I suspect that this is an academic assignment so I'm only going to partially answer the question.

The fibonacci sequence is formally defined for non-negative integers as follows:

```
F(n) = n | n < 2
= F(n - 1) + F(n - 2) | n >= 2
```

This gives:

```
n | F(n)
0 | 0
1 | 1
2 | 1
3 | 2
4 | 3
5 | 5
6 | 8
7 | 13
etc etc...
```

You can do it with just a few registers, let's identify them:

- R
_{n} (the number of the requested fibonacci number)
- R
_{f1} (used to calculate fibonacci numbers)
- R
_{f2} (also used to calculate fibonacci numbers)
- R
_{x} (the register to hold the return value. can overlap with any other register)

R_{n} is passed as the argument to the function. R_{f1} shall start at 0, and R_{f2} shall start at 1.

Here's what we do to get the answer, split up by routines:

**Begin**

- Initialize R
_{f1} to 0.
- Initialize R
_{f2} to 1.
- Continue to Loop.

**Loop**

- Subtract 2 from R
_{n}.
- If R
_{n} is less than 0, jump to Finish.
- Add R
_{f2} to R_{f1}, storing the result in R_{f1}.
- Add R
_{f1} to R_{f2}, storing the result in R_{f2}.
- Jump to Loop.

**Finish**

- If R
_{n} AND 1 is false (implying that R_{n} is even) jump to FinishEven.
- Store R
_{f1} as the return value.
- Return.

**FinishEven**

- Store R
_{f2} as the return value.
- Return.

Tracing through for R_{n} = 5:

- R
_{f1} = 0
- R
_{f2} = 1
- R
_{n} = R_{n} - 2 // R_{n} = 3
- Test R
_{n} < 0 // false
- R
_{f1} = R_{f1} + R_{f2} // R_{f1} = 0 + 1 = 1
- R
_{f2} = R_{f1} + R_{f2} // R_{f2} = 1 + 1 = 2
- Unconditional Jump to Loop
- R
_{n} = R_{n} - 2 // R_{n} = 1
- Test R
_{n} < 0 // false
- R
_{f1} = R_{f1} + R_{f2} // R_{f1} = 1 + 2 = 3
- R
_{f2} = R_{f1} + R_{f2} // R_{f2} = 3 + 2 = 5
- Unconditional Jump to Loop
- R
_{n} = R_{n} - 2 // R_{n} = -1
- Test R
_{n} < 0 // true
- Jump to Finish
- Test R
_{n} & 1 // true
- R
_{x} = R_{f2} // 5

Our table shows that F(5) = 5, so this is correct.

`mov eax, 13`

and you're done. That, or you didn't give the full requirements. – harold Oct 12 '12 at 19:49