I am taking data from a file that receives data from Interactive Brokers 5-second OHLCVT bars via Sierra Chart.
Following advice in earlier posts, rather than append each new row to the dataframe I construct a dataframe with the historical file and append 5000 "blank" records to it with correct timestamps. I then write each new row over a blank row, filling any rows if timestamps are missing and updating pointers.
This works well. Here's the current classes and functions. My initial version created 5000 lines of NaNs (OHLCVxyz). I thought it would be tidier to start with the end data types so converted the "blank" records to zeros with OHLC being floats and Vxyz being ints using:
dg.iloc[0:5000] = 0.0 dg[[v, x, y, z]] = dg[[v, x, y, z]].astype('int')
This only occurs once per additional 5000 lines (once a day for HSI). What surprised me was the impact on the read/write loops. They went from 0.8ms to 3.4ms per row. The only change was from NaNs to zeros.
This picture shows an inital run with a zero filled frame (see timestats 0.0038) then a run with a NaN filled frame (timestats 0.0008).
Can anyone provide insight on why it might add so much time to write to fields of [0.0, 0.0, 0.0, 0.0, 0, 0, 0, 0] instead of [NaN, NaN, NaN, NaN, NaN, NaN, NaN, NaN] ?
Any thoughts on code improvements are also welcome. :)
EDIT +17 hours
Following the questions from @BrenBarn I built a simpler model that could be run by anyone without data. In doing so I eliminated the question of whether the NaNs impact it. In this version I was able to write 0.0s to both versions and the difference was the same:
- the array that has 8 columns of floats is added to 10 times faster than the array that has 4 columns of floats and 4 of int64s.
- in each case the row being added was [1.0, 2.0, 3.0, 4.0, 5, 6, 7, 8]
- the add is done 10000 times with self.df.iloc[self.end] = datarow and increment end.
So, unless I'm mistaken (always possible) it seems that adding to a dataframe with 4 columns of floats and 4 of ints takes 10x as long. Is this an issue for pandas or just what one should expect?
I think that having an array of 350,000 rows of 8 columns before you add to it makes a significant difference. My initial tests adding to 10 rows showed no impact - I must go back and retest them.
EDIT +10 minutes
No I went back and created the intial array with only 10 rows and the impact on the add loops didn't change so its not the size of the original array/dataframe. Its probable that in my earlier test I thought I'd converted the columns to ints but I hadn't - checking this proved that the command I thought would do this didn't.
da = SierraFrame(range(10), np.zeros((10,8))) da.extend_frame1()
EDIT and Possible Answer +35 minutes
Should this question not be answered in more detail.
At this point, my hypothesis is that the underlying functionality to add [1.0, 2.0, 3.0, 4.0, 5, 6, 7, 8] to a spare line in the dataframe is different if the df comprises all one type than if it comprises columns of floats and ints. I just tested it with all int64s and the average add was 0.41ms vs 0.37ms for all floats and 2.8ms for a mixed dataframe. Int8s took 0.39ms. I guess that the mix affects pandas ability to optimize its action so if efficiency is very important then a dataframe with all columns being the same type (float64 probably) is the best bet.
Tests conducted on Linux x64 with Python 3.3.1