# Determine all combinations of flipping a coin without using “itertools.product”

I went through similar posts on the forum but all of them suggest using `itertools.product` but I was wondering if it can be solved without using it.

I want to print all the combinations of outcomes for N flips of a coin. This can be done if N is known in advance. So the number of nested loops will be just N. But if N has to be determined dynamically (`input()` function) then I am stuck in implementing it in code. In plain English it is easy to imagine that the number of for loops is proportional to N, but how do I implement it? Do I have to use lambdas or recursion? Below is as example code for N = 4.

``````results = ["H", "T"]
outcomes = []
for l1 in results:
for l2 in results:
for l3 in results:
for l4 in results:
outcomes.append(l1+l2+l3+l4)

for o in outcomes:
print(o)
``````

• Yes, I would use recursion. – cxw Apr 8 '18 at 14:23
• It would be great if you could show me how. I can imagine that I need to simulate dynamic creation of for loops but do not know how. – Sandeep Apr 8 '18 at 14:26

DIY with generators

Here's one way to calculate a `product` of lists without using the built-in

``````def product (*iters):
def loop (prod, first = [], *rest):
if not rest:
for x in first:
yield prod + (x,)
else:
for x in first:
yield from loop (prod + (x,), *rest)
yield from loop ((), *iters)

for prod in product ("ab", "xyz"):
print (prod)

# ('a', 'x')
# ('a', 'y')
# ('a', 'z')
# ('b', 'x')
# ('b', 'y')
# ('b', 'z')
``````

In python, we can collect the outputs of a generator in a list by using the `list` constructor. Note we can also calculate the product of more than two inputs as seen below

``````print (list (product ("+-", "ab", "xyz")))
# [ ('+', 'a', 'x')
# , ('+', 'a', 'y')
# , ('+', 'a', 'z')
# , ('+', 'b', 'x')
# , ('+', 'b', 'y')
# , ('+', 'b', 'z')
# , ('-', 'a', 'x')
# , ('-', 'a', 'y')
# , ('-', 'a', 'z')
# , ('-', 'b', 'x')
# , ('-', 'b', 'y')
# , ('-', 'b', 'z')
# ]
``````

Because `product` accepts a a list of iterables, any iterable input can be used in the product. They can even be mixed as demonstrated below

``````print (list (product (['@', '%'], range (2), "xy")))
# [ ('@', 0, 'x')
# , ('@', 0, 'y')
# , ('@', 1, 'x')
# , ('@', 1, 'y')
# , ('%', 0, 'x')
# , ('%', 0, 'y')
# , ('%', 1, 'x')
# , ('%', 1, 'y')
# ]
``````

Because `product` is defined as a generator, we are afforded much flexibility even when writing more complex programs. Consider this program that finds right triangles made up whole numbers, a Pythagorean triple. Also note that `product` allows you to repeat an iterable as input as see in `product (r, r, r)` below

``````def is_triple (a, b, c):
return a * a + b * b == c * c

def solver (n):
r = range (1, n)
for p in product (r, r, r):
if is_triple (*p):
yield p

print (list (solver (20)))
# (3, 4, 5)
# (4, 3, 5)
# (5, 12, 13)
# (6, 8, 10)
# (8, 6, 10)
# (8, 15, 17)
# (9, 12, 15)
# (12, 5, 13)
# (12, 9, 15)
# (15, 8, 17)
``````

Implementing your coin tossing program is easy now.

``````def toss_coins (n):
sides = [ 'H', 'T' ]
coins = [ sides ] * n
yield from product (*coins)

print (list (toss_coins (2)))
# [ ('H', 'H'), ('H', 'T'), ('T', 'H'), ('T', 'T') ]

print (list (toss_coins (3)))
# [ ('H', 'H', 'H'), ('H', 'H', 'T'), ('H', 'T', 'H'), ('H', 'T', 'T'), ('T', 'H', 'H'), ('T', 'H', 'T'), ('T', 'T', 'H'), ('T', 'T', 'T') ]
``````

Without generators

But generators are a very high-level language feature and we wonder how we could represent `product` using pure recursion. Below `product` is reimplemented without the use of generators and now returns a filled array with all calculated sub-products

``````def map (f, lst):
if not lst:
return []
else:
first, *rest = lst
return [ f (first ) ] + map (f, rest)

def flat_map (f, lst):
if not lst:
return []
else:
first, *rest = lst
return f (first) + flat_map (f, rest)

def product (*iters):
def loop (acc, iters):
if not iters:
return acc
else:
first, *rest = iters
return flat_map (lambda c: map (lambda x: [x] + c, first), loop (acc, rest))
return loop ([[]], iters)
``````

We can now skip the `yield` and `list` calls in your program

``````def toss_coins (n):
sides = [ 'H', 'T' ]
coins = [ sides ] * n
return product (*coins)

print (toss_coins (2))
# [('H', 'H'), ('H', 'T'), ('T', 'H'), ('T', 'T')]

print (toss_coins (3))
# [('H', 'H', 'H'), ('H', 'H', 'T'), ('H', 'T', 'H'), ('H', 'T', 'T'), ('T', 'H', 'H'), ('T', 'H', 'T'), ('T', 'T', 'H'), ('T', 'T', 'T')]
``````

Above, we define `map` and `flat_map` with as few dependencies as possible, however there is only one subtle distinction in each implementation. Below, we represent each as a fold (using `reduce`) allowing us to see the semantic difference more easily. Also note Python includes its own version of `map` and `reduce` (in `functools`) that differ slightly from the versions provided here.

``````def concat (xs, ys):
return xs + ys

def append (xs, x):
return xs + [ x ]

def reduce (f, init, lst):
if not lst:
return init
else:
first, *rest = lst
return reduce (f, f (init, first), rest)

def map_reduce (m, r):
return lambda acc, x: r (acc, m (x))

def map (f, lst):
return reduce (map_reduce (f, append), [], lst)

def flat_map (f, lst):
return reduce (map_reduce (f, concat), [], lst)

def product (*iters):
# this stays the same
``````
• This works very well and I will mark as the answer, however my mind is stuck in finding a solution using recursion. Is there a way to use the suggested answer here stackoverflow.com/questions/7186518/… to adapt to my coin flipping problem. – Sandeep Apr 8 '18 at 15:21
• Sandeep, I included an edit that shows how to write `product` without generators, but note that all solutions here are using recursion. – Thank you Apr 8 '18 at 15:41