task_id int64 601 974 | text large_stringlengths 38 249 | code large_stringlengths 30 908 | test_list listlengths 3 3 | test_setup_code large_stringclasses 2
values | challenge_test_list listlengths 0 0 |
|---|---|---|---|---|---|
728 | Write a function to caluclate the area of a tetrahedron. | def Check_Solution(a,b,c):
if b == 0:
return ("Yes")
else:
return ("No") | [
"assert Sum_of_Inverse_Divisors(6,12) == 2",
"assert Sum_of_Inverse_Divisors(9,13) == 1.44",
"assert Sum_of_Inverse_Divisors(1,4) == 4"
] | [] | |
947 | Write a function to perform chunking of tuples each of size n. | def remove_similar_row(test_list):
res = set(sorted([tuple(sorted(set(sub))) for sub in test_list]))
return (res) | [
"assert str_to_tuple(\"1, -5, 4, 6, 7\") == (1, -5, 4, 6, 7)",
"assert str_to_tuple(\"1, 2, 3, 4, 5\") == (1, 2, 3, 4, 5)",
"assert str_to_tuple(\"4, 6, 9, 11, 13, 14\") == (4, 6, 9, 11, 13, 14)"
] | [] | |
809 | Write a function to find minimum of two numbers. | 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 even_num(13.5)==False",
"assert even_num(0)==True",
"assert even_num(-9)==False"
] | [] | |
812 | Write a function to convert the given tuple to a key-value dictionary using adjacent elements. | def find_triplet_array(A, arr_size, sum):
for i in range( 0, arr_size-2):
for j in range(i + 1, arr_size-1):
for k in range(j + 1, arr_size):
if A[i] + A[j] + A[k] == sum:
return A[i],A[j],A[k]
return True
return False | [
"assert find_Extra([1,2,3,4],[1,2,3],3) == 3",
"assert find_Extra([2,4,6,8,10],[2,4,6,8],4) == 4",
"assert find_Extra([1,3,5,7,9,11],[1,3,5,7,9],5) == 5"
] | [] | |
939 | Write a python function to get the last element of each sublist. | import math
def count_Divisors(n) :
count = 0
for i in range(1, (int)(math.sqrt(n)) + 2) :
if (n % i == 0) :
if( n // i == i) :
count = count + 1
else :
count = count + 2
if (count % 2 == 0) :
return ("Even")
else... | [
"assert add_dict_to_tuple((4, 5, 6), {\"MSAM\" : 1, \"is\" : 2, \"best\" : 3} ) == (4, 5, 6, {'MSAM': 1, 'is': 2, 'best': 3})",
"assert add_dict_to_tuple((1, 2, 3), {\"UTS\" : 2, \"is\" : 3, \"Worst\" : 4} ) == (1, 2, 3, {'UTS': 2, 'is': 3, 'Worst': 4})",
"assert add_dict_to_tuple((8, 9, 10), {\"POS\" : 3, \"is... | [] | |
648 | Write a function to find the area of a rombus. | def pair_wise(l1):
temp = []
for i in range(len(l1) - 1):
current_element, next_element = l1[i], l1[i + 1]
x = (current_element, next_element)
temp.append(x)
return temp | [
"assert average_Even(2) == 2",
"assert average_Even(4) == 3",
"assert average_Even(100) == 51"
] | [] | |
604 | Write a function that matches a string that has an 'a' followed by anything, ending in 'b'. | import re
def text_match_zero_one(text):
patterns = 'ab?'
if re.search(patterns, text):
return 'Found a match!'
else:
return('Not matched!') | [
"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'"
] | [] | |
663 | Write a python function to find sum of products of all possible subarrays. | def area_trapezium(base1,base2,height):
area = 0.5 * (base1 + base2) * height
return area | [
"assert get_Pairs_Count([1,1,1,1],4,2) == 6",
"assert get_Pairs_Count([1,5,7,-1,5],5,6) == 3",
"assert get_Pairs_Count([1,-2,3],3,1) == 1"
] | [] | |
681 | Write a function to round up a number to specific digits. | def find_Extra(arr1,arr2,n) :
for i in range(0, n) :
if (arr1[i] != arr2[i]) :
return i
return n | [
"assert maximum_segments(7, 5, 2, 5) == 2",
"assert maximum_segments(17, 2, 1, 3) == 17",
"assert maximum_segments(18, 16, 3, 6) == 6"
] | [] | |
614 | Write a python function to check whether a sequence of numbers has an increasing trend or not. | 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]): ... | [
"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]"
] | [] | |
654 | Write a function to count occurrence of a character in a string. | def triangle_area(r) :
if r < 0 :
return -1
return r * r | [
"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]"
] | [] | |
731 | Write a function to check if the given tuples contain the k or not. | import math
def get_First_Set_Bit_Pos(n):
return math.log2(n&-n)+1 | [
"assert join_tuples([(5, 6), (5, 7), (6, 8), (6, 10), (7, 13)] ) == [(5, 6, 7), (6, 8, 10), (7, 13)]",
"assert join_tuples([(6, 7), (6, 8), (7, 9), (7, 11), (8, 14)] ) == [(6, 7, 8), (7, 9, 11), (8, 14)]",
"assert join_tuples([(7, 8), (7, 9), (8, 10), (8, 12), (9, 15)] ) == [(7, 8, 9), (8, 10, 12), (9, 15)]"
] | [] | |
873 | Write a python function to find the first repeated character in a given string. | def odd_position(nums):
return all(nums[i]%2==i%2 for i in range(len(nums))) | [
"assert power_base_sum(2,100)==115",
"assert power_base_sum(8,10)==37",
"assert power_base_sum(8,15)==62"
] | [] | |
669 | Write a python function to count lower case letters in a given string. | 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 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\")==(\... | [] | |
921 | Write a function to find the largest subset where each pair is divisible. | def Average(lst):
return sum(lst) / len(lst) | [
"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!')"
] | [] | |
806 | Write a python function to count the number of pairs whose sum is equal to ‘sum’. | def is_key_present(d,x):
if x in d:
return True
else:
return False | [
"assert add_list([1, 2, 3],[4,5,6])==[5, 7, 9]",
"assert add_list([1,2],[3,4])==[4,6]",
"assert add_list([10,20],[50,70])==[60,90]"
] | [] | |
655 | Write a function to check if the given expression is balanced or not. | def mul_list(nums1,nums2):
result = map(lambda x, y: x * y, nums1, nums2)
return list(result) | [
"assert get_unique([(3, 4), (1, 2), (2, 4), (8, 2), (7, 2), (8, 1), (9, 1), (8, 4), (10, 4)] ) == '{4: 4, 2: 3, 1: 2}'",
"assert get_unique([(4, 5), (2, 3), (3, 5), (9, 3), (8, 3), (9, 2), (10, 2), (9, 5), (11, 5)] ) == '{5: 4, 3: 3, 2: 2}'",
"assert get_unique([(6, 5), (3, 4), (2, 6), (11, 1), (8, 22), (8, 11)... | [] | |
639 | Write a function to convert the given tuples into set. | def sum_Range_list(nums, m, n):
sum_range = 0 ... | [
"assert wind_chill(120,35)==40",
"assert wind_chill(40,70)==86",
"assert wind_chill(10,100)==116"
] | [] | |
813 | Write a function to add the given tuple to the given list. | def div_of_nums(nums,m,n):
result = list(filter(lambda x: (x % m == 0 and x % n == 0), nums))
return result | [
"assert count_Char(\"abcac\",'a') == 4",
"assert count_Char(\"abca\",'c') == 2",
"assert count_Char(\"aba\",'a') == 7"
] | [] | |
601 | Write a python function to find minimum number swaps required to make two binary strings equal. | def sum_Odd(n):
terms = (n + 1)//2
sum1 = terms * terms
return sum1
def sum_in_Range(l,r):
return sum_Odd(r) - sum_Odd(l - 1) | [
"assert find_Index(2) == 4",
"assert find_Index(3) == 14",
"assert find_Index(4) == 45"
] | [] | |
740 | Write a function to find the item with maximum occurrences in a given list. | def nCr_mod_p(n, r, p):
if (r > n- r):
r = n - r
C = [0 for i in range(r + 1)]
C[0] = 1
for i in range(1, n + 1):
for j in range(min(i, r), 0, -1):
C[j] = (C[j] + C[j-1]) % p
return C[r] | [
"assert count_same_pair([1, 2, 3, 4, 5, 6, 7, 8],[2, 2, 3, 1, 2, 6, 7, 9])==4",
"assert count_same_pair([0, 1, 2, -1, -5, 6, 0, -3, -2, 3, 4, 6, 8],[2, 1, 2, -1, -5, 6, 4, -3, -2, 3, 4, 6, 8])==11",
"assert count_same_pair([2, 4, -6, -9, 11, -12, 14, -5, 17],[2, 1, 2, -1, -5, 6, 4, -3, -2, 3, 4, 6, 8])==1"
] | [] | |
680 | Write a function to push all values into a heap and then pop off the smallest values one at a time. | def ntimes_list(nums,n):
result = map(lambda x:n*x, nums)
return list(result) | [
"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)"
] | [] | |
799 | Write a function to check if the triangle is valid or not. | def is_Isomorphic(str1,str2):
dict_str1 = {}
dict_str2 = {}
for i, value in enumerate(str1):
dict_str1[value] = dict_str1.get(value,[]) + [i]
for j, value in enumerate(str2):
dict_str2[value] = dict_str2.get(value,[]) + [j]
if sorted(dict_str1.values()) == so... | [
"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"
] | [] | |
725 | Write a function to check if the given array represents min heap or not. | 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 sum_series(7)==784",
"assert sum_series(5)==225",
"assert sum_series(15)==14400"
] | [] | |
822 | Write a function to join the tuples if they have similar initial elements. | def check_monthnumber_number(monthnum3):
if(monthnum3==4 or monthnum3==6 or monthnum3==9 or monthnum3==11):
return True
else:
return False | [
"assert count_tuplex((2, 4, 5, 6, 2, 3, 4, 4, 7),4)==3",
"assert count_tuplex((2, 4, 5, 6, 2, 3, 4, 4, 7),2)==2",
"assert count_tuplex((2, 4, 7, 7, 7, 3, 4, 4, 7),7)==4"
] | [] | |
972 | Write a python function to find minimum possible value for the given periodic function. | 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 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"
] | [] | |
827 | Write a function to convert an integer into a roman numeral. | import math
def sum_of_odd_Factors(n):
res = 1
while n % 2 == 0:
n = n // 2
for i in range(3,int(math.sqrt(n) + 1)):
count = 0
curr_sum = 1
curr_term = 1
while n % i == 0:
count+=1
n = n // i
curr_term *= i
... | [
"assert palindrome_lambda([\"php\", \"res\", \"Python\", \"abcd\", \"Java\", \"aaa\"])==['php', 'aaa']",
"assert palindrome_lambda([\"abcd\", \"Python\", \"abba\", \"aba\"])==['abba', 'aba']",
"assert palindrome_lambda([\"abcd\", \"abbccbba\", \"abba\", \"aba\"])==['abbccbba', 'abba', 'aba']"
] | [] | |
895 | Write a function to check whether the given string is ending with only alphanumeric characters or not using regex. | def decreasing_trend(nums):
if (sorted(nums)== nums):
return True
else:
return False | [
"assert count_char(\"Python\",'o')==1",
"assert count_char(\"little\",'t')==2",
"assert count_char(\"assert\",'s')==2"
] | [] | |
714 | Write a python function to find the average of a list. | import math
def sum_series(number):
total = 0
total = math.pow((number * (number + 1)) /2, 2)
return total | [
"assert decreasing_trend([-4,-3,-2,-1]) == True",
"assert decreasing_trend([1,2,3]) == True",
"assert decreasing_trend([3,2,1]) == False"
] | [] | |
634 | Write a python function to find the sum of all odd length subarrays. | def multiply_list(items):
tot = 1
for x in items:
tot *= x
return tot | [
"assert end_num('abcdef')==False",
"assert end_num('abcdef7')==True",
"assert end_num('abc')==False"
] | [] | |
752 | Write a python function to move all zeroes to the end of the given list. | def super_seq(X, Y, m, n):
if (not m):
return n
if (not n):
return m
if (X[m - 1] == Y[n - 1]):
return 1 + super_seq(X, Y, m - 1, n - 1)
return 1 + min(super_seq(X, Y, m - 1, n), super_seq(X, Y, m, n - 1)) | [
"assert rombus_perimeter(10)==40",
"assert rombus_perimeter(5)==20",
"assert rombus_perimeter(4)==16"
] | [] | |
776 | Write a function to caluclate arc length of an angle. | def Sum_of_Inverse_Divisors(N,Sum):
ans = float(Sum)*1.0 /float(N);
return round(ans,2); | [
"assert remove_extra_char('**//Google Android// - 12. ') == 'GoogleAndroid12'",
"assert remove_extra_char('****//Google Flutter//*** - 36. ') == 'GoogleFlutter36'",
"assert remove_extra_char('**//Google Firebase// - 478. ') == 'GoogleFirebase478'"
] | [] | |
656 | Write a function to locate the left insertion point for a specified value in sorted order. | def floor_Max(A,B,N):
x = min(B - 1,N)
return (A*x) // B | [
"assert is_Product_Even([1,2,3],3) == True",
"assert is_Product_Even([1,2,1,4],4) == True",
"assert is_Product_Even([1,1],2) == False"
] | [] | |
718 | Write a function to compute the value of ncr mod p. | def check_none(test_tup):
res = any(map(lambda ele: ele is None, test_tup))
return (res) | [
"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"
] | [] | |
894 | Write a function to count the same pair in two given lists using map function. | M = 100
def maxAverageOfPath(cost, N):
dp = [[0 for i in range(N + 1)] for j in range(N + 1)]
dp[0][0] = cost[0][0]
for i in range(1, N):
dp[i][0] = dp[i - 1][0] + cost[i][0]
for j in range(1, N):
dp[0][j] = dp[0][j - 1] + cost[0][j]
for i in range(1, N):
for j in range(1, N):
dp[i][j] ... | [
"assert split_upperstring(\"PythonProgramLanguage\")==['Python','Program','Language']",
"assert split_upperstring(\"PythonProgram\")==['Python','Program']",
"assert split_upperstring(\"ProgrammingLanguage\")==['Programming','Language']"
] | [] | |
773 | Write a function to convert a roman numeral to an integer. | def is_abundant(n):
fctrsum = sum([fctr for fctr in range(1, n) if n % fctr == 0])
return fctrsum > n | [
"assert Average([15, 9, 55, 41, 35, 20, 62, 49]) == 35.75",
"assert Average([4, 5, 1, 2, 9, 7, 10, 8]) == 5.75",
"assert Average([1,2,3]) == 2"
] | [] | |
884 | Write a function to check a decimal with a precision of 2. | def reverse_Array_Upto_K(input, k):
return (input[k-1::-1] + input[k:]) | [
"assert chunk_tuples((10, 4, 5, 6, 7, 6, 8, 3, 4), 3) == [(10, 4, 5), (6, 7, 6), (8, 3, 4)]",
"assert chunk_tuples((1, 2, 3, 4, 5, 6, 7, 8, 9), 2) == [(1, 2), (3, 4), (5, 6), (7, 8), (9,)]",
"assert chunk_tuples((11, 14, 16, 17, 19, 21, 22, 25), 4) == [(11, 14, 16, 17), (19, 21, 22, 25)]"
] | [] | |
623 | Write a function to calculate the sum of all digits of the base to the specified power. | def rearrange_numbs(array_nums):
result = sorted(array_nums, key = lambda i: 0 if i == 0 else -1 / i)
return result | [
"assert roman_to_int('MMMCMLXXXVI')==3986",
"assert roman_to_int('MMMM')==4000",
"assert roman_to_int('C')==100"
] | [] | |
745 | Write a function to find the minimum number of elements that should be removed such that amax-amin<=k. | import re
def text_match_three(text):
patterns = 'ab{3}?'
if re.search(patterns, text):
return 'Found a match!'
else:
return('Not matched!') | [
"assert check_K((10, 4, 5, 6, 8), 6) == True",
"assert check_K((1, 2, 3, 4, 5, 6), 7) == False",
"assert check_K((7, 8, 9, 44, 11, 12), 11) == True"
] | [] | |
678 | Write a function to solve the fibonacci sequence using recursion. | 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 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]"
] | [] | |
893 | Write a function to count the elements in a list until an element is a tuple. | import re
def remove_multiple_spaces(text1):
return (re.sub(' +',' ',text1)) | [
"assert chinese_zodiac(1997)==('Ox')",
"assert chinese_zodiac(1998)==('Tiger')",
"assert chinese_zodiac(1994)==('Dog')"
] | [] | |
971 | Write a function to find the previous palindrome of a specified number. | def sum_Of_Subarray_Prod(arr,n):
ans = 0
res = 0
i = n - 1
while (i >= 0):
incr = arr[i]*(1 + res)
ans += incr
res = incr
i -= 1
return (ans) | [
"assert check_element((4, 5, 7, 9, 3), [6, 7, 10, 11]) == True",
"assert check_element((1, 2, 3, 4), [4, 6, 7, 8, 9]) == True",
"assert check_element((3, 2, 1, 4, 5), [9, 8, 7, 6]) == False"
] | [] | |
957 | Write a function to remove multiple spaces in a string. | def reverse_list_lists(lists):
for l in lists:
l.sort(reverse = True)
return lists | [
"assert max_of_two(10,20)==20",
"assert max_of_two(19,15)==19",
"assert max_of_two(-10,-20)==-10"
] | [] | |
821 | Write a python function to choose points from two ranges such that no point lies in both the ranges. | def generate_matrix(n):
if n<=0:
return []
matrix=[row[:] for row in [[0]*n]*n]
row_st=0
row_ed=n-1
col_st=0
col_ed=n-1
current=1
while (True):
if current>n*n:
break
f... | [
"assert remove_char(\"123abcjw:, .@! eiw\") == '123abcjweiw'",
"assert remove_char(\"Hello1234:, ! Howare33u\") == 'Hello1234Howare33u'",
"assert remove_char(\"Cool543Triks@:, Make@987Trips\") == 'Cool543TriksMake987Trips' "
] | [] | |
721 | Write a function to calculate the sum of series 1³+2³+3³+….+n³. | import math
def round_up(a, digits):
n = 10**-digits
return round(math.ceil(a / n) * n, digits) | [
"assert check_smaller((1, 2, 3), (2, 3, 4)) == False",
"assert check_smaller((4, 5, 6), (3, 4, 5)) == True",
"assert check_smaller((11, 12, 13), (10, 11, 12)) == True"
] | [] | |
742 | Write a function to remove the parenthesis area in a string. | def harmonic_sum(n):
if n < 2:
return 1
else:
return 1 / n + (harmonic_sum(n - 1)) | [
"assert convert([1,2,3]) == 123",
"assert convert([4,5,6]) == 456",
"assert convert([7,8,9]) == 789"
] | [] | |
766 | Write a function to find the longest chain which can be formed from the given set of pairs. | def maximum_value(test_list):
res = [(key, max(lst)) for key, lst in test_list]
return (res) | [
"assert text_starta_endb(\"aabbbb\")==('Found a match!')",
"assert text_starta_endb(\"aabAbbbc\")==('Not matched!')",
"assert text_starta_endb(\"accddbbjjj\")==('Not matched!')"
] | [] | |
719 | Write a function to remove duplicates from a list of lists. | def odd_Num_Sum(n) :
j = 0
sm = 0
for i in range(1,n + 1) :
j = (2*i-1)
sm = sm + (j*j*j*j)
return sm | [
"assert min_Swaps(\"1101\",\"1110\") == 1",
"assert min_Swaps(\"1111\",\"0100\") == \"Not Possible\"",
"assert min_Swaps(\"1110000\",\"0001101\") == 3"
] | [] | |
715 | Write a function to check if one tuple is a subset of another tuple. | def is_decimal(num):
import re
dnumre = re.compile(r"""^[0-9]+(\.[0-9]{1,2})?$""")
result = dnumre.search(num)
return bool(result) | [
"assert all_Characters_Same(\"python\") == False",
"assert all_Characters_Same(\"aaa\") == True",
"assert all_Characters_Same(\"data\") == False"
] | [] | |
962 | Write a python function to find the index of smallest triangular number with n digits. | def check_monthnumb(monthname2):
if(monthname2=="January" or monthname2=="March"or monthname2=="May" or monthname2=="July" or monthname2=="Augest" or monthname2=="October" or monthname2=="December"):
return True
else:
return False | [
"assert fifth_Power_Sum(2) == 33",
"assert fifth_Power_Sum(4) == 1300",
"assert fifth_Power_Sum(3) == 276"
] | [] | |
879 | Write a python function to find the minimum difference between any two elements in a given array. | def check(string):
if len(set(string).intersection("AEIOUaeiou"))>=5:
return ('accepted')
else:
return ("not accepted") | [
"assert sort_tuple([(\"Amana\", 28), (\"Zenat\", 30), (\"Abhishek\", 29),(\"Nikhil\", 21), (\"B\", \"C\")]) == [('Abhishek', 29), ('Amana', 28), ('B', 'C'), ('Nikhil', 21), ('Zenat', 30)]",
"assert sort_tuple([(\"aaaa\", 28), (\"aa\", 30), (\"bab\", 29), (\"bb\", 21), (\"csa\", \"C\")]) == [('aa', 30), ('aaaa', 2... | [] | |
840 | Write a function which accepts an arbitrary list and converts it to a heap using heap queue algorithm. | def min_Swaps(s1,s2) :
c0 = 0; c1 = 0;
for i in range(len(s1)) :
if (s1[i] == '0' and s2[i] == '1') :
c0 += 1;
elif (s1[i] == '1' and s2[i] == '0') :
c1 += 1;
result = c0 // 2 + c1 // 2;
if (c0 % 2 == 0 and c1 % 2 == 0) :
return r... | [
"assert mutiple_tuple((4, 3, 2, 2, -1, 18)) == -864",
"assert mutiple_tuple((1,2,3)) == 6",
"assert mutiple_tuple((-2,-4,-6)) == -48"
] | [] | |
837 | Write a function to convert camel case string to snake case string. | import re
def end_num(string):
text = re.compile(r".*[0-9]$")
if text.match(string):
return True
else:
return False | [
"assert count_alpha_dig_spl(\"abc!@#123\")==(3,3,3)",
"assert count_alpha_dig_spl(\"dgsuy@#$%&1255\")==(5,4,5)",
"assert count_alpha_dig_spl(\"fjdsif627348#%$^&\")==(6,6,5)"
] | [] | |
671 | Write a function that matches a word containing 'z', not at the start or end of the word. | def jacobsthal_num(n):
dp = [0] * (n + 1)
dp[0] = 0
dp[1] = 1
for i in range(2, n+1):
dp[i] = dp[i - 1] + 2 * dp[i - 2]
return dp[n] | [
"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] "
] | [] | |
753 | Write a python function to merge the first and last elements separately in a list of lists. | def divisible_by_digits(startnum, endnum):
return [n for n in range(startnum, endnum+1) \
if not any(map(lambda x: int(x) == 0 or n%int(x) != 0, str(n)))] | [
"assert super_seq(\"AGGTAB\", \"GXTXAYB\", 6, 7) == 9",
"assert super_seq(\"feek\", \"eke\", 4, 3) == 5",
"assert super_seq(\"PARRT\", \"RTA\", 5, 3) == 6"
] | [] | |
616 | Write a python function to find the smallest prime divisor of a number. | def min_difference(test_list):
temp = [abs(b - a) for a, b in test_list]
res = min(temp)
return (res) | [
"assert check_Odd_Parity(13) == True",
"assert check_Odd_Parity(21) == True",
"assert check_Odd_Parity(18) == False"
] | [] | |
820 | Write a python function to set the right most unset bit. | def noprofit_noloss(actual_cost,sale_amount):
if(sale_amount == actual_cost):
return True
else:
return False | [
"assert set_Right_most_Unset_Bit(21) == 23",
"assert set_Right_most_Unset_Bit(11) == 15",
"assert set_Right_most_Unset_Bit(15) == 15"
] | [] | |
946 | Write a function to sort the tuples alphabetically by the first item of each tuple. | def find_ind(key, i, n,
k, arr):
ind = -1
start = i + 1
end = n - 1;
while (start < end):
mid = int(start +
(end - start) / 2)
if (arr[mid] - key <= k):
ind = mid
start = mid + 1
else:
end = mid
return ind
def removals(arr, n, k):
ans = n - 1
arr.sort()
for i in range(0, ... | [
"assert floor_Max(11,10,9) == 9",
"assert floor_Max(5,7,4) == 2",
"assert floor_Max(2,2,1) == 1"
] | [] | |
892 | Write a function to convert the given string of integers into a tuple. | def cube_Sum(n):
sum = 0
for i in range(0,n) :
sum += (2*i+1)*(2*i+1)*(2*i+1)
return sum | [
"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'"
] | [] | |
870 | Write a python function to find the largest triangle that can be inscribed in the semicircle. | class Node:
def __init__(self, data):
self.data = data
self.left = None
self.right = None
def max_height(node):
if node is None:
return 0 ;
else :
left_height = max_height(node.left)
right_height = max_height(node.right)
if (left_height > right_height):
return left_height+1
... | [
"assert sum_column( [[1,2,3,2],[4,5,6,2],[7,8,9,5],],0)==12",
"assert sum_column( [[1,2,3,2],[4,5,6,2],[7,8,9,5],],1)==15",
"assert sum_column( [[1,2,3,2],[4,5,6,2],[7,8,9,5],],3)==9"
] | [] | |
940 | Write a function to calculate the discriminant value. | import heapq
def cheap_items(items,n):
cheap_items = heapq.nsmallest(n, items, key=lambda s: s['price'])
return cheap_items | [
"assert new_tuple([\"WEB\", \"is\"], \"best\") == ('WEB', 'is', 'best')",
"assert new_tuple([\"We\", \"are\"], \"Developers\") == ('We', 'are', 'Developers')",
"assert new_tuple([\"Part\", \"is\"], \"Wrong\") == ('Part', 'is', 'Wrong')"
] | [] | |
632 | Write a function to remove an empty tuple from a list of tuples. | 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 rectangle_perimeter(10,20)==60",
"assert rectangle_perimeter(10,5)==30",
"assert rectangle_perimeter(4,2)==12"
] | [] | |
830 | Write a python function to find the smallest missing number from the given array. | def slope(x1,y1,x2,y2):
return (float)(y2-y1)/(x2-x1) | [
"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"
] | [] | |
864 | Write a python function to sort the given string. | def count_list(input_list):
return len(input_list) | [
"assert test_three_equal(1,1,1) == 3",
"assert test_three_equal(-1,-2,-3) == 0",
"assert test_three_equal(1,2,2) == 2"
] | [] | |
707 | Write a function to find all anagrams of a string in a given list of strings using lambda function. | def check(arr,n):
g = 0
for i in range(1,n):
if (arr[i] - arr[i - 1] > 0 and g == 1):
return False
if (arr[i] - arr[i] < 0):
g = 1
return True | [
"assert is_abundant(12)==True",
"assert is_abundant(13)==False",
"assert is_abundant(9)==False"
] | [] | |
726 | Write a function to check if the given tuple contains only k elements. | def concatenate_nested(test_tup1, test_tup2):
res = test_tup1 + test_tup2
return (res) | [
"assert prime_num(13)==True",
"assert prime_num(7)==True",
"assert prime_num(-1010)==False"
] | [] | |
794 | Write a python function to find the minimun number of subsets with distinct elements. | def find_Sum(arr,n):
arr.sort()
sum = arr[0]
for i in range(0,n-1):
if (arr[i] != arr[i+1]):
sum = sum + arr[i+1]
return sum | [
"assert Check_Solution(2,0,-1) == \"Yes\"",
"assert Check_Solution(1,-5,6) == \"No\"",
"assert Check_Solution(2,0,2) == \"Yes\""
] | [] | |
900 | Write a function to find the lateral surface area of a cone. | import math
def radian_degree(degree):
radian = degree*(math.pi/180)
return radian | [
"assert filter_data({'Cierra Vega': (6.2, 70), 'Alden Cantrell': (5.9, 65), 'Kierra Gentry': (6.0, 68), 'Pierre Cox': (5.8, 66)},6.0,70)=={'Cierra Vega': (6.2, 70)}",
"assert filter_data({'Cierra Vega': (6.2, 70), 'Alden Cantrell': (5.9, 65), 'Kierra Gentry': (6.0, 68), 'Pierre Cox': (5.8, 66)},5.9,67)=={'Cierra ... | [] | |
723 | Write a python function to check whether the given number is a perfect square or not. | def remove_spaces(str1):
str1 = str1.replace(' ','')
return str1 | [
"assert remove_spaces('python program')==('python program')",
"assert remove_spaces('python programming language')==('python programming language')",
"assert remove_spaces('python program')==('python program')"
] | [] | |
818 | Write a function to count number of unique lists within a list. | from collections import deque
def check_expression(exp):
if len(exp) & 1:
return False
stack = deque()
for ch in exp:
if ch == '(' or ch == '{' or ch == '[':
stack.append(ch)
if ch == ')' or ch == '}' or ch == ']':
if not stack:
retur... | [
"assert max_sum_subseq([1, 2, 9, 4, 5, 0, 4, 11, 6]) == 26",
"assert max_sum_subseq([1, 2, 9, 5, 6, 0, 5, 12, 7]) == 28",
"assert max_sum_subseq([1, 3, 10, 5, 6, 0, 6, 14, 21]) == 44"
] | [] | |
626 | Write a function to generate a square matrix filled with elements from 1 to n raised to the power of 2 in spiral order. | def sort_numeric_strings(nums_str):
result = [int(x) for x in nums_str]
result.sort()
return result | [
"assert concatenate_nested((3, 4), (5, 6)) == (3, 4, 5, 6)",
"assert concatenate_nested((1, 2), (3, 4)) == (1, 2, 3, 4)",
"assert concatenate_nested((4, 5), (6, 8)) == (4, 5, 6, 8)"
] | [] | |
835 | Write a function to remove duplicate words from a given list of strings. | 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 check_tuples((3, 5, 6, 5, 3, 6),[3, 6, 5]) == True",
"assert check_tuples((4, 5, 6, 4, 6, 5),[4, 5, 6]) == True",
"assert check_tuples((9, 8, 7, 6, 8, 9),[9, 8, 1]) == False"
] | [] | |
885 | Write a python function to check whether the given two numbers have same number of digits or not. | def chinese_zodiac(year):
if (year - 2000) % 12 == 0:
sign = 'Dragon'
elif (year - 2000) % 12 == 1:
sign = 'Snake'
elif (year - 2000) % 12 == 2:
sign = 'Horse'
elif (year - 2000) % 12 == 3:
sign = 'sheep'
elif (year - 2000) % 12 == 4:
sign = 'Monkey'
elif (year - 2000) % 12 == ... | [
"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"
] | [] | |
888 | Write a python function to check whether the product of digits of a number at even and odd places is equal or not. | import re
regex = '[a-zA-z0-9]$'
def check_alphanumeric(string):
if(re.search(regex, string)):
return ("Accept")
else:
return ("Discard") | [
"assert extract_index_list([1, 1, 3, 4, 5, 6, 7],[0, 1, 2, 3, 4, 5, 7],[0, 1, 2, 3, 4, 5, 7])==[1, 7]",
"assert extract_index_list([1, 1, 3, 4, 5, 6, 7],[0, 1, 2, 3, 4, 6, 5],[0, 1, 2, 3, 4, 6, 7])==[1, 6]",
"assert extract_index_list([1, 1, 3, 4, 6, 5, 6],[0, 1, 2, 3, 4, 5, 7],[0, 1, 2, 3, 4, 5, 7])==[1, 5]"
] | [] | |
902 | Write a function to extract all the adjacent coordinates of the given coordinate tuple. | import datetime
def check_date(m, d, y):
try:
m, d, y = map(int, (m, d, y))
datetime.date(y, m, d)
return True
except ValueError:
return False | [
"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"
] | [] | |
706 | Write a python function to find sum of odd factors of a number. | def is_subset(arr1, m, arr2, n):
hashset = set()
for i in range(0, m):
hashset.add(arr1[i])
for i in range(0, n):
if arr2[i] in hashset:
continue
else:
return False
return True | [
"assert increasing_trend([1,2,3,4]) == True",
"assert increasing_trend([4,3,2,1]) == False",
"assert increasing_trend([0,1,4,9]) == True"
] | [] | |
784 | Write a function to separate and print the numbers and their position of a given string. | def count_Set_Bits(n) :
n += 1;
powerOf2 = 2;
cnt = n // 2;
while (powerOf2 <= n) :
totalPairs = n // powerOf2;
cnt += (totalPairs // 2) * powerOf2;
if (totalPairs & 1) :
cnt += (n % powerOf2)
else :
cnt += 0
powe... | [
"assert unique_Element([1,1,1],3) == 'YES'",
"assert unique_Element([1,2,1,2],4) == 'NO'",
"assert unique_Element([1,2,3,4,5],5) == 'NO'"
] | [] | |
765 | Write a python function to find the length of the shortest word. | import re
def extract_max(input):
numbers = re.findall('\d+',input)
numbers = map(int,numbers)
return max(numbers) | [
"assert second_frequent(['aaa','bbb','ccc','bbb','aaa','aaa']) == 'bbb'",
"assert second_frequent(['abc','bcd','abc','bcd','bcd','bcd']) == 'abc'",
"assert second_frequent(['cdma','gsm','hspa','gsm','cdma','cdma']) == 'gsm'"
] | [] | |
736 | Write a function to combine two dictionaries by adding values for common keys. | def _sum(arr):
sum=0
for i in arr:
sum = sum + i
return(sum) | [
"assert perimeter_polygon(4,20)==80",
"assert perimeter_polygon(10,15)==150",
"assert perimeter_polygon(9,7)==63"
] | [] | |
897 | Write a python function to shift first element to the end of given list. | def lcopy(xs):
return xs[:]
| [
"assert merge_dictionaries({ \"R\": \"Red\", \"B\": \"Black\", \"P\": \"Pink\" }, { \"G\": \"Green\", \"W\": \"White\" })=={'B': 'Black', 'R': 'Red', 'P': 'Pink', 'G': 'Green', 'W': 'White'}",
"assert merge_dictionaries({ \"R\": \"Red\", \"B\": \"Black\", \"P\": \"Pink\" },{ \"O\": \"Orange\", \"W\": \"White\", \... | [] | |
646 | Write a python function to find the sum of fourth power of first n odd natural numbers. | 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 min_k([('Manjeet', 10), ('Akshat', 4), ('Akash', 2), ('Nikhil', 8)], 2) == [('Akash', 2), ('Akshat', 4)]",
"assert min_k([('Sanjeev', 11), ('Angat', 5), ('Akash', 3), ('Nepin', 9)], 3) == [('Akash', 3), ('Angat', 5), ('Nepin', 9)]",
"assert min_k([('tanmay', 14), ('Amer', 11), ('Ayesha', 9), ('SKD', 16)... | [] | |
854 | Write a function to extract specified number of elements from a given list, which follow each other continuously. | def find_Min_Swaps(arr,n) :
noOfZeroes = [0] * n
count = 0
noOfZeroes[n - 1] = 1 - arr[n - 1]
for i in range(n-2,-1,-1) :
noOfZeroes[i] = noOfZeroes[i + 1]
if (arr[i] == 0) :
noOfZeroes[i] = noOfZeroes[i] + 1
for i in range(0,n) :
if (arr[i] == 1)... | [
"assert first_Digit(5) == 1",
"assert first_Digit(10) == 3",
"assert first_Digit(7) == 5"
] | [] | |
667 | Write a python function to find minimum adjacent swaps required to sort binary array. | import re
def match_num(string):
text = re.compile(r"^5")
if text.match(string):
return True
else:
return False | [
"assert len_complex(3,4)==5.0",
"assert len_complex(9,10)==13.45362404707371",
"assert len_complex(7,9)==11.40175425099138"
] | [] | |
754 | Write a function to find the length of the longest sub-sequence such that elements in the subsequences are consecutive integers. | def increasing_trend(nums):
if (sorted(nums)== nums):
return True
else:
return False | [
"assert find_Min_Diff((1,5,3,19,18,25),6) == 1",
"assert find_Min_Diff((4,3,2,6),4) == 1",
"assert find_Min_Diff((30,5,20,9),4) == 4"
] | [] | |
823 | Write a function to check if each element of second tuple is smaller than its corresponding index in first tuple. | def check_identical(test_list1, test_list2):
res = test_list1 == test_list2
return (res) | [
"assert rotate_right([1, 2, 3, 4, 5, 6, 7, 8, 9, 10],3,4)==[8, 9, 10, 1, 2, 3, 4, 5, 6]",
"assert rotate_right([1, 2, 3, 4, 5, 6, 7, 8, 9, 10],2,2)==[9, 10, 1, 2, 3, 4, 5, 6, 7, 8]",
"assert rotate_right([1, 2, 3, 4, 5, 6, 7, 8, 9, 10],5,2)==[6, 7, 8, 9, 10, 1, 2, 3, 4, 5, 6, 7, 8]"
] | [] | |
967 | Write a function to remove all whitespaces from a string. | import math
def find_Index(n):
x = math.sqrt(2 * math.pow(10,(n - 1)));
return round(x); | [
"assert raw_heap([25, 44, 68, 21, 39, 23, 89])==[21, 25, 23, 44, 39, 68, 89]",
"assert raw_heap([25, 35, 22, 85, 14, 65, 75, 25, 58])== [14, 25, 22, 25, 35, 65, 75, 85, 58]",
"assert raw_heap([4, 5, 6, 2])==[2, 4, 6, 5]"
] | [] | |
909 | Write a function to get the length of a complex number. | def last(n):
return n[-1]
def sort_list_last(tuples):
return sorted(tuples, key=last) | [
"assert heap_sort([12, 2, 4, 5, 2, 3]) == [2, 2, 3, 4, 5, 12]",
"assert heap_sort([32, 14, 5, 6, 7, 19]) == [5, 6, 7, 14, 19, 32]",
"assert heap_sort([21, 15, 29, 78, 65]) == [15, 21, 29, 65, 78]"
] | [] | |
788 | Write a python function to check whether the product of numbers is even or not. | 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 anagram_lambda([\"bcda\", \"abce\", \"cbda\", \"cbea\", \"adcb\"],\"abcd\")==['bcda', 'cbda', 'adcb']",
"assert anagram_lambda([\"recitals\",\" python\"], \"articles\" )==[\"recitals\"]",
"assert anagram_lambda([\" keep\",\" abcdef\",\" xyz\"],\" peek\")==[\" keep\"]"
] | [] | |
693 | Write a function to multiply the adjacent elements of the given tuple. | def Check_Vow(string, vowels):
final = [each for each in string if each in vowels]
return(len(final))
| [
"assert slope(4,2,2,5) == -1.5",
"assert slope(2,4,4,6) == 1",
"assert slope(1,2,4,2) == 0"
] | [] | |
637 | Write a function to find the maximum sum of subsequences of given array with no adjacent elements. | import re
def text_match(text):
patterns = 'ab*?'
if re.search(patterns, text):
return ('Found a match!')
else:
return ('Not matched!') | [
"assert mul_even_odd([1,3,5,7,4,1,6,8])==4",
"assert mul_even_odd([1,2,3,4,5,6,7,8,9,10])==2",
"assert mul_even_odd([1,5,7,9,10])==10"
] | [] | |
851 | Write a function to add a dictionary to the tuple. | 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 sum_Even(2,5) == 6",
"assert sum_Even(3,8) == 18",
"assert sum_Even(4,6) == 10"
] | [] | |
716 | Write a python function to check whether all the bits are within a given range or not. | def is_triangleexists(a,b,c):
if(a != 0 and b != 0 and c != 0 and (a + b + c)== 180):
if((a + b)>= c or (b + c)>= a or (a + c)>= b):
return True
else:
return False
else:
return False | [
"assert smallest_multiple(13)==360360",
"assert smallest_multiple(2)==2",
"assert smallest_multiple(1)==1"
] | root = Node(1)
root.left = Node(2)
root.right = Node(3)
root.left.left = Node(4)
root.left.right = Node(5)
root1 = Node(1);
root1.left = Node(2);
root1.right = Node(3);
root1.left.left = Node(4);
root1.right.left = Node(5);
root1.right.right = Node(6);
root1.right.right.right= Node(7);
ro... | [] |
863 | Write a python function to find maximum possible value for the given periodic function. | 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 are_Rotations(\"abc\",\"cba\") == False",
"assert are_Rotations(\"abcd\",\"cdba\") == False",
"assert are_Rotations(\"abacd\",\"cdaba\") == True"
] | [] | |
798 | Write a python function to check if the string is a concatenation of another string. | def clear_tuple(test_tup):
temp = list(test_tup)
temp.clear()
test_tup = tuple(temp)
return (test_tup) | [
"assert is_subset([11, 1, 13, 21, 3, 7], 6, [11, 3, 7, 1], 4) == True",
"assert is_subset([1, 2, 3, 4, 5, 6], 6, [1, 2, 4], 3) == True",
"assert is_subset([10, 5, 2, 23, 19], 5, [19, 5, 3], 3) == False"
] | [] | |
904 | Write a python function to accept the strings which contains all vowels. | def floor_Min(A,B,N):
x = max(B - 1,N)
return (A*x) // B | [
"assert rombus_area(10,20)==100",
"assert rombus_area(10,5)==25",
"assert rombus_area(4,2)==4"
] | [] | |
606 | Write a function to rearrange positive and negative numbers in a given array using lambda function. | def discriminant_value(x,y,z):
discriminant = (y**2) - (4*x*z)
if discriminant > 0:
return ("Two solutions",discriminant)
elif discriminant == 0:
return ("one solution",discriminant)
elif discriminant < 0:
return ("no real solution",discriminant) | [
"assert is_decimal('123.11')==True",
"assert is_decimal('e666.86')==False",
"assert is_decimal('3.124587')==False"
] | [] | |
907 | Write a python function to check whether the length of the word is even or not. | def max_sum_list(lists):
return max(lists, key=sum) | [
"assert recur_gcd(12,14) == 2",
"assert recur_gcd(13,17) == 1",
"assert recur_gcd(9, 3) == 3"
] | [] | |
761 | Write a python function to find number of solutions in quadratic equation. | def product_Equal(n):
if n < 10:
return False
prodOdd = 1; prodEven = 1
while n > 0:
digit = n % 10
prodOdd *= digit
n = n//10
if n == 0:
break;
digit = n % 10
prodEven *= digit
n = n//10
if prodOdd == prodEv... | [
"assert sum_even_odd([1,3,5,7,4,1,6,8])==5",
"assert sum_even_odd([1,2,3,4,5,6,7,8,9,10])==3",
"assert sum_even_odd([1,5,7,9,10])==11"
] | [] | |
621 | Write a python function to find the length of the last word in a given string. | def remove_list_range(list1, leftrange, rigthrange):
result = [i for i in list1 if (min(i)>=leftrange and max(i)<=rigthrange)]
return result | [
"assert min_sum_path([[ 2 ], [3, 9 ], [1, 6, 7 ]]) == 6",
"assert min_sum_path([[ 2 ], [3, 7 ], [8, 5, 6 ]]) == 10 ",
"assert min_sum_path([[ 3 ], [6, 4 ], [5, 2, 7 ]]) == 9"
] | [] | |
677 | Write a function to filter the height and width of students which are stored in a dictionary. | def check_K(test_tup, K):
res = False
for ele in test_tup:
if ele == K:
res = True
break
return (res) | [
"assert count_Unset_Bits(2) == 1",
"assert count_Unset_Bits(5) == 4",
"assert count_Unset_Bits(14) == 17"
] | [] |
End of preview. Expand in Data Studio
edition_2907_google-research-datasets-mbpp-readymade
A Readymade by TheFactoryX
Original Dataset
Process
This dataset is a "readymade" - inspired by Marcel Duchamp's concept of taking everyday objects and recontextualizing them as art.
What we did:
- Selected the original dataset from Hugging Face
- Shuffled each column independently
- Destroyed all row-wise relationships
- Preserved structure, removed meaning
The result: Same data. Wrong order. New meaning. No meaning.
Purpose
This is art. This is not useful. This is the point.
Column relationships have been completely destroyed. The data maintains its types and values, but all semantic meaning has been removed.
Part of the Readymades project by TheFactoryX.
"I am a machine." — Andy Warhol
- Downloads last month
- 8