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NazmusAshrafi
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mbpp_with_visible_tests

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601
Write a function to find the longest chain which can be formed from the given set of pairs.
max_chain_length
class Pair(object): def __init__(self, a, b): self.a = a self.b = b def max_chain_length(arr, n): max = 0 mcl = [1 for i in range(n)] for i in range(1, n): for j in range(0, i): if (arr[i].a > arr[j].b and mcl[i] < mcl[j] + 1): mcl[i] = mcl[j] + 1 for i in range(n): if (max < mcl[i]): max = mcl[i] return max
[ "assert max_chain_length([Pair(68, 86), Pair(80, 24), Pair(15, 34), Pair(49, 41), Pair(84, 33), Pair(28, 3), Pair(72, 52), Pair(5, 81), Pair(75, 41), Pair(42, 17), Pair(48, 94), Pair(82, 37), Pair(98, 46), Pair(99, 63), Pair(16, 84), Pair(7, 40), Pair(55, 15), Pair(26, 98), Pair(17, 10), Pair(25, 87), Pair(70, 73), Pair(4, 35), Pair(56, 63), Pair(17, 38), Pair(45, 15), Pair(78, 28), Pair(69, 16), Pair(62, 50), Pair(48, 19), Pair(31, 35), Pair(29, 78), Pair(86, 4), Pair(22, 49), Pair(49, 74), Pair(19, 82), Pair(57, 87), Pair(97, 59), Pair(87, 68), Pair(43, 54), Pair(33, 89), Pair(49, 64), Pair(74, 23), Pair(85, 59), Pair(85, 8), Pair(15, 82), Pair(48, 2), Pair(8, 18), Pair(41, 52), Pair(53, 56), Pair(27, 71), Pair(85, 4), Pair(81, 98), Pair(57, 7), Pair(27, 76), Pair(43, 81), Pair(26, 31), Pair(90, 14), Pair(53, 21), Pair(68, 36), Pair(92, 73), Pair(21, 71), Pair(20, 93), Pair(52, 95), Pair(68, 47), Pair(72, 61), Pair(85, 45), Pair(39, 44), Pair(42, 30), Pair(9, 80), Pair(55, 89), Pair(5, 27), Pair(28, 89), Pair(10, 45), Pair(59, 57), Pair(79, 24), Pair(97, 41), Pair(7, 98), Pair(79, 87), Pair(64, 26), Pair(36, 50), Pair(22, 5), Pair(5, 28), Pair(87, 82), Pair(40, 40), Pair(62, 9), Pair(47, 74), Pair(87, 16), Pair(48, 85), Pair(32, 37), Pair(31, 69), Pair(32, 77), Pair(17, 48)], 82) == 42", "assert max_chain_length([Pair(40, 56), Pair(29, 57), Pair(68, 68), Pair(78, 78), Pair(82, 11), Pair(26, 42), Pair(35, 82), Pair(71, 15), Pair(52, 64), Pair(30, 98), Pair(25, 83), Pair(25, 55), Pair(7, 3), Pair(24, 60), Pair(78, 4), Pair(39, 50), Pair(94, 25), Pair(42, 86), Pair(33, 72), Pair(45, 84), Pair(93, 7), Pair(94, 51), Pair(96, 60), Pair(96, 97), Pair(64, 83), Pair(98, 5), Pair(60, 49), Pair(65, 75), Pair(67, 56), Pair(37, 76), Pair(46, 36), Pair(46, 48), Pair(78, 89), Pair(7, 21), Pair(78, 99), Pair(88, 81), Pair(30, 30), Pair(13, 16), Pair(74, 12), Pair(19, 86), Pair(3, 64), Pair(18, 34), Pair(64, 74), Pair(6, 63), Pair(9, 37), Pair(69, 54), Pair(6, 44), Pair(53, 67), Pair(50, 88), Pair(71, 9), Pair(30, 13), Pair(89, 90), Pair(80, 39), Pair(28, 49), Pair(14, 39), Pair(33, 25), Pair(65, 59), Pair(36, 63), Pair(64, 53), Pair(57, 19), Pair(76, 9), Pair(15, 18), Pair(24, 13)], 53) == 24", "assert max_chain_length([Pair(93, 41), Pair(29, 49), Pair(62, 90), Pair(68, 55), Pair(65, 80), Pair(63, 71), Pair(77, 73), Pair(80, 31), Pair(22, 24), Pair(71, 42), Pair(31, 79), Pair(76, 68), Pair(57, 4), Pair(97, 73), Pair(46, 89), Pair(97, 83), Pair(6, 16), Pair(95, 80), Pair(53, 38), Pair(52, 28), Pair(4, 14), Pair(44, 64), Pair(85, 32), Pair(39, 38), Pair(80, 11), Pair(48, 67), Pair(15, 42), Pair(28, 95), Pair(38, 81), Pair(47, 87), Pair(26, 64), Pair(15, 94), Pair(21, 28), Pair(42, 26), Pair(89, 95), Pair(61, 91), Pair(74, 22), Pair(37, 70), Pair(24, 22), Pair(35, 19), Pair(42, 5), Pair(65, 58), Pair(76, 89), Pair(25, 47), Pair(38, 85), Pair(98, 8), Pair(82, 41), Pair(78, 43), Pair(29, 57), Pair(51, 88), Pair(93, 65), Pair(67, 97), Pair(36, 91), Pair(14, 6), Pair(20, 90), Pair(46, 29), Pair(32, 71), Pair(77, 26), Pair(97, 83), Pair(46, 2), Pair(52, 71), Pair(47, 40), Pair(96, 78), Pair(55, 18), Pair(38, 23), Pair(76, 72), Pair(85, 25), Pair(6, 62), Pair(28, 34), Pair(60, 23), Pair(85, 49), Pair(17, 9), Pair(82, 43), Pair(66, 80), Pair(28, 96), Pair(9, 85), Pair(75, 7), Pair(99, 14), Pair(44, 43), Pair(40, 82), Pair(99, 59), Pair(95, 54), Pair(87, 100), Pair(62, 30), Pair(98, 61), Pair(49, 78), Pair(55, 67), Pair(22, 17), Pair(20, 35), Pair(61, 53), Pair(76, 6), Pair(50, 85), Pair(59, 29), Pair(79, 15)], 9) == 5" ]
def check(candidate): # Check some simple cases assert max_chain_length([Pair(5, 24), Pair(15, 25),Pair(27, 40), Pair(50, 60)], 4) == 3 assert max_chain_length([Pair(1, 2), Pair(3, 4),Pair(5, 6), Pair(7, 8)], 4) == 4 assert max_chain_length([Pair(19, 10), Pair(11, 12),Pair(13, 14), Pair(15, 16), Pair(31, 54)], 5) == 5
602
Write a python function to find the first repeated character in a given string.
first_repeated_char
def first_repeated_char(str1): for index,c in enumerate(str1): if str1[:index+1].count(c) > 1: return c return "None"
[ "assert first_repeated_char(\"45188\") == 8", "assert first_repeated_char(\"5755\") == 5", "assert first_repeated_char(\"85830262859\") == 8" ]
def check(candidate): # Check some simple cases assert first_repeated_char("abcabc") == "a" assert first_repeated_char("abc") == "None" assert first_repeated_char("123123") == "1"
603
Write a function to get a lucid number smaller than or equal to n.
get_ludic
def get_ludic(n): ludics = [] for i in range(1, n + 1): ludics.append(i) index = 1 while(index != len(ludics)): first_ludic = ludics[index] remove_index = index + first_ludic while(remove_index < len(ludics)): ludics.remove(ludics[remove_index]) remove_index = remove_index + first_ludic - 1 index += 1 return ludics
[ "assert get_ludic(44) == [1, 2, 3, 5, 7, 11, 13, 17, 23, 25, 29, 37, 41, 43]", "assert get_ludic(44) == [1, 2, 3, 5, 7, 11, 13, 17, 23, 25, 29, 37, 41, 43]", "assert get_ludic(49) == [1, 2, 3, 5, 7, 11, 13, 17, 23, 25, 29, 37, 41, 43, 47]" ]
def check(candidate): # Check some simple cases assert get_ludic(10) == [1, 2, 3, 5, 7] assert get_ludic(25) == [1, 2, 3, 5, 7, 11, 13, 17, 23, 25] assert get_ludic(45) == [1, 2, 3, 5, 7, 11, 13, 17, 23, 25, 29, 37, 41, 43]
604
Write a function to reverse words in a given string.
reverse_words
def reverse_words(s): return ' '.join(reversed(s.split()))
[ "assert reverse_words(\"lekdguw\") == \"lekdguw\"", "assert reverse_words(\"cbg fs\") == \"fs cbg\"", "assert reverse_words(\"vzdejlp\") == \"vzdejlp\"" ]
def check(candidate): # Check some simple cases assert reverse_words("python program")==("program python") assert reverse_words("java language")==("language java") assert reverse_words("indian man")==("man indian")
605
Write a function to check if the given integer is a prime number.
prime_num
def prime_num(num): if num >=1: for i in range(2, num//2): if (num % i) == 0: return False else: return True else: return False
[ "assert prime_num(-1010) == False", "assert prime_num(-1006) == False", "assert prime_num(-1012) == False" ]
def check(candidate): # Check some simple cases assert prime_num(13)==True assert prime_num(7)==True assert prime_num(-1010)==False
606
Write a function to convert degrees to radians.
radian_degree
import math def radian_degree(degree): radian = degree*(math.pi/180) return radian
[ "assert radian_degree(119) == 2.076941809873252", "assert radian_degree(115) == 2.007128639793479", "assert radian_degree(123) == 2.1467549799530254" ]
def check(candidate): # Check some simple cases assert radian_degree(90)==1.5707963267948966 assert radian_degree(60)==1.0471975511965976 assert radian_degree(120)==2.0943951023931953
607
Write a function to search a literals string in a string and also find the location within the original string where the pattern occurs by using regex.
find_literals
import re pattern = 'fox' text = 'The quick brown fox jumps over the lazy dog.' def find_literals(text, pattern): match = re.search(pattern, text) s = match.start() e = match.end() return (match.re.pattern, s, e)
[ "assert find_literals(' uwtAKfnBlnjIEAZ phkkXDayre KqsQ XJOjJFnIYUbz', 'phk') == ('phk', 17, 20)", "assert find_literals('kszkHCAaDYJiCbsTapnBrsbHiEsdsIlJYRgqHMWv', 'szk') == ('szk', 1, 4)", "assert find_literals('XzgfKwoUQovT FiMn FCgPFzlciWEeWSvzOe TW', 'lci') == ('lci', 24, 27)" ]
def check(candidate): # Check some simple cases assert find_literals('The quick brown fox jumps over the lazy dog.', 'fox') == ('fox', 16, 19) assert find_literals('Its been a very crazy procedure right', 'crazy') == ('crazy', 16, 21) assert find_literals('Hardest choices required strongest will', 'will') == ('will', 35, 39)
608
Write a python function to find nth bell number.
bell_Number
def bell_Number(n): bell = [[0 for i in range(n+1)] for j in range(n+1)] bell[0][0] = 1 for i in range(1, n+1): bell[i][0] = bell[i-1][i-1] for j in range(1, i+1): bell[i][j] = bell[i-1][j-1] + bell[i][j-1] return bell[n][0]
[ "assert bell_Number(5) == 52", "assert bell_Number(5) == 52", "assert bell_Number(9) == 21147" ]
def check(candidate): # Check some simple cases assert bell_Number(2) == 2 assert bell_Number(3) == 5 assert bell_Number(4) == 15
609
Write a python function to find minimum possible value for the given periodic function.
floor_Min
def floor_Min(A,B,N): x = max(B - 1,N) return (A*x) // B
[ "assert floor_Min(11, 11, 5) == 10", "assert floor_Min(11, 10, 5) == 9", "assert floor_Min(11, 12, 7) == 10" ]
def check(candidate): # Check some simple cases assert floor_Min(10,20,30) == 15 assert floor_Min(1,2,1) == 0 assert floor_Min(11,10,9) == 9
610
Write a python function to remove the k'th element from a given list.
remove_kth_element
def remove_kth_element(list1, L): return list1[:L-1] + list1[L:]
[ "assert remove_kth_element([7, 14, 12, 19, 22, 23, 17, 27, 30, 21, 18, 11], 7) == [7, 14, 12, 19, 22, 23, 27, 30, 21, 18, 11]", "assert remove_kth_element([14, 5, 17, 23, 13, 19, 16, 27, 26, 19, 23, 15], 4) == [14, 5, 17, 13, 19, 16, 27, 26, 19, 23, 15]", "assert remove_kth_element([10, 10, 11, 15, 22, 20, 12, 26, 23, 13, 14, 8], 7) == [10, 10, 11, 15, 22, 20, 26, 23, 13, 14, 8]" ]
def check(candidate): # Check some simple cases assert remove_kth_element([1,1,2,3,4,4,5,1],3)==[1, 1, 3, 4, 4, 5, 1] assert remove_kth_element([0, 0, 1, 2, 3, 4, 4, 5, 6, 6, 6, 7, 8, 9, 4, 4],4)==[0, 0, 1, 3, 4, 4, 5, 6, 6, 6, 7, 8, 9, 4, 4] assert remove_kth_element([10, 10, 15, 19, 18, 18, 17, 26, 26, 17, 18, 10],5)==[10,10,15,19, 18, 17, 26, 26, 17, 18, 10]
611
Write a function to find the maximum of nth column from the given tuple list.
max_of_nth
def max_of_nth(test_list, N): res = max([sub[N] for sub in test_list]) return (res)
[ "assert max_of_nth([(11, 4, 9), (2, 1, 5), (14, 15, 20)], 1) == 15", "assert max_of_nth([(3, 12, 8), (3, 10, 2), (10, 8, 19)], 1) == 12", "assert max_of_nth([(5, 5, 11), (6, 7, 10), (14, 10, 21)], 2) == 21" ]
def check(candidate): # Check some simple cases assert max_of_nth([(5, 6, 7), (1, 3, 5), (8, 9, 19)], 2) == 19 assert max_of_nth([(6, 7, 8), (2, 4, 6), (9, 10, 20)], 1) == 10 assert max_of_nth([(7, 8, 9), (3, 5, 7), (10, 11, 21)], 1) == 11
612
Write a python function to merge the first and last elements separately in a list of lists.
merge
def merge(lst): return [list(ele) for ele in list(zip(*lst))]
[ "assert merge([['a', 'm', 'e'], ['s', 'q', 'p'], ['b', 'm', 'z']]) == [['a', 's', 'b'], ['m', 'q', 'm'], ['e', 'p', 'z']]", "assert merge([['i', 'l', 'p'], ['w', 'i', 'q'], ['f', 'g', 'n']]) == [['i', 'w', 'f'], ['l', 'i', 'g'], ['p', 'q', 'n']]", "assert merge([['t', 'd', 'j'], ['a', 'y', 'i'], ['k', 'c', 'q']]) == [['t', 'a', 'k'], ['d', 'y', 'c'], ['j', 'i', 'q']]" ]
def check(candidate): # Check some simple cases assert merge([['x', 'y'], ['a', 'b'], ['m', 'n']]) == [['x', 'a', 'm'], ['y', 'b', 'n']] assert merge([[1, 2], [3, 4], [5, 6], [7, 8]]) == [[1, 3, 5, 7], [2, 4, 6, 8]] assert merge([['x', 'y','z' ], ['a', 'b','c'], ['m', 'n','o']]) == [['x', 'a', 'm'], ['y', 'b', 'n'],['z', 'c','o']]
613
Write a function to find the maximum value in record list as tuple attribute in the given tuple list.
maximum_value
def maximum_value(test_list): res = [(key, max(lst)) for key, lst in test_list] return (res)
[ "assert maximum_value([('5gjjm5oz', [6, 2, 5]), ('8uidp', [8, 11, 7]), ('0ho0qipv', [12, 9])]) == [('5gjjm5oz', 6), ('8uidp', 11), ('0ho0qipv', 12)]", "assert maximum_value([('gy8i', [5, 8, 12]), ('2zgjt', [6, 2, 4]), ('rxajairc', [15, 3])]) == [('gy8i', 12), ('2zgjt', 6), ('rxajairc', 15)]", "assert maximum_value([('m1j', [4, 11, 12]), ('6ld0', [3, 6, 1]), ('b6hk', [7, 7])]) == [('m1j', 12), ('6ld0', 6), ('b6hk', 7)]" ]
def check(candidate): # Check some simple cases assert maximum_value([('key1', [3, 4, 5]), ('key2', [1, 4, 2]), ('key3', [9, 3])]) == [('key1', 5), ('key2', 4), ('key3', 9)] assert maximum_value([('key1', [4, 5, 6]), ('key2', [2, 5, 3]), ('key3', [10, 4])]) == [('key1', 6), ('key2', 5), ('key3', 10)] assert maximum_value([('key1', [5, 6, 7]), ('key2', [3, 6, 4]), ('key3', [11, 5])]) == [('key1', 7), ('key2', 6), ('key3', 11)]
614
Write a function to find the cumulative sum of all the values that are present in the given tuple list.
cummulative_sum
def cummulative_sum(test_list): res = sum(map(sum, test_list)) return (res)
[ "assert cummulative_sum([(3, 2), (5, 5, 8), (6, 5)]) == 34", "assert cummulative_sum([(4, 6), (2, 9, 8), (2, 5)]) == 36", "assert cummulative_sum([(2, 7), (8, 6, 7), (5, 13)]) == 48" ]
def check(candidate): # Check some simple cases assert cummulative_sum([(1, 3), (5, 6, 7), (2, 6)]) == 30 assert cummulative_sum([(2, 4), (6, 7, 8), (3, 7)]) == 37 assert cummulative_sum([(3, 5), (7, 8, 9), (4, 8)]) == 44
615
Write a function to find average value of the numbers in a given tuple of tuples.
average_tuple
def average_tuple(nums): result = [sum(x) / len(x) for x in zip(*nums)] return result
[ "assert average_tuple(((103, 102, 97, 120), (304, 452, 563, 452), (814, 803, 392, 317), (5, 20, 33, 37))) == [306.5, 344.25, 271.25, 231.5]", "assert average_tuple(((103, 98, 101, 118), (305, 451, 563, 452), (810, 795, 394, 324), (6, 17, 28, 35))) == [306.0, 340.25, 271.5, 232.25]", "assert average_tuple(((100, 99, 96, 120), (303, 451, 557, 447), (805, 803, 385, 322), (11, 24, 33, 43))) == [304.75, 344.25, 267.75, 233.0]" ]
def check(candidate): # Check some simple cases assert average_tuple(((10, 10, 10, 12), (30, 45, 56, 45), (81, 80, 39, 32), (1, 2, 3, 4)))==[30.5, 34.25, 27.0, 23.25] assert average_tuple(((1, 1, -5), (30, -15, 56), (81, -60, -39), (-10, 2, 3)))== [25.5, -18.0, 3.75] assert average_tuple( ((100, 100, 100, 120), (300, 450, 560, 450), (810, 800, 390, 320), (10, 20, 30, 40)))==[305.0, 342.5, 270.0, 232.5]
616
Write a function to perfom the modulo of tuple elements in the given two tuples.
tuple_modulo
def tuple_modulo(test_tup1, test_tup2): res = tuple(ele1 % ele2 for ele1, ele2 in zip(test_tup1, test_tup2)) return (res)
[ "assert tuple_modulo((8, 4, 12, 6), (8, 4, 11, 10)) == (0, 0, 1, 6)", "assert tuple_modulo((13, 6, 12, 9), (4, 4, 9, 12)) == (1, 2, 3, 9)", "assert tuple_modulo((17, 3, 11, 11), (6, 10, 10, 10)) == (5, 3, 1, 1)" ]
def check(candidate): # Check some simple cases assert tuple_modulo((10, 4, 5, 6), (5, 6, 7, 5)) == (0, 4, 5, 1) assert tuple_modulo((11, 5, 6, 7), (6, 7, 8, 6)) == (5, 5, 6, 1) assert tuple_modulo((12, 6, 7, 8), (7, 8, 9, 7)) == (5, 6, 7, 1)
617
Write a function to check for the number of jumps required of given length to reach a point of form (d, 0) from origin in a 2d plane.
min_Jumps
def min_Jumps(a, b, d): temp = a a = min(a, b) b = max(temp, b) if (d >= b): return (d + b - 1) / b if (d == 0): return 0 if (d == a): return 1 else: return 2
[ "assert min_Jumps(16, 10, 10) == 1", "assert min_Jumps(13, 13, 16) == 2.1538461538461537", "assert min_Jumps(10, 12, 13) == 2.0" ]
def check(candidate): # Check some simple cases assert min_Jumps(3,4,11)==3.5 assert min_Jumps(3,4,0)==0 assert min_Jumps(11,14,11)==1
618
Write a function to divide two lists using map and lambda function.
div_list
def div_list(nums1,nums2): result = map(lambda x, y: x / y, nums1, nums2) return list(result)
[ "assert div_list([89, 119], [52, 66]) == [1.7115384615384615, 1.803030303030303]", "assert div_list([95, 119], [49, 70]) == [1.9387755102040816, 1.7]", "assert div_list([95, 115], [54, 74]) == [1.7592592592592593, 1.554054054054054]" ]
def check(candidate): # Check some simple cases assert div_list([4,5,6],[1, 2, 3])==[4.0,2.5,2.0] assert div_list([3,2],[1,4])==[3.0, 0.5] assert div_list([90,120],[50,70])==[1.8, 1.7142857142857142]
619
Write a function to move all the numbers in it to the given string.
move_num
def move_num(test_str): res = '' dig = '' for ele in test_str: if ele.isdigit(): dig += ele else: res += ele res += dig return (res)
[ "assert move_num(\"On1tvNsDxa0aiow0OQvtRak4vrBPm3xbvaSEmJn\") == \"OntvNsDxaaiowOQvtRakvrBPmxbvaSEmJn10043\"", "assert move_num(\"SVv525b5SZwfMwDN5apKTHZM5nWZ1DN8i8PB5jiPi3fNET\") == \"SVvbSZwfMwDNapKTHZMnWZDNiPBjiPifNET52555518853\"", "assert move_num(\"xYnZkbe2Z7U6CTLgpsUliXE5STaLglzJ8NZWIkXh5R\") == \"xYnZkbeZUCTLgpsUliXESTaLglzJNZWIkXhR276585\"" ]
def check(candidate): # Check some simple cases assert move_num('I1love143you55three3000thousand') == 'Iloveyouthreethousand1143553000' assert move_num('Avengers124Assemble') == 'AvengersAssemble124' assert move_num('Its11our12path13to14see15things16do17things') == 'Itsourpathtoseethingsdothings11121314151617'
620
Write a function to find the largest subset where each pair is divisible.
largest_subset
def largest_subset(a, n): dp = [0 for i in range(n)] dp[n - 1] = 1; for i in range(n - 2, -1, -1): mxm = 0; for j in range(i + 1, n): if a[j] % a[i] == 0 or a[i] % a[j] == 0: mxm = max(mxm, dp[j]) dp[i] = 1 + mxm return max(dp)
[ "assert largest_subset([23, 3, 1, 5, 9, 12], 6) == 3", "assert largest_subset([23, 6, 6, 7, 14, 20], 3) == 2", "assert largest_subset([17, 5, 2, 11, 9, 22], 3) == 1" ]
def check(candidate): # Check some simple cases assert largest_subset([ 1, 3, 6, 13, 17, 18 ], 6) == 4 assert largest_subset([10, 5, 3, 15, 20], 5) == 3 assert largest_subset([18, 1, 3, 6, 13, 17], 6) == 4
621
Write a function to increment the numeric values in the given strings by k.
increment_numerics
def increment_numerics(test_list, K): res = [str(int(ele) + K) if ele.isdigit() else ele for ele in test_list] return res
[ "assert increment_numerics(['VLPvyuaEhPGW', '88110', 'ejvz', '39866', '672', 'vNEEsrDaL', '7418'], 28) == ['VLPvyuaEhPGW', '88138', 'ejvz', '39894', '700', 'vNEEsrDaL', '7446']", "assert increment_numerics(['qyNx', '9388014', 'pmi', '959', '492', 'FOIfAyEsv', '778'], 38) == ['qyNx', '9388052', 'pmi', '997', '530', 'FOIfAyEsv', '816']", "assert increment_numerics(['SuzrLLWqE', '2501367', 'yhx', '431716', '873', 'EzoTTeI', '828999'], 38) == ['SuzrLLWqE', '2501405', 'yhx', '431754', '911', 'EzoTTeI', '829037']" ]
def check(candidate): # Check some simple cases assert increment_numerics(["MSM", "234", "is", "98", "123", "best", "4"] , 6) == ['MSM', '240', 'is', '104', '129', 'best', '10'] assert increment_numerics(["Dart", "356", "is", "88", "169", "Super", "6"] , 12) == ['Dart', '368', 'is', '100', '181', 'Super', '18'] assert increment_numerics(["Flutter", "451", "is", "44", "96", "Magnificent", "12"] , 33) == ['Flutter', '484', 'is', '77', '129', 'Magnificent', '45']
622
Write a function to find the median of two sorted arrays of same size.
get_median
def get_median(arr1, arr2, n): i = 0 j = 0 m1 = -1 m2 = -1 count = 0 while count < n + 1: count += 1 if i == n: m1 = m2 m2 = arr2[0] break elif j == n: m1 = m2 m2 = arr1[0] break if arr1[i] <= arr2[j]: m1 = m2 m2 = arr1[i] i += 1 else: m1 = m2 m2 = arr2[j] j += 1 return (m1 + m2)/2
[ "assert get_median([3, 11, 17, 24, 35, 43], [1, 19, 26, 36, 45, 50], 5) == 21.5", "assert get_median([3, 3, 15, 28, 34, 37], [1, 19, 24, 40, 49, 57], 7) == 31.0", "assert get_median([4, 6, 18, 18, 38, 42], [7, 15, 32, 40, 47, 50], 2) == 6.5" ]
def check(candidate): # Check some simple cases assert get_median([1, 12, 15, 26, 38], [2, 13, 17, 30, 45], 5) == 16.0 assert get_median([2, 4, 8, 9], [7, 13, 19, 28], 4) == 8.5 assert get_median([3, 6, 14, 23, 36, 42], [2, 18, 27, 39, 49, 55], 6) == 25.0
623
Write a function to find the n-th power of individual elements in a list using lambda function.
nth_nums
def nth_nums(nums,n): nth_nums = list(map(lambda x: x ** n, nums)) return nth_nums
[ "assert nth_nums([7, 19], 5) == [16807, 2476099]", "assert nth_nums([7, 11], 1) == [7, 11]", "assert nth_nums([13, 17], 8) == [815730721, 6975757441]" ]
def check(candidate): # Check some simple cases assert nth_nums([1, 2, 3, 4, 5, 6, 7, 8, 9, 10],2)==[1, 4, 9, 16, 25, 36, 49, 64, 81, 100] assert nth_nums([10,20,30],3)==([1000, 8000, 27000]) assert nth_nums([12,15],5)==([248832, 759375])
624
Write a python function to convert the given string to upper case.
is_upper
def is_upper(string): return (string.upper())
[ "assert is_upper(\"SINilj\") == \"SINILJ\"", "assert is_upper(\"Hop\") == \"HOP\"", "assert is_upper(\"nnEhr\") == \"NNEHR\"" ]
def check(candidate): # Check some simple cases assert is_upper("person") =="PERSON" assert is_upper("final") == "FINAL" assert is_upper("Valid") == "VALID"
625
Write a python function to interchange first and last elements in a given list.
swap_List
def swap_List(newList): size = len(newList) temp = newList[0] newList[0] = newList[size - 1] newList[size - 1] = temp return newList
[ "assert swap_List([5, 5, 4]) == [4, 5, 5]", "assert swap_List([1, 3, 10]) == [10, 3, 1]", "assert swap_List([6, 5, 8]) == [8, 5, 6]" ]
def check(candidate): # Check some simple cases assert swap_List([1,2,3]) == [3,2,1] assert swap_List([1,2,3,4,4]) == [4,2,3,4,1] assert swap_List([4,5,6]) == [6,5,4]
626
Write a python function to find the largest triangle that can be inscribed in the semicircle.
triangle_area
def triangle_area(r) : if r < 0 : return -1 return r * r
[ "assert triangle_area(2) == 4", "assert triangle_area(4) == 16", "assert triangle_area(4) == 16" ]
def check(candidate): # Check some simple cases assert triangle_area(0) == 0 assert triangle_area(-1) == -1 assert triangle_area(2) == 4
627
Write a python function to find the smallest missing number from the given array.
find_First_Missing
def find_First_Missing(array,start,end): if (start > end): return end + 1 if (start != array[start]): return start; mid = int((start + end) / 2) if (array[mid] == mid): return find_First_Missing(array,mid+1,end) return find_First_Missing(array,start,mid)
[ "assert find_First_Missing([5, 7, 8, 12, 14], 3, 1) == 2", "assert find_First_Missing([1, 7, 4, 3, 13], 5, 4) == 5", "assert find_First_Missing([1, 2, 1, 13, 6], 5, 1) == 2" ]
def check(candidate): # Check some simple cases assert find_First_Missing([0,1,2,3],0,3) == 4 assert find_First_Missing([0,1,2,6,9],0,4) == 3 assert find_First_Missing([2,3,5,8,9],0,4) == 0
628
Write a function to replace all spaces in the given string with character * list item * list item * list item * list item '%20'.
replace_spaces
MAX=1000; def replace_spaces(string): string=string.strip() i=len(string) space_count=string.count(' ') new_length = i + space_count*2 if new_length > MAX: return -1 index = new_length-1 string=list(string) for f in range(i-2, new_length-2): string.append('0') for j in range(i-1, 0, -1): if string[j] == ' ': string[index] = '0' string[index-1] = '2' string[index-2] = '%' index=index-3 else: string[index] = string[j] index -= 1 return ''.join(string)
[ "assert replace_spaces(\"VYzJOJaabryypinwl\") == \"VYzJOJaabryypinwl\"", "assert replace_spaces(\"ylMlxLFsCHolPnTRH\") == \"ylMlxLFsCHolPnTRH\"", "assert replace_spaces(\"hPdSfvTkUBcjT\") == \"hPdSfvTkUBcjT\"" ]
def check(candidate): # Check some simple cases assert replace_spaces("My Name is Dawood") == 'My%20Name%20is%20Dawood' assert replace_spaces("I am a Programmer") == 'I%20am%20a%20Programmer' assert replace_spaces("I love Coding") == 'I%20love%20Coding'
629
Write a python function to find even numbers from a mixed list.
Split
def Split(list): ev_li = [] for i in list: if (i % 2 == 0): ev_li.append(i) return ev_li
[ "assert Split([9, 13, 14, 19]) == [14]", "assert Split([13, 14, 15, 14]) == [14, 14]", "assert Split([7, 15, 11, 19]) == []" ]
def check(candidate): # Check some simple cases assert Split([1,2,3,4,5]) == [2,4] assert Split([4,5,6,7,8,0,1]) == [4,6,8,0] assert Split ([8,12,15,19]) == [8,12]
630
Write a function to extract all the adjacent coordinates of the given coordinate tuple.
get_coordinates
def adjac(ele, sub = []): if not ele: yield sub else: yield from [idx for j in range(ele[0] - 1, ele[0] + 2) for idx in adjac(ele[1:], sub + [j])] def get_coordinates(test_tup): res = list(adjac(test_tup)) return (res)
[ "assert get_coordinates((8, 6)) == [[7, 5], [7, 6], [7, 7], [8, 5], [8, 6], [8, 7], [9, 5], [9, 6], [9, 7]]", "assert get_coordinates((2, 7)) == [[1, 6], [1, 7], [1, 8], [2, 6], [2, 7], [2, 8], [3, 6], [3, 7], [3, 8]]", "assert get_coordinates((4, 2)) == [[3, 1], [3, 2], [3, 3], [4, 1], [4, 2], [4, 3], [5, 1], [5, 2], [5, 3]]" ]
def check(candidate): # Check some simple cases assert get_coordinates((3, 4)) == [[2, 3], [2, 4], [2, 5], [3, 3], [3, 4], [3, 5], [4, 3], [4, 4], [4, 5]] assert get_coordinates((4, 5)) ==[[3, 4], [3, 5], [3, 6], [4, 4], [4, 5], [4, 6], [5, 4], [5, 5], [5, 6]] assert get_coordinates((5, 6)) == [[4, 5], [4, 6], [4, 7], [5, 5], [5, 6], [5, 7], [6, 5], [6, 6], [6, 7]]
631
Write a function to replace whitespaces with an underscore and vice versa in a given string by using regex.
replace_spaces
import re text = 'Python Exercises' def replace_spaces(text): text =text.replace (" ", "_") return (text) text =text.replace ("_", " ") return (text)
[ "assert replace_spaces(\"rlGRYqhUbAuNePWq\") == \"rlGRYqhUbAuNePWq\"", "assert replace_spaces(\"MdEeJIypeGguEvDD\") == \"MdEeJIypeGguEvDD\"", "assert replace_spaces(\"gJMksRpjskKXMQchkF\") == \"gJMksRpjskKXMQchkF\"" ]
def check(candidate): # Check some simple cases assert replace_spaces('Jumanji The Jungle') == 'Jumanji_The_Jungle' assert replace_spaces('The Avengers') == 'The_Avengers' assert replace_spaces('Fast and Furious') == 'Fast_and_Furious'
632
Write a python function to move all zeroes to the end of the given list.
move_zero
def move_zero(num_list): a = [0 for i in range(num_list.count(0))] x = [ i for i in num_list if i != 0] x.extend(a) return (x)
[ "assert move_zero([1, 4, 1, 4, 6]) == [1, 4, 1, 4, 6]", "assert move_zero([1, 3, 5, 1, 4]) == [1, 3, 5, 1, 4]", "assert move_zero([5, 6, 2, 2, 5]) == [5, 6, 2, 2, 5]" ]
def check(candidate): # Check some simple cases assert move_zero([1,0,2,0,3,4]) == [1,2,3,4,0,0] assert move_zero([2,3,2,0,0,4,0,5,0]) == [2,3,2,4,5,0,0,0,0] assert move_zero([0,1,0,1,1]) == [1,1,1,0,0]
633
Write a python function to find the sum of xor of all pairs of numbers in the given array.
pair_OR_Sum
def pair_OR_Sum(arr,n) : ans = 0 for i in range(0,n) : for j in range(i + 1,n) : ans = ans + (arr[i] ^ arr[j]) return ans
[ "assert pair_OR_Sum([10, 1], 1) == 0", "assert pair_OR_Sum([9, 6], 1) == 0", "assert pair_OR_Sum([10, 8], 1) == 0" ]
def check(candidate): # Check some simple cases assert pair_OR_Sum([5,9,7,6],4) == 47 assert pair_OR_Sum([7,3,5],3) == 12 assert pair_OR_Sum([7,3],2) == 4
634
Write a python function to find the sum of fourth power of first n even natural numbers.
even_Power_Sum
def even_Power_Sum(n): sum = 0; for i in range(1,n + 1): j = 2*i; sum = sum + (j*j*j*j); return sum;
[ "assert even_Power_Sum(7) == 74816", "assert even_Power_Sum(3) == 1568", "assert even_Power_Sum(9) == 245328" ]
def check(candidate): # Check some simple cases assert even_Power_Sum(2) == 272 assert even_Power_Sum(3) == 1568 assert even_Power_Sum(4) == 5664
635
Write a function to push all values into a heap and then pop off the smallest values one at a time.
heap_sort
import heapq as hq def heap_sort(iterable): h = [] for value in iterable: hq.heappush(h, value) return [hq.heappop(h) for i in range(len(h))]
[ "assert heap_sort([12, 5, 6, 5]) == [5, 5, 6, 12]", "assert heap_sort([11, 1, 5, 5]) == [1, 5, 5, 11]", "assert heap_sort([10, 2, 6, 7]) == [2, 6, 7, 10]" ]
def check(candidate): # Check some simple cases assert heap_sort([1, 3, 5, 7, 9, 2, 4, 6, 8, 0])==[0, 1, 2, 3, 4, 5, 6, 7, 8, 9] assert heap_sort([25, 35, 22, 85, 14, 65, 75, 25, 58])==[14, 22, 25, 25, 35, 58, 65, 75, 85] assert heap_sort( [7, 1, 9, 5])==[1,5,7,9]
636
Write a python function to check if roots of a quadratic equation are reciprocal of each other or not.
Check_Solution
def Check_Solution(a,b,c): if (a == c): return ("Yes"); else: return ("No");
[ "assert Check_Solution(1, 3, 7) == \"No\"", "assert Check_Solution(4, 5, 4) == \"Yes\"", "assert Check_Solution(1, 1, 4) == \"No\"" ]
def check(candidate): # Check some simple cases assert Check_Solution(2,0,2) == "Yes" assert Check_Solution(2,-5,2) == "Yes" assert Check_Solution(1,2,3) == "No"
637
Write a function to check whether the given amount has no profit and no loss
noprofit_noloss
def noprofit_noloss(actual_cost,sale_amount): if(sale_amount == actual_cost): return True else: return False
[ "assert noprofit_noloss(2225, 5932) == False", "assert noprofit_noloss(1589, 5527) == False", "assert noprofit_noloss(1089, 4031) == False" ]
def check(candidate): # Check some simple cases assert noprofit_noloss(1500,1200)==False assert noprofit_noloss(100,100)==True assert noprofit_noloss(2000,5000)==False
638
Write a function to calculate wind chill index.
wind_chill
import math def wind_chill(v,t): windchill = 13.12 + 0.6215*t - 11.37*math.pow(v, 0.16) + 0.3965*t*math.pow(v, 0.16) return int(round(windchill, 0))
[ "assert wind_chill(10, 105) == 122", "assert wind_chill(6, 96) == 108", "assert wind_chill(13, 101) == 119" ]
def check(candidate): # Check some simple cases assert wind_chill(120,35)==40 assert wind_chill(40,70)==86 assert wind_chill(10,100)==116
639
Write a function to sum the length of the names of a given list of names after removing the names that start with a lowercase letter.
sample_nam
def sample_nam(sample_names): sample_names=list(filter(lambda el:el[0].isupper() and el[1:].islower(),sample_names)) return len(''.join(sample_names))
[ "assert sample_nam(['difxmbt', 'QvKMpYRzraDh', 'yug', 'fwjzlhnyy']) == 0", "assert sample_nam(['ztpadb', 'UTOVUfSXt', 'twbt', 'rwgabzo']) == 0", "assert sample_nam(['gbrvo', 'DRZ', 'akgmpv', 'vfa']) == 0" ]
def check(candidate): # Check some simple cases assert sample_nam(['sally', 'Dylan', 'rebecca', 'Diana', 'Joanne', 'keith'])==16 assert sample_nam(["php", "res", "Python", "abcd", "Java", "aaa"])==10 assert sample_nam(["abcd", "Python", "abba", "aba"])==6
640
Write a function to remove the parenthesis area in a string.
remove_parenthesis
import re def remove_parenthesis(items): for item in items: return (re.sub(r" ?\([^)]+\)", "", item))
[ "assert remove_parenthesis(['ubl[gtfxaaacevr']) == \"ubl[gtfxaaacevr\"", "assert remove_parenthesis(['ntljqsh(s']) == \"ntljqsh(s\"", "assert remove_parenthesis(['cxwxh)}pg']) == \"cxwxh)}pg\"" ]
def check(candidate): # Check some simple cases assert remove_parenthesis(["python (chrome)"])==("python") assert remove_parenthesis(["string(.abc)"])==("string") assert remove_parenthesis(["alpha(num)"])==("alpha")
641
Write a function to find the nth nonagonal number.
is_nonagonal
def is_nonagonal(n): return int(n * (7 * n - 5) / 2)
[ "assert is_nonagonal(17) == 969", "assert is_nonagonal(22) == 1639", "assert is_nonagonal(15) == 750" ]
def check(candidate): # Check some simple cases assert is_nonagonal(10) == 325 assert is_nonagonal(15) == 750 assert is_nonagonal(18) == 1089
642
Write a function to remove similar rows from the given tuple matrix.
remove_similar_row
def remove_similar_row(test_list): res = set(sorted([tuple(sorted(set(sub))) for sub in test_list])) return (res)
[ "assert remove_similar_row([[(11, 6), (6, 9)], [(1, 1), (11, 11)], [(5, 2), (7, 9)]]) == {((6, 9), (11, 6)), ((1, 1), (11, 11)), ((5, 2), (7, 9))}", "assert remove_similar_row([[(1, 10), (10, 1)], [(8, 3), (4, 7)], [(8, 7), (7, 9)]]) == {((7, 9), (8, 7)), ((4, 7), (8, 3)), ((1, 10), (10, 1))}", "assert remove_similar_row([[(6, 5), (1, 2)], [(8, 4), (3, 8)], [(4, 1), (3, 12)]]) == {((3, 12), (4, 1)), ((1, 2), (6, 5)), ((3, 8), (8, 4))}" ]
def check(candidate): # Check some simple cases assert remove_similar_row([[(4, 5), (3, 2)], [(2, 2), (4, 6)], [(3, 2), (4, 5)]] ) == {((2, 2), (4, 6)), ((3, 2), (4, 5))} assert remove_similar_row([[(5, 6), (4, 3)], [(3, 3), (5, 7)], [(4, 3), (5, 6)]] ) == {((4, 3), (5, 6)), ((3, 3), (5, 7))} assert remove_similar_row([[(6, 7), (5, 4)], [(4, 4), (6, 8)], [(5, 4), (6, 7)]] ) =={((4, 4), (6, 8)), ((5, 4), (6, 7))}
643
Write a function that matches a word containing 'z', not at the start or end of the word.
text_match_wordz_middle
import re def text_match_wordz_middle(text): patterns = '\Bz\B' if re.search(patterns, text): return 'Found a match!' else: return('Not matched!')
[ "assert text_match_wordz_middle(\"wnncgnlfjx grlw\") == \"Not matched!\"", "assert text_match_wordz_middle(\"dvimpnqtmfdwax\") == \"Not matched!\"", "assert text_match_wordz_middle(\"qy rnx\") == \"Not matched!\"" ]
def check(candidate): # Check some simple cases assert text_match_wordz_middle("pythonzabc.")==('Found a match!') assert text_match_wordz_middle("xyzabc.")==('Found a match!') assert text_match_wordz_middle(" lang .")==('Not matched!')
644
Write a python function to reverse an array upto a given position.
reverse_Array_Upto_K
def reverse_Array_Upto_K(input, k): return (input[k-1::-1] + input[k:])
[ "assert reverse_Array_Upto_K([12, 5, 10, 1, 1], 3) == [10, 5, 12, 1, 1]", "assert reverse_Array_Upto_K([6, 8, 8, 4, 5], 6) == [5, 4, 8, 8, 6]", "assert reverse_Array_Upto_K([13, 8, 8, 2, 9], 2) == [8, 13, 8, 2, 9]" ]
def check(candidate): # Check some simple cases assert reverse_Array_Upto_K([1, 2, 3, 4, 5, 6],4) == [4, 3, 2, 1, 5, 6] assert reverse_Array_Upto_K([4, 5, 6, 7], 2) == [5, 4, 6, 7] assert reverse_Array_Upto_K([9, 8, 7, 6, 5],3) == [7, 8, 9, 6, 5]
645
Write a function to find the product of it’s kth index in the given tuples.
find_k_product
def get_product(val) : res = 1 for ele in val: res *= ele return res def find_k_product(test_list, K): res = get_product([sub[K] for sub in test_list]) return (res)
[ "assert find_k_product([(8, 3, 11), (8, 7, 10), (7, 9, 16)], 2) == 1760", "assert find_k_product([(5, 10, 10), (1, 3, 11), (15, 9, 16)], 2) == 1760", "assert find_k_product([(5, 9, 5), (7, 8, 6), (5, 14, 21)], 2) == 630" ]
def check(candidate): # Check some simple cases assert find_k_product([(5, 6, 7), (1, 3, 5), (8, 9, 19)], 2) == 665 assert find_k_product([(6, 7, 8), (2, 4, 6), (9, 10, 20)], 1) == 280 assert find_k_product([(7, 8, 9), (3, 5, 7), (10, 11, 21)], 0) == 210
646
Write a python function to count number of cubes of size k in a cube of size n.
No_of_cubes
def No_of_cubes(N,K): No = 0 No = (N - K + 1) No = pow(No, 3) return No
[ "assert No_of_cubes(2, 2) == 1", "assert No_of_cubes(4, 6) == -1", "assert No_of_cubes(2, 5) == -8" ]
def check(candidate): # Check some simple cases assert No_of_cubes(2,1) == 8 assert No_of_cubes(5,2) == 64 assert No_of_cubes(1,1) == 1
647
Write a function to split a string at uppercase letters.
split_upperstring
import re def split_upperstring(text): return (re.findall('[A-Z][^A-Z]*', text))
[ "assert split_upperstring(\"vbhnQAFXKIBDYGZAcwrWDgmR\") == ['Q', 'A', 'F', 'X', 'K', 'I', 'B', 'D', 'Y', 'G', 'Z', 'Acwr', 'W', 'Dgm', 'R']", "assert split_upperstring(\"awBfFjyWZXjqjZagwSnjB\") == ['Bf', 'Fjy', 'W', 'Z', 'Xjqj', 'Zagw', 'Snj', 'B']", "assert split_upperstring(\"bSQsjrZlcJbFRhhLOBxbLWT\") == ['S', 'Qsjr', 'Zlc', 'Jb', 'F', 'Rhh', 'L', 'O', 'Bxb', 'L', 'W', 'T']" ]
def check(candidate): # Check some simple cases assert split_upperstring("PythonProgramLanguage")==['Python','Program','Language'] assert split_upperstring("PythonProgram")==['Python','Program'] assert split_upperstring("ProgrammingLanguage")==['Programming','Language']
648
Write a function to exchange the position of every n-th value with (n+1)th value and (n+1)th value with n-th value in a given list.
exchange_elements
from itertools import zip_longest, chain, tee def exchange_elements(lst): lst1, lst2 = tee(iter(lst), 2) return list(chain.from_iterable(zip_longest(lst[1::2], lst[::2])))
[ "assert exchange_elements([21, 34, 49, 59, 73, 95]) == [34, 21, 59, 49, 95, 73]", "assert exchange_elements([24, 37, 41, 55, 73, 90]) == [37, 24, 55, 41, 90, 73]", "assert exchange_elements([29, 36, 41, 50, 70, 98]) == [36, 29, 50, 41, 98, 70]" ]
def check(candidate): # Check some simple cases assert exchange_elements([0,1,2,3,4,5])==[1, 0, 3, 2, 5, 4] assert exchange_elements([5,6,7,8,9,10])==[6,5,8,7,10,9] assert exchange_elements([25,35,45,55,75,95])==[35,25,55,45,95,75]
649
Write a python function to calculate the sum of the numbers in a list between the indices of a specified range.
sum_Range_list
def sum_Range_list(nums, m, n): sum_range = 0 for i in range(m, n+1, 1): sum_range += nums[i] return sum_range
[ "assert sum_Range_list([5, 5, 4, 2, 7, 11], 7, 1) == 0", "assert sum_Range_list([5, 3, 2, 5, 10, 1], 9, 2) == 0", "assert sum_Range_list([4, 3, 6, 5, 5, 6], 3, 4) == 10" ]
def check(candidate): # Check some simple cases assert sum_Range_list([2, 1, 5, 6, 8, 3, 4, 9, 10, 11, 8, 12],8,10) == 29 assert sum_Range_list([1,2,3,4,5],1,2) == 5 assert sum_Range_list([1,0,1,2,5,6],4,5) == 11
650
Write a python function to check whether the given two arrays are equal or not.
are_Equal
def are_Equal(arr1,arr2,n,m): if (n != m): return False arr1.sort() arr2.sort() for i in range(0,n - 1): if (arr1[i] != arr2[i]): return False return True
[ "assert are_Equal([8, 5], [9, 3, 6], 4, 3) == False", "assert are_Equal([13, 11], [6, 3, 2], 3, 3) == False", "assert are_Equal([7, 7], [2, 2, 11], 4, 4) == False" ]
def check(candidate): # Check some simple cases assert are_Equal([1,2,3],[3,2,1],3,3) == True assert are_Equal([1,1,1],[2,2,2],3,3) == False assert are_Equal([8,9],[4,5,6],2,3) == False
651
Write a function to check if one tuple is a subset of another tuple.
check_subset
def check_subset(test_tup1, test_tup2): res = set(test_tup2).issubset(test_tup1) return (res)
[ "assert check_subset((8, 10, 13, 13), (12, 3)) == False", "assert check_subset((8, 12, 14, 13), (5, 11)) == False", "assert check_subset((10, 13, 4, 12), (8, 11)) == False" ]
def check(candidate): # Check some simple cases assert check_subset((10, 4, 5, 6), (5, 10)) == True assert check_subset((1, 2, 3, 4), (5, 6)) == False assert check_subset((7, 8, 9, 10), (10, 8)) == True
652
Write a function to flatten the given tuple matrix into the tuple list with each tuple representing each column.
matrix_to_list
def matrix_to_list(test_list): temp = [ele for sub in test_list for ele in sub] res = list(zip(*temp)) return (str(res))
[ "assert matrix_to_list([[(3, 8), (5, 15)], [(7, 15), (20, 16)], [(24, 7), (20, 12)]]) == [(3, 5, 7, 20, 24, 20), (8, 15, 15, 16, 7, 12)]", "assert matrix_to_list([[(6, 3), (14, 8)], [(14, 17), (19, 16)], [(25, 9), (19, 4)]]) == [(6, 14, 14, 19, 25, 19), (3, 8, 17, 16, 9, 4)]", "assert matrix_to_list([[(5, 6), (11, 15)], [(10, 15), (24, 25)], [(21, 10), (20, 13)]]) == [(5, 11, 10, 24, 21, 20), (6, 15, 15, 25, 10, 13)]" ]
def check(candidate): # Check some simple cases assert matrix_to_list([[(4, 5), (7, 8)], [(10, 13), (18, 17)], [(0, 4), (10, 1)]]) == '[(4, 7, 10, 18, 0, 10), (5, 8, 13, 17, 4, 1)]' assert matrix_to_list([[(5, 6), (8, 9)], [(11, 14), (19, 18)], [(1, 5), (11, 2)]]) == '[(5, 8, 11, 19, 1, 11), (6, 9, 14, 18, 5, 2)]' assert matrix_to_list([[(6, 7), (9, 10)], [(12, 15), (20, 21)], [(23, 7), (15, 8)]]) == '[(6, 9, 12, 20, 23, 15), (7, 10, 15, 21, 7, 8)]'
653
Write a function to group a sequence of key-value pairs into a dictionary of lists using collections module.
grouping_dictionary
from collections import defaultdict def grouping_dictionary(l): d = defaultdict(list) for k, v in l: d[k].append(v) return d
[ "assert grouping_dictionary([('lxhhyrinbuc', 14), ('ictnmwf', 29), ('lnvd', 31), ('pfqfbywj', 50), ('toqntdht', 10)]) == defaultdict(<class 'list'>, {'lxhhyrinbuc': [14], 'ictnmwf': [29], 'lnvd': [31], 'pfqfbywj': [50], 'toqntdht': [10]})", "assert grouping_dictionary([('mhjm', 15), ('mnaxevg', 23), ('erdqha', 34), ('bdiismy', 49), ('huezldl', 17)]) == defaultdict(<class 'list'>, {'mhjm': [15], 'mnaxevg': [23], 'erdqha': [34], 'bdiismy': [49], 'huezldl': [17]})", "assert grouping_dictionary([('tkqmrcuzhord', 15), ('ywmqeg', 20), ('heqzca', 31), ('ojjchipo', 48), ('aavjg', 16)]) == defaultdict(<class 'list'>, {'tkqmrcuzhord': [15], 'ywmqeg': [20], 'heqzca': [31], 'ojjchipo': [48], 'aavjg': [16]})" ]
def check(candidate): # Check some simple cases assert grouping_dictionary([('yellow', 1), ('blue', 2), ('yellow', 3), ('blue', 4), ('red', 1)])== ({'yellow': [1, 3], 'blue': [2, 4], 'red': [1]}) assert grouping_dictionary([('yellow', 10), ('blue', 20), ('yellow', 30), ('blue', 40), ('red', 10)])== ({'yellow': [10, 30], 'blue': [20, 40], 'red': [10]}) assert grouping_dictionary([('yellow', 15), ('blue', 25), ('yellow', 35), ('blue', 45), ('red', 15)])== ({'yellow': [15, 35], 'blue': [25, 45], 'red': [15]})
654
Write a function to find the perimeter of a rectangle.
rectangle_perimeter
def rectangle_perimeter(l,b): perimeter=2*(l+b) return perimeter
[ "assert rectangle_perimeter(1, 6) == 14", "assert rectangle_perimeter(6, 6) == 24", "assert rectangle_perimeter(8, 4) == 24" ]
def check(candidate): # Check some simple cases assert rectangle_perimeter(10,20)==60 assert rectangle_perimeter(10,5)==30 assert rectangle_perimeter(4,2)==12
655
Write a python function to find the sum of fifth power of n natural numbers.
fifth_Power_Sum
def fifth_Power_Sum(n) : sm = 0 for i in range(1,n+1) : sm = sm + (i*i*i*i*i) return sm
[ "assert fifth_Power_Sum(5) == 4425", "assert fifth_Power_Sum(1) == 1", "assert fifth_Power_Sum(8) == 61776" ]
def check(candidate): # Check some simple cases assert fifth_Power_Sum(2) == 33 assert fifth_Power_Sum(4) == 1300 assert fifth_Power_Sum(3) == 276
656
Write a python function to find the minimum sum of absolute differences of two arrays.
find_Min_Sum
def find_Min_Sum(a,b,n): a.sort() b.sort() sum = 0 for i in range(n): sum = sum + abs(a[i] - b[i]) return sum
[ "assert find_Min_Sum([1, 5, 5, 7], [4, 3, 7, 9], 4) == 7", "assert find_Min_Sum([7, 4, 10, 10], [5, 2, 9, 1], 1) == 3", "assert find_Min_Sum([1, 3, 12, 3], [4, 3, 11, 9], 4) == 10" ]
def check(candidate): # Check some simple cases assert find_Min_Sum([3,2,1],[2,1,3],3) == 0 assert find_Min_Sum([1,2,3],[4,5,6],3) == 9 assert find_Min_Sum([4,1,8,7],[2,3,6,5],4) == 6
657
Write a python function to find the first digit in factorial of a given number.
first_Digit
import math def first_Digit(n) : fact = 1 for i in range(2,n + 1) : fact = fact * i while (fact % 10 == 0) : fact = int(fact / 10) while (fact >= 10) : fact = int(fact / 10) return math.floor(fact)
[ "assert first_Digit(4) == 2", "assert first_Digit(11) == 3", "assert first_Digit(12) == 4" ]
def check(candidate): # Check some simple cases assert first_Digit(5) == 1 assert first_Digit(10) == 3 assert first_Digit(7) == 5
658
Write a function to find the item with maximum occurrences in a given list.
max_occurrences
def max_occurrences(list1): max_val = 0 result = list1[0] for i in list1: occu = list1.count(i) if occu > max_val: max_val = occu result = i return result
[ "assert max_occurrences([2, 2, 5, 2, 6, 1, 4, 6, 6]) == 2", "assert max_occurrences([2, 6, 8, 1, 1, 4, 2, 3, 6]) == 2", "assert max_occurrences([4, 4, 6, 6, 1, 9, 2, 4, 6]) == 4" ]
def check(candidate): # Check some simple cases assert max_occurrences([2,3,8,4,7,9,8,2,6,5,1,6,1,2,3,4,6,9,1,2])==2 assert max_occurrences([1, 3,5, 7,1, 3,13, 15, 17,5, 7,9,1, 11])==1 assert max_occurrences([1, 2, 3,2, 4, 5,1, 1, 1])==1
659
Write a python function to print duplicants from a list of integers.
Repeat
def Repeat(x): _size = len(x) repeated = [] for i in range(_size): k = i + 1 for j in range(k, _size): if x[i] == x[j] and x[i] not in repeated: repeated.append(x[i]) return repeated
[ "assert Repeat([4, 5, 1, 4, 4]) == [4]", "assert Repeat([3, 3, 3, 5, 5]) == [3, 5]", "assert Repeat([3, 5, 6, 4, 3]) == [3]" ]
def check(candidate): # Check some simple cases assert Repeat([10, 20, 30, 20, 20, 30, 40, 50, -20, 60, 60, -20, -20]) == [20, 30, -20, 60] assert Repeat([-1, 1, -1, 8]) == [-1] assert Repeat([1, 2, 3, 1, 2,]) == [1, 2]
660
Write a python function to choose points from two ranges such that no point lies in both the ranges.
find_Points
def find_Points(l1,r1,l2,r2): x = min(l1,l2) if (l1 != l2) else -1 y = max(r1,r2) if (r1 != r2) else -1 return (x,y)
[ "assert find_Points(5, 1, 4, 7) == (4, 7)", "assert find_Points(2, 9, 6, 6) == (2, 9)", "assert find_Points(4, 9, 6, 7) == (4, 9)" ]
def check(candidate): # Check some simple cases assert find_Points(5,10,1,5) == (1,10) assert find_Points(3,5,7,9) == (3,9) assert find_Points(1,5,2,8) == (1,8)
661
Write a function to find the maximum sum that can be formed which has no three consecutive elements present.
max_sum_of_three_consecutive
def max_sum_of_three_consecutive(arr, n): sum = [0 for k in range(n)] if n >= 1: sum[0] = arr[0] if n >= 2: sum[1] = arr[0] + arr[1] if n > 2: sum[2] = max(sum[1], max(arr[1] + arr[2], arr[0] + arr[2])) for i in range(3, n): sum[i] = max(max(sum[i-1], sum[i-2] + arr[i]), arr[i] + arr[i-1] + sum[i-3]) return sum[n-1]
[ "assert max_sum_of_three_consecutive([3, 3, 8, 6, 5, 3, 12, 3], 6) == 20", "assert max_sum_of_three_consecutive([5, 1, 7, 1, 7, 7, 8, 12], 4) == 13", "assert max_sum_of_three_consecutive([3, 4, 5, 4, 1, 6, 2, 5], 5) == 12" ]
def check(candidate): # Check some simple cases assert max_sum_of_three_consecutive([100, 1000, 100, 1000, 1], 5) == 2101 assert max_sum_of_three_consecutive([3000, 2000, 1000, 3, 10], 5) == 5013 assert max_sum_of_three_consecutive([1, 2, 3, 4, 5, 6, 7, 8], 8) == 27
662
Write a function to sort a list in a dictionary.
sorted_dict
def sorted_dict(dict1): sorted_dict = {x: sorted(y) for x, y in dict1.items()} return sorted_dict
[ "assert sorted_dict({'xhv': [59, 39, 52], 'c3f7': [96, 35, 58], 'xpqr0': [97, 197, 298]}) == {'xhv': [39, 52, 59], 'c3f7': [35, 58, 96], 'xpqr0': [97, 197, 298]}", "assert sorted_dict({'gku5': [55, 46, 57], 'wh3': [90, 32, 56], 'l33gt': [101, 204, 300]}) == {'gku5': [46, 55, 57], 'wh3': [32, 56, 90], 'l33gt': [101, 204, 300]}", "assert sorted_dict({'acmu0': [55, 45, 55], '101zak': [91, 30, 55], 'opjb': [100, 198, 303]}) == {'acmu0': [45, 55, 55], '101zak': [30, 55, 91], 'opjb': [100, 198, 303]}" ]
def check(candidate): # Check some simple cases assert sorted_dict({'n1': [2, 3, 1], 'n2': [5, 1, 2], 'n3': [3, 2, 4]})=={'n1': [1, 2, 3], 'n2': [1, 2, 5], 'n3': [2, 3, 4]} assert sorted_dict({'n1': [25,37,41], 'n2': [41,54,63], 'n3': [29,38,93]})=={'n1': [25, 37, 41], 'n2': [41, 54, 63], 'n3': [29, 38, 93]} assert sorted_dict({'n1': [58,44,56], 'n2': [91,34,58], 'n3': [100,200,300]})=={'n1': [44, 56, 58], 'n2': [34, 58, 91], 'n3': [100, 200, 300]}
663
Write a function to find the largest possible value of k such that k modulo x is y.
find_max_val
import sys def find_max_val(n, x, y): ans = -sys.maxsize for k in range(n + 1): if (k % x == y): ans = max(ans, k) return (ans if (ans >= 0 and ans <= n) else -1)
[ "assert find_max_val(18, 13, 3) == 16", "assert find_max_val(11, 13, 5) == 5", "assert find_max_val(13, 10, 2) == 12" ]
def check(candidate): # Check some simple cases assert find_max_val(15, 10, 5) == 15 assert find_max_val(187, 10, 5) == 185 assert find_max_val(16, 11, 1) == 12
664
Write a python function to find the average of even numbers till a given even number.
average_Even
def average_Even(n) : if (n% 2!= 0) : return ("Invalid Input") return -1 sm = 0 count = 0 while (n>= 2) : count = count+1 sm = sm+n n = n-2 return sm // count
[ "assert average_Even(103) == \"Invalid Input\"", "assert average_Even(99) == \"Invalid Input\"", "assert average_Even(95) == \"Invalid Input\"" ]
def check(candidate): # Check some simple cases assert average_Even(2) == 2 assert average_Even(4) == 3 assert average_Even(100) == 51
665
Write a python function to shift first element to the end of given list.
move_last
def move_last(num_list): a = [num_list[0] for i in range(num_list.count(num_list[0]))] x = [ i for i in num_list if i != num_list[0]] x.extend(a) return (x)
[ "assert move_last([10, 9, 4, 7, 3]) == [9, 4, 7, 3, 10]", "assert move_last([7, 8, 6, 4, 2]) == [8, 6, 4, 2, 7]", "assert move_last([1, 8, 5, 1, 6]) == [8, 5, 6, 1, 1]" ]
def check(candidate): # Check some simple cases assert move_last([1,2,3,4]) == [2,3,4,1] assert move_last([2,3,4,1,5,0]) == [3,4,1,5,0,2] assert move_last([5,4,3,2,1]) == [4,3,2,1,5]
666
Write a function to count occurrence of a character in a string.
count_char
def count_char(string,char): count = 0 for i in range(len(string)): if(string[i] == char): count = count + 1 return count
[ "assert count_char('wqrqvmn', 'm') == 1", "assert count_char('vwtin', 'w') == 1", "assert count_char('yfwwruu', 'z') == 0" ]
def check(candidate): # Check some simple cases assert count_char("Python",'o')==1 assert count_char("little",'t')==2 assert count_char("assert",'s')==2
667
Write a python function to count number of vowels in the string.
Check_Vow
def Check_Vow(string, vowels): final = [each for each in string if each in vowels] return(len(final))
[ "assert Check_Vow('xqurz', 'ziziggWhvBzLe') == 1", "assert Check_Vow('dwodytry', 'rDUlCPl') == 1", "assert Check_Vow('uucgalqc', 'prxJtJIoe') == 0" ]
def check(candidate): # Check some simple cases assert Check_Vow('corner','AaEeIiOoUu') == 2 assert Check_Vow('valid','AaEeIiOoUu') == 2 assert Check_Vow('true','AaEeIiOoUu') ==2
668
Write a python function to replace multiple occurence of character by single.
replace
import re def replace(string, char): pattern = char + '{2,}' string = re.sub(pattern, char, string) return string
[ "assert replace('CNKKjUlS', 'a') == \"CNKKjUlS\"", "assert replace('EoaGFm', 'f') == \"EoaGFm\"", "assert replace('KjQtYhIBE', 'f') == \"KjQtYhIBE\"" ]
def check(candidate): # Check some simple cases assert replace('peep','e') == 'pep' assert replace('Greek','e') == 'Grek' assert replace('Moon','o') == 'Mon'
669
Write a function to check whether the given ip address is valid or not using regex.
check_IP
import re regex = '''^(25[0-5]|2[0-4][0-9]|[0-1]?[0-9][0-9]?)\.( 25[0-5]|2[0-4][0-9]|[0-1]?[0-9][0-9]?)\.( 25[0-5]|2[0-4][0-9]|[0-1]?[0-9][0-9]?)\.( 25[0-5]|2[0-4][0-9]|[0-1]?[0-9][0-9]?)$''' def check_IP(Ip): if(re.search(regex, Ip)): return ("Valid IP address") else: return ("Invalid IP address")
[ "assert check_IP(\"7381615\") == \"Invalid IP address\"", "assert check_IP(\"402502.6\") == \"Invalid IP address\"", "assert check_IP(\"78092.017\") == \"Invalid IP address\"" ]
def check(candidate): # Check some simple cases assert check_IP("192.168.0.1") == 'Valid IP address' assert check_IP("110.234.52.124") == 'Valid IP address' assert check_IP("366.1.2.2") == 'Invalid IP address'
670
Write a python function to check whether a sequence of numbers has a decreasing trend or not.
decreasing_trend
def decreasing_trend(nums): if (sorted(nums)== nums): return True else: return False
[ "assert decreasing_trend([1, 4, 6]) == True", "assert decreasing_trend([2, 5, 6]) == True", "assert decreasing_trend([4, 5, 5]) == True" ]
def check(candidate): # Check some simple cases assert decreasing_trend([-4,-3,-2,-1]) == True assert decreasing_trend([1,2,3]) == True assert decreasing_trend([3,2,1]) == False
671
Write a python function to set the right most unset bit.
set_Right_most_Unset_Bit
import math def get_Pos_Of_Right_most_Set_Bit(n): return int(math.log2(n&-n)+1) def set_Right_most_Unset_Bit(n): if (n == 0): return 1 if ((n & (n + 1)) == 0): return n pos = get_Pos_Of_Right_most_Set_Bit(~n) return ((1 << (pos - 1)) | n)
[ "assert set_Right_most_Unset_Bit(14) == 15", "assert set_Right_most_Unset_Bit(17) == 19", "assert set_Right_most_Unset_Bit(13) == 15" ]
def check(candidate): # Check some simple cases assert set_Right_most_Unset_Bit(21) == 23 assert set_Right_most_Unset_Bit(11) == 15 assert set_Right_most_Unset_Bit(15) == 15
672
Write a function to find maximum of three numbers.
max_of_three
def max_of_three(num1,num2,num3): if (num1 >= num2) and (num1 >= num3): lnum = num1 elif (num2 >= num1) and (num2 >= num3): lnum = num2 else: lnum = num3 return lnum
[ "assert max_of_three(5, 54, 25) == 54", "assert max_of_three(7, 45, 28) == 45", "assert max_of_three(14, 49, 35) == 49" ]
def check(candidate): # Check some simple cases assert max_of_three(10,20,30)==30 assert max_of_three(55,47,39)==55 assert max_of_three(10,49,30)==49
673
Write a python function to convert a list of multiple integers into a single integer.
convert
def convert(list): s = [str(i) for i in list] res = int("".join(s)) return (res)
[ "assert convert([9, 7, 7]) == 977", "assert convert([6, 7, 7]) == 677", "assert convert([3, 3, 6]) == 336" ]
def check(candidate): # Check some simple cases assert convert([1,2,3]) == 123 assert convert([4,5,6]) == 456 assert convert([7,8,9]) == 789
674
Write a function to remove duplicate words from a given string using collections module.
remove_duplicate
from collections import OrderedDict def remove_duplicate(string): result = ' '.join(OrderedDict((w,w) for w in string.split()).keys()) return result
[ "assert remove_duplicate(\"ZQLYpNJjzPKWLQLGJ VPoELqXwrNCHtmTxdigLgk\") == \"ZQLYpNJjzPKWLQLGJ VPoELqXwrNCHtmTxdigLgk\"", "assert remove_duplicate(\"yNkoOyTfiomLBLmgSbcyEzlWRyRmrtEdfkjdIUfntvnCxJY\") == \"yNkoOyTfiomLBLmgSbcyEzlWRyRmrtEdfkjdIUfntvnCxJY\"", "assert remove_duplicate(\"JxIGwjixZrgYAfFAYIkxhmuIXaPNLCEEssgfVEsr\") == \"JxIGwjixZrgYAfFAYIkxhmuIXaPNLCEEssgfVEsr\"" ]
def check(candidate): # Check some simple cases assert remove_duplicate("Python Exercises Practice Solution Exercises")==("Python Exercises Practice Solution") assert remove_duplicate("Python Exercises Practice Solution Python")==("Python Exercises Practice Solution") assert remove_duplicate("Python Exercises Practice Solution Practice")==("Python Exercises Practice Solution")
675
Write a function to add two integers. however, if the sum is between the given range it will return 20.
sum_nums
def sum_nums(x, y,m,n): sum_nums= x + y if sum_nums in range(m, n): return 20 else: return sum_nums
[ "assert sum_nums(9, 14, 3, 32) == 20", "assert sum_nums(5, 10, 6, 35) == 20", "assert sum_nums(5, 19, 2, 27) == 20" ]
def check(candidate): # Check some simple cases assert sum_nums(2,10,11,20)==20 assert sum_nums(15,17,1,10)==32 assert sum_nums(10,15,5,30)==20
676
Write a function to remove everything except alphanumeric characters from the given string by using regex.
remove_extra_char
import re def remove_extra_char(text1): pattern = re.compile('[\W_]+') return (pattern.sub('', text1))
[ "assert remove_extra_char(\"-gU4n1fbhT6C-DbFTp0J^xNMiD \") == \"gU4n1fbhT6CDbFTp0JxNMiD\"", "assert remove_extra_char(\"QA^E~JJl#gxaXXltEQCwv&znZ\") == \"QAEJJlgxaXXltEQCwvznZ\"", "assert remove_extra_char(\"U5A+@YbsOl9:!H~*>KwgD>Ed\") == \"U5AYbsOl9HKwgDEd\"" ]
def check(candidate): # Check some simple cases assert remove_extra_char('**//Google Android// - 12. ') == 'GoogleAndroid12' assert remove_extra_char('****//Google Flutter//*** - 36. ') == 'GoogleFlutter36' assert remove_extra_char('**//Google Firebase// - 478. ') == 'GoogleFirebase478'
677
Write a function to check if the triangle is valid or not.
validity_triangle
def validity_triangle(a,b,c): total = a + b + c if total == 180: return True else: return False
[ "assert validity_triangle(27, 47, 102) == False", "assert validity_triangle(27, 47, 99) == False", "assert validity_triangle(31, 52, 101) == False" ]
def check(candidate): # Check some simple cases assert validity_triangle(60,50,90)==False assert validity_triangle(45,75,60)==True assert validity_triangle(30,50,100)==True
678
Write a python function to remove spaces from a given string.
remove_spaces
def remove_spaces(str1): str1 = str1.replace(' ','') return str1
[ "assert remove_spaces(\"iyzgjqkd\") == \"iyzgjqkd\"", "assert remove_spaces(\"a gi zne\") == \"agizne\"", "assert remove_spaces(\"hebqtv\") == \"hebqtv\"" ]
def check(candidate): # Check some simple cases assert remove_spaces("a b c") == "abc" assert remove_spaces("1 2 3") == "123" assert remove_spaces(" b c") == "bc"
679
Write a function to access dictionary key’s element by index.
access_key
def access_key(ditionary,key): return list(ditionary)[key]
[ "assert access_key({'hipu': 16, 'mfakfqxkb': 48}, 1) == \"mfakfqxkb\"", "assert access_key({'ywbyqrvnjxxh': 18, 'heicvsytqgft': 47}, 1) == \"heicvsytqgft\"", "assert access_key({'penuhv': 10, 'ondf': 50}, 1) == \"ondf\"" ]
def check(candidate): # Check some simple cases assert access_key({'physics': 80, 'math': 90, 'chemistry': 86},0)== 'physics' assert access_key({'python':10, 'java': 20, 'C++':30},2)== 'C++' assert access_key({'program':15,'computer':45},1)== 'computer'
680
Write a python function to check whether a sequence of numbers has an increasing trend or not.
increasing_trend
def increasing_trend(nums): if (sorted(nums)== nums): return True else: return False
[ "assert increasing_trend([3, 3, 3, 8]) == True", "assert increasing_trend([2, 1, 1, 12]) == False", "assert increasing_trend([3, 2, 1, 10]) == False" ]
def check(candidate): # Check some simple cases assert increasing_trend([1,2,3,4]) == True assert increasing_trend([4,3,2,1]) == False assert increasing_trend([0,1,4,9]) == True
681
Write a python function to find the smallest prime divisor of a number.
smallest_Divisor
def smallest_Divisor(n): if (n % 2 == 0): return 2; i = 3; while (i*i <= n): if (n % i == 0): return i; i += 2; return n;
[ "assert smallest_Divisor(26) == 2", "assert smallest_Divisor(32) == 2", "assert smallest_Divisor(27) == 3" ]
def check(candidate): # Check some simple cases assert smallest_Divisor(10) == 2 assert smallest_Divisor(25) == 5 assert smallest_Divisor(31) == 31
682
Write a function to multiply two lists using map and lambda function.
mul_list
def mul_list(nums1,nums2): result = map(lambda x, y: x * y, nums1, nums2) return list(result)
[ "assert mul_list([85, 115], [50, 68]) == [4250, 7820]", "assert mul_list([94, 125], [52, 71]) == [4888, 8875]", "assert mul_list([92, 123], [48, 71]) == [4416, 8733]" ]
def check(candidate): # Check some simple cases assert mul_list([1, 2, 3],[4,5,6])==[4,10,18] assert mul_list([1,2],[3,4])==[3,8] assert mul_list([90,120],[50,70])==[4500,8400]
683
Write a python function to check whether the given number can be represented by sum of two squares or not.
sum_Square
def sum_Square(n) : i = 1 while i*i <= n : j = 1 while (j*j <= n) : if (i*i+j*j == n) : return True j = j+1 i = i+1 return False
[ "assert sum_Square(15) == False", "assert sum_Square(20) == True", "assert sum_Square(21) == False" ]
def check(candidate): # Check some simple cases assert sum_Square(25) == True assert sum_Square(24) == False assert sum_Square(17) == True
684
Write a python function to count occurences of a character in a repeated string.
count_Char
def count_Char(str,x): count = 0 for i in range(len(str)): if (str[i] == x) : count += 1 n = 10 repititions = n // len(str) count = count * repititions l = n % len(str) for i in range(l): if (str[i] == x): count += 1 return count
[ "assert count_Char('qcvdp', 'c') == 2", "assert count_Char('spjndu', 'n') == 2", "assert count_Char('ullppoi', 'o') == 1" ]
def check(candidate): # Check some simple cases assert count_Char("abcac",'a') == 4 assert count_Char("abca",'c') == 2 assert count_Char("aba",'a') == 7
685
Write a python function to find sum of prime numbers between 1 to n.
sum_Of_Primes
def sum_Of_Primes(n): prime = [True] * (n + 1) p = 2 while p * p <= n: if prime[p] == True: i = p * 2 while i <= n: prime[i] = False i += p p += 1 sum = 0 for i in range (2,n + 1): if(prime[i]): sum += i return sum
[ "assert sum_Of_Primes(9) == 17", "assert sum_Of_Primes(6) == 10", "assert sum_Of_Primes(10) == 17" ]
def check(candidate): # Check some simple cases assert sum_Of_Primes(10) == 17 assert sum_Of_Primes(20) == 77 assert sum_Of_Primes(5) == 10
686
Write a function to find the frequency of each element in the given list.
freq_element
from collections import defaultdict def freq_element(test_tup): res = defaultdict(int) for ele in test_tup: res[ele] += 1 return (str(dict(res)))
[ "assert freq_element((1, 7, 7, 5, 7, 2, 5, 10, 1, 8)) == {1: 2, 7: 3, 5: 2, 2: 1, 10: 1, 8: 1}", "assert freq_element((2, 1, 2, 2, 5, 7, 3, 4, 6, 3)) == {2: 3, 1: 1, 5: 1, 7: 1, 3: 2, 4: 1, 6: 1}", "assert freq_element((6, 3, 6, 1, 4, 8, 5, 6, 5, 12)) == {6: 3, 3: 1, 1: 1, 4: 1, 8: 1, 5: 2, 12: 1}" ]
def check(candidate): # Check some simple cases assert freq_element((4, 5, 4, 5, 6, 6, 5, 5, 4) ) == '{4: 3, 5: 4, 6: 2}' assert freq_element((7, 8, 8, 9, 4, 7, 6, 5, 4) ) == '{7: 2, 8: 2, 9: 1, 4: 2, 6: 1, 5: 1}' assert freq_element((1, 4, 3, 1, 4, 5, 2, 6, 2, 7) ) == '{1: 2, 4: 2, 3: 1, 5: 1, 2: 2, 6: 1, 7: 1}'
687
Write a function to find the greatest common divisor (gcd) of two integers by using recursion.
recur_gcd
def recur_gcd(a, b): low = min(a, b) high = max(a, b) if low == 0: return high elif low == 1: return 1 else: return recur_gcd(low, high%low)
[ "assert recur_gcd(4, 7) == 1", "assert recur_gcd(7, 5) == 1", "assert recur_gcd(14, 8) == 2" ]
def check(candidate): # Check some simple cases assert recur_gcd(12,14) == 2 assert recur_gcd(13,17) == 1 assert recur_gcd(9, 3) == 3
688
Write a function to get the length of a complex number.
len_complex
import cmath def len_complex(a,b): cn=complex(a,b) length=abs(cn) return length
[ "assert len_complex(7, 13) == 14.7648230602334", "assert len_complex(11, 7) == 13.038404810405298", "assert len_complex(11, 9) == 14.212670403551895" ]
def check(candidate): # Check some simple cases assert len_complex(3,4)==5.0 assert len_complex(9,10)==13.45362404707371 assert len_complex(7,9)==11.40175425099138
689
## write a function to find the minimum number of jumps to reach the end of the array for the given array of integers where each element represents the max number of steps that can be made forward from that element. > indented block > indented block
min_jumps
def min_jumps(arr, n): jumps = [0 for i in range(n)] if (n == 0) or (arr[0] == 0): return float('inf') jumps[0] = 0 for i in range(1, n): jumps[i] = float('inf') for j in range(i): if (i <= j + arr[j]) and (jumps[j] != float('inf')): jumps[i] = min(jumps[i], jumps[j] + 1) break return jumps[n-1]
[ "assert min_jumps([6, 2, 6, 5, 3, 4, 2, 4, 6, 2, 5], 13) == 3", "assert min_jumps([2, 2, 2, 2, 6, 2, 2, 2, 5, 6, 6], 6) == 3", "assert min_jumps([6, 5, 2, 3, 6, 1, 1, 2, 5, 5, 3], 8) == 2" ]
def check(candidate): # Check some simple cases assert min_jumps([1, 3, 6, 1, 0, 9], 6) == 3 assert min_jumps([1, 3, 5, 8, 9, 2, 6, 7, 6, 8, 9], 11) == 3 assert min_jumps([1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1], 11) == 10
690
Write a function to multiply consecutive numbers of a given list.
mul_consecutive_nums
def mul_consecutive_nums(nums): result = [b*a for a, b in zip(nums[:-1], nums[1:])] return result
[ "assert mul_consecutive_nums([2, 7, 5, 7, 7, 7, 3, 12, 9, 12]) == [14, 35, 35, 49, 49, 21, 36, 108, 108]", "assert mul_consecutive_nums([2, 3, 3, 2, 5, 9, 6, 6, 13, 8]) == [6, 9, 6, 10, 45, 54, 36, 78, 104]", "assert mul_consecutive_nums([4, 6, 1, 6, 5, 1, 5, 7, 13, 5]) == [24, 6, 6, 30, 5, 5, 35, 91, 65]" ]
def check(candidate): # Check some simple cases assert mul_consecutive_nums([1, 1, 3, 4, 4, 5, 6, 7])==[1, 3, 12, 16, 20, 30, 42] assert mul_consecutive_nums([4, 5, 8, 9, 6, 10])==[20, 40, 72, 54, 60] assert mul_consecutive_nums([1, 2, 3, 4, 5, 6, 7, 8, 9, 10])==[2, 6, 12, 20, 30, 42, 56, 72, 90]
691
Write a function to group the 1st elements on the basis of 2nd elements in the given tuple list.
group_element
from itertools import groupby def group_element(test_list): res = dict() for key, val in groupby(sorted(test_list, key = lambda ele: ele[1]), key = lambda ele: ele[1]): res[key] = [ele[0] for ele in val] return (res)
[ "assert group_element([(10, 7), (3, 14), (3, 8), (15, 4), (10, 14), (2, 8)]) == {4: [15], 7: [10], 8: [3, 2], 14: [3, 10]}", "assert group_element([(5, 4), (7, 11), (2, 2), (11, 10), (13, 7), (3, 8)]) == {2: [2], 4: [5], 7: [13], 8: [3], 10: [11], 11: [7]}", "assert group_element([(13, 4), (3, 6), (5, 7), (9, 6), (14, 14), (9, 8)]) == {4: [13], 6: [3, 9], 7: [5], 8: [9], 14: [14]}" ]
def check(candidate): # Check some simple cases assert group_element([(6, 5), (2, 7), (2, 5), (8, 7), (9, 8), (3, 7)]) == {5: [6, 2], 7: [2, 8, 3], 8: [9]} assert group_element([(7, 6), (3, 8), (3, 6), (9, 8), (10, 9), (4, 8)]) == {6: [7, 3], 8: [3, 9, 4], 9: [10]} assert group_element([(8, 7), (4, 9), (4, 7), (10, 9), (11, 10), (5, 9)]) == {7: [8, 4], 9: [4, 10, 5], 10: [11]}
692
Write a python function to find the last two digits in factorial of a given number.
last_Two_Digits
def last_Two_Digits(N): if (N >= 10): return fac = 1 for i in range(1,N + 1): fac = (fac * i) % 100 return (fac)
[ "assert last_Two_Digits(6) == 20", "assert last_Two_Digits(4) == 24", "assert last_Two_Digits(1) == 1" ]
def check(candidate): # Check some simple cases assert last_Two_Digits(7) == 40 assert last_Two_Digits(5) == 20 assert last_Two_Digits(2) == 2
693
Write a function to remove multiple spaces in a string by using regex.
remove_multiple_spaces
import re def remove_multiple_spaces(text1): return (re.sub(' +',' ',text1))
[ "assert remove_multiple_spaces(\"aWCT?>F_pP&QN|p/@Vtpl/JUqUsPn\") == \"aWCT?>F_pP&QN|p/@Vtpl/JUqUsPn\"", "assert remove_multiple_spaces(\"P^uR_/<=^x<n#uSwAdSrxDfLWIAQ\") == \"P^uR_/<=^x<n#uSwAdSrxDfLWIAQ\"", "assert remove_multiple_spaces(\"CFlwDllCYjy-F?W^FZq_CIeyTs~%\") == \"CFlwDllCYjy-F?W^FZq_CIeyTs~%\"" ]
def check(candidate): # Check some simple cases assert remove_multiple_spaces('Google Assistant') == 'Google Assistant' assert remove_multiple_spaces('Quad Core') == 'Quad Core' assert remove_multiple_spaces('ChromeCast Built-in') == 'ChromeCast Built-in'
694
Write a function to extract unique values from the given dictionary values.
extract_unique
def extract_unique(test_dict): res = list(sorted({ele for val in test_dict.values() for ele in val})) return res
[ "assert extract_unique({'P': [13, 8, 9, 22], 'I': [12, 6, 14, 18], 'R': [16, 22, 17, 37], 'Y': [35, 33, 30]}) == [6, 8, 9, 12, 13, 14, 16, 17, 18, 22, 30, 33, 35, 37]", "assert extract_unique({'T': [15, 23, 20, 37], 'B': [16, 9, 11, 13], 'K': [42, 35, 34]}) == [9, 11, 13, 15, 16, 20, 23, 34, 35, 37, 42]", "assert extract_unique({'V': [10, 13, 18, 12], 'H': [14, 10, 11, 15], 'Y': [21, 25, 18, 33], 'T': [36, 39, 39]}) == [10, 11, 12, 13, 14, 15, 18, 21, 25, 33, 36, 39]" ]
def check(candidate): # Check some simple cases assert extract_unique({'msm' : [5, 6, 7, 8],'is' : [10, 11, 7, 5],'best' : [6, 12, 10, 8],'for' : [1, 2, 5]} ) == [1, 2, 5, 6, 7, 8, 10, 11, 12] assert extract_unique({'Built' : [7, 1, 9, 4],'for' : [11, 21, 36, 14, 9],'ISP' : [4, 1, 21, 39, 47],'TV' : [1, 32, 38]} ) == [1, 4, 7, 9, 11, 14, 21, 32, 36, 38, 39, 47] assert extract_unique({'F' : [11, 13, 14, 17],'A' : [12, 11, 15, 18],'N' : [19, 21, 15, 36],'G' : [37, 36, 35]}) == [11, 12, 13, 14, 15, 17, 18, 19, 21, 35, 36, 37]
695
Write a function to check if each element of the second tuple is greater than its corresponding index in the first tuple.
check_greater
def check_greater(test_tup1, test_tup2): res = all(x < y for x, y in zip(test_tup1, test_tup2)) return (res)
[ "assert check_greater((1, 5, 2), (3, 5, 5)) == False", "assert check_greater((8, 4, 2), (5, 6, 5)) == False", "assert check_greater((9, 9, 3), (3, 11, 8)) == False" ]
def check(candidate): # Check some simple cases assert check_greater((10, 4, 5), (13, 5, 18)) == True assert check_greater((1, 2, 3), (2, 1, 4)) == False assert check_greater((4, 5, 6), (5, 6, 7)) == True
696
Write a function to zip two given lists of lists.
zip_list
def zip_list(list1,list2): result = list(map(list.__add__, list1, list2)) return result
[ "assert zip_list([['c', 'f'], ['g', 'f']], [['c', 'h'], ['f', 'm']]) == [['c', 'f', 'c', 'h'], ['g', 'f', 'f', 'm']]", "assert zip_list([['d', 's'], ['g', 'g']], [['c', 'b'], ['q', 'm']]) == [['d', 's', 'c', 'b'], ['g', 'g', 'q', 'm']]", "assert zip_list([['e', 'h'], ['z', 'c']], [['g', 'l'], ['w', 't']]) == [['e', 'h', 'g', 'l'], ['z', 'c', 'w', 't']]" ]
def check(candidate): # Check some simple cases assert zip_list([[1, 3], [5, 7], [9, 11]] ,[[2, 4], [6, 8], [10, 12, 14]] )==[[1, 3, 2, 4], [5, 7, 6, 8], [9, 11, 10, 12, 14]] assert zip_list([[1, 2], [3, 4], [5, 6]] ,[[7, 8], [9, 10], [11, 12]] )==[[1, 2, 7, 8], [3, 4, 9, 10], [5, 6, 11, 12]] assert zip_list([['a','b'],['c','d']] , [['e','f'],['g','h']] )==[['a','b','e','f'],['c','d','g','h']]
697
Write a function to find number of even elements in the given list using lambda function.
count_even
def count_even(array_nums): count_even = len(list(filter(lambda x: (x%2 == 0) , array_nums))) return count_even
[ "assert count_even([3, 5, 3, 5, 14]) == 1", "assert count_even([2, 5, 1, 4, 4]) == 3", "assert count_even([4, 3, 8, 13, 12]) == 3" ]
def check(candidate): # Check some simple cases assert count_even([1, 2, 3, 5, 7, 8, 9, 10])==3 assert count_even([10,15,14,13,-18,12,-20])==5 assert count_even([1, 2, 4, 8, 9])==3
698
Write a function to sort dictionary items by tuple product of keys for the given dictionary with tuple keys.
sort_dict_item
def sort_dict_item(test_dict): res = {key: test_dict[key] for key in sorted(test_dict.keys(), key = lambda ele: ele[1] * ele[0])} return (res)
[ "assert sort_dict_item({(4, 7): 2, (1, 5): 10, (13, 4): 7, (12, 8): 9}) == {(1, 5): 10, (4, 7): 2, (13, 4): 7, (12, 8): 9}", "assert sort_dict_item({(8, 8): 5, (5, 8): 8, (15, 6): 11, (13, 9): 19}) == {(5, 8): 8, (8, 8): 5, (15, 6): 11, (13, 9): 19}", "assert sort_dict_item({(10, 4): 10, (5, 2): 15, (11, 7): 13, (7, 6): 16}) == {(5, 2): 15, (10, 4): 10, (7, 6): 16, (11, 7): 13}" ]
def check(candidate): # Check some simple cases assert sort_dict_item({(5, 6) : 3, (2, 3) : 9, (8, 4): 10, (6, 4): 12} ) == {(2, 3): 9, (6, 4): 12, (5, 6): 3, (8, 4): 10} assert sort_dict_item({(6, 7) : 4, (3, 4) : 10, (9, 5): 11, (7, 5): 13} ) == {(3, 4): 10, (7, 5): 13, (6, 7): 4, (9, 5): 11} assert sort_dict_item({(7, 8) : 5, (4, 5) : 11, (10, 6): 12, (8, 6): 14} ) == {(4, 5): 11, (8, 6): 14, (7, 8): 5, (10, 6): 12}
699
Write a python function to find the minimum number of swaps required to convert one binary string to another.
min_Swaps
def min_Swaps(str1,str2) : count = 0 for i in range(len(str1)) : if str1[i] != str2[i] : count += 1 if count % 2 == 0 : return (count // 2) else : return ("Not Possible")
[ "assert min_Swaps('8473', '99395') == 2", "assert min_Swaps('244', '012916') == \"Not Possible\"", "assert min_Swaps('70903112', '5619576853') == 4" ]
def check(candidate): # Check some simple cases assert min_Swaps("1101","1110") == 1 assert min_Swaps("1111","0100") == "Not Possible" assert min_Swaps("1110000","0001101") == 3
700
Write a function to count the number of elements in a list which are within a specific range.
count_range_in_list
def count_range_in_list(li, min, max): ctr = 0 for x in li: if min <= x <= max: ctr += 1 return ctr
[ "assert count_range_in_list([4, 4, 13, 12, 16, 21, 40], 20, 25) == 1", "assert count_range_in_list([10, 10, 10, 20, 20, 18, 45], 12, 25) == 3", "assert count_range_in_list([12, 12, 11, 15, 13, 23, 48], 15, 20) == 1" ]
def check(candidate): # Check some simple cases assert count_range_in_list([10,20,30,40,40,40,70,80,99],40,100)==6 assert count_range_in_list(['a','b','c','d','e','f'],'a','e')==5 assert count_range_in_list([7,8,9,15,17,19,45],15,20)==3