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Aaru/Aaru.Core/Devices/Dumping/SBC.cs

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// /***************************************************************************
// Aaru Data Preservation Suite
// ----------------------------------------------------------------------------
//
// Filename : SBC.cs
// Author(s) : Natalia Portillo <claunia@claunia.com>
//
// Component : Core algorithms.
//
// --[ Description ] ----------------------------------------------------------
//
// Dumps SCSI Block devices.
//
// --[ 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 <http://www.gnu.org/licenses/>.
//
// ----------------------------------------------------------------------------
// Copyright © 2011-2020 Natalia Portillo
// ****************************************************************************/
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Xml.Serialization;
using Aaru.CommonTypes;
using Aaru.CommonTypes.Enums;
using Aaru.CommonTypes.Extents;
using Aaru.CommonTypes.Interfaces;
using Aaru.CommonTypes.Metadata;
using Aaru.CommonTypes.Structs;
using Aaru.CommonTypes.Structs.Devices.SCSI;
using Aaru.Console;
using Aaru.Core.Logging;
using Aaru.Core.Media.Detection;
using Aaru.Decoders.SCSI;
using Aaru.Decoders.SCSI.MMC;
using Aaru.Devices;
using Schemas;
using DeviceReport = Aaru.Core.Devices.Report.DeviceReport;
using MediaType = Aaru.CommonTypes.MediaType;
using TrackType = Aaru.CommonTypes.Enums.TrackType;
using Version = Aaru.CommonTypes.Interop.Version;
// ReSharper disable JoinDeclarationAndInitializer
namespace Aaru.Core.Devices.Dumping
{
/// <summary>Implements dumping SCSI Block Commands and Reduced Block Commands devices</summary>
partial class Dump
{
/// <summary>Dumps a SCSI Block Commands device or a Reduced Block Commands devices</summary>
/// <param name="opticalDisc">If device contains an optical disc (e.g. DVD or BD)</param>
/// <param name="mediaTags">Media tags as retrieved in MMC layer</param>
/// <param name="dskType">Disc type as detected in SCSI or MMC layer</param>
void Sbc(Dictionary<MediaTagType, byte[]> mediaTags, MediaType dskType, bool opticalDisc)
{
bool sense;
byte scsiMediumType = 0;
byte scsiDensityCode = 0;
bool containsFloppyPage = false;
const ushort sbcProfile = 0x0001;
DateTime start;
DateTime end;
double totalDuration = 0;
double currentSpeed = 0;
double maxSpeed = double.MinValue;
double minSpeed = double.MaxValue;
byte[] readBuffer;
Modes.DecodedMode? decMode = null;
bool ret;
bool recoveredError;
if(opticalDisc)
switch(dskType)
{
case MediaType.REV35:
case MediaType.REV70:
case MediaType.REV120:
opticalDisc = false;
break;
}
_dumpLog.WriteLine("Initializing reader.");
var scsiReader = new Reader(_dev, _dev.Timeout, null, _errorLog, _dumpRaw);
ulong blocks = scsiReader.GetDeviceBlocks();
uint blockSize = scsiReader.LogicalBlockSize;
if(!opticalDisc)
{
mediaTags = new Dictionary<MediaTagType, byte[]>();
if(_dev.IsUsb &&
_dev.UsbDescriptors != null)
mediaTags.Add(MediaTagType.USB_Descriptors, null);
if(_dev.Type == DeviceType.ATAPI)
mediaTags.Add(MediaTagType.ATAPI_IDENTIFY, null);
if(_dev.IsPcmcia &&
_dev.Cis != null)
mediaTags.Add(MediaTagType.PCMCIA_CIS, null);
sense = _dev.ScsiInquiry(out byte[] cmdBuf, out _);
if(_private)
cmdBuf = DeviceReport.ClearInquiry(cmdBuf);
mediaTags.Add(MediaTagType.SCSI_INQUIRY, cmdBuf);
if(!sense)
{
_dumpLog.WriteLine("Requesting MODE SENSE (10).");
UpdateStatus?.Invoke("Requesting MODE SENSE (10).");
sense = _dev.ModeSense10(out cmdBuf, out _, false, true, ScsiModeSensePageControl.Current, 0x3F,
0xFF, 5, out _);
if(!sense ||
_dev.Error)
sense = _dev.ModeSense10(out cmdBuf, out _, false, true, ScsiModeSensePageControl.Current, 0x3F,
0x00, 5, out _);
if(!sense &&
!_dev.Error)
if(Modes.DecodeMode10(cmdBuf, _dev.ScsiType).HasValue)
{
mediaTags.Add(MediaTagType.SCSI_MODESENSE_10, cmdBuf);
decMode = Modes.DecodeMode10(cmdBuf, _dev.ScsiType);
}
_dumpLog.WriteLine("Requesting MODE SENSE (6).");
UpdateStatus?.Invoke("Requesting MODE SENSE (6).");
sense = _dev.ModeSense6(out cmdBuf, out _, false, ScsiModeSensePageControl.Current, 0x3F, 0x00, 5,
out _);
if(sense || _dev.Error)
sense = _dev.ModeSense6(out cmdBuf, out _, false, ScsiModeSensePageControl.Current, 0x3F, 0x00,
5, out _);
if(sense || _dev.Error)
sense = _dev.ModeSense(out cmdBuf, out _, 5, out _);
if(!sense &&
!_dev.Error)
if(Modes.DecodeMode6(cmdBuf, _dev.ScsiType).HasValue)
{
mediaTags.Add(MediaTagType.SCSI_MODESENSE_6, cmdBuf);
decMode = Modes.DecodeMode6(cmdBuf, _dev.ScsiType);
}
if(decMode.HasValue)
{
scsiMediumType = (byte)decMode.Value.Header.MediumType;
if(decMode.Value.Header.BlockDescriptors != null &&
decMode.Value.Header.BlockDescriptors.Length >= 1)
scsiDensityCode = (byte)decMode.Value.Header.BlockDescriptors[0].Density;
containsFloppyPage = decMode.Value.Pages?.Aggregate(containsFloppyPage,
(current, modePage) =>
current | (modePage.Page == 0x05)) ==
true;
}
}
}
if(dskType == MediaType.Unknown)
dskType = MediaTypeFromDevice.GetFromScsi((byte)_dev.ScsiType, _dev.Manufacturer, _dev.Model,
scsiMediumType, scsiDensityCode, blocks + 1, blockSize);
if(_dev.ScsiType == PeripheralDeviceTypes.MultiMediaDevice)
MMC.DetectDiscType(ref dskType, 1, null, _dev, out _, out _, 0);
switch(dskType)
{
// Hi-MD devices show the disks while in Hi-MD mode, but they cannot be read using any known command
// SonicStage changes the device mode, so it is no longer a mass storage device, and can only read
// tracks written by that same application ID (changes between computers).
case MediaType.MD:
_dumpLog.WriteLine("MiniDisc albums, NetMD discs or user-written audio MiniDisc cannot be dumped.");
StoppingErrorMessage?.
Invoke("MiniDisc albums, NetMD discs or user-written audio MiniDisc cannot be dumped.");
return;
case MediaType.Unknown when _dev.IsUsb && containsFloppyPage:
dskType = MediaType.FlashDrive;
break;
}
if(scsiReader.FindReadCommand())
{
_dumpLog.WriteLine("ERROR: Cannot find correct read command: {0}.", scsiReader.ErrorMessage);
StoppingErrorMessage?.Invoke("Unable to read medium.");
return;
}
if(blocks != 0 &&
blockSize != 0)
{
blocks++;
ulong totalSize = blocks * blockSize;
if(totalSize > 1099511627776)
UpdateStatus?.
Invoke($"Media has {blocks} blocks of {blockSize} bytes/each. (for a total of {totalSize / 1099511627776d:F3} TiB)");
else if(totalSize > 1073741824)
UpdateStatus?.
Invoke($"Media has {blocks} blocks of {blockSize} bytes/each. (for a total of {totalSize / 1073741824d:F3} GiB)");
else if(totalSize > 1048576)
UpdateStatus?.
Invoke($"Media has {blocks} blocks of {blockSize} bytes/each. (for a total of {totalSize / 1048576d:F3} MiB)");
else if(totalSize > 1024)
UpdateStatus?.
Invoke($"Media has {blocks} blocks of {blockSize} bytes/each. (for a total of {totalSize / 1024d:F3} KiB)");
else
UpdateStatus?.
Invoke($"Media has {blocks} blocks of {blockSize} bytes/each. (for a total of {totalSize} bytes)");
}
// Check how many blocks to read, if error show and return
if(scsiReader.GetBlocksToRead(_maximumReadable))
{
_dumpLog.WriteLine("ERROR: Cannot get blocks to read: {0}.", scsiReader.ErrorMessage);
StoppingErrorMessage?.Invoke(scsiReader.ErrorMessage);
return;
}
uint blocksToRead = scsiReader.BlocksToRead;
uint logicalBlockSize = blockSize;
uint physicalBlockSize = scsiReader.PhysicalBlockSize;
if(blocks == 0)
{
_dumpLog.WriteLine("ERROR: Unable to read medium or empty medium present...");
StoppingErrorMessage?.Invoke("Unable to read medium or empty medium present...");
return;
}
UpdateStatus?.Invoke($"Device reports {blocks} blocks ({blocks * blockSize} bytes).");
UpdateStatus?.Invoke($"Device can read {blocksToRead} blocks at a time.");
UpdateStatus?.Invoke($"Device reports {blockSize} bytes per logical block.");
UpdateStatus?.Invoke($"Device reports {scsiReader.LongBlockSize} bytes per physical block.");
UpdateStatus?.Invoke($"SCSI device type: {_dev.ScsiType}.");
UpdateStatus?.Invoke($"SCSI medium type: {scsiMediumType}.");
UpdateStatus?.Invoke($"SCSI density type: {scsiDensityCode}.");
UpdateStatus?.Invoke($"SCSI floppy mode page present: {containsFloppyPage}.");
UpdateStatus?.Invoke($"Media identified as {dskType}");
_dumpLog.WriteLine("Device reports {0} blocks ({1} bytes).", blocks, blocks * blockSize);
_dumpLog.WriteLine("Device can read {0} blocks at a time.", blocksToRead);
_dumpLog.WriteLine("Device reports {0} bytes per logical block.", blockSize);
_dumpLog.WriteLine("Device reports {0} bytes per physical block.", scsiReader.LongBlockSize);
_dumpLog.WriteLine("SCSI device type: {0}.", _dev.ScsiType);
_dumpLog.WriteLine("SCSI medium type: {0}.", scsiMediumType);
_dumpLog.WriteLine("SCSI density type: {0}.", scsiDensityCode);
_dumpLog.WriteLine("SCSI floppy mode page present: {0}.", containsFloppyPage);
_dumpLog.WriteLine("Media identified as {0}.", dskType);
uint longBlockSize = scsiReader.LongBlockSize;
if(_dumpRaw)
if(blockSize == longBlockSize)
{
ErrorMessage?.Invoke(!scsiReader.CanReadRaw
? "Device doesn't seem capable of reading raw data from media."
: "Device is capable of reading raw data but I've been unable to guess correct sector size.");
if(!_force)
{
StoppingErrorMessage?.
Invoke("Not continuing. If you want to continue reading cooked data when raw is not available use the force option.");
// TODO: Exit more gracefully
return;
}
ErrorMessage?.Invoke("Continuing dumping cooked data.");
}
else
{
// Only a block will be read, but it contains 16 sectors and command expect sector number not block number
blocksToRead = (uint)(longBlockSize == 37856 ? 16 : 1);
UpdateStatus?.
Invoke($"Reading {longBlockSize} raw bytes ({blockSize * blocksToRead} cooked bytes) per sector.");
physicalBlockSize = longBlockSize;
blockSize = longBlockSize;
}
ret = true;
foreach(MediaTagType tag in mediaTags.Keys.Where(tag => !_outputPlugin.SupportedMediaTags.Contains(tag)))
{
ret = false;
_dumpLog.WriteLine($"Output format does not support {tag}.");
ErrorMessage?.Invoke($"Output format does not support {tag}.");
}
if(!ret)
{
if(_force)
{
_dumpLog.WriteLine("Several media tags not supported, continuing...");
ErrorMessage?.Invoke("Several media tags not supported, continuing...");
}
else
{
_dumpLog.WriteLine("Several media tags not supported, not continuing...");
StoppingErrorMessage?.Invoke("Several media tags not supported, not continuing...");
return;
}
}
UpdateStatus?.Invoke($"Reading {blocksToRead} sectors at a time.");
_dumpLog.WriteLine("Reading {0} sectors at a time.", blocksToRead);
var mhddLog = new MhddLog(_outputPrefix + ".mhddlog.bin", _dev, blocks, blockSize, blocksToRead, _private);
var ibgLog = new IbgLog(_outputPrefix + ".ibg", sbcProfile);
ret = _outputPlugin.Create(_outputPath, dskType, _formatOptions, blocks, blockSize);
// Cannot create image
if(!ret)
{
_dumpLog.WriteLine("Error creating output image, not continuing.");
_dumpLog.WriteLine(_outputPlugin.ErrorMessage);
StoppingErrorMessage?.Invoke("Error creating output image, not continuing." + Environment.NewLine +
_outputPlugin.ErrorMessage);
return;
}
start = DateTime.UtcNow;
double imageWriteDuration = 0;
if(opticalDisc)
{
if(_outputPlugin is IWritableOpticalImage opticalPlugin)
{
sense = _dev.ReadDiscInformation(out readBuffer, out _, MmcDiscInformationDataTypes.DiscInformation,
_dev.Timeout, out _);
if(!sense)
{
DiscInformation.StandardDiscInformation? discInformation =
DiscInformation.Decode000b(readBuffer);
// This means the output image can store sessions that are not on a CD, like on a DVD or Blu-ray
bool canStoreNotCdSessions =
opticalPlugin.OpticalCapabilities.HasFlag(OpticalImageCapabilities.CanStoreNotCdSessions);
// This means the output image can store tracks that are not on a CD, like on a DVD or Blu-ray
bool canStoreNotCdTracks =
opticalPlugin.OpticalCapabilities.HasFlag(OpticalImageCapabilities.CanStoreNotCdTracks);
if(discInformation.HasValue)
{
if(discInformation?.Sessions > 1 &&
!canStoreNotCdSessions)
{
if(_force)
{
_dumpLog.
WriteLine("Image does not support multiple sessions in non Compact Disc dumps, continuing...");
ErrorMessage?.
Invoke("Image does not support multiple sessions in non Compact Disc dumps, continuing...");
}
else
{
_dumpLog.
WriteLine("Image does not support multiple sessions in non Compact Disc dumps, not continuing...");
StoppingErrorMessage?.
Invoke("Image does not support multiple sessions in non Compact Disc dumps, not continuing...");
return;
}
}
if((discInformation?.LastTrackLastSession - discInformation?.FirstTrackNumber > 0 ||
discInformation?.FirstTrackNumber != 1) &&
!canStoreNotCdTracks)
{
if(_force)
{
_dumpLog.
WriteLine("Image does not support multiple tracks in non Compact Disc dumps, continuing...");
ErrorMessage?.
Invoke("Image does not support multiple tracks in non Compact Disc dumps, continuing...");
}
else
{
_dumpLog.
WriteLine("Image does not support multiple tracks in non Compact Disc dumps, not continuing...");
StoppingErrorMessage?.
Invoke("Image does not support multiple tracks in non Compact Disc dumps, not continuing...");
return;
}
}
UpdateStatus?.Invoke("Building track map...");
_dumpLog.WriteLine("Building track map...");
List<Track> tracks = new List<Track>();
for(ushort tno = discInformation.Value.FirstTrackNumber;
tno <= discInformation?.LastTrackLastSession; tno++)
{
sense = _dev.ReadTrackInformation(out readBuffer, out _, false,
TrackInformationType.LogicalTrackNumber, tno,
_dev.Timeout, out _);
if(sense)
continue;
var trkInfo = TrackInformation.Decode(readBuffer);
if(trkInfo is null)
continue;
var track = new Track
{
TrackSequence = trkInfo.LogicalTrackNumber,
TrackSession = (ushort)(canStoreNotCdSessions ? trkInfo.SessionNumber : 1),
TrackType = TrackType.Data,
TrackStartSector = trkInfo.LogicalTrackStartAddress,
TrackEndSector = (trkInfo.LogicalTrackSize + trkInfo.LogicalTrackStartAddress) - 1,
TrackRawBytesPerSector = (int)blockSize,
TrackBytesPerSector = (int)blockSize,
TrackSubchannelType = TrackSubchannelType.None
};
tracks.Add(track);
}
tracks = tracks.OrderBy(t => t.TrackSequence).ToList();
#if DEBUG
foreach(Track trk in tracks)
UpdateStatus?.
Invoke($"Track {trk.TrackSequence} starts at LBA {trk.TrackStartSector} and ends at LBA {trk.TrackEndSector}");
#endif
if(canStoreNotCdTracks)
{
ret = opticalPlugin.SetTracks(tracks);
if(!ret)
{
_dumpLog.WriteLine("Error sending tracks to output image, not continuing.");
_dumpLog.WriteLine(opticalPlugin.ErrorMessage);
StoppingErrorMessage?.
Invoke("Error sending tracks to output image, not continuing." +
Environment.NewLine + opticalPlugin.ErrorMessage);
return;
}
}
else
opticalPlugin.SetTracks(new List<Track>
{
new Track
{
TrackBytesPerSector = (int)blockSize,
TrackEndSector = blocks - 1,
TrackSequence = 1,
TrackRawBytesPerSector = (int)blockSize,
TrackSubchannelType = TrackSubchannelType.None,
TrackSession = 1,
TrackType = TrackType.Data
}
});
}
}
}
else
{
_dumpLog.WriteLine("The specified plugin does not support storing optical disc images..");
StoppingErrorMessage?.Invoke("The specified plugin does not support storing optical disc images.");
return;
}
}
else if(decMode?.Pages != null)
{
bool setGeometry = false;
foreach(Modes.ModePage page in decMode.Value.Pages)
if(page.Page == 0x04 &&
page.Subpage == 0x00)
{
Modes.ModePage_04? rigidPage = Modes.DecodeModePage_04(page.PageResponse);
if(!rigidPage.HasValue || setGeometry)
continue;
_dumpLog.WriteLine("Setting geometry to {0} cylinders, {1} heads, {2} sectors per track",
rigidPage.Value.Cylinders, rigidPage.Value.Heads,
(uint)(blocks / (rigidPage.Value.Cylinders * rigidPage.Value.Heads)));
UpdateStatus?.
Invoke($"Setting geometry to {rigidPage.Value.Cylinders} cylinders, {rigidPage.Value.Heads} heads, {(uint)(blocks / (rigidPage.Value.Cylinders * rigidPage.Value.Heads))} sectors per track");
_outputPlugin.SetGeometry(rigidPage.Value.Cylinders, rigidPage.Value.Heads,
(uint)(blocks / (rigidPage.Value.Cylinders * rigidPage.Value.Heads)));
setGeometry = true;
}
else if(page.Page == 0x05 &&
page.Subpage == 0x00)
{
Modes.ModePage_05? flexiblePage = Modes.DecodeModePage_05(page.PageResponse);
if(!flexiblePage.HasValue)
continue;
_dumpLog.WriteLine("Setting geometry to {0} cylinders, {1} heads, {2} sectors per track",
flexiblePage.Value.Cylinders, flexiblePage.Value.Heads,
flexiblePage.Value.SectorsPerTrack);
UpdateStatus?.
Invoke($"Setting geometry to {flexiblePage.Value.Cylinders} cylinders, {flexiblePage.Value.Heads} heads, {flexiblePage.Value.SectorsPerTrack} sectors per track");
_outputPlugin.SetGeometry(flexiblePage.Value.Cylinders, flexiblePage.Value.Heads,
flexiblePage.Value.SectorsPerTrack);
setGeometry = true;
}
}
DumpHardwareType currentTry = null;
ExtentsULong extents = null;
ResumeSupport.Process(true, _dev.IsRemovable, blocks, _dev.Manufacturer, _dev.Model, _dev.Serial,
_dev.PlatformId, ref _resume, ref currentTry, ref extents, _dev.FirmwareRevision,
_private);
if(currentTry == null ||
extents == null)
{
StoppingErrorMessage?.Invoke("Could not process resume file, not continuing...");
return;
}
if(_resume.NextBlock > 0)
{
UpdateStatus?.Invoke($"Resuming from block {_resume.NextBlock}.");
_dumpLog.WriteLine("Resuming from block {0}.", _resume.NextBlock);
}
// Set speed
if(_speedMultiplier >= 0)
{
_dumpLog.WriteLine($"Setting speed to {(_speed == 0 ? "MAX." : $"{_speed}x")}.");
UpdateStatus?.Invoke($"Setting speed to {(_speed == 0 ? "MAX." : $"{_speed}x")}.");
_speed *= _speedMultiplier;
if(_speed == 0 ||
_speed > 0xFFFF)
_speed = 0xFFFF;
_dev.SetCdSpeed(out _, RotationalControl.ClvAndImpureCav, (ushort)_speed, 0, _dev.Timeout, out _);
}
bool newTrim = false;
DateTime timeSpeedStart = DateTime.UtcNow;
ulong sectorSpeedStart = 0;
InitProgress?.Invoke();
for(ulong i = _resume.NextBlock; i < blocks; i += blocksToRead)
{
if(_aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
_dumpLog.WriteLine("Aborted!");
break;
}
if(blocks - i < blocksToRead)
blocksToRead = (uint)(blocks - i);
if(currentSpeed > maxSpeed &&
currentSpeed > 0)
maxSpeed = currentSpeed;
if(currentSpeed < minSpeed &&
currentSpeed > 0)
minSpeed = currentSpeed;
UpdateProgress?.Invoke($"Reading sector {i} of {blocks} ({currentSpeed:F3} MiB/sec.)", (long)i,
(long)blocks);
sense = scsiReader.ReadBlocks(out readBuffer, i, blocksToRead, out double cmdDuration, out _);
totalDuration += cmdDuration;
if(!sense &&
!_dev.Error)
{
mhddLog.Write(i, cmdDuration);
ibgLog.Write(i, currentSpeed * 1024);
DateTime writeStart = DateTime.Now;
_outputPlugin.WriteSectors(readBuffer, i, blocksToRead);
imageWriteDuration += (DateTime.Now - writeStart).TotalSeconds;
extents.Add(i, blocksToRead, true);
}
else
{
if(_dev.Manufacturer.ToLowerInvariant() == "insite")
{
_resume.BadBlocks.Add(i);
_resume.NextBlock++;
_aborted = true;
_dumpLog?.
WriteLine("INSITE floptical drives get crazy on the SCSI bus when an error is found, stopping so you can reboot the computer or reset the scsi bus appropriately.");
UpdateStatus?.
Invoke("INSITE floptical drives get crazy on the SCSI bus when an error is found, stopping so you can reboot the computer or reset the scsi bus appropriately");
continue;
}
// TODO: Reset device after X errors
if(_stopOnError)
return; // TODO: Return more cleanly
if(i + _skip > blocks)
_skip = (uint)(blocks - i);
// Write empty data
DateTime writeStart = DateTime.Now;
_outputPlugin.WriteSectors(new byte[blockSize * _skip], i, _skip);
imageWriteDuration += (DateTime.Now - writeStart).TotalSeconds;
for(ulong b = i; b < i + _skip; b++)
_resume.BadBlocks.Add(b);
mhddLog.Write(i, cmdDuration < 500 ? 65535 : cmdDuration);
ibgLog.Write(i, 0);
_dumpLog.WriteLine("Skipping {0} blocks from errored block {1}.", _skip, i);
i += _skip - blocksToRead;
newTrim = true;
}
sectorSpeedStart += blocksToRead;
_resume.NextBlock = i + blocksToRead;
double elapsed = (DateTime.UtcNow - timeSpeedStart).TotalSeconds;
if(elapsed < 1)
continue;
currentSpeed = (sectorSpeedStart * blockSize) / (1048576 * elapsed);
sectorSpeedStart = 0;
timeSpeedStart = DateTime.UtcNow;
}
end = DateTime.UtcNow;
EndProgress?.Invoke();
mhddLog.Close();
ibgLog.Close(_dev, blocks, blockSize, (end - start).TotalSeconds, currentSpeed * 1024,
(blockSize * (double)(blocks + 1)) / 1024 / (totalDuration / 1000), _devicePath);
UpdateStatus?.Invoke($"Dump finished in {(end - start).TotalSeconds} seconds.");
UpdateStatus?.
Invoke($"Average dump speed {((double)blockSize * (double)(blocks + 1)) / 1024 / (totalDuration / 1000):F3} KiB/sec.");
UpdateStatus?.
Invoke($"Average write speed {((double)blockSize * (double)(blocks + 1)) / 1024 / imageWriteDuration:F3} KiB/sec.");
_dumpLog.WriteLine("Dump finished in {0} seconds.", (end - start).TotalSeconds);
_dumpLog.WriteLine("Average dump speed {0:F3} KiB/sec.",
((double)blockSize * (double)(blocks + 1)) / 1024 / (totalDuration / 1000));
_dumpLog.WriteLine("Average write speed {0:F3} KiB/sec.",
((double)blockSize * (double)(blocks + 1)) / 1024 / imageWriteDuration);
#region Trimming
if(_resume.BadBlocks.Count > 0 &&
!_aborted &&
_trim &&
newTrim)
{
start = DateTime.UtcNow;
UpdateStatus?.Invoke("Trimming skipped sectors");
_dumpLog.WriteLine("Trimming skipped sectors");
ulong[] tmpArray = _resume.BadBlocks.ToArray();
InitProgress?.Invoke();
foreach(ulong badSector in tmpArray)
{
if(_aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
_dumpLog.WriteLine("Aborted!");
break;
}
PulseProgress?.Invoke($"Trimming sector {badSector}");
sense = scsiReader.ReadBlock(out readBuffer, badSector, out double _, out recoveredError);
if((sense || _dev.Error) &&
!recoveredError)
continue;
_resume.BadBlocks.Remove(badSector);
extents.Add(badSector);
_outputPlugin.WriteSector(readBuffer, badSector);
}
EndProgress?.Invoke();
end = DateTime.UtcNow;
UpdateStatus?.Invoke($"Trimming finished in {(end - start).TotalSeconds} seconds.");
_dumpLog.WriteLine("Trimming finished in {0} seconds.", (end - start).TotalSeconds);
}
#endregion Trimming
#region Error handling
if(_resume.BadBlocks.Count > 0 &&
!_aborted &&
_retryPasses > 0)
{
int pass = 1;
bool forward = true;
bool runningPersistent = false;
Modes.ModePage? currentModePage = null;
byte[] md6;
byte[] md10;
if(_persistent)
{
Modes.ModePage_01_MMC pgMmc;
Modes.ModePage_01 pg;
sense = _dev.ModeSense6(out readBuffer, out _, false, ScsiModeSensePageControl.Current, 0x01,
_dev.Timeout, out _);
if(sense)
{
sense = _dev.ModeSense10(out readBuffer, out _, false, ScsiModeSensePageControl.Current, 0x01,
_dev.Timeout, out _);
if(!sense)
{
Modes.DecodedMode? dcMode10 = Modes.DecodeMode10(readBuffer, _dev.ScsiType);
if(dcMode10?.Pages != null)
foreach(Modes.ModePage modePage in dcMode10.Value.Pages.Where(modePage =>
modePage.Page == 0x01 && modePage.Subpage == 0x00))
currentModePage = modePage;
}
}
else
{
Modes.DecodedMode? dcMode6 = Modes.DecodeMode6(readBuffer, _dev.ScsiType);
if(dcMode6?.Pages != null)
foreach(Modes.ModePage modePage in dcMode6.Value.Pages.Where(modePage =>
modePage.Page == 0x01 && modePage.Subpage == 0x00))
currentModePage = modePage;
}
if(currentModePage == null)
{
if(_dev.ScsiType == PeripheralDeviceTypes.MultiMediaDevice)
{
pgMmc = new Modes.ModePage_01_MMC
{
PS = false,
ReadRetryCount = 32,
Parameter = 0x00
};
currentModePage = new Modes.ModePage
{
Page = 0x01,
Subpage = 0x00,
PageResponse = Modes.EncodeModePage_01_MMC(pgMmc)
};
}
else
{
pg = new Modes.ModePage_01
{
PS = false,
AWRE = true,
ARRE = true,
TB = false,
RC = false,
EER = true,
PER = false,
DTE = true,
DCR = false,
ReadRetryCount = 32
};
currentModePage = new Modes.ModePage
{
Page = 0x01,
Subpage = 0x00,
PageResponse = Modes.EncodeModePage_01(pg)
};
}
}
if(_dev.ScsiType == PeripheralDeviceTypes.MultiMediaDevice)
{
pgMmc = new Modes.ModePage_01_MMC
{
PS = false,
ReadRetryCount = 255,
Parameter = 0x20
};
var md = new Modes.DecodedMode
{
Header = new Modes.ModeHeader(),
Pages = new[]
{
new Modes.ModePage
{
Page = 0x01,
Subpage = 0x00,
PageResponse = Modes.EncodeModePage_01_MMC(pgMmc)
}
}
};
md6 = Modes.EncodeMode6(md, _dev.ScsiType);
md10 = Modes.EncodeMode10(md, _dev.ScsiType);
}
else
{
pg = new Modes.ModePage_01
{
PS = false,
AWRE = false,
ARRE = false,
TB = true,
RC = false,
EER = true,
PER = false,
DTE = false,
DCR = false,
ReadRetryCount = 255
};
var md = new Modes.DecodedMode
{
Header = new Modes.ModeHeader(),
Pages = new[]
{
new Modes.ModePage
{
Page = 0x01,
Subpage = 0x00,
PageResponse = Modes.EncodeModePage_01(pg)
}
}
};
md6 = Modes.EncodeMode6(md, _dev.ScsiType);
md10 = Modes.EncodeMode10(md, _dev.ScsiType);
}
UpdateStatus?.Invoke("Sending MODE SELECT to drive (return damaged blocks).");
_dumpLog.WriteLine("Sending MODE SELECT to drive (return damaged blocks).");
sense = _dev.ModeSelect(md6, out byte[] senseBuf, true, false, _dev.Timeout, out _);
if(sense)
sense = _dev.ModeSelect10(md10, out senseBuf, true, false, _dev.Timeout, out _);
if(sense)
{
UpdateStatus?.
Invoke("Drive did not accept MODE SELECT command for persistent error reading, try another drive.");
AaruConsole.DebugWriteLine("Error: {0}", Sense.PrettifySense(senseBuf));
_dumpLog.
WriteLine("Drive did not accept MODE SELECT command for persistent error reading, try another drive.");
}
else
{
runningPersistent = true;
}
}
InitProgress?.Invoke();
repeatRetry:
ulong[] tmpArray = _resume.BadBlocks.ToArray();
foreach(ulong badSector in tmpArray)
{
if(_aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
_dumpLog.WriteLine("Aborted!");
break;
}
PulseProgress?.Invoke(string.Format("Retrying sector {0}, pass {1}, {3}{2}", badSector, pass,
forward ? "forward" : "reverse",
runningPersistent ? "recovering partial data, " : ""));
sense = scsiReader.ReadBlock(out readBuffer, badSector, out double cmdDuration, out recoveredError);
totalDuration += cmdDuration;
if((!sense && !_dev.Error) || recoveredError)
{
_resume.BadBlocks.Remove(badSector);
extents.Add(badSector);
_outputPlugin.WriteSector(readBuffer, badSector);
UpdateStatus?.Invoke($"Correctly retried block {badSector} in pass {pass}.");
_dumpLog.WriteLine("Correctly retried block {0} in pass {1}.", badSector, pass);
}
else if(runningPersistent)
{
_outputPlugin.WriteSector(readBuffer, badSector);
}
}
if(pass < _retryPasses &&
!_aborted &&
_resume.BadBlocks.Count > 0)
{
pass++;
forward = !forward;
_resume.BadBlocks.Sort();
if(!forward)
_resume.BadBlocks.Reverse();
goto repeatRetry;
}
if(runningPersistent && currentModePage.HasValue)
{
var md = new Modes.DecodedMode
{
Header = new Modes.ModeHeader(),
Pages = new[]
{
currentModePage.Value
}
};
md6 = Modes.EncodeMode6(md, _dev.ScsiType);
md10 = Modes.EncodeMode10(md, _dev.ScsiType);
UpdateStatus?.Invoke("Sending MODE SELECT to drive (return device to previous status).");
_dumpLog.WriteLine("Sending MODE SELECT to drive (return device to previous status).");
sense = _dev.ModeSelect(md6, out _, true, false, _dev.Timeout, out _);
if(sense)
_dev.ModeSelect10(md10, out _, true, false, _dev.Timeout, out _);
}
EndProgress?.Invoke();
}
#endregion Error handling
if(!_aborted)
if(opticalDisc)
{
foreach(KeyValuePair<MediaTagType, byte[]> tag in mediaTags)
{
if(tag.Value is null)
{
AaruConsole.ErrorWriteLine("Error: Tag type {0} is null, skipping...", tag.Key);
continue;
}
ret = _outputPlugin.WriteMediaTag(tag.Value, tag.Key);
if(ret || _force)
continue;
// Cannot write tag to image
StoppingErrorMessage?.Invoke($"Cannot write tag {tag.Key}.");
_dumpLog.WriteLine($"Cannot write tag {tag.Key}." + Environment.NewLine +
_outputPlugin.ErrorMessage);
return;
}
}
else
{
if(!_dev.IsRemovable ||
_dev.IsUsb)
{
if(_dev.IsUsb &&
_dev.UsbDescriptors != null)
{
UpdateStatus?.Invoke("Reading USB descriptors.");
_dumpLog.WriteLine("Reading USB descriptors.");
ret = _outputPlugin.WriteMediaTag(_dev.UsbDescriptors, MediaTagType.USB_Descriptors);
if(!ret &&
!_force)
{
_dumpLog.WriteLine("Cannot write USB descriptors.");
StoppingErrorMessage?.Invoke("Cannot write USB descriptors." + Environment.NewLine +
_outputPlugin.ErrorMessage);
return;
}
}
byte[] cmdBuf;
if(_dev.Type == DeviceType.ATAPI)
{
UpdateStatus?.Invoke("Requesting ATAPI IDENTIFY PACKET DEVICE.");
_dumpLog.WriteLine("Requesting ATAPI IDENTIFY PACKET DEVICE.");
sense = _dev.AtapiIdentify(out cmdBuf, out _);
if(!sense)
{
if(_private)
cmdBuf = DeviceReport.ClearIdentify(cmdBuf);
ret = _outputPlugin.WriteMediaTag(cmdBuf, MediaTagType.ATAPI_IDENTIFY);
if(!ret &&
!_force)
{
_dumpLog.WriteLine("Cannot write ATAPI IDENTIFY PACKET DEVICE.");
StoppingErrorMessage?.Invoke("Cannot write ATAPI IDENTIFY PACKET DEVICE." +
Environment.NewLine + _outputPlugin.ErrorMessage);
return;
}
}
}
sense = _dev.ScsiInquiry(out cmdBuf, out _);
if(!sense)
{
UpdateStatus?.Invoke("Requesting SCSI INQUIRY.");
_dumpLog.WriteLine("Requesting SCSI INQUIRY.");
ret = _outputPlugin.WriteMediaTag(cmdBuf, MediaTagType.SCSI_INQUIRY);
if(!ret &&
!_force)
{
StoppingErrorMessage?.Invoke("Cannot write SCSI INQUIRY.");
_dumpLog.WriteLine("Cannot write SCSI INQUIRY." + Environment.NewLine +
_outputPlugin.ErrorMessage);
return;
}
UpdateStatus?.Invoke("Requesting MODE SENSE (10).");
_dumpLog.WriteLine("Requesting MODE SENSE (10).");
sense = _dev.ModeSense10(out cmdBuf, out _, false, true, ScsiModeSensePageControl.Current,
0x3F, 0xFF, 5, out _);
if(!sense ||
_dev.Error)
sense = _dev.ModeSense10(out cmdBuf, out _, false, true,
ScsiModeSensePageControl.Current, 0x3F, 0x00, 5, out _);
if(!sense &&
!_dev.Error)
if(Modes.DecodeMode10(cmdBuf, _dev.ScsiType).HasValue)
{
ret = _outputPlugin.WriteMediaTag(cmdBuf, MediaTagType.SCSI_MODESENSE_10);
if(!ret &&
!_force)
{
_dumpLog.WriteLine("Cannot write SCSI MODE SENSE (10).");
StoppingErrorMessage?.Invoke("Cannot write SCSI MODE SENSE (10)." +
Environment.NewLine + _outputPlugin.ErrorMessage);
return;
}
}
UpdateStatus?.Invoke("Requesting MODE SENSE (6).");
_dumpLog.WriteLine("Requesting MODE SENSE (6).");
sense = _dev.ModeSense6(out cmdBuf, out _, false, ScsiModeSensePageControl.Current, 0x3F,
0x00, 5, out _);
if(sense || _dev.Error)
sense = _dev.ModeSense6(out cmdBuf, out _, false, ScsiModeSensePageControl.Current,
0x3F, 0x00, 5, out _);
if(sense || _dev.Error)
sense = _dev.ModeSense(out cmdBuf, out _, 5, out _);
if(!sense &&
!_dev.Error)
if(Modes.DecodeMode6(cmdBuf, _dev.ScsiType).HasValue)
{
ret = _outputPlugin.WriteMediaTag(cmdBuf, MediaTagType.SCSI_MODESENSE_6);
if(!ret &&
!_force)
{
_dumpLog.WriteLine("Cannot write SCSI MODE SENSE (6).");
StoppingErrorMessage?.Invoke("Cannot write SCSI MODE SENSE (6)." +
Environment.NewLine + _outputPlugin.ErrorMessage);
return;
}
}
}
}
}
_resume.BadBlocks.Sort();
foreach(ulong bad in _resume.BadBlocks)
_dumpLog.WriteLine("Sector {0} could not be read.", bad);
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
_outputPlugin.SetDumpHardware(_resume.Tries);
// TODO: Media Serial Number
// TODO: Non-removable drive information
var metadata = new CommonTypes.Structs.ImageInfo
{
Application = "Aaru",
ApplicationVersion = Version.GetVersion()
};
if(!_outputPlugin.SetMetadata(metadata))
ErrorMessage?.Invoke("Error {0} setting metadata, continuing..." + Environment.NewLine +
_outputPlugin.ErrorMessage);
if(_preSidecar != null)
_outputPlugin.SetCicmMetadata(_preSidecar);
_dumpLog.WriteLine("Closing output file.");
UpdateStatus?.Invoke("Closing output file.");
DateTime closeStart = DateTime.Now;
_outputPlugin.Close();
DateTime closeEnd = DateTime.Now;
UpdateStatus?.Invoke($"Closed in {(closeEnd - closeStart).TotalSeconds} seconds.");
_dumpLog.WriteLine("Closed in {0} seconds.", (closeEnd - closeStart).TotalSeconds);
if(_aborted)
{
UpdateStatus?.Invoke("Aborted!");
_dumpLog.WriteLine("Aborted!");
return;
}
double totalChkDuration = 0;
if(_metadata)
{
// TODO: Layers
if(opticalDisc)
WriteOpticalSidecar(blockSize, blocks, dskType, null, mediaTags, 1, out totalChkDuration, null);
else
{
UpdateStatus?.Invoke("Creating sidecar.");
_dumpLog.WriteLine("Creating sidecar.");
var filters = new FiltersList();
IFilter filter = filters.GetFilter(_outputPath);
IMediaImage inputPlugin = ImageFormat.Detect(filter);
if(!inputPlugin.Open(filter))
{
StoppingErrorMessage?.Invoke("Could not open created image.");
return;
}
DateTime chkStart = DateTime.UtcNow;
_sidecarClass = new Sidecar(inputPlugin, _outputPath, filter.Id, _encoding);
_sidecarClass.InitProgressEvent += InitProgress;
_sidecarClass.UpdateProgressEvent += UpdateProgress;
_sidecarClass.EndProgressEvent += EndProgress;
_sidecarClass.InitProgressEvent2 += InitProgress2;
_sidecarClass.UpdateProgressEvent2 += UpdateProgress2;
_sidecarClass.EndProgressEvent2 += EndProgress2;
_sidecarClass.UpdateStatusEvent += UpdateStatus;
CICMMetadataType sidecar = _sidecarClass.Create();
end = DateTime.UtcNow;
totalChkDuration = (end - chkStart).TotalMilliseconds;
UpdateStatus?.Invoke($"Sidecar created in {(end - chkStart).TotalSeconds} seconds.");
UpdateStatus?.
Invoke($"Average checksum speed {((double)blockSize * (double)(blocks + 1)) / 1024 / (totalChkDuration / 1000):F3} KiB/sec.");
_dumpLog.WriteLine("Sidecar created in {0} seconds.", (end - chkStart).TotalSeconds);
_dumpLog.WriteLine("Average checksum speed {0:F3} KiB/sec.",
((double)blockSize * (double)(blocks + 1)) / 1024 / (totalChkDuration / 1000));
if(_preSidecar != null)
{
_preSidecar.BlockMedia = sidecar.BlockMedia;
sidecar = _preSidecar;
}
// All USB flash drives report as removable, even if the media is not removable
if(!_dev.IsRemovable ||
_dev.IsUsb)
{
if(_dev.IsUsb &&
_dev.UsbDescriptors != null)
if(_outputPlugin.SupportedMediaTags.Contains(MediaTagType.USB_Descriptors))
sidecar.BlockMedia[0].USB = new USBType
{
ProductID = _dev.UsbProductId,
VendorID = _dev.UsbVendorId,
Descriptors = new DumpType
{
Image = _outputPath,
Size = (ulong)_dev.UsbDescriptors.Length,
Checksums = Checksum.GetChecksums(_dev.UsbDescriptors).ToArray()
}
};
byte[] cmdBuf;
if(_dev.Type == DeviceType.ATAPI)
{
sense = _dev.AtapiIdentify(out cmdBuf, out _);
if(!sense)
if(_outputPlugin.SupportedMediaTags.Contains(MediaTagType.ATAPI_IDENTIFY))
sidecar.BlockMedia[0].ATA = new ATAType
{
Identify = new DumpType
{
Image = _outputPath,
Size = (ulong)cmdBuf.Length,
Checksums = Checksum.GetChecksums(cmdBuf).ToArray()
}
};
}
sense = _dev.ScsiInquiry(out cmdBuf, out _);
if(!sense)
{
if(_outputPlugin.SupportedMediaTags.Contains(MediaTagType.SCSI_INQUIRY))
sidecar.BlockMedia[0].SCSI = new SCSIType
{
Inquiry = new DumpType
{
Image = _outputPath,
Size = (ulong)cmdBuf.Length,
Checksums = Checksum.GetChecksums(cmdBuf).ToArray()
}
};
// TODO: SCSI Extended Vendor Page descriptors
/*
UpdateStatus?.Invoke("Reading SCSI Extended Vendor Page Descriptors.");
dumpLog.WriteLine("Reading SCSI Extended Vendor Page Descriptors.");
sense = dev.ScsiInquiry(out cmdBuf, out _, 0x00);
if(!sense)
{
byte[] pages = EVPD.DecodePage00(cmdBuf);
if(pages != null)
{
List<EVPDType> evpds = new List<EVPDType>();
foreach(byte page in pages)
{
dumpLog.WriteLine("Requesting page {0:X2}h.", page);
sense = dev.ScsiInquiry(out cmdBuf, out _, page);
if(sense) continue;
EVPDType evpd = new EVPDType
{
Image = $"{outputPrefix}.evpd_{page:X2}h.bin",
Checksums = Checksum.GetChecksums(cmdBuf).ToArray(),
Size = cmdBuf.Length
};
evpd.Checksums = Checksum.GetChecksums(cmdBuf).ToArray();
DataFile.WriteTo("SCSI Dump", evpd.Image, cmdBuf);
evpds.Add(evpd);
}
if(evpds.Count > 0) sidecar.BlockMedia[0].SCSI.EVPD = evpds.ToArray();
}
}
*/
UpdateStatus?.Invoke("Requesting MODE SENSE (10).");
_dumpLog.WriteLine("Requesting MODE SENSE (10).");
sense = _dev.ModeSense10(out cmdBuf, out _, false, true, ScsiModeSensePageControl.Current,
0x3F, 0xFF, 5, out _);
if(!sense ||
_dev.Error)
sense = _dev.ModeSense10(out cmdBuf, out _, false, true,
ScsiModeSensePageControl.Current, 0x3F, 0x00, 5, out _);
decMode = null;
if(!sense &&
!_dev.Error)
if(Modes.DecodeMode10(cmdBuf, _dev.ScsiType).HasValue)
if(_outputPlugin.SupportedMediaTags.Contains(MediaTagType.SCSI_MODESENSE_10))
sidecar.BlockMedia[0].SCSI.ModeSense10 = new DumpType
{
Image = _outputPath,
Size = (ulong)cmdBuf.Length,
Checksums = Checksum.GetChecksums(cmdBuf).ToArray()
};
UpdateStatus?.Invoke("Requesting MODE SENSE (6).");
_dumpLog.WriteLine("Requesting MODE SENSE (6).");
sense = _dev.ModeSense6(out cmdBuf, out _, false, ScsiModeSensePageControl.Current, 0x3F,
0x00, 5, out _);
if(sense || _dev.Error)
sense = _dev.ModeSense6(out cmdBuf, out _, false, ScsiModeSensePageControl.Current,
0x3F, 0x00, 5, out _);
if(sense || _dev.Error)
sense = _dev.ModeSense(out cmdBuf, out _, 5, out _);
if(!sense &&
!_dev.Error)
if(Modes.DecodeMode6(cmdBuf, _dev.ScsiType).HasValue)
if(_outputPlugin.SupportedMediaTags.Contains(MediaTagType.SCSI_MODESENSE_6))
sidecar.BlockMedia[0].SCSI.ModeSense = new DumpType
{
Image = _outputPath,
Size = (ulong)cmdBuf.Length,
Checksums = Checksum.GetChecksums(cmdBuf).ToArray()
};
}
}
List<(ulong start, string type)> filesystems = new List<(ulong start, string type)>();
if(sidecar.BlockMedia[0].FileSystemInformation != null)
filesystems.AddRange(from partition in sidecar.BlockMedia[0].FileSystemInformation
where partition.FileSystems != null
from fileSystem in partition.FileSystems
select (partition.StartSector, fileSystem.Type));
if(filesystems.Count > 0)
foreach(var filesystem in filesystems.Select(o => new
{
o.start,
o.type
}).Distinct())
{
UpdateStatus?.Invoke($"Found filesystem {filesystem.type} at sector {filesystem.start}");
_dumpLog.WriteLine("Found filesystem {0} at sector {1}", filesystem.type, filesystem.start);
}
sidecar.BlockMedia[0].Dimensions = Dimensions.DimensionsFromMediaType(dskType);
(string type, string subType) xmlType = CommonTypes.Metadata.MediaType.MediaTypeToString(dskType);
sidecar.BlockMedia[0].DiskType = xmlType.type;
sidecar.BlockMedia[0].DiskSubType = xmlType.subType;
// TODO: Implement device firmware revision
if(!_dev.IsRemovable ||
_dev.IsUsb)
if(_dev.Type == DeviceType.ATAPI)
sidecar.BlockMedia[0].Interface = "ATAPI";
else if(_dev.IsUsb)
sidecar.BlockMedia[0].Interface = "USB";
else if(_dev.IsFireWire)
sidecar.BlockMedia[0].Interface = "FireWire";
else
sidecar.BlockMedia[0].Interface = "SCSI";
sidecar.BlockMedia[0].LogicalBlocks = blocks;
sidecar.BlockMedia[0].PhysicalBlockSize = physicalBlockSize;
sidecar.BlockMedia[0].LogicalBlockSize = logicalBlockSize;
sidecar.BlockMedia[0].Manufacturer = _dev.Manufacturer;
sidecar.BlockMedia[0].Model = _dev.Model;
if(!_private)
sidecar.BlockMedia[0].Serial = _dev.Serial;
sidecar.BlockMedia[0].Size = blocks * blockSize;
if(_dev.IsRemovable)
sidecar.BlockMedia[0].DumpHardwareArray = _resume.Tries.ToArray();
UpdateStatus?.Invoke("Writing metadata sidecar");
var xmlFs = new FileStream(_outputPrefix + ".cicm.xml", FileMode.Create);
var xmlSer = new XmlSerializer(typeof(CICMMetadataType));
xmlSer.Serialize(xmlFs, sidecar);
xmlFs.Close();
}
}
UpdateStatus?.Invoke("");
UpdateStatus?.
Invoke($"Took a total of {(end - start).TotalSeconds:F3} seconds ({totalDuration / 1000:F3} processing commands, {totalChkDuration / 1000:F3} checksumming, {imageWriteDuration:F3} writing, {(closeEnd - closeStart).TotalSeconds:F3} closing).");
UpdateStatus?.
Invoke($"Average speed: {((double)blockSize * (double)(blocks + 1)) / 1048576 / (totalDuration / 1000):F3} MiB/sec.");
if(maxSpeed > 0)
UpdateStatus?.Invoke($"Fastest speed burst: {maxSpeed:F3} MiB/sec.");
if(minSpeed > 0 &&
minSpeed < double.MaxValue)
UpdateStatus?.Invoke($"Slowest speed burst: {minSpeed:F3} MiB/sec.");
UpdateStatus?.Invoke($"{_resume.BadBlocks.Count} sectors could not be read.");
UpdateStatus?.Invoke("");
Statistics.AddMedia(dskType, true);
}
}
}
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