leetcode-problemset/leetcode/originData/find-the-safest-path-in-a-grid.json

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            "content": "<p>You are given a <strong>0-indexed</strong> 2D matrix <code>grid</code> of size <code>n x n</code>, where <code>(r, c)</code> represents:</p>\n\n<ul>\n\t<li>A cell containing a thief if <code>grid[r][c] = 1</code></li>\n\t<li>An empty cell if <code>grid[r][c] = 0</code></li>\n</ul>\n\n<p>You are initially positioned at cell <code>(0, 0)</code>. In one move, you can move to any adjacent cell in the grid, including cells containing thieves.</p>\n\n<p>The <strong>safeness factor</strong> of a path on the grid is defined as the <strong>minimum</strong> manhattan distance from any cell in the path to any thief in the grid.</p>\n\n<p>Return <em>the <strong>maximum safeness factor</strong> of all paths leading to cell </em><code>(n - 1, n - 1)</code><em>.</em></p>\n\n<p>An <strong>adjacent</strong> cell of cell <code>(r, c)</code>, is one of the cells <code>(r, c + 1)</code>, <code>(r, c - 1)</code>, <code>(r + 1, c)</code> and <code>(r - 1, c)</code> if it exists.</p>\n\n<p>The <strong>Manhattan distance</strong> between two cells <code>(a, b)</code> and <code>(x, y)</code> is equal to <code>|a - x| + |b - y|</code>, where <code>|val|</code> denotes the absolute value of val.</p>\n\n<p>&nbsp;</p>\n<p><strong class=\"example\">Example 1:</strong></p>\n<img alt=\"\" src=\"https://assets.leetcode.com/uploads/2023/07/02/example1.png\" style=\"width: 362px; height: 242px;\" />\n<pre>\n<strong>Input:</strong> grid = [[1,0,0],[0,0,0],[0,0,1]]\n<strong>Output:</strong> 0\n<strong>Explanation:</strong> All paths from (0, 0) to (n - 1, n - 1) go through the thieves in cells (0, 0) and (n - 1, n - 1).\n</pre>\n\n<p><strong class=\"example\">Example 2:</strong></p>\n<img alt=\"\" src=\"https://assets.leetcode.com/uploads/2023/07/02/example2.png\" style=\"width: 362px; height: 242px;\" />\n<pre>\n<strong>Input:</strong> grid = [[0,0,1],[0,0,0],[0,0,0]]\n<strong>Output:</strong> 2\n<strong>Explanation:</strong> The path depicted in the picture above has a safeness factor of 2 since:\n- The closest cell of the path to the thief at cell (0, 2) is cell (0, 0). The distance between them is | 0 - 0 | + | 0 - 2 | = 2.\nIt can be shown that there are no other paths with a higher safeness factor.\n</pre>\n\n<p><strong class=\"example\">Example 3:</strong></p>\n<img alt=\"\" src=\"https://assets.leetcode.com/uploads/2023/07/02/example3.png\" style=\"width: 362px; height: 242px;\" />\n<pre>\n<strong>Input:</strong> grid = [[0,0,0,1],[0,0,0,0],[0,0,0,0],[1,0,0,0]]\n<strong>Output:</strong> 2\n<strong>Explanation:</strong> The path depicted in the picture above has a safeness factor of 2 since:\n- The closest cell of the path to the thief at cell (0, 3) is cell (1, 2). The distance between them is | 0 - 1 | + | 3 - 2 | = 2.\n- The closest cell of the path to the thief at cell (3, 0) is cell (3, 2). The distance between them is | 3 - 3 | + | 0 - 2 | = 2.\nIt can be shown that there are no other paths with a higher safeness factor.\n</pre>\n\n<p>&nbsp;</p>\n<p><strong>Constraints:</strong></p>\n\n<ul>\n\t<li><code>1 &lt;= grid.length == n &lt;= 400</code></li>\n\t<li><code>grid[i].length == n</code></li>\n\t<li><code>grid[i][j]</code> is either <code>0</code> or <code>1</code>.</li>\n\t<li>There is at least one thief in the <code>grid</code>.</li>\n</ul>\n",
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            "hints": [
                "Consider using both BFS and binary search together.",
                "Launch a BFS starting from all the cells containing thieves to calculate d[x][y] which is the smallest Manhattan distance from (x, y) to the nearest grid that contains thieves.",
                "To check if the bottom-right cell of the grid can be reached **through a path of safeness factor v**, eliminate all cells (x, y) such that grid[x][y]  < v. if (0, 0) and (n - 1, n - 1) are still connected, there exists a path between (0, 0) and (n - 1, n - 1) of safeness factor v.",
                "Binary search over the final safeness factor v."
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update 2023-08-11 23:36:00 +08:00			`{`
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			`"title": "Find the Safest Path in a Grid",`
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			"content": "<p>You are given a <strong>0-indexed</strong> 2D matrix <code>grid</code> of size <code>n x n</code>, where <code>(r, c)</code> represents:</p>\n\n<ul>\n\t<li>A cell containing a thief if <code>grid[r][c] = 1</code></li>\n\t<li>An empty cell if <code>grid[r][c] = 0</code></li>\n</ul>\n\n<p>You are initially positioned at cell <code>(0, 0)</code>. In one move, you can move to any adjacent cell in the grid, including cells containing thieves.</p>\n\n<p>The <strong>safeness factor</strong> of a path on the grid is defined as the <strong>minimum</strong> manhattan distance from any cell in the path to any thief in the grid.</p>\n\n<p>Return <em>the <strong>maximum safeness factor</strong> of all paths leading to cell </em><code>(n - 1, n - 1)</code><em>.</em></p>\n\n<p>An <strong>adjacent</strong> cell of cell <code>(r, c)</code>, is one of the cells <code>(r, c + 1)</code>, <code>(r, c - 1)</code>, <code>(r + 1, c)</code> and <code>(r - 1, c)</code> if it exists.</p>\n\n<p>The <strong>Manhattan distance</strong> between two cells <code>(a, b)</code> and <code>(x, y)</code> is equal to <code>\|a - x\| + \|b - y\|</code>, where <code>\|val\|</code> denotes the absolute value of val.</p>\n\n<p> </p>\n<p><strong class=\"example\">Example 1:</strong></p>\n<img alt=\"\" src=\"https://assets.leetcode.com/uploads/2023/07/02/example1.png\" style=\"width: 362px; height: 242px;\" />\n<pre>\n<strong>Input:</strong> grid = [[1,0,0],[0,0,0],[0,0,1]]\n<strong>Output:</strong> 0\n<strong>Explanation:</strong> All paths from (0, 0) to (n - 1, n - 1) go through the thieves in cells (0, 0) and (n - 1, n - 1).\n</pre>\n\n<p><strong class=\"example\">Example 2:</strong></p>\n<img alt=\"\" src=\"https://assets.leetcode.com/uploads/2023/07/02/example2.png\" style=\"width: 362px; height: 242px;\" />\n<pre>\n<strong>Input:</strong> grid = [[0,0,1],[0,0,0],[0,0,0]]\n<strong>Output:</strong> 2\n<strong>Explanation:</strong> The path depicted in the picture above has a safeness factor of 2 since:\n- The closest cell of the path to the thief at cell (0, 2) is cell (0, 0). The distance between them is \| 0 - 0 \| + \| 0 - 2 \| = 2.\nIt can be shown that there are no other paths with a higher safeness factor.\n</pre>\n\n<p><strong class=\"example\">Example 3:</strong></p>\n<img alt=\"\" src=\"https://assets.leetcode.com/uploads/2023/07/02/example3.png\" style=\"width: 362px; height: 242px;\" />\n<pre>\n<strong>Input:</strong> grid = [[0,0,0,1],[0,0,0,0],[0,0,0,0],[1,0,0,0]]\n<strong>Output:</strong> 2\n<strong>Explanation:</strong> The path depicted in the picture above has a safeness factor of 2 since:\n- The closest cell of the path to the thief at cell (0, 3) is cell (1, 2). The distance between them is \| 0 - 1 \| + \| 3 - 2 \| = 2.\n- The closest cell of the path to the thief at cell (3, 0) is cell (3, 2). The distance between them is \| 3 - 3 \| + \| 0 - 2 \| = 2.\nIt can be shown that there are no other paths with a higher safeness factor.\n</pre>\n\n<p> </p>\n<p><strong>Constraints:</strong></p>\n\n<ul>\n\t<li><code>1 <= grid.length == n <= 400</code></li>\n\t<li><code>grid[i].length == n</code></li>\n\t<li><code>grid[i][j]</code> is either <code>0</code> or <code>1</code>.</li>\n\t<li>There is at least one thief in the <code>grid</code>.</li>\n</ul>\n",
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			`"lang": "PHP",`
			`"langSlug": "php",`
			`"code": "class Solution {\n\n /*\n @param Integer[][] $grid\n * @return Integer\n */\n function maximumSafenessFactor($grid) {\n \n }\n}",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
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			`"lang": "Swift",`
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			`"code": "class Solution {\n func maximumSafenessFactor(_ grid: [[Int]]) -> Int {\n \n }\n}",`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Kotlin",`
			`"langSlug": "kotlin",`
			`"code": "class Solution {\n fun maximumSafenessFactor(grid: List<List<Int>>): Int {\n \n }\n}",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Dart",`
			`"langSlug": "dart",`
			`"code": "class Solution {\n int maximumSafenessFactor(List<List<int>> grid) {\n\n }\n}",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Go",`
			`"langSlug": "golang",`
			`"code": "func maximumSafenessFactor(grid [][]int) int {\n \n}",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Ruby",`
			`"langSlug": "ruby",`
			`"code": "# @param {Integer[][]} grid\n# @return {Integer}\ndef maximum_safeness_factor(grid)\n \nend",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Scala",`
			`"langSlug": "scala",`
			`"code": "object Solution {\n def maximumSafenessFactor(grid: List[List[Int]]): Int = {\n \n }\n}",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Rust",`
			`"langSlug": "rust",`
			`"code": "impl Solution {\n pub fn maximum_safeness_factor(grid: Vec<Vec<i32>>) -> i32 {\n \n }\n}",`
update 2023-08-11 23:36:00 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
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			`"code": "(define/contract (maximum-safeness-factor grid)\n (-> (listof (listof exact-integer?)) exact-integer?)\n\n )",`
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			`"lang": "Erlang",`
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			`"code": "-spec maximum_safeness_factor(Grid :: [[integer()]]) -> integer().\nmaximum_safeness_factor(Grid) ->\n .",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Elixir",`
			`"langSlug": "elixir",`
			`"code": "defmodule Solution do\n @spec maximum_safeness_factor(grid :: [[integer]]) :: integer\n def maximum_safeness_factor(grid) do\n\n end\nend",`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"stats": "{\"totalAccepted\": \"16.3K\", \"totalSubmission\": \"53.2K\", \"totalAcceptedRaw\": 16317, \"totalSubmissionRaw\": 53188, \"acRate\": \"30.7%\"}",`
update 2023-08-11 23:36:00 +08:00			`"hints": [`
			`"Consider using both BFS and binary search together.",`
			`"Launch a BFS starting from all the cells containing thieves to calculate d[x][y] which is the smallest Manhattan distance from (x, y) to the nearest grid that contains thieves.",`
			`"To check if the bottom-right cell of the grid can be reached through a path of safeness factor v, eliminate all cells (x, y) such that grid[x][y] < v. if (0, 0) and (n - 1, n - 1) are still connected, there exists a path between (0, 0) and (n - 1, n - 1) of safeness factor v.",`
			`"Binary search over the final safeness factor v."`
			`],`
			`"solution": null,`
			`"status": null,`
			`"sampleTestCase": "[[1,0,0],[0,0,0],[0,0,1]]",`
			`"metaData": "{\n \"name\": \"maximumSafenessFactor\",\n \"params\": [\n {\n \"name\": \"grid\",\n \"type\": \"list<list<integer>>\"\n }\n ],\n \"return\": {\n \"type\": \"integer\"\n }\n}",`
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