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Ice is a comprehensive RPC framework that helps you build distributed applications with minimal effort using familiar object-oriented idioms
//
// Copyright (c) ZeroC, Inc. All rights reserved.
//
package com.zeroc.IceInternal;
//
// An instance of java.nio.ByteBuffer cannot grow beyond its initial capacity.
// This class wraps a ByteBuffer and supports reallocation.
//
public class Buffer
{
public Buffer(boolean direct)
{
this(direct, java.nio.ByteOrder.LITTLE_ENDIAN);
}
public Buffer(boolean direct, java.nio.ByteOrder order)
{
b = _emptyBuffer;
_size = 0;
_capacity = 0;
_direct = direct;
_order = order;
}
public Buffer(byte[] data)
{
this(data, java.nio.ByteOrder.LITTLE_ENDIAN);
}
public Buffer(byte[] data, java.nio.ByteOrder order)
{
b = java.nio.ByteBuffer.wrap(data);
b.order(order);
_size = data.length;
_capacity = 0;
_direct = false;
_order = order;
}
public Buffer(java.nio.ByteBuffer data)
{
this(data, java.nio.ByteOrder.LITTLE_ENDIAN);
}
public Buffer(java.nio.ByteBuffer data, java.nio.ByteOrder order)
{
b = data;
b.order(order);
_size = data.remaining();
_capacity = 0;
_direct = false;
_order = order;
}
public Buffer(Buffer buf, boolean adopt)
{
b = buf.b;
_size = buf._size;
_capacity = buf._capacity;
_direct = buf._direct;
_shrinkCounter = buf._shrinkCounter;
_order = buf._order;
if(adopt)
{
buf.clear();
}
}
public java.nio.Buffer position(int newPosition)
{
// Cast to java.nio.Buffer to avoid incompatible covariant
// return type used in Java 9 java.nio.ByteBuffer
return ((java.nio.Buffer)b).position(newPosition);
}
public java.nio.Buffer limit(int newLimit)
{
// Cast to java.nio.Buffer to avoid incompatible covariant
// return type used in Java 9 java.nio.ByteBuffer
return ((java.nio.Buffer)b).limit(newLimit);
}
public java.nio.Buffer flip()
{
// Cast to java.nio.Buffer to avoid incompatible covariant
// return type used in Java 9 java.nio.ByteBuffer
return ((java.nio.Buffer)b).flip();
}
public void swap(Buffer buf)
{
final java.nio.ByteBuffer bb = buf.b;
final int size = buf._size;
final int capacity = buf._capacity;
final boolean direct = buf._direct;
final int shrinkCounter = buf._shrinkCounter;
final java.nio.ByteOrder order = buf._order;
buf.b = b;
buf._size = _size;
buf._capacity = _capacity;
buf._direct = _direct;
buf._shrinkCounter = _shrinkCounter;
buf._order = _order;
b = bb;
_size = size;
_capacity = capacity;
_direct = direct;
_shrinkCounter = shrinkCounter;
_order = order;
}
public int size()
{
return _size;
}
public boolean empty()
{
return _size == 0;
}
public void clear()
{
b = _emptyBuffer;
_size = 0;
_capacity = 0;
_shrinkCounter = 0;
}
//
// Call expand(n) to add room for n additional bytes. Note that expand()
// examines the current position of the buffer first; we don't want to
// expand the buffer if the caller is writing to a location that is
// already in the buffer.
//
public void expand(int n)
{
final int sz = (b == _emptyBuffer) ? n : b.position() + n;
if(sz > _size)
{
resize(sz, false);
}
}
public void resize(int n, boolean reading)
{
assert(b == _emptyBuffer || _capacity > 0);
if(n == 0)
{
clear();
}
else if(n > _capacity)
{
reserve(n);
}
_size = n;
//
// When used for reading, we want to set the buffer's limit to the new size.
//
if(reading)
{
limit(_size);
}
}
public void reset()
{
if(_size > 0 && _size * 2 < _capacity)
{
//
// If the current buffer size is smaller than the
// buffer capacity, we shrink the buffer memory to the
// current size. This is to avoid holding on to too much
// memory if it's not needed anymore.
//
if(++_shrinkCounter > 2)
{
reserve(_size);
_shrinkCounter = 0;
}
}
else
{
_shrinkCounter = 0;
}
_size = 0;
if(b != _emptyBuffer)
{
limit(b.capacity());
position(0);
}
}
private void reserve(int n)
{
if(n > _capacity)
{
_capacity = java.lang.Math.max(n, 2 * _capacity);
_capacity = java.lang.Math.max(240, _capacity);
}
else if(n < _capacity)
{
_capacity = n;
}
else
{
return;
}
try
{
java.nio.ByteBuffer buf;
if(_direct)
{
buf = java.nio.ByteBuffer.allocateDirect(_capacity);
}
else
{
buf = java.nio.ByteBuffer.allocate(_capacity);
}
if(b == _emptyBuffer)
{
b = buf;
}
else
{
final int pos = b.position();
position(0);
limit(java.lang.Math.min(_capacity, b.capacity()));
buf.put(b);
b = buf;
limit(b.capacity());
position(pos);
}
b.order(_order); // Preserve the original order.
}
catch(OutOfMemoryError ex)
{
_capacity = b.capacity(); // Restore the previous capacity.
throw ex;
}
}
public java.nio.ByteBuffer b;
// Sentinel used for null buffer.
public java.nio.ByteBuffer _emptyBuffer = java.nio.ByteBuffer.allocate(0);
private int _size;
private int _capacity; // Cache capacity to avoid excessive method calls.
private boolean _direct; // Use direct buffers?
private int _shrinkCounter;
private java.nio.ByteOrder _order;
}
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