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SQLite vs Pandas: Performance Benchmarks

This technical article was written for The Data Incubator by Paul Paczuski, a Fellow of our 2016 Spring cohort in New York City who landed a job with our hiring partner, Genentech as a Clinical Data Scientist.

As a data scientist, we all know that unglamorous data manipulation is 90% of the work. Two of the most common data manipulation tools are SQL and pandas. In this blog, we’ll compare the performance of pandas and SQLite, a simple form of SQL favored by Data Scientists.

Let’s find out the tasks at which each of these excel. Below, we compare Python’s pandas to sqlite for some common data analysis operations: sort, select, load, join, filter, and group by.

 


Note that the axis is logarithmic, so that raw differences are more pronounced.

 

Analysis details

For the analysis, we ran the six tasks 10 times each, for 5 different sample sizes, for each of 3 programs: pandassqlite, and memory-sqlite (where database is in memory instead of on disk). See below for the definitions of each task.

Our sample data was randomly generated. Here’s what it looks like:

sql_vs_pandas$ head -n 5 data/sample.100.csv

qqFjQHQc,c,1981,82405.59262172286
vILuhVGz,a,1908,27712.27152250119
mwCjpoOF,f,1992,58974.38538762843
kGbriYAK,d,1927,42258.24179716961
MeoxuJng,c,1955,96907.56416314292

This consists of a random string of 8 characters, a random single character (for the filtering operation), a random integer simulating a year (1900-2000), and a uniform random float value between 10000 and 100000.

 

Results

sqlite or memory-sqlite is faster for the following tasks:

  • select two columns from data (<.1 millisecond for any data size for sqlitepandas scales with the data, up to just under 0.5 seconds for 10 million records)
  • filter data (>10x-50x faster with sqlite. The difference is more pronounced as data grows in size)
  • sort by single column: pandas is always a bit slower, but this was the closest

pandas is faster for the following tasks:

  • groupby computation of a mean and sum (significantly better for large data, only 2x faster for <10k records)
  • load data from disk (5x faster for >10k records, even better for smaller data)
  • join data (2-5x faster, but slower for smallest dataset of 1000 rows)

Comparing memory-sqlite vs. sqlite, there was no meaningful difference, especially as data size increased.

There is no significant speedup from loading sqlite in its own shell vs. via pandas.

Overall, joining and loading data is the slowest whereas select and filter are generally the fastest. Further, pandas seems to be optimized for group-by operations, where it performs really well (group-by is pandas‘ second fastest operation for larger data).

Note that this analysis assumes you are equally proficient in writing code with both! But these results could encourage you to learn the tool that you are less familiar with, if the performance gains are significant.

 

Code

All code is on our GitHub page.

Below are the definitions of our six tasks: sort, select, load, join, filter, and group by (see driver/sqlite_driver.py or driver/pandas_driver.py).

sqlite is first, followed by pandas:

sort

def sort(self):
  self._cursor.execute('SELECT * FROM employee ORDER BY name ASC;')
  self._conn.commit()

def sort(self):
  self.df_employee.sort_values(by='name')

select

def select(self):
  self._cursor.execute('SELECT name, dept FROM employee;')
  self._conn.commit()

def select(self):
  self.df_employee[["name", "dept"]]

load

def load(self):
  self._cursor.execute('CREATE TABLE employee (name varchar(255), dept char(1), birth int, salary double);')
  df = pd.read_csv(self.employee_file)
  df.columns = employee_columns
  df.to_sql('employee', self._conn, if_exists='replace')

  self._cursor.execute('CREATE TABLE bonus (name varchar(255), bonus double);')
  df_bonus = pd.read_csv(self.bonus_file)
  df_bonus.columns = bonus_columns
  df_bonus.to_sql('bonus', self._conn, if_exists='replace')

def load(self):
  self.df_employee = pd.read_csv(self.employee_file)
  self.df_employee.columns = employee_columns

  self.df_bonus = pd.read_csv(self.bonus_file)
  self.df_bonus.columns = bonus_columns

join

def join(self):
  self._cursor.execute('SELECT employee.name, employee.salary + bonus.bonus '
                       'FROM employee INNER JOIN bonus ON employee.name = bonus.name')
  self._conn.commit()

def join(self):
  joined = self.df_employee.merge(self.df_bonus, on='name')
  joined['total'] = joined['bonus'] + joined['salary']

filter

def filter(self):
  self._cursor.execute('SELECT * FROM employee WHERE dept = "a";')
  self._conn.commit()

def filter(self):
  self.df_employee[self.df_employee['dept'] == 'a']

group by

def groupby(self):
  self._cursor.execute('SELECT avg(birth), sum(salary) FROM employee GROUP BY dept;')
  self._conn.commit()

def groupby(self):
  self.df_employee.groupby("dept").agg({'birth': np.mean, 'salary': np.sum})

 

Details

We used pandas version 0.19.1 and sqlite version 3.13.0. All tests were ran on Digital Ocean Ubuntu 14.04 with 16GB memory and 8 core CPU.

 

References

For resource on becoming a data scientist, check out our blog, particular this article on preparing for our free data science fellowship and this one on data manipulating data like a professional data scientist. And if you’re looking for a class, consider our convenient after-work online instructor lead data science foundations course geared towards working professionals or our free data scinece fellowship for people with advanced degrees.

To learn more how sqlite works, check out this awesome blog series.

Here is a syntax comparison between pandas and sql.

 

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