<p>You are given an <code>n x n</code> integer matrix <code>grid</code> where each value <code>grid[i][j]</code> represents the elevation at that point <code>(i, j)</code>.</p> <p>The rain starts to fall. At time <code>t</code>, the depth of the water everywhere is <code>t</code>. You can swim from a square to another 4-directionally adjacent square if and only if the elevation of both squares individually are at most <code>t</code>. You can swim infinite distances in zero time. Of course, you must stay within the boundaries of the grid during your swim.</p> <p>Return <em>the least time until you can reach the bottom right square </em><code>(n - 1, n - 1)</code><em> if you start at the top left square </em><code>(0, 0)</code>.</p> <p> </p> <p><strong>Example 1:</strong></p> <img alt="" src="https://assets.leetcode.com/uploads/2021/06/29/swim1-grid.jpg" style="width: 164px; height: 165px;" /> <pre> <strong>Input:</strong> grid = [[0,2],[1,3]] <strong>Output:</strong> 3 Explanation: At time 0, you are in grid location (0, 0). You cannot go anywhere else because 4-directionally adjacent neighbors have a higher elevation than t = 0. You cannot reach point (1, 1) until time 3. When the depth of water is 3, we can swim anywhere inside the grid. </pre> <p><strong>Example 2:</strong></p> <img alt="" src="https://assets.leetcode.com/uploads/2021/06/29/swim2-grid-1.jpg" style="width: 404px; height: 405px;" /> <pre> <strong>Input:</strong> grid = [[0,1,2,3,4],[24,23,22,21,5],[12,13,14,15,16],[11,17,18,19,20],[10,9,8,7,6]] <strong>Output:</strong> 16 <strong>Explanation:</strong> The final route is shown. We need to wait until time 16 so that (0, 0) and (4, 4) are connected. </pre> <p> </p> <p><strong>Constraints:</strong></p> <ul> <li><code>n == grid.length</code></li> <li><code>n == grid[i].length</code></li> <li><code>1 <= n <= 50</code></li> <li><code>0 <= grid[i][j] < n<sup>2</sup></code></li> <li>Each value <code>grid[i][j]</code> is <strong>unique</strong>.</li> </ul>