/* * Copyright (c) 2024, 2025, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package compiler.c2.irTests; import jdk.test.lib.Asserts; import jdk.test.lib.Utils; import compiler.lib.ir_framework.*; /* * @test * @bug 8345766 * @summary Test that Ideal transformations of ModFNode are being performed as expected. * @library /test/lib / * @run driver compiler.c2.irTests.ModFNodeTests */ public class ModFNodeTests { public static final float q = Utils.getRandomInstance().nextFloat() * 100.0f; public static void main(String[] args) { TestFramework.run(); } @Run(test = {"constant", "notConstant", "veryNotConstant", "unusedResult", "repeatedlyUnused", "unusedResultAfterLoopOpt1", "unusedResultAfterLoopOpt2", "unusedResultAfterLoopOpt3", }) public void runMethod() { Asserts.assertEQ(constant(), q % 72.0f % 30.0f); Asserts.assertEQ(alsoConstant(), q % 31.432f); Asserts.assertTrue(Float.isNaN(nanLeftConstant())); Asserts.assertTrue(Float.isNaN(nanRightConstant())); Asserts.assertEQ(notConstant(37.5f), 37.5f % 32.0f); Asserts.assertEQ(veryNotConstant(531.25f, 14.5f), 531.25f % 32.0f % 14.5f); unusedResult(1.1f, 2.2f); repeatedlyUnused(1.1f, 2.2f); Asserts.assertEQ(unusedResultAfterLoopOpt1(1.1f, 2.2f), 0.f); Asserts.assertEQ(unusedResultAfterLoopOpt2(1.1f, 2.2f), 0.f); Asserts.assertEQ(unusedResultAfterLoopOpt3(1.1f, 2.2f), 0.f); } @Test @IR(failOn = {"frem"}, phase = CompilePhase.BEFORE_MATCHING) @IR(counts = {IRNode.CON_F, "1"}) public float constant() { // All constants available during parsing return q % 72.0f % 30.0f; } @Test @IR(failOn = {"frem"}, phase = CompilePhase.BEFORE_MATCHING) @IR(counts = {IRNode.CON_F, "1"}) public float alsoConstant() { // Make sure value is only available after second loop opts round float val = 0; for (int i = 0; i < 4; i++) { if ((i % 2) == 0) { val = q; } } return val % 31.432f; } @Test @IR(failOn = {"frem"}, phase = CompilePhase.BEFORE_MATCHING) @IR(counts = {IRNode.CON_F, "1"}) public float nanLeftConstant() { // Make sure value is only available after second loop opts round float val = 134.18f; for (int i = 0; i < 4; i++) { if ((i % 2) == 0) { val = Float.NaN; } } return 56.234f % (val % 31.432f); } @Test @IR(failOn = {"frem"}, phase = CompilePhase.BEFORE_MATCHING) @IR(counts = {IRNode.CON_F, "1"}) public float nanRightConstant() { // Make sure value is only available after second loop opts round float val = 134.18f; for (int i = 0; i < 4; i++) { if ((i % 2) == 0) { val = Float.NaN; } } return 56.234f % (31.432f % val); } @Test @IR(counts = {"frem", "1"}, phase = CompilePhase.BEFORE_MATCHING) @IR(counts = {IRNode.CON_F, "1"}) public float notConstant(float x) { return x % 32.0f; } @Test @IR(counts = {"frem", "2"}, phase = CompilePhase.BEFORE_MATCHING) @IR(counts = {IRNode.CON_F, "1"}) public float veryNotConstant(float x, float y) { return x % 32.0f % y; } @Test @IR(failOn = IRNode.MOD_F, phase = CompilePhase.ITER_GVN1) @IR(counts = {IRNode.MOD_F, "1"}, phase = CompilePhase.AFTER_PARSING) public void unusedResult(float x, float y) { float unused = x % y; } @Test @IR(failOn = IRNode.MOD_F, phase = CompilePhase.ITER_GVN1) @IR(counts = {IRNode.MOD_F, "1"}, phase = CompilePhase.AFTER_PARSING) public void repeatedlyUnused(float x, float y) { float unused = 1.f; for (int i = 0; i < 100_000; i++) { unused = x % y; } } // The difference between unusedResultAfterLoopOpt1 and unusedResultAfterLoopOpt2 // is that they exercise a slightly different reason why the node is being removed, // and thus a different execution path. In unusedResultAfterLoopOpt1 the modulo is // used in the traps of the parse predicates. In unusedResultAfterLoopOpt2, it is not. @Test @IR(counts = {IRNode.MOD_F, "1"}, phase = CompilePhase.ITER_GVN2) @IR(failOn = IRNode.MOD_F, phase = CompilePhase.BEFORE_MACRO_EXPANSION) public float unusedResultAfterLoopOpt1(float x, float y) { float unused = x % y; int a = 77; int b = 0; do { a--; b++; } while (a > 0); if (b == 78) { // dead return unused; } return 0.f; } @Test @IR(counts = {IRNode.MOD_F, "1"}, phase = CompilePhase.AFTER_CLOOPS) @IR(failOn = IRNode.MOD_F, phase = CompilePhase.PHASEIDEALLOOP1) public float unusedResultAfterLoopOpt2(float x, float y) { int a = 77; int b = 0; do { a--; b++; } while (a > 0); float unused = x % y; if (b == 78) { // dead return unused; } return 0.f; } @Test @IR(counts = {IRNode.MOD_F, "2"}, phase = CompilePhase.AFTER_CLOOPS) @IR(failOn = IRNode.MOD_F, phase = CompilePhase.PHASEIDEALLOOP1) public float unusedResultAfterLoopOpt3(float x, float y) { float unused = x % y; int a = 77; int b = 0; do { a--; b++; } while (a > 0); int other = (b - 77) * (int)(x % y % 1.f); return (float)other; } }