ndk-busybox/miscutils/hdparm.c
Denys Vlasenko f560422fa0 Big cleanup in config help and description
Redundant help texts (one which only repeats the description)
are deleted.

Descriptions and help texts are trimmed.

Some config options are moved, even across menus.

No config option _names_ are changed.

Signed-off-by: Denys Vlasenko <vda.linux@googlemail.com>
2017-01-10 14:58:54 +01:00

2202 lines
74 KiB
C

/* 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 GPLv2 or later, see file LICENSE in this source tree.
*
* 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
*/
//config:config HDPARM
//config: bool "hdparm"
//config: default y
//config: select PLATFORM_LINUX
//config: help
//config: Get/Set hard drive parameters. Primarily intended for ATA
//config: drives. Adds about 13k (or around 30k if you enable the
//config: FEATURE_HDPARM_GET_IDENTITY option)....
//config:
//config:config FEATURE_HDPARM_GET_IDENTITY
//config: bool "Support obtaining detailed information directly from drives"
//config: default y
//config: depends on HDPARM
//config: help
//config: Enable the -I and -i options to obtain detailed information
//config: directly from drives about their capabilities and supported ATA
//config: feature set. If no device name is specified, hdparm will read
//config: identify data from stdin. Enabling this option will add about 16k...
//config:
//config:config FEATURE_HDPARM_HDIO_SCAN_HWIF
//config: bool "Register an IDE interface (DANGEROUS)"
//config: default y
//config: depends on HDPARM
//config: help
//config: Enable the 'hdparm -R' option to register an IDE interface.
//config: This is dangerous stuff, so you should probably say N.
//config:
//config:config FEATURE_HDPARM_HDIO_UNREGISTER_HWIF
//config: bool "Un-register an IDE interface (DANGEROUS)"
//config: default y
//config: depends on HDPARM
//config: help
//config: Enable the 'hdparm -U' option to un-register an IDE interface.
//config: This is dangerous stuff, so you should probably say N.
//config:
//config:config FEATURE_HDPARM_HDIO_DRIVE_RESET
//config: bool "Perform device reset (DANGEROUS)"
//config: default y
//config: depends on HDPARM
//config: help
//config: Enable the 'hdparm -w' option to perform a device reset.
//config: This is dangerous stuff, so you should probably say N.
//config:
//config:config FEATURE_HDPARM_HDIO_TRISTATE_HWIF
//config: bool "Tristate device for hotswap (DANGEROUS)"
//config: default y
//config: depends on HDPARM
//config: help
//config: Enable the 'hdparm -x' option to tristate device for hotswap,
//config: and the '-b' option to get/set bus state. This is dangerous
//config: stuff, so you should probably say N.
//config:
//config:config FEATURE_HDPARM_HDIO_GETSET_DMA
//config: bool "Get/set using_dma flag"
//config: default y
//config: depends on HDPARM
//config: help
//config: Enable the 'hdparm -d' option to get/set using_dma flag.
//applet:IF_HDPARM(APPLET(hdparm, BB_DIR_SBIN, BB_SUID_DROP))
//kbuild:lib-$(CONFIG_HDPARM) += hdparm.o
//usage:#define hdparm_trivial_usage
//usage: "[OPTIONS] [DEVICE]"
//usage:#define hdparm_full_usage "\n\n"
//usage: " -a Get/set fs readahead"
//usage: "\n -A Set drive read-lookahead flag (0/1)"
//usage: "\n -b Get/set bus state (0 == off, 1 == on, 2 == tristate)"
//usage: "\n -B Set Advanced Power Management setting (1-255)"
//usage: "\n -c Get/set IDE 32-bit IO setting"
//usage: "\n -C Check IDE power mode status"
//usage: IF_FEATURE_HDPARM_HDIO_GETSET_DMA(
//usage: "\n -d Get/set using_dma flag")
//usage: "\n -D Enable/disable drive defect-mgmt"
//usage: "\n -f Flush buffer cache for device on exit"
//usage: "\n -g Display drive geometry"
//usage: "\n -h Display terse usage information"
//usage: IF_FEATURE_HDPARM_GET_IDENTITY(
//usage: "\n -i Display drive identification")
//usage: IF_FEATURE_HDPARM_GET_IDENTITY(
//usage: "\n -I Detailed/current information directly from drive")
//usage: "\n -k Get/set keep_settings_over_reset flag (0/1)"
//usage: "\n -K Set drive keep_features_over_reset flag (0/1)"
//usage: "\n -L Set drive doorlock (0/1) (removable harddisks only)"
//usage: "\n -m Get/set multiple sector count"
//usage: "\n -n Get/set ignore-write-errors flag (0/1)"
//usage: "\n -p Set PIO mode on IDE interface chipset (0,1,2,3,4,...)"
//usage: "\n -P Set drive prefetch count"
/* //usage: "\n -q Change next setting quietly" - not supported ib bbox */
//usage: "\n -Q Get/set DMA tagged-queuing depth (if supported)"
//usage: "\n -r Get/set readonly flag (DANGEROUS to set)"
//usage: IF_FEATURE_HDPARM_HDIO_SCAN_HWIF(
//usage: "\n -R Register an IDE interface (DANGEROUS)")
//usage: "\n -S Set standby (spindown) timeout"
//usage: "\n -t Perform device read timings"
//usage: "\n -T Perform cache read timings"
//usage: "\n -u Get/set unmaskirq flag (0/1)"
//usage: IF_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF(
//usage: "\n -U Unregister an IDE interface (DANGEROUS)")
//usage: "\n -v Defaults; same as -mcudkrag for IDE drives"
//usage: "\n -V Display program version and exit immediately"
//usage: IF_FEATURE_HDPARM_HDIO_DRIVE_RESET(
//usage: "\n -w Perform device reset (DANGEROUS)")
//usage: "\n -W Set drive write-caching flag (0/1) (DANGEROUS)"
//usage: IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF(
//usage: "\n -x Tristate device for hotswap (0/1) (DANGEROUS)")
//usage: "\n -X Set IDE xfer mode (DANGEROUS)"
//usage: "\n -y Put IDE drive in standby mode"
//usage: "\n -Y Put IDE drive to sleep"
//usage: "\n -Z Disable Seagate auto-powersaving mode"
//usage: "\n -z Reread partition table"
#include "libbb.h"
#include "common_bufsiz.h"
/* must be _after_ libbb.h: */
#include <linux/hdreg.h>
#include <sys/mount.h>
#if !defined(BLKGETSIZE64)
# define BLKGETSIZE64 _IOR(0x12,114,size_t)
#endif
/* 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 */
#define IS_GET 1
#define IS_SET 2
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 getset_readahead;
smallint getset_readonly;
smallint getset_unmask;
smallint getset_mult;
#ifdef HDIO_GET_QDMA
smallint getset_dma_q;
#endif
smallint getset_nowerr;
smallint getset_keep;
smallint getset_io32bit;
int piomode;
unsigned long Xreadahead;
unsigned long readonly;
unsigned long unmask;
unsigned long mult;
#ifdef HDIO_SET_QDMA
unsigned long dma_q;
#endif
unsigned long nowerr;
unsigned long keep;
unsigned long io32bit;
#if ENABLE_FEATURE_HDPARM_HDIO_GETSET_DMA
unsigned long dma;
smallint getset_dma;
#endif
#ifdef HDIO_DRIVE_CMD
smallint set_xfermode, get_xfermode;
smallint getset_dkeep;
smallint getset_standby;
smallint getset_lookahead;
smallint getset_prefetch;
smallint getset_defects;
smallint getset_wcache;
smallint getset_doorlock;
smallint set_seagate;
smallint set_standbynow;
smallint set_sleepnow;
smallint get_powermode;
smallint getset_apmmode;
int xfermode_requested;
unsigned long dkeep;
unsigned long standby_requested; /* 0..255 */
unsigned long lookahead;
unsigned long prefetch;
unsigned long defects;
unsigned long wcache;
unsigned long doorlock;
unsigned long apmmode;
#endif
IF_FEATURE_HDPARM_GET_IDENTITY( smallint get_IDentity;)
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( smallint getset_busstate;)
IF_FEATURE_HDPARM_HDIO_DRIVE_RESET( smallint perform_reset;)
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( smallint perform_tristate;)
IF_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF(smallint unregister_hwif;)
IF_FEATURE_HDPARM_HDIO_SCAN_HWIF( smallint scan_hwif;)
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( unsigned long busstate;)
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF( unsigned long tristate;)
IF_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
} FIX_ALIASING;
#define G (*(struct globals*)bb_common_bufsiz1)
#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 getset_readahead (G.getset_readahead )
#define getset_readonly (G.getset_readonly )
#define getset_unmask (G.getset_unmask )
#define getset_mult (G.getset_mult )
#define getset_dma_q (G.getset_dma_q )
#define getset_nowerr (G.getset_nowerr )
#define getset_keep (G.getset_keep )
#define getset_io32bit (G.getset_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 getset_dma (G.getset_dma )
#define set_xfermode (G.set_xfermode )
#define get_xfermode (G.get_xfermode )
#define getset_dkeep (G.getset_dkeep )
#define getset_standby (G.getset_standby )
#define getset_lookahead (G.getset_lookahead )
#define getset_prefetch (G.getset_prefetch )
#define getset_defects (G.getset_defects )
#define getset_wcache (G.getset_wcache )
#define getset_doorlock (G.getset_doorlock )
#define set_seagate (G.set_seagate )
#define set_standbynow (G.set_standbynow )
#define set_sleepnow (G.set_sleepnow )
#define get_powermode (G.get_powermode )
#define getset_apmmode (G.getset_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 getset_busstate (G.getset_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 )
#define INIT_G() do { \
setup_common_bufsiz(); \
BUILD_BUG_ON(sizeof(G) > COMMON_BUFSIZE); \
} while (0)
/* 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 %lu", s, arg);
on_off(arg);
}
}
static void print_value_on_off(const char *str, unsigned long argp)
{
printf(" %s\t= %2lu", 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) 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 recognize 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))
puts("powers-up in standby; SET FEATURES subcmd spins-up.");
if (((val[CONFIG]==STBY_NID_VAL) || (val[CONFIG]==PWRD_NID_VAL)) && (val[GEN_CONFIG] & INCOMPLETE))
puts("\n\tWARNING: ID response incomplete.\n\tFollowing data may be incorrect.\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;
puts("Configuration:");
/* 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]))
puts("\tCHS addressing not supported");
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
puts("no IORDY");
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))
puts("not supported");
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
puts("?");
}
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))
puts("\tATA sw reset required");
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))
puts("not supported");
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))
puts("\t\tInterleaved DMA support");
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) {
puts("Commands/features:\n"
"\tEnabled\tSupported:");
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])
) {
puts("Security:");
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) {
bb_putchar('\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 NOINLINE 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) {
static const masks_labels_t pio_modes = {
.masks = { 1, 2, ~3 },
.labels = "pio3 \0""pio4 \0""pio? \0",
};
print_flags(&pio_modes, id->eide_pio_modes);
}
if (id->capability & 1) {
if (id->dma_1word | id->dma_mword) {
static const int dma_wmode_masks[] = { 0x100, 1, 0x200, 2, 0x400, 4, 0xf800, 0xf8 };
printf("\n DMA modes: ");
print_flags_separated(dma_wmode_masks,
"*\0""sdma0 \0""*\0""sdma1 \0""*\0""sdma2 \0""*\0""sdma? \0",
id->dma_1word, NULL);
print_flags_separated(dma_wmode_masks,
"*\0""mdma0 \0""*\0""mdma1 \0""*\0""mdma2 \0""*\0""mdma? \0",
id->dma_mword, NULL);
}
}
if (((id->capability & 8) || (id->field_valid & 2)) && id->field_valid & 4) {
static const masks_labels_t ultra_modes1 = {
.masks = { 0x100, 0x001, 0x200, 0x002, 0x400, 0x004 },
.labels = "*\0""udma0 \0""*\0""udma1 \0""*\0""udma2 \0",
};
printf("\n UDMA modes: ");
print_flags(&ultra_modes1, id->dma_ultra);
#ifdef __NEW_HD_DRIVE_ID
if (id->hw_config & 0x2000) {
#else /* !__NEW_HD_DRIVE_ID */
if (id->word93 & 0x2000) {
#endif /* __NEW_HD_DRIVE_ID */
static const masks_labels_t ultra_modes2 = {
.masks = { 0x0800, 0x0008, 0x1000, 0x0010,
0x2000, 0x0020, 0x4000, 0x0040,
0x8000, 0x0080 },
.labels = "*\0""udma3 \0""*\0""udma4 \0"
"*\0""udma5 \0""*\0""udma6 \0"
"*\0""udma7 \0"
};
print_flags(&ultra_modes2, id->dma_ultra);
}
}
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 */
puts("\n\n * current active mode\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_all();
/* 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)
puts(" (tristate)");
else
printf(" (unknown: %u)\n", value);
}
#endif
#ifdef HDIO_DRIVE_CMD
static void interpret_standby(uint8_t standby)
{
printf(" (");
if (standby == 0) {
printf("off");
} else if (standby <= 240 || standby == 252 || standby == 255) {
/* standby is in 5 sec units */
unsigned t = standby * 5;
printf("%u minutes %u seconds", t / 60, t % 60);
} else if (standby <= 251) {
unsigned t = (standby - 240); /* t is in 30 min units */;
printf("%u.%c hours", t / 2, (t & 1) ? '5' : '0');
}
if (standby == 253)
printf("vendor-specific");
if (standby == 254)
printf("reserved");
puts(")");
}
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;
unsigned 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");
puts(")");
}
#endif /* HDIO_DRIVE_CMD */
static void print_flag(int flag, const char *s, unsigned long value)
{
if (flag)
printf(" setting %s to %lu\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_nonblocking(devname);*/
xmove_fd(xopen_nonblocking(devname), fd);
printf("\n%s:\n", devname);
if (getset_readahead == IS_SET) {
print_flag(getset_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 == IS_SET) {
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)
puts("auto-tune PIO mode");
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 (getset_io32bit == IS_SET) {
print_flag(getset_io32bit, "32-bit IO_support flag", io32bit);
ioctl_or_warn(fd, HDIO_SET_32BIT, (int *)io32bit);
}
if (getset_mult == IS_SET) {
print_flag(getset_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 (getset_readonly == IS_SET) {
print_flag_on_off(getset_readonly, "readonly", readonly);
ioctl_or_warn(fd, BLKROSET, &readonly);
}
if (getset_unmask == IS_SET) {
print_flag_on_off(getset_unmask, "unmaskirq", unmask);
ioctl_or_warn(fd, HDIO_SET_UNMASKINTR, (int *)unmask);
}
#if ENABLE_FEATURE_HDPARM_HDIO_GETSET_DMA
if (getset_dma == IS_SET) {
print_flag_on_off(getset_dma, "using_dma", dma);
ioctl_or_warn(fd, HDIO_SET_DMA, (int *)dma);
}
#endif /* FEATURE_HDPARM_HDIO_GETSET_DMA */
#ifdef HDIO_SET_QDMA
if (getset_dma_q == IS_SET) {
print_flag_on_off(getset_dma_q, "DMA queue_depth", dma_q);
ioctl_or_warn(fd, HDIO_SET_QDMA, (int *)dma_q);
}
#endif
if (getset_nowerr == IS_SET) {
print_flag_on_off(getset_nowerr, "nowerr", nowerr);
ioctl_or_warn(fd, HDIO_SET_NOWERR, (int *)nowerr);
}
if (getset_keep == IS_SET) {
print_flag_on_off(getset_keep, "keep_settings", keep);
ioctl_or_warn(fd, HDIO_SET_KEEPSETTINGS, (int *)keep);
}
#ifdef HDIO_DRIVE_CMD
if (getset_doorlock == IS_SET) {
args[0] = doorlock ? WIN_DOORLOCK : WIN_DOORUNLOCK;
args[2] = 0;
print_flag_on_off(getset_doorlock, "drive doorlock", doorlock);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[0] = WIN_SETFEATURES;
}
if (getset_dkeep == IS_SET) {
/* lock/unlock the drive's "feature" settings */
print_flag_on_off(getset_dkeep, "drive keep features", dkeep);
args[2] = dkeep ? 0x66 : 0xcc;
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (getset_defects == IS_SET) {
args[2] = defects ? 0x04 : 0x84;
print_flag(getset_defects, "drive defect-mgmt", defects);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (getset_prefetch == IS_SET) {
args[1] = prefetch;
args[2] = 0xab;
print_flag(getset_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;
print_flag(1, "xfermode", xfermode_requested);
interpret_xfermode(xfermode_requested);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
args[1] = 0;
}
if (getset_lookahead == IS_SET) {
args[2] = lookahead ? 0xaa : 0x55;
print_flag_on_off(getset_lookahead, "drive read-lookahead", lookahead);
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (getset_apmmode == IS_SET) {
/* feature register */
args[2] = (apmmode == 255) ? 0x85 /* disable */ : 0x05 /* set */;
args[1] = apmmode; /* sector count register 1-255 */
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 (getset_wcache == IS_SET) {
#ifdef DO_FLUSHCACHE
#ifndef WIN_FLUSHCACHE
#define WIN_FLUSHCACHE 0xe7
#endif
#endif /* DO_FLUSHCACHE */
args[2] = wcache ? 0x02 : 0x82;
print_flag_on_off(getset_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
puts(" issuing standby command");
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
puts(" issuing sleep command");
args[0] = WIN_SLEEPNOW1;
ioctl_alt_or_warn(HDIO_DRIVE_CMD, args, WIN_SLEEPNOW2);
}
if (set_seagate) {
args[0] = 0xfb;
puts(" disabling Seagate auto powersaving mode");
ioctl_or_warn(fd, HDIO_DRIVE_CMD, &args);
}
if (getset_standby == IS_SET) {
args[0] = WIN_SETIDLE1;
args[1] = standby_requested;
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 of 512 bytes failed");
}
#endif /* HDIO_DRIVE_CMD */
if (getset_mult || get_identity) {
multcount = -1;
if (ioctl(fd, HDIO_GET_MULTCOUNT, &multcount)) {
/* To be coherent with ioctl_or_warn. */
if (getset_mult && ENABLE_IOCTL_HEX2STR_ERROR)
bb_perror_msg("HDIO_GET_MULTCOUNT");
else
bb_perror_msg("ioctl %#x failed", HDIO_GET_MULTCOUNT);
} else if (getset_mult) {
printf(fmt, "multcount", multcount);
on_off(multcount != 0);
}
}
if (getset_io32bit) {
if (!ioctl_or_warn(fd, HDIO_GET_32BIT, &parm)) {
printf(" IO_support\t=%3ld (", parm);
if (parm == 0)
puts("default 16-bit)");
else if (parm == 2)
puts("16-bit)");
else if (parm == 1)
puts("32-bit)");
else if (parm == 3)
puts("32-bit w/sync)");
else if (parm == 8)
puts("Request-Queue-Bypass)");
else
puts("\?\?\?)");
}
}
if (getset_unmask) {
if (!ioctl_or_warn(fd, HDIO_GET_UNMASKINTR, &parm))
print_value_on_off("unmaskirq", parm);
}
#if ENABLE_FEATURE_HDPARM_HDIO_GETSET_DMA
if (getset_dma) {
if (!ioctl_or_warn(fd, HDIO_GET_DMA, &parm)) {
printf(fmt, "using_dma", parm);
if (parm == 8)
puts(" (DMA-Assisted-PIO)");
else
on_off(parm != 0);
}
}
#endif
#ifdef HDIO_GET_QDMA
if (getset_dma_q) {
if (!ioctl_or_warn(fd, HDIO_GET_QDMA, &parm))
print_value_on_off("queue_depth", parm);
}
#endif
if (getset_keep) {
if (!ioctl_or_warn(fd, HDIO_GET_KEEPSETTINGS, &parm))
print_value_on_off("keepsettings", parm);
}
if (getset_nowerr) {
if (!ioctl_or_warn(fd, HDIO_GET_NOWERR, &parm))
print_value_on_off("nowerr", parm);
}
if (getset_readonly) {
if (!ioctl_or_warn(fd, BLKROGET, &parm))
print_value_on_off("readonly", parm);
}
if (getset_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)
puts(" no identification info available");
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 (getset_busstate == IS_SET) {
print_flag(1, "bus state", busstate);
bus_state_value(busstate);
ioctl_or_warn(fd, HDIO_SET_BUSSTATE, (int *)(unsigned long)busstate);
}
if (getset_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) NORETURN;
static void identify_from_stdin(void)
{
uint16_t sbuf[256];
unsigned char buf[1280];
unsigned char *b = (unsigned char *)buf;
int i;
xread(STDIN_FILENO, 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 int parse_opts(unsigned long *value, int min, int max)
{
if (optarg) {
*value = xatol_range(optarg, min, max);
return IS_SET;
}
return IS_GET;
}
static int parse_opts_0_max(unsigned long *value, int max)
{
return parse_opts(value, 0, max);
}
static int parse_opts_0_1(unsigned long *value)
{
return parse_opts(value, 0, 1);
}
static int parse_opts_0_INTMAX(unsigned long *value)
{
return parse_opts(value, 0, INT_MAX);
}
static void parse_xfermode(int flag, smallint *get, smallint *set, int *value)
{
if (flag) {
*get = IS_GET;
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"
IF_FEATURE_HDPARM_GET_IDENTITY("iI")
IF_FEATURE_HDPARM_HDIO_GETSET_DMA("d::")
#ifdef HDIO_DRIVE_CMD
"S:D:P:X:K:A:L:W:CyYzZ"
#endif
IF_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF("U:")
#ifdef HDIO_GET_QDMA
#ifdef HDIO_SET_QDMA
"Q:"
#else
"Q"
#endif
#endif
IF_FEATURE_HDPARM_HDIO_DRIVE_RESET("w")
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF("x::b:")
IF_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;
INIT_G();
while ((c = getopt(argc, argv, hdparm_options)) >= 0) {
flagcount++;
IF_FEATURE_HDPARM_GET_IDENTITY(get_IDentity |= (c == 'I'));
IF_FEATURE_HDPARM_GET_IDENTITY(get_identity |= (c == 'i'));
get_geom |= (c == 'g');
do_flush |= (c == 'f');
if (c == 'u') getset_unmask = parse_opts_0_1(&unmask);
IF_FEATURE_HDPARM_HDIO_GETSET_DMA(
if (c == 'd') getset_dma = parse_opts_0_max(&dma, 9);
)
if (c == 'n') getset_nowerr = parse_opts_0_1(&nowerr);
parse_xfermode((c == 'p'), &noisy_piomode, &set_piomode, &piomode);
if (c == 'r') getset_readonly = parse_opts_0_1(&readonly);
if (c == 'm') getset_mult = parse_opts_0_INTMAX(&mult /*32*/);
if (c == 'c') getset_io32bit = parse_opts_0_INTMAX(&io32bit /*8*/);
if (c == 'k') getset_keep = parse_opts_0_1(&keep);
if (c == 'a') getset_readahead = parse_opts_0_INTMAX(&Xreadahead);
if (c == 'B') getset_apmmode = parse_opts(&apmmode, 1, 255);
do_flush |= do_timings |= (c == 't');
do_flush |= do_ctimings |= (c == 'T');
#ifdef HDIO_DRIVE_CMD
if (c == 'S') getset_standby = parse_opts_0_max(&standby_requested, 255);
if (c == 'D') getset_defects = parse_opts_0_INTMAX(&defects);
if (c == 'P') getset_prefetch = parse_opts_0_INTMAX(&prefetch);
parse_xfermode((c == 'X'), &get_xfermode, &set_xfermode, &xfermode_requested);
if (c == 'K') getset_dkeep = parse_opts_0_1(&prefetch);
if (c == 'A') getset_lookahead = parse_opts_0_1(&lookahead);
if (c == 'L') getset_doorlock = parse_opts_0_1(&doorlock);
if (c == 'W') getset_wcache = parse_opts_0_1(&wcache);
get_powermode |= (c == 'C');
set_standbynow |= (c == 'y');
set_sleepnow |= (c == 'Y');
reread_partn |= (c == 'z');
set_seagate |= (c == 'Z');
#endif
IF_FEATURE_HDPARM_HDIO_UNREGISTER_HWIF(if (c == 'U') unregister_hwif = parse_opts_0_INTMAX(&hwif));
#ifdef HDIO_GET_QDMA
if (c == 'Q') {
getset_dma_q = parse_opts_0_INTMAX(&dma_q);
}
#endif
IF_FEATURE_HDPARM_HDIO_DRIVE_RESET(perform_reset = (c == 'r'));
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF(if (c == 'x') perform_tristate = parse_opts_0_1(&tristate));
IF_FEATURE_HDPARM_HDIO_TRISTATE_HWIF(if (c == 'b') getset_busstate = parse_opts_0_max(&busstate, 2));
#if ENABLE_FEATURE_HDPARM_HDIO_SCAN_HWIF
if (c == 'R') {
scan_hwif = parse_opts_0_INTMAX(&hwif_data);
hwif_ctrl = xatoi_positive((argv[optind]) ? argv[optind] : "");
hwif_irq = xatoi_positive((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) {
getset_mult = getset_io32bit = getset_unmask = getset_keep = getset_readonly = getset_readahead = get_geom = IS_GET;
IF_FEATURE_HDPARM_HDIO_GETSET_DMA(getset_dma = IS_GET);
}
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;
}