The base-9 numbering system is a system that uses nine digits to represent numbers. That is,

231,085 = 2 × 10^{5}

+ 3 × 10^{4}

+ 1 × 10^{3}

+ 0 × 10^{2}

+ 8 × 10^{1}

+ 5 × 10^{0}

in the base-10 system, a.k.a. the decimal numbering system. But in the base-9 system, you write it terms of whole multiples of powers of 9, instead of powers of 10 as shown above:

381,881 = 3 × 9^{5}

+ 8 × 9^{4}

+ 1 × 9^{3} (Your instructor gave you the wrong number, btw. It's 381,881 not 382,871)

+ 8 × 9^{2}

+ 8 × 9^{1}

+ 1 × 9^{0}

Note that the coefficients of the powers of 10 in the base-10 representation (i.e., the 2, 3, 1, 0, 8, and 5) are always one of the ten decimal digits (zero through nine). Likewise, the coefficients of the powers of 9 in the base-9 representation (the 3, 8, 1, 8, 8, 1) are always one of the nine decimal digits (zero through eight). Anything more and you'd have to carry it over, like you learned in the addition of multi-digit numbers in elementary school.

Now, for the algorithm to convert the base-10 representation to base-9, first take a look at Converting a decimal number into binary which converts from base-10 to base-2. The only difference is that you'd divide by powers of 9, instead of powers of 2 as this question does.

Following the example in the linked question,

```
[231085] [53938] [1450] [721] [73] [1]
÷59049 ÷6561 ÷729 ÷81 ÷9 ÷1
[3] [8] [1] [8] [8] [1]
```

If you want to systematically break down a base-10 integer into its digits, you'd follow this pattern:

- Divide the number by 10 (the base).
- The remainder of the division will be the next least significant digit.
- Repeat with the new divided number (i.e. the quotient of the division of step 1) until the quotient reaches 0.

So, for 231,085, the iterations are as follows:

```
Step: 1 2 3 4 5 6
-------------------------------------------------------------
Number: 231,085 23,108 2,310 231 23 2
÷10 ÷10 ÷10 ÷10 ÷10 ÷10
-------------------------------------------------------------
Quotient: 23,108 2,310 231 23 2 0 <-- Quotient reached 0, so stop
Remainder: 5 8 0 1 3 2
```

As you can see, the remainder in each step is the next least significant digit in the number 231,085. That means 5 is the least significant digit. Then comes 8, which is really 8 × 10 = 80, and 10 > 1; then 0 × 100, and 100 > 10, etc.

Now if you were to divide by 9 in each step instead of by 10 as above, then the table would look something like

```
Step: 1 2 3 4 5 6
-------------------------------------------------------------
Number: 231,085 25,676 2,852 316 35 3
÷9 ÷9 ÷9 ÷9 ÷9 ÷9
-------------------------------------------------------------
Quotient: 25,676 2,852 316 35 3 0
Remainder: 1 8 8 1 8 3
```

And now the remainders are in reverse order of the base-9 representation of the base-10 number 231,085.

This answer doesn't actually give you the code for the base conversion, but the basic logic is outlined above, and the algorithm exists all over the internet (maybe for different bases, but all you need to change is the base in the division).