Python 官方文档:入门教程 => 点击学习
目录0、引言1、数据准备2、类型转化3、递归实现方法3.1、Java7及以下纯Java递归实现3.2、Java8及以上借助lamda表达式实现0、引言 在开发的过程中,很多业务场景需
在开发的过程中,很多业务场景需要一个树形结构的结果集进行前端展示,也可以理解为是一个无限父子结构,常见的有报表指标结构、菜单结构等。Java中递归实现树形结构的两种常见方式如下:
package com.wbs.pojo;
import lombok.Data;
import lombok.NoArgsConstructor;
import java.util.List;
@Data
@NoArgsConstructor
public class NodePO {
private String id;
private String name;
private String parentId;
private String orderNo;
private List<NodePO> children;
public NodePO(String id,String name,String parentId,String orderNo){
this.id = id;
this.name = name;
this.parentId = parentId;
this.orderNo = orderNo;
}
}
自己造一些数据模拟从数据库中查询出来的数据:
static final List<NodePO> nodePOs = Arrays.asList(
new NodePO("1","一级节点1",null,"_0001"),
new NodePO("2","二级节点1.1","1","_0002"),
new NodePO("3","二级节点1.2","1","_0003"),
new NodePO("4","一级节点2",null,"_0004"),
new NodePO("5","二级节点2.1","4","_0005"),
new NodePO("6","二级节点2.2","4","_0006"),
new NodePO("7","三级节点2.2.1","6","_0007"),
new NodePO("8","一级节点3",null,"_0008"),
new NodePO("9","二级节点3.1","8","_0009"),
new NodePO("10","三级节点3.1.1","9","_0010"),
new NodePO("11","四级节点3.1.1.1","10","_0011"),
new NodePO("12","五级节点3.1.1.1.1","11","_0012")
);
从开发的过程中发现直接操作实体类集合,专门指定某一个实体类封装的方法是不具有普适性的,所以将实体类集合统一转化为Map集合,操作方便,具有一定的普适性:
List<Map<String, Object>> mapList = BeanMapUtils.listBeanToListMap(JSONObject);BeanMapUtils自己简单封装一个工具类(不惧普适性勿喷):
package com.wbs.util;
import com.alibaba.fastjson.JSON;
import com.alibaba.fastjson.JSONObject;
import com.Google.common.collect.Lists;
import com.google.common.collect.Maps;
import lombok.SneakyThrows;
import org.springframework.cglib.beans.BeanMap;
import java.util.*;
import java.util.function.Function;
import java.util.stream.Collectors;
public class BeanMapUtils {
public static <T> Map<String, Object> beanToMap(T t) {
Map<String, Object> map = new HashMap<>();
if (t != null) {
if (t instanceof JSONObject){
return (JSONObject)t;
}
BeanMap beanMap = BeanMap.create(t);
for (Object key : beanMap.keySet()) {
map.put(key.toString(), beanMap.get(key));
}
}
return map;
}
public static <T> T mapToBean(Map<String, Object> map,Class<T> clazz) throws Exception {
T bean = clazz.newInstance();
if (bean instanceof JSONObject){
JSONObject jsonObject = (JSONObject)bean;
Set<Map.Entry<String, Object>> entries = map.entrySet();
for (Map.Entry<String, Object> entry : entries) {
jsonObject.put(entry.geTKEy(),entry.getValue());
}
return (T)jsonObject;
}
BeanMap beanMap = BeanMap.create(bean);
beanMap.putAll(map);
return bean;
}
public static <T> List<Map<String, Object>> listBeanToListMap(List<T> objList) {
return objList.stream().map(new Function<T, Map<String, Object>>() {
@Override
public Map<String, Object> apply(T t) {
Map<String,Object> map = Maps.newHashMap();
if (t instanceof JSONObject){
return (JSONObject)t;
}
BeanMap beanMap = BeanMap.create(t);
for (Object key : beanMap.keySet()) {
map.put(key.toString(), beanMap.get(key));
}
return map;
}
}).collect(Collectors.toList());
}
public static <T> List<T> listMapToListBean(List<Map<String,Object>> mapList,Class<T> clazz) {
return mapList.stream().map(new Function<Map<String, Object>,T>() {
@SneakyThrows
@Override
public T apply(Map<String, Object> map) {
T t = clazz.newInstance();
if (t instanceof JSONObject){
return (T)map;
}
BeanMap beanMap = BeanMap.create(t);
beanMap.putAll(map);
return t;
}
}).collect(Collectors.toList());
}
}
其中org.springframework.cglib.beans.BeanMap;是org.springframework:spring-core依赖下的工具包,spring-core核心依赖只要导入spring-boot-starter依赖即可
<dependency>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-starter</artifactId>
<version>2.2.0.RELEASE</version>
</dependency>
既然是Java7及以下实现方式,那排序也用最原始的冒泡排序:
public static List<Map<String, Object>> sortJava7Map(List<Map<String, Object>> list){
if(CollectionUtils.isEmpty(list)){
return Lists.newArrayList();
}
boolean flag;
int size = list.size();
for (int i = 0; i < size - 1; i++) {
flag = false;
for (int j = 1; j < size - i; j++) {
Map<String, Object> frontMap = list.get(j - 1);
Map<String, Object> afterMap = list.get(j);
if (String.valueOf(frontMap.get("orderNo")).compareTo(String.valueOf(afterMap.get("orderNo"))) > 0){
list.set(j - 1,afterMap);
list.set(j,frontMap);
flag = true;
}
}
//如果没有发生位置互换,则退出循环
if (!flag){
break;
}
}
return list;
}
给定一个节点,获取它的所有子节点:
public static List<Map<String, Object>> getJava7Children(Map<String,Object> parentNode,List<Map<String, Object>> allList){
//存放当前节点的直系子节点
List<Map<String, Object>> curNodeChildrenList = Lists.newArrayList();
//存放直系子节点以外的节点
List<Map<String, Object>> otherNodeList = Lists.newArrayList();
Object pId = parentNode.get("id");
for (Map<String, Object> map : allList) {
Object curPId = map.get("parentId");
if (ObjectUtils.isNotEmpty(curPId) && Objects.equals(pId,curPId)){
curNodeChildrenList.add(map);
}else {
otherNodeList.add(map);
}
}
if (curNodeChildrenList.isEmpty()){
return curNodeChildrenList;
}
//每一层级都进行排序
curNodeChildrenList = sortJava7Map(curNodeChildrenList);
//迭代直系子节点再获取子节点
for (Map<String, Object> map : curNodeChildrenList) {
map.put("children",getJava7Children(map,otherNodeList));
}
return curNodeChildrenList;
}
给出一个结果集,构建树形结果集:
public static List<Map<String, Object>> getJava7ResultTree(List<Map<String, Object>> allList){
//存放所有的一级节点
List<Map<String, Object>> oneLevelNodeList = Lists.newArrayList();
for (Map<String, Object> map : allList) {
if (ObjectUtils.isEmpty(map.get("parentId"))){
map.put("children",getJava7Children(map,allList));
oneLevelNodeList.add(map);
}
}
return sortJava8Map(oneLevelNodeList);
}
获取树形结构:
//转化为Map集合
List<Map<String, Object>> mapList = BeanMapUtils.listBeanToListMap(nodePOs);
//获取树形结构
List<Map<String, Object>> java7ResultTree = getJava7ResultTree(mapList);
//打印输出
System.out.println(JSON.toJSONString(java7ResultTree));
打印结果:
[{"orderNo":"_0001","children":[{"orderNo":"_0002","children":[],"name":"二级节点1.1","id":"2","parentId":"1"},{"orderNo":"_0003","children":[],"name":"二级节点1.2","id":"3","parentId":"1"}],"name":"一级节点1","id":"1"},{"orderNo":"_0004","children":[{"orderNo":"_0005","children":[],"name":"二级节点2.1","id":"5","parentId":"4"},{"orderNo":"_0006","children":[{"orderNo":"_0007","children":[],"name":"三级节点2.2.1","id":"7","parentId":"6"}],"name":"二级节点2.2","id":"6","parentId":"4"}],"name":"一级节点2","id":"4"},{"orderNo":"_0008","children":[{"orderNo":"_0009","children":[{"orderNo":"_0010","children":[{"orderNo":"_0011","children":[{"orderNo":"_0012","children":[],"name":"五级节点3.1.1.1.1","id":"12","parentId":"11"}],"name":"四级节点3.1.1.1","id":"11","parentId":"10"}],"name":"三级节点3.1.1","id":"10","parentId":"9"}],"name":"二级节点3.1","id":"9","parentId":"8"}],"name":"一级节点3","id":"8"}]
树形结构搞定!
Java7的方式虽然实现了树形结构,但是有一定的缺点,比如:代码量比较大,逻辑相对较复杂,那Java8是如何简化,如下所示:
既然Java8有lamda表达式,那代码我们能省就省,先看排序,一行代码搞定:
public static List<Map<String, Object>> sortJava8Map(List<Map<String, Object>> list){
if(CollectionUtils.isEmpty(list)){
return Lists.newArrayList();
}
//关键之处,一行代码搞定
list.sort(Comparator.comparing(m -> String.valueOf(m.get("orderNo"))));
return list;
}给定一个节点,获取它的所有子节点:
释义:
filter: 过滤,相当于for循环,再if条件判断。
peek: 给定一个节点,往它的children塞子节点。
public static List<Map<String, Object>> getJava8Children(Map<String,Object> parentNode, List<Map<String, Object>> allList){
return allList.stream()
.filter(curNode -> ObjectUtils.isNotEmpty(curNode.get("parentId")) && Objects.equals(curNode.get("parentId"),parentNode.get("id")))
.peek(m -> m.put("children", getJava8Children(m,allList))).collect(Collectors.toList());
}
给出一个结果集,构建树形结果集:
public static List<Map<String, Object>> getJava8ResultTree(List<Map<String, Object>> mapList){
if (CollectionUtils.isEmpty(mapList)){
return Lists.newArrayList();
}
//filter过滤出所有的一级节点
return mapList.stream().filter(m -> Objects.equals(m.get("parentId"), null) || Objects.equals(m.get("parentId"), ""))
.peek(m -> m.put("children", sortJava8Map(getJava8Children(m, mapList)))).collect(Collectors.toList());
}
获取树形结构:
//转化为Map集合
List<Map<String, Object>> mapList = BeanMapUtils.listBeanToListMap(nodePOs);
//获取树形结构
List<Map<String, Object>> java8ResultTree = getJava8ResultTree(mapList);
//打印输出
System.out.println(JSON.toJSONString(java8ResultTree));
打印结果:
[{"orderNo":"_0001","children":[{"orderNo":"_0002","children":[],"name":"二级节点1.1","id":"2","parentId":"1"},{"orderNo":"_0003","children":[],"name":"二级节点1.2","id":"3","parentId":"1"}],"name":"一级节点1","id":"1"},{"orderNo":"_0004","children":[{"orderNo":"_0005","children":[],"name":"二级节点2.1","id":"5","parentId":"4"},{"orderNo":"_0006","children":[{"orderNo":"_0007","children":[],"name":"三级节点2.2.1","id":"7","parentId":"6"}],"name":"二级节点2.2","id":"6","parentId":"4"}],"name":"一级节点2","id":"4"},{"orderNo":"_0008","children":[{"orderNo":"_0009","children":[{"orderNo":"_0010","children":[{"orderNo":"_0011","children":[{"orderNo":"_0012","children":[],"name":"五级节点3.1.1.1.1","id":"12","parentId":"11"}],"name":"四级节点3.1.1.1","id":"11","parentId":"10"}],"name":"三级节点3.1.1","id":"10","parentId":"9"}],"name":"二级节点3.1","id":"9","parentId":"8"}],"name":"一级节点3","id":"8"}]
树形结构搞定!两种实现方式对比一下,你就说Java8的方式哇塞不哇塞!!!
到此这篇关于Java递归实现树形结构的两种方式的文章就介绍到这了,更多相关Java递归实现树形结构内容请搜索编程网以前的文章或继续浏览下面的相关文章希望大家以后多多支持编程网!
--结束END--
本文标题: 详解Java递归实现树形结构的两种方式
本文链接: https://www.lsjlt.com/news/170052.html(转载时请注明来源链接)
有问题或投稿请发送至: 邮箱/279061341@qq.com QQ/279061341
下载Word文档到电脑,方便收藏和打印~
2024-03-01
2024-03-01
2024-03-01
2024-02-29
2024-02-29
2024-02-29
2024-02-29
2024-02-29
2024-02-29
2024-02-29
回答
回答
回答
回答
回答
回答
回答
回答
回答
回答
官方手机版
微信公众号
商务合作
0