task_id
stringlengths 3
14
| prompt
stringlengths 164
742
| canonical_solution
stringlengths 14
760
| test
stringlengths 170
703
| entry_point
stringlengths 3
31
|
---|---|---|---|---|
HumanEval\/701 | from typing import List
def equilibrium_index(arr: List[int]) -> int:
""" Find the equilibrium index of the given array
>>> equilibrium_index([1, 2, 3, 4, 1, 2, 3])
3
>>> equilibrium_index([-7, 1, 5, 2, -4, 3, 0])
3
>>> equilibrium_index([1, 2, 3])
-1
"""
| total_sum = sum(arr)
left_sum = 0
for i, num in enumerate(arr):
total_sum -= num
if left_sum == total_sum:
return i
left_sum += num
return -1
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3, 4, 1, 2, 3]) == 3
assert candidate([-7, 1, 5, 2, -4, 3, 0]) == 3
assert candidate([1, 2, 3]) == -1
| equilibrium_index |
702 | def removals(arr: List[int], n: int, k: int) -> int:
""" Write a function to find the minimum number of elements that should be removed such that amax-amin<=k.
>>> removals([1, 3, 4, 9, 10, 11, 12, 17, 20], 9, 4)
5
>>> removals([1, 5, 6, 2, 8], 5, 2)
3
>>> removals([1, 2, 3, 4, 5, 6], 6, 3)
2
"""
| arr.sort()
ans = n - 1
for i in range(n):
j = find_ind(arr[i], i, n, k, arr)
if j != -1:
ans = min(ans, n - (j - i + 1))
return ans
def find_ind(key: int, i: int, n: int, k: int, arr: List[int]) -> int:
ind = -1
start = i + 1
end = n - 1
while start < end:
mid = (start + end) // 2
if arr[mid] - key <= k:
ind = mid
start = mid + 1
else:
end = mid
return ind
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 3, 4, 9, 10, 11, 12, 17, 20], 9, 4) == 5
assert candidate([1, 5, 6, 2, 8], 5, 2) == 3
assert candidate([1, 2, 3, 4, 5, 6], 6, 3) == 2
| removals |
HumanEval\/703 | def is_key_present(d: dict, x: int) -> bool:
""" Check whether the given key is present in the dictionary or not.
>>> is_key_present({1: 10, 2: 20, 3: 30, 4: 40, 5: 50, 6: 60}, 5)
True
>>> is_key_present({1: 10, 2: 20, 3: 30, 4: 40, 5: 50, 6: 60}, 10)
False
"""
| return x in d
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate({1: 10, 2: 20, 3: 30, 4: 40, 5: 50, 6: 60}, 5) == True
assert candidate({1: 10, 2: 20, 3: 30, 4: 40, 5: 50, 6: 60}, 6) == True
assert candidate({1: 10, 2: 20, 3: 30, 4: 40, 5: 50, 6: 60}, 10) == False
| is_key_present |
HumanEval\/704 | def harmonic_sum(n: int) -> float:
""" Calculate the harmonic sum of n-1.
>>> harmonic_sum(10)
2.9289682539682538
>>> harmonic_sum(4)
2.083333333333333
>>> harmonic_sum(7)
2.5928571428571425
"""
| if n < 2:
return 1
else:
return 1 / n + harmonic_sum(n - 1)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(10) == 2.9289682539682538
assert candidate(4) == 2.083333333333333
assert candidate(7) == 2.5928571428571425
| harmonic_sum |
HumanEval\/705 | from typing import List
def sort_sublists(list1: List[List[int]]) -> List[List[int]]:
""" Sort a list of lists by length and value
>>> sort_sublists([[2], [0], [1, 3], [0, 7], [9, 11], [13, 15, 17]])
[[0], [2], [0, 7], [1, 3], [9, 11], [13, 15, 17]]
>>> sort_sublists([[1], [2, 3], [4, 5, 6], [7], [10, 11]])
[[1], [7], [2, 3], [10, 11], [4, 5, 6]]
>>> sort_sublists([["python"],["java","C","C++"],["DBMS"],["SQL","HTML"]])
[['DBMS'], ['python'], ['SQL', 'HTML'], ['java', 'C', 'C++']]
"""
| list1.sort()
list1.sort(key=len)
return list1
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([[2], [0], [1, 3], [0, 7], [9, 11], [13, 15, 17]]) == [[0], [2], [0, 7], [1, 3], [9, 11], [13, 15, 17]]
assert candidate([[1], [2, 3], [4, 5, 6], [7], [10, 11]]) == [[1], [7], [2, 3], [10, 11], [4, 5, 6]]
assert candidate([["python"],["java","C","C++"],["DBMS"],["SQL","HTML"]]) == [['DBMS'], ['python'], ['SQL', 'HTML'], ['java', 'C', 'C++']]
| sort_sublists |
HumanEval\/706 | def is_subset(arr1, m, arr2, n):
""" Determine if arr2 is a subset of arr1
>>> is_subset([11, 1, 13, 21, 3, 7], 6, [11, 3, 7, 1], 4)
True
>>> is_subset([1, 2, 3, 4, 5, 6], 6, [1, 2, 4], 3)
True
>>> is_subset([10, 5, 2, 23, 19], 5, [19, 5, 3], 3)
False
"""
| 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
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([11, 1, 13, 21, 3, 7], 6, [11, 3, 7, 1], 4) == True
assert candidate([1, 2, 3, 4, 5, 6], 6, [1, 2, 4], 3) == True
assert candidate([10, 5, 2, 23, 19], 5, [19, 5, 3], 3) == False
| is_subset |
HumanEval\/707 | def count_Set_Bits(n: int) -> int:
""" Count the total set bits from 1 to n.
>>> count_Set_Bits(16)
33
>>> count_Set_Bits(2)
2
>>> count_Set_Bits(14)
28
"""
| n += 1
powerOf2 = 2
cnt = n // 2
while powerOf2 <= n:
totalPairs = n // powerOf2
cnt += (totalPairs // 2) * powerOf2
if totalPairs & 1:
cnt += (n % powerOf2)
powerOf2 <<= 1
return cnt
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(16) == 33
assert candidate(2) == 2
assert candidate(14) == 28
| count_Set_Bits |
HumanEval\/708 | from typing import List
def Convert(string: str) -> List[str]:
""" Convert a string to a list of words
>>> Convert('python program')
['python', 'program']
>>> Convert('Data Analysis')
['Data', 'Analysis']
"""
| return list(string.split(" "))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('python program') == ['python', 'program']
assert candidate('Data Analysis') == ['Data', 'Analysis']
assert candidate('Hadoop Training') == ['Hadoop', 'Training']
| Convert |
709 | from collections import defaultdict
def get_unique(test_list):
"""Write a function to count unique keys for each value present in the tuple.
>>> 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}'
"""
| res = defaultdict(list)
for sub in test_list:
res[sub[1]].append(sub[0])
res = dict(res)
res_dict = dict()
for key in res:
res_dict[key] = len(list(set(res[key])))
return str(res_dict)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([(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 candidate([(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 candidate([(6, 5), (3, 4), (2, 6), (11, 1), (8, 22), (8, 11), (4, 3), (14, 3), (11, 6)]) == '{5: 1, 4: 1, 6: 2, 1: 1, 22: 1, 11: 1, 3: 2}'
| get_unique |
HumanEval\/710 | def front_and_rear(test_tup: tuple) -> tuple:
""" Return a tuple containing the first and last elements of the given tuple.
>>> front_and_rear((10, 4, 5, 6, 7))
(10, 7)
>>> front_and_rear((1, 2, 3, 4, 5))
(1, 5)
>>> front_and_rear((6, 7, 8, 9, 10))
(6, 10)
"""
| res = (test_tup[0], test_tup[-1])
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((10, 4, 5, 6, 7)) == (10, 7)
assert candidate((1, 2, 3, 4, 5)) == (1, 5)
assert candidate((6, 7, 8, 9, 10)) == (6, 10)
| front_and_rear |
HumanEval\/711 | def product_Equal(n: int) -> bool:
""" Check whether the product of digits of a number at even and odd places is equal or not.
>>> product_Equal(2841)
True
>>> product_Equal(1234)
False
>>> product_Equal(1212)
False
"""
| 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
return prodOdd == prodEven
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(2841) == True
assert candidate(1234) == False
assert candidate(1212) == False
| product_Equal |
HumanEval\/712 | import itertools
def remove_duplicate(list1):
""" Remove duplicates from a list of lists
>>> remove_duplicate([[10, 20], [40], [30, 56, 25], [10, 20], [33], [40]])
[[10, 20], [30, 56, 25], [33], [40]]
>>> remove_duplicate(['a', 'b', 'a', 'c', 'c'])
['a', 'b', 'c']
>>> remove_duplicate([1, 3, 5, 6, 3, 5, 6, 1])
[1, 3, 5, 6]
"""
| list1.sort()
return list(list1 for list1,_ in itertools.groupby(list1))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([[10, 20], [40], [30, 56, 25], [10, 20], [33], [40]]) == [[10, 20], [30, 56, 25], [33], [40]]
assert candidate(['a', 'b', 'a', 'c', 'c']) == ['a', 'b', 'c']
assert candidate([1, 3, 5, 6, 3, 5, 6, 1]) == [1, 3, 5, 6]
| remove_duplicate |
HumanEval\/713 | def check_valid(test_tup: tuple) -> bool:
""" Check if the given tuple contains all valid values or not.
>>> check_valid((True, True, True, True))
True
>>> check_valid((True, False, True, True))
False
"""
| return not any(map(lambda ele: not ele, test_tup))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((True, True, True, True)) == True
assert candidate((True, False, True, True)) == False
assert candidate((True, True, True, True)) == True
| check_valid |
HumanEval\/714 | def count_Fac(n: int) -> int:
""" Count the number of distinct power of prime factor of given number.
>>> count_Fac(24)
3
>>> count_Fac(12)
2
>>> count_Fac(4)
1
"""
| m = n
count = 0
i = 2
while((i * i) <= m):
total = 0
while (n % i == 0):
n /= i
total += 1
temp = 0
j = 1
while((temp + j) <= total):
temp += j
count += 1
j += 1
i += 1
if (n != 1):
count += 1
return count
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(24) == 3
assert candidate(12) == 2
assert candidate(4) == 1
| count_Fac |
HumanEval\/715 | def str_to_tuple(test_str: str) -> tuple:
""" Convert the given string of integers into a tuple.
>>> str_to_tuple("1, -5, 4, 6, 7")
(1, -5, 4, 6, 7)
>>> str_to_tuple("1, 2, 3, 4, 5")
(1, 2, 3, 4, 5)
"""
| res = tuple(map(int, test_str.split(', ')))
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("1, -5, 4, 6, 7") == (1, -5, 4, 6, 7)
assert candidate("1, 2, 3, 4, 5") == (1, 2, 3, 4, 5)
assert candidate("4, 6, 9, 11, 13, 14") == (4, 6, 9, 11, 13, 14)
| str_to_tuple |
HumanEval\/716 | def rombus_perimeter(a: int) -> int:
""" Calculate the perimeter of a rhombus given the length of one side.
>>> rombus_perimeter(10)
40
>>> rombus_perimeter(5)
20
>>> rombus_perimeter(4)
16
"""
| return 4 * a
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(10) == 40
assert candidate(5) == 20
assert candidate(4) == 16
| rombus_perimeter |
HumanEval\/717 | import math
from typing import List
def sd_calc(data: List[float]) -> float:
""" Calculate the standard deviation of a list of numbers.
>>> sd_calc([4, 2, 5, 8, 6])
2.23606797749979
>>> sd_calc([1,2,3,4,5,6,7])
2.160246899469287
>>> sd_calc([5,9,10,15,6,4])
4.070217029430577
"""
| n = len(data)
if n <= 1:
return 0.0
mean = sum(data) / n
variance = sum((x - mean) ** 2 for x in data) / (n - 1)
return math.sqrt(variance)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([4, 2, 5, 8, 6]) == 2.23606797749979
assert candidate([1, 2, 3, 4, 5, 6, 7]) == 2.160246899469287
assert candidate([5, 9, 10, 15, 6, 4]) == 4.070217029430577
| sd_calc |
HumanEval\/718 | from typing import List
def alternate_elements(list1: List) -> List:
""" Create a list taking alternate elements from another given list.
>>> alternate_elements(['red', 'black', 'white', 'green', 'orange'])
['red', 'white', 'orange']
>>> alternate_elements([2, 0, 3, 4, 0, 2, 8, 3, 4, 2])
[2, 3, 0, 8, 4]
>>> alternate_elements([1, 2, 3, 4, 5, 6, 7, 8, 9, 10])
[1, 3, 5, 7, 9]
"""
| return list1[::2]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(['red', 'black', 'white', 'green', 'orange']) == ['red', 'white', 'orange']
assert candidate([2, 0, 3, 4, 0, 2, 8, 3, 4, 2]) == [2, 3, 0, 8, 4]
assert candidate([1, 2, 3, 4, 5, 6, 7, 8, 9, 10]) == [1, 3, 5, 7, 9]
| alternate_elements |
HumanEval\/719 | import re
def text_match(text: str) -> str:
""" Match a string that has an 'a' followed by zero or more 'b's.
>>> text_match('ac')
'Found a match!'
>>> text_match('dc')
'Not matched!'
>>> text_match('abba')
'Found a match!'
"""
| patterns = 'ab*?'
if re.search(patterns, text):
return 'Found a match!'
else:
return 'Not matched!'
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('ac') == 'Found a match!'
assert candidate('dc') == 'Not matched!'
assert candidate('abba') == 'Found a match!'
| text_match |
HumanEval\/720 | def add_dict_to_tuple(test_tup, test_dict):
""" Add a dictionary to the tuple
>>> add_dict_to_tuple((4, 5, 6), {"MSAM" : 1, "is" : 2, "best" : 3})
(4, 5, 6, {'MSAM': 1, 'is': 2, 'best': 3})
>>> add_dict_to_tuple((1, 2, 3), {"UTS" : 2, "is" : 3, "Worst" : 4})
(1, 2, 3, {'UTS': 2, 'is': 3, 'Worst': 4})
"""
| test_tup = list(test_tup)
test_tup.append(test_dict)
test_tup = tuple(test_tup)
return test_tup
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((4, 5, 6), {"MSAM" : 1, "is" : 2, "best" : 3}) == (4, 5, 6, {'MSAM': 1, 'is': 2, 'best': 3})
assert candidate((1, 2, 3), {"UTS" : 2, "is" : 3, "Worst" : 4}) == (1, 2, 3, {'UTS': 2, 'is': 3, 'Worst': 4})
assert candidate((8, 9, 10), {"POS" : 3, "is" : 4, "Okay" : 5}) == (8, 9, 10, {'POS': 3, 'is': 4, 'Okay': 5})
| add_dict_to_tuple |
HumanEval\/721 | def maxAverageOfPath(cost, N):
"""Find a path with the maximum average over all existing paths for the given square matrix of size n*n.
>>> maxAverageOfPath([[1, 2, 3], [6, 5, 4], [7, 3, 9]], 3)
5.2
>>> maxAverageOfPath([[2, 3, 4], [7, 6, 5], [8, 4, 10]], 3)
6.2
"""
| 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] = max(dp[i - 1][j], dp[i][j - 1]) + cost[i][j]
return dp[N - 1][N - 1] / (2 * N - 1)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([[1, 2, 3], [6, 5, 4], [7, 3, 9]], 3) == 5.2
assert candidate([[2, 3, 4], [7, 6, 5], [8, 4, 10]], 3) == 6.2
assert candidate([[3, 4, 5], [8, 7, 6], [9, 5, 11]], 3) == 7.2
| maxAverageOfPath |
722 | def filter_data(students, h, w):
""" Filter the height and width of students stored in a dictionary.
>>> 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)}
>>> 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 Vega': (6.2, 70), 'Kierra Gentry': (6.0, 68)}
"""
| result = {k: s for k, s in students.items() if s[0] >= h and s[1] >= w}
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate({'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 candidate({'Cierra Vega': (6.2, 70), 'Alden Cantrell': (5.9, 65), 'Kierra Gentry': (6.0, 68), 'Pierre Cox': (5.8, 66)}, 5.9, 67) == {'Cierra Vega': (6.2, 70), 'Kierra Gentry': (6.0, 68)}
assert candidate({'Cierra Vega': (6.2, 70), 'Alden Cantrell': (5.9, 65), 'Kierra Gentry': (6.0, 68), 'Pierre Cox': (5.8, 66)}, 5.7, 64) == {'Cierra Vega': (6.2, 70), 'Alden Cantrell': (5.9, 65), 'Kierra Gentry': (6.0, 68), 'Pierre Cox': (5.8, 66)}
| filter_data |
HumanEval\/723 | from operator import eq
from typing import List
def count_same_pair(nums1: List[int], nums2: List[int]) -> int:
""" Write a function to count the same pair in two given lists using map function.
>>> count_same_pair([1, 2, 3, 4, 5, 6, 7, 8],[2, 2, 3, 1, 2, 6, 7, 9])
4
>>> 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
>>> 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
"""
| result = sum(map(eq, nums1, nums2))
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3, 4, 5, 6, 7, 8],[2, 2, 3, 1, 2, 6, 7, 9]) == 4
assert candidate([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 candidate([2, 4, -6, -9, 11, -12, 14, -5, 17],[2, 1, 2, -1, -5, 6, 4, -3, -2, 3, 4, 6, 8]) == 1
| count_same_pair |
HumanEval\/724 | def power_base_sum(base: int, power: int) -> int:
""" Calculate the sum of all digits of the base to the specified power.
>>> power_base_sum(2, 100)
115
>>> power_base_sum(8, 10)
37
>>> power_base_sum(8, 15)
62
"""
| return sum([int(i) for i in str(pow(base, power))])
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(2, 100) == 115
assert candidate(8, 10) == 37
assert candidate(8, 15) == 62
| power_base_sum |
725 | import re
def extract_quotation(text1):
""" Extract values between quotation marks of the given string by using regex.
>>> extract_quotation('Cortex "A53" Based "multi" tasking "Processor"')
['A53', 'multi', 'Processor']
>>> extract_quotation('Cast your "favorite" entertainment "apps"')
['favorite', 'apps']
>>> extract_quotation('Watch content "4k Ultra HD" resolution with "HDR 10" Support')
['4k Ultra HD', 'HDR 10']
"""
| return re.findall(r'"(.*?)"', text1)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('Cortex "A53" Based "multi" tasking "Processor"') == ['A53', 'multi', 'Processor']
assert candidate('Cast your "favorite" entertainment "apps"') == ['favorite', 'apps']
assert candidate('Watch content "4k Ultra HD" resolution with "HDR 10" Support') == ['4k Ultra HD', 'HDR 10']
| extract_quotation |
HumanEval\/726 | def multiply_elements(test_tup: tuple) -> tuple:
""" Multiply the adjacent elements of the given tuple
>>> multiply_elements((1, 5, 7, 8, 10))
(5, 35, 56, 80)
>>> multiply_elements((2, 4, 5, 6, 7))
(8, 20, 30, 42)
>>> multiply_elements((12, 13, 14, 9, 15))
(156, 182, 126, 135)
"""
| res = tuple(i * j for i, j in zip(test_tup, test_tup[1:]))
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((1, 5, 7, 8, 10)) == (5, 35, 56, 80)
assert candidate((2, 4, 5, 6, 7)) == (8, 20, 30, 42)
assert candidate((12, 13, 14, 9, 15)) == (156, 182, 126, 135)
| multiply_elements |
HumanEval\/727 | import re
def remove_char(S: str) -> str:
""" Remove all characters from the string except letters and numbers using regex.
>>> remove_char("123abcjw:, .@! eiw")
'123abcjweiw'
>>> remove_char("Hello1234:, ! Howare33u")
'Hello1234Howare33u'
>>> remove_char("Cool543Triks@:, Make@987Trips")
'Cool543TriksMake987Trips'
"""
| result = re.sub('[\W_]+', '', S)
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("123abcjw:, .@! eiw") == '123abcjweiw'
assert candidate("Hello1234:, ! Howare33u") == 'Hello1234Howare33u'
assert candidate("Cool543Triks@:, Make@987Trips") == 'Cool543TriksMake987Trips'
| remove_char |
HumanEval\/728 | from typing import List
def sum_list(lst1: List[int], lst2: List[int]) -> List[int]:
""" Sum elements in two lists element-wise
>>> sum_list([10, 20, 30], [15, 25, 35])
[25, 45, 65]
>>> sum_list([1, 2, 3], [5, 6, 7])
[6, 8, 10]
>>> sum_list([15, 20, 30], [15, 45, 75])
[30, 65, 105]
"""
| return [lst1[i] + lst2[i] for i in range(len(lst1))]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([10, 20, 30], [15, 25, 35]) == [25, 45, 65]
assert candidate([1, 2, 3], [5, 6, 7]) == [6, 8, 10]
assert candidate([15, 20, 30], [15, 45, 75]) == [30, 65, 105]
| sum_list |
HumanEval\/729 | from typing import List
def add_list(nums1: List[int], nums2: List[int]) -> List[int]:
""" Add two lists using map and lambda function
>>> add_list([1, 2, 3], [4, 5, 6])
[5, 7, 9]
>>> add_list([1, 2], [3, 4])
[4, 6]
>>> add_list([10, 20], [50, 70])
[60, 90]
"""
| result = map(lambda x, y: x + y, nums1, nums2)
return list(result)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3], [4, 5, 6]) == [5, 7, 9]
assert candidate([1, 2], [3, 4]) == [4, 6]
assert candidate([10, 20], [50, 70]) == [60, 90]
| add_list |
HumanEval\/730 | from itertools import groupby
from typing import List, Union
def consecutive_duplicates(nums: List[Union[int, str]]) -> List[Union[int, str]]:
""" Remove consecutive duplicates from a list.
>>> consecutive_duplicates([0, 0, 1, 2, 3, 4, 4, 5, 6, 6, 6, 7, 8, 9, 4, 4])
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 4]
>>> consecutive_duplicates([10, 10, 15, 19, 18, 18, 17, 26, 26, 17, 18, 10])
[10, 15, 19, 18, 17, 26, 17, 18, 10]
>>> consecutive_duplicates(['a', 'a', 'b', 'c', 'd', 'd'])
['a', 'b', 'c', 'd']
"""
| return [key for key, group in groupby(nums)]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([0, 0, 1, 2, 3, 4, 4, 5, 6, 6, 6, 7, 8, 9, 4, 4]) == [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 4]
assert candidate([10, 10, 15, 19, 18, 18, 17, 26, 26, 17, 18, 10]) == [10, 15, 19, 18, 17, 26, 17, 18, 10]
assert candidate(['a', 'a', 'b', 'c', 'd', 'd']) == ['a', 'b', 'c', 'd']
| consecutive_duplicates |
HumanEval\/731 | import math
def lateralsurface_cone(r: float, h: float) -> float:
""" Calculate the lateral surface area of a cone given its radius and height.
>>> lateralsurface_cone(5, 12)
204.20352248333654
>>> lateralsurface_cone(10, 15)
566.3586699569488
>>> lateralsurface_cone(19, 17)
1521.8090132193388
"""
| l = math.sqrt(r * r + h * h)
LSA = math.pi * r * l
return LSA
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(5, 12) == 204.20352248333654
assert candidate(10, 15) == 566.3586699569488
assert candidate(19, 17) == 1521.8090132193388
| lateralsurface_cone |
732 | import re
def replace_specialchar(text: str) -> str:
""" Replace all occurrences of spaces, commas, or dots with a colon.
>>> replace_specialchar('Python language, Programming language.')
'Python:language::Programming:language:'
>>> replace_specialchar('a b c,d e f')
'a:b:c:d:e:f'
>>> replace_specialchar('ram reshma,ram rahim')
'ram:reshma:ram:rahim'
"""
| return re.sub("[ ,.]", ":", text)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('Python language, Programming language.') == 'Python:language::Programming:language:'
assert candidate('a b c,d e f') == 'a:b:c:d:e:f'
assert candidate('ram reshma,ram rahim') == 'ram:reshma:ram:rahim'
| replace_specialchar |
HumanEval\/733 | from typing import List
def find_first_occurrence(A: List[int], x: int) -> int:
""" Find the index of the first occurrence of a given number in a sorted array
>>> find_first_occurrence([2, 5, 5, 5, 6, 6, 8, 9, 9, 9], 5)
1
>>> find_first_occurrence([2, 3, 5, 5, 6, 6, 8, 9, 9, 9], 5)
2
>>> find_first_occurrence([2, 4, 1, 5, 6, 6, 8, 9, 9, 9], 6)
4
"""
| (left, right) = (0, len(A) - 1)
result = -1
while left <= right:
mid = (left + right) // 2
if x == A[mid]:
result = mid
right = mid - 1
elif x < A[mid]:
right = mid - 1
else:
left = mid + 1
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([2, 5, 5, 5, 6, 6, 8, 9, 9, 9], 5) == 1
assert candidate([2, 3, 5, 5, 6, 6, 8, 9, 9, 9], 5) == 2
assert candidate([2, 4, 1, 5, 6, 6, 8, 9, 9, 9], 6) == 4
| find_first_occurrence |
HumanEval\/734 | def sum_Of_Subarray_Prod(arr: List[int], n: int) -> int:
""" Calculate the sum of products of all possible subarrays.
>>> sum_Of_Subarray_Prod([1, 2, 3], 3)
20
>>> sum_Of_Subarray_Prod([1, 2], 2)
5
>>> sum_Of_Subarray_Prod([1, 2, 3, 4], 4)
84
"""
| ans = 0
res = 0
i = n - 1
while (i >= 0):
incr = arr[i]*(1 + res)
ans += incr
res = incr
i -= 1
return (ans)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3], 3) == 20
assert candidate([1, 2], 2) == 5
assert candidate([1, 2, 3, 4], 4) == 84
| sum_Of_Subarray_Prod |
HumanEval\/735 | def toggle_middle_bits(n):
""" Toggle bits of the number except the first and the last bit.
>>> toggle_middle_bits(9)
15
>>> toggle_middle_bits(10)
12
>>> toggle_middle_bits(11)
13
"""
| def set_middle_bits(n):
n |= n >> 1;
n |= n >> 2;
n |= n >> 4;
n |= n >> 8;
n |= n >> 16;
return (n >> 1) ^ 1
if (n == 1):
return 1
return n ^ set_middle_bits(n)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(9) == 15
assert candidate(10) == 12
assert candidate(11) == 13
| toggle_middle_bits |
HumanEval\/736 | import bisect
def left_insertion(a, x):
""" Locate the left insertion point for a specified value in sorted order.
>>> left_insertion([1,2,4,5], 6)
4
>>> left_insertion([1,2,4,5], 3)
2
>>> left_insertion([1,2,4,5], 7)
4
"""
| i = bisect.bisect_left(a, x)
return i
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,2,4,5], 6) == 4
assert candidate([1,2,4,5], 3) == 2
assert candidate([1,2,4,5], 7) == 4
| left_insertion |
HumanEval\/737 | import re
def check_str(string: str) -> str:
""" Check whether the given string is starting with a vowel or not using regex.
>>> check_str("annie")
'Valid'
>>> check_str("dawood")
'Invalid'
>>> check_str("Else")
'Valid'
"""
| regex = '^[aeiouAEIOU][A-Za-z0-9_]*'
if re.search(regex, string):
return "Valid"
else:
return "Invalid"
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("annie") == 'Valid'
assert candidate("dawood") == 'Invalid'
assert candidate("Else") == 'Valid'
| check_str |
HumanEval\/738 | def geometric_sum(n: int) -> float:
""" Calculate the geometric sum of n-1.
>>> geometric_sum(7)
1.9921875
>>> geometric_sum(4)
1.9375
>>> geometric_sum(8)
1.99609375
"""
| if n < 0:
return 0
else:
return 1 / (pow(2, n)) + geometric_sum(n - 1)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(7) == 1.9921875
assert candidate(4) == 1.9375
assert candidate(8) == 1.99609375
| geometric_sum |
HumanEval\/739 | import math
def find_Index(n: int) -> int:
""" Find the index of the smallest triangular number with n digits.
>>> find_Index(2)
4
>>> find_Index(3)
14
>>> find_Index(4)
45
"""
| x = math.sqrt(2 * math.pow(10, (n - 1)))
return round(x)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(2) == 4
assert candidate(3) == 14
assert candidate(4) == 45
| find_Index |
HumanEval\/740 | def tuple_to_dict(test_tup):
""" Convert the given tuple to a key-value dictionary using adjacent elements.
>>> tuple_to_dict((1, 5, 7, 10, 13, 5))
{1: 5, 7: 10, 13: 5}
>>> tuple_to_dict((1, 2, 3, 4, 5, 6))
{1: 2, 3: 4, 5: 6}
"""
| res = dict(test_tup[idx : idx + 2] for idx in range(0, len(test_tup), 2))
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((1, 5, 7, 10, 13, 5)) == {1: 5, 7: 10, 13: 5}
assert candidate((1, 2, 3, 4, 5, 6)) == {1: 2, 3: 4, 5: 6}
assert candidate((7, 8, 9, 10, 11, 12)) == {7: 8, 9: 10, 11: 12}
| tuple_to_dict |
HumanEval\/741 | def all_Characters_Same(s: str) -> bool:
""" Check whether all the characters in the string are the same.
>>> all_Characters_Same("python")
False
>>> all_Characters_Same("aaa")
True
>>> all_Characters_Same("data")
False
"""
| n = len(s)
for i in range(1, n):
if s[i] != s[0]:
return False
return True
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("python") == False
assert candidate("aaa") == True
assert candidate("data") == False
| all_Characters_Same |
HumanEval\/742 | import math
def area_tetrahedron(side: float) -> float:
""" Calculate the area of a tetrahedron given the length of its side.
>>> area_tetrahedron(3)
15.588457268119894
>>> area_tetrahedron(20)
692.8203230275509
>>> area_tetrahedron(10)
173.20508075688772
"""
| return math.sqrt(3) * (side * side)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(3) == 15.588457268119894
assert candidate(20) == 692.8203230275509
assert candidate(10) == 173.20508075688772
| area_tetrahedron |
HumanEval\/743 | from typing import List
def rotate_right(list1: List[int], m: int, n: int) -> List[int]:
""" Rotate a given list by specified number of items to the right direction.
>>> rotate_right([1, 2, 3, 4, 5, 6, 7, 8, 9, 10], 3, 4)
[8, 9, 10, 1, 2, 3, 4, 5, 6]
>>> rotate_right([1, 2, 3, 4, 5, 6, 7, 8, 9, 10], 2, 2)
[9, 10, 1, 2, 3, 4, 5, 6, 7, 8]
>>> 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]
"""
| result = list1[-(m):] + list1[:-(n)]
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3, 4, 5, 6, 7, 8, 9, 10], 3, 4) == [8, 9, 10, 1, 2, 3, 4, 5, 6]
assert candidate([1, 2, 3, 4, 5, 6, 7, 8, 9, 10], 2, 2) == [9, 10, 1, 2, 3, 4, 5, 6, 7, 8]
assert candidate([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]
| rotate_right |
HumanEval\/744 | def check_none(test_tup: tuple) -> bool:
""" Check if the given tuple has any None value or not.
>>> check_none((10, 4, 5, 6, None))
True
>>> check_none((7, 8, 9, 11, 14))
False
>>> check_none((1, 2, 3, 4, None))
True
"""
| return any(map(lambda ele: ele is None, test_tup))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((10, 4, 5, 6, None)) == True
assert candidate((7, 8, 9, 11, 14)) == False
assert candidate((1, 2, 3, 4, None)) == True
| check_none |
HumanEval\/745 | def divisible_by_digits(startnum: int, endnum: int) -> list:
""" Find numbers within a given range where every number is divisible by every digit it contains.
>>> divisible_by_digits(1, 22)
[1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 12, 15, 22]
>>> divisible_by_digits(1, 15)
[1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 12, 15]
>>> divisible_by_digits(20, 25)
[22, 24]
"""
| 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)))]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(1, 22) == [1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 12, 15, 22]
assert candidate(1, 15) == [1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 12, 15]
assert candidate(20, 25) == [22, 24]
| divisible_by_digits |
HumanEval\/746 | def sector_area(r: float, a: float) -> float:
""" Calculate the area of a sector given the radius and angle in degrees.
Returns None if the angle is 360 degrees or more.
>>> sector_area(4, 45)
6.285714285714286
>>> sector_area(9, 45)
31.82142857142857
>>> sector_area(9, 360)
None
"""
| pi = 22/7
if a >= 360:
return None
sectorarea = (pi * r**2) * (a / 360)
return sectorarea
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(4, 45) == 6.285714285714286
assert candidate(9, 45) == 31.82142857142857
assert candidate(9, 360) == None
| sector_area |
HumanEval\/747 | def lcs_of_three(X: str, Y: str, Z: str, m: int, n: int, o: int) -> int:
""" Write a function to find the longest common subsequence for the given three string sequence.
>>> lcs_of_three('AGGT12', '12TXAYB', '12XBA', 6, 7, 5)
2
>>> lcs_of_three('Reels', 'Reelsfor', 'ReelsforReels', 5, 8, 13)
5
>>> lcs_of_three('abcd1e2', 'bc12ea', 'bd1ea', 7, 6, 5)
3
"""
| L = [[[0 for i in range(o+1)] for j in range(n+1)] for k in range(m+1)]
for i in range(m+1):
for j in range(n+1):
for k in range(o+1):
if (i == 0 or j == 0 or k == 0):
L[i][j][k] = 0
elif (X[i-1] == Y[j-1] and X[i-1] == Z[k-1]):
L[i][j][k] = L[i-1][j-1][k-1] + 1
else:
L[i][j][k] = max(max(L[i-1][j][k], L[i][j-1][k]), L[i][j][k-1])
return L[m][n][o]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('AGGT12', '12TXAYB', '12XBA', 6, 7, 5) == 2
assert candidate('Reels', 'Reelsfor', 'ReelsforReels', 5, 8, 13) == 5
assert candidate('abcd1e2', 'bc12ea', 'bd1ea', 7, 6, 5) == 3
| lcs_of_three |
HumanEval\/748 | import re
def capital_words_spaces(str1: str) -> str:
""" Write a function to put spaces between words starting with capital letters in a given string by using regex.
>>> capital_words_spaces("Python")
'Python'
>>> capital_words_spaces("PythonProgrammingExamples")
'Python Programming Examples'
>>> capital_words_spaces("GetReadyToBeCodingFreak")
'Get Ready To Be Coding Freak'
"""
| return re.sub(r"(\w)([A-Z])", r"\1 \2", str1)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("Python") == 'Python'
assert candidate("PythonProgrammingExamples") == 'Python Programming Examples'
assert candidate("GetReadyToBeCodingFreak") == 'Get Ready To Be Coding Freak'
| capital_words_spaces |
HumanEval\/749 | from typing import List
def sort_numeric_strings(nums_str: List[str]) -> List[int]:
""" Sort a given list of strings of numbers numerically.
>>> sort_numeric_strings(['4','12','45','7','0','100','200','-12','-500'])
[-500, -12, 0, 4, 7, 12, 45, 100, 200]
>>> sort_numeric_strings(['2','3','8','4','7','9','8','2','6','5','1','6','1','2','3','4','6','9','1','2'])
[1, 1, 1, 2, 2, 2, 2, 3, 3, 4, 4, 5, 6, 6, 6, 7, 8, 8, 9, 9]
>>> sort_numeric_strings(['1','3','5','7','1', '3','13', '15', '17','5', '7 ','9','1', '11'])
[1, 1, 1, 3, 3, 5, 5, 7, 7, 9, 11, 13, 15, 17]
"""
| result = [int(x) for x in nums_str]
result.sort()
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(['4','12','45','7','0','100','200','-12','-500']) == [-500, -12, 0, 4, 7, 12, 45, 100, 200]
assert candidate(['2','3','8','4','7','9','8','2','6','5','1','6','1','2','3','4','6','9','1','2']) == [1, 1, 1, 2, 2, 2, 2, 3, 3, 4, 4, 5, 6, 6, 6, 7, 8, 8, 9, 9]
assert candidate(['1','3','5','7','1', '3','13', '15', '17','5', '7 ','9','1', '11']) == [1, 1, 1, 3, 3, 5, 5, 7, 7, 9, 11, 13, 15, 17]
| sort_numeric_strings |
HumanEval\/750 | from typing import List, Tuple
def add_tuple(test_list: List[int], test_tup: Tuple[int, ...]) -> List[int]:
""" Add the given tuple to the given list
>>> add_tuple([5, 6, 7], (9, 10))
[5, 6, 7, 9, 10]
>>> add_tuple([6, 7, 8], (10, 11))
[6, 7, 8, 10, 11]
>>> add_tuple([7, 8, 9], (11, 12))
[7, 8, 9, 11, 12]
"""
| test_list += test_tup
return test_list
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([5, 6, 7], (9, 10)) == [5, 6, 7, 9, 10]
assert candidate([6, 7, 8], (10, 11)) == [6, 7, 8, 10, 11]
assert candidate([7, 8, 9], (11, 12)) == [7, 8, 9, 11, 12]
| add_tuple |
HumanEval\/751 | def check_min_heap(arr, i):
""" Check if the given array represents a min heap starting from index i.
>>> check_min_heap([1, 2, 3, 4, 5, 6], 0)
True
>>> check_min_heap([2, 3, 4, 5, 10, 15], 0)
True
>>> check_min_heap([2, 10, 4, 5, 3, 15], 0)
False
"""
| if 2 * i + 2 > len(arr):
return True
left_child = (arr[i] <= arr[2 * i + 1]) and check_min_heap(arr, 2 * i + 1)
right_child = (2 * i + 2 == len(arr)) or (arr[i] <= arr[2 * i + 2] and check_min_heap(arr, 2 * i + 2))
return left_child and right_child
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3, 4, 5, 6], 0) == True
assert candidate([2, 3, 4, 5, 10, 15], 0) == True
assert candidate([2, 10, 4, 5, 3, 15], 0) == False
| check_min_heap |
HumanEval\/752 | def jacobsthal_num(n: int) -> int:
""" Calculate the nth Jacobsthal number
>>> jacobsthal_num(5)
11
>>> jacobsthal_num(2)
1
>>> jacobsthal_num(4)
5
"""
| 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]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(5) == 11
assert candidate(2) == 1
assert candidate(4) == 5
| jacobsthal_num |
HumanEval\/753 | from typing import List, Tuple
def min_k(test_list: List[Tuple[str, int]], K: int) -> List[Tuple[str, int]]:
""" Write a function to find minimum k records from tuple list.
>>> min_k([('Manjeet', 10), ('Akshat', 4), ('Akash', 2), ('Nikhil', 8)], 2)
[('Akash', 2), ('Akshat', 4)]
>>> min_k([('Sanjeev', 11), ('Angat', 5), ('Akash', 3), ('Nepin', 9)], 3)
[('Akash', 3), ('Angat', 5), ('Nepin', 9)]
>>> min_k([('tanmay', 14), ('Amer', 11), ('Ayesha', 9), ('SKD', 16)], 1)
[('Ayesha', 9)]
"""
| res = sorted(test_list, key=lambda x: x[1])[:K]
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([('Manjeet', 10), ('Akshat', 4), ('Akash', 2), ('Nikhil', 8)], 2) == [('Akash', 2), ('Akshat', 4)]
assert candidate([('Sanjeev', 11), ('Angat', 5), ('Akash', 3), ('Nepin', 9)], 3) == [('Akash', 3), ('Angat', 5), ('Nepin', 9)]
assert candidate([('tanmay', 14), ('Amer', 11), ('Ayesha', 9), ('SKD', 16)], 1) == [('Ayesha', 9)]
| min_k |
754 | def extract_index_list(l1, l2, l3):
""" Write a function to find common index elements from three lists.
>>> 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]
>>> 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]
>>> 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]
"""
| result = []
for m, n, o in zip(l1, l2, l3):
if (m == n == o):
result.append(m)
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 1, 3, 4, 5, 6, 7],[0, 1, 2, 3, 4, 5, 7],[0, 1, 2, 3, 4, 5, 7]) == [1, 7]
assert candidate([1, 1, 3, 4, 5, 6, 7],[0, 1, 2, 3, 4, 6, 5],[0, 1, 2, 3, 4, 6, 7]) == [1, 6]
assert candidate([1, 1, 3, 4, 6, 5, 6],[0, 1, 2, 3, 4, 5, 7],[0, 1, 2, 3, 4, 5, 7]) == [1, 5]
| extract_index_list |
HumanEval\/755 | from typing import List
def second_smallest(numbers: List[int]) -> int:
""" Find the second smallest number in a list
>>> second_smallest([1, 2, -8, -2, 0, -2])
-2
>>> second_smallest([1, 1, -0.5, 0, 2, -2, -2])
-0.5
>>> second_smallest([2, 2])
None
"""
| if len(numbers) < 2:
return None
if len(numbers) == 2 and numbers[0] == numbers[1]:
return None
dup_items = set()
uniq_items = []
for x in numbers:
if x not in dup_items:
uniq_items.append(x)
dup_items.add(x)
uniq_items.sort()
return uniq_items[1]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, -8, -2, 0, -2]) == -2
assert candidate([1, 1, -0.5, 0, 2, -2, -2]) == -0.5
assert candidate([2, 2]) == None
| second_smallest |
HumanEval\/756 | import re
def text_match_zero_one(text: str) -> str:
""" Write a function that matches a string that has an 'a' followed by zero or one 'b'.
>>> text_match_zero_one('ac')
'Found a match!'
>>> text_match_zero_one('dc')
'Not matched!'
>>> text_match_zero_one('abbbba')
'Found a match!'
"""
| patterns = 'ab?'
if re.search(patterns, text):
return 'Found a match!'
else:
return 'Not matched!'
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('ac') == 'Found a match!'
assert candidate('dc') == 'Not matched!'
assert candidate('abbbba') == 'Found a match!'
| text_match_zero_one |
HumanEval\/757 | from typing import List
def count_reverse_pairs(test_list: List[str]) -> str:
""" Count the pairs of reverse strings in the given string list
>>> count_reverse_pairs(["julia", "best", "tseb", "for", "ailuj"])
'2'
>>> count_reverse_pairs(["geeks", "best", "for", "skeeg"])
'1'
>>> count_reverse_pairs(["makes", "best", "sekam", "for", "rof"])
'2'
"""
| res = sum([1 for idx in range(0, len(test_list)) for idxn in range(idx, len(test_list)) if test_list[idxn] == str(''.join(list(reversed(test_list[idx]))))])
return str(res)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(["julia", "best", "tseb", "for", "ailuj"]) == '2'
assert candidate(["geeks", "best", "for", "skeeg"]) == '1'
assert candidate(["makes", "best", "sekam", "for", "rof"]) == '2'
| count_reverse_pairs |
758 | from typing import List
def unique_sublists(list1: List[List[int]]) -> dict:
""" Write a function to count number of unique lists within a list.
>>> unique_sublists([[1, 3], [5, 7], [1, 3], [13, 15, 17], [5, 7], [9, 11]])
{(1, 3): 2, (5, 7): 2, (13, 15, 17): 1, (9, 11): 1}
>>> unique_sublists([['green', 'orange'], ['black'], ['green', 'orange'], ['white']])
{('green', 'orange'): 2, ('black',): 1, ('white',): 1}
"""
| result = {}
for l in list1:
result.setdefault(tuple(l), list()).append(1)
for a, b in result.items():
result[a] = sum(b)
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([[1, 3], [5, 7], [1, 3], [13, 15, 17], [5, 7], [9, 11]]) == {(1, 3): 2, (5, 7): 2, (13, 15, 17): 1, (9, 11): 1}
assert candidate([['green', 'orange'], ['black'], ['green', 'orange'], ['white']]) == {('green', 'orange'): 2, ('black',): 1, ('white',): 1}
assert candidate([[10, 20, 30, 40], [60, 70, 50, 50], [90, 100, 200]]) == {(10, 20, 30, 40): 1, (60, 70, 50, 50): 1, (90, 100, 200): 1}
| unique_sublists |
HumanEval\/759 | import re
def is_decimal(num: str) -> bool:
""" Check if the string is a decimal with a precision of 2
>>> is_decimal('123.11')
True
>>> is_decimal('e666.86')
False
>>> is_decimal('3.124587')
False
"""
| dnumre = re.compile(r"^[0-9]+(\.[0-9]{1,2})?$")
result = dnumre.search(num)
return bool(result)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('123.11') == True
assert candidate('e666.86') == False
assert candidate('3.124587') == False
| is_decimal |
HumanEval\/760 | from typing import List
def unique_Element(arr: List[int], n: int) -> str:
""" Check whether an array contains only one distinct element or not.
>>> unique_Element([1, 1, 1], 3)
'YES'
>>> unique_Element([1, 2, 1, 2], 4)
'NO'
>>> unique_Element([1, 2, 3, 4, 5], 5)
'NO'
"""
| s = set(arr)
if len(s) == 1:
return 'YES'
else:
return 'NO'
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 1, 1], 3) == 'YES'
assert candidate([1, 2, 1, 2], 4) == 'NO'
assert candidate([1, 2, 3, 4, 5], 5) == 'NO'
| unique_Element |
HumanEval\/761 | def arc_length(d: float, a: float) -> float:
""" Calculate the arc length of an angle.
>>> arc_length(9, 45)
3.5357142857142856
>>> arc_length(9, 480)
None
>>> arc_length(5, 270)
11.785714285714285
"""
| pi = 22 / 7
if a >= 360:
return None
arclength = (pi * d) * (a / 360)
return arclength
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(9, 45) == 3.5357142857142856
assert candidate(9, 480) == None
assert candidate(5, 270) == 11.785714285714285
| arc_length |
HumanEval\/762 | def check_monthnumber_number(monthnum3: int) -> bool:
""" Check whether the given month number contains 30 days or not.
>>> check_monthnumber_number(6)
True
>>> check_monthnumber_number(2)
False
>>> check_monthnumber_number(12)
False
"""
| return monthnum3 in {4, 6, 9, 11}
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(6) == True
assert candidate(2) == False
assert candidate(12) == False
| check_monthnumber_number |
HumanEval\/763 | from typing import List
def find_Min_Diff(arr: List[int], n: int) -> int:
""" Find the minimum difference between any two elements in a given array
>>> find_Min_Diff([1,5,3,19,18,25], 6)
1
>>> find_Min_Diff([4,3,2,6], 4)
1
>>> find_Min_Diff([30,5,20,9], 4)
4
"""
| arr = sorted(arr)
diff = 10**20
for i in range(n-1):
if arr[i+1] - arr[i] < diff:
diff = arr[i+1] - arr[i]
return diff
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,5,3,19,18,25], 6) == 1
assert candidate([4,3,2,6], 4) == 1
assert candidate([30,5,20,9], 4) == 4
| find_Min_Diff |
764 | def number_ctr(str):
""" Count numeric values in a given string
>>> number_ctr('program2bedone')
1
>>> number_ctr('3wonders')
1
>>> number_ctr('123')
3
"""
| number_ctr = 0
for i in range(len(str)):
if str[i] >= '0' and str[i] <= '9':
number_ctr += 1
return number_ctr
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('program2bedone') == 1
assert candidate('3wonders') == 1
assert candidate('123') == 3
| number_ctr |
HumanEval\/765 | import math
def is_polite(n: int) -> int:
""" Write a function to find nth polite number.
>>> is_polite(7)
11
>>> is_polite(4)
7
>>> is_polite(9)
13
"""
| n = n + 1
return int(n + (math.log((n + math.log(n, 2)), 2)))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(7) == 11
assert candidate(4) == 7
assert candidate(9) == 13
| is_polite |
HumanEval\/766 | from typing import List, Tuple
def pair_wise(l1: List[int]) -> List[Tuple[int, int]]:
""" Iterate over all pairs of consecutive items in a given list
>>> pair_wise([1,1,2,3,3,4,4,5])
[(1, 1), (1, 2), (2, 3), (3, 3), (3, 4), (4, 4), (4, 5)]
>>> pair_wise([1,5,7,9,10])
[(1, 5), (5, 7), (7, 9), (9, 10)]
>>> pair_wise([1,2,3,4,5,6,7,8,9,10])
[(1, 2), (2, 3), (3, 4), (4, 5), (5, 6), (6, 7), (7, 8), (8, 9), (9, 10)]
"""
| 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
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,1,2,3,3,4,4,5]) == [(1, 1), (1, 2), (2, 3), (3, 3), (3, 4), (4, 4), (4, 5)]
assert candidate([1,5,7,9,10]) == [(1, 5), (5, 7), (7, 9), (9, 10)]
assert candidate([1,2,3,4,5,6,7,8,9,10]) == [(1, 2), (2, 3), (3, 4), (4, 5), (5, 6), (6, 7), (7, 8), (8, 9), (9, 10)]
| pair_wise |
HumanEval\/767 | from typing import List
def get_Pairs_Count(arr: List[int], n: int, sum: int) -> int:
""" Count the number of pairs in the array whose sum is equal to 'sum'.
>>> get_Pairs_Count([1, 1, 1, 1], 4, 2)
6
>>> get_Pairs_Count([1, 5, 7, -1, 5], 5, 6)
3
>>> get_Pairs_Count([1, -2, 3], 3, 1)
1
"""
| count = 0
for i in range(0, n):
for j in range(i + 1, n):
if arr[i] + arr[j] == sum:
count += 1
return count
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 1, 1, 1], 4, 2) == 6
assert candidate([1, 5, 7, -1, 5], 5, 6) == 3
assert candidate([1, -2, 3], 3, 1) == 1
| get_Pairs_Count |
HumanEval\/768 | def check_Odd_Parity(x: int) -> bool:
""" Check for odd parity of a given number
>>> check_Odd_Parity(13)
True
>>> check_Odd_Parity(21)
True
>>> check_Odd_Parity(18)
False
"""
| parity = 0
while (x != 0):
x = x & (x - 1)
parity += 1
return parity % 2 == 1
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(13) == True
assert candidate(21) == True
assert candidate(18) == False
| check_Odd_Parity |
HumanEval\/769 | from typing import List
def Diff(li1: List[int], li2: List[int]) -> List[int]:
""" Get the difference between two lists
>>> Diff([10, 15, 20, 25, 30, 35, 40], [25, 40, 35])
[10, 20, 30, 15]
>>> Diff([1,2,3,4,5], [6,7,1])
[2, 3, 4, 5, 6, 7]
>>> Diff([1,2,3], [6,7,1])
[2, 3, 6, 7]
"""
| return list(set(li1) - set(li2)) + list(set(li2) - set(li1))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([10, 15, 20, 25, 30, 35, 40], [25, 40, 35]) == [10, 20, 30, 15]
assert candidate([1,2,3,4,5], [6,7,1]) == [2, 3, 4, 5, 6, 7]
assert candidate([1,2,3], [6,7,1]) == [2, 3, 6, 7]
| Diff |
HumanEval\/770 | def odd_Num_Sum(n: int) -> int:
"""Calculate the sum of the fourth power of the first n odd natural numbers.
>>> odd_Num_Sum(2)
82
>>> odd_Num_Sum(3)
707
>>> odd_Num_Sum(4)
3108
"""
| j = 0
sm = 0
for i in range(1, n + 1):
j = (2 * i - 1)
sm = sm + (j * j * j * j)
return sm
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(2) == 82
assert candidate(3) == 707
assert candidate(4) == 3108
| odd_Num_Sum |
HumanEval\/771 | from collections import deque
def check_expression(exp: str) -> bool:
""" Check if the given expression is balanced or not.
>>> check_expression("{()}[{}]")
True
>>> check_expression("{()}[{]")
False
>>> check_expression("{()}[{}][]({})")
True
"""
| 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:
return False
top = stack.pop()
if (top == '(' and ch != ')') or (top == '{' and ch != '}' or (top == '[' and ch != ']')):
return False
return not stack
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("{()}[{}]") == True
assert candidate("{()}[{]") == False
assert candidate("{()}[{}][]({})") == True
| check_expression |
HumanEval\/772 | def remove_length(test_str: str, K: int) -> str:
""" Remove all the words with k length in the given string.
>>> remove_length('The person is most value tet', 3)
'person is most value'
>>> remove_length('If you told me about this ok', 4)
'If you me about ok'
>>> remove_length('Forces of darkeness is come into the play', 4)
'Forces of darkeness is the'
"""
| temp = test_str.split()
res = [ele for ele in temp if len(ele) != K]
res = ' '.join(res)
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('The person is most value tet', 3) == 'person is most value'
assert candidate('If you told me about this ok', 4) == 'If you me about ok'
assert candidate('Forces of darkeness is come into the play', 4) == 'Forces of darkeness is the'
| remove_length |
HumanEval\/773 | import re
def occurance_substring(text: str, pattern: str) -> tuple:
""" Find the occurrence and position of the substrings within a string.
>>> occurance_substring('python programming, python language', 'python')
('python', 0, 6)
>>> occurance_substring('python programming,programming language', 'programming')
('programming', 7, 18)
>>> occurance_substring('python programming,programming language', 'language')
('language', 31, 39)
"""
| for match in re.finditer(pattern, text):
s = match.start()
e = match.end()
return (text[s:e], s, e)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('python programming, python language', 'python') == ('python', 0, 6)
assert candidate('python programming,programming language', 'programming') == ('programming', 7, 18)
assert candidate('python programming,programming language', 'language') == ('language', 31, 39)
| occurance_substring |
task_774 | import re
def check_email(email: str) -> str:
"""Check if the string is a valid email address or not using regex.
>>> check_email("[email protected]")
'Valid Email'
>>> check_email("[email protected]")
'Valid Email'
>>> check_email("ankitaoie326.com")
'Invalid Email'
"""
regex = '^[a-z0-9]+[\._]?[a-z0-9]+[@]\w+[.]\w{2,3}$'
if re.search(regex, email):
return "Valid Email"
else:
return "Invalid Email"
| regex = '^[a-z0-9]+[\._]?[a-z0-9]+[@]\w+[.]\w{2,3}$'
if re.search(regex, email):
return "Valid Email"
else:
return "Invalid Email"
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("[email protected]") == 'Valid Email'
assert candidate("[email protected]") == 'Valid Email'
assert candidate("ankitaoie326.com") == 'Invalid Email'
| check_email |
HumanEval\/775 | from typing import List
def odd_position(nums: List[int]) -> bool:
""" Check whether every odd index contains odd numbers of a given list.
>>> odd_position([2,1,4,3,6,7,6,3])
True
>>> odd_position([4,1,2])
True
>>> odd_position([1,2,3])
False
"""
| return all(nums[i]%2==i%2 for i in range(len(nums)))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([2,1,4,3,6,7,6,3]) == True
assert candidate([4,1,2]) == True
assert candidate([1,2,3]) == False
| odd_position |
HumanEval\/776 | def count_vowels(test_str: str) -> int:
"""Write a function to count those characters which have vowels as their neighbors in the given string.
>>> count_vowels('bestinstareels')
7
>>> count_vowels('partofthejourneyistheend')
12
>>> count_vowels('amazonprime')
5
"""
| res = 0
vow_list = ['a', 'e', 'i', 'o', 'u']
for idx in range(1, len(test_str) - 1):
if test_str[idx] not in vow_list and (test_str[idx - 1] in vow_list or test_str[idx + 1] in vow_list):
res += 1
if test_str[0] not in vow_list and test_str[1] in vow_list:
res += 1
if test_str[-1] not in vow_list and test_str[-2] in vow_list:
res += 1
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('bestinstareels') == 7
assert candidate('partofthejourneyistheend') == 12
assert candidate('amazonprime') == 5
| count_vowels |
HumanEval\/777 | def find_Sum(arr: list, n: int) -> int:
""" Write a python function to find the sum of non-repeated elements in a given array.
>>> find_Sum([1,2,3,1,1,4,5,6],8)
21
>>> find_Sum([1,10,9,4,2,10,10,45,4],9)
71
>>> find_Sum([12,10,9,45,2,10,10,45,10],9)
78
"""
| 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
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,2,3,1,1,4,5,6],8) == 21
assert candidate([1,10,9,4,2,10,10,45,4],9) == 71
assert candidate([12,10,9,45,2,10,10,45,10],9) == 78
| find_Sum |
HumanEval\/778 | from itertools import groupby
def pack_consecutive_duplicates(list1):
""" Pack consecutive duplicates of a given list elements into sublists.
>>> pack_consecutive_duplicates([0, 0, 1, 2, 3, 4, 4, 5, 6, 6, 6, 7, 8, 9, 4, 4])
[[0, 0], [1], [2], [3], [4, 4], [5], [6, 6, 6], [7], [8], [9], [4, 4]]
>>> pack_consecutive_duplicates(['a', 'a', 'b', 'c', 'd', 'd'])
[['a', 'a'], ['b'], ['c'], ['d', 'd']]
"""
| return [list(group) for key, group in groupby(list1)]
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([0, 0, 1, 2, 3, 4, 4, 5, 6, 6, 6, 7, 8, 9, 4, 4]) == [[0, 0], [1], [2], [3], [4, 4], [5], [6, 6, 6], [7], [8], [9], [4, 4]]
assert candidate([10, 10, 15, 19, 18, 18, 17, 26, 26, 17, 18, 10]) == [[10, 10], [15], [19], [18, 18], [17], [26, 26], [17], [18], [10]]
assert candidate(['a', 'a', 'b', 'c', 'd', 'd']) == [['a', 'a'], ['b'], ['c'], ['d', 'd']]
| pack_consecutive_duplicates |
HumanEval\/779 | from typing import List, Tuple, Dict
def unique_sublists(list1: List[List[int]]) -> Dict[Tuple[int, ...], int]:
""" Count the number of unique lists within a list.
>>> unique_sublists([[1, 3], [5, 7], [1, 3], [13, 15, 17], [5, 7], [9, 11]])
{(1, 3): 2, (5, 7): 2, (13, 15, 17): 1, (9, 11): 1}
>>> unique_sublists([['green', 'orange'], ['black'], ['green', 'orange'], ['white']])
{('green', 'orange'): 2, ('black',): 1, ('white',): 1}
>>> unique_sublists([[1, 2], [3, 4], [4, 5], [6, 7]])
{(1, 2): 1, (3, 4): 1, (4, 5): 1, (6, 7): 1}
"""
| result = {}
for l in list1:
result.setdefault(tuple(l), 0)
result[tuple(l)] += 1
return result
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([[1, 3], [5, 7], [1, 3], [13, 15, 17], [5, 7], [9, 11]]) == {(1, 3): 2, (5, 7): 2, (13, 15, 17): 1, (9, 11): 1}
assert candidate([['green', 'orange'], ['black'], ['green', 'orange'], ['white']]) == {('green', 'orange'): 2, ('black',): 1, ('white',): 1}
assert candidate([[1, 2], [3, 4], [4, 5], [6, 7]]) == {(1, 2): 1, (3, 4): 1, (4, 5): 1, (6, 7): 1}
| unique_sublists |
HumanEval\/780 | from itertools import combinations
def find_combinations(test_list):
""" Find the combinations of sums with tuples in the given tuple list.
>>> find_combinations([(2, 4), (6, 7), (5, 1), (6, 10)])
[(8, 11), (7, 5), (8, 14), (11, 8), (12, 17), (11, 11)]
>>> find_combinations([(3, 5), (7, 8), (6, 2), (7, 11)])
[(10, 13), (9, 7), (10, 16), (13, 10), (14, 19), (13, 13)]
"""
| res = [(b1 + a1, b2 + a2) for (a1, a2), (b1, b2) in combinations(test_list, 2)]
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([(2, 4), (6, 7), (5, 1), (6, 10)]) == [(8, 11), (7, 5), (8, 14), (11, 8), (12, 17), (11, 11)]
assert candidate([(3, 5), (7, 8), (6, 2), (7, 11)]) == [(10, 13), (9, 7), (10, 16), (13, 10), (14, 19), (13, 13)]
assert candidate([(4, 6), (8, 9), (7, 3), (8, 12)]) == [(12, 15), (11, 9), (12, 18), (15, 12), (16, 21), (15, 15)]
| find_combinations |
HumanEval\/781 | import math
def count_Divisors(n: int) -> str:
""" Check whether the count of divisors is even or odd.
>>> count_Divisors(10)
'Even'
>>> count_Divisors(100)
'Odd'
>>> count_Divisors(125)
'Even'
"""
| count = 0
for i in range(1, int(math.sqrt(n)) + 2):
if n % i == 0:
if n // i == i:
count += 1
else:
count += 2
return "Even" if count % 2 == 0 else "Odd"
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(10) == 'Even'
assert candidate(100) == 'Odd'
assert candidate(125) == 'Even'
| count_Divisors |
HumanEval\/782 | def Odd_Length_Sum(arr):
"""Find the sum of all odd length subarrays.
>>> Odd_Length_Sum([1,2,4])
14
>>> Odd_Length_Sum([1,2,1,2])
15
>>> Odd_Length_Sum([1,7])
8
"""
| Sum = 0
l = len(arr)
for i in range(l):
Sum += ((((i + 1) *(l - i) + 1) // 2) * arr[i])
return Sum
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,2,4]) == 14
assert candidate([1,2,1,2]) == 15
assert candidate([1,7]) == 8
| Odd_Length_Sum |
HumanEval\/783 | def rgb_to_hsv(r: int, g: int, b: int) -> tuple:
""" Convert RGB color to HSV color
>>> rgb_to_hsv(255, 255, 255)
(0, 0.0, 100.0)
>>> rgb_to_hsv(0, 215, 0)
(120.0, 100.0, 84.31372549019608)
>>> rgb_to_hsv(10, 215, 110)
(149.26829268292684, 95.34883720930233, 84.31372549019608)
"""
| r, g, b = r/255.0, g/255.0, b/255.0
mx = max(r, g, b)
mn = min(r, g, b)
df = mx-mn
if mx == mn:
h = 0
elif mx == r:
h = (60 * ((g-b)/df) + 360) % 360
elif mx == g:
h = (60 * ((b-r)/df) + 120) % 360
elif mx == b:
h = (60 * ((r-g)/df) + 240) % 360
if mx == 0:
s = 0
else:
s = (df/mx)*100
v = mx*100
return h, s, v
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(255, 255, 255) == (0, 0.0, 100.0)
assert candidate(0, 215, 0) == (120.0, 100.0, 84.31372549019608)
assert candidate(10, 215, 110) == (149.26829268292684, 95.34883720930233, 84.31372549019608)
| rgb_to_hsv |
HumanEval\/784 | from typing import List
def mul_even_odd(list1: List[int]) -> int:
""" Write a function to find the product of first even and odd number of a given list.
>>> mul_even_odd([1,3,5,7,4,1,6,8])
4
>>> mul_even_odd([1,2,3,4,5,6,7,8,9,10])
2
>>> mul_even_odd([1,5,7,9,10])
10
"""
| first_even = next((el for el in list1 if el%2==0),-1)
first_odd = next((el for el in list1 if el%2!=0),-1)
return (first_even*first_odd)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,3,5,7,4,1,6,8]) == 4
assert candidate([1,2,3,4,5,6,7,8,9,10]) == 2
assert candidate([1,5,7,9,10]) == 10
| mul_even_odd |
HumanEval\/785 | def tuple_str_int(test_str: str) -> tuple:
""" Convert a tuple string to an integer tuple.
>>> tuple_str_int("(7, 8, 9)")
(7, 8, 9)
>>> tuple_str_int("(1, 2, 3)")
(1, 2, 3)
>>> tuple_str_int("(4, 5, 6)")
(4, 5, 6)
"""
| res = tuple(int(num) for num in test_str.replace('(', '').replace(')', '').replace('...', '').split(', '))
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("(7, 8, 9)") == (7, 8, 9)
assert candidate("(1, 2, 3)") == (1, 2, 3)
assert candidate("(4, 5, 6)") == (4, 5, 6)
| tuple_str_int |
HumanEval\/786 | import bisect
def right_insertion(a, x):
""" Locate the right insertion point for a specified value in sorted order.
>>> right_insertion([1,2,4,5], 6)
4
>>> right_insertion([1,2,4,5], 3)
2
>>> right_insertion([1,2,4,5], 7)
4
"""
| i = bisect.bisect_right(a, x)
return i
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,2,4,5], 6) == 4
assert candidate([1,2,4,5], 3) == 2
assert candidate([1,2,4,5], 7) == 4
| right_insertion |
HumanEval\/787 | import re
def text_match_three(text: str) -> str:
""" Match a string that has an 'a' followed by three 'b'.
>>> text_match_three("ac")
'Not matched!'
>>> text_match_three("dc")
'Not matched!'
>>> text_match_three("abbbba")
'Found a match!'
"""
| patterns = 'ab{3}?'
if re.search(patterns, text):
return 'Found a match!'
else:
return 'Not matched!'
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("ac") == 'Not matched!'
assert candidate("dc") == 'Not matched!'
assert candidate("abbbba") == 'Found a match!'
| text_match_three |
HumanEval\/788 | from typing import List, Tuple
def new_tuple(test_list: List[str], test_str: str) -> Tuple[str, ...]:
""" Create a new tuple from the given string and list
>>> new_tuple(["WEB", "is"], "best")
('WEB', 'is', 'best')
>>> new_tuple(["We", "are"], "Developers")
('We', 'are', 'Developers')
"""
| res = tuple(test_list + [test_str])
return (res)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(["WEB", "is"], "best") == ('WEB', 'is', 'best')
assert candidate(["We", "are"], "Developers") == ('We', 'are', 'Developers')
assert candidate(["Part", "is"], "Wrong") == ('Part', 'is', 'Wrong')
| new_tuple |
HumanEval\/789 | from math import tan, pi
def perimeter_polygon(s: int, l: float) -> float:
""" Calculate the perimeter of a regular polygon with s sides each of length l.
>>> perimeter_polygon(4, 20)
80
>>> perimeter_polygon(10, 15)
150
>>> perimeter_polygon(9, 7)
63
"""
| perimeter = s * l
return perimeter
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(4, 20) == 80
assert candidate(10, 15) == 150
assert candidate(9, 7) == 63
| perimeter_polygon |
HumanEval\/790 | from typing import List
def even_position(nums: List[int]) -> bool:
""" Check whether every even index contains even numbers of a given list.
>>> even_position([3,2,1])
False
>>> even_position([1,2,3])
False
>>> even_position([2,1,4])
True
"""
| return all(nums[i]%2==i%2 for i in range(len(nums)))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([3,2,1]) == False
assert candidate([1,2,3]) == False
assert candidate([2,1,4]) == True
| even_position |
HumanEval\/791 | def remove_nested(test_tup: tuple) -> tuple:
""" Remove the nested record from the given tuple.
>>> remove_nested((1, 5, 7, (4, 6), 10))
(1, 5, 7, 10)
>>> remove_nested((2, 6, 8, (5, 7), 11))
(2, 6, 8, 11)
>>> remove_nested((3, 7, 9, (6, 8), 12))
(3, 7, 9, 12)
"""
| res = tuple()
for count, ele in enumerate(test_tup):
if not isinstance(ele, tuple):
res = res + (ele, )
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate((1, 5, 7, (4, 6), 10)) == (1, 5, 7, 10)
assert candidate((2, 6, 8, (5, 7), 11)) == (2, 6, 8, 11)
assert candidate((3, 7, 9, (6, 8), 12)) == (3, 7, 9, 12)
| remove_nested |
HumanEval\/792 | from typing import List
def count_list(input_list: List[List]) -> int:
""" Count the number of lists in a given list of lists.
>>> count_list([[1, 3], [5, 7], [9, 11], [13, 15, 17]])
4
>>> count_list([[1,2],[2,3],[4,5]])
3
>>> count_list([[1,0],[2,0]])
2
"""
| return len(input_list)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([[1, 3], [5, 7], [9, 11], [13, 15, 17]]) == 4
assert candidate([[1,2],[2,3],[4,5]]) == 3
assert candidate([[1,0],[2,0]]) == 2
| count_list |
HumanEval\/793 | from typing import List
def last(arr: List[int], x: int, n: int) -> int:
""" Find the last position of an element in a sorted array
>>> last([1,2,3], 1, 3)
0
>>> last([1,1,1,2,3,4], 1, 6)
2
>>> last([2,3,2,3,6,8,9], 3, 8)
3
"""
| low = 0
high = n - 1
res = -1
while (low <= high):
mid = (low + high) // 2
if arr[mid] > x:
high = mid - 1
elif arr[mid] < x:
low = mid + 1
else:
res = mid
low = mid + 1
return res
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1,2,3], 1, 3) == 0
assert candidate([1,1,1,2,3,4], 1, 6) == 2
assert candidate([2,3,2,3,6,8,9], 3, 8) == 3
| last |
HumanEval\/794 | import re
def text_starta_endb(text: str) -> str:
""" Match a string that has an 'a' followed by anything, ending in 'b'.
>>> text_starta_endb("aabbbb")
'Found a match!'
>>> text_starta_endb("aabAbbbc")
'Not matched!'
>>> text_starta_endb("accddbbjjj")
'Not matched!'
"""
| patterns = 'a.*?b$'
if re.search(patterns, text):
return 'Found a match!'
else:
return 'Not matched!'
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate("aabbbb") == 'Found a match!'
assert candidate("aabAbbbc") == 'Not matched!'
assert candidate("accddbbjjj") == 'Not matched!'
| text_starta_endb |
HumanEval\/795 | import heapq
from typing import List, Dict
def cheap_items(items: List[Dict[str, float]], n: int) -> List[Dict[str, float]]:
""" Find the n cheapest price items from a given dataset using heap queue algorithm.
>>> cheap_items([{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}],1)
[{'name': 'Item-1', 'price': 101.1}]
>>> cheap_items([{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}],2)
[{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}]
>>> cheap_items([{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}, {'name': 'Item-3', 'price': 45.09},{'name': 'Item-4', 'price': 22.75}],1)
[{'name': 'Item-4', 'price': 22.75}]
"""
| return heapq.nsmallest(n, items, key=lambda s: s['price'])
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}],1) == [{'name': 'Item-1', 'price': 101.1}]
assert candidate([{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}],2) == [{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}]
assert candidate([{'name': 'Item-1', 'price': 101.1},{'name': 'Item-2', 'price': 555.22}, {'name': 'Item-3', 'price': 45.09},{'name': 'Item-4', 'price': 22.75}],1) == [{'name': 'Item-4', 'price': 22.75}]
| cheap_items |
HumanEval\/796 | def return_sum(dict):
""" Write function to find the sum of all items in the given dictionary.
>>> return_sum({'a': 100, 'b':200, 'c':300})
600
>>> return_sum({'a': 25, 'b':18, 'c':45})
88
>>> return_sum({'a': 36, 'b':39, 'c':49})
124
"""
| sum = 0
for i in dict.values():
sum = sum + i
return sum
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate({'a': 100, 'b':200, 'c':300}) == 600
assert candidate({'a': 25, 'b':18, 'c':45}) == 88
assert candidate({'a': 36, 'b':39, 'c':49}) == 124
| return_sum |
HumanEval\/797 | def sum_Odd(n):
terms = (n + 1) // 2
sum1 = terms * terms
return sum1
def sum_in_Range(l, r):
""" Find the sum of all odd natural numbers within the range l and r.
>>> sum_in_Range(2, 5)
8
>>> sum_in_Range(5, 7)
12
>>> sum_in_Range(7, 13)
40
"""
| return sum_Odd(r) - sum_Odd(l - 1)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(2, 5) == 8
assert candidate(5, 7) == 12
assert candidate(7, 13) == 40
| sum_in_Range |
HumanEval\/798 | from typing import List
def _sum(arr: List[int]) -> int:
""" Find the sum of an array of integers
>>> _sum([1, 2, 3])
6
>>> _sum([15, 12, 13, 10])
50
>>> _sum([0, 1, 2])
3
"""
| sum=0
for i in arr:
sum = sum + i
return(sum)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate([1, 2, 3]) == 6
assert candidate([15, 12, 13, 10]) == 50
assert candidate([0, 1, 2]) == 3
| _sum |
HumanEval\/799 | INT_BITS = 32
def left_Rotate(n, d):
""" Left rotate the bits of a given number n by d positions.
>>> left_Rotate(16, 2)
64
>>> left_Rotate(10, 2)
40
>>> left_Rotate(99, 3)
792
"""
| return (n << d) | (n >> (INT_BITS - d))
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate(16, 2) == 64
assert candidate(10, 2) == 40
assert candidate(99, 3) == 792
| left_Rotate |
HumanEval\/800 | import re
def remove_all_spaces(text: str) -> str:
""" Remove all whitespaces from a string
>>> remove_all_spaces('python program')
'pythonprogram'
>>> remove_all_spaces('python programming language')
'pythonprogramminglanguage'
>>> remove_all_spaces('python program')
'pythonprogram'
"""
| return re.sub(r'\s+', '', text)
|
METADATA = {
'author': 'jt',
'dataset': 'test'
}
def check(candidate):
assert candidate('python program') == 'pythonprogram'
assert candidate('python programming language') == 'pythonprogramminglanguage'
assert candidate('python program') == 'pythonprogram'
| remove_all_spaces |