/* * This program reads various mode pages and bits of other * information from a scsi device and interprets the raw data for you * with a report written to stdout. Usage: * * ./sginfo [options] /dev/sg2 [replace parameters] * * Options are: * -6 do 6 byte mode sense + select (default: 10 byte) * -a display all mode pages reported by the device: equivalent to '-t 63'. * -A display all mode pages and subpages reported by the device: equivalent * to '-t 63,255'. * -c access Cache control page. * -C access Control Page. * -d display defect lists (default format: index). * -D access disconnect-reconnect page. * -e access Read-Write error recovery page. * -E access Control Extension page. * -f access Format Device Page. * -Farg defect list format (-Flogical, -flba64, -Fphysical, -Findex, -Fhead) * -g access rigid disk geometry page. * -G display only "grown" defect list (default format: index) * -i display information from Inquiry command. * -I access Informational Exceptions page. * -l list known scsi devices on the system [deprecated] * -n access notch parameters page. * -N Negate (stop) storing to saved page (active with -R) * -P access Power Condition Page. * -r list known raw scsi devices on the system * -s display serial number (from INQUIRY VPD page) * -t access page number [and subpage ], try to decode * -u access page number [and subpage ], output in hex * -v show this program's version number * -V access Verify Error Recovery Page. * -T trace commands (for debugging, double for more debug) * -z do a single fetch for mode pages (rather than double fetch) * * Only one of the following three options can be specified. * None of these three implies the current values are returned. * -m Display modifiable fields instead of current values * -M Display manufacturer defaults instead of current values * -S Display saved defaults instead of current values * * -X Display output values in a list. * -R Replace parameters - best used with -X * * Eric Youngdale - 11/1/93. Version 1.0. * * Version 1.1: Ability to change parameters on cache page, support for * X front end. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2, or (at your option) * any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * SPDX-License-Identifier: GPL-2.0-or-later * * Michael Weller (eowmob at exp-math dot uni-essen dot de) * 11/23/94 massive extensions from 1.4a * 08/23/97 fix problems with defect lists * * Douglas Gilbert (dgilbert at interlog dot com) * 990628 port to sg .... (version 1.81) * up 4KB limit on defect list to 32KB * 'sginfo -l' also shows sg devices and mapping to other * scsi devices * 'sginfo' commands can take either an sd, sr (scd), st * or an sg device (all non-sg devices converted to a * sg device) * * 001208 Add Kurt Garloff's "-uno" flag for displaying info * from a page number. [version 1.90] * * Kurt Garloff * 20000715 allow displaying and modification of vendor specific pages * (unformatted - @ hexdatafield) * accept vendor lengths for those pages * enabled page saving * cleaned parameter parsing a bit (it's still a terrible mess!) * Use sr (instead of scd) and sg%d (instead of sga,b,...) in -l * and support much more devs in -l (incl. nosst) * Fix segfault in defect list (len=0xffff) and adapt formatting * to large disks. Support up to 256kB defect lists with * 0xB7 (12byte) command if necessary and fallback to 0x37 * (10byte) in case of failure. Report truncation. * sizeof(buffer) (which is sizeof(char*) == 4 or 32 bit archs) * was used incorrectly all over the place. Fixed. * [version 1.95] * Douglas Gilbert (dgilbert at interlog dot com) * 20020113 snprintf() type cleanup [version 1.96] * 20021211 correct sginfo MODE_SELECT, protect against block devices * that answer sg's ioctls. [version 1.97] * 20021228 scan for some "scd" as well as "sr" device names [1.98] * 20021020 Update control page [1.99] * * Thomas Steudten (thomas at steudten dot com) * 20040521 add -Fhead feature [version 2.04] * * Tim Hunt (tim at timhunt dot net) * 20050427 increase number of mapped SCSI disks devices * * Dave Johnson (djj at ccv dot brown dot edu) * 20051218 improve disk defect list handling */ /* * N.B. This utility is in maintenance mode only. This means that serious * bugs will be fixed but no new features or mode page changes will be * added. Please use the sdparm utility. D. Gilbert 20090316 */ #define _XOPEN_SOURCE 500 #ifndef _GNU_SOURCE #define _GNU_SOURCE 1 #endif static const char * version_str = "2.45 [20220425]"; #include #include #include #include #include #include #include #include #include #define __STDC_FORMAT_MACROS 1 #include #include #include #include #include #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "sg_io_linux.h" static int glob_fd; static char *device_name; #define MAX_SG_DEVS 8192 #define MAX_RESP6_SIZE 252 #define MAX_RESP10_SIZE (4*1024) #define MAX_BUFFER_SIZE MAX_RESP10_SIZE #define INQUIRY_RESP_INITIAL_LEN 36 #define MAX_INQFIELD_LEN 17 #define MAX_HEADS 127 #define HEAD_SORT_TOKEN 0x55 #define SIZEOF_BUFFER (16*1024) #define SIZEOF_BUFFER1 (16*1024) static uint8_t cbuffer[SIZEOF_BUFFER]; static uint8_t cbuffer1[SIZEOF_BUFFER1]; static uint8_t cbuffer2[SIZEOF_BUFFER1]; static char defect = 0; static char defectformat = 0x4; static char grown_defect = 0; static char negate_sp_bit = 0; static char replace = 0; static char serial_number = 0; static char x_interface = 0; static char single_fetch = 0; static char mode6byte = 0; /* defaults to 10 byte mode sense + select */ static char trace_cmd = 0; struct mpage_info { int page; int subpage; int page_control; int peri_type; int inq_byte6; /* EncServ and MChngr bits of interest */ int resp_len; }; /* declarations of functions decoding known mode pages */ static int common_disconnect_reconnect(struct mpage_info * mpi, const char * prefix); static int common_control(struct mpage_info * mpi, const char * prefix); static int common_control_extension(struct mpage_info * mpi, const char * prefix); static int common_proto_spec_lu(struct mpage_info * mpi, const char * prefix); static int common_proto_spec_port(struct mpage_info * mpi, const char * prefix); static int common_proto_spec_port_sp1(struct mpage_info * mpi, const char * prefix); static int common_proto_spec_port_sp2(struct mpage_info * mpi, const char * prefix); static int common_power_condition(struct mpage_info * mpi, const char * prefix); static int common_informational(struct mpage_info * mpi, const char * prefix); static int disk_error_recovery(struct mpage_info * mpi, const char * prefix); static int disk_format(struct mpage_info * mpi, const char * prefix); static int disk_verify_error_recovery(struct mpage_info * mpi, const char * prefix); static int disk_geometry(struct mpage_info * mpi, const char * prefix); static int disk_notch_parameters(struct mpage_info * mpi, const char * prefix); static int disk_cache(struct mpage_info * mpi, const char * prefix); static int disk_xor_control(struct mpage_info * mpi, const char * prefix); static int disk_background(struct mpage_info * mpi, const char * prefix); static int optical_memory(struct mpage_info * mpi, const char * prefix); static int cdvd_error_recovery(struct mpage_info * mpi, const char * prefix); static int cdvd_mrw(struct mpage_info * mpi, const char * prefix); static int cdvd_write_param(struct mpage_info * mpi, const char * prefix); static int cdvd_audio_control(struct mpage_info * mpi, const char * prefix); static int cdvd_timeout(struct mpage_info * mpi, const char * prefix); static int cdvd_device_param(struct mpage_info * mpi, const char * prefix); static int cdvd_cache(struct mpage_info * mpi, const char * prefix); static int cdvd_mm_capab(struct mpage_info * mpi, const char * prefix); static int cdvd_feature(struct mpage_info * mpi, const char * prefix); static int tape_data_compression(struct mpage_info * mpi, const char * prefix); static int tape_dev_config(struct mpage_info * mpi, const char * prefix); static int tape_medium_part1(struct mpage_info * mpi, const char * prefix); static int tape_medium_part2_4(struct mpage_info * mpi, const char * prefix); static int ses_services_manag(struct mpage_info * mpi, const char * prefix); static int spi4_training_config(struct mpage_info * mpi, const char * prefix); static int spi4_negotiated(struct mpage_info * mpi, const char * prefix); static int spi4_report_xfer(struct mpage_info * mpi, const char * prefix); enum page_class {PC_COMMON, PC_DISK, PC_TAPE, PC_CDVD, PC_SES, PC_SMC}; struct mpage_name_func { int page; int subpage; enum page_class pg_class; const char * name; int (*func)(struct mpage_info *, const char *); }; #define MP_LIST_PAGES 0x3f #define MP_LIST_SUBPAGES 0xff static struct mpage_name_func mpage_common[] = { { 0, 0, PC_COMMON, "Vendor (non-page format)", NULL}, { 2, 0, PC_COMMON, "Disconnect-Reconnect", common_disconnect_reconnect}, { 9, 0, PC_COMMON, "Peripheral device (obsolete)", NULL}, { 0xa, 0, PC_COMMON, "Control", common_control}, { 0xa, 1, PC_COMMON, "Control Extension", common_control_extension}, { 0x15, 0, PC_COMMON, "Extended", NULL}, { 0x16, 0, PC_COMMON, "Extended, device-type specific", NULL}, { 0x18, 0, PC_COMMON, "Protocol specific lu", common_proto_spec_lu}, { 0x19, 0, PC_COMMON, "Protocol specific port", common_proto_spec_port}, { 0x19, 1, PC_COMMON, "Protocol specific port, subpage 1 overload", common_proto_spec_port_sp1}, { 0x19, 2, PC_COMMON, "Protocol specific port, subpage 2 overload", common_proto_spec_port_sp2}, /* { 0x19, 2, PC_COMMON, "SPI-4 Saved Training configuration", spi4_training_config}, */ { 0x19, 3, PC_COMMON, "SPI-4 Negotiated Settings", spi4_negotiated}, { 0x19, 4, PC_COMMON, "SPI-4 Report transfer capabilities", spi4_report_xfer}, { 0x1a, 0, PC_COMMON, "Power Condition", common_power_condition}, { 0x1c, 0, PC_COMMON, "Informational Exceptions", common_informational}, { MP_LIST_PAGES, 0, PC_COMMON, "Return all pages", NULL}, }; static const int mpage_common_len = sizeof(mpage_common) / sizeof(mpage_common[0]); static struct mpage_name_func mpage_disk[] = { { 1, 0, PC_DISK, "Read-Write Error Recovery", disk_error_recovery}, { 3, 0, PC_DISK, "Format Device", disk_format}, { 4, 0, PC_DISK, "Rigid Disk Geometry", disk_geometry}, { 5, 0, PC_DISK, "Flexible Disk", NULL}, { 6, 0, PC_DISK, "Optical memory", optical_memory}, { 7, 0, PC_DISK, "Verify Error Recovery", disk_verify_error_recovery}, { 8, 0, PC_DISK, "Caching", disk_cache}, { 0xa, 0xf1, PC_DISK, "Parallel ATA control (SAT)", NULL}, { 0xb, 0, PC_DISK, "Medium Types Supported", NULL}, { 0xc, 0, PC_DISK, "Notch and Partition", disk_notch_parameters}, { 0x10, 0, PC_DISK, "XOR control", disk_xor_control}, { 0x1c, 1, PC_DISK, "Background control", disk_background}, }; static const int mpage_disk_len = sizeof(mpage_disk) / sizeof(mpage_disk[0]); static struct mpage_name_func mpage_cdvd[] = { { 1, 0, PC_CDVD, "Read-Write Error Recovery (cdvd)", cdvd_error_recovery}, { 3, 0, PC_CDVD, "MRW", cdvd_mrw}, { 5, 0, PC_CDVD, "Write parameters", cdvd_write_param}, { 8, 0, PC_CDVD, "Caching", cdvd_cache}, { 0xd, 0, PC_CDVD, "CD device parameters", cdvd_device_param}, { 0xe, 0, PC_CDVD, "CD audio control", cdvd_audio_control}, { 0x18, 0, PC_CDVD, "Feature set support & version", cdvd_feature}, { 0x1a, 0, PC_CDVD, "Power Condition", common_power_condition}, { 0x1c, 0, PC_CDVD, "Fault/failure reporting control", common_informational}, { 0x1d, 0, PC_CDVD, "Time-out & protect", cdvd_timeout}, { 0x2a, 0, PC_CDVD, "MM capabilities & mechanical status", cdvd_mm_capab}, }; static const int mpage_cdvd_len = sizeof(mpage_cdvd) / sizeof(mpage_cdvd[0]); static struct mpage_name_func mpage_tape[] = { { 1, 0, PC_TAPE, "Read-Write Error Recovery", disk_error_recovery}, { 0xf, 0, PC_TAPE, "Data compression", tape_data_compression}, { 0x10, 0, PC_TAPE, "Device configuration", tape_dev_config}, { 0x10, 1, PC_TAPE, "Device configuration extension", NULL}, { 0x11, 0, PC_TAPE, "Medium partition(1)", tape_medium_part1}, { 0x12, 0, PC_TAPE, "Medium partition(2)", tape_medium_part2_4}, { 0x13, 0, PC_TAPE, "Medium partition(3)", tape_medium_part2_4}, { 0x14, 0, PC_TAPE, "Medium partition(4)", tape_medium_part2_4}, { 0x1c, 0, PC_TAPE, "Informational Exceptions", common_informational}, { 0x1d, 0, PC_TAPE, "Medium configuration", NULL}, }; static const int mpage_tape_len = sizeof(mpage_tape) / sizeof(mpage_tape[0]); static struct mpage_name_func mpage_ses[] = { { 0x14, 0, PC_SES, "Enclosure services management", ses_services_manag}, }; static const int mpage_ses_len = sizeof(mpage_ses) / sizeof(mpage_ses[0]); static struct mpage_name_func mpage_smc[] = { { 0x1d, 0, PC_SMC, "Element address assignment", NULL}, { 0x1e, 0, PC_SMC, "Transport geometry parameters", NULL}, { 0x1f, 0, PC_SMC, "Device capabilities", NULL}, { 0x1f, 1, PC_SMC, "Extended device capabilities", NULL}, }; static const int mpage_smc_len = sizeof(mpage_smc) / sizeof(mpage_smc[0]); #define MAXPARM 64 static int next_parameter; static int n_replacement_values; static uint64_t replacement_values[MAXPARM]; static char is_hex[MAXPARM]; #define SMODE_SENSE 0x1a #define SMODE_SENSE_10 0x5a #define SMODE_SELECT 0x15 #define SMODE_SELECT_10 0x55 #define MPHEADER6_LEN 4 #define MPHEADER10_LEN 8 /* forward declarations */ static void usage(const char *); static void dump(void *buffer, unsigned int length); #define DXFER_NONE 0 #define DXFER_FROM_DEVICE 1 #define DXFER_TO_DEVICE 2 struct scsi_cmnd_io { uint8_t * cmnd; /* ptr to SCSI command block (cdb) */ size_t cmnd_len; /* number of bytes in SCSI command */ int dxfer_dir; /* DXFER_NONE, DXFER_FROM_DEVICE, or DXFER_TO_DEVICE */ uint8_t * dxferp; /* ptr to outgoing/incoming data */ size_t dxfer_len; /* bytes to be transferred to/from dxferp */ }; #define SENSE_BUFF_LEN 64 #define CMD_TIMEOUT 60000 /* 60,000 milliseconds (60 seconds) */ #define EBUFF_SZ 512 #define GENERAL_ERROR 1 #define UNKNOWN_OPCODE 2 #define BAD_CDB_FIELD 3 #define UNSUPPORTED_PARAM 4 #define DEVICE_ATTENTION 5 #define DEVICE_NOT_READY 6 #define DECODE_FAILED_TRY_HEX 9999 /* Returns 0 -> ok, 1 -> general error, 2 -> unknown opcode, 3 -> unsupported field in cdb, 4 -> unsupported param in data-in */ static int do_scsi_io(struct scsi_cmnd_io * sio) { uint8_t sense_b[SENSE_BUFF_LEN] SG_C_CPP_ZERO_INIT; struct sg_io_hdr io_hdr; struct sg_scsi_sense_hdr ssh; int res; memset(&io_hdr, 0, sizeof(struct sg_io_hdr)); io_hdr.interface_id = 'S'; io_hdr.cmd_len = sio->cmnd_len; io_hdr.mx_sb_len = sizeof(sense_b); if (DXFER_NONE == sio->dxfer_dir) io_hdr.dxfer_direction = SG_DXFER_NONE; else io_hdr.dxfer_direction = (DXFER_TO_DEVICE == sio->dxfer_dir) ? SG_DXFER_TO_DEV : SG_DXFER_FROM_DEV; io_hdr.dxfer_len = sio->dxfer_len; io_hdr.dxferp = sio->dxferp; io_hdr.cmdp = sio->cmnd; io_hdr.sbp = sense_b; io_hdr.timeout = CMD_TIMEOUT; if (trace_cmd) { printf(" cdb:"); dump(sio->cmnd, sio->cmnd_len); } if ((trace_cmd > 1) && (DXFER_TO_DEVICE == sio->dxfer_dir)) { printf(" additional data:\n"); dump(sio->dxferp, sio->dxfer_len); } if (ioctl(glob_fd, SG_IO, &io_hdr) < 0) { perror("do_scsi_cmd: SG_IO error"); return GENERAL_ERROR; } res = sg_err_category3(&io_hdr); switch (res) { case SG_LIB_CAT_RECOVERED: sg_chk_n_print3("do_scsi_cmd, continuing", &io_hdr, true); #if defined(__GNUC__) #if (__GNUC__ >= 7) __attribute__((fallthrough)); /* FALL THROUGH */ #endif #endif case SG_LIB_CAT_CLEAN: return 0; default: if (trace_cmd) { char ebuff[EBUFF_SZ]; snprintf(ebuff, EBUFF_SZ, "do_scsi_io: opcode=0x%x", sio->cmnd[0]); sg_chk_n_print3(ebuff, &io_hdr, true); } if (sg_normalize_sense(&io_hdr, &ssh)) { if (ILLEGAL_REQUEST == ssh.sense_key) { if (0x20 == ssh.asc) return UNKNOWN_OPCODE; else if (0x24 == ssh.asc) return BAD_CDB_FIELD; else if (0x26 == ssh.asc) return UNSUPPORTED_PARAM; } else if (UNIT_ATTENTION == ssh.sense_key) return DEVICE_ATTENTION; else if (NOT_READY == ssh.sense_key) return DEVICE_NOT_READY; } return GENERAL_ERROR; } } struct mpage_name_func * get_mpage_info(int page_no, int subpage_no, struct mpage_name_func * mpp, int elems) { int k; for (k = 0; k < elems; ++k, ++mpp) { if ((mpp->page == page_no) && (mpp->subpage == subpage_no)) return mpp; if (mpp->page > page_no) break; } return NULL; } enum page_class get_page_class(struct mpage_info * mpi) { switch (mpi->peri_type) { case 0: case 4: case 7: case 0xe: /* should be RBC */ return PC_DISK; case 1: case 2: return PC_TAPE; case 8: return PC_SMC; case 5: return PC_CDVD; case 0xd: return PC_SES; default: return PC_COMMON; } } struct mpage_name_func * get_mpage_name_func(struct mpage_info * mpi) { struct mpage_name_func * mpf = NULL; switch (get_page_class(mpi)) { case PC_DISK: mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_disk, mpage_disk_len); break; case PC_CDVD: mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_cdvd, mpage_cdvd_len); break; case PC_TAPE: mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_tape, mpage_tape_len); break; case PC_SES: mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_ses, mpage_ses_len); break; case PC_SMC: mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_smc, mpage_smc_len); break; case PC_COMMON: /* picked up it catch all next */ break; } if (NULL == mpf) { if ((PC_SES != get_page_class(mpi)) && (mpi->inq_byte6 & 0x40)) { /* check for attached enclosure services processor */ mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_ses, mpage_ses_len); } if ((PC_SMC != get_page_class(mpi)) && (mpi->inq_byte6 & 0x8)) { /* check for attached medium changer device */ mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_smc, mpage_smc_len); } } if (NULL == mpf) mpf = get_mpage_info(mpi->page, mpi->subpage, mpage_common, mpage_common_len); return mpf; } static char unkn_page_str[64]; static const char * get_page_name(struct mpage_info * mpi) { struct mpage_name_func * mpf; if (MP_LIST_PAGES == mpi->page) { if (MP_LIST_SUBPAGES == mpi->subpage) return "List supported pages and subpages"; else return "List supported pages"; } mpf = get_mpage_name_func(mpi); if ((NULL == mpf) || (NULL == mpf->name)) { if (mpi->subpage) snprintf(unkn_page_str, sizeof(unkn_page_str), "page number=0x%x, subpage number=0x%x", mpi->page, mpi->subpage); else snprintf(unkn_page_str, sizeof(unkn_page_str), "page number=0x%x", mpi->page); return unkn_page_str; } return mpf->name; } static void dump(void *buffer, unsigned int length) { unsigned int i; printf(" "); for (i = 0; i < length; i++) { #if 0 if (((uint8_t *) buffer)[i] > 0x20) printf(" %c ", (unsigned int) ((uint8_t *) buffer)[i]); else #endif printf("%02x ", (unsigned int) ((uint8_t *) buffer)[i]); if ((i % 16 == 15) && (i < (length - 1))) { printf("\n "); } } printf("\n"); } static int getnbyte(const uint8_t *pnt, int nbyte) { unsigned int result; int i; if (nbyte > 4) fprintf(stderr, "getnbyte() limited to 32 bits, nbyte=%d\n", nbyte); result = 0; for (i = 0; i < nbyte; i++) result = (result << 8) | (pnt[i] & 0xff); return result; } static int64_t getnbyte_ll(const uint8_t *pnt, int nbyte) { int64_t result; int i; if (nbyte > 8) fprintf(stderr, "getnbyte_ll() limited to 64 bits, nbyte=%d\n", nbyte); result = 0; for (i = 0; i < nbyte; i++) result = (result << 8) + (pnt[i] & 0xff); return result; } static int putnbyte(uint8_t *pnt, unsigned int value, unsigned int nbyte) { int i; for (i = nbyte - 1; i >= 0; i--) { pnt[i] = value & 0xff; value = value >> 8; } return 0; } #define REASON_SZ 128 static void check_parm_type(int i) { char reason[REASON_SZ]; if (i == 1 && is_hex[next_parameter] != 1) { snprintf(reason, REASON_SZ, "simple number (pos %i) instead of @ hexdatafield: %" PRIu64 , next_parameter, replacement_values[next_parameter]); usage(reason); } if (i != 1 && is_hex[next_parameter]) { snprintf(reason, REASON_SZ, "@ hexdatafield (pos %i) instead of a simple number: %" PRIu64 , next_parameter, replacement_values[next_parameter]); usage(reason); } } static void bitfield(uint8_t *pageaddr, const char * text, int mask, int shift) { if (x_interface && replace) { check_parm_type(0); *pageaddr = (*pageaddr & ~(mask << shift)) | ((replacement_values[next_parameter++] & mask) << shift); } else if (x_interface) printf("%d ", (*pageaddr >> shift) & mask); else printf("%-35s%d\n", text, (*pageaddr >> shift) & mask); } #if 0 static void notbitfield(uint8_t *pageaddr, char * text, int mask, int shift) { if (modifiable) { bitfield(pageaddr, text, mask, shift); return; } if (x_interface && replace) { check_parm_type(0); *pageaddr = (*pageaddr & ~(mask << shift)) | (((!replacement_values[next_parameter++]) & mask) << shift); } else if (x_interface) printf("%d ", !((*pageaddr >> shift) & mask)); else printf("%-35s%d\n", text, !((*pageaddr >> shift) & mask)); } #endif static void intfield(uint8_t * pageaddr, int nbytes, const char * text) { if (x_interface && replace) { check_parm_type(0); putnbyte(pageaddr, replacement_values[next_parameter++], nbytes); } else if (x_interface) printf("%d ", getnbyte(pageaddr, nbytes)); else printf("%-35s%d\n", text, getnbyte(pageaddr, nbytes)); } static void hexfield(uint8_t * pageaddr, int nbytes, const char * text) { if (x_interface && replace) { check_parm_type(0); putnbyte(pageaddr, replacement_values[next_parameter++], nbytes); } else if (x_interface) printf("%d ", getnbyte(pageaddr, nbytes)); else printf("%-35s0x%x\n", text, getnbyte(pageaddr, nbytes)); } static void hexdatafield(uint8_t * pageaddr, int nbytes, const char * text) { if (x_interface && replace) { uint8_t *ptr; unsigned tmp; /* Though in main we ensured that a @string has the right format, we have to check that we are working on a @ hexdata field */ check_parm_type(1); ptr = (uint8_t *) (unsigned long) (replacement_values[next_parameter++]); ptr++; /* Skip @ */ while (*ptr) { if (!nbytes) goto illegal; tmp = (*ptr >= 'a') ? (*ptr - 'a' + 'A') : *ptr; tmp -= (tmp >= 'A') ? 'A' - 10 : '0'; *pageaddr = tmp << 4; ptr++; tmp = (*ptr >= 'a') ? (*ptr - 'a' + 'A') : *ptr; tmp -= (tmp >= 'A') ? 'A' - 10 : '0'; *pageaddr++ += tmp; ptr++; nbytes--; } if (nbytes) { illegal: fputs("sginfo: incorrect number of bytes in @hexdatafield.\n", stdout); exit(2); } } else if (x_interface) { putchar('@'); while (nbytes-- > 0) printf("%02x", *pageaddr++); putchar(' '); } else { printf("%-35s0x", text); while (nbytes-- > 0) printf("%02x", *pageaddr++); putchar('\n'); } } /* Offset into mode sense (6 or 10 byte) response that actual mode page * starts at (relative to resp[0]). Returns -1 if problem */ static int modePageOffset(const uint8_t * resp, int len, int modese_6) { int bd_len; int resp_len = 0; int offset = -1; if (resp) { if (modese_6) { resp_len = resp[0] + 1; bd_len = resp[3]; offset = bd_len + MPHEADER6_LEN; } else { resp_len = (resp[0] << 8) + resp[1] + 2; bd_len = (resp[6] << 8) + resp[7]; /* LongLBA doesn't change this calculation */ offset = bd_len + MPHEADER10_LEN; } if ((offset + 2) > len) { printf("modePageOffset: raw_curr too small, offset=%d " "resp_len=%d bd_len=%d\n", offset, resp_len, bd_len); offset = -1; } else if ((offset + 2) > resp_len) { printf("modePageOffset: response length too short, resp_len=%d" " offset=%d bd_len=%d\n", resp_len, offset, bd_len); offset = -1; } } return offset; } /* Reads mode (sub-)page via 6 byte MODE SENSE, returns 0 if ok */ static int get_mode_page6(struct mpage_info * mpi, int dbd, uint8_t * resp, int sngl_fetch) { int status, off; uint8_t cmd[6]; struct scsi_cmnd_io sci; int initial_len = (sngl_fetch ? MAX_RESP6_SIZE : 4); memset(resp, 0, 4); cmd[0] = SMODE_SENSE; /* MODE SENSE (6) */ cmd[1] = 0x00 | (dbd ? 0x8 : 0); /* disable block descriptors bit */ cmd[2] = (mpi->page_control << 6) | mpi->page; cmd[3] = mpi->subpage; /* subpage code */ cmd[4] = initial_len; cmd[5] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = initial_len; sci.dxferp = resp; status = do_scsi_io(&sci); if (status) { if (mpi->subpage) fprintf(stdout, ">>> Unable to read %s mode page 0x%x, subpage " "0x%x [mode_sense_6]\n", get_page_name(mpi), mpi->page, mpi->subpage); else fprintf(stdout, ">>> Unable to read %s mode page (0x%x) " "[mode_sense_6]\n", get_page_name(mpi), mpi->page); return status; } mpi->resp_len = resp[0] + 1; if (sngl_fetch) { if (trace_cmd > 1) { off = modePageOffset(resp, mpi->resp_len, 1); if (off >= 0) { printf(" cdb response:\n"); dump(resp, mpi->resp_len); } } return status; } cmd[4] = mpi->resp_len; sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = mpi->resp_len; sci.dxferp = resp; status = do_scsi_io(&sci); if (status) { if (mpi->subpage) fprintf(stdout, ">>> Unable to read %s mode page 0x%x, subpage " "0x%x [mode_sense_6]\n", get_page_name(mpi), mpi->page, mpi->subpage); else fprintf(stdout, ">>> Unable to read %s mode page (0x%x) " "[mode_sense_6]\n", get_page_name(mpi), mpi->page); } else if (trace_cmd > 1) { off = modePageOffset(resp, mpi->resp_len, 1); if (off >= 0) { printf(" cdb response:\n"); dump(resp, mpi->resp_len); } } return status; } /* Reads mode (sub-)page via 10 byte MODE SENSE, returns 0 if ok */ static int get_mode_page10(struct mpage_info * mpi, int llbaa, int dbd, uint8_t * resp, int sngl_fetch) { int status, off; uint8_t cmd[10]; struct scsi_cmnd_io sci; int initial_len = (sngl_fetch ? MAX_RESP10_SIZE : 4); memset(resp, 0, 4); cmd[0] = SMODE_SENSE_10; /* MODE SENSE (10) */ cmd[1] = 0x00 | (llbaa ? 0x10 : 0) | (dbd ? 0x8 : 0); cmd[2] = (mpi->page_control << 6) | mpi->page; cmd[3] = mpi->subpage; cmd[4] = 0x00; /* (reserved) */ cmd[5] = 0x00; /* (reserved) */ cmd[6] = 0x00; /* (reserved) */ cmd[7] = (initial_len >> 8) & 0xff; cmd[8] = initial_len & 0xff; cmd[9] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = initial_len; sci.dxferp = resp; status = do_scsi_io(&sci); if (status) { if (mpi->subpage) fprintf(stdout, ">>> Unable to read %s mode page 0x%x, subpage " "0x%x [mode_sense_10]\n", get_page_name(mpi), mpi->page, mpi->subpage); else { fprintf(stdout, ">>> Unable to read %s mode page (0x%x) " "[mode_sense_10]\n", get_page_name(mpi), mpi->page); return status; } } mpi->resp_len = (resp[0] << 8) + resp[1] + 2; if (sngl_fetch) { if (trace_cmd > 1) { off = modePageOffset(resp, mpi->resp_len, 0); if (off >= 0) { printf(" cdb response:\n"); dump(resp, mpi->resp_len); } } return status; } cmd[7] = (mpi->resp_len >> 8) & 0xff; cmd[8] = (mpi->resp_len & 0xff); sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = mpi->resp_len; sci.dxferp = resp; status = do_scsi_io(&sci); if (status) { if (mpi->subpage) fprintf(stdout, ">>> Unable to read %s mode page 0x%x, subpage " "0x%x [mode_sense_10]\n", get_page_name(mpi), mpi->page, mpi->subpage); else fprintf(stdout, ">>> Unable to read %s mode page (0x%x) " "[mode_sense_10]\n", get_page_name(mpi), mpi->page); } else if (trace_cmd > 1) { off = modePageOffset(resp, mpi->resp_len, 0); if (off >= 0) { printf(" cdb response:\n"); dump(resp, mpi->resp_len); } } return status; } static int get_mode_page(struct mpage_info * mpi, int dbd, uint8_t * resp) { int res; if (mode6byte) res = get_mode_page6(mpi, dbd, resp, single_fetch); else res = get_mode_page10(mpi, 0, dbd, resp, single_fetch); if (UNKNOWN_OPCODE == res) fprintf(stdout, ">>>>> Try command again with%s '-6' " "argument\n", (mode6byte ? "out the" : " a")); else if (mpi->subpage && (BAD_CDB_FIELD == res)) fprintf(stdout, ">>>>> device doesn't seem to support " "subpages\n"); else if (DEVICE_ATTENTION == res) fprintf(stdout, ">>>>> device reports UNIT ATTENTION, check it or" " just try again\n"); else if (DEVICE_NOT_READY == res) fprintf(stdout, ">>>>> device NOT READY, does it need media?\n"); return res; } /* Contents should point to the mode parameter header that we obtained in a prior read operation. This way we do not have to work out the format of the beast. Assume 0 or 1 block descriptors. */ static int put_mode_page6(struct mpage_info * mpi, const uint8_t * msense6_resp, int sp_bit) { int status; int bdlen, resplen; uint8_t cmd[6]; struct scsi_cmnd_io sci; bdlen = msense6_resp[3]; resplen = msense6_resp[0] + 1; cmd[0] = SMODE_SELECT; cmd[1] = 0x10 | (sp_bit ? 1 : 0); /* always set PF bit */ cmd[2] = 0x00; cmd[3] = 0x00; /* (reserved) */ cmd[4] = resplen; /* parameter list length */ cmd[5] = 0x00; /* (reserved) */ memcpy(cbuffer1, msense6_resp, resplen); cbuffer1[0] = 0; /* Mask off the mode data length - reserved field */ cbuffer1[2] = 0; /* device-specific parameter is not defined and/or reserved for mode select */ #if 0 /* leave block descriptor alone */ if (bdlen > 0) { memset(cbuffer1 + MPHEADER6_LEN, 0, 4); /* clear 'number of blocks' for DAD device */ cbuffer1[MPHEADER6_LEN + 4] = 0; /* clear DAD density code. Why? */ /* leave DAD block length */ } #endif cbuffer1[MPHEADER6_LEN + bdlen] &= 0x7f; /* Mask PS bit */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_TO_DEVICE; sci.dxfer_len = resplen; sci.dxferp = cbuffer1; status = do_scsi_io(&sci); if (status) { if (mpi->subpage) fprintf(stdout, ">>> Unable to store %s mode page 0x%x," " subpage 0x%x [msel_6]\n", get_page_name(mpi), mpi->page, mpi->subpage); else fprintf(stdout, ">>> Unable to store %s mode page 0x%x [msel_6]\n", get_page_name(mpi), mpi->page); } return status; } /* Contents should point to the mode parameter header that we obtained in a prior read operation. This way we do not have to work out the format of the beast. Assume 0 or 1 block descriptors. */ static int put_mode_page10(struct mpage_info * mpi, const uint8_t * msense10_resp, int sp_bit) { int status; int bdlen, resplen; uint8_t cmd[10]; struct scsi_cmnd_io sci; bdlen = (msense10_resp[6] << 8) + msense10_resp[7]; resplen = (msense10_resp[0] << 8) + msense10_resp[1] + 2; cmd[0] = SMODE_SELECT_10; cmd[1] = 0x10 | (sp_bit ? 1 : 0); /* always set PF bit */ cmd[2] = 0x00; /* (reserved) */ cmd[3] = 0x00; /* (reserved) */ cmd[4] = 0x00; /* (reserved) */ cmd[5] = 0x00; /* (reserved) */ cmd[6] = 0x00; /* (reserved) */ cmd[7] = (resplen >> 8) & 0xff; cmd[8] = resplen & 0xff; cmd[9] = 0x00; /* (reserved) */ memcpy(cbuffer1, msense10_resp, resplen); cbuffer1[0] = 0; /* Mask off the mode data length */ cbuffer1[1] = 0; /* Mask off the mode data length */ cbuffer1[3] = 0; /* device-specific parameter is not defined and/or reserved for mode select */ #if 0 /* leave block descriptor alone */ if (bdlen > 0) { memset(cbuffer1 + MPHEADER10_LEN, 0, 4); /* clear 'number of blocks' for DAD device */ cbuffer1[MPHEADER10_LEN + 4] = 0; /* clear DAD density code. Why? */ /* leave DAD block length */ } #endif cbuffer1[MPHEADER10_LEN + bdlen] &= 0x7f; /* Mask PS bit */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_TO_DEVICE; sci.dxfer_len = resplen; sci.dxferp = cbuffer1; status = do_scsi_io(&sci); if (status) { if (mpi->subpage) fprintf(stdout, ">>> Unable to store %s mode page 0x%x," " subpage 0x%x [msel_10]\n", get_page_name(mpi), mpi->page, mpi->subpage); else fprintf(stdout, ">>> Unable to store %s mode page 0x%x " "[msel_10]\n", get_page_name(mpi), mpi->page); } return status; } static int put_mode_page(struct mpage_info * mpi, const uint8_t * msense_resp) { if (mode6byte) return put_mode_page6(mpi, msense_resp, ! negate_sp_bit); else return put_mode_page10(mpi, msense_resp, ! negate_sp_bit); } static int setup_mode_page(struct mpage_info * mpi, int nparam, uint8_t * buff, uint8_t ** o_pagestart) { int status, offset, rem_pglen; uint8_t * pgp; status = get_mode_page(mpi, 0, buff); if (status) { printf("\n"); return status; } offset = modePageOffset(buff, mpi->resp_len, mode6byte); if (offset < 0) { fprintf(stdout, "mode page=0x%x has bad page format\n", mpi->page); fprintf(stdout, " perhaps '-z' switch may help\n"); return -1; } pgp = buff + offset; *o_pagestart = pgp; rem_pglen = (0x40 & pgp[0]) ? ((pgp[2] << 8) + pgp[3]) : pgp[1]; if (x_interface && replace) { if ((nparam && (n_replacement_values != nparam)) || ((! nparam) && (n_replacement_values != rem_pglen))) { fprintf(stdout, "Wrong number of replacement values (%i instead " "of %i)\n", n_replacement_values, nparam ? nparam : rem_pglen); return 1; } next_parameter = 1; } return 0; } static int get_protocol_id(int port_not_lu, uint8_t * buff, int * proto_idp, int * offp) { int status, off, proto_id, spf; struct mpage_info mp_i; char b[64]; memset(&mp_i, 0, sizeof(mp_i)); mp_i.page = (port_not_lu ? 0x19 : 0x18); /* N.B. getting port or lu specific mode page (not subpage) */ status = get_mode_page(&mp_i, 0, buff); if (status) return status; off = modePageOffset(buff, mp_i.resp_len, mode6byte); if (off < 0) return off; spf = (buff[off] & 0x40) ? 1 : 0; /* subpages won't happen here */ proto_id = buff[off + (spf ? 5 : 2)] & 0xf; if (trace_cmd > 0) printf("Protocol specific %s, protocol_id=%s\n", (port_not_lu ? "port" : "lu"), sg_get_trans_proto_str(proto_id, sizeof(b), b)); if (proto_idp) *proto_idp = proto_id; if (offp) *offp = off; return 0; } static int disk_geometry(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 9, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------------------\n"); }; intfield(pagestart + 2, 3, "Number of cylinders"); intfield(pagestart + 5, 1, "Number of heads"); intfield(pagestart + 6, 3, "Starting cyl. write precomp"); intfield(pagestart + 9, 3, "Starting cyl. reduced current"); intfield(pagestart + 12, 2, "Device step rate"); intfield(pagestart + 14, 3, "Landing Zone Cylinder"); bitfield(pagestart + 17, "RPL", 3, 0); intfield(pagestart + 18, 1, "Rotational Offset"); intfield(pagestart + 20, 2, "Rotational Rate"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_disconnect_reconnect(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 11, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("------------------------------------\n"); }; intfield(pagestart + 2, 1, "Buffer full ratio"); intfield(pagestart + 3, 1, "Buffer empty ratio"); intfield(pagestart + 4, 2, "Bus Inactivity Limit (SAS: 100us)"); intfield(pagestart + 6, 2, "Disconnect Time Limit"); intfield(pagestart + 8, 2, "Connect Time Limit (SAS: 100us)"); intfield(pagestart + 10, 2, "Maximum Burst Size"); bitfield(pagestart + 12, "EMDP", 1, 7); bitfield(pagestart + 12, "Fair Arbitration (fcp:faa,fab,fac)", 0x7, 4); bitfield(pagestart + 12, "DIMM", 1, 3); bitfield(pagestart + 12, "DTDC", 0x7, 0); intfield(pagestart + 14, 2, "First Burst Size"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_control(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 21, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------\n"); } bitfield(pagestart + 2, "TST", 0x7, 5); bitfield(pagestart + 2, "TMF_ONLY", 1, 4); bitfield(pagestart + 2, "D_SENSE", 1, 2); bitfield(pagestart + 2, "GLTSD", 1, 1); bitfield(pagestart + 2, "RLEC", 1, 0); bitfield(pagestart + 3, "Queue Algorithm Modifier", 0xf, 4); bitfield(pagestart + 3, "QErr", 0x3, 1); bitfield(pagestart + 3, "DQue [obsolete]", 1, 0); bitfield(pagestart + 4, "TAS", 1, 7); bitfield(pagestart + 4, "RAC", 1, 6); bitfield(pagestart + 4, "UA_INTLCK_CTRL", 0x3, 4); bitfield(pagestart + 4, "SWP", 1, 3); bitfield(pagestart + 4, "RAERP [obs.]", 1, 2); bitfield(pagestart + 4, "UAAERP [obs.]", 1, 1); bitfield(pagestart + 4, "EAERP [obs.]", 1, 0); bitfield(pagestart + 5, "ATO", 1, 7); bitfield(pagestart + 5, "TAS", 1, 6); bitfield(pagestart + 5, "AUTOLOAD MODE", 0x7, 0); intfield(pagestart + 6, 2, "Ready AER Holdoff Period [obs.]"); intfield(pagestart + 8, 2, "Busy Timeout Period"); intfield(pagestart + 10, 2, "Extended self-test completion time"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_control_extension(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 4, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", get_page_name(mpi), mpi->page, mpi->subpage); printf("--------------------------------------------\n"); } bitfield(pagestart + 4, "TCMOS", 1, 2); bitfield(pagestart + 4, "SCSIP", 1, 1); bitfield(pagestart + 4, "IALUAE", 1, 0); bitfield(pagestart + 5, "Initial Priority", 0xf, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_informational(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 10, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------------------------\n"); } bitfield(pagestart + 2, "PERF", 1, 7); bitfield(pagestart + 2, "EBF", 1, 5); bitfield(pagestart + 2, "EWASC", 1, 4); bitfield(pagestart + 2, "DEXCPT", 1, 3); bitfield(pagestart + 2, "TEST", 1, 2); bitfield(pagestart + 2, "EBACKERR", 1, 1); bitfield(pagestart + 2, "LOGERR", 1, 0); bitfield(pagestart + 3, "MRIE", 0xf, 0); intfield(pagestart + 4, 4, "Interval Timer"); intfield(pagestart + 8, 4, "Report Count"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int disk_error_recovery(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 14, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------------------------\n"); } bitfield(pagestart + 2, "AWRE", 1, 7); bitfield(pagestart + 2, "ARRE", 1, 6); bitfield(pagestart + 2, "TB", 1, 5); bitfield(pagestart + 2, "RC", 1, 4); bitfield(pagestart + 2, "EER", 1, 3); bitfield(pagestart + 2, "PER", 1, 2); bitfield(pagestart + 2, "DTE", 1, 1); bitfield(pagestart + 2, "DCR", 1, 0); intfield(pagestart + 3, 1, "Read Retry Count"); intfield(pagestart + 4, 1, "Correction Span"); intfield(pagestart + 5, 1, "Head Offset Count"); intfield(pagestart + 6, 1, "Data Strobe Offset Count"); intfield(pagestart + 8, 1, "Write Retry Count"); intfield(pagestart + 10, 2, "Recovery Time Limit (ms)"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_error_recovery(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 10, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("------------------------------------------------\n"); } bitfield(pagestart + 2, "AWRE", 1, 7); bitfield(pagestart + 2, "ARRE", 1, 6); bitfield(pagestart + 2, "TB", 1, 5); bitfield(pagestart + 2, "RC", 1, 4); bitfield(pagestart + 2, "PER", 1, 2); bitfield(pagestart + 2, "DTE", 1, 1); bitfield(pagestart + 2, "DCR", 1, 0); intfield(pagestart + 3, 1, "Read Retry Count"); bitfield(pagestart + 7, "EMCDR", 3, 0); intfield(pagestart + 8, 1, "Write Retry Count"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_mrw(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 1, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("------------------------------------------------\n"); } bitfield(pagestart + 3, "LBA space", 1, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int disk_notch_parameters(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 6, cbuffer, &pagestart); if (status) { fprintf(stdout, "Special case: only give 6 fields to '-XR' since" " 'Pages Notched' is unchangeable\n"); return status; } if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------------------\n"); }; bitfield(pagestart + 2, "Notched Drive", 1, 7); bitfield(pagestart + 2, "Logical or Physical Notch", 1, 6); intfield(pagestart + 4, 2, "Max # of notches"); intfield(pagestart + 6, 2, "Active Notch"); if (pagestart[2] & 0x40) { intfield(pagestart + 8, 4, "Starting Boundary"); intfield(pagestart + 12, 4, "Ending Boundary"); } else { /* Hex is more meaningful for physical notches */ hexfield(pagestart + 8, 4, "Starting Boundary"); hexfield(pagestart + 12, 4, "Ending Boundary"); } if (x_interface && !replace) { #if 1 ; /* do nothing, skip this field */ #else if (1 == mpi->page_control) /* modifiable */ printf("0"); else printf("0x%8.8x%8.8x", getnbyte(pagestart + 16, 4), getnbyte(pagestart + 20, 4)); #endif }; if (!x_interface) printf("Pages Notched %8.8x %8.8x\n", getnbyte(pagestart + 16, 4), getnbyte(pagestart + 20, 4)); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static const char * formatname(int format) { switch(format) { case 0x0: return "logical block addresses (32 bit)"; case 0x3: return "logical block addresses (64 bit)"; case 0x4: return "bytes from index [Cyl:Head:Off]\n" "Offset -1 marks whole track as bad.\n"; case 0x5: return "physical blocks [Cyl:Head:Sect]\n" "Sector -1 marks whole track as bad.\n"; } return "Weird, unknown format"; } static int read_defect_list(int grown_only) { int i, len, reallen, table, k, defect_format; int status = 0; int header = 1; int sorthead = 0; uint8_t cmd[10]; uint8_t cmd12[12]; uint8_t *df = NULL; uint8_t *bp = NULL; uint8_t *heapp = NULL; unsigned int *headsp = NULL; int trunc; struct scsi_cmnd_io sci; if (defectformat == HEAD_SORT_TOKEN) { defectformat = 0x04; sorthead = 1; headsp = (unsigned int *)calloc(MAX_HEADS, sizeof(unsigned int)); if (headsp == NULL) { perror("malloc failed"); return status; } } for (table = grown_only; table < 2; table++) { if (heapp) { free(heapp); heapp = NULL; } bp = cbuffer; memset(bp, 0, 4); trunc = 0; reallen = -1; cmd[0] = 0x37; /* READ DEFECT DATA (10) */ cmd[1] = 0x00; cmd[2] = (table ? 0x08 : 0x10) | defectformat; /* List, Format */ cmd[3] = 0x00; /* (reserved) */ cmd[4] = 0x00; /* (reserved) */ cmd[5] = 0x00; /* (reserved) */ cmd[6] = 0x00; /* (reserved) */ cmd[7] = 0x00; /* Alloc len */ cmd[8] = 0x04; /* Alloc len (size finder) */ cmd[9] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = 4; sci.dxferp = bp; i = do_scsi_io(&sci); if (i) { fprintf(stdout, ">>> Unable to read %s defect data.\n", (table ? "grown (GLIST)" : "primary (PLIST)")); status |= i; continue; } if (trace_cmd > 1) { printf(" cdb response:\n"); dump(bp, 4); } /* * Check validity of response: * bp[0] reserved, must be zero * bp[1] bits 7-5 reserved, must be zero * bp[1] bits 4-3 should match table requested */ if (0 != bp[0] || (table ? 0x08 : 0x10) != (bp[1] & 0xf8)) { fprintf(stdout, ">>> Invalid header for %s defect list.\n", (table ? "grown (GLIST)" : "primary (PLIST)")); status |= 1; continue; } if (header) { printf("Defect Lists\n" "------------\n"); header = 0; } len = (bp[2] << 8) + bp[3]; if (len < 0xfff8) reallen = len; else { /* * List length is at or over capacity of READ DEFECT DATA (10) * Try to get actual length with READ DEFECT DATA (12) */ bp = cbuffer; memset(bp, 0, 8); cmd12[0] = 0xB7; /* READ DEFECT DATA (12) */ cmd12[1] = (table ? 0x08 : 0x10) | defectformat;/* List, Format */ cmd12[2] = 0x00; /* (reserved) */ cmd12[3] = 0x00; /* (reserved) */ cmd12[4] = 0x00; /* (reserved) */ cmd12[5] = 0x00; /* (reserved) */ cmd12[6] = 0x00; /* Alloc len */ cmd12[7] = 0x00; /* Alloc len */ cmd12[8] = 0x00; /* Alloc len */ cmd12[9] = 0x08; /* Alloc len (size finder) */ cmd12[10] = 0x00; /* reserved */ cmd12[11] = 0x00; /* control */ sci.cmnd = cmd12; sci.cmnd_len = sizeof(cmd12); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = 8; sci.dxferp = bp; i = do_scsi_io(&sci); if (i) { if (trace_cmd) { fprintf(stdout, ">>> No 12 byte command support, " "but list is too long for 10 byte version.\n" "List will be truncated at 8191 elements\n"); } goto trytenbyte; } if (trace_cmd > 1) { printf(" cdb response:\n"); dump(bp, 8); } /* * Check validity of response: * bp[0], bp[2] and bp[3] reserved, must be zero * bp[1] bits 7-5 reserved, must be zero * bp[1] bits 4-3 should match table we requested */ if (0 != bp[0] || 0 != bp[2] || 0 != bp[3] || ((table ? 0x08 : 0x10) != (bp[1] & 0xf8))) { if (trace_cmd) fprintf(stdout, ">>> Invalid header for %s defect list.\n", (table ? "grown (GLIST)" : "primary (PLIST)")); goto trytenbyte; } len = (bp[4] << 24) + (bp[5] << 16) + (bp[6] << 8) + bp[7]; reallen = len; } if (len > 0) { k = len + 8; /* length of defect list + header */ if (k > (int)sizeof(cbuffer)) { heapp = (uint8_t *)malloc(k); if (len > 0x80000 && NULL == heapp) { len = 0x80000; /* go large: 512 KB */ k = len + 8; heapp = (uint8_t *)malloc(k); } if (heapp != NULL) bp = heapp; } if (len > 0xfff0 && heapp != NULL) { cmd12[0] = 0xB7; /* READ DEFECT DATA (12) */ cmd12[1] = (table ? 0x08 : 0x10) | defectformat; /* List, Format */ cmd12[2] = 0x00; /* (reserved) */ cmd12[3] = 0x00; /* (reserved) */ cmd12[4] = 0x00; /* (reserved) */ cmd12[5] = 0x00; /* (reserved) */ cmd12[6] = 0x00; /* Alloc len */ cmd12[7] = (k >> 16) & 0xff; /* Alloc len */ cmd12[8] = (k >> 8) & 0xff; /* Alloc len */ cmd12[9] = (k & 0xff); /* Alloc len */ cmd12[10] = 0x00; /* reserved */ cmd12[11] = 0x00; /* control */ sci.cmnd = cmd12; sci.cmnd_len = sizeof(cmd12); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = k; sci.dxferp = bp; i = do_scsi_io(&sci); if (i) goto trytenbyte; if (trace_cmd > 1) { printf(" cdb response:\n"); dump(bp, 8); } reallen = (bp[4] << 24) + (bp[5] << 16) + (bp[6] << 8) + bp[7]; if (reallen > len) { trunc = 1; } df = (uint8_t *) (bp + 8); } else { trytenbyte: if (len > 0xfff8) { len = 0xfff8; trunc = 1; } k = len + 4; /* length of defect list + header */ if (k > (int)sizeof(cbuffer) && NULL == heapp) { heapp = (uint8_t *)malloc(k); if (heapp != NULL) bp = heapp; } if (k > (int)sizeof(cbuffer) && NULL == heapp) { bp = cbuffer; k = sizeof(cbuffer); len = k - 4; trunc = 1; } cmd[0] = 0x37; /* READ DEFECT DATA (10) */ cmd[1] = 0x00; cmd[2] = (table ? 0x08 : 0x10) | defectformat; /* List, Format */ cmd[3] = 0x00; /* (reserved) */ cmd[4] = 0x00; /* (reserved) */ cmd[5] = 0x00; /* (reserved) */ cmd[6] = 0x00; /* (reserved) */ cmd[7] = (k >> 8); /* Alloc len */ cmd[8] = (k & 0xff); /* Alloc len */ cmd[9] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = k; sci.dxferp = bp; i = do_scsi_io(&sci); df = (uint8_t *) (bp + 4); } } if (i) { fprintf(stdout, ">>> Unable to read %s defect data.\n", (table ? "grown (GLIST)" : "primary (PLIST)")); status |= i; continue; } else { if (table && !status && !sorthead) printf("\n"); defect_format = (bp[1] & 0x7); if (-1 == reallen) { printf("at least "); reallen = len; } printf("%d entries (%d bytes) in %s table.\n", reallen / ((0 == defect_format) ? 4 : 8), reallen, table ? "grown (GLIST)" : "primary (PLIST)"); if (!sorthead) printf("Format (%x) is: %s\n", defect_format, formatname(defect_format)); i = 0; switch (defect_format) { case 4: /* bytes from index */ while (len > 0) { snprintf((char *)cbuffer1, 40, "%6d:%3u:%8d", getnbyte(df, 3), df[3], getnbyte(df + 4, 4)); if (sorthead == 0) printf("%19s", (char *)cbuffer1); else if (df[3] < MAX_HEADS) headsp[df[3]]++; len -= 8; df += 8; i++; if (i >= 4 && !sorthead) { printf("\n"); i = 0; } else if (!sorthead) printf("|"); } break; case 5: /* physical sector */ while (len > 0) { snprintf((char *)cbuffer1, 40, "%6d:%2u:%5d", getnbyte(df, 3), df[3], getnbyte(df + 4, 4)); if (sorthead == 0) printf("%15s", (char *)cbuffer1); else if (df[3] < MAX_HEADS) headsp[df[3]]++; len -= 8; df += 8; i++; if (i >= 5 && !sorthead) { printf("\n"); i = 0; } else if (!sorthead) printf("|"); } break; case 0: /* lba (32 bit) */ while (len > 0) { printf("%10d", getnbyte(df, 4)); len -= 4; df += 4; i++; if (i >= 7) { printf("\n"); i = 0; } else printf("|"); } break; case 3: /* lba (64 bit) */ while (len > 0) { printf("%15" PRId64 , getnbyte_ll(df, 8)); len -= 8; df += 8; i++; if (i >= 5) { printf("\n"); i = 0; } else printf("|"); } break; default: printf("unknown defect list format: %d\n", defect_format); break; } if (i && !sorthead) printf("\n"); } if (trunc) printf("[truncated]\n"); } if (heapp) { free(heapp); heapp = NULL; } if (sorthead) { printf("Format is: [head:# entries for this head in list]\n\n"); for (i=0; i 0) { printf("%3d: %u\n", i, headsp[i]); } } free(headsp); } printf("\n"); return status; } static int disk_cache(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 21, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------\n"); }; bitfield(pagestart + 2, "Initiator Control", 1, 7); bitfield(pagestart + 2, "ABPF", 1, 6); bitfield(pagestart + 2, "CAP", 1, 5); bitfield(pagestart + 2, "DISC", 1, 4); bitfield(pagestart + 2, "SIZE", 1, 3); bitfield(pagestart + 2, "Write Cache Enabled", 1, 2); bitfield(pagestart + 2, "MF", 1, 1); bitfield(pagestart + 2, "Read Cache Disabled", 1, 0); bitfield(pagestart + 3, "Demand Read Retention Priority", 0xf, 4); bitfield(pagestart + 3, "Demand Write Retention Priority", 0xf, 0); intfield(pagestart + 4, 2, "Disable Pre-fetch Transfer Length"); intfield(pagestart + 6, 2, "Minimum Pre-fetch"); intfield(pagestart + 8, 2, "Maximum Pre-fetch"); intfield(pagestart + 10, 2, "Maximum Pre-fetch Ceiling"); bitfield(pagestart + 12, "FSW", 1, 7); bitfield(pagestart + 12, "LBCSS", 1, 6); bitfield(pagestart + 12, "DRA", 1, 5); bitfield(pagestart + 12, "NV_DIS", 1, 0); intfield(pagestart + 13, 1, "Number of Cache Segments"); intfield(pagestart + 14, 2, "Cache Segment size"); intfield(pagestart + 17, 3, "Non-Cache Segment size"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int disk_format(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 13, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------------\n"); }; intfield(pagestart + 2, 2, "Tracks per Zone"); intfield(pagestart + 4, 2, "Alternate sectors per zone"); intfield(pagestart + 6, 2, "Alternate tracks per zone"); intfield(pagestart + 8, 2, "Alternate tracks per lu"); intfield(pagestart + 10, 2, "Sectors per track"); intfield(pagestart + 12, 2, "Data bytes per physical sector"); intfield(pagestart + 14, 2, "Interleave"); intfield(pagestart + 16, 2, "Track skew factor"); intfield(pagestart + 18, 2, "Cylinder skew factor"); bitfield(pagestart + 20, "Supports Soft Sectoring", 1, 7); bitfield(pagestart + 20, "Supports Hard Sectoring", 1, 6); bitfield(pagestart + 20, "Removable Medium", 1, 5); bitfield(pagestart + 20, "Surface", 1, 4); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int disk_verify_error_recovery(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 7, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-------------------------------------\n"); } bitfield(pagestart + 2, "EER", 1, 3); bitfield(pagestart + 2, "PER", 1, 2); bitfield(pagestart + 2, "DTE", 1, 1); bitfield(pagestart + 2, "DCR", 1, 0); intfield(pagestart + 3, 1, "Verify Retry Count"); intfield(pagestart + 4, 1, "Verify Correction Span (bits)"); intfield(pagestart + 10, 2, "Verify Recovery Time Limit (ms)"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } #if 0 static int peripheral_device_page(struct mpage_info * mpi, const char * prefix) { static char *idents[] = { "X3.131: Small Computer System Interface", "X3.91M-1987: Storage Module Interface", "X3.170: Enhanced Small Device Interface", "X3.130-1986; X3T9.3/87-002: IPI-2", "X3.132-1987; X3.147-1988: IPI-3" }; int status; unsigned ident; uint8_t *pagestart; char *name; status = setup_mode_page(mpi, 2, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("---------------------------------\n"); }; #if 0 dump(pagestart, 20); pagestart[1] += 2; /*TEST */ cbuffer[8] += 2; /*TEST */ #endif ident = getnbyte(pagestart + 2, 2); if (ident < (sizeof(idents) / sizeof(char *))) name = idents[ident]; else if (ident < 0x8000) name = "Reserved"; else name = "Vendor Specific"; #ifdef DPG_CHECK_THIS_OUT bdlen = pagestart[1] - 6; if (bdlen < 0) bdlen = 0; else { status = setup_mode_page(mpi, 2, cbuffer, &bdlen, &pagestart); if (status) return status; } hexfield(pagestart + 2, 2, "Interface Identifier"); if (!x_interface) { for (ident = 0; ident < 35; ident++) putchar(' '); puts(name); } hexdatafield(pagestart + 8, bdlen, "Vendor Specific Data"); #endif if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); if (x_interface) puts(name); return 0; } #endif static int common_power_condition(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 4, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("--------------------------------\n"); } bitfield(pagestart + 3, "Idle", 1, 1); bitfield(pagestart + 3, "Standby", 1, 0); intfield(pagestart + 4, 4, "Idle Condition counter (100ms)"); intfield(pagestart + 8, 4, "Standby Condition counter (100ms)"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int disk_xor_control(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 5, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("--------------------------------\n"); } bitfield(pagestart + 2, "XORDS", 1, 1); intfield(pagestart + 4, 4, "Maximum XOR write size"); intfield(pagestart + 12, 4, "Maximum regenerate size"); intfield(pagestart + 16, 4, "Maximum rebuild transfer size"); intfield(pagestart + 22, 2, "Rebuild delay"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int disk_background(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 4, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", get_page_name(mpi), mpi->page, mpi->subpage); printf("--------------------------------------------\n"); } bitfield(pagestart + 4, "Enable background medium scan", 1, 0); bitfield(pagestart + 5, "Enable pre-scan", 1, 0); intfield(pagestart + 6, 2, "BMS interval time (hour)"); intfield(pagestart + 8, 2, "Pre-scan timeout value (hour)"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int optical_memory(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 1, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("--------------------------------\n"); } bitfield(pagestart + 2, "RUBR", 1, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_write_param(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 20, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("--------------------------------\n"); } bitfield(pagestart + 2, "BUFE", 1, 6); bitfield(pagestart + 2, "LS_V", 1, 5); bitfield(pagestart + 2, "Test Write", 1, 4); bitfield(pagestart + 2, "Write Type", 0xf, 0); bitfield(pagestart + 3, "MultiSession", 3, 6); bitfield(pagestart + 3, "FP", 1, 5); bitfield(pagestart + 3, "Copy", 1, 4); bitfield(pagestart + 3, "Track Mode", 0xf, 0); bitfield(pagestart + 4, "Data Block type", 0xf, 0); intfield(pagestart + 5, 1, "Link size"); bitfield(pagestart + 7, "Initiator app. code", 0x3f, 0); intfield(pagestart + 8, 1, "Session Format"); intfield(pagestart + 10, 4, "Packet size"); intfield(pagestart + 14, 2, "Audio Pause Length"); hexdatafield(pagestart + 16, 16, "Media Catalog number"); hexdatafield(pagestart + 32, 16, "Int. standard recording code"); hexdatafield(pagestart + 48, 1, "Subheader byte 1"); hexdatafield(pagestart + 49, 1, "Subheader byte 2"); hexdatafield(pagestart + 50, 1, "Subheader byte 3"); hexdatafield(pagestart + 51, 1, "Subheader byte 4"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_audio_control(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 10, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("--------------------------------\n"); } bitfield(pagestart + 2, "IMMED", 1, 2); bitfield(pagestart + 2, "SOTC", 1, 1); bitfield(pagestart + 8, "CDDA out port 0, channel select", 0xf, 0); intfield(pagestart + 9, 1, "Channel port 0 volume"); bitfield(pagestart + 10, "CDDA out port 1, channel select", 0xf, 0); intfield(pagestart + 11, 1, "Channel port 1 volume"); bitfield(pagestart + 12, "CDDA out port 2, channel select", 0xf, 0); intfield(pagestart + 13, 1, "Channel port 2 volume"); bitfield(pagestart + 14, "CDDA out port 3, channel select", 0xf, 0); intfield(pagestart + 15, 1, "Channel port 3 volume"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_timeout(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 6, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------------------\n"); } bitfield(pagestart + 4, "G3Enable", 1, 3); bitfield(pagestart + 4, "TMOE", 1, 2); bitfield(pagestart + 4, "DISP", 1, 1); bitfield(pagestart + 4, "SWPP", 1, 0); intfield(pagestart + 6, 2, "Group 1 minimum time-out"); intfield(pagestart + 8, 2, "Group 2 minimum time-out"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_device_param(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 3, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("------------------------------------\n"); } bitfield(pagestart + 3, "Inactivity timer multiplier", 0xf, 0); intfield(pagestart + 4, 2, "MSF-S units per MSF_M unit"); intfield(pagestart + 6, 2, "MSF-F units per MSF_S unit"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } /* This is not a standard t10.org MMC mode page (it is now "protocol specific lu" mode page). This definition was found in Hitachi GF-2050/GF-2055 DVD-RAM drive SCSI reference manual. */ static int cdvd_feature(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 12, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------\n"); } intfield(pagestart + 2, 2, "DVD feature set"); intfield(pagestart + 4, 2, "CD audio"); intfield(pagestart + 6, 2, "Embedded changer"); intfield(pagestart + 8, 2, "Packet SMART"); intfield(pagestart + 10, 2, "Persistent prevent(MESN)"); intfield(pagestart + 12, 2, "Event status notification"); intfield(pagestart + 14, 2, "Digital output"); intfield(pagestart + 16, 2, "CD sequential recordable"); intfield(pagestart + 18, 2, "DVD sequential recordable"); intfield(pagestart + 20, 2, "Random recordable"); intfield(pagestart + 22, 2, "Key management"); intfield(pagestart + 24, 2, "Partial recorded CD media read"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_mm_capab(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 49, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 2, "DVD-RAM read", 1, 5); bitfield(pagestart + 2, "DVD-R read", 1, 4); bitfield(pagestart + 2, "DVD-ROM read", 1, 3); bitfield(pagestart + 2, "Method 2", 1, 2); bitfield(pagestart + 2, "CD-RW read", 1, 1); bitfield(pagestart + 2, "CD-R read", 1, 0); bitfield(pagestart + 3, "DVD-RAM write", 1, 5); bitfield(pagestart + 3, "DVD-R write", 1, 4); bitfield(pagestart + 3, "DVD-ROM write", 1, 3); bitfield(pagestart + 3, "Test Write", 1, 2); bitfield(pagestart + 3, "CD-RW write", 1, 1); bitfield(pagestart + 3, "CD-R write", 1, 0); bitfield(pagestart + 4, "BUF", 1, 7); bitfield(pagestart + 4, "MultiSession", 1, 6); bitfield(pagestart + 4, "Mode 2 Form 2", 1, 5); bitfield(pagestart + 4, "Mode 2 Form 1", 1, 4); bitfield(pagestart + 4, "Digital port (2)", 1, 3); bitfield(pagestart + 4, "Digital port (1)", 1, 2); bitfield(pagestart + 4, "Composite", 1, 1); bitfield(pagestart + 4, "Audio play", 1, 0); bitfield(pagestart + 5, "Read bar code", 1, 7); bitfield(pagestart + 5, "UPC", 1, 6); bitfield(pagestart + 5, "ISRC", 1, 5); bitfield(pagestart + 5, "C2 pointers supported", 1, 4); bitfield(pagestart + 5, "R-W de-interleaved & corrected", 1, 3); bitfield(pagestart + 5, "R-W supported", 1, 2); bitfield(pagestart + 5, "CD-DA stream is accurate", 1, 1); bitfield(pagestart + 5, "CD-DA commands supported", 1, 0); bitfield(pagestart + 6, "Loading mechanism type", 7, 5); bitfield(pagestart + 6, "Eject (individual or magazine)", 1, 3); bitfield(pagestart + 6, "Prevent jumper", 1, 2); bitfield(pagestart + 6, "Lock state", 1, 1); bitfield(pagestart + 6, "Lock", 1, 0); bitfield(pagestart + 7, "R-W in lead-in", 1, 5); bitfield(pagestart + 7, "Side change capable", 1, 4); bitfield(pagestart + 7, "S/W slot selection", 1, 3); bitfield(pagestart + 7, "Changer supports disc present", 1, 2); bitfield(pagestart + 7, "Separate channel mute", 1, 1); bitfield(pagestart + 7, "Separate volume levels", 1, 0); intfield(pagestart + 10, 2, "number of volume level supported"); intfield(pagestart + 12, 2, "Buffer size supported"); bitfield(pagestart + 17, "Length", 3, 4); bitfield(pagestart + 17, "LSBF", 1, 3); bitfield(pagestart + 17, "RCK", 1, 2); bitfield(pagestart + 17, "BCKF", 1, 1); intfield(pagestart + 22, 2, "Copy management revision supported"); bitfield(pagestart + 27, "Rotation control selected", 3, 0); intfield(pagestart + 28, 2, "Current write speed selected"); intfield(pagestart + 30, 2, "# of lu speed performance tables"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int cdvd_cache(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 2, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("-----------------------\n"); }; bitfield(pagestart + 2, "Write Cache Enabled", 1, 2); bitfield(pagestart + 2, "Read Cache Disabled", 1, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int tape_data_compression(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 6, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 2, "DCE", 1, 7); bitfield(pagestart + 2, "DCC", 1, 6); bitfield(pagestart + 3, "DDE", 1, 7); bitfield(pagestart + 3, "RED", 3, 5); intfield(pagestart + 4, 4, "Compression algorithm"); intfield(pagestart + 8, 4, "Decompression algorithm"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int tape_dev_config(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 25, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 2, "CAF", 1, 5); bitfield(pagestart + 2, "Active format", 0x1f, 0); intfield(pagestart + 3, 1, "Active partition"); intfield(pagestart + 4, 1, "Write object cbuffer full ratio"); intfield(pagestart + 5, 1, "Read object cbuffer full ratio"); intfield(pagestart + 6, 2, "Wire delay time"); bitfield(pagestart + 8, "OBR", 1, 7); bitfield(pagestart + 8, "LOIS", 1, 6); bitfield(pagestart + 8, "RSMK", 1, 5); bitfield(pagestart + 8, "AVC", 1, 4); bitfield(pagestart + 8, "SOCF", 3, 2); bitfield(pagestart + 8, "ROBO", 1, 1); bitfield(pagestart + 8, "REW", 1, 0); intfield(pagestart + 9, 1, "Gap size"); bitfield(pagestart + 10, "EOD defined", 7, 5); bitfield(pagestart + 10, "EEG", 1, 4); bitfield(pagestart + 10, "SEW", 1, 3); bitfield(pagestart + 10, "SWP", 1, 2); bitfield(pagestart + 10, "BAML", 1, 1); bitfield(pagestart + 10, "BAM", 1, 0); intfield(pagestart + 11, 3, "Object cbuffer size at early warning"); intfield(pagestart + 14, 1, "Select data compression algorithm"); bitfield(pagestart + 15, "ASOCWP", 1, 2); bitfield(pagestart + 15, "PERSWO", 1, 1); bitfield(pagestart + 15, "PRMWP", 1, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int tape_medium_part1(struct mpage_info * mpi, const char * prefix) { int status, off, len; uint8_t *pagestart; /* variable length mode page, need to know its response length */ status = get_mode_page(mpi, 0, cbuffer); if (status) return status; off = modePageOffset(cbuffer, mpi->resp_len, mode6byte); if (off < 0) return off; len = mpi->resp_len - off; status = setup_mode_page(mpi, 12 + ((len - 10) / 2), cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------------\n"); } intfield(pagestart + 2, 1, "Maximum additional partitions"); intfield(pagestart + 3, 1, "Additional partitions defined"); bitfield(pagestart + 4, "FDP", 1, 7); bitfield(pagestart + 4, "SDP", 1, 6); bitfield(pagestart + 4, "IDP", 1, 5); bitfield(pagestart + 4, "PSUM", 3, 3); bitfield(pagestart + 4, "POFM", 1, 2); bitfield(pagestart + 4, "CLEAR", 1, 1); bitfield(pagestart + 4, "ADDP", 1, 0); intfield(pagestart + 5, 1, "Medium format recognition"); bitfield(pagestart + 6, "Partition units", 0xf, 0); intfield(pagestart + 8, 2, "Partition size"); for (off = 10; off < len; off += 2) intfield(pagestart + off, 2, "Partition size"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int tape_medium_part2_4(struct mpage_info * mpi, const char * prefix) { int status, off, len; uint8_t *pagestart; /* variable length mode page, need to know its response length */ status = get_mode_page(mpi, 0, cbuffer); if (status) return status; off = modePageOffset(cbuffer, mpi->resp_len, mode6byte); if (off < 0) return off; len = mpi->resp_len - off; status = setup_mode_page(mpi, 1 + ((len - 4) / 2), cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------------\n"); } intfield(pagestart + 2, 2, "Partition size"); for (off = 4; off < len; off += 2) intfield(pagestart + off, 2, "Partition size"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int ses_services_manag(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 2, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", get_page_name(mpi), mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 5, "ENBLTC", 1, 0); intfield(pagestart + 6, 2, "Maximum time to completion (100 ms units)"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int fcp_proto_spec_lu(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 1, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", "Fibre Channel logical unit", mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 3, "EPDC", 1, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int sas_proto_spec_lu(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 1, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", "SAS logical unit", mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 2, "Transport Layer Retries", 1, 4); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_proto_spec_lu(struct mpage_info * mpi, const char * prefix) { int status; int proto_id = 0; status = get_protocol_id(0, cbuffer, &proto_id, NULL); if (status) return status; if (0 == proto_id) return fcp_proto_spec_lu(mpi, prefix); else if (6 == proto_id) return sas_proto_spec_lu(mpi, prefix); else return DECODE_FAILED_TRY_HEX; } static int fcp_proto_spec_port(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 10, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", "Fibre Channel port control", mpi->page); printf("----------------------------------------------------\n"); } bitfield(pagestart + 3, "DTFD", 1, 7); bitfield(pagestart + 3, "PLPB", 1, 6); bitfield(pagestart + 3, "DDIS", 1, 5); bitfield(pagestart + 3, "DLM", 1, 4); bitfield(pagestart + 3, "RHA", 1, 3); bitfield(pagestart + 3, "ALWI", 1, 2); bitfield(pagestart + 3, "DTIPE", 1, 1); bitfield(pagestart + 3, "DTOLI", 1, 0); bitfield(pagestart + 6, "RR_TOV units", 7, 0); intfield(pagestart + 7, 1, "Resource recovery time-out"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int spi4_proto_spec_port(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 1, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", "SPI-4 port control", mpi->page); printf("-----------------------------------\n"); } intfield(pagestart + 4, 2, "Synchronous transfer time-out"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } /* Protocol specific mode page for SAS, short format (subpage 0) */ static int sas_proto_spec_port(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 3, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode page (0x%x)\n", "SAS SSP port control", mpi->page); printf("-------------------------------------\n"); } bitfield(pagestart + 2, "Ready LED meaning", 0x1, 4); intfield(pagestart + 4, 2, "I_T Nexus Loss time"); intfield(pagestart + 6, 2, "Initiator response time-out"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_proto_spec_port(struct mpage_info * mpi, const char * prefix) { int status; int proto_id = 0; status = get_protocol_id(1, cbuffer, &proto_id, NULL); if (status) return status; if (0 == proto_id) return fcp_proto_spec_port(mpi, prefix); else if (1 == proto_id) return spi4_proto_spec_port(mpi, prefix); else if (6 == proto_id) return sas_proto_spec_port(mpi, prefix); else return DECODE_FAILED_TRY_HEX; } static int spi4_margin_control(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 5, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", "SPI-4 Margin control", mpi->page, mpi->subpage); printf("--------------------------------------------\n"); } bitfield(pagestart + 5, "Protocol identifier", 0xf, 0); bitfield(pagestart + 7, "Driver Strength", 0xf, 4); bitfield(pagestart + 8, "Driver Asymmetry", 0xf, 4); bitfield(pagestart + 8, "Driver Precompensation", 0xf, 0); bitfield(pagestart + 9, "Driver Slew rate", 0xf, 4); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } /* Protocol specific mode page for SAS, phy control + discover (subpage 1) */ static int sas_phy_control_discover(struct mpage_info * mpi, const char * prefix) { int status, off, num_phys, k; uint8_t *pagestart; uint8_t *p; /* variable length mode page, need to know its response length */ status = get_mode_page(mpi, 0, cbuffer); if (status) return status; off = modePageOffset(cbuffer, mpi->resp_len, mode6byte); if (off < 0) return off; num_phys = cbuffer[off + 7]; status = setup_mode_page(mpi, 1 + (16 * num_phys), cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", "SAS Phy Control and " "Discover", mpi->page, mpi->subpage); printf("--------------------------------------------\n"); } intfield(pagestart + 7, 1, "Number of phys"); for (k = 0, p = pagestart + 8; k < num_phys; ++k, p += 48) { intfield(p + 1, 1, "Phy Identifier"); bitfield(p + 4, "Attached Device type", 0x7, 4); bitfield(p + 5, "Negotiated Logical Link rate", 0xf, 0); bitfield(p + 6, "Attached SSP Initiator port", 0x1, 3); bitfield(p + 6, "Attached STP Initiator port", 0x1, 2); bitfield(p + 6, "Attached SMP Initiator port", 0x1, 1); bitfield(p + 7, "Attached SSP Target port", 0x1, 3); bitfield(p + 7, "Attached STP Target port", 0x1, 2); bitfield(p + 7, "Attached SMP Target port", 0x1, 1); hexdatafield(p + 8, 8, "SAS address"); hexdatafield(p + 16, 8, "Attached SAS address"); intfield(p + 24, 1, "Attached Phy identifier"); bitfield(p + 32, "Programmed Min Physical Link rate", 0xf, 4); bitfield(p + 32, "Hardware Min Physical Link rate", 0xf, 0); bitfield(p + 33, "Programmed Max Physical Link rate", 0xf, 4); bitfield(p + 33, "Hardware Max Physical Link rate", 0xf, 0); } if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_proto_spec_port_sp1(struct mpage_info * mpi, const char * prefix) { int status; int proto_id = 0; status = get_protocol_id(1, cbuffer, &proto_id, NULL); if (status) return status; if (1 == proto_id) return spi4_margin_control(mpi, prefix); else if (6 == proto_id) return sas_phy_control_discover(mpi, prefix); else return DECODE_FAILED_TRY_HEX; } static int spi4_training_config(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 27, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", "training configuration", mpi->page, mpi->subpage); printf("----------------------------------------------------------\n"); } hexdatafield(pagestart + 10, 4, "DB(0) value"); hexdatafield(pagestart + 14, 4, "DB(1) value"); hexdatafield(pagestart + 18, 4, "DB(2) value"); hexdatafield(pagestart + 22, 4, "DB(3) value"); hexdatafield(pagestart + 26, 4, "DB(4) value"); hexdatafield(pagestart + 30, 4, "DB(5) value"); hexdatafield(pagestart + 34, 4, "DB(6) value"); hexdatafield(pagestart + 38, 4, "DB(7) value"); hexdatafield(pagestart + 42, 4, "DB(8) value"); hexdatafield(pagestart + 46, 4, "DB(9) value"); hexdatafield(pagestart + 50, 4, "DB(10) value"); hexdatafield(pagestart + 54, 4, "DB(11) value"); hexdatafield(pagestart + 58, 4, "DB(12) value"); hexdatafield(pagestart + 62, 4, "DB(13) value"); hexdatafield(pagestart + 66, 4, "DB(14) value"); hexdatafield(pagestart + 70, 4, "DB(15) value"); hexdatafield(pagestart + 74, 4, "P_CRCA value"); hexdatafield(pagestart + 78, 4, "P1 value"); hexdatafield(pagestart + 82, 4, "BSY value"); hexdatafield(pagestart + 86, 4, "SEL value"); hexdatafield(pagestart + 90, 4, "RST value"); hexdatafield(pagestart + 94, 4, "REQ value"); hexdatafield(pagestart + 98, 4, "ACK value"); hexdatafield(pagestart + 102, 4, "ATN value"); hexdatafield(pagestart + 106, 4, "C/D value"); hexdatafield(pagestart + 110, 4, "I/O value"); hexdatafield(pagestart + 114, 4, "MSG value"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } /* SAS(2) SSP, shared protocol specific port mode subpage (subpage 2) */ static int sas_shared_spec_port(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 1, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", "SAS SSP shared protocol " "specific port", mpi->page, mpi->subpage); printf("-----------------------------------------------------\n"); } intfield(pagestart + 6, 2, "Power loss timeout(ms)"); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int common_proto_spec_port_sp2(struct mpage_info * mpi, const char * prefix) { int status; int proto_id = 0; status = get_protocol_id(1, cbuffer, &proto_id, NULL); if (status) return status; if (1 == proto_id) return spi4_training_config(mpi, prefix); else if (6 == proto_id) return sas_shared_spec_port(mpi, prefix); else return DECODE_FAILED_TRY_HEX; } static int spi4_negotiated(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 7, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", get_page_name(mpi), mpi->page, mpi->subpage); printf("--------------------------------------------\n"); } intfield(pagestart + 6, 1, "Transfer period"); intfield(pagestart + 8, 1, "REQ/ACK offset"); intfield(pagestart + 9, 1, "Transfer width exponent"); bitfield(pagestart + 10, "Protocol option bits", 0x7f, 0); bitfield(pagestart + 11, "Transceiver mode", 3, 2); bitfield(pagestart + 11, "Sent PCOMP_EN", 1, 1); bitfield(pagestart + 11, "Received PCOMP_EN", 1, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static int spi4_report_xfer(struct mpage_info * mpi, const char * prefix) { int status; uint8_t *pagestart; status = setup_mode_page(mpi, 4, cbuffer, &pagestart); if (status) return status; if (prefix[0]) printf("%s", prefix); if (!x_interface && !replace) { printf("%s mode subpage (0x%x,0x%x)\n", get_page_name(mpi), mpi->page, mpi->subpage); printf("--------------------------------------------\n"); } intfield(pagestart + 6, 1, "Minimum transfer period factor"); intfield(pagestart + 8, 1, "Maximum REQ/ACK offset"); intfield(pagestart + 9, 1, "Maximum transfer width exponent"); bitfield(pagestart + 10, "Protocol option bits supported", 0xff, 0); if (x_interface && replace) return put_mode_page(mpi, cbuffer); else printf("\n"); return 0; } static void print_hex_page(struct mpage_info * mpi, const char * prefix, uint8_t *pagestart, int off, int len) { int k; const char * pg_name; if (prefix[0]) printf("%s", prefix); if (! x_interface) { pg_name = get_page_name(mpi); if (mpi->subpage) { if (pg_name && (unkn_page_str != pg_name)) printf("mode page: 0x%02x subpage: 0x%02x [%s]\n", mpi->page, mpi->subpage, pg_name); else printf("mode page: 0x%02x subpage: 0x%02x\n", mpi->page, mpi->subpage); printf("------------------------------\n"); } else { if (pg_name && (unkn_page_str != pg_name)) printf("mode page: 0x%02x [%s]\n", mpi->page, pg_name); else printf("mode page: 0x%02x\n", mpi->page); printf("---------------\n"); } } for (k = off; k < len; k++) { char nm[8]; snprintf(nm, sizeof(nm), "0x%02x", (unsigned char)k); hexdatafield(pagestart + k, 1, nm); } printf("\n"); } static int do_user_page(struct mpage_info * mpi, int decode_in_hex) { int status = 0; int len, off, res, done; int offset = 0; uint8_t *pagestart; char prefix[96]; struct mpage_info local_mp_i; struct mpage_name_func * mpf; int multiple = ((MP_LIST_PAGES == mpi->page) || (MP_LIST_SUBPAGES == mpi->subpage)); if (replace && multiple) { printf("Can't list all (sub)pages and use replace (-R) together\n"); return 1; } status = get_mode_page(mpi, 0, cbuffer2); if (status) { printf("\n"); return status; } else { offset = modePageOffset(cbuffer2, mpi->resp_len, mode6byte); if (offset < 0) { fprintf(stdout, "mode page=0x%x has bad page format\n", mpi->page); fprintf(stdout, " perhaps '-z' switch may help\n"); return -1; } pagestart = cbuffer2 + offset; } memset(&local_mp_i, 0, sizeof(local_mp_i)); local_mp_i.page_control = mpi->page_control; local_mp_i.peri_type = mpi->peri_type; local_mp_i.inq_byte6 = mpi->inq_byte6; local_mp_i.resp_len = mpi->resp_len; do { local_mp_i.page = (pagestart[0] & 0x3f); local_mp_i.subpage = (pagestart[0] & 0x40) ? pagestart[1] : 0; if(0 == local_mp_i.page) { /* page==0 vendor (unknown) format */ off = 0; len = mpi->resp_len - offset; /* should be last listed page */ } else if (local_mp_i.subpage) { off = 4; len = (pagestart[2] << 8) + pagestart[3] + 4; } else { off = 2; len = pagestart[1] + 2; } prefix[0] = '\0'; done = 0; if ((! decode_in_hex) && ((mpf = get_mpage_name_func(&local_mp_i))) && mpf->func) { if (multiple && x_interface && !replace) { if (local_mp_i.subpage) snprintf(prefix, sizeof(prefix), "sginfo -t 0x%x,0x%x" " -XR %s ", local_mp_i.page, local_mp_i.subpage, device_name); else snprintf(prefix, sizeof(prefix), "sginfo -t 0x%x -XR %s ", local_mp_i.page, device_name); } res = mpf->func(&local_mp_i, prefix); if (DECODE_FAILED_TRY_HEX != res) { done = 1; status |= res; } } if (! done) { if (x_interface && replace) return put_mode_page(&local_mp_i, cbuffer2); else { if (multiple && x_interface && !replace) { if (local_mp_i.subpage) snprintf(prefix, sizeof(prefix), "sginfo -u 0x%x,0x%x" " -XR %s ", local_mp_i.page, local_mp_i.subpage, device_name); else snprintf(prefix, sizeof(prefix), "sginfo -u 0x%x -XR " "%s ", local_mp_i.page, device_name); } print_hex_page(&local_mp_i, prefix, pagestart, off, len); } } offset += len; pagestart = cbuffer2 + offset; } while (multiple && (offset < mpi->resp_len)); return status; } static void inqfieldname(uint8_t *deststr, const uint8_t *srcbuf, int maxlen) { int i; memset(deststr, '\0', MAX_INQFIELD_LEN); for (i = maxlen - 1; i >= 0 && isspace(srcbuf[i]); --i) ; memcpy(deststr, srcbuf, i + 1); } static int do_inquiry(int * peri_type, int * resp_byte6, int inquiry_verbosity) { int status; uint8_t cmd[6]; uint8_t fieldname[MAX_INQFIELD_LEN]; uint8_t *pagestart; struct scsi_cmnd_io sci; memset(cbuffer, 0, INQUIRY_RESP_INITIAL_LEN); cbuffer[0] = 0x7f; cmd[0] = 0x12; /* INQUIRY */ cmd[1] = 0x00; /* evpd=0 */ cmd[2] = 0x00; /* page code = 0 */ cmd[3] = 0x00; /* (reserved) */ cmd[4] = INQUIRY_RESP_INITIAL_LEN; /* allocation length */ cmd[5] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = INQUIRY_RESP_INITIAL_LEN; sci.dxferp = cbuffer; status = do_scsi_io(&sci); if (status) { printf("Error doing INQUIRY (1)\n"); return status; } if (trace_cmd > 1) { printf(" inquiry response:\n"); dump(cbuffer, INQUIRY_RESP_INITIAL_LEN); } pagestart = cbuffer; if (peri_type) *peri_type = pagestart[0] & 0x1f; if (resp_byte6) *resp_byte6 = pagestart[6]; if (0 == inquiry_verbosity) return 0; if ((pagestart[4] + 5) < INQUIRY_RESP_INITIAL_LEN) { printf("INQUIRY response too short: expected 36 bytes, got %d\n", pagestart[4] + 5); return -EINVAL; } if (!x_interface && !replace) { printf("INQUIRY response (cmd: 0x12)\n"); printf("----------------------------\n"); }; bitfield(pagestart + 0, "Device Type", 0x1f, 0); if (2 == inquiry_verbosity) { bitfield(pagestart + 0, "Peripheral Qualifier", 0x7, 5); bitfield(pagestart + 1, "Removable", 1, 7); bitfield(pagestart + 2, "Version", 0xff, 0); bitfield(pagestart + 3, "NormACA", 1, 5); bitfield(pagestart + 3, "HiSup", 1, 4); bitfield(pagestart + 3, "Response Data Format", 0xf, 0); bitfield(pagestart + 5, "SCCS", 1, 7); bitfield(pagestart + 5, "ACC", 1, 6); bitfield(pagestart + 5, "ALUA", 3, 4); bitfield(pagestart + 5, "3PC", 1, 3); bitfield(pagestart + 5, "Protect", 1, 0); bitfield(pagestart + 6, "BQue", 1, 7); bitfield(pagestart + 6, "EncServ", 1, 6); bitfield(pagestart + 6, "MultiP", 1, 4); bitfield(pagestart + 6, "MChngr", 1, 3); bitfield(pagestart + 6, "Addr16", 1, 0); bitfield(pagestart + 7, "Relative Address", 1, 7); bitfield(pagestart + 7, "Wide bus 16", 1, 5); bitfield(pagestart + 7, "Synchronous neg.", 1, 4); bitfield(pagestart + 7, "Linked Commands", 1, 3); bitfield(pagestart + 7, "Command Queueing", 1, 1); } if (x_interface) printf("\n"); inqfieldname(fieldname, pagestart + 8, 8); printf("%s%s\n", (!x_interface ? "Vendor: " : ""), fieldname); inqfieldname(fieldname, pagestart + 16, 16); printf("%s%s\n", (!x_interface ? "Product: " : ""), fieldname); inqfieldname(fieldname, pagestart + 32, 4); printf("%s%s\n", (!x_interface ? "Revision level: " : ""), fieldname); printf("\n"); return status; } static int do_serial_number(void) { int status, pagelen; uint8_t cmd[6]; uint8_t *pagestart; struct scsi_cmnd_io sci; const uint8_t serial_vpd = 0x80; const uint8_t supported_vpd = 0x0; /* check supported VPD pages + unit serial number well formed */ cmd[0] = 0x12; /* INQUIRY */ cmd[1] = 0x01; /* evpd=1 */ cmd[2] = supported_vpd; cmd[3] = 0x00; /* (reserved) */ cmd[4] = 0x04; /* allocation length */ cmd[5] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = 4; sci.dxferp = cbuffer; status = do_scsi_io(&sci); if (status) { printf("No serial number (error doing INQUIRY, supported VPDs)\n\n"); return status; } if (! ((supported_vpd == cbuffer[1]) && (0 == cbuffer[2]))) { printf("No serial number (bad format for supported VPDs)\n\n"); return -1; } cmd[0] = 0x12; /* INQUIRY */ cmd[1] = 0x01; /* evpd=1 */ cmd[2] = serial_vpd; cmd[3] = 0x00; /* (reserved) */ cmd[4] = 0x04; /* allocation length */ cmd[5] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = 4; sci.dxferp = cbuffer; status = do_scsi_io(&sci); if (status) { printf("No serial number (error doing INQUIRY, serial number)\n\n"); return status; } if (! ((serial_vpd == cbuffer[1]) && (0 == cbuffer[2]))) { printf("No serial number (bad format for serial number)\n\n"); return -1; } pagestart = cbuffer; pagelen = 4 + pagestart[3]; cmd[0] = 0x12; /* INQUIRY */ cmd[1] = 0x01; /* evpd=1 */ cmd[2] = serial_vpd; cmd[3] = 0x00; /* (reserved) */ cmd[4] = (uint8_t)pagelen; /* allocation length */ cmd[5] = 0x00; /* control */ sci.cmnd = cmd; sci.cmnd_len = sizeof(cmd); sci.dxfer_dir = DXFER_FROM_DEVICE; sci.dxfer_len = pagelen; sci.dxferp = cbuffer; status = do_scsi_io(&sci); if (status) { printf("No serial number (error doing INQUIRY, serial number)\n\n"); return status; } if (trace_cmd > 1) { printf(" inquiry (vpd page 0x80) response:\n"); dump(cbuffer, pagelen); } pagestart[pagestart[3] + 4] = '\0'; printf("Serial Number '%s'\n\n", pagestart + 4); return status; } typedef struct sg_map { int bus; int channel; int target_id; int lun; char * dev_name; } Sg_map; typedef struct my_scsi_idlun { int mux4; int host_unique_id; } My_scsi_idlun; #define MDEV_NAME_SZ 256 static void make_dev_name(char * fname, int k, int do_numeric) { char buff[MDEV_NAME_SZ]; size_t len; strncpy(fname, "/dev/sg", MDEV_NAME_SZ); fname[MDEV_NAME_SZ - 1] = '\0'; len = strlen(fname); if (do_numeric) snprintf(fname + len, MDEV_NAME_SZ - len, "%d", k); else { if (k <= 26) { buff[0] = 'a' + (char)k; buff[1] = '\0'; strcat(fname, buff); } else strcat(fname, "xxxx"); } } static Sg_map sg_map_arr[MAX_SG_DEVS + 1]; #define MAX_HOLES 4 /* Print out a list of the known devices on the system */ static void show_devices(int raw) { int k, j, fd, err, bus, n; My_scsi_idlun m_idlun; char name[MDEV_NAME_SZ]; char dev_name[MDEV_NAME_SZ + 6]; char ebuff[EBUFF_SZ]; int do_numeric = 1; int max_holes = MAX_HOLES; DIR *dir_ptr; struct dirent *entry; char *tmpptr; dir_ptr=opendir("/dev"); if ( dir_ptr == NULL ) { perror("/dev"); exit(1); } j=0; while ( (entry=readdir(dir_ptr)) != NULL ) { switch(entry->d_type) { case DT_LNK: case DT_CHR: case DT_BLK: break; default: continue; } switch(entry->d_name[0]) { case 's': case 'n': break; default: continue; } if ( strncmp("sg",entry->d_name,2) == 0 ) { continue; } if ( strncmp("sd",entry->d_name,2) == 0 ) { continue; } if ( isdigit(entry->d_name[strlen(entry->d_name)-1]) ) { continue; } if ( strncmp("snapshot",entry->d_name,8) == 0 ) { continue; } snprintf(dev_name, sizeof(dev_name),"/dev/%s",entry->d_name); fd = open(dev_name, O_RDONLY | O_NONBLOCK); if (fd < 0) continue; err = ioctl(fd, SCSI_IOCTL_GET_BUS_NUMBER, &(sg_map_arr[j].bus)); if (err < 0) { #if 0 snprintf(ebuff, EBUFF_SZ, "SCSI(1) ioctl on %s failed", dev_name); perror(ebuff); #endif close(fd); continue; } err = ioctl(fd, SCSI_IOCTL_GET_IDLUN, &m_idlun); if (err < 0) { snprintf(ebuff, EBUFF_SZ, "SCSI(2) ioctl on %s failed", dev_name); perror(ebuff); close(fd); continue; } sg_map_arr[j].channel = (m_idlun.mux4 >> 16) & 0xff; sg_map_arr[j].lun = (m_idlun.mux4 >> 8) & 0xff; sg_map_arr[j].target_id = m_idlun.mux4 & 0xff; n = strlen(dev_name); /* memory leak ... no free()s for this malloc() */ tmpptr = (char *)malloc(n + 1); snprintf(tmpptr, n + 1, "%.*s", n, dev_name); /* strncpy(tmpptr,dev_name,strlen(dev_name)+1); */ sg_map_arr[j].dev_name = tmpptr; #if 0 printf("[scsi%d ch=%d id=%d lun=%d %s] ", sg_map_arr[j].bus, sg_map_arr[j].channel, sg_map_arr[j].target_id, sg_map_arr[j].lun, sg_map_arr[j].dev_name); #endif printf("%s ", dev_name); close(fd); if (++j >= MAX_SG_DEVS) break; } closedir(dir_ptr); printf("\n"); /* <<<<<<<<<<<<<<<<<<<<< */ for (k = 0; k < MAX_SG_DEVS; k++) { if ( raw ) { sprintf(name,"/dev/raw/raw%d",k); fd = open(name, O_RDWR | O_NONBLOCK); if (fd < 0) { continue; } } else { make_dev_name(name, k, do_numeric); fd = open(name, O_RDWR | O_NONBLOCK); if (fd < 0) { if ((ENOENT == errno) && (0 == k)) { do_numeric = 0; make_dev_name(name, k, do_numeric); fd = open(name, O_RDWR | O_NONBLOCK); } if (fd < 0) { if (EBUSY == errno) continue; /* step over if O_EXCL already on it */ else { #if 0 snprintf(ebuff, EBUFF_SZ, "open on %s failed (%d)", name, errno); perror(ebuff); #endif if (max_holes-- > 0) continue; else break; } } } } max_holes = MAX_HOLES; err = ioctl(fd, SCSI_IOCTL_GET_BUS_NUMBER, &bus); if (err < 0) { if ( ! raw ) { snprintf(ebuff, EBUFF_SZ, "SCSI(3) ioctl on %s failed", name); perror(ebuff); } close(fd); continue; } err = ioctl(fd, SCSI_IOCTL_GET_IDLUN, &m_idlun); if (err < 0) { if ( ! raw ) { snprintf(ebuff, EBUFF_SZ, "SCSI(3) ioctl on %s failed", name); perror(ebuff); } close(fd); continue; } #if 0 printf("[scsi%d ch=%d id=%d lun=%d %s]", bus, (m_idlun.mux4 >> 16) & 0xff, m_idlun.mux4 & 0xff, (m_idlun.mux4 >> 8) & 0xff, name); #endif for (j = 0; sg_map_arr[j].dev_name; ++j) { if ((bus == sg_map_arr[j].bus) && ((m_idlun.mux4 & 0xff) == sg_map_arr[j].target_id) && (((m_idlun.mux4 >> 16) & 0xff) == sg_map_arr[j].channel) && (((m_idlun.mux4 >> 8) & 0xff) == sg_map_arr[j].lun)) { printf("%s [=%s scsi%d ch=%d id=%d lun=%d]\n", name, sg_map_arr[j].dev_name, bus, ((m_idlun.mux4 >> 16) & 0xff), m_idlun.mux4 & 0xff, ((m_idlun.mux4 >> 8) & 0xff)); break; } } if (NULL == sg_map_arr[j].dev_name) printf("%s [scsi%d ch=%d id=%d lun=%d]\n", name, bus, ((m_idlun.mux4 >> 16) & 0xff), m_idlun.mux4 & 0xff, ((m_idlun.mux4 >> 8) & 0xff)); close(fd); } printf("\n"); } #define DEVNAME_SZ 256 static int open_sg_io_dev(char * devname) { int fd, fdrw, err, bus, bbus, k, v; My_scsi_idlun m_idlun, mm_idlun; int do_numeric = 1; char name[DEVNAME_SZ]; struct stat a_st; int block_dev = 0; strncpy(name, devname, DEVNAME_SZ); name[DEVNAME_SZ - 1] = '\0'; fd = open(name, O_RDONLY | O_NONBLOCK); if (fd < 0) return fd; if ((ioctl(fd, SG_GET_VERSION_NUM, &v) >= 0) && (v >= 30000)) { fdrw = open(name, O_RDWR | O_NONBLOCK); if (fdrw >= 0) { close(fd); return fdrw; } return fd; } if (fstat(fd, &a_st) < 0) { fprintf(stderr, "could do fstat() on fd ??\n"); close(fd); return -9999; } if (S_ISBLK(a_st.st_mode)) block_dev = 1; if (block_dev || (ioctl(fd, SG_GET_TIMEOUT, 0) < 0)) { err = ioctl(fd, SCSI_IOCTL_GET_BUS_NUMBER, &bus); if (err < 0) { fprintf(stderr, "A device name that understands SCSI commands " "is required\n"); close(fd); return -9999; } err = ioctl(fd, SCSI_IOCTL_GET_IDLUN, &m_idlun); if (err < 0) { fprintf(stderr, "A SCSI device name is required(2)\n"); close(fd); return -9999; } close(fd); for (k = 0; k < MAX_SG_DEVS; k++) { make_dev_name(name, k, do_numeric); fd = open(name, O_RDWR | O_NONBLOCK); if (fd < 0) { if ((ENOENT == errno) && (0 == k)) { do_numeric = 0; make_dev_name(name, k, do_numeric); fd = open(name, O_RDWR | O_NONBLOCK); } if (fd < 0) { if (EBUSY == errno) continue; /* step over if O_EXCL already on it */ else break; } } err = ioctl(fd, SCSI_IOCTL_GET_BUS_NUMBER, &bbus); if (err < 0) { perror("sg ioctl failed"); close(fd); fd = -9999; } err = ioctl(fd, SCSI_IOCTL_GET_IDLUN, &mm_idlun); if (err < 0) { perror("sg ioctl failed"); close(fd); fd = -9999; } if ((bus == bbus) && ((m_idlun.mux4 & 0xff) == (mm_idlun.mux4 & 0xff)) && (((m_idlun.mux4 >> 8) & 0xff) == ((mm_idlun.mux4 >> 8) & 0xff)) && (((m_idlun.mux4 >> 16) & 0xff) == ((mm_idlun.mux4 >> 16) & 0xff))) break; else { close(fd); fd = -9999; } } } if (fd >= 0) { if ((ioctl(fd, SG_GET_VERSION_NUM, &v) < 0) || (v < 30000)) { fprintf(stderr, "requires lk 2.4 (sg driver), lk 2.6 or lk 3 " "series\n"); close(fd); return -9999; } close(fd); return open(name, O_RDWR | O_NONBLOCK); } else return fd; } static void usage(const char *errtext) { if (errtext) fprintf(stderr, "Error: sginfo: %s\n", errtext); fprintf(stderr, "Usage: sginfo [-options] [device] " "[replacement_values]\n"); fputs("\tAllowed options are:\n" "\t-6 Do 6 byte mode sense and select commands (def: 10 " "bytes).\n" "\t-a Display inquiry info, serial # and all mode pages.\n" "\t-A Similar to '-a' but displays all subpages as well.\n" "\t-c Access Caching Page.\n" "\t-C Access Control Mode Page.\n" "\t-d Display defect lists (default format: index).\n" "\t-D Access Disconnect-Reconnect Page.\n" "\t-e Access Read-Write Error Recovery page.\n" "\t-E Access Control Extension page.\n" "\t-f Access Format Device Page.\n" "\t-Farg Format of the defect list:\n" "\t\t-Flogical - logical block addresses (32 bit)\n" "\t\t-Flba64 - logical block addresses (64 bit)\n" "\t\t-Fphysical - physical blocks\n" "\t\t-Findex - defect bytes from index\n" "\t\t-Fhead - sort by head\n", stdout); fputs("\t-g Access Rigid Disk Drive Geometry Page.\n" "\t-G Display 'grown' defect list (default format: index).\n" "\t-i Display information from INQUIRY command.\n" "\t-I Access Informational Exception page.\n" "\t-l List known scsi devices on the system [DEPRECATED]\n" "\t-n Access Notch and Partition Page.\n" "\t-N Negate (stop) storing to saved page (active with -R).\n" "\t-P Access Power Condition Page.\n" "\t-r List known raw scsi devices on the system\n" "\t-s Display serial number (from INQUIRY VPD page).\n" "\t-t Access mode page [subpage ] and decode.\n" "\t-T Trace commands (for debugging, double for more)\n" "\t-u Access mode page [subpage ], output in hex\n" "\t-v Show version number\n" "\t-V Access Verify Error Recovery Page.\n" "\t-z single fetch mode pages (rather than double fetch)\n" "\n", stdout); fputs("\tOnly one of the following three options can be specified.\n" "\tNone of these three implies the current values are returned.\n", stdout); fputs("\t-m Access modifiable fields instead of current values\n" "\t-M Access manufacturer defaults instead of current values\n" "\t-S Access saved defaults instead of current values\n\n" "\t-X Use list (space separated values) rather than table.\n" "\t-R Replace parameters - best used with -X (expert use only)\n" "\t [replacement parameters placed after device on command line]\n\n", stdout); printf("\t sginfo version: %s; See man page for more details.\n", version_str); exit(2); } int main(int argc, char *argv[]) { int k, j, n; unsigned int unum, unum2; int decode_in_hex = 0; char c; char * cp; int status = 0; long tmp; struct mpage_info mp_i; int inquiry_verbosity = 0; int show_devs = 0, show_raw = 0; int found = 0; if (argc < 2) usage(NULL); memset(&mp_i, 0, sizeof(mp_i)); while ((k = getopt(argc, argv, "6aAcCdDeEfgGiIlmMnNPrRsSTvVXzF:t:u:")) != EOF) { c = (char)k; switch (c) { case '6': mode6byte = 1; break; case 'a': inquiry_verbosity = 1; serial_number = 1; mp_i.page = MP_LIST_PAGES; break; case 'A': inquiry_verbosity = 1; serial_number = 1; mp_i.page = MP_LIST_PAGES; mp_i.subpage = MP_LIST_SUBPAGES; break; case 'c': mp_i.page = 0x8; break; case 'C': mp_i.page = 0xa; break; case 'd': defect = 1; break; case 'D': mp_i.page = 0x2; break; case 'e': mp_i.page = 0x1; break; case 'E': mp_i.page = 0xa; mp_i.subpage = 0x1; break; case 'f': mp_i.page = 0x3; break; case 'F': if (!strcasecmp(optarg, "logical")) defectformat = 0x0; else if (!strcasecmp(optarg, "lba64")) defectformat = 0x3; else if (!strcasecmp(optarg, "physical")) defectformat = 0x5; else if (!strcasecmp(optarg, "index")) defectformat = 0x4; else if (!strcasecmp(optarg, "head")) defectformat = HEAD_SORT_TOKEN; else usage("Illegal -F parameter, must be one of logical, " "physical, index or head"); break; case 'g': mp_i.page = 0x4; break; case 'G': grown_defect = 1; break; case 'i': /* just vendor, product and revision for '-i -i' */ inquiry_verbosity = (2 == inquiry_verbosity) ? 1 : 2; break; case 'I': mp_i.page = 0x1c; break; case 'l': show_devs = 1; break; case 'm': /* modifiable page control */ if (0 == mp_i.page_control) mp_i.page_control = 1; else usage("can only have one of 'm', 'M' and 'S'"); break; case 'M': /* manufacturer's==default page control */ if (0 == mp_i.page_control) mp_i.page_control = 2; else usage("can only have one of 'M', 'm' and 'S'"); break; case 'n': mp_i.page = 0xc; break; case 'N': negate_sp_bit = 1; break; case 'P': mp_i.page = 0x1a; break; case 'r': show_raw = 1; break; case 'R': replace = 1; break; case 's': serial_number = 1; break; case 'S': /* saved page control */ if (0 == mp_i.page_control) mp_i.page_control = 3; else usage("can only have one of 'S', 'm' and 'M'"); break; case 'T': trace_cmd++; break; case 't': case 'u': if ('u' == c) decode_in_hex = 1; while (' ' == *optarg) optarg++; if ('0' == *optarg) { unum = 0; unum2 = 0; j = sscanf(optarg, "0x%x,0x%x", &unum, &unum2); mp_i.page = unum; if (1 == j) { cp = strchr(optarg, ','); if (cp && (1 == sscanf(cp, ",%d", &mp_i.subpage))) j = 2; } else mp_i.subpage = unum2; } else j = sscanf(optarg, "%d,%d", &mp_i.page, &mp_i.subpage); if (1 == j) mp_i.subpage = 0; else if (j < 1) usage("argument following '-u' should be of form " "[,]"); if ((mp_i.page < 0) || (mp_i.page > MP_LIST_PAGES) || (mp_i.subpage < 0) || (mp_i.subpage > MP_LIST_SUBPAGES)) usage("mode pages range from 0 .. 63, subpages from " "1 .. 255"); found = 1; break; case 'v': fprintf(stdout, "sginfo version: %s\n", version_str); return 0; case 'V': mp_i.page = 0x7; break; case 'X': x_interface = 1; break; case 'z': single_fetch = 1; break; case '?': usage("Unknown option"); break; default: fprintf(stdout, "Unknown option '-%c' (ascii 0x%02x)\n", c, c); usage("bad option"); } } if (replace && !x_interface) usage("-R requires -X"); if (replace && mp_i.page_control) usage("-R not allowed for -m, -M or -S"); if (x_interface && replace && ((MP_LIST_PAGES == mp_i.page) || (MP_LIST_SUBPAGES == mp_i.subpage))) usage("-XR can be used only with exactly one page."); if (replace && (3 != mp_i.page_control)) { memset (is_hex, 0, 32); for (j = 1; j < argc - optind; j++) { if (strncmp(argv[optind + j], "0x", 2) == 0) { char *pnt = argv[optind + j] + 2; replacement_values[j] = 0; /* This is a kluge, but we can handle 64 bit quantities this way. */ while (*pnt) { if (*pnt >= 'a' && *pnt <= 'f') *pnt -= 32; replacement_values[j] = (replacement_values[j] << 4) | (*pnt > '9' ? (*pnt - 'A' + 10) : (*pnt - '0')); pnt++; } continue; } if (argv[optind + j][0] == '@') { /*Ensure that this string contains an even number of hex-digits */ int len = strlen(argv[optind + j] + 1); if ((len & 1) || (len != (int)strspn(argv[optind + j] + 1, "0123456789ABCDEFabcdef"))) usage("Odd number of chars or non-hex digit in " "@hexdatafield"); replacement_values[j] = (unsigned long) argv[optind + j]; is_hex[j] = 1; continue; } /* Using a tmp here is silly but the most clean approach */ n = sscanf(argv[optind + j], "%ld", &tmp); replacement_values[j] = ((1 == n) ? tmp : 0); } n_replacement_values = argc - optind - 1; } if (show_devs) { show_devices(0); exit(0); } if (show_raw) { show_devices(1); exit(0); } if (optind >= argc) usage("no device name given"); glob_fd = open_sg_io_dev(device_name = argv[optind]); if (glob_fd < 0) { if (-9999 == glob_fd) fprintf(stderr, "Couldn't find sg device corresponding to %s\n", device_name); else { perror("sginfo(open)"); fprintf(stderr, "file=%s, or no corresponding sg device found\n", device_name); fprintf(stderr, "Is sg driver loaded?\n"); } exit(1); } #if 0 if (!x_interface) printf("\n"); #endif if (! (found || mp_i.page || mp_i.subpage || inquiry_verbosity || serial_number)) { if (trace_cmd > 0) fprintf(stdout, "nothing selected so do a short INQUIRY\n"); inquiry_verbosity = 1; } status |= do_inquiry(&mp_i.peri_type, &mp_i.inq_byte6, inquiry_verbosity); if (serial_number) do_serial_number(); /* ignore error */ if (mp_i.page > 0) status |= do_user_page(&mp_i, decode_in_hex); if (defect) status |= read_defect_list(0); if (grown_defect) status |= read_defect_list(1); return status ? 1 : 0; }