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I'm optimizing some code whose main bottleneck is running through and accessing a very large list of struct-like objects. Currently I'm using namedtuples, for readability. But some quick benchmarking using 'timeit' shows that this is really the wrong way to go where performance is a factor:

Named tuple with a, b, c:

>>> timeit("z = a.c", "from __main__ import a")

Class using __slots__, with a, b, c:

>>> timeit("z = b.c", "from __main__ import b")

Dictionary with keys a, b, c:

>>> timeit("z = c['c']", "from __main__ import c")

Tuple with three values, using a constant key:

>>> timeit("z = d[2]", "from __main__ import d")

List with three values, using a constant key:

>>> timeit("z = e[2]", "from __main__ import e")

Tuple with three values, using a local key:

>>> timeit("z = d[key]", "from __main__ import d, key")

List with three values, using a local key:

>>> timeit("z = e[key]", "from __main__ import e, key")

First of all, is there anything about these little timeit tests that would render them invalid? I ran each several times, to make sure no random system event had thrown them off, and the results were almost identical.

It would appear that dictionaries offer the best balance between performance and readability, with classes coming in second. This is unfortunate, since, for my purposes, I also need the object to be sequence-like; hence my choice of namedtuple.

Lists are substantially faster, but constant keys are unmaintainable; I'd have to create a bunch of index-constants, i.e. KEY_1 = 1, KEY_2 = 2, etc. which is also not ideal.

Am I stuck with these choices, or is there an alternative that I've missed?

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If performance is such a priority, why not use C? – Skilldrick Apr 15 '10 at 14:31
@Skilldrick: This is only a small part of a larger program, which benefits from being written in Python. Rewriting this part as a C-extension is an option, but somewhat undesirable, since other code touches the data as well, complicating things a bit. Performance is important, but not that crucial; I'd be quite happy with the 4x improvement offered by lists, if not for the reduced maintainability. I'm just looking for other options before I decide which way to go. – DNS Apr 15 '10 at 14:46
@Warren P: Yes; I'm not prematurely optimizing. This is a very tight loop in which simply accessing the structures is a significant fraction of the work. It's the slowest remaining loop in the program. Even a modest improvement could cut a second or two off the real-world run-time. Since the whole thing is repeated, that adds up. – DNS Apr 15 '10 at 15:01
Also consider trying pypy. With pypy I didn't get any differences in performance between the cases. – Thomas Ahle Feb 9 '14 at 23:05
numpy has some sort of structs, and can give better performance than C in some cases. I haven't tried this and YMMV! – Sam Watkins Sep 26 '14 at 4:42

5 Answers 5

up vote 21 down vote accepted

One thing to bear in mind is that namedtuples are optimised for access as tuples. If you change your accessor to be a[2] instead of a.c, you'll see similar performance to the tuples. The reason is that the name accessors are effectively translating into calls to self[idx], so pay both the indexing and the name lookup price.

If your usage pattern is such that access by name is common, but access as tuple isn't, you could write a quick equivalent to namedtuple that does things the opposite way: defers index lookups to access by-name. However, you'll pay the price on the index lookups then. Eg here's a quick implementation:

def makestruct(name, fields):
    fields = fields.split()
    import textwrap
    template = textwrap.dedent("""\
    class {name}(object):
        __slots__ = {fields!r}
        def __init__(self, {args}):
            {self_fields} = {args}
        def __getitem__(self, idx): 
            return getattr(self, fields[idx])
        self_fields=','.join('self.' + f for f in fields))
    d = {'fields': fields}
    exec template in d
    return d[name]

But the timings are very bad when __getitem__ must be called:

namedtuple.a  :  0.473686933517 
namedtuple[0] :  0.180409193039
struct.a      :  0.180846214294
struct[0]     :  1.32191514969

ie, the same performance as a __slots__ class for attribute access (unsurprisingly - that's what it is), but huge penalties due to the double lookup in index-based accesses. (Noteworthy is that __slots__ doesn't actually help much speed-wise. It saves memory, but the access time is about the same without them.)

One third option would be to duplicate the data, eg. subclass from list and store the values both in the attributes and listdata. However you don't actually get list-equivalent performance. There's a big speed hit just in having subclassed (bringing in checks for pure-python overloads). Thus struct[0] still takes around 0.5s (compared with 0.18 for raw list) in this case, and you do double the memory usage, so this may not be worth it.

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Careful with this recipe where fields could have user-input data -- the exec on fields could run arbitrary code. Otherwise super cool. – Michael Scott Cuthbert Aug 2 at 17:57

This question is fairly old (internet-time), so I thought I'd try duplicating your test today, both with regular CPython (2.7.6), and with pypy (2.2.1) and see how the various methods compared. (I also added in an indexed lookup for the named tuple.)

This is a bit of a micro-benchmark, so YMMV, but pypy seemed to speed up named tuple access by a factor of 30 vs CPython (whereas dictionary access was only sped up by a factor of 3).

from collections import namedtuple

STest = namedtuple("TEST", "a b c")
a = STest(a=1,b=2,c=3)

class Test(object):
    __slots__ = ["a","b","c"]


b = Test()

c = {'a':1, 'b':2, 'c':3}

d = (1,2,3)
e = [1,2,3]
f = (1,2,3)
g = [1,2,3]
key = 2

if __name__ == '__main__':
    from timeit import timeit

    print("Named tuple with a, b, c:")
    print(timeit("z = a.c", "from __main__ import a"))

    print("Named tuple, using index:")
    print(timeit("z = a[2]", "from __main__ import a"))

    print("Class using __slots__, with a, b, c:")
    print(timeit("z = b.c", "from __main__ import b"))

    print("Dictionary with keys a, b, c:")
    print(timeit("z = c['c']", "from __main__ import c"))

    print("Tuple with three values, using a constant key:")    
    print(timeit("z = d[2]", "from __main__ import d"))

    print("List with three values, using a constant key:")
    print(timeit("z = e[2]", "from __main__ import e"))

    print("Tuple with three values, using a local key:")
    print(timeit("z = d[key]", "from __main__ import d, key"))

    print("List with three values, using a local key:")
    print(timeit("z = e[key]", "from __main__ import e, key"))

Python Results:

Named tuple with a, b, c:
Named tuple, using index:
Class using __slots__, with a, b, c:
Dictionary with keys a, b, c:
Tuple with three values, using a constant key:
List with three values, using a constant key:
Tuple with three values, using a local key:
List with three values, using a local key:

PyPy Results:

Named tuple with a, b, c:
Named tuple, using index:
Class using __slots__, with a, b, c:
Dictionary with keys a, b, c:
Tuple with three values, using a constant key:
List with three values, using a constant key:
Tuple with three values, using a local key:
List with three values, using a local key:
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A couple points and ideas:

1) You're timing accessing the same index many times in a row. Your actual program probably uses random or linear access, which will have different behavior. In particular, there will be more CPU cache misses. You might get slightly different results using your actual program.

2) OrderedDictionary is written as a wrapper around dict, ergo it will be slower than dict. That's a non-solution.

3) Have you tried both new-style and old-style classes? (new-style classes inherit from object; old-style classes do not)

4) Have you tried using psyco or Unladen Swallow?

5) Does your inner loop to modify the data or just access it? It might be possible to transform the data into the most efficient possible form before entering the loop, but use the most convenient form elsewhere in the program.

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I would be tempted to either (a) invent some kind of workload specific caching, and offload the storage and retrieval of my data to a memcachedb-like process, to improve scalability rather than performance alone or (b) rewrite as a C extension, with native data storage. An ordered-dictionary type perhaps.

You could start with this:

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You can make your classes sequence like by adding __iter__, and __getitem__ methods, to make them sequence like (indexable and iterable.)

Would an OrderedDict work? There are several implementations available, and it is included in the Python31 collections module.

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