**Problem** Hey folks. I'm looking for some advice on python performance. Some background on my problem:

Given:

- A
`(x,y)`

mesh of nodes each with a value`(0...255)`

starting at 0 - A list of
`N`

input coordinates each at a specified location within the range`(0...x, 0...y)`

- A value
`Z`

that defines the "neighborhood" in count of nodes

Increment the value of the node at the input coordinate and the node's neighbors. Neighbors beyond the mesh edge are ignored. (No wrapping)

*BASE CASE:* A mesh of size `1024x1024`

nodes, with `400`

input coordinates and a range `Z`

of `75`

nodes.

Processing should be `O(x*y*Z*N)`

. I expect x, y and Z to remain roughly around the values in the base case, but the number of input coordinates N could increase up to 100,000. **My goal** is to minimize processing time.

**Current results** Between my start and the comments below, we've got several implementations.

Running speed on my 2.26 GHz Intel Core 2 Duo with Python 2.6.1:

```
f1: 2.819s
f2: 1.567s
f3: 1.593s
f: 1.579s
f3b: 1.526s
f4: 0.978s
```

`f1`

is the initial naive implementation: three nested `for`

loops.
`f2`

is replaces the inner `for`

loop with a list comprehension.
`f3`

is based on Andrei's suggestion in the comments and replaces the outer `for`

with `map()`

`f`

is Chris's suggestion in the answers below
`f3b`

is kriss's take on `f3`

`f4`

is Alex's contribution.

Code is included below for your perusal.

**Question** How can I further reduce the processing time? I'd prefer sub-1.0s for the test parameters.

**Please,** keep the recommendations to native Python. I know I can move to a third-party package such as numpy, but I'm trying to avoid *any* third party packages. Also, I've generated random input coordinates, and simplified the definition of the node value updates to keep our discussion simple. The specifics have to change slightly and are outside the scope of my question.

thanks much!

`f1`

is the initial naive implementation: three nested `for`

loops.```
def f1(x,y,n,z):
rows = [[0]*x for i in xrange(y)]
for i in range(n):
inputX, inputY = (int(x*random.random()), int(y*random.random()))
topleft = (inputX - z, inputY - z)
for i in xrange(max(0, topleft[0]), min(topleft[0]+(z*2), x)):
for j in xrange(max(0, topleft[1]), min(topleft[1]+(z*2), y)):
if rows[i][j] <= 255: rows[i][j] += 1
```

`f2`

is replaces the inner `for`

loop with a list comprehension.

```
def f2(x,y,n,z):
rows = [[0]*x for i in xrange(y)]
for i in range(n):
inputX, inputY = (int(x*random.random()), int(y*random.random()))
topleft = (inputX - z, inputY - z)
for i in xrange(max(0, topleft[0]), min(topleft[0]+(z*2), x)):
l = max(0, topleft[1])
r = min(topleft[1]+(z*2), y)
rows[i][l:r] = [j+(j<255) for j in rows[i][l:r]]
```

**UPDATE:** `f3`

is based on Andrei's suggestion in the comments and replaces the outer `for`

with `map()`

. My first hack at this requires several out-of-local-scope lookups, specifically recommended against by Guido: *local variable lookups are much faster than global or built-in variable lookups* I hardcoded all but the reference to the main data structure itself to minimize that overhead.

```
rows = [[0]*x for i in xrange(y)]
def f3(x,y,n,z):
inputs = [(int(x*random.random()), int(y*random.random())) for i in range(n)]
rows = map(g, inputs)
def g(input):
inputX, inputY = input
topleft = (inputX - 75, inputY - 75)
for i in xrange(max(0, topleft[0]), min(topleft[0]+(75*2), 1024)):
l = max(0, topleft[1])
r = min(topleft[1]+(75*2), 1024)
rows[i][l:r] = [j+(j<255) for j in rows[i][l:r]]
```

**UPDATE3:** ChristopeD also pointed out a couple improvements.

```
def f(x,y,n,z):
rows = [[0] * y for i in xrange(x)]
rn = random.random
for i in xrange(n):
topleft = (int(x*rn()) - z, int(y*rn()) - z)
l = max(0, topleft[1])
r = min(topleft[1]+(z*2), y)
for u in xrange(max(0, topleft[0]), min(topleft[0]+(z*2), x)):
rows[u][l:r] = [j+(j<255) for j in rows[u][l:r]]
```

**UPDATE4:** kriss added a few improvements to `f3`

, replacing min/max with the new ternary operator syntax.

```
def f3b(x,y,n,z):
rn = random.random
rows = [g1(x, y, z) for x, y in [(int(x*rn()), int(y*rn())) for i in xrange(n)]]
def g1(x, y, z):
l = y - z if y - z > 0 else 0
r = y + z if y + z < 1024 else 1024
for i in xrange(x - z if x - z > 0 else 0, x + z if x + z < 1024 else 1024 ):
rows[i][l:r] = [j+(j<255) for j in rows[i][l:r]]
```

**UPDATE5:** Alex weighed in with his substantive revision, adding a separate `map()`

operation to cap the values at 255 and removing all non-local-scope lookups. The perf differences are non-trivial.

```
def f4(x,y,n,z):
rows = [[0]*y for i in range(x)]
rr = random.randrange
inc = (1).__add__
sat = (0xff).__and__
for i in range(n):
inputX, inputY = rr(x), rr(y)
b = max(0, inputX - z)
t = min(inputX + z, x)
l = max(0, inputY - z)
r = min(inputY + z, y)
for i in range(b, t):
rows[i][l:r] = map(inc, rows[i][l:r])
for i in range(x):
rows[i] = map(sat, rows[i])
```

Also, since we all seem to be hacking around with variations, here's my test harness to compare speeds: *(improved by ChristopheD)*

```
def timing(f,x,y,z,n):
fn = "%s(%d,%d,%d,%d)" % (f.__name__, x, y, z, n)
ctx = "from __main__ import %s" % f.__name__
results = timeit.Timer(fn, ctx).timeit(10)
return "%4.4s: %.3f" % (f.__name__, results / 10.0)
if __name__ == "__main__":
print timing(f, 1024, 1024, 400, 75)
#add more here.
```

`map()`

replacing the outer`for`

– J.J. Mar 21 '10 at 22:18`xrange`

instead of`range`

. In my experience, it's always faster. You may win a few ms – Romuald Brunet Mar 21 '10 at 22:54