/* * Copyright (c) 2019, 2020, 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. */ /* * @test * @modules java.base/sun.nio.ch * jdk.incubator.foreign/jdk.internal.foreign * @run testng/othervm -Dforeign.restricted=permit TestByteBuffer */ import jdk.incubator.foreign.MappedMemorySegments; import jdk.incubator.foreign.MemoryAccess; import jdk.incubator.foreign.MemoryLayouts; import jdk.incubator.foreign.MemoryLayout; import jdk.incubator.foreign.MemoryAddress; import jdk.incubator.foreign.MemorySegment; import jdk.incubator.foreign.MemoryLayout.PathElement; import jdk.incubator.foreign.SequenceLayout; import java.io.File; import java.io.IOException; import java.lang.invoke.MethodHandle; import java.lang.invoke.MethodHandles; import java.lang.invoke.VarHandle; import java.lang.ref.WeakReference; import java.lang.reflect.InvocationTargetException; import java.lang.reflect.Method; import java.lang.reflect.Modifier; import java.nio.Buffer; import java.nio.ByteBuffer; import java.nio.ByteOrder; import java.nio.CharBuffer; import java.nio.DoubleBuffer; import java.nio.FloatBuffer; import java.nio.IntBuffer; import java.nio.LongBuffer; import java.nio.MappedByteBuffer; import java.nio.ShortBuffer; import java.nio.channels.FileChannel; import java.nio.file.Files; import java.nio.file.Path; import java.nio.file.StandardOpenOption; import java.util.ArrayList; import java.util.HashMap; import java.util.List; import java.util.Map; import java.util.function.BiConsumer; import java.util.function.BiFunction; import java.util.function.Consumer; import java.util.function.Function; import java.util.function.Predicate; import java.util.stream.Stream; import jdk.internal.foreign.HeapMemorySegmentImpl; import jdk.internal.foreign.MappedMemorySegmentImpl; import jdk.internal.foreign.NativeMemorySegmentImpl; import org.testng.SkipException; import org.testng.annotations.*; import sun.nio.ch.DirectBuffer; import static jdk.incubator.foreign.MemorySegment.*; import static org.testng.Assert.*; public class TestByteBuffer { static Path tempPath; static { try { File file = File.createTempFile("buffer", "txt"); file.deleteOnExit(); tempPath = file.toPath(); Files.write(file.toPath(), new byte[256], StandardOpenOption.WRITE); } catch (IOException ex) { throw new ExceptionInInitializerError(ex); } } static SequenceLayout tuples = MemoryLayout.ofSequence(500, MemoryLayout.ofStruct( MemoryLayouts.BITS_32_BE.withName("index"), MemoryLayouts.BITS_32_BE.withName("value") )); static SequenceLayout bytes = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_8_BE ); static SequenceLayout chars = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_16_BE ); static SequenceLayout shorts = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_16_BE ); static SequenceLayout ints = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_32_BE ); static SequenceLayout floats = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_32_BE ); static SequenceLayout longs = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_64_BE ); static SequenceLayout doubles = MemoryLayout.ofSequence(100, MemoryLayouts.BITS_64_BE ); static VarHandle indexHandle = tuples.varHandle(int.class, PathElement.sequenceElement(), PathElement.groupElement("index")); static VarHandle valueHandle = tuples.varHandle(float.class, PathElement.sequenceElement(), PathElement.groupElement("value")); static void initTuples(MemorySegment base, long count) { for (long i = 0; i < count ; i++) { indexHandle.set(base, i, (int)i); valueHandle.set(base, i, (float)(i / 500f)); } } static void checkTuples(MemorySegment base, ByteBuffer bb, long count) { for (long i = 0; i < count ; i++) { int index; float value; assertEquals(index = bb.getInt(), (int)indexHandle.get(base, i)); assertEquals(value = bb.getFloat(), (float)valueHandle.get(base, i)); assertEquals(value, index / 500f); } } static void initBytes(MemorySegment base, SequenceLayout seq, BiConsumer handleSetter) { for (long i = 0; i < seq.elementCount().getAsLong() ; i++) { handleSetter.accept(base, i); } } static void checkBytes(MemorySegment base, SequenceLayout layout, Function bufFactory, BiFunction handleExtractor, Function bufferExtractor) { long nelems = layout.elementCount().getAsLong(); long elemSize = layout.elementLayout().byteSize(); for (long i = 0 ; i < nelems ; i++) { long limit = nelems - i; MemorySegment resizedSegment = base.asSlice(i * elemSize, limit * elemSize); ByteBuffer bb = resizedSegment.asByteBuffer(); Z z = bufFactory.apply(bb); for (long j = i ; j < limit ; j++) { Object handleValue = handleExtractor.apply(resizedSegment, j - i); Object bufferValue = bufferExtractor.apply(z); if (handleValue instanceof Number) { assertEquals(((Number)handleValue).longValue(), j); assertEquals(((Number)bufferValue).longValue(), j); } else { assertEquals((long)(char)handleValue, j); assertEquals((long)(char)bufferValue, j); } } } } @Test public void testOffheap() { try (MemorySegment segment = MemorySegment.allocateNative(tuples)) { initTuples(segment, tuples.elementCount().getAsLong()); ByteBuffer bb = segment.asByteBuffer(); checkTuples(segment, bb, tuples.elementCount().getAsLong()); } } @Test public void testHeap() { byte[] arr = new byte[(int) tuples.byteSize()]; MemorySegment region = MemorySegment.ofArray(arr); initTuples(region, tuples.elementCount().getAsLong()); ByteBuffer bb = region.asByteBuffer(); checkTuples(region, bb, tuples.elementCount().getAsLong()); } @Test public void testChannel() throws Throwable { File f = new File("test.out"); assertTrue(f.createNewFile()); f.deleteOnExit(); //write to channel try (FileChannel channel = FileChannel.open(f.toPath(), StandardOpenOption.READ, StandardOpenOption.WRITE)) { withMappedBuffer(channel, FileChannel.MapMode.READ_WRITE, 0, tuples.byteSize(), mbb -> { MemorySegment segment = MemorySegment.ofByteBuffer(mbb); initTuples(segment, tuples.elementCount().getAsLong()); mbb.force(); }); } //read from channel try (FileChannel channel = FileChannel.open(f.toPath(), StandardOpenOption.READ)) { withMappedBuffer(channel, FileChannel.MapMode.READ_ONLY, 0, tuples.byteSize(), mbb -> { MemorySegment segment = MemorySegment.ofByteBuffer(mbb); checkTuples(segment, mbb, tuples.elementCount().getAsLong()); }); } } @Test public void testDefaultAccessModesMappedSegment() throws Throwable { try (MemorySegment segment = MemorySegment.mapFile(tempPath, 0L, 8, FileChannel.MapMode.READ_WRITE)) { assertTrue(segment.hasAccessModes(ALL_ACCESS)); assertEquals(segment.accessModes(), ALL_ACCESS); } try (MemorySegment segment = MemorySegment.mapFile(tempPath, 0L, 8, FileChannel.MapMode.READ_ONLY)) { assertTrue(segment.hasAccessModes(ALL_ACCESS & ~WRITE)); assertEquals(segment.accessModes(), ALL_ACCESS & ~WRITE); } } @Test public void testMappedSegment() throws Throwable { File f = new File("test2.out"); f.createNewFile(); f.deleteOnExit(); //write to channel try (MemorySegment segment = MemorySegment.mapFile(f.toPath(), 0L, tuples.byteSize(), FileChannel.MapMode.READ_WRITE)) { initTuples(segment, tuples.elementCount().getAsLong()); MappedMemorySegments.force(segment); } //read from channel try (MemorySegment segment = MemorySegment.mapFile(f.toPath(), 0L, tuples.byteSize(), FileChannel.MapMode.READ_ONLY)) { checkTuples(segment, segment.asByteBuffer(), tuples.elementCount().getAsLong()); } } @Test(dataProvider = "mappedOps", expectedExceptions = IllegalStateException.class) public void testMappedSegmentOperations(MappedSegmentOp mappedBufferOp) throws Throwable { File f = new File("test3.out"); f.createNewFile(); f.deleteOnExit(); MemorySegment segment = MemorySegment.mapFile(f.toPath(), 0L, 8, FileChannel.MapMode.READ_WRITE); assertTrue(segment.isMapped()); segment.close(); mappedBufferOp.apply(segment); } @Test public void testMappedSegmentOffset() throws Throwable { File f = new File("test3.out"); f.createNewFile(); f.deleteOnExit(); MemoryLayout tupleLayout = tuples.elementLayout(); // write one at a time for (int i = 0 ; i < tuples.byteSize() ; i += tupleLayout.byteSize()) { //write to channel try (MemorySegment segment = MemorySegment.mapFile(f.toPath(), i, tuples.byteSize(), FileChannel.MapMode.READ_WRITE)) { initTuples(segment, 1); MappedMemorySegments.force(segment); } } // check one at a time for (int i = 0 ; i < tuples.byteSize() ; i += tupleLayout.byteSize()) { //read from channel try (MemorySegment segment = MemorySegment.mapFile(f.toPath(), 0L, tuples.byteSize(), FileChannel.MapMode.READ_ONLY)) { checkTuples(segment, segment.asByteBuffer(), 1); } } } static void withMappedBuffer(FileChannel channel, FileChannel.MapMode mode, long pos, long size, Consumer action) throws Throwable { MappedByteBuffer mbb = channel.map(mode, pos, size); var ref = new WeakReference<>(mbb); action.accept(mbb); mbb = null; //wait for it to be GCed System.gc(); while (ref.get() != null) { Thread.sleep(20); } } static void checkByteArrayAlignment(MemoryLayout layout) { if (layout.bitSize() > 32 && System.getProperty("sun.arch.data.model").equals("32")) { throw new SkipException("avoid unaligned access on 32-bit system"); } } @Test(dataProvider = "bufferOps") public void testScopedBuffer(Function bufferFactory, @NoInjection Method method, Object[] args) { Buffer bb; try (MemorySegment segment = MemorySegment.allocateNative(bytes)) { bb = bufferFactory.apply(segment.asByteBuffer()); } //outside of scope!! try { method.invoke(bb, args); fail("Exception expected"); } catch (InvocationTargetException ex) { Throwable cause = ex.getCause(); if (cause instanceof IllegalStateException) { //all get/set buffer operation should fail because of the scope check assertTrue(ex.getCause().getMessage().contains("already closed")); } else { //all other exceptions were unexpected - fail fail("Unexpected exception", cause); } } catch (Throwable ex) { //unexpected exception - fail fail("Unexpected exception", ex); } } @Test(dataProvider = "bufferHandleOps") public void testScopedBufferAndVarHandle(VarHandle bufferHandle) { ByteBuffer bb; try (MemorySegment segment = MemorySegment.allocateNative(bytes)) { bb = segment.asByteBuffer(); for (Map.Entry e : varHandleMembers(bb, bufferHandle).entrySet()) { MethodHandle handle = e.getKey().bindTo(bufferHandle) .asSpreader(Object[].class, e.getValue().length); try { handle.invoke(e.getValue()); } catch (UnsupportedOperationException ex) { //skip } catch (Throwable ex) { //should not fail - segment is alive! fail(); } } } for (Map.Entry e : varHandleMembers(bb, bufferHandle).entrySet()) { try { MethodHandle handle = e.getKey().bindTo(bufferHandle) .asSpreader(Object[].class, e.getValue().length); handle.invoke(e.getValue()); fail(); } catch (IllegalStateException ex) { assertTrue(ex.getMessage().contains("already closed")); } catch (UnsupportedOperationException ex) { //skip } catch (Throwable ex) { fail(); } } } @Test(dataProvider = "bufferOps") public void testDirectBuffer(Function bufferFactory, @NoInjection Method method, Object[] args) { try (MemorySegment segment = MemorySegment.allocateNative(bytes)) { Buffer bb = bufferFactory.apply(segment.asByteBuffer()); assertTrue(bb.isDirect()); DirectBuffer directBuffer = ((DirectBuffer)bb); assertEquals(directBuffer.address(), segment.address().toRawLongValue()); assertTrue((directBuffer.attachment() == null) == (bb instanceof ByteBuffer)); assertTrue(directBuffer.cleaner() == null); } } @Test(dataProvider="resizeOps") public void testResizeOffheap(Consumer checker, Consumer initializer, SequenceLayout seq) { try (MemorySegment segment = MemorySegment.allocateNative(seq)) { initializer.accept(segment); checker.accept(segment); } } @Test(dataProvider="resizeOps") public void testResizeHeap(Consumer checker, Consumer initializer, SequenceLayout seq) { checkByteArrayAlignment(seq.elementLayout()); int capacity = (int)seq.byteSize(); MemorySegment base = MemorySegment.ofArray(new byte[capacity]); initializer.accept(base); checker.accept(base); } @Test(dataProvider="resizeOps") public void testResizeBuffer(Consumer checker, Consumer initializer, SequenceLayout seq) { checkByteArrayAlignment(seq.elementLayout()); int capacity = (int)seq.byteSize(); MemorySegment base = MemorySegment.ofByteBuffer(ByteBuffer.wrap(new byte[capacity])); initializer.accept(base); checker.accept(base); } @Test(dataProvider="resizeOps") public void testResizeRoundtripHeap(Consumer checker, Consumer initializer, SequenceLayout seq) { checkByteArrayAlignment(seq.elementLayout()); int capacity = (int)seq.byteSize(); byte[] arr = new byte[capacity]; MemorySegment segment = MemorySegment.ofArray(arr); initializer.accept(segment); MemorySegment second = MemorySegment.ofByteBuffer(segment.asByteBuffer()); checker.accept(second); } @Test(dataProvider="resizeOps") public void testResizeRoundtripNative(Consumer checker, Consumer initializer, SequenceLayout seq) { try (MemorySegment segment = MemorySegment.allocateNative(seq)) { initializer.accept(segment); MemorySegment second = MemorySegment.ofByteBuffer(segment.asByteBuffer()); checker.accept(second); } } @Test(expectedExceptions = IllegalStateException.class) public void testBufferOnClosedScope() { MemorySegment leaked; try (MemorySegment segment = MemorySegment.allocateNative(bytes)) { leaked = segment; } ByteBuffer byteBuffer = leaked.asByteBuffer(); // ok byteBuffer.get(); // should throw } @Test(expectedExceptions = UnsupportedOperationException.class) public void testTooBigForByteBuffer() { try (MemorySegment segment = MemoryAddress.NULL.asSegmentRestricted(Integer.MAX_VALUE + 10L)) { segment.asByteBuffer(); } } @Test(expectedExceptions = IllegalArgumentException.class) public void testBadMapNegativeSize() throws IOException { File f = new File("testNeg1.out"); f.createNewFile(); f.deleteOnExit(); MemorySegment.mapFile(f.toPath(), 0L, -1, FileChannel.MapMode.READ_WRITE); } @Test(expectedExceptions = IllegalArgumentException.class) public void testBadMapNegativeOffset() throws IOException { File f = new File("testNeg2.out"); f.createNewFile(); f.deleteOnExit(); MemorySegment.mapFile(f.toPath(), -1, 1, FileChannel.MapMode.READ_WRITE); } public void testMapZeroSize() throws IOException { File f = new File("testPos1.out"); f.createNewFile(); f.deleteOnExit(); try (MemorySegment segment = MemorySegment.mapFile(f.toPath(), 0L, 0L, FileChannel.MapMode.READ_WRITE)) { assertEquals(segment.byteSize(), 0); } } @Test(dataProvider="resizeOps") public void testCopyHeapToNative(Consumer checker, Consumer initializer, SequenceLayout seq) { checkByteArrayAlignment(seq.elementLayout()); int bytes = (int)seq.byteSize(); try (MemorySegment nativeArray = MemorySegment.allocateNative(bytes); MemorySegment heapArray = MemorySegment.ofArray(new byte[bytes])) { initializer.accept(heapArray); nativeArray.copyFrom(heapArray); checker.accept(nativeArray); } } @Test(dataProvider="resizeOps") public void testCopyNativeToHeap(Consumer checker, Consumer initializer, SequenceLayout seq) { checkByteArrayAlignment(seq.elementLayout()); int bytes = (int)seq.byteSize(); try (MemorySegment nativeArray = MemorySegment.allocateNative(seq); MemorySegment heapArray = MemorySegment.ofArray(new byte[bytes])) { initializer.accept(nativeArray); heapArray.copyFrom(nativeArray); checker.accept(heapArray); } } @Test public void testDefaultAccessModesOfBuffer() { ByteBuffer rwBuffer = ByteBuffer.wrap(new byte[4]); try (MemorySegment segment = MemorySegment.ofByteBuffer(rwBuffer)) { assertTrue(segment.hasAccessModes(ALL_ACCESS)); assertEquals(segment.accessModes(), ALL_ACCESS); } ByteBuffer roBuffer = rwBuffer.asReadOnlyBuffer(); try (MemorySegment segment = MemorySegment.ofByteBuffer(roBuffer)) { assertTrue(segment.hasAccessModes(ALL_ACCESS & ~WRITE)); assertEquals(segment.accessModes(), ALL_ACCESS & ~WRITE); } } @Test(dataProvider="bufferSources") public void testBufferToSegment(ByteBuffer bb, Predicate segmentChecker) { MemorySegment segment = MemorySegment.ofByteBuffer(bb); assertEquals(segment.hasAccessModes(MemorySegment.WRITE), !bb.isReadOnly()); assertTrue(segmentChecker.test(segment)); assertTrue(segmentChecker.test(segment.asSlice(0, segment.byteSize()))); assertTrue(segmentChecker.test(segment.withAccessModes(MemorySegment.READ))); assertEquals(bb.capacity(), segment.byteSize()); //another round trip segment = MemorySegment.ofByteBuffer(segment.asByteBuffer()); assertEquals(segment.hasAccessModes(MemorySegment.WRITE), !bb.isReadOnly()); assertTrue(segmentChecker.test(segment)); assertTrue(segmentChecker.test(segment.asSlice(0, segment.byteSize()))); assertTrue(segmentChecker.test(segment.withAccessModes(MemorySegment.READ))); assertEquals(bb.capacity(), segment.byteSize()); } @Test(dataProvider="bufferSources") public void bufferProperties(ByteBuffer bb, Predicate _unused) { try (MemorySegment segment = MemorySegment.ofByteBuffer(bb)) { ByteBuffer buffer = segment.asByteBuffer(); assertEquals(buffer.position(), 0); assertEquals(buffer.capacity(), segment.byteSize()); assertEquals(buffer.limit(), segment.byteSize()); } } @Test public void testRoundTripAccess() { try(MemorySegment ms = MemorySegment.allocateNative(4)) { MemorySegment msNoAccess = ms.withAccessModes(MemorySegment.READ); // READ is required to make BB MemorySegment msRoundTrip = MemorySegment.ofByteBuffer(msNoAccess.asByteBuffer()); assertEquals(msNoAccess.accessModes(), msRoundTrip.accessModes()); } } @Test(expectedExceptions = IllegalStateException.class) public void testDeadAccessOnClosedBufferSegment() { MemorySegment s1 = MemorySegment.allocateNative(MemoryLayouts.JAVA_INT); MemorySegment s2 = MemorySegment.ofByteBuffer(s1.asByteBuffer()); s1.close(); // memory freed MemoryAccess.setInt(s2, 10); // Dead access! } @Test(expectedExceptions = UnsupportedOperationException.class) public void testIOOnSharedSegmentBuffer() throws IOException { File tmp = File.createTempFile("tmp", "txt"); tmp.deleteOnExit(); try (FileChannel channel = FileChannel.open(tmp.toPath(), StandardOpenOption.WRITE)) { MemorySegment segment = MemorySegment.allocateNative(10).share(); for (int i = 0; i < 10; i++) { MemoryAccess.setByteAtOffset(segment, i, (byte) i); } ByteBuffer bb = segment.asByteBuffer(); segment.close(); channel.write(bb); } } @Test(expectedExceptions = IllegalStateException.class) public void testIOOnClosedConfinedSegmentBuffer() throws IOException { File tmp = File.createTempFile("tmp", "txt"); tmp.deleteOnExit(); try (FileChannel channel = FileChannel.open(tmp.toPath(), StandardOpenOption.WRITE)) { MemorySegment segment = MemorySegment.allocateNative(10); for (int i = 0; i < 10; i++) { MemoryAccess.setByteAtOffset(segment, i, (byte) i); } ByteBuffer bb = segment.asByteBuffer(); segment.close(); channel.write(bb); } } public void testIOOnClosedConfinedSegment() throws IOException { File tmp = File.createTempFile("tmp", "txt"); tmp.deleteOnExit(); try (FileChannel channel = FileChannel.open(tmp.toPath(), StandardOpenOption.WRITE)) { MemorySegment segment = MemorySegment.allocateNative(10); for (int i = 0; i < 10; i++) { MemoryAccess.setByteAtOffset(segment, i, (byte) i); } ByteBuffer bb = segment.asByteBuffer(); channel.write(bb); } } @DataProvider(name = "bufferOps") public static Object[][] bufferOps() throws Throwable { List args = new ArrayList<>(); bufferOpsArgs(args, bb -> bb, ByteBuffer.class); bufferOpsArgs(args, ByteBuffer::asCharBuffer, CharBuffer.class); bufferOpsArgs(args, ByteBuffer::asShortBuffer, ShortBuffer.class); bufferOpsArgs(args, ByteBuffer::asIntBuffer, IntBuffer.class); bufferOpsArgs(args, ByteBuffer::asFloatBuffer, FloatBuffer.class); bufferOpsArgs(args, ByteBuffer::asLongBuffer, LongBuffer.class); bufferOpsArgs(args, ByteBuffer::asDoubleBuffer, DoubleBuffer.class); return args.toArray(Object[][]::new); } static void bufferOpsArgs(List argsList, Function factory, Class bufferClass) { for (Method m : bufferClass.getMethods()) { //skip statics and method declared in j.l.Object if (m.getDeclaringClass().equals(Object.class) || ((m.getModifiers() & Modifier.STATIC) != 0) || (!m.getName().contains("get") && !m.getName().contains("put")) || m.getParameterCount() > 2) continue; Object[] args = Stream.of(m.getParameterTypes()) .map(TestByteBuffer::defaultValue) .toArray(); argsList.add(new Object[] { factory, m, args }); } } @DataProvider(name = "bufferHandleOps") public static Object[][] bufferHandleOps() throws Throwable { return new Object[][]{ { MethodHandles.byteBufferViewVarHandle(char[].class, ByteOrder.nativeOrder()) }, { MethodHandles.byteBufferViewVarHandle(short[].class, ByteOrder.nativeOrder()) }, { MethodHandles.byteBufferViewVarHandle(int[].class, ByteOrder.nativeOrder()) }, { MethodHandles.byteBufferViewVarHandle(long[].class, ByteOrder.nativeOrder()) }, { MethodHandles.byteBufferViewVarHandle(float[].class, ByteOrder.nativeOrder()) }, { MethodHandles.byteBufferViewVarHandle(double[].class, ByteOrder.nativeOrder()) } }; } static Map varHandleMembers(ByteBuffer bb, VarHandle handle) { Map members = new HashMap<>(); for (VarHandle.AccessMode mode : VarHandle.AccessMode.values()) { Class[] params = handle.accessModeType(mode).parameterArray(); Object[] args = Stream.concat(Stream.of(bb), Stream.of(params).skip(1) .map(TestByteBuffer::defaultValue)) .toArray(); try { members.put(MethodHandles.varHandleInvoker(mode, handle.accessModeType(mode)), args); } catch (Throwable ex) { throw new AssertionError(ex); } } return members; } @DataProvider(name = "resizeOps") public Object[][] resizeOps() { Consumer byteInitializer = (base) -> initBytes(base, bytes, (addr, pos) -> MemoryAccess.setByteAtOffset(addr, pos, (byte)(long)pos)); Consumer charInitializer = (base) -> initBytes(base, chars, (addr, pos) -> MemoryAccess.setCharAtIndex(addr, pos, ByteOrder.BIG_ENDIAN, (char)(long)pos)); Consumer shortInitializer = (base) -> initBytes(base, shorts, (addr, pos) -> MemoryAccess.setShortAtIndex(addr, pos, ByteOrder.BIG_ENDIAN, (short)(long)pos)); Consumer intInitializer = (base) -> initBytes(base, ints, (addr, pos) -> MemoryAccess.setIntAtIndex(addr, pos, ByteOrder.BIG_ENDIAN, (int)(long)pos)); Consumer floatInitializer = (base) -> initBytes(base, floats, (addr, pos) -> MemoryAccess.setFloatAtIndex(addr, pos, ByteOrder.BIG_ENDIAN, (float)(long)pos)); Consumer longInitializer = (base) -> initBytes(base, longs, (addr, pos) -> MemoryAccess.setLongAtIndex(addr, pos, ByteOrder.BIG_ENDIAN, (long)pos)); Consumer doubleInitializer = (base) -> initBytes(base, doubles, (addr, pos) -> MemoryAccess.setDoubleAtIndex(addr, pos, ByteOrder.BIG_ENDIAN, (double)(long)pos)); Consumer byteChecker = (base) -> checkBytes(base, bytes, Function.identity(), (addr, pos) -> MemoryAccess.getByteAtOffset(addr, pos), ByteBuffer::get); Consumer charChecker = (base) -> checkBytes(base, chars, ByteBuffer::asCharBuffer, (addr, pos) -> MemoryAccess.getCharAtIndex(addr, pos, ByteOrder.BIG_ENDIAN), CharBuffer::get); Consumer shortChecker = (base) -> checkBytes(base, shorts, ByteBuffer::asShortBuffer, (addr, pos) -> MemoryAccess.getShortAtIndex(addr, pos, ByteOrder.BIG_ENDIAN), ShortBuffer::get); Consumer intChecker = (base) -> checkBytes(base, ints, ByteBuffer::asIntBuffer, (addr, pos) -> MemoryAccess.getIntAtIndex(addr, pos, ByteOrder.BIG_ENDIAN), IntBuffer::get); Consumer floatChecker = (base) -> checkBytes(base, floats, ByteBuffer::asFloatBuffer, (addr, pos) -> MemoryAccess.getFloatAtIndex(addr, pos, ByteOrder.BIG_ENDIAN), FloatBuffer::get); Consumer longChecker = (base) -> checkBytes(base, longs, ByteBuffer::asLongBuffer, (addr, pos) -> MemoryAccess.getLongAtIndex(addr, pos, ByteOrder.BIG_ENDIAN), LongBuffer::get); Consumer doubleChecker = (base) -> checkBytes(base, doubles, ByteBuffer::asDoubleBuffer, (addr, pos) -> MemoryAccess.getDoubleAtIndex(addr, pos, ByteOrder.BIG_ENDIAN), DoubleBuffer::get); return new Object[][]{ {byteChecker, byteInitializer, bytes}, {charChecker, charInitializer, chars}, {shortChecker, shortInitializer, shorts}, {intChecker, intInitializer, ints}, {floatChecker, floatInitializer, floats}, {longChecker, longInitializer, longs}, {doubleChecker, doubleInitializer, doubles} }; } static Object defaultValue(Class c) { if (c.isPrimitive()) { if (c == char.class) { return (char)0; } else if (c == boolean.class) { return false; } else if (c == byte.class) { return (byte)0; } else if (c == short.class) { return (short)0; } else if (c == int.class) { return 0; } else if (c == long.class) { return 0L; } else if (c == float.class) { return 0f; } else if (c == double.class) { return 0d; } else { throw new IllegalStateException(); } } else if (c.isArray()) { if (c == char[].class) { return new char[1]; } else if (c == boolean[].class) { return new boolean[1]; } else if (c == byte[].class) { return new byte[1]; } else if (c == short[].class) { return new short[1]; } else if (c == int[].class) { return new int[1]; } else if (c == long[].class) { return new long[1]; } else if (c == float[].class) { return new float[1]; } else if (c == double[].class) { return new double[1]; } else { throw new IllegalStateException(); } } else if (c == String.class) { return "asdf"; } else if (c == ByteBuffer.class) { return ByteBuffer.wrap(new byte[1]); } else if (c == CharBuffer.class) { return CharBuffer.wrap(new char[1]); } else if (c == ShortBuffer.class) { return ShortBuffer.wrap(new short[1]); } else if (c == IntBuffer.class) { return IntBuffer.wrap(new int[1]); } else if (c == FloatBuffer.class) { return FloatBuffer.wrap(new float[1]); } else if (c == LongBuffer.class) { return LongBuffer.wrap(new long[1]); } else if (c == DoubleBuffer.class) { return DoubleBuffer.wrap(new double[1]); } else { return null; } } @DataProvider(name = "bufferSources") public static Object[][] bufferSources() { Predicate heapTest = segment -> segment instanceof HeapMemorySegmentImpl; Predicate nativeTest = segment -> segment instanceof NativeMemorySegmentImpl; Predicate mappedTest = segment -> segment instanceof MappedMemorySegmentImpl; try (FileChannel channel = FileChannel.open(tempPath, StandardOpenOption.READ, StandardOpenOption.WRITE)) { return new Object[][]{ { ByteBuffer.wrap(new byte[256]), heapTest }, { ByteBuffer.allocate(256), heapTest }, { ByteBuffer.allocateDirect(256), nativeTest }, { channel.map(FileChannel.MapMode.READ_WRITE, 0L, 256), mappedTest }, { ByteBuffer.wrap(new byte[256]).asReadOnlyBuffer(), heapTest }, { ByteBuffer.allocate(256).asReadOnlyBuffer(), heapTest }, { ByteBuffer.allocateDirect(256).asReadOnlyBuffer(), nativeTest }, { channel.map(FileChannel.MapMode.READ_WRITE, 0L, 256).asReadOnlyBuffer(), nativeTest /* this seems to be an existing bug in the BB implementation */ } }; } catch (IOException ex) { throw new ExceptionInInitializerError(ex); } } enum MappedSegmentOp { LOAD(MappedMemorySegments::load), UNLOAD(MappedMemorySegments::unload), IS_LOADED(MappedMemorySegments::isLoaded), FORCE(MappedMemorySegments::force), BUFFER_LOAD(m -> ((MappedByteBuffer)m.asByteBuffer()).load()), BUFFER_IS_LOADED(m -> ((MappedByteBuffer)m.asByteBuffer()).isLoaded()), BUFFER_FORCE(m -> ((MappedByteBuffer)m.asByteBuffer()).force()); private Consumer segmentOp; MappedSegmentOp(Consumer segmentOp) { this.segmentOp = segmentOp; } void apply(MemorySegment segment) { segmentOp.accept(segment); } } @DataProvider(name = "mappedOps") public static Object[][] mappedOps() { return Stream.of(MappedSegmentOp.values()) .map(op -> new Object[] { op }) .toArray(Object[][]::new); } }