def find_values(ticker, event_time):
filename = ticker+'.csv'
df = pd.read_csv(filename, parse_dates=[0])
idx = df['Timestamp'].searchsorted(event_time, side='right')
price_1, price_2 = df['Price'].iloc[idx-1:idx+1]
df_later = df.iloc[idx:]
return price_1, price_2, df_later
For example, using the data you posted:
In [176]: p1, p2, df_later = find_values('ABC', pd.Timestamp('4:15:03'))
In [177]: p1, p2
Out[177]: (35.710000000000001, 37.369999999999997)
In [178]: df_later
Out[178]:
Timestamp Price
2 2015-01-19 04:15:05.184000 37.37
3 2015-01-19 05:36:25.240000 37.60
4 2015-01-19 05:44:40.678000 36.51
Parsing a csv can be expensive if the csv is large. Therefore, you do not want
to call pd.read_csv
more than once if you can help it. By extension, you
should not call find_values
more than once for each ticker. If you do need to
call find_values
more than once for the same ticker, thought needs to be put
into how the algorithm can be reworked so ideally pd.read_csv
can be called
only once. Caching the value returned by pd.read_csv
might be one way, or
collecting the event_times
into one call to find_values
might be another
way.
Now assuming you are already calling find_values
parsimoniously, let's move on to how we can improve it's speed.
You are right that using apply
here is also a potential bottleneck, since it is calling a Python function once for each row of the dataframe. Instead of parsing the time strings using to_timestamp
, you could instead use pd.read_csv
's built-in date string parsing ability:
df = pd.read_csv(filename, parse_dates=[0])
This will parse the 0-th indexed column as a date string. This will make
df['Timestamp']
a column with dtype datetime64[ns]
.
That's terrific, since it makes finding the index where event_time
(which I assume is the same thing as newstime
) fits into df['Timestamp']
very easy. Moreover, date calculations can in general be performed much faster on datetime64s than equivalent calculations done on Python datetime.datetime
objects.
To find the integer index where event_time
would fit use the searchsorted
method:
idx = df['Timestamp'].searchsorted(event_time)
idx
will be the integer index where event_time
would go if it were to be inserted into df['Timestamp']
while maintaining df['Timestamp']
's sortedness.
Next, note that using
df_earlier = df[df['Time']<=newstime]
is also expensive because it forms a (potentially large) dataframe just to pick off one value. Since df['Time']<=newstime
is a boolean mask, this new dataframe df[df['Time']<=newstime]
makes a copy of data from df
. That's a lot of unnecessary copying.
Instead, you could use
price_1, price_2 = df['Price'].iloc[idx-1:idx+1]
to pick off just the values you want without a lot of extra copying.
Finally, you could use
df_later = df.iloc[idx:]
to define df_later
. Since this uses basic slicing instead of a boolean mask, df_later
is a view of df
. This is faster to generate than df[df['Time']>event_time]
because there is no copying. But also beware that this means the underlying data in df_later
is the very same data underlying df
. As a consequence, modifying df_later
also modifies df
and vice versa. If you do not want df_later
to be a view, then use
df_later = df.iloc[idx:].copy()