Given up to 3 non-repeating numbers from a range of 1-10, identify any prime numbers where 1 <= prime_numbers <= n where n is the number given by the concatenation of the given numbers put together in the order they were chosen. So given the numbers [1, 10, 8] is 1108.
Return the midmost prime number in the list you generated before.
If there are an even number of prime numbers, get the lower number.
def middle_prime(*args): nArg = 3 minArgValue = 1 maxArgValue = 10 argsLen = len(args) try: if argsLen > nArg: raise Exception('Only accepts up to {} params.'.format(nArg)) elif argsLen < 1: raise Exception('At least 1 param is required.') else: for i in args: if not minArgValue <= i <= maxArgValue: raise Exception('Only accepts numbers from {} to {}.'.format(minArgValue, maxArgValue)) num = int(''.join([str(i) for i in args])) primes = generate_primes(num) if primes: mididx = len(primes) // 2 if len(primes) % 2 else len(primes) // 2 - 1 return primes[mididx] return -1 except Exception as e: print(e) return -1 def is_prime(number:int, primes = [2,3]): if not primes: primes = [2, 3] for i in primes: if not number % i: return False if not i % 2: i += 1 while i <= (number // i): if not number % i: return False i += 2 return True def generate_primes(number): primes = [2] i = 3 while i <= number: if is_prime(i, primes): primes.append(i) i += 2 return primes1 1 def middle_prime(*args): 2 - maximum = 10 3 - try: 4 - if len(args) > 3: 5 - raise Exception('Only 3 numbers are allowed.') 6 - else: 7 - for i in args: 8 - if not 0 < i <= maximum: 9 - raise Exception('Only type numbers from 1 to {}.'.format(maximum)) 2 + nArg = 3 3 + minArgValue = 1 4 + maxArgValue = 10 5 + argsLen = len(args) 6 + try: 7 + if argsLen > nArg: 8 + raise Exception('Only accepts up to {} params.'.format(nArg)) 9 + elif argsLen < 1: 10 + raise Exception('At least 1 param is required.') 11 + else: 12 + for i in args: 13 + if not minArgValue <= i <= maxArgValue: 14 + raise Exception('Only accepts numbers from {} to {}.'.format(minArgValue, maxArgValue)) 15 + num = int(''.join([str(i) for i in args])) 16 + primes = generate_primes(num) 17 + if primes: 18 + mididx = len(primes) // 2 if len(primes) % 2 else len(primes) // 2 - 1 19 + return primes[mididx] 20 + return -1 21 + except Exception as e: 22 + print(e) 23 + return -1 10 10 11 - num = int(''.join([str(i) for i in args])) 12 - primes = [i for i in range(2, num + 1) if is_prime(i)] 13 - if primes: 14 - mididx = len(primes) // 2 if len(primes) % 2 else len(primes) // 2 - 1 15 - return primes[mididx] 16 - return -1 17 - except Exception as e: 18 - return e 19 - 20 - def is_prime(int:int): 21 - for i in range(2, int): 22 - if not int % i: 23 - return False 24 - return True 25 + def is_prime(number:int, primes = [2,3]): 26 + if not primes: 27 + primes = [2, 3] 28 + for i in primes: 29 + if not number % i: 30 + return False 31 + if not i % 2: 32 + i += 1 33 + while i <= (number // i): 34 + if not number % i: 35 + return False 36 + i += 2 37 + return True 38 + 39 + def generate_primes(number): 40 + primes = [2] 41 + i = 3 42 + while i <= number: 43 + if is_prime(i, primes): 44 + primes.append(i) 45 + i += 2 46 + return primes
test.assert_equals(middle_prime(2, 3, 8), 101) test.assert_equals(middle_prime(10, 9, 8), 479) test.assert_equals(middle_prime(4, 1, 3), 173) test.assert_equals(middle_prime(9, 10, 3), 4099) test.assert_equals(middle_prime(1, 1), 5) test.assert_equals(middle_prime(11), -1) test.assert_equals(middle_prime(), -1) test.assert_equals(middle_prime(6,5,5,1,1), -1) #302411 1 test.assert_equals(middle_prime(2, 3, 8), 101) 2 2 test.assert_equals(middle_prime(10, 9, 8), 479) 3 3 test.assert_equals(middle_prime(4, 1, 3), 173) 4 4 test.assert_equals(middle_prime(9, 10, 3), 4099) 5 + test.assert_equals(middle_prime(1, 1), 5) 6 + test.assert_equals(middle_prime(11), -1) 7 + test.assert_equals(middle_prime(), -1) 8 + test.assert_equals(middle_prime(6,5,5,1,1), -1) #30241
I would use a dictionary for this rather than adding multiple elif statements. It's easier to add new cases and is easier to read.
There's also no need to add items to a "grade" array if you use the dictionary approach as you can look up the key's (grade) value (score) straight away.
Removing the while loop means we don't need the y variable.
Applying the .upper() method to the input straight away makes it more readable in my oppinion.
total = 0 grade_dictionary = { "A+":4.0, "A":4.0, "A-":3.7, "B+":3.3, "B":3.0, "B-":2.7, "C+":2.3, "C":2.0, "C-": 1.7, "D": 1.0, } for _ in range(6): grade = input("Enter Your Grade For Each Class Listed in Order (Letter Form): ").upper() total += grade_dictionary.get(grade, 0) print(total / 6)1 - y = 0 2 - while (y <=5): 3 - grade = input("Enter Your Grade For Each Class Listed in Order (Letter Form): ") 4 - grade = grade.upper() 5 - grades.append(grade) 6 - y = y + 1 7 - calculate() 1 + total = 0 8 8 9 - def calculate(): 10 - total= 0 11 - for element in grades: 12 - if element == "A+": 13 - total = total + 4.0 14 - elif element == "A": ... lines 15 to 29 have been collapsed. expand 15 - total = total + 4.0 16 - elif element == "A-": 17 - total = total + 3.7 18 - elif element == "B+": 19 - total = total + 3.3 20 - elif element == "B": 21 - total = total + 3.0 22 - elif element == "B-": 23 - total = total + 2.7 24 - elif element == "C+": 25 - total = total + 2.3 26 - elif element == "C": 27 - total = total + 2.0 28 - elif element == "C-": 29 - total = total + 1.7 30 - elif element == "D": 31 - total = total + 1.0 32 - gpa = total / 6 33 - print(gpa) 3 + grade_dictionary = { 4 + "A+":4.0, 5 + "A":4.0, 6 + "A-":3.7, 7 + "B+":3.3, 8 + "B":3.0, 9 + "B-":2.7, 10 + "C+":2.3, 11 + "C":2.0, 12 + "C-": 1.7, 13 + "D": 1.0, 14 + } 34 34 35 - 36 - collect() ... lines 16 to 20 have been collapsed. expand 16 + for _ in range(6): 17 + grade = input("Enter Your Grade For Each Class Listed in Order (Letter Form): ").upper() 18 + total += grade_dictionary.get(grade, 0) 19 + 20 + print(total / 6)
Mathematics
Algorithms
Numbers
module Example where isPoly :: Integer -> Bool isPoly = fold ( \ n z -> n `mod` len n == 0 && z ) True fold :: (Integer -> z -> z) -> z -> Integer -> z fold _ z 0 = z fold fn z n = n `fn` fold fn z (n `div` 10) -- Foldable doesn't allow an (Eq Integer,Integral Integer) constraint -- otherwise, this is functionally identical to foldr len :: Integer -> Integer len = fold ( \ _ c -> c+1 ) 0 -- Foldable uses foldl' -- this is, m.m., otherwise verbatim1 1 module Example where 2 2 3 3 isPoly :: Integer -> Bool 4 - isPoly 0 = True 5 - isPoly n = n `mod` len n == 0 && isPoly (n `div` 10) 4 + isPoly = fold ( \ n z -> n `mod` len n == 0 && z ) True 5 + 6 + fold :: (Integer -> z -> z) -> z -> Integer -> z 7 + fold _ z 0 = z 8 + fold fn z n = n `fn` fold fn z (n `div` 10) 9 + -- Foldable doesn't allow an (Eq Integer,Integral Integer) constraint -- otherwise, this is functionally identical to foldr 6 6 7 7 len :: Integer -> Integer 8 - len 0 = 0 9 - len n = 1 + len (n `div` 10) 12 + len = fold ( \ _ c -> c+1 ) 0 13 + -- Foldable uses foldl' -- this is, m.m., otherwise verbatim
A short cut.
class FirstClass { static byte sum(byte a, byte b) { return a += b; } }1 - public class FirstClass { 2 - public static byte sum (byte a, byte b) { 3 - return (byte)(a + b); 4 - } 1 + class FirstClass { 2 + static byte sum(byte a, byte b) { 3 + return a += b; 4 + } 5 5 }
import static org.junit.Assert.assertEquals; import org.junit.Test; public class FirstClassTest { @Test public void testSum() { byte a = 1; byte b = 2; assertEquals(3, FirstClass.sum(a, b)); } }1 - import org.junit.Test; import static org.junit.Assert.assertEquals; public class FirstClassTest { @Test public void testSum() throws Exception { byte a = 1; byte b = 2; assertEquals(3, FirstClass.sum(a, b)); } } 1 + import static org.junit.Assert.assertEquals; 2 + 3 + import org.junit.Test; 4 + 5 + public class FirstClassTest { 6 + @Test 7 + public void testSum() { 8 + byte a = 1; 9 + byte b = 2; 10 + assertEquals(3, FirstClass.sum(a, b)); 11 + } 12 + }
A bit ugly, but an efficient way of doing this :)
Complexity: O(n)
A few optimizations here:
- Ignores extra spaces between words;
- If the shortest word is found (a single character), stop searching;
class Kata { static int findShort(String s) { int min = -1; for (int i = 0, l = 0; i < s.length(); i++, l++) { if (s.charAt(i) == ' ') { if (l > 0 && (min < 0 || l < min)) { if ((min = l) == 1) { break; } } l = -1; } } return min; } }1 - import java.util.stream.*; 2 - public class Kata { 3 - public static int findShort(String s) { 4 - return Stream.of(s.split(" ")) 5 - .mapToInt(String::length) 6 - .min() 7 - .getAsInt(); 1 + class Kata { 2 + static int findShort(String s) { 3 + int min = -1; 4 + for (int i = 0, l = 0; i < s.length(); i++, l++) { 5 + if (s.charAt(i) == ' ') { 6 + if (l > 0 && (min < 0 || l < min)) { 7 + if ((min = l) == 1) { 8 + break; 9 + } 10 + } 11 + l = -1; 12 + } 8 8 } 14 + return min; 15 + } 9 9 }
import static org.junit.Assert.assertEquals; import org.junit.Test; public class KataTest { @Test public void findShort() { assertEquals(3, Kata.findShort("bitcoin take over the world maybe who knows perhaps")); assertEquals(3, Kata.findShort("turns out random test cases are easier than writing out basic ones")); assertEquals(4, Kata.findShort("this string contains multiple whitespaces")); assertEquals(1, Kata.findShort("a single character - the shortest possible answer, bla-bla")); } }1 - import org.junit.Test; 2 - 3 3 import static org.junit.Assert.assertEquals; 4 4 5 - /** 6 - * Created by Javatlacati on 01/03/2017. 7 - */ 8 - public class KataTest { ... lines 9 to 13 have been collapsed. expand 9 - @Test 10 - public void findShort() throws Exception { 11 - assertEquals(3, Kata.findShort("bitcoin take over the world maybe who knows perhaps")); 12 - assertEquals(3, Kata.findShort("turns out random test cases are easier than writing out basic ones")); 13 - } 3 + import org.junit.Test; 14 14 5 + public class KataTest { 6 + @Test 7 + public void findShort() { 8 + assertEquals(3, Kata.findShort("bitcoin take over the world maybe who knows perhaps")); ... lines 9 to 15 have been collapsed. expand 9 + assertEquals(3, Kata.findShort("turns out random test cases are easier than writing out basic ones")); 10 + assertEquals(4, Kata.findShort("this string contains multiple whitespaces")); 11 + assertEquals(1, Kata.findShort("a single character - the shortest possible answer, bla-bla")); 12 + } 15 15 }