com.fitbur.jackson.core.io.IOContext Maven / Gradle / Ivy
package com.fitbur.jackson.core.io;
import com.fitbur.jackson.core.JsonEncoding;
import com.fitbur.jackson.core.util.BufferRecycler;
import com.fitbur.jackson.core.util.TextBuffer;
/**
* To limit number of configuration and state objects to pass, all
* contextual objects that need to be passed by the factory to
* readers and writers are combined under this object. One instance
* is created for each reader and writer.
*
* NOTE: non-final since 2.4, to allow sub-classing.
*/
public class IOContext
{
/*
/**********************************************************
/* Configuration
/**********************************************************
*/
/**
* Reference to the source object, which can be used for displaying
* location information
*/
protected final Object _sourceRef;
/**
* Encoding used by the underlying stream, if known.
*/
protected JsonEncoding _encoding;
/**
* Flag that indicates whether underlying input/output source/target
* object is fully managed by the owner of this context (parser or
* generator). If true, it is, and is to be closed by parser/generator;
* if false, calling application has to do closing (unless auto-closing
* feature is enabled for the parser/generator in question; in which
* case it acts like the owner).
*/
protected final boolean _managedResource;
/*
/**********************************************************
/* Buffer handling, recycling
/**********************************************************
*/
/**
* Recycler used for actual allocation/deallocation/reuse
*/
protected final BufferRecycler _bufferRecycler;
/**
* Reference to the allocated I/O buffer for low-level input reading,
* if any allocated.
*/
protected byte[] _readIOBuffer;
/**
* Reference to the allocated I/O buffer used for low-level
* encoding-related buffering.
*/
protected byte[] _writeEncodingBuffer;
/**
* Reference to the buffer allocated for temporary use with
* base64 encoding or decoding.
*/
protected byte[] _base64Buffer;
/**
* Reference to the buffer allocated for tokenization purposes,
* in which character input is read, and from which it can be
* further returned.
*/
protected char[] _tokenCBuffer;
/**
* Reference to the buffer allocated for buffering it for
* output, before being encoded: generally this means concatenating
* output, then encoding when buffer fills up.
*/
protected char[] _concatCBuffer;
/**
* Reference temporary buffer Parser instances need if calling
* app decides it wants to access name via 'getTextCharacters' method.
* Regular text buffer can not be used as it may contain textual
* representation of the value token.
*/
protected char[] _nameCopyBuffer;
/*
/**********************************************************
/* Life-cycle
/**********************************************************
*/
public IOContext(BufferRecycler br, Object sourceRef, boolean managedResource)
{
_bufferRecycler = br;
_sourceRef = sourceRef;
_managedResource = managedResource;
}
public void setEncoding(JsonEncoding enc) {
_encoding = enc;
}
/**
* @since 1.6
*/
public IOContext withEncoding(JsonEncoding enc) {
_encoding = enc;
return this;
}
/*
/**********************************************************
/* Public API, accessors
/**********************************************************
*/
public Object getSourceReference() { return _sourceRef; }
public JsonEncoding getEncoding() { return _encoding; }
public boolean isResourceManaged() { return _managedResource; }
/*
/**********************************************************
/* Public API, buffer management
/**********************************************************
*/
public TextBuffer constructTextBuffer() {
return new TextBuffer(_bufferRecycler);
}
/**
*
* Note: the method can only be called once during its life cycle.
* This is to protect against accidental sharing.
*/
public byte[] allocReadIOBuffer() {
_verifyAlloc(_readIOBuffer);
return (_readIOBuffer = _bufferRecycler.allocByteBuffer(BufferRecycler.BYTE_READ_IO_BUFFER));
}
/**
* @since 2.4
*/
public byte[] allocReadIOBuffer(int minSize) {
_verifyAlloc(_readIOBuffer);
return (_readIOBuffer = _bufferRecycler.allocByteBuffer(BufferRecycler.BYTE_READ_IO_BUFFER, minSize));
}
public byte[] allocWriteEncodingBuffer() {
_verifyAlloc(_writeEncodingBuffer);
return (_writeEncodingBuffer = _bufferRecycler.allocByteBuffer(BufferRecycler.BYTE_WRITE_ENCODING_BUFFER));
}
/**
* @since 2.4
*/
public byte[] allocWriteEncodingBuffer(int minSize) {
_verifyAlloc(_writeEncodingBuffer);
return (_writeEncodingBuffer = _bufferRecycler.allocByteBuffer(BufferRecycler.BYTE_WRITE_ENCODING_BUFFER, minSize));
}
/**
* @since 2.1
*/
public byte[] allocBase64Buffer() {
_verifyAlloc(_base64Buffer);
return (_base64Buffer = _bufferRecycler.allocByteBuffer(BufferRecycler.BYTE_BASE64_CODEC_BUFFER));
}
public char[] allocTokenBuffer() {
_verifyAlloc(_tokenCBuffer);
return (_tokenCBuffer = _bufferRecycler.allocCharBuffer(BufferRecycler.CHAR_TOKEN_BUFFER));
}
/**
* @since 2.4
*/
public char[] allocTokenBuffer(int minSize) {
_verifyAlloc(_tokenCBuffer);
return (_tokenCBuffer = _bufferRecycler.allocCharBuffer(BufferRecycler.CHAR_TOKEN_BUFFER, minSize));
}
public char[] allocConcatBuffer() {
_verifyAlloc(_concatCBuffer);
return (_concatCBuffer = _bufferRecycler.allocCharBuffer(BufferRecycler.CHAR_CONCAT_BUFFER));
}
public char[] allocNameCopyBuffer(int minSize) {
_verifyAlloc(_nameCopyBuffer);
return (_nameCopyBuffer = _bufferRecycler.allocCharBuffer(BufferRecycler.CHAR_NAME_COPY_BUFFER, minSize));
}
/**
* Method to call when all the processing buffers can be safely
* recycled.
*/
public void releaseReadIOBuffer(byte[] buf) {
if (buf != null) {
/* Let's do sanity checks to ensure once-and-only-once release,
* as well as avoiding trying to release buffers not owned
*/
_verifyRelease(buf, _readIOBuffer);
_readIOBuffer = null;
_bufferRecycler.releaseByteBuffer(BufferRecycler.BYTE_READ_IO_BUFFER, buf);
}
}
public void releaseWriteEncodingBuffer(byte[] buf) {
if (buf != null) {
/* Let's do sanity checks to ensure once-and-only-once release,
* as well as avoiding trying to release buffers not owned
*/
_verifyRelease(buf, _writeEncodingBuffer);
_writeEncodingBuffer = null;
_bufferRecycler.releaseByteBuffer(BufferRecycler.BYTE_WRITE_ENCODING_BUFFER, buf);
}
}
public void releaseBase64Buffer(byte[] buf) {
if (buf != null) { // sanity checks, release once-and-only-once, must be one owned
_verifyRelease(buf, _base64Buffer);
_base64Buffer = null;
_bufferRecycler.releaseByteBuffer(BufferRecycler.BYTE_BASE64_CODEC_BUFFER, buf);
}
}
public void releaseTokenBuffer(char[] buf) {
if (buf != null) {
_verifyRelease(buf, _tokenCBuffer);
_tokenCBuffer = null;
_bufferRecycler.releaseCharBuffer(BufferRecycler.CHAR_TOKEN_BUFFER, buf);
}
}
public void releaseConcatBuffer(char[] buf) {
if (buf != null) {
// 14-Jan-2014, tatu: Let's actually allow upgrade of the original buffer.
_verifyRelease(buf, _concatCBuffer);
_concatCBuffer = null;
_bufferRecycler.releaseCharBuffer(BufferRecycler.CHAR_CONCAT_BUFFER, buf);
}
}
public void releaseNameCopyBuffer(char[] buf) {
if (buf != null) {
// 14-Jan-2014, tatu: Let's actually allow upgrade of the original buffer.
_verifyRelease(buf, _nameCopyBuffer);
_nameCopyBuffer = null;
_bufferRecycler.releaseCharBuffer(BufferRecycler.CHAR_NAME_COPY_BUFFER, buf);
}
}
/*
/**********************************************************
/* Internal helpers
/**********************************************************
*/
protected final void _verifyAlloc(Object buffer) {
if (buffer != null) { throw new IllegalStateException("Trying to call same allocXxx() method second time"); }
}
protected final void _verifyRelease(byte[] toRelease, byte[] src) {
if ((toRelease != src) && (toRelease.length <= src.length)) { throw wrongBuf(); }
}
protected final void _verifyRelease(char[] toRelease, char[] src) {
if ((toRelease != src) && (toRelease.length <= src.length)) { throw wrongBuf(); }
}
private IllegalArgumentException wrongBuf() { return new IllegalArgumentException("Trying to release buffer not owned by the context"); }
}