jdk-24/test/hotspot/jtreg/compiler/vectorization/TestReverseBytes.java

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 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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/**
 * @test
 * @bug 8288112
 * @summary Auto-vectorization of ReverseBytes operations.
 * @requires vm.compiler2.enabled
 * @requires (os.simpleArch == "x64" & vm.cpu.features ~= ".*avx2.*") | os.simpleArch == "AArch64" |
 *           (os.simpleArch == "riscv64" & vm.cpu.features ~= ".*zvbb.*")
 * @library /test/lib /
 * @run driver compiler.vectorization.TestReverseBytes
 */

package compiler.vectorization;

import compiler.lib.ir_framework.*;
import java.util.Random;

public class TestReverseBytes {
  private static final int ARRLEN = 1024;
  private static final int ITERS  = 11000;

  private static long [] linp;
  private static long [] lout;
  private static int  [] iinp;
  private static int  [] iout;
  private static short [] sinp;
  private static short [] sout;
  private static char [] cinp;
  private static char [] cout;

  public static void setup() {
      Random r = new Random(1024);
      linp = new long[ARRLEN];
      lout = new long[ARRLEN];
      iinp = new int[ARRLEN];
      iout = new int[ARRLEN];
      sinp = new short[ARRLEN];
      sout = new short[ARRLEN];
      cinp = new char[ARRLEN];
      cout = new char[ARRLEN];
      for(int i = 0; i < ARRLEN; i++) {
          linp[i] = r.nextLong();
          iinp[i] = r.nextInt();
          sinp[i] = (short)r.nextInt();
          cinp[i] = (char)r.nextInt();
      }
  }

  public static void main(String args[]) {
      setup();
      TestFramework.runWithFlags("-XX:-TieredCompilation",
                                  "-XX:CompileThresholdScaling=0.3");
      System.out.println("PASSED");
  }

  @Test
  @IR(counts = {IRNode.REVERSE_BYTES_VL, "> 0"})
  public void test_reverse_bytes_long(long[] lout, long[] linp) {
      for (int i = 0; i < lout.length; i+=1) {
          lout[i] = Long.reverseBytes(linp[i]);
      }
  }

  @Run(test = {"test_reverse_bytes_long"}, mode = RunMode.STANDALONE)
  public void kernel_test_reverse_bytes_long() {
      setup();
      for (int i = 0; i < ITERS; i++) {
          test_reverse_bytes_long(lout , linp);
      }
  }

  @Test
  @IR(counts = {IRNode.REVERSE_BYTES_VI, "> 0"})
  public void test_reverse_bytes_int(int[] iout, int[] iinp) {
      for (int i = 0; i < iout.length; i+=1) {
          iout[i] = Integer.reverseBytes(iinp[i]);
      }
  }

  @Run(test = {"test_reverse_bytes_int"}, mode = RunMode.STANDALONE)
  public void kernel_test_reverse_bytes_int() {
      setup();
      for (int i = 0; i < ITERS; i++) {
          test_reverse_bytes_int(iout , iinp);
      }
  }

  @Test
  @IR(counts = {IRNode.REVERSE_BYTES_VS, "> 0"})
  public void test_reverse_bytes_short(short[] sout, short[] sinp) {
      for (int i = 0; i < sout.length; i+=1) {
          sout[i] = Short.reverseBytes(sinp[i]);
      }
  }

  @Run(test = {"test_reverse_bytes_short"}, mode = RunMode.STANDALONE)
  public void kernel_test_reverse_bytes_short() {
      setup();
      for (int i = 0; i < ITERS; i++) {
          test_reverse_bytes_short(sout , sinp);
      }
  }

  @Test
  @IR(counts = {IRNode.REVERSE_BYTES_VS, "> 0"})
  public void test_reverse_bytes_char(char[] cout, char[] cinp) {
      for (int i = 0; i < cout.length; i+=1) {
          cout[i] = Character.reverseBytes(cinp[i]);
      }
  }

  @Run(test = {"test_reverse_bytes_char"}, mode = RunMode.STANDALONE)
  public void kernel_test_reverse_bytes_char() {
      setup();
      for (int i = 0; i < ITERS; i++) {
          test_reverse_bytes_char(cout , cinp);
      }
  }
}