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gerrit-public.fairphone.software / fp2-dev / platform / external / busybox / 99a61842df559f0cfc8613436b3bf89f4e757abf / . / miscutils / hdparm.c
blob: 0aaff45f2ea908a1ad8952ecfcb6aecc99b40c6d [file] [log] [blame]
/* vi: set sw=4 ts=4: */
/*
* hdparm implementation for busybox
*
* Copyright (C) [2003] by [Matteo Croce] <3297627799@wind.it>
* Hacked by Tito <farmatito@tiscali.it> for size optimization.
*
* Licensed under the GPL v2 or later, see the file LICENSE in this tarball.
*
* This program is based on the source code of hdparm: see below...
* hdparm.c - Command line interface to get/set hard disk parameters
* - by Mark Lord (C) 1994-2002 -- freely distributable
*/
#include "libbb.h"
#include <linux/hdreg.h>
/* device types */
/* ------------ */
#define NO_DEV 0xffff
#define ATA_DEV 0x0000
#define ATAPI_DEV 0x0001
/* word definitions */
/* ---------------- */
#define GEN_CONFIG 0 /* general configuration */
#define LCYLS 1 /* number of logical cylinders */
#define CONFIG 2 /* specific configuration */
#define LHEADS 3 /* number of logical heads */
#define TRACK_BYTES 4 /* number of bytes/track (ATA-1) */
#define SECT_BYTES 5 /* number of bytes/sector (ATA-1) */
#define LSECTS 6 /* number of logical sectors/track */
#define START_SERIAL 10 /* ASCII serial number */
#define LENGTH_SERIAL 10 /* 10 words (20 bytes or characters) */
#define BUF_TYPE 20 /* buffer type (ATA-1) */
#define BUFFER__SIZE 21 /* buffer size (ATA-1) */
#define RW_LONG 22 /* extra bytes in R/W LONG cmd ( < ATA-4)*/
#define START_FW_REV 23 /* ASCII firmware revision */
#define LENGTH_FW_REV 4 /* 4 words (8 bytes or characters) */
#define START_MODEL 27 /* ASCII model number */
#define LENGTH_MODEL 20 /* 20 words (40 bytes or characters) */
#define SECTOR_XFER_MAX 47 /* r/w multiple: max sectors xfered */
#define DWORD_IO 48 /* can do double-word IO (ATA-1 only) */
#define CAPAB_0 49 /* capabilities */
#define CAPAB_1 50
#define PIO_MODE 51 /* max PIO mode supported (obsolete)*/
#define DMA_MODE 52 /* max Singleword DMA mode supported (obs)*/
#define WHATS_VALID 53 /* what fields are valid */
#define LCYLS_CUR 54 /* current logical cylinders */
#define LHEADS_CUR 55 /* current logical heads */
#define LSECTS_CUR 56 /* current logical sectors/track */
#define CAPACITY_LSB 57 /* current capacity in sectors */
#define CAPACITY_MSB 58
#define SECTOR_XFER_CUR 59 /* r/w multiple: current sectors xfered */
#define LBA_SECTS_LSB 60 /* LBA: total number of user */
#define LBA_SECTS_MSB 61 /* addressable sectors */
#define SINGLE_DMA 62 /* singleword DMA modes */
#define MULTI_DMA 63 /* multiword DMA modes */
#define ADV_PIO_MODES 64 /* advanced PIO modes supported */
/* multiword DMA xfer cycle time: */
#define DMA_TIME_MIN 65 /* - minimum */
#define DMA_TIME_NORM 66 /* - manufacturer's recommended */
/* minimum PIO xfer cycle time: */
#define PIO_NO_FLOW 67 /* - without flow control */
#define PIO_FLOW 68 /* - with IORDY flow control */
#define PKT_REL 71 /* typical #ns from PKT cmd to bus rel */
#define SVC_NBSY 72 /* typical #ns from SERVICE cmd to !BSY */
#define CDR_MAJOR 73 /* CD ROM: major version number */
#define CDR_MINOR 74 /* CD ROM: minor version number */
#define QUEUE_DEPTH 75 /* queue depth */
#define MAJOR 80 /* major version number */
#define MINOR 81 /* minor version number */
#define CMDS_SUPP_0 82 /* command/feature set(s) supported */
#define CMDS_SUPP_1 83
#define CMDS_SUPP_2 84
#define CMDS_EN_0 85 /* command/feature set(s) enabled */
#define CMDS_EN_1 86
#define CMDS_EN_2 87
#define ULTRA_DMA 88 /* ultra DMA modes */
/* time to complete security erase */
#define ERASE_TIME 89 /* - ordinary */
#define ENH_ERASE_TIME 90 /* - enhanced */
#define ADV_PWR 91 /* current advanced power management level
in low byte, 0x40 in high byte. */
#define PSWD_CODE 92 /* master password revision code */
#define HWRST_RSLT 93 /* hardware reset result */
#define ACOUSTIC 94 /* acoustic mgmt values ( >= ATA-6) */
#define LBA_LSB 100 /* LBA: maximum. Currently only 48 */
#define LBA_MID 101 /* bits are used, but addr 103 */
#define LBA_48_MSB 102 /* has been reserved for LBA in */
#define LBA_64_MSB 103 /* the future. */
#define RM_STAT 127 /* removable media status notification feature set support */
#define SECU_STATUS 128 /* security status */
#define CFA_PWR_MODE 160 /* CFA power mode 1 */
#define START_MEDIA 176 /* media serial number */
#define LENGTH_MEDIA 20 /* 20 words (40 bytes or characters)*/
#define START_MANUF 196 /* media manufacturer I.D. */
#define LENGTH_MANUF 10 /* 10 words (20 bytes or characters) */
#define INTEGRITY 255 /* integrity word */
/* bit definitions within the words */
/* -------------------------------- */
/* many words are considered valid if bit 15 is 0 and bit 14 is 1 */
#define VALID 0xc000
#define VALID_VAL 0x4000
/* many words are considered invalid if they are either all-0 or all-1 */
#define NOVAL_0 0x0000
#define NOVAL_1 0xffff
/* word 0: gen_config */
#define NOT_ATA 0x8000
#define NOT_ATAPI 0x4000 /* (check only if bit 15 == 1) */
#define MEDIA_REMOVABLE 0x0080
#define DRIVE_NOT_REMOVABLE 0x0040 /* bit obsoleted in ATA 6 */
#define INCOMPLETE 0x0004
#define CFA_SUPPORT_VAL 0x848a /* 848a=CFA feature set support */
#define DRQ_RESPONSE_TIME 0x0060
#define DRQ_3MS_VAL 0x0000
#define DRQ_INTR_VAL 0x0020
#define DRQ_50US_VAL 0x0040
#define PKT_SIZE_SUPPORTED 0x0003
#define PKT_SIZE_12_VAL 0x0000
#define PKT_SIZE_16_VAL 0x0001
#define EQPT_TYPE 0x1f00
#define SHIFT_EQPT 8
#define CDROM 0x0005
/* word 1: number of logical cylinders */
#define LCYLS_MAX 0x3fff /* maximum allowable value */
/* word 2: specific configuration
* (a) require SET FEATURES to spin-up
* (b) require spin-up to fully reply to IDENTIFY DEVICE
*/
#define STBY_NID_VAL 0x37c8 /* (a) and (b) */
#define STBY_ID_VAL 0x738c /* (a) and not (b) */
#define PWRD_NID_VAL 0x8c73 /* not (a) and (b) */
#define PWRD_ID_VAL 0xc837 /* not (a) and not (b) */
/* words 47 & 59: sector_xfer_max & sector_xfer_cur */
#define SECTOR_XFER 0x00ff /* sectors xfered on r/w multiple cmds*/
#define MULTIPLE_SETTING_VALID 0x0100 /* 1=multiple sector setting is valid */
/* word 49: capabilities 0 */
#define STD_STBY 0x2000 /* 1=standard values supported (ATA); 0=vendor specific values */
#define IORDY_SUP 0x0800 /* 1=support; 0=may be supported */
#define IORDY_OFF 0x0400 /* 1=may be disabled */
#define LBA_SUP 0x0200 /* 1=Logical Block Address support */
#define DMA_SUP 0x0100 /* 1=Direct Memory Access support */
#define DMA_IL_SUP 0x8000 /* 1=interleaved DMA support (ATAPI) */
#define CMD_Q_SUP 0x4000 /* 1=command queuing support (ATAPI) */
#define OVLP_SUP 0x2000 /* 1=overlap operation support (ATAPI) */
#define SWRST_REQ 0x1000 /* 1=ATA SW reset required (ATAPI, obsolete */
/* word 50: capabilities 1 */
#define MIN_STANDBY_TIMER 0x0001 /* 1=device specific standby timer value minimum */
/* words 51 & 52: PIO & DMA cycle times */
#define MODE 0xff00 /* the mode is in the MSBs */
/* word 53: whats_valid */
#define OK_W88 0x0004 /* the ultra_dma info is valid */
#define OK_W64_70 0x0002 /* see above for word descriptions */
#define OK_W54_58 0x0001 /* current cyl, head, sector, cap. info valid */
/*word 63,88: dma_mode, ultra_dma_mode*/
#define MODE_MAX 7 /* bit definitions force udma <=7 (when
* udma >=8 comes out it'll have to be
* defined in a new dma_mode word!) */
/* word 64: PIO transfer modes */
#define PIO_SUP 0x00ff /* only bits 0 & 1 are used so far, */
#define PIO_MODE_MAX 8 /* but all 8 bits are defined */
/* word 75: queue_depth */
#define DEPTH_BITS 0x001f /* bits used for queue depth */
/* words 80-81: version numbers */
/* NOVAL_0 or NOVAL_1 means device does not report version */
/* word 81: minor version number */
#define MINOR_MAX 0x22
/* words 82-84: cmds/feats supported */
#define CMDS_W82 0x77ff /* word 82: defined command locations*/
#define CMDS_W83 0x3fff /* word 83: defined command locations*/
#define CMDS_W84 0x002f /* word 83: defined command locations*/
#define SUPPORT_48_BIT 0x0400
#define NUM_CMD_FEAT_STR 48
/* words 85-87: cmds/feats enabled */
/* use cmd_feat_str[] to display what commands and features have
* been enabled with words 85-87
*/
/* words 89, 90, SECU ERASE TIME */
#define ERASE_BITS 0x00ff
/* word 92: master password revision */
/* NOVAL_0 or NOVAL_1 means no support for master password revision */
/* word 93: hw reset result */
#define CBLID 0x2000 /* CBLID status */
#define RST0 0x0001 /* 1=reset to device #0 */
#define DEV_DET 0x0006 /* how device num determined */
#define JUMPER_VAL 0x0002 /* device num determined by jumper */
#define CSEL_VAL 0x0004 /* device num determined by CSEL_VAL */
/* word 127: removable media status notification feature set support */
#define RM_STAT_BITS 0x0003
#define RM_STAT_SUP 0x0001
/* word 128: security */
#define SECU_ENABLED 0x0002
#define SECU_LEVEL 0x0010
#define NUM_SECU_STR 6
/* word 160: CFA power mode */
#define VALID_W160 0x8000 /* 1=word valid */
#define PWR_MODE_REQ 0x2000 /* 1=CFA power mode req'd by some cmds*/
#define PWR_MODE_OFF 0x1000 /* 1=CFA power moded disabled */
#define MAX_AMPS 0x0fff /* value = max current in ma */
/* word 255: integrity */
#define SIG 0x00ff /* signature location */
#define SIG_VAL 0x00a5 /* signature value */
#define TIMING_BUF_MB 1
#define TIMING_BUF_BYTES (TIMING_BUF_MB * 1024 * 1024)
#undef DO_FLUSHCACHE /* under construction: force cache flush on -W0 */
enum { fd = 3 };
struct globals {
smallint get_identity, get_geom;
smallint do_flush;
smallint do_ctimings, do_timings;
smallint reread_partn;
smallint set_piomode, noisy_piomode;
smallint set_readahead, get_readahead;
smallint set_readonly, get_readonly;
smallint set_unmask, get_unmask;
smallint set_mult, get_mult;
smallint set_dma_q, get_dma_q;
smallint set_nowerr, get_nowerr;
smallint set_keep, get_keep;
smallint set_io32bit, get_io32bit;
int piomode;
unsigned long Xreadahead;
unsigned long readonly;
unsigned long unmask;
unsigned long mult;
unsigned long dma_q;
unsigned long nowerr;
unsigned long keep;
unsigned long io32bit;
#if ENABLE_FEATURE_HDPARM_HDIO_GETSET_DMA
unsigned long dma;
smallint set_dma, get_dma;
#endif
#ifdef HDIO_DRIVE_CMD
smallint set_xfermode, get_xfermode;
smallint set_dkeep, get_dkeep;
smallint set_standby, get_standby;
smallint set_lookahead, get_lookahead;
smallint set_prefetch, get_prefetch;
smallint set_defects, get_defects;
smallint set_wcache, get_wcache;
smallint set_doorlock, get_doorlock;
smallint set_seagate, get_seagate;
smallint set_standbynow, get_standbynow;
smallint set_sleepnow, get_sleepnow;
smallint get_powermode;
smallint set_apmmode, get_apmmode;
int xfermode_requested;
unsigned long dkeep;
unsigned long standby_requested;
unsigned long lookahead;
unsigned long prefetch;
unsigned long defects;
unsigned long wcache;
unsigned long doorlock;
unsigned long apmmode;
#endif
USE_FEATURE_HDPARM_GET_IDENTITY( smallint get_IDentity;)
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( smallint set_busstate, get_busstate;)
USE_FEATURE_HDPARM_HDIO_DRIVE_RESET( smallint perform_reset;)
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( smallint perform_tristate;)
USE_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF(smallint unregister_hwif;)
USE_FEATURE_HDPARM_HDIO_SCAN_HWIF( smallint scan_hwif;)
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( unsigned long busstate;)
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( unsigned long tristate;)
USE_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF(unsigned long hwif;)
#if ENABLE_FEATURE_HDPARM_HDIO_SCAN_HWIF
unsigned long hwif_data;
unsigned long hwif_ctrl;
unsigned long hwif_irq;
#endif
#ifdef DO_FLUSHCACHE
unsigned char flushcache[4] = { WIN_FLUSHCACHE, 0, 0, 0 };
#endif
};
#define G (*(struct globals*)&bb_common_bufsiz1)
struct BUG_G_too_big {
char BUG_G_too_big[sizeof(G) <= COMMON_BUFSIZE ? 1 : -1];
};
#define get_identity (G.get_identity )
#define get_geom (G.get_geom )
#define do_flush (G.do_flush )
#define do_ctimings (G.do_ctimings )
#define do_timings (G.do_timings )
#define reread_partn (G.reread_partn )
#define set_piomode (G.set_piomode )
#define noisy_piomode (G.noisy_piomode )
#define set_readahead (G.set_readahead )
#define get_readahead (G.get_readahead )
#define set_readonly (G.set_readonly )
#define get_readonly (G.get_readonly )
#define set_unmask (G.set_unmask )
#define get_unmask (G.get_unmask )
#define set_mult (G.set_mult )
#define get_mult (G.get_mult )
#define set_dma_q (G.set_dma_q )
#define get_dma_q (G.get_dma_q )
#define set_nowerr (G.set_nowerr )
#define get_nowerr (G.get_nowerr )
#define set_keep (G.set_keep )
#define get_keep (G.get_keep )
#define set_io32bit (G.set_io32bit )
#define get_io32bit (G.get_io32bit )
#define piomode (G.piomode )
#define Xreadahead (G.Xreadahead )
#define readonly (G.readonly )
#define unmask (G.unmask )
#define mult (G.mult )
#define dma_q (G.dma_q )
#define nowerr (G.nowerr )
#define keep (G.keep )
#define io32bit (G.io32bit )
#define dma (G.dma )
#define set_dma (G.set_dma )
#define get_dma (G.get_dma )
#define set_xfermode (G.set_xfermode )
#define get_xfermode (G.get_xfermode )
#define set_dkeep (G.set_dkeep )
#define get_dkeep (G.get_dkeep )
#define set_standby (G.set_standby )
#define get_standby (G.get_standby )
#define set_lookahead (G.set_lookahead )
#define get_lookahead (G.get_lookahead )
#define set_prefetch (G.set_prefetch )
#define get_prefetch (G.get_prefetch )
#define set_defects (G.set_defects )
#define get_defects (G.get_defects )
#define set_wcache (G.set_wcache )
#define get_wcache (G.get_wcache )
#define set_doorlock (G.set_doorlock )
#define get_doorlock (G.get_doorlock )
#define set_seagate (G.set_seagate )
#define get_seagate (G.get_seagate )
#define set_standbynow (G.set_standbynow )
#define get_standbynow (G.get_standbynow )
#define set_sleepnow (G.set_sleepnow )
#define get_sleepnow (G.get_sleepnow )
#define get_powermode (G.get_powermode )
#define set_apmmode (G.set_apmmode )
#define get_apmmode (G.get_apmmode )
#define xfermode_requested (G.xfermode_requested )
#define dkeep (G.dkeep )
#define standby_requested (G.standby_requested )
#define lookahead (G.lookahead )
#define prefetch (G.prefetch )
#define defects (G.defects )
#define wcache (G.wcache )
#define doorlock (G.doorlock )
#define apmmode (G.apmmode )
#define get_IDentity (G.get_IDentity )
#define set_busstate (G.set_busstate )
#define get_busstate (G.get_busstate )
#define perform_reset (G.perform_reset )
#define perform_tristate (G.perform_tristate )
#define unregister_hwif (G.unregister_hwif )
#define scan_hwif (G.scan_hwif )
#define busstate (G.busstate )
#define tristate (G.tristate )
#define hwif (G.hwif )
#define hwif_data (G.hwif_data )
#define hwif_ctrl (G.hwif_ctrl )
#define hwif_irq (G.hwif_irq )
/* Busybox messages and functions */
#if ENABLE_IOCTL_HEX2STR_ERROR
static int ioctl_alt_func(/*int fd,*/ int cmd, unsigned char *args, int alt, const char *string)
{
if (!ioctl(fd, cmd, args))
return 0;
args[0] = alt;
return bb_ioctl_or_warn(fd, cmd, args, string);
}
#define ioctl_alt_or_warn(cmd,args,alt) ioctl_alt_func(cmd,args,alt,#cmd)
#else
static int ioctl_alt_func(/*int fd,*/ int cmd, unsigned char *args, int alt)
{
if (!ioctl(fd, cmd, args))
return 0;
args[0] = alt;
return bb_ioctl_or_warn(fd, cmd, args);
}
#define ioctl_alt_or_warn(cmd,args,alt) ioctl_alt_func(cmd,args,alt)
#endif
static void on_off(int value)
{
puts(value ? " (on)" : " (off)");
}
static void print_flag_on_off(int get_arg, const char *s, unsigned long arg)
{
if (get_arg) {
printf(" setting %s to %ld", s, arg);
on_off(arg);
}
}
static void print_value_on_off(const char *str, unsigned long argp)
{
printf(" %s\t= %2ld", str, argp);
on_off(argp != 0);
}
#if ENABLE_FEATURE_HDPARM_GET_IDENTITY
static void print_ascii(const char *p, int length)
{
#if BB_BIG_ENDIAN
#define LE_ONLY(x)
enum { ofs = 0 };
#else
#define LE_ONLY(x) x
/* every 16bit word is big-endian (i.e. inverted) */
/* accessing bytes in 1,0, 3,2, 5,4... sequence */
int ofs = 1;
#endif
length *= 2;
/* find first non-space & print it */
while (length && p[ofs] != ' ') {
p++;
LE_ONLY(ofs = -ofs;)
length--;
}
while (length && p[ofs]) {
bb_putchar(p[ofs]);
p++;
LE_ONLY(ofs = -ofs;)
length--;
}
bb_putchar('\n');
#undef LE_ONLY
}
static void xprint_ascii(uint16_t *val, int i, const char *string, int n)
{
if (val[i]) {
printf("\t%-20s", string);
print_ascii((void*)&val[i], n);
}
}
static uint8_t mode_loop(uint16_t mode_sup, uint16_t mode_sel, int cc, uint8_t *have_mode)
{
uint16_t ii;
uint8_t err_dma = 0;
for (ii = 0; ii <= MODE_MAX; ii++) {
if (mode_sel & 0x0001) {
printf("*%cdma%u ", cc, ii);
if (*have_mode)
err_dma = 1;
*have_mode = 1;
} else if (mode_sup & 0x0001)
printf("%cdma%u ", cc, ii);
mode_sup >>= 1;
mode_sel >>= 1;
}
return err_dma;
}
static const char pkt_str[] ALIGN1 =
"Direct-access device" "\0" /* word 0, bits 12-8 = 00 */
"Sequential-access device" "\0" /* word 0, bits 12-8 = 01 */
"Printer" "\0" /* word 0, bits 12-8 = 02 */
"Processor" "\0" /* word 0, bits 12-8 = 03 */
"Write-once device" "\0" /* word 0, bits 12-8 = 04 */
"CD-ROM" "\0" /* word 0, bits 12-8 = 05 */
"Scanner" "\0" /* word 0, bits 12-8 = 06 */
"Optical memory" "\0" /* word 0, bits 12-8 = 07 */
"Medium changer" "\0" /* word 0, bits 12-8 = 08 */
"Communications device" "\0" /* word 0, bits 12-8 = 09 */
"ACS-IT8 device" "\0" /* word 0, bits 12-8 = 0a */
"ACS-IT8 device" "\0" /* word 0, bits 12-8 = 0b */
"Array controller" "\0" /* word 0, bits 12-8 = 0c */
"Enclosure services" "\0" /* word 0, bits 12-8 = 0d */
"Reduced block command device" "\0" /* word 0, bits 12-8 = 0e */
"Optical card reader/writer" "\0" /* word 0, bits 12-8 = 0f */
;
static const char ata1_cfg_str[] ALIGN1 = /* word 0 in ATA-1 mode */
"reserved" "\0" /* bit 0 */
"hard sectored" "\0" /* bit 1 */
"soft sectored" "\0" /* bit 2 */
"not MFM encoded " "\0" /* bit 3 */
"head switch time > 15us" "\0" /* bit 4 */
"spindle motor control option" "\0" /* bit 5 */
"fixed drive" "\0" /* bit 6 */
"removable drive" "\0" /* bit 7 */
"disk xfer rate <= 5Mbs" "\0" /* bit 8 */
"disk xfer rate > 5Mbs, <= 10Mbs" "\0" /* bit 9 */
"disk xfer rate > 5Mbs" "\0" /* bit 10 */
"rotational speed tol." "\0" /* bit 11 */
"data strobe offset option" "\0" /* bit 12 */
"track offset option" "\0" /* bit 13 */
"format speed tolerance gap reqd" "\0" /* bit 14 */
"ATAPI" /* bit 14 */
;
static const char minor_str[] ALIGN1 =
/* word 81 value: */
"Unspecified" "\0" /* 0x0000 */
"ATA-1 X3T9.2 781D prior to rev.4" "\0" /* 0x0001 */
"ATA-1 published, ANSI X3.221-1994" "\0" /* 0x0002 */
"ATA-1 X3T9.2 781D rev.4" "\0" /* 0x0003 */
"ATA-2 published, ANSI X3.279-1996" "\0" /* 0x0004 */
"ATA-2 X3T10 948D prior to rev.2k" "\0" /* 0x0005 */
"ATA-3 X3T10 2008D rev.1" "\0" /* 0x0006 */
"ATA-2 X3T10 948D rev.2k" "\0" /* 0x0007 */
"ATA-3 X3T10 2008D rev.0" "\0" /* 0x0008 */
"ATA-2 X3T10 948D rev.3" "\0" /* 0x0009 */
"ATA-3 published, ANSI X3.298-199x" "\0" /* 0x000a */
"ATA-3 X3T10 2008D rev.6" "\0" /* 0x000b */
"ATA-3 X3T13 2008D rev.7 and 7a" "\0" /* 0x000c */
"ATA/ATAPI-4 X3T13 1153D rev.6" "\0" /* 0x000d */
"ATA/ATAPI-4 T13 1153D rev.13" "\0" /* 0x000e */
"ATA/ATAPI-4 X3T13 1153D rev.7" "\0" /* 0x000f */
"ATA/ATAPI-4 T13 1153D rev.18" "\0" /* 0x0010 */
"ATA/ATAPI-4 T13 1153D rev.15" "\0" /* 0x0011 */
"ATA/ATAPI-4 published, ANSI INCITS 317-1998" "\0" /* 0x0012 */
"ATA/ATAPI-5 T13 1321D rev.3" "\0" /* 0x0013 */
"ATA/ATAPI-4 T13 1153D rev.14" "\0" /* 0x0014 */
"ATA/ATAPI-5 T13 1321D rev.1" "\0" /* 0x0015 */
"ATA/ATAPI-5 published, ANSI INCITS 340-2000" "\0" /* 0x0016 */
"ATA/ATAPI-4 T13 1153D rev.17" "\0" /* 0x0017 */
"ATA/ATAPI-6 T13 1410D rev.0" "\0" /* 0x0018 */
"ATA/ATAPI-6 T13 1410D rev.3a" "\0" /* 0x0019 */
"ATA/ATAPI-7 T13 1532D rev.1" "\0" /* 0x001a */
"ATA/ATAPI-6 T13 1410D rev.2" "\0" /* 0x001b */
"ATA/ATAPI-6 T13 1410D rev.1" "\0" /* 0x001c */
"ATA/ATAPI-7 published, ANSI INCITS 397-2005" "\0" /* 0x001d */
"ATA/ATAPI-7 T13 1532D rev.0" "\0" /* 0x001e */
"reserved" "\0" /* 0x001f */
"reserved" "\0" /* 0x0020 */
"ATA/ATAPI-7 T13 1532D rev.4a" "\0" /* 0x0021 */
"ATA/ATAPI-6 published, ANSI INCITS 361-2002" "\0" /* 0x0022 */
"reserved" /* 0x0023-0xfffe */
;
static const char actual_ver[MINOR_MAX + 2] ALIGN1 = {
/* word 81 value: */
0, /* 0x0000 WARNING: actual_ver[] array */
1, /* 0x0001 WARNING: corresponds */
1, /* 0x0002 WARNING: *exactly* */
1, /* 0x0003 WARNING: to the ATA/ */
2, /* 0x0004 WARNING: ATAPI version */
2, /* 0x0005 WARNING: listed in */
3, /* 0x0006 WARNING: the */
2, /* 0x0007 WARNING: minor_str */
3, /* 0x0008 WARNING: array */
2, /* 0x0009 WARNING: above. */
3, /* 0x000a WARNING: */
3, /* 0x000b WARNING: If you change */
3, /* 0x000c WARNING: that one, */
4, /* 0x000d WARNING: change this one */
4, /* 0x000e WARNING: too!!! */
4, /* 0x000f */
4, /* 0x0010 */
4, /* 0x0011 */
4, /* 0x0012 */
5, /* 0x0013 */
4, /* 0x0014 */
5, /* 0x0015 */
5, /* 0x0016 */
4, /* 0x0017 */
6, /* 0x0018 */
6, /* 0x0019 */
7, /* 0x001a */
6, /* 0x001b */
6, /* 0x001c */
7, /* 0x001d */
7, /* 0x001e */
0, /* 0x001f */
0, /* 0x0020 */
7, /* 0x0021 */
6, /* 0x0022 */
0 /* 0x0023-0xfffe */
};
static const char cmd_feat_str[] ALIGN1 =
"" "\0" /* word 82 bit 15: obsolete */
"NOP cmd" "\0" /* word 82 bit 14 */
"READ BUFFER cmd" "\0" /* word 82 bit 13 */
"WRITE BUFFER cmd" "\0" /* word 82 bit 12 */
"" "\0" /* word 82 bit 11: obsolete */
"Host Protected Area feature set" "\0" /* word 82 bit 10 */
"DEVICE RESET cmd" "\0" /* word 82 bit 9 */
"SERVICE interrupt" "\0" /* word 82 bit 8 */
"Release interrupt" "\0" /* word 82 bit 7 */
"Look-ahead" "\0" /* word 82 bit 6 */
"Write cache" "\0" /* word 82 bit 5 */
"PACKET command feature set" "\0" /* word 82 bit 4 */
"Power Management feature set" "\0" /* word 82 bit 3 */
"Removable Media feature set" "\0" /* word 82 bit 2 */
"Security Mode feature set" "\0" /* word 82 bit 1 */
"SMART feature set" "\0" /* word 82 bit 0 */
/* -------------- */
"" "\0" /* word 83 bit 15: !valid bit */
"" "\0" /* word 83 bit 14: valid bit */
"FLUSH CACHE EXT cmd" "\0" /* word 83 bit 13 */
"Mandatory FLUSH CACHE cmd " "\0" /* word 83 bit 12 */
"Device Configuration Overlay feature set " "\0"
"48-bit Address feature set " "\0" /* word 83 bit 10 */
"" "\0"
"SET MAX security extension" "\0" /* word 83 bit 8 */
"Address Offset Reserved Area Boot" "\0" /* word 83 bit 7 */
"SET FEATURES subcommand required to spinup after power up" "\0"
"Power-Up In Standby feature set" "\0" /* word 83 bit 5 */
"Removable Media Status Notification feature set" "\0"
"Adv. Power Management feature set" "\0" /* word 83 bit 3 */
"CFA feature set" "\0" /* word 83 bit 2 */
"READ/WRITE DMA QUEUED" "\0" /* word 83 bit 1 */
"DOWNLOAD MICROCODE cmd" "\0" /* word 83 bit 0 */
/* -------------- */
"" "\0" /* word 84 bit 15: !valid bit */
"" "\0" /* word 84 bit 14: valid bit */
"" "\0" /* word 84 bit 13: reserved */
"" "\0" /* word 84 bit 12: reserved */
"" "\0" /* word 84 bit 11: reserved */
"" "\0" /* word 84 bit 10: reserved */
"" "\0" /* word 84 bit 9: reserved */
"" "\0" /* word 84 bit 8: reserved */
"" "\0" /* word 84 bit 7: reserved */
"" "\0" /* word 84 bit 6: reserved */
"General Purpose Logging feature set" "\0" /* word 84 bit 5 */
"" "\0" /* word 84 bit 4: reserved */
"Media Card Pass Through Command feature set " "\0"
"Media serial number " "\0" /* word 84 bit 2 */
"SMART self-test " "\0" /* word 84 bit 1 */
"SMART error logging " /* word 84 bit 0 */
;
static const char secu_str[] ALIGN1 =
"supported" "\0" /* word 128, bit 0 */
"enabled" "\0" /* word 128, bit 1 */
"locked" "\0" /* word 128, bit 2 */
"frozen" "\0" /* word 128, bit 3 */
"expired: security count" "\0" /* word 128, bit 4 */
"supported: enhanced erase" /* word 128, bit 5 */
;
// Parse 512 byte disk identification block and print much crap.
static void identify(uint16_t *val) ATTRIBUTE_NORETURN;
static void identify(uint16_t *val)
{
uint16_t ii, jj, kk;
uint16_t like_std = 1, std = 0, min_std = 0xffff;
uint16_t dev = NO_DEV, eqpt = NO_DEV;
uint8_t have_mode = 0, err_dma = 0;
uint8_t chksum = 0;
uint32_t ll, mm, nn, oo;
uint64_t bbbig; /* (:) */
const char *strng;
#if BB_BIG_ENDIAN
uint16_t buf[256];
// Adjust for endianness
swab(val, buf, sizeof(buf));
val = buf;
#endif
/* check if we recognise the device type */
bb_putchar('\n');
if (!(val[GEN_CONFIG] & NOT_ATA)) {
dev = ATA_DEV;
printf("ATA device, with ");
} else if (val[GEN_CONFIG]==CFA_SUPPORT_VAL) {
dev = ATA_DEV;
like_std = 4;
printf("CompactFlash ATA device, with ");
} else if (!(val[GEN_CONFIG] & NOT_ATAPI)) {
dev = ATAPI_DEV;
eqpt = (val[GEN_CONFIG] & EQPT_TYPE) >> SHIFT_EQPT;
printf("ATAPI %s, with ", eqpt <= 0xf ? nth_string(pkt_str, eqpt) : "unknown");
like_std = 3;
} else
/* "Unknown device type:\n\tbits 15&14 of general configuration word 0 both set to 1.\n" */
bb_error_msg_and_die("unknown device type");
printf("%sremovable media\n", !(val[GEN_CONFIG] & MEDIA_REMOVABLE) ? "non-" : "");
/* Info from the specific configuration word says whether or not the
* ID command completed correctly. It is only defined, however in
* ATA/ATAPI-5 & 6; it is reserved (value theoretically 0) in prior
* standards. Since the values allowed for this word are extremely
* specific, it should be safe to check it now, even though we don't
* know yet what standard this device is using.
*/
if ((val[CONFIG]==STBY_NID_VAL) || (val[CONFIG]==STBY_ID_VAL)
|| (val[CONFIG]==PWRD_NID_VAL) || (val[CONFIG]==PWRD_ID_VAL)
) {
like_std = 5;
if ((val[CONFIG]==STBY_NID_VAL) || (val[CONFIG]==STBY_ID_VAL))
printf("powers-up in standby; SET FEATURES subcmd spins-up.\n");
if (((val[CONFIG]==STBY_NID_VAL) || (val[CONFIG]==PWRD_NID_VAL)) && (val[GEN_CONFIG] & INCOMPLETE))
printf("\n\tWARNING: ID response incomplete.\n\tFollowing data may be incorrect.\n\n");
}
/* output the model and serial numbers and the fw revision */
xprint_ascii(val, START_MODEL, "Model Number:", LENGTH_MODEL);
xprint_ascii(val, START_SERIAL, "Serial Number:", LENGTH_SERIAL);
xprint_ascii(val, START_FW_REV, "Firmware Revision:", LENGTH_FW_REV);
xprint_ascii(val, START_MEDIA, "Media Serial Num:", LENGTH_MEDIA);
xprint_ascii(val, START_MANUF, "Media Manufacturer:", LENGTH_MANUF);
/* major & minor standards version number (Note: these words were not
* defined until ATA-3 & the CDROM std uses different words.) */
printf("Standards:");
if (eqpt != CDROM) {
if (val[MINOR] && (val[MINOR] <= MINOR_MAX)) {
if (like_std < 3) like_std = 3;
std = actual_ver[val[MINOR]];
if (std) printf("\n\tUsed: %s ", nth_string(minor_str, val[MINOR]));
}
/* looks like when they up-issue the std, they obsolete one;
* thus, only the newest 4 issues need be supported. (That's
* what "kk" and "min_std" are all about.) */
if (val[MAJOR] && (val[MAJOR] != NOVAL_1)) {
printf("\n\tSupported: ");
jj = val[MAJOR] << 1;
kk = like_std >4 ? like_std-4: 0;
for (ii = 14; (ii >0)&&(ii>kk); ii--) {
if (jj & 0x8000) {
printf("%u ", ii);
if (like_std < ii) {
like_std = ii;
kk = like_std >4 ? like_std-4: 0;
}
if (min_std > ii) min_std = ii;
}
jj <<= 1;
}
if (like_std < 3) like_std = 3;
}
/* Figure out what standard the device is using if it hasn't told
* us. If we know the std, check if the device is using any of
* the words from the next level up. It happens.
*/
if (like_std < std) like_std = std;
if (((std == 5) || (!std && (like_std < 6))) &&
((((val[CMDS_SUPP_1] & VALID) == VALID_VAL) &&
(( val[CMDS_SUPP_1] & CMDS_W83) > 0x00ff)) ||
((( val[CMDS_SUPP_2] & VALID) == VALID_VAL) &&
( val[CMDS_SUPP_2] & CMDS_W84) ) )
) {
like_std = 6;
} else if (((std == 4) || (!std && (like_std < 5))) &&
((((val[INTEGRITY] & SIG) == SIG_VAL) && !chksum) ||
(( val[HWRST_RSLT] & VALID) == VALID_VAL) ||
((( val[CMDS_SUPP_1] & VALID) == VALID_VAL) &&
(( val[CMDS_SUPP_1] & CMDS_W83) > 0x001f)) ) )
{
like_std = 5;
} else if (((std == 3) || (!std && (like_std < 4))) &&
((((val[CMDS_SUPP_1] & VALID) == VALID_VAL) &&
((( val[CMDS_SUPP_1] & CMDS_W83) > 0x0000) ||
(( val[CMDS_SUPP_0] & CMDS_W82) > 0x000f))) ||
(( val[CAPAB_1] & VALID) == VALID_VAL) ||
(( val[WHATS_VALID] & OK_W88) && val[ULTRA_DMA]) ||
(( val[RM_STAT] & RM_STAT_BITS) == RM_STAT_SUP) )
) {
like_std = 4;
} else if (((std == 2) || (!std && (like_std < 3)))
&& ((val[CMDS_SUPP_1] & VALID) == VALID_VAL)
) {
like_std = 3;
} else if (((std == 1) || (!std && (like_std < 2))) &&
((val[CAPAB_0] & (IORDY_SUP | IORDY_OFF)) ||
(val[WHATS_VALID] & OK_W64_70)) )
{
like_std = 2;
}
if (!std)
printf("\n\tLikely used: %u\n", like_std);
else if (like_std > std)
printf("& some of %u\n", like_std);
else
bb_putchar('\n');
} else {
/* TBD: do CDROM stuff more thoroughly. For now... */
kk = 0;
if (val[CDR_MINOR] == 9) {
kk = 1;
printf("\n\tUsed: ATAPI for CD-ROMs, SFF-8020i, r2.5");
}
if (val[CDR_MAJOR] && (val[CDR_MAJOR] !=NOVAL_1)) {
kk = 1;
printf("\n\tSupported: CD-ROM ATAPI");
jj = val[CDR_MAJOR] >> 1;
for (ii = 1; ii < 15; ii++) {
if (jj & 0x0001) printf("-%u ", ii);
jj >>= 1;
}
}
puts(kk ? "" : "\n\tLikely used CD-ROM ATAPI-1");
/* the cdrom stuff is more like ATA-2 than anything else, so: */
like_std = 2;
}
if (min_std == 0xffff)
min_std = like_std > 4 ? like_std - 3 : 1;
printf("Configuration:\n");
/* more info from the general configuration word */
if ((eqpt != CDROM) && (like_std == 1)) {
jj = val[GEN_CONFIG] >> 1;
for (ii = 1; ii < 15; ii++) {
if (jj & 0x0001)
printf("\t%s\n", nth_string(ata1_cfg_str, ii));
jj >>=1;
}
}
if (dev == ATAPI_DEV) {
if ((val[GEN_CONFIG] & DRQ_RESPONSE_TIME) == DRQ_3MS_VAL)
strng = "3ms";
else if ((val[GEN_CONFIG] & DRQ_RESPONSE_TIME) == DRQ_INTR_VAL)
strng = "<=10ms with INTRQ";
else if ((val[GEN_CONFIG] & DRQ_RESPONSE_TIME) == DRQ_50US_VAL)
strng ="50us";
else
strng = "unknown";
printf("\tDRQ response: %s\n\tPacket size: ", strng); /* Data Request (DRQ) */
if ((val[GEN_CONFIG] & PKT_SIZE_SUPPORTED) == PKT_SIZE_12_VAL)
strng = "12 bytes";
else if ((val[GEN_CONFIG] & PKT_SIZE_SUPPORTED) == PKT_SIZE_16_VAL)
strng = "16 bytes";
else
strng = "unknown";
puts(strng);
} else {
/* addressing...CHS? See section 6.2 of ATA specs 4 or 5 */
ll = (uint32_t)val[LBA_SECTS_MSB] << 16 | val[LBA_SECTS_LSB];
mm = 0; bbbig = 0;
if ((ll > 0x00FBFC10) && (!val[LCYLS]))
printf("\tCHS addressing not supported\n");
else {
jj = val[WHATS_VALID] & OK_W54_58;
printf("\tLogical\t\tmax\tcurrent\n\tcylinders\t%u\t%u\n\theads\t\t%u\t%u\n\tsectors/track\t%u\t%u\n\t--\n",
val[LCYLS],jj?val[LCYLS_CUR]:0, val[LHEADS],jj?val[LHEADS_CUR]:0, val[LSECTS],jj?val[LSECTS_CUR]:0);
if ((min_std == 1) && (val[TRACK_BYTES] || val[SECT_BYTES]))
printf("\tbytes/track: %u\tbytes/sector: %u\n", val[TRACK_BYTES], val[SECT_BYTES]);
if (jj) {
mm = (uint32_t)val[CAPACITY_MSB] << 16 | val[CAPACITY_LSB];
if (like_std < 3) {
/* check Endian of capacity bytes */
nn = val[LCYLS_CUR] * val[LHEADS_CUR] * val[LSECTS_CUR];
oo = (uint32_t)val[CAPACITY_LSB] << 16 | val[CAPACITY_MSB];
if (abs(mm - nn) > abs(oo - nn))
mm = oo;
}
printf("\tCHS current addressable sectors:%11u\n", mm);
}
}
/* LBA addressing */
printf("\tLBA user addressable sectors:%11u\n", ll);
if (((val[CMDS_SUPP_1] & VALID) == VALID_VAL)
&& (val[CMDS_SUPP_1] & SUPPORT_48_BIT)
) {
bbbig = (uint64_t)val[LBA_64_MSB] << 48 |
(uint64_t)val[LBA_48_MSB] << 32 |
(uint64_t)val[LBA_MID] << 16 |
val[LBA_LSB];
printf("\tLBA48 user addressable sectors:%11"PRIu64"\n", bbbig);
}
if (!bbbig)
bbbig = (uint64_t)(ll>mm ? ll : mm); /* # 512 byte blocks */
printf("\tdevice size with M = 1024*1024: %11"PRIu64" MBytes\n", bbbig>>11);
bbbig = (bbbig << 9) / 1000000;
printf("\tdevice size with M = 1000*1000: %11"PRIu64" MBytes ", bbbig);
if (bbbig > 1000)
printf("(%"PRIu64" GB)\n", bbbig/1000);
else
bb_putchar('\n');
}
/* hw support of commands (capabilities) */
printf("Capabilities:\n\t");
if (dev == ATAPI_DEV) {
if (eqpt != CDROM && (val[CAPAB_0] & CMD_Q_SUP)) printf("Cmd queuing, ");
if (val[CAPAB_0] & OVLP_SUP) printf("Cmd overlap, ");
}
if (val[CAPAB_0] & LBA_SUP) printf("LBA, ");
if (like_std != 1) {
printf("IORDY%s(can%s be disabled)\n",
!(val[CAPAB_0] & IORDY_SUP) ? "(may be)" : "",
(val[CAPAB_0] & IORDY_OFF) ? "" :"not");
} else
printf("no IORDY\n");
if ((like_std == 1) && val[BUF_TYPE]) {
printf("\tBuffer type: %04x: %s%s\n", val[BUF_TYPE],
(val[BUF_TYPE] < 2) ? "single port, single-sector" : "dual port, multi-sector",
(val[BUF_TYPE] > 2) ? " with read caching ability" : "");
}
if ((min_std == 1) && (val[BUFFER__SIZE] && (val[BUFFER__SIZE] != NOVAL_1))) {
printf("\tBuffer size: %.1fkB\n", (float)val[BUFFER__SIZE]/2);
}
if ((min_std < 4) && (val[RW_LONG])) {
printf("\tbytes avail on r/w long: %u\n", val[RW_LONG]);
}
if ((eqpt != CDROM) && (like_std > 3)) {
printf("\tQueue depth: %u\n", (val[QUEUE_DEPTH] & DEPTH_BITS) + 1);
}
if (dev == ATA_DEV) {
if (like_std == 1)
printf("\tCan%s perform double-word IO\n", (!val[DWORD_IO]) ? "not" : "");
else {
printf("\tStandby timer values: spec'd by %s", (val[CAPAB_0] & STD_STBY) ? "Standard" : "Vendor");
if ((like_std > 3) && ((val[CAPAB_1] & VALID) == VALID_VAL))
printf(", %s device specific minimum\n", (val[CAPAB_1] & MIN_STANDBY_TIMER) ? "with" : "no");
else
bb_putchar('\n');
}
printf("\tR/W multiple sector transfer: ");
if ((like_std < 3) && !(val[SECTOR_XFER_MAX] & SECTOR_XFER))
printf("not supported\n");
else {
printf("Max = %u\tCurrent = ", val[SECTOR_XFER_MAX] & SECTOR_XFER);
if (val[SECTOR_XFER_CUR] & MULTIPLE_SETTING_VALID)
printf("%u\n", val[SECTOR_XFER_CUR] & SECTOR_XFER);
else
printf("?\n");
}
if ((like_std > 3) && (val[CMDS_SUPP_1] & 0x0008)) {
/* We print out elsewhere whether the APM feature is enabled or
not. If it's not enabled, let's not repeat the info; just print
nothing here. */
printf("\tAdvancedPM level: ");
if ((val[ADV_PWR] & 0xFF00) == 0x4000) {
uint8_t apm_level = val[ADV_PWR] & 0x00FF;
printf("%u (0x%x)\n", apm_level, apm_level);
}
else
printf("unknown setting (0x%04x)\n", val[ADV_PWR]);
}
if (like_std > 5 && val[ACOUSTIC]) {
printf("\tRecommended acoustic management value: %u, current value: %u\n",
(val[ACOUSTIC] >> 8) & 0x00ff, val[ACOUSTIC] & 0x00ff);
}
} else {
/* ATAPI */
if (eqpt != CDROM && (val[CAPAB_0] & SWRST_REQ))
printf("\tATA sw reset required\n");
if (val[PKT_REL] || val[SVC_NBSY]) {
printf("\tOverlap support:");
if (val[PKT_REL]) printf(" %uus to release bus.", val[PKT_REL]);
if (val[SVC_NBSY]) printf(" %uus to clear BSY after SERVICE cmd.", val[SVC_NBSY]);
bb_putchar('\n');
}
}
/* DMA stuff. Check that only one DMA mode is selected. */
printf("\tDMA: ");
if (!(val[CAPAB_0] & DMA_SUP))
printf("not supported\n");
else {
if (val[DMA_MODE] && !val[SINGLE_DMA] && !val[MULTI_DMA])
printf(" sdma%u\n", (val[DMA_MODE] & MODE) >> 8);
if (val[SINGLE_DMA]) {
jj = val[SINGLE_DMA];
kk = val[SINGLE_DMA] >> 8;
err_dma += mode_loop(jj, kk, 's', &have_mode);
}
if (val[MULTI_DMA]) {
jj = val[MULTI_DMA];
kk = val[MULTI_DMA] >> 8;
err_dma += mode_loop(jj, kk, 'm', &have_mode);
}
if ((val[WHATS_VALID] & OK_W88) && val[ULTRA_DMA]) {
jj = val[ULTRA_DMA];
kk = val[ULTRA_DMA] >> 8;
err_dma += mode_loop(jj, kk, 'u', &have_mode);
}
if (err_dma || !have_mode) printf("(?)");
bb_putchar('\n');
if ((dev == ATAPI_DEV) && (eqpt != CDROM) && (val[CAPAB_0] & DMA_IL_SUP))
printf("\t\tInterleaved DMA support\n");
if ((val[WHATS_VALID] & OK_W64_70)
&& (val[DMA_TIME_MIN] || val[DMA_TIME_NORM])
) {
printf("\t\tCycle time:");
if (val[DMA_TIME_MIN]) printf(" min=%uns", val[DMA_TIME_MIN]);
if (val[DMA_TIME_NORM]) printf(" recommended=%uns", val[DMA_TIME_NORM]);
bb_putchar('\n');
}
}
/* Programmed IO stuff */
printf("\tPIO: ");
/* If a drive supports mode n (e.g. 3), it also supports all modes less
* than n (e.g. 3, 2, 1 and 0). Print all the modes. */
if ((val[WHATS_VALID] & OK_W64_70) && (val[ADV_PIO_MODES] & PIO_SUP)) {
jj = ((val[ADV_PIO_MODES] & PIO_SUP) << 3) | 0x0007;
for (ii = 0; ii <= PIO_MODE_MAX; ii++) {
if (jj & 0x0001) printf("pio%d ", ii);
jj >>=1;
}
bb_putchar('\n');
} else if (((min_std < 5) || (eqpt == CDROM)) && (val[PIO_MODE] & MODE)) {
for (ii = 0; ii <= val[PIO_MODE]>>8; ii++)
printf("pio%d ", ii);
bb_putchar('\n');
} else
puts("unknown");
if (val[WHATS_VALID] & OK_W64_70) {
if (val[PIO_NO_FLOW] || val[PIO_FLOW]) {
printf("\t\tCycle time:");
if (val[PIO_NO_FLOW]) printf(" no flow control=%uns", val[PIO_NO_FLOW]);
if (val[PIO_FLOW]) printf(" IORDY flow control=%uns", val[PIO_FLOW]);
bb_putchar('\n');
}
}
if ((val[CMDS_SUPP_1] & VALID) == VALID_VAL) {
printf("Commands/features:\n\tEnabled\tSupported:\n");
jj = val[CMDS_SUPP_0];
kk = val[CMDS_EN_0];
for (ii = 0; ii < NUM_CMD_FEAT_STR; ii++) {
const char *feat_str = nth_string(cmd_feat_str, ii);
if ((jj & 0x8000) && (*feat_str != '\0')) {
printf("\t%s\t%s\n", (kk & 0x8000) ? " *" : "", feat_str);
}
jj <<= 1;
kk <<= 1;
if (ii % 16 == 15) {
jj = val[CMDS_SUPP_0+1+(ii/16)];
kk = val[CMDS_EN_0+1+(ii/16)];
}
if (ii == 31) {
if ((val[CMDS_SUPP_2] & VALID) != VALID_VAL)
ii +=16;
}
}
}
/* Removable Media Status Notification feature set */
if ((val[RM_STAT] & RM_STAT_BITS) == RM_STAT_SUP)
printf("\t%s supported\n", nth_string(cmd_feat_str, 27));
/* security */
if ((eqpt != CDROM) && (like_std > 3)
&& (val[SECU_STATUS] || val[ERASE_TIME] || val[ENH_ERASE_TIME])
) {
printf("Security:\n");
if (val[PSWD_CODE] && (val[PSWD_CODE] != NOVAL_1))
printf("\tMaster password revision code = %u\n", val[PSWD_CODE]);
jj = val[SECU_STATUS];
if (jj) {
for (ii = 0; ii < NUM_SECU_STR; ii++) {
printf("\t%s\t%s\n", (!(jj & 0x0001)) ? "not" : "", nth_string(secu_str, ii));
jj >>=1;
}
if (val[SECU_STATUS] & SECU_ENABLED) {
printf("\tSecurity level %s\n", (val[SECU_STATUS] & SECU_LEVEL) ? "maximum" : "high");
}
}
jj = val[ERASE_TIME] & ERASE_BITS;
kk = val[ENH_ERASE_TIME] & ERASE_BITS;
if (jj || kk) {
printf("\t");
if (jj) printf("%umin for %sSECURITY ERASE UNIT. ", jj==ERASE_BITS ? 508 : jj<<1, "");
if (kk) printf("%umin for %sSECURITY ERASE UNIT. ", kk==ERASE_BITS ? 508 : kk<<1, "ENHANCED ");
bb_putchar('\n');
}
}
/* reset result */
jj = val[HWRST_RSLT];
if ((jj & VALID) == VALID_VAL) {
oo = (jj & RST0);
if (!oo)
jj >>= 8;
if ((jj & DEV_DET) == JUMPER_VAL)
strng = " determined by the jumper";
else if ((jj & DEV_DET) == CSEL_VAL)
strng = " determined by CSEL";
else
strng = "";
printf("HW reset results:\n\tCBLID- %s Vih\n\tDevice num = %i%s\n",
(val[HWRST_RSLT] & CBLID) ? "above" : "below", !(oo), strng);
}
/* more stuff from std 5 */
if ((like_std > 4) && (eqpt != CDROM)) {
if (val[CFA_PWR_MODE] & VALID_W160) {
printf("CFA power mode 1:\n\t%s%s\n", (val[CFA_PWR_MODE] & PWR_MODE_OFF) ? "disabled" : "enabled",
(val[CFA_PWR_MODE] & PWR_MODE_REQ) ? " and required by some commands" : "");
if (val[CFA_PWR_MODE] & MAX_AMPS)
printf("\tMaximum current = %uma\n", val[CFA_PWR_MODE] & MAX_AMPS);
}
if ((val[INTEGRITY] & SIG) == SIG_VAL) {
printf("Checksum: %scorrect\n", chksum ? "in" : "");
}
}
exit(EXIT_SUCCESS);
}
#endif
// Historically, if there was no HDIO_OBSOLETE_IDENTITY, then
// then the HDIO_GET_IDENTITY only returned 142 bytes.
// Otherwise, HDIO_OBSOLETE_IDENTITY returns 142 bytes,
// and HDIO_GET_IDENTITY returns 512 bytes. But the latest
// 2.5.xx kernels no longer define HDIO_OBSOLETE_IDENTITY
// (which they should, but they should just return -EINVAL).
//
// So.. we must now assume that HDIO_GET_IDENTITY returns 512 bytes.
// On a really old system, it will not, and we will be confused.
// Too bad, really.
#if ENABLE_FEATURE_HDPARM_GET_IDENTITY
static const char cfg_str[] ALIGN1 =
"""\0" "HardSect""\0" "SoftSect""\0" "NotMFM""\0"
"HdSw>15uSec""\0" "SpinMotCtl""\0" "Fixed""\0" "Removeable""\0"
"DTR<=5Mbs""\0" "DTR>5Mbs""\0" "DTR>10Mbs""\0" "RotSpdTol>.5%""\0"
"dStbOff""\0" "TrkOff""\0" "FmtGapReq""\0" "nonMagnetic"
;
static const char BuffType[] ALIGN1 =
"unknown""\0" "1Sect""\0" "DualPort""\0" "DualPortCache"
;
static void dump_identity(const struct hd_driveid *id)
{
int i;
const unsigned short *id_regs = (const void*) id;
printf("\n Model=%.40s, FwRev=%.8s, SerialNo=%.20s\n Config={",
id->model, id->fw_rev, id->serial_no);
for (i = 0; i <= 15; i++) {
if (id->config & (1<<i))
printf(" %s", nth_string(cfg_str, i));
}
printf(" }\n RawCHS=%u/%u/%u, TrkSize=%u, SectSize=%u, ECCbytes=%u\n"
" BuffType=(%u) %s, BuffSize=%ukB, MaxMultSect=%u",
id->cyls, id->heads, id->sectors, id->track_bytes,
id->sector_bytes, id->ecc_bytes,
id->buf_type, nth_string(BuffType, (id->buf_type > 3) ? 0 : id->buf_type),
id->buf_size/2, id->max_multsect);
if (id->max_multsect) {
printf(", MultSect=");
if (!(id->multsect_valid & 1))
printf("?%u?", id->multsect);
else if (id->multsect)
printf("%u", id->multsect);
else
printf("off");
}
bb_putchar('\n');
if (!(id->field_valid & 1))
printf(" (maybe):");
printf(" CurCHS=%u/%u/%u, CurSects=%lu, LBA=%s", id->cur_cyls, id->cur_heads,
id->cur_sectors,
(BB_BIG_ENDIAN) ?
(unsigned long)(id->cur_capacity0 << 16) | id->cur_capacity1 :
(unsigned long)(id->cur_capacity1 << 16) | id->cur_capacity0,
((id->capability&2) == 0) ? "no" : "yes");
if (id->capability & 2)
printf(", LBAsects=%u", id->lba_capacity);
printf("\n IORDY=%s", (id->capability & 8) ? (id->capability & 4) ? "on/off" : "yes" : "no");
if (((id->capability & 8) || (id->field_valid & 2)) && (id->field_valid & 2))
printf(", tPIO={min:%u,w/IORDY:%u}", id->eide_pio, id->eide_pio_iordy);
if ((id->capability & 1) && (id->field_valid & 2))
printf(", tDMA={min:%u,rec:%u}", id->eide_dma_min, id->eide_dma_time);
printf("\n PIO modes: ");
if (id->tPIO <= 5) {
printf("pio0 ");
if (id->tPIO >= 1) printf("pio1 ");
if (id->tPIO >= 2) printf("pio2 ");
}
if (id->field_valid & 2) {
if (id->eide_pio_modes & 1) printf("pio3 ");
if (id->eide_pio_modes & 2) printf("pio4 ");
if (id->eide_pio_modes &~3) printf("pio? ");
}
if (id->capability & 1) {
if (id->dma_1word | id->dma_mword) {
printf("\n DMA modes: ");
if (id->dma_1word & 0x100) printf("*");
if (id->dma_1word & 1) printf("sdma0 ");
if (id->dma_1word & 0x200) printf("*");
if (id->dma_1word & 2) printf("sdma1 ");
if (id->dma_1word & 0x400) printf("*");
if (id->dma_1word & 4) printf("sdma2 ");
if (id->dma_1word & 0xf800) printf("*");
if (id->dma_1word & 0xf8) printf("sdma? ");
if (id->dma_mword & 0x100) printf("*");
if (id->dma_mword & 1) printf("mdma0 ");
if (id->dma_mword & 0x200) printf("*");
if (id->dma_mword & 2) printf("mdma1 ");
if (id->dma_mword & 0x400) printf("*");
if (id->dma_mword & 4) printf("mdma2 ");
if (id->dma_mword & 0xf800) printf("*");
if (id->dma_mword & 0xf8) printf("mdma? ");
}
}
if (((id->capability & 8) || (id->field_valid & 2)) && id->field_valid & 4) {
printf("\n UDMA modes: ");
if (id->dma_ultra & 0x100) printf("*");
if (id->dma_ultra & 0x001) printf("udma0 ");
if (id->dma_ultra & 0x200) printf("*");
if (id->dma_ultra & 0x002) printf("udma1 ");
if (id->dma_ultra & 0x400) printf("*");
if (id->dma_ultra & 0x004) printf("udma2 ");
#ifdef __NEW_HD_DRIVE_ID
if (id->hw_config & 0x2000) {
#else /* !__NEW_HD_DRIVE_ID */
if (id->word93 & 0x2000) {
#endif /* __NEW_HD_DRIVE_ID */
if (id->dma_ultra & 0x0800) printf("*");
if (id->dma_ultra & 0x0008) printf("udma3 ");
if (id->dma_ultra & 0x1000) printf("*");
if (id->dma_ultra & 0x0010) printf("udma4 ");
if (id->dma_ultra & 0x2000) printf("*");
if (id->dma_ultra & 0x0020) printf("udma5 ");
if (id->dma_ultra & 0x4000) printf("*");
if (id->dma_ultra & 0x0040) printf("udma6 ");
if (id->dma_ultra & 0x8000) printf("*");
if (id->dma_ultra & 0x0080) printf("udma7 ");
}
}
printf("\n AdvancedPM=%s", (!(id_regs[83] & 8)) ? "no" : "yes");
if (id_regs[83] & 8) {
if (!(id_regs[86] & 8))
printf(": disabled (255)");
else if ((id_regs[91] & 0xFF00) != 0x4000)
printf(": unknown setting");
else
printf(": mode=0x%02X (%u)", id_regs[91] & 0xFF, id_regs[91] & 0xFF);
}
if (id_regs[82] & 0x20)
printf(" WriteCache=%s", (id_regs[85] & 0x20) ? "enabled" : "disabled");
#ifdef __NEW_HD_DRIVE_ID
if ((id->minor_rev_num && id->minor_rev_num <= 31)
|| (id->major_rev_num && id->minor_rev_num <= 31)
) {
printf("\n Drive conforms to: %s: ", (id->minor_rev_num <= 31) ? nth_string(minor_str, id->minor_rev_num) : "unknown");
if (id->major_rev_num != 0x0000 && /* NOVAL_0 */
id->major_rev_num != 0xFFFF) { /* NOVAL_1 */
for (i = 0; i <= 15; i++) {
if (id->major_rev_num & (1<<i))
printf(" ATA/ATAPI-%u", i);
}
}
}
#endif /* __NEW_HD_DRIVE_ID */
printf("\n\n * current active mode\n\n");
}
#endif
static void flush_buffer_cache(/*int fd*/ void)
{
fsync(fd); /* flush buffers */
ioctl_or_warn(fd, BLKFLSBUF, NULL); /* do it again, big time */
#ifdef HDIO_DRIVE_CMD
sleep(1);
if (ioctl(fd, HDIO_DRIVE_CMD, NULL) && errno != EINVAL) { /* await completion */
if (ENABLE_IOCTL_HEX2STR_ERROR) /* To be coherent with ioctl_or_warn */
bb_perror_msg("HDIO_DRIVE_CMD");
else
bb_perror_msg("ioctl %#x failed", HDIO_DRIVE_CMD);
}
#endif
}
static void seek_to_zero(/*int fd*/ void)
{
xlseek(fd, (off_t) 0, SEEK_SET);
}
static void read_big_block(/*int fd,*/ char *buf)
{
int i;
xread(fd, buf, TIMING_BUF_BYTES);
/* access all sectors of buf to ensure the read fully completed */
for (i = 0; i < TIMING_BUF_BYTES; i += 512)
buf[i] &= 1;
}
static unsigned dev_size_mb(/*int fd*/ void)
{
union {
unsigned long long blksize64;
unsigned blksize32;
} u;
if (0 == ioctl(fd, BLKGETSIZE64, &u.blksize64)) { // bytes
u.blksize64 /= (1024 * 1024);
} else {
xioctl(fd, BLKGETSIZE, &u.blksize32); // sectors
u.blksize64 = u.blksize32 / (2 * 1024);
}
if (u.blksize64 > UINT_MAX)
return UINT_MAX;
return u.blksize64;
}
static void print_timing(unsigned m, unsigned elapsed_us)
{
unsigned sec = elapsed_us / 1000000;
unsigned hs = (elapsed_us % 1000000) / 10000;
printf("%5u MB in %u.%02u seconds = %u kB/s\n",
m, sec, hs,
/* "| 1" prevents div-by-0 */
(unsigned) ((unsigned long long)m * (1024 * 1000000) / (elapsed_us | 1))
// ~= (m * 1024) / (elapsed_us / 1000000)
// = kb / elapsed_sec
);
}
static void do_time(int cache /*,int fd*/)
/* cache=1: time cache: repeatedly read N MB at offset 0
* cache=0: time device: linear read, starting at offset 0
*/
{
unsigned max_iterations, iterations;
unsigned start; /* doesn't need to be long long */
unsigned elapsed, elapsed2;
unsigned total_MB;
char *buf = xmalloc(TIMING_BUF_BYTES);
if (mlock(buf, TIMING_BUF_BYTES))
bb_perror_msg_and_die("mlock");
/* Clear out the device request queues & give them time to complete.
* NB: *small* delay. User is expected to have a clue and to not run
* heavy io in parallel with measurements. */
sync();
sleep(1);
if (cache) { /* Time cache */
seek_to_zero();
read_big_block(buf);
printf("Timing buffer-cache reads: ");
} else { /* Time device */
printf("Timing buffered disk reads:");
}
fflush(stdout);
/* Now do the timing */
iterations = 0;
/* Max time to run (small for cache, avoids getting
* huge total_MB which can overlow unsigned type) */
elapsed2 = 510000; /* cache */
max_iterations = UINT_MAX;
if (!cache) {
elapsed2 = 3000000; /* not cache */
/* Don't want to read past the end! */
max_iterations = dev_size_mb() / TIMING_BUF_MB;
}
start = monotonic_us();
do {
if (cache)
seek_to_zero();
read_big_block(buf);
elapsed = (unsigned)monotonic_us() - start;
++iterations;
} while (elapsed < elapsed2 && iterations < max_iterations);
total_MB = iterations * TIMING_BUF_MB;
//printf(" elapsed:%u iterations:%u ", elapsed, iterations);
if (cache) {
/* Cache: remove lseek() and monotonic_us() overheads
* from elapsed */
start = monotonic_us();
do {
seek_to_zero();
elapsed2 = (unsigned)monotonic_us() - start;
} while (--iterations);
//printf(" elapsed2:%u ", elapsed2);
elapsed -= elapsed2;
total_MB *= 2; // BUFCACHE_FACTOR (why?)
flush_buffer_cache();
}
print_timing(total_MB, elapsed);
munlock(buf, TIMING_BUF_BYTES);
free(buf);
}
#if ENABLE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF
static void bus_state_value(unsigned value)
{
if (value == BUSSTATE_ON)
on_off(1);
else if (value == BUSSTATE_OFF)
on_off(0);
else if (value == BUSSTATE_TRISTATE)
printf(" (tristate)\n");
else
printf(" (unknown: %d)\n", value);
}
#endif
#ifdef HDIO_DRIVE_CMD
static void interpret_standby(unsigned standby)
{
unsigned t;
printf(" (");
if (standby == 0)
printf("off");
else if (standby == 252)
printf("21 minutes");
else if (standby == 253)
printf("vendor-specific");
else if (standby == 254)
printf("reserved");
else if (standby == 255)
printf("21 minutes + 15 seconds");
else if (standby <= 240) {
t = standby * 5;
printf("%u minutes + %u seconds", t / 60, t % 60);
} else if (standby <= 251) {
t = (standby - 240) * 30;
printf("%u hours + %u minutes", t / 60, t % 60);
} else
printf("illegal value");
printf(")\n");
}
static const uint8_t xfermode_val[] ALIGN1 = {
8, 9, 10, 11, 12, 13, 14, 15,
16, 17, 18, 19, 20, 21, 22, 23,
32, 33, 34, 35, 36, 37, 38, 39,
64, 65, 66, 67, 68, 69, 70, 71
};
/* NB: we save size by _not_ storing terninating NUL! */
static const char xfermode_name[][5] ALIGN1 = {
"pio0", "pio1", "pio2", "pio3", "pio4", "pio5", "pio6", "pio7",
"sdma0","sdma1","sdma2","sdma3","sdma4","sdma5","sdma6","sdma7",
"mdma0","mdma1","mdma2","mdma3","mdma4","mdma5","mdma6","mdma7",
"udma0","udma1","udma2","udma3","udma4","udma5","udma6","udma7"
};
static int translate_xfermode(const char *name)
{
int val, i;
for (i = 0; i < ARRAY_SIZE(xfermode_val); i++) {
if (!strncmp(name, xfermode_name[i], 5))
if (strlen(name) <= 5)
return xfermode_val[i];
}
/* Negative numbers are invalid and are caught later */
val = bb_strtoi(name, NULL, 10);
if (!errno)
return val;
return -1;
}
static void interpret_xfermode(unsigned xfermode)
{
printf(" (");
if (xfermode == 0)
printf("default PIO mode");
else if (xfermode == 1)
printf("default PIO mode, disable IORDY");
else if (xfermode >= 8 && xfermode <= 15)
printf("PIO flow control mode%u", xfermode - 8);
else if (xfermode >= 16 && xfermode <= 23)
printf("singleword DMA mode%u", xfermode - 16);
else if (xfermode >= 32 && xfermode <= 39)
printf("multiword DMA mode%u", xfermode - 32);
else if (xfermode >= 64 && xfermode <= 71)
printf("UltraDMA mode%u", xfermode - 64);
else
printf("unknown");
printf(")\n");
}
#endif /* HDIO_DRIVE_CMD */
static void print_flag(int flag, const char *s, unsigned long value)
{
if (flag)
printf(" setting %s to %ld\n", s, value);
}
static void process_dev(char *devname)
{
/*int fd;*/
long parm, multcount;
#ifndef HDIO_DRIVE_CMD
int force_operation = 0;
#endif
/* Please restore args[n] to these values after each ioctl
except for args[2] */
unsigned char args[4] = { WIN_SETFEATURES, 0, 0, 0 };
const char *fmt = " %s\t= %2ld";
/*fd = xopen(devname, O_RDONLY | O_NONBLOCK);*/
xmove_fd(xopen(devname, O_RDONLY | O_NONBLOCK), fd);
printf("\n%s:\n", devname);
if (set_readahead) {
print_flag(get_readahead, "fs readahead", Xreadahead);
ioctl_or_warn(fd, BLKRASET, (int *)Xreadahead);
}
#if ENABLE_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF
if (unregister_hwif) {
printf(" attempting to unregister hwif#%lu\n", hwif);
ioctl_or_warn(fd, HDIO_UNREGISTER_HWIF, (int *)(unsigned long)hwif);
}
#endif
#if ENABLE_FEATURE_HDPARM_HDIO_SCAN_HWIF
if (scan_hwif) {
printf(" attempting to scan hwif (0x%lx, 0x%lx, %lu)\n", hwif_data, hwif_ctrl, hwif_irq);
args[0] = hwif_data;
args[1] = hwif_ctrl;
args[2] = hwif_irq;
ioctl_or_warn(fd, HDIO_SCAN_HWIF, args);
args[0] = WIN_SETFEATURES;
args[1] = 0;
}
#endif
if (set_piomode) {
if (noisy_piomode) {
printf(" attempting to ");
if (piomode == 255)
printf("auto-tune PIO mode\n");
else if (piomode < 100)
printf("set PIO mode to %d\n", piomode);
else if (piomode < 200)
printf("set MDMA mode to %d\n", (piomode-100));
else
printf("set UDMA mode to %d\n", (piomode-200));
}
ioctl_or_warn(fd, HDIO_SET_PIO_MODE, (int *)(unsigned long)piomode);
}
if (set_io32bit) {
print_flag(get_io32bit, "32-bit IO_support flag", io32bit);
ioctl_or_warn(fd, HDIO_SET_32BIT, (int *)io32bit);
}
if (set_mult) {
print_flag(get_mult, "multcount", mult);
#ifdef HDIO_DRIVE_CMD
ioctl_or_warn(fd, HDIO_SET_MULTCOUNT, (void *)mult);
#else
force_operation |= (!ioctl_or_warn(fd, HDIO_SET_MULTCOUNT, (void *)mult));
#endif
}
if (set_readonly) {
print_flag_on_off(get_readonly, "readonly", readonly);
ioctl_or_warn(fd, BLKROSET, &readonly);
}
if (set_unmask) {
print_flag_on_off(get_unmask, "unmaskirq", unmask);
ioctl_or_warn(fd, HDIO_SET_UNMASKINTR, (int *)unmask);
}
#if ENABLE_FEATURE_HDPARM_HDIO_GETSET_DMA
if (set_dma) {
print_flag_on_off(get_dma, "using_dma", dma);
ioctl_or_warn(fd, HDIO_SET_DMA, (int *)dma);
}
#endif /* FEATURE_HDPARM_HDIO_GETSET_DMA */
if (set_dma_q) {
print_flag_on_off(get_dma_q, "DMA queue_depth", dma_q);
ioctl_or_warn(fd, HDIO_SET_QDMA, (int *)dma_q);
}
if (set_nowerr) {
print_flag_on_off(get_nowerr, "nowerr", nowerr);
ioctl_or_warn(fd, HDIO_SET_NOWERR, (int *)nowerr);
}
if (set_keep) {
print_flag_on_off(get_keep, "keep_settings", keep);
ioctl_or_warn(fd, HDIO_SET_KEEPSETTINGS, (int *)keep);
}
#ifdef HDIO_DRIVE_CMD
if (set_doorlock) {
args[0] = doorlock ? WIN_DOORLOCK : WIN_DOORUNLOCK;
args[2] = 0;
print_flag_on_off(get_doorlock, "drive doorlock", doorlock);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[0] = WIN_SETFEATURES;
}
if (set_dkeep) {
/* lock/unlock the drive's "feature" settings */
print_flag_on_off(get_dkeep, "drive keep features", dkeep);
args[2] = dkeep ? 0x66 : 0xcc;
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (set_defects) {
args[2] = defects ? 0x04 : 0x84;
print_flag(get_defects, "drive defect-mgmt", defects);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (set_prefetch) {
args[1] = prefetch;
args[2] = 0xab;
print_flag(get_prefetch, "drive prefetch", prefetch);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[1] = 0;
}
if (set_xfermode) {
args[1] = xfermode_requested;
args[2] = 3;
if (get_xfermode) {
print_flag(1, "xfermode", xfermode_requested);
interpret_xfermode(xfermode_requested);
}
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[1] = 0;
}
if (set_lookahead) {
args[2] = lookahead ? 0xaa : 0x55;
print_flag_on_off(get_lookahead, "drive read-lookahead", lookahead);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (set_apmmode) {
args[2] = (apmmode == 255) ? 0x85 /* disable */ : 0x05 /* set */; /* feature register */
args[1] = apmmode; /* sector count register 1-255 */
if (get_apmmode)
printf(" setting APM level to %s 0x%02lX (%ld)\n", (apmmode == 255) ? "disabled" : "", apmmode, apmmode);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[1] = 0;
}
if (set_wcache) {
#ifdef DO_FLUSHCACHE
#ifndef WIN_FLUSHCACHE
#define WIN_FLUSHCACHE 0xe7
#endif
#endif /* DO_FLUSHCACHE */
args[2] = wcache ? 0x02 : 0x82;
print_flag_on_off(get_wcache, "drive write-caching", wcache);
#ifdef DO_FLUSHCACHE
if (!wcache)
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &flushcache);
#endif /* DO_FLUSHCACHE */
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
#ifdef DO_FLUSHCACHE
if (!wcache)
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &flushcache);
#endif /* DO_FLUSHCACHE */
}
/* In code below, we do not preserve args[0], but the rest
is preserved, including args[2] */
args[2] = 0;
if (set_standbynow) {
#ifndef WIN_STANDBYNOW1
#define WIN_STANDBYNOW1 0xE0
#endif
#ifndef WIN_STANDBYNOW2
#define WIN_STANDBYNOW2 0x94
#endif
if (get_standbynow) printf(" issuing standby command\n");
args[0] = WIN_STANDBYNOW1;
ioctl_alt_or_warn(HDIO_DRIVE_CMD, args, WIN_STANDBYNOW2);
}
if (set_sleepnow) {
#ifndef WIN_SLEEPNOW1
#define WIN_SLEEPNOW1 0xE6
#endif
#ifndef WIN_SLEEPNOW2
#define WIN_SLEEPNOW2 0x99
#endif
if (get_sleepnow) printf(" issuing sleep command\n");
args[0] = WIN_SLEEPNOW1;
ioctl_alt_or_warn(HDIO_DRIVE_CMD, args, WIN_SLEEPNOW2);
}
if (set_seagate) {
args[0] = 0xfb;
if (get_seagate) printf(" disabling Seagate auto powersaving mode\n");
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (set_standby) {
args[0] = WIN_SETIDLE1;
args[1] = standby_requested;
if (get_standby) {
print_flag(1, "standby", standby_requested);
interpret_standby(standby_requested);
}
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[1] = 0;
}
#else /* HDIO_DRIVE_CMD */
if (force_operation) {
char buf[512];
flush_buffer_cache();
if (-1 == read(fd, buf, sizeof(buf)))
bb_perror_msg("read(%d bytes) failed (rc=-1)", sizeof(buf));
}
#endif /* HDIO_DRIVE_CMD */
if (get_mult || get_identity) {
multcount = -1;
if (ioctl(fd, HDIO_GET_MULTCOUNT, &multcount)) {
if (get_mult && ENABLE_IOCTL_HEX2STR_ERROR) /* To be coherent with ioctl_or_warn. */
bb_perror_msg("HDIO_GET_MULTCOUNT");
else
bb_perror_msg("ioctl %#x failed", HDIO_GET_MULTCOUNT);
} else if (get_mult) {
printf(fmt, "multcount", multcount);
on_off(multcount != 0);
}
}
if (get_io32bit) {
if (!ioctl_or_warn(fd, HDIO_GET_32BIT, &parm)) {
printf(" IO_support\t=%3ld (", parm);
if (parm == 0)
printf("default 16-bit)\n");
else if (parm == 2)
printf("16-bit)\n");
else if (parm == 1)
printf("32-bit)\n");
else if (parm == 3)
printf("32-bit w/sync)\n");
else if (parm == 8)
printf("Request-Queue-Bypass)\n");
else
printf("\?\?\?)\n");
}
}
if (get_unmask) {
if(!ioctl_or_warn(fd, HDIO_GET_UNMASKINTR, &parm))
print_value_on_off("unmaskirq", parm);
}
#if ENABLE_FEATURE_HDPARM_HDIO_GETSET_DMA
if (get_dma) {
if (!ioctl_or_warn(fd, HDIO_GET_DMA, &parm)) {
printf(fmt, "using_dma", parm);
if (parm == 8)
printf(" (DMA-Assisted-PIO)\n");
else
on_off(parm != 0);
}
}
#endif
if (get_dma_q) {
if(!ioctl_or_warn(fd, HDIO_GET_QDMA, &parm))
print_value_on_off("queue_depth", parm);
}
if (get_keep) {
if(!ioctl_or_warn(fd, HDIO_GET_KEEPSETTINGS, &parm))
print_value_on_off("keepsettings", parm);
}
if (get_nowerr) {
if(!ioctl_or_warn(fd, HDIO_GET_NOWERR, &parm))
print_value_on_off("nowerr", parm);
}
if (get_readonly) {
if(!ioctl_or_warn(fd, BLKROGET, &parm))
print_value_on_off("readonly", parm);
}
if (get_readahead) {
if(!ioctl_or_warn(fd, BLKRAGET, &parm))
print_value_on_off("readahead", parm);
}
if (get_geom) {
if (!ioctl_or_warn(fd, BLKGETSIZE, &parm)) {
struct hd_geometry g;
if (!ioctl_or_warn(fd, HDIO_GETGEO, &g))
printf(" geometry\t= %u/%u/%u, sectors = %ld, start = %ld\n",
g.cylinders, g.heads, g.sectors, parm, g.start);
}
}
#ifdef HDIO_DRIVE_CMD
if (get_powermode) {
#ifndef WIN_CHECKPOWERMODE1
#define WIN_CHECKPOWERMODE1 0xE5
#endif
#ifndef WIN_CHECKPOWERMODE2
#define WIN_CHECKPOWERMODE2 0x98
#endif
const char *state;
args[0] = WIN_CHECKPOWERMODE1;
if (ioctl_alt_or_warn(HDIO_DRIVE_CMD, args, WIN_CHECKPOWERMODE2)) {
if (errno != EIO || args[0] != 0 || args[1] != 0)
state = "unknown";
else
state = "sleeping";
} else
state = (args[2] == 255) ? "active/idle" : "standby";
args[1] = args[2] = 0;
printf(" drive state is: %s\n", state);
}
#endif
#if ENABLE_FEATURE_HDPARM_HDIO_DRIVE_RESET
if (perform_reset) {
ioctl_or_warn(fd, HDIO_DRIVE_RESET, NULL);
}
#endif /* FEATURE_HDPARM_HDIO_DRIVE_RESET */
#if ENABLE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF
if (perform_tristate) {
args[0] = 0;
args[1] = tristate;
ioctl_or_warn(fd, HDIO_TRISTATE_HWIF, &args);
}
#endif /* FEATURE_HDPARM_HDIO_TRISTATE_HWIF */
#if ENABLE_FEATURE_HDPARM_GET_IDENTITY
if (get_identity) {
struct hd_driveid id;
if (!ioctl(fd, HDIO_GET_IDENTITY, &id)) {
if (multcount != -1) {
id.multsect = multcount;
id.multsect_valid |= 1;
} else
id.multsect_valid &= ~1;
dump_identity(&id);
} else if (errno == -ENOMSG)
printf(" no identification info available\n");
else if (ENABLE_IOCTL_HEX2STR_ERROR) /* To be coherent with ioctl_or_warn */
bb_perror_msg("HDIO_GET_IDENTITY");
else
bb_perror_msg("ioctl %#x failed", HDIO_GET_IDENTITY);
}
if (get_IDentity) {
unsigned char args1[4+512]; /* = { ... } will eat 0.5k of rodata! */
memset(args1, 0, sizeof(args1));
args1[0] = WIN_IDENTIFY;
args1[3] = 1;
if (!ioctl_alt_or_warn(HDIO_DRIVE_CMD, args1, WIN_PIDENTIFY))
identify((void *)(args1 + 4));
}
#endif
#if ENABLE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF
if (set_busstate) {
if (get_busstate) {
print_flag(1, "bus state", busstate);
bus_state_value(busstate);
}
ioctl_or_warn(fd, HDIO_SET_BUSSTATE, (int *)(unsigned long)busstate);
}
if (get_busstate) {
if (!ioctl_or_warn(fd, HDIO_GET_BUSSTATE, &parm)) {
printf(fmt, "bus state", parm);
bus_state_value(parm);
}
}
#endif
if (reread_partn)
ioctl_or_warn(fd, BLKRRPART, NULL);
if (do_ctimings)
do_time(1 /*,fd*/); /* time cache */
if (do_timings)
do_time(0 /*,fd*/); /* time device */
if (do_flush)
flush_buffer_cache();
close(fd);
}
#if ENABLE_FEATURE_HDPARM_GET_IDENTITY
static int fromhex(unsigned char c)
{
if (isdigit(c))
return (c - '0');
if (c >= 'a' && c <= 'f')
return (c - ('a' - 10));
bb_error_msg_and_die("bad char: '%c' 0x%02x", c, c);
}
static void identify_from_stdin(void) ATTRIBUTE_NORETURN;
static void identify_from_stdin(void)
{
uint16_t sbuf[256];
unsigned char buf[1280];
unsigned char *b = (unsigned char *)buf;
int i;
xread(0, buf, 1280);
// Convert the newline-separated hex data into an identify block.
for (i = 0; i < 256; i++) {
int j;
for (j = 0; j < 4; j++)
sbuf[i] = (sbuf[i] << 4) + fromhex(*(b++));
}
// Parse the data.
identify(sbuf);
}
#else
void identify_from_stdin(void);
#endif
/* busybox specific stuff */
static void parse_opts(smallint *get, smallint *set, unsigned long *value, int min, int max)
{
if (get) {
*get = 1;
}
if (optarg) {
*set = 1;
*value = xatol_range(optarg, min, max);
}
}
static void parse_xfermode(int flag, smallint *get, smallint *set, int *value)
{
if (flag) {
*get = 1;
if (optarg) {
*value = translate_xfermode(optarg);
*set = (*value > -1);
}
}
}
/*------- getopt short options --------*/
static const char hdparm_options[] ALIGN1 =
"gfu::n::p:r::m::c::k::a::B:tT"
USE_FEATURE_HDPARM_GET_IDENTITY("iI")
USE_FEATURE_HDPARM_HDIO_GETSET_DMA("d::")
#ifdef HDIO_DRIVE_CMD
"S:D:P:X:K:A:L:W:CyYzZ"
#endif
USE_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF("U:")
#ifdef HDIO_GET_QDMA
#ifdef HDIO_SET_QDMA
"Q:"
#else
"Q"
#endif
#endif
USE_FEATURE_HDPARM_HDIO_DRIVE_RESET("w")
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF("x::b:")
USE_FEATURE_HDPARM_HDIO_SCAN_HWIF("R:");
/*-------------------------------------*/
/* our main() routine: */
int hdparm_main(int argc, char **argv) MAIN_EXTERNALLY_VISIBLE;
int hdparm_main(int argc, char **argv)
{
int c;
int flagcount = 0;
while ((c = getopt(argc, argv, hdparm_options)) >= 0) {
flagcount++;
USE_FEATURE_HDPARM_GET_IDENTITY(get_IDentity |= (c == 'I'));
USE_FEATURE_HDPARM_GET_IDENTITY(get_identity |= (c == 'i'));
get_geom |= (c == 'g');
do_flush |= (c == 'f');
if (c == 'u') parse_opts(&get_unmask, &set_unmask, &unmask, 0, 1);
USE_FEATURE_HDPARM_HDIO_GETSET_DMA(if (c == 'd') parse_opts(&get_dma, &set_dma, &dma, 0, 9));
if (c == 'n') parse_opts(&get_nowerr, &set_nowerr, &nowerr, 0, 1);
parse_xfermode((c == 'p'), &noisy_piomode, &set_piomode, &piomode);
if (c == 'r') parse_opts(&get_readonly, &set_readonly, &readonly, 0, 1);
if (c == 'm') parse_opts(&get_mult, &set_mult, &mult, 0, INT_MAX /*32*/);
if (c == 'c') parse_opts(&get_io32bit, &set_io32bit, &io32bit, 0, INT_MAX /*8*/);
if (c == 'k') parse_opts(&get_keep, &set_keep, &keep, 0, 1);
if (c == 'a') parse_opts(&get_readahead, &set_readahead, &Xreadahead, 0, INT_MAX);
if (c == 'B') parse_opts(&get_apmmode, &set_apmmode, &apmmode, 1, 255);
do_flush |= do_timings |= (c == 't');
do_flush |= do_ctimings |= (c == 'T');
#ifdef HDIO_DRIVE_CMD
if (c == 'S') parse_opts(&get_standby, &set_standby, &standby_requested, 0, INT_MAX);
if (c == 'D') parse_opts(&get_defects, &set_defects, &defects, 0, INT_MAX);
if (c == 'P') parse_opts(&get_prefetch, &set_prefetch, &prefetch, 0, INT_MAX);
parse_xfermode((c == 'X'), &get_xfermode, &set_xfermode, &xfermode_requested);
if (c == 'K') parse_opts(&get_dkeep, &set_dkeep, &prefetch, 0, 1);
if (c == 'A') parse_opts(&get_lookahead, &set_lookahead, &lookahead, 0, 1);
if (c == 'L') parse_opts(&get_doorlock, &set_doorlock, &doorlock, 0, 1);
if (c == 'W') parse_opts(&get_wcache, &set_wcache, &wcache, 0, 1);
get_powermode |= (c == 'C');
get_standbynow = set_standbynow |= (c == 'y');
get_sleepnow = set_sleepnow |= (c == 'Y');
reread_partn |= (c == 'z');
get_seagate = set_seagate |= (c == 'Z');
#endif
USE_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF(if (c == 'U') parse_opts(NULL, &unregister_hwif, &hwif, 0, INT_MAX));
#ifdef HDIO_GET_QDMA
if (c == 'Q') {
#ifdef HDIO_SET_QDMA
parse_opts(&get_dma_q, &set_dma_q, &dma_q, 0, INT_MAX);
#else
parse_opts(&get_dma_q, NULL, NULL, 0, 0);
#endif
}
#endif
USE_FEATURE_HDPARM_HDIO_DRIVE_RESET(perform_reset = (c == 'r'));
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF(if (c == 'x') parse_opts(NULL, &perform_tristate, &tristate, 0, 1));
USE_FEATURE_HDPARM_HDIO_TRISTATE_HWIF(if (c == 'b') parse_opts(&get_busstate, &set_busstate, &busstate, 0, 2));
#if ENABLE_FEATURE_HDPARM_HDIO_SCAN_HWIF
if (c == 'R') {
parse_opts(NULL, &scan_hwif, &hwif_data, 0, INT_MAX);
hwif_ctrl = xatoi_u((argv[optind]) ? argv[optind] : "");
hwif_irq = xatoi_u((argv[optind+1]) ? argv[optind+1] : "");
/* Move past the 2 additional arguments */
argv += 2;
argc -= 2;
}
#endif
}
/* When no flags are given (flagcount = 0), -acdgkmnru is assumed. */
if (!flagcount) {
get_mult = get_io32bit = get_unmask = get_keep = get_readonly = get_readahead = get_geom = 1;
USE_FEATURE_HDPARM_HDIO_GETSET_DMA(get_dma = 1);
}
argv += optind;
if (!*argv) {
if (ENABLE_FEATURE_HDPARM_GET_IDENTITY && !isatty(STDIN_FILENO))
identify_from_stdin(); /* EXIT */
bb_show_usage();
}
do {
process_dev(*argv++);
} while (*argv);
return EXIT_SUCCESS;
}