going to put in a vote for np.vectorize. It allows you to just shoot over x number of columns and not deal with the dataframe in the function, so it's great for functions you don't control or doing something like sending 2 columns and a constant into a function (i.e. col_1, col_2, 'foo').
import numpy as np
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
#df['col_3'] = df[['col_1','col_2']].apply(get_sublist,axis=1)
# expect above to output df as below
df.loc[:,'col_3'] = np.vectorize(get_sublist, otypes=["O"]) (df['col_1'], df['col_2'])
df
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
Here is a faster solution:
def func_1(a,b):
return a + b
df["C"] = func_1(df["A"].to_numpy(),df["B"].to_numpy())
This is 380 times faster than df.apply(f, axis=1) from #Aman and 310 times faster than df['col_3'] = df.apply(lambda x: f(x.col_1, x.col_2), axis=1) from #ajrwhite.
I add some benchmarks too:
Results:
FUNCTIONS TIMINGS GAIN
apply lambda 0.7 x 1
apply 0.56 x 1.25
map 0.3 x 2.3
np.vectorize 0.01 x 70
f3 on Series 0.0026 x 270
f3 on np arrays 0.0018 x 380
f3 numba 0.0018 x 380
In short:
Using apply is slow. We can speed up things very simply, just by using a function that will operate directly on Pandas Series (or better on numpy arrays). And because we will operate on Pandas Series or numpy arrays, we will be able to vectorize the operations. The function will return a Pandas Series or numpy array that we will assign as a new column.
And here is the benchmark code:
import timeit
timeit_setup = """
import pandas as pd
import numpy as np
import numba
np.random.seed(0)
# Create a DataFrame of 10000 rows with 2 columns "A" and "B"
# containing integers between 0 and 100
df = pd.DataFrame(np.random.randint(0,10,size=(10000, 2)), columns=["A", "B"])
def f1(a,b):
# Here a and b are the values of column A and B for a specific row: integers
return a + b
def f2(x):
# Here, x is pandas Series, and corresponds to a specific row of the DataFrame
# 0 and 1 are the indexes of columns A and B
return x[0] + x[1]
def f3(a,b):
# Same as f1 but we will pass parameters that will allow vectorization
# Here, A and B will be Pandas Series or numpy arrays
# with df["C"] = f3(df["A"],df["B"]): Pandas Series
# with df["C"] = f3(df["A"].to_numpy(),df["B"].to_numpy()): numpy arrays
return a + b
#numba.njit('int64[:](int64[:], int64[:])')
def f3_numba_vectorize(a,b):
# Here a and b are 2 numpy arrays with dtype int64
# This function must return a numpy array whith dtype int64
return a + b
"""
test_functions = [
'df["C"] = df.apply(lambda row: f1(row["A"], row["B"]), axis=1)',
'df["C"] = df.apply(f2, axis=1)',
'df["C"] = list(map(f3,df["A"],df["B"]))',
'df["C"] = np.vectorize(f3) (df["A"].to_numpy(),df["B"].to_numpy())',
'df["C"] = f3(df["A"],df["B"])',
'df["C"] = f3(df["A"].to_numpy(),df["B"].to_numpy())',
'df["C"] = f3_numba_vectorize(df["A"].to_numpy(),df["B"].to_numpy())'
]
for test_function in test_functions:
print(min(timeit.repeat(setup=timeit_setup, stmt=test_function, repeat=7, number=10)))
Output:
0.7
0.56
0.3
0.01
0.0026
0.0018
0.0018
Final note: things could be optimzed with Cython and other numba tricks too.
The way you have written f it needs two inputs. If you look at the error message it says you are not providing two inputs to f, just one. The error message is correct.
The mismatch is because df[['col1','col2']] returns a single dataframe with two columns, not two separate columns.
You need to change your f so that it takes a single input, keep the above data frame as input, then break it up into x,y inside the function body. Then do whatever you need and return a single value.
You need this function signature because the syntax is .apply(f)
So f needs to take the single thing = dataframe and not two things which is what your current f expects.
Since you haven't provided the body of f I can't help in anymore detail - but this should provide the way out without fundamentally changing your code or using some other methods rather than apply
Another option is df.itertuples() (generally faster and recommended over df.iterrows() by docs and user testing):
import pandas as pd
df = pd.DataFrame([range(4) for _ in range(4)], columns=list("abcd"))
df
a b c d
0 0 1 2 3
1 0 1 2 3
2 0 1 2 3
3 0 1 2 3
df["e"] = [sum(row) for row in df[["b", "d"]].itertuples(index=False)]
df
a b c d e
0 0 1 2 3 4
1 0 1 2 3 4
2 0 1 2 3 4
3 0 1 2 3 4
Since itertuples returns an Iterable of namedtuples, you can access tuple elements both as attributes by column name (aka dot notation) and by index:
b, d = row
b = row.b
d = row[1]
My example to your questions:
def get_sublist(row, col1, col2):
return mylist[row[col1]:row[col2]+1]
df.apply(get_sublist, axis=1, col1='col_1', col2='col_2')
It can be done in two simple ways:
Let's say, we want sum of col1 and col2 in output column named col_sum
Method 1
f = lambda x : x.col1 + x.col2
df['col_sum'] = df.apply(f, axis=1)
Method 2
def f(x):
x['col_sum'] = x.col_1 + col_2
return x
df = df.apply(f, axis=1)
Method 2 should be used when some complex function has to applied to the dataframe. Method 2 can also be used when output in multiple columns is required.
I suppose you don't want to change get_sublist function, and just want to use DataFrame's apply method to do the job. To get the result you want, I've wrote two help functions: get_sublist_list and unlist. As the function name suggest, first get the list of sublist, second extract that sublist from that list. Finally, We need to call apply function to apply those two functions to the df[['col_1','col_2']] DataFrame subsequently.
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
def get_sublist_list(cols):
return [get_sublist(cols[0],cols[1])]
def unlist(list_of_lists):
return list_of_lists[0]
df['col_3'] = df[['col_1','col_2']].apply(get_sublist_list,axis=1).apply(unlist)
df
If you don't use [] to enclose the get_sublist function, then the get_sublist_list function will return a plain list, it'll raise ValueError: could not broadcast input array from shape (3) into shape (2), as #Ted Petrou had mentioned.
If you have a huge data-set, then you can use an easy but faster(execution time) way of doing this using swifter:
import pandas as pd
import swifter
def fnc(m,x,c):
return m*x+c
df = pd.DataFrame({"m": [1,2,3,4,5,6], "c": [1,1,1,1,1,1], "x":[5,3,6,2,6,1]})
df["y"] = df.swifter.apply(lambda x: fnc(x.m, x.x, x.c), axis=1)
Suppose I have a df which has columns of 'ID', 'col_1', 'col_2'. And I define a function :
f = lambda x, y : my_function_expression.
Now I want to apply the f to df's two columns 'col_1', 'col_2' to element-wise calculate a new column 'col_3' , somewhat like :
df['col_3'] = df[['col_1','col_2']].apply(f)
# Pandas gives : TypeError: ('<lambda>() takes exactly 2 arguments (1 given)'
How to do ?
** Add detail sample as below ***
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
#df['col_3'] = df[['col_1','col_2']].apply(get_sublist,axis=1)
# expect above to output df as below
ID col_1 col_2 col_3
0 1 0 1 ['a', 'b']
1 2 2 4 ['c', 'd', 'e']
2 3 3 5 ['d', 'e', 'f']
There is a clean, one-line way of doing this in Pandas:
df['col_3'] = df.apply(lambda x: f(x.col_1, x.col_2), axis=1)
This allows f to be a user-defined function with multiple input values, and uses (safe) column names rather than (unsafe) numeric indices to access the columns.
Example with data (based on original question):
import pandas as pd
df = pd.DataFrame({'ID':['1', '2', '3'], 'col_1': [0, 2, 3], 'col_2':[1, 4, 5]})
mylist = ['a', 'b', 'c', 'd', 'e', 'f']
def get_sublist(sta,end):
return mylist[sta:end+1]
df['col_3'] = df.apply(lambda x: get_sublist(x.col_1, x.col_2), axis=1)
Output of print(df):
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
If your column names contain spaces or share a name with an existing dataframe attribute, you can index with square brackets:
df['col_3'] = df.apply(lambda x: f(x['col 1'], x['col 2']), axis=1)
Here's an example using apply on the dataframe, which I am calling with axis = 1.
Note the difference is that instead of trying to pass two values to the function f, rewrite the function to accept a pandas Series object, and then index the Series to get the values needed.
In [49]: df
Out[49]:
0 1
0 1.000000 0.000000
1 -0.494375 0.570994
2 1.000000 0.000000
3 1.876360 -0.229738
4 1.000000 0.000000
In [50]: def f(x):
....: return x[0] + x[1]
....:
In [51]: df.apply(f, axis=1) #passes a Series object, row-wise
Out[51]:
0 1.000000
1 0.076619
2 1.000000
3 1.646622
4 1.000000
Depending on your use case, it is sometimes helpful to create a pandas group object, and then use apply on the group.
A simple solution is:
df['col_3'] = df[['col_1','col_2']].apply(lambda x: f(*x), axis=1)
A interesting question! my answer as below:
import pandas as pd
def sublst(row):
return lst[row['J1']:row['J2']]
df = pd.DataFrame({'ID':['1','2','3'], 'J1': [0,2,3], 'J2':[1,4,5]})
print df
lst = ['a','b','c','d','e','f']
df['J3'] = df.apply(sublst,axis=1)
print df
Output:
ID J1 J2
0 1 0 1
1 2 2 4
2 3 3 5
ID J1 J2 J3
0 1 0 1 [a]
1 2 2 4 [c, d]
2 3 3 5 [d, e]
I changed the column name to ID,J1,J2,J3 to ensure ID < J1 < J2 < J3, so the column display in right sequence.
One more brief version:
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'J1': [0,2,3], 'J2':[1,4,5]})
print df
lst = ['a','b','c','d','e','f']
df['J3'] = df.apply(lambda row:lst[row['J1']:row['J2']],axis=1)
print df
The method you are looking for is Series.combine.
However, it seems some care has to be taken around datatypes.
In your example, you would (as I did when testing the answer) naively call
df['col_3'] = df.col_1.combine(df.col_2, func=get_sublist)
However, this throws the error:
ValueError: setting an array element with a sequence.
My best guess is that it seems to expect the result to be of the same type as the series calling the method (df.col_1 here). However, the following works:
df['col_3'] = df.col_1.astype(object).combine(df.col_2, func=get_sublist)
df
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
Returning a list from apply is a dangerous operation as the resulting object is not guaranteed to be either a Series or a DataFrame. And exceptions might be raised in certain cases. Let's walk through a simple example:
df = pd.DataFrame(data=np.random.randint(0, 5, (5,3)),
columns=['a', 'b', 'c'])
df
a b c
0 4 0 0
1 2 0 1
2 2 2 2
3 1 2 2
4 3 0 0
There are three possible outcomes with returning a list from apply
1) If the length of the returned list is not equal to the number of columns, then a Series of lists is returned.
df.apply(lambda x: list(range(2)), axis=1) # returns a Series
0 [0, 1]
1 [0, 1]
2 [0, 1]
3 [0, 1]
4 [0, 1]
dtype: object
2) When the length of the returned list is equal to the number of
columns then a DataFrame is returned and each column gets the
corresponding value in the list.
df.apply(lambda x: list(range(3)), axis=1) # returns a DataFrame
a b c
0 0 1 2
1 0 1 2
2 0 1 2
3 0 1 2
4 0 1 2
3) If the length of the returned list equals the number of columns for the first row but has at least one row where the list has a different number of elements than number of columns a ValueError is raised.
i = 0
def f(x):
global i
if i == 0:
i += 1
return list(range(3))
return list(range(4))
df.apply(f, axis=1)
ValueError: Shape of passed values is (5, 4), indices imply (5, 3)
Answering the problem without apply
Using apply with axis=1 is very slow. It is possible to get much better performance (especially on larger datasets) with basic iterative methods.
Create larger dataframe
df1 = df.sample(100000, replace=True).reset_index(drop=True)
Timings
# apply is slow with axis=1
%timeit df1.apply(lambda x: mylist[x['col_1']: x['col_2']+1], axis=1)
2.59 s ± 76.8 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
# zip - similar to #Thomas
%timeit [mylist[v1:v2+1] for v1, v2 in zip(df1.col_1, df1.col_2)]
29.5 ms ± 534 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
#Thomas answer
%timeit list(map(get_sublist, df1['col_1'],df1['col_2']))
34 ms ± 459 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
I'm sure this isn't as fast as the solutions using Pandas or Numpy operations, but if you don't want to rewrite your function you can use map. Using the original example data -
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
df['col_3'] = list(map(get_sublist,df['col_1'],df['col_2']))
#In Python 2 don't convert above to list
We could pass as many arguments as we wanted into the function this way. The output is what we wanted
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
I'm going to put in a vote for np.vectorize. It allows you to just shoot over x number of columns and not deal with the dataframe in the function, so it's great for functions you don't control or doing something like sending 2 columns and a constant into a function (i.e. col_1, col_2, 'foo').
import numpy as np
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
#df['col_3'] = df[['col_1','col_2']].apply(get_sublist,axis=1)
# expect above to output df as below
df.loc[:,'col_3'] = np.vectorize(get_sublist, otypes=["O"]) (df['col_1'], df['col_2'])
df
ID col_1 col_2 col_3
0 1 0 1 [a, b]
1 2 2 4 [c, d, e]
2 3 3 5 [d, e, f]
Here is a faster solution:
def func_1(a,b):
return a + b
df["C"] = func_1(df["A"].to_numpy(),df["B"].to_numpy())
This is 380 times faster than df.apply(f, axis=1) from #Aman and 310 times faster than df['col_3'] = df.apply(lambda x: f(x.col_1, x.col_2), axis=1) from #ajrwhite.
I add some benchmarks too:
Results:
FUNCTIONS TIMINGS GAIN
apply lambda 0.7 x 1
apply 0.56 x 1.25
map 0.3 x 2.3
np.vectorize 0.01 x 70
f3 on Series 0.0026 x 270
f3 on np arrays 0.0018 x 380
f3 numba 0.0018 x 380
In short:
Using apply is slow. We can speed up things very simply, just by using a function that will operate directly on Pandas Series (or better on numpy arrays). And because we will operate on Pandas Series or numpy arrays, we will be able to vectorize the operations. The function will return a Pandas Series or numpy array that we will assign as a new column.
And here is the benchmark code:
import timeit
timeit_setup = """
import pandas as pd
import numpy as np
import numba
np.random.seed(0)
# Create a DataFrame of 10000 rows with 2 columns "A" and "B"
# containing integers between 0 and 100
df = pd.DataFrame(np.random.randint(0,10,size=(10000, 2)), columns=["A", "B"])
def f1(a,b):
# Here a and b are the values of column A and B for a specific row: integers
return a + b
def f2(x):
# Here, x is pandas Series, and corresponds to a specific row of the DataFrame
# 0 and 1 are the indexes of columns A and B
return x[0] + x[1]
def f3(a,b):
# Same as f1 but we will pass parameters that will allow vectorization
# Here, A and B will be Pandas Series or numpy arrays
# with df["C"] = f3(df["A"],df["B"]): Pandas Series
# with df["C"] = f3(df["A"].to_numpy(),df["B"].to_numpy()): numpy arrays
return a + b
#numba.njit('int64[:](int64[:], int64[:])')
def f3_numba_vectorize(a,b):
# Here a and b are 2 numpy arrays with dtype int64
# This function must return a numpy array whith dtype int64
return a + b
"""
test_functions = [
'df["C"] = df.apply(lambda row: f1(row["A"], row["B"]), axis=1)',
'df["C"] = df.apply(f2, axis=1)',
'df["C"] = list(map(f3,df["A"],df["B"]))',
'df["C"] = np.vectorize(f3) (df["A"].to_numpy(),df["B"].to_numpy())',
'df["C"] = f3(df["A"],df["B"])',
'df["C"] = f3(df["A"].to_numpy(),df["B"].to_numpy())',
'df["C"] = f3_numba_vectorize(df["A"].to_numpy(),df["B"].to_numpy())'
]
for test_function in test_functions:
print(min(timeit.repeat(setup=timeit_setup, stmt=test_function, repeat=7, number=10)))
Output:
0.7
0.56
0.3
0.01
0.0026
0.0018
0.0018
Final note: things could be optimzed with Cython and other numba tricks too.
The way you have written f it needs two inputs. If you look at the error message it says you are not providing two inputs to f, just one. The error message is correct.
The mismatch is because df[['col1','col2']] returns a single dataframe with two columns, not two separate columns.
You need to change your f so that it takes a single input, keep the above data frame as input, then break it up into x,y inside the function body. Then do whatever you need and return a single value.
You need this function signature because the syntax is .apply(f)
So f needs to take the single thing = dataframe and not two things which is what your current f expects.
Since you haven't provided the body of f I can't help in anymore detail - but this should provide the way out without fundamentally changing your code or using some other methods rather than apply
Another option is df.itertuples() (generally faster and recommended over df.iterrows() by docs and user testing):
import pandas as pd
df = pd.DataFrame([range(4) for _ in range(4)], columns=list("abcd"))
df
a b c d
0 0 1 2 3
1 0 1 2 3
2 0 1 2 3
3 0 1 2 3
df["e"] = [sum(row) for row in df[["b", "d"]].itertuples(index=False)]
df
a b c d e
0 0 1 2 3 4
1 0 1 2 3 4
2 0 1 2 3 4
3 0 1 2 3 4
Since itertuples returns an Iterable of namedtuples, you can access tuple elements both as attributes by column name (aka dot notation) and by index:
b, d = row
b = row.b
d = row[1]
My example to your questions:
def get_sublist(row, col1, col2):
return mylist[row[col1]:row[col2]+1]
df.apply(get_sublist, axis=1, col1='col_1', col2='col_2')
It can be done in two simple ways:
Let's say, we want sum of col1 and col2 in output column named col_sum
Method 1
f = lambda x : x.col1 + x.col2
df['col_sum'] = df.apply(f, axis=1)
Method 2
def f(x):
x['col_sum'] = x.col_1 + col_2
return x
df = df.apply(f, axis=1)
Method 2 should be used when some complex function has to applied to the dataframe. Method 2 can also be used when output in multiple columns is required.
I suppose you don't want to change get_sublist function, and just want to use DataFrame's apply method to do the job. To get the result you want, I've wrote two help functions: get_sublist_list and unlist. As the function name suggest, first get the list of sublist, second extract that sublist from that list. Finally, We need to call apply function to apply those two functions to the df[['col_1','col_2']] DataFrame subsequently.
import pandas as pd
df = pd.DataFrame({'ID':['1','2','3'], 'col_1': [0,2,3], 'col_2':[1,4,5]})
mylist = ['a','b','c','d','e','f']
def get_sublist(sta,end):
return mylist[sta:end+1]
def get_sublist_list(cols):
return [get_sublist(cols[0],cols[1])]
def unlist(list_of_lists):
return list_of_lists[0]
df['col_3'] = df[['col_1','col_2']].apply(get_sublist_list,axis=1).apply(unlist)
df
If you don't use [] to enclose the get_sublist function, then the get_sublist_list function will return a plain list, it'll raise ValueError: could not broadcast input array from shape (3) into shape (2), as #Ted Petrou had mentioned.
If you have a huge data-set, then you can use an easy but faster(execution time) way of doing this using swifter:
import pandas as pd
import swifter
def fnc(m,x,c):
return m*x+c
df = pd.DataFrame({"m": [1,2,3,4,5,6], "c": [1,1,1,1,1,1], "x":[5,3,6,2,6,1]})
df["y"] = df.swifter.apply(lambda x: fnc(x.m, x.x, x.c), axis=1)
I want to append a Series to a DataFrame where Series's index matches DataFrame's columns using pd.concat, but it gives me surprises:
df = pd.DataFrame(columns=['a', 'b'])
sr = pd.Series(data=[1,2], index=['a', 'b'], name=1)
pd.concat([df, sr], axis=0)
Out[11]:
a b 0
a NaN NaN 1.0
b NaN NaN 2.0
What I expected is of course:
df.append(sr)
Out[14]:
a b
1 1 2
It really surprises me that pd.concat is not index-columns aware. So is it true that if I want to concat a Series as a new row to a DF, then I can only use df.append instead?
Need DataFrame from Series by to_frame and transpose:
a = pd.concat([df, sr.to_frame(1).T])
print (a)
a b
1 1 2
Detail:
print (sr.to_frame(1).T)
a b
1 1 2
Or use setting with enlargement:
df.loc[1] = sr
print (df)
a b
1 1 2
"df.loc[1] = sr" will drop the column if it isn't in df
df = pd.DataFrame(columns = ['a','b'])
sr = pd.Series({'a':1,'b':2,'c':3})
df.loc[1] = sr
df will be like:
a b
1 1 2
having a dataframe, I want to update subset of columns with a series of same length as number of columns being updated:
>>> df = pd.DataFrame(np.random.randint(0,5,(6, 2)), columns=['col1','col2'])
>>> df
col1 col2
0 1 0
1 2 4
2 4 4
3 4 0
4 0 0
5 3 1
>>> df.loc[:,['col1','col2']] = pd.Series([0,1])
...
ValueError: shape mismatch: value array of shape (6,) could not be broadcast to indexing result of shape (2,6)
it fails, however, I am able to do the same thing using list:
>>> df.loc[:,['col1','col2']] = list(pd.Series([0,1]))
>>> df
col1 col2
0 0 1
1 0 1
2 0 1
3 0 1
4 0 1
5 0 1
could you please help me to understand, why updating with series fails? do I have to perform some particular reshaping?
When assigning with a pandas object, pandas treats the assignment more "rigorously". A pandas to pandas assignment must pass stricter protocols. Only when you turn it to a list (or equivalently pd.Series([0, 1]).values) did pandas give in and allow you to assign in the way you'd imagine it should work.
That higher standard of assignment requires that the indices line up as well, so even if you had the right shape, it still wouldn't have worked without the correct indices.
df.loc[:, ['col1', 'col2']] = pd.DataFrame([[0, 1] for _ in range(6)])
df
df.loc[:, ['col1', 'col2']] = pd.DataFrame([[0, 1] for _ in range(6)], columns=['col1', 'col2'])
df