third_party/protobuf/3.6.1/java/core/src/test/java/com/google/protobuf/LiteralByteStringTest.java - bazel - Git at Google

 // Protocol Buffers - Google's data interchange format
 // Copyright 2008 Google Inc.  All rights reserved.
 // https://developers.google.com/protocol-buffers/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 // notice, this list of conditions and the following disclaimer.
 //     * 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.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "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 THE COPYRIGHT
 // OWNER 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.

 package com.google.protobuf;

 import java.io.ByteArrayInputStream;
 import java.io.ByteArrayOutputStream;
 import java.io.EOFException;
 import java.io.IOException;
 import java.io.InputStream;
 import java.io.ObjectInputStream;
 import java.io.ObjectOutputStream;
 import java.io.OutputStream;
 import java.io.UnsupportedEncodingException;
 import java.nio.ByteBuffer;
 import java.util.Arrays;
 import java.util.List;
 import java.util.NoSuchElementException;
 import junit.framework.TestCase;

 /**
  * Test {@code LiteralByteString} by setting up a reference string in {@link #setUp()}.
  * This class is designed to be extended for testing extensions of {@code LiteralByteString}
  * such as {@code BoundedByteString}, see {@link BoundedByteStringTest}.
  *
  * @author carlanton@google.com (Carl Haverl)
  */
 public class LiteralByteStringTest extends TestCase {
   protected static final String UTF_8 = "UTF-8";

   protected String classUnderTest;
   protected byte[] referenceBytes;
   protected ByteString stringUnderTest;
   protected int expectedHashCode;

   @Override
   protected void setUp() throws Exception {
     classUnderTest = "LiteralByteString";
     referenceBytes = ByteStringTest.getTestBytes(1234, 11337766L);
     stringUnderTest = ByteString.copyFrom(referenceBytes);
     expectedHashCode = 331161852;
   }

   public void testExpectedType() {
     String actualClassName = getActualClassName(stringUnderTest);
     assertEquals(classUnderTest + " should match type exactly", classUnderTest, actualClassName);
   }

   protected String getActualClassName(Object object) {
     return object.getClass().getSimpleName();
   }

   public void testByteAt() {
     boolean stillEqual = true;
     for (int i = 0; stillEqual && i < referenceBytes.length; ++i) {
       stillEqual = (referenceBytes[i] == stringUnderTest.byteAt(i));
     }
     assertTrue(classUnderTest + " must capture the right bytes", stillEqual);
   }

   public void testByteIterator() {
     boolean stillEqual = true;
     ByteString.ByteIterator iter = stringUnderTest.iterator();
     for (int i = 0; stillEqual && i < referenceBytes.length; ++i) {
       stillEqual = (iter.hasNext() && referenceBytes[i] == iter.nextByte());
     }
     assertTrue(classUnderTest + " must capture the right bytes", stillEqual);
     assertFalse(classUnderTest + " must have exhausted the itertor", iter.hasNext());

     try {
       iter.nextByte();
       fail("Should have thrown an exception.");
     } catch (NoSuchElementException e) {
       // This is success
     }
   }

   public void testByteIterable() {
     boolean stillEqual = true;
     int j = 0;
     for (byte quantum : stringUnderTest) {
       stillEqual = (referenceBytes[j] == quantum);
       ++j;
     }
     assertTrue(classUnderTest + " must capture the right bytes as Bytes", stillEqual);
     assertEquals(classUnderTest + " iterable character count", referenceBytes.length, j);
   }

   public void testSize() {
     assertEquals(classUnderTest + " must have the expected size", referenceBytes.length,
         stringUnderTest.size());
   }

   public void testGetTreeDepth() {
     assertEquals(classUnderTest + " must have depth 0", 0, stringUnderTest.getTreeDepth());
   }

   public void testIsBalanced() {
     assertTrue(classUnderTest + " is technically balanced", stringUnderTest.isBalanced());
   }

   public void testCopyTo_ByteArrayOffsetLength() {
     int destinationOffset = 50;
     int length = 100;
     byte[] destination = new byte[destinationOffset + length];
     int sourceOffset = 213;
     stringUnderTest.copyTo(destination, sourceOffset, destinationOffset, length);
     boolean stillEqual = true;
     for (int i = 0; stillEqual && i < length; ++i) {
       stillEqual = referenceBytes[i + sourceOffset] == destination[i + destinationOffset];
     }
     assertTrue(classUnderTest + ".copyTo(4 arg) must give the expected bytes", stillEqual);
   }

   public void testCopyTo_ByteArrayOffsetLengthErrors() {
     int destinationOffset = 50;
     int length = 100;
     byte[] destination = new byte[destinationOffset + length];

     try {
       // Copy one too many bytes
       stringUnderTest.copyTo(destination, stringUnderTest.size() + 1 - length,
           destinationOffset, length);
       fail("Should have thrown an exception when copying too many bytes of a "
           + classUnderTest);
     } catch (IndexOutOfBoundsException expected) {
       // This is success
     }

     try {
       // Copy with illegal negative sourceOffset
       stringUnderTest.copyTo(destination, -1, destinationOffset, length);
       fail("Should have thrown an exception when given a negative sourceOffset in "
           + classUnderTest);
     } catch (IndexOutOfBoundsException expected) {
       // This is success
     }

     try {
       // Copy with illegal negative destinationOffset
       stringUnderTest.copyTo(destination, 0, -1, length);
       fail("Should have thrown an exception when given a negative destinationOffset in "
           + classUnderTest);
     } catch (IndexOutOfBoundsException expected) {
       // This is success
     }

     try {
       // Copy with illegal negative size
       stringUnderTest.copyTo(destination, 0, 0, -1);
       fail("Should have thrown an exception when given a negative size in "
           + classUnderTest);
     } catch (IndexOutOfBoundsException expected) {
       // This is success
     }

     try {
       // Copy with illegal too-large sourceOffset
       stringUnderTest.copyTo(destination, 2 * stringUnderTest.size(), 0, length);
       fail("Should have thrown an exception when the destinationOffset is too large in "
           + classUnderTest);
     } catch (IndexOutOfBoundsException expected) {
       // This is success
     }

     try {
       // Copy with illegal too-large destinationOffset
       stringUnderTest.copyTo(destination, 0, 2 * destination.length, length);
       fail("Should have thrown an exception when the destinationOffset is too large in "
           + classUnderTest);
     } catch (IndexOutOfBoundsException expected) {
       // This is success
     }
   }

   public void testCopyTo_ByteBuffer() {
     ByteBuffer myBuffer = ByteBuffer.allocate(referenceBytes.length);
     stringUnderTest.copyTo(myBuffer);
     assertTrue(classUnderTest + ".copyTo(ByteBuffer) must give back the same bytes",
         Arrays.equals(referenceBytes, myBuffer.array()));
   }

   public void testMarkSupported() {
     InputStream stream = stringUnderTest.newInput();
     assertTrue(classUnderTest + ".newInput() must support marking", stream.markSupported());
   }

   public void testMarkAndReset() throws IOException {
     int fraction = stringUnderTest.size() / 3;

     InputStream stream = stringUnderTest.newInput();
     stream.mark(stringUnderTest.size()); // First, mark() the end.

     skipFully(stream, fraction); // Skip a large fraction, but not all.
     int available = stream.available();
     assertTrue(
         classUnderTest + ": after skipping to the 'middle', half the bytes are available",
         (stringUnderTest.size() - fraction) == available);
     stream.reset();

     skipFully(stream, stringUnderTest.size()); // Skip to the end.
     available = stream.available();
     assertTrue(
         classUnderTest + ": after skipping to the end, no more bytes are available",
         0 == available);
   }

   /**
    * Discards {@code n} bytes of data from the input stream. This method
    * will block until the full amount has been skipped. Does not close the
    * stream.
    * <p>Copied from com.google.common.io.ByteStreams to avoid adding dependency.
    *
    * @param in the input stream to read from
    * @param n the number of bytes to skip
    * @throws EOFException if this stream reaches the end before skipping all
    *     the bytes
    * @throws IOException if an I/O error occurs, or the stream does not
    *     support skipping
    */
   static void skipFully(InputStream in, long n) throws IOException {
     long toSkip = n;
     while (n > 0) {
       long amt = in.skip(n);
       if (amt == 0) {
         // Force a blocking read to avoid infinite loop
         if (in.read() == -1) {
           long skipped = toSkip - n;
           throw new EOFException("reached end of stream after skipping "
               + skipped + " bytes; " + toSkip + " bytes expected");
         }
         n--;
       } else {
         n -= amt;
       }
     }
   }

   public void testAsReadOnlyByteBuffer() {
     ByteBuffer byteBuffer = stringUnderTest.asReadOnlyByteBuffer();
     byte[] roundTripBytes = new byte[referenceBytes.length];
     assertTrue(byteBuffer.remaining() == referenceBytes.length);
     assertTrue(byteBuffer.isReadOnly());
     byteBuffer.get(roundTripBytes);
     assertTrue(classUnderTest + ".asReadOnlyByteBuffer() must give back the same bytes",
         Arrays.equals(referenceBytes, roundTripBytes));
   }

   public void testAsReadOnlyByteBufferList() {
     List<ByteBuffer> byteBuffers = stringUnderTest.asReadOnlyByteBufferList();
     int bytesSeen = 0;
     byte[] roundTripBytes = new byte[referenceBytes.length];
     for (ByteBuffer byteBuffer : byteBuffers) {
       int thisLength = byteBuffer.remaining();
       assertTrue(byteBuffer.isReadOnly());
       assertTrue(bytesSeen + thisLength <= referenceBytes.length);
       byteBuffer.get(roundTripBytes, bytesSeen, thisLength);
       bytesSeen += thisLength;
     }
     assertTrue(bytesSeen == referenceBytes.length);
     assertTrue(classUnderTest + ".asReadOnlyByteBufferTest() must give back the same bytes",
         Arrays.equals(referenceBytes, roundTripBytes));
   }

   public void testToByteArray() {
     byte[] roundTripBytes = stringUnderTest.toByteArray();
     assertTrue(classUnderTest + ".toByteArray() must give back the same bytes",
         Arrays.equals(referenceBytes, roundTripBytes));
   }

   public void testWriteTo() throws IOException {
     ByteArrayOutputStream bos = new ByteArrayOutputStream();
     stringUnderTest.writeTo(bos);
     byte[] roundTripBytes = bos.toByteArray();
     assertTrue(classUnderTest + ".writeTo() must give back the same bytes",
         Arrays.equals(referenceBytes, roundTripBytes));
   }

   public void testWriteToShouldNotExposeInternalBufferToOutputStream() throws IOException {
     OutputStream os = new OutputStream() {
       @Override
       public void write(byte[] b, int off, int len) {
         Arrays.fill(b, off, off + len, (byte) 0);
       }

       @Override
       public void write(int b) {
         throw new UnsupportedOperationException();
       }
     };

     stringUnderTest.writeTo(os);
     assertTrue(classUnderTest + ".writeTo() must not grant access to underlying array",
         Arrays.equals(referenceBytes, stringUnderTest.toByteArray()));
   }

   public void testWriteToInternalShouldExposeInternalBufferToOutputStream() throws IOException {
     OutputStream os = new OutputStream() {
       @Override
       public void write(byte[] b, int off, int len) {
         Arrays.fill(b, off, off + len, (byte) 0);
       }

       @Override
       public void write(int b) {
         throw new UnsupportedOperationException();
       }
     };

     stringUnderTest.writeToInternal(os, 0, stringUnderTest.size());
     byte[] allZeros = new byte[stringUnderTest.size()];
     assertTrue(classUnderTest + ".writeToInternal() must grant access to underlying array",
         Arrays.equals(allZeros, stringUnderTest.toByteArray()));
   }

   public void testWriteToShouldExposeInternalBufferToByteOutput() throws IOException {
     ByteOutput out = new ByteOutput() {
       @Override
       public void write(byte value) throws IOException {
         throw new UnsupportedOperationException();
       }

       @Override
       public void write(byte[] value, int offset, int length) throws IOException {
         throw new UnsupportedOperationException();
       }

       @Override
       public void writeLazy(byte[] value, int offset, int length) throws IOException {
         Arrays.fill(value, offset, offset + length, (byte) 0);
       }

       @Override
       public void write(ByteBuffer value) throws IOException {
         throw new UnsupportedOperationException();
       }

       @Override
       public void writeLazy(ByteBuffer value) throws IOException {
         throw new UnsupportedOperationException();
       }
     };

     stringUnderTest.writeTo(out);
     byte[] allZeros = new byte[stringUnderTest.size()];
     assertTrue(classUnderTest + ".writeToInternal() must grant access to underlying array",
         Arrays.equals(allZeros, stringUnderTest.toByteArray()));
   }

   public void testNewOutput() throws IOException {
     ByteArrayOutputStream bos = new ByteArrayOutputStream();
     ByteString.Output output = ByteString.newOutput();
     stringUnderTest.writeTo(output);
     assertEquals("Output Size returns correct result",
         output.size(), stringUnderTest.size());
     output.writeTo(bos);
     assertTrue("Output.writeTo() must give back the same bytes",
         Arrays.equals(referenceBytes, bos.toByteArray()));

     // write the output stream to itself! This should cause it to double
     output.writeTo(output);
     assertEquals("Writing an output stream to itself is successful",
         stringUnderTest.concat(stringUnderTest), output.toByteString());

     output.reset();
     assertEquals("Output.reset() resets the output", 0, output.size());
     assertEquals("Output.reset() resets the output",
         ByteString.EMPTY, output.toByteString());
   }

   public void testToString() throws UnsupportedEncodingException {
     String testString = "I love unicode \u1234\u5678 characters";
     ByteString unicode = ByteString.wrap(testString.getBytes(Internal.UTF_8));
     String roundTripString = unicode.toString(UTF_8);
     assertEquals(classUnderTest + " unicode must match", testString, roundTripString);
   }

   public void testCharsetToString() {
     String testString = "I love unicode \u1234\u5678 characters";
     ByteString unicode = ByteString.wrap(testString.getBytes(Internal.UTF_8));
     String roundTripString = unicode.toString(Internal.UTF_8);
     assertEquals(classUnderTest + " unicode must match", testString, roundTripString);
   }

   public void testToString_returnsCanonicalEmptyString() {
     assertSame(classUnderTest + " must be the same string references",
         ByteString.EMPTY.toString(Internal.UTF_8),
         ByteString.wrap(new byte[]{}).toString(Internal.UTF_8));
   }

   public void testToString_raisesException() {
     try {
       ByteString.EMPTY.toString("invalid");
       fail("Should have thrown an exception.");
     } catch (UnsupportedEncodingException expected) {
       // This is success
     }

     try {
       ByteString.wrap(referenceBytes).toString("invalid");
       fail("Should have thrown an exception.");
     } catch (UnsupportedEncodingException expected) {
       // This is success
     }
   }

   public void testEquals() {
     assertEquals(classUnderTest + " must not equal null", false, stringUnderTest.equals(null));
     assertEquals(classUnderTest + " must equal self", stringUnderTest, stringUnderTest);
     assertFalse(classUnderTest + " must not equal the empty string",
         stringUnderTest.equals(ByteString.EMPTY));
     assertEquals(classUnderTest + " empty strings must be equal",
         ByteString.wrap(new byte[]{}), stringUnderTest.substring(55, 55));
     assertEquals(classUnderTest + " must equal another string with the same value",
         stringUnderTest, ByteString.wrap(referenceBytes));

     byte[] mungedBytes = new byte[referenceBytes.length];
     System.arraycopy(referenceBytes, 0, mungedBytes, 0, referenceBytes.length);
     mungedBytes[mungedBytes.length - 5] = (byte) (mungedBytes[mungedBytes.length - 5] ^ 0xFF);
     assertFalse(classUnderTest + " must not equal every string with the same length",
         stringUnderTest.equals(ByteString.wrap(mungedBytes)));
   }

   public void testHashCode() {
     int hash = stringUnderTest.hashCode();
     assertEquals(classUnderTest + " must have expected hashCode", expectedHashCode, hash);
   }

   public void testPeekCachedHashCode() {
     assertEquals(classUnderTest + ".peekCachedHashCode() should return zero at first", 0,
         stringUnderTest.peekCachedHashCode());
     stringUnderTest.hashCode();
     assertEquals(classUnderTest + ".peekCachedHashCode should return zero at first",
         expectedHashCode, stringUnderTest.peekCachedHashCode());
   }

   public void testPartialHash() {
     // partialHash() is more strenuously tested elsewhere by testing hashes of substrings.
     // This test would fail if the expected hash were 1.  It's not.
     int hash = stringUnderTest.partialHash(stringUnderTest.size(), 0, stringUnderTest.size());
     assertEquals(classUnderTest + ".partialHash() must yield expected hashCode",
         expectedHashCode, hash);
   }

   public void testNewInput() throws IOException {
     InputStream input = stringUnderTest.newInput();
     assertEquals("InputStream.available() returns correct value",
         stringUnderTest.size(), input.available());
     boolean stillEqual = true;
     for (byte referenceByte : referenceBytes) {
       int expectedInt = (referenceByte & 0xFF);
       stillEqual = (expectedInt == input.read());
     }
     assertEquals("InputStream.available() returns correct value",
         0, input.available());
     assertTrue(classUnderTest + " must give the same bytes from the InputStream", stillEqual);
     assertEquals(classUnderTest + " InputStream must now be exhausted", -1, input.read());
   }

   public void testNewInput_skip() throws IOException {
     InputStream input = stringUnderTest.newInput();
     int stringSize = stringUnderTest.size();
     int nearEndIndex = stringSize * 2 / 3;
     long skipped1 = input.skip(nearEndIndex);
     assertEquals("InputStream.skip()", skipped1, nearEndIndex);
     assertEquals("InputStream.available()",
         stringSize - skipped1, input.available());
     assertTrue("InputStream.mark() is available", input.markSupported());
     input.mark(0);
     assertEquals("InputStream.skip(), read()",
         stringUnderTest.byteAt(nearEndIndex) & 0xFF, input.read());
     assertEquals("InputStream.available()",
                  stringSize - skipped1 - 1, input.available());
     long skipped2 = input.skip(stringSize);
     assertEquals("InputStream.skip() incomplete",
         skipped2, stringSize - skipped1 - 1);
     assertEquals("InputStream.skip(), no more input", 0, input.available());
     assertEquals("InputStream.skip(), no more input", -1, input.read());
     input.reset();
     assertEquals("InputStream.reset() succeded",
                  stringSize - skipped1, input.available());
     assertEquals("InputStream.reset(), read()",
         stringUnderTest.byteAt(nearEndIndex) & 0xFF, input.read());
   }

   public void testNewCodedInput() throws IOException {
     CodedInputStream cis = stringUnderTest.newCodedInput();
     byte[] roundTripBytes = cis.readRawBytes(referenceBytes.length);
     assertTrue(classUnderTest + " must give the same bytes back from the CodedInputStream",
         Arrays.equals(referenceBytes, roundTripBytes));
     assertTrue(classUnderTest + " CodedInputStream must now be exhausted", cis.isAtEnd());
   }

   /**
    * Make sure we keep things simple when concatenating with empty. See also
    * {@link ByteStringTest#testConcat_empty()}.
    */
   public void testConcat_empty() {
     assertSame(classUnderTest + " concatenated with empty must give " + classUnderTest,
         stringUnderTest.concat(ByteString.EMPTY), stringUnderTest);
     assertSame("empty concatenated with " + classUnderTest + " must give " + classUnderTest,
         ByteString.EMPTY.concat(stringUnderTest), stringUnderTest);
   }

   public void testJavaSerialization() throws Exception {
     ByteArrayOutputStream out = new ByteArrayOutputStream();
     ObjectOutputStream oos = new ObjectOutputStream(out);
     oos.writeObject(stringUnderTest);
     oos.close();
     byte[] pickled = out.toByteArray();
     InputStream in = new ByteArrayInputStream(pickled);
     ObjectInputStream ois = new ObjectInputStream(in);
     Object o = ois.readObject();
     assertTrue("Didn't get a ByteString back", o instanceof ByteString);
     assertEquals("Should get an equal ByteString back", stringUnderTest, o);
   }
 }
	// Protocol Buffers - Google's data interchange format
	// Copyright 2008 Google Inc. All rights reserved.
	// https://developers.google.com/protocol-buffers/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * 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.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "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 THE COPYRIGHT
	// OWNER 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.

	package com.google.protobuf;

	import java.io.ByteArrayInputStream;
	import java.io.ByteArrayOutputStream;
	import java.io.EOFException;
	import java.io.IOException;
	import java.io.InputStream;
	import java.io.ObjectInputStream;
	import java.io.ObjectOutputStream;
	import java.io.OutputStream;
	import java.io.UnsupportedEncodingException;
	import java.nio.ByteBuffer;
	import java.util.Arrays;
	import java.util.List;
	import java.util.NoSuchElementException;
	import junit.framework.TestCase;

	/**
	* Test {@code LiteralByteString} by setting up a reference string in {@link #setUp()}.
	* This class is designed to be extended for testing extensions of {@code LiteralByteString}
	* such as {@code BoundedByteString}, see {@link BoundedByteStringTest}.
	*
	* @author carlanton@google.com (Carl Haverl)
	*/
	public class LiteralByteStringTest extends TestCase {
	protected static final String UTF_8 = "UTF-8";

	protected String classUnderTest;
	protected byte[] referenceBytes;
	protected ByteString stringUnderTest;
	protected int expectedHashCode;

	@Override
	protected void setUp() throws Exception {
	classUnderTest = "LiteralByteString";
	referenceBytes = ByteStringTest.getTestBytes(1234, 11337766L);
	stringUnderTest = ByteString.copyFrom(referenceBytes);
	expectedHashCode = 331161852;
	}

	public void testExpectedType() {
	String actualClassName = getActualClassName(stringUnderTest);
	assertEquals(classUnderTest + " should match type exactly", classUnderTest, actualClassName);
	}

	protected String getActualClassName(Object object) {
	return object.getClass().getSimpleName();
	}

	public void testByteAt() {
	boolean stillEqual = true;
	for (int i = 0; stillEqual && i < referenceBytes.length; ++i) {
	stillEqual = (referenceBytes[i] == stringUnderTest.byteAt(i));
	}
	assertTrue(classUnderTest + " must capture the right bytes", stillEqual);
	}

	public void testByteIterator() {
	boolean stillEqual = true;
	ByteString.ByteIterator iter = stringUnderTest.iterator();
	for (int i = 0; stillEqual && i < referenceBytes.length; ++i) {
	stillEqual = (iter.hasNext() && referenceBytes[i] == iter.nextByte());
	}
	assertTrue(classUnderTest + " must capture the right bytes", stillEqual);
	assertFalse(classUnderTest + " must have exhausted the itertor", iter.hasNext());

	try {
	iter.nextByte();
	fail("Should have thrown an exception.");
	} catch (NoSuchElementException e) {
	// This is success
	}
	}

	public void testByteIterable() {
	boolean stillEqual = true;
	int j = 0;
	for (byte quantum : stringUnderTest) {
	stillEqual = (referenceBytes[j] == quantum);
	++j;
	}
	assertTrue(classUnderTest + " must capture the right bytes as Bytes", stillEqual);
	assertEquals(classUnderTest + " iterable character count", referenceBytes.length, j);
	}

	public void testSize() {
	assertEquals(classUnderTest + " must have the expected size", referenceBytes.length,
	stringUnderTest.size());
	}

	public void testGetTreeDepth() {
	assertEquals(classUnderTest + " must have depth 0", 0, stringUnderTest.getTreeDepth());
	}

	public void testIsBalanced() {
	assertTrue(classUnderTest + " is technically balanced", stringUnderTest.isBalanced());
	}

	public void testCopyTo_ByteArrayOffsetLength() {
	int destinationOffset = 50;
	int length = 100;
	byte[] destination = new byte[destinationOffset + length];
	int sourceOffset = 213;
	stringUnderTest.copyTo(destination, sourceOffset, destinationOffset, length);
	boolean stillEqual = true;
	for (int i = 0; stillEqual && i < length; ++i) {
	stillEqual = referenceBytes[i + sourceOffset] == destination[i + destinationOffset];
	}
	assertTrue(classUnderTest + ".copyTo(4 arg) must give the expected bytes", stillEqual);
	}

	public void testCopyTo_ByteArrayOffsetLengthErrors() {
	int destinationOffset = 50;
	int length = 100;
	byte[] destination = new byte[destinationOffset + length];

	try {
	// Copy one too many bytes
	stringUnderTest.copyTo(destination, stringUnderTest.size() + 1 - length,
	destinationOffset, length);
	fail("Should have thrown an exception when copying too many bytes of a "
	+ classUnderTest);
	} catch (IndexOutOfBoundsException expected) {
	// This is success
	}

	try {
	// Copy with illegal negative sourceOffset
	stringUnderTest.copyTo(destination, -1, destinationOffset, length);
	fail("Should have thrown an exception when given a negative sourceOffset in "
	+ classUnderTest);
	} catch (IndexOutOfBoundsException expected) {
	// This is success
	}

	try {
	// Copy with illegal negative destinationOffset
	stringUnderTest.copyTo(destination, 0, -1, length);
	fail("Should have thrown an exception when given a negative destinationOffset in "
	+ classUnderTest);
	} catch (IndexOutOfBoundsException expected) {
	// This is success
	}

	try {
	// Copy with illegal negative size
	stringUnderTest.copyTo(destination, 0, 0, -1);
	fail("Should have thrown an exception when given a negative size in "
	+ classUnderTest);
	} catch (IndexOutOfBoundsException expected) {
	// This is success
	}

	try {
	// Copy with illegal too-large sourceOffset
	stringUnderTest.copyTo(destination, 2 * stringUnderTest.size(), 0, length);
	fail("Should have thrown an exception when the destinationOffset is too large in "
	+ classUnderTest);
	} catch (IndexOutOfBoundsException expected) {
	// This is success
	}

	try {
	// Copy with illegal too-large destinationOffset
	stringUnderTest.copyTo(destination, 0, 2 * destination.length, length);
	fail("Should have thrown an exception when the destinationOffset is too large in "
	+ classUnderTest);
	} catch (IndexOutOfBoundsException expected) {
	// This is success
	}
	}

	public void testCopyTo_ByteBuffer() {
	ByteBuffer myBuffer = ByteBuffer.allocate(referenceBytes.length);
	stringUnderTest.copyTo(myBuffer);
	assertTrue(classUnderTest + ".copyTo(ByteBuffer) must give back the same bytes",
	Arrays.equals(referenceBytes, myBuffer.array()));
	}

	public void testMarkSupported() {
	InputStream stream = stringUnderTest.newInput();
	assertTrue(classUnderTest + ".newInput() must support marking", stream.markSupported());
	}

	public void testMarkAndReset() throws IOException {
	int fraction = stringUnderTest.size() / 3;

	InputStream stream = stringUnderTest.newInput();
	stream.mark(stringUnderTest.size()); // First, mark() the end.

	skipFully(stream, fraction); // Skip a large fraction, but not all.
	int available = stream.available();
	assertTrue(
	classUnderTest + ": after skipping to the 'middle', half the bytes are available",
	(stringUnderTest.size() - fraction) == available);
	stream.reset();

	skipFully(stream, stringUnderTest.size()); // Skip to the end.
	available = stream.available();
	assertTrue(
	classUnderTest + ": after skipping to the end, no more bytes are available",
	0 == available);
	}

	/**
	* Discards {@code n} bytes of data from the input stream. This method
	* will block until the full amount has been skipped. Does not close the
	* stream.
	* <p>Copied from com.google.common.io.ByteStreams to avoid adding dependency.
	*
	* @param in the input stream to read from
	* @param n the number of bytes to skip
	* @throws EOFException if this stream reaches the end before skipping all
	* the bytes
	* @throws IOException if an I/O error occurs, or the stream does not
	* support skipping
	*/
	static void skipFully(InputStream in, long n) throws IOException {
	long toSkip = n;
	while (n > 0) {
	long amt = in.skip(n);
	if (amt == 0) {
	// Force a blocking read to avoid infinite loop
	if (in.read() == -1) {
	long skipped = toSkip - n;
	throw new EOFException("reached end of stream after skipping "
	+ skipped + " bytes; " + toSkip + " bytes expected");
	}
	n--;
	} else {
	n -= amt;
	}
	}
	}

	public void testAsReadOnlyByteBuffer() {
	ByteBuffer byteBuffer = stringUnderTest.asReadOnlyByteBuffer();
	byte[] roundTripBytes = new byte[referenceBytes.length];
	assertTrue(byteBuffer.remaining() == referenceBytes.length);
	assertTrue(byteBuffer.isReadOnly());
	byteBuffer.get(roundTripBytes);
	assertTrue(classUnderTest + ".asReadOnlyByteBuffer() must give back the same bytes",
	Arrays.equals(referenceBytes, roundTripBytes));
	}

	public void testAsReadOnlyByteBufferList() {
	List<ByteBuffer> byteBuffers = stringUnderTest.asReadOnlyByteBufferList();
	int bytesSeen = 0;
	byte[] roundTripBytes = new byte[referenceBytes.length];
	for (ByteBuffer byteBuffer : byteBuffers) {
	int thisLength = byteBuffer.remaining();
	assertTrue(byteBuffer.isReadOnly());
	assertTrue(bytesSeen + thisLength <= referenceBytes.length);
	byteBuffer.get(roundTripBytes, bytesSeen, thisLength);
	bytesSeen += thisLength;
	}
	assertTrue(bytesSeen == referenceBytes.length);
	assertTrue(classUnderTest + ".asReadOnlyByteBufferTest() must give back the same bytes",
	Arrays.equals(referenceBytes, roundTripBytes));
	}

	public void testToByteArray() {
	byte[] roundTripBytes = stringUnderTest.toByteArray();
	assertTrue(classUnderTest + ".toByteArray() must give back the same bytes",
	Arrays.equals(referenceBytes, roundTripBytes));
	}

	public void testWriteTo() throws IOException {
	ByteArrayOutputStream bos = new ByteArrayOutputStream();
	stringUnderTest.writeTo(bos);
	byte[] roundTripBytes = bos.toByteArray();
	assertTrue(classUnderTest + ".writeTo() must give back the same bytes",
	Arrays.equals(referenceBytes, roundTripBytes));
	}

	public void testWriteToShouldNotExposeInternalBufferToOutputStream() throws IOException {
	OutputStream os = new OutputStream() {
	@Override
	public void write(byte[] b, int off, int len) {
	Arrays.fill(b, off, off + len, (byte) 0);
	}

	@Override
	public void write(int b) {
	throw new UnsupportedOperationException();
	}
	};

	stringUnderTest.writeTo(os);
	assertTrue(classUnderTest + ".writeTo() must not grant access to underlying array",
	Arrays.equals(referenceBytes, stringUnderTest.toByteArray()));
	}

	public void testWriteToInternalShouldExposeInternalBufferToOutputStream() throws IOException {
	OutputStream os = new OutputStream() {
	@Override
	public void write(byte[] b, int off, int len) {
	Arrays.fill(b, off, off + len, (byte) 0);
	}

	@Override
	public void write(int b) {
	throw new UnsupportedOperationException();
	}
	};

	stringUnderTest.writeToInternal(os, 0, stringUnderTest.size());
	byte[] allZeros = new byte[stringUnderTest.size()];
	assertTrue(classUnderTest + ".writeToInternal() must grant access to underlying array",
	Arrays.equals(allZeros, stringUnderTest.toByteArray()));
	}

	public void testWriteToShouldExposeInternalBufferToByteOutput() throws IOException {
	ByteOutput out = new ByteOutput() {
	@Override
	public void write(byte value) throws IOException {
	throw new UnsupportedOperationException();
	}

	@Override
	public void write(byte[] value, int offset, int length) throws IOException {
	throw new UnsupportedOperationException();
	}

	@Override
	public void writeLazy(byte[] value, int offset, int length) throws IOException {
	Arrays.fill(value, offset, offset + length, (byte) 0);
	}

	@Override
	public void write(ByteBuffer value) throws IOException {
	throw new UnsupportedOperationException();
	}

	@Override
	public void writeLazy(ByteBuffer value) throws IOException {
	throw new UnsupportedOperationException();
	}
	};

	stringUnderTest.writeTo(out);
	byte[] allZeros = new byte[stringUnderTest.size()];
	assertTrue(classUnderTest + ".writeToInternal() must grant access to underlying array",
	Arrays.equals(allZeros, stringUnderTest.toByteArray()));
	}

	public void testNewOutput() throws IOException {
	ByteArrayOutputStream bos = new ByteArrayOutputStream();
	ByteString.Output output = ByteString.newOutput();
	stringUnderTest.writeTo(output);
	assertEquals("Output Size returns correct result",
	output.size(), stringUnderTest.size());
	output.writeTo(bos);
	assertTrue("Output.writeTo() must give back the same bytes",
	Arrays.equals(referenceBytes, bos.toByteArray()));

	// write the output stream to itself! This should cause it to double
	output.writeTo(output);
	assertEquals("Writing an output stream to itself is successful",
	stringUnderTest.concat(stringUnderTest), output.toByteString());

	output.reset();
	assertEquals("Output.reset() resets the output", 0, output.size());
	assertEquals("Output.reset() resets the output",
	ByteString.EMPTY, output.toByteString());
	}

	public void testToString() throws UnsupportedEncodingException {
	String testString = "I love unicode \u1234\u5678 characters";
	ByteString unicode = ByteString.wrap(testString.getBytes(Internal.UTF_8));
	String roundTripString = unicode.toString(UTF_8);
	assertEquals(classUnderTest + " unicode must match", testString, roundTripString);
	}

	public void testCharsetToString() {
	String testString = "I love unicode \u1234\u5678 characters";
	ByteString unicode = ByteString.wrap(testString.getBytes(Internal.UTF_8));
	String roundTripString = unicode.toString(Internal.UTF_8);
	assertEquals(classUnderTest + " unicode must match", testString, roundTripString);
	}

	public void testToString_returnsCanonicalEmptyString() {
	assertSame(classUnderTest + " must be the same string references",
	ByteString.EMPTY.toString(Internal.UTF_8),
	ByteString.wrap(new byte[]{}).toString(Internal.UTF_8));
	}

	public void testToString_raisesException() {
	try {
	ByteString.EMPTY.toString("invalid");
	fail("Should have thrown an exception.");
	} catch (UnsupportedEncodingException expected) {
	// This is success
	}

	try {
	ByteString.wrap(referenceBytes).toString("invalid");
	fail("Should have thrown an exception.");
	} catch (UnsupportedEncodingException expected) {
	// This is success
	}
	}

	public void testEquals() {
	assertEquals(classUnderTest + " must not equal null", false, stringUnderTest.equals(null));
	assertEquals(classUnderTest + " must equal self", stringUnderTest, stringUnderTest);
	assertFalse(classUnderTest + " must not equal the empty string",
	stringUnderTest.equals(ByteString.EMPTY));
	assertEquals(classUnderTest + " empty strings must be equal",
	ByteString.wrap(new byte[]{}), stringUnderTest.substring(55, 55));
	assertEquals(classUnderTest + " must equal another string with the same value",
	stringUnderTest, ByteString.wrap(referenceBytes));

	byte[] mungedBytes = new byte[referenceBytes.length];
	System.arraycopy(referenceBytes, 0, mungedBytes, 0, referenceBytes.length);
	mungedBytes[mungedBytes.length - 5] = (byte) (mungedBytes[mungedBytes.length - 5] ^ 0xFF);
	assertFalse(classUnderTest + " must not equal every string with the same length",
	stringUnderTest.equals(ByteString.wrap(mungedBytes)));
	}

	public void testHashCode() {
	int hash = stringUnderTest.hashCode();
	assertEquals(classUnderTest + " must have expected hashCode", expectedHashCode, hash);
	}

	public void testPeekCachedHashCode() {
	assertEquals(classUnderTest + ".peekCachedHashCode() should return zero at first", 0,
	stringUnderTest.peekCachedHashCode());
	stringUnderTest.hashCode();
	assertEquals(classUnderTest + ".peekCachedHashCode should return zero at first",
	expectedHashCode, stringUnderTest.peekCachedHashCode());
	}

	public void testPartialHash() {
	// partialHash() is more strenuously tested elsewhere by testing hashes of substrings.
	// This test would fail if the expected hash were 1. It's not.
	int hash = stringUnderTest.partialHash(stringUnderTest.size(), 0, stringUnderTest.size());
	assertEquals(classUnderTest + ".partialHash() must yield expected hashCode",
	expectedHashCode, hash);
	}

	public void testNewInput() throws IOException {
	InputStream input = stringUnderTest.newInput();
	assertEquals("InputStream.available() returns correct value",
	stringUnderTest.size(), input.available());
	boolean stillEqual = true;
	for (byte referenceByte : referenceBytes) {
	int expectedInt = (referenceByte & 0xFF);
	stillEqual = (expectedInt == input.read());
	}
	assertEquals("InputStream.available() returns correct value",
	0, input.available());
	assertTrue(classUnderTest + " must give the same bytes from the InputStream", stillEqual);
	assertEquals(classUnderTest + " InputStream must now be exhausted", -1, input.read());
	}

	public void testNewInput_skip() throws IOException {
	InputStream input = stringUnderTest.newInput();
	int stringSize = stringUnderTest.size();
	int nearEndIndex = stringSize * 2 / 3;
	long skipped1 = input.skip(nearEndIndex);
	assertEquals("InputStream.skip()", skipped1, nearEndIndex);
	assertEquals("InputStream.available()",
	stringSize - skipped1, input.available());
	assertTrue("InputStream.mark() is available", input.markSupported());
	input.mark(0);
	assertEquals("InputStream.skip(), read()",
	stringUnderTest.byteAt(nearEndIndex) & 0xFF, input.read());
	assertEquals("InputStream.available()",
	stringSize - skipped1 - 1, input.available());
	long skipped2 = input.skip(stringSize);
	assertEquals("InputStream.skip() incomplete",
	skipped2, stringSize - skipped1 - 1);
	assertEquals("InputStream.skip(), no more input", 0, input.available());
	assertEquals("InputStream.skip(), no more input", -1, input.read());
	input.reset();
	assertEquals("InputStream.reset() succeded",
	stringSize - skipped1, input.available());
	assertEquals("InputStream.reset(), read()",
	stringUnderTest.byteAt(nearEndIndex) & 0xFF, input.read());
	}

	public void testNewCodedInput() throws IOException {
	CodedInputStream cis = stringUnderTest.newCodedInput();
	byte[] roundTripBytes = cis.readRawBytes(referenceBytes.length);
	assertTrue(classUnderTest + " must give the same bytes back from the CodedInputStream",
	Arrays.equals(referenceBytes, roundTripBytes));
	assertTrue(classUnderTest + " CodedInputStream must now be exhausted", cis.isAtEnd());
	}

	/**
	* Make sure we keep things simple when concatenating with empty. See also
	* {@link ByteStringTest#testConcat_empty()}.
	*/
	public void testConcat_empty() {
	assertSame(classUnderTest + " concatenated with empty must give " + classUnderTest,
	stringUnderTest.concat(ByteString.EMPTY), stringUnderTest);
	assertSame("empty concatenated with " + classUnderTest + " must give " + classUnderTest,
	ByteString.EMPTY.concat(stringUnderTest), stringUnderTest);
	}

	public void testJavaSerialization() throws Exception {
	ByteArrayOutputStream out = new ByteArrayOutputStream();
	ObjectOutputStream oos = new ObjectOutputStream(out);
	oos.writeObject(stringUnderTest);
	oos.close();
	byte[] pickled = out.toByteArray();
	InputStream in = new ByteArrayInputStream(pickled);
	ObjectInputStream ois = new ObjectInputStream(in);
	Object o = ois.readObject();
	assertTrue("Didn't get a ByteString back", o instanceof ByteString);
	assertEquals("Should get an equal ByteString back", stringUnderTest, o);
	}
	}