I started with the answer by @mgilson and reworked it a bit. I wanted to test the "decision bit" and lookup table techniques as discussed in my answer to the original question: http://stackoverflow.com/a/17782979/166949

I made a few changes to the original. Some were just style things that reflect my personal preference. However, I discovered bugs in the original, and I think it's important to measure the correct code.

I made the Python code now take arguments from the command line, and wrote a shell script that runs the Python script using Python 2.x, Python 3.x, and PyPy. The exact versions were: Python 2.7.6, Python 3.4.0, and PyPy 2.7.3

I ran the tests on Linux Mint 17, 64-bit version. The CPU is an AMD Phenom 9850 running at 2.5 GHz with 16 GB of RAM. The Linux kernel version, per `uname -r`

, is: 3.13.0-24-generic

The reason I made the code take arguments from the command line is that 327 is a pretty short list. I figured that the `sum()`

and generator expressions would do better when the list was much longer, so I made list size and number of trials be passed from the command line. The results shows which Python, and the list length and number of trials.

Conclusion: to my surprise, even with a long list, Python was fastest using `sum()`

with a list comprehension! There is some overhead to running a generator that seems to be slower than the overhead of building a list and then tearing it down.

However, if the list got truly large, I expected the generator would begin to out-perform the list comprehension. With a list of a million random values, the listcomp was still faster, but when I went to 16 million random values, the genexp became faster. And the speed penalty of the generator expression is not large for shorter lists. So I still favor the generator expression as the go-to way to solve this problem in Python.

Interestingly, PyPy was fastest with the table lookup. This makes sense: that was the fastest way I found in C, and PyPy is generating native code from the JIT.

For CPython, with its virtual machine, it is faster to invoke a single operation than several operations; the overhead of the Python VM can outweigh a more expensive fundamental operation. Thus integer division is faster than bit masking plus bit shifting, because the division is a single operation. But in PyPy, the bit masking+shifting is much faster than the division.

Also, in CPython, using `sum()`

lets your code run in the C internals so it can be very fast; but in PyPy, `sum()`

is slower than just writing a straighforward loop that the JIT can turn into a wicked fast native loop. My guess is that the generator machinery is hard for PyPy to grok and optimize away into native code.

The shell script:

```
for P in python python3 pypy; do
echo "$P ($1, $2)"
$P test_branches.py $1 $2
echo
done
```

The Python code:

```
import random
import sys
import timeit
try:
RANGE = xrange
except NameError:
RANGE = range
if len(sys.argv) != 3:
print("Usage: python test_branches.py <length_of_array> <number_of_trials>")
sys.exit(1)
TEST_DATA_LEN = int(sys.argv[1])
NUM_REPEATS = int(sys.argv[2])
_test_data = [random.randint(0,255) for _ in RANGE(TEST_DATA_LEN)]
def test0(data):
"""original way"""
total = 0
for i in RANGE(TEST_DATA_LEN):
if data[i] >= 128:
total += data[i]
return total
def test1(data):
"""better loop"""
total = 0
for n in data:
if n >= 128:
total += n
return total
def test2(data):
"""sum + generator"""
return sum(n for n in data if n >= 128)
def test3(data):
"""sum + listcomp"""
return sum([n for n in data if n >= 128])
def test4(data):
"""decision bit -- bit mask and shift"""
lst = [0, 0]
for n in data:
lst[(n & 0x80) >> 7] += n
return lst[1]
def test5(data):
"""decision bit -- division"""
lst = [0, 0]
for n in data:
lst[n // 128] += n
return lst[1]
_lut = [0 if n < 128 else n for n in RANGE(256)]
def test6(data):
"""lookup table"""
total = 0
for n in data:
total += _lut[n]
return total
def test7(data):
"""lookup table with sum()"""
return sum(_lut[n] for n in data)
test_functions = [v for k,v in globals().items() if k.startswith("test")]
test_functions.sort(key=lambda x: x.__name__)
correct = test0(_test_data)
for fn in test_functions:
name = fn.__name__
doc = fn.__doc__
if fn(_test_data) != correct:
print("{}() not correct!!!".format(name))
s_call = "{}(_test_data)".format(name)
s_import = "from __main__ import {},_test_data".format(name)
t = timeit.timeit(s_call,s_import,number=NUM_REPEATS)
print("{:7.03f}: {}".format(t, doc))
```

The results:

```
python (327, 100000)
3.170: original way
2.211: better loop
2.378: sum + generator
2.188: sum + listcomp
5.321: decision bit -- bit mask and shift
4.977: decision bit -- division
2.937: lookup table
3.464: lookup table with sum()
python3 (327, 100000)
5.786: original way
3.444: better loop
3.286: sum + generator
2.968: sum + listcomp
8.858: decision bit -- bit mask and shift
7.056: decision bit -- division
4.640: lookup table
4.783: lookup table with sum()
pypy (327, 100000)
0.296: original way
0.312: better loop
1.932: sum + generator
1.011: sum + listcomp
0.172: decision bit -- bit mask and shift
0.613: decision bit -- division
0.140: lookup table
1.977: lookup table with sum()
python (65536, 1000)
6.528: original way
4.661: better loop
4.974: sum + generator
4.150: sum + listcomp
10.971: decision bit -- bit mask and shift
10.218: decision bit -- division
6.052: lookup table
7.070: lookup table with sum()
python3 (65536, 1000)
12.999: original way
7.618: better loop
6.826: sum + generator
5.587: sum + listcomp
19.326: decision bit -- bit mask and shift
14.917: decision bit -- division
9.779: lookup table
9.575: lookup table with sum()
pypy (65536, 1000)
0.681: original way
0.884: better loop
2.640: sum + generator
2.642: sum + listcomp
0.316: decision bit -- bit mask and shift
1.573: decision bit -- division
0.280: lookup table
1.561: lookup table with sum()
python (1048576, 100)
10.371: original way
7.065: better loop
7.910: sum + generator
6.579: sum + listcomp
17.583: decision bit -- bit mask and shift
15.426: decision bit -- division
9.285: lookup table
10.850: lookup table with sum()
python3 (1048576, 100)
20.435: original way
11.221: better loop
10.162: sum + generator
8.981: sum + listcomp
29.108: decision bit -- bit mask and shift
23.626: decision bit -- division
14.706: lookup table
14.173: lookup table with sum()
pypy (1048576, 100)
0.985: original way
0.926: better loop
5.462: sum + generator
6.623: sum + listcomp
0.527: decision bit -- bit mask and shift
2.334: decision bit -- division
0.481: lookup table
5.800: lookup table with sum()
python (16777216, 10)
15.704: original way
11.331: better loop
11.995: sum + generator
13.787: sum + listcomp
28.527: decision bit -- bit mask and shift
25.204: decision bit -- division
15.349: lookup table
17.607: lookup table with sum()
python3 (16777216, 10)
32.822: original way
18.530: better loop
16.339: sum + generator
14.999: sum + listcomp
47.755: decision bit -- bit mask and shift
38.930: decision bit -- division
23.704: lookup table
22.693: lookup table with sum()
pypy (16777216, 10)
1.559: original way
2.234: better loop
6.586: sum + generator
10.931: sum + listcomp
0.817: decision bit -- bit mask and shift
3.714: decision bit -- division
0.752: lookup table
3.837: lookup table with sum()
```

`timeit`

module; it makes the right choice of timer for you regardless of platform. – Martijn Pieters Sep 21 '12 at 12:46`sum()`

function with a list comprehension (e.g.`sum(c for c in data if c >= 128)`

). – Martijn Pieters Sep 21 '12 at 12:47