Generate All Strings With n Matched Parentheses - Backtracking ("Generate Parentheses" on LeetCode)

Back To Back SWE ยท Beginner ยท๐Ÿ—๏ธ Systems Design & Architecture ยท7y ago
Free 5-Day Mini-Course: https://backtobackswe.com Try Our Full Platform: https://backtobackswe.com/pricing ๐Ÿ“น Intuitive Video Explanations ๐Ÿƒ Run Code As You Learn ๐Ÿ’พ Save Progress โ“New Unseen Questions ๐Ÿ”Ž Get All Solutions Question: Write a program that takes as input a number n in and returns all the strings with n matched pairs of parens. Examples: n = 1 [ "()" ] n = 2 [ "(())", "()()" ] n = 3 [ "((()))","(()())","(())()","()(())","()()()" ] Approach 1 (Brute Force Then Validate) Generate all (2 ^ (2n)) possible parenthese strings and then validate each for being balanced. If n = 2 then the string length will be 2 times that since all open parentheses are matched by closed parentheses. This lower bounds our time complexity. Even if we restrict the enumeration to just sets with an equal number of left and right parentheses we will have choose(2k, k) strings to consider for validation. Approach 2 (Directed Backtracking) The 3 Keys To Backtracking Our Choice: Whether we place a left or right paren at a certain decision point in our recursion. Our Constraints: We can't place a right paren unless we have left parens to match against. Our Goal: Place all k left and all k right parens. The Key At each point of constructing the string of length 2k we make a choice. We can place a "(" and recurse or we can place a ")" and recurse. But we can't just do that placement, we need 2 critical pieces of information. The amount of left parens left to place. The amount of right parens left to place. We have 2 critical rules at each placement step. We can place a left parentheses if we have more than 0 left to place. We can only place a right parentheses if there are left parentheses that we can match against. We know this is the case when we have less left parentheses to place than right parentheses to place. Once we establish these constraints on our branching we know that when we have 0 of both parens to place that we are done, we have an ans
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