started on unsorted array function (previous was sorted)

2024-11-14 23:12:58 +08:00 · 2024-01-09 08:00:58 -08:00 · 2024-01-09 08:00:58 -08:00 · 44f3b4cc2f
commit 44f3b4cc2f
parent a46cc24527
1 changed files with 40 additions and 26 deletions
--- a/src/algorithms/search/twin-pointers/twinPointers.js
+++ b/src/algorithms/search/twin-pointers/twinPointers.js
@ -41,34 +41,48 @@ export function twinPointerSorted(sortedArray, seekElement, comparatorCallback)
  return [0, 0];
 }
-// An example of a twin pointer method on an unsorted array.
+/* An example of a twin pointer method on an unsorted array. In this problem, we aim to get the heighest possible area from two numbers,
-export function twinPointerUnsorted(sortedArray, seekElement, comparatorCallback) {
+    assuming that each number n is a rectangle of 1 width and n height. (Problem and solution taken from Leetcode #11)
-    const comparator = new Comparator(comparatorCallback);
+*/
    // These variables will be our pointers; since the array is sorted, we can set them to the left and rightmost elements.
    let left = 0;
    let right = sortedArray.length - 1
    // If our left and right pointers have met then we have iterated through the entire array.
    while (left < right) {
 /**
-       * If our sum is less than the target then we can increase said sum but by increasing the left value; 
+ *
-       * since the array is sorted, this will always result in array[left] becoming a larger number.
+ * @param {*[]} unsortedArray
 * @param {function(a, b)} [comparatorCallback]
 * @return {number}
 */
 export function twinPointerUnsorted(unsortedArray, comparatorCallback) {
    const comparator = new Comparator(comparatorCallback);
    // Again, we set our two pointers to the left and rightmost elements of the array.
    let left = 0;
    let right = unsortedArray.length - 1;
    // We initialize two area variables; one for our current area between our two pointers and one for the highest that we'll return.
    let area = 0;
    let mostArea = 0;
    // Functionally equivalent to the while conditional we set in the first example.
    while (left !== right) {
        // In this situation, since we don't have a specific "target" in mind we instead compare the two values at our two pointers to each other.
        if (height[left] < height[right]) {
            // Here we simply calculate our current area and whether we need to change our highest area by comparing it with the current.
            area = (Math.min(height[left], height[right]) * (right - left));
            mostArea = Math.max(area, mostArea);
            /**
             * Again, we move the left pointer forward or the right pointer backwards. You may be thinking that 
             */
      if (comparator.lessThan(sortedArray[left] + sortedarray[right], seekElement)) {
            left++;
      // Same concept as before, only now we decrease our sum because it's greater than the target.    
      } else if (comparator.greaterThan(sortedArray[left] + sortedarray[right], seekElement)) {
          right--;
      // Assuming we have found our target, return left and right since they represent the indices that our correct sum is located at.
        } else {
-          return [left, right]
+            area = (Math.min(height[left], height[right]) * (right - left));
            mostArea = Math.max(area, mostArea);
            right--;
        }
    }
-    // Return [0, 0] (an impossible answer due to our while loop) if we haven't found any combination of numbers that works.
+    return mostArea
    return [0, 0];
  }