397 核心思想应该是尽量减少奇数操作
public static int integerReplacement(int n) { if (n == Integer.MAX_VALUE){ return 0; } int k = 0; int result = 0; while (n !=1){ System.out.println(Integer.toBinaryString(n)); if ((n&1)==0){ n>>=1; }else { if (n == 3){ n--; } else if (((n>>(k+1)) & 1 ) == 0){ n--; }else { n++; } } result++; } return result; }
477 汉明距离总和
我的解法是这样
public static int totalHammingDistance(int[] nums) { int max = Integer.MIN_VALUE; for (int num : nums) { max = Math.max(max,num); } int result = 0; Integer len = Integer.toBinaryString(max).length(); int total = nums.length; for (int i = 0; i < len ; i++) { int c = 0; for (int num : nums) { if ( ((num>>i) & 1) == 0){ c++; } } result+=( (total-c)*c); } return result; }
784 字母大小写全排列
暴力解法如下,效率低,但是我看官方给的几种答案复杂度都和我这个一样。。。。
public static List<String> letterCasePermutation(String S) { List<String> list = new ArrayList<>(); if (S.length() == 0){ return list; } for (int i = 0; i < S.length(); i++) { char c = S.charAt(i); if (i == 0){ if (c>='0' && c <= '9'){ list.add(c+""); }else { list.add(Character.toLowerCase(c)+""); list.add(Character.toUpperCase(c)+""); } continue; } List<String> tp = new ArrayList<>(); for (String s : list) { if (c>='0' && c <= '9'){ tp.add(s+c); }else { tp.add(s+Character.toLowerCase(c)); tp.add(s+Character.toUpperCase(c)); } } list = tp; } return list; }
898 和上题有点像
public static int subarrayBitwiseORs(int[] arr) { Set<Integer> set = new HashSet<>(); Set<Integer> res = new HashSet<>(); for (int i = 0; i < arr.length; i++) { int k = arr[i]; Set<Integer> tps = new HashSet<>(); for (Integer p : set) { tps.add(p|k); } tps.add(k); set = tps; res.addAll(set); } return res.size(); }
100
class Solution { public boolean isSameTree(TreeNode p, TreeNode q) { return check(p,q); } private static boolean check(TreeNode p,TreeNode q){ if ((p != null && q == null) || (p == null && q != null)){ return false; } if (p == null && q == null){ return true; } if (p.val != q.val ){ return false; } if (!check(p.left,q.left)){ return false; } if (!check(p.right,q.right)){ return false; } return true; } }
101
class Solution { public boolean isSymmetric(TreeNode root) { if(root == null){ return true; } return check(root.left,root.right); } public static boolean check(TreeNode p,TreeNode q) { if ((p != null && q == null) || (p == null && q != null)){ return false; } if (p == null && q == null){ return true; } if (p.val != q.val ){ return false; } if (!check(p.left,q.right)){ return false; } if (!check(p.right,q.left)){ return false; } return true; } }
104
class Solution { public int maxDepth(TreeNode root) { if(root == null){ return 0; } return check(root,1); } public int check(TreeNode p,int level) { if (p == null){ return level-1; } return Math.max(check(p.left, level + 1), check(p.right, level + 1)); } }
108
class Solution { public TreeNode sortedArrayToBST(int[] nums) { return setVal(0,nums.length-1,nums); } public static TreeNode setVal(int left,int right,int[] nums){ if (left>right){ return null; } int len = (left+right)/2; TreeNode node = new TreeNode(nums[len]); TreeNode leftNode = setVal(left, len-1, nums); node.left = leftNode; TreeNode rightNode = setVal(len+1, right, nums); node.right = rightNode; return node; } }
110 判断平衡二叉树
class Solution { public boolean isBalanced(TreeNode root) { if(root == null){ return true; } int level = getLevel(root.left); int level1 = getLevel(root.right); if (level == -1 || level1 == -1){ return false; } return Math.abs(level-level1) <=1; } public static int getLevel(TreeNode root){ if (root == null)return 0; int left = getLevel(root.left); int right = getLevel(root.right); if (left == -1 || right == -1){ return -1; } if (Math.abs(left-right) >1){ return -1; } return Math.max(left+1,right+1); } }
111 这题注意nil节点不是子节点
class Solution { public int minDepth(TreeNode root) { if(root == null){ return 0; } int left = check(root.left, 1); int right = check(root.right, 1); if(root.left != null && root.right != null){ return Math.min(left,right); } if(root.left != null){ return left; }else{ return right; } } public int check(TreeNode p,int level) { if (p == null){ return level; } int left = check(p.left, level + 1); int right = check(p.right, level + 1); if(p.left != null && p.right != null){ return Math.min(left,right); } if(p.left != null){ return left; }else{ return right; } } }
112 路径总和
class Solution { public boolean hasPathSum(TreeNode root, int targetSum) { if (root == null){ return false; } if (root.left == null && root.right == null && root.val == targetSum){ return true; } if (root.left != null && count(root.left,root.val,targetSum) ){ return true; } if (root.right != null && count(root.right,root.val,targetSum) ){ return true; } return false; } public static boolean count(TreeNode root,int score,int target){ int co = score+root.val; if (root.left != null && count(root.left,co,target)){ return true; } if (root.right != null && count(root.right,co,target)){ return true; } if (root.left == null && root.right == null && co == target){ return true; } return false; } }
226 反转二叉树
我能写出来,所以我离进谷歌就只差一个homebrew了吗 
class Solution { public TreeNode invertTree(TreeNode root) { invert(root); return root; } private static void invert(TreeNode treeNode){ if (treeNode == null){ return; } TreeNode left = treeNode.left; TreeNode right = treeNode.right; treeNode.left = right; treeNode.right = left; invert(left); invert(right); } }
235 最近公共父节点
class Solution { public TreeNode lowestCommonAncestor(TreeNode root, TreeNode p, TreeNode q) { int k = root.val; if ((k-p.val)*(k-q.val) <=0){ return root; } return lowestCommonAncestor((k-p.val)>0?root.left:root.right,p,q); } }
257
class Solution { public List<String> binaryTreePaths(TreeNode root) { List<String> result = new ArrayList<>(); if(root == null){ return result; } if (root.left == null && root.right == null){ result.add(root.val+""); return result; } find(root.left,result,root.val+""); find(root.right,result,root.val+""); return result; } public static void find(TreeNode root, List<String> result,String current){ if (root == null){ return; } if (root.left == null && root.right == null){ result.add(current+"->"+root.val); return; } find(root.left,result,current+"->"+root.val); find(root.right,result,current+"->"+root.val); } }