1 实现Runnable线程案例
使用() -> {} 替代匿名类:
//Before Java 8:
new Thread(new Runnable() {
@Override
public void run() {
System.out.println("Before Java8 ");
}
}).start();
//Java 8 way:
new Thread( () -> System.out.println("In Java8!") ).start();Output:
too much code, for too little to do
Lambda expression rocks !!
你可以使用 下面语法实现Lambda:
(params) -> expression
(params) -> statement
(params) -> { statements }如果你的方法并不改变任何方法参数,比如只是输出,那么可以简写如下:
() -> System.out.println("Hello Lambda Expressions");如果你的方法接受两个方法参数,如下:
(int even, int odd) -> even + odd2 实现事件处理
如果你曾经做过Swing 编程,你将永远不会忘记编写事件侦听器代码。使用lambda表达式如下所示写出更好的事件侦听器的代码。
// Before Java 8:
JButton show = new JButton("Show");
show.addActionListener(new ActionListener() {
@Override
public void actionPerformed(ActionEvent e) {
System.out.println("without lambda expression is boring");
}
});
// Java 8 way:
show.addActionListener((e) -> {
System.out.println("Action !! Lambda expressions Rocks");
});在java 8中你可以使用Lambda表达式替代丑陋的匿名类。
3 使用Lambda表达式遍历List集合
//Prior Java 8 :
List features = Arrays.asList("Lambdas", "Default Method",
"Stream API", "Date and Time API");
for (String feature : features) {
System.out.println(feature);
}
//In Java 8:
List features = Arrays.asList("Lambdas", "Default Method", "Stream API",
"Date and Time API");
features.forEach(n -> System.out.println(n));
// Even better use Method reference feature of Java 8
// method reference is denoted by :: (double colon) operator
// looks similar to score resolution operator of C++
features.forEach(System.out::println);Output:
Lambdas
Default Method
Stream API
Date and Time API
方法引用是使用两个冒号::这个操作符号。
4 使用Lambda表达式和函数接口
为了支持函数编程,Java 8加入了一个新的包java.util.function,其中有一个接口java.util.function.Predicate是支持Lambda函数编程:
public static void main(args[]){
List languages = Arrays.asList("Java", "Scala", "C++", "Haskell", "Lisp");
System.out.println("Languages which starts with J :");
filter(languages, (str)->str.startsWith("J"));
System.out.println("Languages which ends with a ");
filter(languages, (str)->str.endsWith("a"));
System.out.println("Print all languages :");
filter(languages, (str)->true);
System.out.println("Print no language : ");
filter(languages, (str)->false);
System.out.println("Print language whose length greater than 4:");
filter(languages, (str)->str.length() > 4);
}
public static void filter(List names, Predicate condition) {
for(String name: names) {
if(condition.test(name)) {
System.out.println(name + " ");
}
}
}
}Output:
Languages which starts with J :
Java
Languages which ends with a
Java
Scala
Print all languages :
Java
Scala
C++
Haskell
Lisp
Print no language :
Print language whose length greater than 4:
Scala
Haskell
//Even better
public static void filter(List names, Predicate condition) {
names.stream().filter((name) -> (condition.test(name)))
.forEach((name) -> {System.out.println(name + " ");
});
}你能看到来自Stream API 的filter方法能够接受 Predicate参数, 能够允许测试多个条件。
5 复杂的结合Predicate 使用
java.util.function.Predicate提供and(), or() 和 xor()可以进行逻辑操作,比如为了得到一串字符串中以”J”开头的4个长度:
// We can even combine Predicate using and(), or() And xor() logical functions
// for example to find names, which starts with J and four letters long, you
// can pass combination of two Predicate
Predicate<String> startsWithJ = (n) -> n.startsWith("J");
Predicate<String> fourLetterLong = (n) -> n.length() == 4;
names.stream()
.filter(startsWithJ.and(fourLetterLong))
.forEach((n) -> System.out.print("\nName, which starts with
'J' and four letter long is : " + n));其中startsWithJ.and(fourLetterLong)是使用了AND逻辑操作。
6 使用Lambda实现Map 和 Reduce
最流行的函数编程概念是map,它允许你改变你的对象,在这个案例中,我们将costBeforeTeax集合中每个元素改变了增加一定的数值,我们将Lambda表达式 x -> x*x传送map()方法,这将应用到stream中所有元素。然后我们使用 forEach() 打印出这个集合的元素.
// applying 12% VAT on each purchase
// Without lambda expressions:
List costBeforeTax = Arrays.asList(100, 200, 300, 400, 500);
for (Integer cost : costBeforeTax) {
double price = cost + .12*cost;
System.out.println(price);
}
// With Lambda expression:
List costBeforeTax = Arrays.asList(100, 200, 300, 400, 500);
costBeforeTax.stream().map((cost) -> cost + .12*cost)
.forEach(System.out::println);Output
112.0
224.0
336.0
448.0
560.0
112.0
224.0
336.0
448.0
560.0
reduce() 是将集合中所有值结合进一个,Reduce类似SQL语句中的sum(), avg() 或count(),
// Applying 12% VAT on each purchase
// Old way:
List costBeforeTax = Arrays.asList(100, 200, 300, 400, 500);
double total = 0;
for (Integer cost : costBeforeTax) {
double price = cost + .12*cost;
total = total + price;
}
System.out.println("Total : " + total);
// New way:
List costBeforeTax = Arrays.asList(100, 200, 300, 400, 500);
double bill = costBeforeTax.stream().map((cost) -> cost + .12*cost)
.reduce((sum, cost) -> sum + cost)
.get();
System.out.println("Total : " + bill);Output
Total : 1680.0
Total : 1680.0
7 通过filtering 创建一个字符串String的集合
Filtering是对大型Collection操作的一个通用操作,Stream提供filter()方法,接受一个Predicate对象,意味着你能传送lambda表达式作为一个过滤逻辑进入这个方法:
// Create a List with String more than 2 characters
List<String> filtered = strList.stream().filter(x -> x.length()> 2)
.collect(Collectors.toList());
System.out.printf("Original List : %s, filtered list : %s %n",
strList, filtered);Output :
Original List : [abc, , bcd, , defg, jk], filtered list : [abc, bcd, defg]
8 对集合中每个元素应用函数
我们经常需要对集合中元素运用一定的功能,如表中的每个元素乘以或除以一个值等等.
// Convert String to Uppercase and join them using coma
List<String> G7 = Arrays.asList("USA", "Japan", "France", "Germany",
"Italy", "U.K.","Canada");
String G7Countries = G7.stream().map(x -> x.toUpperCase())
.collect(Collectors.joining(", "));
System.out.println(G7Countries);Output :
USA, JAPAN, FRANCE, GERMANY, ITALY, U.K., CANADA
上面是将字符串转换为大写,然后使用逗号串起来。
9 通过复制不同的值创建一个子列表
使用Stream的distinct()方法过滤集合中重复元素。
// Create List of square of all distinct numbers
List<Integer> numbers = Arrays.asList(9, 10, 3, 4, 7, 3, 4);
List<Integer> distinct = numbers.stream().map( i -> i*i).distinct()
.collect(Collectors.toList());
System.out.printf("Original List : %s, Square Without duplicates :
%s %n", numbers, distinct);Output :
Original List : [9, 10, 3, 4, 7, 3, 4], Square Without
duplicates : [81, 100, 9, 16, 49]
10 计算List中的元素的最大值,最小值,总和及平均值
//Get count, min, max, sum, and average for numbers
List<Integer> primes = Arrays.asList(2, 3, 5, 7, 11, 13, 17, 19, 23, 29);
IntSummaryStatistics stats = primes.stream().mapToInt((x) -> x)
.summaryStatistics();
System.out.println("Highest prime number in List : " + stats.getMax());
System.out.println("Lowest prime number in List : " + stats.getMin());
System.out.println("Sum of all prime numbers : " + stats.getSum());
System.out.println("Average of all prime numbers : " + stats.getAverage());Output :
Highest prime number in List : 29
Lowest prime number in List : 2
Sum of all prime numbers : 129
Average of all prime numbers : 12.9
