leetcode-problemset/leetcode/originData/make-lexicographically-smallest-array-by-swapping-elements.json

{
    "data": {
        "question": {
            "questionId": "3219",
            "questionFrontendId": "2948",
            "boundTopicId": null,
            "title": "Make Lexicographically Smallest Array by Swapping Elements",
            "titleSlug": "make-lexicographically-smallest-array-by-swapping-elements",
            "content": "<p>You are given a <strong>0-indexed</strong> array of <strong>positive</strong> integers <code>nums</code> and a <strong>positive</strong> integer <code>limit</code>.</p>\n\n<p>In one operation, you can choose any two indices <code>i</code> and <code>j</code> and swap <code>nums[i]</code> and <code>nums[j]</code> <strong>if</strong> <code>|nums[i] - nums[j]| &lt;= limit</code>.</p>\n\n<p>Return <em>the <strong>lexicographically smallest array</strong> that can be obtained by performing the operation any number of times</em>.</p>\n\n<p>An array <code>a</code> is lexicographically smaller than an array <code>b</code> if in the first position where <code>a</code> and <code>b</code> differ, array <code>a</code> has an element that is less than the corresponding element in <code>b</code>. For example, the array <code>[2,10,3]</code> is lexicographically smaller than the array <code>[10,2,3]</code> because they differ at index <code>0</code> and <code>2 &lt; 10</code>.</p>\n\n<p>&nbsp;</p>\n<p><strong class=\"example\">Example 1:</strong></p>\n\n<pre>\n<strong>Input:</strong> nums = [1,5,3,9,8], limit = 2\n<strong>Output:</strong> [1,3,5,8,9]\n<strong>Explanation:</strong> Apply the operation 2 times:\n- Swap nums[1] with nums[2]. The array becomes [1,3,5,9,8]\n- Swap nums[3] with nums[4]. The array becomes [1,3,5,8,9]\nWe cannot obtain a lexicographically smaller array by applying any more operations.\nNote that it may be possible to get the same result by doing different operations.\n</pre>\n\n<p><strong class=\"example\">Example 2:</strong></p>\n\n<pre>\n<strong>Input:</strong> nums = [1,7,6,18,2,1], limit = 3\n<strong>Output:</strong> [1,6,7,18,1,2]\n<strong>Explanation:</strong> Apply the operation 3 times:\n- Swap nums[1] with nums[2]. The array becomes [1,6,7,18,2,1]\n- Swap nums[0] with nums[4]. The array becomes [2,6,7,18,1,1]\n- Swap nums[0] with nums[5]. The array becomes [1,6,7,18,1,2]\nWe cannot obtain a lexicographically smaller array by applying any more operations.\n</pre>\n\n<p><strong class=\"example\">Example 3:</strong></p>\n\n<pre>\n<strong>Input:</strong> nums = [1,7,28,19,10], limit = 3\n<strong>Output:</strong> [1,7,28,19,10]\n<strong>Explanation:</strong> [1,7,28,19,10] is the lexicographically smallest array we can obtain because we cannot apply the operation on any two indices.\n</pre>\n\n<p>&nbsp;</p>\n<p><strong>Constraints:</strong></p>\n\n<ul>\n\t<li><code>1 &lt;= nums.length &lt;= 10<sup>5</sup></code></li>\n\t<li><code>1 &lt;= nums[i] &lt;= 10<sup>9</sup></code></li>\n\t<li><code>1 &lt;= limit &lt;= 10<sup>9</sup></code></li>\n</ul>\n",
            "translatedTitle": null,
            "translatedContent": null,
            "isPaidOnly": false,
            "difficulty": "Medium",
            "likes": 179,
            "dislikes": 9,
            "isLiked": null,
            "similarQuestions": "[{\"title\": \"Smallest String With Swaps\", \"titleSlug\": \"smallest-string-with-swaps\", \"difficulty\": \"Medium\", \"translatedTitle\": null}, {\"title\": \"Minimize Hamming Distance After Swap Operations\", \"titleSlug\": \"minimize-hamming-distance-after-swap-operations\", \"difficulty\": \"Medium\", \"translatedTitle\": null}]",
            "exampleTestcases": "[1,5,3,9,8]\n2\n[1,7,6,18,2,1]\n3\n[1,7,28,19,10]\n3",
            "categoryTitle": "Algorithms",
            "contributors": [],
            "topicTags": [
                {
                    "name": "Array",
                    "slug": "array",
                    "translatedName": null,
                    "__typename": "TopicTagNode"
                },
                {
                    "name": "Union Find",
                    "slug": "union-find",
                    "translatedName": null,
                    "__typename": "TopicTagNode"
                },
                {
                    "name": "Sorting",
                    "slug": "sorting",
                    "translatedName": null,
                    "__typename": "TopicTagNode"
                }
            ],
            "companyTagStats": null,
            "codeSnippets": [
                {
                    "lang": "C++",
                    "langSlug": "cpp",
                    "code": "class Solution {\npublic:\n    vector<int> lexicographicallySmallestArray(vector<int>& nums, int limit) {\n        \n    }\n};",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Java",
                    "langSlug": "java",
                    "code": "class Solution {\n    public int[] lexicographicallySmallestArray(int[] nums, int limit) {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Python",
                    "langSlug": "python",
                    "code": "class Solution(object):\n    def lexicographicallySmallestArray(self, nums, limit):\n        \"\"\"\n        :type nums: List[int]\n        :type limit: int\n        :rtype: List[int]\n        \"\"\"\n        ",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Python3",
                    "langSlug": "python3",
                    "code": "class Solution:\n    def lexicographicallySmallestArray(self, nums: List[int], limit: int) -> List[int]:\n        ",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "C",
                    "langSlug": "c",
                    "code": "/**\n * Note: The returned array must be malloced, assume caller calls free().\n */\nint* lexicographicallySmallestArray(int* nums, int numsSize, int limit, int* returnSize) {\n    \n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "C#",
                    "langSlug": "csharp",
                    "code": "public class Solution {\n    public int[] LexicographicallySmallestArray(int[] nums, int limit) {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "JavaScript",
                    "langSlug": "javascript",
                    "code": "/**\n * @param {number[]} nums\n * @param {number} limit\n * @return {number[]}\n */\nvar lexicographicallySmallestArray = function(nums, limit) {\n    \n};",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "TypeScript",
                    "langSlug": "typescript",
                    "code": "function lexicographicallySmallestArray(nums: number[], limit: number): number[] {\n    \n};",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "PHP",
                    "langSlug": "php",
                    "code": "class Solution {\n\n    /**\n     * @param Integer[] $nums\n     * @param Integer $limit\n     * @return Integer[]\n     */\n    function lexicographicallySmallestArray($nums, $limit) {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Swift",
                    "langSlug": "swift",
                    "code": "class Solution {\n    func lexicographicallySmallestArray(_ nums: [Int], _ limit: Int) -> [Int] {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Kotlin",
                    "langSlug": "kotlin",
                    "code": "class Solution {\n    fun lexicographicallySmallestArray(nums: IntArray, limit: Int): IntArray {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Dart",
                    "langSlug": "dart",
                    "code": "class Solution {\n  List<int> lexicographicallySmallestArray(List<int> nums, int limit) {\n    \n  }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Go",
                    "langSlug": "golang",
                    "code": "func lexicographicallySmallestArray(nums []int, limit int) []int {\n    \n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Ruby",
                    "langSlug": "ruby",
                    "code": "# @param {Integer[]} nums\n# @param {Integer} limit\n# @return {Integer[]}\ndef lexicographically_smallest_array(nums, limit)\n    \nend",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Scala",
                    "langSlug": "scala",
                    "code": "object Solution {\n    def lexicographicallySmallestArray(nums: Array[Int], limit: Int): Array[Int] = {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Rust",
                    "langSlug": "rust",
                    "code": "impl Solution {\n    pub fn lexicographically_smallest_array(nums: Vec<i32>, limit: i32) -> Vec<i32> {\n        \n    }\n}",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Racket",
                    "langSlug": "racket",
                    "code": "(define/contract (lexicographically-smallest-array nums limit)\n  (-> (listof exact-integer?) exact-integer? (listof exact-integer?))\n  )",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Erlang",
                    "langSlug": "erlang",
                    "code": "-spec lexicographically_smallest_array(Nums :: [integer()], Limit :: integer()) -> [integer()].\nlexicographically_smallest_array(Nums, Limit) ->\n  .",
                    "__typename": "CodeSnippetNode"
                },
                {
                    "lang": "Elixir",
                    "langSlug": "elixir",
                    "code": "defmodule Solution do\n  @spec lexicographically_smallest_array(nums :: [integer], limit :: integer) :: [integer]\n  def lexicographically_smallest_array(nums, limit) do\n    \n  end\nend",
                    "__typename": "CodeSnippetNode"
                }
            ],
            "stats": "{\"totalAccepted\": \"6.2K\", \"totalSubmission\": \"17K\", \"totalAcceptedRaw\": 6244, \"totalSubmissionRaw\": 17002, \"acRate\": \"36.7%\"}",
            "hints": [
                "Construct a virtual graph where all elements in <code>nums</code> are nodes and the pairs satisfying the condition have an edge between them.",
                "Instead of constructing all edges, we only care about the connected components.",
                "Can we use DSU?",
                "Sort <code>nums</code>. Now we just need to consider if the consecutive elements have an edge to check if they belong to the same connected component. Hence, all connected components become a list of position-consecutive elements after sorting.",
                "For each index of <code>nums</code> from <code>0</code> to <code>nums.length - 1</code> we can change it to the current minimum value we have in its connected component and remove that value from the connected component."
            ],
            "solution": null,
            "status": null,
            "sampleTestCase": "[1,5,3,9,8]\n2",
            "metaData": "{\n  \"name\": \"lexicographicallySmallestArray\",\n  \"params\": [\n    {\n      \"name\": \"nums\",\n      \"type\": \"integer[]\"\n    },\n    {\n      \"type\": \"integer\",\n      \"name\": \"limit\"\n    }\n  ],\n  \"return\": {\n    \"type\": \"integer[]\"\n  }\n}",
            "judgerAvailable": true,
            "judgeType": "large",
            "mysqlSchemas": [],
            "enableRunCode": true,
            "enableTestMode": false,
            "enableDebugger": true,
            "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
            "libraryUrl": null,
            "adminUrl": null,
            "challengeQuestion": null,
            "__typename": "QuestionNode"
        }
    }
}
update 2023-12-09 01:16:38 +08:00			`{`
			`"data": {`
			`"question": {`
			`"questionId": "3219",`
			`"questionFrontendId": "2948",`
			`"boundTopicId": null,`
			`"title": "Make Lexicographically Smallest Array by Swapping Elements",`
			`"titleSlug": "make-lexicographically-smallest-array-by-swapping-elements",`
			"content": "<p>You are given a <strong>0-indexed</strong> array of <strong>positive</strong> integers <code>nums</code> and a <strong>positive</strong> integer <code>limit</code>.</p>\n\n<p>In one operation, you can choose any two indices <code>i</code> and <code>j</code> and swap <code>nums[i]</code> and <code>nums[j]</code> <strong>if</strong> <code>\|nums[i] - nums[j]\| <= limit</code>.</p>\n\n<p>Return <em>the <strong>lexicographically smallest array</strong> that can be obtained by performing the operation any number of times</em>.</p>\n\n<p>An array <code>a</code> is lexicographically smaller than an array <code>b</code> if in the first position where <code>a</code> and <code>b</code> differ, array <code>a</code> has an element that is less than the corresponding element in <code>b</code>. For example, the array <code>[2,10,3]</code> is lexicographically smaller than the array <code>[10,2,3]</code> because they differ at index <code>0</code> and <code>2 < 10</code>.</p>\n\n<p> </p>\n<p><strong class=\"example\">Example 1:</strong></p>\n\n<pre>\n<strong>Input:</strong> nums = [1,5,3,9,8], limit = 2\n<strong>Output:</strong> [1,3,5,8,9]\n<strong>Explanation:</strong> Apply the operation 2 times:\n- Swap nums[1] with nums[2]. The array becomes [1,3,5,9,8]\n- Swap nums[3] with nums[4]. The array becomes [1,3,5,8,9]\nWe cannot obtain a lexicographically smaller array by applying any more operations.\nNote that it may be possible to get the same result by doing different operations.\n</pre>\n\n<p><strong class=\"example\">Example 2:</strong></p>\n\n<pre>\n<strong>Input:</strong> nums = [1,7,6,18,2,1], limit = 3\n<strong>Output:</strong> [1,6,7,18,1,2]\n<strong>Explanation:</strong> Apply the operation 3 times:\n- Swap nums[1] with nums[2]. The array becomes [1,6,7,18,2,1]\n- Swap nums[0] with nums[4]. The array becomes [2,6,7,18,1,1]\n- Swap nums[0] with nums[5]. The array becomes [1,6,7,18,1,2]\nWe cannot obtain a lexicographically smaller array by applying any more operations.\n</pre>\n\n<p><strong class=\"example\">Example 3:</strong></p>\n\n<pre>\n<strong>Input:</strong> nums = [1,7,28,19,10], limit = 3\n<strong>Output:</strong> [1,7,28,19,10]\n<strong>Explanation:</strong> [1,7,28,19,10] is the lexicographically smallest array we can obtain because we cannot apply the operation on any two indices.\n</pre>\n\n<p> </p>\n<p><strong>Constraints:</strong></p>\n\n<ul>\n\t<li><code>1 <= nums.length <= 10<sup>5</sup></code></li>\n\t<li><code>1 <= nums[i] <= 10<sup>9</sup></code></li>\n\t<li><code>1 <= limit <= 10<sup>9</sup></code></li>\n</ul>\n",
			`"translatedTitle": null,`
			`"translatedContent": null,`
			`"isPaidOnly": false,`
			`"difficulty": "Medium",`
update 2023-12-09 19:57:46 +08:00			`"likes": 179,`
update 2023-12-09 01:16:38 +08:00			`"dislikes": 9,`
			`"isLiked": null,`
			`"similarQuestions": "[{\"title\": \"Smallest String With Swaps\", \"titleSlug\": \"smallest-string-with-swaps\", \"difficulty\": \"Medium\", \"translatedTitle\": null}, {\"title\": \"Minimize Hamming Distance After Swap Operations\", \"titleSlug\": \"minimize-hamming-distance-after-swap-operations\", \"difficulty\": \"Medium\", \"translatedTitle\": null}]",`
			`"exampleTestcases": "[1,5,3,9,8]\n2\n[1,7,6,18,2,1]\n3\n[1,7,28,19,10]\n3",`
			`"categoryTitle": "Algorithms",`
			`"contributors": [],`
			`"topicTags": [`
			`{`
			`"name": "Array",`
			`"slug": "array",`
			`"translatedName": null,`
			`"__typename": "TopicTagNode"`
			`},`
			`{`
			`"name": "Union Find",`
			`"slug": "union-find",`
			`"translatedName": null,`
			`"__typename": "TopicTagNode"`
			`},`
			`{`
			`"name": "Sorting",`
			`"slug": "sorting",`
			`"translatedName": null,`
			`"__typename": "TopicTagNode"`
			`}`
			`],`
			`"companyTagStats": null,`
			`"codeSnippets": [`
			`{`
			`"lang": "C++",`
			`"langSlug": "cpp",`
			`"code": "class Solution {\npublic:\n vector<int> lexicographicallySmallestArray(vector<int>& nums, int limit) {\n \n }\n};",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Java",`
			`"langSlug": "java",`
			`"code": "class Solution {\n public int[] lexicographicallySmallestArray(int[] nums, int limit) {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Python",`
			`"langSlug": "python",`
			`"code": "class Solution(object):\n def lexicographicallySmallestArray(self, nums, limit):\n \"\"\"\n :type nums: List[int]\n :type limit: int\n :rtype: List[int]\n \"\"\"\n ",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Python3",`
			`"langSlug": "python3",`
			`"code": "class Solution:\n def lexicographicallySmallestArray(self, nums: List[int], limit: int) -> List[int]:\n ",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "C",`
			`"langSlug": "c",`
			`"code": "/*\n Note: The returned array must be malloced, assume caller calls free().\n /\nint lexicographicallySmallestArray(int* nums, int numsSize, int limit, int* returnSize) {\n \n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "C#",`
			`"langSlug": "csharp",`
			`"code": "public class Solution {\n public int[] LexicographicallySmallestArray(int[] nums, int limit) {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "JavaScript",`
			`"langSlug": "javascript",`
			`"code": "/*\n @param {number[]} nums\n * @param {number} limit\n * @return {number[]}\n */\nvar lexicographicallySmallestArray = function(nums, limit) {\n \n};",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "TypeScript",`
			`"langSlug": "typescript",`
			`"code": "function lexicographicallySmallestArray(nums: number[], limit: number): number[] {\n \n};",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "PHP",`
			`"langSlug": "php",`
			`"code": "class Solution {\n\n /*\n @param Integer[] $nums\n * @param Integer $limit\n * @return Integer[]\n */\n function lexicographicallySmallestArray($nums, $limit) {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Swift",`
			`"langSlug": "swift",`
			`"code": "class Solution {\n func lexicographicallySmallestArray(_ nums: [Int], _ limit: Int) -> [Int] {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Kotlin",`
			`"langSlug": "kotlin",`
			`"code": "class Solution {\n fun lexicographicallySmallestArray(nums: IntArray, limit: Int): IntArray {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Dart",`
			`"langSlug": "dart",`
			`"code": "class Solution {\n List<int> lexicographicallySmallestArray(List<int> nums, int limit) {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Go",`
			`"langSlug": "golang",`
			`"code": "func lexicographicallySmallestArray(nums []int, limit int) []int {\n \n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Ruby",`
			`"langSlug": "ruby",`
			`"code": "# @param {Integer[]} nums\n# @param {Integer} limit\n# @return {Integer[]}\ndef lexicographically_smallest_array(nums, limit)\n \nend",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Scala",`
			`"langSlug": "scala",`
			`"code": "object Solution {\n def lexicographicallySmallestArray(nums: Array[Int], limit: Int): Array[Int] = {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Rust",`
			`"langSlug": "rust",`
			`"code": "impl Solution {\n pub fn lexicographically_smallest_array(nums: Vec<i32>, limit: i32) -> Vec<i32> {\n \n }\n}",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Racket",`
			`"langSlug": "racket",`
			`"code": "(define/contract (lexicographically-smallest-array nums limit)\n (-> (listof exact-integer?) exact-integer? (listof exact-integer?))\n )",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Erlang",`
			`"langSlug": "erlang",`
			`"code": "-spec lexicographically_smallest_array(Nums :: [integer()], Limit :: integer()) -> [integer()].\nlexicographically_smallest_array(Nums, Limit) ->\n .",`
			`"__typename": "CodeSnippetNode"`
			`},`
			`{`
			`"lang": "Elixir",`
			`"langSlug": "elixir",`
			`"code": "defmodule Solution do\n @spec lexicographically_smallest_array(nums :: [integer], limit :: integer) :: [integer]\n def lexicographically_smallest_array(nums, limit) do\n \n end\nend",`
			`"__typename": "CodeSnippetNode"`
			`}`
			`],`
update 2023-12-09 19:57:46 +08:00			`"stats": "{\"totalAccepted\": \"6.2K\", \"totalSubmission\": \"17K\", \"totalAcceptedRaw\": 6244, \"totalSubmissionRaw\": 17002, \"acRate\": \"36.7%\"}",`
update 2023-12-09 01:16:38 +08:00			`"hints": [`
			`"Construct a virtual graph where all elements in <code>nums</code> are nodes and the pairs satisfying the condition have an edge between them.",`
			`"Instead of constructing all edges, we only care about the connected components.",`
			`"Can we use DSU?",`
			`"Sort <code>nums</code>. Now we just need to consider if the consecutive elements have an edge to check if they belong to the same connected component. Hence, all connected components become a list of position-consecutive elements after sorting.",`
			`"For each index of <code>nums</code> from <code>0</code> to <code>nums.length - 1</code> we can change it to the current minimum value we have in its connected component and remove that value from the connected component."`
			`],`
			`"solution": null,`
			`"status": null,`
			`"sampleTestCase": "[1,5,3,9,8]\n2",`
			`"metaData": "{\n \"name\": \"lexicographicallySmallestArray\",\n \"params\": [\n {\n \"name\": \"nums\",\n \"type\": \"integer[]\"\n },\n {\n \"type\": \"integer\",\n \"name\": \"limit\"\n }\n ],\n \"return\": {\n \"type\": \"integer[]\"\n }\n}",`
			`"judgerAvailable": true,`
			`"judgeType": "large",`
			`"mysqlSchemas": [],`
			`"enableRunCode": true,`
			`"enableTestMode": false,`
			`"enableDebugger": true,`
			"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
			`"libraryUrl": null,`
			`"adminUrl": null,`
			`"challengeQuestion": null,`
			`"__typename": "QuestionNode"`
			`}`
			`}`
			`}`