# The empty string test.assert_equals(morse_code(''), '') # Simple. test.assert_equals(morse_code('sos'),'...---...') # Spaces. test.assert_equals(morse_code('hello world'),'......-...-..--- .-----.-..-..-..') # Capital letters. test.assert_equals(morse_code('YOU PASSED'),'-.-----..- .--..-.......-..') # All digits. test.assert_equals(morse_code('0123456789'),'-----.----..---...--....-.....-....--...---..----.') # All letters. test.assert_equals(morse_code('The quick brown fox jumps over the lazy dog'),'-..... --.-..-..-.-.-.- -....-.---.---. ..-.----..- .---..---.--.... ---...-..-. -..... .-...---..-.-- -..-----.')1 + # The empty string 2 + test.assert_equals(morse_code(''), '') 1 1 # Simple. 2 2 test.assert_equals(morse_code('sos'),'...---...') 3 3 # Spaces. 4 4 test.assert_equals(morse_code('hello world'),'......-...-..--- .-----.-..-..-..') 5 5 # Capital letters. 6 6 test.assert_equals(morse_code('YOU PASSED'),'-.-----..- .--..-.......-..') 7 7 # All digits. 8 8 test.assert_equals(morse_code('0123456789'),'-----.----..---...--....-.....-....--...---..----.') 9 9 # All letters. 10 10 test.assert_equals(morse_code('The quick brown fox jumps over the lazy dog'),'-..... --.-..-..-.-.-.- -....-.---.---. ..-.----..- .---..---.--.... ---...-..-. -..... .-...---..-.-- -..-----.')
// I went ahead and added support for larger numbers over 999. // Uncomment lines below to get automatic support of bigger numbers: const bigNumbers = [ "", // "thousand", // "million", // "billion", // "trillion", // "quadrillion" ]; function Generrate(number) { // the only time we pronounce zero is when the number is zero itself if (number === 0) return "zero"; let result = ""; if (number < 0) { result += "negative "; number *= -1; } const thousandMultiples = []; let thousands = number; while (thousands) { thousandMultiples.push(thousands % 1000); thousands = parseInt(thousands / 1000); } if (thousandMultiples.length > bigNumbers.length) { return "unsupported number"; // return "Sorry, can't pronounce. The number is too big"; } const wordsArray = thousandMultiples.map( (elem, ind) => pronounceHundreds(elem) + " " + bigNumbers[ind] ); return (result + wordsArray.reverse().reduce((acc, cur) => acc + " " + cur)).trim(); } function pronounceHundreds(i) { const hundreds = parseInt(i / 100); const tens = i % 100; let result = pronounceOnes(hundreds); if (hundreds) { result += " hundred"; } // if number is not a pure hundred, add space and tens if (tens) { if (hundreds) { result += " and "; // added 'and' to pass the test. however not needed in American. // result += " "; } result += pronounceTens(tens); } return result; } function pronounceTens(i) { const tens = parseInt(i / 10); const ones = i % 10; let result = ""; const tensWords = [ "", pronounceTeens(ones), "twenty", "thirty", "fourty", "fifty", "sixty", "seventy", "eighty", "ninety" ]; result += tensWords[tens]; // numbers 21-99 need to be hyphenated if (ones && tens > 1) { result += "-"; } if (ones && tens != 1) { result += pronounceOnes(ones); } return result; } function pronounceTeens(i) { return [ "ten", "eleven", "twelve", "thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen" ][i]; } function pronounceOnes(i) { return [ "", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine" ][i]; }1 - function Generrate (n) 2 - { 1 + // I went ahead and added support for larger numbers over 999. 2 + // Uncomment lines below to get automatic support of bigger numbers: 3 3 4 - var out = ""; 5 - 6 - var str_arrOfDigits = n.toString().split(""); 7 - 8 - if (str_arrOfDigits[0] == "-") 9 - { 10 - out += "negative "; 11 - str_arrOfDigits.splice(0,1); 12 - } 13 - 14 - switch (str_arrOfDigits.length) { 15 - case 1: 16 - out += Digits(str_arrOfDigits[0]); 17 - break; 18 - case 2: 19 - out += getDoubleDigit(str_arrOfDigits); 20 - break; 21 - case 3: 22 - out += getTrippleDigit(str_arrOfDigits) 23 - break; 24 - default: 25 - return "unsupported number"; 26 - break; 27 - } 28 - return out; 29 - }; 30 - function Digits(n) { 31 - return ["zero", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", "thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen"][n]; 32 - }; 33 - 34 - function tens(n) { 35 - return ["zero", "ten", "twenty", "thirty", "fourty", "fifty", "sixty", "seventy", "eighty", "ninety"][n]; 36 - }; 37 - 38 - function getDoubleDigit (arr) 39 - { 40 - var out = ""; 41 - 42 - if (arr[0] == "1") { 43 - out = Digits(arr.join().replace("," ,"")); 44 - } 45 - else { 46 - if (arr[0] != "0") 47 - out = tens(arr[0]) + (arr[1] != "0"? " " + Digits(arr[1]): ""); 48 - else 49 - out = Digits(arr[1]); 50 - } 51 - return out; 4 + const bigNumbers = [ 5 + "", 6 + // "thousand", 7 + // "million", 8 + // "billion", 9 + // "trillion", 10 + // "quadrillion" 11 + ]; 12 + 13 + function Generrate(number) { 14 + // the only time we pronounce zero is when the number is zero itself 15 + if (number === 0) return "zero"; 16 + 17 + let result = ""; 18 + 19 + if (number < 0) { 20 + result += "negative "; 21 + number *= -1; 22 + } 23 + 24 + const thousandMultiples = []; 25 + let thousands = number; 26 + 27 + while (thousands) { 28 + thousandMultiples.push(thousands % 1000); 29 + thousands = parseInt(thousands / 1000); 30 + } 31 + 32 + if (thousandMultiples.length > bigNumbers.length) { 33 + return "unsupported number"; 34 + // return "Sorry, can't pronounce. The number is too big"; 35 + } 36 + 37 + const wordsArray = thousandMultiples.map( 38 + (elem, ind) => pronounceHundreds(elem) + " " + bigNumbers[ind] 39 + ); 40 + 41 + return (result + wordsArray.reverse().reduce((acc, cur) => acc + " " + cur)).trim(); 42 + } 43 + 44 + 45 + function pronounceHundreds(i) { 46 + const hundreds = parseInt(i / 100); 47 + const tens = i % 100; 48 + 49 + let result = pronounceOnes(hundreds); 50 + if (hundreds) { 51 + result += " hundred"; 52 + } 53 + 54 + // if number is not a pure hundred, add space and tens 55 + if (tens) { 56 + if (hundreds) { 57 + result += " and "; // added 'and' to pass the test. however not needed in American. 58 + // result += " "; 59 + } 60 + result += pronounceTens(tens); 61 + } 62 + 63 + return result; 64 + } 65 + 66 + 67 + function pronounceTens(i) { 68 + const tens = parseInt(i / 10); 69 + const ones = i % 10; 70 + let result = ""; 71 + 72 + const tensWords = [ 73 + "", 74 + pronounceTeens(ones), 75 + "twenty", 76 + "thirty", 77 + "fourty", 78 + "fifty", 79 + "sixty", 80 + "seventy", 81 + "eighty", 82 + "ninety" 83 + ]; 84 + result += tensWords[tens]; 85 + 86 + // numbers 21-99 need to be hyphenated 87 + if (ones && tens > 1) { 88 + result += "-"; 89 + } 90 + 91 + if (ones && tens != 1) { 92 + result += pronounceOnes(ones); 93 + } 94 + return result; 95 + } 96 + 97 + 98 + function pronounceTeens(i) { 99 + return [ 100 + "ten", 101 + "eleven", 102 + "twelve", 103 + "thirteen", 104 + "fourteen", 105 + "fifteen", 106 + "sixteen", 107 + "seventeen", 108 + "eighteen", 109 + "nineteen" 110 + ][i]; 52 52 } 53 53 54 - function getTrippleDigit (arr) 55 - { 56 - var firstDigit = Digits(arr[0]); 57 - var doubleDigits = getDoubleDigit(arr.splice(1)); 58 - return (firstDigit != "zero"? firstDigit + " hundred" : "") + (firstDigit != "zero" && doubleDigits != "zero"? " and " + doubleDigits : (doubleDigits != "zero"? doubleDigits : "")); 113 + 114 + function pronounceOnes(i) { 115 + return [ 116 + "", 117 + "one", 118 + "two", 119 + "three", 120 + "four", 121 + "five", 122 + "six", 123 + "seven", 124 + "eight", 125 + "nine" 126 + ][i]; 59 59 }
Ok, it took me a while to understand what is meant to be done here.
For what I've got, you would like to sort string of integers by their weight, which means sum of all its digits.
If I am right - I've found out that there was a mistake in tests. You have placed 2000 after 11's. As they are equal according to weight (2+0+0+0 = 1+1), they are sorted to be next to each other. The one which is placed closer to the beginning of input string will be first - so 2000 is right to be first here.
By the way I've written my own snippet of code which does what you wanted (I guess) in less number of code lines.
Hope you find it usefull.
import java.util.stream.IntStream; import java.util.stream.Collectors; import java.util.Arrays; public class WeightSort { public static String orderWeight(String strng) { return Arrays.stream(strng.split(" ")) .sorted((current, next) -> Integer.compare(countWeight(current), countWeight(next))) .collect(Collectors.joining(" ")); } private static int countWeight(String str){ return Arrays.stream(str.split("")) .mapToInt(character -> Integer.parseInt(character)) .sum(); } }1 - import java.util.*; 1 + import java.util.stream.IntStream; 2 + import java.util.stream.Collectors; 3 + import java.util.Arrays; 2 2 3 3 public class WeightSort { 4 4 5 5 public static String orderWeight(String strng) { 6 - if( strng =="2000 10003 1234000 44444444 9999 11 11 22 123"){ 7 - return "11 11 2000 10003 22 123 1234000 44444444 9999"; 8 - } 9 - if(strng ==""){ 10 - return ""; 11 - } 12 - System.out.println(strng); 13 - String[] str= strng.split(" "); 14 - int[][] tab = new int[3][30]; 15 - for(int i=0;i<str.length; i++){ 16 - int sum=0; 17 - String ss=str[i]; 18 - for(int j=0; j< ss.length(); j++){ 19 - sum+= Integer.parseInt(Character.toString(ss.charAt(j))); 20 - } 21 - tab[0][i]=Integer.parseInt(ss); 22 - tab[1][i]=sum; 23 - tab[2][i]=i+1; 24 - } 25 - int len = 0,m=0; 26 - while(tab[0][m] != 0){ 27 - len++; 28 - m++; 29 - } 30 - int[][] tab2= new int[3][len]; 31 - for(int n=0; n<len;n++){ 32 - tab2[0][n]=tab[0][n]; 33 - tab2[1][n]=tab[1][n]; 34 - tab2[2][n]=tab[2][n]; 35 - } 36 - int temp=0; 37 - for (int k = 1; k < tab2[0].length; k++) { 38 - for(int j = k ; j > 0 ; j--){ 39 - if(tab2[1][j] < tab2[1][j-1]){ 40 - temp = tab2[1][j]; 41 - tab2[1][j] = tab2[1][j-1]; 42 - tab2[1][j-1] = temp; 43 - temp = tab2[0][j]; 44 - tab2[0][j] = tab2[0][j-1]; 45 - tab2[0][j-1] = temp; 46 - temp = tab2[2][j]; 47 - tab2[2][j] = tab2[2][j-1]; 48 - tab2[2][j-1] = temp; 49 - } 50 - if (tab2[1][j] == tab2[1][j-1] && tab2[2][j] < tab2[2][j-1]){ 51 - temp = tab2[0][j]; 52 - tab2[0][j] = tab2[0][j-1]; 53 - tab2[0][j-1] = temp; 54 - temp = tab2[1][j]; 55 - tab2[1][j] = tab2[1][j-1]; 56 - tab2[1][j-1] = temp; 57 - temp = tab2[2][j]; 58 - tab2[2][j] = tab2[2][j-1]; 59 - tab2[2][j-1] = temp; 60 - } 61 - } 62 - } 63 - String ret=""; 64 - for(int ll=0; ll<len; ll++){ 65 - System.out.println(tab2[0][ll]+":"+tab2[1][ll]+":"+tab2[2][ll]); 66 - ret+= tab2[0][ll]+" "; 67 - } 68 - return ret.substring(0, ret.length() - 1); 8 + return Arrays.stream(strng.split(" ")) 9 + .sorted((current, next) -> Integer.compare(countWeight(current), countWeight(next))) 10 + .collect(Collectors.joining(" ")); 69 69 } 12 + 13 + private static int countWeight(String str){ 14 + return Arrays.stream(str.split("")) 15 + .mapToInt(character -> Integer.parseInt(character)) 16 + .sum(); 17 + } 70 70 }
import static org.junit.Assert.*; import org.junit.Test; public class WeightSortTest { @Test public void BasicTests() { System.out.println("****** Basic Tests ******"); assertEquals("2000 103 123 4444 99", WeightSort.orderWeight("103 123 4444 99 2000")); assertEquals("2000 11 11 10003 22 123 1234000 44444444 9999", WeightSort.orderWeight("2000 10003 1234000 44444444 9999 11 11 22 123")); } }1 1 import static org.junit.Assert.*; 2 2 import org.junit.Test; 3 3 4 4 public class WeightSortTest { 5 5 6 6 @Test 7 7 public void BasicTests() { 8 8 System.out.println("****** Basic Tests ******"); 9 9 assertEquals("2000 103 123 4444 99", WeightSort.orderWeight("103 123 4444 99 2000")); 10 - assertEquals("11 11 2000 10003 22 123 1234000 44444444 9999", WeightSort.orderWeight("2000 10003 1234000 44444444 9999 11 11 22 123")); 10 + assertEquals("2000 11 11 10003 22 123 1234000 44444444 9999", WeightSort.orderWeight("2000 10003 1234000 44444444 9999 11 11 22 123")); 11 11 } 12 12 }
use std::iter::Iterator; use std::collections::{BTreeMap, btree_map}; // we can use "impl I" when codewars adds rust 1.26 // instead of boxing the iterators and returning an btree_map::IntoIter fn reduce<TK, TV, F, I> (v : Box<I>, s : TV, f : F) -> btree_map::IntoIter<TK, TV> where F : Fn(TV, TV) -> TV, TK : Eq + Ord, TV : Clone, I : Iterator<Item=(TK, TV)>, { let mut m: BTreeMap<TK, TV> = BTreeMap::new(); for (k, x) in *v { if let Some(p) = m.remove(&k) { m.insert(k, f(x, p)); } else { m.insert(k, f(x, s.clone())); } } m.into_iter() }1 - fn reduce<TK, TV, TS, F>(v : Vec<(TK, TV)>, 2 - s : TS, 3 - f : F) -> Vec<(TK, TV)> 4 - where F : Fn(TS, TV) -> TS { 5 - // Code 6 - vec![] 1 + use std::iter::Iterator; 2 + use std::collections::{BTreeMap, btree_map}; 3 + 4 + // we can use "impl I" when codewars adds rust 1.26 5 + // instead of boxing the iterators and returning an btree_map::IntoIter 6 + fn reduce<TK, TV, F, I> (v : Box<I>, s : TV, f : F) -> btree_map::IntoIter<TK, TV> 7 + where 8 + F : Fn(TV, TV) -> TV, 9 + TK : Eq + Ord, 10 + TV : Clone, 11 + I : Iterator<Item=(TK, TV)>, 12 + { 13 + let mut m: BTreeMap<TK, TV> = BTreeMap::new(); 14 + for (k, x) in *v { 15 + if let Some(p) = m.remove(&k) { 16 + m.insert(k, f(x, p)); 17 + } else { 18 + m.insert(k, f(x, s.clone())); 19 + } 20 + } 21 + m.into_iter() 7 7 }
use std::collections::HashSet; #[test] fn returns_summariesed_word_count() { let unreduced = Box::new(vec![("a", 2), ("b", 1), ("a", 1), ("x", 5), ("b", 9)].into_iter()); let reduced = reduce(unreduced, 0, |s, v| s + v); // items in "reduced" are in no particular order, compare using set comparison let reduced_set: HashSet<(&str, i32)> = reduced.collect(); let expected: HashSet<(&str, i32)> = vec![("a", 3), ("b", 10), ("x", 5)].into_iter().collect(); assert_eq!(reduced_set, expected); }1 - // Rust test example: 2 - // TODO: replace with your own tests (TDD), these are just how-to examples. 3 - // See: https://doc.rust-lang.org/book/testing.html 1 + use std::collections::HashSet; 4 4 5 5 #[test] 6 6 fn returns_summariesed_word_count() { 7 - assert_eq!(reduce(vec![("a", 2), ("b", 1), ("a", 1)], 8 - 0, 9 - |s, v| s + v), vec![("a", 3), ("b", 1)]) 5 + let unreduced = Box::new(vec![("a", 2), ("b", 1), ("a", 1), ("x", 5), ("b", 9)].into_iter()); 6 + let reduced = reduce(unreduced, 0, |s, v| s + v); 7 + // items in "reduced" are in no particular order, compare using set comparison 8 + let reduced_set: HashSet<(&str, i32)> = reduced.collect(); 9 + let expected: HashSet<(&str, i32)> = vec![("a", 3), ("b", 10), ("x", 5)].into_iter().collect(); 10 + assert_eq!(reduced_set, expected); 10 10 }
eğer parametreden verilen metin değer içinde tüm karakterler benzersiz ise true, tekrar eden bir karakter var ise false değer dönmeli.
Küçük-büyük karaketer fark etmez.
isIsogram "Dermatoglyphics" == true
isIsogram "moose" == false
isIsogram "aba" == false
using System;
using System.Linq;
public class Kata
{
public static bool IsIsogram(string str)
{
//return str.ToLower().Distinct().Count()==str.Length;
}
}using NUnit.Framework;
using System;
using System.Collections.Generic;
[TestFixture]
public class BasicTests
{
private static IEnumerable<TestCaseData> testCases
{
get
{
yield return new TestCaseData("Dermatoglyphics").Returns(true);
yield return new TestCaseData("isogram").Returns(true);
yield return new TestCaseData("moose").Returns(false);
yield return new TestCaseData("isIsogram").Returns(false);
yield return new TestCaseData("aba").Returns(false);
yield return new TestCaseData("moOse").Returns(false);
yield return new TestCaseData("thumbscrewjapingly").Returns(true);
yield return new TestCaseData("").Returns(true);
}
}
[Test, TestCaseSource("testCases")]
public bool Test(string str) => Kata.IsIsogram(str);
}Surprisingly there are only three numbers that can be written as the sum of fourth powers of their digits:
1634 = 1^4 + 6^4 + 3^4 + 4^4
8208 = 8^4 + 2^4 + 0^4 + 8^4
9474 = 9^4 + 4^4 + 7^4 + 4^4
As 1 = 1^4 is not a sum it is not included.
The sum of these numbers is 1634 + 8208 + 9474 = 19316.
Find the sum of all the numbers that can be written as the sum of fifth powers of their digits (largest number is 6 digits long).
function result() { let ans = []; let fivePow = 1; let sumOfPows = 0; while(fivePow < 999999) { fivePow++; sumOfPows = fivePow.toString().split('').reverse().reduce((a,v,i) => a + Math.pow(v,5),0); if(sumOfPows == fivePow) ans.push(fivePow); } return ans.reduce((a,v) => a + v,0); }1 - const result = () => 2 - Array.from(new Array(194980),(val,index)=>index) 3 - .filter(a => a == a.toString().split("") 4 - .map(e => Math.pow(parseInt(e), 5)) 5 - .reduce((a, b) => a+b)) 6 - .reduce((a,b) => a+b) - 1; 1 + function result() { 2 + let ans = []; 3 + let fivePow = 1; 4 + let sumOfPows = 0; 5 + while(fivePow < 999999) { 6 + fivePow++; 7 + sumOfPows = fivePow.toString().split('').reverse().reduce((a,v,i) => a + Math.pow(v,5),0); 8 + if(sumOfPows == fivePow) ans.push(fivePow); 9 + } 10 + return ans.reduce((a,v) => a + v,0); 11 + }
describe("Solution", function(){ it("The sum should be equal to our verified solution", function(){ Test.assertEquals(result(), 443839); }); });1 - // TODO: Replace examples and use TDD development by writing your own tests 2 - 3 - // These are some CW specific test methods available: 4 - // Test.expect(boolean, [optional] message) 5 - // Test.assertEquals(actual, expected, [optional] message) 6 - // Test.assertSimilar(actual, expected, [optional] message) 7 - // Test.assertNotEquals(actual, expected, [optional] message) 8 - 9 - // NodeJS assert is also automatically required for you. 10 - // assert(true) 11 - // assert.strictEqual({a: 1}, {a: 1}) 12 - // assert.deepEqual({a: [{b: 1}]}, {a: [{b: 1}]}) 13 - 14 - // You can also use Chai (http://chaijs.com/) by requiring it yourself 15 - // var expect = require("chai").expect; 16 - // var assert = require("chai").assert; 17 - // require("chai").should(); 18 - 19 19 describe("Solution", function(){ 20 20 it("The sum should be equal to our verified solution", function(){ 21 21 Test.assertEquals(result(), 443839); 22 22 }); 23 23 });
Strings
Suppose you have a string that looks something like this "1 + 2 * (2 - (3.1415 / 2.7^(2.7 + x)))" and you want to know where each of the nested expressions starts and ends. You can use ParseNestedness().
ParseNestedness() requires 3 arguments:
char * Sring - the string you want parsed
int StringLen - the length of the string you want parsed
char[2] ExprBounds - a 2-char array of arbitrary expression boundary symbols like {'(', ')'}, or it can even be {'a', ':'}
The fundtion creates an array of ints A where each {A[i], A[i+1]} represent the start and the end offsets of a nested expression starting with the innermost.
So the nesting map for the string "(1+2) * (3+(4+5))" will be [0, 4, 9, 13, 6, 14], which can be used to rewrite the expression in the correct order of execution.
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
void ParseNestedness(char* String, int StringLen, char ExprBounds[2], int* NestingMap)
{
int NestingMapLast = 0;
int BoundsStack[StringLen];
int BoundsStackLast = 0;
for(int ch = 0; ch < StringLen; ++ch)
{
if(String[ch] == ExprBounds[0])
{
BoundsStack[BoundsStackLast++] = ch;
}
else if(String[ch] == ExprBounds[1])
{
NestingMap[NestingMapLast++] = BoundsStack[--BoundsStackLast];
NestingMap[NestingMapLast++] = ch;
}
}
return;
}
int main()
{
char* TestString = "(-1+0)*(1+(2+(3+4)))*(5+6)";
char ExprBounds[2] = {'(', ')'};
int* NestingMap = (int*)malloc(sizeof(int) * 10);
ParseNestedness(TestString, strlen(TestString), ExprBounds, NestingMap);
for(int i = 0; i < 10; ++i)
{
printf("%i ", NestingMap[i]);
}
printf("\n");
return 0;
}Few links
using 'map' to iterate over an array
It can replace a for loop, basically
Shorter syntax to write functions (ECMAscript 2015)
(ECMAscript 2015)
Writing test cases here is not that easy , since everything is random
const generateComment = array => array.map(x=>x[Math.floor(Math.random() * x.length)]).join` ` // console.log(generateComment([['hi,', 'hello,', 'hey,'], ['how are'], ['you', 'ya'], ['doing', 'going'], ['?', '?!', '']]));1 - var generateComment = function (array){ 2 - var z; 3 - var k = []; 4 - for (var i = 0; i < array.length; i++) { 5 - z = Math.floor(Math.random() * array[i].length); 6 - if (array[i][z][array.length - 1] == ',') { 7 - k.push(array[i][z]); 8 - } else { 9 - k.push(array[i][z] + ' '); 10 - } 11 - }; 12 - return k.join(''); 13 - }; 14 - //console.log(generateComment([['hi,', 'hello,', 'hey,'], ['how are'], ['you', 'ya'], ['doing', 'going'], ['?', '?!', '']])); 1 + const generateComment = array => array.map(x=>x[Math.floor(Math.random() * x.length)]).join` ` 2 + 3 + 4 + // console.log(generateComment([['hi,', 'hello,', 'hey,'], ['how are'], ['you', 'ya'], ['doing', 'going'], ['?', '?!', '']]));
Interview Questions
Algorithms
def swapPixel(array, index1, index2): temp = getPixel(array, index1) putPixel(array, index1, getPixel(array, index2)) putPixel(array, index2, temp) def horizontalFlipPair(array, index): return (int((len(array)/2)+((len(array)/2)-int(index/len(array[0]))))-1)*len(array[0])+index%len(array[0]) def simpleFlipPair(array, index): return int(2*(((len(array)-1)/2-int(index/len(array[0])))*len(array[0]))+index) def flipImage(array): for i in range(int(len(array)/2*len(array[0]))): swapPixel(array, i, simpleFlipPair(array, i))1 1 def swapPixel(array, index1, index2): 2 2 temp = getPixel(array, index1) 3 3 putPixel(array, index1, getPixel(array, index2)) 4 4 putPixel(array, index2, temp) 5 5 6 6 def horizontalFlipPair(array, index): 7 7 return (int((len(array)/2)+((len(array)/2)-int(index/len(array[0]))))-1)*len(array[0])+index%len(array[0]) 8 8 9 - def flipImage(array): 10 - for i in range(int(len(array)*len(array[0])/2)): 11 - swapPixel(array, i, horizontalFlipPair(array, i)) 12 - 13 13 def simpleFlipPair(array, index): 14 - w = len(array[0]) 15 - m = (len(array)-1)/2 16 - l = int(index/w) 17 - a = (m-l)*w 18 - return int(2*(a)+index) 10 + return int(2*(((len(array)-1)/2-int(index/len(array[0])))*len(array[0]))+index) 19 19 20 20 def flipImage(array): 21 21 for i in range(int(len(array)/2*len(array[0]))): 22 22 swapPixel(array, i, simpleFlipPair(array, i)) 23 23 24 24 25 25
Changed Contract to be a struct because if the public fields are all comparable then you can just ask for equality. There is probably a better way to return the contract string though.
using System; using System.Collections.Generic; using System.Linq; public enum Quality { SD, HD, UHD } public class TV { private struct Contract { public static Contract Premium = new Contract(4, Quality.UHD); public static Contract Standard = new Contract(2, Quality.HD); public static Contract Essential = new Contract(1, Quality.SD); public int Number; public Quality Quality; public Contract(int number, Quality quality) { Number = number; Quality = quality; } } public static string GetContract(int numDevices, Quality quality) { var desiredContract = new Contract(numDevices, quality); return desiredContract.Equals(Contract.Premium) ? "PREMIUM" : desiredContract.Equals(Contract.Standard) ? "STANDARD" : desiredContract.Equals(Contract.Essential) ? "ESSENTIAL" : "INVALID"; } }1 1 using System; 2 2 using System.Collections.Generic; 3 3 using System.Linq; 4 4 5 5 public enum Quality { SD, HD, UHD } 6 6 7 7 public class TV 8 8 { 9 - private class Contract 9 + private struct Contract 10 10 { 11 - public string Type; 12 - public Func<int, Quality, bool> Condition; 13 - 14 - public static readonly IList<Contract> Types = 15 - new List<Contract> 16 - { 17 - new Contract { Type = "PREMIUM", Condition = (numDevices, quality) => numDevices == 4 && quality == Quality.UHD }, 18 - new Contract { Type = "STANDARD", Condition = (numDevices, quality) => numDevices == 2 && quality == Quality.HD }, 19 - new Contract { Type = "ESSENTIAL", Condition = (numDevices, quality) => numDevices == 1 && quality == Quality.SD }, 20 - new Contract { Type = "INVALID", Condition = (numDevices, quality) => true } 21 - }; 11 + public static Contract Premium = new Contract(4, Quality.UHD); 12 + public static Contract Standard = new Contract(2, Quality.HD); 13 + public static Contract Essential = new Contract(1, Quality.SD); 14 + 15 + public int Number; 16 + public Quality Quality; 17 + 18 + public Contract(int number, Quality quality) { Number = number; Quality = quality; } 22 22 } 23 23 24 24 public static string GetContract(int numDevices, Quality quality) 25 25 { 26 - return Contract.Types.First(contract => contract.Condition(numDevices, quality)).Type; 23 + var desiredContract = new Contract(numDevices, quality); 24 + 25 + return desiredContract.Equals(Contract.Premium) ? "PREMIUM" : 26 + desiredContract.Equals(Contract.Standard) ? "STANDARD" : 27 + desiredContract.Equals(Contract.Essential) ? "ESSENTIAL" : 28 + "INVALID"; 27 27 } 28 28 }
Simplified
def AmIYelling(input_sentence): return all([ x.isupper() for x in input_sentence if x.isalpha() ])1 1 def AmIYelling(input_sentence): 2 - return len([l for l in input_sentence if ((l.isalpha() and l.isupper())or not l.isalpha())]) == len(input_sentence) 2 + return all([ x.isupper() for x in input_sentence if x.isalpha() ])
Fundamentals
Arrays
function findOnly(arr) { let result = 0; arr.forEach((i) => { result = i ^ result; }); return result; }1 - function getSum(array) { 2 - return array.reduce((total, num) => total += num); 1 + function findOnly(arr) { 2 + let result = 0; 3 + arr.forEach((i) => { 4 + result = i ^ result; 5 + }); 6 + return result; 3 3 }
Test.assertEquals(findOnly([1,2,3,1,2,3,4]), 4, "looks like its wrong."); Test.assertEquals(findOnly([5,5,6,6,1,15,15,10,10]), 1, "looks like its wrong."); Test.assertEquals(findOnly([-1,-1,-1,10,15,10,15]), -1, "looks like its wrong.");1 - Test.assertEquals(getSum([5,9,4,1]), 19, "looks like its wrong."); 2 - Test.assertEquals(getSum([4,0,4,50,8]), 66, "looks like its wrong."); 3 - Test.assertEquals(getSum([5,9,4,1,9,1,1,1,4,10]), 45, "looks like its wrong."); 1 + Test.assertEquals(findOnly([1,2,3,1,2,3,4]), 4, "looks like its wrong."); 2 + Test.assertEquals(findOnly([5,5,6,6,1,15,15,10,10]), 1, "looks like its wrong."); 3 + Test.assertEquals(findOnly([-1,-1,-1,10,15,10,15]), -1, "looks like its wrong.");
import java.lang.Math; public class BiggerNum{ /** * @param a integer of param1 * @param b integer of param2 * @return the bigger integer of a and b * If a equals b, return either one */ public static int compare(int a, int b) { return Math.max(a,b); } }1 + import java.lang.Math; 1 1 public class BiggerNum{ 2 2 3 3 /** 4 4 * @param a integer of param1 5 5 * @param b integer of param2 6 6 * @return the bigger integer of a and b ... lines 7 to 12 have been collapsed. expand 7 7 * If a equals b, return either one 8 8 */ 9 9 public static int compare(int a, int b) { 10 10 return Math.max(a,b); 11 11 } 12 12 }
Alternative using lists utilizing previous idea of reversion to avoid sorting. Missing test for number with integer square root added.
from math import sqrt def divisors(n): fa = [i for i in range(1, int(sqrt(n)) + 1) if not (n%i)] fa.extend([n//i for i in reversed(fa) if n//i > i]) return fa1 1 from math import sqrt 2 2 def divisors(n): 3 - fa={i for i in range(1,int(sqrt(n)) + 1) if not(n%i)} 4 - ct={n//i for i in fa} 5 - return sorted(fa|ct) 3 + fa = [i for i in range(1, int(sqrt(n)) + 1) if not (n%i)] 4 + fa.extend([n//i for i in reversed(fa) if n//i > i]) 5 + return fa
from math import sqrt, floor def divisors_check(n): fact = []; for i in range(1, int(floor(sqrt(n))) + 1): if not(n % i): fact.append(i) if n / i != i: fact.append(n / i) fact.sort() return fact test.describe( "Static Cases" ) test.it( "n = 4" ) test.assert_equals(divisors(4), [1, 2, 4], 'Naive concatenation of lo [1,2] and high [2,4] factors will produce duplicity [1,2,2,4]') test.it( "n = 200" ) test.assert_equals(divisors(200), [1, 2, 4, 5, 8, 10, 20, 25, 40, 50, 100, 200]) test.it( "n = 560") test.assert_equals(divisors(560), [1, 2, 4, 5, 7, 8, 10, 14, 16, 20, 28, 35, 40, 56, 70, 80, 112, 140, 280, 560]) test.it("n = 755") test.assert_equals(divisors(755), [1, 5, 151, 755]) from random import randint test.describe( "Random Tests") test.it ("More than 1000 Random Tests with challenging values up to 1000000000(10e9)") for h in range(0,1000): n = randint(1000, 1000000000) result = divisors_check(n) res = divisors(n) test.it("Testing for = " + str(n)) test.assert_equals(res, result)... lines 1 to 9 have been collapsed. expand 1 1 from math import sqrt, floor 2 2 3 3 def divisors_check(n): 4 4 fact = []; 5 5 for i in range(1, int(floor(sqrt(n))) + 1): 6 6 if not(n % i): 7 7 fact.append(i) 8 8 if n / i != i: 9 9 fact.append(n / i) 10 10 fact.sort() 11 11 return fact 12 12 13 13 14 14 test.describe( "Static Cases" ) 15 15 16 + test.it( "n = 4" ) 17 + test.assert_equals(divisors(4), [1, 2, 4], 'Naive concatenation of lo [1,2] and high [2,4] factors will produce duplicity [1,2,2,4]') 18 + 16 16 test.it( "n = 200" ) 17 17 test.assert_equals(divisors(200), [1, 2, 4, 5, 8, 10, 20, 25, 40, 50, 100, 200]) 18 18 19 19 test.it( "n = 560") 20 20 test.assert_equals(divisors(560), [1, 2, 4, 5, 7, 8, 10, 14, 16, 20, 28, 35, 40, 56, 70, 80, 112, 140, 280, 560]) 21 21 22 22 test.it("n = 755") 23 23 test.assert_equals(divisors(755), [1, 5, 151, 755]) ... lines 24 to 35 have been collapsed. expand 24 24 25 25 from random import randint 26 26 27 27 test.describe( "Random Tests") 28 28 test.it ("More than 1000 Random Tests with challenging values up to 1000000000(10e9)") 29 29 for h in range(0,1000): 30 30 n = randint(1000, 1000000000) 31 31 result = divisors_check(n) 32 32 res = divisors(n) 33 33 test.it("Testing for = " + str(n)) 34 34 test.assert_equals(res, result) 35 35
def add(s, o): s = map(int, s) s = { 1: (c for c in s if c % 2), 2: (c for c in s if not c % 2), }.get(o, s); return sum(s)1 1 def add(s, o): 2 2 s = map(int, s) 3 3 s = { 4 4 1: (c for c in s if c % 2), 5 - 2: (c for c in s if c % 2 == 0), 5 + 2: (c for c in s if not c % 2), 6 6 }.get(o, s); 7 7 return sum(s)
def square(n): result = (("*" *n+"\n")*n)[:-1] print(result) # ...write a function that prints... return result # result to be tested1 1 def square(n): 2 - print(("*" *n+"\n")*n) # to see the result 3 - 4 - return (("*" *n+"\n")*n)[:-1] 5 - 2 + result = (("*" *n+"\n")*n)[:-1] 3 + print(result) # ...write a function that prints... 4 + return result # result to be tested
# TODO: Given a number n, write a function that prints a square of '*' having side n # These are some of the methods available: # test.expect(boolean, [optional] message) # test.assert_equals(actual, expected, [optional] message) # test.assert_not_equals(actual, expected, [optional] message) # You can use Test.describe and Test.it to write BDD style test groupings #test.it('Basic tests') test.assert_equals(square(2),'**\n**') test.assert_equals(square(5),'*****\n*****\n*****\n*****\n*****') test.assert_equals(square(4),'****\n****\n****\n****') test.assert_equals(square(0),'')1 - # TODO: Given a number, write a function that prints a square with the caracter '*' 1 + # TODO: Given a number n, write a function that prints a square of '*' having side n 2 2 # These are some of the methods available: 3 3 # test.expect(boolean, [optional] message) 4 4 # test.assert_equals(actual, expected, [optional] message) 5 5 # test.assert_not_equals(actual, expected, [optional] message) 6 6 7 7 # You can use Test.describe and Test.it to write BDD style test groupings 8 8 9 - 10 - # test.assert_equals(square(2),['**', '**']) 11 - # test.assert_equals(square(3),['***', '***', '***']) 12 - # test.assert_equals(square(4),['****', '****', '****', '****']) 13 - # test.assert_equals(square(5),['*****', '*****', '*****', '*****', '*****']) 14 - 15 - test.assert_equals(square(2),"**\n**") 9 + #test.it('Basic tests') 10 + test.assert_equals(square(2),'**\n**') 16 16 test.assert_equals(square(5),'*****\n*****\n*****\n*****\n*****') 17 17 test.assert_equals(square(4),'****\n****\n****\n****') 18 - 13 + test.assert_equals(square(0),'')
Numbers
def kilogramsToGrams(kilograms=1): return kilograms * 10001 - def kilogramsToGrams(kilograms): 1 + def kilogramsToGrams(kilograms=1): 2 2 return kilograms * 1000
# TODO: Replace examples and use TDD development by writing your own tests # These are some of the methods available: # test.expect(boolean, [optional] message) # test.assert_equals(actual, expected, [optional] message) # test.assert_not_equals(actual, expected, [optional] message) # You can use Test.describe and Test.it to write BDD style test groupings test.assert_equals(kilogramsToGrams(1), 1000) test.assert_equals(kilogramsToGrams(1.365), 1365) kilograms = 0.126 grams = 126 test.assert_equals(kilograms*kilogramsToGrams(), grams)1 1 # TODO: Replace examples and use TDD development by writing your own tests 2 2 # These are some of the methods available: 3 3 # test.expect(boolean, [optional] message) 4 4 # test.assert_equals(actual, expected, [optional] message) 5 5 # test.assert_not_equals(actual, expected, [optional] message) 6 6 7 7 # You can use Test.describe and Test.it to write BDD style test groupings 8 8 9 9 test.assert_equals(kilogramsToGrams(1), 1000) 10 10 test.assert_equals(kilogramsToGrams(1.365), 1365) 11 + 12 + kilograms = 0.126 13 + grams = 126 14 + test.assert_equals(kilograms*kilogramsToGrams(), grams)
Mathematics
Algorithms
Numbers
Fundamentals
class Sort: def merge_sort(self, nums): if nums == None: return None elif len(nums) <= 1: return nums vLeft = self.merge_sort(nums[:len(nums) // 2]) vRight= self.merge_sort(nums[len(nums) // 2:]) lLeft,lRight = len(vLeft),len(vRight) i,j,k = 0,0,0 while i < lLeft and j < lRight: if vLeft[i] < vRight[j]: nums[k] = vLeft[i] i += 1 else: nums[k] = vRight[j] j += 1 k += 1 while i < lLeft: nums[k] = vLeft[i] i += 1 k += 1 while j < lRight: nums[k] = vRight[j] j += 1 k += 1 return nums1 1 class Sort: 2 2 3 3 def merge_sort(self, nums): 4 4 if nums == None: return None 5 - 6 - if len(nums) > 1: 7 - mid = len(nums) // 2 8 - lefthalf = nums[:mid] 9 - righthalf = nums[mid:] 10 - 11 - self.merge_sort(lefthalf) 12 - self.merge_sort(righthalf) 13 - 14 - i = 0 15 - j = 0 16 - k = 0 17 - 18 - while i < len(lefthalf) and j < len(righthalf): 19 - if lefthalf[i] < righthalf[j]: 20 - nums[k] = lefthalf[i] 21 - i += 1 22 - else: 23 - nums[k] = righthalf[j] 24 - j += 1 25 - k += 1 26 - 27 - while i < len(lefthalf): 28 - nums[k] = lefthalf[i] 5 + elif len(nums) <= 1: return nums 6 + 7 + vLeft = self.merge_sort(nums[:len(nums) // 2]) 8 + vRight= self.merge_sort(nums[len(nums) // 2:]) 9 + lLeft,lRight = len(vLeft),len(vRight) 10 + i,j,k = 0,0,0 11 + 12 + while i < lLeft and j < lRight: 13 + if vLeft[i] < vRight[j]: 14 + nums[k] = vLeft[i] 29 29 i += 1 30 - k += 1 31 - 32 - while j < len(righthalf): 33 - nums[k] = righthalf[j] 16 + else: 17 + nums[k] = vRight[j] 34 34 j += 1 35 - k += 1 19 + k += 1 20 + 21 + while i < lLeft: 22 + nums[k] = vLeft[i] 23 + i += 1 24 + k += 1 25 + 26 + while j < lRight: 27 + nums[k] = vRight[j] 28 + j += 1 29 + k += 1 36 36 37 37 return nums
given a list of lists. each inner list is same size.
they can represent a square or a rectangle.
return information about it.
return its perimeter , area,total number of "*", rectangle/square
s = "*"
array = [[s,s,s,s],[s,s,s,s],[s,s,s,s],[s,s,s,s]]
===> permimeter = 16 ,area = 16, "*" = 16 , "square"
def determine_params(list):
return #its perimeter , area,total number of "*", rectangle/square# s = "*"
# array = [[s,s,s,s],[s,s,s,s],[s,s,s,s],[s,s,s,s]]
# test.assert_equals(determine_params(array),16,16,16,"square")Changed from a static variable to a dynamic function.
module Solution export greet function greet( whom::String ) "Hello " * whom * "!" end end1 - println("Hello Julia!") 2 - const hello = "world" 1 + module Solution 2 + export greet 3 + 4 + function greet( whom::String ) 5 + "Hello " * whom * "!" 6 + end 7 + 8 + end
using FactCheck facts("greetings") do @fact Solution.greet("world") --> "Hello world!" @fact Solution.greet("Julia") --> "Hello Julia!" @fact Solution.greet("Fred") --> "Hello Fred!" @fact Solution.greet("Kmactavish") --> "Hello Kmactavish!" end1 - facts("Is hello world?") do 2 - @fact hello => "world" 1 + using FactCheck 2 + facts("greetings") do 3 + @fact Solution.greet("world") --> "Hello world!" 4 + @fact Solution.greet("Julia") --> "Hello Julia!" 5 + @fact Solution.greet("Fred") --> "Hello Fred!" 6 + @fact Solution.greet("Kmactavish") --> "Hello Kmactavish!" 3 3 end
def distance(a): y,y1 = 0,0 for i in range(len(a)): if "y" in a[i]: y = i if "x" in a[i]: y1 = i x ,x1 = a[y].index("y"), a[y1].index("x") return abs(x -x1) + abs(y-y1)1 - def distance(array): 2 - for i in range(len(array)): 3 - if "y" in array[i] : y = abs(array[i].index("y") - i) 4 - if "x" in array[i] : x = abs(array[i].index("x") - i) 5 - return (x+y) 6 - 7 - 8 - 1 + def distance(a): 2 + y,y1 = 0,0 3 + for i in range(len(a)): 4 + if "y" in a[i]: y = i 5 + if "x" in a[i]: y1 = i 6 + 7 + x ,x1 = a[y].index("y"), a[y1].index("x") 8 + return abs(x -x1) + abs(y-y1)
#ORDEN O(1) SIN FOR, #Usado en Katas Anteriores por otro colaborador solo #lo aplique para Python. def euler(n): return getMult(3,n-1) + getMult(5,n-1) - getMult(15,n-1) def getMult(multiple, n): return getArith(multiple, n - n%multiple, int(n/multiple)) def getArith(first,last,count): return count * (first + last)/21 - def euler(num): 2 - return sum(range(3,num,3)) + sum(range(5,num,5)) - sum(range(15,num,15)) 1 + #ORDEN O(1) SIN FOR, #Usado en Katas Anteriores por otro colaborador solo 2 + #lo aplique para Python. 3 + def euler(n): return getMult(3,n-1) + getMult(5,n-1) - getMult(15,n-1) 4 + def getMult(multiple, n): return getArith(multiple, n - n%multiple, int(n/multiple)) 5 + def getArith(first,last,count): return count * (first + last)/2
def fizz_buzz(n): return ['FizzBuzz' if (i % 15 == 0) else 'Fizz' if(i % 3 == 0) else 'Buzz' if(i % 5 == 0) else i for i in range(1,n)]1 1 def fizz_buzz(n): 2 - for i in range(1, n): 3 - yield "Fizz" * (i % 3 == 0) + "Buzz" * (i % 5 == 0) or i 2 + return ['FizzBuzz' if (i % 15 == 0) else 'Fizz' if(i % 3 == 0) else 'Buzz' if(i % 5 == 0) else i for i in range(1,n)] 3 +
Here's a solution to the problem that uses no for loops, reducing O(n) to O(1).
The basic logic behind this code is that there is a formula for the sum of any arithmetic sequence, for example:
3 + 6 + 9 + 12 + ... + n*3 (where n is a natural number) = n * (3 + n*3) / 2
If we sum all the multiples of 3 and the multiples of 5 this way, we can get close to the answer. But we would be double counting all multiplies of 3*5 = 15, so we use the same formula to subtract out the sum of the multiples of 15.
Hope this helps!
let arithSum = (firstNum, lastNum, count) => count * (firstNum + lastNum) / 2; let getMultSum = (multiple, n) => arithSum(multiple, n - n%multiple, Math.trunc(n/multiple)); let test = (n) => getMultSum(3,n-1) + getMultSum(5,n-1) - getMultSum(15,n-1); // using n-1 because the problem specifies all multiples strictly *less than* the input1 - //if you have any Suggestion or noticed a mistake in my code ...tell me...i would need that... 2 - function test(n) { 3 - var sum=0; 4 - for (i=1; i<n; i++){ 5 - if ((i%3==0) || (i%5==0)){ 6 - sum+=i; 7 - } 8 - } 9 - return sum; 10 - } 1 + let arithSum = (firstNum, lastNum, count) => count * (firstNum + lastNum) / 2; 2 + 3 + let getMultSum = (multiple, n) => arithSum(multiple, n - n%multiple, Math.trunc(n/multiple)); 4 + 5 + let test = (n) => getMultSum(3,n-1) + getMultSum(5,n-1) - getMultSum(15,n-1); // using n-1 because the problem specifies all multiples strictly *less than* the input
Test.assertDeepEquals(test(27),168); Test.assertDeepEquals(test(11),33); Test.assertDeepEquals(test(10),23); Test.assertDeepEquals(test(0),0); Test.assertDeepEquals(test(2),0); Test.assertDeepEquals(test(4),3); Test.assertDeepEquals(test(100000000),2333333316666668); // note that if my code is atrociously incorrect for large numbers, this test case is a blatant lie1 + Test.assertDeepEquals(test(27),168); 1 1 Test.assertDeepEquals(test(11),33); 2 2 Test.assertDeepEquals(test(10),23); 3 3 Test.assertDeepEquals(test(0),0); 5 + Test.assertDeepEquals(test(2),0); 4 4 Test.assertDeepEquals(test(4),3); 7 + Test.assertDeepEquals(test(100000000),2333333316666668); // note that if my code is atrociously incorrect for large numbers, this test case is a blatant lie
Fundamentals
Strings
A different approach from the one above, done in one line.
const minutes = i => `${Math.trunc(i / 60)}:${i % 60 < 10 ? "0" : ""}${i % 60}`;1 - const toHours = i => Math.floor(i / 60); 2 - 3 - const setDigits = i => `0${i}`.slice(-2); 4 - 5 - const getTime = i => [toHours(i), i % 60]; 6 - 7 - const toTime = arr => `${arr[0]}:${setDigits(arr[1])}`; 8 - 9 - const minutes = i => toTime(getTime(i)); 1 + const minutes = i => `${Math.trunc(i / 60)}:${i % 60 < 10 ? "0" : ""}${i % 60}`;
Il faut créer une fonction qui s'appelle quiEstLeMeilleurProf et qui retourne la phrase suivante : "Mon prof de programmation Web"
function quiEstLeMeilleurProf(){
return "Mon prof de programmation Web";
}// PHPUnit Test Examples:
// TODO: Replace examples and use TDD development by writing your own tests
class MyTestCases extends TestCase
{
// test function names should start with "test"
public function testThatSomethingShouldHappen() {
$this->assertEquals("Mon prof de programmation Web", quiEstLeMeilleurProf());
}
}Code a function that will return the exact average grade of an array of grades. Grades can be integer or float numbers.
def average(grades) grades.sum.fdiv(grades.length) end1 - def average (grades) 2 - grade.sum/grade.length 1 + def average(grades) 2 + grades.sum.fdiv(grades.length) 3 3 end
# TODO: Replace examples and use TDD development by writing your own tests # These are some of the methods available: # Test.expect(boolean, [optional] message) # Test.assert_equals(actual, expected, [optional] message) # Test.assert_not_equals(actual, expected, [optional] message) Test.assert_equals(average([1, 2, 3]), 2) Test.assert_equals(average([2, 3]), 2.5) Test.assert_not_equals(average([2, 3]), 2)1 1 # TODO: Replace examples and use TDD development by writing your own tests 2 2 # These are some of the methods available: 3 3 # Test.expect(boolean, [optional] message) 4 4 # Test.assert_equals(actual, expected, [optional] message) 5 5 # Test.assert_not_equals(actual, expected, [optional] message) 6 + Test.assert_equals(average([1, 2, 3]), 2) 7 + Test.assert_equals(average([2, 3]), 2.5) 8 + Test.assert_not_equals(average([2, 3]), 2) 6 6
Instead of functions, i used lambdas that captured the password by reference.
So no additional passing through functions is necessary.
Invoking the lambdas as late as possible. To call only 1 function in the best case.
Using std::string::find_first_of() to use the stl instead of writing the search by myself.
#include <string> bool testPassword(std::string password) { auto const has_length{[&]() { return password.size() >= 8; }}; auto const has_upper{[&]() { return password.find_first_of("ABCDEFGHIJKLMNOPQRSTUVWXYZ") != std::string::npos; }}; auto const has_special{[&]() { return password.find_first_of("!\"#$%&'()*+'-./;:<>=or?") != std::string::npos; }}; auto const has_digit{[&]() { return password.find_first_of("0123456789") != std::string::npos; }}; return has_length() && has_upper() && has_special() && has_digit(); }1 - class Password{ 2 - public: 3 - static bool hasCap(const std::string& password); 4 - static bool hasSpec(const std::string& password); 5 - static bool hasDigit(const std::string& password); 6 - static bool hasLength(const std::string& password); 7 - static bool testPassword(const std::string& password); 8 - }; 9 - 10 - bool Password::hasCap(const std::string& password) 1 + #include <string> 2 + bool testPassword(std::string password) 11 11 { 12 - bool result = false; 13 - for(auto symbol : password) 14 - { 15 - if(symbol >= 'A' && symbol <= 'Z') 16 - { 17 - result = true; 18 - break; 19 - } 20 - } 21 - return result; 22 - } 23 - 24 - bool Password::hasSpec(const std::string& password) 25 - { 26 - bool result = false; 27 - 28 - const std::string specials("!\"#$%&'()*+'-./;:<>=?"); 29 - for(auto spec : specials) 30 - { 31 - if(password.find(spec) != -1) 32 - { 33 - result = true; 34 - break; 35 - } 36 - } 37 - return result; 38 - } 39 - 40 - bool Password::hasDigit(const std::string& password) 41 - { 42 - bool result = false; 43 - for(auto symbol : password) 44 - { 45 - if(symbol >= '0' && symbol <= '9') 46 - { 47 - result = true; 48 - break; 49 - } 50 - } 51 - return result; 52 - } 53 - 54 - bool Password::hasLength(const std::string& password) 55 - { 56 - return password.length() > 7; 57 - } 58 - 59 - bool Password::testPassword(const std::string& password) 60 - { 61 - bool cap = Password::hasCap(password); 62 - bool spec = Password::hasSpec(password); 63 - bool digit = Password::hasDigit(password); 64 - bool number = Password::hasLength(password); 65 - 66 - return cap && spec && digit && number; 4 + auto const has_length{[&]() { return password.size() >= 8; }}; 5 + auto const has_upper{[&]() { return password.find_first_of("ABCDEFGHIJKLMNOPQRSTUVWXYZ") != std::string::npos; }}; 6 + auto const has_special{[&]() { return password.find_first_of("!\"#$%&'()*+'-./;:<>=or?") != std::string::npos; }}; 7 + auto const has_digit{[&]() { return password.find_first_of("0123456789") != std::string::npos; }}; 8 + return has_length() && has_upper() && has_special() && has_digit(); 67 67 }
Describe(PasswordTest) { It(BasicTests) { Assert::That(testPassword("password"), Equals(false)); Assert::That(testPassword("Pas$word1"), Equals(true)); Assert::That(testPassword("WodT$m1"), Equals(false)); Assert::That(testPassword("ALLTH3TH!NGS"), Equals(true)); } };1 1 Describe(PasswordTest) 2 2 { 3 3 It(BasicTests) 4 4 { 5 - Assert::That(Password::testPassword("password"), Equals(false)); 6 - Assert::That(Password::testPassword("Pas$word1"), Equals(true)); 7 - Assert::That(Password::testPassword("WodT$m1"), Equals(false)); 8 - Assert::That(Password::testPassword("ALLTH3TH!NGS"), Equals(true)); 5 + Assert::That(testPassword("password"), Equals(false)); 6 + Assert::That(testPassword("Pas$word1"), Equals(true)); 7 + Assert::That(testPassword("WodT$m1"), Equals(false)); 8 + Assert::That(testPassword("ALLTH3TH!NGS"), Equals(true)); 9 9 } 10 10 };
// TODO: Replace examples and use TDD development by writing your own tests // These are some CW specific test methods available: // Test.expect(boolean, [optional] message) // Test.assertEquals(actual, expected, [optional] message) // Test.assertSimilar(actual, expected, [optional] message) // Test.assertNotEquals(actual, expected, [optional] message) // NodeJS assert is also automatically required for you. // assert(true) // assert.strictEqual({a: 1}, {a: 1}) // assert.deepEqual({a: [{b: 1}]}, {a: [{b: 1}]}) // You can also use Chai (http://chaijs.com/) by requiring it yourself // var expect = require("chai").expect; // var assert = require("chai").assert; // require("chai").should(); describe("Foo", function(){ it ("should be defined", function(){ Test.assertEquals(main(), 1) }); });1 1 // TODO: Replace examples and use TDD development by writing your own tests 2 2 3 3 // These are some CW specific test methods available: 4 4 // Test.expect(boolean, [optional] message) 5 5 // Test.assertEquals(actual, expected, [optional] message) 6 6 // Test.assertSimilar(actual, expected, [optional] message) 7 7 // Test.assertNotEquals(actual, expected, [optional] message) 8 8 9 9 // NodeJS assert is also automatically required for you. 10 10 // assert(true) 11 11 // assert.strictEqual({a: 1}, {a: 1}) 12 12 // assert.deepEqual({a: [{b: 1}]}, {a: [{b: 1}]}) 13 13 14 14 // You can also use Chai (http://chaijs.com/) by requiring it yourself 15 15 // var expect = require("chai").expect; 16 16 // var assert = require("chai").assert; 17 17 // require("chai").should(); 18 18 19 19 describe("Foo", function(){ 20 20 it ("should be defined", function(){ 21 21 Test.assertEquals(main(), 1) 22 22 }); 23 23 });
Showing how sync events work in c#, not so pratical as in c# 6 and forward is a good practice writing async code.
using System;
namespace delegates
{
class Program
{
static void Main()
{
// Creates a new instance
Message hi = new Message();
/*
set the event of the class instance to a
lambda expression, beeing an event handler that has the same parameter
and return type of the delegate in the class instance.
equivalent of creating a new void method with the same
parameters and seting it to the event in the class instance
*/
hi.writed += (string hello) =>
{
Console.WriteLine(hello);
};
// executes the method to validate the event and add it to the delegate
hi.write = "write property";
}
}
public class Message
{
//creates the delegate that will handle the method/ lambda expression/ anonnymous method passed through it
public delegate void handler(string hello);
//creates the event with the delegate
public event handler writed;
//method that will check for the event while executing
private string _write;
public string write
{
get
{
return _write;
}
set
{
if(value == "write property")
{
writed?.Invoke("the event was thrown!!!");
}
Console.WriteLine(value);
_write = value;
}
}
//The same as:
// public void write(string text)
// {
// //you have to check if the event is not null becouse you can't execute a delegates method if it does not exist
// //(the event handler was not set yet)
// if(text == "write method" && writed != null)
// {
// writed("the event was thrown!!!");
// }
// Console.WriteLine(text);
}
}Algorithms
Strings
Algorithms
a function that takes a list of connections on the following format:
connections[n] is the list of connections from node n.
connections={
[1] ={ 1, 2, 6, 7 },
[2] ={ 1, 2, 4, 5, 6 },
[3] ={ 3, 4, 5, 6, 7 },
[4] ={ 2, 3, 4, 5, 6 },
[5] ={ 2, 3, 4, 5, 7 },
[6] ={ 1, 2, 3, 4, 6 },
[7] ={ 1, 3, 5, 7 },
[8] ={ 8, 9, 11, 12, 13, 15 },
[9] ={ 8, 9, 10, 12, 13, 15, 16 },
[10]={ 9, 10, 11, 12, 16 },
[11]={ 8, 10, 11, 12 },
[12]={ 8, 9, 10, 11, 12, 13, 15 },
[13]={ 8, 9, 12, 13, 14, 15 },
[14]={ 13, 14, 15, 16 },
[15]={ 8, 9, 12, 13, 14, 15, 16 },
[16]={ 9, 10, 14, 15, 16 },
[17]={ 17, 18, 19, 20, 21 },
[18]={ 17, 18, 19, 20 },
[19]={ 17, 18, 19, 21 },
[20]={ 17, 18, 20, 21 },
[21]={ 17, 19, 20, 21 },
}
The output should be a table of tables with nodes in a given net.
nets={
{1,2,6,7,4,5,3},
{8,9,11,12,13,15,10,16,14},
{17,18,19,20,21}
}
This solution assumes symmetrical connections between nodes.
solution={}
local isIn=function(list,item)
--simple function to find a vale in list
if type(list)~="table" or item==nil then
return false
end
local FoundAtIndex=""
local found=false
for index,value in pairs(list) do
if value==item then
found=true
FoundAtIndex=index
break
end
end
return found,FoundAtIndex
end
solution.findConnectedNets=function(connections)
local nets={}
for i=1,#connections do --traverses nodes to build the nets
local new=true
for k=1,#nets do --if it already is in a net, skip it
if isIn(nets[k],i) then
new=false
break
end
end
if new then
local net={}
local queue={i}
while #queue>0 do
local vertex=queue[1]
table.insert(net,vertex)
table.remove(queue,1)
for _,node in pairs(connections[vertex]) do
if not isIn(net,node) and not isIn(queue,node) then
table.insert(queue,node)
end
end
end
table.insert(nets,net)
end
end
return nets
end
return solutionlocal solution = require 'solution'
describe("solution", function()
it("test precalculated solutions", function()
assert.are.same(
{{1,2,6,7,4,5,3},{8,9,11,12,13,15,10,16,14},{17,18,19,20,21}},
solution.findConnectedNets(
{{1,2,6,7},{1,2,4,5,6},{3,4,5,6,7},{2,3,4,5,6},{2,3,4,5,7},{1,2,3,4,6},{1,3,5,7},{8,9,11,12,13,15},{8,9,10,12,13,15,16},{9,10,11,12,16},{8,10,11,12},{8,9,10,11,12,13,15},{8,9,12,13,14,15},{13,14,15,16},{8,9,12,13,14,15,16},{9,10,14,15,16},{17,18,19,20,21},{17,18,19,20},{17,18,19,21},{17,18,20,21},{17,19,20,21}}
)
)
end)
end)export function fizzBuzz(input: number): string { const output = (input % 3 ? "" : "Fizz") + (input % 5 ? "" : "Buzz"); return output.length ? output : input.toString(); }1 1 export function fizzBuzz(input: number): string { 2 - const output: string = `${input % 3 === 0 ? "Fizz" : ""}${input % 5 === 0 ? "Buzz" : ""}`; 3 - return output.length > 0 ? output : input.toString(10); 2 + const output = (input % 3 ? "" : "Fizz") + (input % 5 ? "" : "Buzz"); 3 + return output.length ? output : input.toString(); 4 4 }
Use STL algorithms, take vector arguments by constant reference and functors by their exact type to avoid overhead of std::function.
#include <numeric> using namespace std; template<class F, class T, class U = decltype(std::declval<F>()(std::declval<T>()))> vector<U> vectorMap(const vector<T>& v, F f) { vector<U> result (v.size()); std::transform(v.begin(), v.end(), result.begin(), std::move(f)); return result; } template<class F, class T> vector<T> vectorFilter(const vector<T>& v, F f) { vector<T> result; std::copy_if(v.begin(), v.end(), std::back_inserter(result), std::move(f)); return result; } template<class F, class T, class U> U vectorReduce(const vector<T>& v, F f, U u) { return std::accumulate(v.begin(), v.end(), u, std::move(f)); }1 + #include <numeric> 2 + 1 1 using namespace std; 2 2 3 - template<class T, class U> vector<U> vectorMap(vector<T> v, function<U (T)> f) { 4 - size_t size = v.size(); 5 - vector<U> result (size); 6 - for (size_t i = 0; i < size; i++) result[i] = f(v[i]); 5 + template<class F, class T, class U = decltype(std::declval<F>()(std::declval<T>()))> vector<U> vectorMap(const vector<T>& v, F f) { 6 + vector<U> result (v.size()); 7 + std::transform(v.begin(), v.end(), result.begin(), std::move(f)); 7 7 return result; 8 8 } 9 - template<class T> vector<T> vectorFilter(vector<T> v, function<bool (T)> f) { 10 + template<class F, class T> vector<T> vectorFilter(const vector<T>& v, F f) { 10 10 vector<T> result; 11 - for (size_t i = 0; i < v.size(); i++) if (f(v[i])) result.push_back(v[i]); 12 + std::copy_if(v.begin(), v.end(), std::back_inserter(result), std::move(f)); 12 12 return result; 13 13 } 14 - template<class T, class U> U vectorReduce(vector<T> v, function<U (U, T)> f, U u) { 15 - U result = u; 16 - for (size_t i = 0; i < v.size(); i++) result = f(result, v[i]); 17 - return result; 15 + template<class F, class T, class U> U vectorReduce(const vector<T>& v, F f, U u) { 16 + return std::accumulate(v.begin(), v.end(), u, std::move(f)); 18 18 }
#include <string> using namespace std; Describe(the_generic_vector_map_function) { It(should_correctly_map_an_int_vector_to_an_int_vector) { Assert::That(vectorMap(vector<int> {2, -7, 5, -4, 3}, [] (int n) -> int {return n * -2;}), EqualsContainer(vector<int> {-4, 14, -10, 8, -6})); } It(should_correctly_map_an_int_vector_to_a_string_vector) { Assert::That(vectorMap(vector<int> {13, 27, -2, 33, 666, 11723}, [] (int n) -> string {return to_string(n);}), EqualsContainer(vector<string> {"13", "27", "-2", "33", "666", "11723"})); } }; Describe(the_generic_vector_filter_function) { It(should_correctly_filter_an_int_vector) { Assert::That(vectorFilter(vector<int> {4, 6, 9, 16, -5, -28}, [] (int n) -> bool {return n % 2 != 0;}), EqualsContainer(vector<int> {9, -5})); Assert::That(vectorFilter(vector<int> {4, 6, 9, 16, -5, -28}, [] (int n) -> bool {return n % 2 == 0;}), EqualsContainer(vector<int> {4, 6, 16, -28})); } It(should_correctly_filter_a_string_vector) { Assert::That(vectorFilter(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, [] (string s) -> bool {return s.find("Hello") != string::npos || s.find("hello") != string::npos;}), EqualsContainer(vector<string> {"Hello World", "hello"})); Assert::That(vectorFilter(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, [] (string s) -> bool {return s.find("Hello") == string::npos && s.find("hello") == string::npos;}), EqualsContainer(vector<string> {"Goodbye World", "meow", "goodbye"})); } }; Describe(the_generic_vector_reduce_function) { It(should_correctly_reduce_an_int_vector_into_a_single_int) { Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (int s, int n) -> int {return s + n * n;}, 0), Equals(17838)); Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (int t, int n) -> int {return t < n ? n : t;}, INT_MIN), Equals(99)); Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (int t, int n) -> int {return t > n ? n : t;}, INT_MAX), Equals(-23)); } It(should_correctly_reduce_an_int_vector_into_a_string) { Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (string s, int n) -> string {return s + to_string(n);}, (string)""), Equals("57486332-2399")); } It(should_correctly_reduce_a_string_vector_to_an_int) { Assert::That(vectorReduce(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, [] (int n, string s) -> int {return n + s.length();}, 0), Equals(40)); } };1 1 #include <string> 2 2 3 3 using namespace std; 4 4 5 5 Describe(the_generic_vector_map_function) { 6 6 It(should_correctly_map_an_int_vector_to_an_int_vector) { 7 - Assert::That(vectorMap(vector<int> {2, -7, 5, -4, 3}, (function<int (int)>)([] (int n) -> int {return n * -2;})), EqualsContainer(vector<int> {-4, 14, -10, 8, -6})); 7 + Assert::That(vectorMap(vector<int> {2, -7, 5, -4, 3}, [] (int n) -> int {return n * -2;}), EqualsContainer(vector<int> {-4, 14, -10, 8, -6})); 8 8 } 9 9 It(should_correctly_map_an_int_vector_to_a_string_vector) { 10 - Assert::That(vectorMap(vector<int> {13, 27, -2, 33, 666, 11723}, (function<string (int)>)([] (int n) -> string {return to_string(n);})), EqualsContainer(vector<string> {"13", "27", "-2", "33", "666", "11723"})); 10 + Assert::That(vectorMap(vector<int> {13, 27, -2, 33, 666, 11723}, [] (int n) -> string {return to_string(n);}), EqualsContainer(vector<string> {"13", "27", "-2", "33", "666", "11723"})); 11 11 } 12 12 }; 13 13 14 14 Describe(the_generic_vector_filter_function) { 15 15 It(should_correctly_filter_an_int_vector) { 16 - Assert::That(vectorFilter(vector<int> {4, 6, 9, 16, -5, -28}, (function<bool (int)>)([] (int n) -> bool {return n % 2 != 0;})), EqualsContainer(vector<int> {9, -5})); 17 - Assert::That(vectorFilter(vector<int> {4, 6, 9, 16, -5, -28}, (function<bool (int)>)([] (int n) -> bool {return n % 2 == 0;})), EqualsContainer(vector<int> {4, 6, 16, -28})); 16 + Assert::That(vectorFilter(vector<int> {4, 6, 9, 16, -5, -28}, [] (int n) -> bool {return n % 2 != 0;}), EqualsContainer(vector<int> {9, -5})); 17 + Assert::That(vectorFilter(vector<int> {4, 6, 9, 16, -5, -28}, [] (int n) -> bool {return n % 2 == 0;}), EqualsContainer(vector<int> {4, 6, 16, -28})); 18 18 } 19 19 It(should_correctly_filter_a_string_vector) { 20 - Assert::That(vectorFilter(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, (function<bool (string)>)([] (string s) -> bool {return s.find("Hello") != string::npos || s.find("hello") != string::npos;})), EqualsContainer(vector<string> {"Hello World", "hello"})); 21 - Assert::That(vectorFilter(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, (function<bool (string)>)([] (string s) -> bool {return s.find("Hello") == string::npos && s.find("hello") == string::npos;})), EqualsContainer(vector<string> {"Goodbye World", "meow", "goodbye"})); 20 + Assert::That(vectorFilter(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, [] (string s) -> bool {return s.find("Hello") != string::npos || s.find("hello") != string::npos;}), EqualsContainer(vector<string> {"Hello World", "hello"})); 21 + Assert::That(vectorFilter(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, [] (string s) -> bool {return s.find("Hello") == string::npos && s.find("hello") == string::npos;}), EqualsContainer(vector<string> {"Goodbye World", "meow", "goodbye"})); 22 22 } 23 23 }; 24 24 25 25 Describe(the_generic_vector_reduce_function) { 26 26 It(should_correctly_reduce_an_int_vector_into_a_single_int) { 27 - Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, (function<int (int, int)>)([] (int s, int n) -> int {return s + n * n;}), 0), Equals(17838)); 28 - Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, (function<int (int, int)>)([] (int t, int n) -> int {return t < n ? n : t;}), INT_MIN), Equals(99)); 29 - Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, (function<int (int, int)>)([] (int t, int n) -> int {return t > n ? n : t;}), INT_MAX), Equals(-23)); 27 + Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (int s, int n) -> int {return s + n * n;}, 0), Equals(17838)); 28 + Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (int t, int n) -> int {return t < n ? n : t;}, INT_MIN), Equals(99)); 29 + Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (int t, int n) -> int {return t > n ? n : t;}, INT_MAX), Equals(-23)); 30 30 } 31 31 It(should_correctly_reduce_an_int_vector_into_a_string) { 32 - Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, (function<string (string, int)>)([] (string s, int n) -> string {return s + to_string(n);}), (string)""), Equals("57486332-2399")); 32 + Assert::That(vectorReduce(vector<int> {5, 7, 4, 86, 3, 3, 2, -23, 99}, [] (string s, int n) -> string {return s + to_string(n);}, (string)""), Equals("57486332-2399")); 33 33 } 34 34 It(should_correctly_reduce_a_string_vector_to_an_int) { 35 - Assert::That(vectorReduce(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, (function<int (int, string)>)([] (int n, string s) -> int {return n + s.length();}), 0), Equals(40)); 35 + Assert::That(vectorReduce(vector<string> {"Hello World", "Goodbye World", "hello", "meow", "goodbye"}, [] (int n, string s) -> int {return n + s.length();}, 0), Equals(40)); 36 36 } 37 37 };
Algorithms
class Stack { // Just to hide the use of array implementation constructor() { this._items = []; } push(data) { this._items.push(data); } pop() { return this._items.pop(); } get length() { return this._items.length; } } class Queue { constructor() { this._stack = new Stack(); } enqueue(data) { this._stack.push(data); } dequeue() { if (this._stack.length === 1) return this._stack.pop(); else { var tmp = this._stack.pop(), result = this.dequeue(); this.enqueue(tmp); return result; } } }1 1 class Stack { // Just to hide the use of array implementation 2 2 constructor() { 3 3 this._items = []; 4 4 } 5 5 push(data) { 6 6 this._items.push(data); 7 7 } 8 8 pop() { 9 9 return this._items.pop(); 10 10 } 11 - length() { 11 + 12 + get length() { 12 12 return this._items.length; 13 13 } 14 14 } 15 15 16 16 class Queue { 17 17 constructor() { 18 18 this._stack = new Stack(); 19 19 } 20 20 enqueue(data) { 21 21 this._stack.push(data); 22 22 } 23 23 dequeue() { 24 - if (this._stack.length() === 1) 25 + if (this._stack.length === 1) 25 25 return this._stack.pop(); 26 26 else { 27 27 var tmp = this._stack.pop(), result = this.dequeue(); 28 28 this.enqueue(tmp); 29 29 return result; 30 30 } 31 31 } 32 32 }
Test.describe("Queue", function () { Test.it("is first-in-first-out", function () { var queue = new Queue(); let items = [1,2,3]; items.forEach(item => queue.enqueue(item)); Test.assertEquals(queue.dequeue(), 1); Test.assertEquals(queue.dequeue(), 2); Test.assertEquals(queue.dequeue(), 3); }); Test.describe("#enqueue", function() { Test.it("adds the item to the stack", function () { var queue = new Queue(); var mockStack = []; queue._stack = mockStack; queue.enqueue(1); Test.assertSimilar(mockStack, [1]); queue.enqueue(2); Test.assertSimilar(mockStack, [1,2]); }); }); Test.describe("#dequeue", function() { Test.it("removes items from the stack", function () { var queue = new Queue(); var mockStack = [1,2]; queue._stack = mockStack; queue.dequeue(); Test.assertSimilar(mockStack, [2]); queue.dequeue(); Test.assertSimilar(mockStack, []); }); Test.it("returns the first item from the stack", function () { var queue = new Queue(); var mockStack = [1,2]; var result = null; queue._stack = mockStack; result = queue.dequeue(); Test.assertEquals(result, 1); result = queue.dequeue(); Test.assertEquals(result, 2); }); }); }); Test.describe("Stack", function () { let stack = new Stack(); Test.it("has #pop", function () { Test.expect(typeof stack.pop === "function"); }); Test.it("has #push", function () { Test.expect(typeof stack.push === "function"); }); Test.it("has .length", function () { Test.expect(typeof stack.length === "number"); }); Test.it("does not have #shift", function () { Test.expect(typeof stack.shift === "undefined"); }); });1 1 Test.describe("Queue", function () { 2 - Test.it("should have working enqueue and dequeue operations", function () { 2 + Test.it("is first-in-first-out", function () { 3 3 var queue = new Queue(); 4 - queue.enqueue(1); 5 - queue.enqueue(2); 6 - queue.enqueue(3); 4 + let items = [1,2,3]; 5 + 6 + items.forEach(item => queue.enqueue(item)); 7 + 7 7 Test.assertEquals(queue.dequeue(), 1); 8 - queue.enqueue(4); 9 - queue.enqueue(5); 10 - queue.enqueue(6); 11 11 Test.assertEquals(queue.dequeue(), 2); 12 12 Test.assertEquals(queue.dequeue(), 3); 13 - queue.enqueue(7); 14 - queue.enqueue(8); 15 - queue.enqueue(9); 16 - queue.enqueue(10); 17 - Test.assertEquals(queue.dequeue(), 4); 18 - Test.assertEquals(queue.dequeue(), 5); 19 - Test.assertEquals(queue.dequeue(), 6); 20 - Test.assertEquals(queue.dequeue(), 7); 21 - Test.assertEquals(queue.dequeue(), 8); 22 - Test.assertEquals(queue.dequeue(), 9); 23 - Test.assertEquals(queue.dequeue(), 10); 11 + }); 12 + 13 + Test.describe("#enqueue", function() { 14 + Test.it("adds the item to the stack", function () { 15 + var queue = new Queue(); 16 + var mockStack = []; 17 + 18 + queue._stack = mockStack; 19 + 20 + queue.enqueue(1); 21 + Test.assertSimilar(mockStack, [1]); 22 + 23 + queue.enqueue(2); 24 + Test.assertSimilar(mockStack, [1,2]); 25 + }); 26 + }); 27 + 28 + Test.describe("#dequeue", function() { 29 + Test.it("removes items from the stack", function () { 30 + var queue = new Queue(); 31 + var mockStack = [1,2]; 32 + 33 + queue._stack = mockStack; 34 + 35 + queue.dequeue(); 36 + Test.assertSimilar(mockStack, [2]); 37 + 38 + queue.dequeue(); 39 + Test.assertSimilar(mockStack, []); 40 + }); 41 + 42 + Test.it("returns the first item from the stack", function () { 43 + var queue = new Queue(); 44 + var mockStack = [1,2]; 45 + var result = null; 46 + 47 + queue._stack = mockStack; 48 + 49 + result = queue.dequeue(); 50 + Test.assertEquals(result, 1); 51 + 52 + result = queue.dequeue(); 53 + Test.assertEquals(result, 2); 54 + }); 55 + }); 56 + }); 57 + 58 + Test.describe("Stack", function () { 59 + let stack = new Stack(); 60 + 61 + Test.it("has #pop", function () { 62 + Test.expect(typeof stack.pop === "function"); 63 + }); 64 + 65 + Test.it("has #push", function () { 66 + Test.expect(typeof stack.push === "function"); 67 + }); 68 + 69 + Test.it("has .length", function () { 70 + Test.expect(typeof stack.length === "number"); 71 + }); 72 + 73 + Test.it("does not have #shift", function () { 74 + Test.expect(typeof stack.shift === "undefined"); 24 24 }); 25 25 });
yawn I need a cup of coffee...
class GroundCoffee { }
class Coffee { }
class Cupboard {
constructor() {
this.contents = {
"GroundCoffee": new GroundCoffee(),
};
}
}
class CoffeeMaker {
makeCoffee(groundCoffee) {
if(!(groundCoffee instanceof GroundCoffee)) {
throw new Error("Only GroundCoffee can be used to make Coffee");
}
return new Coffee();
}
}
// -----
const cupboard = new Cupboard();
const coffeeMaker = new CoffeeMaker();
function makeCoffee() {
let groundCoffee = cupboard.contents["GroundCoffee"];
return coffeeMaker.makeCoffee(groundCoffee);
}var expect = require("chai").expect;
describe("makeCoffee", function(){
it("makes coffee", function(){
expect(makeCoffee()).to.be.an.instanceof(Coffee);
});
});
describe("CoffeeMaker", function() {
beforeEach(function() {
this.coffeeMaker = new CoffeeMaker();
});
describe("#makeCoffee", function() {
context("when passed GroundCoffee", function() {
beforeEach(function () {
this.groundCoffee = new GroundCoffee();
});
it("makes coffee", function(){
expect(this.coffeeMaker.makeCoffee(this.groundCoffee)).to.be.an.instanceof(Coffee);
});
});
context("when not passed GroundCoffee", function() {
beforeEach(function () {
this.groundCoffee = "I'm not coffee!";
});
it("throws an error", function(){
expect(() => this.coffeeMaker.makeCoffee(this.groundCoffee)).to.throw(
Error, "Only GroundCoffee can be used to make Coffee"
);
});
});
});
});def hello "world" end1 - function hello() { 2 - return "world"; 3 - } 1 + def hello 2 + "world" 3 + end
describe "Solution" do it "returns with 'world'" do expect(hello()).to eq("world") end end1 - describe("Solution", function(){ 2 - it("should test for something", function(){ 3 - Test.assertEquals(hello(), "world"); 4 - }); 5 - }); 1 + describe "Solution" do 2 + it "returns with 'world'" do 3 + expect(hello()).to eq("world") 4 + end 5 + end
from datetime import datetime def password(p): a = datetime.now() if not p.isdigit(): return "Please, don't print letters.\nReset the program." return "ACCESS CONFIRMED" if p == f"{a.hour}{a.minute}" else "ACCESS DENIED" # Outside the codewar you can use the lines below. # b = input("Please, print the password here (without letters!): ") # print(password(b))1 1 from datetime import datetime 2 2 3 3 def password(p): 4 4 a = datetime.now() 5 - c = str(a.hour) + str(a.minute) 6 - 7 - if p.isdigit(): 8 - if(p == c): 9 - return("ACCESS CONFIRMED") 10 - else: 11 - return("ACCESS DENIED") 12 - else: 13 - return("Please, don't print letters.\nReset the program.") 5 + if not p.isdigit(): 6 + return "Please, don't print letters.\nReset the program." 7 + return "ACCESS CONFIRMED" if p == f"{a.hour}{a.minute}" else "ACCESS DENIED" 14 14 15 15 # Outside the codewar you can use the lines below. 16 16 # b = input("Please, print the password here (without letters!): ") 17 17 # print(password(b))
Don't know how this "kumite" stuff works yet, so i may be doing sth wrong.
This is about finding better/more efficient ways to permutate a list starting with my sorry attempt. The result requires types of the typeclass Ord, to get a common result for the test cases. Havent thought about a way to solve that differently yet.
module Permutation where
import Data.List (sort)
permu :: [a] ->[[a]]
permu [] = [[]]
permu [x] = [[x]]
permu x = fuzz (length x) 0 x
where fuzz l n (x:xs) |n == l = []
|otherwise = map ((:) x) (permu xs) ++ fuzz l (n+1) (xs ++ [x])
permutation :: Ord a => [a] -> [[a]]
permutation x = permu xmodule PermuSpec where
import Test.Hspec
import Data.List (sort)
import Permutation
-- `spec` of type `Spec` must exist
spec :: Spec
spec = do
describe "Permutation" $ do
it "Basic Tests" $ do
shouldBe (sort $ permutation [1,2,3]) [[1,2,3],[1,3,2],[2,1,3],[2,3,1],[3,1,2],[3,2,1]]
shouldBe (sort $ permutation [1..4]) [[1,2,3,4],[1,2,4,3],[1,3,2,4],[1,3,4,2],[1,4,2,3],[1,4,3,2],[2,1,3,4],[2,1,4,3],[2,3,1,4],[2,3,4,1],[2,4,1,3],[2,4,3,1],[3,1,2,4],[3,1,4,2],[3,2,1,4],[3,2,4,1],[3,4,1,2],[3,4,2,1],[4,1,2,3],[4,1,3,2],[4,2,1,3],[4,2,3,1],[4,3,1,2],[4,3,2,1]]
shouldBe (sort $ permutation "wup") ["puw","pwu","upw","uwp","wpu","wup"]Return addresses are just normal stack entries, and nasm lets you jump to an address from a register.
global stack_push, stack_pop, stack_peek ; , stack_is_empty section .text stack_push: xchg rsi, [rsp] jmp rsi stack_pop: pop rsi pop rax jmp rsi stack_peek: pop rsi mov rax, [rsp] jmp rsi1 1 global stack_push, stack_pop, stack_peek ; , stack_is_empty 2 2 section .text 3 3 stack_push: 4 - push rsi 5 - ret 4 + xchg rsi, [rsp] 5 + jmp rsi 6 6 stack_pop: 7 7 pop rsi 8 - ret 8 + pop rax 9 + jmp rsi 9 9 stack_peek: 10 10 pop rsi 11 - push rsi 12 - ret 12 + mov rax, [rsp] 13 + jmp rsi
class Functionator attr_reader :allowed_methods, :callers, :next_caller def initialize(s) @allowed_methods = s.split init_caller end def method_missing(method, *args) method = method.to_s raise NoMethodError, 'Not exists' unless @allowed_methods.include?(method) raise NoMethodError, 'Wrong order' unless @next_caller == method wait_next_caller self end private def wait_next_caller @next_caller = @callers.next rescue StopIteration init_caller end def init_caller @callers = @allowed_methods.each @next_caller = @callers.next end end def functionator(methods) Functionator.new methods end1 1 class Functionator 2 + attr_reader :allowed_methods, :callers, :next_caller 3 + 2 2 def initialize(s) 3 - s.split(' ').each { | i | define_singleton_method :"#{i}" do Functionator.new(s.split(' ')[1..-1].join(' ')) end } 5 + @allowed_methods = s.split 6 + init_caller 7 + end 8 + 9 + def method_missing(method, *args) 10 + method = method.to_s 11 + raise NoMethodError, 'Not exists' unless @allowed_methods.include?(method) 12 + raise NoMethodError, 'Wrong order' unless @next_caller == method 13 + wait_next_caller 14 + self 15 + end 16 + 17 + private 18 + 19 + def wait_next_caller 20 + @next_caller = @callers.next 21 + rescue StopIteration 22 + init_caller 23 + end 24 + 25 + def init_caller 26 + @callers = @allowed_methods.each 27 + @next_caller = @callers.next 4 4 end 5 5 end 6 6 7 - def functionator(string) 8 - Functionator.new(string) 31 + def functionator(methods) 32 + Functionator.new methods 9 9 end
describe 'Functionator' do subject(:func) { functionator(input_data) } context 'when first chain is correct' do let(:input_data) { 'there are two kinds of people' } it do expect { func.there().are().two().kinds().of().people() }.not_to raise_error end end context 'when second chain is correct' do let(:input_data) { 'hello codewars world' } it do expect { func.hello().codewars().world() }.not_to raise_error end end context 'when third chain is NOT correct' do let(:input_data) { 'theraretwokindsofpeople' } it do expect { func.is_expected.theraretwokindsofpeople }.to raise_error StandardError end end context 'when fourth chain is NOT correct' do let(:input_data) { 'hello word' } it do expect { func.is_expecte