1
1
Fork 0
mirror of https://github.com/pbatard/rufus.git synced 2024-08-14 23:57:05 +00:00
rufus/src/smart.c

501 lines
17 KiB
C
Raw Normal View History

/*
* Rufus: The Reliable USB Formatting Utility
* SMART HDD vs Flash detection (using ATA over USB, S.M.A.R.T., etc.)
* Copyright © 2013-2020 Pete Batard <pete@akeo.ie>
*
* Based in part on scsiata.cpp from Smartmontools: http://smartmontools.sourceforge.net
* Copyright © 2006-2012 Douglas Gilbert <dgilbert@interlog.com>
* Copyright © 2009-2013 Christian Franke <smartmontools-support@lists.sourceforge.net>
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifdef _CRTDBG_MAP_ALLOC
#include <stdlib.h>
#include <crtdbg.h>
#endif
#include <windows.h>
#include <stdio.h>
#include <string.h>
#include <ctype.h>
#include <stddef.h>
#include "rufus.h"
#include "missing.h"
#include "msapi_utf8.h"
#include "drive.h"
#include "smart.h"
#include "hdd_vs_ufd.h"
#if defined(RUFUS_TEST)
/* Helper functions */
static uint8_t GetAtaDirection(uint8_t AtaCmd, uint8_t Features) {
// Far from complete -- only the commands we *may* use.
// Most SMART commands require DATA_IN but there are a couple exceptions
BOOL smart_out = (AtaCmd == ATA_SMART_CMD) &&
((Features == ATA_SMART_STATUS) || (Features == ATA_SMART_WRITE_LOG_SECTOR));
switch (AtaCmd) {
case ATA_IDENTIFY_DEVICE:
case ATA_READ_LOG_EXT:
return ATA_PASSTHROUGH_DATA_IN;
case ATA_SMART_CMD:
if (!smart_out)
return ATA_PASSTHROUGH_DATA_IN;
// fall through
case ATA_DATA_SET_MANAGEMENT:
return ATA_PASSTHROUGH_DATA_OUT;
default:
return ATA_PASSTHROUGH_DATA_NONE;
}
}
const char* SptStrerr(int errcode)
{
static char scsi_err[64];
if ((errcode > 0) && (errcode <= 0xff)) {
static_sprintf(scsi_err, "SCSI status: 0x%02X", (uint8_t)errcode);
return (const char*)scsi_err;
}
switch(errcode) {
case SPT_SUCCESS:
return "Success";
case SPT_ERROR_CDB_LENGTH:
return "Invalid CDB length";
case SPT_ERROR_BUFFER:
return "Buffer must be aligned to a page boundary and less than 64KB in size";
case SPT_ERROR_DIRECTION:
return "Invalid Direction";
case SPT_ERROR_EXTENDED_CDB:
return "Extended and variable length CDB commands are not supported";
case SPT_ERROR_CDB_OPCODE:
return "Opcodes above 0xC0 are not supported";
case SPT_ERROR_TIMEOUT:
return "Timeout";
case SPT_ERROR_INVALID_PARAMETER:
return "Invalid DeviceIoControl parameter";
case SPT_ERROR_CHECK_STATUS:
return "SCSI error (check Status)";
default:
return "Unknown error";
}
}
/*
* SCSI Passthrough (using IOCTL_SCSI_PASS_THROUGH_DIRECT)
* Should be provided a handle to the physical device (R/W) as well as a Cdb and a buffer that is page aligned
* Direction should be one of SCSI_IOCTL_DATA_###
*
* Returns 0 (SPT_SUCCESS) on success, a positive SCSI Status in case of an SCSI error or negative otherwise.
*/
BOOL ScsiPassthroughDirect(HANDLE hPhysical, uint8_t* Cdb, size_t CdbLen, uint8_t Direction,
void* DataBuffer, size_t BufLen, uint32_t Timeout)
{
SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER sptdwb = {{0}, 0, {0}};
DWORD err, size = sizeof(SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER);
BOOL r;
// Sanity checks
if ((CdbLen == 0) || (CdbLen > sizeof(sptdwb.sptd.Cdb)))
return SPT_ERROR_CDB_LENGTH;
if (((uintptr_t)DataBuffer % 0x10 != 0) || (BufLen > 0xFFFF))
return SPT_ERROR_BUFFER;
if (Direction > SCSI_IOCTL_DATA_UNSPECIFIED)
return SPT_ERROR_DIRECTION;
// http://en.wikipedia.org/wiki/SCSI_command
if ((Cdb[0] == 0x7e) || (Cdb[0] == 0x7f))
return SPT_ERROR_EXTENDED_CDB;
// Opcodes above 0xC0 are unsupported (apart for the special JMicron/Sunplus modes)
if ( (Cdb[0] >= 0xc0) && (Cdb[0] != USB_JMICRON_ATA_PASSTHROUGH)
&& (Cdb[0] != USB_SUNPLUS_ATA_PASSTHROUGH) )
return SPT_ERROR_CDB_OPCODE;
sptdwb.sptd.Length = sizeof(SCSI_PASS_THROUGH_DIRECT);
sptdwb.sptd.PathId = 0;
sptdwb.sptd.TargetId = 0;
sptdwb.sptd.Lun = 0;
sptdwb.sptd.CdbLength = (uint8_t)CdbLen;
sptdwb.sptd.DataIn = Direction; // One of SCSI_IOCTL_DATA_###
sptdwb.sptd.SenseInfoLength = SPT_SENSE_LENGTH;
sptdwb.sptd.DataTransferLength = (uint16_t)BufLen;
sptdwb.sptd.TimeOutValue = Timeout;
sptdwb.sptd.DataBuffer = DataBuffer;
sptdwb.sptd.SenseInfoOffset = offsetof(SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER, SenseBuf);
memcpy(sptdwb.sptd.Cdb, Cdb, CdbLen);
r = DeviceIoControl(hPhysical, IOCTL_SCSI_PASS_THROUGH_DIRECT, &sptdwb, size, &sptdwb, size, &size, FALSE);
if ((r) && (sptdwb.sptd.ScsiStatus == 0)) {
return SPT_SUCCESS;
}
if (sptdwb.sptd.ScsiStatus != 0) {
// uprintf("ScsiPassthroughDirect: CDB command 0x%02X failed (SCSI status 0x%02X)\n", Cdb[0], sptdwb.sptd.ScsiStatus);
return (int)sptdwb.sptd.ScsiStatus;
} else {
err = GetLastError();
// uprintf("ScsiPassthroughDirect: CDB command 0x%02X failed %s\n", Cdb[0], WindowsErrorString()); SetLastError(err);
switch(err) {
case ERROR_SEM_TIMEOUT:
return SPT_ERROR_TIMEOUT;
case ERROR_INVALID_PARAMETER:
return SPT_ERROR_INVALID_PARAMETER;
default:
return SPT_ERROR_UNKNOWN_ERROR;
}
}
return FALSE;
}
/* See ftp://ftp.t10.org/t10/document.04/04-262r8.pdf, http://www.scsitoolbox.com/pdfs/UsingSAT.pdf,
* as well as http://nevar.pl/pliki/ATA8-ACS-3.pdf */
static int SatAtaPassthrough(HANDLE hPhysical, ATA_PASSTHROUGH_CMD* Command, void* DataBuffer, size_t BufLen, uint32_t Timeout)
{
uint8_t Cdb[12] = {0};
int extend = 0; /* For 48-bit ATA command (unused here) */
int ck_cond = 0; /* Set to 1 to read register(s) back */
int protocol = 3; /* Non-data */
int t_dir = 1; /* 0 -> to device, 1 -> from device */
int byte_block = 1; /* 0 -> bytes, 1 -> 512 byte blocks */
int t_length = 0; /* 0 -> no data transferred */
uint8_t Direction;
if (BufLen % SelectedDrive.SectorSize != 0) {
uprintf("SatAtaPassthrough: BufLen must be a multiple of <block size>\n");
return SPT_ERROR_BUFFER;
}
// Set data direction
Direction = GetAtaDirection(Command->AtaCmd, Command->Features);
if (BufLen != 0) {
switch (Direction) {
case ATA_PASSTHROUGH_DATA_NONE:
break;
case ATA_PASSTHROUGH_DATA_IN:
protocol = 4; // PIO data-in
t_length = 2; // The transfer length is specified in the sector_count field
break;
case ATA_PASSTHROUGH_DATA_OUT:
protocol = 5; // PIO data-out
t_length = 2; // The transfer length is specified in the sector_count field
t_dir = 0; // to device
break;
}
}
Cdb[0] = SAT_ATA_PASSTHROUGH_12;
Cdb[1] = (protocol << 1) | extend;
Cdb[2] = (ck_cond << 5) | (t_dir << 3) | (byte_block << 2) | t_length;
Cdb[3] = Command->Features;
Cdb[4] = (uint8_t)(BufLen >> SECTOR_SIZE_SHIFT_BIT);
Cdb[5] = Command->Lba_low;
Cdb[6] = Command->Lba_mid;
Cdb[7] = Command->Lba_high;
Cdb[8] = Command->Device; // (m_port == 0 ? 0xa0 : 0xb0); // Must be 0 for identify
Cdb[9] = Command->AtaCmd;
return ScsiPassthroughDirect(hPhysical, Cdb, sizeof(Cdb), Direction, DataBuffer, BufLen, Timeout);
}
/* The only differences between JMicron and Prolific are the extra 2 bytes for the CDB */
static int _UsbJMPLAtaPassthrough(HANDLE hPhysical, ATA_PASSTHROUGH_CMD* Command,
void* DataBuffer, size_t BufLen, uint32_t Timeout, BOOL prolific)
{
uint8_t Cdb[14] = {0};
uint8_t Direction;
Direction = GetAtaDirection(Command->AtaCmd, Command->Features);
Cdb[0] = USB_JMICRON_ATA_PASSTHROUGH;
Cdb[1] = ((BufLen != 0) && (Direction == ATA_PASSTHROUGH_DATA_OUT))?0x00:0x10;
Cdb[3] = (uint8_t)(BufLen >> 8);
Cdb[4] = (uint8_t)(BufLen);
Cdb[5] = Command->Features;
Cdb[6] = (uint8_t)(BufLen >> SECTOR_SIZE_SHIFT_BIT);
Cdb[7] = Command->Lba_low;
Cdb[8] = Command->Lba_mid;
Cdb[9] = Command->Lba_high;
Cdb[10] = Command->Device; // (m_port == 0 ? 0xa0 : 0xb0); // Must be 0 for identify
Cdb[11] = Command->AtaCmd;
// Prolific PL3507
Cdb[12] = 0x06;
Cdb[13] = 0x7b;
return ScsiPassthroughDirect(hPhysical, Cdb, sizeof(Cdb)-(prolific?2:0), Direction, DataBuffer, BufLen, Timeout);
}
static int UsbJmicronAtaPassthrough(HANDLE hPhysical, ATA_PASSTHROUGH_CMD* Command, void* DataBuffer, size_t BufLen, uint32_t Timeout)
{
return _UsbJMPLAtaPassthrough(hPhysical, Command, DataBuffer, BufLen, Timeout, FALSE);
}
/* UNTESTED!!! */
static int UsbProlificAtaPassthrough(HANDLE hPhysical, ATA_PASSTHROUGH_CMD* Command, void* DataBuffer, size_t BufLen, uint32_t Timeout)
{
return _UsbJMPLAtaPassthrough(hPhysical, Command, DataBuffer, BufLen, Timeout, TRUE);
}
/* UNTESTED!!! */
static int UsbSunPlusAtaPassthrough(HANDLE hPhysical, ATA_PASSTHROUGH_CMD* Command, void* DataBuffer, size_t BufLen, uint32_t Timeout)
{
uint8_t Cdb[12] = {0};
uint8_t Direction;
Direction = GetAtaDirection(Command->AtaCmd, Command->Features);
Cdb[0] = USB_SUNPLUS_ATA_PASSTHROUGH;
Cdb[2] = 0x22;
if (BufLen != 0) {
if (Direction == ATA_PASSTHROUGH_DATA_IN)
Cdb[3] = 0x10;
else if (Direction == ATA_PASSTHROUGH_DATA_OUT)
Cdb[3] = 0x11;
}
Cdb[4] = (uint8_t)(BufLen >> SECTOR_SIZE_SHIFT_BIT);
Cdb[5] = Command->Features;
Cdb[6] = (uint8_t)(BufLen >> SECTOR_SIZE_SHIFT_BIT);
Cdb[7] = Command->Lba_low;
Cdb[8] = Command->Lba_mid;
Cdb[9] = Command->Lba_high;
Cdb[10] = Command->Device | 0xa0;
Cdb[11] = Command->AtaCmd;
return ScsiPassthroughDirect(hPhysical, Cdb, sizeof(Cdb), Direction, DataBuffer, BufLen, Timeout);
}
/* UNTESTED!!! */
/* See: http://kernel.opensuse.org/cgit/kernel/tree/drivers/usb/storage/cypress_atacb.c */
static int UsbCypressAtaPassthrough(HANDLE hPhysical, ATA_PASSTHROUGH_CMD* Command, void* DataBuffer, size_t BufLen, uint32_t Timeout)
{
uint8_t Cdb[16] = {0};
uint8_t Direction;
Direction = GetAtaDirection(Command->AtaCmd, Command->Features);
Cdb[0] = USB_CYPRESS_ATA_PASSTHROUGH;
Cdb[1] = USB_CYPRESS_ATA_PASSTHROUGH;
if (Command->AtaCmd == ATA_IDENTIFY_DEVICE || Command->AtaCmd == ATA_IDENTIFY_PACKET_DEVICE)
Cdb[2] = (1<<7); // Set IdentifyPacketDevice
Cdb[3] = 0xff - (1<<0) - (1<<6); // Features, sector count, lba low, lba med, lba high
Cdb[4] = 1; // Units in blocks rather than bytes
Cdb[6] = Command->Features;
Cdb[7] = (uint8_t)(BufLen >> SECTOR_SIZE_SHIFT_BIT);
Cdb[8] = Command->Lba_low;
Cdb[9] = Command->Lba_mid;
Cdb[10] = Command->Lba_high;
Cdb[11] = Command->Device;
Cdb[12] = Command->AtaCmd;
return ScsiPassthroughDirect(hPhysical, Cdb, sizeof(Cdb), Direction, DataBuffer, BufLen, Timeout);
}
/* The various bridges we will try, in order */
AtaPassThroughType ata_pt[] = {
{ SatAtaPassthrough, "SAT" },
{ UsbJmicronAtaPassthrough, "JMicron" },
{ UsbProlificAtaPassthrough, "Prolific" },
{ UsbSunPlusAtaPassthrough, "SunPlus" },
{ UsbCypressAtaPassthrough, "Cypress" },
};
BOOL Identify(HANDLE hPhysical)
{
ATA_PASSTHROUGH_CMD Command = {0};
IDENTIFY_DEVICE_DATA* idd;
int i, r;
Command.AtaCmd = ATA_IDENTIFY_DEVICE;
// You'll get an error here if your compiler does not properly pack the IDENTIFY struct
COMPILE_TIME_ASSERT(sizeof(IDENTIFY_DEVICE_DATA) == 512);
idd = (IDENTIFY_DEVICE_DATA*)_mm_malloc(sizeof(IDENTIFY_DEVICE_DATA), 0x10);
if (idd == NULL)
return FALSE;
for (i=0; i<ARRAYSIZE(ata_pt); i++) {
r = ata_pt[i].fn(hPhysical, &Command, idd, sizeof(IDENTIFY_DEVICE_DATA), SPT_TIMEOUT_VALUE);
if (r == SPT_SUCCESS) {
uprintf("Success using %s\n", ata_pt[i].type);
if (idd->CommandSetSupport.SmartCommands) {
DumpBufferHex(idd, sizeof(IDENTIFY_DEVICE_DATA));
uprintf("SMART support detected!\n");
} else {
uprintf("No SMART support\n");
}
break;
}
uprintf("No joy with: %s (%s)\n", ata_pt[i].type, SptStrerr(r));
}
if (i >= ARRAYSIZE(ata_pt))
uprintf("NO ATA FOR YOU!\n");
_mm_free(idd);
return TRUE;
}
#endif
/* Generic SMART access. Kept for reference, as it doesn't work for USB to ATA/SATA bridges */
#if 0
#pragma pack(1)
typedef struct {
UCHAR bVersion;
UCHAR bRevision;
UCHAR bReserved;
UCHAR bIDEDeviceMap;
ULONG fCapabilities;
ULONG dwReserved[4];
} MY_GETVERSIONINPARAMS;
#pragma pack()
#ifndef SMART_GET_VERSION
#define SMART_GET_VERSION \
CTL_CODE(IOCTL_DISK_BASE, 0x0020, METHOD_BUFFERED, FILE_READ_ACCESS)
#endif
BOOL SmartGetVersion(HANDLE hdevice)
{
MY_GETVERSIONINPARAMS vers;
DWORD size = sizeof(MY_GETVERSIONINPARAMS);
BOOL r;
memset(&vers, 0, sizeof(vers));
r = DeviceIoControl(hdevice, SMART_GET_VERSION, NULL, 0, &vers, sizeof(vers), &size, NULL);
if ( (!r) || (size != sizeof(MY_GETVERSIONINPARAMS)) ) {
uprintf("SmartGetVersion failed: %s\n", r?"unexpected size":WindowsErrorString());
return FALSE;
}
uprintf("Smart Version: %d.%d, Caps = 0x%x, DeviceMap = 0x%02x\n",
vers.bVersion, vers.bRevision, (unsigned)vers.fCapabilities, vers.bIDEDeviceMap);
return vers.bIDEDeviceMap;
}
#endif
/*
* This attempts to detect whether a drive is an USB HDD or an USB Flash Drive (UFD).
* A positive score means that we think it's an USB HDD, zero or negative means that
* we think it's an UFD.
*
* This is done so that, if someone already has an USB HDD plugged in (say as a
* backup drive) and plugs an UFD we *try* to do what we can to avoid them formatting
* that drive by mistake.
* However, because there is no foolproof (let alone easy) way to differentiate UFDs
* from HDDs, thanks to every manufacturer, Microsoft, and their mothers, making it
* exceedingly troublesome to find what type of hardware we are actually accessing,
* you are expected to pay heed to the following:
*
* WARNING: NO PROMISE IS MADE ABOUT THIS ALGORITHM BEING ABLE TO CORRECTLY
* DIFFERENTIATE AN USB HDD FROM AN USB FLASH DRIVE. MOREOVER, YOU ARE REMINDED THAT
* THE LICENSE OF THIS APPLICATION MAKES NO PROMISE ABOUT AVOIDING DATA LOSS EITHER
* (PROVIDED "AS IS").
* THUS, IF DATA LOSS IS INCURRED DUE TO THIS, OR ANY OTHER PART OF THIS APPLICATION,
* NOT BEHAVING IN THE MANNER YOU EXPECTED, THE RESPONSIBILITY IS ENTIRELY ON YOU!
*
* What you have below, then, is our *current best guess* at differentiating UFDs
* from HDDs. But short of a crystal ball, this remains just a guess, which may be
* way off mark. Still, you are also reminded that Rufus does produce PROMINENT
* warnings before you format a drive, and also provides extensive info about the
* drive (from the tooltips and the log) => PAY ATTENTION TO THESE OR PAY THE PRICE!
*
* But let me just elaborate further on why differentiating UFDs from HDDs is not as
* 'simple' as it seems:
* - many USB flash drives manufacturer will present UFDs as non-removable, which used
* to be reserved for HDDs => we can't use that as differentiator.
* - some UFDs (SanDisk Extreme) have added S.M.A.R.T. support, which also used to be
* reserved for HDDs => can't use that either
* - even if S.M.A.R.T. was enough, not all USB->IDE or USB->SATA bridges support ATA
* passthrough, which is required S.M.A.R.T. data, and each manufacturer of an
* USB<->(S)ATA bridge seem to have their own method of implementing passthrough.
* - SSDs have also changed the deal completely, as you can get something that looks
* like Flash but that is really an HDD.
* - Some manufacturers (eg. verbatim) provide both USB Flash Drives and USB HDDs, so
* we can't exactly use the VID to say for sure what we're looking at.
* - Finally, Microsoft is absolutely no help either (which is kind of understandable
* from the above) => there is no magic API we can query that will tell us what we're
* really looking at.
*/
int IsHDD(DWORD DriveIndex, uint16_t vid, uint16_t pid, const char* strid)
{
int score = 0;
size_t i, mlen, ilen;
BOOL wc;
uint64_t drive_size;
// Boost the score if fixed, as these are *generally* HDDs
if (GetDriveTypeFromIndex(DriveIndex) == DRIVE_FIXED)
score += 3;
// Adjust the score depending on the size
drive_size = GetDriveSize(DriveIndex);
if (drive_size > 512*GB)
score += 10;
else if (drive_size < 8*GB)
score -= 10;
// Check the string against well known HDD identifiers
if (strid != NULL) {
ilen = strlen(strid);
for (i=0; i<ARRAYSIZE(str_score); i++) {
mlen = strlen(str_score[i].name);
if (mlen > ilen)
break;
wc = (str_score[i].name[mlen-1] == '#');
if ( (_strnicmp(strid, str_score[i].name, mlen-((wc)?1:0)) == 0)
&& ((!wc) || ((strid[mlen] >= '0') && (strid[mlen] <= '9'))) ) {
score += str_score[i].score;
break;
}
}
}
// Adjust for oddball devices
if (strid != NULL) {
for (i=0; i<ARRAYSIZE(str_adjust); i++)
if (strstr(strid, str_adjust[i].name) != NULL)
score += str_adjust[i].score;
}
// Check against known VIDs
for (i=0; i<ARRAYSIZE(vid_score); i++) {
if (vid == vid_score[i].vid) {
score += vid_score[i].score;
break;
}
}
// Check against known VID:PIDs
for (i=0; i<ARRAYSIZE(vidpid_score); i++) {
if ((vid == vidpid_score[i].vid) && (pid == vidpid_score[i].pid)) {
score += vidpid_score[i].score;
break;
}
}
duprintf(" Score: %d\n", score);
return score;
}