leetcode-problemset/leetcode/originData/minimum-cost-of-a-path-with-special-roads.json

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            "title": "Minimum Cost of a Path With Special Roads",
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            "content": "<p>You are given an array <code>start</code> where <code>start = [startX, startY]</code> represents your initial position <code>(startX, startY)</code> in a 2D space. You are also given the array <code>target</code> where <code>target = [targetX, targetY]</code> represents your target position <code>(targetX, targetY)</code>.</p>\n\n<p>The cost of going from a position <code>(x1, y1)</code> to any other position in the space <code>(x2, y2)</code> is <code>|x2 - x1| + |y2 - y1|</code>.</p>\n\n<p>There are also some special roads. You are given a 2D array <code>specialRoads</code> where <code>specialRoads[i] = [x1<sub>i</sub>, y1<sub>i</sub>, x2<sub>i</sub>, y2<sub>i</sub>, cost<sub>i</sub>]</code> indicates that the <code>i<sup>th</sup></code> special road can take you from <code>(x1<sub>i</sub>, y1<sub>i</sub>)</code> to <code>(x2<sub>i</sub>, y2<sub>i</sub>)</code> with a cost equal to <code>cost<sub>i</sub></code>. You can use each special road any number of times.</p>\n\n<p>Return <em>the minimum cost required to go from</em> <code>(startX, startY)</code> to <code>(targetX, targetY)</code>.</p>\n\n<p>&nbsp;</p>\n<p><strong class=\"example\">Example 1:</strong></p>\n\n<pre>\n<strong>Input:</strong> start = [1,1], target = [4,5], specialRoads = [[1,2,3,3,2],[3,4,4,5,1]]\n<strong>Output:</strong> 5\n<strong>Explanation:</strong> The optimal path from (1,1) to (4,5) is the following:\n- (1,1) -&gt; (1,2). This move has a cost of |1 - 1| + |2 - 1| = 1.\n- (1,2) -&gt; (3,3). This move uses the first special edge, the cost is 2.\n- (3,3) -&gt; (3,4). This move has a cost of |3 - 3| + |4 - 3| = 1.\n- (3,4) -&gt; (4,5). This move uses the second special edge, the cost is 1.\nSo the total cost is 1 + 2 + 1 + 1 = 5.\nIt can be shown that we cannot achieve a smaller total cost than 5.\n</pre>\n\n<p><strong class=\"example\">Example 2:</strong></p>\n\n<pre>\n<strong>Input:</strong> start = [3,2], target = [5,7], specialRoads = [[3,2,3,4,4],[3,3,5,5,5],[3,4,5,6,6]]\n<strong>Output:</strong> 7\n<strong>Explanation:</strong> It is optimal to not use any special edges and go directly from the starting to the ending position with a cost |5 - 3| + |7 - 2| = 7.\n</pre>\n\n<p>&nbsp;</p>\n<p><strong>Constraints:</strong></p>\n\n<ul>\n\t<li><code>start.length == target.length == 2</code></li>\n\t<li><code>1 &lt;= startX &lt;= targetX &lt;= 10<sup>5</sup></code></li>\n\t<li><code>1 &lt;= startY &lt;= targetY &lt;= 10<sup>5</sup></code></li>\n\t<li><code>1 &lt;= specialRoads.length &lt;= 200</code></li>\n\t<li><code>specialRoads[i].length == 5</code></li>\n\t<li><code>startX &lt;= x1<sub>i</sub>, x2<sub>i</sub> &lt;= targetX</code></li>\n\t<li><code>startY &lt;= y1<sub>i</sub>, y2<sub>i</sub> &lt;= targetY</code></li>\n\t<li><code>1 &lt;= cost<sub>i</sub> &lt;= 10<sup>5</sup></code></li>\n</ul>\n",
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                    "code": "/**\n * @param {number[]} start\n * @param {number[]} target\n * @param {number[][]} specialRoads\n * @return {number}\n */\nvar minimumCost = function(start, target, specialRoads) {\n    \n};",
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                    "code": "class Solution {\n\n    /**\n     * @param Integer[] $start\n     * @param Integer[] $target\n     * @param Integer[][] $specialRoads\n     * @return Integer\n     */\n    function minimumCost($start, $target, $specialRoads) {\n        \n    }\n}",
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                    "code": "class Solution {\n    fun minimumCost(start: IntArray, target: IntArray, specialRoads: Array<IntArray>): Int {\n        \n    }\n}",
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                    "code": "# @param {Integer[]} start\n# @param {Integer[]} target\n# @param {Integer[][]} special_roads\n# @return {Integer}\ndef minimum_cost(start, target, special_roads)\n    \nend",
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                    "code": "impl Solution {\n    pub fn minimum_cost(start: Vec<i32>, target: Vec<i32>, special_roads: Vec<Vec<i32>>) -> i32 {\n        \n    }\n}",
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                    "code": "(define/contract (minimum-cost start target specialRoads)\n  (-> (listof exact-integer?) (listof exact-integer?) (listof (listof exact-integer?)) exact-integer?)\n\n  )",
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                    "code": "defmodule Solution do\n  @spec minimum_cost(start :: [integer], target :: [integer], special_roads :: [[integer]]) :: integer\n  def minimum_cost(start, target, special_roads) do\n\n  end\nend",
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                "It can be proven that it is optimal to go only to the positions that are either the start or the end of a special road or the target position.",
                "Consider all positions given to you as nodes in a graph, and the edges of the graph are the special roads.",
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update 2023-05-03 20:22:43 +08:00			`{`
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			`"title": "Minimum Cost of a Path With Special Roads",`
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			"content": "<p>You are given an array <code>start</code> where <code>start = [startX, startY]</code> represents your initial position <code>(startX, startY)</code> in a 2D space. You are also given the array <code>target</code> where <code>target = [targetX, targetY]</code> represents your target position <code>(targetX, targetY)</code>.</p>\n\n<p>The cost of going from a position <code>(x1, y1)</code> to any other position in the space <code>(x2, y2)</code> is <code>\|x2 - x1\| + \|y2 - y1\|</code>.</p>\n\n<p>There are also some special roads. You are given a 2D array <code>specialRoads</code> where <code>specialRoads[i] = [x1<sub>i</sub>, y1<sub>i</sub>, x2<sub>i</sub>, y2<sub>i</sub>, cost<sub>i</sub>]</code> indicates that the <code>i<sup>th</sup></code> special road can take you from <code>(x1<sub>i</sub>, y1<sub>i</sub>)</code> to <code>(x2<sub>i</sub>, y2<sub>i</sub>)</code> with a cost equal to <code>cost<sub>i</sub></code>. You can use each special road any number of times.</p>\n\n<p>Return <em>the minimum cost required to go from</em> <code>(startX, startY)</code> to <code>(targetX, targetY)</code>.</p>\n\n<p> </p>\n<p><strong class=\"example\">Example 1:</strong></p>\n\n<pre>\n<strong>Input:</strong> start = [1,1], target = [4,5], specialRoads = [[1,2,3,3,2],[3,4,4,5,1]]\n<strong>Output:</strong> 5\n<strong>Explanation:</strong> The optimal path from (1,1) to (4,5) is the following:\n- (1,1) -> (1,2). This move has a cost of \|1 - 1\| + \|2 - 1\| = 1.\n- (1,2) -> (3,3). This move uses the first special edge, the cost is 2.\n- (3,3) -> (3,4). This move has a cost of \|3 - 3\| + \|4 - 3\| = 1.\n- (3,4) -> (4,5). This move uses the second special edge, the cost is 1.\nSo the total cost is 1 + 2 + 1 + 1 = 5.\nIt can be shown that we cannot achieve a smaller total cost than 5.\n</pre>\n\n<p><strong class=\"example\">Example 2:</strong></p>\n\n<pre>\n<strong>Input:</strong> start = [3,2], target = [5,7], specialRoads = [[3,2,3,4,4],[3,3,5,5,5],[3,4,5,6,6]]\n<strong>Output:</strong> 7\n<strong>Explanation:</strong> It is optimal to not use any special edges and go directly from the starting to the ending position with a cost \|5 - 3\| + \|7 - 2\| = 7.\n</pre>\n\n<p> </p>\n<p><strong>Constraints:</strong></p>\n\n<ul>\n\t<li><code>start.length == target.length == 2</code></li>\n\t<li><code>1 <= startX <= targetX <= 10<sup>5</sup></code></li>\n\t<li><code>1 <= startY <= targetY <= 10<sup>5</sup></code></li>\n\t<li><code>1 <= specialRoads.length <= 200</code></li>\n\t<li><code>specialRoads[i].length == 5</code></li>\n\t<li><code>startX <= x1<sub>i</sub>, x2<sub>i</sub> <= targetX</code></li>\n\t<li><code>startY <= y1<sub>i</sub>, y2<sub>i</sub> <= targetY</code></li>\n\t<li><code>1 <= cost<sub>i</sub> <= 10<sup>5</sup></code></li>\n</ul>\n",
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"likes": 491,`
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update 2023-05-03 20:22:43 +08:00			`"isLiked": null,`
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			`"code": "/*\n @param {number[]} start\n * @param {number[]} target\n * @param {number[][]} specialRoads\n * @return {number}\n */\nvar minimumCost = function(start, target, specialRoads) {\n \n};",`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "TypeScript",`
			`"langSlug": "typescript",`
			`"code": "function minimumCost(start: number[], target: number[], specialRoads: number[][]): number {\n\n};",`
			`"__typename": "CodeSnippetNode"`
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			`"lang": "PHP",`
			`"langSlug": "php",`
			`"code": "class Solution {\n\n /*\n @param Integer[] $start\n * @param Integer[] $target\n * @param Integer[][] $specialRoads\n * @return Integer\n */\n function minimumCost($start, $target, $specialRoads) {\n \n }\n}",`
update 2023-05-03 20:22:43 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
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			`"lang": "Swift",`
			`"langSlug": "swift",`
			`"code": "class Solution {\n func minimumCost(_ start: [Int], _ target: [Int], _ specialRoads: [[Int]]) -> Int {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
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 minimumCost(start: IntArray, target: IntArray, specialRoads: Array<IntArray>): Int {\n \n }\n}",`
update 2023-05-03 20:22:43 +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 minimumCost(List<int> start, List<int> target, List<List<int>> specialRoads) {\n\n }\n}",`
update 2023-05-03 20:22:43 +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 minimumCost(start []int, target []int, specialRoads [][]int) int {\n \n}",`
update 2023-05-03 20:22:43 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
存量题库数据更新 2023-12-09 18:42:21 +08:00			`"lang": "Ruby",`
			`"langSlug": "ruby",`
			`"code": "# @param {Integer[]} start\n# @param {Integer[]} target\n# @param {Integer[][]} special_roads\n# @return {Integer}\ndef minimum_cost(start, target, special_roads)\n \nend",`
update 2023-05-03 20:22:43 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
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 minimumCost(start: Array[Int], target: Array[Int], specialRoads: Array[Array[Int]]): Int = {\n \n }\n}",`
update 2023-05-03 20:22:43 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
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 minimum_cost(start: Vec<i32>, target: Vec<i32>, special_roads: Vec<Vec<i32>>) -> i32 {\n \n }\n}",`
update 2023-05-03 20:22:43 +08:00			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Racket",`
			`"langSlug": "racket",`
			`"code": "(define/contract (minimum-cost start target specialRoads)\n (-> (listof exact-integer?) (listof exact-integer?) (listof (listof exact-integer?)) exact-integer?)\n\n )",`
			`"__typename": "CodeSnippetNode"`
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			`"lang": "Erlang",`
			`"langSlug": "erlang",`
			`"code": "-spec minimum_cost(Start :: [integer()], Target :: [integer()], SpecialRoads :: [[integer()]]) -> integer().\nminimum_cost(Start, Target, SpecialRoads) ->\n .",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Elixir",`
			`"langSlug": "elixir",`
			`"code": "defmodule Solution do\n @spec minimum_cost(start :: [integer], target :: [integer], special_roads :: [[integer]]) :: integer\n def minimum_cost(start, target, special_roads) do\n\n end\nend",`
			`"__typename": "CodeSnippetNode"`
			`}`
			`],`
update 2023-12-09 19:57:46 +08:00			`"stats": "{\"totalAccepted\": \"10.1K\", \"totalSubmission\": \"27.9K\", \"totalAcceptedRaw\": 10099, \"totalSubmissionRaw\": 27900, \"acRate\": \"36.2%\"}",`
update 2023-05-03 20:22:43 +08:00			`"hints": [`
			`"It can be proven that it is optimal to go only to the positions that are either the start or the end of a special road or the target position.",`
			`"Consider all positions given to you as nodes in a graph, and the edges of the graph are the special roads.",`
			`"Now the problem is equivalent to finding the shortest path in a directed graph."`
			`],`
			`"solution": null,`
			`"status": null,`
			`"sampleTestCase": "[1,1]\n[4,5]\n[[1,2,3,3,2],[3,4,4,5,1]]",`
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存量题库数据更新 2023-12-09 18:42:21 +08:00			"envInfo": "{\"cpp\": [\"C++\", \"<p>Compiled with <code> clang 11 </code> using the latest C++ 20 standard.</p>\\r\\n\\r\\n<p>Your code is compiled with level two optimization (<code>-O2</code>). <a href=\\\"https://github.com/google/sanitizers/wiki/AddressSanitizer\\\" target=\\\"_blank\\\">AddressSanitizer</a> is also enabled to help detect out-of-bounds and use-after-free bugs.</p>\\r\\n\\r\\n<p>Most standard library headers are already included automatically for your convenience.</p>\"], \"java\": [\"Java\", \"<p><code>OpenJDK 17</code>. Java 8 features such as lambda expressions and stream API can be used. </p>\\r\\n\\r\\n<p>Most standard library headers are already included automatically for your convenience.</p>\\r\\n<p>Includes <code>Pair</code> class from https://docs.oracle.com/javase/8/javafx/api/javafx/util/Pair.html.</p>\"], \"python\": [\"Python\", \"<p><code>Python 2.7.12</code>.</p>\\r\\n\\r\\n<p>Most libraries are already imported automatically for your convenience, such as <a href=\\\"https://docs.python.org/2/library/array.html\\\" target=\\\"_blank\\\">array</a>, <a href=\\\"https://docs.python.org/2/library/bisect.html\\\" target=\\\"_blank\\\">bisect</a>, <a href=\\\"https://docs.python.org/2/library/collections.html\\\" target=\\\"_blank\\\">collections</a>. If you need more libraries, you can import it yourself.</p>\\r\\n\\r\\n<p>For Map/TreeMap data structure, you may use <a href=\\\"http://www.grantjenks.com/docs/sortedcontainers/\\\" target=\\\"_blank\\\">sortedcontainers</a> library.</p>\\r\\n\\r\\n<p>Note that Python 2.7 <a href=\\\"https://www.python.org/dev/peps/pep-0373/\\\" target=\\\"_blank\\\">will not be maintained past 2020</a>. For the latest Python, please choose Python3 instead.</p>\"], \"c\": [\"C\", \"<p>Compiled with <code>gcc 8.2</code> using the gnu11 standard.</p>\\r\\n\\r\\n<p>Your code is compiled with level one optimization (<code>-O1</code>). <a href=\\\"https://github.com/google/sanitizers/wiki/AddressSanitizer\\\" target=\\\"_blank\\\">AddressSanitizer</a> is also enabled to help detect out-of-bounds and use-after-free bugs.</p>\\r\\n\\r\\n<p>Most standard library headers are already included automatically for your convenience.</p>\\r\\n\\r\\n<p>For hash table operations, you may use <a href=\\\"https://troydhanson.github.io/uthash/\\\" target=\\\"_blank\\\">uthash</a>. \\\"uthash.h\\\" is included by default. Below are some examples:</p>\\r\\n\\r\\n<p><b>1. Adding an item to a hash.</b>\\r\\n<pre>\\r\\nstruct hash_entry {\\r\\n int id; /* we'll use this field as the key /\\r\\n char name[10];\\r\\n UT_hash_handle hh; / makes this structure hashable /\\r\\n};\\r\\n\\r\\nstruct hash_entry users = NULL;\\r\\n\\r\\nvoid add_user(struct hash_entry s) {\\r\\n HASH_ADD_INT(users, id, s);\\r\\n}\\r\\n</pre>\\r\\n</p>\\r\\n\\r\\n<p><b>2. Looking up an item in a hash:</b>\\r\\n<pre>\\r\\nstruct hash_entry find_user(int user_id) {\\r\\n struct hash_entry s;\\r\\n HASH_FIND_INT(users, &user_id, s);\\r\\n return s;\\r\\n}\\r\\n</pre>\\r\\n</p>\\r\\n\\r\\n<p><b>3. Deleting an item in a hash:</b>\\r\\n<pre>\\r\\nvoid delete_user(struct hash_entry user) {\\r\\n HASH_DEL(users, user); \\r\\n}\\r\\n</pre>\\r\\n</p>\"], \"csharp\": [\"C#\", \"<p><a href=\\\"https://learn.microsoft.com/en-us/dotnet/csharp/whats-new/csharp-10\\\" target=\\\"_blank\\\">C# 10 with .NET 6 runtime</a></p>\"], \"javascript\": [\"JavaScript\", \"<p><code>Node.js 16.13.2</code>.</p>\\r\\n\\r\\n<p>Your code is run with <code>--harmony</code> flag, enabling <a href=\\\"http://node.green/\\\" target=\\\"_blank\\\">new ES6 features</a>.</p>\\r\\n\\r\\n<p><a href=\\\"https://lodash.com\\\" target=\\\"_blank\\\">lodash.js</a> library is included by default.</p>\\r\\n\\r\\n<p>For Priority Queue / Queue data structures, you may use 5.3.0 version of <a href=\\\"https://github.com/datastructures-js/priority-queue/tree/fb4fdb984834421279aeb081df7af624d17c2a03\\\" target=\\\"_blank\\\">datastructures-js/priority-queue</a> and 4.2.1 version of <a href=\\\"https://githu
update 2023-05-03 20:22:43 +08:00			`"libraryUrl": null,`
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