8.5. The 3n + 1 Sequence¶
As another example of indefinite iteration, let’s look at a sequence that has fascinated mathematicians for many years.
The rule for creating the sequence is to start from
some positive integer, call it n
, and to generate
the next term of the sequence from n
, either by halving n
,
whenever n
is even, or else by multiplying it by three and adding 1 when it is odd. The sequence
terminates when n
reaches 1.
This Python function captures that algorithm. Try running this program several times supplying different values for n.
The condition for this loop is n != 1
. The loop will continue running until
n == 1
(which will make the condition false).
Each time through the loop, the program prints the value of n
and then
checks whether it is even or odd using the remainder operator. If it is even, the value of n
is divided
by 2 using integer division. If it is odd, the value is replaced by n * 3 + 1
.
Try some other examples.
Since n
sometimes increases and sometimes decreases, there is no obvious
proof that n
will ever reach 1, or that the program terminates. For some
particular values of n
, we can prove termination. For example, if the
starting value is a power of two, then the value of n
will be even each
time through the loop until it reaches 1.
You might like to have some fun and see if you can find a small starting number that needs more than a hundred steps before it terminates.
Lab
 Experimenting with the 3n+1 Sequence In this guided lab exercise we will try to learn more about this sequence.
Particular values aside, the interesting question is whether we can prove that
this sequence terminates for all positive values of n
. So far, no one has been able
to prove it or disprove it!
Think carefully about what would be needed for a proof or disproof of the hypothesis “All positive integers will eventually converge to 1”. With fast computers we have been able to test every integer up to very large values, and so far, they all eventually end up at 1. But this doesn’t mean that there might not be some asyet untested number which does not reduce to 1.
You’ll notice that if you don’t stop when you reach one, the sequence gets into its own loop: 1, 4, 2, 1, 4, 2, 1, 4, and so on. One possibility is that there might be other cycles that we just haven’t found.
Choosing between for
and while
Use a for
loop if you know the maximum number of times that you’ll
need to execute the body. For example, if you’re traversing a list of elements,
or can formulate a suitable call to range
, then choose the for
loop.
So any problem like “iterate this weather model run for 1000 cycles”, or “search this
list of words”, “check all integers up to 10000 to see which are prime” suggest that a for
loop is best.
By contrast, if you are required to repeat some computation until some condition is
met, as we did in this 3n + 1 problem, you’ll need a while
loop.
As we noted before, the first case is called definite iteration — we have some definite bounds for what is needed. The latter case is called indefinite iteration — we are not sure how many iterations we’ll need — we cannot even establish an upper bound!
Check your understanding

iter51: Consider the code that prints the 3n+1 sequence in ActiveCode box 6. Will the while loop in this code always terminate for any positive integer value of n?
 (A) Yes.
 The 3n+1 sequence has not been proven to terminate for all values of n.
 (B) No.
 It has not been disproven that the 3n+1 sequence will terminate for all values of n. In other words, there might be some value for n such that this sequence does not terminate. We just have not found it yet.
 (C) No one knows.
 That this sequence terminates for all values of n has not been proven or disproven so no one knows whether the while loop will always terminate or not.