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A Java implementation of the Amazon Ion data notation.
/*
* Copyright 2007-2019 Amazon.com, Inc. or its affiliates. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License").
* You may not use this file except in compliance with the License.
* A copy of the License is located at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* or in the "license" file accompanying this file. This file is distributed
* on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
* express or implied. See the License for the specific language governing
* permissions and limitations under the License.
*/
package com.amazon.ion.impl;
import com.amazon.ion.Decimal;
import com.amazon.ion.IonException;
import com.amazon.ion.Timestamp;
import com.amazon.ion.Timestamp.Precision;
import java.io.IOException;
import java.io.OutputStream;
import java.math.BigDecimal;
import java.math.BigInteger;
import java.math.MathContext;
/**
* Manages a very simple byte buffer that is a single contiguous
* byte array, without resize ability.
*/
final class SimpleByteBuffer
implements ByteBuffer
{
byte[] _bytes;
int _start;
int _eob;
boolean _is_read_only;
/**
* Creates a read-write buffer.
*
* @param bytes assumed to be owned by this new instance.
*/
public SimpleByteBuffer(byte[] bytes) {
this(bytes, 0, bytes.length, false);
}
/**
*
* @param bytes assumed to be owned by this new instance.
*/
public SimpleByteBuffer(byte[] bytes, boolean isReadOnly) {
this(bytes, 0, bytes.length, isReadOnly);
}
/**
* Creates a read-write buffer.
*
* @param bytes assumed to be owned by this new instance.
*/
public SimpleByteBuffer(byte[] bytes, int start, int length) {
this(bytes, start, length, false);
}
/**
*
* @param bytes assumed to be owned by this new instance.
*/
public SimpleByteBuffer(byte[] bytes, int start, int length, boolean isReadOnly) {
if (bytes == null || start < 0 || start > bytes.length || length < 0 || start + length > bytes.length) {
throw new IllegalArgumentException();
}
_bytes = bytes;
_start = start;
_eob = start + length;
_is_read_only = isReadOnly;
}
public int getLength()
{
int length = _eob - _start;
return length;
}
/**
* Makes a copy of the internal byte array.
*/
public byte[] getBytes()
{
int length = _eob - _start;
byte[] copy = new byte[length];
System.arraycopy(_bytes, _start, copy, 0, length);
return copy;
}
public int getBytes(byte[] buffer, int offset, int length)
{
if (buffer == null || offset < 0 || offset > buffer.length || length < 0 || offset + length > buffer.length) {
throw new IllegalArgumentException();
}
int datalength = _eob - _start;
if (datalength > length) {
throw new IllegalArgumentException("insufficient space in destination buffer");
}
System.arraycopy(_bytes, _start, buffer, offset, datalength);
return datalength;
}
public ByteReader getReader()
{
ByteReader reader = new SimpleByteReader(this);
return reader;
}
public ByteWriter getWriter()
{
if (_is_read_only) {
throw new IllegalStateException("this buffer is read only");
}
SimpleByteWriter writer = new SimpleByteWriter(this);
return writer;
}
public void writeBytes(OutputStream out) throws IOException
{
int length = _eob - _start;
out.write(_bytes, _start, length);
}
static final class SimpleByteReader implements ByteReader
{
SimpleByteBuffer _buffer;
int _position;
SimpleByteReader(SimpleByteBuffer bytebuffer) {
_buffer = bytebuffer;
_position = bytebuffer._start;
}
public int position()
{
int pos = _position - _buffer._start;
return pos;
}
public void position(int newPosition)
{
if (newPosition < 0) {
throw new IllegalArgumentException("position must be non-negative");
}
int pos = newPosition + _buffer._start;
if (pos > _buffer._eob) {
throw new IllegalArgumentException("position is past end of buffer");
}
_position = pos;
}
public void skip(int length)
{
if (length < 0) {
throw new IllegalArgumentException("length to skip must be non-negative");
}
int pos = _position + length;
if (pos > _buffer._eob) {
throw new IllegalArgumentException("skip would skip past end of buffer");
}
_position = pos;
}
public int read()
{
if (_position >= _buffer._eob) return EOF;
int b = _buffer._bytes[_position++];
return (b & 0xff);
}
public int read(byte[] dst, int start, int len)
{
if (dst == null || start < 0 || len < 0 || start + len > dst.length) {
// no need to test this start >= dst.length ||
// since we test start+len > dst.length which is the correct test
throw new IllegalArgumentException();
}
if (_position >= _buffer._eob) return 0;
int readlen = len;
if (readlen + _position > _buffer._eob) readlen = _buffer._eob - _position;
System.arraycopy(_buffer._bytes, _position, dst, start, readlen);
_position += readlen;
return readlen;
}
public int readTypeDesc()
{
return read();
}
public long readULong(int len) throws IOException
{
long retvalue = 0;
int b;
switch (len) {
default:
throw new IonException("value too large for Java long");
case 8:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 7:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 6:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 5:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 4:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 3:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 2:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 1:
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 8) | b;
case 0:
// do nothing, it's just a 0 length is a 0 value
}
return retvalue;
}
public int readVarInt() throws IOException
{
int retvalue = 0;
boolean is_negative = false;
int b;
// synthetic label "done" (yuck)
done: for (;;) {
// read the first byte - it has the sign bit
if ((b = read()) < 0) throwUnexpectedEOFException();
if ((b & 0x40) != 0) {
is_negative = true;
}
retvalue = (b & 0x3F);
if ((b & 0x80) != 0) break done;
// for the second byte we shift our eariler bits just as much,
// but there are fewer of them there to shift
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// if we get here we have more bits than we have room for :(
throwIntOverflowExeption();
}
if (is_negative) {
retvalue = -retvalue;
}
return retvalue;
}
public long readVarLong() throws IOException
{
long retvalue = 0;
boolean is_negative = false;
int b;
// synthetic label "done" (yuck)
done: for (;;) {
// read the first byte - it has the sign bit
if ((b = read()) < 0) throwUnexpectedEOFException();
if ((b & 0x40) != 0) {
is_negative = true;
}
retvalue = (b & 0x3F);
if ((b & 0x80) != 0) break done;
// for the second byte we shift our eariler bits just as much,
// but there are fewer of them there to shift
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
for (;;) {
if ((b = read()) < 0) throwUnexpectedEOFException();
if ((retvalue & 0xFE00000000000000L) != 0) throwIntOverflowExeption();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
}
}
if (is_negative) {
retvalue = -retvalue;
}
return retvalue;
}
/**
* Reads an integer value, returning null to mean -0.
* @throws IOException
*/
public Integer readVarInteger() throws IOException
{
int retvalue = 0;
boolean is_negative = false;
int b;
// sythetic label "done" (yuck)
done: for (;;) {
// read the first byte - it has the sign bit
if ((b = read()) < 0) throwUnexpectedEOFException();
if ((b & 0x40) != 0) {
is_negative = true;
}
retvalue = (b & 0x3F);
if ((b & 0x80) != 0) break done;
// for the second byte we shift our eariler bits just as much,
// but there are fewer of them there to shift
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// for the rest, they're all the same
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break done;
// if we get here we have more bits than we have room for :(
throwIntOverflowExeption();
}
Integer retInteger = null;
if (is_negative) {
if (retvalue != 0) {
retInteger = Integer.valueOf(-retvalue);
}
}
else {
retInteger = Integer.valueOf(retvalue);
}
return retInteger;
}
public int readVarUInt() throws IOException
{
int retvalue = 0;
int b;
for (;;) { // fake loop to create a "goto done"
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break;
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break;
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break;
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break;
if ((b = read()) < 0) throwUnexpectedEOFException();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break;
// if we get here we have more bits than we have room for :(
throwIntOverflowExeption();
}
return retvalue;
}
public double readFloat(int len) throws IOException
{
if (len == 0)
{
// special case, return pos zero
return 0.0d;
}
if (len != 8)
{
throw new IOException("Length of float read must be 0 or 8");
}
long dBits = this.readULong(len);
return Double.longBitsToDouble(dBits);
}
public long readVarULong() throws IOException
{
long retvalue = 0;
int b;
for (;;) {
if ((b = read()) < 0) throwUnexpectedEOFException();
if ((retvalue & 0xFE00000000000000L) != 0) throwIntOverflowExeption();
retvalue = (retvalue << 7) | (b & 0x7F);
if ((b & 0x80) != 0) break;
}
return retvalue;
}
/**
* Near clone of {@link IonReaderBinaryRawX#readDecimal(int)}
* and {@link IonBinary.Reader#readDecimalValue(IonDecimalImpl, int)}
* so keep them in sync!
*/
public Decimal readDecimal(int len) throws IOException
{
MathContext mathContext = MathContext.UNLIMITED;
Decimal bd;
// we only write out the '0' value as the nibble 0
if (len == 0) {
bd = Decimal.valueOf(0, mathContext);
}
else {
// otherwise we to it the hard way ....
int startpos = this.position();
int exponent = this.readVarInt();
int bitlen = len - (this.position() - startpos);
BigInteger value;
int signum;
if (bitlen > 0)
{
byte[] bits = new byte[bitlen];
this.read(bits, 0, bitlen);
signum = 1;
if (bits[0] < 0)
{
// value is negative, clear the sign
bits[0] &= 0x7F;
signum = -1;
}
value = new BigInteger(signum, bits);
}
else {
signum = 0;
value = BigInteger.ZERO;
}
// Ion stores exponent, BigDecimal uses the negation "scale"
int scale = -exponent;
if (value.signum() == 0 && signum == -1)
{
assert value.equals(BigInteger.ZERO);
bd = Decimal.negativeZero(scale, mathContext);
}
else
{
bd = Decimal.valueOf(value, scale, mathContext);
}
}
return bd;
}
public Timestamp readTimestamp(int len) throws IOException
{
if (len < 1) {
// nothing to do here - and the timestamp will be NULL
return null;
}
Timestamp val;
Precision p = null; // FIXME remove
Integer offset = null;
int year = 0, month = 0, day = 0, hour = 0, minute = 0, second = 0;
BigDecimal frac = null;
int remaining, end = this.position() + len;
// first up is the offset, which requires a special int reader
// to return the -0 as a null Integer
offset = this.readVarInteger();
// now we'll read the struct values from the input stream
assert position() < end;
if (position() < end) { // FIXME remove
// year is from 0001 to 9999
// or 0x1 to 0x270F or 14 bits - 1 or 2 bytes
year = readVarUInt();
p = Precision.YEAR; // our lowest significant option
// now we look for hours and minutes
if (position() < end) {
month = readVarUInt();
p = Precision.MONTH;
// now we look for hours and minutes
if (position() < end) {
day = readVarUInt();
p = Precision.DAY; // our lowest significant option
// now we look for hours and minutes
if (position() < end) {
hour = readVarUInt();
minute = readVarUInt();
p = Precision.MINUTE;
if (position() < end) {
second = readVarUInt();
p = Precision.SECOND;
remaining = end - position();
if (remaining > 0) {
// now we read in our actual "milliseconds since the epoch"
frac = this.readDecimal(remaining);
}
}
}
}
}
}
// now we let timestamp put it all together
val = Timestamp.createFromUtcFields(p, year, month, day, hour, minute, second, frac, offset);
return val;
}
public String readString(int len) throws IOException
{
// len is bytes, which is greater than or equal to java
// chars even after utf8 to utf16 decoding nonsense
// the char array is way faster than using string buffer
char[] chars = new char[len];
int ii = 0;
int c;
int endPosition = this.position() + len;
while (this.position() < endPosition) {
c = readUnicodeScalar();
if (c < 0) throwUnexpectedEOFException();
if (c < 0x10000) {
chars[ii++] = (char)c;
}
else { // when c is >= 0x10000 we need surrogate encoding
chars[ii++] = (char)_Private_IonConstants.makeHighSurrogate(c);
chars[ii++] = (char)_Private_IonConstants.makeLowSurrogate(c);
}
}
if (this.position() < endPosition) throwUnexpectedEOFException();
return new String(chars, 0, ii);
}
public final int readUnicodeScalar() throws IOException {
int b;
b = read();
// ascii is all good, even -1 (eof)
if (b >= 0x80) {
b = readUnicodeScalar_helper(b);
}
return b;
}
private final int readUnicodeScalar_helper(int b) throws IOException
{
int c = -1;
// now we start gluing the multi-byte value together
if ((b & 0xe0) == 0xc0) {
// for values from 0x80 to 0x7FF (all legal)
c = (b & ~0xe0);
b = read();
if ((b & 0xc0) != 0x80) throwUTF8Exception();
c <<= 6;
c |= (b & ~0x80);
}
else if ((b & 0xf0) == 0xe0) {
// for values from 0x800 to 0xFFFFF (NOT all legal)
c = (b & ~0xf0);
b = read();
if ((b & 0xc0) != 0x80) throwUTF8Exception();
c <<= 6;
c |= (b & ~0x80);
b = read();
if ((b & 0xc0) != 0x80) throwUTF8Exception();
c <<= 6;
c |= (b & ~0x80);
if (c > 0x00D7FF && c < 0x00E000) {
throw new IonException("illegal surrogate value encountered in input utf-8 stream");
}
}
else if ((b & 0xf8) == 0xf0) {
// for values from 0x010000 to 0x1FFFFF (NOT all legal)
c = (b & ~0xf8);
b = read();
if ((b & 0xc0) != 0x80) throwUTF8Exception();
c <<= 6;
c |= (b & ~0x80);
b = read();
if ((b & 0xc0) != 0x80) throwUTF8Exception();
c <<= 6;
c |= (b & ~0x80);
b = read();
if ((b & 0xc0) != 0x80) throwUTF8Exception();
c <<= 6;
c |= (b & ~0x80);
if (c > 0x10FFFF) {
throw new IonException("illegal utf value encountered in input utf-8 stream");
}
}
else {
throwUTF8Exception();
}
return c;
}
void throwUTF8Exception() throws IOException
{
throw new IOException("Invalid UTF-8 character encounter in a string at pos " + this.position());
}
void throwUnexpectedEOFException() throws IOException {
throw new IOException("unexpected EOF in value at offset " + this.position());
}
void throwIntOverflowExeption() throws IOException {
throw new IOException("int in stream is too long for a Java int 32 use readLong()");
}
}
static final class UserByteWriter extends OutputStream implements ByteWriter
{
SimpleByteWriter _simple_writer;
OutputStream _user_stream;
int _position;
int _limit;
int _buffer_size;
// constants used for the various write routines to verify
// sufficient room in the output buffer for writing
private final static int MAX_UINT7_BINARY_LENGTH = 5; // (1 + (32 / 7))
private final static int MAX_FLOAT_BINARY_LENGTH = 8; // ieee 64 bit float
private final static int REQUIRED_BUFFER_SPACE = 8; // max of the required lengths
UserByteWriter(OutputStream userOuputStream, byte[] buf)
{
if (buf == null || buf.length < REQUIRED_BUFFER_SPACE) {
throw new IllegalArgumentException("requires a buffer at least "+REQUIRED_BUFFER_SPACE+" bytes long");
}
SimpleByteBuffer bytebuffer = new SimpleByteBuffer(buf);
_simple_writer = new SimpleByteWriter(bytebuffer);
_user_stream = userOuputStream;
_buffer_size = buf.length;
_limit = _buffer_size;
}
private final void checkForSpace(int needed) {
if (_position + needed > _limit) {
flush();
}
}
/**
* this flushes the current buffer to the users output
* stream and resets the buffer. It is called automatically
* as the buffer fills. It can be called at any time if more
* frequent flushing is desired.
*/
@Override
public void flush() {
// is there anything to flush?
if (_position + _buffer_size > _limit) {
try {
_simple_writer.flushTo(_user_stream);
}
catch (IOException e) {
throw new IonException(e);
}
_limit = _position + _buffer_size;
}
}
public void insert(int length)
{
throw new UnsupportedOperationException("use a SimpleByteWriter if you need to insert");
}
public int position()
{
return _position;
}
public void position(int newPosition)
{
throw new UnsupportedOperationException("use a SimpleByteWriter if you need to set your position");
}
public void remove(int length)
{
throw new UnsupportedOperationException("use a SimpleByteWriter if you need to remove bytes");
}
@Override
public void write(int b) throws IOException
{
write((byte)b);
}
public void write(byte b) throws IOException
{
checkForSpace(1);
_simple_writer.write(b);
_position++;
}
// cloned from SimpleByteBuffer as we need to check the
// length and this may require flushing more often than
// the default writeDecimal supports.
public int writeDecimal(BigDecimal value) throws IOException
{
int returnlen = _simple_writer.writeDecimal(value, this);
return returnlen;
}
public int writeFloat(double value) throws IOException
{
checkForSpace(MAX_FLOAT_BINARY_LENGTH);
int returnlen = _simple_writer.writeFloat(value);
return returnlen;
}
public int writeIonInt(long value, int len) throws IOException
{
checkForSpace(len);
int returnlen = _simple_writer.writeIonInt(value, len);
return returnlen;
}
public int writeIonInt(int value, int len) throws IOException
{
checkForSpace(len);
int returnlen = _simple_writer.writeIonInt(value, len);
return returnlen;
}
public int writeString(String value) throws IOException
{
int returnlen = _simple_writer.writeString(value, this);
return returnlen;
}
public void writeTypeDesc(int typeDescByte) throws IOException
{
checkForSpace(1);
_simple_writer.writeTypeDesc(typeDescByte);
}
public int writeTypeDescWithLength(int typeid, int lenOfLength,
int valueLength) throws IOException
{
checkForSpace(1 + MAX_UINT7_BINARY_LENGTH);
int returnlen = _simple_writer.writeTypeDescWithLength(typeid, lenOfLength, valueLength);
return returnlen;
}
public int writeTypeDescWithLength(int typeid, int valueLength) throws IOException
{
checkForSpace(1 + MAX_UINT7_BINARY_LENGTH);
int returnlen = _simple_writer.writeTypeDescWithLength(typeid, valueLength);
return returnlen;
}
public int writeVarInt(long value, int len, boolean forceZeroWrite)
throws IOException
{
checkForSpace(len);
int returnlen = _simple_writer.writeVarInt(value, len, forceZeroWrite);
return returnlen;
}
public int writeVarInt(int value, int len, boolean forceZeroWrite)
throws IOException
{
checkForSpace(len);
int returnlen = _simple_writer.writeVarInt(value, len, forceZeroWrite);
return returnlen;
}
public int writeVarUInt(int value, int len, boolean forceZeroWrite)
throws IOException
{
checkForSpace(len);
int returnlen = _simple_writer.writeVarUInt(value, len, forceZeroWrite);
return returnlen;
}
public int writeVarUInt(long value, int len, boolean forceZeroWrite)
throws IOException
{
checkForSpace(len);
int returnlen = _simple_writer.writeVarUInt(value, len, forceZeroWrite);
return returnlen;
}
}
static final class SimpleByteWriter extends OutputStream implements ByteWriter
{
private static final int _ib_FLOAT64_LEN = 8;
private static final Double DOUBLE_POS_ZERO = Double.valueOf(0.0);
SimpleByteBuffer _buffer;
int _position;
SimpleByteWriter(SimpleByteBuffer bytebuffer) {
_buffer = bytebuffer;
_position = bytebuffer._start;
}
protected void flushTo(OutputStream userOutput) throws IOException {
_buffer.writeBytes(userOutput);
_position = 0;
}
public int position()
{
return _position - _buffer._start;
}
public void position(int newPosition)
{
if (newPosition < 0) {
throw new IllegalArgumentException("position must be non-negative");
}
int pos = newPosition + _buffer._start;
if (pos > _buffer._eob) {
throw new IllegalArgumentException("position is past end of buffer");
}
_position = pos;
}
public void insert(int length)
{
if (length < 0) {
throw new IllegalArgumentException("insert length must be non negative");
}
int remaining = _buffer._eob - _position;
System.arraycopy(_buffer._bytes, _position, _buffer._bytes, _position + length, remaining);
_buffer._eob += length;
}
public void remove(int length)
{
if (length < 0) {
throw new IllegalArgumentException("remove length must be non negative");
}
int remaining = _buffer._eob - _position;
System.arraycopy(_buffer._bytes, _position + length, _buffer._bytes, _position, remaining);
_buffer._eob -= length;
}
@Override
final public void write(int arg0)
throws IOException
{
write((byte)arg0);
}
final public void write(byte b)
{
_buffer._bytes[_position++] = b;
if (_position > _buffer._eob) _buffer._eob = _position;
}
@Override
public void write(byte[] bytes, int start, int len)
{
if (bytes == null || start < 0 || start >= bytes.length || len < 0 || start + len > bytes.length) {
throw new IllegalArgumentException();
}
System.arraycopy(bytes, start, _buffer._bytes, _position, len);
_position += len;
if (_position > _buffer._eob) _buffer._eob = _position;
return;
}
public void writeTypeDesc(int typeDescByte)
{
write((byte)(typeDescByte & 0xff));
}
public int writeTypeDescWithLength(int typeid, int lenOfLength, int valueLength)
{
int written_len = 1;
int td = ((typeid & 0xf) << 4);
if (valueLength >= _Private_IonConstants.lnIsVarLen) {
td |= _Private_IonConstants.lnIsVarLen;
writeTypeDesc(td);
written_len += writeVarUInt(valueLength, lenOfLength, true);
}
else {
td |= (valueLength & 0xf);
writeTypeDesc(td);
}
return written_len;
}
public int writeTypeDescWithLength(int typeid, int valueLength)
{
int written_len = 1;
int td = ((typeid & 0xf) << 4);
if (valueLength >= _Private_IonConstants.lnIsVarLen) {
td |= _Private_IonConstants.lnIsVarLen;
writeTypeDesc(td);
int lenOfLength = IonBinary.lenVarUInt(valueLength);
written_len += writeVarUInt(valueLength, lenOfLength, true);
}
else {
td |= (valueLength & 0xf);
writeTypeDesc(td);
}
return written_len;
}
public int writeVarInt(int value, int len, boolean force_zero_write)
{
// int len = 0;
if (value != 0) {
int mask = 0x7F;
boolean is_negative = false;
assert len == IonBinary.lenVarInt(value);
if (is_negative = (value < 0)) {
value = -value;
}
// we write the first "byte" separately as it has the sign
// changed shift operator from >> to >>>, we don't want to
// sign extend, this is only a problem with MIN_VALUE where
// negating the value (above) still results in a negative number
int b = (byte)((value >>> (7*(len-1))) & mask);
if (is_negative) b |= 0x40; // the sign bit only on the first byte
if (len == 1) b |= 0x80; // the terminator in case the first "byte" is the last
write((byte)b);
// write the rest
switch (len) { // we already wrote 1 byte
case 5: write((byte)((value >> (7*3)) & mask));
case 4: write((byte)((value >> (7*2)) & mask));
case 3: write((byte)((value >> (7*1)) & mask));
case 2: write((byte)((value & mask) | 0x80));
case 1: // do nothing
}
}
else if (force_zero_write) {
write((byte)0x80);
assert len == 1;
}
else {
assert len == 0;
}
return len;
}
public int writeVarInt(int value, boolean force_zero_write)
{
int len = IonBinary.lenVarInt(value);
len = writeVarInt(value, len, force_zero_write);
return len;
}
public int writeVarUInt(int value, int len, boolean force_zero_write)
{
int mask = 0x7F;
if (value < 0) {
throw new IllegalArgumentException("signed int where unsigned (>= 0) was expected");
}
assert len == IonBinary.lenVarUInt(value);
switch (len - 1) {
case 4: write((byte)((value >> (7*4)) & mask));
case 3: write((byte)((value >> (7*3)) & mask));
case 2: write((byte)((value >> (7*2)) & mask));
case 1: write((byte)((value >> (7*1)) & mask));
case 0: write((byte)((value & mask) | 0x80L));
break;
case -1: // or 0
if (force_zero_write) {
write((byte)0x80);
len = 1;
}
break;
}
return len;
}
public int writeVarUInt(int value, boolean force_zero_write)
{
int len = IonBinary.lenVarUInt(value);
len = writeVarUInt(value, len, force_zero_write);
return len;
}
public int writeIonInt(int value, int len)
{
return writeIonInt((long)value, len);
}
public int writeIonInt(long value, int len)
{
// we shouldn't be writing out 0's as an Ion int value
if (value == 0) {
assert len == 0;
return len; // aka 0
}
// figure out how many we have bytes we have to write out
long mask = 0xffL;
boolean is_negative = (value < 0);
assert len == IonBinary.lenIonInt(value);
if (is_negative) {
value = -value;
// note for Long.MIN_VALUE the negation returns
// itself as a value, but that's also the correct
// "positive" value to write out anyway, so it
// all works out
}
// write the rest
switch (len) { // we already wrote 1 byte
case 8: write((byte)((value >> (8*7)) & mask));
case 7: write((byte)((value >> (8*6)) & mask));
case 6: write((byte)((value >> (8*5)) & mask));
case 5: write((byte)((value >> (8*4)) & mask));
case 4: write((byte)((value >> (8*3)) & mask));
case 3: write((byte)((value >> (8*2)) & mask));
case 2: write((byte)((value >> (8*1)) & mask));
case 1: write((byte)(value & mask));
}
return len;
}
public int writeVarInt(long value, int len, boolean forceZeroWrite)
{
//int len = 0;
if (value != 0) {
long mask = 0x7fL;
assert len == IonBinary.lenInt(value);
int b;
if (value < 0) {
value = -value;
// we write the first "byte" separately as it has the sign
// and we have to deal with the oddball MIN_VALUE case
if (value == Long.MIN_VALUE) {
// we use the shift without sign extension as this
// represents a positive value (even though it's neg)
b = (byte)((value >>> (7*len)) & mask);
// len must be greater than 1 so we don't need to set the high bit
}
else {
// here, and hereafter, we don't care about sign extension
b = (byte)((value >>> (7*len)) & mask);
if (len == 1) b |= 0x80; // the terminator in case the first "byte" is the last
}
// we don't worry about stepping on a data bit here as
// we have extra bits at the max size and below that we've
// already taken the sign bit into account
b |= 0x40; // the sign bit
write((byte)b);
}
else {
// we write the first "byte" separately as it has the sign
b = (byte)((value >>> (7*len)) & mask);
if (len == 1) b |= 0x80; // the terminator in case the first "byte" is the last
write((byte)b);
}
// write the rest
switch (len - 1) { // we already wrote 1 byte
case 9: write((byte)((value >>> (7*9)) & mask));
case 8: write((byte)((value >> (7*8)) & mask));
case 7: write((byte)((value >> (7*7)) & mask));
case 6: write((byte)((value >> (7*6)) & mask));
case 5: write((byte)((value >> (7*5)) & mask));
case 4: write((byte)((value >> (7*4)) & mask));
case 3: write((byte)((value >> (7*3)) & mask));
case 2: write((byte)((value >> (7*2)) & mask));
case 1: write((byte)((value >> (7*1)) & mask));
case 0: write((byte)((value & mask) | 0x80L));
}
}
else if (forceZeroWrite) {
write((byte)0x80);
assert len == 1;
}
else {
assert len == 0;
}
return len;
}
public int writeVarUInt(long value, int len, boolean force_zero_write)
{
int mask = 0x7F;
assert len == IonBinary.lenVarUInt(value);
assert value > 0;
switch (len - 1) {
case 9: write((byte)((value >> (7*9)) & mask));
case 8: write((byte)((value >> (7*8)) & mask));
case 7: write((byte)((value >> (7*7)) & mask));
case 6: write((byte)((value >> (7*6)) & mask));
case 5: write((byte)((value >> (7*5)) & mask));
case 4: write((byte)((value >> (7*4)) & mask));
case 3: write((byte)((value >> (7*3)) & mask));
case 2: write((byte)((value >> (7*2)) & mask));
case 1: write((byte)((value >> (7*1)) & mask));
case 0: write((byte)((value & mask) | 0x80L));
break;
case -1: // or len == 0
if (force_zero_write) {
write((byte)0x80);
assert len == 1;
}
else {
assert len == 0;
}
break;
}
return len;
}
public int writeULong(long value, int lenToWrite) throws IOException
{
switch (lenToWrite) {
case 8: write((byte)((value >> 56) & 0xffL));
case 7: write((byte)((value >> 48) & 0xffL));
case 6: write((byte)((value >> 40) & 0xffL));
case 5: write((byte)((value >> 32) & 0xffL));
case 4: write((byte)((value >> 24) & 0xffL));
case 3: write((byte)((value >> 16) & 0xffL));
case 2: write((byte)((value >> 8) & 0xffL));
case 1: write((byte)((value >> 0) & 0xffL));
}
return lenToWrite;
}
public int writeFloat(double value) throws IOException
{
if (Double.valueOf(value).equals(DOUBLE_POS_ZERO))
{
// pos zero special case
return 0;
}
// TODO write "custom" serialization or verify that
// the java routine is doing the right thing
long dBits = Double.doubleToRawLongBits(value);
return this.writeULong(dBits, _ib_FLOAT64_LEN);
}
public int writeDecimal(BigDecimal value) throws IOException
{
int returnlen = writeDecimal(value, null);
return returnlen;
}
// this is a private version that supports both the buffer write
// and the output to the user stream. This is slower (since there
// are extra tests, an extra call, and an extra paramenter), but
// it avoids duplicating this code. And decimals are generally
// expensive anyway.
private int writeDecimal(BigDecimal value, UserByteWriter userWriter) throws IOException
{
int returnlen = 0;
// we only write out the '0' value as the nibble 0
if (value != null && !BigDecimal.ZERO.equals(value)) {
// otherwise we do it the hard way ....
BigInteger mantissa = value.unscaledValue();
boolean isNegative = (mantissa.compareTo(BigInteger.ZERO) < 0);
if (isNegative) {
mantissa = mantissa.negate();
}
byte[] bits = mantissa.toByteArray();
int scale = value.scale();
// Ion stores exponent, BigDecimal uses the negation "scale"
int exponent = -scale;
if (userWriter != null) {
returnlen += userWriter.writeIonInt(exponent, IonBinary.lenVarUInt(exponent));
}
else {
returnlen += this.writeIonInt(exponent, IonBinary.lenVarUInt(exponent));
}
// If the first bit is set, we can't use it for the sign,
// and we need to write an extra byte to hold it.
boolean needExtraByteForSign = ((bits[0] & 0x80) != 0);
if (needExtraByteForSign)
{
if (userWriter != null) {
userWriter.write((byte)(isNegative ? 0x80 : 0x00));
}
else {
this.write((byte)(isNegative ? 0x80 : 0x00));
}
returnlen++;
}
else if (isNegative)
{
bits[0] |= 0x80;
}
// if we have a userWriter to write to, we really don't care about
// the value in our local buffer.
if (userWriter != null) {
userWriter.write(bits, 0, bits.length);
}
else {
this.write(bits, 0, bits.length);
}
returnlen += bits.length;
}
return returnlen;
}
public int writeTimestamp(Timestamp di)
throws IOException
{
if (di == null) return 0;
int returnlen = 0;
Precision precision = di.getPrecision();
Integer offset = di.getLocalOffset();
if (offset == null) {
// TODO don't use magic numbers!
this.write((byte)(0xff & (0x80 | 0x40))); // negative 0 (no timezone)
returnlen ++;
}
else {
int value = offset.intValue();
returnlen += this.writeVarInt(value, true);
}
// now the date - year, month, day as varUint7's
// if we have a non-null value we have at least the date
if (precision.includes(Precision.YEAR)) {
returnlen += this.writeVarUInt(di.getZYear(), true);
}
if (precision.includes(Precision.MONTH)) {
returnlen += this.writeVarUInt(di.getZMonth(), true);
}
if (precision.includes(Precision.DAY)) {
returnlen += this.writeVarUInt(di.getZDay(), true);
}
// now the time part
if (precision.includes(Precision.MINUTE)) {
returnlen += this.writeVarUInt(di.getZHour(), true);
returnlen += this.writeVarUInt(di.getZMinute(), true);
}
if (precision.includes(Precision.SECOND)) {
returnlen += this.writeVarUInt(di.getZSecond(), true);
BigDecimal fraction = di.getZFractionalSecond();
if (fraction != null) {
// and, finally, any fractional component that is known
returnlen += this.writeDecimal(di.getZFractionalSecond());
}
}
return returnlen;
}
final public int writeString(String value) throws IOException
{
int returnlen = writeString(value, null);
return returnlen;
}
final private int writeString(String value, UserByteWriter userWriter) throws IOException
{
int len = 0;
for (int ii=0; ii 127) {
if (c >= 0xD800 && c <= 0xDFFF) {
if (_Private_IonConstants.isHighSurrogate(c)) {
ii++;
// houston we have a high surrogate (let's hope it has a partner
if (ii >= value.length()) {
throw new IonException("invalid string, unpaired high surrogate character");
}
int c2 = value.charAt(ii);
if (!_Private_IonConstants.isLowSurrogate(c2)) {
throw new IonException("invalid string, unpaired high surrogate character");
}
c = _Private_IonConstants.makeUnicodeScalar(c, c2);
}
else if (_Private_IonConstants.isLowSurrogate(c)) {
// it's a loner low surrogate - that's an error
throw new IonException("invalid string, unpaired low surrogate character");
}
// from 0xE000 up the _writeUnicodeScalar will check for us
}
c = IonBinary.makeUTF8IntFromScalar(c);
}
// write it here - try to test userWriter as little as possible
if (userWriter == null) {
for (;;) {
write((byte)(c & 0xff));
len++;
if ((c & 0xffffff00) == 0) {
break;
}
c = c >>> 8;
}
}
else {
for (;;) {
userWriter.write((byte)(c & 0xff));
len++;
if ((c & 0xffffff00) == 0) {
break;
}
c = c >>> 8;
}
}
}
return len;
}
void throwUTF8Exception() throws IOException
{
throwException("Invalid UTF-8 character encounter in a string at pos " + this.position());
}
void throwException(String msg) throws IOException {
throw new IOException(msg);
}
}
}