// /*************************************************************************** // Aaru Data Preservation Suite // ---------------------------------------------------------------------------- // // Filename : Subchannel.cs // Author(s) : Natalia Portillo // // Component : CompactDisc dumping. // // --[ Description ] ---------------------------------------------------------- // // Handles CompactDisc subchannel data. // // --[ License ] -------------------------------------------------------------- // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as // published by the Free Software Foundation, either version 3 of the // License, or (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // // ---------------------------------------------------------------------------- // Copyright © 2011-2020 Natalia Portillo // ****************************************************************************/ using System; using System.Collections.Generic; using Aaru.Checksums; using Aaru.CommonTypes.Enums; using Aaru.CommonTypes.Structs; using Aaru.Core.Logging; using Aaru.Decoders.CD; using Aaru.Devices; // ReSharper disable JoinDeclarationAndInitializer // ReSharper disable InlineOutVariableDeclaration // ReSharper disable TooWideLocalVariableScope namespace Aaru.Core.Devices.Dumping { partial class Dump { public static bool SupportsRwSubchannel(Device dev, DumpLog dumpLog, UpdateStatusHandler updateStatus) { dumpLog?.WriteLine("Checking if drive supports full raw subchannel reading..."); updateStatus?.Invoke("Checking if drive supports full raw subchannel reading..."); return !dev.ReadCd(out _, out _, 0, 2352 + 96, 1, MmcSectorTypes.AllTypes, false, false, true, MmcHeaderCodes.AllHeaders, true, true, MmcErrorField.None, MmcSubchannel.Raw, dev.Timeout, out _); } public static bool SupportsPqSubchannel(Device dev, DumpLog dumpLog, UpdateStatusHandler updateStatus) { dumpLog?.WriteLine("Checking if drive supports PQ subchannel reading..."); updateStatus?.Invoke("Checking if drive supports PQ subchannel reading..."); return !dev.ReadCd(out _, out _, 0, 2352 + 16, 1, MmcSectorTypes.AllTypes, false, false, true, MmcHeaderCodes.AllHeaders, true, true, MmcErrorField.None, MmcSubchannel.Q16, dev.Timeout, out _); } // Return true if indexes have changed bool WriteSubchannelToImage(MmcSubchannel supportedSubchannel, MmcSubchannel desiredSubchannel, byte[] sub, ulong sectorAddress, uint length, SubchannelLog subLog, Dictionary isrcs, byte currentTrack, ref string mcn, Track[] tracks) { if(supportedSubchannel == MmcSubchannel.Q16) sub = Subchannel.ConvertQToRaw(sub); if(desiredSubchannel != MmcSubchannel.None) _outputPlugin.WriteSectorsTag(sub, sectorAddress, length, SectorTagType.CdSectorSubchannel); subLog?.WriteEntry(sub, supportedSubchannel == MmcSubchannel.Raw, (long)sectorAddress, length); byte[] deSub = Subchannel.Deinterleave(sub); // Check subchannel for(int subPos = 0; subPos < deSub.Length; subPos += 96) { byte[] q = new byte[12]; Array.Copy(deSub, subPos + 12, q, 0, 12); CRC16CCITTContext.Data(q, 10, out byte[] crc); bool crcOk = crc[0] == q[10] && crc[1] == q[11]; // ISRC if((q[0] & 0x3) == 3) { string isrc = Subchannel.DecodeIsrc(q); if(isrc == null || isrc == "000000000000") continue; if(!crcOk) continue; if(!isrcs.ContainsKey(currentTrack)) { _dumpLog?.WriteLine($"Found new ISRC {isrc} for track {currentTrack}."); UpdateStatus?.Invoke($"Found new ISRC {isrc} for track {currentTrack}."); } else if(isrcs[currentTrack] != isrc) { _dumpLog?. WriteLine($"ISRC for track {currentTrack} changed from {isrcs[currentTrack]} to {isrc}."); UpdateStatus?. Invoke($"ISRC for track {currentTrack} changed from {isrcs[currentTrack]} to {isrc}."); } isrcs[currentTrack] = isrc; } else if((q[0] & 0x3) == 2) { string newMcn = Subchannel.DecodeMcn(q); if(newMcn == null || newMcn == "0000000000000") continue; if(!crcOk) continue; if(mcn is null) { _dumpLog?.WriteLine($"Found new MCN {newMcn}."); UpdateStatus?.Invoke($"Found new MCN {newMcn}."); } else if(mcn != newMcn) { _dumpLog?.WriteLine($"MCN changed from {mcn} to {newMcn}."); UpdateStatus?.Invoke($"MCN changed from {mcn} to {newMcn}."); } mcn = newMcn; } else if((q[0] & 0x3) == 1) { // TODO: Indexes // Pregap if(q[2] != 0) continue; if(!crcOk) continue; byte trackNo = (byte)(((q[1] / 16) * 10) + (q[1] & 0x0F)); for(int i = 0; i < tracks.Length; i++) { if(tracks[i].TrackSequence != trackNo || trackNo == 1) { continue; } byte pmin = (byte)(((q[3] / 16) * 10) + (q[3] & 0x0F)); byte psec = (byte)(((q[4] / 16) * 10) + (q[4] & 0x0F)); byte pframe = (byte)(((q[5] / 16) * 10) + (q[5] & 0x0F)); int qPos = (pmin * 60 * 75) + (psec * 75) + pframe; if(tracks[i].TrackPregap >= (ulong)(qPos + 1)) continue; tracks[i].TrackPregap = (ulong)(qPos + 1); tracks[i].TrackStartSector -= tracks[i].TrackPregap; if(i > 0) tracks[i - 1].TrackEndSector = tracks[i].TrackStartSector - 1; _dumpLog?.WriteLine($"Pregap for track {trackNo} set to {tracks[i].TrackPregap} sectors."); UpdateStatus?.Invoke($"Pregap for track {trackNo} set to {tracks[i].TrackPregap} sectors."); return true; } } } return false; } } }