To do this, you just have to extract the last digit, check if it is a prime and continue with the rest.

Writing a recursion basically consists of a trivial case and a recursion, where you break down the problem into a smaller one until you are in a trivial case.

So, what you need to do is, find your trivial case, where no further recursion is needed, and think about how to achieve this:

```
#separate the number (123) into a last Digit (3) and the rest (12)
lastDigit = n % 10
rest = int(n / 10)
```

if we have a none-prime, we can return False and not goint further into a recursion:

```
if not isPrime(lastDigit):
return False
```

The trivial part is just one digit, therefore the non-trivial part is this, where we go into recursion:

```
if n > 10:
return allPrime(rest)
```

so we have the case, where we stop because of a non-prime, we have the non-trivial-case
the trivial case does not go into recursion either, and because we already had the case where we have a non-prime, we just need:

```
return True
```

**sum it up:**

```
def isPrime(n):
if n < 2: return False
if n == 2: return True
if n & 1 == 0: return False
for x in range(3, int(n ** 0.5)+1, 2):
if n % x == 0:
return False
return True
def allPrime(n):
lastDigit = n % 10
rest = int(n / 10)
if not isPrime(lastDigit):
return False
if n > 10:
return allPrime(rest)
return True
print(allPrime(9777))
print(allPrime(773))
```

`for`

loops. For the record, sure there's a mathematical equivalence - recursion can be rewritten as repetition and visa-versa - but that doesn't mean they're the same thing. Similarly, binary and decimal aren't the same thing just because any binary number can be converted to decimal and visa versa. The form you actually used is significant too. – Steve314 Mar 3 '13 at 17:48