/* * apcsmart.c - driver for APC smart protocol units (originally "newapc") * * Copyright (C) 1999 Russell Kroll * (C) 2000 Nigel Metheringham * (C) 2011 Michal Soltys * * 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 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include #include #include #include #include "main.h" #include "serial.h" #include "timehead.h" #include "apcsmart.h" #include "apcsmart_tabs.h" /* driver description structure */ upsdrv_info_t upsdrv_info = { DRIVER_NAME, DRIVER_VERSION, "Russell Kroll \n" "Nigel Metheringham \n" "Michal Soltys ", DRV_STABLE, { &apc_tab_info, NULL } }; static int ups_status = 0; /* some forwards */ static int sdcmd_S(const void *); static int sdcmd_AT(const void *); static int sdcmd_K(const void *); static int sdcmd_Z(const void *); static int sdcmd_CS(const void *); static int (*sdlist[])(const void *) = { sdcmd_S, sdcmd_AT, sdcmd_K, sdcmd_Z, sdcmd_CS, }; #define SDIDX_S 0 #define SDIDX_AT 1 #define SDIDX_K 2 #define SDIDX_Z 3 #define SDIDX_CS 4 #define SDCNT ((int)(sizeof(sdlist)/sizeof(sdlist[0]))) static apc_vartab_t *vartab_lookup_char(char cmdchar) { int i; for (i = 0; apc_vartab[i].name != NULL; i++) if (apc_vartab[i].cmd == cmdchar) return &apc_vartab[i]; return NULL; } static apc_vartab_t *vartab_lookup_name(const char *var) { int i; for (i = 0; apc_vartab[i].name != NULL; i++) if (!(apc_vartab[i].flags & APC_DEPR) && !strcasecmp(apc_vartab[i].name, var)) return &apc_vartab[i]; return NULL; } /* FUTURE: change to use function pointers */ static int rexhlp(const char *rex, const char *val) { int ret; regex_t mbuf; regcomp(&mbuf, rex, REG_EXTENDED|REG_NOSUB); ret = regexec(&mbuf, val, 0,0,0); regfree(&mbuf); return ret; } /* convert APC formatting to NUT formatting */ /* TODO: handle errors better */ static const char *convert_data(apc_vartab_t *cmd_entry, const char *upsval) { static char temp[APC_LBUF]; int tval; /* this should never happen */ if (strlen(upsval) >= sizeof(temp)) { upslogx(LOG_CRIT, "length of [%s] too long", cmd_entry->name); strncpy(temp, upsval, sizeof(temp) - 1); temp[sizeof(temp) - 1] = '\0'; return temp; } switch(cmd_entry->flags & APC_F_MASK) { case APC_F_PERCENT: case APC_F_VOLT: case APC_F_AMP: case APC_F_CELSIUS: case APC_F_HEX: case APC_F_DEC: case APC_F_SECONDS: case APC_F_LEAVE: /* no conversion for any of these */ strcpy(temp, upsval); return temp; case APC_F_HOURS: /* convert to seconds */ tval = 60 * 60 * strtol(upsval, NULL, 10); snprintf(temp, sizeof(temp), "%d", tval); return temp; case APC_F_MINUTES: /* Convert to seconds - NUT standard time measurement */ tval = 60 * strtol(upsval, NULL, 10); /* Ignore errors - there's not much we can do */ snprintf(temp, sizeof(temp), "%d", tval); return temp; case APC_F_REASON: switch (upsval[0]) { case 'R': return "unacceptable utility voltage rate of change"; case 'H': return "high utility voltage"; case 'L': return "low utility voltage"; case 'T': return "line voltage notch or spike"; case 'O': return "no transfers yet since turnon"; case 'S': return "simulated power failure or UPS test"; default: strcpy(temp, upsval); return temp; } } upslogx(LOG_NOTICE, "Unable to handle conversion of [%s]", cmd_entry->name); strcpy(temp, upsval); return temp; } static void apc_ser_set(void) { struct termios tio, tio_chk; char *cable; /* * this must be called before the rest, as ser_set_speed() performs * early initialization of the port, apart from changing speed */ ser_set_speed(upsfd, device_path, B2400); memset(&tio, 0, sizeof(tio)); errno = 0; if (tcgetattr(upsfd, &tio)) fatal_with_errno(EXIT_FAILURE, "tcgetattr(%s)", device_path); /* set port mode: common stuff, canonical processing */ tio.c_cflag |= (CS8 | CLOCAL | CREAD); tio.c_lflag |= ICANON; tio.c_lflag &= ~ISIG; tio.c_iflag |= (IGNCR | IGNPAR); tio.c_iflag &= ~(IXON | IXOFF); tio.c_cc[VEOL] = '*'; /* specially handled in apc_read() */ #ifdef _POSIX_VDISABLE tio.c_cc[VERASE] = _POSIX_VDISABLE; tio.c_cc[VKILL] = _POSIX_VDISABLE; tio.c_cc[VEOF] = _POSIX_VDISABLE; tio.c_cc[VEOL2] = _POSIX_VDISABLE; #endif #if 0 /* unused in canonical mode: */ tio.c_cc[VMIN] = 1; tio.c_cc[VTIME] = 0; #endif if (tcflush(upsfd, TCIOFLUSH)) fatal_with_errno(EXIT_FAILURE, "tcflush(%s)", device_path); /* * warn: * Note, that tcsetattr() returns success if /any/ of the requested * changes could be successfully carried out. Thus the more complicated * test. */ if (tcsetattr(upsfd, TCSANOW, &tio)) fatal_with_errno(EXIT_FAILURE, "tcsetattr(%s)", device_path); memset(&tio_chk, 0, sizeof(tio_chk)); if (tcgetattr(upsfd, &tio_chk)) fatal_with_errno(EXIT_FAILURE, "tcgetattr(%s)", device_path); if (memcmp(&tio_chk, &tio, sizeof(tio))) fatalx(EXIT_FAILURE, "unable to set the required attributes (%s)", device_path); cable = getval("cable"); if (cable && !strcasecmp(cable, ALT_CABLE_1)) { if (ser_set_dtr(upsfd, 1) == -1) fatalx(EXIT_FAILURE, "ser_set_dtr() failed (%s)", device_path); if (ser_set_rts(upsfd, 0) == -1) fatalx(EXIT_FAILURE, "ser_set_rts() failed (%s)", device_path); } } static void ups_status_set(void) { status_init(); if (ups_status & APC_STAT_CAL) status_set("CAL"); /* calibration */ if (ups_status & APC_STAT_TRIM) status_set("TRIM"); /* SmartTrim */ if (ups_status & APC_STAT_BOOST) status_set("BOOST"); /* SmartBoost */ if (ups_status & APC_STAT_OL) status_set("OL"); /* on line */ if (ups_status & APC_STAT_OB) status_set("OB"); /* on battery */ if (ups_status & APC_STAT_OVER) status_set("OVER"); /* overload */ if (ups_status & APC_STAT_LB) status_set("LB"); /* low battery */ if (ups_status & APC_STAT_RB) status_set("RB"); /* replace batt */ if (ups_status == 0) status_set("OFF"); status_commit(); } static void alert_handler(char ch) { switch (ch) { case '!': /* clear OL, set OB */ upsdebugx(4, "alert_handler: OB"); ups_status &= ~APC_STAT_OL; ups_status |= APC_STAT_OB; break; case '$': /* clear OB, set OL */ upsdebugx(4, "alert_handler: OL"); ups_status &= ~APC_STAT_OB; ups_status |= APC_STAT_OL; break; case '%': /* set LB */ upsdebugx(4, "alert_handler: LB"); ups_status |= APC_STAT_LB; break; case '+': /* clear LB */ upsdebugx(4, "alert_handler: not LB"); ups_status &= ~APC_STAT_LB; break; case '#': /* set RB */ upsdebugx(4, "alert_handler: RB"); ups_status |= APC_STAT_RB; break; case '?': /* set OVER */ upsdebugx(4, "alert_handler: OVER"); ups_status |= APC_STAT_OVER; break; case '=': /* clear OVER */ upsdebugx(4, "alert_handler: not OVER"); ups_status &= ~APC_STAT_OVER; break; default: upsdebugx(4, "alert_handler got 0x%02x (unhandled)", ch); break; } ups_status_set(); } /* * we need a tiny bit different processing due to '*' and canonical mode; the * function is subtly different from generic ser_get_line_alert() */ static int apc_read(char *buf, size_t buflen, int flags) { const char *iset = IGN_CHARS, *aset = ""; size_t count = 0; int i, ret, sec = 3, usec = 0; char temp[APC_LBUF]; if (upsfd == -1) return 0; if (flags & SER_D0) { sec = 0; usec = 0; } if (flags & SER_DX) { sec = 0; usec = 200000; } if (flags & SER_D1) { sec = 1; usec = 500000; } if (flags & SER_D3) { sec = 3; usec = 0; } if (flags & SER_AA) { iset = IGN_AACHARS; aset = ALERT_CHARS; } if (flags & SER_CC) { iset = IGN_CCCHARS; aset = ""; sec = 6; usec = 0; } if (flags & SER_CS) { iset = IGN_CSCHARS; aset = ""; sec = 6; usec = 0; } memset(buf, '\0', buflen); while (count < buflen - 1) { errno = 0; ret = select_read(upsfd, temp, sizeof(temp), sec, usec); /* error or no timeout allowed */ if (ret < 0 || (ret == 0 && !(flags & SER_TO))) { ser_comm_fail("%s", ret ? strerror(errno) : "timeout"); return ret; } /* ok, timeout is acceptable */ if (ret == 0 && (flags & SER_TO)) { /* * but it doesn't imply ser_comm_good * * to be more precise - we might be in comm_fail * condition, trying to "nudge" the UPS with some * command obviously expecting timeout if the comm is * still lost. This would result with filling logs with * confusing comm lost/comm re-established pairs. Thus * - just return here. */ return count; } /* parse input */ for (i = 0; i < ret; i++) { /* standard "line received" condition */ if ((count == buflen - 1) || (temp[i] == ENDCHAR)) { ser_comm_good(); return count; } /* * '*' is set as a secondary EOL; convert to 'OK' only as a * reply to shutdown command in sdok(); otherwise next * select_read() will continue normally */ if ((flags & SER_HA) && temp[i] == '*') { /* * a bit paranoid, but remember '*' is not real EOL; * there could be some firmware in existence, that * would send both string: 'OK\n' and alert: '*'. * Just in case, try to flush the input with small 1 sec. * timeout */ memset(buf, '\0', buflen); errno = 0; ret = select_read(upsfd, temp, sizeof(temp), 1, 0); if (ret < 0) { ser_comm_fail("%s", strerror(errno)); return ret; } buf[0] = 'O'; buf[1] = 'K'; ser_comm_good(); return 2; } /* ignore set */ if (strchr(iset, temp[i]) || temp[i] == '*') { continue; } /* alert set */ if (strchr(aset, temp[i])) { alert_handler(temp[i]); continue; } buf[count++] = temp[i]; } } ser_comm_good(); return count; } static int apc_write(unsigned char code) { errno = 0; if (upsfd == -1) return 0; return ser_send_char(upsfd, code); } /* * We have to watch out for NA, here; * This is generally safe, as otherwise we will just timeout. The reason we do * it, is that under certain conditions an ups might respond with NA for * something it would normally handle (e.g. calling @ while being in powered * off or hibernated state. If we keep sending the "arguments" after getting * NA, they will be interpreted as commands, which is quite a bug :) * Furthermore later flushes might not work properly, if the reply to those * commands are generated with some delay. * * We also set errno to something usable, so outside upslog calls don't output * confusing "success". */ static int apc_write_long(const char *code) { char temp[APC_LBUF]; int ret; errno = 0; if (upsfd == -1) return 0; ret = ser_send_char(upsfd, *code); if (ret != 1) return ret; /* peek for the answer - anything at this point is failure */ ret = apc_read(temp, sizeof(temp), SER_DX|SER_TO); if (ret) { errno = ECANCELED; return -1; } return ser_send_pace(upsfd, 50000, "%s", code + 1); } static int apc_write_rep(unsigned char code) { char temp[APC_LBUF]; int ret; errno = 0; if (upsfd == -1) return 0; ret = ser_send_char(upsfd, code); if (ret != 1) return ret; /* peek for the answer - anything at this point is failure */ ret = apc_read(temp, sizeof(temp), SER_DX|SER_TO); if (ret) { errno = ECANCELED; return -1; } usleep(1300000); ret = ser_send_char(upsfd, code); if (ret != 1) return ret; return 2; } /* all flags other than SER_AA are ignored */ static void apc_flush(int flags) { char temp[APC_LBUF]; if (flags & SER_AA) { tcflush(upsfd, TCOFLUSH); while(apc_read(temp, sizeof(temp), SER_D0|SER_TO|SER_AA)); } else { tcflush(upsfd, TCIOFLUSH); /* tcflush(upsfd, TCIFLUSH); */ /* while(apc_read(temp, sizeof(temp), SER_D0|SER_TO)); */ } } static const char *preread_data(apc_vartab_t *vt) { int ret; char temp[APC_LBUF]; upsdebugx(4, "preread_data: %s", vt->name); apc_flush(0); ret = apc_write(vt->cmd); if (ret != 1) { upslogx(LOG_ERR, "preread_data: apc_write failed"); return 0; } ret = apc_read(temp, sizeof(temp), SER_TO); if (ret < 0) { upslogx(LOG_ERR, "preread_data: apc_read failed"); return 0; } if (!ret || !strcmp(temp, "NA")) { upslogx(LOG_ERR, "preread_data: %s timed out or not supported", vt->name); return 0; } return convert_data(vt, temp); } static void remove_var(const char *cal, apc_vartab_t *vt) { const char *fmt; char info[256]; if (isprint(vt->cmd)) fmt = "[%c]"; else fmt = "[0x%02x]"; snprintf(info, sizeof(info), "%s%s%s", "%s: verified variable [%s] (APC: ", fmt, ") returned NA" ); upsdebugx(1, info, cal, vt->name, vt->cmd); snprintf(info, sizeof(info), "%s%s%s", "%s: removing [%s] (APC: ", fmt, ")" ); upsdebugx(1, info, cal, vt->name, vt->cmd); vt->flags &= ~APC_PRESENT; dstate_delinfo(vt->name); } static int poll_data(apc_vartab_t *vt) { int ret; char temp[APC_LBUF]; if (!(vt->flags & APC_PRESENT)) return 1; upsdebugx(4, "poll_data: %s", vt->name); apc_flush(SER_AA); ret = apc_write(vt->cmd); if (ret != 1) { upslogx(LOG_ERR, "poll_data: apc_write failed"); dstate_datastale(); return 0; } if (apc_read(temp, sizeof(temp), SER_AA) < 1) { dstate_datastale(); return 0; } /* automagically no longer supported by the hardware somehow */ if (!strcmp(temp, "NA")) remove_var("poll_data", vt); dstate_setinfo(vt->name, "%s", convert_data(vt, temp)); dstate_dataok(); return 1; } static int dfa_fwnew(const char *val) { int ret; regex_t mbuf; /* must be xx.yy.zz */ const char rex[] = "^[[:alnum:]]+\\.[[:alnum:]]+\\.[[:alnum:]]+$"; regcomp(&mbuf, rex, REG_EXTENDED|REG_NOSUB); ret = regexec(&mbuf, val, 0,0,0); regfree(&mbuf); return ret; } static int dfa_cmdset(const char *val) { int ret; regex_t mbuf; /* * must be #.alerts.commands ; we'll be a bit lax here */ const char rex[] = "^[0-9]\\.[^.]*\\.[^.]+$"; regcomp(&mbuf, rex, REG_EXTENDED|REG_NOSUB); ret = regexec(&mbuf, val, 0,0,0); regfree(&mbuf); return ret; } static int valid_cmd(char cmd, const char *val) { char info[256], *fmt; int ret; switch (cmd) { case APC_FW_NEW: ret = dfa_fwnew(val); break; case APC_CMDSET: ret = dfa_cmdset(val); break; default: return 1; } if (ret) { if (isprint(cmd)) fmt = "[%c]"; else fmt = "[0x%02x]"; snprintf(info, sizeof(info), "%s%s%s", "valid_cmd: cmd ", fmt, " failed regex match" ); upslogx(LOG_WARNING, info, cmd); } return !ret; } /* * query_ups() is called before any APC_PRESENT flags are determined; * only for the variable provided */ static int query_ups(const char *var) { int i, j; const char *temp; apc_vartab_t *vt, *vtn; /* * at first run we know nothing about variable; we have to handle * APC_MULTI gracefully as well */ for (i = 0; apc_vartab[i].name != NULL; i++) { vt = &apc_vartab[i]; if (strcmp(vt->name, var) || vt->flags & APC_DEPR) continue; /* found, [try to] get it */ temp = preread_data(vt); if (!temp || !valid_cmd(vt->cmd, temp)) { if (vt->flags & APC_MULTI) { vt->flags |= APC_DEPR; continue; } upsdebugx(1, "query_ups: unknown variable %s", var); break; } vt->flags |= APC_PRESENT; dstate_setinfo(vt->name, "%s", temp); dstate_dataok(); /* supported, deprecate all the remaining ones */ if (vt->flags & APC_MULTI) for (j = i + 1; apc_vartab[j].name != NULL; j++) { vtn = &apc_vartab[j]; if (strcmp(vtn->name, vt->name)) continue; vtn->flags |= APC_DEPR; vtn->flags &= ~APC_PRESENT; } return 1; /* success */ } return 0; } /* * This function iterates over vartab, deprecating nut:apc 1:n variables. We * prefer earliest present variable. All the other ones must be marked as * deprecated and as not present. * This is intended to call after verifying the presence of variables. * Otherwise it would take a while to execute due to preread_data() */ static void deprecate_vars(void) { int i, j; const char *temp; apc_vartab_t *vt, *vtn; for (i = 0; apc_vartab[i].name != NULL; i++) { vt = &apc_vartab[i]; if (vt->flags & APC_DEPR) /* already handled */ continue; if (!(vt->flags & APC_MULTI)) continue; if (!(vt->flags & APC_PRESENT)) { vt->flags |= APC_DEPR; continue; } /* pre-read data, we have to verify it */ temp = preread_data(vt); if (!temp || !valid_cmd(vt->cmd, temp)) { upslogx(LOG_ERR, "deprecate_vars: [%s] is unreadable or invalid, deprecating", vt->name); vt->flags |= APC_DEPR; vt->flags &= ~APC_PRESENT; continue; } /* multi & present, deprecate all the remaining ones */ for (j = i + 1; apc_vartab[j].name != NULL; j++) { vtn = &apc_vartab[j]; if (strcmp(vtn->name, vt->name)) continue; vtn->flags |= APC_DEPR; vtn->flags &= ~APC_PRESENT; } dstate_setinfo(vt->name, "%s", temp); dstate_dataok(); } } static void do_capabilities(int qco) { const char *ptr, *entptr; char upsloc, temp[APC_LBUF], cmd, loc, etmp[APC_SBUF], *endtemp; int nument, entlen, i, matrix, ret, valid; apc_vartab_t *vt; upsdebugx(1, "APC - About to get capabilities string"); /* If we can do caps, then we need the Firmware revision which has the locale descriptor as the last character (ugh) */ ptr = dstate_getinfo("ups.firmware"); if (ptr) upsloc = ptr[strlen(ptr) - 1]; else upsloc = 0; /* get capability string */ apc_flush(0); ret = apc_write(APC_CAPS); if (ret != 1) { upslog_with_errno(LOG_ERR, "do_capabilities: apc_write failed"); return; } /* * note - apc_read() needs larger timeout grace and different * ignore set due to certain characters like '#' being received */ ret = apc_read(temp, sizeof(temp), SER_CC|SER_TO); if ((ret < 1) || (!strcmp(temp, "NA"))) { /* Early Smart-UPS, not as smart as later ones */ /* This should never happen since we only call this if the REQ_CAPABILITIES command is supported */ upslogx(LOG_ERR, "ERROR: APC cannot do capabilities but said it could !"); return; } /* recv always puts a \0 at the end, so this is safe */ /* however it assumes a zero byte cannot be embedded */ endtemp = &temp[0] + strlen(temp); if (temp[0] != '#') { upsdebugx(1, "unrecognized capability start char %c", temp[0]); upsdebugx(1, "please report this error [%s]", temp); upslogx(LOG_ERR, "ERROR: unknown capability start char %c!", temp[0]); return; } if (temp[1] == '#') { /* Matrix-UPS */ matrix = 1; ptr = &temp[0]; } else { ptr = &temp[1]; matrix = 0; } /* command char, location, # of entries, entry length */ while (ptr[0] != '\0') { if (matrix) ptr += 2; /* jump over repeating ## */ /* check for idiocy */ if (ptr >= endtemp) { /* if we expected this, just ignore it */ if (qco) return; fatalx(EXIT_FAILURE, "capability string has overflowed\n" "please report this error\n" "ERROR: capability overflow!" ); } cmd = ptr[0]; loc = ptr[1]; nument = ptr[2] - 48; entlen = ptr[3] - 48; entptr = &ptr[4]; vt = vartab_lookup_char(cmd); valid = vt && ((loc == upsloc) || (loc == '4')); /* mark this as writable */ if (valid) { upsdebugx(1, "supported capability: %02x (%c) - %s", cmd, loc, vt->name); dstate_setflags(vt->name, ST_FLAG_RW); /* make sure setvar knows what this is */ vt->flags |= APC_RW | APC_ENUM; } for (i = 0; i < nument; i++) { if (valid) { snprintf(etmp, entlen + 1, "%s", entptr); dstate_addenum(vt->name, "%s", convert_data(vt, etmp)); } entptr += entlen; } ptr = entptr; } } static int update_status(void) { int ret; char buf[APC_LBUF]; upsdebugx(4, "update_status"); apc_flush(SER_AA); ret = apc_write(APC_STATUS); if (ret != 1) { upslog_with_errno(LOG_ERR, "update_status: apc_write failed"); dstate_datastale(); return 0; } ret = apc_read(buf, sizeof(buf), SER_AA); if ((ret < 1) || (!strcmp(buf, "NA"))) { dstate_datastale(); return 0; } ups_status = strtol(buf, 0, 16) & 0xff; ups_status_set(); dstate_dataok(); return 1; } static void oldapcsetup(void) { /* really old models ignore REQ_MODEL, so find them first */ if (!query_ups("ups.model")) { /* force the model name */ dstate_setinfo("ups.model", "Smart-UPS"); } /* see if this might be an old Matrix-UPS instead */ if (query_ups("output.current")) dstate_setinfo("ups.model", "Matrix-UPS"); query_ups("ups.firmware"); query_ups("ups.serial"); query_ups("input.voltage"); query_ups("battery.charge"); query_ups("battery.voltage"); query_ups("input.voltage"); query_ups("output.voltage"); query_ups("ups.temperature"); query_ups("ups.load"); update_status(); /* * If we have come down this path then we dont do capabilities and * other shiny features. */ } static void protocol_verify(unsigned char cmd) { int i, found; const char *fmt, *temp; char info[256]; /* don't bother with cmd/var we don't care about */ if (strchr(APC_UNR_CMDS, cmd)) return; if (isprint(cmd)) fmt = "[%c]"; else fmt = "[0x%02x]"; /* * see if it's a variable * note: some nut variables map onto multiple APC ones (firmware) */ for (i = 0; apc_vartab[i].name != NULL; i++) { if (apc_vartab[i].cmd == cmd) { if (apc_vartab[i].flags & APC_MULTI) { /* APC_MULTI are handled by deprecate_vars() */ apc_vartab[i].flags |= APC_PRESENT; return; } temp = preread_data(&apc_vartab[i]); if (!temp || !valid_cmd(cmd, temp)) { snprintf(info, sizeof(info), "%s%s%s", "UPS variable [%s] - APC: ", fmt, " invalid or unreadable" ); upsdebugx(3, info, apc_vartab[i].name, cmd); return; } apc_vartab[i].flags |= APC_PRESENT; snprintf(info, sizeof(info), "%s%s", "UPS supports variable [%s] - APC: ", fmt ); upsdebugx(3, info, apc_vartab[i].name, cmd); dstate_setinfo(apc_vartab[i].name, "%s", temp); dstate_dataok(); /* handle special data for our two strings */ if (apc_vartab[i].flags & APC_STRING) { dstate_setflags(apc_vartab[i].name, ST_FLAG_RW | ST_FLAG_STRING); dstate_setaux(apc_vartab[i].name, APC_STRLEN); apc_vartab[i].flags |= APC_RW; } return; } } /* * check the command list * some APC commands map onto multiple nut ones (start and stop) */ found = 0; for (i = 0; apc_cmdtab[i].name != NULL; i++) { if (apc_cmdtab[i].cmd == cmd) { snprintf(info, sizeof(info), "%s%s", "UPS supports command [%s] - APC: ", fmt ); upsdebugx(3, info, apc_cmdtab[i].name, cmd); dstate_addcmd(apc_cmdtab[i].name); apc_cmdtab[i].flags |= APC_PRESENT; found = 1; } } if (found) return; snprintf(info, sizeof(info), "%s%s%s", "protocol_verify - APC: ", fmt, " unrecognized" ); upsdebugx(1, info, cmd); } /* some hardware is a special case - hotwire the list of cmdchars */ static int firmware_table_lookup(void) { int ret; unsigned int i, j; char buf[APC_LBUF]; upsdebugx(1, "attempting firmware lookup using command 'V'"); apc_flush(0); ret = apc_write(APC_FW_OLD); if (ret != 1) { upslog_with_errno(LOG_ERR, "firmware_table_lookup: apc_write failed"); return 0; } ret = apc_read(buf, sizeof(buf), SER_TO); /* * Some UPSes support both 'V' and 'b'. As 'b' doesn't always return * firmware version, we attempt that only if 'V' doesn't work. */ if ((ret < 1) || (!strcmp(buf, "NA"))) { upsdebugx(1, "attempting firmware lookup using command 'b'"); ret = apc_write(APC_FW_NEW); if (ret != 1) { upslog_with_errno(LOG_ERR, "firmware_table_lookup: apc_write failed"); return 0; } ret = apc_read(buf, sizeof(buf), SER_TO); if (ret < 1) { upslog_with_errno(LOG_ERR, "firmware_table_lookup: apc_read failed"); return 0; } } upsdebugx(2, "firmware: [%s]", buf); /* this will be reworked if we get a lot of these things */ if (!strcmp(buf, "451.2.I")) /* quirk_capability_overflow */ return 2; for (i = 0; apc_compattab[i].firmware != NULL; i++) { if (!strcmp(apc_compattab[i].firmware, buf)) { upsdebugx(2, "matched - cmdchars: %s", apc_compattab[i].cmdchars); if (strspn(apc_compattab[i].firmware, "05")) { dstate_setinfo("ups.model", "Matrix-UPS"); } else { dstate_setinfo("ups.model", "Smart-UPS"); } /* matched - run the cmdchars from the table */ for (j = 0; j < strlen(apc_compattab[i].cmdchars); j++) protocol_verify(apc_compattab[i].cmdchars[j]); deprecate_vars(); return 1; /* matched */ } } return 0; } static void getbaseinfo(void) { unsigned int i; int ret, qco; char *cmds, temp[APC_LBUF]; /* * try firmware lookup first; we could start with 'a', but older models * sometimes return other things than a command set */ qco = firmware_table_lookup(); if (qco == 1) /* found compat */ return; upsdebugx(2, "firmware not found in compatibility table - trying normal method"); upsdebugx(1, "APC - attempting to find command set"); /* * Initially we ask the UPS what commands it takes If this fails we are * going to need an alternate strategy - we can deal with that if it * happens */ apc_flush(0); ret = apc_write(APC_CMDSET); if (ret != 1) { upslog_with_errno(LOG_ERR, "getbaseinfo: apc_write failed"); return; } ret = apc_read(temp, sizeof(temp), SER_CS|SER_TO); if ((ret < 1) || (!strcmp(temp, "NA")) || !valid_cmd(APC_CMDSET, temp)) { /* We have an old dumb UPS - go to specific code for old stuff */ upsdebugx(1, "APC - trying to handle unknown model"); oldapcsetup(); return; } upsdebugx(1, "APC - Parsing out supported cmds and vars"); /* * returned set is verified for validity above, so just extract * what's interesting for us */ cmds = strrchr(temp, '.'); for (i = 1; i < strlen(cmds); i++) protocol_verify(cmds[i]); deprecate_vars(); /* if capabilities are supported, add them here */ if (strchr(cmds, APC_CAPS)) { do_capabilities(qco); upsdebugx(1, "APC - UPS capabilities determined"); } } /* check for calibration status and either start or stop */ static int do_cal(int start) { char temp[APC_LBUF]; int tval, ret; apc_flush(SER_AA); ret = apc_write(APC_STATUS); if (ret != 1) { upslog_with_errno(LOG_ERR, "do_cal: apc_write failed"); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } ret = apc_read(temp, sizeof(temp), SER_AA); /* if we can't check the current calibration status, bail out */ if ((ret < 1) || (!strcmp(temp, "NA"))) return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ tval = strtol(temp, 0, 16); if (tval & APC_STAT_CAL) { /* calibration currently happening */ if (start == 1) { /* requested start while calibration still running */ upslogx(LOG_INFO, "runtime calibration already in progress"); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } /* stop requested */ upslogx(LOG_INFO, "stopping runtime calibration"); ret = apc_write(APC_CMD_CALTOGGLE); if (ret != 1) { upslog_with_errno(LOG_ERR, "do_cal: apc_write failed"); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } ret = apc_read(temp, sizeof(temp), SER_AA); if ((ret < 1) || (!strcmp(temp, "NA")) || (!strcmp(temp, "NO"))) { upslogx(LOG_WARNING, "stop calibration failed: %s", temp); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } return STAT_INSTCMD_HANDLED; /* FUTURE: success */ } /* calibration not happening */ if (start == 0) { /* stop requested */ upslogx(LOG_INFO, "runtime calibration not occurring"); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } upslogx(LOG_INFO, "starting runtime calibration"); ret = apc_write(APC_CMD_CALTOGGLE); if (ret != 1) { upslog_with_errno(LOG_ERR, "do_cal: apc_write failed"); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } ret = apc_read(temp, sizeof(temp), SER_AA); if ((ret < 1) || (!strcmp(temp, "NA")) || (!strcmp(temp, "NO"))) { upslogx(LOG_WARNING, "start calibration failed: %s", temp); return STAT_INSTCMD_HANDLED; /* FUTURE: failure */ } return STAT_INSTCMD_HANDLED; /* FUTURE: success */ } #if 0 /* get the UPS talking to us in smart mode */ static int smartmode(void) { int ret; char temp[APC_LBUF]; apc_flush(0); ret = apc_write(APC_GOSMART); if (ret != 1) { upslog_with_errno(LOG_ERR, "smartmode: apc_write failed"); return 0; } ret = apc_read(temp, sizeof(temp), 0); if ((ret < 1) || (!strcmp(temp, "NA")) || (!strcmp(temp, "NO"))) { upslogx(LOG_CRIT, "enabling smartmode failed !"); return 0; } return 1; } #endif /* * get the UPS talking to us in smart mode * note: this is weird overkill, but possibly excused due to some obscure * hardware/firmware combinations; simpler version commmented out above, for * now let's keep minimally adjusted old one */ static int smartmode(int cnt) { int ret, tries; char temp[APC_LBUF]; for (tries = 0; tries < cnt; tries++) { apc_flush(0); ret = apc_write(APC_GOSMART); if (ret != 1) { upslog_with_errno(LOG_ERR, "smartmode: issuing 'Y' failed"); return 0; } ret = apc_read(temp, sizeof(temp), SER_D1); if (ret > 0 && !strcmp(temp, "SM")) return 1; /* success */ if (ret < 0) { /* error, so we didn't timeout - wait a bit before retry */ sleep(1); } apc_flush(0); ret = apc_write(27); /* ESC */ if (ret != 1) { upslog_with_errno(LOG_ERR, "smartmode: issuing ESC failed"); return 0; } /* eat the response (might be NA, might be something else) */ apc_read(temp, sizeof(temp), SER_TO|SER_D1); } return 0; /* failure */ } /* * all shutdown commands should respond with 'OK' or '*' * apc_read() handles conversion to 'OK' so we care only about that one * ign allows for timeout without assuming an error */ static int sdok(int ign) { int ret; char temp[APC_SBUF]; /* * older upses on failed commands might just timeout, we cut down * timeout grace though * furthermore, command 'Z' will not reply with anything */ ret = apc_read(temp, sizeof(temp), SER_HA|SER_D1|SER_TO); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdok: apc_read failed"); return STAT_INSTCMD_FAILED; } upsdebugx(4, "sdok: got \"%s\"", temp); if ((!ret && ign) || !strcmp(temp, "OK")) { upsdebugx(4, "sdok: last issued shutdown cmd succeeded"); return STAT_INSTCMD_HANDLED; } upsdebugx(1, "sdok: last issued shutdown cmd failed"); return STAT_INSTCMD_FAILED; } /* soft hibernate: S - working only when OB, otherwise ignored */ static int sdcmd_S(const void *foo) { int ret; apc_flush(0); upsdebugx(1, "issuing soft hibernate"); ret = apc_write(APC_CMD_SOFTDOWN); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdcmd_S: issuing 'S' failed"); return STAT_INSTCMD_FAILED; } return sdok(0); } /* soft hibernate, hack version for CS 350 & co. */ static int sdcmd_CS(const void *foo) { int ret; char temp[APC_SBUF]; upsdebugx(1, "using CS 350 'force OB' shutdown method"); if (ups_status & APC_STAT_OL) { apc_flush(0); upsdebugx(1, "status OL - forcing OB temporarily"); ret = apc_write(APC_CMD_SIMPWF); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdcmd_CS: issuing 'U' failed"); return STAT_INSTCMD_FAILED; } /* eat response */ ret = apc_read(temp, sizeof(temp), SER_D1); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdcmd_CS: 'U' returned nothing ?"); return STAT_INSTCMD_FAILED; } } return sdcmd_S(0); } /* * hard hibernate: @nnn / @nn * note: works differently for older and new models, see manual page for * thorough explanation */ static int sdcmd_AT(const void *str) { int ret, cnt, padto, i; const char *awd = str; char temp[APC_SBUF], *ptr; if (!awd) awd = "000"; cnt = strlen(awd); padto = cnt == 2 ? 2 : 3; temp[0] = APC_CMD_GRACEDOWN; ptr = temp + 1; for (i = cnt; i < padto ; i++) { *ptr++ = '0'; } strcpy(ptr, awd); upsdebugx(1, "issuing '@' with %d minutes of additional wakeup delay", (int)strtol(awd, NULL, 10)*6); apc_flush(0); ret = apc_write_long(temp); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdcmd_AT: issuing '@' with %d digits failed", padto); return STAT_INSTCMD_FAILED; } ret = sdok(0); if (ret == STAT_INSTCMD_HANDLED || padto == 3) return ret; upslog_with_errno(LOG_ERR, "sdcmd_AT: command '@' with 2 digits doesn't work - try 3 digits"); /* * "tricky" part - we tried @nn variation and it (unsurprisingly) * failed; we have to abort the sequence with something bogus to have * the clean state; newer upses will respond with 'NO', older will be * silent (YMMV); */ apc_write(APC_CMD_GRACEDOWN); /* eat response, allow it to timeout */ apc_read(temp, sizeof(temp), SER_D1|SER_TO); return STAT_INSTCMD_FAILED; } /* shutdown: K - delayed poweroff */ static int sdcmd_K(const void *foo) { int ret; upsdebugx(1, "issuing 'K'"); apc_flush(0); ret = apc_write_rep(APC_CMD_SHUTDOWN); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdcmd_K: issuing 'K' failed"); return STAT_INSTCMD_FAILED; } return sdok(0); } /* shutdown: Z - immediate poweroff */ static int sdcmd_Z(const void *foo) { int ret; upsdebugx(1, "issuing 'Z'"); apc_flush(0); ret = apc_write_rep(APC_CMD_OFF); if (ret < 0) { upslog_with_errno(LOG_ERR, "sdcmd_Z: issuing 'Z' failed"); return STAT_INSTCMD_FAILED; } /* note: ups will not reply anything after this command */ return sdok(1); } static void upsdrv_shutdown_simple(void) { unsigned int sdtype = 0; const char *val; if ((val = getval("sdtype"))) sdtype = strtol(val, NULL, 10); switch (sdtype) { case 5: /* hard hibernate */ sdcmd_AT(getval("awd")); break; case 4: /* special hack for CS 350 and similar models */ sdcmd_CS(0); break; case 3: /* delayed poweroff */ sdcmd_K(0); break; case 2: /* instant poweroff */ sdcmd_Z(0); break; case 1: /* * Send a combined set of shutdown commands which can work * better if the UPS gets power during shutdown process * Specifically it sends both the soft shutdown 'S' and the * hard hibernate '@nnn' commands */ upsdebugx(1, "UPS - currently %s - sending soft/hard hibernate commands", (ups_status & APC_STAT_OL) ? "on-line" : "on battery"); /* S works only when OB */ if ((ups_status & APC_STAT_OB) && sdcmd_S(0) == STAT_INSTCMD_HANDLED) break; sdcmd_AT(getval("awd")); break; default: /* * Send @nnn or S, depending on OB / OL status */ if (ups_status & APC_STAT_OL) /* on line */ sdcmd_AT(getval("awd")); else sdcmd_S(0); } } static void upsdrv_shutdown_advanced(void) { const void *arg; const char *val; size_t i, len; val = getval("advorder"); len = strlen(val); /* * try each method in the list with a little bit of handling in certain * cases */ for (i = 0; i < len; i++) { switch (val[i] - '0') { case SDIDX_AT: arg = getval("awd"); break; default: arg = NULL; } if (sdlist[val[i] - '0'](arg) == STAT_INSTCMD_HANDLED) break; /* finish if command succeeded */ } } /* power down the attached load immediately */ void upsdrv_shutdown(void) { char temp[APC_LBUF]; int ret; if (!smartmode(1)) upsdebugx(1, "SM detection failed. Trying a shutdown command anyway"); /* check the line status */ ret = apc_write(APC_STATUS); if (ret == 1) { ret = apc_read(temp, sizeof(temp), SER_D1); if (ret < 1) { upsdebugx(1, "status read failed ! assuming on battery state"); ups_status = APC_STAT_LB | APC_STAT_OB; } else { ups_status = strtol(temp, 0, 16); } } else { upsdebugx(1, "status request failed; assuming on battery state"); ups_status = APC_STAT_LB | APC_STAT_OB; } if (testvar("advorder") && strcasecmp(getval("advorder"), "no")) upsdrv_shutdown_advanced(); else upsdrv_shutdown_simple(); } static void update_info_normal(void) { int i; upsdebugx(3, "update_info_normal: starting"); for (i = 0; apc_vartab[i].name != NULL; i++) { if ((apc_vartab[i].flags & APC_POLL) == 0) continue; if (!poll_data(&apc_vartab[i])) { upsdebugx(3, "update_info_normal: poll_data (%s) failed - " "aborting scan", apc_vartab[i].name); return; } } upsdebugx(3, "update_info_normal: done"); } static void update_info_all(void) { int i; upsdebugx(3, "update_info_all: starting"); for (i = 0; apc_vartab[i].name != NULL; i++) { if (!poll_data(&apc_vartab[i])) { upsdebugx(3, "update_info_all: poll_data (%s) failed - " "aborting scan", apc_vartab[i].name); return; } } upsdebugx(3, "update_info_all: done"); } static int setvar_enum(apc_vartab_t *vt, const char *val) { int i, ret; char orig[APC_LBUF], temp[APC_LBUF]; const char *ptr; apc_flush(SER_AA); ret = apc_write(vt->cmd); if (ret != 1) { upslog_with_errno(LOG_ERR, "setvar_enum: apc_write failed"); return STAT_SET_FAILED; } ret = apc_read(orig, sizeof(orig), SER_AA); if ((ret < 1) || (!strcmp(orig, "NA"))) return STAT_SET_FAILED; ptr = convert_data(vt, orig); /* suppress redundant changes - easier on the eeprom */ if (!strcmp(ptr, val)) { upslogx(LOG_INFO, "ignoring enum SET %s='%s' (unchanged value)", vt->name, val); return STAT_SET_HANDLED; /* FUTURE: no change */ } for (i = 0; i < 6; i++) { ret = apc_write(APC_NEXTVAL); if (ret != 1) { upslog_with_errno(LOG_ERR, "setvar_enum: apc_write failed"); return STAT_SET_FAILED; } /* this should return either OK (if rotated) or NO (if not) */ ret = apc_read(temp, sizeof(temp), SER_AA); if ((ret < 1) || (!strcmp(temp, "NA"))) return STAT_SET_FAILED; /* sanity checks */ if (!strcmp(temp, "NO")) return STAT_SET_FAILED; if (strcmp(temp, "OK")) return STAT_SET_FAILED; /* see what it rotated onto */ ret = apc_write(vt->cmd); if (ret != 1) { upslog_with_errno(LOG_ERR, "setvar_enum: apc_write failed"); return STAT_SET_FAILED; } ret = apc_read(temp, sizeof(temp), SER_AA); if ((ret < 1) || (!strcmp(temp, "NA"))) return STAT_SET_FAILED; ptr = convert_data(vt, temp); upsdebugx(1, "rotate value: got [%s], want [%s]", ptr, val); if (!strcmp(ptr, val)) { /* got it */ upslogx(LOG_INFO, "SET %s='%s'", vt->name, val); /* refresh data from the hardware */ poll_data(vt); /* query_ups(vt->name, 0); */ return STAT_SET_HANDLED; /* FUTURE: success */ } /* check for wraparound */ if (!strcmp(ptr, orig)) { upslogx(LOG_ERR, "setvar: variable %s wrapped", vt->name); return STAT_SET_FAILED; } } upslogx(LOG_ERR, "setvar: gave up after 6 tries for %s", vt->name); /* refresh data from the hardware */ poll_data(vt); /* query_ups(vt->name, 0); */ return STAT_SET_HANDLED; } static int setvar_string(apc_vartab_t *vt, const char *val) { unsigned int i; int ret; char temp[APC_LBUF], *ptr; /* sanitize length */ if (strlen(val) > APC_STRLEN) { upslogx(LOG_ERR, "setvar_string: value (%s) too long", val); return STAT_SET_FAILED; } apc_flush(SER_AA); ret = apc_write(vt->cmd); if (ret != 1) { upslog_with_errno(LOG_ERR, "setvar_string: apc_write failed"); return STAT_SET_FAILED; } ret = apc_read(temp, sizeof(temp), SER_AA); if ((ret < 1) || (!strcmp(temp, "NA"))) return STAT_SET_FAILED; /* suppress redundant changes - easier on the eeprom */ if (!strcmp(temp, val)) { upslogx(LOG_INFO, "ignoring string SET %s='%s' (unchanged value)", vt->name, val); return STAT_SET_HANDLED; /* FUTURE: no change */ } /* length sanitized above */ temp[0] = APC_NEXTVAL; strcpy(temp + 1, val); ptr = temp + strlen(temp); for (i = strlen(val); i < APC_STRLEN; i++) *ptr++ = '\015'; /* pad with CRs */ *ptr = 0; ret = apc_write_long(ptr); if ((size_t)ret != strlen(ptr)) { upslog_with_errno(LOG_ERR, "setvar_string: apc_write_long failed"); return STAT_SET_FAILED; } ret = apc_read(temp, sizeof(temp), SER_AA); if (ret < 1) { upslogx(LOG_ERR, "setvar_string: short final read"); return STAT_SET_FAILED; } if (!strcmp(temp, "NO")) { upslogx(LOG_ERR, "setvar_string: got NO at final read"); return STAT_SET_FAILED; } /* refresh data from the hardware */ poll_data(vt); /* query_ups(vt->name, 0); */ upslogx(LOG_INFO, "SET %s='%s'", vt->name, val); return STAT_SET_HANDLED; /* FUTURE: success */ } static int setvar(const char *varname, const char *val) { apc_vartab_t *vt; vt = vartab_lookup_name(varname); if (!vt) return STAT_SET_UNKNOWN; if ((vt->flags & APC_RW) == 0) { upslogx(LOG_WARNING, "setvar: [%s] is not writable", varname); return STAT_SET_UNKNOWN; } if (vt->flags & APC_ENUM) return setvar_enum(vt, val); if (vt->flags & APC_STRING) return setvar_string(vt, val); upslogx(LOG_WARNING, "setvar: Unknown type for [%s]", varname); return STAT_SET_UNKNOWN; } /* load on */ static int do_loadon(void) { int ret; apc_flush(0); upsdebugx(1, "issuing load-on command"); ret = apc_write_rep(APC_CMD_ON); if (ret < 0) { upslog_with_errno(LOG_ERR, "do_loadon: apc_write_rep failed"); return STAT_INSTCMD_FAILED; } /* * ups will not reply anything after this command, but might * generate brief OVER condition (which will be corrected on * the next status update) */ upsdebugx(1, "load-on command (apc:^N) executed"); return STAT_INSTCMD_HANDLED; } /* actually send the instcmd's char to the ups */ static int do_cmd(const apc_cmdtab_t *ct) { int ret; char temp[APC_LBUF]; const char *strerr; apc_flush(SER_AA); if (ct->flags & APC_REPEAT) { ret = apc_write_rep(ct->cmd); strerr = "apc_write_rep"; } else { ret = apc_write(ct->cmd); strerr = "apc_write"; } if (ret < 1) { upslog_with_errno(LOG_ERR, "do_cmd: %s failed", strerr); return STAT_INSTCMD_FAILED; } ret = apc_read(temp, sizeof(temp), SER_AA); if (ret < 1) return STAT_INSTCMD_FAILED; if (strcmp(temp, "OK")) { upslogx(LOG_WARNING, "got [%s] after command [%s]", temp, ct->name); return STAT_INSTCMD_FAILED; } upslogx(LOG_INFO, "command: %s", ct->name); return STAT_INSTCMD_HANDLED; } /* some commands must be repeated in a window to execute */ static int instcmd_chktime(apc_cmdtab_t *ct, const char *ext) { double elapsed; time_t now; static time_t last = 0; time(&now); elapsed = difftime(now, last); last = now; /* you have to hit this in a small window or it fails */ if ((elapsed < MINCMDTIME) || (elapsed > MAXCMDTIME)) { upsdebugx(1, "instcmd_chktime: outside window for [%s %s] (%2.0f)", ct->name, ext ? ext : "\b", elapsed); return 0; } return 1; } static int instcmd(const char *cmd, const char *ext) { int i; apc_cmdtab_t *ct = NULL; for (i = 0; apc_cmdtab[i].name != NULL; i++) { /* main command must match */ if (strcasecmp(apc_cmdtab[i].name, cmd)) continue; /* extra was provided - check it */ if (ext && *ext) { if (!apc_cmdtab[i].ext) continue; if (strlen(apc_cmdtab[i].ext) > 2) { if (rexhlp(apc_cmdtab[i].ext, ext)) continue; } else { if (strcasecmp(apc_cmdtab[i].ext, ext)) continue; } } else if (apc_cmdtab[i].ext) continue; ct = &apc_cmdtab[i]; break; } if (!ct) { upslogx(LOG_WARNING, "instcmd: unknown command [%s %s]", cmd, ext ? ext : "\b"); return STAT_INSTCMD_INVALID; } if (!(ct->flags & APC_PRESENT)) { upslogx(LOG_WARNING, "instcmd: command [%s %s] recognized, but" " not supported by your UPS model", cmd, ext ? ext : "\b"); return STAT_INSTCMD_INVALID; } /* first verify if the command is "nasty" */ if ((ct->flags & APC_NASTY) && !instcmd_chktime(ct, ext)) return STAT_INSTCMD_HANDLED; /* future: again */ /* we're good to go, handle special stuff first, then generic cmd */ if (!strcasecmp(cmd, "calibrate.start")) return do_cal(1); if (!strcasecmp(cmd, "calibrate.stop")) return do_cal(0); if (!strcasecmp(cmd, "load.on")) return do_loadon(); if (!strcasecmp(cmd, "load.off")) return sdcmd_Z(0); if (!strcasecmp(cmd, "shutdown.stayoff")) return sdcmd_K(0); if (!strcasecmp(cmd, "shutdown.return")) { if (!ext || !*ext) return sdcmd_S(0); /* ext length is guaranteed by regex match above */ if (!strncasecmp(ext, "at", 2)) return sdcmd_AT(ext + 3); if (!strncasecmp(ext, "cs", 2)) return sdcmd_CS(0); } /* nothing special here */ return do_cmd(ct); } /* install pointers to functions for msg handlers called from msgparse */ static void setuphandlers(void) { upsh.setvar = setvar; upsh.instcmd = instcmd; } /* functions that interface with main.c */ void upsdrv_makevartable(void) { addvar(VAR_VALUE, "cable", "specify alternate cable (940-0095B)"); addvar(VAR_VALUE, "awd", "hard hibernate's additional wakeup delay"); addvar(VAR_VALUE, "sdtype", "specify simple shutdown method (0 - " APC_SDMAX ")"); addvar(VAR_VALUE, "advorder", "enable advanced shutdown control"); } void upsdrv_initups(void) { size_t i, len; char *val; upsfd = extrafd = ser_open(device_path); apc_ser_set(); /* sanitize awd (additional waekup delay of '@' command) */ if ((val = getval("awd")) && rexhlp(APC_AWDFMT, val)) { fatalx(EXIT_FAILURE, "invalid value (%s) for option 'awd'", val); } /* sanitize sdtype */ if ((val = getval("sdtype")) && rexhlp(APC_SDFMT, val)) { fatalx(EXIT_FAILURE, "invalid value (%s) for option 'sdtype'", val); } /* sanitize advorder */ if ((val = getval("advorder")) && strcasecmp(val, "no")) { len = strlen(val); if (!len || len > SDCNT) fatalx(EXIT_FAILURE, "invalid length of 'advorder' option (%s)", val); for (i = 0; i < len; i++) { if (val[i] < '0' || val[i] >= '0' + SDCNT) { fatalx(EXIT_FAILURE, "invalid characters in 'advorder' option (%s)", val); } } } } void upsdrv_cleanup(void) { char temp[APC_LBUF]; apc_flush(0); /* try to bring the UPS out of smart mode */ apc_write(APC_GODUMB); apc_read(temp, sizeof(temp), SER_TO); ser_close(upsfd, device_path); } void upsdrv_help(void) { } void upsdrv_initinfo(void) { const char *pmod, *pser; if (!smartmode(5)) { fatalx(EXIT_FAILURE, "unable to detect an APC Smart protocol UPS on port %s\n" "check the cabling, port name or model name and try again", device_path ); } /* manufacturer ID - hardcoded in this particular module */ dstate_setinfo("ups.mfr", "APC"); getbaseinfo(); if (!(pmod = dstate_getinfo("ups.model"))) pmod = "\"unknown model\""; if (!(pser = dstate_getinfo("ups.serial"))) pser = "unknown serial"; upsdebugx(1, "detected %s [%s] on %s", pmod, pser, device_path); setuphandlers(); } void upsdrv_updateinfo(void) { static int last_worked = 0; static time_t last_full = 0; time_t now; /* try to wake up a dead ups once in awhile */ if (dstate_is_stale()) { if (!last_worked) upsdebugx(LOG_DEBUG, "upsdrv_updateinfo: comm lost"); /* reset this so a full update runs when the UPS returns */ last_full = 0; if (++last_worked < 10) return; /* become aggressive after a few tries */ upsdebugx(LOG_DEBUG, "upsdrv_updateinfo: nudging ups with 'Y', iteration #%d ...", last_worked); if (!smartmode(1)) return; last_worked = 0; } if (!update_status()) return; time(&now); /* refresh all variables hourly */ /* does not catch measure-ups II insertion/removal */ if (difftime(now, last_full) > 3600) { last_full = now; update_info_all(); return; } update_info_normal(); }