1.用两个栈实现队列
232.Implement Queue using Stacks
Implement the following operations of a queue using stacks.
- push(x) -- Push element x to the back of queue.
- pop() -- Removes the element from in front of queue.
- peek() -- Get the front element.
- empty() -- Return whether the queue is empty.
Notes:
- You must use only standard operations of a stack -- which means only push to top, peek/pop from top, size, and is empty operations are valid.
- Depending on your language, stack may not be supported natively. You may simulate a stack by using a list or deque (double-ended queue), as long as you use only standard operations of a stack.
- You may assume that all operations are valid (for example, no pop or peek operations will be called on an empty queue).
Solution
class Queue(object):
def __init__(self):
"""
initialize your data structure here.
"""
self.input = [] # stack, only append,pop are allowed
self.output = []
def push(self, x):
"""
:type x: int
:rtype: nothing
"""
self.input.append(x)
def pop(self):
"""
:rtype: nothing
"""
self.peek
return self.output.pop()
def peek(self):
"""
:rtype: int
"""
if self.output == []:
while self.input != []:
self.output.append(self.input.pop())
return self.output[-1]
def empty(self):
"""
:rtype: bool
"""
return len(self.input) == 0 and len(self.output) == 0
2.用两个队列实现栈
225. Implement Stack using Queues
Implement the following operations of a stack using queues.
- push(x) -- Push element x onto stack.
- pop() -- Removes the element on top of the stack.
- top() -- Get the top element.
- empty() -- Return whether the stack is empty.
Notes:
- You must use only standard operations of a queue -- which means only push to back, peek/pop from front, size, and is empty operations are valid.
- Depending on your language, queue may not be supported natively. You may simulate a queue by using a list or deque (double-ended queue), as long as you use only standard operations of a queue.
- You may assume that all operations are valid (for example, no pop or top operations will be called on an empty stack).
Solution
class Stack(object):
# initialize your data structure here.
def __init__(self):
self.queue1 = []
self.queue2 = []
self.size = 0
# @param x, an integer
# @return nothing
def push(self, x):
if not self.queue2:
self.queue1.append(x)
else:
self.queue2.append(x)
self.size += 1
# @return nothing
def pop(self):
if not self.queue2:
for _ in xrange(self.size-1):
self.queue2.append(self.queue1.pop(0))
self.queue1.pop(0)
else:
for _ in xrange(self.size-1):
self.queue1.append(self.queue2.pop(0))
self.queue2.pop(0)
self.size -= 1
# @return an integer
def top(self):
if not self.queue2:
for _ in xrange(self.size-1):
self.queue2.append(self.queue1.pop(0))
tmp = self.queue1.pop(0)
self.queue2.append(tmp)
return tmp
else:
for _ in xrange(self.size-1):
self.queue1.append(self.queue2.pop(0))
tmp = self.queue2.pop(0)
self.queue1.append(tmp)
return tmp
# @return an boolean
def empty(self):
return self.size == 0
using one queue
class Stack(object):
def __init__(self):
"""
initialize your data structure here.
"""
import collections
self.queue = collections.deque()
def push(self, x):
"""
:type x: int
:rtype: nothing
"""
q = self.queue
q.append(x)
for i in range(len(q)-1):
q.append(q.popleft())
def pop(self):
"""
:rtype: nothing
"""
self.queue.popleft()
def top(self):
"""
:rtype: int
"""
return self.queue[0]
def empty(self):
"""
:rtype: bool
"""
return not len(self.queue)