在Java中连接两个字符串的最快方法是什么？

string performance java

2022-09-01 00:21:03

即

String ccyPair = ccy1 + ccy2;

我在 a 中用作键，它在一个非常紧凑的循环中调用以检索值。cyPairHashMap

当我分析时，这就是瓶颈

java.lang.StringBuilder.append(StringBuilder.java:119)  
java.lang.StringBuilder.(StringBuilder.java:93)

答案 1

很多理论 - 有时间进行一些练习！

private final String s1 = new String("1234567890");
private final String s2 = new String("1234567890");

在预热的 64 位热点上使用 10，000，000 的普通循环，在 Intel Mac OS 上使用 1.6.0_22。

例如

@Test public void testConcatenation() {
    for (int i = 0; i < COUNT; i++) {
        String s3 = s1 + s2;
    }
}

循环中包含以下语句

String s3 = s1 + s2;

1.33 秒

String s3 = new StringBuilder(s1).append(s2).toString();

1.485

String s3 = new StringBuffer(s1).append(s2).toString();

1.92 秒

String s3 = s1.concat(s2);

0.70 秒

String s3 = "1234567890" + "1234567890";

0.0 秒

因此，concat是明显的赢家，除非你有静态字符串，在这种情况下，编译器已经照顾好了你。

答案 2

我相信答案可能已经确定，但我发帖分享代码。

简短的答案，如果你正在寻找的纯串联，是：String.concat（...）

输出：

ITERATION_LIMIT1: 1
ITERATION_LIMIT2: 10000000
s1: STRING1-1111111111111111111111
s2: STRING2-2222222222222222222222

iteration: 1
                                          null:    1.7 nanos
                                 s1.concat(s2):  106.1 nanos
                                       s1 + s2:  251.7 nanos
   new StringBuilder(s1).append(s2).toString():  246.6 nanos
    new StringBuffer(s1).append(s2).toString():  404.7 nanos
                 String.format("%s%s", s1, s2): 3276.0 nanos

Tests complete

示例代码：

package net.fosdal.scratch;

public class StringConcatenationPerformance {
    private static final int    ITERATION_LIMIT1    = 1;
    private static final int    ITERATION_LIMIT2    = 10000000;

    public static void main(String[] args) {
        String s1 = "STRING1-1111111111111111111111";
        String s2 = "STRING2-2222222222222222222222";
        String methodName;
        long startNanos, durationNanos;
        int iteration2;

        System.out.println("ITERATION_LIMIT1: " + ITERATION_LIMIT1);
        System.out.println("ITERATION_LIMIT2: " + ITERATION_LIMIT2);
        System.out.println("s1: " + s1);
        System.out.println("s2: " + s2);
        int iteration1 = 0;
        while (iteration1++ < ITERATION_LIMIT1) {
            System.out.println();
            System.out.println("iteration: " + iteration1);

            // method #0
            methodName = "null";
            iteration2 = 0;
            startNanos = System.nanoTime();
            while (iteration2++ < ITERATION_LIMIT2) {
                method0(s1, s2);
            }
            durationNanos = System.nanoTime() - startNanos;
            System.out.println(String.format("%50s: %6.1f nanos", methodName, ((double) durationNanos) / ITERATION_LIMIT2));

            // method #1
            methodName = "s1.concat(s2)";
            iteration2 = 0;
            startNanos = System.nanoTime();
            while (iteration2++ < ITERATION_LIMIT2) {
                method1(s1, s2);
            }
            durationNanos = System.nanoTime() - startNanos;
            System.out.println(String.format("%50s: %6.1f nanos", methodName, ((double) durationNanos) / ITERATION_LIMIT2));

            // method #2
            iteration2 = 0;
            startNanos = System.nanoTime();
            methodName = "s1 + s2";
            while (iteration2++ < ITERATION_LIMIT2) {
                method2(s1, s2);
            }
            durationNanos = System.nanoTime() - startNanos;
            System.out.println(String.format("%50s: %6.1f nanos", methodName, ((double) durationNanos) / ITERATION_LIMIT2));

            // method #3
            iteration2 = 0;
            startNanos = System.nanoTime();
            methodName = "new StringBuilder(s1).append(s2).toString()";
            while (iteration2++ < ITERATION_LIMIT2) {
                method3(s1, s2);
            }
            durationNanos = System.nanoTime() - startNanos;
            System.out.println(String.format("%50s: %6.1f nanos", methodName, ((double) durationNanos) / ITERATION_LIMIT2));

            // method #4
            iteration2 = 0;
            startNanos = System.nanoTime();
            methodName = "new StringBuffer(s1).append(s2).toString()";
            while (iteration2++ < ITERATION_LIMIT2) {
                method4(s1, s2);
            }
            durationNanos = System.nanoTime() - startNanos;
            System.out.println(String.format("%50s: %6.1f nanos", methodName, ((double) durationNanos) / ITERATION_LIMIT2));

            // method #5
            iteration2 = 0;
            startNanos = System.nanoTime();
            methodName = "String.format(\"%s%s\", s1, s2)";
            while (iteration2++ < ITERATION_LIMIT2) {
                method5(s1, s2);
            }
            durationNanos = System.nanoTime() - startNanos;
            System.out.println(String.format("%50s: %6.1f nanos", methodName, ((double) durationNanos) / ITERATION_LIMIT2));

        }
        System.out.println();
        System.out.println("Tests complete");

    }

    public static String method0(String s1, String s2) {
        return "";
    }

    public static String method1(String s1, String s2) {
        return s1.concat(s2);
    }

    public static String method2(String s1, String s2) {
        return s1 + s2;
    }

    public static String method3(String s1, String s2) {
        return new StringBuilder(s1).append(s2).toString();
    }

    public static String method4(String s1, String s2) {
        return new StringBuffer(s1).append(s2).toString();
    }

    public static String method5(String s1, String s2) {
        return String.format("%s%s", s1, s2);
    }

}