Python的集合set原理
集合(set)是一个无序的不重复元素序列。
可以使用大括号 { } 或者 set() 函数创建集合,注意:创建一个空集合必须用 set() 而不是 { },因为 { } 是用来创建一个空字典。
class Array(object):
def __init__(self, size=32, init=None):
self._size = size
self._items = [init] * self._size
def __getitem__(self, index):
return self._items[index]
def __setitem__(self, index, value):
self._items[index] = value
def __len__(self):
return self._size
def clear(self, value=None):
for i in range(len(self._items)):
self._items[i] = value
def __iter__(self):
for item in self._items:
yield item
class Slot(object):
"""定义一个 hash 表 数组的槽
注意,一个槽有三种状态,看你能否想明白
1.从未使用 HashMap.UNUSED。此槽没有被使用和冲突过,查找时只要找到 UNUSED 就不用再继续探查了
2.使用过但是 remove 了,此时是 HashMap.EMPTY,该探查点后边的元素扔可能是有key
3.槽正在使用 Slot 节点
"""
def __init__(self, key, value):
self.key, self.value = key, value
class HashTable(object):
# 表示从未被使用过
UNUSED = None
# 使用过,但是被删除了
EMPTY = Slot(None, None)
def __init__(self):
self._table = Array(8, init=HashTable.UNUSED)
self.length = 0
# 负载因子
@property
def _load_factor(self):
return self.length/float(len(self._table))
def __len__(self):
return self.length
# 哈希函数 用内置的哈希哈数进行哈希一下,然后对数组长度取模
def _hash(self, key):
return abs(hash(key)) % len(self._table)
def _find_key(self, key):
# 得到第一个值的位置
index = self._hash(key)
_len = len(self._table)
# 当这个槽不是未使用过的,才接着往下找;如果是未使用过的,这个key肯定不存在
while self._table[index] is not HashTable.UNUSED:
# 槽使用过,但是被删除了
if self._table[index] is HashTable.EMPTY:
# cpython解决哈希冲突的一种方式
index = (index*5 + 1) % _len
continue
elif self._table[index] == key:
return index
else:
index = (index * 5 + 1) % _len
return None
# 检测槽是否能被插入
def _slot_can_insert(self, index):
return (self._table[index] is HashTable.EMPTY or self._table[index] is HashTable.UNUSED)
# 找到能被插入的槽的index
def _find_slot_insert(self, key):
# 得到第一个值的位置
index = self._hash(key)
_len = len(self._table)
while not self._slot_can_insert(index):
index = (index * 5 + 1) % _len
return index
# in 操作符
def __contains__(self, key):
index = self._find_key(key)
return index is not None
def add(self, key, value):
if key in self:
index = self._find_key(key)
# 更新值
self._table[index].value = value
return False
else:
index = self._find_slot_insert(key)
self._table[index] = Slot(key, value)
self.length += 1
if self._load_factor > 0.8:
return self._rehash()
return True
def _rehash(self):
oldtable = self._table
newsize = len(self._table) * 2
# 新的table
self._table = Array(newsize, HashTable.UNUSED)
self.length = 0
for slot in oldtable:
if slot is not HashTable.UNUSED and slot is not HashTable.EMPTY:
index = self._find_slot_insert(slot.key)
self._table[index] = slot
self.length += 1
def get(self, key, default=None):
index = self._find_key(key)
if index is None:
return default
else:
return self._table[index].value
def remove(self, key):
index = self._find_key(key)
if index is None:
raise KeyError
value = self._table[index].value
self.length -= 1
# 把槽设置为空槽
self._table[index] = HashTable.EMPTY
return value
def __iter__(self):
for slot in self._table:
if slot not in (HashTable.UNUSED, HashTable.EMPTY):
yield slot.value
class SetADT(HashTable):
def add(self, key):
return super(SetADT, self).add(key, True)
def __and__(self, other_set):
# 求交集
new_set = SetADT()
for element_a in self:
if element_a in other_set:
new_set.add(element_a)
return new_set
def __sub__(self, other_set):
# 求差集
new_set = SetADT()
for element_a in self:
if element_a not in other_set:
new_set.add(element_a)
return new_set
def __or__(self, other_set):
# 求交集
new_set = SetADT()
for element_a in self:
new_set.add(element_a)
for element_b in other_set:
new_set.add(element_b)
return new_set
