--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/userlibandfileserver/fileserver/sfat/sl_bpb.cpp	Thu Dec 17 09:24:54 2009 +0200
@@ -0,0 +1,314 @@
+// Copyright (c) 1996-2009 Nokia Corporation and/or its subsidiary(-ies).
+// All rights reserved.
+// This component and the accompanying materials are made available
+// under the terms of the License "Eclipse Public License v1.0"
+// which accompanies this distribution, and is available
+// at the URL "http://www.eclipse.org/legal/epl-v10.html".
+//
+// Initial Contributors:
+// Nokia Corporation - initial contribution.
+//
+// Contributors:
+//
+// Description:
+// f32\sfat\sl_bpb.cpp
+// Boot sector code, specific for EFat.fsy
+// 
+//
+
+
+/**
+ @file
+ @internalTechnology
+*/
+
+
+//!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
+//!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
+//!!
+//!! WARNING!! DO NOT edit this file !! '\sfat' component is obsolete and is not being used. '\sfat32'replaces it
+//!!
+//!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
+//!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
+
+#include "sl_std.h"
+
+//-------------------------------------------------------------------------------------------------------------------
+
+TFatBootSector::TFatBootSector()
+    {
+    Initialise();    
+    }
+
+/** initialises the boot sector data */
+void TFatBootSector::Initialise()
+    {
+    Mem::FillZ(this, sizeof(TFatBootSector));
+    }
+
+//-------------------------------------------------------------------------------------------------------------------
+
+/**
+    @return ETrue if the boot sector contents seems to be valid
+*/
+TBool TFatBootSector::IsValid() const
+    {
+    const TFatType fatType = FatType();
+   
+    
+    const TUint32 totSectors = Max(TotalSectors(), HugeSectors());
+    const TUint32 rootDirStartSec =  ReservedSectors() + FatSectors()*NumberOfFats(); //-- root directory start sector
+
+    if(fatType == EInvalid || ReservedSectors() < 1 || NumberOfFats() < 1 || FatSectors() < 1 || rootDirStartSec < 3 ||
+       RootDirEntries() < 1 || totSectors < 5)
+        goto Invalid;
+
+    if(TotalSectors() >0 && HugeSectors() >0 )
+        goto Invalid; //-- values clash
+
+    return ETrue;
+  
+    Invalid:
+        __PRINT(_L("TFatBootSector::IsValid() failed!"));
+
+    return EFalse;
+    }
+
+//-------------------------------------------------------------------------------------------------------------------
+
+/**
+    Initialize boot sector object from the given bufer. Does not validate the data.
+    @param  aBuf buffer with data.
+*/
+void TFatBootSector::Internalize(const TDesC8& aBuf)
+    {
+    ASSERT(aBuf.Size() >= KSizeOfFatBootSector);
+
+    Initialise();
+    
+    TInt pos=0;
+
+    Mem::Copy(&iJumpInstruction, &aBuf[pos],3);     pos+=3; // 0    TUint8 iJumpInstruction[3]
+    Mem::Copy(&iVendorId,&aBuf[pos],KVendorIdSize); pos+=KVendorIdSize; // 3    TUint8 iVendorId[KVendorIdSize]
+    Mem::Copy(&iBytesPerSector,&aBuf[pos],2);       pos+=2; // 11   TUint16 iBytesPerSector
+    Mem::Copy(&iSectorsPerCluster,&aBuf[pos],1);    pos+=1; // 13   TUint8 iSectorsPerCluster   
+    Mem::Copy(&iReservedSectors,&aBuf[pos],2);      pos+=2; // 14   TUint16 iReservedSectors
+    Mem::Copy(&iNumberOfFats,&aBuf[pos],1);         pos+=1; // 16   TUint8 iNumberOfFats
+    Mem::Copy(&iRootDirEntries,&aBuf[pos],2);       pos+=2; // 17   TUint16 iRootDirEntries
+    Mem::Copy(&iTotalSectors,&aBuf[pos],2);         pos+=2; // 19   TUint16 iTotalSectors
+    Mem::Copy(&iMediaDescriptor,&aBuf[pos],1);      pos+=1; // 21   TUint8 iMediaDescriptor
+    Mem::Copy(&iFatSectors,&aBuf[pos],2);           pos+=2; // 22   TUint16 iFatSectors
+    Mem::Copy(&iSectorsPerTrack,&aBuf[pos],2);      pos+=2; // 24   TUint16 iSectorsPerTrack
+    Mem::Copy(&iNumberOfHeads,&aBuf[pos],2);        pos+=2; // 26   TUint16 iNumberOfHeads
+    Mem::Copy(&iHiddenSectors,&aBuf[pos],4);        pos+=4; // 28   TUint32 iHiddenSectors
+    Mem::Copy(&iHugeSectors,&aBuf[pos],4);          pos+=4; // 32   TUint32 iHugeSectors
+    Mem::Copy(&iPhysicalDriveNumber,&aBuf[pos],1);  pos+=1;// 36|64 TUint8 iPhysicalDriveNumber
+    Mem::Copy(&iReserved,&aBuf[pos],1);             pos+=1;// 37|65 TUint8 iReserved
+    Mem::Copy(&iExtendedBootSignature,&aBuf[pos],1);pos+=1;// 38|66 TUint8 iExtendedBootSignature
+    Mem::Copy(&iUniqueID,&aBuf[pos],4);             pos+=4;// 39|67 TUint32 iUniqueID
+    Mem::Copy(&iVolumeLabel,&aBuf[pos],KVolumeLabelSize);  // 43|71 TUint8 iVolumeLabel[KVolumeLabelSize]
+    pos+=KVolumeLabelSize;
+
+    // 54|82    TUint8 iFileSysType[KFileSysTypeSize]
+    ASSERT(aBuf.Size() >= pos+KFileSysTypeSize);
+    Mem::Copy(&iFileSysType,&aBuf[pos],KFileSysTypeSize);
+    }
+
+//-------------------------------------------------------------------------------------------------------------------
+
+/**
+    Externalize boot sector object to the given data buffer.
+    @param  aBuf buffer to externalize.
+*/
+void TFatBootSector::Externalize(TDes8& aBuf) const
+    {
+    ASSERT(aBuf.MaxSize() >= KSizeOfFatBootSector);
+
+    if(aBuf.Size() < KSizeOfFatBootSector)
+        aBuf.SetLength(KSizeOfFatBootSector);
+
+    TInt pos=0;
+
+    Mem::Copy(&aBuf[pos],&iJumpInstruction,3);      pos+=3;
+    Mem::Copy(&aBuf[pos],&iVendorId,KVendorIdSize); pos+=8;
+    Mem::Copy(&aBuf[pos],&iBytesPerSector,2);       pos+=2;
+    Mem::Copy(&aBuf[pos],&iSectorsPerCluster,1);    pos+=1;
+    Mem::Copy(&aBuf[pos],&iReservedSectors,2);      pos+=2;
+    Mem::Copy(&aBuf[pos],&iNumberOfFats,1);         pos+=1;
+    Mem::Copy(&aBuf[pos],&iRootDirEntries,2);       pos+=2;
+    Mem::Copy(&aBuf[pos],&iTotalSectors,2);         pos+=2;
+    Mem::Copy(&aBuf[pos],&iMediaDescriptor,1);      pos+=1;
+    Mem::Copy(&aBuf[pos],&iFatSectors,2);           pos+=2;
+    Mem::Copy(&aBuf[pos],&iSectorsPerTrack,2);      pos+=2;
+    Mem::Copy(&aBuf[pos],&iNumberOfHeads,2);        pos+=2;
+    Mem::Copy(&aBuf[pos],&iHiddenSectors,4);        pos+=4;
+    Mem::Copy(&aBuf[pos],&iHugeSectors,4);          pos+=4;
+    Mem::Copy(&aBuf[pos],&iPhysicalDriveNumber,1);  pos+=1;
+    Mem::FillZ(&aBuf[pos],1);                       pos+=1;
+    Mem::Copy(&aBuf[pos],&iExtendedBootSignature,1);pos+=1;
+    Mem::Copy(&aBuf[pos],&iUniqueID,4);             pos+=4;
+    
+    Mem::Copy(&aBuf[pos],&iVolumeLabel,KVolumeLabelSize); 
+    pos+=KVolumeLabelSize;
+    
+    ASSERT(aBuf.MaxSize() >= pos+KFileSysTypeSize);
+    Mem::Copy(&aBuf[pos],&iFileSysType,KFileSysTypeSize);
+    }
+
+//-------------------------------------------------------------------------------------------------------------------
+
+#ifdef _DEBUG
+/** replaces all non-printable characters in a buffer with spaces */
+static void FixDes(TDes& aDes)
+{
+    for(TInt i=0; i< aDes.Length(); ++i)
+    {
+        TChar ch=aDes[i];
+        if(!ch.IsPrint())
+            aDes[i]=' ';    
+    }
+}
+#endif
+
+/** 
+    Print out the boot sector info.
+*/
+void TFatBootSector::PrintDebugInfo() const
+    {
+#ifdef _DEBUG
+    __PRINT(_L("\n======== BootSector info: =======\n"));
+    
+    TBuf<40> buf;
+    buf.Copy(FileSysType()); FixDes(buf);    
+    __PRINT1(_L("FAT type:%S"), &buf);
+
+    buf.Copy(VendorId()); FixDes(buf);    
+    __PRINT1(_L("Vendor ID:%S"), &buf);
+
+    __PRINT1(_L("BytesPerSector:%d"),BytesPerSector());
+    __PRINT1(_L("SectorsPerCluster:%d"),SectorsPerCluster());
+    __PRINT1(_L("ReservedSectors:%d"),ReservedSectors());
+    __PRINT1(_L("NumberOfFats:%d"),NumberOfFats());
+    __PRINT1(_L("RootDirEntries:%d"),RootDirEntries());
+    __PRINT1(_L("Total Sectors:%d"),TotalSectors());
+    __PRINT1(_L("MediaDescriptor:0x%x"),MediaDescriptor());
+    __PRINT1(_L("FatSectors:%d"),FatSectors());
+    __PRINT1(_L("SectorsPerTrack:%d"),SectorsPerTrack());
+    __PRINT1(_L("NumberOfHeads:%d"),NumberOfHeads());
+    __PRINT1(_L("HugeSectors:%d"),HugeSectors());
+    __PRINT1(_L("Root Cluster Number:%d"),RootClusterNum());
+    __PRINT1(_L("FSInfo Sector Number:%d"),FSInfoSectorNum());
+    __PRINT1(_L("Backup Boot Rec Sector Number:%d"),BkBootRecSector());
+    __PRINT1(_L("PhysicalDriveNumber:%d"),PhysicalDriveNumber());
+    __PRINT1(_L("ExtendedBootSignature:%d"),ExtendedBootSignature());
+    __PRINT1(_L("UniqueID:0x%x"),UniqueID());
+    
+    buf.Copy(VolumeLabel()); FixDes(buf);    
+    __PRINT1(_L("VolumeLabel:%S"), &buf);
+    
+    __PRINT(_L("=============================\n"));
+#endif
+
+    }
+
+//-------------------------------------------------------------------------------------------------------------------
+
+/**
+    Determine FAT type according to the information from boot sector, see FAT32 specs.
+    @return  FAT type. 
+*/
+TFatType TFatBootSector::FatType(void) const
+    {
+    //-- check iBytesPerSector validity; it shall be one of: 512,1024,2048,4096
+    if(!IsPowerOf2(iBytesPerSector) || iBytesPerSector < 512 ||  iBytesPerSector > 4096)
+        return EInvalid; //-- invalid iBytesPerSector value
+
+    //-- check iSectorsPerCluster validity, it shall be one of: 1,2,4,8...128
+    if(!IsPowerOf2(iSectorsPerCluster) || iSectorsPerCluster > 128)
+        return EInvalid; //-- invalid iSectorsPerCluster value
+
+
+    const TUint32 rootDirSectors = (iRootDirEntries*KSizeOfFatDirEntry + (iBytesPerSector-1)) / iBytesPerSector;
+    const TUint32 totSec = iTotalSectors ? iTotalSectors : iHugeSectors;
+    const TUint32 dataSec = totSec - (iReservedSectors + (iNumberOfFats * iFatSectors) + rootDirSectors);
+    const TUint32 clusterCnt = dataSec / iSectorsPerCluster;
+
+    //-- magic. see FAT specs for details.
+    if(clusterCnt < 4085)
+        return EFat12;
+    else if(clusterCnt < 65525)
+        return EFat16;
+    else
+        return EInvalid; //-- FAT32 is not supported by this fsy
+    }
+
+//-------------------------------------------------------------------------------------------------------------------
+
+/** @return The first Fat sector number */
+TInt TFatBootSector::FirstFatSector() const
+    {
+    __ASSERT_DEBUG(IsValid(), Fault(EFatBadBootSectorParameter));
+    return ReservedSectors();
+    }
+
+/**
+    @return Number of sectors in root directory. 0 for FAT32
+*/
+TUint32 TFatBootSector::RootDirSectors() const
+    {
+    __ASSERT_DEBUG(IsValid(), Fault(EFatBadBootSectorParameter));
+    return ( (RootDirEntries()*KSizeOfFatDirEntry + (BytesPerSector()-1)) / BytesPerSector() );
+    }
+
+
+/** @return Start sector number of the root directory */
+TInt TFatBootSector::RootDirStartSector()  const
+    {
+    __ASSERT_DEBUG(IsValid(), Fault(EFatBadBootSectorParameter));
+
+    //-- FAT12/16 root dir starts just after the FATs
+    return ReservedSectors() + TotalFatSectors()*NumberOfFats();
+    }
+
+
+/** @return first data sector number. for FAT32 it includes the root directory */
+TInt TFatBootSector::FirstDataSector() const
+    {
+    return( ReservedSectors() + NumberOfFats()*TotalFatSectors() + RootDirSectors() );
+    }
+
+/** @return FAT-type independent sector count on the volume */
+TUint32 TFatBootSector::VolumeTotalSectorNumber() const
+    {
+    __ASSERT_DEBUG(IsValid(), Fault(EFatBadBootSectorParameter));
+    return TotalSectors() >0 ? (TUint32)TotalSectors() : (TUint32)HugeSectors();
+    }
+
+/** @return FAT-type independent number of sectors in one FAT */
+TUint32 TFatBootSector::TotalFatSectors() const
+    {
+    __ASSERT_DEBUG(IsValid(), Fault(EFatBadBootSectorParameter));
+    return (TUint32)FatSectors();
+    }
+
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