reactos/base/applications/atactl/atactl.cpp
2019-08-15 14:20:00 +02:00

1944 lines
59 KiB
C++

#include <stdarg.h>
#include <windef.h>
#include <winbase.h>
#include <winreg.h>
#include <winioctl.h>
#include <stdlib.h>
//#include <ntdddisk.h>
//#include <ntddscsi.h>
#include <ntddscsi.h>
#include <atapi.h>
#include <bm_devs.h>
#include <uata_ctl.h>
#include <tools.h>
#include <uniata_ver.h>
#include "helper.h"
#define DEFAULT_REMOVAL_LOCK_TIMEOUT 20
#define MOV_DW_SWP(a,b) \
do \
{ \
*(unsigned short *)&(a) = _byteswap_ushort(*(unsigned short *)&(b)); \
} \
while (0)
#define MOV_DD_SWP(a,b) \
{ \
PFOUR_BYTE _from_, _to_; \
_from_ = ((PFOUR_BYTE)&(b)); \
_to_ = ((PFOUR_BYTE)&(a)); \
__asm mov ebx,_from_ \
__asm mov eax,[ebx] \
__asm bswap eax \
__asm mov ebx,_to_ \
__asm mov [ebx],eax \
}
int g_extended = 0;
int g_adapter_info = 0;
char* g_bb_list = NULL;
int gRadix = 16;
PADAPTERINFO g_AdapterInfo = NULL;
BOOLEAN
ata_power_mode(
int bus_id,
int dev_id,
int power_mode
);
void print_help() {
printf("Usage:\n"
" atactl -<switches> c|s<controller id>:b<bus id>:d<device id>[:l<lun>]\n"
"Switches:\n"
" l (L)ist devices on SCSI and ATA controllers bus(es)\n"
" Note: ATA Pri/Sec controller are usually represented\n"
" as Scsi0/Scsi1 under NT-family OSes\n"
" x show e(X)tended info\n"
" a show (A)dapter info\n"
" s (S)can for new devices on ATA/SATA bus(es) (experimental)\n"
" S (S)can for new devices on ATA/SATA bus(es) (experimental)\n"
" device, hidden with 'H' can be redetected\n"
" h (H)ide device on ATA/SATA bus for removal (experimental)\n"
" device can be redetected\n"
" H (H)ide device on ATA/SATA bus (experimental)\n"
" device can not be redetected until 'h' or 'S' is issued\n"
" m [MODE] set i/o (M)ode for device or revert to default\n"
" available MODEs are PIO, PIO0-PIO5, DMA, WDMA0-WDMA2,\n"
" UDMA33/44/66/100/133, UDMA0-UDMA5\n"
" d [XXX] lock ATA/SATA bus for device removal for XXX seconds or\n"
" for %d seconds if no lock timeout specified.\n"
" can be used with -h, -m or standalone.\n"
" D [XXX] disable device (turn into sleep mode) and lock ATA/SATA bus \n"
" for device removal for XXX seconds or\n"
" for %d seconds if no lock timeout specified.\n"
" can be used with -h, -m or standalone.\n"
" pX change power state to X, where X is\n"
" 0 - active, 1 - idle, 2 - standby, 3 - sleep\n"
" r (R)eset device\n"
" ba (A)ssign (B)ad-block list\n"
" bl get assigned (B)ad-block (L)ist\n"
" br (R)eset assigned (B)ad-block list\n"
" f specify (F)ile for bad-block list\n"
" n XXX block (n)ubmering radix. XXX can be hex or dec\n"
"------\n"
"Examples:\n"
" atactl -l\n"
" will list all scsi buses and all connected devices\n"
" atactl -m udma0 s2:b1:d1\n"
" will switch device at Scsi2, bus 1, taget_id 1 to UDMA0 mode\n"
" atactl -h -d 30 c1:b0:d0:l0 \n"
" will hide Master (d0:l0) device on secondary (c1:b0) IDE channel\n"
" and lock i/o on this channel for 30 seconds to ensure safety\n"
" of removal process"
"------\n"
"Device address format:\n"
"\n"
"s<controller id> number of controller in system. Is assigned during hardware\n"
" detection. Usually s0/s1 are ATA Pri/Sec.\n"
" Note, due do NT internal design ATA controllers are represented\n"
" as SCSI controllers.\n"
"b<bus id> For ATA controllers it is channel number.\n"
" Note, usually onboard controller is represented as 2 legacy\n"
" ISA-compatible single-channel controllers (Scsi9/Scsi1). Additional\n"
" ATA, ATA-RAID and some specific onboard controllers are represented\n"
" as multichannel controllers.\n"
"d<device id> For ATA controllers d0 is Master, d1 is Slave.\n"
"l<lun> Not used in ATA controller drivers, alway 0\n"
"------\n"
"Bad-block list format:\n"
"\n"
"# Comment\n"
"; Still one comment\n"
"hex: switch to hexadecimal mode\n"
"<Bad Area 1 Start LBA, e.g. FD50> <Block count 1, e.g. 60>\n"
"<Bad Area 2 Start LBA> <Block count 2>\n"
"...\n"
"dec: switch to decimal mode\n"
"<Bad Area N Start LBA, e.g. 16384> <Block count N, e.g. 48>\n"
"...\n"
"------\n"
"",
DEFAULT_REMOVAL_LOCK_TIMEOUT,
DEFAULT_REMOVAL_LOCK_TIMEOUT
);
exit(0);
}
#define CMD_ATA_LIST 0x01
#define CMD_ATA_FIND 0x02
#define CMD_ATA_HIDE 0x03
#define CMD_ATA_MODE 0x04
#define CMD_ATA_RESET 0x05
#define CMD_ATA_BBLK 0x06
#define CMD_ATA_POWER 0x07
HANDLE
ata_open_dev(
char* Name
)
{
ULONG i;
HANDLE h;
for(i=0; i<4; i++) {
h = CreateFile(Name,
READ_CONTROL | GENERIC_READ | GENERIC_WRITE ,
((i & 1) ? 0 : FILE_SHARE_READ) | ((i & 2) ? 0 : FILE_SHARE_WRITE),
NULL,
OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL,
NULL);
if(h && (h != ((HANDLE)(-1))) ) {
return h;
}
}
for(i=0; i<4; i++) {
h = CreateFile(Name,
GENERIC_READ | GENERIC_WRITE ,
((i & 1) ? 0 : FILE_SHARE_READ) | ((i & 2) ? 0 : FILE_SHARE_WRITE),
NULL,
OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL,
NULL);
if(h && (h != ((HANDLE)(-1))) ) {
return h;
}
}
for(i=0; i<4; i++) {
h = CreateFile(Name,
GENERIC_READ,
((i & 1) ? 0 : FILE_SHARE_READ) | ((i & 2) ? 0 : FILE_SHARE_WRITE),
NULL,
OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL,
NULL);
if(h && (h != ((HANDLE)(-1))) ) {
return h;
}
}
for(i=0; i<4; i++) {
h = CreateFile(Name,
READ_CONTROL,
((i & 1) ? 0 : FILE_SHARE_READ) | ((i & 2) ? 0 : FILE_SHARE_WRITE),
NULL,
OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL,
NULL);
if(h && (h != ((HANDLE)(-1))) ) {
return h;
}
}
return NULL;
} // end ata_open_dev()
HANDLE
ata_open_file(
char* Name,
BOOLEAN create
)
{
ULONG i;
HANDLE h;
if(!Name) {
if(create) {
return GetStdHandle(STD_OUTPUT_HANDLE);
} else {
return GetStdHandle(STD_INPUT_HANDLE);
}
}
for(i=0; i<4; i++) {
h = CreateFile(Name,
create ? GENERIC_WRITE : GENERIC_READ ,
((i & 1) ? 0 : FILE_SHARE_READ) | ((i & 2) ? 0 : FILE_SHARE_WRITE),
NULL,
create ? CREATE_NEW : OPEN_EXISTING,
FILE_ATTRIBUTE_NORMAL,
NULL);
if(h && (h != ((HANDLE)(-1))) ) {
return h;
}
}
return NULL;
} // end ata_open_file()
void
ata_close_dev(
HANDLE h
)
{
CloseHandle(h);
} // end ata_close_dev()
int
ata_send_ioctl(
HANDLE h,
PSCSI_ADDRESS addr,
PCCH Signature,
ULONG Ioctl,
PVOID inBuffer,
ULONG inBufferLength,
PVOID outBuffer,
ULONG outBufferLength,
PULONG returned
)
{
ULONG status;
PUNIATA_CTL AtaCtl;
ULONG data_len = max(inBufferLength, outBufferLength);
ULONG len;
if(addr) {
len = data_len + offsetof(UNIATA_CTL, RawData);
} else {
len = data_len + sizeof(AtaCtl->hdr);
}
AtaCtl = (PUNIATA_CTL)GlobalAlloc(GMEM_FIXED, len);
AtaCtl->hdr.HeaderLength = sizeof(SRB_IO_CONTROL);
if(addr) {
AtaCtl->hdr.Length = data_len + offsetof(UNIATA_CTL, RawData) - sizeof(AtaCtl->hdr);
} else {
AtaCtl->hdr.Length = data_len;
}
memcpy(&AtaCtl->hdr.Signature, Signature, 8);
AtaCtl->hdr.Timeout = 10000;
AtaCtl->hdr.ControlCode = Ioctl;
AtaCtl->hdr.ReturnCode = 0;
if(addr) {
AtaCtl->addr = *addr;
AtaCtl->addr.Length = sizeof(AtaCtl->addr);
}
if(outBufferLength) {
if(addr) {
memset(&AtaCtl->RawData, 0, outBufferLength);
} else {
memset(&AtaCtl->addr, 0, outBufferLength);
}
}
if(inBuffer && inBufferLength) {
if(addr) {
memcpy(&AtaCtl->RawData, inBuffer, inBufferLength);
} else {
memcpy(&AtaCtl->addr, inBuffer, inBufferLength);
}
}
status = DeviceIoControl(h,
IOCTL_SCSI_MINIPORT,
AtaCtl,
len,
AtaCtl,
len,
returned,
FALSE);
if(outBuffer && outBufferLength) {
if(addr) {
memcpy(outBuffer, &AtaCtl->RawData, outBufferLength);
} else {
memcpy(outBuffer, &AtaCtl->addr, outBufferLength);
}
}
GlobalFree(AtaCtl);
if(!status) {
status = GetLastError();
return FALSE;
}
return TRUE;
} // end ata_send_ioctl()
int
ata_send_scsi(
HANDLE h,
PSCSI_ADDRESS addr,
PCDB cdb,
UCHAR cdbLength,
PVOID Buffer,
ULONG BufferLength,
BOOLEAN DataIn,
PSENSE_DATA senseData,
PULONG returned
)
{
ULONG status;
PSCSI_PASS_THROUGH_WITH_BUFFERS sptwb;
//ULONG data_len = BufferLength;
ULONG len;
len = BufferLength + offsetof(SCSI_PASS_THROUGH_WITH_BUFFERS, ucDataBuf);
sptwb = (PSCSI_PASS_THROUGH_WITH_BUFFERS)GlobalAlloc(GMEM_FIXED, len);
if(!sptwb) {
return FALSE;
}
memset(sptwb, 0, offsetof(SCSI_PASS_THROUGH_WITH_BUFFERS, ucDataBuf));
sptwb->spt.Length = sizeof(SCSI_PASS_THROUGH);
sptwb->spt.PathId = addr->PathId;
sptwb->spt.TargetId = addr->TargetId;
sptwb->spt.Lun = addr->Lun;
sptwb->spt.CdbLength = cdbLength;
sptwb->spt.SenseInfoLength = 24;
sptwb->spt.DataIn = Buffer ? (DataIn ? SCSI_IOCTL_DATA_IN : SCSI_IOCTL_DATA_OUT) : 0;
sptwb->spt.DataTransferLength = BufferLength;
sptwb->spt.TimeOutValue = 10;
sptwb->spt.DataBufferOffset =
offsetof(SCSI_PASS_THROUGH_WITH_BUFFERS,ucDataBuf);
sptwb->spt.SenseInfoOffset =
offsetof(SCSI_PASS_THROUGH_WITH_BUFFERS,ucSenseBuf);
memcpy(&sptwb->spt.Cdb, cdb, cdbLength);
if(Buffer && !DataIn) {
memcpy(&sptwb->ucSenseBuf, Buffer, BufferLength);
}
status = DeviceIoControl(h,
IOCTL_SCSI_PASS_THROUGH,
sptwb,
(Buffer && !DataIn) ? len : sizeof(SCSI_PASS_THROUGH),
sptwb,
(Buffer && DataIn) ? len : offsetof(SCSI_PASS_THROUGH_WITH_BUFFERS, ucDataBuf),
returned,
FALSE);
if(Buffer && DataIn) {
memcpy(Buffer, &sptwb->ucDataBuf, BufferLength);
}
if(senseData) {
memcpy(senseData, &sptwb->ucSenseBuf, sizeof(sptwb->ucSenseBuf));
}
GlobalFree(sptwb);
if(!status) {
status = GetLastError();
return FALSE;
}
return TRUE;
} // end ata_send_scsi()
IO_SCSI_CAPABILITIES g_capabilities;
UCHAR g_inquiry_buffer[2048];
void
ata_mode_to_str(
char* str,
int mode
)
{
if(mode > ATA_SA600) {
sprintf(str, "SATA-600+");
} else
if(mode >= ATA_SA600) {
sprintf(str, "SATA-600");
} else
if(mode >= ATA_SA300) {
sprintf(str, "SATA-300");
} else
if(mode >= ATA_SA150) {
sprintf(str, "SATA-150");
} else
if(mode >= ATA_UDMA0) {
sprintf(str, "UDMA%d", mode-ATA_UDMA0);
} else
if(mode >= ATA_WDMA0) {
sprintf(str, "WDMA%d", mode-ATA_WDMA0);
} else
if(mode >= ATA_SDMA0) {
sprintf(str, "SDMA%d", mode-ATA_SDMA0);
} else
if(mode >= ATA_PIO0) {
sprintf(str, "PIO%d", mode-ATA_PIO0);
} else
if(mode == ATA_PIO_NRDY) {
sprintf(str, "PIO nRDY");
} else
{
sprintf(str, "PIO");
}
} // end ata_mode_to_str()
#define check_atamode_str(str, mode) \
(!_stricmp(str, "UDMA" #mode) || \
!_stricmp(str, "UDMA-" #mode) || \
!_stricmp(str, "ATA-" #mode) || \
!_stricmp(str, "ATA#" #mode))
int
ata_str_to_mode(
char* str
)
{
int mode;
size_t len;
if(!_stricmp(str, "SATA600"))
return ATA_SA600;
if(!_stricmp(str, "SATA300"))
return ATA_SA300;
if(!_stricmp(str, "SATA150"))
return ATA_SA150;
if(!_stricmp(str, "SATA"))
return ATA_SA150;
if(check_atamode_str(str, 16))
return ATA_UDMA0;
if(check_atamode_str(str, 25))
return ATA_UDMA1;
if(check_atamode_str(str, 33))
return ATA_UDMA2;
if(check_atamode_str(str, 44))
return ATA_UDMA3;
if(check_atamode_str(str, 66))
return ATA_UDMA4;
if(check_atamode_str(str, 100))
return ATA_UDMA5;
if(check_atamode_str(str, 122))
return ATA_UDMA6;
len = strlen(str);
if(len >= 4 && !_memicmp(str, "UDMA", 4)) {
if(len == 4)
return ATA_UDMA0;
if(len > 5)
return -1;
mode = str[4] - '0';
if(mode < 0 || mode > 7)
return -1;
return ATA_UDMA0+mode;
}
if(len >= 4 && !_memicmp(str, "WDMA", 4)) {
if(len == 4)
return ATA_WDMA0;
if(len > 5)
return -1;
mode = str[4] - '0';
if(mode < 0 || mode > 2)
return -1;
return ATA_WDMA0+mode;
}
if(len >= 4 && !_memicmp(str, "SDMA", 4)) {
if(len == 4)
return ATA_SDMA0;
if(len > 5)
return -1;
mode = str[4] - '0';
if(mode < 0 || mode > 2)
return -1;
return ATA_SDMA0+mode;
}
if(len == 4 && !_memicmp(str, "DMA", 4)) {
return ATA_SDMA0;
}
if(len >= 3 && !_memicmp(str, "PIO", 3)) {
if(len == 3)
return ATA_PIO;
if(len > 4)
return -1;
mode = str[3] - '0';
if(mode < 0 || mode > 5)
return -1;
return ATA_PIO0+mode;
}
return -1;
} // end ata_str_to_mode()
ULONG
EncodeVendorStr(
OUT char* Buffer,
IN PUCHAR Str,
IN ULONG Length,
IN ULONG Xorer
)
{
ULONG i,j;
UCHAR a;
for(i=0, j=0; i<Length; i++, j++) {
a = Str[i ^ Xorer];
if(!a) {
Buffer[j] = 0;
return j;
} else
if(a == ' ') {
Buffer[j] = '_';
} else
if((a == '_') ||
(a == '#') ||
(a == '\\') ||
(a == '\"') ||
(a == '\'') ||
(a < ' ') ||
(a >= 127)) {
Buffer[j] = '#';
j++;
sprintf(Buffer+j, "%2.2x", a);
j++;
} else {
Buffer[j] = a;
}
}
Buffer[j] = 0;
return j;
} // end EncodeVendorStr()
HKEY
ata_get_bblist_regh(
IN PIDENTIFY_DATA ident,
OUT char* DevSerial,
BOOLEAN read_only
)
{
HKEY hKey = NULL;
HKEY hKey2 = NULL;
ULONG Length;
REGSAM access = read_only ? KEY_READ : KEY_ALL_ACCESS;
Length = EncodeVendorStr(DevSerial, (PUCHAR)ident->ModelNumber, sizeof(ident->ModelNumber), 0x01);
DevSerial[Length] = '-';
Length++;
Length += EncodeVendorStr(DevSerial+Length, ident->SerialNumber, sizeof(ident->SerialNumber), 0x01);
if(RegOpenKeyEx(HKEY_LOCAL_MACHINE, "SYSTEM\\CurrentControlSet\\Services\\UniATA", NULL, access, &hKey) != ERROR_SUCCESS) {
hKey = NULL;
goto exit;
}
if(RegOpenKey(hKey, "Parameters", &hKey2) != ERROR_SUCCESS) {
hKey2 = NULL;
if(read_only || (RegCreateKey(hKey, "Parameters", &hKey2) != ERROR_SUCCESS)) {
hKey2 = NULL;
goto exit;
}
}
RegCloseKey(hKey2);
if(RegOpenKey(hKey, "Parameters\\BadBlocks", &hKey2) != ERROR_SUCCESS) {
hKey2 = NULL;
if(read_only || (RegCreateKey(hKey, "Parameters\\BadBlocks", &hKey2) != ERROR_SUCCESS)) {
hKey2 = NULL;
goto exit;
}
}
exit:
if(hKey)
RegCloseKey(hKey);
return hKey2;
} // end ata_get_bblist_regh()
IDENTIFY_DATA g_ident;
int
ata_check_unit(
HANDLE h, // handle to ScsiXXX:
int dev_id
)
{
ULONG status;
ULONG returned;
PSCSI_ADAPTER_BUS_INFO adapterInfo;
PSCSI_INQUIRY_DATA inquiryData;
SCSI_ADDRESS addr;
ULONG i, j;
int l_dev_id;
ULONG len;
GETTRANSFERMODE IoMode;
PSENDCMDOUTPARAMS pout;
PIDENTIFY_DATA ident;
PINQUIRYDATA scsi_ident;
char buff[sizeof(SENDCMDOUTPARAMS)+/*sizeof(IDENTIFY_DATA)*/2048];
char mode_str[12];
//ULONG bus_id = (dev_id >> 24) & 0xff;
BOOLEAN found = FALSE;
SENDCMDINPARAMS pin;
int io_mode = -1;
char SerNum[128];
char DevSerial[128];
char lun_str[10];
HKEY hKey2;
ULONGLONG max_lba = -1;
USHORT chs[3] = { 0 };
if(dev_id != -1) {
dev_id &= 0x00ffffff;
}
if(dev_id == 0x007f7f7f) {
return TRUE;
}
pout = (PSENDCMDOUTPARAMS)buff;
ident = (PIDENTIFY_DATA)&(pout->bBuffer);
status = DeviceIoControl(h,
IOCTL_SCSI_GET_INQUIRY_DATA,
NULL,
0,
g_inquiry_buffer,
sizeof(g_inquiry_buffer),
&returned,
FALSE);
if(!status) {
printf("Can't get device info\n");
return FALSE;
}
// Note: adapterInfo->NumberOfBuses is 1 greater than g_AdapterInfo->NumberChannels
// because of virtual communication port
adapterInfo = (PSCSI_ADAPTER_BUS_INFO)g_inquiry_buffer;
for (i = 0; i+1 < adapterInfo->NumberOfBuses; i++) {
inquiryData = (PSCSI_INQUIRY_DATA) (g_inquiry_buffer +
adapterInfo->BusData[i].InquiryDataOffset);
if(g_extended && g_AdapterInfo && g_AdapterInfo->ChanHeaderLengthValid &&
g_AdapterInfo->NumberChannels < i) {
PCHANINFO ChanInfo;
ChanInfo = (PCHANINFO)
(((PCHAR)g_AdapterInfo)+
sizeof(ADAPTERINFO)+
g_AdapterInfo->ChanHeaderLength*i);
io_mode = ChanInfo->MaxTransferMode;
if(io_mode != -1) {
ata_mode_to_str(mode_str, io_mode);
} else {
mode_str[0] = 0;
}
printf(" b%lu [%s]\n",
i,
mode_str
);
}
while (adapterInfo->BusData[i].InquiryDataOffset) {
/*
if(dev_id/adapterInfo->BusData[i].NumberOfLogicalUnits ==
inquiryData->TargetId &&
dev_id%adapterInfo->BusData[i].NumberOfLogicalUnits ==
inquiryData->Lun) {
printf(" %d %d %3d %s %.28s ",
i,
inquiryData->TargetId,
inquiryData->Lun,
(inquiryData->DeviceClaimed) ? "Y" : "N",
&inquiryData->InquiryData[8]);
}*/
l_dev_id = (i << 16) | ((ULONG)(inquiryData->TargetId) << 8) | inquiryData->Lun;
if(l_dev_id == dev_id || dev_id == -1) {
scsi_ident = (PINQUIRYDATA)&(inquiryData->InquiryData);
if(!memcmp(&(scsi_ident->VendorId[0]), UNIATA_COMM_PORT_VENDOR_STR, 24)) {
// skip communication port
goto next_dev;
}
found = TRUE;
if(inquiryData->Lun) {
sprintf(lun_str, ":l%d", inquiryData->Lun);
} else {
sprintf(lun_str, " ");
}
/*
for (j = 0; j < 8; j++) {
printf("%02X ", inquiryData->InquiryData[j]);
}
*/
addr.Length = sizeof(addr);
addr.PortNumber = -1;
addr.PathId = inquiryData->PathId;
addr.TargetId = inquiryData->TargetId;
addr.Lun = inquiryData->Lun;
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_GET_MODE,
NULL, 0,
&IoMode, sizeof(IoMode),
&returned);
if(status) {
//io_mode = min(IoMode.CurrentMode, IoMode.MaxMode);
io_mode = IoMode.PhyMode;
if(!io_mode) {
io_mode = min(max(IoMode.CurrentMode,IoMode.OrigMode),IoMode.MaxMode);
}
} else {
io_mode = -1;
}
memset(&pin, 0, sizeof(pin));
memset(buff, 0, sizeof(buff));
pin.irDriveRegs.bCommandReg = ID_CMD;
// this is valid for IDE/ATA, where only 2 devices can be attached to the bus.
// probably, we shall change this in future to support SATA splitters
pin.bDriveNumber = inquiryData->PathId*2+inquiryData->TargetId;
status = ata_send_ioctl(h, NULL, "SCSIDISK",
IOCTL_SCSI_MINIPORT_IDENTIFY,
&pin, sizeof(pin),
buff, sizeof(buff),
&returned);
if(!status) {
memset(&pin, 0, sizeof(pin));
memset(buff, 0, sizeof(buff));
pin.irDriveRegs.bCommandReg = ATAPI_ID_CMD;
// this is valid for IDE/ATA, where only 2 devices can be attached to the bus.
// probably, we shall change this in future to support SATA splitters
pin.bDriveNumber = inquiryData->PathId*2+inquiryData->TargetId;
status = ata_send_ioctl(h, NULL, "SCSIDISK",
IOCTL_SCSI_MINIPORT_IDENTIFY,
&pin, sizeof(pin),
buff, sizeof(buff),
&returned);
}
if(!g_extended) {
printf(" b%lu:d%d%s %24.24s %4.4s ",
i,
inquiryData->TargetId,
lun_str,
/*(inquiryData->DeviceClaimed) ? "Y" : "N",*/
(g_extended ? (PUCHAR)"" : &scsi_ident->VendorId[0]),
(g_extended ? (PUCHAR)"" : &scsi_ident->ProductRevisionLevel[0])
);
} else {
printf(" b%lu:d%d%s ",
i,
inquiryData->TargetId,
lun_str
);
}
if(status) {
if(io_mode == -1) {
io_mode = ata_cur_mode_from_ident(ident, IDENT_MODE_ACTIVE);
}
}
if(io_mode != -1) {
ata_mode_to_str(mode_str, io_mode);
}
if(!g_extended || !status) {
if(g_extended) {
printf(" %24.24s %4.4s ",
(&inquiryData->InquiryData[8]),
(&inquiryData->InquiryData[8+24])
);
}
if(io_mode != -1) {
printf(" %.12s ", mode_str);
}
}
printf("\n");
if(g_extended) {
if(status) {
BOOLEAN BlockMode_valid = TRUE;
BOOLEAN print_geom = FALSE;
switch(ident->DeviceType) {
case ATAPI_TYPE_DIRECT:
if(ident->Removable) {
printf(" Floppy ");
} else {
printf(" Hard Drive ");
}
break;
case ATAPI_TYPE_TAPE:
printf(" Tape Drive ");
break;
case ATAPI_TYPE_CDROM:
printf(" CD/DVD Drive ");
BlockMode_valid = FALSE;
break;
case ATAPI_TYPE_OPTICAL:
printf(" Optical Drive ");
BlockMode_valid = FALSE;
break;
default:
printf(" Hard Drive ");
print_geom = TRUE;
//MOV_DD_SWP(max_lba, ident->UserAddressableSectors);
max_lba = ident->UserAddressableSectors;
if(ident->FeaturesSupport.Address48) {
max_lba = ident->UserAddressableSectors48;
}
//MOV_DW_SWP(chs[0], ident->NumberOfCylinders);
//MOV_DW_SWP(chs[1], ident->NumberOfHeads);
//MOV_DW_SWP(chs[2], ident->SectorsPerTrack);
chs[0] = ident->NumberOfCylinders;
chs[1] = ident->NumberOfHeads;
chs[2] = ident->SectorsPerTrack;
if(!max_lba) {
max_lba = (ULONG)(chs[0])*(ULONG)(chs[1])*(ULONG)(chs[2]);
}
}
if(io_mode != -1) {
printf(" %.12s\n", mode_str);
}
for (j = 0; j < 40; j += 2) {
MOV_DW_SWP(SerNum[j], ((PUCHAR)ident->ModelNumber)[j]);
}
printf(" Mod: %40.40s\n", SerNum);
for (j = 0; j < 8; j += 2) {
MOV_DW_SWP(SerNum[j], ((PUCHAR)ident->FirmwareRevision)[j]);
}
printf(" Rev: %8.8s\n", SerNum);
for (j = 0; j < 20; j += 2) {
MOV_DW_SWP(SerNum[j], ((PUCHAR)ident->SerialNumber)[j]);
}
printf(" S/N: %20.20s\n", SerNum);
if(BlockMode_valid) {
if(ident->MaximumBlockTransfer) {
printf(" Multi-block mode: %u block%s\n", ident->MaximumBlockTransfer, ident->MaximumBlockTransfer == 1 ? "" : "s");
} else {
printf(" Multi-block mode: N/A\n");
}
}
if(print_geom) {
printf(" C/H/S: %u/%u/%u \n", chs[0], chs[1], chs[2]);
printf(" LBA: %I64u \n", max_lba);
if(max_lba < 2) {
printf(" Size: %lu kb\n", (ULONG)(max_lba/2));
} else
if(max_lba < 2*1024*1024) {
printf(" Size: %lu Mb\n", (ULONG)(max_lba/2048));
} else
if(max_lba < (ULONG)2*1024*1024*1024) {
printf(" Size: %lu.%lu (%lu) Gb\n", (ULONG)(max_lba/2048/1024),
(ULONG)(((max_lba/2048)%1024)/10),
(ULONG)(max_lba*512/1000/1000/1000)
);
} else {
printf(" Size: %lu.%lu (%lu) Tb\n", (ULONG)(max_lba/2048/1024/1024),
(ULONG)((max_lba/2048/1024)%1024)/10,
(ULONG)(max_lba*512/1000/1000/1000)
);
}
}
len = 0;
if((hKey2 = ata_get_bblist_regh(ident, DevSerial, TRUE))) {
if(RegQueryValueEx(hKey2, DevSerial, NULL, NULL, NULL, &len) == ERROR_SUCCESS) {
printf(" !!! Assigned bad-block list !!!\n");
}
RegCloseKey(hKey2);
}
} else {
switch(scsi_ident->DeviceType) {
case DIRECT_ACCESS_DEVICE:
if(scsi_ident->RemovableMedia) {
printf(" Floppy ");
} else {
printf(" Hard Drive ");
}
break;
case SEQUENTIAL_ACCESS_DEVICE:
printf(" Tape Drive ");
break;
case PRINTER_DEVICE:
printf(" Printer ");
break;
case PROCESSOR_DEVICE:
printf(" Processor ");
break;
case WRITE_ONCE_READ_MULTIPLE_DEVICE:
printf(" WORM Drive ");
break;
case READ_ONLY_DIRECT_ACCESS_DEVICE:
printf(" CDROM Drive ");
break;
case SCANNER_DEVICE:
printf(" Scanner ");
break;
case OPTICAL_DEVICE:
printf(" Optical Drive ");
break;
case MEDIUM_CHANGER:
printf(" Changer ");
break;
case COMMUNICATION_DEVICE:
printf(" Comm. device ");
break;
}
printf("\n");
}
}
memcpy(&g_ident, ident, sizeof(IDENTIFY_DATA));
}
next_dev:
if (inquiryData->NextInquiryDataOffset == 0) {
break;
}
inquiryData = (PSCSI_INQUIRY_DATA) (g_inquiry_buffer +
inquiryData->NextInquiryDataOffset);
}
}
if(!found) {
printf(" No device(s) found.\n");
return FALSE;
}
return TRUE;
} // end ata_check_unit()
BOOLEAN
ata_adapter_info(
int bus_id,
int print_info
)
{
char dev_name[64];
HANDLE h;
PADAPTERINFO AdapterInfo;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
PCI_SLOT_NUMBER slotData;
char mode_str[12];
ULONG len;
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
addr.Length = sizeof(addr);
addr.PortNumber = bus_id;
len = sizeof(ADAPTERINFO)+sizeof(CHANINFO)*AHCI_MAX_PORT;
if(!g_AdapterInfo) {
AdapterInfo = (PADAPTERINFO)GlobalAlloc(GMEM_FIXED, len);
if(!AdapterInfo) {
ata_close_dev(h);
return FALSE;
}
} else {
AdapterInfo = g_AdapterInfo;
}
memset(AdapterInfo, 0, len);
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_ADAPTER_INFO,
AdapterInfo, len,
AdapterInfo, len,
&returned);
if(status) {
ata_mode_to_str(mode_str, AdapterInfo->MaxTransferMode);
}
printf("Scsi%d: %s %s\n", bus_id, status ? "[UniATA]" : "", status ? mode_str : "");
if(print_info) {
if(!status) {
printf("Can't get adapter info\n");
} else {
if(AdapterInfo->AdapterInterfaceType == PCIBus) {
slotData.u.AsULONG = AdapterInfo->slotNumber;
printf(" PCI Bus/Dev/Func: %lu/%lu/%lu%s\n",
AdapterInfo->SystemIoBusNumber, slotData.u.bits.DeviceNumber, slotData.u.bits.FunctionNumber,
AdapterInfo->AdapterInterfaceType == AdapterInfo->OrigAdapterInterfaceType ? "" : " (ISA-Bridged)");
printf(" VendorId/DevId/Rev: %#04x/%#04x/%#02x\n",
(USHORT)(AdapterInfo->DevID >> 16),
(USHORT)(AdapterInfo->DevID & 0xffff),
(UCHAR)(AdapterInfo->RevID));
if(AdapterInfo->DeviceName[0]) {
printf(" Name: %s\n", AdapterInfo->DeviceName);
}
} else
if(AdapterInfo->AdapterInterfaceType == Isa) {
printf(" ISA Bus\n");
}
printf(" IRQ: %ld\n", AdapterInfo->BusInterruptLevel);
}
}
ata_close_dev(h);
//GlobalFree(AdapterInfo);
g_AdapterInfo = AdapterInfo;
return status ? TRUE : FALSE;
} // end ata_adapter_info()
int
ata_check_controller(
HANDLE h, // handle to ScsiXXX:
PIO_SCSI_CAPABILITIES capabilities
)
{
ULONG status;
ULONG returned;
status = DeviceIoControl(h,
IOCTL_SCSI_GET_CAPABILITIES,
NULL,
0,
capabilities,
sizeof(IO_SCSI_CAPABILITIES),
&returned,
FALSE);
return status;
} // end ata_check_controller()
BOOLEAN
ata_list(
int bus_id,
int dev_id
)
{
char dev_name[64];
HANDLE h;
//BOOLEAN uniata_driven;
if(bus_id == -1) {
for(bus_id=0; TRUE; bus_id++) {
if(!ata_list(bus_id, dev_id))
break;
}
return TRUE;
}
/*uniata_driven =*/ ata_adapter_info(bus_id, g_adapter_info);
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
if(dev_id == -1) {
ata_check_controller(h, &g_capabilities);
ata_check_unit(h, -1);
ata_close_dev(h);
return TRUE;
}
ata_check_unit(h, dev_id | (bus_id << 24));
ata_close_dev(h);
return TRUE;
} // end ata_list()
BOOLEAN
ata_mode(
int bus_id,
int dev_id,
int mode
)
{
char dev_name[64];
HANDLE h;
SETTRANSFERMODE IoMode;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
if(dev_id == -1) {
return FALSE;
}
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
addr.Length = sizeof(addr);
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = (UCHAR)(dev_id >> 8);
addr.Lun = (UCHAR)(dev_id);
IoMode.MaxMode = mode;
IoMode.ApplyImmediately = FALSE;
// IoMode.ApplyImmediately = TRUE;
IoMode.OrigMode = mode;
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_SET_MAX_MODE,
&IoMode, sizeof(IoMode),
NULL, 0,
&returned);
if(!status) {
printf("Can't apply specified transfer mode\n");
} else {
ata_mode_to_str(dev_name, mode);
printf("Transfer rate switched to %s\n", dev_name);
}
ata_close_dev(h);
return status ? TRUE : FALSE;
} // end ata_mode()
BOOLEAN
ata_reset(
int bus_id,
int dev_id
)
{
char dev_name[64];
HANDLE h;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
if(dev_id == -1) {
return FALSE;
}
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
addr.Length = sizeof(addr);
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = (UCHAR)(dev_id >> 8);
addr.Lun = (UCHAR)(dev_id);
if(addr.TargetId == 0x7f && addr.Lun == 0x7f) {
addr.TargetId = (UCHAR)0xff;
addr.Lun = 0;
printf("Resetting channel...\n");
} else {
printf("Resetting device...\n");
}
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_RESET_DEVICE,
NULL, 0,
NULL, 0,
&returned);
if(!status) {
printf("Reset failed\n");
} else {
printf("Channel reset done\n");
}
ata_close_dev(h);
return TRUE;
} // end ata_reset()
BOOLEAN
ata_hide(
int bus_id,
int dev_id,
int lock,
int persistent_hide,
int power_mode
)
{
char dev_name[64];
HANDLE h;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
ADDREMOVEDEV to;
if(dev_id == -1) {
return FALSE;
}
if(power_mode) {
ata_power_mode(bus_id, dev_id, power_mode);
}
if(lock < 0) {
lock = DEFAULT_REMOVAL_LOCK_TIMEOUT;
}
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
addr.Length = sizeof(addr);
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = (UCHAR)(dev_id >> 8);
addr.Lun = (UCHAR)(dev_id);
to.WaitForPhysicalLink = lock;
to.Flags = persistent_hide ? UNIATA_REMOVE_FLAGS_HIDE : 0;
printf("Deleting device.\n");
if(lock) {
printf("ATTENTION: you have %d seconds to disconnect cable\n", lock);
}
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_DELETE_DEVICE,
&to, sizeof(to),
NULL, 0,
&returned);
if(!status) {
printf("Delete failed\n");
} else {
printf("Device is detached\n");
}
ata_close_dev(h);
return status ? TRUE : FALSE;
} // end ata_hide()
BOOLEAN
ata_scan(
int bus_id,
int dev_id,
int lock,
int unhide
)
{
char dev_name[64];
HANDLE h;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
ADDREMOVEDEV to;
if(dev_id == -1) {
return FALSE;
}
if(lock < 0) {
lock = DEFAULT_REMOVAL_LOCK_TIMEOUT;
}
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
if((UCHAR)(dev_id) != 0xff &&
(UCHAR)(dev_id >> 8) != 0xff) {
addr.Length = sizeof(addr);
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = 0;
addr.Lun = 0;
to.WaitForPhysicalLink = lock;
to.Flags = unhide ? UNIATA_ADD_FLAGS_UNHIDE : 0;
printf("Scanning bus for new devices.\n");
if(lock) {
printf("You have %d seconds to connect device.\n", lock);
}
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_FIND_DEVICES,
&to, sizeof(to),
NULL, 0,
&returned);
} else {
status = DeviceIoControl(h,
IOCTL_SCSI_RESCAN_BUS,
NULL, 0,
NULL, 0,
&returned,
FALSE);
}
ata_close_dev(h);
return status ? TRUE : FALSE;
} // end ata_scan()
CHAR*
_fgets(
CHAR *string,
int count,
HANDLE stream
)
{
CHAR *pointer = string;
ULONG read_bytes;
CHAR *retval = string;
int ch = 0;
if (count <= 0)
return(NULL);
while (--count)
{
if(!ReadFile(stream, &ch, 1, &read_bytes, NULL) ||
!read_bytes)
{
if (pointer == string) {
retval=NULL;
goto done;
}
break;
}
if ((*pointer++ = (CHAR)ch) == '\n') {
break;
}
}
*pointer = '\0';
/* Common return */
done:
return(retval);
} // end _fgets()
BOOLEAN
ata_bblk(
int bus_id,
int dev_id,
int list_bb
)
{
char dev_name[64];
char tmp[64];
char DevSerial[128];
HANDLE h = NULL;
HANDLE hf = NULL;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
ULONG len;
ULONG Length;
BOOLEAN retval = FALSE;
HKEY hKey2 = NULL;
char* bblist = NULL;
LONGLONG tmp_bb_lba;
LONGLONG tmp_bb_len;
char BB_Msg[256];
int radix=gRadix;
int i, j;
ULONG b;
if(dev_id == -1) {
printf("\nERROR: Target device/bus ID must be specified\n\n");
print_help();
return FALSE;
}
if(((dev_id >> 16) & 0xff) == 0xff) {
printf("\nERROR: Target device bus number (channel) must be specified with b:<bus id>\n\n");
print_help();
return FALSE;
}
if(((dev_id >> 8) & 0xff) == 0xff) {
printf("\nERROR: Target device ID must be specified with d:<device id>\n\n");
print_help();
return FALSE;
}
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h) {
if(bus_id == -1) {
printf("Controller number must be specified\n");
} else {
printf("Can't open Controller %d\n", bus_id);
}
return FALSE;
}
if(list_bb == 0) {
hf = ata_open_file(g_bb_list, FALSE);
if(!hf) {
printf("Can't open bad block list file:\n %s\n", g_bb_list);
ata_close_dev(h);
return FALSE;
}
len = GetFileSize(hf, NULL);
if(!len || len == INVALID_FILE_SIZE)
goto exit;
bblist = (char*)GlobalAlloc(GMEM_FIXED, len*8);
}
if(!ata_check_unit(h, dev_id | (bus_id << 24))) {
goto exit;
}
hKey2 = ata_get_bblist_regh(&g_ident, DevSerial, list_bb==1);
if(!hKey2) {
printf("Can't open registry key:\n HKLM\\SYSTEM\\CurrentControlSet\\Services\\UniATA\\Parameters\\BadBlocks\n");
goto exit;
}
if(list_bb == -1) {
if(RegDeleteValue(hKey2, DevSerial) != ERROR_SUCCESS) {
printf("Can't delete registry value:\n %s\n", DevSerial);
goto exit;
}
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = (UCHAR)(dev_id >> 8);
addr.Lun = (UCHAR)(dev_id);
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_RESETBB,
NULL, 0,
NULL, 0,
&returned);
if(!status) {
printf("Bad block list shall be cleared after reboot.\n");
} else {
printf("Bad block list cleared\n");
}
} else
if(list_bb == 0) {
LONGLONG* pData = ((LONGLONG*)bblist);
char a;
int k, k0;
Length=0;
i=0;
j=0;
k=0;
while(_fgets(BB_Msg, sizeof(BB_Msg), hf)) {
j++;
BB_Msg[sizeof(BB_Msg)-1] = 0;
k=0;
while((a = BB_Msg[k])) {
if(a == ' ' || a == '\t' || a == '\r') {
k++;
continue;
}
break;
}
if(!a || a == ';' || a == '#') {
continue;
}
if(!strncmp(BB_Msg+k, "hex:", 4)) {
radix=16;
continue;
}
if(!strncmp(BB_Msg+k, "dec:", 4)) {
radix=10;
continue;
}
k0 = k;
while((a = BB_Msg[k])) {
if(a == ' ' || a == '\t' || a == '\r') {
BB_Msg[k] = '\t';
}
k++;
if(a == ';' || a == '#') {
break;
}
if(a >= '0' && a <= '9') {
continue;
}
if(radix == 16 && ((a >= 'A' && a <= 'F') || (a >= 'a' && a <= 'f'))) {
continue;
}
printf("Bad input BB list file:\n %s\n", g_bb_list);
printf("Illegal character '%1.1s' in line %d:\n%s\n", BB_Msg+k-1, j, BB_Msg);
k0=-1;
break;
}
if(k0 == -1) {
continue;
}
k = k0;
if(radix == 10) {
b = sscanf(BB_Msg+k, "%I64u\t%I64u", &tmp_bb_lba, &tmp_bb_len);
} else {
b = sscanf(BB_Msg+k, "%I64x\t%I64x", &tmp_bb_lba, &tmp_bb_len);
}
if(b == 1) {
tmp_bb_len = 1;
} else
if(b != 2) {
printf("Bad input BB list file:\n %s\n", g_bb_list);
printf("Can't parse line %d:\n%s\n", j, BB_Msg);
continue;
}
if(!tmp_bb_len) {
printf("Bad input BB list file:\n %s\n", g_bb_list);
printf("BlockCount evaluated to 0 in line %d:\n%s\n", j, BB_Msg);
continue;
}
if(tmp_bb_lba < 0) {
printf("Bad input BB list file:\n %s\n", g_bb_list);
printf("Start LBA evaluated to negative in line %d:\n%s\n", j, BB_Msg);
continue;
}
if(tmp_bb_len < 0) {
printf("Bad input BB list file:\n %s\n", g_bb_list);
printf("BlockCount evaluated to negative in line %d:\n%s\n", j, BB_Msg);
continue;
}
if(i &&
(pData[(i-1)*2+1] == tmp_bb_lba)) {
pData[(i-1)*2+1]+=tmp_bb_len;
} else {
pData[i*2+0]=tmp_bb_lba;
pData[i*2+1]=tmp_bb_lba+tmp_bb_len;
i++;
Length += sizeof(LONGLONG)*2;
}
}
if(RegSetValueEx(hKey2, DevSerial, NULL, REG_BINARY, (const UCHAR*)bblist, Length) != ERROR_SUCCESS) {
printf("Can't set registry value:\n %s\n", DevSerial);
goto exit;
}
/*
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = (UCHAR)(dev_id >> 8);
addr.Lun = (UCHAR)(dev_id);
status = ata_send_ioctl(h, &addr, "-UNIATA-",
IOCTL_SCSI_MINIPORT_UNIATA_SETBB,
NULL, 0,
NULL, 0,
&returned);
*/
printf("Bad block list shall be applied after reboot\n");
} else {
len = 0;
returned = RegQueryValueEx(hKey2, DevSerial, NULL, NULL, NULL, &len);
if(returned == 2) {
printf("No bad block list assigned\n");
goto exit;
} else
if(returned != ERROR_SUCCESS) {
printf("Can't get registry value:\n %s\n", DevSerial);
goto exit;
}
hf = ata_open_file(g_bb_list, TRUE);
if(!hf) {
printf("Can't create bad block list file:\n %s\n", g_bb_list);
goto exit;
}
bblist = (char*)GlobalAlloc(GMEM_FIXED, len);
if(RegQueryValueEx(hKey2, DevSerial, NULL, NULL, (UCHAR*)bblist, &len) != ERROR_SUCCESS) {
printf("Can't get registry value:\n %s\n", DevSerial);
goto exit;
}
if(g_bb_list) {
for (j = 0; j < 20; j += 2) {
MOV_DW_SWP(tmp[j], ((PUCHAR)(&g_ident.ModelNumber))[j]);
}
b = sprintf(BB_Msg, "#model: %20.20s\n", tmp);
WriteFile(hf, BB_Msg, b, &returned, NULL);
for (j = 0; j < 4; j += 2) {
MOV_DW_SWP(tmp[j], ((PUCHAR)(&g_ident.FirmwareRevision))[j]);
}
b = sprintf(BB_Msg, "#rev: %4.4s\n", tmp);
WriteFile(hf, BB_Msg, b, &returned, NULL);
for (j = 0; j < 20; j += 2) {
MOV_DW_SWP(tmp[j], ((PUCHAR)(&g_ident.SerialNumber))[j]);
}
b = sprintf(BB_Msg, "#s/n: %20.20s\n", tmp);
WriteFile(hf, BB_Msg, b, &returned, NULL);
b = sprintf(BB_Msg, "#%s\n", DevSerial);
WriteFile(hf, BB_Msg, b, &returned, NULL);
b = sprintf(BB_Msg, "#Starting LBA\tNum. of Blocks\n");
WriteFile(hf, BB_Msg, b, &returned, NULL);
b = sprintf(BB_Msg, "hex:\n");
WriteFile(hf, BB_Msg, b, &returned, NULL);
} else {
b = sprintf(BB_Msg, "Starting LBA\tNum. of Blocks (HEX)\n");
WriteFile(hf, BB_Msg, b, &returned, NULL);
}
i = 0;
while(len >= sizeof(LONGLONG)*2) {
tmp_bb_lba = ((LONGLONG*)bblist)[i*2+0];
tmp_bb_len = ((LONGLONG*)bblist)[i*2+1] - tmp_bb_lba;
b = sprintf(BB_Msg, "%I64u\t%I64u\n", tmp_bb_lba, tmp_bb_len);
WriteFile(hf, BB_Msg, b, &returned, NULL);
i++;
len -= sizeof(LONGLONG)*2;
}
}
retval = TRUE;
exit:
if(hKey2)
RegCloseKey(hKey2);
if(bblist) {
GlobalFree(bblist);
}
ata_close_dev(hf);
ata_close_dev(h);
return retval;
} // end ata_bblk()
BOOLEAN
ata_power_mode(
int bus_id,
int dev_id,
int power_mode
)
{
char dev_name[64];
HANDLE h;
ULONG status;
ULONG returned;
SCSI_ADDRESS addr;
CDB cdb;
SENSE_DATA senseData;
if(dev_id == -1) {
return FALSE;
}
if(!power_mode) {
return TRUE;
}
sprintf(dev_name, "\\\\.\\Scsi%d:", bus_id);
h = ata_open_dev(dev_name);
if(!h)
return FALSE;
addr.PortNumber = bus_id;
addr.PathId = (UCHAR)(dev_id >> 16);
addr.TargetId = (UCHAR)(dev_id >> 8);
addr.Lun = (UCHAR)(dev_id);
memset(&cdb, 0, sizeof(cdb));
cdb.START_STOP.OperationCode = SCSIOP_START_STOP_UNIT;
cdb.START_STOP.Immediate = 1;
cdb.START_STOP.PowerConditions = power_mode;
cdb.START_STOP.Start = (power_mode != StartStop_Power_Sleep);
printf("Changing power state to ...\n");
status = ata_send_scsi(h, &addr, &cdb, 6,
NULL, 0, FALSE,
&senseData, &returned);
ata_close_dev(h);
return status ? TRUE : FALSE;
} // end ata_power_mode()
int
ata_num_to_x_dev(
char a
)
{
if(a >= '0' && a <= '9')
return a-'0';
return -1;
}
int
main (
int argc,
char* argv[]
)
{
//ULONG Flags = 0;
intptr_t i;
uintptr_t j;
char a;
int bus_id = -1;
int dev_id = -1;
int cmd = 0;
int lock = -1;
int b_dev=-1, d_dev=-1, l_dev=0;
int mode=-1;
int list_bb=0;
int persistent_hide=0;
int power_mode=StartStop_Power_NoChg;
printf("Console ATA control utility for Windows NT3.51/NT4/2000/XP/2003\n"
"Version 0." UNIATA_VER_STR ", Copyright (c) Alexander A. Telyatnikov, 2003-2012\n"
"Home site: http://alter.org.ua\n");
for(i=1; i<argc; i++) {
if(!argv[i])
continue;
if((a = argv[i][0]) != '-') {
for(j=0; (a = argv[i][j]); j++) {
switch(a) {
case 'a' :
case 's' :
case 'c' :
j++;
bus_id = ata_num_to_x_dev(argv[i][j]);
break;
case 'b' :
j++;
b_dev = ata_num_to_x_dev(argv[i][j]);
break;
case 'd' :
j++;
d_dev = ata_num_to_x_dev(argv[i][j]);
break;
case 'l' :
j++;
l_dev = ata_num_to_x_dev(argv[i][j]);
break;
case ':' :
break;
default:
print_help();
}
}
continue;
}
j=1;
while(argv[i] && (a = argv[i][j]) && (a != ' ') && (a != '\t')) {
switch(a) {
case 'l' :
if(cmd || lock>0) {
print_help();
}
cmd = CMD_ATA_LIST;
break;
case 'x' :
g_extended = 1;
break;
case 'a' :
g_adapter_info = 1;
break;
case 'S' :
persistent_hide = 1;
case 's' :
if(cmd || lock>0) {
print_help();
}
cmd = CMD_ATA_FIND;
d_dev = 0;
break;
case 'H' :
persistent_hide = 1;
case 'h' :
if(cmd) {
print_help();
}
cmd = CMD_ATA_HIDE;
d_dev = 0;
break;
case 'm' :
if(cmd) {
print_help();
}
cmd = CMD_ATA_MODE;
i++;
if(!argv[i]) {
print_help();
}
mode = ata_str_to_mode(argv[i]);
if(mode == -1) {
i--;
} else {
j = strlen(argv[i])-1;
}
break;
case 'r' :
if(cmd) {
print_help();
}
cmd = CMD_ATA_RESET;
break;
case 'b' :
if(cmd) {
print_help();
}
switch(argv[i][j+1]) {
case 'l':
list_bb = 1;
break;
case 'a':
list_bb = 0;
break;
case 'r':
list_bb = -1;
break;
default:
j--;
}
j++;
cmd = CMD_ATA_BBLK;
break;
case 'f' :
if(cmd != CMD_ATA_BBLK) {
print_help();
}
i++;
if(!argv[i]) {
print_help();
}
g_bb_list=argv[i];
j = strlen(argv[i])-1;
break;
case 'p' :
if(cmd && (cmd != CMD_ATA_FIND) && (cmd != CMD_ATA_HIDE)) {
print_help();
}
switch(argv[i][j+1]) {
case '0':
case 'a':
// do nothing
break;
case '1':
case 'i':
power_mode = StartStop_Power_Idle;
break;
case '2':
case 's':
power_mode = StartStop_Power_Standby;
break;
case '3':
case 'p':
power_mode = StartStop_Power_Sleep;
break;
default:
j--;
}
j++;
if(power_mode && !cmd) {
cmd = CMD_ATA_POWER;
}
break;
case 'D' :
power_mode = StartStop_Power_Sleep;
if(cmd && (cmd != CMD_ATA_HIDE)) {
print_help();
}
case 'd' :
if(cmd && (cmd != CMD_ATA_FIND) && (cmd != CMD_ATA_HIDE) && (cmd != CMD_ATA_POWER)) {
print_help();
}
if(!cmd) {
cmd = CMD_ATA_HIDE;
}
i++;
if(!argv[i]) {
print_help();
}
if(!sscanf(argv[i], "%d", &lock)) {
lock = DEFAULT_REMOVAL_LOCK_TIMEOUT;
i--;
}
j = strlen(argv[i])-1;
break;
case 'n' :
if(cmd != CMD_ATA_BBLK) {
print_help();
}
i++;
if(!argv[i]) {
print_help();
}
if(!strcmp(argv[i], "hex") ||
!strcmp(argv[i], "16")) {
gRadix = 16;
} else
if(!strcmp(argv[i], "dec") ||
!strcmp(argv[i], "10")) {
gRadix = 10;
} else {
print_help();
}
j = strlen(argv[i])-1;
break;
case '?' :
default:
print_help();
}
j++;
}
}
if(g_adapter_info && !cmd) {
cmd = CMD_ATA_LIST;
b_dev = 127;
d_dev = 127;
l_dev = 127;
} else
if((d_dev == -1) && (b_dev != -1)) {
d_dev = 127;
l_dev = 127;
}
if((d_dev != -1) && (b_dev != -1)) {
dev_id = (b_dev << 16) | (d_dev << 8) | l_dev;
}
if(cmd == CMD_ATA_LIST) {
ata_list(bus_id, dev_id);
} else
if(cmd == CMD_ATA_MODE) {
ata_mode(bus_id, dev_id, mode);
} else
if(cmd == CMD_ATA_RESET) {
ata_reset(bus_id, dev_id);
} else
if(cmd == CMD_ATA_FIND) {
ata_scan(bus_id, dev_id, lock, persistent_hide);
} else
if(cmd == CMD_ATA_HIDE) {
ata_hide(bus_id, dev_id, lock, persistent_hide, power_mode);
} else
if(cmd == CMD_ATA_BBLK) {
ata_bblk(bus_id, dev_id, list_bb);
} else
if(cmd == CMD_ATA_POWER) {
ata_power_mode(bus_id, dev_id, power_mode);
} else {
print_help();
}
exit(0);
}