/* * Copyright 2013-2014 Con Kolivas * Copyright 2014 Lketc Integrated Systems Limited * Copyright 2014 Dominik Lehner * * 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 3 of the License, or (at your option) * any later version. See COPYING for more details. */ #include "config.h" #include #include #include #include #include #include #ifndef WIN32 #include #include #include #include #ifndef O_CLOEXEC #define O_CLOEXEC 0 #endif #else #include "compat.h" #include #include #endif #include "miner.h" #include "usbutils.h" #include "fpgautils.h" #include "elist.h" #include "util.h" #include "driver-lketc.h" #define using_libusb(info) ((info)->using_libusb > 0) #define using_serial(info) ((info)->using_libusb == 0) // Configuration options extern bool opt_lketc_debug; extern int opt_lketc_chips_count; // number of Lketc chips chained together extern int opt_lketc_chip_clk; // frequency to run chips with extern bool opt_lketc_nocheck_golden; // bypass hashrate check //static int opt_lketc_chips_count_max = 1; // smallest power of 2 >= opt_lketc_chips_count // is currently auto-calculated // Index for device-specific options //static int option_offset = -1; // Unset upon first hotplug check static bool initial_startup_phase = true; static struct name_chip_map { char *model_name; int chips_count; } lketc_models[] = { { "Stick", 1 }, { "Dragon", 2 }, { NULL, 0 } }; /************************************************************ * Utility Functions ************************************************************/ static void flush_uart(int fd) { #ifdef WIN32 const HANDLE fh = (HANDLE)_get_osfhandle(fd); PurgeComm(fh, PURGE_RXCLEAR); #else tcflush(fd, TCIFLUSH); #endif } static int __maybe_unused flush_fd(int fd) { static char discard[10]; return read(fd, discard, sizeof(discard)); } static void rev(unsigned char *s, size_t l) { size_t i, j; unsigned char t; for (i = 0, j = l - 1; i < j; i++, j--) { t = s[i]; s[i] = s[j]; s[j] = t; } } static int log_2(int value) { int x = 0; while (value > 1) { value >>= 1; x++; } return x; } static uint32_t __maybe_unused chip_index(uint32_t value, int bit_num) { uint32_t newvalue = 0; int i; // isolate bits 19-28, then shift right to get the // highest bits that distinguish multiple chips value = (value & 0x1ff80000) >> (29 - bit_num); for (i = 0; i < bit_num; i++) { newvalue = newvalue << 1; newvalue += value & 0x01; value = value >> 1; } return newvalue; } static int lowest_pow2(int min) { int i; for (i = 1; i < 1024; i = i * 2) { if (min <= i){ return i; } } return 1024; } static void notify_send_work_thread(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; cgsem_post(&info->wusem); } /************************************************************ * I/O helper functions ************************************************************/ #define lketc_serial_open_detect(devpath, baud, purge) serial_open_ex(devpath, baud, LKETC_READ_FAULT_DECISECONDS, 0, purge, true) #define lketc_serial_open(devpath, baud, purge) serial_open_ex(devpath, baud, LKETC_READ_FAULT_DECISECONDS, 0, purge, true) #define lketc_serial_close(fd) close(fd) static bool lketc_reopen(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; int try, fd = -1; if (!using_serial(info)) // sanity check return false; if (info->device_fd != -1) { applog(LOG_DEBUG, "Closing %s%d on %s (fd=%d)", lketc->drv->name, lketc->device_id, lketc->device_path, info->device_fd); lketc_serial_close(info->device_fd); info->device_fd = -1; cgsleep_ms(2000); } applog(LOG_DEBUG, "Attempting to open %s%d on %s", lketc->drv->name, lketc->device_id, lketc->device_path); for (try = 0; try < 3; ++try) { fd = lketc_serial_open(lketc->device_path, info->baud, true); if (likely(fd > -1)) break; cgsleep_ms(3000); } if (unlikely(fd < 0)) { applog(LOG_ERR, "Failed to open %s%d on %s (%d attempts)", lketc->drv->name, lketc->device_id, lketc->device_path, try); return false; } info->device_fd = fd; applog(LOG_DEBUG, "Successfully opened %s%d on %s (%d attempts, fd=%d)", lketc->drv->name, lketc->device_id, lketc->device_path, try, info->device_fd); return true; } static int lketc_serial_write(int fd, const void *buf, size_t len) { ssize_t ret; size_t total = 0; #if LKETC_PROTOCOL_DEBUG if (opt_lketc_debug) { char *hexstr; hexstr = bin2hex(buf, len); applog(LOG_DEBUG, "> %s", hexstr); free(hexstr); } #endif while (total < len) { #ifndef WIN32 ret = write(fd, buf, len); #else ret = win32write(fd, buf, len); #endif if (ret < 0) { applog(LOG_ERR, "lketc_serial_write (%d): error on write: %s", fd, strerror(errno)); return -1; } total += (size_t)ret; } return total; } static int lketc_serial_read(int fd, void *buf, size_t len, int read_count, struct timeval *tv_firstbyte) { ssize_t ret; size_t total = 0; int rc = 0; while (total < len) { #ifndef WIN32 ret = read(fd, buf + total, len - total); #else ret = win32read(fd, buf + total, len - total); #endif if (ret < 0) { applog(LOG_ERR, "lketc_serial_read (%d): error on read: %s", fd, strerror(errno)); return -1; } if (tv_firstbyte != NULL && total == 0) cgtime(tv_firstbyte); applog(LOG_DEBUG, "lketc_serial_read: read returned %d", (int)ret); if (ret == 0 && ++rc >= read_count) break; total += (size_t)ret; } #if LKETC_PROTOCOL_DEBUG if (opt_lketc_debug) { char *hexstr; if (total > 0) { hexstr = bin2hex(buf, total); applog(LOG_DEBUG, "< %s", hexstr); free(hexstr); } else { applog(LOG_DEBUG, "< (no data)"); } } #endif return total; } /************************************************************ * Detection and setup ************************************************************/ static unsigned char lketc_clk_to_freqcode(int clkfreq) { if (clkfreq > LKETC_CLK_MAX) { applog(LOG_WARNING, "Clock frequency %d too high, resetting to %d", clkfreq, LKETC_CLK_MAX); clkfreq = LKETC_CLK_MAX; } if (clkfreq < LKETC_CLK_MIN) { applog(LOG_WARNING, "Clock frequency %d too low, resetting to %d", clkfreq, LKETC_CLK_MIN); clkfreq = LKETC_CLK_MIN; } return (unsigned char)((double)clkfreq * 2. / 3.); } static void lketc_get_device_options(const char *devid, int *chips_count, int *chip_clk, const char *options) { char *p, *all, *found = NULL; long lval; int index = 0; char *lastslsh = MAX(strrchr(devid, '/'), strrchr(devid, '\\')); if (lastslsh != NULL) ++lastslsh; // set global default options *chips_count = (opt_lketc_chips_count) ? opt_lketc_chips_count : LKETC_MIN_CHIPS; *chip_clk = (opt_lketc_chip_clk) ? opt_lketc_chip_clk : LKETC_CLK_MIN; if (options == NULL) return; all = strdup(options); for (p = strtok(all, ";"); p != NULL; p = strtok(NULL, ";")) { if (strncmp(p, devid, strlen(devid)) == 0) { found = p; break; } if (lastslsh != NULL && strncmp(p, lastslsh, strlen(lastslsh)) == 0) { found = p; break; } } if (found == NULL) { free(all); return; } for (p = strtok(found, ","); p != NULL; p = strtok(NULL, ",")) { lval = strtol(p, NULL, 10); switch (index++) { case 1: // chip count if (lval < LKETC_MIN_CHIPS || lval > LKETC_MAX_CHIPS) { applog(LOG_ERR, "Invalid chip count %ld for Lketc device %s", lval, devid); break; } *chips_count = (int)lval; break; case 2: // clock if (lval < LKETC_CLK_MIN || lval > LKETC_CLK_MAX) { applog(LOG_ERR, "Invalid clock speed %ld for Lketc device %s", lval, devid); break; } *chip_clk = (int)lval; break; default: break; } } free(all); return; } static char *lketc_device_name(int chips_count) { struct name_chip_map *p; for (p = lketc_models; p->model_name != NULL; ++p) { if (p->chips_count == chips_count) return p->model_name; } return NULL; } static int lketc_usb_control_transfer_data(struct cgpu_info *lketc, uint8_t request_type, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, uint32_t *data, int siz, enum usb_cmds cmd) { int err = usb_transfer_data(lketc, request_type, bRequest, wValue, wIndex, data, siz, cmd); if (err) applog(LOG_DEBUG, "%s%d: error %d on USB control transfer %s", lketc->drv->name, lketc->cgminer_id, err, usb_cmdname(cmd)); return err; } static inline int lketc_usb_control_transfer(struct cgpu_info *lketc, uint8_t request_type, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, enum usb_cmds cmd) { return lketc_usb_control_transfer_data(lketc, request_type, bRequest, wValue, wIndex, NULL, 0, cmd); } static bool lketc_initialize_cp2102(struct cgpu_info *lketc) { int interface = usb_interface(lketc); //uint32_t baudrate = CP210X_DATA_BAUD; // Enable the UART if (lketc_usb_control_transfer(lketc, CP210X_TYPE_OUT, CP210X_REQUEST_IFC_ENABLE, CP210X_VALUE_UART_ENABLE, interface, C_ENABLE_UART)) return false; // Set data control if (lketc_usb_control_transfer(lketc, CP210X_TYPE_OUT, CP210X_REQUEST_DATA, CP210X_VALUE_DATA, interface, C_SETDATA)) return false; // Lketcminers have baud hardcoded to 115200, and reject baud commands, even to same value // Set the baud //if (lketc_usb_control_transfer_data(lketc, CP210X_TYPE_OUT, CP210X_REQUEST_BAUD, // 0, interface, &baudrate, sizeof(baudrate), C_SETBAUD)) // return false; return true; } static bool lketc_initialize_usb(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; enum sub_ident ident; if (lketc->usbinfo.nodev) return false; ident = usb_ident(lketc); switch (ident) { case IDENT_LKE: info->read_data_offset = 0; return lketc_initialize_cp2102(lketc); default: applog(LOG_ERR, "lketc_initialize_usb called on wrong device, ident=%d", ident); return false; } } static struct cgpu_info *lketc_detect_one_usb(struct libusb_device *dev, struct usb_find_devices *found) { struct cgpu_info *lketc; struct LKETC_INFO *info; lketc = usb_alloc_cgpu(&lketc_drv, 1); if (!usb_init(lketc, dev, found)) goto usbdealloc; info = calloc(1, sizeof(struct LKETC_INFO)); if (unlikely(!info)) goto usbdealloc; lketc->device_data = info; lketc->deven = DEV_ENABLED; lketc->threads = 1; info->device_fd = -1; info->using_libusb = 1; if (lketc->usbdev->serial_string && strlen(lketc->usbdev->serial_string) > 4) lketc->unique_id = lketc->usbdev->serial_string; else lketc->unique_id = lketc->device_path; strncpy(info->device_name, lketc->unique_id, sizeof(info->device_name) - 1); info->device_name[sizeof(info->device_name) - 1] = '\0'; lketc_get_device_options(lketc->unique_id, &info->chips_count, &info->chip_clk, opt_lketc_options); lketc->name = lketc_device_name(info->chips_count); info->freqcode = lketc_clk_to_freqcode(info->chip_clk); info->baud = LKETC_IO_SPEED; info->cores_per_chip = LKETC_CHIP_CORES; info->chips_count_max = lowest_pow2(info->chips_count); info->chips_bit_num = log_2(info->chips_count_max); info->next_chip_clk = -1; libusb_reset_device(lketc->usbdev->handle); update_usb_stats(lketc); lketc->usbdev->usb_type = USB_TYPE_STD; if (!lketc_initialize_usb(lketc)) { applog(LOG_ERR, "Failed to initialize Lketc USB-UART interface"); goto alldealloc; } info->golden_speed_per_core = (((info->chip_clk * 2.) / 3.) * 1024.) / 8.; info->work_timeout.tv_sec = 4294967296LL / (info->golden_speed_per_core * info->cores_per_chip * info->chips_count_max) * 0.9; info->work_timeout.tv_usec = 0; info->read_count = (uint32_t)((4294967296LL*10)/(info->cores_per_chip*info->chips_count_max*info->golden_speed_per_core*2)); info->read_count = info->read_count*3/4; if (!add_cgpu(lketc)) goto alldealloc; return lketc; alldealloc: usb_uninit(lketc); free(lketc->device_data); lketc->device_data = NULL; usbdealloc: lketc = usb_free_cgpu(lketc); return NULL; } static bool lketc_detect_one_serial(const char *devpath) { struct timeval tv_start, tv_finish; int i, fd, baud, cores_per_chip, chips_count_max, chips_count, chip_clk; //int this_option_offset = ++option_offset; unsigned char freqcode_init, freqcode; uint32_t nonce; uint64_t golden_speed_per_core; /* this check here is needed as a failsafe because the serial_detect * functions do not keep track of devices already opened */ for (i = 0; i < total_devices; ++i) { if (devices[i]->device_path && !strcasecmp(devices[i]->device_path, devpath)) return false; } uint32_t golden_nonce_val = be32toh(0x268d0300); // 0xd26 = 3366 unsigned char ob_bin[LKETC_COMMAND_PKT_LEN], nonce_bin[LKETC_EVENT_PKT_LEN]; static const char golden_ob[] = "55aa0001" "00038000063b0b1b028f32535e900609c15dc49a42b1d8492a6dd4f8f15295c989a1decf584a6aa93be26066d3185f55ef635b5865a7a79b7fa74121a6bb819da416328a9bd2f8cef72794bf02000000"; static const char golden_ob2[] = "55aa00ff" "c00278894532091be6f16a5381ad33619dacb9e6a4a6e79956aac97b51112bfb93dc450b8fc765181a344b6244d42d78625f5c39463bbfdc10405ff711dc1222dd065b015ac9c2c66e28da7202000000"; lketc_get_device_options(devpath, &chips_count, &chip_clk, opt_lketc_options); baud = LKETC_IO_SPEED; // baud rate is fixed cores_per_chip = LKETC_CHIP_CORES; // cores/chip also fixed chips_count_max = lowest_pow2(chips_count); //if (chips_count > opt_lketc_chips_count_max) // opt_lketc_chips_count_max = lowest_pow2(chips_count); //chips_count_max = opt_lketc_chips_count_max; if (initial_startup_phase) applog(LOG_INFO, "Lketc Detect: Attempting to open %s", devpath); fd = lketc_serial_open_detect(devpath, baud, true); if (unlikely(fd == -1)) { if (initial_startup_phase) applog(LOG_ERR, "Lketc Detect: Failed to open %s", devpath); return false; } freqcode = lketc_clk_to_freqcode(chip_clk); // from 150M step to the high or low speed. we need to add delay and resend to init chip if (chip_clk > 150) freqcode_init = lketc_clk_to_freqcode(170); else freqcode_init = lketc_clk_to_freqcode(139); flush_uart(fd); hex2bin(ob_bin, golden_ob2, sizeof(ob_bin)); ob_bin[0] = freqcode_init; ob_bin[1] = ~freqcode_init; ob_bin[2] = 0x00; ob_bin[3] = 0x01; for (i = 0; i < 2; ++i) { lketc_serial_write(fd, ob_bin, sizeof(ob_bin)); cgsleep_ms(500); // what is the minimum the miners need/will accept? flush_uart(fd); } hex2bin(ob_bin, golden_ob2, sizeof(ob_bin)); ob_bin[0] = freqcode; ob_bin[1] = ~freqcode; ob_bin[2] = 0x00; ob_bin[3] = 0x01; for (i = 0; i < 2; ++i) { lketc_serial_write(fd, ob_bin, sizeof(ob_bin)); cgsleep_ms(500); flush_uart(fd); } if (!opt_lketc_nocheck_golden) { memset(nonce_bin, 0, sizeof(nonce_bin)); hex2bin(ob_bin, golden_ob, sizeof(ob_bin)); ob_bin[0] = freqcode; ob_bin[1] = ~freqcode; ob_bin[2] = 0x00; ob_bin[3] = 0x01; for (i = 0; i < 2; ++i) { lketc_serial_write(fd, ob_bin, sizeof(ob_bin)); cgtime(&tv_start); if (lketc_serial_read(fd, nonce_bin, sizeof(nonce_bin), 25, &tv_finish) == sizeof(nonce_bin)) break; } lketc_serial_close(fd); memcpy(&nonce, nonce_bin, sizeof(nonce_bin)); nonce = be32toh(nonce); if (nonce != golden_nonce_val) { applog(LOG_ERR, "Lketc Detect: " "Test failed at %s: got %08x, should be: %08x", devpath, nonce, golden_nonce_val); return false; } golden_speed_per_core = (uint64_t)((double)0xd26 / tdiff(&tv_finish, &tv_start)); if (opt_lketc_debug) applog(LOG_INFO, "Test succeeded at %s: got %08x", devpath, nonce); } else { lketc_serial_close(fd); golden_speed_per_core = (((chip_clk * 2.) / 3.) * 1024.) / 8.; } /* We have a real Lketc miner! */ struct cgpu_info *lketc; struct LKETC_INFO *info; lketc = calloc(1, sizeof(struct cgpu_info)); if (unlikely(!lketc)) quit(1, "Failed to malloc struct cgpu_info"); info = calloc(1, sizeof(struct LKETC_INFO)); if (unlikely(!info)) quit(1, "Failed to malloc struct LKETC_INFO"); lketc->drv = &lketc_drv; lketc->name = lketc_device_name(chips_count); lketc->device_path = strdup(devpath); lketc->device_data = info; lketc->deven = DEV_ENABLED; lketc->threads = 1; applog(LOG_NOTICE, "Found Lketc at %s, mark as %d", devpath, lketc->device_id); applog(LOG_INFO, "Lketc: Init: %d baud=%d cores_per_chip=%d chips_count=%d", lketc->device_id, baud, cores_per_chip, chips_count); info->device_fd = -1; info->using_libusb = 0; lketc->unique_id = MAX( strrchr(lketc->device_path, '/'), strrchr(lketc->device_path, '\\')); if (lketc->unique_id == NULL) lketc->unique_id = lketc->device_path; else ++lketc->unique_id; strncpy(info->device_name, lketc->unique_id, sizeof(info->device_name) - 1); info->device_name[sizeof(info->device_name) - 1] = '\0'; info->work_timeout.tv_sec = 4294967296LL / (golden_speed_per_core * cores_per_chip * chips_count_max) * 0.9; info->work_timeout.tv_usec = 0; info->golden_speed_per_core = golden_speed_per_core; info->read_count = (uint32_t)((4294967296LL*10)/(cores_per_chip*chips_count_max*golden_speed_per_core*2)); info->read_count = info->read_count*3/4; info->next_chip_clk = -1; info->freqcode = freqcode; info->baud = baud; info->cores_per_chip = cores_per_chip; info->chips_count = chips_count; info->chips_count_max = chips_count_max; if ((chips_count_max & (chips_count_max - 1)) != 0) quit(1, "chips_count_max must be a power of 2"); info->chip_clk = chip_clk; info->chips_bit_num = log_2(chips_count_max); info->read_data_offset = 0; if (!add_cgpu(lketc)) quit(1, "Failed to add_cgpu"); return true; } /************************************************************ * Host <-> ASIC protocol implementation ************************************************************/ static void lketc_purge_work(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; mutex_lock(&info->lock); if (info->current_work != NULL) { free_work(info->current_work); info->current_work = NULL; } notify_send_work_thread(lketc); mutex_unlock(&info->lock); } #define nonce_range_start(cperc, cmax, core, chip) \ (((0xffffffff / cperc + 1) * core) + ((0x1fffffff / cmax + 1) * chip)) static bool lketc_read_response(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; unsigned char evtpkt[LKETC_READ_BUFFER]; uint32_t nonce, chip, core; int ret, err; double duration_s; bool valid; if (using_libusb(info)) { //err = usb_read_timeout(lketc, (char *)evtpkt, sizeof(evtpkt), &ret, 250, C_GETRESULTS); err = usb_read_once(lketc, (char *)evtpkt, sizeof(evtpkt), &ret, C_GETRESULTS); #if LKETC_PROTOCOL_DEBUG if (opt_lketc_debug) { char *hexstr; hexstr = bin2hex(evtpkt, ret); applog(LOG_DEBUG, "< %s err=%d ret=%d", hexstr, err, ret); free(hexstr); } #endif if (err != LIBUSB_SUCCESS && err != LIBUSB_ERROR_TIMEOUT) { applog(LOG_ERR, "%s%d: USB read error: %s", lketc->drv->name, lketc->device_id, libusb_error_name(err)); return false; } if (ret < LKETC_EVENT_PKT_LEN + info->read_data_offset) return true; } else { ret = lketc_serial_read(info->device_fd, evtpkt, LKETC_EVENT_PKT_LEN, 1, NULL); if (ret < 0) { // error info->serial_reopen = true; notify_send_work_thread(lketc); return false; } else if (ret == 0) { // timeout return true; } flush_uart(info->device_fd); } cgtime(&info->workend); memcpy(&nonce, evtpkt + info->read_data_offset, LKETC_EVENT_PKT_LEN); nonce = be32toh(nonce); mutex_lock(&info->lock); if (info->current_work == NULL) { // work was flushed before we read response applog(LOG_DEBUG, "%s%d: Received nonce for flushed work", lketc->drv->name, lketc->device_id); mutex_unlock(&info->lock); return true; } valid = submit_nonce(info->thr, info->current_work, nonce); ++info->workdone; core = (nonce & 0xe0000000) >> 29; // core indicated by 3 highest bits chip = (nonce & 0x1ff80000) >> (29 - info->chips_bit_num); duration_s = tdiff(&info->workend, &info->workstart); if (chip < LKETC_MAX_CHIPS && core < LKETC_CHIP_CORES) { ++info->nonce_count[chip][core]; if (!valid) ++info->error_count[chip][core]; if (valid && duration_s > 0) { info->hashes_per_s = (nonce - nonce_range_start(info->cores_per_chip, info->chips_count_max, core, chip)) / duration_s * info->cores_per_chip * info->chips_count; info->last_nonce = nonce; } } else { applog(LOG_INFO, "%s%d: Corrupt nonce message received, cannot determine chip and core", lketc->drv->name, lketc->device_id); } mutex_unlock(&info->lock); return true; } static bool lketc_check_need_work(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; struct thr_info *thr = info->thr; struct work *work; bool need_work; need_work = (info->current_work == NULL); if (need_work) { work = get_work(thr, thr->id); // get_work can block, so done outside mutex_lock mutex_lock(&info->lock); if (info->current_work == NULL) { // verify still NULL work->devflag = false; info->current_work = work; } else { need_work = false; } mutex_unlock(&info->lock); if (!need_work) discard_work(work); } return need_work; } static bool lketc_send_work(struct cgpu_info *lketc, struct work *work) { struct LKETC_INFO *info = lketc->device_data; unsigned char cmdpkt[LKETC_COMMAND_PKT_LEN]; uint32_t diff_code, diff; int ret; diff = work->work_difficulty; if (diff < 1) diff = 1; diff_code = 0xffff / diff; applog(LOG_DEBUG, "lketc_send_work: diff=%d diff_code=%04x", diff, diff_code); cmdpkt[0] = info->freqcode; cmdpkt[1] = ~(info->freqcode); cmdpkt[2] = (diff_code & 0xff00) >> 8; cmdpkt[3] = (diff_code & 0x00ff); memcpy(cmdpkt + 4, work->data, 80); rev(cmdpkt + 4, 80); if (using_libusb(info)) { // in libusb mode we send via usb ;) #if LKETC_PROTOCOL_DEBUG if (opt_lketc_debug) { char *hexstr; hexstr = bin2hex(cmdpkt, sizeof(cmdpkt)); applog(LOG_DEBUG, "> %s", hexstr); free(hexstr); } #endif if (usb_write(lketc, (char *)cmdpkt, sizeof(cmdpkt), &ret, C_SENDWORK) != LIBUSB_SUCCESS || ret != sizeof(cmdpkt)) return false; } else { // otherwise direct via serial port ret = lketc_serial_write(info->device_fd, cmdpkt, sizeof(cmdpkt)); if (ret < 0) { info->serial_reopen = true; notify_send_work_thread(lketc); return false; } } return true; } static void *lketc_send_work_thread(void *data) { struct cgpu_info *lketc = (struct cgpu_info *)data; struct LKETC_INFO *info = lketc->device_data; char threadname[24]; struct timeval tv_now, tv_spent, tv_rem; int retval; snprintf(threadname, sizeof(threadname), "Lketc/%d", lketc->device_id); RenameThread(threadname); applog(LOG_INFO, "%s%d: serial I/O thread running, %s", lketc->drv->name, lketc->device_id, threadname); while (likely(!lketc->shutdown)) { if (unlikely(info->thr->pause || lketc->deven != DEV_ENABLED)) { cgsem_wait(&info->wusem); lketc_purge_work(lketc); continue; } if (unlikely(using_libusb(info) && lketc->usbinfo.nodev)) break; if (unlikely(info->serial_reopen)) { if (using_serial(info) && !lketc_reopen(lketc)) { applog(LOG_ERR, "Failed to reopen %s%d on %s, shutting down", lketc->drv->name, lketc->device_id, lketc->device_path); break; } info->serial_reopen = false; lketc_purge_work(lketc); } lketc_check_need_work(lketc); mutex_lock(&info->lock); if (info->current_work && !info->current_work->devflag) { /* send task to device */ if (opt_lketc_debug) applog(LOG_INFO, "Sending work"); if (lketc_send_work(lketc, info->current_work)) { info->current_work->devflag = true; cgtime(&info->workstart); if (info->next_chip_clk != -1) { info->chip_clk = info->next_chip_clk; info->next_chip_clk = -1; } } else { applog(LOG_NOTICE, "%s%d: I/O error while sending work, will retry", lketc->drv->name, lketc->device_id); mutex_unlock(&info->lock); continue; } } mutex_unlock(&info->lock); cgtime(&tv_now); timersub(&tv_now, &info->workstart, &tv_spent); timersub(&info->work_timeout, &tv_spent, &tv_rem); if (opt_lketc_debug) { applog(LOG_DEBUG, "Workstart: %d.%06d", (int)info->workstart.tv_sec, (int)info->workstart.tv_usec); applog(LOG_DEBUG, "Spent: %d.%06d", (int)tv_spent.tv_sec, (int)tv_spent.tv_usec); applog(LOG_DEBUG, "Remaining: %d.%06d", (int)tv_rem.tv_sec, (int)tv_rem.tv_usec); } retval = cgsem_mswait(&info->wusem, (tv_rem.tv_sec < 1) ? 5000 : tv_rem.tv_sec * 1000); if (retval == ETIMEDOUT) lketc_purge_work(lketc); // abandon current work } lketc->shutdown = true; return NULL; } /************************************************************ * CGMiner Interface functions ************************************************************/ static int lketc_autoscan() { int found = 0; applog(LOG_DEBUG, "lketc_autoscan() called"); found += serial_autodetect_udev(lketc_detect_one_serial, LKETC_USB_ID_MODEL_STR1); return found; } static void lketc_detect(bool __maybe_unused hotplug) { static int serial_usb = 0; if (initial_startup_phase && hotplug) initial_startup_phase = false; if (serial_usb == 0) serial_usb = (list_empty(&scan_devices)) ? -1 : 1; if (serial_usb < 0) usb_detect(&lketc_drv, lketc_detect_one_usb); else serial_detect_iauto(&lketc_drv, lketc_detect_one_serial, lketc_autoscan); } static bool lketc_prepare(struct thr_info *thr) { struct cgpu_info *lketc = thr->cgpu; struct LKETC_INFO *info = lketc->device_data; applog(LOG_NOTICE, "%s%d opened on %s", lketc->drv->name, lketc->device_id, lketc->device_path); info->serial_reopen = (using_serial(info)) ? true : false; info->thr = thr; mutex_init(&info->lock); cgsem_init(&info->wusem); // Use qualitative value until first result is returned info->hashes_per_s = info->golden_speed_per_core * info->cores_per_chip * info->chips_count; return true; } static bool lketc_thread_init(struct thr_info *thr) { struct cgpu_info *lketc = thr->cgpu; struct LKETC_INFO *info = lketc->device_data; if (pthread_create(&info->sworkpth, NULL, lketc_send_work_thread, lketc)) { applog(LOG_ERR, "%s%d: Failed to create I/O thread", lketc->drv->name, lketc->device_id); return false; } return true; } static int64_t lketc_scanwork(struct thr_info *thr) { struct cgpu_info *lketc = thr->cgpu; struct LKETC_INFO *info = lketc->device_data; struct timeval old_scanwork_time; double elapsed_s; int64_t estimate_hashes; if (unlikely(using_libusb(info) && lketc->usbinfo.nodev)) return -1; if (unlikely(using_serial(info) && info->serial_reopen)) { cgsleep_ms(500); return 0; } if (unlikely(!lketc_read_response(lketc))) // reads either from serial or libusb or times out return 0; if (thr->work_restart || thr->work_update) { lketc_purge_work(lketc); thr->work_restart = false; thr->work_update = false; } mutex_lock(&info->lock); old_scanwork_time = info->scanwork_time; cgtime(&info->scanwork_time); elapsed_s = tdiff(&info->scanwork_time, &old_scanwork_time); estimate_hashes = elapsed_s * info->hashes_per_s; mutex_unlock(&info->lock); if (unlikely(estimate_hashes > 0xffffffff)) estimate_hashes = 0xffffffff; return estimate_hashes; } #define lketc_update_work lketc_flush_work static void lketc_flush_work(struct cgpu_info *lketc) { lketc_purge_work(lketc); if (opt_lketc_debug) applog(LOG_INFO, "lketc_flush_work: Tickling I/O thread"); } static struct api_data *lketc_api_stats(struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; struct api_data *root = NULL; static struct timeval tv_now, tv_diff, tv_diff2; static double khs_core, khs_chip, khs_board; cgtime(&tv_now); timersub(&tv_now, &(info->workstart), &tv_diff); timersub(&(info->workend), &(info->workstart), &tv_diff2); root = api_add_string(root, "Device Name", lketc->unique_id, false); khs_core = (double)info->golden_speed_per_core / 1000.; khs_chip = (double)info->golden_speed_per_core * (double)info->cores_per_chip / 1000.; khs_board = (double)info->golden_speed_per_core * (double)info->cores_per_chip * (double)info->chips_count / 1000.; root = api_add_khs(root, "KHS/Core", &khs_core, false); root = api_add_khs(root, "KHS/Chip", &khs_chip, false); root = api_add_khs(root, "KHS/Board", &khs_board, false); root = api_add_int(root, "Frequency", &(info->chip_clk), false); root = api_add_int(root, "Cores/Chip", &(info->cores_per_chip), false); root = api_add_int(root, "Chips Count", &(info->chips_count), false); root = api_add_timeval(root, "Time Spent Current Work", &tv_diff, false); root = api_add_timeval(root, "Work Timeout", &(info->work_timeout), false); /* It would be nice to report per chip/core nonce and error counts, * but with more powerful miners with > 100 chips each with 8 cores * there is too much information and we'd overflow the api buffer. * Perhaps another api command to query individual chips? */ /* these values are more for diagnostic and debugging */ if (opt_lketc_debug) { root = api_add_int(root, "chips_count_max", &(info->chips_count_max), false); root = api_add_int(root, "chips_bit_num", &(info->chips_bit_num), false); root = api_add_uint32(root, "read_count", &(info->read_count), false); root = api_add_double(root, "hashes_per_s", &(info->hashes_per_s), false); root = api_add_uint32(root, "last_nonce", &(info->last_nonce), false); root = api_add_timeval(root, "last_nonce_time", &tv_diff2, false); } return root; } static void lketc_get_statline_before(char *buf, size_t bufsiz, struct cgpu_info *lketc) { struct LKETC_INFO *info = lketc->device_data; if (lketc->name) tailsprintf(buf, bufsiz, "%-12s %4d MHz ", lketc->name, info->chip_clk); else tailsprintf(buf, bufsiz, "%4d chips %4d MHz ", info->chips_count, info->chip_clk); } static char *lketc_set_device(struct cgpu_info *lketc, char *option, char *setting, char *replybuf) { struct LKETC_INFO *info = lketc->device_data; int val; if (strcasecmp(option, "help") == 0) { sprintf(replybuf, "freq: range %d-%d, abortwork: true/false", LKETC_CLK_MIN, LKETC_CLK_MAX); return replybuf; } if (strcasecmp(option, "freq") == 0) { if (!setting || !*setting) { sprintf(replybuf, "missing freq setting"); return replybuf; } val = atoi(setting); if (val < LKETC_CLK_MIN || val > LKETC_CLK_MAX) { sprintf(replybuf, "invalid freq: '%s' valid range %d-%d", setting, LKETC_CLK_MIN, LKETC_CLK_MAX); return replybuf; } mutex_lock(&info->lock); info->next_chip_clk = val; info->freqcode = lketc_clk_to_freqcode(val); mutex_unlock(&info->lock); return NULL; } if (strcasecmp(option, "abortwork") == 0) { if (!setting || !*setting) { sprintf(replybuf, "missing true/false"); return replybuf; } if (strcasecmp(setting, "true") != 0) { sprintf(replybuf, "not aborting current work"); return replybuf; } lketc_purge_work(lketc); return NULL; } sprintf(replybuf, "Unknown option: %s", option); return replybuf; } static void lketc_thread_enable(struct thr_info *thr) { struct cgpu_info *lketc = thr->cgpu; notify_send_work_thread(lketc); } static void lketc_shutdown(struct thr_info *thr) { struct cgpu_info *lketc = thr->cgpu; struct LKETC_INFO *info = lketc->device_data; applog(LOG_NOTICE, "%s%d: Shutting down", lketc->drv->name, lketc->device_id); pthread_join(info->sworkpth, NULL); mutex_destroy(&info->lock); cgsem_destroy(&info->wusem); if (info->device_fd != -1) { lketc_serial_close(info->device_fd); info->device_fd = -1; } } struct device_drv lketc_drv = { .drv_id = DRIVER_lketc, .dname = "LKETC", .name = "LKE", .max_diff = 32768, .drv_detect = lketc_detect, .thread_prepare = lketc_prepare, .thread_init = lketc_thread_init, .hash_work = hash_driver_work, .scanwork = lketc_scanwork, .flush_work = lketc_flush_work, .update_work = lketc_update_work, .get_api_stats = lketc_api_stats, .get_statline_before = lketc_get_statline_before, .set_device = lketc_set_device, .thread_enable = lketc_thread_enable, .thread_shutdown = lketc_shutdown, };