/** * Copyright 2014 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: * * 1. Redistributions of source code must retain the above copyright notice, this list of * conditions and the following disclaimer. * * 2. Redistributions 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. * * THIS SOFTWARE IS PROVIDED BY JogAmp Community ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND * FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL JogAmp Community OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation are those of the * authors and should not be interpreted as representing official policies, either expressed * or implied, of JogAmp Community. */ package com.jogamp.common.util; import java.io.IOException; import java.nio.ByteBuffer; import java.nio.ByteOrder; import java.nio.IntBuffer; import java.nio.LongBuffer; import org.junit.Test; import org.junit.Assert; import com.jogamp.common.nio.Buffers; import com.jogamp.common.os.Platform; import static com.jogamp.common.util.BitDemoData.*; import com.jogamp.junit.util.SingletonJunitCase; import org.junit.FixMethodOrder; import org.junit.runners.MethodSorters; /** * Test basic bit operations for {@link Bitstream} */ @FixMethodOrder(MethodSorters.NAME_ASCENDING) public class TestBitstream00 extends SingletonJunitCase { @Test public void test00ShowByteOrder() { final int i_ff = 0xff; final byte b_ff = (byte)i_ff; System.err.println("i_ff "+i_ff+", "+toHexBinaryString(i_ff, 8)); System.err.println("b_ff "+b_ff+", "+toHexBinaryString(0xff & b_ff, 8)); System.err.println("Platform.LITTLE_ENDIAN: "+Platform.isLittleEndian()); showOrderImpl(null); showOrderImpl(ByteOrder.BIG_ENDIAN); showOrderImpl(ByteOrder.LITTLE_ENDIAN); dumpData("tstMSB.whole", testBytesMSB, 0, testBytesMSB.length); dumpData("tstLSB.pbyte", testBytesLSB_revByte, 0, testBytesLSB_revByte.length); dumpData("tstLSB.whole", testBytesLSB, 0, testBytesLSB.length); } void showOrderImpl(final ByteOrder byteOrder) { final ByteBuffer bb_long = ByteBuffer.allocate(Buffers.SIZEOF_LONG); if( null != byteOrder ) { bb_long.order(byteOrder); } System.err.println("Order: "+byteOrder+" -> "+bb_long.order()); final LongBuffer lb = bb_long.asLongBuffer(); lb.put(0, 0x0807060504030201L); dumpData("long."+byteOrder, bb_long, 0, bb_long.capacity()); final ByteBuffer bb_int = ByteBuffer.allocate(Buffers.SIZEOF_INT); if( null != byteOrder ) { bb_int.order(byteOrder); } final IntBuffer ib = bb_int.asIntBuffer(); ib.put(0, 0x04030201); dumpData("long."+byteOrder, bb_int, 0, bb_int.capacity()); dumpData("tstMSB.whole", testBytesMSB, 0, testBytesMSB.length); dumpData("tstLSB.pbyte", testBytesLSB_revByte, 0, testBytesLSB_revByte.length); dumpData("tstLSB.whole", testBytesLSB, 0, testBytesLSB.length); } @Test public void test01Uint32Conversion() { testUInt32Conversion(1, 1); testUInt32Conversion(-2, -1); testUInt32Conversion(Integer.MAX_VALUE, Integer.MAX_VALUE); testUInt32Conversion(0xffff0000, -1); testUInt32Conversion(0xffffffff, -1); } void testUInt32Conversion(final int int32, final int expUInt32Int) { final String int32_hStr = toHexString(int32); final long l = Bitstream.toUInt32Long(int32); final String l_hStr = toHexString(l); final int i = Bitstream.toUInt32Int(int32); final String i_hStr = toHexString(i); System.err.printf("int32_t %012d %10s -> (long) %012d %10s, (int) %012d %10s%n", int32, int32_hStr, l, l_hStr, i, i_hStr); Assert.assertEquals(int32_hStr, l_hStr); Assert.assertEquals(expUInt32Int, i); } @Test public void test02ShiftSigned() { shiftSigned(0xA0000000); // negative w/ '1010' top-nibble shiftSigned(-1); } void shiftSigned(final int i0) { System.err.printf("i0 %012d, %s%n", i0, toHexBinaryString(i0, 32)); { int im = i0; for(int i=0; i<32; i++) { final int bitA = ( 0 != ( i0 & ( 1 << i ) ) ) ? 1 : 0; final int bitB = im & 0x01; System.err.printf("[%02d]: bit[%d, %d], im %012d, %s%n", i, bitA, bitB, im, toHexBinaryString(im, 32)); im = im >>> 1; } } } @Test public void test10ReadWrite_13() throws UnsupportedOperationException, IllegalStateException, IOException { // H->L : 00000011 00000010 00000001 000000110000001000000001 // H->L rev: 10000000 01000000 11000000 100000000100000011000000 // // L->H : 00000001 00000010 00000011 000000010000001000000011 // L->H rev: 11000000 01000000 10000000 110000000100000010000000 test10ReadWrite1_31Impl(8, 8, 8, 0x030201, "000000110000001000000001"); // H->L: 00011 000010 00001 0001100001000001 // L->H: 10000 010000 11000 1000001000011000 test10ReadWrite1_31Impl(5, 6, 5, 0x1841, "0001100001000001"); } void test10ReadWrite1_31Impl(final int c1, final int c2, final int c3, final int v, final String vStrHigh2LowExp) throws UnsupportedOperationException, IllegalStateException, IOException { // final Bitstream source = new Bitstream(); final int bitCount = c1+c2+c3; final int byteCount = ( bitCount + 7 ) / 8; final String vStrHigh2Low0 = Bitstream.toBinString(true, v, bitCount); System.err.printf("test10ReadWrite31 bits %d:%d:%d = %d = %d bytes%n", c1, c2, c3, bitCount, byteCount); System.err.printf("test10ReadWrite31 %s%n", Bitstream.toHexBinString(true, v, bitCount)); System.err.printf("test10ReadWrite31 %s%n", Bitstream.toHexBinString(false, v, bitCount)); Assert.assertEquals(vStrHigh2LowExp, vStrHigh2Low0); final ByteBuffer bbRead = ByteBuffer.allocate(byteCount); for(int i=0; i>> 8*i ) & 0xff; bbRead.put(i, (byte) b); System.err.printf("testBytes[%d]: %s%n", i, Bitstream.toHexBinString(true, b, 8)); } final Bitstream.ByteBufferStream bbsRead = new Bitstream.ByteBufferStream(bbRead); final Bitstream bsRead = new Bitstream(bbsRead, false /* outputMode */); String vStrHigh2Low1C1 = ""; String vStrHigh2Low1C2 = ""; String vStrHigh2Low1C3 = ""; String vStrHigh2Low1 = ""; { bsRead.mark(byteCount); System.err.println("readBit (msbFirst false): "); int b; int i=0; String vStrHigh2Low1T = ""; // OK for LSB, MSB segmented while( Bitstream.EOS != ( b = bsRead.readBit(false /* msbFirst */) ) ) { vStrHigh2Low1T = b + vStrHigh2Low1T; if(i < c1) { vStrHigh2Low1C1 = b + vStrHigh2Low1C1; } else if(i < c1+c2) { vStrHigh2Low1C2 = b + vStrHigh2Low1C2; } else { vStrHigh2Low1C3 = b + vStrHigh2Low1C3; } i++; } vStrHigh2Low1 = vStrHigh2Low1C3 + vStrHigh2Low1C2 + vStrHigh2Low1C1; System.err.printf("readBit.1 %s, 0x%s%n", vStrHigh2Low1C1, Integer.toHexString(Integer.valueOf(vStrHigh2Low1C1, 2))); System.err.printf("readBit.2 %s, 0x%s%n", vStrHigh2Low1C2, Integer.toHexString(Integer.valueOf(vStrHigh2Low1C2, 2))); System.err.printf("readBit.3 %s, 0x%s%n", vStrHigh2Low1C3, Integer.toHexString(Integer.valueOf(vStrHigh2Low1C3, 2))); System.err.printf("readBit.T %s, ok %b%n%n", vStrHigh2Low1T, vStrHigh2LowExp.equals(vStrHigh2Low1T)); System.err.printf("readBit.X %s, ok %b%n%n", vStrHigh2Low1, vStrHigh2LowExp.equals(vStrHigh2Low1)); bsRead.reset(); } { String vStrHigh2Low3T = ""; // OK for LSB, MSB segmented System.err.println("readBits32: "); final int b = bsRead.readBits31(bitCount); vStrHigh2Low3T = Bitstream.toBinString(true, b, bitCount); System.err.printf("readBits31.T %s, ok %b, %s%n%n", vStrHigh2Low3T, vStrHigh2LowExp.equals(vStrHigh2Low3T), Bitstream.toHexBinString(true, b, bitCount)); bsRead.reset(); } String vStrHigh2Low2 = ""; { System.err.println("readBits32: "); final int bC1 = bsRead.readBits31(c1); System.err.printf("readBits31.1 %s%n", Bitstream.toHexBinString(true, bC1, c1)); final int bC2 = bsRead.readBits31(c2); System.err.printf("readBits31.2 %s%n", Bitstream.toHexBinString(true, bC2, c2)); final int bC3 = bsRead.readBits31(c3); System.err.printf("readBits31.3 %s%n", Bitstream.toHexBinString(true, bC3, c3)); final int b = bC3 << (c1+c2) | bC2 << c1 | bC1; vStrHigh2Low2 = Bitstream.toBinString(true, b, bitCount); System.err.printf("readBits31.X %s, ok %b, %s%n%n", vStrHigh2Low2, vStrHigh2LowExp.equals(vStrHigh2Low2), Bitstream.toHexBinString(true, b, bitCount)); bsRead.reset(); } Assert.assertEquals(vStrHigh2LowExp, vStrHigh2Low1); Assert.assertEquals(vStrHigh2LowExp, vStrHigh2Low2); boolean ok = true; { final ByteBuffer bbWrite = ByteBuffer.allocate(byteCount); final Bitstream.ByteBufferStream bbsWrite = new Bitstream.ByteBufferStream(bbWrite); final Bitstream bsWrite = new Bitstream(bbsWrite, true /* outputMode */); { int b; while( Bitstream.EOS != ( b = bsRead.readBit(false)) ) { bsWrite.writeBit(false, b); } } bsRead.reset(); for(int i=0; i bsWrite = new Bitstream(bbsWrite, true /* outputMode */); { bsWrite.writeBits31(bitCount, bsRead.readBits31(bitCount)); } bsRead.reset(); for(int i=0; i