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.
M1: dp (optimal), time = O(n), space = O(1)
class Solution { public int maxProfit(int[] prices) { int n = prices.length; if(n < 2) { return 0; } int[] local = new int[3]; // local[i]: the max profit in first i days, stock must be sold on day i int[] global = new int[3]; // global[i]: the max profit in first i days for(int i = 1; i < n; i++) { int diff = prices[i] - prices[i - 1]; for(int j = 2; j >= 1; j--) { // local[i-1][j]+diff是把本来在第i-1天卖出的第j次交易改在第i天卖出 // 因为是连续的,因此不会多出一次交易 local[j] = Math.max(global[j - 1] + Math.max(0, diff), local[j] + diff); global[j] = Math.max(global[j], local[j]); } } return global[2]; } }
M2: dp, time = O(n), space = O(n)
class Solution { public int maxProfit(int[] prices) { int n = prices.length; if(n < 2) { return 0; } // mustSell[i][j]: the max profit in first i days with at most j transactions, stock must be sold on day i // globalBest[i][j]: the max profit in first i days with at most j transactions int[][] mustSell = new int[n][3]; int[][] globalBest = new int[n][3]; for(int i = 1; i < n; i++) { int diff = prices[i] - prices[i - 1]; mustSell[i][0] = 0; for(int j = 1; j <= 2; j++) { mustSell[i][j] = Math.max(globalBest[i - 1][j - 1] + diff, mustSell[i - 1][j] + diff); globalBest[i][j] = Math.max(globalBest[i - 1][j], mustSell[i][j]); } } return globalBest[n - 1][2]; } }