8.4. Randomly Walking Turtles¶
Suppose we want to entertain ourselves by watching a turtle wander around randomly inside the screen. When we run the program we want the turtle and program to behave in the following way:
The turtle begins in the center of the screen.
Flip a coin. If it’s heads then turn to the left 90 degrees. If it’s tails then turn to the right 90 degrees.
Take 50 steps forward.
If the turtle has moved outside the screen then stop, otherwise go back to step 2 and repeat.
Notice that we cannot predict how many times the turtle will need to flip the coin before it wanders out of the screen, so we can’t use a for loop in this case. In fact, although very unlikely, this program might never end, that is why we call this indefinite iteration.
So based on the problem description above, we can outline a program as follows:
create a window and a turtle while the turtle is still in the window: generate a random number between 0 and 1 if the number == 0 (heads): turn left else: turn right move the turtle forward 50
Now, probably the only thing that seems a bit confusing to you is the part
about whether or not the turtle is still in the screen. But this is the nice
thing about programming, we can delay the tough stuff and get something in
our program working right away. The way we are going to do this is to
delegate the work of deciding whether the turtle is still in the screen or
not to a boolean function. Let’s call this boolean function
can write a very simple version of this boolean function by having
it always return
True, or by having it decide randomly,
the point is to have it do something simple so that we can focus on the parts
we already know how to do well and get them working. Since having it always
return true would not be a good idea we will write our version to decide
randomly. Let’s say that there is a 90% chance the turtle is still in the
window and 10% that the turtle has escaped.
Now we have a working program that draws a random walk of our turtle that has a 90% chance of staying on the screen. We are in a good position, because a large part of our program is working and we can focus on the next bit of work – deciding whether the turtle is inside the screen boundaries or not.
We can find out the width and the height of the screen using the
window_height methods of the screen object.
However, remember that the turtle starts at position 0,0 in the middle of the
screen. So we never want the turtle to go farther right than width/2 or
farther left than negative width/2. We never want the turtle to go further
up than height/2 or further down than negative height/2. Once we know what
the boundaries are we can use some conditionals to check the turtle position
against the boundaries and return
False if the turtle is outside or
True if the turtle is inside.
Once we have computed our boundaries we can get the current position of the turtle and then use conditionals to decide. Here is one implementation:
def isInScreen(wn,t): leftBound = -(wn.window_width() / 2) rightBound = wn.window_width() / 2 topBound = wn.window_height() / 2 bottomBound = -(wn.window_height() / 2) turtleX = t.xcor() turtleY = t.ycor() stillIn = True if turtleX > rightBound or turtleX < leftBound: stillIn = False if turtleY > topBound or turtleY < bottomBound: stillIn = False return stillIn
There are lots of ways that the conditional could be written. In this case
we have given
stillIn the default value of
True and use two
to possibly set the value to
False. You could rewrite this to use nested
elif statements and set
True in an else
Here is the full version of our random walk program.
We could have written this program without using a boolean function. You might want to try to rewrite it using a complex condition on the while statement. However, using a boolean function makes the program much more readable and easier to understand. It also gives us another tool to use if this was a larger program and we needed to have a check for whether the turtle was still in the screen in another part of the program. Another advantage is that if you ever need to write a similar program, you can reuse this function with confidence the next time you need it. Breaking up this program into a couple of parts is another example of functional decomposition.
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