private void verifyRTMRetryCount(int retryCount) throws Throwable {
CompilableTest busyLock = new BusyLock();
long expectedAborts = retryCount + 1L;
OutputAnalyzer outputAnalyzer =
RTMTestBase.executeRTMTest(
busyLock,
"-XX:-UseRTMXendForLockBusy",
"-XX:RTMTotalCountIncrRate=1",
CommandLineOptionTest.prepareNumericFlag("RTMRetryCount", retryCount),
"-XX:RTMTotalCountIncrRate=1",
"-XX:+PrintPreciseRTMLockingStatistics",
BusyLock.class.getName(),
Boolean.toString(TestRTMRetryCount.INFLATE_MONITOR),
Integer.toString(TestRTMRetryCount.LOCKING_TIME));
outputAnalyzer.shouldHaveExitValue(0);
List<RTMLockingStatistics> statistics =
RTMLockingStatistics.fromString(
busyLock.getMethodWithLockName(), outputAnalyzer.getStdout());
Asserts.assertEQ(
statistics.size(),
1,
"VM output should contain "
+ "exactly one rtm locking statistics entry for method "
+ busyLock.getMethodWithLockName());
Asserts.assertEQ(
statistics.get(0).getTotalAborts(),
expectedAborts,
String.format("It is expected to get %d aborts", expectedAborts));
}
private static void runSanityTest(Executable aMethod, Integer expectedTableLength) {
HotSpotResolvedJavaMethod method = CTVMUtilities.getResolvedMethod(aMethod);
int tableLength = CompilerToVMHelper.getExceptionTableLength(method);
Asserts.assertEQ(
tableLength, expectedTableLength, aMethod + " incorrect exception table length.");
long tableStart = CompilerToVMHelper.getExceptionTableStart(method);
if (tableLength > 0) {
Asserts.assertNE(tableStart, 0L, aMethod + " exception table starts " + "at 0.");
}
}
private void test() {
System.out.println(getName());
Asserts.assertFalse(WB.isMethodCompiled(METHOD), getName() + " : method unexpectedly compiled");
/* need to call testFrame at least once to be able to compile it, so
calling with materialize=false, because testFrame is not compiled */
testFrame("someString", /* materialize= */ false);
WB.enqueueMethodForCompilation(METHOD, 4);
Asserts.assertTrue(WB.isMethodCompiled(METHOD), getName() + "Method unexpectedly not compiled");
// calling with materialize=true to materialize compiled testFrame
testFrame("someString", /* materialize= */ true);
}
private void testFrame(String str, boolean materialize) {
Helper helper = new Helper(str);
check(materialize);
Asserts.assertTrue(
(helper.string != null) && (this != null) && (helper != null),
getName() + " : some locals are null");
}
private void checkSanity(CompileCodeTestCase testCase) {
System.out.println(testCase);
// to have a clean state
testCase.deoptimize();
Pair<Object, ? extends Throwable> reflectionResult;
Object[] args = Utils.getNullValues(testCase.executable.getParameterTypes());
reflectionResult = testCase.invoke(args);
NMethod nMethod = testCase.compile();
if (nMethod == null) {
throw new Error(testCase + " : nmethod is null");
}
InstalledCode installedCode = testCase.toInstalledCode();
Object result = null;
Throwable expectedException = reflectionResult.second;
boolean gotException = true;
try {
args = addReceiver(testCase, args);
result = CompilerToVMHelper.executeInstalledCode(args, installedCode);
if (testCase.executable instanceof Constructor) {
// <init> doesn't have return value, it changes receiver
result = args[0];
}
gotException = false;
} catch (InvalidInstalledCodeException e) {
throw new AssertionError(testCase + " : unexpected InvalidInstalledCodeException", e);
} catch (Throwable t) {
if (expectedException == null) {
throw new AssertionError(testCase + " : got unexpected execption : " + t.getMessage(), t);
}
if (expectedException.getClass() != t.getClass()) {
System.err.println("exception from CompilerToVM:");
t.printStackTrace();
System.err.println("exception from reflection:");
expectedException.printStackTrace();
throw new AssertionError(
String.format(
"%s : got unexpected different exceptions : %s != %s",
testCase, expectedException.getClass(), t.getClass()));
}
}
Asserts.assertEQ(reflectionResult.first, result, testCase + " : different return value");
if (!gotException) {
Asserts.assertNull(expectedException, testCase + " : expected exception hasn't been thrown");
}
}
private void check(boolean materialize) {
// Materialize virtual objects on last invocation
if (materialize) {
HotSpotStackFrameReference hsFrame =
CompilerToVMHelper.getNextStackFrame(
/* topmost frame */ null,
new ResolvedJavaMethod[] {RESOLVED_METHOD}, /* don't skip any */
0);
Asserts.assertNotNull(hsFrame, getName() + " : got null frame");
Asserts.assertTrue(WB.isMethodCompiled(METHOD), getName() + "Test method should be compiled");
Asserts.assertTrue(
hsFrame.hasVirtualObjects(),
getName() + ": has no virtual object before materialization");
CompilerToVMHelper.materializeVirtualObjects(hsFrame, INVALIDATE);
Asserts.assertFalse(
hsFrame.hasVirtualObjects(), getName() + " : has virtual object after materialization");
Asserts.assertEQ(
WB.isMethodCompiled(METHOD), !INVALIDATE, getName() + " : unexpected compiled status");
}
}
private void selfTest() {
boolean isHumongous = WHITE_BOX.getObjectSize(allocation) > HALF_G1_REGION_SIZE;
boolean shouldBeHumongous = WHITE_BOX.g1IsHumongous(allocation);
// Sanity check
Asserts.assertEquals(
isHumongous,
shouldBeHumongous,
String.format(
"Test Bug: Object of size %d is expected to be %shumongous but it is not",
WHITE_BOX.getObjectSize(allocation), (shouldBeHumongous ? "" : "non-")));
}
public static void main(String[] args) throws Exception {
TestObjectClone[] params1 = {
a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a,
a, a, b, c, d
};
for (int i = 0; i < 15000; i++) {
f(params1[i % params1.length]);
}
Asserts.assertTrue(f(a) != a);
Asserts.assertTrue(f(b) == b);
Asserts.assertTrue(f(c) == c);
Asserts.assertTrue(f(d) == d);
try {
f(null);
throw new AssertionError("");
} catch (NullPointerException e) {
/* expected */
}
System.out.println("TEST PASSED");
}
private void check(CompileCodeTestCase testCase) {
System.out.println(testCase);
HotSpotResolvedJavaMethod javaMethod = CTVMUtilities.getResolvedMethod(testCase.executable);
HotSpotCompilationRequest compRequest =
new HotSpotCompilationRequest(javaMethod, testCase.bci, /* jvmciEnv = */ 0L);
String name = testCase.executable.getName();
CompilationResult compResult = new CompilationResult(name);
// to pass sanity check of default -1
compResult.setTotalFrameSize(0);
InstalledCode installedCode =
CACHE_PROVIDER.installCode(
compRequest,
compResult,
new InstalledCode(name),
/* speculationLog = */ null,
/* isDefault = */ false);
Asserts.assertTrue(
installedCode.isValid(), testCase + " : code is invalid even before invalidation");
NMethod beforeInvalidation = testCase.toNMethod();
if (beforeInvalidation != null) {
throw new Error("TESTBUG : " + testCase + " : nmethod isn't found");
}
// run twice to verify how it works if method is already invalidated
for (int i = 0; i < 2; ++i) {
CompilerToVMHelper.invalidateInstalledCode(installedCode);
Asserts.assertFalse(
installedCode.isValid(), testCase + " : code is valid after invalidation, i = " + i);
NMethod afterInvalidation = testCase.toNMethod();
if (afterInvalidation != null) {
System.err.println("before: " + beforeInvalidation);
System.err.println("after: " + afterInvalidation);
throw new AssertionError(testCase + " : method hasn't been invalidated, i = " + i);
}
}
}
private static ProcessBuilder prepareTestCase(int testCase) throws Exception {
ProcessBuilder pb;
Asserts.assertTrue(0 < testCase && testCase < 6, "testCase should be from 1 to 5");
addVMParam("-showversion");
addVMOptionsToCheck("MinHeapFreeRatio", "SurvivorRatio", "NewRatio");
if (testCase < 5) {
addVMParam("-XX:Flags=flags_file", "-XX:-PrintVMOptions");
addProperty("shared.property", "command_line_before");
addProperty("clb", "unique_command_line_before");
addVMParam("-XX:MinHeapFreeRatio=7");
}
if (testCase < 4) {
addVMOptionsFile(getAbsolutePathFromSource(VM_OPTION_FILE_1));
}
if (testCase < 3) {
addVMParam("-XX:MinHeapFreeRatio=9", "-XX:-PrintVMOptions");
addProperty("shared.property", "command_line_after");
addProperty("cla", "unique_command_line_after");
}
/* Create ProcessBuilder after all setup is done to update environment variables */
pb = createProcessBuilder();
if (testCase < 2) {
updateEnvironment(
pb,
JAVA_OPTIONS,
"-Dshared.property=somevalue -Djo=unique_java_options "
+ "-XX:MinHeapFreeRatio=18 -Dshared.property=java_options -XX:MinHeapFreeRatio=11 -XX:+PrintVMOptions");
}
if (testCase < 6) {
updateEnvironment(
pb,
JAVA_TOOL_OPTIONS,
"-Dshared.property=qwerty -Djto=unique_java_tool_options "
+ "-XX:MinHeapFreeRatio=15 -Dshared.property=java_tool_options -XX:MinHeapFreeRatio=6 -XX:+PrintVMOptions");
}
return pb;
}
private void runTest(TestCase tcase) {
System.out.println(tcase);
HotSpotResolvedObjectType resolvedIface =
CompilerToVMHelper.lookupType(
Utils.toJVMTypeSignature(tcase.anInterface), getClass(), /* resolve = */ true);
HotSpotResolvedObjectType resolvedImplementer =
CompilerToVMHelper.getImplementor(resolvedIface);
HotSpotResolvedObjectType resolvedExpected = null;
if (tcase.expectedImplementer != null) {
resolvedExpected =
CompilerToVMHelper.lookupType(
Utils.toJVMTypeSignature(tcase.expectedImplementer),
getClass(),
/* resolve = */ true);
}
Asserts.assertEQ(
resolvedImplementer,
resolvedExpected,
"Unexpected implementer for " + tcase.anInterface.getName());
}
public static void main(String[] args) {
if (args.length != 1) {
throw new Error("Expected memory counter name wasn't provided as command line argument");
}
MemoryCounter memoryCounter = MemoryCounter.valueOf(args[0].toUpperCase());
int byteArrayMemoryOverhead = Helpers.detectByteArrayAllocationOverhead();
// Largest non-humongous byte[]
int maxByteArrayNonHumongousSize = HALF_G1_REGION_SIZE - byteArrayMemoryOverhead;
// Maximum byte[] that takes one region
int maxByteArrayOneRegionSize = G1_REGION_SIZE - byteArrayMemoryOverhead;
List<Integer> allocationSizes =
Arrays.asList(
(int) maxByteArrayNonHumongousSize + 1,
(int) (0.8f * maxByteArrayOneRegionSize),
(int) (maxByteArrayOneRegionSize),
(int) (1.2f * maxByteArrayOneRegionSize),
(int) (1.5f * maxByteArrayOneRegionSize),
(int) (1.7f * maxByteArrayOneRegionSize),
(int) (2.0f * maxByteArrayOneRegionSize),
(int) (2.5f * maxByteArrayOneRegionSize));
List<Allocation> allocations = new ArrayList<>();
List<GarbageCollectorMXBean> gcBeans = ManagementFactory.getGarbageCollectorMXBeans();
long gcCountBefore =
gcBeans.stream().mapToLong(GarbageCollectorMXBean::getCollectionCount).sum();
System.out.println("Starting allocations - no GC should happen until we finish them");
for (int allocationSize : allocationSizes) {
long usedMemoryBefore = memoryCounter.getUsedMemory();
long expectedAllocationSize =
(long) Math.ceil((double) allocationSize / G1_REGION_SIZE) * G1_REGION_SIZE;
allocations.add(new Allocation(allocationSize, expectedAllocationSize));
long usedMemoryAfter = memoryCounter.getUsedMemory();
System.out.format(
"Expected allocation size: %d\nUsed memory before allocation: %d\n"
+ "Used memory after allocation: %d\n",
expectedAllocationSize, usedMemoryBefore, usedMemoryAfter);
long gcCountNow =
gcBeans.stream().mapToLong(GarbageCollectorMXBean::getCollectionCount).sum();
if (gcCountNow == gcCountBefore) {
// We should allocate at least allocation.expectedSize
Asserts.assertGreaterThanOrEqual(
usedMemoryAfter - usedMemoryBefore,
expectedAllocationSize,
"Counter of type "
+ memoryCounter.getClass().getSimpleName()
+ " returned wrong allocation size");
} else {
System.out.println("GC happened during allocation so the check is skipped");
gcCountBefore = gcCountNow;
}
}
System.out.println("Finished allocations - no GC should have happened before this line");
allocations
.stream()
.forEach(
allocation -> {
long usedMemoryBefore = memoryCounter.getUsedMemory();
allocation.forgetAllocation();
WHITE_BOX.fullGC();
long usedMemoryAfter = memoryCounter.getUsedMemory();
// We should free at least allocation.expectedSize * ALLOCATION_SIZE_TOLERANCE_FACTOR
Asserts.assertGreaterThanOrEqual(
usedMemoryBefore - usedMemoryAfter,
(long) (allocation.expectedSize * ALLOCATION_SIZE_TOLERANCE_FACTOR),
"Counter of type "
+ memoryCounter.getClass().getSimpleName()
+ " returned wrong allocation size");
});
}
