**Note:** This code may not be what you're really looking for, however I thought it could help you in some way... I hope so...

Anyway, before viewing my ptential solution, I suggest you try to learn Python (synthax, how to create functions, create random numbers, etc). You'll see that it is quite easy to learn and you'll totally like it! :P

You can find several ways to learn Python (books, online courses / docs, a friend addicted to Python XD, etc).

Check the following link for example: http://docs.python.org/tutorial/

Keep in mind that having a clear and understandable code helps us understand what is your problem, and gives you the best chance to get a better answer to your question ;).

Here is a simple code, **I suggest you focus in reading the comments carefully**:

```
import random
# The function "prob_head" below return the number of head divided by the number of coin toss
# The input variable "number_toss" is number of times we toss a coin
def prob_head(number_toss):
# "heads" is our number of heads.
# Initially it is equal to 0
heads = 0
# We toss a coin "number_toss" times...
for i in range(0, number_toss):
# We create a random number "flip" comprised in {0,1}
flip = int(random.random()*2)
# Let's say we follow the following rule:
# If "flip" = 0, then it's a head
# Else, if "flip" = 1, then it's a tail
if (flip == 0):
# "flip" = 0, so it's a head !
# We have to increment the number of "heads" by 1:
heads=heads + 1
return float(heads)/number_toss
# Here's a test of our function: "prob_head"
my_number_toss = 100
my_head_probability = prob_head(my_number_toss)
print "Probability of heads = "+str(my_head_probability)
```

**Example of output:**

Probability of heads = 0.41

The code above gives you an idea of simulating a normal coin tossing.

After re-reading your comments, I think I understood a bit more what you really wanted so I added this additional part...

**The below code represents a way to simulate a "tricked" / "fake" coin tossing game**.

Pay attention to the comments I made...

```
# The function "unbiasedFlip" returns the average probability of heads considering "n" coin
# The variable "p" is a fixed probability condition for getting a head.
def unbiasedFlip(n, p):
# The number of heads, initially set to 0
heads = 0
# We toss a coin n times...
for i in range(0, n):
# We generate "prob_heads": a random float number such that "prob_heads" < 1
prob_heads = float(random.random())
# If "prob_heads" is greater of equal to "p", then we have a head
# and we increase the number of heads "heads" by 1:
if prob_heads>=p:
heads = heads+1
# We return the average probability of heads, considering n coin tosses
# Note: we don't need to return the average prob. for Tails since:
# it's equal to 1-Avg_Prob(Heads)
return float(heads)/n
# An example for testing our function...
# We consider 100 coin toss
my_number_toss = 100
# We want a Head only if our generated probability of head is greater or equal to 0.8
# In fact, considering that the random number generator generates equally probability numbers
# (which means that it provides as many chance to give a Tail or a Head)
# it would be like saying: "we want a probability of 1-0.8 =0.2 chance of getting a head"
my_defined_prob_heads = 0.8
# We get our average probability of heads...
average_prob_heads = unbiasedFlip(my_number_toss, my_defined_prob_heads)
# We get our average probability of tails = 1-Avg_Prob(Heads)
average_prob_tails = 1-average_prob_heads
# We print the results...
print "- Number of toss = "+str(my_number_toss)
print "- Defined probability for head = "+str(my_defined_prob_heads)
print "- Average P(Heads) for n tosses = "+str(average_prob_heads)
print "- Average P(Tails) for n tosses = "+str(average_prob_tails)
```

**Example of output:**

```
- Number of toss = 100
- Defined probability for head = 0.8
- Average P(Heads) for n tosses = 0.24
- Average P(Tails) for n tosses = 0.76
```

Hope this helps mate.

Let me know if you have a question or if something is not clear.

`Pr`

and`Heads`

aren't going to be magically defined for you... – Keith Randall Sep 22 '12 at 4:20