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I am trying to speed up the sum for several big multilevel dataframes.

Here is a sample:

df1 = mul_df(5000,30,400) # mul_df to create a big multilevel dataframe
#let df2, df3, df4 = df1, df1, df1 to minimize the memory usage, 
#they can also be mul_df(5000,30,400) 
df2, df3, df4 = df1, df1, df1

In [12]: timeit df1+df2+df3+df4
1 loops, best of 3: 993 ms per loop

I am not satisfy with the 993ms, Is there any way to speed up ? Can cython improve the performance ? If yes, how to write the cython code ? Thanks.

Note: mul_df() is the function to create the demo multilevel dataframe.

import itertools
import numpy as np
import pandas as pd

def mul_df(level1_rownum, level2_rownum, col_num, data_ty='float32'):
    ''' create multilevel dataframe, for example: mul_df(4,2,6)'''

    index_name = ['STK_ID','RPT_Date']
    col_name = ['COL'+str(x).zfill(3) for x in range(col_num)]

    first_level_dt = [['A'+str(x).zfill(4)]*level2_rownum for x in range(level1_rownum)]
    first_level_dt = list(itertools.chain(*first_level_dt)) #flatten the list
    second_level_dt = ['B'+str(x).zfill(3) for x in range(level2_rownum)]*level1_rownum

    dt = pd.DataFrame(np.random.randn(level1_rownum*level2_rownum, col_num), columns=col_name, dtype = data_ty)
    dt[index_name[0]] = first_level_dt
    dt[index_name[1]] = second_level_dt

    rst = dt.set_index(index_name, drop=True, inplace=False)
    return rst


Data on my Pentium Dual-Core T4200@2.00GHZ, 3.00GB RAM, WindowXP, Python 2.7.4, Numpy 1.7.1, Pandas 0.11.0, numexpr 2.0.1 (Anaconda 1.5.0 (32-bit))

In [1]: from pandas.core import expressions as expr
In [2]: import numexpr as ne

In [3]: df1 = mul_df(5000,30,400)
In [4]: df2, df3, df4 = df1, df1, df1

In [5]: expr.set_use_numexpr(False)
In [6]: %timeit df1+df2+df3+df4
1 loops, best of 3: 1.06 s per loop

In [7]: expr.set_use_numexpr(True)
In [8]: %timeit df1+df2+df3+df4
1 loops, best of 3: 986 ms per loop

In [9]: %timeit  DataFrame(ne.evaluate('df1+df2+df3+df4'),columns=df1.columns,index=df1.index,dtype='float32')
1 loops, best of 3: 388 ms per loop
share|improve this question
up vote 9 down vote accepted

method 1: On my machine not so bad (with numexpr disabled)

In [41]: from pandas.core import expressions as expr

In [42]: expr.set_use_numexpr(False)

In [43]: %timeit df1+df2+df3+df4
1 loops, best of 3: 349 ms per loop

method 2: Using numexpr (which is by default enabled if numexpr is installed)

In [44]: expr.set_use_numexpr(True)

In [45]: %timeit df1+df2+df3+df4
10 loops, best of 3: 173 ms per loop

method 3: Direct use of numexpr

In [34]: import numexpr as ne

In [46]: %timeit  DataFrame(ne.evaluate('df1+df2+df3+df4'),columns=df1.columns,index=df1.index,dtype='float32')
10 loops, best of 3: 47.7 ms per loop

These speedups are achieved using numexpr because:

  • avoids using intermediate temporary arrays (which in the case you are presenting is probably quite inefficient in numpy, I suspect this is being evaluated like ((df1+df2)+df3)+df4
  • uses multi-cores as available

As I hinted above, pandas uses numexpr under the hood for certain types of ops (in 0.11), e.g. df1 + df2 would be evaluated this way, however the example you are giving here will result in several calls to numexpr (this is method 2 is faster than method 1.). Using the direct (method 3) ne.evaluate(...) achieves even more speedups.

Note that in pandas 0.13 (0.12 will be released this week), we are implemented a function pd.eval which will in effect do exactly what my example above does. Stay tuned (if you are adventurous this will be in master somewhat soon: https://github.com/pydata/pandas/pull/4037)

In [5]: %timeit pd.eval('df1+df2+df3+df4')
10 loops, best of 3: 50.9 ms per loop

Lastly to answer your question, cython will not help here at all; numexpr is quite efficient at this type of problem (that said, there are situation where cython is helpful)

One caveat: in order to use the direct Numexpr method the frames should be already aligned (Numexpr operates on the numpy array and doesn't know anything about the indices). also they should be a single dtype

share|improve this answer
@bigbug Take the leap and try eval! It does alignment for you. Currently the dtype must at least be numeric, the caveat there is that mixed numeric dtype frames will be slower, especially large ones since a new array must be allocated to hold the promoted, concatenated array, but they should still be faster than using direct numexpr and plain ol' Python. – Phillip Cloud Jul 1 '13 at 0:48
@Jeff, Thanks for the tips. I test your methods on my machine (An old machine which I bought 4yrs ago), and the data is posted on the 'Update' section. The performance variance of turn on/off set_use_numexpr() is not much, while direcly ne.evaluate('df1+df2+df3+df4') did give 2.5X improvement. – bigbug Jul 1 '13 at 4:35
@cpcloud. I will try eval() after I figure out how to import the eval function. Thanks. – bigbug Jul 1 '13 at 4:36
@Jeff, if df2, df3, df4 is not same as df1, then DataFrame(ne.evaluate('df1+df2+df3+df4'),columns=df1.columns,index=df1.index,dty‌​pe='float32') will not boost the speed that much. I suppose it is due to the cache . – bigbug Jul 1 '13 at 10:09
@bigbug looking at your config, you are running 32-bit and have a small amount of memory. I bet you are swapping. – Jeff Jul 1 '13 at 11:09

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