This is pseudo code for a function that turns decimal digits into binary representations.

The question is Show that Ldiv2[A] for an n-digit number is O(n). and determine the running complexity of the algorithm

The input is a decimal representation of a number X, give by an array of digits A[n-1], …,

The following algorithm uses a “long division by two” procedure Ldiv2 that divides a decimal number by 2. The binary conversion algorithm below convert the array of decimal digits A[0..n-1] to the array of bits B[0, ..4n-1] as follows:

```
Initialize B[0, ..4n-1] array of bits,
For i = 0 to 4n-1 do:
Begin
B[i]= A[0] %2; // % is the mod;
A = Ldiv2[A];
End;
Return B (possibly removing initial 0’s)
```

So for the above example X=169, n=2, B[0] = A[0]%2 = 9%2=1, then A=Ldiv2[A] = 84, B[1]=A[0]%2 = 4%2=0, etc.

for Ldiv2[A] i put that 4n-1 for n > 1 so that by definition should be O(n) and for the running complexity of the algorithm i put it was O(n) too because it only has one for loop running from 0 to 4n -1 although bit unclear if there is proof for that.

`A`

is not defined anywhere... – alfasin Sep 18 '13 at 5:16