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Natalia Portillo
2022-03-06 13:29:37 +00:00
parent c7178d94c6
commit 3b6091c02c
119 changed files with 38048 additions and 38172 deletions
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SCSI/Modes/08.cs
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@@ -33,247 +33,246 @@
using System.Diagnostics.CodeAnalysis;
using System.Text;
namespace Aaru.Decoders.SCSI
namespace Aaru.Decoders.SCSI;
[SuppressMessage("ReSharper", "InconsistentNaming"), SuppressMessage("ReSharper", "MemberCanBeInternal"),
SuppressMessage("ReSharper", "MemberCanBePrivate.Global")]
public static partial class Modes
{
[SuppressMessage("ReSharper", "InconsistentNaming"), SuppressMessage("ReSharper", "MemberCanBeInternal"),
SuppressMessage("ReSharper", "MemberCanBePrivate.Global")]
public static partial class Modes
#region Mode Page 0x08: Caching page
/// <summary>Disconnect-reconnect page Page code 0x08 12 bytes in SCSI-2 20 bytes in SBC-1, SBC-2, SBC-3</summary>
public struct ModePage_08
{
#region Mode Page 0x08: Caching page
/// <summary>Disconnect-reconnect page Page code 0x08 12 bytes in SCSI-2 20 bytes in SBC-1, SBC-2, SBC-3</summary>
public struct ModePage_08
{
/// <summary>Parameters can be saved</summary>
public bool PS;
/// <summary><c>true</c> if write cache is enabled</summary>
public bool WCE;
/// <summary>Multiplication factor</summary>
public bool MF;
/// <summary><c>true</c> if read cache is enabled</summary>
public bool RCD;
/// <summary>Advices on reading-cache retention priority</summary>
public byte DemandReadRetentionPrio;
/// <summary>Advices on writing-cache retention priority</summary>
public byte WriteRetentionPriority;
/// <summary>If requested read blocks are more than this, no pre-fetch is done</summary>
public ushort DisablePreFetch;
/// <summary>Minimum pre-fetch</summary>
public ushort MinimumPreFetch;
/// <summary>Maximum pre-fetch</summary>
public ushort MaximumPreFetch;
/// <summary>Upper limit on maximum pre-fetch value</summary>
public ushort MaximumPreFetchCeiling;
/// <summary>Parameters can be saved</summary>
public bool PS;
/// <summary><c>true</c> if write cache is enabled</summary>
public bool WCE;
/// <summary>Multiplication factor</summary>
public bool MF;
/// <summary><c>true</c> if read cache is enabled</summary>
public bool RCD;
/// <summary>Advices on reading-cache retention priority</summary>
public byte DemandReadRetentionPrio;
/// <summary>Advices on writing-cache retention priority</summary>
public byte WriteRetentionPriority;
/// <summary>If requested read blocks are more than this, no pre-fetch is done</summary>
public ushort DisablePreFetch;
/// <summary>Minimum pre-fetch</summary>
public ushort MinimumPreFetch;
/// <summary>Maximum pre-fetch</summary>
public ushort MaximumPreFetch;
/// <summary>Upper limit on maximum pre-fetch value</summary>
public ushort MaximumPreFetchCeiling;
/// <summary>Manual cache controlling</summary>
public bool IC;
/// <summary>Abort pre-fetch</summary>
public bool ABPF;
/// <summary>Caching analysis permitted</summary>
public bool CAP;
/// <summary>Pre-fetch over discontinuities</summary>
public bool Disc;
/// <summary><see cref="CacheSegmentSize" /> is to be used to control caching segmentation</summary>
public bool Size;
/// <summary>Force sequential write</summary>
public bool FSW;
/// <summary>Logical block cache segment size</summary>
public bool LBCSS;
/// <summary>Disable read-ahead</summary>
public bool DRA;
/// <summary>How many segments should the cache be divided upon</summary>
public byte CacheSegments;
/// <summary>How many bytes should the cache be divided upon</summary>
public ushort CacheSegmentSize;
/// <summary>How many bytes should be used as a buffer when all other cached data cannot be evicted</summary>
public uint NonCacheSegmentSize;
/// <summary>Manual cache controlling</summary>
public bool IC;
/// <summary>Abort pre-fetch</summary>
public bool ABPF;
/// <summary>Caching analysis permitted</summary>
public bool CAP;
/// <summary>Pre-fetch over discontinuities</summary>
public bool Disc;
/// <summary><see cref="CacheSegmentSize" /> is to be used to control caching segmentation</summary>
public bool Size;
/// <summary>Force sequential write</summary>
public bool FSW;
/// <summary>Logical block cache segment size</summary>
public bool LBCSS;
/// <summary>Disable read-ahead</summary>
public bool DRA;
/// <summary>How many segments should the cache be divided upon</summary>
public byte CacheSegments;
/// <summary>How many bytes should the cache be divided upon</summary>
public ushort CacheSegmentSize;
/// <summary>How many bytes should be used as a buffer when all other cached data cannot be evicted</summary>
public uint NonCacheSegmentSize;
public bool NV_DIS;
}
public bool NV_DIS;
}
public static ModePage_08? DecodeModePage_08(byte[] pageResponse)
{
if((pageResponse?[0] & 0x40) == 0x40)
return null;
public static ModePage_08? DecodeModePage_08(byte[] pageResponse)
{
if((pageResponse?[0] & 0x40) == 0x40)
return null;
if((pageResponse?[0] & 0x3F) != 0x08)
return null;
if((pageResponse?[0] & 0x3F) != 0x08)
return null;
if(pageResponse[1] + 2 != pageResponse.Length)
return null;
if(pageResponse[1] + 2 != pageResponse.Length)
return null;
if(pageResponse.Length < 12)
return null;
if(pageResponse.Length < 12)
return null;
var decoded = new ModePage_08();
var decoded = new ModePage_08();
decoded.PS |= (pageResponse[0] & 0x80) == 0x80;
decoded.WCE |= (pageResponse[2] & 0x04) == 0x04;
decoded.MF |= (pageResponse[2] & 0x02) == 0x02;
decoded.RCD |= (pageResponse[2] & 0x01) == 0x01;
decoded.PS |= (pageResponse[0] & 0x80) == 0x80;
decoded.WCE |= (pageResponse[2] & 0x04) == 0x04;
decoded.MF |= (pageResponse[2] & 0x02) == 0x02;
decoded.RCD |= (pageResponse[2] & 0x01) == 0x01;
decoded.DemandReadRetentionPrio = (byte)((pageResponse[3] & 0xF0) >> 4);
decoded.WriteRetentionPriority = (byte)(pageResponse[3] & 0x0F);
decoded.DisablePreFetch = (ushort)((pageResponse[4] << 8) + pageResponse[5]);
decoded.MinimumPreFetch = (ushort)((pageResponse[6] << 8) + pageResponse[7]);
decoded.MaximumPreFetch = (ushort)((pageResponse[8] << 8) + pageResponse[9]);
decoded.MaximumPreFetchCeiling = (ushort)((pageResponse[10] << 8) + pageResponse[11]);
if(pageResponse.Length < 20)
return decoded;
decoded.IC |= (pageResponse[2] & 0x80) == 0x80;
decoded.ABPF |= (pageResponse[2] & 0x40) == 0x40;
decoded.CAP |= (pageResponse[2] & 0x20) == 0x20;
decoded.Disc |= (pageResponse[2] & 0x10) == 0x10;
decoded.Size |= (pageResponse[2] & 0x08) == 0x08;
decoded.FSW |= (pageResponse[12] & 0x80) == 0x80;
decoded.LBCSS |= (pageResponse[12] & 0x40) == 0x40;
decoded.DRA |= (pageResponse[12] & 0x20) == 0x20;
decoded.CacheSegments = pageResponse[13];
decoded.CacheSegmentSize = (ushort)((pageResponse[14] << 8) + pageResponse[15]);
decoded.NonCacheSegmentSize = (uint)((pageResponse[17] << 16) + (pageResponse[18] << 8) + pageResponse[19]);
decoded.NV_DIS |= (pageResponse[12] & 0x01) == 0x01;
decoded.DemandReadRetentionPrio = (byte)((pageResponse[3] & 0xF0) >> 4);
decoded.WriteRetentionPriority = (byte)(pageResponse[3] & 0x0F);
decoded.DisablePreFetch = (ushort)((pageResponse[4] << 8) + pageResponse[5]);
decoded.MinimumPreFetch = (ushort)((pageResponse[6] << 8) + pageResponse[7]);
decoded.MaximumPreFetch = (ushort)((pageResponse[8] << 8) + pageResponse[9]);
decoded.MaximumPreFetchCeiling = (ushort)((pageResponse[10] << 8) + pageResponse[11]);
if(pageResponse.Length < 20)
return decoded;
decoded.IC |= (pageResponse[2] & 0x80) == 0x80;
decoded.ABPF |= (pageResponse[2] & 0x40) == 0x40;
decoded.CAP |= (pageResponse[2] & 0x20) == 0x20;
decoded.Disc |= (pageResponse[2] & 0x10) == 0x10;
decoded.Size |= (pageResponse[2] & 0x08) == 0x08;
decoded.FSW |= (pageResponse[12] & 0x80) == 0x80;
decoded.LBCSS |= (pageResponse[12] & 0x40) == 0x40;
decoded.DRA |= (pageResponse[12] & 0x20) == 0x20;
decoded.CacheSegments = pageResponse[13];
decoded.CacheSegmentSize = (ushort)((pageResponse[14] << 8) + pageResponse[15]);
decoded.NonCacheSegmentSize = (uint)((pageResponse[17] << 16) + (pageResponse[18] << 8) + pageResponse[19]);
decoded.NV_DIS |= (pageResponse[12] & 0x01) == 0x01;
return decoded;
}
public static string PrettifyModePage_08(byte[] pageResponse) =>
PrettifyModePage_08(DecodeModePage_08(pageResponse));
public static string PrettifyModePage_08(ModePage_08? modePage)
{
if(!modePage.HasValue)
return null;
ModePage_08 page = modePage.Value;
var sb = new StringBuilder();
sb.AppendLine("SCSI Caching mode page:");
if(page.PS)
sb.AppendLine("\tParameters can be saved");
if(page.RCD)
sb.AppendLine("\tRead-cache is enabled");
if(page.WCE)
sb.AppendLine("\tWrite-cache is enabled");
switch(page.DemandReadRetentionPrio)
{
case 0:
sb.AppendLine("\tDrive does not distinguish between cached read data");
break;
case 1:
sb.AppendLine("\tData put by READ commands should be evicted from cache sooner than data put in read cache by other means");
break;
case 0xF:
sb.AppendLine("\tData put by READ commands should not be evicted if there is data cached by other means that can be evicted");
break;
default:
sb.AppendFormat("\tUnknown demand read retention priority value {0}", page.DemandReadRetentionPrio).
AppendLine();
break;
}
public static string PrettifyModePage_08(byte[] pageResponse) =>
PrettifyModePage_08(DecodeModePage_08(pageResponse));
public static string PrettifyModePage_08(ModePage_08? modePage)
switch(page.WriteRetentionPriority)
{
if(!modePage.HasValue)
return null;
case 0:
sb.AppendLine("\tDrive does not distinguish between cached write data");
ModePage_08 page = modePage.Value;
var sb = new StringBuilder();
break;
case 1:
sb.AppendLine("\tData put by WRITE commands should be evicted from cache sooner than data put in write cache by other means");
sb.AppendLine("SCSI Caching mode page:");
break;
case 0xF:
sb.AppendLine("\tData put by WRITE commands should not be evicted if there is data cached by other means that can be evicted");
if(page.PS)
sb.AppendLine("\tParameters can be saved");
break;
default:
sb.AppendFormat("\tUnknown demand write retention priority value {0}",
page.DemandReadRetentionPrio).AppendLine();
if(page.RCD)
sb.AppendLine("\tRead-cache is enabled");
break;
}
if(page.WCE)
sb.AppendLine("\tWrite-cache is enabled");
if(page.DRA)
sb.AppendLine("\tRead-ahead is disabled");
else
{
if(page.MF)
sb.AppendLine("\tPre-fetch values indicate a block multiplier");
switch(page.DemandReadRetentionPrio)
if(page.DisablePreFetch == 0)
sb.AppendLine("\tNo pre-fetch will be done");
else
{
case 0:
sb.AppendLine("\tDrive does not distinguish between cached read data");
sb.AppendFormat("\tPre-fetch will be done for READ commands of {0} blocks or less",
page.DisablePreFetch).AppendLine();
break;
case 1:
sb.AppendLine("\tData put by READ commands should be evicted from cache sooner than data put in read cache by other means");
break;
case 0xF:
sb.AppendLine("\tData put by READ commands should not be evicted if there is data cached by other means that can be evicted");
break;
default:
sb.AppendFormat("\tUnknown demand read retention priority value {0}", page.DemandReadRetentionPrio).
if(page.MinimumPreFetch > 0)
sb.AppendFormat("At least {0} blocks will be always pre-fetched", page.MinimumPreFetch).
AppendLine();
break;
if(page.MaximumPreFetch > 0)
sb.AppendFormat("\tA maximum of {0} blocks will be pre-fetched", page.MaximumPreFetch).
AppendLine();
if(page.MaximumPreFetchCeiling > 0)
sb.
AppendFormat("\tA maximum of {0} blocks will be pre-fetched even if it is commanded to pre-fetch more",
page.MaximumPreFetchCeiling).AppendLine();
if(page.IC)
sb.AppendLine("\tDevice should use number of cache segments or cache segment size for caching");
if(page.ABPF)
sb.AppendLine("\tPre-fetch should be aborted upong receiving a new command");
if(page.CAP)
sb.AppendLine("\tCaching analysis is permitted");
if(page.Disc)
sb.AppendLine("\tPre-fetch can continue across discontinuities (such as cylinders or tracks)");
}
switch(page.WriteRetentionPriority)
{
case 0:
sb.AppendLine("\tDrive does not distinguish between cached write data");
break;
case 1:
sb.AppendLine("\tData put by WRITE commands should be evicted from cache sooner than data put in write cache by other means");
break;
case 0xF:
sb.AppendLine("\tData put by WRITE commands should not be evicted if there is data cached by other means that can be evicted");
break;
default:
sb.AppendFormat("\tUnknown demand write retention priority value {0}",
page.DemandReadRetentionPrio).AppendLine();
break;
}
if(page.DRA)
sb.AppendLine("\tRead-ahead is disabled");
else
{
if(page.MF)
sb.AppendLine("\tPre-fetch values indicate a block multiplier");
if(page.DisablePreFetch == 0)
sb.AppendLine("\tNo pre-fetch will be done");
else
{
sb.AppendFormat("\tPre-fetch will be done for READ commands of {0} blocks or less",
page.DisablePreFetch).AppendLine();
if(page.MinimumPreFetch > 0)
sb.AppendFormat("At least {0} blocks will be always pre-fetched", page.MinimumPreFetch).
AppendLine();
if(page.MaximumPreFetch > 0)
sb.AppendFormat("\tA maximum of {0} blocks will be pre-fetched", page.MaximumPreFetch).
AppendLine();
if(page.MaximumPreFetchCeiling > 0)
sb.
AppendFormat("\tA maximum of {0} blocks will be pre-fetched even if it is commanded to pre-fetch more",
page.MaximumPreFetchCeiling).AppendLine();
if(page.IC)
sb.AppendLine("\tDevice should use number of cache segments or cache segment size for caching");
if(page.ABPF)
sb.AppendLine("\tPre-fetch should be aborted upong receiving a new command");
if(page.CAP)
sb.AppendLine("\tCaching analysis is permitted");
if(page.Disc)
sb.AppendLine("\tPre-fetch can continue across discontinuities (such as cylinders or tracks)");
}
}
if(page.FSW)
sb.AppendLine("\tDrive should not reorder the sequence of write commands to be faster");
if(page.Size)
{
if(page.CacheSegmentSize > 0)
if(page.LBCSS)
sb.AppendFormat("\tDrive cache segments should be {0} blocks long", page.CacheSegmentSize).
AppendLine();
else
sb.AppendFormat("\tDrive cache segments should be {0} bytes long", page.CacheSegmentSize).
AppendLine();
}
else
{
if(page.CacheSegments > 0)
sb.AppendFormat("\tDrive should have {0} cache segments", page.CacheSegments).AppendLine();
}
if(page.NonCacheSegmentSize > 0)
sb.
AppendFormat("\tDrive shall allocate {0} bytes to buffer even when all cached data cannot be evicted",
page.NonCacheSegmentSize).AppendLine();
if(page.NV_DIS)
sb.AppendLine("\tNon-Volatile cache is disabled");
return sb.ToString();
}
#endregion Mode Page 0x08: Caching page
if(page.FSW)
sb.AppendLine("\tDrive should not reorder the sequence of write commands to be faster");
if(page.Size)
{
if(page.CacheSegmentSize > 0)
if(page.LBCSS)
sb.AppendFormat("\tDrive cache segments should be {0} blocks long", page.CacheSegmentSize).
AppendLine();
else
sb.AppendFormat("\tDrive cache segments should be {0} bytes long", page.CacheSegmentSize).
AppendLine();
}
else
{
if(page.CacheSegments > 0)
sb.AppendFormat("\tDrive should have {0} cache segments", page.CacheSegments).AppendLine();
}
if(page.NonCacheSegmentSize > 0)
sb.
AppendFormat("\tDrive shall allocate {0} bytes to buffer even when all cached data cannot be evicted",
page.NonCacheSegmentSize).AppendLine();
if(page.NV_DIS)
sb.AppendLine("\tNon-Volatile cache is disabled");
return sb.ToString();
}
#endregion Mode Page 0x08: Caching page
}