/* * Copyright (c) 2003 Sun Microsystems, Inc. All Rights Reserved. * Copyright (c) 2010 JogAmp Community. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * - Redistribution of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * - Redistribution in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Sun Microsystems, Inc. or the names of * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * This software is provided "AS IS," without a warranty of any kind. ALL * EXPRESS OR IMPLIED CONDITIONS, REPRESENTATIONS AND WARRANTIES, * INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A * PARTICULAR PURPOSE OR NON-INFRINGEMENT, ARE HEREBY EXCLUDED. SUN * MICROSYSTEMS, INC. ("SUN") AND ITS LICENSORS SHALL NOT BE LIABLE FOR * ANY DAMAGES SUFFERED BY LICENSEE AS A RESULT OF USING, MODIFYING OR * DISTRIBUTING THIS SOFTWARE OR ITS DERIVATIVES. IN NO EVENT WILL SUN OR * ITS LICENSORS BE LIABLE FOR ANY LOST REVENUE, PROFIT OR DATA, OR FOR * DIRECT, INDIRECT, SPECIAL, CONSEQUENTIAL, INCIDENTAL OR PUNITIVE * DAMAGES, HOWEVER CAUSED AND REGARDLESS OF THE THEORY OF LIABILITY, * ARISING OUT OF THE USE OF OR INABILITY TO USE THIS SOFTWARE, EVEN IF * SUN HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. * * You acknowledge that this software is not designed or intended for use * in the design, construction, operation or maintenance of any nuclear * facility. * * Sun gratefully acknowledges that this software was originally authored * and developed by Kenneth Bradley Russell and Christopher John Kline. */ package com.jogamp.common.nio; import java.lang.reflect.Field; import java.lang.reflect.Method; 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.ShortBuffer; import java.security.PrivilegedAction; import com.jogamp.common.ExceptionUtils; import com.jogamp.common.util.ReflectionUtil; import com.jogamp.common.util.SecurityUtil; import com.jogamp.common.util.UnsafeUtil; import com.jogamp.common.util.ValueConv; import jogamp.common.Debug; import jogamp.common.os.PlatformPropsImpl; /** * Utility methods allowing easy {@link java.nio.Buffer} manipulations. * * @author Kenneth Russel * @author Sven Gothel * @author Michael Bien */ public class Buffers { static final boolean DEBUG; static { DEBUG = Debug.debug("Buffers"); } public static final int SIZEOF_BYTE = 1; public static final int SIZEOF_SHORT = 2; public static final int SIZEOF_CHAR = 2; public static final int SIZEOF_INT = 4; public static final int SIZEOF_FLOAT = 4; public static final int SIZEOF_LONG = 8; public static final int SIZEOF_DOUBLE = 8; protected Buffers() {} /** * Allocates a new direct ByteBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static ByteBuffer newDirectByteBuffer(final int numElements) { return nativeOrder(ByteBuffer.allocateDirect(numElements)); } public static ByteBuffer newDirectByteBuffer(final byte[] values, final int offset, final int length) { return (ByteBuffer)newDirectByteBuffer(length).put(values, offset, length).rewind(); } public static ByteBuffer newDirectByteBuffer(final byte[] values, final int offset) { return newDirectByteBuffer(values, offset, values.length-offset); } public static ByteBuffer newDirectByteBuffer(final byte[] values) { return newDirectByteBuffer(values, 0); } /** * Allocates a new direct DoubleBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static DoubleBuffer newDirectDoubleBuffer(final int numElements) { return newDirectByteBuffer(numElements * SIZEOF_DOUBLE).asDoubleBuffer(); } public static DoubleBuffer newDirectDoubleBuffer(final double[] values, final int offset, final int length) { return (DoubleBuffer)newDirectDoubleBuffer(length).put(values, offset, length).rewind(); } public static DoubleBuffer newDirectDoubleBuffer(final double[] values, final int offset) { return newDirectDoubleBuffer(values, offset, values.length - offset); } public static DoubleBuffer newDirectDoubleBuffer(final double[] values) { return newDirectDoubleBuffer(values, 0); } /** * Allocates a new direct FloatBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static FloatBuffer newDirectFloatBuffer(final int numElements) { return newDirectByteBuffer(numElements * SIZEOF_FLOAT).asFloatBuffer(); } public static FloatBuffer newDirectFloatBuffer(final float[] values, final int offset, final int length) { return (FloatBuffer)newDirectFloatBuffer(length).put(values, offset, length).rewind(); } public static FloatBuffer newDirectFloatBuffer(final float[] values, final int offset) { return newDirectFloatBuffer(values, offset, values.length - offset); } public static FloatBuffer newDirectFloatBuffer(final float[] values) { return newDirectFloatBuffer(values, 0); } /** * Allocates a new direct IntBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static IntBuffer newDirectIntBuffer(final int numElements) { return newDirectByteBuffer(numElements * SIZEOF_INT).asIntBuffer(); } public static IntBuffer newDirectIntBuffer(final int[] values, final int offset, final int length) { return (IntBuffer)newDirectIntBuffer(length).put(values, offset, length).rewind(); } public static IntBuffer newDirectIntBuffer(final int[] values, final int offset) { return newDirectIntBuffer(values, offset, values.length - offset); } public static IntBuffer newDirectIntBuffer(final int[] values) { return newDirectIntBuffer(values, 0); } /** * Allocates a new direct LongBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static LongBuffer newDirectLongBuffer(final int numElements) { return newDirectByteBuffer(numElements * SIZEOF_LONG).asLongBuffer(); } public static LongBuffer newDirectLongBuffer(final long[] values, final int offset, final int length) { return (LongBuffer)newDirectLongBuffer(length).put(values, offset, length).rewind(); } public static LongBuffer newDirectLongBuffer(final long[] values, final int offset) { return newDirectLongBuffer(values, offset, values.length - offset); } public static LongBuffer newDirectLongBuffer(final long[] values) { return newDirectLongBuffer(values, 0); } /** * Allocates a new direct ShortBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static ShortBuffer newDirectShortBuffer(final int numElements) { return newDirectByteBuffer(numElements * SIZEOF_SHORT).asShortBuffer(); } public static ShortBuffer newDirectShortBuffer(final short[] values, final int offset, final int length) { return (ShortBuffer)newDirectShortBuffer(length).put(values, offset, length).rewind(); } public static ShortBuffer newDirectShortBuffer(final short[] values, final int offset) { return newDirectShortBuffer(values, offset, values.length - offset); } public static ShortBuffer newDirectShortBuffer(final short[] values) { return newDirectShortBuffer(values, 0); } /** * Allocates a new direct CharBuffer with the specified number of * elements. The returned buffer will have its byte order set to * the host platform's native byte order. */ public static CharBuffer newDirectCharBuffer(final int numElements) { return newDirectByteBuffer(numElements * SIZEOF_SHORT).asCharBuffer(); } public static CharBuffer newDirectCharBuffer(final char[] values, final int offset, final int length) { return (CharBuffer)newDirectCharBuffer(length).put(values, offset, length).rewind(); } public static CharBuffer newDirectCharBuffer(final char[] values, final int offset) { return newDirectCharBuffer(values, offset, values.length - offset); } public static CharBuffer newDirectCharBuffer(final char[] values) { return newDirectCharBuffer(values, 0); } /** * Calls slice on the specified buffer while maintaining the byteorder. * @see #slice(java.nio.Buffer, int, int) */ @SuppressWarnings("unchecked") public static B slice(final B buffer) { if (buffer instanceof ByteBuffer) { final ByteBuffer bb = (ByteBuffer) buffer; return (B) bb.slice().order(bb.order()); // slice and duplicate may change byte order } else if (buffer instanceof IntBuffer) { return (B) ((IntBuffer) buffer).slice(); } else if (buffer instanceof ShortBuffer) { return (B) ((ShortBuffer) buffer).slice(); } else if (buffer instanceof FloatBuffer) { return (B) ((FloatBuffer) buffer).slice(); } else if (buffer instanceof DoubleBuffer) { return (B) ((DoubleBuffer) buffer).slice(); } else if (buffer instanceof LongBuffer) { return (B) ((LongBuffer) buffer).slice(); } else if (buffer instanceof CharBuffer) { return (B) ((CharBuffer) buffer).slice(); } throw new IllegalArgumentException("unexpected buffer type: " + buffer.getClass()); } /** * Slices the specified buffer with offset as position and offset+size as limit * while maintaining the byteorder. * Concurrency warning: this method changes the buffers position and limit but * will restore it before return. */ public static B slice(final B buffer, final int offset, final int size) { final int pos = buffer.position(); final int limit = buffer.limit(); B slice = null; try { buffer.position(offset).limit(offset+size); slice = slice(buffer); } finally { buffer.position(pos).limit(limit); } return slice; } /** * Slices a ByteBuffer or a FloatBuffer to a FloatBuffer * at the given position with the given size in float-space. *

* The returned sliced buffer's start position is always zero. *

*

* The returned sliced buffer is {@link FloatBuffer#mark() marked} at it's {@link FloatBuffer#position() start position}. Hence * {@link FloatBuffer#reset()} will rewind it to start after applying relative operations like {@link FloatBuffer#get()}. *

*

* Using a ByteBuffer as the source guarantees * keeping the source native order programmatically. * This works around Honeycomb / Android 3.0 Issue 16434. * This bug is resolved at least in Android 3.2. *

* * @param buf source Buffer, maybe ByteBuffer (recommended) or FloatBuffer. * Buffer's position is ignored and floatPos is being used. * @param floatStartPos {@link Buffers#SIZEOF_FLOAT} position * @param floatSize {@link Buffers#SIZEOF_FLOAT} size * @return FloatBuffer w/ native byte order as given ByteBuffer */ public static final FloatBuffer slice2Float(final Buffer buf, final int floatStartPos, final int floatSize) { final int pos; final int limit; if(null != buf) { pos = buf.position(); limit = buf.limit(); } else { pos = 0; limit = 0; } final FloatBuffer res; try { if(buf instanceof ByteBuffer) { final ByteBuffer bb = (ByteBuffer) buf; bb.position( floatStartPos * Buffers.SIZEOF_FLOAT ); bb.limit( (floatStartPos + floatSize) * Buffers.SIZEOF_FLOAT ); res = bb.slice().order(bb.order()).asFloatBuffer(); // slice and duplicate may change byte order } else if(buf instanceof FloatBuffer) { final FloatBuffer fb = (FloatBuffer) buf; fb.position( floatStartPos ); fb.limit( floatStartPos + floatSize ); res = fb.slice(); // slice and duplicate may change byte order } else { throw new InternalError("Buffer not ByteBuffer, nor FloarBuffer, nor backing array given"); } } finally { if(null != buf) { buf.position(pos).limit(limit); } } res.mark(); return res; } /** * Slices a primitive float backing array to a FloatBuffer at the given position with the given size * in float-space by {@link FloatBuffer#wrap(float[], int, int) wrapping} the backing array. *

* Due to {@link FloatBuffer#wrap(float[], int, int) wrapping} the backing array, * the returned sliced buffer's {@link FloatBuffer#position() start position} equals * the given floatStartPos within the given backing array * while it's {@link FloatBuffer#arrayOffset() array-offset} is zero. * This has the advantage of being able to dismiss the {@link FloatBuffer#arrayOffset() array-offset} * in user code, while only being required to consider it's {@link FloatBuffer#position() position}. *

*

* The returned sliced buffer is {@link FloatBuffer#mark() marked} at it's {@link FloatBuffer#position() start position}. Hence * {@link FloatBuffer#reset()} will rewind it to start after applying relative operations like {@link FloatBuffer#get()}. *

* * @param backing source float array * @param floatStartPos {@link Buffers#SIZEOF_FLOAT} position * @param floatSize {@link Buffers#SIZEOF_FLOAT} size * @return FloatBuffer w/ native byte order as given ByteBuffer */ public static final FloatBuffer slice2Float(final float[] backing, final int floatStartPos, final int floatSize) { return (FloatBuffer) FloatBuffer.wrap(backing, floatStartPos, floatSize).mark(); } /** * Helper routine to set a ByteBuffer to the native byte order, if * that operation is supported by the underlying NIO * implementation. */ public static ByteBuffer nativeOrder(final ByteBuffer buf) { return buf.order(ByteOrder.nativeOrder()); } /** * Returns the size of a single element of the given buffer in bytes * or 0 if the given buffer is null. */ public static int sizeOfBufferElem(final Object buffer) { if (buffer == null) { return 0; } if (buffer instanceof ByteBuffer) { return SIZEOF_BYTE; } else if (buffer instanceof IntBuffer) { return SIZEOF_INT; } else if (buffer instanceof ShortBuffer) { return SIZEOF_SHORT; } else if (buffer instanceof FloatBuffer) { return SIZEOF_FLOAT; } else if (buffer instanceof DoubleBuffer) { return SIZEOF_DOUBLE; } else if (buffer instanceof LongBuffer) { return SIZEOF_LONG; } else if (buffer instanceof CharBuffer) { return SIZEOF_CHAR; } else if (buffer instanceof NativeBuffer) { return ((NativeBuffer) buffer).elementSize(); } throw new RuntimeException("Unexpected buffer type " + buffer.getClass().getName()); } /** * Returns the number of remaining elements of the given anonymous buffer. * * @param buffer Anonymous Buffer of type {@link NativeBuffer} or a derivation of {@link Buffer}. * @return If buffer is null, returns 0, otherwise the remaining size in elements. * @throws IllegalArgumentException if buffer is of invalid type. */ public static int remainingElem(final Object buffer) throws IllegalArgumentException { if (buffer == null) { return 0; } if (buffer instanceof Buffer) { return ((Buffer) buffer).remaining(); } else if (buffer instanceof NativeBuffer) { return ((NativeBuffer) buffer).remaining(); } else { throw new IllegalArgumentException("Unsupported anonymous buffer type: "+buffer.getClass().getCanonicalName()); } } /** * Returns the number of remaining bytes of the given anonymous buffer. * * @param buffer Anonymous Buffer of type {@link NativeBuffer} or a derivation of {@link Buffer}. * @return If buffer is null, returns 0, otherwise the remaining size in bytes. * @throws IllegalArgumentException if buffer is of invalid type. */ public static int remainingBytes(final Object buffer) throws IllegalArgumentException { if (buffer == null) { return 0; } final int bytesRemaining; if (buffer instanceof Buffer) { final int elementsRemaining = ((Buffer) buffer).remaining(); if (buffer instanceof ByteBuffer) { bytesRemaining = elementsRemaining; } else if (buffer instanceof FloatBuffer) { bytesRemaining = elementsRemaining * SIZEOF_FLOAT; } else if (buffer instanceof IntBuffer) { bytesRemaining = elementsRemaining * SIZEOF_INT; } else if (buffer instanceof ShortBuffer) { bytesRemaining = elementsRemaining * SIZEOF_SHORT; } else if (buffer instanceof DoubleBuffer) { bytesRemaining = elementsRemaining * SIZEOF_DOUBLE; } else if (buffer instanceof LongBuffer) { bytesRemaining = elementsRemaining * SIZEOF_LONG; } else if (buffer instanceof CharBuffer) { bytesRemaining = elementsRemaining * SIZEOF_CHAR; } else { throw new InternalError("Unsupported Buffer type: "+buffer.getClass().getCanonicalName()); } } else if (buffer instanceof NativeBuffer) { final NativeBuffer nb = (NativeBuffer) buffer; bytesRemaining = nb.remaining() * nb.elementSize(); } else { throw new IllegalArgumentException("Unsupported anonymous buffer type: "+buffer.getClass().getCanonicalName()); } return bytesRemaining; } /** * Helper routine to tell whether a buffer is direct or not. Null * pointers are considered direct. */ public static boolean isDirect(final Object buf) { if (buf == null) { return true; } if (buf instanceof Buffer) { return ((Buffer) buf).isDirect(); } else if (buf instanceof PointerBuffer) { return ((PointerBuffer) buf).isDirect(); } throw new IllegalArgumentException("Unexpected buffer type " + buf.getClass().getName()); } /** * Helper routine to get the Buffer byte offset by taking into * account the Buffer position and the underlying type. This is * the total offset for Direct Buffers. */ public static int getDirectBufferByteOffset(final Object buf) { if (buf == null) { return 0; } if (buf instanceof Buffer) { final int pos = ((Buffer) buf).position(); if (buf instanceof ByteBuffer) { return pos; } else if (buf instanceof FloatBuffer) { return pos * SIZEOF_FLOAT; } else if (buf instanceof IntBuffer) { return pos * SIZEOF_INT; } else if (buf instanceof ShortBuffer) { return pos * SIZEOF_SHORT; } else if (buf instanceof DoubleBuffer) { return pos * SIZEOF_DOUBLE; } else if (buf instanceof LongBuffer) { return pos * SIZEOF_LONG; } else if (buf instanceof CharBuffer) { return pos * SIZEOF_CHAR; } } else if (buf instanceof NativeBuffer) { final NativeBuffer nb = (NativeBuffer) buf; return nb.position() * nb.elementSize() ; } throw new IllegalArgumentException("Disallowed array backing store type in buffer " + buf.getClass().getName()); } /** * Helper routine to return the array backing store reference from * a Buffer object. * @throws UnsupportedOperationException if the passed Object does not have an array backing store * @throws IllegalArgumentException if the passed Object is neither of type {@link java.nio.Buffer} or {@link NativeBuffer}. */ public static Object getArray(final Object buf) throws UnsupportedOperationException, IllegalArgumentException { if (buf == null) { return null; } if (buf instanceof Buffer) { return ((Buffer) buf).array(); } else if (buf instanceof NativeBuffer) { return ((NativeBuffer) buf).array(); } throw new IllegalArgumentException("Disallowed array backing store type in buffer " + buf.getClass().getName()); } /** * Helper routine to get the full byte offset from the beginning of * the array that is the storage for the indirect Buffer * object. The array offset also includes the position offset * within the buffer, in addition to any array offset. */ public static int getIndirectBufferByteOffset(final Object buf) { if (buf == null) { return 0; } if (buf instanceof Buffer) { final int pos = ((Buffer) buf).position(); if (buf instanceof ByteBuffer) { return (((ByteBuffer) buf).arrayOffset() + pos); } else if (buf instanceof FloatBuffer) { return (SIZEOF_FLOAT * (((FloatBuffer) buf).arrayOffset() + pos)); } else if (buf instanceof IntBuffer) { return (SIZEOF_INT * (((IntBuffer) buf).arrayOffset() + pos)); } else if (buf instanceof ShortBuffer) { return (SIZEOF_SHORT * (((ShortBuffer) buf).arrayOffset() + pos)); } else if (buf instanceof DoubleBuffer) { return (SIZEOF_DOUBLE * (((DoubleBuffer) buf).arrayOffset() + pos)); } else if (buf instanceof LongBuffer) { return (SIZEOF_LONG * (((LongBuffer) buf).arrayOffset() + pos)); } else if (buf instanceof CharBuffer) { return (SIZEOF_CHAR * (((CharBuffer) buf).arrayOffset() + pos)); } } else if (buf instanceof NativeBuffer) { final NativeBuffer nb = (NativeBuffer) buf; return nb.elementSize() * ( nb.arrayOffset() + nb.position() ); } throw new IllegalArgumentException("Unknown buffer type " + buf.getClass().getName()); } //---------------------------------------------------------------------- // Copy routines (type-to-type) // /** * Copies the remaining elements (as defined by * limit() - position()) in the passed ByteBuffer into * a newly-allocated direct ByteBuffer. The returned buffer will * have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static ByteBuffer copyByteBuffer(final ByteBuffer orig) { final int op0 = orig.position(); final ByteBuffer dest = newDirectByteBuffer(orig.remaining()); dest.put(orig); dest.rewind(); orig.position(op0); return dest; } /** * Copies the remaining elements (as defined by * limit() - position()) in the passed FloatBuffer * into a newly-allocated direct FloatBuffer. The returned buffer * will have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static FloatBuffer copyFloatBuffer(final FloatBuffer orig) { return copyFloatBufferAsByteBuffer(orig).asFloatBuffer(); } /** * Copies the remaining elements (as defined by * limit() - position()) in the passed IntBuffer * into a newly-allocated direct IntBuffer. The returned buffer * will have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static IntBuffer copyIntBuffer(final IntBuffer orig) { return copyIntBufferAsByteBuffer(orig).asIntBuffer(); } /** * Copies the remaining elements (as defined by * limit() - position()) in the passed ShortBuffer * into a newly-allocated direct ShortBuffer. The returned buffer * will have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static ShortBuffer copyShortBuffer(final ShortBuffer orig) { return copyShortBufferAsByteBuffer(orig).asShortBuffer(); } //---------------------------------------------------------------------- // Copy routines (type-to-ByteBuffer) // /** * Copies the remaining elements (as defined by * limit() - position()) in the passed FloatBuffer * into a newly-allocated direct ByteBuffer. The returned buffer * will have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static ByteBuffer copyFloatBufferAsByteBuffer(final FloatBuffer orig) { final int op0 = orig.position(); final ByteBuffer dest = newDirectByteBuffer(orig.remaining() * SIZEOF_FLOAT); dest.asFloatBuffer().put(orig); dest.rewind(); orig.position(op0); return dest; } /** * Copies the remaining elements (as defined by * limit() - position()) in the passed IntBuffer into * a newly-allocated direct ByteBuffer. The returned buffer will * have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static ByteBuffer copyIntBufferAsByteBuffer(final IntBuffer orig) { final int op0 = orig.position(); final ByteBuffer dest = newDirectByteBuffer(orig.remaining() * SIZEOF_INT); dest.asIntBuffer().put(orig); dest.rewind(); orig.position(op0); return dest; } /** * Copies the remaining elements (as defined by * limit() - position()) in the passed ShortBuffer * into a newly-allocated direct ByteBuffer. The returned buffer * will have its byte order set to the host platform's native byte * order. The position of the newly-allocated buffer will be zero, * and the position of the passed buffer is unchanged. */ public static ByteBuffer copyShortBufferAsByteBuffer(final ShortBuffer orig) { final int op0 = orig.position(); final ByteBuffer dest = newDirectByteBuffer(orig.remaining() * SIZEOF_SHORT); dest.asShortBuffer().put(orig); dest.rewind(); orig.position(op0); return dest; } //---------------------------------------------------------------------- // Conversion routines // /** * @param source the source array * @param soffset the offset * @param dest the target array, if null, a new array is being created with size len. * @param doffset the offset in the dest array * @param len the payload of elements to be copied, if len < 0 then len = source.length - soffset * @return the passed or newly created target array */ public static float[] getFloatArray(final double[] source, final int soffset, float[] dest, int doffset, int len) { if(0>len) { len = source.length - soffset; } if(len > source.length - soffset) { throw new IllegalArgumentException("payload ("+len+") greater than remaining source bytes [len "+source.length+", offset "+soffset+"]"); } if(null==dest) { dest = new float[len]; doffset = 0; } if(len > dest.length - doffset) { throw new IllegalArgumentException("payload ("+len+") greater than remaining dest bytes [len "+dest.length+", offset "+doffset+"]"); } for(int i=0; isource.remaining() * @return the passed or newly created target buffer */ public static FloatBuffer getFloatBuffer(final DoubleBuffer source, FloatBuffer dest) { if(null == dest) { dest = newDirectFloatBuffer(source.remaining()); } if( dest.remaining() < source.remaining() ) { throw new IllegalArgumentException("payload ("+source.remaining()+") is greater than remaining dest bytes: "+dest.remaining()); } while (source.hasRemaining()) { dest.put((float) source.get()); } return dest; } /** * @param source the source array * @param soffset the offset * @param dest the target array, if null, a new array is being created with size len. * @param doffset the offset in the dest array * @param len the payload of elements to be copied, if len < 0 then len = source.length - soffset * @return the passed or newly created target array */ public static double[] getDoubleArray(final float[] source, final int soffset, double[] dest, int doffset, int len) { if(0>len) { len = source.length - soffset; } if(len > source.length - soffset) { throw new IllegalArgumentException("payload ("+len+") greater than remaining source bytes [len "+source.length+", offset "+soffset+"]"); } if(null==dest) { dest = new double[len]; doffset = 0; } if(len > dest.length - doffset) { throw new IllegalArgumentException("payload ("+len+") greater than remaining dest bytes [len "+dest.length+", offset "+doffset+"]"); } for(int i=0; isource.remaining() * @return the passed or newly created target buffer */ public static DoubleBuffer getDoubleBuffer(final FloatBuffer source, DoubleBuffer dest) { if(null == dest) { dest = newDirectDoubleBuffer(source.remaining()); } if( dest.remaining() < source.remaining() ) { throw new IllegalArgumentException("payload ("+source.remaining()+") is greater than remaining dest bytes: "+dest.remaining()); } while (source.hasRemaining()) { dest.put(source.get()); } return dest; } //---------------------------------------------------------------------- // Convenient put methods with generic target Buffer w/o value range conversion, i.e. normalization // @SuppressWarnings("unchecked") public static B put(final B dest, final Buffer src) { if ((dest instanceof ByteBuffer) && (src instanceof ByteBuffer)) { return (B) ((ByteBuffer) dest).put((ByteBuffer) src); } else if ((dest instanceof ShortBuffer) && (src instanceof ShortBuffer)) { return (B) ((ShortBuffer) dest).put((ShortBuffer) src); } else if ((dest instanceof IntBuffer) && (src instanceof IntBuffer)) { return (B) ((IntBuffer) dest).put((IntBuffer) src); } else if ((dest instanceof FloatBuffer) && (src instanceof FloatBuffer)) { return (B) ((FloatBuffer) dest).put((FloatBuffer) src); } else if ((dest instanceof LongBuffer) && (src instanceof LongBuffer)) { return (B) ((LongBuffer) dest).put((LongBuffer) src); } else if ((dest instanceof DoubleBuffer) && (src instanceof DoubleBuffer)) { return (B) ((DoubleBuffer) dest).put((DoubleBuffer) src); } else if ((dest instanceof CharBuffer) && (src instanceof CharBuffer)) { return (B) ((CharBuffer) dest).put((CharBuffer) src); } throw new IllegalArgumentException("Incompatible Buffer classes: dest = " + dest.getClass().getName() + ", src = " + src.getClass().getName()); } @SuppressWarnings("unchecked") public static B putb(final B dest, final byte v) { if (dest instanceof ByteBuffer) { return (B) ((ByteBuffer) dest).put(v); } else if (dest instanceof ShortBuffer) { return (B) ((ShortBuffer) dest).put(v); } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put(v); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put(v); } else if (dest instanceof LongBuffer) { return (B) ((LongBuffer) dest).put(v); } else if (dest instanceof DoubleBuffer) { return (B) ((DoubleBuffer) dest).put(v); } else if (dest instanceof CharBuffer) { return (B) ((CharBuffer) dest).put((char) v); } else { throw new IllegalArgumentException("Byte doesn't match Buffer Class: " + dest); } } @SuppressWarnings("unchecked") public static B puts(final B dest, final short v) { if (dest instanceof ShortBuffer) { return (B) ((ShortBuffer) dest).put(v); } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put(v); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put(v); } else if (dest instanceof LongBuffer) { return (B) ((LongBuffer) dest).put(v); } else if (dest instanceof DoubleBuffer) { return (B) ((DoubleBuffer) dest).put(v); } else { throw new IllegalArgumentException("Short doesn't match Buffer Class: " + dest); } } @SuppressWarnings("unchecked") public static B puti(final B dest, final int v) { if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put(v); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put(v); } else if (dest instanceof LongBuffer) { return (B) ((LongBuffer) dest).put(v); } else if (dest instanceof DoubleBuffer) { return (B) ((DoubleBuffer) dest).put(v); } else { throw new IllegalArgumentException("Integer doesn't match Buffer Class: " + dest); } } @SuppressWarnings("unchecked") public static B putf(final B dest, final float v) { if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put(v); } else if (dest instanceof DoubleBuffer) { return (B) ((DoubleBuffer) dest).put(v); /* TODO FixedPoint required } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put(FixedPoint.toFixed(v)); */ } else { throw new IllegalArgumentException("Float doesn't match Buffer Class: " + dest); } } @SuppressWarnings("unchecked") public static B putd(final B dest, final double v) { if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put((float) v); } else { throw new IllegalArgumentException("Double doesn't match Buffer Class: " + dest); } } //---------------------------------------------------------------------- // Convenient put methods with generic target Buffer and value range conversion, i.e. normalization // /** * Store byte source value in given buffer after normalizing it to the destination value range * considering signed and unsigned source and destination representation. * * @param dest One of {@link ByteBuffer}, {@link ShortBuffer}, {@link IntBuffer}, {@link FloatBuffer} * @param dSigned true if destination buffer holds signed values, false if destination buffer holds unsigned values * @param v source byte value to be put in dest buffer * @param sSigned true if source represents a signed value, false if source represents an unsigned value */ @SuppressWarnings("unchecked") public static B putNb(final B dest, final boolean dSigned, final byte v, final boolean sSigned) { if (dest instanceof ByteBuffer) { return (B) ((ByteBuffer) dest).put( v ); } else if (dest instanceof ShortBuffer) { return (B) ((ShortBuffer) dest).put( ValueConv.byte_to_short(v, sSigned, dSigned) ); } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put( ValueConv.byte_to_int(v, sSigned, dSigned) ); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put( ValueConv.byte_to_float(v, sSigned) ); } else { throw new IllegalArgumentException("Byte doesn't match Buffer Class: " + dest); } } /** * Store short source value in given buffer after normalizing it to the destination value range * considering signed and unsigned source and destination representation. * * @param dest One of {@link ByteBuffer}, {@link ShortBuffer}, {@link IntBuffer}, {@link FloatBuffer} * @param dSigned true if destination buffer holds signed values, false if destination buffer holds unsigned values * @param v source short value to be put in dest buffer * @param sSigned true if source represents a signed value, false if source represents an unsigned value */ @SuppressWarnings("unchecked") public static B putNs(final B dest, final boolean dSigned, final short v, final boolean sSigned) { if (dest instanceof ByteBuffer) { return (B) ((ByteBuffer) dest).put( ValueConv.short_to_byte(v, sSigned, dSigned) ); } else if (dest instanceof ShortBuffer) { return (B) ((ShortBuffer) dest).put( v ); } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put( ValueConv.short_to_int(v, sSigned, dSigned) ); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put( ValueConv.short_to_float(v, sSigned) ); } else { throw new IllegalArgumentException("Byte doesn't match Buffer Class: " + dest); } } /** * Store short source value in given buffer after normalizing it to the destination value range * considering signed and unsigned source and destination representation. * * @param dest One of {@link ByteBuffer}, {@link ShortBuffer}, {@link IntBuffer}, {@link FloatBuffer} * @param dSigned true if destination buffer holds signed values, false if destination buffer holds unsigned values * @param v source short value to be put in dest buffer * @param sSigned true if source represents a signed value, false if source represents an unsigned value */ @SuppressWarnings("unchecked") public static B putNi(final B dest, final boolean dSigned, final int v, final boolean sSigned) { if (dest instanceof ByteBuffer) { return (B) ((ByteBuffer) dest).put( ValueConv.int_to_byte(v, sSigned, dSigned) ); } else if (dest instanceof ShortBuffer) { return (B) ((ShortBuffer) dest).put( ValueConv.int_to_short(v, sSigned, dSigned) ); } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put( v ); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put( ValueConv.int_to_float(v, sSigned) ); } else { throw new IllegalArgumentException("Byte doesn't match Buffer Class: " + dest); } } /** * Store float source value in given buffer after normalizing it to the destination value range * considering signed and unsigned destination representation. * * @param dest One of {@link ByteBuffer}, {@link ShortBuffer}, {@link IntBuffer}, {@link FloatBuffer} * @param dSigned true if destination buffer holds signed values, false if destination buffer holds unsigned values * @param v source float value to be put in dest buffer */ @SuppressWarnings("unchecked") public static B putNf(final B dest, final boolean dSigned, final float v) { if (dest instanceof ByteBuffer) { return (B) ((ByteBuffer) dest).put( ValueConv.float_to_byte(v, dSigned) ); } else if (dest instanceof ShortBuffer) { return (B) ((ShortBuffer) dest).put( ValueConv.float_to_short(v, dSigned) ); } else if (dest instanceof IntBuffer) { return (B) ((IntBuffer) dest).put( ValueConv.float_to_int(v, dSigned) ); } else if (dest instanceof FloatBuffer) { return (B) ((FloatBuffer) dest).put( v ); } else { throw new IllegalArgumentException("Byte doesn't match Buffer Class: " + dest); } } //---------------------------------------------------------------------- // Range check methods // public static void rangeCheck(final byte[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final char[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final short[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final int[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final long[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final float[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final double[] array, final int offset, final int minElementsRemaining) { if (array == null) { return; } if (array.length < offset + minElementsRemaining) { throw new ArrayIndexOutOfBoundsException("Required " + minElementsRemaining + " elements in array, only had " + (array.length - offset)); } } public static void rangeCheck(final Buffer buffer, final int minElementsRemaining) { if (buffer == null) { return; } if (buffer.remaining() < minElementsRemaining) { throw new IndexOutOfBoundsException("Required " + minElementsRemaining + " remaining elements in buffer, only had " + buffer.remaining()); } } /** * @param buffer buffer to test for minimum * @param minBytesRemaining minimum bytes remaining * @throws IllegalArgumentException if buffer is of invalid type. * @throws IndexOutOfBoundsException if {@link #remainingBytes(Object)} is < minBytesRemaining. */ public static void rangeCheckBytes(final Object buffer, final int minBytesRemaining) throws IllegalArgumentException, IndexOutOfBoundsException { if (buffer == null) { return; } final int bytesRemaining = remainingBytes(buffer); if (bytesRemaining < minBytesRemaining) { throw new IndexOutOfBoundsException("Required " + minBytesRemaining + " remaining bytes in buffer, only had " + bytesRemaining); } } /** * Appends Buffer details inclusive data to a StringBuilder instance. * @param sb optional pass through StringBuilder * @param f optional format string of one element, i.e. "%10.5f" for {@link FloatBuffer}, see {@link java.util.Formatter}, * or null for unformatted output. * Note: Caller is responsible to match the format string w/ the data type as expected in the given buffer. * @param buffer Any valid Buffer instance * @return the modified StringBuilder containing the Buffer details */ public static StringBuilder toString(StringBuilder sb, final String f, final Buffer buffer) { if(null == sb) { sb = new StringBuilder(); } sb.append(buffer.getClass().getSimpleName()); sb.append("[pos ").append(buffer.position()).append(", lim ").append(buffer.limit()).append(", cap ").append(buffer.capacity()); sb.append(", remaining ").append(buffer.remaining()); sb.append("; array ").append(buffer.hasArray()).append(", direct ").append(buffer.isDirect()); sb.append(", r/w ").append(!buffer.isReadOnly()).append(": "); if (buffer instanceof ByteBuffer) { final ByteBuffer b = (ByteBuffer)buffer; for(int i=0; i() { @Override public Boolean run() { try { if( PlatformPropsImpl.JAVA_9 ) { return UnsafeUtil.hasInvokeCleaner(); } else { _mbbCleaner[0] = ReflectionUtil.getMethod("sun.nio.ch.DirectBuffer", "cleaner", null, Buffers.class.getClassLoader()); _mbbCleaner[0].setAccessible(true); final Class cleanerType = _mbbCleaner[0].getReturnType(); // Java >= 9: jdk.internal.ref.Cleaner (NOT accessible!) // "Unable to make public void jdk.internal.ref.Cleaner.clean() accessible: // module java.base does not "exports jdk.internal.ref" to unnamed module" // Java <= 8: sun.misc.Cleaner OK _cClean[0] = cleanerType.getMethod("clean"); _cClean[0].setAccessible(true); return Boolean.TRUE; } } catch(final Throwable t) { if( DEBUG ) { ExceptionUtils.dumpThrowable("Buffers", t); } return Boolean.FALSE; } } } ).booleanValue() ) { mbbCleaner = _mbbCleaner[0]; cClean = _cClean[0]; hasCleaner = PlatformPropsImpl.JAVA_9 || ( null != mbbCleaner && null != cClean ); } else { mbbCleaner = null; cClean = null; hasCleaner = false; } cleanerError = !hasCleaner; if( DEBUG ) { System.err.print("Buffers.Cleaner.init: hasCleaner: "+hasCleaner+", cleanerError "+cleanerError); if( null != mbbCleaner ) { System.err.print(", using Cleaner class: "+mbbCleaner.getReturnType().getName()); } System.err.println(); } } /** * If {@code b} is an direct NIO buffer, i.e {@link sun.nio.ch.DirectBuffer}, * calls it's {@link sun.misc.Cleaner} instance {@code clean()} method once. * @return {@code true} if successful, otherwise {@code false}. */ public static boolean clean(final ByteBuffer bb) { if( cleanerError || !bb.isDirect() ) { return false; } try { if( PlatformPropsImpl.JAVA_9 ) { UnsafeUtil.invokeCleaner(bb); } else { cClean.invoke(mbbCleaner.invoke(bb)); } return true; } catch(final Throwable t) { cleanerError = true; if( DEBUG ) { ExceptionUtils.dumpThrowable("Buffers", t); } return false; } } } }