123. Best Time to Buy and Sell Stock III
Say you have an array for which the ith element is the price of a given stock on day i.
Design an algorithm to find the maximum profit. You may complete at most two transactions.
Note: You may not engage in multiple transactions at the same time (i.e., you must sell the stock before you buy again).
Example 1:
Input: [3,3,5,0,0,3,1,4]
Output: 6
Explanation: Buy on day 4 (price = 0) and sell on day 6 (price = 3), profit = 3-0 = 3.
Then buy on day 7 (price = 1) and sell on day 8 (price = 4), profit = 4-1 = 3.
Example 2:
Input: [1,2,3,4,5]
Output: 4
Explanation: Buy on day 1 (price = 1) and sell on day 5 (price = 5), profit = 5-1 = 4.
Note that you cannot buy on day 1, buy on day 2 and sell them later, as you are
engaging multiple transactions at the same time. You must sell before buying again.
Example 3:
Input: [7,6,4,3,1]
Output: 0
Explanation: In this case, no transaction is done, i.e. max profit = 0.
方法一:
class Solution
{
public:
int maxProfit(vector<int>& prices)
{
int n = prices.size();
if (!n) return 0;
vector<int> f(n, 0);
int minv = INT_MAX;
for (int i = 0; i < n; i ++ )
{
if (i) f[i] = f[i - 1];
if (prices[i] > minv)
f[i] = max(f[i], prices[i] - minv);
minv = min(minv, prices[i]);
}
int res = f[n - 1];
int maxv = INT_MIN;
for (int i = n - 1; i > 0; i -- )
{
if (prices[i] < maxv)
res = max(res, maxv - prices[i] + f[i - 1]);
maxv = max(maxv, prices[i]);
}
return res;
}
};
方法二:
//solve2
//它定义了4个状态:
//Buy1[i]表示前i天做第一笔交易买入股票后剩下的最多的钱
//Sell1[i]表示前i天做第一笔交易卖出股票后剩下的最多的钱
//Buy2[i]表示前i天做第二笔交易买入股票后剩下的最多的钱
//Sell2[i]表示前i天做第二笔交易卖出股票后剩下的最多的钱
//so
// Sell2[i]=max{Sell2[i-1],Buy2[i-1]+prices[i]}
// Buy2[i]=max{Buy2[i-1],Sell[i-1]-prices[i]}
// Sell1[i]=max{Sell[i-1],Buy1[i-1]+prices[i]}
// Buy1[i]=max{Buy[i-1],-prices[i]}
class Solution
{
public:
int maxProfit(vector<int>& prices)
{
int buy1=numeric_limits<int>::min();
int buy2=numeric_limits<int>::min();
int sell1=0;
int sell2=0;
for(int i=0;i<prices.size();i++)
{
sell2=max(sell2,buy2+prices[i]);
buy2=max(buy2,sell1-prices[i]);
sell1=max(sell1,buy1+prices[i]);
buy1=max(buy1,-prices[i]);
}
return sell2;
}
};
方法三:
这里我们先解释最多可以进行k次交易的算法,然后最多进行两次我们只需要把k取成2即可。我们还是使用“局部最优和全局最优解法”。我们维护两种量,一个是当前到达第i天可以最多进行j次交易,最好的利润是多少(global[i][j]),另一个是当前到达第i天,最多可进行j次交易,并且最后一次交易在当天卖出的最好的利润是多少(local[i][j])。下面我们来看递推式,全局的比较简单,
global[i][j]=max(local[i][j],global[i-1][j]),
也就是去当前局部最好的,和过往全局最好的中大的那个(因为最后一次交易如果包含当前天一定在局部最好的里面,否则一定在过往全局最优的里面)。对于局部变量的维护,递推式是
local[i][j]=max(global[i-1][j-1]+max(diff,0),local[i-1][j]+diff),
也就是看两个量,第一个是全局到i-1天进行j-1次交易,然后加上今天的交易,如果今天是赚钱的话(也就是前面只要j-1次交易,最后一次交易取当前天),第二个量则是取local第i-1天j次交易,然后加上今天的差值(这里因为local[i-1][j]比如包含第i-1天卖出的交易,所以现在变成第i天卖出,并不会增加交易次数,而且这里无论diff是不是大于0都一定要加上,因为否则就不满足local[i][j]必须在最后一天卖出的条件了)。
class Solution
{
public:
int maxProfit(vector<int> &prices)
{
if (prices.empty()) return 0;
int n = prices.size(), g[n][3] = {0}, l[n][3] = {0};
for (int i = 1; i < prices.size(); ++i)
{
int diff = prices[i] - prices[i - 1];
for (int j = 1; j <= 2; ++j)
{
l[i][j] = max(g[i - 1][j - 1] + max(diff, 0), l[i - 1][j] + diff);
g[i][j] = max(l[i][j], g[i - 1][j]);
}
}
return g[n - 1][2];
}
};
一维写法:
class Solution
{
public:
int maxProfit(vector<int> &prices)
{
if (prices.empty()) return 0;
int g[3] = {0};
int l[3] = {0};
for (int i = 0; i < prices.size() - 1; ++i)
{
int diff = prices[i + 1] - prices[i];
for (int j = 2; j >= 1; --j)
{
l[j] = max(g[j - 1] + max(diff, 0), l[j] + diff);
g[j] = max(l[j], g[j]);
}
}
return g[2];
}
};
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