Pascal's Triangle with iterative algorithm via list comprehension in Python

Just for the sake of exercise I'm trying to find a way to express Pascal's Triangle with Python list comprehension, and do that in iterative way. I'm representing Pascal's Triangle in Python as:

``````tri = [[1], [1, 1], [1, 2, 1], [1, 3, 3, 1], [1, 4, 6, 4, 1], ...]
``````

As I'm doing it iteratively, I need to somehow access previously calculated lines of the triangle, and I'm trying to do this without declaring a local variable.

So far I have this:

``````tri = [lines.append(
([1] + [lines[i][j]+lines[i][j-1] for j in xrange(1, i+1)] + [1]) if i > 0
else [1, 1])
or lines[i] for i, lines in enumerate([[[1]]]*height)]
``````

Any ideas?

EDIT: As pointed out by @brc this is really bad example of how and/or when to use list comprehensions.

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In case anyone else gets any ideas, this is a great example of when not to use list comprehensions. As an exercise, fine, but don't ever use something like that in real code, please. –  brc Oct 24 '11 at 18:48
What? Aren't `i` and `lines` and `j` local variables??? –  Matt Fenwick Oct 24 '11 at 19:23
@brc Totally, I probably should've put that note in my question. –  MisterMetaphor Oct 24 '11 at 20:20
@MattFenwick Yes, but they are declared implicitly. –  MisterMetaphor Oct 24 '11 at 20:21

Obeying all the slightly insane restrictions you imposed upon yourself, the only simplifications I can think of are incorporated here:

``````[d.setdefault(j, [sum(d[len(d)-1][max(i, 0):i + 2]) for i in range(-1, j)])
for j, d in enumerate([{0: [1]}] * 5)]
``````

At least this is shorter than your version and gets rid of all the conditional expressions. Of course it's still insane.

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I like this answer, although this (sadly) works a bit slower than my initial ugly version. –  MisterMetaphor Oct 24 '11 at 22:48

You can simply use the definition of the binomial coefficients:

``````from math import factorial
tri = [[factorial(n) // (factorial(k) * factorial(n - k)) for k in range(n+1)]
for n in range(height)]
``````
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+1 for using math (I wish it could be +10 for a problem like this) –  brc Oct 24 '11 at 22:44
This is probably how it should be done in production code. –  MisterMetaphor Oct 24 '11 at 22:44

As explicitly iterative approaches are wanted, I would use an iterator.

``````def bincoeff(num=None):
from math import factorial
if num is None:
it = iter(lambda: True, False) # waiting for Godot
else:
it = xrange(num)
for _ in it:
yield [factorial(n) // (factorial(k) * factorial(n - k)) for k in range(n+1)]
``````

With this generator, you can

• build a list:

``````bc = list(bincoeff(100))
``````
• get all up to a certain maximum:

``````for bc in bincoeff():
if len(bc) > 100: break
print bc
``````
• ...

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