/* * Copyright Amazon.com Inc. 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.loopopts; import compiler.lib.ir_framework.*; import jdk.test.lib.Asserts; import jdk.test.lib.Utils; import java.util.Random; /* * @test * @bug 8323220 * @summary Test loop invariant code motion for cmp nodes through reassociation * @library /test/lib / * @run driver compiler.c2.loopopts.InvariantCodeMotionReassociateCmp */ public class InvariantCodeMotionReassociateCmp { private static final Random RANDOM = Utils.getRandomInstance(); private int size; private int inv1; private int inv2; public static void main(String[] args) { TestFramework.run(); } @DontInline private void blackhole() {} @Setup public Object[] setup(SetupInfo info) { int count = info.invocationCounter(); size = count + 500; inv1 = count; if (RANDOM.nextInt() % 7 == 0) { // Setup inputs to be equals sometimes to avoid uncommon traps inv2 = inv1; } else { inv2 = count * 2; } return new Object[] { inv1, inv2, size }; } public void fail(int returnValue) { throw new RuntimeException("Illegal reassociation: returnValue=" + returnValue + ", inv1=" + inv1 + ", inv2=" + inv2 + ", size=" + size); } public void checkEq(int returnValue) { int invDiff = inv2 - inv1; if ((invDiff < size && returnValue != invDiff) || (invDiff >= size && returnValue != size)) { fail(returnValue); } } public void checkNe(int returnValue) { int invDiff = inv2 - inv1; if ((invDiff != 0 && returnValue != 0) || (invDiff == 0 && returnValue != 1)) { fail(returnValue); } } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_I, "1"}) public int equalsAddInt(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv2 - inv1 == i` if (inv1 + i == inv2) { break; } } return i; } @Check(test = "equalsAddInt") public void checkEqualsAddInt(int returnValue) { checkEq(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_L, "1"}) public int equalsAddLong(long inv1, long inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv2 - inv1 == i` if (inv1 + i == inv2) { break; } } return i; } @Check(test = "equalsAddLong") public void checkEqualsAddLong(int returnValue) { checkEq(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_I, "1"}) public int equalsInvariantSubVariantInt(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv1 - inv2 == i` if (inv2 - i == inv1) { break; } } return i; } @Check(test = "equalsInvariantSubVariantInt") public void checkEqualsInvariantSubVariantInt(int returnValue) { checkEq(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_L, "1"}) public int equalsInvariantSubVariantLong(long inv1, long inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv2 - inv1 == i` if (inv2 - i == inv1) { break; } } return i; } @Check(test = "equalsInvariantSubVariantLong") public void checkEqualsInvariantSubVariantLong(int returnValue) { checkEq(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_I, "1"}) public int equalsVariantSubInvariantInt(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv2 - inv1 == i` if (i - inv2 == -inv1) { break; } } return i; } @Check(test = "equalsVariantSubInvariantInt") public void checkEqualsVariantSubInvariantInt(int returnValue) { checkEq(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_L, "1"}) public int equalsVariantSubInvariantLong(long inv1, long inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv2 - inv1 == i` if (i - inv2 == -inv1) { break; } } return i; } @Check(test = "equalsVariantSubInvariantLong") public void checkEqualsVariantSubInvariantLong(int returnValue) { checkEq(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_I, "1"}) public int notEqualsAddInt(int inv1, int inv2, int size) { int i = 0; for (; i < 500; ++i) { blackhole(); // Reassociate to `inv1 - inv2 != i` if (inv1 + i != inv2) { break; } } return i; } @Check(test = "notEqualsAddInt") public void checkNotEqualsAddInt(int returnValue) { checkNe(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_L, "1"}) public int notEqualsAddLong(long inv1, long inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv1 - inv2 != i` if (inv1 + i != inv2) { break; } } return i; } @Check(test = "notEqualsAddLong") public void checkNotEqualsAddLong(int returnValue) { checkNe(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_I, "1"}) public int notEqualsInvariantSubVariantInt(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv1 - inv2 != i` if (inv1 - i != inv2) { break; } } return i; } @Check(test = "notEqualsInvariantSubVariantInt") public void checkNotEqualsInvariantSubVariantInt(int returnValue) { checkNe(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_L, "1"}) public int notEqualsInvariantSubVariantLong(long inv1, long inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv1 - inv2 != i` if (inv1 - i != inv2) { break; } } return i; } @Check(test = "notEqualsInvariantSubVariantLong") public void checkNotEqualsInvariantSubVariantLong(int returnValue) { checkNe(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_I, "1"}) public int notEqualsVariantSubInvariantInt(int inv1, int inv2, int size) { int i = 0; for (; i < 500; ++i) { blackhole(); // Reassociate to `inv2 - inv1 != i` if (i - inv2 != -inv1) { break; } } return i; } @Check(test = "notEqualsVariantSubInvariantInt") public void checkNotEqualsVariantSubInvariantInt(int returnValue) { checkNe(returnValue); } @Test @Arguments(setup = "setup") @IR(counts = {IRNode.SUB_L, "1"}) public int notEqualsVariantSubInvariantLong(long inv1, long inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); // Reassociate to `inv1 - inv1 != i` if (i - inv2 != -inv1) { break; } } return i; } @Check(test = "notEqualsVariantSubInvariantLong") public void checkNotEqualsVariantSubInvariantLong(int returnValue) { checkNe(returnValue); } @Test @Arguments(setup = "setup") @IR(failOn = {IRNode.SUB_I}) public int ltDontReassociate(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); if (inv1 + i < inv2) { break; } } return i; } @Check(test = "ltDontReassociate") public void checkLtDontReassociate(int returnValue) { int sum = inv1 + returnValue; if ((returnValue < size && sum >= inv2) || (returnValue > size && sum < inv2)) { fail(returnValue); } } @Test @Arguments(setup = "setup") @IR(failOn = {IRNode.SUB_I}) public int leDontReassociate(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); if (inv1 + i <= inv2) { break; } } return i; } @Check(test = "leDontReassociate") public void checkLeDontReassociate(int returnValue) { int sum = inv1 + returnValue; if ((returnValue < size && sum > inv2) || (returnValue > size && sum <= inv2)) { fail(returnValue); } } @Test @Arguments(setup = "setup") @IR(failOn = {IRNode.SUB_I}) public int gtDontReassociate(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); if (inv1 + i > inv2) { break; } } return i; } @Check(test = "gtDontReassociate") public void checkGtDontReassociate(int returnValue) { int sum = inv1 + returnValue; if ((returnValue < size && sum <= inv2) || (returnValue > size && sum > inv2)) { fail(returnValue); } } @Test @Arguments(setup = "setup") @IR(failOn = {IRNode.SUB_I}) public int geDontReassociate(int inv1, int inv2, int size) { int i = 0; for (; i < size; ++i) { blackhole(); if (inv1 + i >= inv2) { break; } } return i; } @Check(test = "geDontReassociate") public void checkGeDontReassociate(int returnValue) { int sum = inv1 + returnValue; if ((returnValue < size && sum < inv2) || (returnValue > size && sum >= inv2)) { fail(returnValue); } } }