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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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*
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* version 2 for more details (a copy is included in the LICENSE file that
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*
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/*
* @test
* @requires ((os.arch == "amd64" | os.arch == "x86_64") & sun.arch.data.model == "64") | os.arch == "aarch64"
* @run testng/othervm -Xmx4G -XX:MaxDirectMemorySize=1M TestSegments
*/
import jdk.incubator.foreign.MemoryAccess;
import jdk.incubator.foreign.MemoryLayout;
import jdk.incubator.foreign.MemoryLayouts;
import jdk.incubator.foreign.MemorySegment;
import jdk.incubator.foreign.ResourceScope;
import org.testng.annotations.DataProvider;
import org.testng.annotations.Test;
import java.lang.invoke.VarHandle;
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.util.List;
import java.util.concurrent.atomic.AtomicReference;
import java.util.function.IntFunction;
import java.util.function.LongFunction;
import java.util.function.Supplier;
import static org.testng.Assert.*;
public class TestSegments {
@Test(dataProvider = "badSizeAndAlignments", expectedExceptions = IllegalArgumentException.class)
public void testBadAllocateAlign(long size, long align) {
MemorySegment.allocateNative(size, align, ResourceScope.newImplicitScope());
}
@Test(dataProvider = "badLayouts", expectedExceptions = UnsupportedOperationException.class)
public void testBadAllocateLayout(MemoryLayout layout) {
MemorySegment.allocateNative(layout, ResourceScope.newImplicitScope());
}
@Test(expectedExceptions = { OutOfMemoryError.class,
IllegalArgumentException.class })
public void testAllocateTooBig() {
MemorySegment.allocateNative(Long.MAX_VALUE, ResourceScope.newImplicitScope());
}
@Test(expectedExceptions = OutOfMemoryError.class)
public void testNativeAllocationTooBig() {
MemorySegment segment = MemorySegment.allocateNative(1024 * 1024 * 8 * 2, ResourceScope.newImplicitScope()); // 2M
}
@Test
public void testNativeSegmentIsZeroed() {
VarHandle byteHandle = MemoryLayout.sequenceLayout(MemoryLayouts.JAVA_BYTE)
.varHandle(byte.class, MemoryLayout.PathElement.sequenceElement());
try (ResourceScope scope = ResourceScope.newConfinedScope()) {
MemorySegment segment = MemorySegment.allocateNative(1000, 1, scope);
for (long i = 0 ; i < segment.byteSize() ; i++) {
assertEquals(0, (byte)byteHandle.get(segment, i));
}
}
}
@Test
public void testSlices() {
VarHandle byteHandle = MemoryLayout.sequenceLayout(MemoryLayouts.JAVA_BYTE)
.varHandle(byte.class, MemoryLayout.PathElement.sequenceElement());
try (ResourceScope scope = ResourceScope.newConfinedScope()) {
MemorySegment segment = MemorySegment.allocateNative(10, 1, scope);
//init
for (byte i = 0 ; i < segment.byteSize() ; i++) {
byteHandle.set(segment, (long)i, i);
}
for (int offset = 0 ; offset < 10 ; offset++) {
MemorySegment slice = segment.asSlice(offset);
for (long i = offset ; i < 10 ; i++) {
assertEquals(
byteHandle.get(segment, i),
byteHandle.get(slice, i - offset)
);
}
}
}
}
@Test(expectedExceptions = IndexOutOfBoundsException.class)
public void testSmallSegmentMax() {
long offset = (long)Integer.MAX_VALUE + (long)Integer.MAX_VALUE + 2L + 6L; // overflows to 6 when casted to int
MemorySegment memorySegment = MemorySegment.allocateNative(10, ResourceScope.newImplicitScope());
MemoryAccess.getIntAtOffset(memorySegment, offset);
}
@Test(expectedExceptions = IndexOutOfBoundsException.class)
public void testSmallSegmentMin() {
long offset = ((long)Integer.MIN_VALUE * 2L) + 6L; // underflows to 6 when casted to int
MemorySegment memorySegment = MemorySegment.allocateNative(10, ResourceScope.newImplicitScope());
MemoryAccess.getIntAtOffset(memorySegment, offset);
}
@Test(dataProvider = "segmentFactories")
public void testAccessModesOfFactories(Supplier<MemorySegment> memorySegmentSupplier) {
MemorySegment segment = memorySegmentSupplier.get();
assertFalse(segment.isReadOnly());
tryClose(segment);
}
static void tryClose(MemorySegment segment) {
if (!segment.scope().isImplicit()) {
segment.scope().close();
}
}
@DataProvider(name = "segmentFactories")
public Object[][] segmentFactories() {
List<Supplier<MemorySegment>> l = List.of(
() -> MemorySegment.ofArray(new byte[] { 0x00, 0x01, 0x02, 0x03 }),
() -> MemorySegment.ofArray(new char[] {'a', 'b', 'c', 'd' }),
() -> MemorySegment.ofArray(new double[] { 1d, 2d, 3d, 4d} ),
() -> MemorySegment.ofArray(new float[] { 1.0f, 2.0f, 3.0f, 4.0f }),
() -> MemorySegment.ofArray(new int[] { 1, 2, 3, 4 }),
() -> MemorySegment.ofArray(new long[] { 1l, 2l, 3l, 4l } ),
() -> MemorySegment.ofArray(new short[] { 1, 2, 3, 4 } ),
() -> MemorySegment.allocateNative(4, ResourceScope.newImplicitScope()),
() -> MemorySegment.allocateNative(4, 8, ResourceScope.newImplicitScope()),
() -> MemorySegment.allocateNative(MemoryLayout.valueLayout(32, ByteOrder.nativeOrder()), ResourceScope.newImplicitScope()),
() -> MemorySegment.allocateNative(4, ResourceScope.newConfinedScope()),
() -> MemorySegment.allocateNative(4, 8, ResourceScope.newConfinedScope()),
() -> MemorySegment.allocateNative(MemoryLayout.valueLayout(32, ByteOrder.nativeOrder()), ResourceScope.newConfinedScope())
);
return l.stream().map(s -> new Object[] { s }).toArray(Object[][]::new);
}
@Test(dataProvider = "segmentFactories")
public void testFill(Supplier<MemorySegment> memorySegmentSupplier) {
VarHandle byteHandle = MemoryLayout.sequenceLayout(MemoryLayouts.JAVA_BYTE)
.varHandle(byte.class, MemoryLayout.PathElement.sequenceElement());
for (byte value : new byte[] {(byte) 0xFF, (byte) 0x00, (byte) 0x45}) {
MemorySegment segment = memorySegmentSupplier.get();
segment.fill(value);
for (long l = 0; l < segment.byteSize(); l++) {
assertEquals((byte) byteHandle.get(segment, l), value);
}
// fill a slice
var sliceSegment = segment.asSlice(1, segment.byteSize() - 2).fill((byte) ~value);
for (long l = 0; l < sliceSegment.byteSize(); l++) {
assertEquals((byte) byteHandle.get(sliceSegment, l), ~value);
}
// assert enclosing slice
assertEquals((byte) byteHandle.get(segment, 0L), value);
for (long l = 1; l < segment.byteSize() - 2; l++) {
assertEquals((byte) byteHandle.get(segment, l), (byte) ~value);
}
assertEquals((byte) byteHandle.get(segment, segment.byteSize() - 1L), value);
tryClose(segment);
}
}
@Test(dataProvider = "segmentFactories")
public void testFillClosed(Supplier<MemorySegment> memorySegmentSupplier) {
MemorySegment segment = memorySegmentSupplier.get();
tryClose(segment);
if (!segment.scope().isAlive()) {
try {
segment.fill((byte) 0xFF);
fail();
} catch (IllegalStateException ex) {
assertTrue(true);
}
}
}
@Test(dataProvider = "segmentFactories")
public void testNativeSegments(Supplier<MemorySegment> memorySegmentSupplier) throws Exception {
MemorySegment segment = memorySegmentSupplier.get();
try {
segment.address().toRawLongValue();
assertTrue(segment.isNative());
assertTrue(segment.address().isNative());
} catch (UnsupportedOperationException exception) {
assertFalse(segment.isNative());
assertFalse(segment.address().isNative());
}
tryClose(segment);
}
@Test(dataProvider = "segmentFactories", expectedExceptions = UnsupportedOperationException.class)
public void testFillIllegalAccessMode(Supplier<MemorySegment> memorySegmentSupplier) {
MemorySegment segment = memorySegmentSupplier.get();
segment.asReadOnly().fill((byte) 0xFF);
tryClose(segment);
}
@Test(dataProvider = "segmentFactories")
public void testFillThread(Supplier<MemorySegment> memorySegmentSupplier) throws Exception {
MemorySegment segment = memorySegmentSupplier.get();
AtomicReference<RuntimeException> exception = new AtomicReference<>();
Runnable action = () -> {
try {
segment.fill((byte) 0xBA);
} catch (RuntimeException e) {
exception.set(e);
}
};
Thread thread = new Thread(action);
thread.start();
thread.join();
if (segment.scope().ownerThread() != null) {
RuntimeException e = exception.get();
if (!(e instanceof IllegalStateException)) {
throw e;
}
} else {
assertNull(exception.get());
}
tryClose(segment);
}
@Test
public void testFillEmpty() {
MemorySegment.ofArray(new byte[] { }).fill((byte) 0xFF);
MemorySegment.ofArray(new byte[2]).asSlice(0, 0).fill((byte) 0xFF);
MemorySegment.ofByteBuffer(ByteBuffer.allocateDirect(0)).fill((byte) 0xFF);
}
@Test(dataProvider = "heapFactories")
public void testBigHeapSegments(IntFunction<MemorySegment> heapSegmentFactory, int factor) {
int bigSize = (Integer.MAX_VALUE / factor) + 1;
MemorySegment segment = heapSegmentFactory.apply(bigSize);
assertTrue(segment.byteSize() > 0);
}
@DataProvider(name = "badSizeAndAlignments")
public Object[][] sizesAndAlignments() {
return new Object[][] {
{ -1, 8 },
{ 1, 15 },
{ 1, -15 }
};
}
@DataProvider(name = "badLayouts")
public Object[][] layouts() {
SizedLayoutFactory[] layoutFactories = SizedLayoutFactory.values();
Object[][] values = new Object[layoutFactories.length * 2][2];
for (int i = 0; i < layoutFactories.length ; i++) {
values[i * 2] = new Object[] { MemoryLayout.structLayout(layoutFactories[i].make(7), MemoryLayout.paddingLayout(9)) }; // good size, bad align
values[(i * 2) + 1] = new Object[] { layoutFactories[i].make(15).withBitAlignment(16) }; // bad size, good align
}
return values;
}
enum SizedLayoutFactory {
VALUE_BE(size -> MemoryLayout.valueLayout(size, ByteOrder.BIG_ENDIAN)),
VALUE_LE(size -> MemoryLayout.valueLayout(size, ByteOrder.LITTLE_ENDIAN)),
PADDING(MemoryLayout::paddingLayout);
private final LongFunction<MemoryLayout> factory;
SizedLayoutFactory(LongFunction<MemoryLayout> factory) {
this.factory = factory;
}
MemoryLayout make(long size) {
return factory.apply(size);
}
}
@DataProvider(name = "heapFactories")
public Object[][] heapFactories() {
return new Object[][] {
{ (IntFunction<MemorySegment>) size -> MemorySegment.ofArray(new char[size]), 2 },
{ (IntFunction<MemorySegment>) size -> MemorySegment.ofArray(new short[size]), 2 },
{ (IntFunction<MemorySegment>) size -> MemorySegment.ofArray(new int[size]), 4 },
{ (IntFunction<MemorySegment>) size -> MemorySegment.ofArray(new float[size]), 4 },
{ (IntFunction<MemorySegment>) size -> MemorySegment.ofArray(new long[size]), 8 },
{ (IntFunction<MemorySegment>) size -> MemorySegment.ofArray(new double[size]), 8 }
};
}
}