I am reading the book **Computational Complexity: A Modern Approach** and I am having problems understanding **oblivious Turing machines**.

An oblivious Turing machine (TM) is such a TM that the movement of its heads is entirely determined by the **length of the input**. That is, the TM is oblivious to its input. So far so good.

But one of the excercises is to prove the following theorem:

```
If a language L is decidable in time T(n)
then there exists an oblivious TM that decides L in time O(T(n)^2).
```

It is obvious that the oblivious TM must not operate on the original input of `L`

but at some *coded* version. That is, the gist of the theorem is the *coding* of a **bitstring** to an **integer** (length of the input of the oblivious TM). But if one would want to code the set of possible inputs of `L`

(bitstrings) to an integer, one would run into very high numbers fairly quickly since there are `2^n`

bitstrings of length `n`

.

Am I understanding the problem correctly? How do you prove the theorem?