hey how exactly can I find the square root of an integer using MIPS assembly?
It is not in MIPS, but assembly nonetheless. The basic algorithm I found was based on the fact that the first n odd numbers added together = n^2.
So if you take advantage of that by reversing the process and subtracting from the number you would like to take the square root of, you can loop through to get either the exact answer, or an approximation. I believe its the root + 1 for non-perfect squares.
The idea being that the number of times you loop through is n, which is your square root.
Hope this helps.
We can use an algorithm like the one submitted for this question and adapt it as needed. Before getting into MIPS, lets look at an implementation in C:
From the C code, we can outline what the MIPS code will look like:
I found Newton's method
I took a digit-by-digit root calculation method from wikipedia, and created a MIPS version. It does not suffer from inefficiency (
First, I translated the C example to use only less-than (
Here is the resulting MIPS code:
You call it like any other MIPS procedure:
This procedure always returns
Beware: the code enters an infinite loop for negative arguments. Sanitize your input before calling this procedure.
You can try this algorithm, which gives the integer smaller than or equal to the square root of your number.
Suppose you want the square root of
Here's a simple to understand algorithm for calculating the floor of the square root of a positive integer, in C:
It relies on the same principle as okstory's answer, in a slightly different manner.
Theory: Progressively increasing odd numbers are added to a partialSum, as long as the partialSum is less than the operand. The result is equal to the number of odd numbers summed to produce the partialSum.