I was looking at the source of sorted_containers and was surprised to see this line:

self._load, self._twice, self._half = load, load * 2, load >> 1

Here load is an integer. Why use bit shift in one place, and multiplication in another? It seems reasonable that bit shifting may be faster than integral division by 2, but why not replace the multiplication by a shift as well? I benchmarked the the following cases:

  1. (times, divide)
  2. (shift, shift)
  3. (times, shift)
  4. (shift, divide)

and found that #3 is consistently faster than other alternatives:

# self._load, self._twice, self._half = load, load * 2, load >> 1

import random
import timeit
import pandas as pd

x = random.randint(10 ** 3, 10 ** 6)

def test_naive():
    a, b, c = x, 2 * x, x // 2

def test_shift():
    a, b, c = x, x << 1, x >> 1    

def test_mixed():
    a, b, c = x, x * 2, x >> 1    

def test_mixed_swapped():
    a, b, c = x, x << 1, x // 2

def observe(k):
    return {
        'naive': timeit.timeit(test_naive),
        'shift': timeit.timeit(test_shift),
        'mixed': timeit.timeit(test_mixed),
        'mixed_swapped': timeit.timeit(test_mixed_swapped),

def get_observations():
    return pd.DataFrame([observe(k) for k in range(100)])

enter image description here enter image description here

The question:

Is my test valid? If so, why is (multiply, shift) faster than (shift, shift)?

I run Python 3.5 on Ubuntu 14.04.


Above is the original statement of the question. Dan Getz provides an excellent explanation in his answer.

For the sake of completeness, here are sample illustrations for larger x when multiplication optimizations do not apply.

enter image description here enter image description here

  • 3
    Where did you define x?
    – JBernardo
    May 5, 2016 at 14:42
  • 3
    I would really like to see if there is any difference using little endian/big endian. Really cool question btw !
    – LiGhTx117
    May 5, 2016 at 14:45
  • 1
    @LiGhTx117 I'd expect that to be unrelated to the operations, unless x is very large, because that's just a question of how it's stored in memory, right?
    – Dan Getz
    May 5, 2016 at 14:47
  • 2
    I'm curious, what about multiplying by 0.5 instead of dividing by 2? From previous experience with mips assembly programming, division normally results in a multiplication operation anyway. (That would explain the preference of bit shifting instead of division)
    – Sayse
    May 5, 2016 at 14:58
  • 4
    @Sayse that would convert it to floating point. Hopefully integer floor division would be quicker than a round trip through floating point.
    – Dan Getz
    May 5, 2016 at 15:05

1 Answer 1


This seems to be because multiplication of small numbers is optimized in CPython 3.5, in a way that left shifts by small numbers are not. Positive left shifts always create a larger integer object to store the result, as part of the calculation, while for multiplications of the sort you used in your test, a special optimization avoids this and creates an integer object of the correct size. This can be seen in the source code of Python's integer implementation.

Because integers in Python are arbitrary-precision, they are stored as arrays of integer "digits", with a limit on the number of bits per integer digit. So in the general case, operations involving integers are not single operations, but instead need to handle the case of multiple "digits". In pyport.h, this bit limit is defined as 30 bits on 64-bit platform, or 15 bits otherwise. (I'll just call this 30 from here on to keep the explanation simple. But note that if you were using Python compiled for 32-bit, your benchmark's result would depend on if x were less than 32,768 or not.)

When an operation's inputs and outputs stay within this 30-bit limit, the operation can be handled in an optimized way instead of the general way. The beginning of the integer multiplication implementation is as follows:

static PyObject *
long_mul(PyLongObject *a, PyLongObject *b)
    PyLongObject *z;

    CHECK_BINOP(a, b);

    /* fast path for single-digit multiplication */
    if (Py_ABS(Py_SIZE(a)) <= 1 && Py_ABS(Py_SIZE(b)) <= 1) {
        stwodigits v = (stwodigits)(MEDIUM_VALUE(a)) * MEDIUM_VALUE(b);
        return PyLong_FromLongLong((PY_LONG_LONG)v);
        /* if we don't have long long then we're almost certainly
           using 15-bit digits, so v will fit in a long.  In the
           unlikely event that we're using 30-bit digits on a platform
           without long long, a large v will just cause us to fall
           through to the general multiplication code below. */
        if (v >= LONG_MIN && v <= LONG_MAX)
            return PyLong_FromLong((long)v);

So when multiplying two integers where each fits in a 30-bit digit, this is done as a direct multiplication by the CPython interpreter, instead of working with the integers as arrays. (MEDIUM_VALUE() called on a positive integer object simply gets its first 30-bit digit.) If the result fits in a single 30-bit digit, PyLong_FromLongLong() will notice this in a relatively small number of operations, and create a single-digit integer object to store it.

In contrast, left shifts are not optimized this way, and every left shift deals with the integer being shifted as an array. In particular, if you look at the source code for long_lshift(), in the case of a small but positive left shift, a 2-digit integer object is always created, if only to have its length truncated to 1 later: (my comments in /*** ***/)

static PyObject *
long_lshift(PyObject *v, PyObject *w)
    /*** ... ***/

    wordshift = shiftby / PyLong_SHIFT;   /*** zero for small w ***/
    remshift  = shiftby - wordshift * PyLong_SHIFT;   /*** w for small w ***/

    oldsize = Py_ABS(Py_SIZE(a));   /*** 1 for small v > 0 ***/
    newsize = oldsize + wordshift;
    if (remshift)
        ++newsize;   /*** here newsize becomes at least 2 for w > 0, v > 0 ***/
    z = _PyLong_New(newsize);

    /*** ... ***/

Integer division

You didn't ask about the worse performance of integer floor division compared to right shifts, because that fit your (and my) expectations. But dividing a small positive number by another small positive number is not as optimized as small multiplications, either. Every // computes both the quotient and the remainder using the function long_divrem(). This remainder is computed for a small divisor with a multiplication, and is stored in a newly-allocated integer object, which in this situation is immediately discarded.

Or at least, that was the case when this question was originally asked. In CPython 3.6, a fast path for small int // was added, so // now beats >> for small ints too.

  • 2
    It is an interesting observation with the division, thanks for pointing it out. It goes without saying that this is an excellent answer overall. May 6, 2016 at 20:09
  • 2
    A well-researched adn written answer to an excellent question. It might be interesting to show graphs for the timing for x outside the optimized range.
    – Barmar
    May 10, 2016 at 18:36

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