44

I have a function which processes a DataFrame, largely to process data into buckets create a binary matrix of features in a particular column using pd.get_dummies(df[col]).

To avoid processing all of my data using this function at once (which goes out of memory and causes iPython to crash), I have broken the large DataFrame into chunks using:

chunks = (len(df) / 10000) + 1
df_list = np.array_split(df, chunks)

pd.get_dummies(df) will automatically create new columns based on the contents of df[col] and these are likely to differ for each df in df_list.

After processing, I am concatenating the DataFrames back together using:

for i, df_chunk in enumerate(df_list):
    print "chunk", i
    [x, y] = preprocess_data(df_chunk)
    super_x = pd.concat([super_x, x], axis=0)
    super_y = pd.concat([super_y, y], axis=0)
    print datetime.datetime.utcnow()

The processing time of the first chunk is perfectly acceptable, however, it grows per chunk! This is not to do with the preprocess_data(df_chunk) as there is no reason for it to increase. Is this increase in time occurring as a result of the call to pd.concat()?

Please see log below:

chunks 6
chunk 0
2016-04-08 00:22:17.728849
chunk 1
2016-04-08 00:22:42.387693 
chunk 2
2016-04-08 00:23:43.124381
chunk 3
2016-04-08 00:25:30.249369
chunk 4
2016-04-08 00:28:11.922305
chunk 5
2016-04-08 00:32:00.357365

Is there a workaround to speed this up? I have 2900 chunks to process so any help is appreciated!

Open to any other suggestions in Python!

73

Never call DataFrame.append or pd.concat inside a for-loop. It leads to quadratic copying.

pd.concat returns a new DataFrame. Space has to be allocated for the new DataFrame, and data from the old DataFrames have to be copied into the new DataFrame. Consider the amount of copying required by this line inside the for-loop (assuming each x has size 1):

super_x = pd.concat([super_x, x], axis=0)

| iteration | size of old super_x | size of x | copying required |
|         0 |                   0 |         1 |                1 |
|         1 |                   1 |         1 |                2 |
|         2 |                   2 |         1 |                3 |
|       ... |                     |           |                  |
|       N-1 |                 N-1 |         1 |                N |

1 + 2 + 3 + ... + N = N(N+1)/2. So there is O(N**2) copies required to complete the loop.

Now consider

super_x = []
for i, df_chunk in enumerate(df_list):
    [x, y] = preprocess_data(df_chunk)
    super_x.append(x)
super_x = pd.concat(super_x, axis=0)

Appending to a list is an O(1) operation and does not require copying. Now there is a single call to pd.concat after the loop is done. This call to pd.concat requires N copies to be made, since super_x contains N DataFrames of size 1. So when constructed this way, super_x requires O(N) copies.

| improve this answer | |
  • 1
    Hi @unutbu, thanks for the detailed explanation, this really explained the theory in detail! – jfive Apr 8 '16 at 1:00
  • Is it feasible to concatenate 2900 blocks of this shape, this way (43717, 3261)? The processing step now only takes 10 seconds. – jfive Apr 8 '16 at 1:05
  • if using concat in a loop, wouldn't deleting the old dataframes in the loop resolve the issue? – SantoshGupta7 Jun 7 '19 at 2:21
  • 3
    @SantoshGupta7: The issue is about speed, not memory. The peak memory usage is about the same either way. Copying can be a slow operation when the dataframe is large and/or the loop is performed many times. Making O(n^2) copies is unnecessarily slow, since there is an O(n) alternative -- append to a list, concat once after the loop. – unutbu Jun 7 '19 at 11:59
  • 2
    Applying your solution to my program with more than 1.5 M data records resulted in execution time going from 60+ hours to under 1h! And I even understand why...! :-) Thanks! – Pryderide Feb 5 at 10:41
8

Every time you concatenate, you are returning a copy of the data.

You want to keep a list of your chunks, and then concatenate everything as the final step.

df_x = []
df_y = []
for i, df_chunk in enumerate(df_list):
    print "chunk", i
    [x, y] = preprocess_data(df_chunk)
    df_x.append(x)
    df_y.append(y)

super_x = pd.concat(df_x, axis=0)
del df_x  # Free-up memory.
super_y = pd.concat(df_y, axis=0)
del df_y  # Free-up memory.
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