/*!@file tripplite_usb.c * @brief Driver for Tripp Lite non-PDC/HID USB models. */ /* tripplite_usb.c was derived from tripplite.c by Charles Lepple tripplite.c was derived from Russell Kroll's bestups.c by Rik Faith. Copyright (C) 1999 Russell Kroll Copyright (C) 2001 Rickard E. (Rik) Faith Copyright (C) 2004 Nicholas J. Kain Copyright (C) 2005-2008, 2014 Charles Lepple Copyright (C) 2016 Eaton 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 */ /* % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % * * Protocol 1001 * * OMNIVS Commands: (capital letters are literals, lower-case are variables) * :B -> Bxxxxyy (xxxx/55.0: Hz in, yy/16: battery voltage) * :F -> F1143_A (where _ = \0) Firmware version? * :L -> LvvvvXX (vvvv/2.0: VAC out) * :P -> P01000X (1000VA unit) * :S -> Sbb_XXX (bb = 10: on-line, 11: on battery) * :V -> V102XXX (firmware/protocol version?) * :Wt -> Wt (watchdog; t = time in seconds (binary, not hex), * 0 = disable; if UPS is not pinged in this interval, it * will power off the load, and then power it back on after * a delay.) * * % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % * * The outgoing commands are sent with HID Set_Report commands over EP0 * (control message), and incoming commands are received on EP1IN (interrupt * endpoint). The UPS completely ignores the conventions of Set_Idle (where * you NAK the interrupt read if you have no new data), so you constantly have * to poll EP1IN. * * The descriptors say that bInterval is 10 ms. You generally need to wait at * least 80-90 ms to get some characters back from the device. If it takes * more than 250 ms, you probably need to resend the command. * * All outgoing commands are followed by a checksum, which is 255 - (sum of * characters after ':'), and then by '\r'. All responses should start with * the command letter that was sent (no colon), and should be followed by * '\r'. If the command is not supported (or apparently if there is a serial * timeout internally), the previous response will be echoed back. * * % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % * * SMARTPRO commands (3003): * * :A -> ? (start self-test) * :D -> D7187 (? - doesn't match tripplite.c) * :F -> F1019 A firmware rev * :H__ -> H (delay before action?) * :I_ -> I (set flags for conditions that cause a reset?) * :J__ -> J (set 16-bit unit ID) * :K#0 -> (turn outlet off: # in 0..2; 0 is main relay) * :K#1 -> (turn outlet on: # in 0..2) * :L -> L290D_X * :M -> M007F (min/max voltage seen) * :N__ -> N * :P -> P01500X (max power) * :Q -> (while online: reboot) * :R -> R<01> (query flags for conditions that cause a reset?) * :S -> S100_Z0 (status?) * :T -> T7D2581 (temperature, frequency) * :U -> U (unit ID, 1-65535) * :V -> V1062XX (outlets in groups of 2-2-4, with the groups of 2 * individually switchable.) * :W_ -> W_ (watchdog) * :Z -> Z (reset for max/min; takes a moment to complete) * * % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % * * The SMARTPRO unit seems to be slightly saner with regard to message * polling. It specifies an interrupt in interval of 100 ms, but I just * started at a 2 second timeout to obtain the above table. * * % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % * * Commands from serial tripplite.c: * * :N%02X -- delay the UPS for provided time (hex seconds) * :H%06X -- reboot the UPS. UPS will restart after provided time (hex s) * :A -- begins a self-test * :C -- fetches result of a self-test * :K1 -- turns on power receptacles * :K0 -- turns off power receptacles * :G -- unconfirmed: shuts down UPS until power returns * :Q1 -- enable "Remote Reboot" * :Q0 -- disable "Remote Reboot" * :W -- returns 'W' data * :L -- returns 'L' data * :V -- returns 'V' data (firmware revision) * :X -- returns 'X' data (firmware revision) * :D -- returns general status data * :B -- returns battery voltage (hexadecimal decivolts) * :I -- returns minimum input voltage (hexadecimal hertz) [sic] * :M -- returns maximum input voltage (hexadecimal hertz) [sic] * :P -- returns power rating * :Z -- unknown * :U -- unknown * :O -- unknown * :E -- unknown * :Y -- returns mains frequency (':D' is preferred) * :T -- returns ups temperature (':D' is preferred) * :R -- returns input voltage (':D' is preferred) * :F -- returns load percentage (':D' is preferred) * :S -- enables remote reboot/remote power on */ /* Watchdog for 3005 is 15 - 255 seconds. */ #include "main.h" #include "nut_libusb.h" #include #include #include "usb-common.h" #define DRIVER_NAME "Tripp Lite OMNIVS / SMARTPRO driver" #define DRIVER_VERSION "0.33" /* driver description structure */ upsdrv_info_t upsdrv_info = { DRIVER_NAME, DRIVER_VERSION, "Charles Lepple \n" \ "Russell Kroll \n" \ "Rickard E. (Rik) Faith \n" \ "Nicholas J. Kain ", DRV_EXPERIMENTAL, { NULL } }; /* TrippLite */ #define TRIPPLITE_VENDORID 0x09ae /* USB IDs device table */ static usb_device_id_t tripplite_usb_device_table[] = { /* e.g. OMNIVS1000, SMART550USB, ... */ { USB_DEVICE(TRIPPLITE_VENDORID, 0x0001), NULL }, /* Terminating entry */ { 0, 0, NULL } }; static int subdriver_match_func(USBDevice_t *arghd, void *privdata) { NUT_UNUSED_VARIABLE(privdata); /* FIXME? Should we save "arghd" into global "hd" variable? * This was previously shadowed by function argument named "hd"... */ /* hd = arghd; */ switch (is_usb_device_supported(tripplite_usb_device_table, arghd)) { case SUPPORTED: return 1; case POSSIBLY_SUPPORTED: /* by default, reject, unless the productid option is given */ if (getval("productid")) { return 1; } return 0; case NOT_SUPPORTED: default: return 0; } } static USBDeviceMatcher_t subdriver_matcher = { &subdriver_match_func, NULL, NULL }; static enum tl_model_t { TRIPP_LITE_UNKNOWN = 0, TRIPP_LITE_OMNIVS, TRIPP_LITE_OMNIVS_2001, TRIPP_LITE_SMARTPRO, TRIPP_LITE_SMART_0004, TRIPP_LITE_SMART_3005 } tl_model = TRIPP_LITE_UNKNOWN; /*! Are the values encoded in ASCII or binary? * TODO: Add 3004? */ static int is_binary_protocol() { switch(tl_model) { case TRIPP_LITE_SMART_3005: return 1; case TRIPP_LITE_SMARTPRO: case TRIPP_LITE_SMART_0004: case TRIPP_LITE_OMNIVS: case TRIPP_LITE_OMNIVS_2001: case TRIPP_LITE_UNKNOWN: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic push # pragma GCC diagnostic ignored "-Wcovered-switch-default" #endif /* All enum cases defined as of the time of coding * have been covered above. Handle later definitions, * memory corruptions and buggy inputs below... */ default: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic pop #endif return 0; } } /*! Is this the "SMART" family of protocols? * TODO: Add 3004? */ static int is_smart_protocol() { switch(tl_model) { case TRIPP_LITE_SMARTPRO: case TRIPP_LITE_SMART_0004: case TRIPP_LITE_SMART_3005: return 1; case TRIPP_LITE_OMNIVS: case TRIPP_LITE_OMNIVS_2001: case TRIPP_LITE_UNKNOWN: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic push # pragma GCC diagnostic ignored "-Wcovered-switch-default" #endif /* All enum cases defined as of the time of coding * have been covered above. Handle later definitions, * memory corruptions and buggy inputs below... */ default: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic pop #endif return 0; } } /*!@brief If a character is not printable, return a dot. */ #define toprint(x) (isalnum((int)x) ? (char)(x) : (char)'.') #define ENDCHAR 13 #define MAX_SEND_TRIES 10 #define SEND_WAIT_SEC 0 #define SEND_WAIT_NSEC (1000*1000*100) #define MAX_RECV_TRIES 10 #define RECV_WAIT_MSEC 1000 /*!< was 100 for OMNIVS; SMARTPRO units need longer */ #define MAX_RECONNECT_TRIES 10 #define DEFAULT_OFFDELAY 64 /*!< seconds (max 0xFF) */ #define DEFAULT_STARTDELAY 60 /*!< seconds (max 0xFFFFFF) */ #define DEFAULT_BOOTDELAY 64 /*!< seconds (max 0xFF) */ #define MAX_VOLT 13.4 /*!< Max battery voltage (100%) */ #define MIN_VOLT 11.0 /*!< Min battery voltage (10%) */ static USBDevice_t *hd = NULL; static USBDevice_t curDevice; static USBDeviceMatcher_t *reopen_matcher = NULL; static USBDeviceMatcher_t *regex_matcher = NULL; static usb_dev_handle *udev; static usb_communication_subdriver_t *comm_driver = &usb_subdriver; /* We calculate battery charge (q) as a function of voltage (V). * It seems that this function probably varies by firmware revision or * UPS model - the Windows monitoring software gives different q for a * given V than the old open source Tripp Lite monitoring software. * * The discharge curve should be the same for any given battery chemistry, * so it should only be necessary to specify the minimum and maximum * voltages likely to be seen in operation. */ /* Interval notation for Q% = 10% <= [minV, maxV] <= 100% */ static double V_interval[2] = {MIN_VOLT, MAX_VOLT}; static long battery_voltage_nominal = 12, input_voltage_nominal = 120, input_voltage_scaled = 120, /* input_voltage_maximum = -1, input_voltage_minimum = -1, */ switchable_load_banks = 0, unit_id = -1; /*!< range: 1-65535, most likely */ /*! Time in seconds to delay before shutting down. */ static unsigned int offdelay = DEFAULT_OFFDELAY; /* static unsigned int bootdelay = DEFAULT_BOOTDELAY; */ /*!@brief Try to reconnect once. * @return 1 if reconnection was successful. */ static int reconnect_ups(void) { int ret; if (hd != NULL) { return 1; } upsdebugx(2, "=================================================="); upsdebugx(2, "= device has been disconnected, try to reconnect ="); upsdebugx(2, "=================================================="); ret = comm_driver->open(&udev, &curDevice, reopen_matcher, NULL); if (ret < 1) { upslogx(LOG_INFO, "Reconnecting to UPS failed; will retry later..."); dstate_datastale(); return 0; } hd = &curDevice; return ret; } /*!@brief Convert a string to printable characters (in-place) * * @param[in,out] str String to convert * @param[in] len Maximum number of characters to convert, or == 0 to * convert all. * * Uses toprint() macro defined above. */ static void toprint_str(char *str, size_t len) { size_t i; if (len == 0) len = strlen(str); /* FIXME? Should we check for '\0' along the way? */ for (i = 0; i < len; i++) str[i] = toprint(str[i]); } /*!@brief Convert N characters from hex to decimal * * @param start Beginning of string to convert * @param len Maximum number of characters to consider (max 32) * * @a len characters of @a start are copied to a temporary buffer, then passed * to strtol() to be converted to decimal. * * @return See strtol(3) */ static long hex2d(const unsigned char *start, unsigned int len) { unsigned char buf[32]; buf[31] = '\0'; strncpy((char *)buf, (const char *)start, (len < (sizeof buf) ? len : (sizeof buf - 1))); if(len < sizeof(buf)) buf[len] = '\0'; return strtol((char *)buf, NULL, 16); } /*!@brief Convert N characters from big-endian binary to decimal * * @param start Beginning of string to convert * @param len Maximum number of characters to consider (max 32) * * @a len characters of @a start are shifted into an accumulator. * * We assume len < sizeof(int), and that value > 0. * * @return the value */ static unsigned int bin2d(const unsigned char *start, unsigned int len) { unsigned int value = 0, index = 0; for(index = 0; index < len; index++) { value <<= 8; value |= start[index]; } return value; } static long hex_or_bin2d(const unsigned char *start, unsigned int len) { if(is_binary_protocol()) { return bin2d(start, len); } return hex2d(start, len); } /*!@brief Dump message in both hex and ASCII * * @param[in] msg Buffer to dump * @param[in] len Number of bytes to dump * * @return Pointer to static buffer with decoded message */ static const char *hexascdump(unsigned char *msg, size_t len) { size_t i; static unsigned char buf[256]; unsigned char *bufp, *end; bufp = buf; end = bufp + sizeof(buf); buf[0] = 0; /* Dump each byte in hex: */ for(i=0; i=3; i++) { bufp += sprintf((char *)bufp, "%02x ", msg[i]); } /* Dump single-quoted string with printable version of each byte: */ if (end-bufp > 0) *bufp++ = '\''; for(i=0; i0; i++) { *bufp++ = (unsigned char)toprint(msg[i]); } if (end-bufp > 0) *bufp++ = '\''; if (end-bufp > 0) *bufp = '\0'; else *--end='\0'; return (char *)buf; } static enum tl_model_t decode_protocol(unsigned int proto) { switch(proto) { case 0x0004: upslogx(3, "Using older SMART protocol (%04x)", proto); return TRIPP_LITE_SMART_0004; case 0x1001: upslogx(3, "Using OMNIVS protocol (%x)", proto); return TRIPP_LITE_OMNIVS; case 0x2001: upslogx(3, "Using OMNIVS 2001 protocol (%x)", proto); return TRIPP_LITE_OMNIVS_2001; case 0x3003: upslogx(3, "Using SMARTPRO protocol (%x)", proto); return TRIPP_LITE_SMARTPRO; case 0x3005: upslogx(3, "Using binary SMART protocol (%x)", proto); return TRIPP_LITE_SMART_3005; default: printf("Unknown protocol (%04x)", proto); break; } return TRIPP_LITE_UNKNOWN; } static void decode_v(const unsigned char *value) { unsigned char ivn, lb; long bv; if(is_binary_protocol()) { /* 0x00 0x0c -> 12V ? */ battery_voltage_nominal = (value[2] << 8) | value[3]; } else { bv = hex2d(value+2, 2); battery_voltage_nominal = bv * 6; } ivn = value[1]; lb = value[4]; switch(ivn) { case '0': input_voltage_nominal = input_voltage_scaled = 100; break; case 2: /* protocol 3005 */ case '1': input_voltage_nominal = input_voltage_scaled = 120; break; case '2': input_voltage_nominal = input_voltage_scaled = 230; break; case '3': input_voltage_nominal = 208; input_voltage_scaled = 230; break; case 6: input_voltage_nominal = input_voltage_scaled = 230; break; default: upslogx(2, "Unknown input voltage range: 0x%02x", (unsigned int)ivn); break; } if( (lb >= '0') && (lb <= '9') ) { switchable_load_banks = lb - '0'; } else { if(is_binary_protocol()) { switchable_load_banks = lb; } else { if( lb != 'X' ) { upslogx(2, "Unknown number of switchable load banks: 0x%02x", (unsigned int)lb); } } } upsdebugx(2, "Switchable load banks: %ld", switchable_load_banks); } void upsdrv_initinfo(void); /*!@brief Report a USB comm failure, and reconnect if necessary * * @param[in] res Result code from libusb/libhid call * @param[in] msg Error message to display */ static void usb_comm_fail(int res, const char *msg) { static int try = 0; switch(res) { case ERROR_BUSY: upslogx(LOG_WARNING, "%s: Device claimed by another process", msg); fatalx(EXIT_FAILURE, "Terminating: EBUSY"); #ifndef HAVE___ATTRIBUTE__NORETURN break; #endif default: upslogx(LOG_WARNING, "%s: Device detached? (error %d: %s)", msg, res, nut_usb_strerror(res)); upslogx(LOG_NOTICE, "Reconnect attempt #%d", ++try); hd = NULL; reconnect_ups(); if(hd) { upslogx(LOG_NOTICE, "Successfully reconnected"); try = 0; upsdrv_initinfo(); } else { if(try > MAX_RECONNECT_TRIES) { fatalx(EXIT_FAILURE, "Too many unsuccessful reconnection attempts"); } } break; } } /*!@brief Send a command to the UPS, and wait for a reply. * * All of the UPS commands are challenge-response. If a command does not have * anything to return, it simply returns the command character. * * @param[in] msg Command string, minus the ':' or CR * @param[in] msg_len Be sure to use sizeof(msg) instead of strlen(msg), * since some commands have embedded NUL characters * @param[out] reply Reply (but check return code for validity) * @param[out] reply_len (currently unused) * * @return number of chars in reply, excluding terminating NUL * @return 0 if command was not accepted */ static int send_cmd(const unsigned char *msg, size_t msg_len, unsigned char *reply, size_t reply_len) { NUT_UNUSED_VARIABLE(reply_len); unsigned char buffer_out[8]; unsigned char csum = 0; int ret = 0, send_try, recv_try=0, done = 0; size_t i = 0; upsdebugx(3, "send_cmd(msg_len=%u, type='%c')", (unsigned)msg_len, msg[0]); if(msg_len > 5) { fatalx(EXIT_FAILURE, "send_cmd(): Trying to pass too many characters to UPS (%u)", (unsigned)msg_len); } buffer_out[0] = ':'; for(i=1; i<8; i++) buffer_out[i] = '\0'; for(i=0; iset_report(udev, 0, (usb_ctrl_charbuf)buffer_out, (usb_ctrl_charbufsize)sizeof(buffer_out)); if(ret != sizeof(buffer_out)) { upslogx(1, "libusb_set_report() returned %d instead of %zu", ret, sizeof(buffer_out)); return ret; } #if ! defined(__FreeBSD__) usleep(1000*100); /* TODO: nanosleep */ #endif for(recv_try=0; !done && recv_try < MAX_RECV_TRIES; recv_try++) { upsdebugx(7, "send_cmd recv_try %d", recv_try+1); ret = comm_driver->get_interrupt(udev, (usb_ctrl_charbuf)reply, (usb_ctrl_charbufsize)sizeof(buffer_out), RECV_WAIT_MSEC); if(ret != sizeof(buffer_out)) { upslogx(1, "libusb_get_interrupt() returned %d instead of %u while sending %s", ret, (unsigned)(sizeof(buffer_out)), hexascdump(buffer_out, sizeof(buffer_out))); } done = (ret == sizeof(buffer_out)) && (buffer_out[1] == reply[0]); } } if(ret == sizeof(buffer_out)) { upsdebugx(5, "send_cmd: received %s (%s)", hexascdump(reply, sizeof(buffer_out)), done ? "OK" : "bad"); } upsdebugx(((send_try > 2) || (recv_try > 2)) ? 3 : 6, "send_cmd: send_try = %d, recv_try = %d\n", send_try, recv_try); return done ? sizeof(buffer_out) : 0; } /*!@brief Send an unknown command to the UPS, and store response in a variable * * @param msg Command string (usually a character and a null) * @param len Length of command plus null * * The variables are of the form "ups.debug.X" where "X" is the command * character. */ static void debug_message(const char *msg, size_t len) { int ret; unsigned char tmp_value[9]; char var_name[20], err_msg[80]; snprintf(var_name, sizeof(var_name), "ups.debug.%c", *msg); ret = send_cmd((const unsigned char *)msg, len, tmp_value, sizeof(tmp_value)); if(ret <= 0) { sprintf(err_msg, "Error reading '%c' value", *msg); usb_comm_fail(ret, err_msg); return; } dstate_setinfo(var_name, "%s", hexascdump(tmp_value+1, 7)); } #if 0 /* using the watchdog to reboot won't work while polling */ static void do_reboot_wait(unsigned dly) { int ret; char buf[256], cmd_W[]="Wx"; cmd_W[1] = dly; upsdebugx(3, "do_reboot_wait(wait=%d): N", dly); ret = send_cmd(cmd_W, sizeof(cmd_W), buf, sizeof(buf)); } static int do_reboot_now(void) { do_reboot_wait(1); return 0; } static void do_reboot(void) { do_reboot_wait(bootdelay); } #endif /*! Called by 'tripplite_usb -k' */ static int soft_shutdown(void) { int ret; unsigned char buf[256], cmd_N[]="N\0x", cmd_G[] = "G"; /* Already binary: */ /* FIXME: Assumes memory layout / endianness? */ cmd_N[2] = (unsigned char)(offdelay & 0x00FF); cmd_N[1] = (unsigned char)(offdelay >> 8); upsdebugx(3, "soft_shutdown(offdelay=%d): N", offdelay); ret = send_cmd(cmd_N, sizeof(cmd_N), buf, sizeof(buf)); if(ret != 8) { upslogx(LOG_ERR, "Could not set offdelay to %d", offdelay); return ret; } sleep(2); /*! The unit must be on battery for this to work. * * @todo check for on-battery condition, and print error if not. * @todo Find an equivalent command for non-OMNIVS models. */ ret = send_cmd(cmd_G, sizeof(cmd_G), buf, sizeof(buf)); if(ret != 8) { upslogx(LOG_ERR, "Could not turn off UPS (is it still on battery?)"); return 0; } return 1; } #if 0 static int hard_shutdown(void) { int ret; unsigned char buf[256], cmd_N[]="N\0x", cmd_K[] = "K\0"; /* FIXME: Assumes memory layout / endianness? */ cmd_N[2] = (unsigned char)(offdelay & 0x00FF); cmd_N[1] = (unsigned char)(offdelay >> 8); upsdebugx(3, "hard_shutdown(offdelay=%d): N", offdelay); ret = send_cmd(cmd_N, sizeof(cmd_N), buf, sizeof(buf)); if(ret != 8) return ret; sleep(2); ret = send_cmd(cmd_K, sizeof(cmd_K), buf, sizeof(buf)); return (ret == 8); } #endif /*!@brief Turn an outlet on or off. * * @return 1 if the command worked, 0 if not. */ static int control_outlet(int outlet_id, int state) { char k_cmd[10], buf[10]; int ret; switch(tl_model) { case TRIPP_LITE_SMARTPRO: /* tested */ case TRIPP_LITE_SMART_0004: /* untested */ snprintf(k_cmd, sizeof(k_cmd)-1, "N%02X", 5); ret = send_cmd((unsigned char *)k_cmd, strlen(k_cmd) + 1, (unsigned char *)buf, sizeof buf); snprintf(k_cmd, sizeof(k_cmd)-1, "K%d%d", outlet_id, state & 1); ret = send_cmd((unsigned char *)k_cmd, strlen(k_cmd) + 1, (unsigned char *)buf, sizeof buf); if(ret != 8) { upslogx(LOG_ERR, "Could not set outlet %d to state %d, ret = %d", outlet_id, state, ret); return 0; } else { return 1; } #ifdef HAVE_PRAGMAS_FOR_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE #pragma GCC diagnostic push #endif #ifdef HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE_BREAK #pragma GCC diagnostic ignored "-Wunreachable-code-break" #endif #ifdef HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE #pragma GCC diagnostic ignored "-Wunreachable-code" #endif break; #ifdef HAVE_PRAGMAS_FOR_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE #pragma GCC diagnostic pop #endif case TRIPP_LITE_SMART_3005: snprintf(k_cmd, sizeof(k_cmd)-1, "N%c", 5); ret = send_cmd((unsigned char *)k_cmd, strlen(k_cmd) + 1, (unsigned char *)buf, sizeof buf); snprintf(k_cmd, sizeof(k_cmd)-1, "K%c%c", outlet_id, state & 1); ret = send_cmd((unsigned char *)k_cmd, strlen(k_cmd) + 1, (unsigned char *)buf, sizeof buf); if(ret != 8) { upslogx(LOG_ERR, "Could not set outlet %d to state %d, ret = %d", outlet_id, state, ret); return 0; } else { return 1; } #ifdef HAVE_PRAGMAS_FOR_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE #pragma GCC diagnostic push #endif #ifdef HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE_BREAK #pragma GCC diagnostic ignored "-Wunreachable-code-break" #endif #ifdef HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE #pragma GCC diagnostic ignored "-Wunreachable-code" #endif break; #ifdef HAVE_PRAGMAS_FOR_GCC_DIAGNOSTIC_IGNORED_UNREACHABLE_CODE #pragma GCC diagnostic pop #endif case TRIPP_LITE_OMNIVS: case TRIPP_LITE_OMNIVS_2001: case TRIPP_LITE_UNKNOWN: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic push # pragma GCC diagnostic ignored "-Wcovered-switch-default" #endif /* All enum cases defined as of the time of coding * have been covered above. Handle later definitions, * memory corruptions and buggy inputs below... */ default: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic pop #endif upslogx(LOG_ERR, "control_outlet unimplemented for protocol %04x", tl_model); } return 0; } /*!@brief Handler for "instant commands" */ static int instcmd(const char *cmdname, const char *extra) { unsigned char buf[10]; if(is_smart_protocol()) { if (!strcasecmp(cmdname, "test.battery.start")) { send_cmd((const unsigned char *)"A", 2, buf, sizeof buf); return STAT_INSTCMD_HANDLED; } if(!strcasecmp(cmdname, "reset.input.minmax")) { return (send_cmd((const unsigned char *)"Z", 2, buf, sizeof buf) == 2) ? STAT_INSTCMD_HANDLED : STAT_INSTCMD_UNKNOWN; } } if (!strcasecmp(cmdname, "load.off")) { return control_outlet(0, 0) ? STAT_INSTCMD_HANDLED : STAT_INSTCMD_UNKNOWN; } if (!strcasecmp(cmdname, "load.on")) { return control_outlet(0, 1) ? STAT_INSTCMD_HANDLED : STAT_INSTCMD_UNKNOWN; } /* code for individual outlets is in setvar() */ #if 0 if (!strcasecmp(cmdname, "shutdown.reboot")) { do_reboot_now(); return STAT_INSTCMD_HANDLED; } if (!strcasecmp(cmdname, "shutdown.reboot.graceful")) { do_reboot(); return STAT_INSTCMD_HANDLED; } if (!strcasecmp(cmdname, "shutdown.stayoff")) { hard_shutdown(); return STAT_INSTCMD_HANDLED; } #endif if (!strcasecmp(cmdname, "shutdown.return")) { soft_shutdown(); return STAT_INSTCMD_HANDLED; } upslogx(LOG_NOTICE, "instcmd: unknown command [%s] [%s]", cmdname, extra); return STAT_INSTCMD_UNKNOWN; } static int setvar(const char *varname, const char *val) { if (!strcasecmp(varname, "ups.delay.shutdown")) { int ival = atoi(val); if (ival >= 0) { offdelay = (unsigned int)ival; dstate_setinfo("ups.delay.shutdown", "%d", offdelay); return STAT_SET_HANDLED; } else { upslogx(LOG_NOTICE, "FAILED to set '%s' to %d", varname, ival); return STAT_SET_UNKNOWN; } } if (unit_id >= 0 && !strcasecmp(varname, "ups.id")) { int new_unit_id, ret; unsigned char J_msg[] = "J__", buf[9]; new_unit_id = atoi(val); /* FIXME: Assumes memory layout / endianness? */ J_msg[1] = (unsigned char)(new_unit_id >> 8); J_msg[2] = (unsigned char)(new_unit_id & 0xff); ret = send_cmd(J_msg, sizeof(J_msg), buf, sizeof(buf)); if(ret <= 0) { upslogx(LOG_NOTICE, "Could not set Unit ID (return code: %d).", ret); return STAT_SET_UNKNOWN; } dstate_setinfo("ups.id", "%s", val); return STAT_SET_HANDLED; } if(!strncmp(varname, "outlet.", strlen("outlet."))) { char outlet_name[80]; char index_str[10], *first_dot, *next_dot; long index_chars; int index, state, ret; first_dot = strstr(varname, "."); next_dot = strstr(first_dot + 1, "."); if (!next_dot) { upslogx(LOG_NOTICE, "FAILED to get outlet index from '%s' (no second dot)", varname); return STAT_SET_UNKNOWN; } index_chars = next_dot - (first_dot + 1); if(index_chars > 9 || index_chars < 0) return STAT_SET_UNKNOWN; if(strcmp(next_dot, ".switch")) return STAT_SET_UNKNOWN; strncpy(index_str, first_dot + 1, (size_t)index_chars); index_str[index_chars] = 0; index = atoi(index_str); upslogx(LOG_DEBUG, "outlet.%d.switch = %s", index, val); if(!strcasecmp(val, "on") || !strcmp(val, "1")) { state = 1; } else { state = 0; } upslogx(LOG_DEBUG, "outlet.%d.switch = %s -> %d", index, val, state); snprintf(outlet_name, sizeof(outlet_name)-1, "outlet.%d.switch", index); ret = control_outlet(index, state); if(ret) { dstate_setinfo(outlet_name, "%d", state); return STAT_SET_HANDLED; } else { return STAT_SET_UNKNOWN; } } #if 0 if (!strcasecmp(varname, "ups.delay.start")) { startdelay = atoi(val); dstate_setinfo("ups.delay.start", val); return STAT_SET_HANDLED; } if (!strcasecmp(varname, "ups.delay.reboot")) { bootdelay = atoi(val); dstate_setinfo("ups.delay.reboot", val); return STAT_SET_HANDLED; } #endif return STAT_SET_UNKNOWN; } void upsdrv_initinfo(void) { const unsigned char proto_msg[] = "\0", f_msg[] = "F", p_msg[] = "P", s_msg[] = "S", u_msg[] = "U", v_msg[] = "V", w_msg[] = "W\0"; char *model, *model_end; unsigned char proto_value[9], f_value[9], p_value[9], s_value[9], u_value[9], v_value[9], w_value[9]; long va; ssize_t ret; unsigned int proto_number = 0; /* Read protocol: */ ret = send_cmd(proto_msg, sizeof(proto_msg), proto_value, sizeof(proto_value)-1); if(ret <= 0) { fatalx(EXIT_FAILURE, "Error reading protocol"); } proto_number = ((unsigned)(proto_value[1]) << 8) | (unsigned)(proto_value[2]); tl_model = decode_protocol(proto_number); if(tl_model == TRIPP_LITE_UNKNOWN) dstate_setinfo("ups.debug.0", "%s", hexascdump(proto_value+1, 7)); dstate_setinfo("ups.firmware.aux", "protocol %04x", proto_number); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ /* Reset watchdog: */ /* Watchdog not supported on TRIPP_LITE_SMARTPRO models */ if(tl_model != TRIPP_LITE_SMARTPRO ) { ret = send_cmd(w_msg, sizeof(w_msg), w_value, sizeof(w_value)-1); if(ret <= 0) { if(ret == ERROR_PIPE) { fatalx(EXIT_FAILURE, "Could not reset watchdog. Please check and" "see if usbhid-ups(8) works with this UPS."); } else { upslogx(3, "Could not reset watchdog. Please send model " "information to nut-upsdev mailing list"); } } } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ ret = send_cmd(s_msg, sizeof(s_msg), s_value, sizeof(s_value)-1); if(ret <= 0) { fatalx(EXIT_FAILURE, "Could not retrieve status ... is this an OMNIVS model?"); } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ dstate_setinfo("ups.mfr", "%s", "Tripp Lite"); /* Get nominal power: */ ret = send_cmd(p_msg, sizeof(p_msg), p_value, sizeof(p_value)-1); va = strtol((char *)(p_value+1), NULL, 10); if(tl_model == TRIPP_LITE_SMART_0004) { dstate_setinfo("ups.debug.P","%s", hexascdump(p_value+1, 7)); va *= 10; /* TODO: confirm? */ } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ /* trim "TRIPP LITE" from beginning of model */ model = strdup(hd->Product); if(strstr(model, hd->Vendor) == model) { model += strlen(hd->Vendor); } /* trim leading spaces: */ for(; *model == ' '; model++); /* Trim trailing spaces */ for(model_end = model + strlen(model) - 1; model_end > model && *model_end == ' '; model_end--) { *model_end = '\0'; } dstate_setinfo("ups.model", "%s", model); dstate_setinfo("ups.power.nominal", "%ld", va); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ /* Fetch firmware version: */ ret = send_cmd(f_msg, sizeof(f_msg), f_value, sizeof(f_value)-1); toprint_str((char *)(f_value+1), 6); f_value[7] = 0; dstate_setinfo("ups.firmware", "F%s", f_value+1); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ /* Get configuration: */ ret = send_cmd(v_msg, sizeof(v_msg), v_value, sizeof(v_value)-1); decode_v(v_value); /* FIXME: redundant, but since it's static, we don't need to poll * every time. */ debug_message("V", 2); if(switchable_load_banks > 0) { int i; char outlet_name[80]; for(i = 1; i <= switchable_load_banks + 1; i++) { snprintf(outlet_name, sizeof(outlet_name), "outlet.%d.id", i); dstate_setinfo(outlet_name, "%d", i); snprintf(outlet_name, sizeof(outlet_name), "outlet.%d.desc", i); dstate_setinfo(outlet_name, "Load %d", i); snprintf(outlet_name, sizeof(outlet_name), "outlet.%d.switchable", i); if( i <= switchable_load_banks ) { dstate_setinfo(outlet_name, "1"); snprintf(outlet_name, sizeof(outlet_name)-1, "outlet.%d.switch", i); dstate_setinfo(outlet_name, "1"); dstate_setflags(outlet_name, ST_FLAG_RW | ST_FLAG_STRING); dstate_setaux(outlet_name, 3); } else { /* Last bank is not switchable: */ dstate_setinfo(outlet_name, "0"); } } /* For the main relay: */ dstate_addcmd("load.on"); dstate_addcmd("load.off"); } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if(tl_model != TRIPP_LITE_OMNIVS && tl_model != TRIPP_LITE_SMART_0004) { /* Unit ID might not be supported by all models: */ ret = send_cmd(u_msg, sizeof(u_msg), u_value, sizeof(u_value)-1); if(ret <= 0) { upslogx(LOG_INFO, "Unit ID not retrieved (not available on all models)"); } else { unit_id = (long)((unsigned)(u_value[1]) << 8) | (unsigned)(u_value[2]); } if(tl_model == TRIPP_LITE_SMART_0004) { debug_message("U", 2); } } if(unit_id >= 0) { dstate_setinfo("ups.id", "%ld", unit_id); dstate_setflags("ups.id", ST_FLAG_RW | ST_FLAG_STRING); dstate_setaux("ups.id", 5); upslogx(LOG_DEBUG,"Unit ID: %ld", unit_id); } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ dstate_setinfo("input.voltage.nominal", "%ld", input_voltage_nominal); dstate_setinfo("battery.voltage.nominal", "%ld", battery_voltage_nominal); dstate_setinfo("ups.debug.load_banks", "%ld", switchable_load_banks); dstate_setinfo("ups.delay.shutdown", "%u", offdelay); dstate_setflags("ups.delay.shutdown", ST_FLAG_RW | ST_FLAG_STRING); dstate_setaux("ups.delay.shutdown", 3); #if 0 dstate_setinfo("ups.delay.start", "%u", startdelay); dstate_setflags("ups.delay.start", ST_FLAG_RW | ST_FLAG_STRING); dstate_setaux("ups.delay.start", 8); dstate_setinfo("ups.delay.reboot", "%u", bootdelay); dstate_setflags("ups.delay.reboot", ST_FLAG_RW | ST_FLAG_STRING); dstate_setaux("ups.delay.reboot", 3); #endif if(is_smart_protocol()) { dstate_addcmd("test.battery.start"); dstate_addcmd("reset.input.minmax"); } dstate_addcmd("shutdown.return"); #if 0 dstate_addcmd("shutdown.stayoff"); dstate_addcmd("test.battery.start"); /* Turns off automatically */ dstate_addcmd("load.off"); dstate_addcmd("load.on"); dstate_addcmd("shutdown.reboot"); dstate_addcmd("shutdown.reboot.graceful"); #endif upsh.instcmd = instcmd; upsh.setvar = setvar; printf("Attached to %s %s\n", dstate_getinfo("ups.mfr"), dstate_getinfo("ups.model")); } void upsdrv_shutdown(void) { soft_shutdown(); } void upsdrv_updateinfo(void) { unsigned char b_msg[] = "B", d_msg[] = "D", l_msg[] = "L", s_msg[] = "S", m_msg[] = "M", t_msg[] = "T"; unsigned char b_value[9], d_value[9], l_value[9], s_value[9], m_value[9], t_value[9]; int bp; long freq; double bv_12V = 0.0; /*!< battery voltage, relative to a 12V battery */ double battery_voltage; /*!< the total battery voltage */ unsigned int s_value_1; int ret; status_init(); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ /* General status (e.g. "S10") */ ret = send_cmd(s_msg, sizeof(s_msg), s_value, sizeof(s_value)); if(ret <= 0) { dstate_datastale(); usb_comm_fail(ret, "Error reading S value"); return; } if(tl_model != TRIPP_LITE_OMNIVS && tl_model != TRIPP_LITE_OMNIVS_2001) { dstate_setinfo("ups.debug.S","%s", hexascdump(s_value+1, 7)); } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if(tl_model == TRIPP_LITE_OMNIVS) { switch(s_value[2]) { case '0': status_set("OL"); break; case '1': status_set("OB"); break; case '2': /* "charge-only" mode, no AC in or out... the PC * shouldn't see this, because there is no power in * that case (OMNIVS), but it's here for testing. * * Entered by holding down the power button. */ status_set("BYPASS"); break; case '3': /* I have seen this once when switching from off+LB to charging */ upslogx(LOG_WARNING, "Unknown value for s[2]: 0x%02x", s_value[2]); break; default: upslogx(LOG_ERR, "Unknown value for s[2]: 0x%02x", s_value[2]); dstate_datastale(); break; } } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if(is_smart_protocol() || tl_model == TRIPP_LITE_OMNIVS_2001) { unsigned int s_value_2 = s_value[2]; if(is_binary_protocol()) { s_value_2 += '0'; } switch(s_value_2) { case '0': dstate_setinfo("battery.test.status", "Battery OK"); break; case '1': dstate_setinfo("battery.test.status", "Battery bad - replace"); break; case '2': status_set("CAL"); break; case '3': status_set("OVER"); dstate_setinfo("battery.test.status", "Overcurrent?"); break; case '4': /* The following message is confusing, and may not be accurate: */ /* dstate_setinfo("battery.test.status", "Battery state unknown"); */ break; case '5': status_set("OVER"); dstate_setinfo("battery.test.status", "Battery fail - overcurrent?"); break; default: upslogx(LOG_ERR, "Unknown value for s[2]: 0x%02x", s_value[2]); dstate_datastale(); break; } if(s_value[4] & 4) { status_set("OFF"); } else { /* Online/on battery: */ if(s_value[4] & 1) { status_set("OB"); } else { status_set("OL"); } } #if 0 /* Apparently, this value changes more frequently when the * battery is discharged, but it does not track the actual * state-of-charge. See battery.charge calculation below. */ if(tl_model == TRIPP_LITE_SMARTPRO) { unsigned battery_charge; battery_charge = (unsigned)(s_value[5]); dstate_setinfo("battery.charge", "%u", battery_charge); } #endif } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ s_value_1 = s_value[1]; if(is_binary_protocol()) { s_value_1 += '0'; } switch(s_value_1) { case '0': status_set("LB"); break; case '1': /* Depends on s_value[2] */ break; case '2': if( tl_model == TRIPP_LITE_SMARTPRO ) { status_set("RB"); break; } /* else fall through: */ goto fallthrough_case_default; default: fallthrough_case_default: upslogx(LOG_ERR, "Unknown value for s[1]: 0x%02x", s_value[1]); dstate_datastale(); break; } status_commit(); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if( tl_model == TRIPP_LITE_OMNIVS || tl_model == TRIPP_LITE_OMNIVS_2001 ) { ret = send_cmd(b_msg, sizeof(b_msg), b_value, sizeof(b_value)); if(ret <= 0) { dstate_datastale(); usb_comm_fail(ret, "Error reading B value"); return; } dstate_setinfo("input.voltage", "%.2f", hex2d(b_value+1, 4)/3600.0*input_voltage_scaled); bv_12V = hex2d(b_value+5, 2)/16.0; /* TODO: use battery_voltage_nominal, even though it is most likely 12V */ dstate_setinfo("battery.voltage", "%.2f", bv_12V); } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if( is_smart_protocol() ) { ret = send_cmd(d_msg, sizeof(d_msg), d_value, sizeof(d_value)); if(ret <= 0) { dstate_datastale(); usb_comm_fail(ret, "Error reading D value"); return; } dstate_setinfo("input.voltage", "%ld", hex_or_bin2d(d_value+1, 2) * input_voltage_scaled / 120); /* TODO: factor out the two constants */ bv_12V = hex_or_bin2d(d_value+3, 2) / 10.0 ; battery_voltage = bv_12V * battery_voltage_nominal / 12.0; dstate_setinfo("battery.voltage", "%.2f", battery_voltage); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ ret = send_cmd(m_msg, sizeof(m_msg), m_value, sizeof(m_value)); if(m_value[5] != 0x0d) { /* we only expect 4 hex/binary digits */ dstate_setinfo("ups.debug.M", "%s", hexascdump(m_value+1, 7)); } if(ret <= 0) { dstate_datastale(); usb_comm_fail(ret, "Error reading M (min/max input voltage)"); return; } dstate_setinfo("input.voltage.minimum", "%3ld", hex_or_bin2d(m_value+1, 2) * input_voltage_scaled / 120); dstate_setinfo("input.voltage.maximum", "%3ld", hex_or_bin2d(m_value+3, 2) * input_voltage_scaled / 120); /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ ret = send_cmd(t_msg, sizeof(t_msg), t_value, sizeof(t_value)); dstate_setinfo("ups.debug.T", "%s", hexascdump(t_value+1, 7)); if(ret <= 0) { dstate_datastale(); usb_comm_fail(ret, "Error reading T value"); return; } if( tl_model == TRIPP_LITE_SMARTPRO ) { freq = hex2d(t_value + 3, 3); dstate_setinfo("input.frequency", "%.1f", freq / 10.0); switch(t_value[6]) { case '1': dstate_setinfo("input.frequency.nominal", "%d", 60); break; case '0': dstate_setinfo("input.frequency.nominal", "%d", 50); break; } } if( tl_model == TRIPP_LITE_SMART_0004 ) { freq = hex2d(t_value + 3, 4); dstate_setinfo("input.frequency", "%.1f", freq / 10.0); } if( tl_model == TRIPP_LITE_SMART_3005 ) { dstate_setinfo("ups.temperature", "%d", (unsigned)(hex2d(t_value+1, 1))); } else { /* I'm guessing this is a calibration constant of some sort. */ dstate_setinfo("ups.temperature", "%.1f", (unsigned)(hex2d(t_value+1, 2)) * 0.3636 - 21); } } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if( tl_model == TRIPP_LITE_OMNIVS || tl_model == TRIPP_LITE_OMNIVS_2001 || tl_model == TRIPP_LITE_SMARTPRO || tl_model == TRIPP_LITE_SMART_0004 || tl_model == TRIPP_LITE_SMART_3005) { /* dq ~= sqrt(dV) is a reasonable approximation * Results fit well against the discrete function used in the Tripp Lite * source, but give a continuous result. */ if (bv_12V >= V_interval[1]) bp = 100; else if (bv_12V <= V_interval[0]) bp = 10; else bp = (int)(100*sqrt((bv_12V - V_interval[0]) / (V_interval[1] - V_interval[0]))); dstate_setinfo("battery.charge", "%3d", bp); } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ ret = send_cmd(l_msg, sizeof(l_msg), l_value, sizeof(l_value)); if(ret <= 0) { dstate_datastale(); usb_comm_fail(ret, "Error reading L value"); return; } switch(tl_model) { case TRIPP_LITE_OMNIVS: case TRIPP_LITE_OMNIVS_2001: dstate_setinfo("output.voltage", "%.1f", hex2d(l_value+1, 4)/240.0*input_voltage_scaled); break; case TRIPP_LITE_SMARTPRO: dstate_setinfo("ups.load", "%ld", hex2d(l_value+1, 2)); break; case TRIPP_LITE_SMART_3005: dstate_setinfo("ups.load", "%ld", hex_or_bin2d(l_value+1, 1)); break; case TRIPP_LITE_SMART_0004: dstate_setinfo("ups.load", "%ld", hex2d(l_value+1, 2)); dstate_setinfo("ups.debug.L","%s", hexascdump(l_value+1, 7)); break; case TRIPP_LITE_UNKNOWN: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic push # pragma GCC diagnostic ignored "-Wcovered-switch-default" #endif /* All enum cases defined as of the time of coding * have been covered above. Handle later definitions, * memory corruptions and buggy inputs below... */ default: #if (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_PUSH_POP) && (defined HAVE_PRAGMA_GCC_DIAGNOSTIC_IGNORED_COVERED_SWITCH_DEFAULT) # pragma GCC diagnostic pop #endif dstate_setinfo("ups.debug.L","%s", hexascdump(l_value+1, 7)); break; } /* - * - * - * - * - * - * - * - * - * - * - * - * - * - * - */ if(tl_model != TRIPP_LITE_OMNIVS && tl_model != TRIPP_LITE_OMNIVS_2001) { debug_message("D", 2); /* We already grabbed these above: */ if(tl_model != TRIPP_LITE_SMARTPRO) { debug_message("V", 2); /* Probably not necessary - seems to be static */ debug_message("M", 2); debug_message("T", 2); debug_message("P", 2); } /* debug_message("U", 2); */ } dstate_dataok(); } void upsdrv_help(void) { } void upsdrv_makevartable(void) { char msg[256]; snprintf(msg, sizeof msg, "Set shutdown delay, in seconds (default=%d)", DEFAULT_OFFDELAY); addvar(VAR_VALUE, "offdelay", msg); /* allow -x vendor=X, vendorid=X, product=X, productid=X, serial=X */ nut_usb_addvars(); snprintf(msg, sizeof msg, "Minimum battery voltage, corresponding to 10%% charge (default=%.1f)", MIN_VOLT); addvar(VAR_VALUE, "battery_min", msg); snprintf(msg, sizeof msg, "Maximum battery voltage, corresponding to 100%% charge (default=%.1f)", MAX_VOLT); addvar(VAR_VALUE, "battery_max", msg); #if 0 snprintf(msg, sizeof msg, "Set start delay, in seconds (default=%d).", DEFAULT_STARTDELAY); addvar(VAR_VALUE, "startdelay", msg); snprintf(msg, sizeof msg, "Set reboot delay, in seconds (default=%d).", DEFAULT_BOOTDELAY); addvar(VAR_VALUE, "rebootdelay", msg); #endif } /*!@brief Initialize UPS and variables from ups.conf * * @todo Allow binding based on firmware version (which seems to vary wildly * from unit to unit) */ void upsdrv_initups(void) { char *regex_array[7]; char *value; int r; warn_if_bad_usb_port_filename(device_path); /* process the UPS selection options */ regex_array[0] = NULL; /* handled by USB IDs device table */ regex_array[1] = getval("productid"); regex_array[2] = getval("vendor"); /* vendor string */ regex_array[3] = getval("product"); /* product string */ regex_array[4] = getval("serial"); /* probably won't see this */ regex_array[5] = getval("bus"); regex_array[6] = getval("device"); r = USBNewRegexMatcher(®ex_matcher, regex_array, REG_ICASE | REG_EXTENDED); if (r==-1) { fatal_with_errno(EXIT_FAILURE, "USBNewRegexMatcher"); } else if (r) { fatalx(EXIT_FAILURE, "invalid regular expression: %s", regex_array[r]); } /* link the matchers */ regex_matcher->next = &subdriver_matcher; /* Search for the first supported UPS matching the regular * expression */ r = comm_driver->open(&udev, &curDevice, regex_matcher, NULL); if (r < 1) { fatalx(EXIT_FAILURE, "No matching USB/HID UPS found"); } hd = &curDevice; upslogx(1, "Detected a UPS: %s/%s", hd->Vendor ? hd->Vendor : "unknown", hd->Product ? hd->Product : "unknown"); dstate_setinfo("ups.vendorid", "%04x", hd->VendorID); dstate_setinfo("ups.productid", "%04x", hd->ProductID); /* create a new matcher for later reopening */ r = USBNewExactMatcher(&reopen_matcher, hd); if (r) { fatal_with_errno(EXIT_FAILURE, "USBNewExactMatcher"); } /* link the two matchers */ reopen_matcher->next = regex_matcher; value = getval("offdelay"); if (value) { int ival = atoi(value); if (ival >= 0) { offdelay = (unsigned int)ival; upsdebugx(2, "Setting 'offdelay' to %u", offdelay); } else { upsdebugx(2, "FAILED to set 'offdelay' to %d", ival); } } value = getval("battery_min"); if (value) { V_interval[0] = atof(value); upsdebugx(2, "Setting 'battery_min' to %.g", V_interval[0]); } value = getval("battery_max"); if (value) { V_interval[1] = atof(value); upsdebugx(2, "Setting 'battery_max' to %.g", V_interval[1]); } #if 0 if (getval("startdelay")) startdelay = atoi(getval("startdelay")); if (getval("rebootdelay")) bootdelay = atoi(getval("rebootdelay")); #endif } void upsdrv_cleanup(void) { comm_driver->close(udev); USBFreeExactMatcher(reopen_matcher); USBFreeRegexMatcher(regex_matcher); free(curDevice.Vendor); free(curDevice.Product); free(curDevice.Serial); free(curDevice.Bus); free(curDevice.Device); }