It seems that loading data from a CSV is faster than from SQL (Postgre SQL) with Pandas. (I have a SSD)

Here is my test code :

import pandas as pd
import numpy as np

start = time.time()
df = pd.read_csv('foo.csv')
df *= 3
duration = time.time() - start

engine = create_engine('postgresql://user:password@host:port/schema')
start = time.time()
df = pd.read_sql_query("select * from mytable", engine)
df *= 3
duration = time.time() - start

The foo.csv and the database are the same (same amount of data and columns in both, 4 columns, 100 000 rows full of random int).

CSV takes 0.05s

SQL takes 0.5s

Do you think it's normal that CSV is 10 time faster than SQL ? I'm wondering if I'm missing something here...

  • yes. normal.... – Steven G May 9 '17 at 16:11
  • Ok thanks, I really though SQL was faster – Haelle May 9 '17 at 16:17

This is a normal behavior, reading a csv file is always one of the quickest way to simply load data

A CSV is very naive and simple. loading directly from it will be very quick. For massive database with complex structure CSV is not an option. SQL is super fast to select data from table an return that data to you. naturally, if you can select, modify and manipulate data it will add an overhead time cost to your call.

imagine that you have a time series in a csv from 1920 to 2017 in a csv but you only want data from 2010 to today.

csv approach would be to load the entire csv then select the years 2010 to 2017.

SQL approach would be to pre-select the years via SQL select function

In that scenario, SQL would be MUCH faster.

  • 1
    Could you please elaborate a bit on this? Why loading a CSV faster than getting the data out of a relational database? – Vame May 10 '17 at 11:51
  • @Vame a CSV is very naive and simple. loading directly from it is super quick. you cant really select only certain rows of a csv when you load it. For massive database with complex strucutre CSV is not an option. SQL is super fast to select data from table an return that data to you. naturally, if you can select, modify and manipulate data this will add an overhead time cost to your call. example in answer – Steven G May 10 '17 at 12:12
  • @StevenG Haelle is using Pandas which can do quite a lot with this type of query. The call would be df[(df.year>=2010) & (df.year<=2017)] I would like to see a timing comparison between these two. Take into considerations of "is it loaded in RAM to start". – Back2Basics Sep 26 '17 at 6:18

When working with a PostgreSQL database, you can use a combination of SQL and CSV to get the best from both methods. SQL to select exactly the data you need and CSV output to quickly load it into a pandas DataFrame.

conn = psycopg2.connect(**conn_params)
with conn.cursor() as cur:
    sql = 'SELECT * FROM large_table'
    buf = io.StringIO()
    cur.copy_expert(f'COPY ({sql}) TO STDOUT WITH CSV HEADER', buf)
    df = pd.read_csv(buf, header=0, low_memory=False,
                     true_values='t', false_values='f')

This uses PostgreSQL's fast COPY command in combination with psycopg2's copy_expert() function to read query results into a string buffer in CSV format. You can then use pandas read_csv() on that string buffer.

The drawback is that you may have to convert data types afterwards (e.g. timestamps would be strings). The read_csv() function has a few parameters that can help deal with that (e.g. parse_dates, true_values, false_values, ...).

In my use case (30 million rows, 15 columns) this gave me a performance improvement of about 2-3x compared to the pandas read_sql() function.


While Steven G's explanation of the process is fundamentally the answer to your question, and Simon G's COPY solution is the most efficient one I've been able to find, I decided to look into your question in more depth, and actually measure the different aspects relevant to it.

At https://git.mikael.io/mikaelhg/pandas-pg-csv-speed-poc there is a project which contains pytest benchmarks for the various alternative solutions.

The CSV for this test is a order of magnitude larger than in the question, with the shape of (3742616, 6). Just to make sure that there is less of a chance for various buffers being just the right size to skew the results.

Thanks to the Finnish Traffic Safety Bureau Trafi's open data initiative for providing the test data.

As for the PostgreSQL installation, it's inside the canonical Docker container, and was started with upped shared_buffers and work_mem values, with the data files stored under the host machine's /dev/shm mount point, in order to negate actual disk I/O. Its UNIX socket connection point is also similarly exposed.

version: '3'


    image: 'postgres:10-alpine'
    command: "postgres -c 'shared_buffers=512MB' -c 'temp_buffers=80MB' -c 'work_mem=256MB'"
      - '5432:5432'
      - '/dev/shm/pgtest/data:/var/lib/postgresql/data'
      - '/dev/shm/pgtest/run:/var/run/postgresql'
      POSTGRES_USER: test
      POSTGRES_DB: test

    image: pandas_speed_poc:temp
      context: .
      dockerfile: Dockerfile.test-runner
      - '.:/app'
      - '/dev/shm/pgtest/run:/var/run/postgresql'
    working_dir: '/app'
    user: '1000'

The test runner is a simple Ubuntu 18.04 container:

FROM ubuntu:18.04
ENV DEBIAN_FRONTEND noninteractive
RUN apt-get -qq update && \
    apt-get -y -qq install python3-dev python3-pip python3-psycopg2 \
                    build-essential \
                    bash less nano wait-for-it
RUN pip3 install sqlalchemy numpy pandas \
                pytest pytest-benchmark
CMD wait-for-it db:5432 -- /bin/bash -c "trap : TERM INT; sleep infinity & wait"

The actual benchmark is a Python 3 unittest written for pytest-benchmark:


from sqlalchemy import create_engine
import psycopg2
import psycopg2.extensions

import pandas as pd
import numpy as np

import io
import time
import gzip

import unittest
import pytest

DATA_FILE = 'data/licenses.csv.gz'


    CREATE TABLE licenses (
        a VARCHAR(16),
        b CHAR(3),
        c CHAR(6),
        d INTEGER,
        e INTEGER,
        f INTEGER

    COPY licenses (a, b, c, d, e, f) FROM STDIN




DB_UNIX_SOCKET_URL = 'postgresql://test:test@/test'

DB_TCP_URL = 'postgresql://test:test@db/test'

def my_cursor_factory(*args, **kwargs):
    cursor = psycopg2.extensions.cursor(*args, **kwargs)
    cursor.itersize = 10240
    return cursor

class TestImportDataSpeed(unittest.TestCase):

    def setupBenchmark(self, benchmark):
        self.benchmark = benchmark

    def setUpClass(cls):
        cls.engine = create_engine(DB_TCP_URL, connect_args={'cursor_factory': my_cursor_factory})
        connection = cls.engine.connect().connection
        cursor = connection.cursor()


        with gzip.open(DATA_FILE, 'rb') as f:
            cursor.copy_expert(COPY_FROM, file=f, size=1048576)




    def test_pd_csv(self):

        def result():
            return pd.read_csv(DATA_FILE, delimiter=';', low_memory=False)

        df = self.benchmark(result)
        assert df.shape == (3742616, 6)

    def test_psycopg2_cursor(self):

        def result():
            connection = self.engine.connect().connection
            cursor = connection.cursor()
            cursor.itersize = 102400
            cursor.arraysize = 102400
            rows = cursor.fetchall()
            return pd.DataFrame(rows)

        df = self.benchmark(result)
        assert df.shape == (3742616, 6)

    def test_pd_sqla_naive(self):

        def result():
            return pd.read_sql_query(SELECT_FROM, self.engine)

        df = self.benchmark(result)
        assert df.shape == (3742616, 6)

    def test_pd_sqla_chunked(self):

        def result():
            gen = (x for x in pd.read_sql(SELECT_FROM, self.engine, chunksize=10240))
            return pd.concat(gen, ignore_index=True)

        df = self.benchmark(result)
        assert df.shape == (3742616, 6)

    def test_pg_copy(self):
        connection = self.engine.connect().connection
        cursor = connection.cursor()

        def result(cursor):
            f = io.StringIO()
            cursor.copy_expert(COPY_TO, file=f, size=1048576)
            return pd.read_csv(f, low_memory=False)

        df = self.benchmark(result, cursor)
        assert df.shape == (3742616, 6)

The final results:

speed_test.py .....

-------------------------------------------------------------------------------- benchmark: 5 tests -------------------------------------------------------------------------------
Name (time in s)            Min               Max              Mean            StdDev            Median               IQR            Outliers     OPS            Rounds  Iterations
test_pd_csv              1.4623 (1.0)      1.4903 (1.0)      1.4776 (1.0)      0.0110 (1.21)     1.4786 (1.0)      0.0171 (1.15)          2;0  0.6768 (1.0)           5           1
test_pg_copy             3.0631 (2.09)     3.0842 (2.07)     3.0732 (2.08)     0.0091 (1.0)      3.0769 (2.08)     0.0149 (1.0)           2;0  0.3254 (0.48)          5           1
test_psycopg2_cursor     4.5325 (3.10)     4.5724 (3.07)     4.5531 (3.08)     0.0161 (1.77)     4.5481 (3.08)     0.0249 (1.68)          2;0  0.2196 (0.32)          5           1
test_pd_sqla_naive       6.0177 (4.12)     6.0523 (4.06)     6.0369 (4.09)     0.0147 (1.62)     6.0332 (4.08)     0.0242 (1.63)          2;0  0.1656 (0.24)          5           1
test_pd_sqla_chunked     6.0247 (4.12)     6.1454 (4.12)     6.0889 (4.12)     0.0442 (4.86)     6.0963 (4.12)     0.0524 (3.52)          2;0  0.1642 (0.24)          5           1

Your results will vary! Run the tests on your own architecture for relevant results.


It's perfectly normal that CSV is much faster than SQL, but they are not meant for the same thing, even though you can use them for the same thing :

  1. CSV is for sequential access, ie, you start at the beginning of the file and you read each row one after the other, treating it as needed.

  2. SQL is for indexed access, ie, you look at an index and then you go to the row you're looking for. You can also perform a full table scan, ie not make use of any index, which makes the table essentially a bloated CSV.

Your query is a full table scan, it doesn't look at the index, because it goes for ALL the data, so yes, it's normal.

On the other hand, if you try a query like

select * from mytable where myindex = "myvalue";

You'll get a HUGE boost compared to searching for the same rows in the csv. That's because of the indexes in SQL

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