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keyword_sorting.py
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from utils import core, generate
# choose flag version for its best performance.
def bubble_sort(array: list, key=None, reverse: bool=False) -> None:
'''
array: 同一数据维度下,支持数值型数据,如整型与浮点型混合;支持全为字符串类型的数据;不支持字符串型与数值型混合。
key: lambda函数, 仅含一个参量,用于关键字排序, 例如: key=lambda x: x[1], key=lambda x: (x[0], x[1])。
reverse: 是否降序, 默认采用升序。
'''
compare = generate(array, key)
for i in range(len(array) - 1): # loop to access each array element
flag = False # 旗帜
for j in range(len(array) - i - 1): # loop to compare array elements
# compare two adjacent elements and change > to < to sort in descending order
if core(compare[j], compare[j + 1], key, reverse):
# swapping elements if elements are not in the intended order
array[j], array[j + 1] = array[j + 1], array[j]
flag = True # 旗帜
if key != None:
compare[j], compare[j + 1] = compare[j + 1], compare[j]
if not flag:
break
# choose binary version for its optimization.
def insertion_sort(array: list, key=None, reverse: bool=False) -> None:
'''
array: 支持数值型数据,如整型与浮点型混合;支持全为字符串类型的数据;不支持字符串型与数值型混合。
key: lambda函数, 仅含一个参量,用于关键字排序, 例如: key=lambda x: x[1], key=lambda x: (x[0], x[1])。
reverse: 是否降序, 默认采用升序。
'''
compare = generate(array, key)
for index in range(1, len(array)):
keyc, keya = compare[index], array[index]
low, high = 0, index - 1
while low <= high: # 符合单调性的序列
mid = (low + high) // 2
if core(keyc, compare[mid], key, reverse):
low = mid + 1
else:
high = mid - 1
for pre in range(index, low, -1): # 从后往前
array[pre] = array[pre - 1]
if key != None:
compare[pre] = compare[pre - 1]
array[low] = keya
if key != None:
compare[low] = keyc
# choose knuth version for its smallest time.
def shell_sort(array: list, key=None, reverse: bool=False) -> None:
'''
array: 支持数值型数据,如整型与浮点型混合;支持全为字符串类型的数据;不支持字符串型与数值型混合。
key: lambda函数, 仅含一个参量,用于关键字排序, 例如: key=lambda x: x[1], key=lambda x: (x[0], x[1])。
reverse: 是否降序, 默认采用升序。
'''
compare = generate(array, key)
length = len(array)
gap = 1
while gap < length / 3:
gap = int(3 * gap + 1)
while gap >= 1:
for index in range(gap, length):
next = index
while next >= gap and core(compare[next - gap], compare[next], key, reverse):
array[next], array[next - gap] = array[next - gap], array[next]
if key != None:
compare[next], compare[next - gap] = compare[next - gap], compare[next]
next -= gap
gap = int(gap / 3)
# choose recursion version for its best performance.
def heap_sort(array: list, key=None, reverse: bool=False) -> None:
'''
array: 支持数值型数据,如整型与浮点型混合;支持全为字符串类型的数据;不支持字符串型与数值型混合。
key: lambda函数, 仅含一个参量,用于关键字排序, 例如: key=lambda x: x[1], key=lambda x: (x[0], x[1])。
reverse: 是否降序, 默认采用升序。
'''
compare = generate(array, key)
def build(root: int, end: int) -> None:
'''
root: 指示根节点的游标(整型), end: 指示数组末尾的游标(整型)
'''
piv = root # 根据reverse
left = 2 * root + 1
right = 2 * root + 2
if left < end and core(compare[left], compare[root], key, reverse):
piv = left
if right < end and core(compare[right], compare[piv], key, reverse):
piv = right
if piv != root:
array[root], array[piv] = array[piv], array[root]
if key != None:
compare[root], compare[piv] = compare[piv], compare[root]
build(piv, end)
length = len(array)
for root in range(length // 2 - 1 , -1, -1):
build(root, length)
for end in range(length - 1, 0, -1):
array[0], array[end] = array[end], array[0]
if key != None:
compare[0], compare[end] = compare[end], compare[0]
build(0, end)
# choose recursion version for its best performance.
def quick_sort(array: list, l: int, r: int, key=None, reverse: bool=False) -> None:
'''
array: 支持数值型数据,如整型与浮点型混合;支持全为字符串类型的数据;不支持字符串型与数值型混合。
l: 数据左侧游标(整型), r: 数据右侧游标(整型)
key: lambda函数, 仅含一个参量,用于关键字排序, 例如: key=lambda x: x[1], key=lambda x: (x[0], x[1])。
reverse: 是否降序, 默认采用升序。
'''
compare = generate(array, key)
if l >= r:
return None
def solve(l: int, r: int) -> None:
'''
算法主体
'''
if l < r:
mid = partition(l, r)
solve(l, mid - 1)
solve(mid + 1, r)
def partition(l: int, r: int) -> int:
'''
array: 数据(列表), l: 数据左侧游标(整型), r: 数据右侧游标(整型)
'''
val = compare[r]
index = l - 1
for ind in range(l, r):
if core(val, compare[ind], key, reverse):
index += 1
array[index], array[ind] = array[ind], array[index]
if key != None:
compare[index], compare[ind] = compare[ind], compare[index]
array[index + 1], array[r] = array[r], array[index + 1]
if key != None:
compare[index + 1], compare[r] = compare[r], compare[index + 1]
return index + 1
solve(l, r)
# choose stack version for its smallest time.
def merge_sort(array: list, key=None, reverse: bool=False) -> None:
'''
array: 支持数值型数据,如整型与浮点型混合;支持全为字符串类型的数据;不支持字符串型与数值型混合。
key: lambda函数, 仅含一个参量,用于关键字排序, 例如: key=lambda x: x[1], key=lambda x: (x[0], x[1])。
reverse: 是否降序, 默认采用升序。
'''
compare = generate(array, key)
def merge(low: int, mid: int, high: int) -> None:
'''
low: 数据低侧游标(整型), mid: 数据中间游标(整型), high: 数据高侧游标(整型)
'''
left, lc = array[low: mid], compare[low: mid]
right, rc = array[mid: high], compare[mid: high]
i = 0
j = 0
result, store = [], []
while i < len(left) and j < len(right):
if core(rc[j], lc[i], key, reverse):
result.append(left[i])
store.append(lc[i])
i += 1
else:
result.append(right[j])
store.append(rc[j])
j += 1
result += left[i:]
store += lc[i:]
result += right[j:]
store += rc[j:]
array[low: high] = result
compare[low: high] = store
def solve() -> None:
'''
算法主体
'''
i = 1
while i < len(array):
low = 0
while low < len(array):
mid = low + i
high = min(low + 2 * i, len(array))
if mid < high:
merge(low, mid, high)
low += 2 * i
i *= 2
solve()