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2025-01-22 16:18:30 +01:00
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Kha/Tools/linux_arm64/std/haxe/io/Input.hx Normal file
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/*
* Copyright (C)2005-2019 Haxe Foundation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
package haxe.io;
/**
An Input is an abstract reader. See other classes in the `haxe.io` package
for several possible implementations.
All functions which read data throw `Eof` when the end of the stream
is reached.
**/
class Input {
/**
Endianness (word byte order) used when reading numbers.
If `true`, big-endian is used, otherwise `little-endian` is used.
**/
public var bigEndian(default, set):Bool;
#if cs
private var helper:BytesData;
#elseif java
private var helper:java.nio.ByteBuffer;
#end
/**
Read and return one byte.
**/
public function readByte():Int {
#if cpp
throw new haxe.exceptions.NotImplementedException();
#else
return throw new haxe.exceptions.NotImplementedException();
#end
}
/**
Read `len` bytes and write them into `s` to the position specified by `pos`.
Returns the actual length of read data that can be smaller than `len`.
See `readFullBytes` that tries to read the exact amount of specified bytes.
**/
public function readBytes(s:Bytes, pos:Int, len:Int):Int {
var k = len;
var b = #if (js || hl) @:privateAccess s.b #else s.getData() #end;
if (pos < 0 || len < 0 || pos + len > s.length)
throw Error.OutsideBounds;
try {
while (k > 0) {
#if neko
untyped __dollar__sset(b, pos, readByte());
#elseif php
b.set(pos, readByte());
#elseif cpp
b[pos] = untyped readByte();
#else
b[pos] = cast readByte();
#end
pos++;
k--;
}
} catch (eof:haxe.io.Eof) {}
return len - k;
}
/**
Close the input source.
Behaviour while reading after calling this method is unspecified.
**/
public function close():Void {}
function set_bigEndian(b:Bool):Bool {
bigEndian = b;
return b;
}
/* ------------------ API ------------------ */
/**
Read and return all available data.
The `bufsize` optional argument specifies the size of chunks by
which data is read. Its default value is target-specific.
**/
public function readAll(?bufsize:Int):Bytes {
if (bufsize == null)
#if php
bufsize = 8192; // default value for PHP and max under certain circumstances
#else
bufsize = (1 << 14); // 16 Ko
#end
var buf = Bytes.alloc(bufsize);
var total = new haxe.io.BytesBuffer();
try {
while (true) {
var len = readBytes(buf, 0, bufsize);
if (len == 0)
throw Error.Blocked;
total.addBytes(buf, 0, len);
}
} catch (e:Eof) {}
return total.getBytes();
}
/**
Read `len` bytes and write them into `s` to the position specified by `pos`.
Unlike `readBytes`, this method tries to read the exact `len` amount of bytes.
**/
public function readFullBytes(s:Bytes, pos:Int, len:Int):Void {
while (len > 0) {
var k = readBytes(s, pos, len);
if (k == 0)
throw Error.Blocked;
pos += k;
len -= k;
}
}
/**
Read and return `nbytes` bytes.
**/
public function read(nbytes:Int):Bytes {
var s = Bytes.alloc(nbytes);
var p = 0;
while (nbytes > 0) {
var k = readBytes(s, p, nbytes);
if (k == 0)
throw Error.Blocked;
p += k;
nbytes -= k;
}
return s;
}
/**
Read a string until a character code specified by `end` is occurred.
The final character is not included in the resulting string.
**/
public function readUntil(end:Int):String {
var buf = new BytesBuffer();
var last:Int;
while ((last = readByte()) != end)
buf.addByte(last);
return buf.getBytes().toString();
}
/**
Read a line of text separated by CR and/or LF bytes.
The CR/LF characters are not included in the resulting string.
**/
public function readLine():String {
var buf = new BytesBuffer();
var last:Int;
var s;
try {
while ((last = readByte()) != 10)
buf.addByte(last);
s = buf.getBytes().toString();
if (s.charCodeAt(s.length - 1) == 13)
s = s.substr(0, -1);
} catch (e:Eof) {
s = buf.getBytes().toString();
if (s.length == 0)
#if neko neko.Lib.rethrow #else throw #end (e);
}
return s;
}
/**
Read a 32-bit floating point number.
Endianness is specified by the `bigEndian` property.
**/
public function readFloat():Float {
return FPHelper.i32ToFloat(readInt32());
}
/**
Read a 64-bit double-precision floating point number.
Endianness is specified by the `bigEndian` property.
**/
public function readDouble():Float {
var i1 = readInt32();
var i2 = readInt32();
return bigEndian ? FPHelper.i64ToDouble(i2, i1) : FPHelper.i64ToDouble(i1, i2);
}
/**
Read a 8-bit signed integer.
**/
public function readInt8():Int {
var n = readByte();
if (n >= 128)
return n - 256;
return n;
}
/**
Read a 16-bit signed integer.
Endianness is specified by the `bigEndian` property.
**/
public function readInt16():Int {
var ch1 = readByte();
var ch2 = readByte();
var n = bigEndian ? ch2 | (ch1 << 8) : ch1 | (ch2 << 8);
if (n & 0x8000 != 0)
return n - 0x10000;
return n;
}
/**
Read a 16-bit unsigned integer.
Endianness is specified by the `bigEndian` property.
**/
public function readUInt16():Int {
var ch1 = readByte();
var ch2 = readByte();
return bigEndian ? ch2 | (ch1 << 8) : ch1 | (ch2 << 8);
}
/**
Read a 24-bit signed integer.
Endianness is specified by the `bigEndian` property.
**/
public function readInt24():Int {
var ch1 = readByte();
var ch2 = readByte();
var ch3 = readByte();
var n = bigEndian ? ch3 | (ch2 << 8) | (ch1 << 16) : ch1 | (ch2 << 8) | (ch3 << 16);
if (n & 0x800000 != 0)
return n - 0x1000000;
return n;
}
/**
Read a 24-bit unsigned integer.
Endianness is specified by the `bigEndian` property.
**/
public function readUInt24():Int {
var ch1 = readByte();
var ch2 = readByte();
var ch3 = readByte();
return bigEndian ? ch3 | (ch2 << 8) | (ch1 << 16) : ch1 | (ch2 << 8) | (ch3 << 16);
}
/**
Read a 32-bit signed integer.
Endianness is specified by the `bigEndian` property.
**/
public function readInt32():Int {
var ch1 = readByte();
var ch2 = readByte();
var ch3 = readByte();
var ch4 = readByte();
#if (php || python)
// php will overflow integers. Convert them back to signed 32-bit ints.
var n = bigEndian ? ch4 | (ch3 << 8) | (ch2 << 16) | (ch1 << 24) : ch1 | (ch2 << 8) | (ch3 << 16) | (ch4 << 24);
if (n & 0x80000000 != 0)
return (n | 0x80000000);
else
return n;
#elseif lua
var n = bigEndian ? ch4 | (ch3 << 8) | (ch2 << 16) | (ch1 << 24) : ch1 | (ch2 << 8) | (ch3 << 16) | (ch4 << 24);
return lua.Boot.clampInt32(n);
#else
return bigEndian ? ch4 | (ch3 << 8) | (ch2 << 16) | (ch1 << 24) : ch1 | (ch2 << 8) | (ch3 << 16) | (ch4 << 24);
#end
}
/**
Read and `len` bytes as a string.
**/
public function readString(len:Int, ?encoding:Encoding):String {
var b = Bytes.alloc(len);
readFullBytes(b, 0, len);
#if neko
return neko.Lib.stringReference(b);
#else
return b.getString(0, len, encoding);
#end
}
#if neko
static var _float_of_bytes = neko.Lib.load("std", "float_of_bytes", 2);
static var _double_of_bytes = neko.Lib.load("std", "double_of_bytes", 2);
static function __init__()
untyped {
Input.prototype.bigEndian = false;
}
#end
#if (flash || js || python)
function getDoubleSig(bytes:Array<Int>) {
return (((bytes[1] & 0xF) << 16) | (bytes[2] << 8) | bytes[3]) * 4294967296.
+ (bytes[4] >> 7) * 2147483648
+ (((bytes[4] & 0x7F) << 24) | (bytes[5] << 16) | (bytes[6] << 8) | bytes[7]);
}
#end
}