# Efficiency formula code in Pattern matching

I need a formula that will determine the efficiency of the system in pattern matching using time and the number of comparison factors.

Is there any formula that would produce numeric output using these factors?

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Could you give an example of a program that does this? –  Brian Noah Oct 13 '12 at 5:54
You would have to look at the compiled regex and apply O(n) analysis to each individual operation, where `n` would be different at each point depending on the input. In other words, there's probably no "formula" other than benchmarking. –  Jim Garrison Oct 13 '12 at 6:03
Good luck. This will depend extremely heavily on your regex engine. –  Louis Wasserman Oct 13 '12 at 6:07
I would like to determine the efficiency of the pattern matching algorithm that is used. where the system observes the time and the number of comparisons that the process spent to finish the task. The input would also be different at each point.. –  Lore Jairus Camero Oct 13 '12 at 6:08

If you wish to know how to determine efficiency of an algorithm, given you have the algorithm for pattern matching. Let me give it a try:

First, let us understand the most common terms:
O(1) or “Order One”: Constant time
• does not mean that it takes only one operation
• does mean that the work doesn’t change as N changes
• is a notation for “constant work”

O(n) or “Order n”: Linear time
• does not mean that it takes N operations
• does mean that the work changes in a way that is proportional to N
• is a notation for “work grows at a linear rate”

O(n2) or “Order n2 ”: Quadratic time

O(n3) or “Order n3 ”: Cubic time

Algorithms whose efficiency can be expressed in terms of a polynomial of the form

``````a(base m)n^m + a(base m-1)n^(m-1) + ... + a(base 2)n^2 + a(base 1)n + a(base 0)
``````

are called polynomial algorithms. Order O(n^m).

Some algorithms even take less time than the number of elements in the problem. There is a notion of logarithmic time algorithms.

We know `10^3 =1000` So we can write it as l`og(base 10)1000 = 3`

Similarly suppose we have

``````2^6  =64
``````

then we can write

``````log(base 2)64  = 6
``````

If the work of an algorithm can be reduced by half in one step, and in k steps we are able to solve the problem then

``````2^k  =  n
``````

or in other words

``````log(base 2)n  = k
``````

This algorithm will be having a logarithmic time complexity ,usually written as `O(ln n)`. Because logan will increase much more slowly than n itself, logarithmic algorithms are generally very efficient. It also can be shown that it does not matter as to what base value is chosen.

Example:

Use big-O notation to analyze the time efficiency of the following fragment of C code:

``````k = n;
while (k > 1)
{
.
.
k = k/2;
}
``````

Since the loop variable is cut in half each time through the loop, the number of times the statements inside the loop will be executed is `log(base 2)n`. Thus, an algorithm that halves the data remaining to be processed on each iteration of a loop will be an `O(log(base 2)n)` algorithm.

There are a large number of algorithms whose complexity is `O( n log(base 2)n)` .

Finally there are algorithms whose efficiency is dominated by a term of the form `a^n` These are called exponential algorithms. They are of more theoretical rather than practical interest because they cannot reasonably run on typical computers for moderate values of n.

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is the (number of comparison) / (Time duration) workable? –  Lore Jairus Camero Oct 13 '12 at 8:59
+1 for a really good explanation! –  Hayati Guvence Oct 13 '12 at 13:35

If you asking if there is a general formula that characterizes the performance of a regular expression pattern matcher for a given pattern and a given input, then the answer is that there is no such formula. The problem is far too complicated to be reduced to a formula.

And when you add in the fact that different pattern matching algorithms work in different ways, the problem gets even more complicated.

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