351

I'm starting from the pandas DataFrame docs here: http://pandas.pydata.org/pandas-docs/stable/dsintro.html

I'd like to iteratively fill the DataFrame with values in a time series kind of calculation. So basically, I'd like to initialize the DataFrame with columns A, B and timestamp rows, all 0 or all NaN.

I'd then add initial values and go over this data calculating the new row from the row before, say row[A][t] = row[A][t-1]+1 or so.

I'm currently using the code as below, but I feel it's kind of ugly and there must be a way to do this with a DataFrame directly, or just a better way in general. Note: I'm using Python 2.7.

import datetime as dt
import pandas as pd
import scipy as s

if __name__ == '__main__':
    base = dt.datetime.today().date()
    dates = [ base - dt.timedelta(days=x) for x in range(0,10) ]
    dates.sort()

    valdict = {}
    symbols = ['A','B', 'C']
    for symb in symbols:
        valdict[symb] = pd.Series( s.zeros( len(dates)), dates )

    for thedate in dates:
        if thedate > dates[0]:
            for symb in valdict:
                valdict[symb][thedate] = 1+valdict[symb][thedate - dt.timedelta(days=1)]

    print valdict
271

Here's a couple of suggestions:

Use date_range for the index:

import datetime
import pandas as pd
import numpy as np

todays_date = datetime.datetime.now().date()
index = pd.date_range(todays_date-datetime.timedelta(10), periods=10, freq='D')

columns = ['A','B', 'C']

Note: we could create an empty DataFrame (with NaNs) simply by writing:

df_ = pd.DataFrame(index=index, columns=columns)
df_ = df_.fillna(0) # with 0s rather than NaNs

To do these type of calculations for the data, use a numpy array:

data = np.array([np.arange(10)]*3).T

Hence we can create the DataFrame:

In [10]: df = pd.DataFrame(data, index=index, columns=columns)

In [11]: df
Out[11]: 
            A  B  C
2012-11-29  0  0  0
2012-11-30  1  1  1
2012-12-01  2  2  2
2012-12-02  3  3  3
2012-12-03  4  4  4
2012-12-04  5  5  5
2012-12-05  6  6  6
2012-12-06  7  7  7
2012-12-07  8  8  8
2012-12-08  9  9  9
  • 2
    pd.date_range() does not work for me. I tried with DateRange (from eclipse's autocompletion), but that works with strings as date format, right? The overall approach works though (I changed index to something else). – Matthias Kauer Dec 15 '12 at 8:42
  • 2
    date_range is a factory function for creating datetime indexes and was a new feature in 0.8.0, I would definitely recommend upgrading to the latest stable release (0.9.1) there are many bug fixes and new features. :) – Andy Hayden Dec 15 '12 at 9:52
  • 25
    In my experiences, creating a data frame of the necessary size filled with NaNs, and then filling up with values is much-much slower than creating a data frame with index x 0 dimensions (columns = []), and attaching one column in each turn of a loop. I mean df[col_name] = pandas.Series([...]) in a loop iterating through column names. In the former case, not only the memory allocation takes time, but replacing NaNs with new values seems extremely slow. – deeenes Mar 3 '15 at 16:33
  • 5
    @deeenes definitely. this answer should probably make that clearer - you very rarely (if ever) want to do create an empty Dataframe (of NaNs). – Andy Hayden Mar 3 '15 at 17:33
  • 1
    As per this answer stackoverflow.com/a/30267881/2302569 You need to assign the result of fillna, or pass param inplace=True – JayJay Jan 2 '17 at 20:09
131

If you simply want to create an empty data frame and fill it with some incoming data frames later, try this:

In this example I am using this pandas doc to create a new data frame and then using append to write to the newDF with data from oldDF.


Have a look at this

newDF = pd.DataFrame() #creates a new dataframe that's empty
newDF = newDF.append(oldDF, ignore_index = True) # ignoring index is optional
# try printing some data from newDF
print newDF.head() #again optional 
  • if I have to keep appending new data into this newDF from more than one oldDFs, I just use a for loop to iterate over pandas.DataFrame.append()
97

If you want to have your column names in place from the start, use this approach:

import pandas as pd

col_names =  ['A', 'B', 'C']
my_df  = pd.DataFrame(columns = col_names)
my_df

If you want to add a record to the dataframe it would be better to use:

my_df.loc[len(my_df)] = [2, 4, 5]

You also might want to pass a dictionary:

my_dic = {'A':2, 'B':4, 'C':5}
my_df.loc[len(my_df)] = my_dic 

However if you want to add another dataframe to my_df do as follows:

col_names =  ['A', 'B', 'C']
my_df2  = pd.DataFrame(columns = col_names)
my_df = my_df.append(my_df2)

If you are adding rows inside a loop consider performance issues:
For around the first 1000 records "my_df.loc" performance is better, but it gradually becomes slower by increasing the number of records in the loop.

If you plan to do thins inside a big loop (say 10M‌ records or so):
You are better off using a mixture of these two; fill a dataframe with iloc until the size gets around 1000, then append it to the original dataframe, and empty the temp dataframe. This would boost your performance by around 10 times.

35

The Right Way™ to Create a DataFrame

Most answers here will tell you how to create an empty DataFrame and fill it out, but no one will tell you that it is a bad thing to do.

Here is my advice: Wait until you are sure you have all the data you need to work with. Use a list to collect your data, then initialise a DataFrame when you are ready.

data = []
for a, b, c in some_function_that_yields_data():
    data.append([a, b, c])

df = pd.DataFrame(data, columns=['A', 'B', 'C'])

It is always cheaper to append to a list and create a DataFrame in one go than it is to create an empty DataFrame (or one of of NaNs) and append to it over and over again. Lists also take up less memory and are a much lighter data structure to work with, append, and remove (if needed).

The other advantage of this method is dtypes are automatically inferred (rather than assigning object to all of them).

The last advantage is that a RangeIndex is automatically created for your data, so it is one less thing to worry about (take a look at the poor append and loc methods below, you will see elements in both that require handling the index appropriately).


Things you should NOT do

append or concat inside a loop

Here is the biggest mistake I've seen from beginners:

df = pd.DataFrame(columns=['A', 'B', 'C'])
for a, b, c in some_function_that_yields_data():
    df = df.append({'A': i, 'B': b, 'C': c}, ignore_index=True) # yuck
    # or similarly,
    # df = pd.concat([df, pd.Series({'A': i, 'B': b, 'C': c})], ignore_index=True)

Memory is re-allocated for every append or concat operation you have. Couple this with a loop and you have a quadratic complexity operation. From the df.append doc page:

Iteratively appending rows to a DataFrame can be more computationally intensive than a single concatenate. A better solution is to append those rows to a list and then concatenate the list with the original DataFrame all at once.

The other mistake associated with df.append is that users tend to forget append is not an in-place function, so the result must be assigned back. You also have to worry about the dtypes:

df = pd.DataFrame(columns=['A', 'B', 'C'])
df = df.append({'A': 1, 'B': 12.3, 'C': 'xyz'}, ignore_index=True)

df.dtypes
A     object   # yuck!
B    float64
C     object
dtype: object

Dealing with object columns is never a good thing, because pandas cannot vectorize operations on those columns. You will need to do this to fix it:

df.infer_objects().dtypes
A      int64
B    float64
C     object
dtype: object

loc inside a loop

I have also seen loc used to append to a DataFrame that was created empty:

df = pd.DataFrame(columns=['A', 'B', 'C'])
for a, b, c in some_function_that_yields_data():
    df.loc[len(df)] = [a, b, c]

As before, you have not pre-allocated the amount of memory you need each time, so the memory is re-grown each time you create a new row. It's just as bad as append, and even more ugly.

Empty DataFrame of NaNs

And then, there's creating a DataFrame of NaNs, and all the caveats associated therewith.

df = pd.DataFrame(columns=['A', 'B', 'C'], index=range(5))
df
     A    B    C
0  NaN  NaN  NaN
1  NaN  NaN  NaN
2  NaN  NaN  NaN
3  NaN  NaN  NaN
4  NaN  NaN  NaN

It creates a DataFrame of object columns, like the others.

df.dtypes
A    object  # you DON'T want this
B    object
C    object
dtype: object

Appending still has all the issues as the methods above.

for i, (a, b, c) in enumerate(some_function_that_yields_data()):
    df.iloc[i] = [a, b, c]

The Proof is in the Pudding

Timing these methods is the fastest way to see just how much they differ in terms of their memory and utility.

enter image description here

Benchmarking code for reference.

  • 3
    List append should be the best way for this type of question – WeNYoBen Jun 25 at 3:21
  • 4
    This needs to be upvoted a million times more. Never grow a dataframe! – user3293236 Jul 2 at 16:27
  • 2
    @user3293236 Too bad you have to start from the bottom every time you answer an old question ;) – cs95 Jul 2 at 16:31
  • 1
    This is one of the things I hate the most. Those many times you see the 𝒓𝒆𝒂𝒍 𝒄𝒐𝒓𝒓𝒆𝒄𝒕 𝒂𝒏𝒔𝒘𝒆𝒓 that just stays somewhere down with few votes and never accepted. I miss code with 𝚍𝚏 = 𝚙𝚍.𝙳𝚊𝚝𝚊𝙵𝚛𝚊𝚖𝚎([]) to create an empty pandas dataframe. Upvoting this answer. Excellent explanation, @cs95! – jonathan Jul 11 at 0:55
  • This is literally in the documentation. "Iteratively appending rows to a DataFrame can be more computationally intensive than a single concatenate. A better solution is to append those rows to a list and then concatenate the list with the original DataFrame all at once." pandas.pydata.org/pandas-docs/version/0.21/generated/… – endolith Aug 11 at 0:06
-1

Assume a dataframe with 19 rows

index=range(0,19)
index

columns=['A']
test = pd.DataFrame(index=index, columns=columns)

Keeping Column A as a constant

test['A']=10

Keeping column b as a variable given by a loop

for x in range(0,19):
    test.loc[[x], 'b'] = pd.Series([x], index = [x])

You can replace the first x in pd.Series([x], index = [x]) with any value

protected by cs95 May 17 '18 at 7:29

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