**Background:** The problem of finding if parenthesis are balanced is actually a decision problem, and the language^{1} describing it is a context-free language.

Context free grammers can be parsed using an automaton with a stack^{2}

So, the following **iterative solution** can be achieved to this problem:

```
iterative(str):
stack <- empty stack
for each char in str:
if char is open paranthesis: //push the paranhtesis to stack
stack.push(char)
else if char is close parantesis: //if close paranthesis - check if it is closing an open parenthesis
if stack.head() == matchingParanthesis(char):
stack.pop()
else: //if the closing parenthesis do not close anything previously opened, return false
return false
//end of loop - check if all opened parenthesis were closed:
return stack.isEmpty()
```

The idea is that the parenthesis representing the opened scope is in the head of the stack, and each closing parenthesis - you can validate if it is closing the appropriate open parenthesis by looking the head of the stack.

Note: It is easy to see that for a single type parenthesis we could use an integer to mimic the stack (since we only actually needed to count the number, and don't care for the type of the parenthesis).

Also, since a loop+stack algorithms are really similar to recursion actually, we can derive the following **recursive algorithm**:

```
checkValidty(str,currentParenthesis,currentIndex):
//currentIndex is a common variable, changed by reference to affect all levels of recursion!
while (currentIndex < str.size()):
char <- str[currentIndex]
currentIndex <- currentIndex + 1
if char is open paranthesis:
//if the recursive call is unseccesfull - end the check, the answer is no
if !checkValidity(str,char,currentIndex):
return false
else if char is close parantesis:
if currentParenthesis == matchingParanthesis(char):
return true
else: //if the closing parenthesis do not close anything previously opened, return false
return false
//end of loop - check if all opened parenthesis were closed:
return currentParenthesis == nil
```

Invoke with `checkValidty(str,nil,0)`

- where `str`

is the validated string.

It is easy to see that the iterative and recursive algorithms are actually the same, in the second we use the call stack and the variable `lastParenthesis`

as the head of the stack.

(1) The language is all the words accepted by the problem. for example `(w)`

is in the language while `)w(`

is not.

(2) to be exact: some grammers need a non-deterministic automata and a stack, but this is a bit more theoretical thing, and is not the issue here.