calibre-web/cps/static/js/archive/unrar.js

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/**
* unrar.js
*
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* Licensed under the MIT License
*
* Copyright(c) 2011 Google Inc.
* Copyright(c) 2011 antimatter15
*
* Reference Documentation:
*
* http://kthoom.googlecode.com/hg/docs/unrar.html
*/
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/* global bitjs, importScripts */
// This file expects to be invoked as a Worker (see onmessage below).
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importScripts('../io/bitstream.js');
importScripts('../io/bytebuffer.js');
importScripts('archive.js');
importScripts('rarvm.js');
// Progress variables.
var currentFilename = "";
var currentFileNumber = 0;
var currentBytesUnarchivedInFile = 0;
var currentBytesUnarchived = 0;
var totalUncompressedBytesInArchive = 0;
var totalFilesInArchive = 0;
// Helper functions.
var info = function(str) {
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postMessage(new bitjs.archive.UnarchiveInfoEvent(str));
};
var err = function(str) {
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postMessage(new bitjs.archive.UnarchiveErrorEvent(str));
};
var postProgress = function() {
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postMessage(new bitjs.archive.UnarchiveProgressEvent(
currentFilename,
currentFileNumber,
currentBytesUnarchivedInFile,
currentBytesUnarchived,
totalUncompressedBytesInArchive,
totalFilesInArchive));
};
// shows a byte value as its hex representation
var nibble = "0123456789ABCDEF";
var byteValueToHexString = function(num) {
return nibble[num >> 4] + nibble[num & 0xF];
};
var twoByteValueToHexString = function(num) {
return nibble[(num >> 12) & 0xF] + nibble[(num >> 8) & 0xF] + nibble[(num >> 4) & 0xF] + nibble[num & 0xF];
};
// Volume Types
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// MARK_HEAD = 0x72;
var MAIN_HEAD = 0x73,
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FILE_HEAD = 0x74,
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// COMM_HEAD = 0x75,
// AV_HEAD = 0x76,
// SUB_HEAD = 0x77,
// PROTECT_HEAD = 0x78,
// SIGN_HEAD = 0x79,
// NEWSUB_HEAD = 0x7a,
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ENDARC_HEAD = 0x7b;
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// ============================================================================================== //
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/**
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* @param {bitjs.io.BitStream} bstream
* @constructor
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*/
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var RarVolumeHeader = function(bstream) {
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var headPos = bstream.bytePtr;
// byte 1,2
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info("Rar Volume Header @" + bstream.bytePtr);
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this.crc = bstream.readBits(16);
info(" crc=" + this.crc);
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// byte 3
this.headType = bstream.readBits(8);
info(" headType=" + this.headType);
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// Get flags
// bytes 4,5
this.flags = {};
this.flags.value = bstream.peekBits(16);
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info(" flags=" + twoByteValueToHexString(this.flags.value));
switch (this.headType) {
case MAIN_HEAD:
this.flags.MHD_VOLUME = !!bstream.readBits(1);
this.flags.MHD_COMMENT = !!bstream.readBits(1);
this.flags.MHD_LOCK = !!bstream.readBits(1);
this.flags.MHD_SOLID = !!bstream.readBits(1);
this.flags.MHD_PACK_COMMENT = !!bstream.readBits(1);
this.flags.MHD_NEWNUMBERING = this.flags.MHD_PACK_COMMENT;
this.flags.MHD_AV = !!bstream.readBits(1);
this.flags.MHD_PROTECT = !!bstream.readBits(1);
this.flags.MHD_PASSWORD = !!bstream.readBits(1);
this.flags.MHD_FIRSTVOLUME = !!bstream.readBits(1);
this.flags.MHD_ENCRYPTVER = !!bstream.readBits(1);
bstream.readBits(6); // unused
break;
case FILE_HEAD:
this.flags.LHD_SPLIT_BEFORE = !!bstream.readBits(1); // 0x0001
this.flags.LHD_SPLIT_AFTER = !!bstream.readBits(1); // 0x0002
this.flags.LHD_PASSWORD = !!bstream.readBits(1); // 0x0004
this.flags.LHD_COMMENT = !!bstream.readBits(1); // 0x0008
this.flags.LHD_SOLID = !!bstream.readBits(1); // 0x0010
bstream.readBits(3); // unused
this.flags.LHD_LARGE = !!bstream.readBits(1); // 0x0100
this.flags.LHD_UNICODE = !!bstream.readBits(1); // 0x0200
this.flags.LHD_SALT = !!bstream.readBits(1); // 0x0400
this.flags.LHD_VERSION = !!bstream.readBits(1); // 0x0800
this.flags.LHD_EXTTIME = !!bstream.readBits(1); // 0x1000
this.flags.LHD_EXTFLAGS = !!bstream.readBits(1); // 0x2000
bstream.readBits(2); // unused
info(" LHD_SPLIT_BEFORE = " + this.flags.LHD_SPLIT_BEFORE);
break;
default:
bstream.readBits(16);
}
// byte 6,7
this.headSize = bstream.readBits(16);
info(" headSize=" + this.headSize);
switch (this.headType) {
case MAIN_HEAD:
this.highPosAv = bstream.readBits(16);
this.posAv = bstream.readBits(32);
if (this.flags.MHD_ENCRYPTVER) {
this.encryptVer = bstream.readBits(8);
}
info("Found MAIN_HEAD with highPosAv=" + this.highPosAv + ", posAv=" + this.posAv);
break;
case FILE_HEAD:
this.packSize = bstream.readBits(32);
this.unpackedSize = bstream.readBits(32);
this.hostOS = bstream.readBits(8);
this.fileCRC = bstream.readBits(32);
this.fileTime = bstream.readBits(32);
this.unpVer = bstream.readBits(8);
this.method = bstream.readBits(8);
this.nameSize = bstream.readBits(16);
this.fileAttr = bstream.readBits(32);
if (this.flags.LHD_LARGE) {
info("Warning: Reading in LHD_LARGE 64-bit size values");
this.HighPackSize = bstream.readBits(32);
this.HighUnpSize = bstream.readBits(32);
} else {
this.HighPackSize = 0;
this.HighUnpSize = 0;
if (this.unpackedSize === 0xffffffff) {
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this.HighUnpSize = 0x7fffffff;
this.unpackedSize = 0xffffffff;
}
}
this.fullPackSize = 0;
this.fullUnpackSize = 0;
this.fullPackSize |= this.HighPackSize;
this.fullPackSize <<= 32;
this.fullPackSize |= this.packSize;
// read in filename
this.filename = bstream.readBytes(this.nameSize);
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var _s = "";
for (var _i = 0; _i < this.filename.length ; _i++) {
_s += String.fromCharCode(this.filename[_i]);
}
this.filename = _s;
if (this.flags.LHD_SALT) {
info("Warning: Reading in 64-bit salt value");
this.salt = bstream.readBits(64); // 8 bytes
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}
if (this.flags.LHD_EXTTIME) {
// 16-bit flags
var extTimeFlags = bstream.readBits(16);
// this is adapted straight out of arcread.cpp, Archive::ReadHeader()
for (var I = 0; I < 4; ++I) {
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var rmode = extTimeFlags >> ((3 - I) * 4);
if ((rmode & 8) === 0) {
continue;
}
if (I !== 0) {
bstream.readBits(16);
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}
var count = (rmode & 3);
for (var J = 0; J < count; ++J) {
bstream.readBits(8);
}
}
}
if (this.flags.LHD_COMMENT) {
info("Found a LHD_COMMENT");
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}
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while (headPos + this.headSize > bstream.bytePtr) {
bstream.readBits(1);
}
// If Info line is commented in firefox fails if server on same computer than browser with error "expected expression, got default"
//info("Found FILE_HEAD with packSize=" + this.packSize + ", unpackedSize= " + this.unpackedSize + ", hostOS=" + this.hostOS + ", unpVer=" + this.unpVer + ", method=" + this.method + ", filename=" + this.filename);
break;
default:
info("Found a header of type 0x" + byteValueToHexString(this.headType));
// skip the rest of the header bytes (for now)
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bstream.readBytes(this.headSize - 7);
break;
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}
};
//var BLOCK_LZ = 0;
var rLDecode = [0, 1, 2, 3, 4, 5, 6, 7, 8, 10, 12, 14, 16, 20, 24, 28, 32, 40, 48, 56, 64, 80, 96, 112, 128, 160, 192, 224],
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rLBits = [0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 4, 4, 5, 5, 5, 5],
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rDBitLengthCounts = [4, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 14, 0, 12],
rSDDecode = [0, 4, 8, 16, 32, 64, 128, 192],
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rSDBits = [2, 2, 3, 4, 5, 6, 6, 6];
var rDDecode = [0, 1, 2, 3, 4, 6, 8, 12, 16, 24, 32,
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48, 64, 96, 128, 192, 256, 384, 512, 768, 1024, 1536, 2048, 3072,
4096, 6144, 8192, 12288, 16384, 24576, 32768, 49152, 65536, 98304,
131072, 196608, 262144, 327680, 393216, 458752, 524288, 589824,
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655360, 720896, 786432, 851968, 917504, 983040
];
var rDBits = [0, 0, 0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5,
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5, 6, 6, 7, 7, 8, 8, 9, 9, 10, 10, 11, 11, 12, 12, 13, 13, 14, 14,
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15, 15, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16
];
var rLowDistRepCount = 16;
var rNC = 299,
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rDC = 60,
rLDC = 17,
rRC = 28,
rBC = 20,
rHuffTableSize = (rNC + rDC + rRC + rLDC);
//var UnpBlockType = BLOCK_LZ;
var UnpOldTable = new Array(rHuffTableSize);
var BD = { //bitdecode
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DecodeLen: new Array(16),
DecodePos: new Array(16),
DecodeNum: new Array(rBC)
};
var LD = { //litdecode
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DecodeLen: new Array(16),
DecodePos: new Array(16),
DecodeNum: new Array(rNC)
};
var DD = { //distdecode
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DecodeLen: new Array(16),
DecodePos: new Array(16),
DecodeNum: new Array(rDC)
};
var LDD = { //low dist decode
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DecodeLen: new Array(16),
DecodePos: new Array(16),
DecodeNum: new Array(rLDC)
};
var RD = { //rep decode
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DecodeLen: new Array(16),
DecodePos: new Array(16),
DecodeNum: new Array(rRC)
};
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/**
* @type {Array<bitjs.io.ByteBuffer>}
*/
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var rOldBuffers = [];
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/**
* The current buffer we are unpacking to.
* @type {bitjs.io.ByteBuffer}
*/
var rBuffer;
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/**
* The buffer of the final bytes after filtering (only used in Unpack29).
* @type {bitjs.io.ByteBuffer}
*/
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var wBuffer;
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/**
* In unpack.cpp, UnpPtr keeps track of what bytes have been unpacked
* into the Window buffer and WrPtr keeps track of what bytes have been
* actually written to disk after the unpacking and optional filtering
* has been done.
*
* In our case, rBuffer is the buffer for the unpacked bytes and wBuffer is
* the final output bytes.
*/
/**
* Read in Huffman tables for RAR
* @param {bitjs.io.BitStream} bstream
*/
function rarReadTables(bstream) {
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var BitLength = new Array(rBC);
var Table = new Array(rHuffTableSize);
var i;
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// before we start anything we need to get byte-aligned
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bstream.readBits((8 - bstream.bitPtr) & 0x7);
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if (bstream.readBits(1)) {
info("Error! PPM not implemented yet");
return;
}
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if (!bstream.readBits(1)) { //discard old table
for (i = UnpOldTable.length; i--;) {
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UnpOldTable[i] = 0;
}
}
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// read in bit lengths
for (var I = 0; I < rBC; ++I) {
var Length = bstream.readBits(4);
if (Length === 15) {
var ZeroCount = bstream.readBits(4);
if (ZeroCount === 0) {
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BitLength[I] = 15;
} else {
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ZeroCount += 2;
while (ZeroCount-- > 0 && I < rBC) {
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BitLength[I++] = 0;
}
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--I;
}
} else {
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BitLength[I] = Length;
}
}
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// now all 20 bit lengths are obtained, we construct the Huffman Table:
rarMakeDecodeTables(BitLength, 0, BD, rBC);
var TableSize = rHuffTableSize;
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//console.log(DecodeLen, DecodePos, DecodeNum);
for (i = 0; i < TableSize;) {
var N;
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var num = rarDecodeNumber(bstream, BD);
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if (num < 16) {
Table[i] = (num + UnpOldTable[i]) & 0xf;
i++;
} else if (num < 18) {
N = (num === 16) ? (bstream.readBits(3) + 3) : (bstream.readBits(7) + 11);
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while (N-- > 0 && i < TableSize) {
Table[i] = Table[i - 1];
i++;
}
} else {
N = (num === 18) ? (bstream.readBits(3) + 3) : (bstream.readBits(7) + 11);
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while (N-- > 0 && i < TableSize) {
Table[i++] = 0;
}
}
}
rarMakeDecodeTables(Table, 0, LD, rNC);
rarMakeDecodeTables(Table, rNC, DD, rDC);
rarMakeDecodeTables(Table, rNC + rDC, LDD, rLDC);
rarMakeDecodeTables(Table, rNC + rDC + rLDC, RD, rRC);
for (i = UnpOldTable.length; i--;) {
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UnpOldTable[i] = Table[i];
}
return true;
}
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function rarDecodeNumber(bstream, dec) {
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var DecodeLen = dec.DecodeLen,
DecodePos = dec.DecodePos,
DecodeNum = dec.DecodeNum;
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var bitField = bstream.getBits() & 0xfffe;
//some sort of rolled out binary search
var bits = ((bitField < DecodeLen[8]) ?
((bitField < DecodeLen[4]) ?
((bitField < DecodeLen[2]) ?
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((bitField < DecodeLen[1]) ? 1 : 2) :
((bitField < DecodeLen[3]) ? 3 : 4)) :
(bitField < DecodeLen[6]) ?
((bitField < DecodeLen[5]) ? 5 : 6) :
((bitField < DecodeLen[7]) ? 7 : 8)) :
((bitField < DecodeLen[12]) ?
((bitField < DecodeLen[10]) ?
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((bitField < DecodeLen[9]) ? 9 : 10) :
((bitField < DecodeLen[11]) ? 11 : 12)) :
(bitField < DecodeLen[14]) ?
((bitField < DecodeLen[13]) ? 13 : 14) :
15));
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bstream.readBits(bits);
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var N = DecodePos[bits] + ((bitField - DecodeLen[bits - 1]) >>> (16 - bits));
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return DecodeNum[N];
}
function rarMakeDecodeTables(BitLength, offset, dec, size) {
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var DecodeLen = dec.DecodeLen;
var DecodePos = dec.DecodePos;
var DecodeNum = dec.DecodeNum;
var LenCount = [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0];
var TmpPos = [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0];
var N = 0;
var M = 0;
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var i;
for (i = DecodeNum.length; i--;) {
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DecodeNum[i] = 0;
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}
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for (i = 0; i < size; i++) {
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LenCount[BitLength[i + offset] & 0xF]++;
}
LenCount[0] = 0;
TmpPos[0] = 0;
DecodePos[0] = 0;
DecodeLen[0] = 0;
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var I;
for (I = 1; I < 16; ++I) {
N = 2 * (N + LenCount[I]);
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M = (N << (15 - I));
if (M > 0xFFFF) {
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M = 0xFFFF;
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}
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DecodeLen[I] = M;
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DecodePos[I] = DecodePos[I - 1] + LenCount[I - 1];
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TmpPos[I] = DecodePos[I];
}
for (I = 0; I < size; ++I) {
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if (BitLength[I + offset] != 0) {
DecodeNum[TmpPos[BitLength[offset + I] & 0xF]++] = I;
}
}
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}
// TODO: implement
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/**
* @param {bitjs.io.BitStream} bstream
* @param {boolean} Solid
*/
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function unpack15() { //bstream, Solid) {
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info("ERROR! RAR 1.5 compression not supported");
}
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/**
* Unpacks the bit stream into rBuffer using the Unpack20 algorithm.
* @param {bitjs.io.BitStream} bstream
* @param {boolean} Solid
*/
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function unpack20(bstream) { //, Solid) {
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var destUnpSize = rBuffer.data.length;
var oldDistPtr = 0;
var Length;
var Distance;
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rarReadTables20(bstream);
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while (destUnpSize > rBuffer.ptr) {
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var num = rarDecodeNumber(bstream, LD);
var Bits;
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if (num < 256) {
rBuffer.insertByte(num);
continue;
}
if (num > 269) {
Length = rLDecode[num -= 270] + 3;
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if ((Bits = rLBits[num]) > 0) {
Length += bstream.readBits(Bits);
}
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var DistNumber = rarDecodeNumber(bstream, DD);
Distance = rDDecode[DistNumber] + 1;
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if ((Bits = rDBits[DistNumber]) > 0) {
Distance += bstream.readBits(Bits);
}
if (Distance >= 0x2000) {
Length++;
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if (Distance >= 0x40000) {
Length++;
}
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}
lastLength = Length;
lastDist = rOldDist[oldDistPtr++ & 3] = Distance;
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rarCopyString(Length, Distance);
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continue;
}
if (num === 269) {
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rarReadTables20(bstream);
rarUpdateProgress();
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continue;
}
if (num === 256) {
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lastDist = rOldDist[oldDistPtr++ & 3] = lastDist;
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rarCopyString(lastLength, lastDist);
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continue;
}
if (num < 261) {
Distance = rOldDist[(oldDistPtr - (num - 256)) & 3];
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var LengthNumber = rarDecodeNumber(bstream, RD);
Length = rLDecode[LengthNumber] + 2;
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if ((Bits = rLBits[LengthNumber]) > 0) {
Length += bstream.readBits(Bits);
}
if (Distance >= 0x101) {
Length++;
if (Distance >= 0x2000) {
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Length++
if (Distance >= 0x40000) {
Length++;
}
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}
}
lastLength = Length;
lastDist = rOldDist[oldDistPtr++ & 3] = Distance;
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rarCopyString(Length, Distance);
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continue;
}
if (num < 270) {
Distance = rSDDecode[num -= 261] + 1;
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if ((Bits = rSDBits[num]) > 0) {
Distance += bstream.readBits(Bits);
}
lastLength = 2;
lastDist = rOldDist[oldDistPtr++ & 3] = Distance;
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rarCopyString(2, Distance);
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continue;
}
}
rarUpdateProgress();
}
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function rarUpdateProgress() {
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var change = rBuffer.ptr - currentBytesUnarchivedInFile;
currentBytesUnarchivedInFile = rBuffer.ptr;
currentBytesUnarchived += change;
postProgress();
}
var rNC20 = 298,
rDC20 = 48,
rRC20 = 28,
rBC20 = 19,
rMC20 = 257;
var UnpOldTable20 = new Array(rMC20 * 4);
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function rarReadTables20(bstream) {
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var BitLength = new Array(rBC20);
var Table = new Array(rMC20 * 4);
var TableSize, N, I;
var i;
bstream.readBits(1);
if (!bstream.readBits(1)) {
for (i = UnpOldTable20.length; i--;) {
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UnpOldTable20[i] = 0;
}
}
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TableSize = rNC20 + rDC20 + rRC20;
for (I = 0; I < rBC20; I++) {
BitLength[I] = bstream.readBits(4);
}
rarMakeDecodeTables(BitLength, 0, BD, rBC20);
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I = 0;
while (I < TableSize) {
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var num = rarDecodeNumber(bstream, BD);
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if (num < 16) {
Table[I] = num + UnpOldTable20[I] & 0xf;
I++;
} else if (num === 16) {
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N = bstream.readBits(2) + 3;
while (N-- > 0 && I < TableSize) {
Table[I] = Table[I - 1];
I++;
}
} else {
if (num === 17) {
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N = bstream.readBits(3) + 3;
} else {
N = bstream.readBits(7) + 11;
}
while (N-- > 0 && I < TableSize) {
Table[I++] = 0;
}
}
}
rarMakeDecodeTables(Table, 0, LD, rNC20);
rarMakeDecodeTables(Table, rNC20, DD, rDC20);
rarMakeDecodeTables(Table, rNC20 + rDC20, RD, rRC20);
for (i = UnpOldTable20.length; i--;) {
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UnpOldTable20[i] = Table[i];
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}
}
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var lowDistRepCount = 0;
var prevLowDist = 0;
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var rOldDist = [0, 0, 0, 0];
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var lastDist;
var lastLength;
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// ============================================================================================== //
// Unpack code specific to RarVM
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var VM = new RarVM();
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/**
* Filters code, one entry per filter.
* @type {Array<UnpackFilter>}
*/
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var Filters = [];
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/**
* Filters stack, several entrances of same filter are possible.
* @type {Array<UnpackFilter>}
*/
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var PrgStack = [];
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/**
* Lengths of preceding blocks, one length per filter. Used to reduce
* size required to write block length if lengths are repeating.
* @type {Array<number>}
*/
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var OldFilterLengths = [];
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var LastFilter = 0;
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function InitFilters() {
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OldFilterLengths = [];
LastFilter = 0;
Filters = [];
PrgStack = [];
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}
/**
* @param {number} firstByte The first byte (flags).
* @param {Uint8Array} vmCode An array of bytes.
*/
function rarAddVMCode(firstByte, vmCode) {
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VM.init();
var bstream = new bitjs.io.BitStream(vmCode.buffer, true /* rtl */ );
var filtPos;
if (firstByte & 0x80) {
filtPos = RarVM.readData(bstream);
if (filtPos == 0) {
InitFilters();
} else {
filtPos--;
}
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} else {
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filtPos = LastFilter;
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}
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if (filtPos > Filters.length || filtPos > OldFilterLengths.length) {
return false;
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}
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LastFilter = filtPos;
var newFilter = (filtPos == Filters.length);
// new filter for PrgStack
var stackFilter = new UnpackFilter();
var filter = null;
// new filter code, never used before since VM reset
if (newFilter) {
// too many different filters, corrupt archive
if (filtPos > 1024) {
return false;
}
filter = new UnpackFilter();
Filters.push(filter);
stackFilter.ParentFilter = (Filters.length - 1);
OldFilterLengths.push(0); // OldFilterLengths.Add(1)
filter.ExecCount = 0;
} else { // filter was used in the past
filter = Filters[filtPos];
stackFilter.ParentFilter = filtPos;
filter.ExecCount++;
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}
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var emptyCount = 0;
for (var i = 0; i < PrgStack.length; ++i) {
PrgStack[i - emptyCount] = PrgStack[i];
if (PrgStack[i] == null) {
emptyCount++;
}
if (emptyCount > 0) {
PrgStack[i] = null;
}
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}
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if (emptyCount == 0) {
PrgStack.push(null); //PrgStack.Add(1);
emptyCount = 1;
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}
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var stackPos = PrgStack.length - emptyCount;
PrgStack[stackPos] = stackFilter;
stackFilter.ExecCount = filter.ExecCount;
var blockStart = RarVM.readData(bstream);
if (firstByte & 0x40) {
blockStart += 258;
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}
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stackFilter.BlockStart = (blockStart + rBuffer.ptr) & MAXWINMASK;
if (firstByte & 0x20) {
stackFilter.BlockLength = RarVM.readData(bstream);
} else {
stackFilter.BlockLength = filtPos < OldFilterLengths.length ?
OldFilterLengths[filtPos] :
0;
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}
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stackFilter.NextWindow = (wBuffer.ptr != rBuffer.ptr) &&
(((wBuffer.ptr - rBuffer.ptr) & MAXWINMASK) <= blockStart);
OldFilterLengths[filtPos] = stackFilter.BlockLength;
for (var i = 0; i < 7; ++i) {
stackFilter.Prg.InitR[i] = 0;
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}
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stackFilter.Prg.InitR[3] = VM_GLOBALMEMADDR;
stackFilter.Prg.InitR[4] = stackFilter.BlockLength;
stackFilter.Prg.InitR[5] = stackFilter.ExecCount;
// set registers to optional parameters if any
if (firstByte & 0x10) {
var initMask = bstream.readBits(7);
for (var i = 0; i < 7; ++i) {
if (initMask & (1 << i)) {
stackFilter.Prg.InitR[i] = RarVM.readData(bstream);
}
}
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}
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if (newFilter) {
var vmCodeSize = RarVM.readData(bstream);
if (vmCodeSize >= 0x10000 || vmCodeSize == 0) {
return false;
}
var vmCode = new Uint8Array(vmCodeSize);
for (var i = 0; i < vmCodeSize; ++i) {
//if (Inp.Overflow(3))
// return(false);
vmCode[i] = bstream.readBits(8);
}
VM.prepare(vmCode, filter.Prg);
}
stackFilter.Prg.Cmd = filter.Prg.Cmd;
stackFilter.Prg.AltCmd = filter.Prg.Cmd;
var staticDataSize = filter.Prg.StaticData.length;
if (staticDataSize > 0 && staticDataSize < VM_GLOBALMEMSIZE) {
// read statically defined data contained in DB commands
for (var i = 0; i < staticDataSize; ++i) {
stackFilter.Prg.StaticData[i] = filter.Prg.StaticData[i];
}
}
if (stackFilter.Prg.GlobalData.length < VM_FIXEDGLOBALSIZE) {
stackFilter.Prg.GlobalData = new Uint8Array(VM_FIXEDGLOBALSIZE);
}
var globalData = stackFilter.Prg.GlobalData;
for (var i = 0; i < 7; ++i) {
VM.setLowEndianValue(globalData, stackFilter.Prg.InitR[i], i * 4);
}
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VM.setLowEndianValue(globalData, stackFilter.BlockLength, 0x1c);
VM.setLowEndianValue(globalData, 0, 0x20);
VM.setLowEndianValue(globalData, stackFilter.ExecCount, 0x2c);
for (var i = 0; i < 16; ++i) {
globalData[0x30 + i] = 0;
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}
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// put data block passed as parameter if any
if (firstByte & 8) {
//if (Inp.Overflow(3))
// return(false);
var dataSize = RarVM.readData(bstream);
if (dataSize > (VM_GLOBALMEMSIZE - VM_FIXEDGLOBALSIZE)) {
return (false);
}
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var curSize = stackFilter.Prg.GlobalData.length;
if (curSize < dataSize + VM_FIXEDGLOBALSIZE) {
// Resize global data and update the stackFilter and local variable.
var numBytesToAdd = dataSize + VM_FIXEDGLOBALSIZE - curSize;
var newGlobalData = new Uint8Array(globalData.length + numBytesToAdd);
newGlobalData.set(globalData);
stackFilter.Prg.GlobalData = newGlobalData;
globalData = newGlobalData;
}
//byte *GlobalData=&StackFilter->Prg.GlobalData[VM_FIXEDGLOBALSIZE];
for (var i = 0; i < dataSize; ++i) {
//if (Inp.Overflow(3))
// return(false);
globalData[VM_FIXEDGLOBALSIZE + i] = bstream.readBits(8);
}
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}
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return true;
}
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/**
* @param {!bitjs.io.BitStream} bstream
*/
function rarReadVMCode(bstream) {
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var firstByte = bstream.readBits(8);
var length = (firstByte & 7) + 1;
if (length == 7) {
length = bstream.readBits(8) + 7;
} else if (length == 8) {
length = bstream.readBits(16);
}
// Read all bytes of VM code into an array.
var vmCode = new Uint8Array(length);
for (var i = 0; i < length; i++) {
// Do something here with checking readbuf.
vmCode[i] = bstream.readBits(8);
}
return RarAddVMCode(firstByte, vmCode);
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}
/**
* Unpacks the bit stream into rBuffer using the Unpack29 algorithm.
* @param {bitjs.io.BitStream} bstream
* @param {boolean} Solid
*/
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function unpack29(bstream) {
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// lazy initialize rDDecode and rDBits
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var DDecode = new Array(rDC);
var DBits = new Array(rDC);
var Distance = 0;
var Length = 0;
var Dist = 0, BitLength = 0, Slot = 0;
var I;
for (I = 0; I < rDBitLengthCounts.length; I++, BitLength++) {
for (var J = 0; J < rDBitLengthCounts[I]; J++, Slot++, Dist += (1 << BitLength)) {
DDecode[Slot] = Dist;
DBits[Slot] = BitLength;
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}
}
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var Bits;
//tablesRead = false;
rOldDist = [0, 0, 0, 0];
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lastDist = 0;
lastLength = 0;
var i;
for (i = UnpOldTable.length; i--;) {
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UnpOldTable[i] = 0;
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}
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// read in Huffman tables
rarReadTables(bstream);
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while (true) {
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var num = rarDecodeNumber(bstream, LD);
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if (num < 256) {
rBuffer.insertByte(num);
continue;
}
if (num >= 271) {
Length = rLDecode[num -= 271] + 3;
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if ((Bits = rLBits[num]) > 0) {
Length += bstream.readBits(Bits);
}
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var DistNumber = rarDecodeNumber(bstream, DD);
Distance = DDecode[DistNumber] + 1;
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if ((Bits = DBits[DistNumber]) > 0) {
if (DistNumber > 9) {
if (Bits > 4) {
Distance += ((bstream.getBits() >>> (20 - Bits)) << 4);
bstream.readBits(Bits - 4);
//todo: check this
}
if (lowDistRepCount > 0) {
lowDistRepCount--;
Distance += prevLowDist;
} else {
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var LowDist = rarDecodeNumber(bstream, LDD);
if (LowDist === 16) {
lowDistRepCount = rLowDistRepCount - 1;
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Distance += prevLowDist;
} else {
Distance += LowDist;
prevLowDist = LowDist;
}
}
} else {
Distance += bstream.readBits(Bits);
}
}
if (Distance >= 0x2000) {
Length++;
if (Distance >= 0x40000) {
Length++;
}
}
rarInsertOldDist(Distance);
rarInsertLastMatch(Length, Distance);
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rarCopyString(Length, Distance);
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continue;
}
if (num === 256) {
if (!rarReadEndOfBlock(bstream)) {
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break;
}
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continue;
}
if (num === 257) {
if (!rarReadVMCode(bstream)) {
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break;
}
continue;
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}
if (num === 258) {
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if (lastLength !== 0) {
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rarCopyString(lastLength, lastDist);
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}
continue;
}
if (num < 263) {
var DistNum = num - 259;
Distance = rOldDist[DistNum];
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for (var I2 = DistNum; I2 > 0; I2--) {
rOldDist[I2] = rOldDist[I2 - 1];
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}
rOldDist[0] = Distance;
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var LengthNumber = rarDecodeNumber(bstream, RD);
Length = rLDecode[LengthNumber] + 2;
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if ((Bits = rLBits[LengthNumber]) > 0) {
Length += bstream.readBits(Bits);
}
rarInsertLastMatch(Length, Distance);
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rarCopyString(Length, Distance);
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continue;
}
if (num < 272) {
Distance = rSDDecode[num -= 263] + 1;
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if ((Bits = rSDBits[num]) > 0) {
Distance += bstream.readBits(Bits);
}
rarInsertOldDist(Distance);
rarInsertLastMatch(2, Distance);
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rarCopyString(2, Distance);
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continue;
}
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} // while (true)
rarUpdateProgress();
rarWriteBuf();
}
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/**
* Does stuff to the current byte buffer (rBuffer) based on
* the filters loaded into the RarVM and writes out to wBuffer.
*/
function rarWriteBuf() {
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var writeSize = (rBuffer.ptr & MAXWINMASK);
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for (var i = 0; i < PrgStack.length; ++i) {
var flt = PrgStack[i];
if (flt == null) {
continue;
}
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if (flt.NextWindow) {
flt.NextWindow = false;
continue;
}
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var blockStart = flt.BlockStart;
var blockLength = flt.BlockLength;
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// WrittenBorder = wBuffer.ptr
if (((blockStart - wBuffer.ptr) & MAXWINMASK) < writeSize) {
if (wBuffer.ptr != blockStart) {
// Copy blockStart bytes from rBuffer into wBuffer.
rarWriteArea(wBuffer.ptr, blockStart);
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writeSize = (rBuffer.ptr - wBuffer.ptr) & MAXWINMASK;
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}
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if (blockLength <= writeSize) {
var blockEnd = (blockStart + blockLength) & MAXWINMASK;
if (blockStart < blockEnd || blockEnd == 0) {
VM.setMemory(0, rBuffer.data.subarray(blockStart, blockStart + blockLength), blockLength);
} else {
var firstPartLength = MAXWINSIZE - blockStart;
VM.setMemory(0, rBuffer.data.subarray(blockStart, blockStart + firstPartLength), firstPartLength);
VM.setMemory(firstPartLength, rBuffer.data, blockEnd);
}
var parentPrg = Filters[flt.ParentFilter].Prg;
var prg = flt.Prg;
if (parentPrg.GlobalData.length > VM_FIXEDGLOBALSIZE) {
// Copy global data from previous script execution if any.
prg.GlobalData = new Uint8Array(parentPrg.GlobalData);
}
rarExecuteCode(prg);
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if (prg.GlobalData.length > VM_FIXEDGLOBALSIZE) {
// Save global data for next script execution.
var globalDataLen = prg.GlobalData.length;
if (parentPrg.GlobalData.length < globalDataLen) {
parentPrg.GlobalData = new Uint8Array(globalDataLen);
}
parentPrg.GlobalData.set(
this.mem_.subarray(VM_FIXEDGLOBALSIZE, VM_FIXEDGLOBALSIZE + globalDataLen),
VM_FIXEDGLOBALSIZE);
} else {
parentPrg.GlobalData = new Uint8Array(0);
}
var filteredData = prg.FilteredData;
PrgStack[i] = null;
while (i + 1 < PrgStack.length) {
var nextFilter = PrgStack[i + 1];
if (nextFilter == null || nextFilter.BlockStart != blockStart ||
nextFilter.BlockLength != filteredData.length || nextFilter.NextWindow) {
break;
}
// Apply several filters to same data block.
VM.setMemory(0, filteredData, filteredData.length);
var parentPrg = Filters[nextFilter.ParentFilter].Prg;
var nextPrg = nextFilter.Prg;
var globalDataLen = parentPrg.GlobalData.length;
if (globalDataLen > VM_FIXEDGLOBALSIZE) {
// Copy global data from previous script execution if any.
nextPrg.GlobalData = new Uint8Array(globalDataLen);
nextPrg.GlobalData.set(parentPrg.GlobalData.subarray(VM_FIXEDGLOBALSIZE, VM_FIXEDGLOBALSIZE + globalDataLen), VM_FIXEDGLOBALSIZE);
}
rarExecuteCode(nextPrg);
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if (nextPrg.GlobalData.length > VM_GLOBALMEMSIZE) {
// Save global data for next script execution.
var globalDataLen = nextPrg.GlobalData.length;
if (parentPrg.GlobalData.length < globalDataLen) {
parentPrg.GlobalData = new Uint8Array(globalDataLen);
}
parentPrg.GlobalData.set(
this.mem_.subarray(VM_FIXEDGLOBALSIZE, VM_FIXEDGLOBALSIZE + globalDataLen),
VM_FIXEDGLOBALSIZE);
} else {
parentPrg.GlobalData = new Uint8Array(0);
}
filteredData = nextPrg.FilteredData;
i++;
PrgStack[i] = null;
} // while (i + 1 < PrgStack.length)
for (var j = 0; j < filteredData.length; ++j) {
wBuffer.insertByte(filteredData[j]);
}
writeSize = (rBuffer.ptr - wBuffer.ptr) & MAXWINMASK;
} // if (blockLength <= writeSize)
else {
for (var j = i; j < PrgStack.length; ++j) {
var flt = PrgStack[j];
if (flt != null && flt.NextWindow) {
flt.NextWindow = false;
}
}
//WrPtr=WrittenBorder;
return;
}
} // if (((blockStart - wBuffer.ptr) & MAXWINMASK) < writeSize)
} // for (var i = 0; i < PrgStack.length; ++i)
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// Write any remaining bytes from rBuffer to wBuffer;
rarWriteArea(wBuffer.ptr, rBuffer.ptr);
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// Now that the filtered buffer has been written, swap it back to rBuffer.
rBuffer = wBuffer;
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}
/**
* Copy bytes from rBuffer to wBuffer.
* @param {number} startPtr The starting point to copy from rBuffer.
* @param {number} endPtr The ending point to copy from rBuffer.
*/
function rarWriteArea(startPtr, endPtr) {
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if (endPtr < startPtr) {
console.error('endPtr < startPtr, endPtr=' + endPtr + ', startPtr=' + startPtr);
// rarWriteData(startPtr, -(int)StartPtr & MAXWINMASK);
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// RarWriteData(0, endPtr);
return;
} else if (startPtr < endPtr) {
rarWriteData(startPtr, endPtr - startPtr);
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}
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}
/**
* Writes bytes into wBuffer from rBuffer.
* @param {number} offset The starting point to copy bytes from rBuffer.
* @param {number} numBytes The number of bytes to copy.
*/
function rarWriteData(offset, numBytes) {
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if (wBuffer.ptr >= rBuffer.data.length) {
return;
}
var leftToWrite = rBuffer.data.length - wBuffer.ptr;
if (numBytes > leftToWrite) {
numBytes = leftToWrite;
}
for (var i = 0; i < numBytes; ++i) {
wBuffer.insertByte(rBuffer.data[offset + i]);
}
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}
/**
* @param {VM_PreparedProgram} prg
*/
function rarExecuteCode(prg) {
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if (prg.GlobalData.length > 0) {
var writtenFileSize = wBuffer.ptr;
prg.InitR[6] = writtenFileSize;
VM.setLowEndianValue(prg.GlobalData, writtenFileSize, 0x24);
VM.setLowEndianValue(prg.GlobalData, (writtenFileSize >>> 32) >> 0, 0x28);
VM.execute(prg);
}
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}
function rarReadEndOfBlock(bstream) {
rarUpdateProgress();
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var NewTable = false,
NewFile = false;
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if (bstream.readBits(1)) {
NewTable = true;
} else {
NewFile = true;
NewTable = !!bstream.readBits(1);
}
//tablesRead = !NewTable;
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return !(NewFile || (NewTable && !rarReadTables(bstream)));
}
function rarInsertLastMatch(length, distance) {
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lastDist = distance;
lastLength = length;
}
function rarInsertOldDist(distance) {
rOldDist.splice(3, 1);
rOldDist.splice(0, 0, distance);
}
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/**
* Copies len bytes from distance bytes ago in the buffer to the end of the
* current byte buffer.
* @param {number} length How many bytes to copy.
* @param {number} distance How far back in the buffer from the current write
* pointer to start copying from.
*/
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function rarCopyString(length, distance) {
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var srcPtr = rBuffer.ptr - distance;
if (srcPtr < 0) {
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var l = rOldBuffers.length;
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while (srcPtr < 0) {
srcPtr = rOldBuffers[--l].data.length + srcPtr;
}
// TODO: lets hope that it never needs to read beyond file boundaries
while (length--) {
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rBuffer.insertByte(rOldBuffers[l].data[srcPtr++]);
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}
}
if (length > distance) {
while (length--) {
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rBuffer.insertByte(rBuffer.data[srcPtr++]);
}
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} else {
rBuffer.insertBytes(rBuffer.data.subarray(srcPtr, srcPtr + length));
}
}
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/**
* @param {RarLocalFile} v
*/
function unpack(v) {
// TODO: implement what happens when unpVer is < 15
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var Ver = v.header.unpVer <= 15 ? 15 : v.header.unpVer;
var Solid = v.header.LHD_SOLID;
var bstream = new bitjs.io.BitStream(v.fileData.buffer, true /* rtl */ , v.fileData.byteOffset, v.fileData.byteLength);
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rBuffer = new bitjs.io.ByteBuffer(v.header.unpackedSize);
info("Unpacking " + v.filename + " RAR v" + Ver);
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switch (Ver) {
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case 15: // rar 1.5 compression
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unpack15(); //(bstream, Solid);
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break;
case 20: // rar 2.x compression
case 26: // files larger than 2GB
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unpack20(bstream); //, Solid);
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break;
case 29: // rar 3.x compression
case 36: // alternative hash
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wBuffer = new bitjs.io.ByteBuffer(rBuffer.data.length);
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unpack29(bstream);
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break;
} // switch(method)
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rOldBuffers.push(rBuffer);
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// TODO: clear these old buffers when there's over 4MB of history
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return rBuffer.data;
}
// bstream is a bit stream
var RarLocalFile = function(bstream) {
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this.header = new RarVolumeHeader(bstream);
this.filename = this.header.filename;
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if (this.header.headType !== FILE_HEAD && this.header.headType !== ENDARC_HEAD) {
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this.isValid = false;
info("Error! RAR Volume did not include a FILE_HEAD header ");
} else {
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// read in the compressed data
this.fileData = null;
if (this.header.packSize > 0) {
this.fileData = bstream.readBytes(this.header.packSize);
this.isValid = true;
}
}
};
RarLocalFile.prototype.unrar = function() {
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if (!this.header.flags.LHD_SPLIT_BEFORE) {
// unstore file
if (this.header.method === 0x30) {
info("Unstore " + this.filename);
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this.isValid = true;
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currentBytesUnarchivedInFile += this.fileData.length;
currentBytesUnarchived += this.fileData.length;
// Create a new buffer and copy it over.
var len = this.header.packSize;
var newBuffer = new bitjs.io.ByteBuffer(len);
newBuffer.insertBytes(this.fileData);
this.fileData = newBuffer.data;
} else {
this.isValid = true;
this.fileData = unpack(this);
}
}
};
var unrar = function(arrayBuffer) {
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currentFilename = "";
currentFileNumber = 0;
currentBytesUnarchivedInFile = 0;
currentBytesUnarchived = 0;
totalUncompressedBytesInArchive = 0;
totalFilesInArchive = 0;
postMessage(new bitjs.archive.UnarchiveStartEvent());
var bstream = new bitjs.io.BitStream(arrayBuffer, false /* rtl */);
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var header = new RarVolumeHeader(bstream);
if (header.crc === 0x6152 &&
header.headType === 0x72 &&
header.flags.value === 0x1A21 &&
header.headSize === 7) {
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info("Found RAR signature");
var mhead = new RarVolumeHeader(bstream);
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if (mhead.headType !== MAIN_HEAD) {
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info("Error! RAR did not include a MAIN_HEAD header");
} else {
var localFiles = [];
var localFile = null;
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do {
try {
localFile = new RarLocalFile(bstream);
info("RAR localFile isValid=" + localFile.isValid + ", volume packSize=" + localFile.header.packSize);
if (localFile && localFile.isValid && localFile.header.packSize > 0) {
totalUncompressedBytesInArchive += localFile.header.unpackedSize;
localFiles.push(localFile);
} else if (localFile.header.packSize === 0 && localFile.header.unpackedSize === 0) {
localFile.isValid = true;
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}
} catch (err) {
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break;
}
//info("bstream" + bstream.bytePtr+"/"+bstream.bytes.length);
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} while (localFile.isValid);
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totalFilesInArchive = localFiles.length;
// now we have all information but things are unpacked
// TODO: unpack
localFiles = localFiles.sort(function(a, b) {
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var aname = a.filename.toLowerCase();
var bname = b.filename.toLowerCase();
return aname > bname ? 1 : -1;
});
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info(localFiles.map(function(a) {
return a.filename;
}).join(", "));
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for (var i = 0; i < localFiles.length; ++i) {
var localfile = localFiles[i];
// update progress
currentFilename = localfile.header.filename;
currentBytesUnarchivedInFile = 0;
// actually do the unzipping
localfile.unrar();
if (localfile.isValid) {
postMessage(new bitjs.archive.UnarchiveExtractEvent(localfile));
postProgress();
}
}
postProgress();
}
} else {
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err("Invalid RAR file");
}
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postMessage(new bitjs.archive.UnarchiveFinishEvent());
};
// event.data.file has the ArrayBuffer.
onmessage = function(event) {
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var ab = event.data.file;
unrar(ab, true);
};