Leaked source code of windows server 2003
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 
 

3134 lines
93 KiB

/*++
Copyright (c) 1992 Microsoft Corporation
Module Name:
bootini.c
Abstract:
Code to lay boot blocks on x86, and to configure for boot loader,
including munging/creating boot.ini and bootsect.dos.
Author:
Ted Miller (tedm) 12-November-1992
Revision History:
Sunil Pai ( sunilp ) 2-November-1993 rewrote for new text setup
--*/
#include "spprecmp.h"
#pragma hdrstop
#include "spboot.h"
#include "bootvar.h"
#include "spfile.h" //NEC98
#include <hdlsblk.h>
#include <hdlsterm.h>
extern PDISK_REGION TargetRegion_Nec98; //NEC98
SIGNATURED_PARTITIONS SignedBootVars;
BOOLEAN
SpHasMZHeader(
IN PWSTR FileName
);
NTSTATUS
Spx86WriteBootIni(
IN PWCHAR BootIni,
IN PWSTR **BootVars,
IN ULONG Timeout,
IN PWSTR Default,
IN ULONG Count
);
//
// DefSwitches support
//
UCHAR DefSwitches[128];
UCHAR DefSwitchesNoRedirect[128];
//
// Routines
//
BOOLEAN
Spx86InitBootVars(
OUT PWSTR **BootVars,
OUT PWSTR *Default,
OUT PULONG Timeout
)
{
WCHAR BootIni[512];
HANDLE FileHandle;
HANDLE SectionHandle;
PVOID ViewBase;
NTSTATUS Status;
ULONG FileSize;
PUCHAR BootIniBuf;
PDISK_REGION CColonRegion;
BOOTVAR i;
PUCHAR p;
ULONG index;
//
// Initialize the defaults
//
for(i = FIRSTBOOTVAR; i <= LASTBOOTVAR; i++) {
BootVars[i] = (PWSTR *)SpMemAlloc( sizeof ( PWSTR * ) );
ASSERT( BootVars[i] );
*BootVars[i] = NULL;
}
*Default = NULL;
*Timeout = DEFAULT_TIMEOUT;
//
// See if there is a valid C: already. If not, then silently fail.
//
if (!IsNEC_98 // NEC98
#if defined(REMOTE_BOOT)
|| RemoteBootSetup
#endif // defined(REMOTE_BOOT)
) {
#if defined(REMOTE_BOOT)
if (RemoteBootSetup && !RemoteInstallSetup) {
ASSERT(RemoteBootTargetRegion != NULL);
CColonRegion = RemoteBootTargetRegion;
} else
#endif // defined(REMOTE_BOOT)
{
CColonRegion = SpPtValidSystemPartition();
if(!CColonRegion) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "SETUP: no C:, no boot.ini!\n"));
return(TRUE);
}
}
//
// Form name of file. Boot.ini better not be on a doublespace drive.
//
ASSERT(CColonRegion->Filesystem != FilesystemDoubleSpace);
SpNtNameFromRegion(CColonRegion,BootIni,sizeof(BootIni),PartitionOrdinalCurrent);
SpConcatenatePaths(BootIni,WBOOT_INI);
//
// Open and map the file.
//
FileHandle = 0;
Status = SpOpenAndMapFile(BootIni,&FileHandle,&SectionHandle,&ViewBase,&FileSize,FALSE);
if(!NT_SUCCESS(Status)) {
return TRUE;
}
//
// Allocate a buffer for the file.
//
BootIniBuf = SpMemAlloc(FileSize+1);
ASSERT(BootIniBuf);
RtlZeroMemory(BootIniBuf, FileSize+1);
//
// Transfer boot.ini into the buffer. We do this because we also
// want to place a 0 byte at the end of the buffer to terminate
// the file.
//
// Guard the RtlMoveMemory because if we touch the memory backed by boot.ini
// and get an i/o error, the memory manager will raise an exception.
try {
RtlMoveMemory(BootIniBuf,ViewBase,FileSize);
}
except( IN_PAGE_ERROR ) {
//
// Do nothing, boot ini processing can proceed with whatever has been
// read
//
}
//
// Not needed since buffer has already been zeroed, however just do this
// just the same
//
BootIniBuf[FileSize] = 0;
//
// Cleanup
//
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(FileHandle);
} else { //NEC98
//
// Serch for all drive which include boot.ini file.
//
FileSize = 0;
BootIniBuf = SpCreateBootiniImage(&FileSize);
if(BootIniBuf == NULL){
return(TRUE);
}
} //NEC98
//
// Do the actual processing of the file.
//
SppProcessBootIni(BootIniBuf, BootVars, Default, Timeout);
//
// Dump the boot vars
//
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "Spx86InitBootVars - Boot.ini entries:\n") );
for( index = 0; BootVars[OSLOADPARTITION][index] ; index++ ) {
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, " BootVar: %d\n =========\n", index) );
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, " OsLoadpartition: %ws\n", BootVars[OSLOADPARTITION][index]) );
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, " OsLoadFileName: %ws\n\n", BootVars[OSLOADFILENAME][index]) );
}
//
// Dump the signatures too...
//
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "Spx86InitBootVars - Boot.ini signed entries:\n") );
{
SIGNATURED_PARTITIONS *my_ptr = &SignedBootVars;
do{
if( my_ptr->SignedString ) {
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "Signature entry:\n================\n") );
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, " %ws\n", my_ptr->SignedString) );
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, " %ws\n", my_ptr->MultiString) );
};
my_ptr = my_ptr->Next;
} while( my_ptr );
}
//
// Scan the Buffer to see if there is a DefSwitches line,
// to move into new boot.ini in the [boot loader] section.
// If no DefSwitches, just point to a null string to be moved.
//
DefSwitches[0] = '\0';
for(p=BootIniBuf; *p && (p < BootIniBuf+FileSize-(sizeof("DefSwitches")-1)); p++) {
if(!_strnicmp(p,"DefSwitches",sizeof("DefSwitches")-1)) {
index = 0;
while ((*p != '\r') && (*p != '\n') && *p && (index < sizeof(DefSwitches)-4)) {
DefSwitches[index++] = *p++;
}
DefSwitches[index++] = '\r';
DefSwitches[index++] = '\n';
DefSwitches[index] = '\0';
break;
}
}
//
// get a copy of the defswitches without any redirection switches
//
strcpy(DefSwitchesNoRedirect, DefSwitches);
//
// Now add any headless parameters to the default switches.
// Scan the Buffer to see if there's already a headless line.
// If so, keep it.
//
for(p=BootIniBuf; *p && (p < BootIniBuf+FileSize-(sizeof("redirect=")-1)); p++) {
if(!_strnicmp(p,"[Operat",sizeof("[Operat")-1)) {
//
// We're past the [Boot Loader] section. Stop looking.
//
break;
}
if(!_strnicmp(p,"redirect=",sizeof("redirect=")-1)) {
PUCHAR q = p;
UCHAR temp;
while ((*p != '\r') && (*p != '\n') && *p) {
p++;
}
temp = *p;
*p = '\0';
strcat(DefSwitches, q);
strcat(DefSwitches, "\r\n");
*p = temp;
}
}
//
// Now look for a 'redirectbaudrate' line.
//
for(p=BootIniBuf; *p && (p < BootIniBuf+FileSize-(sizeof("redirectbaudrate=")-1)); p++) {
if(!_strnicmp(p,"[Operat",sizeof("[Operat")-1)) {
//
// We're past the [Boot Loader] section. Stop looking.
//
break;
}
if(!_strnicmp(p,"redirectbaudrate=",sizeof("redirectbaudrate=")-1)) {
PUCHAR q = p;
UCHAR temp;
while ((*p != '\r') && (*p != '\n') && *p) {
p++;
}
temp = *p;
*p = '\0';
strcat(DefSwitches, q);
strcat(DefSwitches, "\r\n");
*p = temp;
}
}
SpMemFree(BootIniBuf);
return( TRUE );
}
BOOLEAN
Spx86FlushBootVars(
IN PWSTR **BootVars,
IN ULONG Timeout,
IN PWSTR Default
)
{
PDISK_REGION CColonRegion;
WCHAR *BootIni;
WCHAR *BootIniBak;
BOOLEAN BootIniBackedUp = FALSE;
NTSTATUS Status;
//
// See if there is a valid C: already. If not, then fail.
//
#if defined(REMOTE_BOOT)
// On a remote boot machine, it's acceptable to have no local disk.
//
#endif // defined(REMOTE_BOOT)
if (!IsNEC_98){ //NEC98
CColonRegion = SpPtValidSystemPartition();
if(!CColonRegion) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "SETUP: no C:, no boot.ini!\n"));
#if defined(REMOTE_BOOT)
if (RemoteBootSetup && !RemoteInstallSetup) {
return(TRUE);
}
#endif // defined(REMOTE_BOOT)
return(FALSE);
}
} else {
//
// CColonRegion equal TargetRegion on NEC98.
//
CColonRegion = TargetRegion_Nec98;
} //NEC98
//
// Allocate the buffers to 2K worth of stack space.
//
BootIni = SpMemAlloc(512*sizeof(WCHAR));
if (!BootIni) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: No memory for boot.ini!\n"));
return FALSE;
}
BootIniBak = SpMemAlloc(512*sizeof(WCHAR));
if (!BootIniBak) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: No memory for boot.ini.bak!\n"));
SpMemFree(BootIni);
return FALSE;
}
//
// Form name of file. Boot.ini better not be on a doublespace drive.
//
ASSERT(CColonRegion->Filesystem != FilesystemDoubleSpace);
SpNtNameFromRegion(CColonRegion,BootIni,512*sizeof(WCHAR),PartitionOrdinalCurrent);
wcscpy(BootIniBak, BootIni);
SpConcatenatePaths(BootIni,WBOOT_INI);
SpConcatenatePaths(BootIniBak,WBOOT_INI_BAK);
//
// If Boot.ini already exists, delete any backup bootini
// rename the existing bootini to the backup bootini, if unable
// to rename, delete the file
//
if( SpFileExists( BootIni, FALSE ) ) {
if( SpFileExists( BootIniBak, FALSE ) ) {
SpDeleteFile( BootIniBak, NULL, NULL);
}
Status = SpRenameFile( BootIni, BootIniBak, FALSE );
if (!(BootIniBackedUp = NT_SUCCESS( Status ))) {
SpDeleteFile( BootIni, NULL, NULL );
}
}
//
// Write boot.ini.
//
Status = Spx86WriteBootIni(
BootIni,
BootVars,
Timeout,
Default,
0 // write all lines
);
if(!NT_SUCCESS( Status )) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Error writing boot.ini!\n"));
goto cleanup;
}
cleanup:
//
// If we were unsuccessful in writing out boot ini then try recovering
// the old boot ini from the backed up file, else delete the backed up
// file.
//
if( !NT_SUCCESS(Status) ) {
//
// If the backup copy of boot ini exists then delete incomplete boot
// ini and rename the backup copy of boot into bootini
//
if ( BootIniBackedUp ) {
SpDeleteFile( BootIni, NULL, NULL );
SpRenameFile( BootIniBak, BootIni, FALSE );
}
}
else {
SpDeleteFile( BootIniBak, NULL, NULL );
}
SpMemFree(BootIni);
SpMemFree(BootIniBak);
return( NT_SUCCESS(Status) );
}
PCHAR
Spx86ConvertToSignatureArcName(
IN PWSTR ArcPathIn,
IN ULONG Signature
)
{
PWSTR s,p,b;
PWSTR UseSignatures;
SIGNATURED_PARTITIONS *SignedEntries = &SignedBootVars;
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "Spx86ConvertToSignatureArcName - Incoming ArcPath: %ws\n\tIncoming Signature %lx\n", ArcPathIn, Signature ) );
//
// First, check for any boot.ini entries that already had a 'signature'
// string.
//
do {
if( (SignedEntries->MultiString) && (SignedEntries->SignedString) ) {
if( !_wcsicmp( ArcPathIn, SignedEntries->MultiString ) ) {
//
// We hit. Convert the signatured string
// to ASCII and return.
//
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "Spx86ConvertToSignatureArcName - Matched a multi-signed boot.ini entry:\n") );
KdPrintEx( (DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "\t%ws\n\t%ws\n", SignedEntries->MultiString, SignedEntries->SignedString) );
return SpToOem( SignedEntries->SignedString );
}
}
SignedEntries = SignedEntries->Next;
} while( SignedEntries );
#if 0
//
// Don't do this because winnt.exe and CDROM-boot installs won't
// have this entry set, so we won't use signature entries, which
// is a mistake.
//
UseSignatures = SpGetSectionKeyIndex(WinntSifHandle,SIF_DATA,L"UseSignatures",0);
if (UseSignatures == NULL || _wcsicmp(UseSignatures,WINNT_A_YES_W) != 0) {
//
// Just return the string we came in with.
//
return SpToOem(ArcPathIn);
}
#endif
if (_wcsnicmp( ArcPathIn, L"scsi(", 5 ) != 0) {
//
// If he's anything but a "scsi(..." entry,
// just return the string that was sent in.
//
return SpToOem(ArcPathIn);
}
if( Signature ) {
b = (PWSTR)TemporaryBuffer;
p = ArcPathIn;
s = wcschr( p, L')' ) + 1;
swprintf( b, L"signature(%x)%ws", Signature, s );
return SpToOem( b );
} else {
//
// Just return the string we came in with.
//
return SpToOem(ArcPathIn);
}
}
NTSTATUS
Spx86WriteBootIni(
IN PWCHAR BootIni,
IN PWSTR **BootVars,
IN ULONG Timeout,
IN PWSTR Default,
IN ULONG Count
)
{
IO_STATUS_BLOCK IoStatusBlock;
UNICODE_STRING BootIni_U;
HANDLE fh = NULL;
PCHAR Default_O, Osloadpartition_O, Osloadfilename_O, Osloadoptions_O, Loadidentifier_O;
FILE_BASIC_INFORMATION BasicInfo;
OBJECT_ATTRIBUTES oa;
ULONG i;
NTSTATUS Status1;
NTSTATUS Status;
PWSTR s;
PDISK_REGION Region;
WCHAR _Default[MAX_PATH] = {0};
extern ULONG DefaultSignature;
//
// Open Bootini file. Open if write through because we'll be shutting down
// shortly (this is for safety).
//
RtlInitUnicodeString(&BootIni_U,BootIni);
InitializeObjectAttributes(&oa,&BootIni_U,OBJ_CASE_INSENSITIVE,NULL,NULL);
Status = ZwCreateFile(
&fh,
FILE_GENERIC_WRITE | DELETE,
&oa,
&IoStatusBlock,
NULL,
FILE_ATTRIBUTE_NORMAL,
0, // no sharing
FILE_OVERWRITE_IF,
FILE_NON_DIRECTORY_FILE | FILE_SYNCHRONOUS_IO_NONALERT | FILE_WRITE_THROUGH,
NULL,
0
);
if( !NT_SUCCESS( Status ) ) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Unable to open %ws for writing!\n", BootIni));
goto cleanup;
}
//
// make sure there is a Default specified before we use it.
//
if (Default != NULL) {
//
// use the temporary buffer to form the FLEXBOOT section.
// and then write it out
//
s = NULL;
s = wcschr( Default, L'\\' );
if( s ) {
//
// Save off the Default string, then terminate
// the Default string where the directory path starts.
//
wcscpy( _Default, Default );
*s = L'\0';
s = wcschr( _Default, L'\\' );
}
if( ForceBIOSBoot ) {
//
// If ForceBIOSBoot is TRUE, then we want to
// force a "multi(..." string. Don't even bother calling
// Spx86ConvertToSignatureArcName on the off chance
// that we may get erroneously converted.
//
if (_wcsnicmp( Default, L"scsi(", 5 ) == 0) {
PWSTR MyStringPointer = NULL;
//
// Darn! We have a string that the old standard
// thought should be converted into a signature(...
// string, but we didn't write out a miniport driver.
// That can happen if someone asked us not to via
// an unattend switch.
//
// We need to change the "scsi(" to "multi("
//
// We must preserve Default because we use it later
// for comparison.
//
MyStringPointer = SpScsiArcToMultiArc( Default );
if( MyStringPointer ) {
Default_O = SpToOem( MyStringPointer );
} else {
//
// We're in trouble. Take a shot though. Just
// change the "scsi(" part to "multi(".
//
wcscpy( TemporaryBuffer, L"multi" );
wcscat( TemporaryBuffer, &Default[4] );
Default_O = SpToOem( TemporaryBuffer );
}
} else {
//
// Just convert to ANSI.
//
Default_O = SpToOem( Default );
}
} else {
Default_O = Spx86ConvertToSignatureArcName( Default, DefaultSignature );
}
if( s ) {
//
// We need to append our directory path back on.
//
strcpy( (PCHAR)TemporaryBuffer, Default_O );
SpMemFree( Default_O );
Default_O = SpToOem( s );
strcat( (PCHAR)TemporaryBuffer, Default_O );
SpMemFree( Default_O );
Default_O = SpDupString( (PCHAR)TemporaryBuffer );
}
if (Default_O == NULL) {
Default_O = SpToOem( Default );
}
} else {
//
// the Default was not set, so make a null Default_O
//
Default_O = SpDupString("");
}
ASSERT( Default_O );
//
// See if we should use the loaded redirect switches,
// if there were any, or insert user defined swithes
//
if(RedirectSwitchesMode != UseDefaultSwitches) {
//
// get a copy of the switches up to the [operat region
//
strcpy(DefSwitches, DefSwitchesNoRedirect);
//
// insert our custom switch(s) if appropriate
//
switch(RedirectSwitchesMode){
case DisableRedirect: {
//
// we don't have to do anything here
//
break;
}
case UseUserDefinedRedirect: {
sprintf((PUCHAR)TemporaryBuffer,
"redirect=%s\r\n",
RedirectSwitches.port
);
(void)StringCchCatA(DefSwitches,
sizeof(DefSwitches)/sizeof(DefSwitches[0]),
(PUCHAR)TemporaryBuffer);
break;
}
case UseUserDefinedRedirectAndBaudRate: {
sprintf((PUCHAR)TemporaryBuffer,
"redirect=%s\r\n",
RedirectSwitches.port
);
(void)StringCchCatA(DefSwitches,
sizeof(DefSwitches)/sizeof(DefSwitches[0]),
(PUCHAR)TemporaryBuffer);
sprintf((PUCHAR)TemporaryBuffer,
"redirectbaudrate=%s\r\n",
RedirectSwitches.baudrate
);
(void)StringCchCatA(DefSwitches,
sizeof(DefSwitches)/sizeof(DefSwitches[0]),
(PUCHAR)TemporaryBuffer);
break;
}
default:{
ASSERT(0);
}
}
} else {
//
// Make sure the required headless settings are already in the DefSwitches string before
// we write it out.
//
_strlwr( DefSwitches );
if( !strstr(DefSwitches, "redirect") ) {
PUCHAR p;
HEADLESS_RSP_QUERY_INFO Response;
SIZE_T Length;
//
// There are no headless settings. See if we need to add any.
//
Length = sizeof(HEADLESS_RSP_QUERY_INFO);
Status = HeadlessDispatch(HeadlessCmdQueryInformation,
NULL,
0,
&Response,
&Length
);
p=NULL;
if (NT_SUCCESS(Status) &&
(Response.PortType == HeadlessSerialPort) &&
Response.Serial.TerminalAttached) {
if (Response.Serial.UsedBiosSettings) {
strcat(DefSwitches, "redirect=UseBiosSettings\r\n");
} else {
switch (Response.Serial.TerminalPort) {
case ComPort1:
p = "redirect=com1\r\n";
break;
case ComPort2:
p = "redirect=com2\r\n";
break;
case ComPort3:
p = "redirect=com3\r\n";
break;
case ComPort4:
p = "redirect=com4\r\n";
break;
default:
ASSERT(0);
p = NULL;
break;
}
if (p) {
strcat(DefSwitches, p);
}
//
// Now take care of the 'redirectbaudrate' entry.
//
switch (Response.Serial.TerminalBaudRate) {
case 115200:
p = "redirectbaudrate=115200\r\n";
break;
case 57600:
p = "redirectbaudrate=57600\r\n";
break;
case 19200:
p = "redirectbaudrate=19200\r\n";
break;
default:
p = "redirectbaudrate=9600\r\n";
break;
}
strcat(DefSwitches, p);
}
}
}
}
sprintf(
(PUCHAR)TemporaryBuffer,
"%s%s%s%s%s%ld%s%s%s%s%s",
FLEXBOOT_SECTION2,
CRLF,
DefSwitches,
TIMEOUT,
EQUALS,
Timeout,
CRLF,
DEFAULT,
EQUALS,
Default_O,
CRLF
);
SpMemFree( Default_O );
Status = ZwWriteFile(
fh,
NULL,
NULL,
NULL,
&IoStatusBlock,
TemporaryBuffer,
strlen((PUCHAR)TemporaryBuffer) * sizeof(UCHAR),
NULL,
NULL
);
if(!NT_SUCCESS( Status )) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Error writing %s section to %ws!\n", FLEXBOOT_SECTION2, BootIni));
goto cleanup;
}
//
// Now write the BOOTINI_OS_SECTION label to boot.ini
//
sprintf(
(PUCHAR)TemporaryBuffer,
"%s%s",
BOOTINI_OS_SECTION,
CRLF
);
Status = ZwWriteFile(
fh,
NULL,
NULL,
NULL,
&IoStatusBlock,
TemporaryBuffer,
strlen((PUCHAR)TemporaryBuffer) * sizeof(UCHAR),
NULL,
NULL
);
if(!NT_SUCCESS( Status )) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Error writing %s section to %ws!\n", BOOTINI_OS_SECTION, BootIni));
goto cleanup;
}
//
// run through all the systems that we have and write them out
//
for( i = 0; BootVars[OSLOADPARTITION][i] ; i++ ) {
//
// If we were told to write a specified number of lines, exit
// when we have done that.
//
if (Count && (i == Count)) {
Status = STATUS_SUCCESS;
goto cleanup;
}
ASSERT( BootVars[OSLOADFILENAME][i] );
ASSERT( BootVars[OSLOADOPTIONS][i] );
ASSERT( BootVars[LOADIDENTIFIER][i] );
//
// On some upgrades, if we're upgrading a "signature" entry,
// then we may not have a DefaultSignature. I fixed that case over
// in Spx86ConvertToSignatureArcName. The other case is where
// we have a DefaultSignature, but there are also some "scsi(..."
// entries in the boot.ini that don't pertain to the entry we're
// upgrading. For that case, we need to send in a signature
// of 0 here, which will force Spx86ConvertToSignatureArcName
// to return us the correct item.
//
//
// You thought the hack above was gross... This one's even
// worse. Problem: we don't think we need a miniport to boot,
// but there are some other boot.ini entries (that point to our
// partition) that do. We always want to leave existing
// boot.ini entries alone though, so we'll leave those broken.
//
// Solution: if the OSLOADPARTITION that we're translating ==
// Default, && ForceBIOSBoot is TRUE && we're translating
// the first OSLOADPARTITION (which is the one for our Default),
// then just don't call Spx86ConvertToSignatureArcName.
// This is bad because it assumes that our entry is the first,
// which it is, but it's a shakey assumption.
//
if( !_wcsicmp( BootVars[OSLOADPARTITION][i], Default ) ) {
//
// This might be our Default entry. Make sure it
// really is and if so, process it the same way.
//
if( i == 0 ) {
//
// It is.
//
if( ForceBIOSBoot ) {
//
// If ForceBIOSBoot is TRUE, then we want to
// force a "multi(..." string. Don't even bother calling
// Spx86ConvertToSignatureArcName on the off chance
// that we may get erroneously converted.
//
if (_wcsnicmp( BootVars[OSLOADPARTITION][i], L"scsi(", 5 ) == 0) {
PWSTR MyStringPointer = NULL;
//
// Darn! We have a string that the old standard
// thought should be converted into a signature(...
// string, but we didn't write out a miniport driver.
// That can happen if someone asked us not to via
// an unattend switch.
//
// We need to change the "scsi(" to "multi("
//
MyStringPointer = SpScsiArcToMultiArc( BootVars[OSLOADPARTITION][i] );
if( MyStringPointer ) {
Osloadpartition_O = SpToOem( MyStringPointer );
} else {
//
// We're in trouble. Take a shot though. Just
// change the "scsi(" part to "multi(".
//
wcscpy( TemporaryBuffer, L"multi" );
wcscat( TemporaryBuffer, &BootVars[OSLOADPARTITION][i][4] );
Osloadpartition_O = SpToOem( TemporaryBuffer );
}
} else {
//
// Just convert to ANSI.
//
Osloadpartition_O = SpToOem( BootVars[OSLOADPARTITION][i] );
}
} else {
//
// We may need to convert this entry.
//
Osloadpartition_O = Spx86ConvertToSignatureArcName( BootVars[OSLOADPARTITION][i], DefaultSignature );
}
} else {
//
// This entry looks just like our Default, but it's point
// to a different installation. Just call Spx86ConvertToSignatureArcName
//
Osloadpartition_O = Spx86ConvertToSignatureArcName( BootVars[OSLOADPARTITION][i], DefaultSignature );
}
} else {
//
// This entry doesn't even look like our string. Send in a
// 0x0 DefaultSignature so that it will only get translated if it
// matches some entry that we know was signed in the original boot.ini.
//
Osloadpartition_O = Spx86ConvertToSignatureArcName( BootVars[OSLOADPARTITION][i], 0 );
}
//
// Insurance...
//
if (Osloadpartition_O == NULL) {
Osloadpartition_O = SpToOem( BootVars[OSLOADPARTITION][i] );
}
Osloadfilename_O = SpToOem( BootVars[OSLOADFILENAME][i] );
Osloadoptions_O = SpToOem( BootVars[OSLOADOPTIONS][i] );
Loadidentifier_O = SpToOem( BootVars[LOADIDENTIFIER][i] );
sprintf(
(PUCHAR)TemporaryBuffer,
"%s%s%s%s %s%s",
Osloadpartition_O,
Osloadfilename_O,
EQUALS,
Loadidentifier_O,
Osloadoptions_O,
CRLF
);
SpMemFree( Osloadpartition_O );
SpMemFree( Osloadfilename_O );
SpMemFree( Osloadoptions_O );
SpMemFree( Loadidentifier_O );
Status = ZwWriteFile(
fh,
NULL,
NULL,
NULL,
&IoStatusBlock,
TemporaryBuffer,
strlen((PUCHAR)TemporaryBuffer) * sizeof(UCHAR),
NULL,
NULL
);
if(!NT_SUCCESS( Status )) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Error writing %s section entry to %ws!\n", BOOTINI_OS_SECTION, BootIni));
goto cleanup;
}
}
//
// Finally write the old operating system line to boot.ini
// (but only if not installing on top of Win9x) and if it was
// not specifically disabled
//
if (!DiscardOldSystemLine && (WinUpgradeType != UpgradeWin95)) {
Status = ZwWriteFile(
fh,
NULL,
NULL,
NULL,
&IoStatusBlock,
OldSystemLine,
strlen(OldSystemLine) * sizeof(UCHAR),
NULL,
NULL
);
if (!NT_SUCCESS(Status)) {
KdPrintEx((DPFLTR_SETUP_ID,
DPFLTR_ERROR_LEVEL,
"SETUP: Error writing %s section line to %ws!\n",
BOOTINI_OS_SECTION,
BootIni));
goto cleanup;
}
}
cleanup:
if( !NT_SUCCESS(Status) ) {
if( fh ) {
ZwClose( fh );
}
}
else {
//
// Set the hidden, system, readonly attributes on bootini. ignore
// error
//
RtlZeroMemory( &BasicInfo, sizeof( FILE_BASIC_INFORMATION ) );
BasicInfo.FileAttributes = FILE_ATTRIBUTE_READONLY |
FILE_ATTRIBUTE_HIDDEN |
FILE_ATTRIBUTE_SYSTEM |
FILE_ATTRIBUTE_ARCHIVE
;
Status1 = SpSetInformationFile(
fh,
FileBasicInformation,
sizeof(BasicInfo),
&BasicInfo
);
if(!NT_SUCCESS(Status1)) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Unable to change attribute of %ws. Status = (%lx). Ignoring error.\n",BootIni,Status1));
}
ZwClose( fh );
}
//
// If we copied out the Default, then
// put the original copy of Default back
//
if (Default != NULL) {
wcscpy(Default, _Default);
}
return Status;
}
VOID
SppProcessBootIni(
IN PCHAR BootIni,
OUT PWSTR **BootVars,
OUT PWSTR *Default,
OUT PULONG Timeout
)
/*++
Routine Description:
Look through the [operating systems] section and save all lines
except the one for "C:\" (previous operating system) and one other
optionally specified line.
Filters out the local boot line (C:\$WIN_NT$.~BT) if present.
Arguments:
Return Value:
--*/
{
PCHAR sect,s,p,n;
PWSTR tmp;
CHAR Key[MAX_PATH], Value[MAX_PATH], RestOfLine[MAX_PATH];
ULONG NumComponents;
BOOTVAR i;
ULONG DiskSignature,digval;
SIGNATURED_PARTITIONS *SignedBootIniVars = &SignedBootVars;;
//
// Process the flexboot section, extract timeout and default
//
sect = SppFindSectionInBootIni(BootIni, FLEXBOOT_SECTION1);
if (!sect) {
sect = SppFindSectionInBootIni(BootIni, FLEXBOOT_SECTION2);
}
if (!sect) {
sect = SppFindSectionInBootIni(BootIni, FLEXBOOT_SECTION3);
}
if ( sect ) {
while (sect = SppNextLineInSection(sect)) {
if( SppProcessLine( sect, Key, Value, RestOfLine) ) {
if ( !_stricmp( Key, TIMEOUT ) ) {
*Timeout = atol( Value );
}
else if( !_stricmp( Key, DEFAULT ) ) {
*Default = SpToUnicode( Value );
}
}
}
}
//
// Process the operating systems section
//
sect = SppFindSectionInBootIni(BootIni,BOOTINI_OS_SECTION);
if(!sect) {
return;
}
NumComponents = 0;
while(sect = SppNextLineInSection(sect)) {
if( SppProcessLine( sect, Key, Value, RestOfLine)) {
PCHAR OsLoaddir;
//
// Check if the line is the old bootloader line in which case just
// save it above, else add it to the BootVars structure
//
if (!IsNEC_98) { //NEC98
if( !_stricmp( Key, "C:\\" ) ) {
sprintf( OldSystemLine, "%s=%s %s\r\n", Key, Value, RestOfLine );
} else {
//
// Ignore if local boot directory. This automatically
// filters out that directory when boot.ini is later flushed.
//
if(_strnicmp(Key,"C:\\$WIN_NT$.~BT",15) && (OsLoaddir = strchr(Key,'\\'))) {
//
// Get the ARC name of the x86 system partition region.
//
PDISK_REGION SystemPartitionRegion;
WCHAR SystemPartitionPath[256];
NumComponents++;
for(i = FIRSTBOOTVAR; i <= LASTBOOTVAR; i++) {
BootVars[i] = SpMemRealloc( BootVars[i], (NumComponents + 1) * sizeof( PWSTR * ) );
ASSERT( BootVars[i] );
BootVars[i][NumComponents] = NULL;
}
SystemPartitionRegion = SpPtValidSystemPartition();
#if defined(REMOTE_BOOT)
ASSERT(SystemPartitionRegion ||
(RemoteBootSetup && !RemoteInstallSetup));
#else
ASSERT(SystemPartitionRegion);
#endif // defined(REMOTE_BOOT)
if (SystemPartitionRegion) {
SpArcNameFromRegion(
SystemPartitionRegion,
SystemPartitionPath,
sizeof(SystemPartitionPath),
PartitionOrdinalOriginal,
PrimaryArcPath
);
BootVars[OSLOADER][NumComponents - 1] = SpMemAlloc((wcslen(SystemPartitionPath)*sizeof(WCHAR))+sizeof(L"ntldr")+sizeof(WCHAR));
wcscpy(BootVars[OSLOADER][NumComponents - 1],SystemPartitionPath);
SpConcatenatePaths(BootVars[OSLOADER][NumComponents - 1],L"ntldr");
BootVars[SYSTEMPARTITION][NumComponents - 1] = SpDupStringW( SystemPartitionPath );
}
BootVars[LOADIDENTIFIER][NumComponents - 1] = SpToUnicode( Value );
BootVars[OSLOADOPTIONS][NumComponents - 1] = SpToUnicode( RestOfLine );
*OsLoaddir = '\0';
//
// Now convert the signature entry into a 'multi...' entry.
//
s = strstr( Key, "signature(" );
if (s) {
s += 10;
p = strchr( s, ')' );
if (p) {
//
// We've got a boot.ini entry with a 'signature' string.
// Let's save it off before we convert it into a 'multi'
// string so we can convert back easily when we're ready
// to write out the boot.ini.
//
if( SignedBootIniVars->SignedString != NULL ) {
//
// We've used this entry, get another...
//
SignedBootIniVars->Next = SpMemAlloc(sizeof(SIGNATURED_PARTITIONS));
SignedBootIniVars = SignedBootIniVars->Next;
//
// Make sure...
//
SignedBootIniVars->Next = NULL;
SignedBootIniVars->SignedString = NULL;
SignedBootIniVars->MultiString = NULL;
}
SignedBootIniVars->SignedString = SpToUnicode( Key );
*p = 0;
DiskSignature = 0;
for (n=s; *n; n++) {
if (isdigit((int)(unsigned char)*n)) {
digval = *n - '0';
} else if (isxdigit((int)(unsigned char)*n)) {
digval = toupper(*n) - 'A' + 10;
} else {
digval = 0;
}
DiskSignature = DiskSignature * 16 + digval;
}
*p = ')';
//
// !!! ISSUE : 4/27/01 : vijayj !!!
//
// Sometimes we might map a arcname to wrong region on
// disk.
//
// Although we compute a new multi(0)... style arcname
// from the nt device name, we don't have an entry in
// the map which actually maps the scsi(0)... style
// arcname to nt device name.
//
// In a multi installation scenario, if the current installation
// is on a disk which is not visible by firmware and the
// boot.ini has scsi(...) entry for this installation we
// would convert it into multi(0)... format which could be
// similar to the actual multi(0) disk. If this is the case
// and another installation exists on the first disk also
// with the same partition number and WINDOWS directory
// then we would end up using the first disk region as the
// region to upgrade and fail subsequently while trying
// to match unique IDs. User will end up with "unable to
// locate installation to upgrade message".
//
// Since the probability of all this conditions being replicated
// on different machines is very very less, currently
// I am not going to fix this.
//
//
// We've isolated the signature. Now go find a disk
// with that signature and get his ARC path.
//
for(i=0; (ULONG)i<HardDiskCount; i++) {
if (HardDisks[i].Signature == DiskSignature) {
tmp = SpNtToArc( HardDisks[i].DevicePath, PrimaryArcPath );
if( tmp ) {
wcscpy( (PWSTR)TemporaryBuffer, tmp );
SpMemFree(tmp);
p = strstr( Key, "partition(" );
if( p ) {
tmp = SpToUnicode(p);
if( tmp ) {
wcscat( (PWSTR)TemporaryBuffer, tmp );
SpMemFree(tmp);
BootVars[OSLOADPARTITION][NumComponents - 1] = SpDupStringW( (PWSTR)TemporaryBuffer );
break;
}
}
}
}
}
if ((ULONG)i == HardDiskCount) {
BootVars[OSLOADPARTITION][NumComponents - 1] = SpToUnicode( Key );
}
//
// Save off the 'multi' entry in our list of signatures.
//
SignedBootIniVars->MultiString = SpDupStringW( BootVars[OSLOADPARTITION][NumComponents - 1] );
}
} else {
BootVars[OSLOADPARTITION][NumComponents - 1] = SpToUnicode( Key );
}
*OsLoaddir = '\\';
#if defined(REMOTE_BOOT)
if (RemoteBootSetup && !RemoteInstallSetup) {
BootVars[OSLOADFILENAME][NumComponents - 1] = SpToUnicode( strrchr(OsLoaddir,'\\') );
} else
#endif // defined(REMOTE_BOOT)
{
BootVars[OSLOADFILENAME][NumComponents - 1] = SpToUnicode( OsLoaddir );
}
}
}
} else { //NEC98
if (_strnicmp(Key,"C:\\$WIN_NT$.~BT",15) && (OsLoaddir = strchr( Key, '\\' ))) {
NumComponents++;
for(i = FIRSTBOOTVAR; i <= LASTBOOTVAR; i++) {
BootVars[i] = SpMemRealloc( BootVars[i], (NumComponents + 1) * sizeof( PWSTR * ) );
ASSERT( BootVars[i] );
BootVars[i][NumComponents] = NULL;
}
BootVars[OSLOADER][NumComponents - 1] = SpMemAlloc(sizeof(L"ntldr")+sizeof(WCHAR));
wcscpy(BootVars[OSLOADER][NumComponents - 1],L"\\");
SpConcatenatePaths(BootVars[OSLOADER][NumComponents - 1],L"ntldr");
BootVars[SYSTEMPARTITION][NumComponents - 1] = SpToUnicode( Key );
BootVars[LOADIDENTIFIER][NumComponents - 1] = SpToUnicode( Value );
BootVars[OSLOADOPTIONS][NumComponents - 1] = SpToUnicode( RestOfLine );
*OsLoaddir = '\0';
BootVars[OSLOADPARTITION][NumComponents - 1] = SpToUnicode( Key );
*OsLoaddir = '\\';
BootVars[OSLOADFILENAME][NumComponents - 1] = SpToUnicode( OsLoaddir );
ASSERT( BootVars[OSLOADER][NumComponents - 1] );
ASSERT( BootVars[SYSTEMPARTITION][NumComponents - 1] );
ASSERT( BootVars[LOADIDENTIFIER][NumComponents - 1] );
ASSERT( BootVars[OSLOADOPTIONS][NumComponents - 1] );
ASSERT( BootVars[OSLOADPARTITION][NumComponents - 1] );
ASSERT( BootVars[OSLOADPARTITION][NumComponents - 1] );
}
} //NEC98
}
}
return;
}
PCHAR
SppNextLineInSection(
IN PCHAR p
)
{
//
// Find the next \n.
//
p = strchr(p,'\n');
if(!p) {
return(NULL);
}
//
// skip crs, lfs, spaces, and tabs.
//
while(*p && strchr("\r\n \t",*p)) {
p++;
}
// detect if at end of file or section
if(!(*p) || (*p == '[')) {
return(NULL);
}
return(p);
}
PCHAR
SppFindSectionInBootIni(
IN PCHAR p,
IN PCHAR Section
)
{
ULONG len = strlen(Section);
do {
//
// Skip space at front of line
//
while(*p && ((*p == ' ') || (*p == '\t'))) {
p++;
}
if(*p) {
//
// See if this line matches.
//
if(!_strnicmp(p,Section,len)) {
return(p);
}
//
// Advance to the start of the next line.
//
while(*p && (*p != '\n')) {
p++;
}
if(*p) { // skip nl if that terminated the loop.
p++;
}
}
} while(*p);
return(NULL);
}
BOOLEAN
SppProcessLine(
IN PCHAR Line,
IN OUT PCHAR Key,
IN OUT PCHAR Value,
IN OUT PCHAR RestOfLine
)
{
PCHAR p = Line, pLine = Line, pToken;
CHAR savec;
BOOLEAN Status = FALSE;
//
// Determine end of line
//
if(!p) {
return( Status );
}
while( *p && (*p != '\r') && (*p != '\n') ) {
p++;
}
//
// back up from this position to squeeze out any whitespaces at the
// end of the line
//
while( ((p - 1) >= Line) && strchr(" \t", *(p - 1)) ) {
p--;
}
//
// terminate the line with null temporarily
//
savec = *p;
*p = '\0';
//
// Start at beginning of line and pick out the key
//
if ( SppNextToken( pLine, &pToken, &pLine ) ) {
CHAR savec1 = *pLine;
*pLine = '\0';
strcpy( Key, pToken );
*pLine = savec1;
//
// Get next token, it should be a =
//
if ( SppNextToken( pLine, &pToken, &pLine ) && *pToken == '=') {
//
// Get next token, it will be the value
//
if( SppNextToken( pLine, &pToken, &pLine ) ) {
savec1 = *pLine;
*pLine = '\0';
strcpy( Value, pToken );
*pLine = savec1;
//
// if another token exists then take the whole remaining line
// and make it the RestOfLine token
//
if( SppNextToken( pLine, &pToken, &pLine ) ) {
strcpy( RestOfLine, pToken );
}
else {
*RestOfLine = '\0';
}
//
// We have a well formed line
//
Status = TRUE;
}
}
}
*p = savec;
return( Status );
}
BOOLEAN
SppNextToken(
PCHAR p,
PCHAR *pBegin,
PCHAR *pEnd
)
{
BOOLEAN Status = FALSE;
//
// Validate pointer
//
if( !p ) {
return( Status );
}
//
// Skip whitespace
//
while (*p && strchr( " \t", *p ) ) {
p++;
}
//
// Valid tokens are "=", space delimited strings, quoted strings
//
if (*p) {
*pBegin = p;
if ( *p == '=' ) {
*pEnd = p + 1;
Status = TRUE;
}
else if ( *p == '\"' ) {
if ( p = strchr( p + 1, '\"' ) ) {
*pEnd = p + 1;
Status = TRUE;
}
}
else {
while (*p && !strchr(" \t\"=", *p) ) {
p++;
}
*pEnd = p;
Status = TRUE;
}
}
return( Status );
}
//
// Boot code stuff.
//
NTSTATUS
pSpBootCodeIo(
IN PWSTR FilePath,
IN PWSTR AdditionalFilePath, OPTIONAL
IN ULONG BytesToRead,
IN OUT PUCHAR *Buffer,
IN ULONG OpenDisposition,
IN BOOLEAN Write,
IN ULONGLONG Offset,
IN ULONG BytesPerSector
)
{
PWSTR FullPath;
PUCHAR buffer = NULL;
NTSTATUS Status;
IO_STATUS_BLOCK IoStatusBlock;
UNICODE_STRING UnicodeString;
OBJECT_ATTRIBUTES Obja;
HANDLE Handle;
LARGE_INTEGER LargeZero;
PVOID UnalignedMem,AlignedBuffer;
LargeZero.QuadPart = Offset;
//
// Form the name of the file.
//
wcscpy((PWSTR)TemporaryBuffer,FilePath);
if(AdditionalFilePath) {
SpConcatenatePaths((PWSTR)TemporaryBuffer,AdditionalFilePath);
}
FullPath = SpDupStringW((PWSTR)TemporaryBuffer);
//
// Open the file.
//
INIT_OBJA(&Obja,&UnicodeString,FullPath);
Status = ZwCreateFile(
&Handle,
Write ? FILE_GENERIC_WRITE : FILE_GENERIC_READ,
&Obja,
&IoStatusBlock,
NULL,
FILE_ATTRIBUTE_NORMAL,
FILE_SHARE_READ | FILE_SHARE_WRITE,
OpenDisposition,
FILE_SYNCHRONOUS_IO_NONALERT | (Write ? FILE_WRITE_THROUGH : 0),
NULL,
0
);
if(NT_SUCCESS(Status)) {
//
// Allocate a buffer if we are reading.
// Otherwise the caller passed us the buffer.
//
buffer = Write ? *Buffer : SpMemAlloc(BytesToRead);
//
// Read or write the disk -- properly aligned. Note that we force at least
// 512-byte alignment, since there's a hard-coded alignment requirement
// in the FT driver that must be satisfied.
//
if(BytesPerSector < 512) {
BytesPerSector = 512;
}
UnalignedMem = SpMemAlloc(BytesToRead + BytesPerSector);
AlignedBuffer = ALIGN(UnalignedMem,BytesPerSector);
if(Write) {
RtlMoveMemory(AlignedBuffer,buffer,BytesToRead);
}
Status = Write
?
ZwWriteFile(
Handle,
NULL,
NULL,
NULL,
&IoStatusBlock,
AlignedBuffer,
BytesToRead,
&LargeZero,
NULL
)
:
ZwReadFile(
Handle,
NULL,
NULL,
NULL,
&IoStatusBlock,
AlignedBuffer,
BytesToRead,
&LargeZero,
NULL
);
if(NT_SUCCESS(Status)) {
if(!Write) {
RtlMoveMemory(buffer,AlignedBuffer,BytesToRead);
}
} else {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL,
"SETUP: Unable to %ws %u bytes from %ws (%lx)\n",
Write ? L"write" : L"read",
BytesToRead,
FullPath,
Status
));
}
SpMemFree(UnalignedMem);
//
// Close the file.
//
ZwClose(Handle);
} else {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: pSpBootCodeIo: Unable to open %ws (%lx)\n",FullPath,Status));
}
SpMemFree(FullPath);
if(!Write) {
if(NT_SUCCESS(Status)) {
*Buffer = buffer;
} else {
if(buffer) {
SpMemFree(buffer);
}
}
}
return(Status);
}
BOOLEAN
pSpScanBootcode(
IN PVOID Buffer,
IN PCHAR String
)
/*++
Routine Description:
Look in a boot sector to find an identifying string. The scan starts
at offset 128 and continues through byte 509 of the buffer.
The search is case-sensitive.
Arguments:
Buffer - buffer to scan
String - string to scan for
Return Value:
--*/
{
ULONG len = strlen(String);
ULONG LastFirstByte = 510 - len;
ULONG i;
PCHAR p = Buffer;
//
// Use the obvious brute force method.
//
for(i=128; i<LastFirstByte; i++) {
if(!strncmp(p+i,String,len)) {
return(TRUE);
}
}
return(FALSE);
}
VOID
SpDetermineOsTypeFromBootSector(
IN PWSTR CColonPath,
IN PUCHAR BootSector,
OUT PUCHAR *OsDescription,
OUT PBOOLEAN IsNtBootcode,
OUT PBOOLEAN IsOtherOsInstalled,
IN WCHAR DriveLetter
)
{
PWSTR description;
PWSTR *FilesToLookFor;
ULONG FileCount;
BOOLEAN PossiblyChicago = FALSE;
PWSTR MsDosFiles[2] = { L"MSDOS.SYS" , L"IO.SYS" };
//
// Some versions of PC-DOS have ibmio.com, others have ibmbio.com.
//
//PWSTR PcDosFiles[2] = { L"IBMDOS.COM", L"IBMIO.COM" };
PWSTR PcDosFiles[1] = { L"IBMDOS.COM" };
PWSTR Os2Files[2] = { L"OS2LDR" , L"OS2KRNL" };
//
// Check for nt boot code.
//
if(pSpScanBootcode(BootSector,"NTLDR")) {
*IsNtBootcode = TRUE;
*IsOtherOsInstalled = FALSE;
description = L"";
} else {
//
// It's not NT bootcode.
//
*IsNtBootcode = FALSE;
*IsOtherOsInstalled = TRUE;
//
// Check for MS-DOS.
//
if (pSpScanBootcode(BootSector,((!IsNEC_98) ? "MSDOS SYS" : "IO SYS"))) { //NEC98
FilesToLookFor = MsDosFiles;
FileCount = ELEMENT_COUNT(MsDosFiles);
description = L"MS-DOS";
PossiblyChicago = TRUE; // Chicago uses same signature files
} else {
//
// Check for PC-DOS.
//
if(pSpScanBootcode(BootSector,"IBMDOS COM")) {
FilesToLookFor = PcDosFiles;
FileCount = ELEMENT_COUNT(PcDosFiles);
description = L"PC-DOS";
} else {
//
// Check for OS/2.
//
if(pSpScanBootcode(BootSector,"OS2")) {
FilesToLookFor = Os2Files;
FileCount = ELEMENT_COUNT(Os2Files);
description = L"OS/2";
} else {
//
// Not NT, DOS, or OS/2.
// It's just plain old "previous operating system."
// Fetch the string from the resources.
//
WCHAR DriveLetterString[2];
DriveLetterString[0] = DriveLetter;
DriveLetterString[1] = L'\0';
SpStringToUpper(DriveLetterString);
FilesToLookFor = NULL;
FileCount = 0;
description = (PWSTR)TemporaryBuffer;
SpFormatMessage(description,sizeof(TemporaryBuffer),SP_TEXT_PREVIOUS_OS, DriveLetterString);
}
}
}
//
// If we think we have found an os, check to see whether
// its signature files are present.
// We could have, say, a disk where the user formats is using DOS
// and then installs NT immediately thereafter.
//
if(FilesToLookFor) {
//
// Copy CColonPath into a larger buffer, because
// SpNFilesExist wants to append a backslash onto it.
//
wcscpy((PWSTR)TemporaryBuffer,CColonPath);
if(!SpNFilesExist((PWSTR)TemporaryBuffer,FilesToLookFor,FileCount,FALSE)) {
//
// Ths os is not really there.
//
*IsOtherOsInstalled = FALSE;
description = L"";
} else if(PossiblyChicago) {
wcscpy((PWSTR)TemporaryBuffer, CColonPath);
SpConcatenatePaths((PWSTR)TemporaryBuffer, L"IO.SYS");
if(SpHasMZHeader((PWSTR)TemporaryBuffer)) {
description = L"Microsoft Windows";
}
}
}
}
//
// convert the description to oem text.
//
*OsDescription = SpToOem(description);
}
VOID
SpLayBootCode(
IN OUT PDISK_REGION CColonRegion
)
{
PUCHAR NewBootCode;
ULONG BootCodeSize;
PUCHAR ExistingBootCode;
NTSTATUS Status;
PUCHAR ExistingBootCodeOs;
PWSTR CColonPath;
HANDLE PartitionHandle;
PWSTR BootsectDosName = L"\\bootsect.dos";
PWSTR OldBootsectDosName = L"\\bootsect.bak";
PWSTR BootSectDosFullName, OldBootSectDosFullName, p;
BOOLEAN IsNtBootcode,OtherOsInstalled, FileExist;
UNICODE_STRING UnicodeString;
OBJECT_ATTRIBUTES Obja;
IO_STATUS_BLOCK IoStatusBlock;
BOOLEAN BootSectorCorrupt = FALSE;
ULONG MirrorSector;
ULONG BytesPerSector;
ULONGLONG ActualSectorCount, hidden_sectors, super_area_size;
UCHAR SysId;
ULONGLONG HiddenSectorCount,VolumeSectorCount; //NEC98
PUCHAR DiskArraySectorData,TmpBuffer; //NEC98
ExistingBootCode = NULL;
BytesPerSector = HardDisks[CColonRegion->DiskNumber].Geometry.BytesPerSector;
CLEAR_CLIENT_SCREEN();
SpDisplayStatusText(SP_STAT_INITING_FLEXBOOT,DEFAULT_STATUS_ATTRIBUTE);
switch(CColonRegion->Filesystem) {
case FilesystemNewlyCreated:
//
// If the filesystem is newly-created, then there is
// nothing to do, because there can be no previous
// operating system.
//
return;
case FilesystemNtfs:
NewBootCode = (!IsNEC_98) ? NtfsBootCode : PC98NtfsBootCode; //NEC98
BootCodeSize = (!IsNEC_98) ? sizeof(NtfsBootCode) : sizeof(PC98NtfsBootCode); //NEC98
ASSERT(BootCodeSize == 8192);
break;
case FilesystemFat:
NewBootCode = (!IsNEC_98) ? FatBootCode : PC98FatBootCode; //NEC98
BootCodeSize = (!IsNEC_98) ? sizeof(FatBootCode) : sizeof(PC98FatBootCode); //NEC98
ASSERT(BootCodeSize == 512);
break;
case FilesystemFat32:
//
// Special hackage required for Fat32 because its NT boot code
// is discontiguous.
//
ASSERT(sizeof(Fat32BootCode) == 1536);
NewBootCode = (!IsNEC_98) ? Fat32BootCode : PC98Fat32BootCode; //NEC98
BootCodeSize = 512;
break;
default:
if (RepairItems[RepairBootSect]) {
BootSectorCorrupt = TRUE;
} else {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: bogus filesystem %u for C:!\n",CColonRegion->Filesystem));
ASSERT(0);
return;
}
}
//
// Form the device path to C: and open the partition.
//
SpNtNameFromRegion(CColonRegion,(PWSTR)TemporaryBuffer,sizeof(TemporaryBuffer),PartitionOrdinalCurrent);
CColonPath = SpDupStringW((PWSTR)TemporaryBuffer);
INIT_OBJA(&Obja,&UnicodeString,CColonPath);
Status = ZwCreateFile(
&PartitionHandle,
FILE_GENERIC_READ | FILE_GENERIC_WRITE,
&Obja,
&IoStatusBlock,
NULL,
FILE_ATTRIBUTE_NORMAL,
FILE_SHARE_READ | FILE_SHARE_WRITE,
FILE_OPEN,
FILE_SYNCHRONOUS_IO_NONALERT,
NULL,
0
);
if (!NT_SUCCESS(Status)) {
KdPrintEx ((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: unable to open the partition for C:!\n"));
ASSERT(0);
return;
}
//
// Allocate a buffer and read in the boot sector(s) currently on the disk.
//
if (BootSectorCorrupt) {
//
// We can't determine the file system type from the boot sector, so
// we assume it's NTFS if we find a mirror sector, and FAT otherwise.
//
if (MirrorSector = NtfsMirrorBootSector (PartitionHandle,
BytesPerSector, &ExistingBootCode)) {
//
// It's NTFS - use the mirror boot sector
//
NewBootCode = (!IsNEC_98) ? NtfsBootCode : PC98NtfsBootCode; //NEC98
BootCodeSize = (!IsNEC_98) ? sizeof(NtfsBootCode) : sizeof(PC98NtfsBootCode); //NEC98
ASSERT(BootCodeSize == 8192);
CColonRegion->Filesystem = FilesystemNtfs;
IsNtBootcode = TRUE;
} else {
//
// It's FAT - create a new boot sector
//
NewBootCode = (!IsNEC_98) ? FatBootCode : PC98FatBootCode; //NEC98
BootCodeSize = (!IsNEC_98) ? sizeof(FatBootCode) : sizeof(PC98FatBootCode); //NEC98
ASSERT(BootCodeSize == 512);
CColonRegion->Filesystem = FilesystemFat;
IsNtBootcode = FALSE;
SpPtGetSectorLayoutInformation (CColonRegion, &hidden_sectors,
&ActualSectorCount);
//
// No alignment requirement here
//
ExistingBootCode = SpMemAlloc(BytesPerSector);
//
// This will actually fail with STATUS_BUFFER_TOO_SMALL but it will fill in
// the bpb, which is what we want
//
FmtFillFormatBuffer (
ActualSectorCount,
BytesPerSector,
HardDisks[CColonRegion->DiskNumber].Geometry.SectorsPerTrack,
HardDisks[CColonRegion->DiskNumber].Geometry.TracksPerCylinder,
hidden_sectors,
ExistingBootCode,
BytesPerSector,
&super_area_size,
NULL,
0,
&SysId
);
}
Status = STATUS_SUCCESS;
} else if (
RepairItems[RepairBootSect] &&
CColonRegion->Filesystem == FilesystemNtfs &&
(MirrorSector = NtfsMirrorBootSector (PartitionHandle, BytesPerSector,
&ExistingBootCode))
) {
//
// We use the mirror sector to repair a NTFS file system
//
} else {
//
// Just use the existing boot code.
//
Status = pSpBootCodeIo(
CColonPath,
NULL,
BootCodeSize,
&ExistingBootCode,
FILE_OPEN,
FALSE,
0,
BytesPerSector
);
if(CColonRegion->Filesystem == FilesystemNtfs) {
MirrorSector = NtfsMirrorBootSector(PartitionHandle,BytesPerSector,NULL);
}
}
if(NT_SUCCESS(Status)) {
//
// Determine the type of operating system the existing boot sector(s) are for
// and whether that os is actually installed. Note that we don't need to call
// this for NTFS.
//
if (BootSectorCorrupt) {
OtherOsInstalled = FALSE;
ExistingBootCodeOs = NULL;
} else if(CColonRegion->Filesystem != FilesystemNtfs) {
SpDetermineOsTypeFromBootSector(
CColonPath,
ExistingBootCode,
&ExistingBootCodeOs,
&IsNtBootcode,
&OtherOsInstalled,
CColonRegion->DriveLetter
);
} else {
IsNtBootcode = TRUE;
OtherOsInstalled = FALSE;
ExistingBootCodeOs = NULL;
}
//
// lay down the new boot code
//
if(OtherOsInstalled) {
if(RepairItems[RepairBootSect]) {
p = (PWSTR)TemporaryBuffer;
wcscpy(p,CColonPath);
SpConcatenatePaths(p,OldBootsectDosName);
OldBootSectDosFullName = SpDupStringW(p);
p = (PWSTR)TemporaryBuffer;
wcscpy(p,CColonPath);
SpConcatenatePaths(p,BootsectDosName);
BootSectDosFullName = SpDupStringW(p);
//
// If bootsect.dos already exists, we need to delete
// bootsect.pre, which may or may not exist and
// rename the bootsect.dos to bootsect.pre.
//
FileExist = SpFileExists(BootSectDosFullName, FALSE);
if (SpFileExists(OldBootSectDosFullName, FALSE) && FileExist) {
SpDeleteFile(CColonPath,OldBootsectDosName,NULL);
}
if (FileExist) {
SpRenameFile(BootSectDosFullName, OldBootSectDosFullName, FALSE);
}
SpMemFree(BootSectDosFullName);
SpMemFree(OldBootSectDosFullName);
} else {
//
// Delete bootsect.dos in preparation for rewriting it below.
// Doing this leverages code to set its attributes in SpDeleteFile.
// (We need to remove read-only attribute before overwriting).
//
SpDeleteFile(CColonPath,BootsectDosName,NULL);
}
//
// Write out the existing (old) boot sector into c:\bootsect.dos.
//
Status = pSpBootCodeIo(
CColonPath,
BootsectDosName,
BootCodeSize,
&ExistingBootCode,
FILE_OVERWRITE_IF,
TRUE,
0,
BytesPerSector
);
//
// Set the description text to the description calculated
// by SpDetermineOsTypeFromBootSector().
//
_snprintf(
OldSystemLine,
sizeof(OldSystemLine),
"C:\\ = \"%s\"\r\n",
ExistingBootCodeOs
);
} // end if(OtherOsInstalled)
if(NT_SUCCESS(Status)) {
//
// Transfer the bpb from the existing boot sector into the boot code buffer
// and make sure the physical drive field is set to hard disk (0x80).
//
// The first three bytes of the NT boot code are going to be something like
// EB 3C 90, which is intel jump instruction to an offset in the boot sector,
// past the BPB, to continue execution. We want to preserve everything in the
// current boot sector up to the start of that code. Instead of harcoding
// a value, we'll use the offset of the jump instruction to determine how many
// bytes must be preserved.
//
RtlMoveMemory(NewBootCode+3,ExistingBootCode+3,NewBootCode[1]-1);
if(CColonRegion->Filesystem != FilesystemFat32) {
//
// On fat32 this overwrites the BigNumFatSecs field,
// a very bad thing to do indeed!
//
NewBootCode[36] = 0x80;
}
//
// get Hidden sector informatin.
//
if (IsNEC_98) { //NEC98
SpPtGetSectorLayoutInformation(
CColonRegion,
&HiddenSectorCount,
&VolumeSectorCount // not used
);
//
// write Hidden sector informatin.
//
if (!RepairWinnt) { // for install a partition where before DOS 3.x
*((ULONG *)&(NewBootCode[0x1c])) = (ULONG)HiddenSectorCount;
if(*((USHORT *)&(NewBootCode[0x13])) != 0) {
*((ULONG *)&(NewBootCode[0x20])) = 0L;
}
}
} //NEC98
//
// Write out boot code buffer, which now contains the valid bpb,
// to the boot sector(s).
//
Status = pSpBootCodeIo(
CColonPath,
NULL,
BootCodeSize,
&NewBootCode,
FILE_OPEN,
TRUE,
0,
BytesPerSector
);
//
// Special case for Fat32, which has a second sector of boot code
// at sector 12, discontiguous from the code on sector 0.
//
if(NT_SUCCESS(Status) && (CColonRegion->Filesystem == FilesystemFat32)) {
NewBootCode = (!IsNEC_98) ? Fat32BootCode + 1024
: PC98Fat32BootCode + 1024; //NEC98
Status = pSpBootCodeIo(
CColonPath,
NULL,
BootCodeSize,
&NewBootCode,
FILE_OPEN,
TRUE,
12*512,
BytesPerSector
);
}
//
// Update the mirror boot sector.
//
if((CColonRegion->Filesystem == FilesystemNtfs) && MirrorSector) {
WriteNtfsBootSector(PartitionHandle,BytesPerSector,NewBootCode,MirrorSector);
}
}
if(ExistingBootCodeOs) {
SpMemFree(ExistingBootCodeOs);
}
}
if(ExistingBootCode) {
SpMemFree(ExistingBootCode);
}
SpMemFree(CColonPath);
ZwClose (PartitionHandle);
//
// Handle the error case.
//
if(!NT_SUCCESS(Status)) {
WCHAR DriveLetterString[2];
DriveLetterString[0] = CColonRegion->DriveLetter;
DriveLetterString[1] = L'\0';
SpStringToUpper(DriveLetterString);
SpStartScreen(SP_SCRN_CANT_INIT_FLEXBOOT,
3,
HEADER_HEIGHT+1,
FALSE,
FALSE,
DEFAULT_ATTRIBUTE,
DriveLetterString,
DriveLetterString
);
SpDisplayStatusOptions(DEFAULT_STATUS_ATTRIBUTE,SP_STAT_F3_EQUALS_EXIT,0);
SpInputDrain();
while(SpInputGetKeypress() != KEY_F3) ;
SpDone(0,FALSE,TRUE);
}
}
#if defined(REMOTE_BOOT)
BOOLEAN
Spx86FlushRemoteBootVars(
IN PDISK_REGION TargetRegion,
IN PWSTR **BootVars,
IN PWSTR Default
)
{
WCHAR BootIni[512];
NTSTATUS Status;
//
// Form the path to boot.ini.
//
SpNtNameFromRegion(TargetRegion,BootIni,sizeof(BootIni),PartitionOrdinalCurrent);
SpConcatenatePaths(BootIni,WBOOT_INI);
//
// If Boot.ini already exists, delete it.
//
if( SpFileExists( BootIni, FALSE ) ) {
SpDeleteFile( BootIni, NULL, NULL );
}
Status = Spx86WriteBootIni(
BootIni,
BootVars,
1, // timeout
Default,
1 // only write one line
);
if(!NT_SUCCESS( Status )) {
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_ERROR_LEVEL, "SETUP: Error writing boot.ini!\n"));
goto cleanup;
}
cleanup:
return( NT_SUCCESS(Status) );
}
#endif // defined(REMOTE_BOOT)
BOOLEAN
SpHasMZHeader(
IN PWSTR FileName
)
{
HANDLE FileHandle;
HANDLE SectionHandle;
PVOID ViewBase;
ULONG FileSize;
NTSTATUS Status;
PUCHAR Header;
BOOLEAN Ret = FALSE;
//
// Open and map the file.
//
FileHandle = 0;
Status = SpOpenAndMapFile(FileName,
&FileHandle,
&SectionHandle,
&ViewBase,
&FileSize,
FALSE
);
if(!NT_SUCCESS(Status)) {
return FALSE;
}
Header = (PUCHAR)ViewBase;
//
// Guard with try/except in case we get an inpage error
//
try {
if((FileSize >= 2) && (Header[0] == 'M') && (Header[1] == 'Z')) {
Ret = TRUE;
}
} except(IN_PAGE_ERROR) {
//
// Do nothing, we simply want to return FALSE.
//
}
SpUnmapFile(SectionHandle, ViewBase);
ZwClose(FileHandle);
return Ret;
}
//
// NEC98
//
PUCHAR
SpCreateBootiniImage(
OUT PULONG FileSize
)
{
PUCHAR BootIniBuf,IniImageBuf,IniImageBufSave,IniCreateBuf,IniCreateBufSave;
PUCHAR FindSectPtr;
PUCHAR sect; // point to target section. if it is NULL,not existing target section.
PUCHAR pArcNameA;
WCHAR TempBuffer[256];
WCHAR TempArcPath[256];
ULONG NtDirLen,TotalNtDirlen,CreateBufCnt;
ULONG Timeout;
ULONG Disk;
ULONG BootiniSize;
ULONG ArcNameLen;
PDISK_REGION pRegion;
HANDLE fh;
HANDLE SectionHandle;
PVOID ViewBase;
#define Default_Dir "\\MOCHI"
if(!HardDiskCount){
return(NULL);
}
//
// Create basic style of boot.ini image and progress pointer end of line.
//
NtDirLen = TotalNtDirlen = CreateBufCnt = 0;
IniCreateBufSave = IniCreateBuf = SpMemAlloc(1024);
RtlZeroMemory(IniCreateBuf,1024);
Timeout = DEFAULT_TIMEOUT;
sprintf(
IniCreateBuf,
"%s%s%s%s%ld%s%s%s%s%s%s%s%s",
FLEXBOOT_SECTION2, // [boot loader]
CRLF,
TIMEOUT,
EQUALS,
Timeout,
CRLF,
DEFAULT,
EQUALS,
"c:",
Default_Dir,
CRLF,
BOOTINI_OS_SECTION, // [operating systems]
CRLF
);
sect = SppFindSectionInBootIni(IniCreateBuf,FLEXBOOT_SECTION2);
if(sect == NULL){
return(NULL);
}
for( IniCreateBuf = sect; *IniCreateBuf && (*IniCreateBuf != '\n'); IniCreateBuf++,CreateBufCnt++);
CreateBufCnt++;
sect = SppFindSectionInBootIni(IniCreateBuf,TIMEOUT);
if(sect == NULL){
return(NULL);
}
for( IniCreateBuf = sect; *IniCreateBuf && (*IniCreateBuf != '\n'); IniCreateBuf++,CreateBufCnt++);
CreateBufCnt++;
sect = SppFindSectionInBootIni(IniCreateBuf,DEFAULT);
if(sect == NULL){
return(NULL);
}
for( IniCreateBuf = sect; *IniCreateBuf && (*IniCreateBuf != '\n'); IniCreateBuf++,CreateBufCnt++);
CreateBufCnt++;
sect = SppFindSectionInBootIni(IniCreateBuf,BOOTINI_OS_SECTION);
if(sect == NULL){
return(NULL);
}
for( IniCreateBuf = sect; *IniCreateBuf && (*IniCreateBuf != '\n'); IniCreateBuf++,CreateBufCnt++);
IniCreateBuf++;
CreateBufCnt++;
//
// Read boot.ini files from all drives.(except sleep and non bootable drives.)
//
for(Disk=0; Disk < HardDiskCount; Disk++){
for(pRegion=PartitionedDisks[Disk].PrimaryDiskRegions; pRegion;pRegion=pRegion->Next){
if(!pRegion->PartitionedSpace) {
continue;
}
SpNtNameFromRegion(
pRegion,
TempBuffer,
sizeof(TempBuffer),
PartitionOrdinalCurrent
);
SpConcatenatePaths(TempBuffer,WBOOT_INI);
//
// Open and map the boot.ini file.
//
fh = 0;
if(!NT_SUCCESS(SpOpenAndMapFile(TempBuffer,&fh,&SectionHandle,&ViewBase,&BootiniSize,FALSE))) {
continue;
}
//
// Allocate a buffer for the file.
//
IniImageBuf = SpMemAlloc(BootiniSize+1);
IniImageBufSave = IniImageBuf;
ASSERT(IniImageBuf);
RtlZeroMemory(IniImageBuf, BootiniSize+1);
//
// Transfer boot.ini into the buffer. We do this because we also
// want to place a 0 byte at the end of the buffer to terminate
// the file.
//
// Guard the RtlMoveMemory because if we touch the memory backed by boot.ini
// and get an i/o error, the memory manager will raise an exception.
try {
RtlMoveMemory(IniImageBuf,ViewBase,BootiniSize);
}
except( IN_PAGE_ERROR ) {
//
// Do nothing, boot ini processing can proceed with whatever has been
// read
//
}
//
// check out existing target section in boot.ini
//
sect = SppFindSectionInBootIni(IniImageBuf,FLEXBOOT_SECTION2);
if(sect==NULL){
SpMemFree(IniImageBufSave);
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(fh);
continue;
}
sect = SppFindSectionInBootIni(IniImageBuf,DEFAULT);
if(sect==NULL){
SpMemFree(IniImageBufSave);
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(fh);
continue;
}
sect = SppFindSectionInBootIni(IniImageBuf,BOOTINI_OS_SECTION);
if(sect == NULL){
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(fh);
continue;
}
//
// move pointer to end of line and skip the space.
//
for( IniImageBuf = sect; *IniImageBuf && (*IniImageBuf != '\n'); IniImageBuf++ );
for( ; *IniImageBuf && (( *IniImageBuf == ' ' ) || (*IniImageBuf == '\t')) ; IniImageBuf++ );
IniImageBuf++;
FindSectPtr = IniImageBuf;
//
// NOTE:
// override arc name when boot path written as "C:", not as arc name.
//
ArcNameLen = 0;
pArcNameA = (PUCHAR)NULL;
if( ( *(IniImageBuf+1) == L':' )&&( *(IniImageBuf+2) == L'\\' ) ) {
//
// This is NEC98 legacy style format, like "C:\WINNT=...",
// So translate to arc name for boot.ini in NT 5.0
//
SpArcNameFromRegion(pRegion,
TempArcPath,
sizeof(TempArcPath),
PartitionOrdinalOriginal,
PrimaryArcPath
);
pArcNameA = SpToOem(TempArcPath);
if( pArcNameA ) {
ArcNameLen = strlen(pArcNameA);
IniImageBuf += 2;
FindSectPtr = IniImageBuf;
}
}
for( NtDirLen = 0 ; *IniImageBuf && (*IniImageBuf != '\n');NtDirLen++,IniImageBuf++);
NtDirLen++;
if( ArcNameLen && pArcNameA ) { // Only case of override arc path.
RtlMoveMemory( IniCreateBuf+TotalNtDirlen, pArcNameA, ArcNameLen );
TotalNtDirlen += ArcNameLen;
SpMemFree(pArcNameA);
}
RtlMoveMemory(IniCreateBuf+TotalNtDirlen,FindSectPtr,NtDirLen);
TotalNtDirlen += NtDirLen;
SpMemFree(IniImageBufSave);
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(fh);
}
}
if(TotalNtDirlen == 0){
SpMemFree(IniCreateBufSave);
return(NULL);
}
BootIniBuf = SpMemAlloc(CreateBufCnt + TotalNtDirlen + 1);
if(!(BootIniBuf)){
SpMemFree(IniCreateBufSave);
return(NULL);
}
if(FileSize) {
*FileSize = CreateBufCnt + TotalNtDirlen;
}
RtlZeroMemory(BootIniBuf,CreateBufCnt + TotalNtDirlen + 1);
RtlMoveMemory(BootIniBuf,IniCreateBufSave,CreateBufCnt + TotalNtDirlen);
BootIniBuf[CreateBufCnt + TotalNtDirlen] = 0;
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "SETUP: Create NT List\n%s\n",BootIniBuf));
SpMemFree(IniCreateBufSave);
return(BootIniBuf);
}
//
// NEC98
//
BOOLEAN
SppReInitializeBootVars_Nec98(
OUT PWSTR **BootVars,
OUT PWSTR *Default,
OUT PULONG Timeout
)
{
WCHAR BootIni[512];
HANDLE FileHandle;
HANDLE SectionHandle;
PVOID ViewBase;
NTSTATUS Status;
ULONG FileSize;
PUCHAR BootIniBuf;
PDISK_REGION CColonRegion;
BOOTVAR i;
PUCHAR p;
ULONG index;
PUCHAR TmpBootIniBuf;
PUCHAR pBuf;
PUCHAR pTmpBuf;
PUCHAR pArcNameA;
PUCHAR NtDir;
ULONG ArcNameLen;
ULONG NtDirLen;
WCHAR TempArcPath[256];
BOOLEAN IsChanged = FALSE;
SIZE_T Length;
HEADLESS_RSP_QUERY_INFO Response;
//
// Initialize the defaults
//
for(i = FIRSTBOOTVAR; i <= LASTBOOTVAR; i++) {
if(BootVars[i]){
SpMemFree(BootVars[i]);
}
}
for(i = FIRSTBOOTVAR; i <= LASTBOOTVAR; i++) {
BootVars[i] = (PWSTR *)SpMemAlloc( sizeof ( PWSTR * ) );
ASSERT( BootVars[i] );
*BootVars[i] = NULL;
}
*Default = NULL;
*Timeout = DEFAULT_TIMEOUT;
//
// Just clear BOOTVARS[] when fresh setup.
//
if(NTUpgrade != UpgradeFull)
return TRUE;
//
// See if there is a valid C: already. If not, then silently fail.
//
#if defined(REMOTE_BOOT)
if (RemoteBootSetup && !RemoteInstallSetup) {
ASSERT(RemoteBootTargetRegion != NULL);
CColonRegion = RemoteBootTargetRegion;
} else
#endif // defined(REMOTE_BOOT)
{
CColonRegion = TargetRegion_Nec98;
}
//
// Form name of file. Boot.ini better not be on a doublespace drive.
//
ASSERT(CColonRegion->Filesystem != FilesystemDoubleSpace);
SpNtNameFromRegion(CColonRegion,BootIni,sizeof(BootIni),PartitionOrdinalCurrent);
SpConcatenatePaths(BootIni,WBOOT_INI);
//
// Open and map the file.
//
FileHandle = 0;
Status = SpOpenAndMapFile(BootIni,&FileHandle,&SectionHandle,&ViewBase,&FileSize,FALSE);
if(!NT_SUCCESS(Status)) {
return TRUE;
}
//
// Allocate a buffer for the file.
//
BootIniBuf = SpMemAlloc(FileSize+1);
ASSERT(BootIniBuf);
RtlZeroMemory(BootIniBuf, FileSize+1);
//
// Transfer boot.ini into the buffer. We do this because we also
// want to place a 0 byte at the end of the buffer to terminate
// the file.
//
// Guard the RtlMoveMemory because if we touch the memory backed by boot.ini
// and get an i/o error, the memory manager will raise an exception.
try {
RtlMoveMemory(BootIniBuf,ViewBase,FileSize);
}
except( IN_PAGE_ERROR ) {
//
// Do nothing, boot ini processing can proceed with whatever has been
// read
//
}
//
// Not needed since buffer has already been zeroed, however just do this
// just the same
//
BootIniBuf[FileSize] = 0;
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL, "SETUP: Create NT List\n%s\n",BootIniBuf));
//***
TmpBootIniBuf = SpMemAlloc(FileSize+256);
RtlZeroMemory(TmpBootIniBuf,FileSize+256);
RtlMoveMemory(TmpBootIniBuf,BootIniBuf,FileSize);
pBuf = SppFindSectionInBootIni(BootIniBuf,BOOTINI_OS_SECTION);
pTmpBuf = SppFindSectionInBootIni(TmpBootIniBuf,BOOTINI_OS_SECTION);
if (pBuf && pTmpBuf) {
while( *pBuf && (pBuf < BootIniBuf+FileSize-(sizeof("C:\\")-1)) ) {
if((!_strnicmp(pBuf,"C:\\",sizeof("C:\\")-1))||
(!_strnicmp(pBuf,"c:\\",sizeof("c:\\")-1))) {
ArcNameLen = 0;
pArcNameA = NULL;
p = strchr(pBuf+3,'='); // *(pBuf+3) == '\\'
if((p != pBuf+3) && (*p == '=')) {
NtDirLen = (ULONG)(p - (pBuf+3));
NtDir = SpMemAlloc(NtDirLen+1);
RtlZeroMemory(NtDir,NtDirLen+1);
RtlMoveMemory(NtDir,pBuf+3,NtDirLen);
if(SpIsNtInDirectory(TargetRegion_Nec98,SpToUnicode(NtDir))){
SpArcNameFromRegion(TargetRegion_Nec98,
TempArcPath,
sizeof(TempArcPath),
PartitionOrdinalOriginal,
PrimaryArcPath
);
if(pArcNameA=SpToOem(TempArcPath)) {
ArcNameLen = strlen(pArcNameA);
RtlMoveMemory(pTmpBuf,pArcNameA,ArcNameLen);
pBuf += 2;
pTmpBuf += ArcNameLen;
if( !IsChanged)
IsChanged = TRUE;
SpMemFree(NtDir);
continue;
}
}
SpMemFree(NtDir);
}
}
*pTmpBuf = *pBuf;
pBuf++;
pTmpBuf++;
}
}
if (IsChanged) {
if (pTmpBuf) {
*pTmpBuf = 0;
}
SpMemFree(BootIniBuf);
BootIniBuf = TmpBootIniBuf;
TmpBootIniBuf = (PUCHAR)NULL;
KdPrintEx((DPFLTR_SETUP_ID, DPFLTR_INFO_LEVEL,
"SETUP: Create New NT List\n%s\n",BootIniBuf));
} else {
SpMemFree(TmpBootIniBuf);
TmpBootIniBuf = (PUCHAR)NULL;
}
//
// Cleanup
//
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(FileHandle);
//
// Do the actual processing of the file.
//
SppProcessBootIni(BootIniBuf, BootVars, Default, Timeout);
//
// Scan the Buffer to see if there is a DefSwitches line,
// to move into new boot.ini in the [boot loader] section.
// If no DefSwitches, just point to a null string to be moved.
//
DefSwitches[0] = '\0';
for(p=BootIniBuf; *p && (p < BootIniBuf+FileSize-(sizeof("DefSwitches")-1)); p++) {
if(!_strnicmp(p,"DefSwitches",sizeof("DefSwitches")-1)) {
index = 0;
while ((*p != '\r') && (*p != '\n') && *p && (index < sizeof(DefSwitches)-4)) {
DefSwitches[index++] = *p++;
}
DefSwitches[index++] = '\r';
DefSwitches[index++] = '\n';
DefSwitches[index] = '\0';
break;
}
}
//
// Now add any headless parameters to the default switches.
//
Length = sizeof(HEADLESS_RSP_QUERY_INFO);
Status = HeadlessDispatch(HeadlessCmdQueryInformation,
NULL,
0,
&Response,
&Length
);
if (NT_SUCCESS(Status) &&
(Response.PortType == HeadlessSerialPort) &&
Response.Serial.TerminalAttached) {
if (Response.Serial.UsedBiosSettings) {
p = "redirect=UseBiosSettings\r\n";
} else {
switch (Response.Serial.TerminalPort) {
case ComPort1:
p = "redirect=com1\r\n";
break;
case ComPort2:
p = "redirect=com2\r\n";
break;
case ComPort3:
p = "redirect=com3\r\n";
break;
case ComPort4:
p = "redirect=com4\r\n";
break;
default:
ASSERT(0);
p = NULL;
break;
}
}
if (p != NULL) {
strcat(DefSwitches, p);
}
}
SpMemFree(BootIniBuf);
return( TRUE );
}
//
// NEC98
//
NTSTATUS
SppRestoreBootCode(
VOID
)
{
//
// Restore previous OS boot code to boot sector from bootsect.dos.
//
WCHAR p1[256] = {0};
PUCHAR BootSectBuf;
PUCHAR BootCodeBuf;
HANDLE FileHandle;
HANDLE SectionHandle;
PVOID ViewBase;
ULONG FileSize;
NTSTATUS Status;
PDISK_REGION SystemRegion;
//
// add some code to determine bytes per sector.
//
ULONG BytesPerSector;
// BytesPerSector = HardDisks[SystemPartitionRegion->DiskNumber].Geometry.BytesPerSector;
BytesPerSector = 512; //???
wcscpy(p1,NtBootDevicePath);
SpConcatenatePaths(p1,L"bootsect.dos");
FileHandle = 0;
Status = SpOpenAndMapFile(p1,&FileHandle,&SectionHandle,&ViewBase,&FileSize,FALSE);
if(!NT_SUCCESS(Status)) {
return(Status);
}
BootCodeBuf = SpMemAlloc(FileSize+1);
try {
RtlMoveMemory(BootCodeBuf,ViewBase,FileSize);
}
except( IN_PAGE_ERROR ) {
//
// Do nothing, boot ini processing can proceed with whatever has been
// read
//
}
Status = pSpBootCodeIo(
NtBootDevicePath,
NULL,
2048,
&BootSectBuf,
FILE_OPEN,
FALSE,
0,
BytesPerSector
);
if(!NT_SUCCESS(Status)) {
SpMemFree(BootCodeBuf);
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(FileHandle);
return(Status);
}
//
// Keep dirty flag in FAT BPB, to avoid confusion in disk management.
//
SystemRegion = SpRegionFromNtName(NtBootDevicePath, PartitionOrdinalCurrent);
if(SystemRegion && (SystemRegion->Filesystem != FilesystemNtfs)) {
BootCodeBuf[0x25] = BootSectBuf[0x25]; // Dirty flag in BPB.
}
RtlMoveMemory(BootSectBuf,BootCodeBuf,512);
pSpBootCodeIo(
NtBootDevicePath,
NULL,
2048,
&BootSectBuf,
FILE_OPEN,
TRUE,
0,
BytesPerSector
);
SpMemFree(BootCodeBuf);
SpMemFree(BootSectBuf);
SpUnmapFile(SectionHandle,ViewBase);
ZwClose(FileHandle);
return(Status);
}