diff --git a/doc/source/basicgameplay/codingcontracts.rst b/doc/source/basicgameplay/codingcontracts.rst index f57bee54e..596f6033f 100644 --- a/doc/source/basicgameplay/codingcontracts.rst +++ b/doc/source/basicgameplay/codingcontracts.rst @@ -84,176 +84,225 @@ The following is a list of all of the problem types that a Coding Contract can c The list contains the name of (i.e. the value returned by :js:func:`getContractType`) and a brief summary of the problem it poses. -+------------------------------------+------------------------------------------------------------------------------------------+ -| Name | Problem Summary | -+====================================+==========================================================================================+ -| Find Largest Prime Factor | | Given a number, find its largest prime factor. A prime factor | -| | | is a factor that is a prime number. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Subarray with Maximum Sum | | Given an array of integers, find the contiguous subarray (containing | -| | | at least one number) which has the largest sum and return that sum. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Total Ways to Sum | | Given a number, how many different distinct ways can that number be written as | -| | | a sum of at least two positive integers? | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Total Ways to Sum II | | You are given an array with two elements. The first element is an integer n. | -| | | The second element is an array of numbers representing the set of available integers. | -| | | How many different distinct ways can that number n be written as | -| | | a sum of integers contained in the given set? | -| | | You may use each integer in the set zero or more times. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Spiralize Matrix | | Given an array of array of numbers representing a 2D matrix, return the | -| | | elements of that matrix in clockwise spiral order. | -| | | | -| | | Example: The spiral order of | -| | | | -| | | [1, 2, 3, 4] | -| | | [5, 6, 7, 8] | -| | | [9, 10, 11, 12] | -| | | | -| | | is [1, 2, 3, 4, 8, 12, 11, 10, 9, 5, 6, 7] | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Array Jumping Game | | You are given an array of integers where each element represents the | -| | | maximum possible jump distance from that position. For example, if you | -| | | are at position i and your maximum jump length is n, then you can jump | -| | | to any position from i to i+n. | -| | | | -| | | Assuming you are initially positioned at the start of the array, determine | -| | | whether you are able to reach the last index of the array. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Array Jumping Game II | | You are given an array of integers where each element represents the | -| | | maximum possible jump distance from that position. For example, if you | -| | | are at position i and your maximum jump length is n, then you can jump | -| | | to any position from i to i+n. | -| | | | -| | | Assuming you are initially positioned at the start of the array, determine | -| | | the minimum number of jumps to reach the end of the array. | -| | | | -| | | If it's impossible to reach the end, then the answer should be 0. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Merge Overlapping Intervals | | Given an array of intervals, merge all overlapping intervals. An interval | -| | | is an array with two numbers, where the first number is always less than | -| | | the second (e.g. [1, 5]). | -| | | | -| | | The intervals must be returned in ASCENDING order. | -| | | | -| | | Example: | -| | | [[1, 3], [8, 10], [2, 6], [10, 16]] | -| | | merges into [[1, 6], [8, 16]] | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Generate IP Addresses | | Given a string containing only digits, return an array with all possible | -| | | valid IP address combinations that can be created from the string. | -| | | | -| | | An octet in the IP address cannot begin with '0' unless the number itself | -| | | is actually 0. For example, "192.168.010.1" is NOT a valid IP. | -| | | | -| | | Examples: | -| | | 25525511135 -> [255.255.11.135, 255.255.111.35] | -| | | 1938718066 -> [193.87.180.66] | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Algorithmic Stock Trader I | | You are given an array of numbers representing stock prices, where the | -| | | i-th element represents the stock price on day i. | -| | | | -| | | Determine the maximum possible profit you can earn using at most one | -| | | transaction (i.e. you can buy an sell the stock once). If no profit | -| | | can be made, then the answer should be 0. Note that you must buy the stock | -| | | before you can sell it. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Algorithmic Stock Trader II | | You are given an array of numbers representing stock prices, where the | -| | | i-th element represents the stock price on day i. | -| | | | -| | | Determine the maximum possible profit you can earn using as many transactions | -| | | as you'd like. A transaction is defined as buying and then selling one | -| | | share of the stock. Note that you cannot engage in multiple transactions at | -| | | once. In other words, you must sell the stock before you buy it again. If no | -| | | profit can be made, then the answer should be 0. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Algorithmic Stock Trader III | | You are given an array of numbers representing stock prices, where the | -| | | i-th element represents the stock price on day i. | -| | | | -| | | Determine the maximum possible profit you can earn using at most two | -| | | transactions. A transaction is defined as buying and then selling one share | -| | | of the stock. Note that you cannot engage in multiple transactions at once. | -| | | In other words, you must sell the stock before you buy it again. If no profit | -| | | can be made, then the answer should be 0. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Algorithmic Stock Trader IV | | You are given an array with two elements. The first element is an integer k. | -| | | The second element is an array of numbers representing stock prices, where the | -| | | i-th element represents the stock price on day i. | -| | | | -| | | Determine the maximum possible profit you can earn using at most k transactions. | -| | | A transaction is defined as buying and then selling one share of the stock. | -| | | Note that you cannot engage in multiple transactions at once. In other words, | -| | | you must sell the stock before you can buy it. If no profit can be made, then | -| | | the answer should be 0. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Minimum Path Sum in a Triangle | | You are given a 2D array of numbers (array of array of numbers) that represents a | -| | | triangle (the first array has one element, and each array has one more element than | -| | | the one before it, forming a triangle). Find the minimum path sum from the top to the | -| | | bottom of the triangle. In each step of the path, you may only move to adjacent | -| | | numbers in the row below. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Unique Paths in a Grid I | | You are given an array with two numbers: [m, n]. These numbers represent a | -| | | m x n grid. Assume you are initially positioned in the top-left corner of that | -| | | grid and that you are trying to reach the bottom-right corner. On each step, | -| | | you may only move down or to the right. | -| | | | -| | | -| | | Determine how many unique paths there are from start to finish. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Unique Paths in a Grid II | | You are given a 2D array of numbers (array of array of numbers) representing | -| | | a grid. The 2D array contains 1's and 0's, where 1 represents an obstacle and | -| | | -| | | 0 represents a free space. | -| | | | -| | | Assume you are initially positioned in top-left corner of that grid and that you | -| | | are trying to reach the bottom-right corner. In each step, you may only move down | -| | | or to the right. Furthermore, you cannot move onto spaces which have obstacles. | -| | | | -| | | Determine how many unique paths there are from start to finish. | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Shortest Path in a Grid | | You are given a 2D array of numbers (array of array of numbers) representing | -| | | a grid. The 2D array contains 1's and 0's, where 1 represents an obstacle and | -| | | 0 represents a free space. | -| | | | -| | | Assume you are initially positioned in top-left corner of that grid and that you | -| | | are trying to reach the bottom-right corner. In each step, you may move to the up, | -| | | down, left or right. Furthermore, you cannot move onto spaces which have obstacles. | -| | | | -| | | Determine if paths exist from start to destination, and find the shortest one. | -| | | | -| | | Examples: | -| | | [[0,1,0,0,0], | -| | | [0,0,0,1,0]] -> "DRRURRD" | -| | | [[0,1], | -| | | [1,0]] -> "" | -| | | | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Sanitize Parentheses in Expression | | Given a string with parentheses and letters, remove the minimum number of invalid | -| | | parentheses in order to validate the string. If there are multiple minimal ways | -| | | to validate the string, provide all of the possible results. | -| | | | -| | | The answer should be provided as an array of strings. If it is impossible to validate | -| | | the string, the result should be an array with only an empty string. | -| | | | -| | | Examples: | -| | | ()())() -> [()()(), (())()] | -| | | (a)())() -> [(a)()(), (a())()] | -| | | )( -> [""] | -+------------------------------------+------------------------------------------------------------------------------------------+ -| Find All Valid Math Expressions | | You are given a string which contains only digits between 0 and 9 as well as a target | -| | | number. Return all possible ways you can add the +, -, and * operators to the string | -| | | of digits such that it evaluates to the target number. | -| | | | -| | | The answer should be provided as an array of strings containing the valid expressions. | -| | | | -| | | NOTE: Numbers in an expression cannot have leading 0's | -| | | NOTE: The order of evaluation expects script operator precedence | -| | | | -| | | Examples: | -| | | Input: digits = "123", target = 6 | -| | | Output: [1+2+3, 1*2*3] | -| | | | -| | | Input: digits = "105", target = 5 | -| | | Output: [1*0+5, 10-5] | -+------------------------------------+------------------------------------------------------------------------------------------+ ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Name | Problem Summary | ++=========================================+==========================================================================================+ +| Find Largest Prime Factor | | Given a number, find its largest prime factor. A prime factor | +| | | is a factor that is a prime number. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Subarray with Maximum Sum | | Given an array of integers, find the contiguous subarray (containing | +| | | at least one number) which has the largest sum and return that sum. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Total Ways to Sum | | Given a number, how many different distinct ways can that number be written as | +| | | a sum of at least two positive integers? | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Total Ways to Sum II | | You are given an array with two elements. The first element is an integer n. | +| | | The second element is an array of numbers representing the set of available integers. | +| | | How many different distinct ways can that number n be written as | +| | | a sum of integers contained in the given set? | +| | | You may use each integer in the set zero or more times. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Spiralize Matrix | | Given an array of array of numbers representing a 2D matrix, return the | +| | | elements of that matrix in clockwise spiral order. | +| | | | +| | | Example: The spiral order of | +| | | | +| | | [1, 2, 3, 4] | +| | | [5, 6, 7, 8] | +| | | [9, 10, 11, 12] | +| | | | +| | | is [1, 2, 3, 4, 8, 12, 11, 10, 9, 5, 6, 7] | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Array Jumping Game | | You are given an array of integers where each element represents the | +| | | maximum possible jump distance from that position. For example, if you | +| | | are at position i and your maximum jump length is n, then you can jump | +| | | to any position from i to i+n. | +| | | | +| | | Assuming you are initially positioned at the start of the array, determine | +| | | whether you are able to reach the last index of the array. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Array Jumping Game II | | You are given an array of integers where each element represents the | +| | | maximum possible jump distance from that position. For example, if you | +| | | are at position i and your maximum jump length is n, then you can jump | +| | | to any position from i to i+n. | +| | | | +| | | Assuming you are initially positioned at the start of the array, determine | +| | | the minimum number of jumps to reach the end of the array. | +| | | | +| | | If it's impossible to reach the end, then the answer should be 0. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Merge Overlapping Intervals | | Given an array of intervals, merge all overlapping intervals. An interval | +| | | is an array with two numbers, where the first number is always less than | +| | | the second (e.g. [1, 5]). | +| | | | +| | | The intervals must be returned in ASCENDING order. | +| | | | +| | | Example: | +| | | [[1, 3], [8, 10], [2, 6], [10, 16]] | +| | | merges into [[1, 6], [8, 16]] | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Generate IP Addresses | | Given a string containing only digits, return an array with all possible | +| | | valid IP address combinations that can be created from the string. | +| | | | +| | | An octet in the IP address cannot begin with '0' unless the number itself | +| | | is actually 0. For example, "192.168.010.1" is NOT a valid IP. | +| | | | +| | | Examples: | +| | | 25525511135 -> [255.255.11.135, 255.255.111.35] | +| | | 1938718066 -> [193.87.180.66] | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Algorithmic Stock Trader I | | You are given an array of numbers representing stock prices, where the | +| | | i-th element represents the stock price on day i. | +| | | | +| | | Determine the maximum possible profit you can earn using at most one | +| | | transaction (i.e. you can buy an sell the stock once). If no profit | +| | | can be made, then the answer should be 0. Note that you must buy the stock | +| | | before you can sell it. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Algorithmic Stock Trader II | | You are given an array of numbers representing stock prices, where the | +| | | i-th element represents the stock price on day i. | +| | | | +| | | Determine the maximum possible profit you can earn using as many transactions | +| | | as you'd like. A transaction is defined as buying and then selling one | +| | | share of the stock. Note that you cannot engage in multiple transactions at | +| | | once. In other words, you must sell the stock before you buy it again. If no | +| | | profit can be made, then the answer should be 0. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Algorithmic Stock Trader III | | You are given an array of numbers representing stock prices, where the | +| | | i-th element represents the stock price on day i. | +| | | | +| | | Determine the maximum possible profit you can earn using at most two | +| | | transactions. A transaction is defined as buying and then selling one share | +| | | of the stock. Note that you cannot engage in multiple transactions at once. | +| | | In other words, you must sell the stock before you buy it again. If no profit | +| | | can be made, then the answer should be 0. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Algorithmic Stock Trader IV | | You are given an array with two elements. The first element is an integer k. | +| | | The second element is an array of numbers representing stock prices, where the | +| | | i-th element represents the stock price on day i. | +| | | | +| | | Determine the maximum possible profit you can earn using at most k transactions. | +| | | A transaction is defined as buying and then selling one share of the stock. | +| | | Note that you cannot engage in multiple transactions at once. In other words, | +| | | you must sell the stock before you can buy it. If no profit can be made, then | +| | | the answer should be 0. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Minimum Path Sum in a Triangle | | You are given a 2D array of numbers (array of array of numbers) that represents a | +| | | triangle (the first array has one element, and each array has one more element than | +| | | the one before it, forming a triangle). Find the minimum path sum from the top to the | +| | | bottom of the triangle. In each step of the path, you may only move to adjacent | +| | | numbers in the row below. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Unique Paths in a Grid I | | You are given an array with two numbers: [m, n]. These numbers represent a | +| | | m x n grid. Assume you are initially positioned in the top-left corner of that | +| | | grid and that you are trying to reach the bottom-right corner. On each step, | +| | | you may only move down or to the right. | +| | | | +| | | | +| | | Determine how many unique paths there are from start to finish. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Unique Paths in a Grid II | | You are given a 2D array of numbers (array of array of numbers) representing | +| | | a grid. The 2D array contains 1's and 0's, where 1 represents an obstacle and | +| | | | +| | | 0 represents a free space. | +| | | | +| | | Assume you are initially positioned in top-left corner of that grid and that you | +| | | are trying to reach the bottom-right corner. In each step, you may only move down | +| | | or to the right. Furthermore, you cannot move onto spaces which have obstacles. | +| | | | +| | | Determine how many unique paths there are from start to finish. | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Shortest Path in a Grid | | You are given a 2D array of numbers (array of array of numbers) representing | +| | | a grid. The 2D array contains 1's and 0's, where 1 represents an obstacle and | +| | | 0 represents a free space. | +| | | | +| | | Assume you are initially positioned in top-left corner of that grid and that you | +| | | are trying to reach the bottom-right corner. In each step, you may move to the up, | +| | | down, left or right. Furthermore, you cannot move onto spaces which have obstacles. | +| | | | +| | | Determine if paths exist from start to destination, and find the shortest one. | +| | | | +| | | Examples: | +| | | [[0,1,0,0,0], | +| | | [0,0,0,1,0]] -> "DRRURRD" | +| | | [[0,1], | +| | | [1,0]] -> "" | +| | | | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Sanitize Parentheses in Expression | | Given a string with parentheses and letters, remove the minimum number of invalid | +| | | parentheses in order to validate the string. If there are multiple minimal ways | +| | | to validate the string, provide all of the possible results. | +| | | | +| | | The answer should be provided as an array of strings. If it is impossible to validate | +| | | the string, the result should be an array with only an empty string. | +| | | | +| | | Examples: | +| | | ()())() -> [()()(), (())()] | +| | | (a)())() -> [(a)()(), (a())()] | +| | | )( -> [""] | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Find All Valid Math Expressions | | You are given a string which contains only digits between 0 and 9 as well as a target | +| | | number. Return all possible ways you can add the +, -, and * operators to the string | +| | | of digits such that it evaluates to the target number. | +| | | | +| | | The answer should be provided as an array of strings containing the valid expressions. | +| | | | +| | | NOTE: Numbers in an expression cannot have leading 0's | +| | | NOTE: The order of evaluation expects script operator precedence | +| | | | +| | | Examples: | +| | | Input: digits = "123", target = 6 | +| | | Output: [1+2+3, 1*2*3] | +| | | | +| | | Input: digits = "105", target = 5 | +| | | Output: [1*0+5, 10-5] | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| HammingCodes: Integer to Encoded Binary | | You are given a decimal value. | +| | | Convert it into a binary string and encode it as a 'Hamming-Code'. eg: | +| | | Value 8 will result into binary '1000', which will be encoded | +| | | with the pattern 'pppdpddd', where p is a paritybit and d a databit, | +| | | or '10101' (Value 21) will result into (pppdpdddpd) '1001101011'. | +| | | NOTE: You need an parity Bit on Index 0 as an 'overall'-paritybit. | +| | | NOTE 2: You should watch the HammingCode-video from 3Blue1Brown, which | +| | | explains the 'rule' of encoding, | +| | | including the first Index parity-bit mentioned on the first note. | +| | | Now the only one rule for this encoding: | +| | | It's not allowed to add additional leading '0's to the binary value | +| | | That means, the binary value has to be encoded as it is | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| HammingCodes: Encoded Binary to Integer | | You are given an encoded binary string. | +| | | Treat it as a Hammingcode with 1 'possible' error on an random Index. | +| | | Find the 'possible' wrong bit, fix it and extract the decimal value, which is | +| | | hidden inside the string.\n\n", | +| | | Note: The length of the binary string is dynamic, but it's encoding/decoding is | +| | | following Hammings 'rule'\n", | +| | | Note 2: Index 0 is an 'overall' parity bit. Watch the Hammingcode-video from | +| | | 3Blue1Brown for more information\n", | +| | | Note 3: There's a ~55% chance for an altered Bit. So... MAYBE | +| | | there is an altered Bit 😉\n", | +| | | Extranote for automation: return the decimal value as a string", | ++-----------------------------------------+------------------------------------------------------------------------------------------+ +| Proper 2-Coloring of a Graph | | You are given data, representing a graph. Note that "graph", as used here, refers to | +| | | the field of graph theory, and has no relation to statistics or plotting. | +| | | | +| | | The first element of the data represents the number of vertices in the graph. Each | +| | | vertex is a unique number between 0 and ${data[0] - 1}. The next element of the data | +| | | represents the edges of the graph. | +| | | | +| | | Two vertices u,v in a graph are said to be adjacent if there exists an edge [u,v]. | +| | | Note that an edge [u,v] is the same as an edge [v,u], as order does not matter. | +| | | | +| | | You must construct a 2-coloring of the graph, meaning that you have to assign each | +| | | vertex in the graph a "color", either 0 or 1, such that no two adjacent vertices have | +| | | the same color. Submit your answer in the form of an array, where element i | +| | | represents the color of vertex i. If it is impossible to construct a 2-coloring of | +| | | the given graph, instead submit an empty array. | +| | | | +| | | Examples: | +| | | | +| | | Input: [4, [[0, 2], [0, 3], [1, 2], [1, 3]]] | +| | | Output: [0, 0, 1, 1] | +| | | | +| | | Input: [3, [[0, 1], [0, 2], [1, 2]]] | +| | | Output: [] | ++-----------------------------------------+------------------------------------------------------------------------------------------+