com.tangosol.util.Binary Maven / Gradle / Ivy
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/*
* Copyright (c) 2000, 2022, Oracle and/or its affiliates.
*
* Licensed under the Universal Permissive License v 1.0 as shown at
* http://oss.oracle.com/licenses/upl.
*/
package com.tangosol.util;
import com.tangosol.io.AbstractByteArrayReadBuffer;
import com.tangosol.io.ExternalizableLite;
import com.tangosol.io.ReadBuffer;
import com.tangosol.io.WrapperInputStream;
import java.io.ByteArrayOutputStream;
import java.io.DataInput;
import java.io.DataInputStream;
import java.io.DataOutput;
import java.io.EOFException;
import java.io.Externalizable;
import java.io.File;
import java.io.FileInputStream;
import java.io.InputStream;
import java.io.IOException;
import java.io.NotActiveException;
import java.io.ObjectInput;
import java.io.ObjectOutput;
import java.net.URL;
import java.nio.ByteBuffer;
import java.nio.channels.FileChannel;
import java.util.Arrays;
/**
* A thread-safe immutable binary object.
*
* @author cp 2002.01.25
*/
public final class Binary
extends AbstractByteArrayReadBuffer
implements Comparable, Externalizable, ExternalizableLite
{
// ----- constructors ---------------------------------------------------
/**
* Default constructor for a binary object. Supports deserialization.
*/
public Binary()
{
super(NO_BYTES, 0, 0);
}
/**
* Construct a binary object from a byte array.
*
* @param ab an array of bytes
*/
public Binary(byte[] ab)
{
this(ab, 0, ab.length, true);
}
/**
* Construct a binary object from a portion of a byte array.
*
* @param ab an array of bytes
* @param of the offset into the byte array
* @param cb the number of bytes to extract
*/
public Binary(byte[] ab, int of, int cb)
{
this(ab, of, cb, true);
}
/**
* Construct a Binary object from a portion of a byte array. This
* constructor allows internal methods to efficiently create Binary
* objects without forcing a copy.
*
* @param ab a byte array to construct this Binary object from
* @param of the offset into the byte array
* @param cb the number of bytes
* @param fCopy true to force a copy of any mutable data
*/
private Binary(byte[] ab, int of, int cb, boolean fCopy)
{
super();
if (cb == 0)
{
m_ab = NO_BYTES;
}
else if (fCopy)
{
byte[] abNew;
try
{
abNew = new byte[cb];
System.arraycopy(ab, of, abNew, 0, cb);
}
catch (Exception e)
{
azzert(ab != null, "byte array is null");
azzert(of >= 0, "offset is negative");
// note: of == ab.length iff cb == 0
azzert(of <= ab.length, "offset > array length");
azzert(cb >= 0, "length is negative");
azzert(of + cb <= ab.length, "offset + length > array length");
throw ensureRuntimeException(e);
}
m_ab = abNew;
m_cb = cb;
}
else
{
m_ab = ab;
m_of = of;
m_cb = cb;
}
}
/**
* Construct a Binary object from a Binary object.
*
* @param that another Binary object
*
* @see java.lang.String#String(String)
*/
public Binary(Binary that)
{
super();
// the purpose could be to shrink the buffer (see String); no reason
// to reallocate though unless shrinkage is major (at least 25% and
// at least 1024 bytes)
int cbAlloc = that.m_ab.length;
int cbUsed = that.m_cb;
if (cbAlloc - 1024 > cbUsed && (cbAlloc >>> 1) + (cbAlloc >>> 2) > cbUsed)
{
byte[] abNew = new byte[cbUsed];
System.arraycopy(that.m_ab, that.m_of, abNew, 0, cbUsed);
m_ab = abNew;
m_cb = cbUsed;
}
else
{
this.m_ab = that.m_ab;
this.m_of = that.m_of;
this.m_cb = that.m_cb;
this.m_nHash = that.m_nHash;
}
}
/**
* Construct a Binary object from the contents of a ByteArrayOutputStream.
*
* @param stream the ByteArrayOutputStream that holds the value that
* this Binary object will represent
*/
public Binary(ByteArrayOutputStream stream)
{
super();
// the toByteArray method of ByteArrayOutputStream is specified as
// always creating a new byte array, thus maintaining the immutable
// contract of this class
byte[] ab = stream.toByteArray();
// paranoia: only take it as immutable if it comes from the real
// ByteArrayOutputStream
if (stream.getClass() != ByteArrayOutputStream.class)
{
ab = ab.clone();
}
m_ab = ab;
m_cb = ab.length;
}
/**
* Construct a binary object from a DataInput interface.
*
* @param stream the object implementing DataInput from which this
* Binary object will load its data
*
* @throws IOException if an I/O error occurs reading the Binary
*/
public Binary(DataInput stream)
throws IOException
{
super();
readExternal(stream);
}
/**
* Construct a Binary object from a portion of another Binary object.
* This is similar to the package-private String constructor.
*
* @param that a Binary object to construct this Binary object from
* @param of the offset into the byte array
* @param cb the number of bytes to extract
*/
Binary(Binary that, int of, int cb)
{
super(that.m_ab, that.m_of + of, cb);
}
/**
* Construct a Binary object from a BinaryWriteBuffer.
*
* @param buf a BinaryWriteBuffer to construct this Binary object from
*/
Binary(BinaryWriteBuffer buf)
{
byte[] ab = buf.getInternalByteArray();
int cbData = buf.length();
int cbTotal = ab.length;
int cbWaste = cbTotal - cbData;
// tolerate up to 12.5% waste
if (cbWaste <= Math.max(16, cbTotal >>> 3))
{
m_ab = ab;
}
else
{
byte[] abNew = new byte[cbData];
System.arraycopy(ab, 0, abNew, 0, cbData);
m_ab = abNew;
}
m_cb = cbData;
}
// ----- String-like methods --------------------------------------------
/**
* Tests if two Binary regions are equal.
*
* @param ofThis the starting offset of the subregion in this Binary
* object
* @param that the Binary object containing the subregion to compare to
* @param ofThat the starting offset of the subregion in the passed
* Binary object that
* @param cb the number of bytes to compare
*
* @return true
if the specified subregion of this Binary
* object exactly matches the specified subregion of
* the that
Binary object; false
* otherwise
*
* @exception java.lang.NullPointerException if that
is
* null
*
* @see java.lang.String#regionMatches
*/
public boolean regionMatches(int ofThis, Binary that, int ofThat, int cb)
{
if ( ofThis < 0 || ofThis > (long) this.m_cb - cb
|| ofThat < 0 || ofThat > (long) that.m_cb - cb)
{
return false;
}
return equals(this.m_ab, this.m_of + ofThis,
that.m_ab, that.m_of + ofThat, cb);
}
/**
* Tests if this Binary object starts with the specified prefix beginning
* a specified offset.
*
* @param bin the prefix
* @param ofFrom the offset to begin looking in this Binary object
*
* @return true
if the byte sequence represented by the
* bin
argument is a prefix of the substring of
* this Binary object starting at offset ofFrom
;
* false
otherwise
*
* @exception java.lang.NullPointerException if bin
is
* null
.
*
* @see java.lang.String#startsWith
*/
public boolean startsWith(Binary bin, int ofFrom)
{
return regionMatches(ofFrom, bin, 0, bin.m_cb);
}
/**
* Tests if this Binary object starts with the specified prefix.
*
* @param bin the prefix
*
* @return true
if the byte sequence represented by the
* bin
argument is a prefix of this Binary object;
* false
otherwise
*
* @exception java.lang.NullPointerException if bin
is
* null
.
*
* @see java.lang.String#startsWith
*/
public boolean startsWith(Binary bin)
{
return startsWith(bin, 0);
}
/**
* Tests if this Binary object ends with the specified suffix.
*
* @param bin the suffix
*
* @return true
if the byte sequence represented by the
* bin
argument is a suffix of this Binary object;
* false
otherwise
*
* @exception java.lang.NullPointerException if bin
is
* null
.
*
* @see java.lang.String#endsWith
*/
public boolean endsWith(Binary bin)
{
return startsWith(bin, this.m_cb - bin.m_cb);
}
/**
* Returns the offset within this Binary object of the first occurrence of
* the specified byte.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param b the byte to search for
*
* @return the offset of the first occurrence of the specified byte in the
* byte sequence represented by this Binary object, or
* -1
if the byte does not occur in the sequence
*
* @see java.lang.String#indexOf(int)
*/
public int indexOf(byte b)
{
int ofThis = m_of;
int ofResult = memchr(m_ab, ofThis, m_cb, b);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the first occurrence of
* the specified byte, starting the search at the specified offset.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param b the byte to search for
* @param ofFrom the offset to search from
*
* @return the offset of the first occurrence of the specified byte in the
* byte sequence represented by this Binary object that is greater
* than or equal to ofFrom
, or -1
if the
* byte does not occur from that offset to the end of the sequence
*
* @see java.lang.String#indexOf(int, int)
*/
public int indexOf(byte b, int ofFrom)
{
if (ofFrom < 0)
{
ofFrom = 0;
}
int ofThis = m_of;
int ofResult = memchr(m_ab, ofThis + ofFrom, m_cb - ofFrom, b);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the first occurrence of
* the specified Binary.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param bin the Binary to search for
*
* @return the offset of the first occurrence of the byte sequence
* represented by the specified Binary in the byte sequence
* represented by this Binary object, or -1
if the
* byte sequence does not occur
*
* @see java.lang.String#indexOf(String)
*
* @since 3.5
*/
public int indexOf(Binary bin)
{
final Binary that = bin;
int ofThis = this.m_of;
int ofResult = memmem(this.m_ab, ofThis, this.m_cb,
that.m_ab, that.m_of, that.m_cb);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the first occurrence of
* the specified Binary, starting the search at the specified offset.
*
* This method is identical in its functionality to the corresponding
* method in String. Note that one side-effect of maintaining
* compatibility with the String behavior is that zero-length Strings can
* be found even when the from-index is out-of-bounds. Given any
* Binary value "value" and a zero-length binary value
* "empty", the following will always hold true:
*
* int rnd = new Random().nextInt(Integer.MAX_VALUE - value.length());
* assert value.indexOf(empty, value.length() + rnd) == value.length();
*
*
* @param bin the Binary to search for
* @param ofFrom the offset to search from
*
* @return the offset of the first occurrence of the byte sequence
* represented by the specified Binary in the byte sequence
* represented by this Binary object that is greater than or equal
* to ofFrom
, or -1
if the byte sequence
* does not occur from that offset to the end of this Binary
*
* @see java.lang.String#indexOf(String, int)
*
* @since 3.5
*/
public int indexOf(Binary bin, int ofFrom)
{
final Binary that = bin;
if (ofFrom < 0)
{
ofFrom = 0;
}
int ofThis = this.m_of;
int cbThis = this.m_cb;
int cbThat = that.m_cb;
int cbRemain = cbThis - ofFrom;
if (cbRemain < 0)
{
return cbThat == 0 ? cbThis : -1;
}
int ofResult = memmem(this.m_ab, ofThis + ofFrom, cbRemain,
that.m_ab, that.m_of, cbThat);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the last occurrence of
* the specified byte. The byte sequence of the Binary object is searched
* in backwards order.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param b the byte to search for
*
* @return the offset of the last occurrence of the specified byte in the
* byte sequence represented by this Binary object, or
* -1
if the byte does not occur in the sequence
*
* @see java.lang.String#lastIndexOf(int)
*/
public int lastIndexOf(byte b)
{
int ofThis = m_of;
int ofResult = memchr(m_ab, ofThis, m_cb, b, true);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the last occurrence of
* the specified byte, starting the search at the specified offset and
* searching backwards.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param b the byte to search for
* @param ofFrom the offset to search backwards from (inclusive)
*
* @return the offset of the last occurrence of the specified byte in the
* byte sequence represented by this Binary object that is less
* than or equal to ofFrom
, or -1
if the
* byte does not occur from that offset to the start of the
* sequence
*
* @see java.lang.String#lastIndexOf(int, int)
*/
public int lastIndexOf(byte b, int ofFrom)
{
int ofThis = m_of;
int ofResult = memchr(m_ab, ofThis, Math.min(m_cb, ofFrom + 1), b, true);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the last occurrence of
* the specified Binary.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param bin the Binary to search for
*
* @return the offset of the last occurrence of the byte sequence
* represented by the specified Binary in the byte sequence
* represented by this Binary object, or -1
if the
* byte sequence does not occur
*
* @see java.lang.String#lastIndexOf(String)
*
* @since 3.5
*/
public int lastIndexOf(Binary bin)
{
final Binary that = bin;
int ofThis = this.m_of;
int ofResult = memmem(this.m_ab, ofThis, this.m_cb,
that.m_ab, that.m_of, that.m_cb, true);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Returns the offset within this Binary object of the last occurrence of
* the specified Binary, starting the search at the specified offset.
*
* This method is identical in its functionality to the corresponding
* method in String.
*
* @param bin the Binary to search for
* @param ofFrom the offset to search from
*
* @return the offset of the last occurrence of the byte sequence
* represented by the specified Binary in the byte sequence
* represented by this Binary object that is less than or equal
* to ofFrom
, or -1
if the byte sequence
* does not occur from that offset to the beginning of this Binary
*
* @see java.lang.String#lastIndexOf(String, int)
*
* @since 3.5
*/
public int lastIndexOf(Binary bin, int ofFrom)
{
final Binary that = bin;
int ofThis = this.m_of;
int cbThat = that.m_cb;
int ofResult = memmem(this.m_ab, ofThis, Math.min(this.m_cb, ofFrom + cbThat),
that.m_ab, that.m_of, cbThat, true);
return ofResult < 0 ? ofResult : ofResult - ofThis;
}
/**
* Replace all occurrences of one specified byte with another in this
* Binary object. (This method does not alter the state of this Binary;
* if replacement must occur, it is accomplished by creating a new Binary
* instance.)
*
* @param bOld the byte value to replace
* @param bNew the byte value to replace bOld with
*
* @return a Binary whose value is the same as this Binary's value, except
* that all occurrences of bOld will have been replaced
* with bNew
*/
public Binary replace(byte bOld, byte bNew)
{
// verify that the replace is actually changing from one byte to a
// different byte (if not, there is nothing to replace)
if (bOld == bNew)
{
return this;
}
// verify that there is at least one instance of the byte to replace
byte[] abThis = m_ab;
int ofThis = m_of;
int cbThis = m_cb;
int ofByte = memchr(abThis, ofThis, cbThis, bOld);
if (ofByte < 0)
{
return this;
}
// allocate new byte[] to hold the result
byte[] abResult = clone(abThis, ofThis, cbThis);
// adjust from the region starting at "ofThis" to the region starting
// at zero (in the new byte array)
ofByte -= ofThis;
// replace all occurrences
do
{
abResult[ofByte++] = bNew;
ofByte = memchr(abResult, ofByte, cbThis - ofByte, bOld);
}
while (ofByte >= 0);
return new Binary(abResult, 0, cbThis, false);
}
/**
* Replace all occurrences of one specified Binary with another in this
* Binary object. (This method does not alter the state of this Binary;
* if replacement must occur, it is accomplished by creating a new Binary
* instance.)
*
* @param binOld the Binary value to replace
* @param binNew the Binary value to replace binOld with
*
* @return a Binary whose value is the same as this Binary's value, except
* that all occurrences of binOld will have been replaced
* with binNew
*/
public Binary replace(Binary binOld, Binary binNew)
{
// replacing nothing with something is considered a no-op
int cbOld = binOld.m_cb;
if (cbOld == 0)
{
return this;
}
// if both the old and new are 1 byte, then use the optimized 1-byte
// replace() method
int cbNew = binNew.m_cb;
if (cbOld == 1 && cbNew == 1)
{
return replace(binOld.byteAt(0), binNew.byteAt(0));
}
// verify that there is at least one instance of the value that is
// being replaced
byte[] abThis = m_ab;
int ofThis = m_of;
int cbThis = m_cb;
byte[] abOld = binOld.m_ab;
int ofOld = binOld.m_of;
byte[] abNew = binNew.m_ab;
int ofNew = binNew.m_of;
int ofNext = memmem(abThis, ofThis, cbThis, abOld, ofOld, cbOld);
if (ofNext < 0)
{
return this;
}
// easy optimization if the before and after are the same length
if (cbOld == cbNew)
{
// allocate new byte[] to hold the result
byte[] abResult = clone(abThis, ofThis, cbThis);
// adjust from the region starting at "ofThis" to the region starting
// at zero (in the new byte array)
ofNext -= ofThis;
// replace all occurrences
do
{
memcpy(abNew, ofNew, abResult, ofNext, cbNew);
ofNext += cbNew;
ofNext = memmem(abResult, ofNext, cbThis - ofNext, abOld, ofOld, cbOld);
}
while (ofNext >= 0);
return new Binary(abResult, 0, cbThis, false);
}
// presize it as if only one region were changing (it's as
// reasonable a guess as any)
BinaryWriteBuffer buf = new BinaryWriteBuffer(cbThis + cbNew - cbOld);
BinaryWriteBuffer.BufferOutput out = buf.getBufferOutput();
try
{
int ofPrev = ofThis;
int cbRemain;
do
{
// write the portion from the previous match up to the
// current match
int cbCopy = ofNext - ofPrev;
if (cbCopy > 0)
{
out.write(abThis, ofPrev, cbCopy);
}
if (cbNew > 0)
{
out.write(abNew, ofNew, cbNew);
}
ofPrev = ofNext + cbOld;
cbRemain = cbThis - (ofPrev - ofThis);
ofNext = memmem(abThis, ofPrev, cbRemain, abOld, ofOld, cbOld);
}
while (ofNext >= 0);
// copy any trailing bytes
if (cbRemain > 0)
{
out.write(abThis, ofPrev, cbRemain);
}
}
catch (IOException e)
{
throw ensureRuntimeException(e);
}
return buf.toBinary();
}
/**
* Replace a region within this Binary with another Binary.
*
* This method does not alter the state of this Binary; it creates a new
* Binary instance instead.
*
* @param of the offset of the range to replace within this Binary
* @param cb the length of the range to replace in bytes
* @param binNew the Binary value to replace the range with
*
* @return a Binary whose value is the same as this Binary's value,
* except that the specified range will have been replaced
* with binNew
*
* @since 3.5
*/
public Binary replaceRegion(int of, int cb, Binary binNew)
{
byte[] abThis = m_ab;
int ofThis = m_of;
int cbThis = m_cb;
byte[] abNew = binNew.m_ab;
int ofNew = binNew.m_of;
int cbNew = binNew.m_cb;
// optimization if the range and the new value are the same length
if (cb == cbNew)
{
// allocate new byte[] to hold the result
byte[] abResult = clone(abThis, ofThis, cbThis);
// replace region
memcpy(abNew, ofNew, abResult, of, cb);
return new Binary(abResult, 0, cbThis, false);
}
BinaryWriteBuffer buf = new BinaryWriteBuffer(cbThis + cbNew - cb);
BinaryWriteBuffer.BufferOutput out = buf.getBufferOutput();
try
{
this.writeTo(out, 0, of);
binNew.writeTo(out);
final int ofRemain = of + cb;
this.writeTo(out, ofRemain, length() - ofRemain);
}
catch (IOException e)
{
throw ensureRuntimeException(e);
}
return buf.toBinary();
}
/**
* Concatenate the passed Binary onto this Binary.
*
* @param bin the Binary to concatenate to this Binary
*
* @return a Binary containing the byte sequence of this Binary object
* followed immediately by the byte sequence of the passed Binary
* object
*
* @since 3.5
*/
public Binary concat(Binary bin)
{
final Binary that = bin;
int cbThis = this.m_cb;
if (cbThis == 0)
{
return that;
}
int cbThat = that.m_cb;
if (cbThat == 0)
{
return this;
}
int cbNew = cbThis + cbThat;
byte[] abNew = new byte[cbNew];
System.arraycopy(this.m_ab, this.m_of, abNew, 0, cbThis);
System.arraycopy(that.m_ab, that.m_of, abNew, cbThis, cbThat);
return new Binary(abNew, 0, cbNew, false);
}
/**
* Reverse this Binary object's byte sequence such that the byte at offset
* zero of this sequence occurs at offset length()-1 in the
* resulting sequence, the byte at offset one of this sequence occurs at
* offset length()-2 in the resulting sequence, and so on. The
* resulting Binary object will have the same length as this Binary
* object.
*
* @return a Binary whose byte sequence contains the same byte values as
* this Binary, but in reverse sequence
*
* @since 3.5
*/
public Binary reverse()
{
int cb = m_cb;
if (cb < 2)
{
return this;
}
byte[] abOld = m_ab;
byte[] abNew = new byte[cb];
int ofOld = m_of;
int ofNew = cb - 1;
while (ofNew >= 0)
{
abNew[ofNew--] = abOld[ofOld++];
}
return new Binary(abNew, 0, cb, false);
}
/**
* Split a Binary into an array of Binaries each of which does not exceed
* the specified size.
*
* @param nSize the size of result Binaries
*
* @return an array of Binaries
*
* @since 12.2.1.4
*/
public Binary[] split(int nSize)
{
int nLen = m_cb / nSize;
int remainder = m_cb % nSize;
Binary[] aBinaries = new Binary[remainder == 0 ? nLen : nLen + 1];
for (int i = 0; i < nLen; i++)
{
aBinaries[i] = new Binary(m_ab, m_of + nSize * i, nSize);
}
if (remainder > 0)
{
aBinaries[nLen] = new Binary(m_ab, m_of + nSize * nLen, remainder);
}
return aBinaries;
}
// ----- ReadBuffer methods ---------------------------------------------
/**
* {@inheritDoc}
*/
public Binary toBinary()
{
return this;
}
/**
* {@inheritDoc}
*/
public Binary toBinary(int of, int cb)
{
int cbBuf = m_cb;
if (of == 0 && cb == cbBuf)
{
return this;
}
// validate parameters
if (of < 0 || cb < 0 || of + cb > cbBuf)
{
throw new IndexOutOfBoundsException("of=" + of + ", cb=" + cb
+ ", length()=" + cbBuf);
}
return cb == 0 ? NO_BINARY
: new Binary(this, of, cb);
}
// ----- AbstractByteArrayReadBuffer methods ----------------------------
/**
* {@inheritDoc}
*/
protected ReadBuffer instantiateReadBuffer(int of, int cb)
{
return toBinary(of, cb);
}
/**
* {@inheritDoc}
*/
protected boolean isByteArrayPrivate()
{
return true;
}
// ----- Object methods -------------------------------------------------
/**
* Create a clone of this Binary object.
*
* @return a Binary object with the same contents as this Binary object
*/
public Object clone()
{
// it is self-evident that cloning an immutable object is ridiculous
return this;
}
/**
* Provide a human-readable representation of the Binary object.
*
* @return a String whose contents represent the value of this Binary object
*/
public String toString()
{
// "Binary(length=4, value=0x01F03DA7)"
int cb = m_cb;
final int MAX = 256;
boolean fTrunc = cb > MAX;
return "Binary(length=" + cb + ", value="
+ toHexEscape(m_ab, m_of, fTrunc ? MAX : cb)
+ (fTrunc ? "...)" : ")");
}
/**
* Returns a hash code value for the object. This method is supported
* for the benefit of hashed data structures.
*
* The Binary object uses a CRC32 algorithm to determine the hash code.
*
* @return a hash code value for this object
*
* @see Base#toCrc(byte[], int, int)
*/
public int hashCode()
{
int nHash = m_nHash;
if (nHash == 0)
{
// cache the CRC32 result
nHash = toCrc(m_ab, m_of, m_cb);
if (nHash == 0)
{
// to allow for caching of the hashcode
nHash = 17;
}
m_nHash = nHash;
}
return nHash;
}
/**
* Compares this Binary object with another object for equality.
*
* @param o an object reference or null
*
* @return true iff the passed object reference is a Binary object
* representing the same exact sequence of byte values
*/
public boolean equals(Object o)
{
if (this == o)
{
return true;
}
if (o instanceof Binary)
{
Binary that = (Binary) o;
// compare length (a quick way to disprove equality)
int cbThis = this.m_cb;
int cbThat = that.m_cb;
if (cbThis == cbThat)
{
// 0-length binary values are identical
if (cbThis == 0)
{
return true;
}
// compare hash-code (another quick way to disprove equality)
int nThisHash = this.m_nHash;
int nThatHash = that.m_nHash;
if (nThisHash == 0 || nThatHash == 0 || nThisHash == nThatHash)
{
// COH-2279 - Use Arrays.equals if the entire buffers should
// be equal. Intentionally only using cbThis since the equality
// is checked previously.
if (this.m_of == 0 && that.m_of == 0
&& this.m_ab.length == cbThis
&& that.m_ab.length == cbThis)
{
return Arrays.equals(this.m_ab, that.m_ab);
}
else
{
// brute force byte-by-byte comparison
return equals(this.m_ab, this.m_of,
that.m_ab, that.m_of, cbThat);
}
}
}
return false;
}
else
{
return super.equals(o);
}
}
// ----- partitioning helpers -------------------------------------------
/**
* Calculate the partition ID to which the specified Binary should be
* naturally assigned. This calculation should not be applied to Binary
* objects {@link ExternalizableHelper#decorateBinary decorated} with
* artificially assigned partitions.
*
* The resulting partition ID will be in the range [0..cPartitions).
*
* Note: if the specified partition count is zero, this method will
* return a hash code fo the binary, thus allowing clients that don't have a
* concept of partitioning or knowledge of the partition count to defer the
* partition id calculation until the partition count is known.
*
* @param cPartitions the partition count
*
* @return the partition that the this Binary is naturally assigned to
* or a natural hash code if the partition count is not specified
*/
public int calculateNaturalPartition(int cPartitions)
{
long lHash = ((long) hashCode()) & 0xFFFFFFFFL;
return cPartitions == 0 ? (int) lHash : (int) (lHash % (long) cPartitions);
}
// ----- Comparable interface -------------------------------------------
/**
* Compares this object with the specified object for order. Returns a
* negative integer, zero, or a positive integer as this object is less
* than, equal to, or greater than the specified object.
*
* @param o the Object to be compared.
*
* @return a negative integer, zero, or a positive integer as this object
* is less than, equal to, or greater than the specified object
*
* @throws ClassCastException if the specified object's type prevents it
* from being compared to this Object
* @throws NullPointerException if the specified object is
* null
*/
public int compareTo(Object o)
{
Binary that = (Binary) o; // ClassCastException
return memcmp(this.m_ab, this.m_of, this.m_cb,
that.m_ab, that.m_of, that.m_cb);
}
// ----- Externalizable interface ---------------------------------------
/**
* The object implements the readExternal method to restore its
* contents by calling the methods of DataInput for primitive
* types and readObject for objects, strings and arrays. The
* readExternal method must read the values in the same sequence
* and with the same types as were written by writeExternal.
*
* @param in the stream to read data from in order to restore the object
*
* @exception IOException if an I/O exception occurs
*/
public void readExternal(ObjectInput in)
throws IOException
{
readExternal((DataInput) in);
}
/**
* The object implements the writeExternal method to save its contents
* by calling the methods of DataOutput for its primitive values or
* calling the writeObject method of ObjectOutput for objects, strings,
* and arrays.
*
* @param out the stream to write the object to
*
* @exception IOException if an I/O exception occurs
*/
public void writeExternal(ObjectOutput out)
throws IOException
{
writeExternal((DataOutput) out);
}
// ----- ExternalizableLite interface -----------------------------------
/**
* {@inheritDoc}
*/
public void readExternal(DataInput in)
throws IOException
{
if (m_cb > 0)
{
throw new NotActiveException();
}
int cb = in.readInt();
byte[] ab;
ExternalizableHelper.validateLoadArray(byte[].class, cb, in);
if (cb < ExternalizableHelper.CHUNK_THRESHOLD)
{
ab = new byte[cb];
in.readFully(ab);
}
else
{
ab = ExternalizableHelper.readLargeByteArray(in, cb);
}
m_ab = ab;
m_cb = cb;
}
/**
* {@inheritDoc}
*/
public void writeExternal(DataOutput out)
throws IOException
{
out.writeInt(m_cb);
out.write(m_ab, m_of, m_cb);
}
/**
* Write the contents of the specified ReadBuffer to the specified DataOutput
* stream in a format that can be restored as a Binary via {@link #readExternal}
*
* @param out the DataOutput stream to write to
* @param buf the ReadBuffer to write the contents of
*
* @throws IOException if an I/O exception occurs
*/
public static void writeExternal(DataOutput out, ReadBuffer buf)
throws IOException
{
out.writeInt(buf.length());
buf.writeTo(out);
}
// ----- misc i/o optimizations -----------------------------------------
/**
* Get an InputStream to read the Binary object's contents from.
*
* @return an InputStream backed by this Binary object
*/
public InputStream getInputStream()
{
return (InputStream) getBufferInput();
}
/**
* Read a Binary of the specified length at the specified offset from the
* specified FileChannel.
*
* @param channel the FileChannel to read from
* @param of the offset within the FileChannel to read from
* @param cb the number of bytes to read from the FileChannel, which
* will be the length of the Binary
* @param ab2 reserved; pass in null
*
* @return a Binary containing the specified sequence of bytes from the
* channel
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(FileChannel channel, long of, int cb, byte[] ab2)
throws IOException
{
if (cb == 0)
{
return NO_BINARY;
}
byte[] ab = new byte[cb];
ByteBuffer buf = ByteBuffer.wrap(ab);
int cbRead = 0;
do
{
int cbChunk = channel.read(buf, of + cbRead);
if (cbChunk < 0)
{
throw new EOFException("succeeded in only reading " + cbRead
+ " bytes out of a requested " + cb + " bytes at offset "
+ of + " from channel: " + channel.toString());
}
cbRead += cbChunk;
}
while (cbRead < cb);
assert cb == cbRead;
// decrypt bytes
if (ab2 != null && ab2.length == 0x100)
{
for (int ofCur = 0, ofOv = (int) (of & 0xFF); ofCur < cb; ++ofCur, ++ofOv)
{
ab[ofCur] = (byte) (ab[ofCur] ^ ab2[ofOv & 0xFF]);
}
}
return new Binary(ab, 0, cb, false);
}
/**
* Read a Binary from the specified InputStream.
*
* @param in the InputStream to read from
*
* @return a Binary containing all the bytes from the specified InputStream
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(InputStream in)
throws IOException
{
BinaryWriteBuffer buf = new BinaryWriteBuffer(in.available());
try (WrapperInputStream stream = new WrapperInputStream(in))
{
buf.getBufferOutput().writeStream(stream);
return buf.toBinary();
}
}
/**
* Read a Binary from the specified InputStream.
*
* @param in the InputStream to read from
* @param cb the exact number of bytes to read from the stream
*
* @return a Binary containing {@code cb} bytes
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(InputStream in, int cb)
throws IOException
{
BinaryWriteBuffer buf = new BinaryWriteBuffer(cb);
try (WrapperInputStream stream = new WrapperInputStream(in))
{
buf.getBufferOutput().writeStream(stream, cb);
return buf.toBinary();
}
}
/**
* Read a Binary from the specified File.
*
* @param file the File to read from
*
* @return a Binary containing all the bytes from the specified file
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(File file)
throws IOException
{
return readBinary(new FileInputStream(file));
}
/**
* Read a Binary from the specified URL.
*
* @param url the URL to read from
*
* @return a Binary containing all the bytes from the specified URL
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(URL url)
throws IOException
{
byte[] ab = read(url);
return new Binary(ab, 0, ab.length, false);
}
/**
* Read a Binary from the specified DataInput.
*
* @param input the DataInput to read from
*
* @return a Binary containing all the bytes from the specified DataInput
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(DataInput input)
throws IOException
{
byte[] ab = read(input);
return new Binary(ab, 0, ab.length, false);
}
/**
* Read a Binary from the specified DataInputStream.
*
* @param in the DataInputStream to read from
*
* @return a Binary containing all the bytes from the specified DataInputStream
*
* @throws IOException if an I/O exception or unexpected EOF occurs
*/
public static Binary readBinary(DataInputStream in)
throws IOException
{
// this method resolves the ambiguity between the readBinary(InputStream)
// and readBinary(DataInput) methods for DataInputStreams and its derivatives
return readBinary((InputStream) in);
}
// ----- C Runtime Library functions ------------------------------------
/**
* Find the specified byte (a "needle") in the specified binary region
* ("the haystack").
*
* @param abHaystack the byte array containing the binary region to
* search within (the "haystack")
* @param ofHaystack the offset of the binary region within
* abHaystack
* @param cbHaystack the size in bytes of the binary region within
* abHaystack
* @param bNeedle the byte to search for (a "needle")
*
* @return the offset within the binary region (the "haystack") at which
* the specified byte (the "needle") was found, or -1 if
* the specified byte does not occur within the binary region
*
* @since 3.5
*/
public static int memchr(byte[] abHaystack, int ofHaystack, int cbHaystack,
byte bNeedle)
{
return memchr(abHaystack, ofHaystack, cbHaystack, bNeedle, false);
}
/**
* Find the specified byte (a "needle") in the specified binary region
* ("the haystack").
*
* @param abHaystack the byte array containing the binary region to
* search within (the "haystack")
* @param ofHaystack the offset of the binary region within
* abHaystack
* @param cbHaystack the size in bytes of the binary region within
* abHaystack
* @param bNeedle the byte to search for (a "needle")
* @param fBackwards pass false to find the first occurrence, or true to
* find the last occurrence
*
* @return the offset within the binary region (the "haystack") at which
* the specified byte (the "needle") was found, or -1 if
* the specified byte does not occur within the binary region
*
* @since 3.5
*/
public static int memchr(byte[] abHaystack, int ofHaystack, int cbHaystack,
byte bNeedle, boolean fBackwards)
{
try
{
if (fBackwards)
{
for (int ofStop = ofHaystack, of = ofStop + cbHaystack - 1; of >= ofStop; --of)
{
if (abHaystack[of] == bNeedle)
{
return of;
}
}
}
else
{
for (int of = ofHaystack, ofStop = of + cbHaystack; of < ofStop; ++of)
{
if (abHaystack[of] == bNeedle)
{
return of;
}
}
}
return -1;
}
catch (RuntimeException e)
{
throw new WrapperException(e, "abHaystack=" + toString(abHaystack)
+ ", ofHaystack=" + ofHaystack + ", cbHaystack=" + cbHaystack);
}
}
/**
* Find the second binary region (a "needle") in the first binary region
* ("the haystack").
*
* @param abHaystack the byte array containing the binary region to
* search within (the "haystack")
* @param ofHaystack the offset of the binary region within
* abHaystack
* @param cbHaystack the size in bytes of the binary region within
* abHaystack
* @param abNeedle the byte array containing the binary region to
* search for (a "needle")
* @param ofNeedle the offset of the binary region within
* abNeedle
* @param cbNeedle the size in bytes of the binary region within
* abNeedle
*
* @return the offset within the first binary region (the "haystack") at
* which the second binary region (the "needle") was found, or
* -1 if the second binary region does not occur within
* the first
*
* @since 3.5
*/
public static int memmem(byte[] abHaystack, int ofHaystack, int cbHaystack,
byte[] abNeedle, int ofNeedle, int cbNeedle)
{
return memmem(abHaystack, ofHaystack, cbHaystack,
abNeedle, ofNeedle, cbNeedle, false);
}
/**
* Find the second binary region (a "needle") in the first binary region
* ("the haystack").
*
* @param abHaystack the byte array containing the binary region to
* search within (the "haystack")
* @param ofHaystack the offset of the binary region within
* abHaystack
* @param cbHaystack the size in bytes of the binary region within
* abHaystack
* @param abNeedle the byte array containing the binary region to
* search for (a "needle")
* @param ofNeedle the offset of the binary region within
* abNeedle
* @param cbNeedle the size in bytes of the binary region within
* abNeedle
* @param fBackwards pass false to find the first occurrence, or true to
* find the last occurrence
*
* @return the offset within the first binary region (the "haystack") at
* which the second binary region (the "needle") was found, or
* -1 if the second binary region does not occur within
* the first
*
* @since 3.5
*/
public static int memmem(byte[] abHaystack, int ofHaystack, int cbHaystack,
byte[] abNeedle, int ofNeedle, int cbNeedle,
boolean fBackwards)
{
try
{
// handle the various edge conditions
if (cbNeedle >= cbHaystack)
{
// if the needle is larger than the haystack, then it cannot
// be found within the haystack, and if it is the same size,
// then the needle has to be identical to the haystack
return (cbNeedle == cbHaystack && equals(abHaystack, ofHaystack,
abNeedle, ofNeedle, cbNeedle))
? ofHaystack
: -1;
}
else if (cbNeedle <= 1)
{
// the only legal values for cbNeedle at this point are zero
// and one; if zero, then an empty region matches immediately
// and the result is thus at the very start (or end) of the
// haystack, and if one, then switch to memchr() since it is
// more efficient for searching for a single byte; the
// multiplication just asserts that the cbNeedle value was
// not less than zero
return cbNeedle == 0
? ofHaystack + (fBackwards ? cbHaystack : 0)
: memchr(abHaystack, ofHaystack, cbHaystack,
abNeedle[ofNeedle * cbNeedle], fBackwards);
}
int bNeedle = abNeedle[ofNeedle];
if (fBackwards)
{
for (int ofStop = ofHaystack, of = ofStop + cbHaystack - cbNeedle;
of >= ofStop; --of)
{
if (abHaystack[of] == bNeedle &&
equals(abHaystack, of+1, abNeedle, ofNeedle+1, cbNeedle-1))
{
return of;
}
}
}
else
{
for (int of = ofHaystack, ofStop = of + cbHaystack - cbNeedle;
of <= ofStop; ++of)
{
if (abHaystack[of] == bNeedle &&
equals(abHaystack, of+1, abNeedle, ofNeedle+1, cbNeedle-1))
{
return of;
}
}
}
return -1;
}
catch (RuntimeException e)
{
throw new WrapperException(e, "abHaystack=" + toString(abHaystack)
+ ", ofHaystack=" + ofHaystack + ", cbHaystack=" + cbHaystack
+ ", abNeedle=" + toString(abNeedle)
+ ", ofNeedle=" + ofNeedle + ", cbNeedle=" + cbNeedle);
}
}
/**
* Compare two binary regions.
*
* @param ab1 the byte array containing the first binary region to
* compare
* @param of1 the offset of the binary region within ab1
* @param cb1 the size in bytes of the binary region within ab1
* @param ab2 the byte array containing the second binary region to
* compare
* @param of2 the offset of the binary region within ab2
* @param cb2 the size in bytes of the binary region within ab2
*
* @return a value less than zero, zero or greater than zero if the first
* binary region is "less than," "equal to" or "greater than" the
* second binary region
*
* @since 3.5
*/
public static int memcmp(byte[] ab1, int of1, int cb1, byte[] ab2, int of2, int cb2)
{
try
{
for (int i = 0, c = Math.min(cb1, cb2); i < c; ++i)
{
if (ab1[of1 + i] != ab2[of2 + i])
{
// byte is implemented in Java as a signed value, but
// the expected result of comparison is as if the bytes
// were unsigned
return (ab1[of1 + i] & 0xFF) - (ab2[of2 + i] & 0xFF);
}
}
return cb1 - cb2;
}
catch (RuntimeException e)
{
throw new WrapperException(e, "ab1=" + toString(ab1)
+ ", of1=" + of1 + ", cb1=" + cb1 + ", ab2=" + toString(ab2)
+ ", of2=" + of2 + ", cb2=" + cb2);
}
}
/**
* Copy binary data from one binary region to another. This is safe for
* copying a region from an array to itself, even if the regions are
* overlapping; as such, it is equivalent to both memmov() and memcpy().
* The implementation uses the arraycopy() method of the System class;
* the only difference between this method and the raw arraycopy() is that
* this method is typed and decorates any exception with debugging
* information about the arguments that caused the exception.
*
* @param abSrc the byte array containing the binary region to copy from
* @param ofSrc the offset of the binary region within abSrc
* @param abDest the byte array containing the binary region to copy to
* @param ofDest the offset of the binary region within abDest
* @param cbCopy the size in bytes of the binary region to copy
*
* @since 3.5
*/
public static void memcpy(byte[] abSrc, int ofSrc, byte[] abDest, int ofDest, int cbCopy)
{
try
{
System.arraycopy(abSrc, ofSrc, abDest, ofDest, cbCopy);
}
catch (RuntimeException e)
{
throw new WrapperException(e, "abSrc=" + toString(abSrc)
+ ", ofSrc=" + ofSrc + ", abDest=" + toString(abDest)
+ ", ofDest=" + ofDest + ", cbCopy=" + cbCopy);
}
}
/**
* Compare two binary regions, testing for equality.
*
* @param ab1 the byte array containing the first binary region to
* compare
* @param of1 the offset of the binary region within ab1
* @param ab2 the byte array containing the second binary region to
* compare
* @param of2 the offset of the binary region within ab2
* @param cb the size of the binary regions, which is the number of
* bytes to compare
*
* @return true iff the two specified binary regions are identical
*
* @since 3.5
*/
public static boolean equals(byte[] ab1, int of1, byte[] ab2, int of2, int cb)
{
try
{
while (--cb >= 0)
{
if (ab1[of1++] != ab2[of2++])
{
return false;
}
}
return true;
}
catch (RuntimeException e)
{
throw new WrapperException(e, "ab1=" + toString(ab1)
+ ", of1=" + of1 + ", ab2=" + toString(ab2)
+ ", of2=" + of2 + ", cb=" + cb);
}
}
/**
* Create a clone of the specified binary region.
*
* @param ab the byte array containing the binary region to copy from
* @param of the offset of the binary region within ab
* @param cb the size in bytes of the binary region to copy
*
* @return a copy of the specified binary region
*
* @since 3.5
*/
public static byte[] clone(byte[] ab, int of, int cb)
{
try
{
byte[] abNew = new byte[cb];
System.arraycopy(ab, of, abNew, 0, cb);
return abNew;
}
catch (RuntimeException e)
{
throw new WrapperException(e, "ab=" + toString(ab)
+ ", of=" + of + ", cb=" + cb);
}
}
/**
* For debugging purposes, convert the passed byte array into a string
* that contains the information regarding whether the reference is null,
* and if it is not null, what the length of the byte array is.
*
* @param ab a byte array; may be null
*
* @return a String; never null
*
* @since 3.5
*/
public static String toString(byte[] ab)
{
return ab == null ? "null" : ("byte[" + ab.length + "]");
}
/**
* Join an array of Binaries into a single Binary.
*
* @param aBinaries an array of Binaries to join
*
* @since 12.2.1.4
*/
public static Binary join(Binary[] aBinaries)
{
int cbNew = 0;
for (int i = 0; i < aBinaries.length; i++)
{
cbNew += aBinaries[i].m_cb;
}
byte[] abNew = new byte[cbNew];
int offset = 0;
for (int i = 0; i < aBinaries.length; i++)
{
System.arraycopy(aBinaries[i].m_ab, aBinaries[i].m_of, abNew, offset, aBinaries[i].m_cb);
offset += aBinaries[i].m_cb;
}
return new Binary(abNew, 0, cbNew, false);
}
// ----- inner class: Unsafe --------------------------------------------
static void registerUnsafe(com.tangosol.util.Unsafe unsafe)
{
/**
* Method is intentionally not javadoc'd.
*
* Register an instance of the Binary accessor with the specified {@link
* Unsafe} instance.
*
* This "double-dispatch" pattern is used in order to centralize the access
* checks to all "unsafe" utilities. See
*
* @param unsafe
*/
unsafe.register(Unsafe.INSTANCE);
}
static class Unsafe
{
/**
* Class is intentionally not javadoc'd.
*
* Unsafe accessors for Binary.
* @see com.tangosol.util.Unsafe
*/
// ----- constructors -----------------------------------------------
/**
* Hidden constructor
*/
private Unsafe()
{}
// ----- Unsafe methods ---------------------------------------------
/**
* Return the underlying byte[] for the specified binary.
*
* @param bin the binary
*
* @return the underlying byte[]
*/
public byte[] getByteArray(Binary bin)
{
return bin.m_ab;
}
/**
* Return the offset into the {@link #getByteArray(Binary) underlying
* byte[]} of the specified binary.
*
* @param bin the binary
*
* @return the offset into the underlying byte[]
*/
public int getArrayOffset(Binary bin)
{
return bin.m_of;
}
/**
* Return a new {@link Binary} instance backed by the specified byte[]
* beginning at the specified offset and of the specified length.
*
* Note: unlike the {@link #Binary(byte[],int,int) analagous constructor},
* this method does not create a copy of the passed array; it is the
* caller's responsibility not to mutate the contents of the array.
*
* @param ab the byte array
* @param of the starting offset
* @param cb the length of the binary
*
* @return a new Binary based on the specified array
*/
public Binary newBinary(byte[] ab, int of, int cb)
{
if (of < 0 || of + cb > ab.length)
{
throw new IndexOutOfBoundsException();
}
return new Binary(ab, of, cb, false);
}
// ----- constants --------------------------------------------------
/**
* The singleton instance.
*/
private static final Unsafe INSTANCE = new Unsafe();
}
// ----- data members ---------------------------------------------------
/**
* Cached hash code.
*/
private transient int m_nHash;
}