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Aaru/DiscImageChef.Core/Devices/Dumping/ATA.cs

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// /***************************************************************************
// The Disc Image Chef
// ----------------------------------------------------------------------------
//
// Filename : ATA.cs
// Author(s) : Natalia Portillo <claunia@claunia.com>
//
// Component : Core algorithms.
//
// --[ Description ] ----------------------------------------------------------
//
// Dumps media from ATA 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 © 2011-2019 Natalia Portillo
// ****************************************************************************/
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Text;
using System.Xml.Serialization;
using DiscImageChef.CommonTypes;
using DiscImageChef.CommonTypes.Enums;
using DiscImageChef.CommonTypes.Extents;
using DiscImageChef.CommonTypes.Interfaces;
using DiscImageChef.CommonTypes.Metadata;
using DiscImageChef.Core.Logging;
using DiscImageChef.Decoders.ATA;
using DiscImageChef.Decoders.PCMCIA;
using DiscImageChef.Devices;
using Schemas;
using MediaType = DiscImageChef.CommonTypes.MediaType;
using Tuple = DiscImageChef.Decoders.PCMCIA.Tuple;
namespace DiscImageChef.Core.Devices.Dumping
{
/// <summary>
/// Implements dumping ATA devices
/// </summary>
public partial class Dump
{
/// <summary>
/// Dumps an ATA device
/// </summary>
/// <param name="dev">Device</param>
/// <param name="devicePath">Path to the device</param>
/// <param name="outputPrefix">Prefix for output log files</param>
/// <param name="outputPlugin">Plugin for output file</param>
/// <param name="retryPasses">How many times to retry</param>
/// <param name="force">Force to continue dump whenever possible</param>
/// <param name="dumpRaw">Dump long sectors</param>
/// <param name="persistent">Store whatever data the drive returned on error</param>
/// <param name="stopOnError">Stop dump on first error</param>
/// <param name="resume">Information for dump resuming</param>
/// <param name="dumpLog">Dump logger</param>
/// <param name="encoding">Encoding to use when analyzing dump</param>
/// <param name="outputPath">Path to output file</param>
/// <param name="formatOptions">Formats to pass to output file plugin</param>
/// <exception cref="InvalidOperationException">If the resume file is invalid</exception>
public void Ata(Device dev, string devicePath,
IWritableImage outputPlugin, ushort retryPasses, bool force,
bool dumpRaw, bool persistent,
bool stopOnError, ref Resume resume, ref DumpLog dumpLog,
Encoding encoding, string outputPrefix,
string outputPath,
Dictionary<string, string> formatOptions, CICMMetadataType preSidecar, uint skip,
bool nometadata, bool notrim)
{
bool aborted;
if(dumpRaw)
{
if(force) ErrorMessage?.Invoke("Raw dumping not yet supported in ATA devices, continuing...");
else
{
StoppingErrorMessage?.Invoke("Raw dumping not yet supported in ATA devices, aborting...");
return;
}
}
const ushort ATA_PROFILE = 0x0001;
const uint TIMEOUT = 5;
double imageWriteDuration = 0;
UpdateStatus?.Invoke("Requesting ATA IDENTIFY DEVICE.");
dumpLog.WriteLine("Requesting ATA IDENTIFY DEVICE.");
bool sense = dev.AtaIdentify(out byte[] cmdBuf, out _);
if(!sense && Identify.Decode(cmdBuf).HasValue)
{
Identify.IdentifyDevice? ataIdNullable = Identify.Decode(cmdBuf);
if(ataIdNullable != null)
{
Identify.IdentifyDevice ataId = ataIdNullable.Value;
byte[] ataIdentify = cmdBuf;
cmdBuf = new byte[0];
DateTime start;
DateTime end;
double totalDuration = 0;
double currentSpeed = 0;
double maxSpeed = double.MinValue;
double minSpeed = double.MaxValue;
aborted = false;
System.Console.CancelKeyPress += (sender, e) => e.Cancel = aborted = true;
// Initializate reader
UpdateStatus?.Invoke("Initializing reader.");
dumpLog.WriteLine("Initializing reader.");
Reader ataReader = new Reader(dev, TIMEOUT, ataIdentify);
// Fill reader blocks
ulong blocks = ataReader.GetDeviceBlocks();
// Check block sizes
if(ataReader.GetBlockSize())
{
dumpLog.WriteLine("ERROR: Cannot get block size: {0}.", ataReader.ErrorMessage);
ErrorMessage(ataReader.ErrorMessage);
return;
}
uint blockSize = ataReader.LogicalBlockSize;
uint physicalsectorsize = ataReader.PhysicalBlockSize;
if(ataReader.FindReadCommand())
{
dumpLog.WriteLine("ERROR: Cannot find correct read command: {0}.", ataReader.ErrorMessage);
ErrorMessage(ataReader.ErrorMessage);
return;
}
// Check how many blocks to read, if error show and return
if(ataReader.GetBlocksToRead())
{
dumpLog.WriteLine("ERROR: Cannot get blocks to read: {0}.", ataReader.ErrorMessage);
ErrorMessage(ataReader.ErrorMessage);
return;
}
uint blocksToRead = ataReader.BlocksToRead;
ushort cylinders = ataReader.Cylinders;
byte heads = ataReader.Heads;
byte sectors = ataReader.Sectors;
UpdateStatus?.Invoke($"Device reports {blocks} blocks ({blocks * blockSize} bytes).");
UpdateStatus
?.Invoke($"Device reports {cylinders} cylinders {heads} heads {sectors} sectors per track.");
UpdateStatus?.Invoke($"Device can read {blocksToRead} blocks at a time.");
UpdateStatus?.Invoke($"Device reports {blockSize} bytes per logical block.");
UpdateStatus?.Invoke($"Device reports {physicalsectorsize} bytes per physical block.");
dumpLog.WriteLine("Device reports {0} blocks ({1} bytes).", blocks, blocks * blockSize);
dumpLog.WriteLine("Device reports {0} cylinders {1} heads {2} sectors per track.", cylinders, heads,
sectors);
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.", physicalsectorsize);
bool removable = !dev.IsCompactFlash &&
ataId.GeneralConfiguration.HasFlag(Identify.GeneralConfigurationBit.Removable);
DumpHardwareType currentTry = null;
ExtentsULong extents = null;
ResumeSupport.Process(ataReader.IsLba, removable, blocks, dev.Manufacturer, dev.Model, dev.Serial,
dev.PlatformId, ref resume, ref currentTry, ref extents);
if(currentTry == null || extents == null)
throw new InvalidOperationException("Could not process resume file, not continuing...");
MhddLog mhddLog;
IbgLog ibgLog;
double duration;
bool ret = true;
if(dev.IsUsb && dev.UsbDescriptors != null &&
!outputPlugin.SupportedMediaTags.Contains(MediaTagType.USB_Descriptors))
{
ret = false;
dumpLog.WriteLine("Output format does not support USB descriptors.");
ErrorMessage("Output format does not support USB descriptors.");
}
if(dev.IsPcmcia && dev.Cis != null &&
!outputPlugin.SupportedMediaTags.Contains(MediaTagType.PCMCIA_CIS))
{
ret = false;
dumpLog.WriteLine("Output format does not support PCMCIA CIS descriptors.");
ErrorMessage("Output format does not support PCMCIA CIS descriptors.");
}
if(!outputPlugin.SupportedMediaTags.Contains(MediaTagType.ATA_IDENTIFY))
{
ret = false;
dumpLog.WriteLine("Output format does not support ATA IDENTIFY.");
ErrorMessage("Output format does not support ATA IDENTIFY.");
}
if(!ret)
{
dumpLog.WriteLine("Several media tags not supported, {0}continuing...", force ? "" : "not ");
if(force) ErrorMessage("Several media tags not supported, continuing...");
else
{
StoppingErrorMessage?.Invoke("Several media tags not supported, not continuing...");
return;
}
}
ret = outputPlugin.Create(outputPath,
dev.IsCompactFlash ? MediaType.CompactFlash : MediaType.GENERIC_HDD,
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;
}
// Setting geometry
outputPlugin.SetGeometry(cylinders, heads, sectors);
if(ataReader.IsLba)
{
UpdateStatus?.Invoke($"Reading {blocksToRead} sectors at a time.");
if(skip < blocksToRead) skip = blocksToRead;
mhddLog = new MhddLog(outputPrefix + ".mhddlog.bin", dev, blocks, blockSize, blocksToRead);
ibgLog = new IbgLog(outputPrefix + ".ibg", ATA_PROFILE);
if(resume.NextBlock > 0)
{
UpdateStatus?.Invoke($"Resuming from block {resume.NextBlock}.");
dumpLog.WriteLine("Resuming from block {0}.", resume.NextBlock);
}
bool newTrim = false;
start = DateTime.UtcNow;
DateTime timeSpeedStart = DateTime.UtcNow;
ulong sectorSpeedStart = 0;
InitProgress?.Invoke();
for(ulong i = resume.NextBlock; i < blocks; i += blocksToRead)
{
if(aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
dumpLog.WriteLine("Aborted!");
break;
}
if(blocks - i < blocksToRead) blocksToRead = (byte)(blocks - i);
#pragma warning disable RECS0018 // Comparison of floating point numbers with equality operator
if(currentSpeed > maxSpeed && currentSpeed != 0) maxSpeed = currentSpeed;
if(currentSpeed < minSpeed && currentSpeed != 0) minSpeed = currentSpeed;
#pragma warning restore RECS0018 // Comparison of floating point numbers with equality operator
UpdateProgress?.Invoke($"\rReading sector {i} of {blocks} ({currentSpeed:F3} MiB/sec.)",
(long)i, (long)blocks);
bool error = ataReader.ReadBlocks(out cmdBuf, i, blocksToRead, out duration);
if(!error)
{
mhddLog.Write(i, duration);
ibgLog.Write(i, currentSpeed * 1024);
DateTime writeStart = DateTime.Now;
outputPlugin.WriteSectors(cmdBuf, i, blocksToRead);
imageWriteDuration += (DateTime.Now - writeStart).TotalSeconds;
extents.Add(i, blocksToRead, true);
}
else
{
if(i + skip > blocks) skip = (uint)(blocks - i);
for(ulong b = i; b < i + skip; b++) resume.BadBlocks.Add(b);
mhddLog.Write(i, duration < 500 ? 65535 : duration);
ibgLog.Write(i, 0);
DateTime writeStart = DateTime.Now;
outputPlugin.WriteSectors(new byte[blockSize * skip], i, skip);
imageWriteDuration += (DateTime.Now - writeStart).TotalSeconds;
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.Now;
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($"Average write speed {(double)blockSize * (double)(blocks + 1) / 1024 / imageWriteDuration:F3} KiB/sec.");
dumpLog.WriteLine("Dump finished in {0} seconds.", (end - start).TotalSeconds);
dumpLog.WriteLine("Average dump speed {0:F3} KiB/sec.",
(double)blockSize * (double)(blocks + 1) / 1024 / (totalDuration / 1000));
dumpLog.WriteLine("Average write speed {0:F3} KiB/sec.",
(double)blockSize * (double)(blocks + 1) / 1024 / imageWriteDuration);
#region Trimming
if(resume.BadBlocks.Count > 0 && !aborted && !notrim && newTrim)
{
start = DateTime.UtcNow;
UpdateStatus?.Invoke("Trimming bad sectors");
dumpLog.WriteLine("Trimming bad sectors");
ulong[] tmpArray = resume.BadBlocks.ToArray();
InitProgress?.Invoke();
foreach(ulong badSector in tmpArray)
{
if(aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
dumpLog.WriteLine("Aborted!");
break;
}
PulseProgress?.Invoke($"\rTrimming sector {badSector}");
bool error = ataReader.ReadBlock(out cmdBuf, badSector, out duration);
totalDuration += duration;
if(error) continue;
resume.BadBlocks.Remove(badSector);
extents.Add(badSector);
outputPlugin.WriteSector(cmdBuf, badSector);
}
EndProgress?.Invoke();
end = DateTime.UtcNow;
UpdateStatus?.Invoke($"Trimmming finished in {(end - start).TotalSeconds} seconds.");
dumpLog.WriteLine("Trimmming finished in {0} seconds.", (end - start).TotalSeconds);
}
#endregion Trimming
#region Error handling
if(resume.BadBlocks.Count > 0 && !aborted && retryPasses > 0)
{
int pass = 1;
bool forward = true;
InitProgress?.Invoke();
repeatRetryLba:
ulong[] tmpArray = resume.BadBlocks.ToArray();
foreach(ulong badSector in tmpArray)
{
if(aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
dumpLog.WriteLine("Aborted!");
break;
}
PulseProgress?.Invoke(string.Format("\rRetrying sector {0}, pass {1}, {3}{2}",
badSector, pass, forward ? "forward" : "reverse",
persistent ? "recovering partial data, " : ""));
bool error = ataReader.ReadBlock(out cmdBuf, badSector, out duration);
totalDuration += duration;
if(!error)
{
resume.BadBlocks.Remove(badSector);
extents.Add(badSector);
outputPlugin.WriteSector(cmdBuf, badSector);
UpdateStatus?.Invoke($"Correctly retried block {badSector} in pass {pass}.");
dumpLog.WriteLine("Correctly retried block {0} in pass {1}.", badSector, pass);
}
else if(persistent) outputPlugin.WriteSector(cmdBuf, badSector);
}
if(pass < retryPasses && !aborted && resume.BadBlocks.Count > 0)
{
pass++;
forward = !forward;
resume.BadBlocks.Sort();
resume.BadBlocks.Reverse();
goto repeatRetryLba;
}
EndProgress?.Invoke();
}
#endregion Error handling LBA
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
}
else
{
mhddLog = new MhddLog(outputPrefix + ".mhddlog.bin", dev, blocks, blockSize, blocksToRead);
ibgLog = new IbgLog(outputPrefix + ".ibg", ATA_PROFILE);
ulong currentBlock = 0;
blocks = (ulong)(cylinders * heads * sectors);
start = DateTime.UtcNow;
DateTime timeSpeedStart = DateTime.UtcNow;
ulong sectorSpeedStart = 0;
InitProgress?.Invoke();
for(ushort cy = 0; cy < cylinders; cy++)
{
for(byte hd = 0; hd < heads; hd++)
{
for(byte sc = 1; sc < sectors; sc++)
{
if(aborted)
{
currentTry.Extents = ExtentsConverter.ToMetadata(extents);
UpdateStatus?.Invoke("Aborted!");
dumpLog.WriteLine("Aborted!");
break;
}
#pragma warning disable RECS0018 // Comparison of floating point numbers with equality operator
if(currentSpeed > maxSpeed && currentSpeed != 0) maxSpeed = currentSpeed;
if(currentSpeed < minSpeed && currentSpeed != 0) minSpeed = currentSpeed;
#pragma warning restore RECS0018 // Comparison of floating point numbers with equality operator
PulseProgress
?.Invoke($"\rReading cylinder {cy} head {hd} sector {sc} ({currentSpeed:F3} MiB/sec.)");
bool error = ataReader.ReadChs(out cmdBuf, cy, hd, sc, out duration);
totalDuration += duration;
if(!error)
{
mhddLog.Write(currentBlock, duration);
ibgLog.Write(currentBlock, currentSpeed * 1024);
DateTime writeStart = DateTime.Now;
outputPlugin.WriteSector(cmdBuf,
(ulong)((cy * heads + hd) * sectors + (sc - 1)));
imageWriteDuration += (DateTime.Now - writeStart).TotalSeconds;
extents.Add(currentBlock);
dumpLog.WriteLine("Error reading cylinder {0} head {1} sector {2}.", cy, hd,
sc);
}
else
{
resume.BadBlocks.Add(currentBlock);
mhddLog.Write(currentBlock, duration < 500 ? 65535 : duration);
ibgLog.Write(currentBlock, 0);
DateTime writeStart = DateTime.Now;
outputPlugin.WriteSector(new byte[blockSize],
(ulong)((cy * heads + hd) * sectors + (sc - 1)));
imageWriteDuration += (DateTime.Now - writeStart).TotalSeconds;
}
sectorSpeedStart++;
currentBlock++;
double elapsed = (DateTime.UtcNow - timeSpeedStart).TotalSeconds;
if(elapsed < 1) continue;
currentSpeed = sectorSpeedStart * blockSize / (1048576 * elapsed);
sectorSpeedStart = 0;
timeSpeedStart = DateTime.UtcNow;
}
}
}
end = DateTime.Now;
EndProgress?.Invoke();
mhddLog.Close();
ibgLog.Close(dev, blocks, blockSize, (end - start).TotalSeconds, currentSpeed * 1024,
blockSize * (double)(blocks + 1) / 1024 /
(totalDuration / 1000), devicePath);
UpdateStatus?.Invoke($"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 / 1000):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 / 1000));
}
foreach(ulong bad in resume.BadBlocks) dumpLog.WriteLine("Sector {0} could not be read.", bad);
outputPlugin.SetDumpHardware(resume.Tries);
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)
{
dumpLog.WriteLine("Aborted!");
UpdateStatus?.Invoke("Aborted!");
return;
}
double totalChkDuration = 0;
if(!nometadata)
{
dumpLog.WriteLine("Creating sidecar.");
UpdateStatus?.Invoke("Creating sidecar.");
FiltersList filters = new FiltersList();
IFilter filter = filters.GetFilter(outputPath);
IMediaImage inputPlugin = ImageFormat.Detect(filter);
if(!inputPlugin.Open(filter)) throw new ArgumentException("Could not open created image.");
DateTime chkStart = DateTime.UtcNow;
CICMMetadataType sidecar = Sidecar.Create(inputPlugin, outputPath, filter.Id, encoding);
if(preSidecar != null)
{
preSidecar.BlockMedia = sidecar.BlockMedia;
sidecar = preSidecar;
}
if(dev.IsUsb)
{
dumpLog.WriteLine("Reading USB descriptors.");
UpdateStatus?.Invoke("Reading USB descriptors.");
ret = outputPlugin.WriteMediaTag(dev.UsbDescriptors, MediaTagType.USB_Descriptors);
if(ret)
sidecar.BlockMedia[0].USB = new USBType
{
ProductID = dev.UsbProductId,
VendorID = dev.UsbVendorId,
Descriptors = new DumpType
{
Image = outputPath,
Size = dev.UsbDescriptors.Length,
Checksums = Checksum.GetChecksums(dev.UsbDescriptors).ToArray()
}
};
}
if(dev.IsPcmcia)
{
dumpLog.WriteLine("Reading PCMCIA CIS.");
UpdateStatus?.Invoke("Reading PCMCIA CIS.");
ret = outputPlugin.WriteMediaTag(dev.Cis, MediaTagType.PCMCIA_CIS);
if(ret)
sidecar.BlockMedia[0].PCMCIA = new PCMCIAType
{
CIS = new DumpType
{
Image = outputPath,
Size = dev.Cis.Length,
Checksums = Checksum.GetChecksums(dev.Cis).ToArray()
}
};
dumpLog.WriteLine("Decoding PCMCIA CIS.");
UpdateStatus?.Invoke("Decoding PCMCIA CIS.");
Tuple[] tuples = CIS.GetTuples(dev.Cis);
if(tuples != null)
foreach(Tuple tuple in tuples)
switch(tuple.Code)
{
case TupleCodes.CISTPL_MANFID:
ManufacturerIdentificationTuple manfid =
CIS.DecodeManufacturerIdentificationTuple(tuple);
if(manfid != null)
{
sidecar.BlockMedia[0].PCMCIA.ManufacturerCode =
manfid.ManufacturerID;
sidecar.BlockMedia[0].PCMCIA.CardCode = manfid.CardID;
sidecar.BlockMedia[0].PCMCIA.ManufacturerCodeSpecified = true;
sidecar.BlockMedia[0].PCMCIA.CardCodeSpecified = true;
}
break;
case TupleCodes.CISTPL_VERS_1:
Level1VersionTuple vers = CIS.DecodeLevel1VersionTuple(tuple);
if(vers != null)
{
sidecar.BlockMedia[0].PCMCIA.Manufacturer = vers.Manufacturer;
sidecar.BlockMedia[0].PCMCIA.ProductName = vers.Product;
sidecar.BlockMedia[0].PCMCIA.Compliance =
$"{vers.MajorVersion}.{vers.MinorVersion}";
sidecar.BlockMedia[0].PCMCIA.AdditionalInformation =
vers.AdditionalInformation;
}
break;
}
}
ret = outputPlugin.WriteMediaTag(ataIdentify, MediaTagType.ATA_IDENTIFY);
if(ret)
sidecar.BlockMedia[0].ATA = new ATAType
{
Identify = new DumpType
{
Image = outputPath,
Size = cmdBuf.Length,
Checksums = Checksum.GetChecksums(cmdBuf).ToArray()
}
};
DateTime chkEnd = DateTime.UtcNow;
totalChkDuration = (chkEnd - chkStart).TotalMilliseconds;
UpdateStatus?.Invoke($"Sidecar created in {(chkEnd - chkStart).TotalSeconds} seconds.");
UpdateStatus
?.Invoke($"Average checksum speed {(double)blockSize * (double)(blocks + 1) / 1024 / (totalChkDuration / 1000):F3} KiB/sec.");
dumpLog.WriteLine("Sidecar created in {0} seconds.", (chkEnd - chkStart).TotalSeconds);
dumpLog.WriteLine("Average checksum speed {0:F3} KiB/sec.",
(double)blockSize * (double)(blocks + 1) / 1024 / (totalChkDuration / 1000));
List<(ulong start, string type)> filesystems = new List<(ulong start, string type)>();
if(sidecar.BlockMedia[0].FileSystemInformation != null)
filesystems.AddRange(from partition in sidecar.BlockMedia[0].FileSystemInformation
where partition.FileSystems != null
from fileSystem in partition.FileSystems
select ((ulong)partition.StartSector, fileSystem.Type));
if(filesystems.Count > 0)
foreach(var filesystem in filesystems.Select(o => new {o.start, o.type}).Distinct())
{
UpdateStatus
?.Invoke($"Found filesystem {filesystem.type} at sector {filesystem.start}");
dumpLog.WriteLine("Found filesystem {0} at sector {1}", filesystem.type,
filesystem.start);
}
string xmlDskTyp, xmlDskSubTyp;
if(dev.IsCompactFlash)
CommonTypes.Metadata.MediaType.MediaTypeToString(MediaType.CompactFlash, out xmlDskTyp,
out xmlDskSubTyp);
else if(dev.IsPcmcia)
CommonTypes.Metadata.MediaType.MediaTypeToString(MediaType.PCCardTypeI, out xmlDskTyp,
out xmlDskSubTyp);
else
CommonTypes.Metadata.MediaType.MediaTypeToString(MediaType.GENERIC_HDD, out xmlDskTyp,
out xmlDskSubTyp);
sidecar.BlockMedia[0].DiskType = xmlDskTyp;
sidecar.BlockMedia[0].DiskSubType = xmlDskSubTyp;
sidecar.BlockMedia[0].Interface = "ATA";
sidecar.BlockMedia[0].LogicalBlocks = (long)blocks;
sidecar.BlockMedia[0].PhysicalBlockSize = (int)physicalsectorsize;
sidecar.BlockMedia[0].LogicalBlockSize = (int)blockSize;
sidecar.BlockMedia[0].Manufacturer = dev.Manufacturer;
sidecar.BlockMedia[0].Model = dev.Model;
sidecar.BlockMedia[0].Serial = dev.Serial;
sidecar.BlockMedia[0].Size = (long)(blocks * blockSize);
if(cylinders > 0 && heads > 0 && sectors > 0)
{
sidecar.BlockMedia[0].Cylinders = cylinders;
sidecar.BlockMedia[0].CylindersSpecified = true;
sidecar.BlockMedia[0].Heads = heads;
sidecar.BlockMedia[0].HeadsSpecified = true;
sidecar.BlockMedia[0].SectorsPerTrack = sectors;
sidecar.BlockMedia[0].SectorsPerTrackSpecified = true;
}
UpdateStatus?.Invoke("Writing metadata sidecar");
FileStream xmlFs = new FileStream(outputPrefix + ".cicm.xml", FileMode.Create);
XmlSerializer 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.");
UpdateStatus?.Invoke($"Fastest speed burst: {maxSpeed:F3} MiB/sec.");
UpdateStatus?.Invoke($"Slowest speed burst: {minSpeed:F3} MiB/sec.");
UpdateStatus?.Invoke($"{resume.BadBlocks.Count} sectors could not be read.");
if(resume.BadBlocks.Count > 0) resume.BadBlocks.Sort();
UpdateStatus?.Invoke("");
}
if(dev.IsCompactFlash) Statistics.AddMedia(MediaType.CompactFlash, true);
else if(dev.IsPcmcia) Statistics.AddMedia(MediaType.PCCardTypeI, true);
else Statistics.AddMedia(MediaType.GENERIC_HDD, true);
}
else StoppingErrorMessage?.Invoke("Unable to communicate with ATA device.");
}
}
}
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