CavalliumDBEngine/src/main/java/org/warp/commonutils/stream/SafeDataOutput.java

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/*
* Copyright (c) 1995, 2020, Oracle and/or its affiliates. All rights reserved.
* ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
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package org.warp.commonutils.stream;
/**
* The {@code SafeDataOutput} interface provides
* for converting data from any of the Java
* primitive types to a series of bytes and
* writing these bytes to a binary stream.
* There is also a facility for converting
* a {@code String} into
* <a href="DataInput.html#modified-utf-8">modified UTF-8</a>
* format and writing the resulting series
* of bytes.
* <p>
* For all the methods in this interface that
* write bytes, it is generally true that if
* a byte cannot be written for any reason,
* an {@code IOException} is thrown.
*
* @author Frank Yellin
* @see java.io.DataInput
* @see java.io.DataOutputStream
* @since 1.0
*/
public interface SafeDataOutput {
/**
* Writes to the output stream the eight
* low-order bits of the argument {@code b}.
* The 24 high-order bits of {@code b}
* are ignored.
*
* @param b the byte to be written.
*/
void write(int b);
/**
* Writes to the output stream all the bytes in array {@code b}.
* If {@code b} is {@code null},
* a {@code NullPointerException} is thrown.
* If {@code b.length} is zero, then
* no bytes are written. Otherwise, the byte
* {@code b[0]} is written first, then
* {@code b[1]}, and so on; the last byte
* written is {@code b[b.length-1]}.
*
* @param b the data.
*/
void write(byte b[]);
/**
* Writes {@code len} bytes from array
* {@code b}, in order, to
* the output stream. If {@code b}
* is {@code null}, a {@code NullPointerException}
* is thrown. If {@code off} is negative,
* or {@code len} is negative, or {@code off+len}
* is greater than the length of the array
* {@code b}, then an {@code IndexOutOfBoundsException}
* is thrown. If {@code len} is zero,
* then no bytes are written. Otherwise, the
* byte {@code b[off]} is written first,
* then {@code b[off+1]}, and so on; the
* last byte written is {@code b[off+len-1]}.
*
* @param b the data.
* @param off the start offset in the data.
* @param len the number of bytes to write.
*/
void write(byte b[], int off, int len);
/**
* Writes a {@code boolean} value to this output stream.
* If the argument {@code v}
* is {@code true}, the value {@code (byte)1}
* is written; if {@code v} is {@code false},
* the value {@code (byte)0} is written.
* The byte written by this method may
* be read by the {@code readBoolean}
* method of interface {@code DataInput},
* which will then return a {@code boolean}
* equal to {@code v}.
*
* @param v the boolean to be written.
*/
void writeBoolean(boolean v);
/**
* Writes to the output stream the eight low-order
* bits of the argument {@code v}.
* The 24 high-order bits of {@code v}
* are ignored. (This means that {@code writeByte}
* does exactly the same thing as {@code write}
* for an integer argument.) The byte written
* by this method may be read by the {@code readByte}
* method of interface {@code DataInput},
* which will then return a {@code byte}
* equal to {@code (byte)v}.
*
* @param v the byte value to be written.
*/
void writeByte(int v);
/**
* Writes two bytes to the output
* stream to represent the value of the argument.
* The byte values to be written, in the order
* shown, are:
* <pre>{@code
* (byte)(0xff & (v >> 8))
* (byte)(0xff & v)
* }</pre> <p>
* The bytes written by this method may be
* read by the {@code readShort} method
* of interface {@code DataInput}, which
* will then return a {@code short} equal
* to {@code (short)v}.
*
* @param v the {@code short} value to be written.
*/
void writeShort(int v);
/**
* Writes a {@code char} value, which
* is comprised of two bytes, to the
* output stream.
* The byte values to be written, in the order
* shown, are:
* <pre>{@code
* (byte)(0xff & (v >> 8))
* (byte)(0xff & v)
* }</pre><p>
* The bytes written by this method may be
* read by the {@code readChar} method
* of interface {@code DataInput}, which
* will then return a {@code char} equal
* to {@code (char)v}.
*
* @param v the {@code char} value to be written.
*/
void writeChar(int v);
/**
* Writes an {@code int} value, which is
* comprised of four bytes, to the output stream.
* The byte values to be written, in the order
* shown, are:
* <pre>{@code
* (byte)(0xff & (v >> 24))
* (byte)(0xff & (v >> 16))
* (byte)(0xff & (v >> 8))
* (byte)(0xff & v)
* }</pre><p>
* The bytes written by this method may be read
* by the {@code readInt} method of interface
* {@code DataInput}, which will then
* return an {@code int} equal to {@code v}.
*
* @param v the {@code int} value to be written.
*/
void writeInt(int v);
/**
* Writes a {@code long} value, which is
* comprised of eight bytes, to the output stream.
* The byte values to be written, in the order
* shown, are:
* <pre>{@code
* (byte)(0xff & (v >> 56))
* (byte)(0xff & (v >> 48))
* (byte)(0xff & (v >> 40))
* (byte)(0xff & (v >> 32))
* (byte)(0xff & (v >> 24))
* (byte)(0xff & (v >> 16))
* (byte)(0xff & (v >> 8))
* (byte)(0xff & v)
* }</pre><p>
* The bytes written by this method may be
* read by the {@code readLong} method
* of interface {@code DataInput}, which
* will then return a {@code long} equal
* to {@code v}.
*
* @param v the {@code long} value to be written.
*/
void writeLong(long v);
/**
* Writes a {@code float} value,
* which is comprised of four bytes, to the output stream.
* It does this as if it first converts this
* {@code float} value to an {@code int}
* in exactly the manner of the {@code Float.floatToIntBits}
* method and then writes the {@code int}
* value in exactly the manner of the {@code writeInt}
* method. The bytes written by this method
* may be read by the {@code readFloat}
* method of interface {@code DataInput},
* which will then return a {@code float}
* equal to {@code v}.
*
* @param v the {@code float} value to be written.
*/
void writeFloat(float v);
/**
* Writes a {@code double} value,
* which is comprised of eight bytes, to the output stream.
* It does this as if it first converts this
* {@code double} value to a {@code long}
* in exactly the manner of the {@code Double.doubleToLongBits}
* method and then writes the {@code long}
* value in exactly the manner of the {@code writeLong}
* method. The bytes written by this method
* may be read by the {@code readDouble}
* method of interface {@code DataInput},
* which will then return a {@code double}
* equal to {@code v}.
*
* @param v the {@code double} value to be written.
*/
void writeDouble(double v);
/**
* Writes a string to the output stream.
* For every character in the string
* {@code s}, taken in order, one byte
* is written to the output stream. If
* {@code s} is {@code null}, a {@code NullPointerException}
* is thrown.<p> If {@code s.length}
* is zero, then no bytes are written. Otherwise,
* the character {@code s[0]} is written
* first, then {@code s[1]}, and so on;
* the last character written is {@code s[s.length-1]}.
* For each character, one byte is written,
* the low-order byte, in exactly the manner
* of the {@code writeByte} method . The
* high-order eight bits of each character
* in the string are ignored.
*
* @param s the string of bytes to be written.
*/
void writeBytes(String s);
/**
* Writes every character in the string {@code s},
* to the output stream, in order,
* two bytes per character. If {@code s}
* is {@code null}, a {@code NullPointerException}
* is thrown. If {@code s.length}
* is zero, then no characters are written.
* Otherwise, the character {@code s[0]}
* is written first, then {@code s[1]},
* and so on; the last character written is
* {@code s[s.length-1]}. For each character,
* two bytes are actually written, high-order
* byte first, in exactly the manner of the
* {@code writeChar} method.
*
* @param s the string value to be written.
*/
void writeChars(String s);
/**
* Writes two bytes of length information
* to the output stream, followed
* by the
* <a href="DataInput.html#modified-utf-8">modified UTF-8</a>
* representation
* of every character in the string {@code s}.
* If {@code s} is {@code null},
* a {@code NullPointerException} is thrown.
* Each character in the string {@code s}
* is converted to a group of one, two, or
* three bytes, depending on the value of the
* character.<p>
* If a character {@code c}
* is in the range <code>&#92;u0001</code> through
* <code>&#92;u007f</code>, it is represented
* by one byte:
* <pre>(byte)c </pre> <p>
* If a character {@code c} is <code>&#92;u0000</code>
* or is in the range <code>&#92;u0080</code>
* through <code>&#92;u07ff</code>, then it is
* represented by two bytes, to be written
* in the order shown: <pre>{@code
* (byte)(0xc0 | (0x1f & (c >> 6)))
* (byte)(0x80 | (0x3f & c))
* }</pre> <p> If a character
* {@code c} is in the range <code>&#92;u0800</code>
* through {@code uffff}, then it is
* represented by three bytes, to be written
* in the order shown: <pre>{@code
* (byte)(0xe0 | (0x0f & (c >> 12)))
* (byte)(0x80 | (0x3f & (c >> 6)))
* (byte)(0x80 | (0x3f & c))
* }</pre> <p> First,
* the total number of bytes needed to represent
* all the characters of {@code s} is
* calculated. If this number is larger than
* {@code 65535}, then a {@code UTFDataFormatException}
* is thrown. Otherwise, this length is written
* to the output stream in exactly the manner
* of the {@code writeShort} method;
* after this, the one-, two-, or three-byte
* representation of each character in the
* string {@code s} is written.<p> The
* bytes written by this method may be read
* by the {@code readUTF} method of interface
* {@code DataInput}, which will then
* return a {@code String} equal to {@code s}.
*
* @param s the string value to be written.
*/
void writeUTF(String s);
}