/* * Copyright 2013-2014 Con Kolivas * * 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 "miner.h" #include "driver-bitfury.h" #include "sha2.h" #include "mcp2210.h" #include "libbitfury.h" int opt_bxf_temp_target = BXF_TEMP_TARGET / 10; int opt_nfu_bits = 50; int opt_bxm_bits = 54; int opt_bxf_bits = 54; int opt_bxf_debug; int opt_osm_led_mode = 4; /* Wait longer 1/3 longer than it would take for a full nonce range */ #define BF1WAIT 1600 #define BF1MSGSIZE 7 #define BF1INFOSIZE 14 #define TWELVE_MHZ 12000000 //Low port pins #define SK 1 #define DO 2 #define DI 4 #define CS 8 #define GPIO0 16 #define GPIO1 32 #define GPIO2 64 #define GPIO3 128 //GPIO pins #define GPIOL0 0 #define GPIOL1 1 #define GPIOL2 2 #define GPIOL3 3 #define GPIOH 4 #define GPIOH1 5 #define GPIOH2 6 #define GPIOH3 7 #define GPIOH4 8 #define GPIOH5 9 #define GPIOH6 10 #define GPIOH7 11 #define DEFAULT_DIR (SK | DO | CS | GPIO0 | GPIO1 | GPIO2 | GPIO3) /* Setup default input or output state per FTDI for SPI */ #define DEFAULT_STATE (CS) /* CS idles high, CLK idles LOW for SPI0 */ //MPSSE commands from FTDI AN_108 #define INVALID_COMMAND 0xAB #define ENABLE_ADAPTIVE_CLOCK 0x96 #define DISABLE_ADAPTIVE_CLOCK 0x97 #define ENABLE_3_PHASE_CLOCK 0x8C #define DISABLE_3_PHASE_CLOCK 0x8D #define TCK_X5 0x8A #define TCK_D5 0x8B #define CLOCK_N_CYCLES 0x8E #define CLOCK_N8_CYCLES 0x8F #define PULSE_CLOCK_IO_HIGH 0x94 #define PULSE_CLOCK_IO_LOW 0x95 #define CLOCK_N8_CYCLES_IO_HIGH 0x9C #define CLOCK_N8_CYCLES_IO_LOW 0x9D #define TRISTATE_IO 0x9E #define TCK_DIVISOR 0x86 #define LOOPBACK_END 0x85 #define SET_OUT_ADBUS 0x80 #define SET_OUT_ACBUS 0x82 #define WRITE_BYTES_SPI0 0x11 #define READ_WRITE_BYTES_SPI0 0x31 static void bf1_empty_buffer(struct cgpu_info *bitfury) { char buf[512]; int amount; do { usb_read_once(bitfury, buf, 512, &amount, C_BF1_FLUSH); } while (amount); } static bool bf1_open(struct cgpu_info *bitfury) { uint32_t buf[2]; int err; bf1_empty_buffer(bitfury); /* Magic sequence to reset device only really needed for windows but * harmless on linux. */ buf[0] = 0x80250000; buf[1] = 0x00000800; err = usb_transfer(bitfury, 0, 9, 1, 0, C_ATMEL_RESET); if (!err) err = usb_transfer(bitfury, 0x21, 0x22, 0, 0, C_ATMEL_OPEN); if (!err) { err = usb_transfer_data(bitfury, 0x21, 0x20, 0x0000, 0, buf, BF1MSGSIZE, C_ATMEL_INIT); } if (err < 0) { applog(LOG_INFO, "%s %d: Failed to open with error %s", bitfury->drv->name, bitfury->device_id, libusb_error_name(err)); } return (err == BF1MSGSIZE); } static void bf1_close(struct cgpu_info *bitfury) { bf1_empty_buffer(bitfury); } static void bf1_identify(struct cgpu_info *bitfury) { int amount; usb_write(bitfury, "L", 1, &amount, C_BF1_IDENTIFY); } static void bitfury_identify(struct cgpu_info *bitfury) { struct bitfury_info *info = bitfury->device_data; switch(info->ident) { case IDENT_BF1: bf1_identify(bitfury); break; case IDENT_BXF: case IDENT_OSM: default: break; } } static bool bf1_getinfo(struct cgpu_info *bitfury, struct bitfury_info *info) { int amount, err; char buf[16]; err = usb_write(bitfury, "I", 1, &amount, C_BF1_REQINFO); if (err) { applog(LOG_INFO, "%s %d: Failed to write REQINFO", bitfury->drv->name, bitfury->device_id); return false; } err = usb_read(bitfury, buf, BF1INFOSIZE, &amount, C_BF1_GETINFO); if (err) { applog(LOG_INFO, "%s %d: Failed to read GETINFO", bitfury->drv->name, bitfury->device_id); return false; } if (amount != BF1INFOSIZE) { applog(LOG_INFO, "%s %d: Getinfo received %d bytes instead of %d", bitfury->drv->name, bitfury->device_id, amount, BF1INFOSIZE); return false; } info->version = buf[1]; cg_memcpy(&info->product, buf + 2, 8); cg_memcpy(&info->serial, buf + 10, 4); bitfury->unique_id = bin2hex((unsigned char *)buf + 10, 4); applog(LOG_INFO, "%s %d: Getinfo returned version %d, product %s serial %s", bitfury->drv->name, bitfury->device_id, info->version, info->product, bitfury->unique_id); bf1_empty_buffer(bitfury); return true; } static bool bf1_reset(struct cgpu_info *bitfury) { int amount, err; char buf[16]; err = usb_write(bitfury, "R", 1, &amount, C_BF1_REQRESET); if (err) { applog(LOG_INFO, "%s %d: Failed to write REQRESET", bitfury->drv->name, bitfury->device_id); return false; } err = usb_read_timeout(bitfury, buf, BF1MSGSIZE, &amount, BF1WAIT, C_BF1_GETRESET); if (err) { applog(LOG_INFO, "%s %d: Failed to read GETRESET", bitfury->drv->name, bitfury->device_id); return false; } if (amount != BF1MSGSIZE) { applog(LOG_INFO, "%s %d: Getreset received %d bytes instead of %d", bitfury->drv->name, bitfury->device_id, amount, BF1MSGSIZE); return false; } applog(LOG_DEBUG, "%s %d: Getreset returned %s", bitfury->drv->name, bitfury->device_id, buf); bf1_empty_buffer(bitfury); return true; } static bool bxf_send_msg(struct cgpu_info *bitfury, char *buf, enum usb_cmds cmd) { int err, amount, len; if (unlikely(bitfury->usbinfo.nodev)) return false; if (opt_bxf_debug) { char *strbuf = str_text(buf); applog(LOG_ERR, "%s %d: >BXF [%s]", bitfury->drv->name, bitfury->device_id, strbuf); free(strbuf); } len = strlen(buf); applog(LOG_DEBUG, "%s %d: Sending %s", bitfury->drv->name, bitfury->device_id, buf); err = usb_write(bitfury, buf, len, &amount, cmd); if (err || amount != len) { applog(LOG_WARNING, "%s %d: Error %d sending %s sent %d of %d", bitfury->drv->name, bitfury->device_id, err, usb_cmdname(cmd), amount, len); return false; } return true; } static bool bxf_send_debugmode(struct cgpu_info *bitfury) { char buf[16]; sprintf(buf, "debug-mode %d\n", opt_bxf_debug); return bxf_send_msg(bitfury, buf, C_BXF_DEBUGMODE); } static bool bxf_send_ledmode(struct cgpu_info *bitfury) { char buf[16]; sprintf(buf, "led-mode %d\n", opt_osm_led_mode); return bxf_send_msg(bitfury, buf, C_BXF_LEDMODE); } /* Returns the amount received only if we receive a full message, otherwise * it returns the err value. */ static int bxf_recv_msg(struct cgpu_info *bitfury, char *buf) { int err, amount; err = usb_read_nl(bitfury, buf, 512, &amount, C_BXF_READ); if (amount) applog(LOG_DEBUG, "%s %d: Received %s", bitfury->drv->name, bitfury->device_id, buf); if (!err) return amount; return err; } /* Keep reading till the first timeout or error */ static void bxf_clear_buffer(struct cgpu_info *bitfury) { int err, retries = 0; char buf[512]; do { err = bxf_recv_msg(bitfury, buf); usb_buffer_clear(bitfury); if (err < 0) break; } while (retries++ < 10); } static bool bxf_send_flush(struct cgpu_info *bitfury) { char buf[8]; sprintf(buf, "flush\n"); return bxf_send_msg(bitfury, buf, C_BXF_FLUSH); } static bool bxf_detect_one(struct cgpu_info *bitfury, struct bitfury_info *info) { int err, retries = 0; char buf[512]; if (!bxf_send_flush(bitfury)) return false; bxf_clear_buffer(bitfury); sprintf(buf, "version\n"); if (!bxf_send_msg(bitfury, buf, C_BXF_VERSION)) return false; do { err = bxf_recv_msg(bitfury, buf); if (err < 0 && err != LIBUSB_ERROR_TIMEOUT) return false; if (err > 0 && !strncmp(buf, "version", 7)) { sscanf(&buf[8], "%d.%d rev %d chips %d", &info->ver_major, &info->ver_minor, &info->hw_rev, &info->chips); applog(LOG_INFO, "%s %d: Version %d.%d rev %d chips %d", bitfury->drv->name, bitfury->device_id, info->ver_major, info->ver_minor, info->hw_rev, info->chips); break; } /* Keep parsing if the buffer is full without counting it as * a retry. */ if (usb_buffer_size(bitfury)) continue; } while (retries++ < 10); if (!add_cgpu(bitfury)) quit(1, "Failed to add_cgpu in bxf_detect_one"); update_usb_stats(bitfury); applog(LOG_INFO, "%s %d: Successfully initialised %s", bitfury->drv->name, bitfury->device_id, bitfury->device_path); /* Sanity check and recognise variations */ if (info->chips <= 2 || info->chips > 999) info->chips = 2; else if (info->chips <= 6 && info->ident == IDENT_BXF) bitfury->drv->name = "HXF"; else if (info->chips > 6 && info->ident == IDENT_BXF) bitfury->drv->name = "MXF"; info->filtered_hw = cgcalloc(sizeof(int), info->chips); info->job = cgcalloc(sizeof(int), info->chips); info->submits = cgcalloc(sizeof(int), info->chips); info->total_nonces = 1; info->temp_target = opt_bxf_temp_target * 10; /* This unsets it to make sure it gets set on the first pass */ info->maxroll = -1; return true; } static bool bf1_detect_one(struct cgpu_info *bitfury, struct bitfury_info *info) { if (!bf1_open(bitfury)) goto out_close; /* Send getinfo request */ if (!bf1_getinfo(bitfury, info)) goto out_close; /* Send reset request */ if (!bf1_reset(bitfury)) goto out_close; bf1_identify(bitfury); bf1_empty_buffer(bitfury); if (!add_cgpu(bitfury)) quit(1, "Failed to add_cgpu in bf1_detect_one"); update_usb_stats(bitfury); applog(LOG_INFO, "%s %d: Successfully initialised %s", bitfury->drv->name, bitfury->device_id, bitfury->device_path); /* This does not artificially raise hashrate, it simply allows the * hashrate to adapt quickly on starting. */ info->total_nonces = 1; return true; out_close: bf1_close(bitfury); return false; } static void nfu_close(struct cgpu_info *bitfury) { struct bitfury_info *info = bitfury->device_data; struct mcp_settings *mcp = &info->mcp; int i; mcp2210_spi_cancel(bitfury); /* Set all pins to input mode, ignoring return code */ for (i = 0; i < 9; i++) { mcp->direction.pin[i] = MCP2210_GPIO_INPUT; mcp->value.pin[i] = MCP2210_GPIO_PIN_LOW; } mcp2210_set_gpio_settings(bitfury, mcp); } static bool nfu_reinit(struct cgpu_info *bitfury, struct bitfury_info *info) { bool ret = true; int i; for (i = 0; i < info->chips; i++) { spi_clear_buf(info); spi_add_break(info); spi_add_fasync(info, i); spi_set_freq(info); spi_send_conf(info); spi_send_init(info); spi_reset(bitfury, info); ret = info->spi_txrx(bitfury, info); if (!ret) break; } return ret; } static bool nfu_set_spi_settings(struct cgpu_info *bitfury, struct bitfury_info *info) { struct mcp_settings *mcp = &info->mcp; return mcp2210_set_spi_transfer_settings(bitfury, mcp->bitrate, mcp->icsv, mcp->acsv, mcp->cstdd, mcp->ldbtcsd, mcp->sdbd, mcp->bpst, mcp->spimode); } static void nfu_alloc_arrays(struct bitfury_info *info) { info->payload = cgcalloc(sizeof(struct bitfury_payload), info->chips); info->oldbuf = cgcalloc(sizeof(unsigned int) * 17, info->chips); info->job_switched = cgcalloc(sizeof(bool), info->chips); info->second_run = cgcalloc(sizeof(bool), info->chips); info->work = cgcalloc(sizeof(struct work *), info->chips); info->owork = cgcalloc(sizeof(struct work *), info->chips); info->submits = cgcalloc(sizeof(int *), info->chips); } static bool nfu_detect_one(struct cgpu_info *bitfury, struct bitfury_info *info) { struct mcp_settings *mcp = &info->mcp; char buf[MCP2210_BUFFER_LENGTH]; unsigned int length; bool ret = false; int i, val; /* Identify number of chips, and use it in device name if it can fit * into 3 chars, otherwise use generic NFU name. */ val = sscanf(bitfury->usbdev->prod_string, "NanoFury NF%u ", &info->chips); if (val < 1) info->chips = 1; else if (info->chips < 10) { sprintf(info->product, "NF%u", info->chips); bitfury->drv->name = info->product; } nfu_alloc_arrays(info); info->spi_txrx = &mcp_spi_txrx; mcp2210_get_gpio_settings(bitfury, mcp); for (i = 0; i < 9; i++) { /* Set all pins to GPIO mode */ mcp->designation.pin[i] = MCP2210_PIN_GPIO; /* Set all pins to input mode */ mcp->direction.pin[i] = MCP2210_GPIO_INPUT; mcp->value.pin[i] = MCP2210_GPIO_PIN_LOW; } /* Set LED and PWR pins to output and high */ mcp->direction.pin[NFU_PIN_LED] = mcp->direction.pin[NFU_PIN_PWR_EN] = MCP2210_GPIO_OUTPUT; mcp->value.pin[NFU_PIN_LED] = mcp->value.pin[NFU_PIN_PWR_EN] = MCP2210_GPIO_PIN_HIGH; mcp->direction.pin[NFU_PIN_PWR_EN0] = MCP2210_GPIO_OUTPUT; mcp->value.pin[NFU_PIN_PWR_EN0] = MCP2210_GPIO_PIN_LOW; mcp->direction.pin[4] = MCP2210_GPIO_OUTPUT; mcp->designation.pin[4] = MCP2210_PIN_CS; if (!mcp2210_set_gpio_settings(bitfury, mcp)) goto out; if (opt_debug) { struct gpio_pin gp; mcp2210_get_gpio_pindirs(bitfury, &gp); for (i = 0; i < 9; i++) { applog(LOG_DEBUG, "%s %d: Pin dir %d %d", bitfury->drv->name, bitfury->device_id, i, gp.pin[i]); } mcp2210_get_gpio_pinvals(bitfury, &gp); for (i = 0; i < 9; i++) { applog(LOG_DEBUG, "%s %d: Pin val %d %d", bitfury->drv->name, bitfury->device_id, i, gp.pin[i]); } mcp2210_get_gpio_pindes(bitfury, &gp); for (i = 0; i < 9; i++) { applog(LOG_DEBUG, "%s %d: Pin des %d %d", bitfury->drv->name, bitfury->device_id, i, gp.pin[i]); } } /* Cancel any transfers in progress */ if (!mcp2210_spi_cancel(bitfury)) goto out; if (!mcp2210_get_spi_transfer_settings(bitfury, &mcp->bitrate, &mcp->icsv, &mcp->acsv, &mcp->cstdd, &mcp->ldbtcsd, &mcp->sdbd, &mcp->bpst, &mcp->spimode)) goto out; mcp->bitrate = 200000; // default to 200kHz mcp->icsv = 0xffff; mcp->acsv = 0xffef; mcp->cstdd = mcp->ldbtcsd = mcp->sdbd = mcp->spimode = 0; mcp->bpst = 1; if (!nfu_set_spi_settings(bitfury, info)) goto out; buf[0] = 0; length = 1; if (!mcp2210_spi_transfer(bitfury, mcp, buf, &length)) goto out; /* after this command SCK_OVRRIDE should read the same as current SCK * value (which for mode 0 should be 0) */ if (!mcp2210_get_gpio_pinval(bitfury, NFU_PIN_SCK_OVR, &val)) goto out; if (val != MCP2210_GPIO_PIN_LOW) goto out; /* switch SCK to polarity (default SCK=1 in mode 2) */ mcp->spimode = 2; if (!nfu_set_spi_settings(bitfury, info)) goto out; buf[0] = 0; length = 1; if (!mcp2210_spi_transfer(bitfury, mcp, buf, &length)) goto out; /* after this command SCK_OVRRIDE should read the same as current SCK * value (which for mode 2 should be 1) */ if (!mcp2210_get_gpio_pinval(bitfury, NFU_PIN_SCK_OVR, &val)) goto out; if (val != MCP2210_GPIO_PIN_HIGH) goto out; /* switch SCK to polarity (default SCK=0 in mode 0) */ mcp->spimode = 0; if (!nfu_set_spi_settings(bitfury, info)) goto out; buf[0] = 0; length = 1; if (!mcp2210_spi_transfer(bitfury, mcp, buf, &length)) goto out; if (!mcp2210_get_gpio_pinval(bitfury, NFU_PIN_SCK_OVR, &val)) goto out; if (val != MCP2210_GPIO_PIN_LOW) goto out; info->osc6_bits = opt_nfu_bits; if (!nfu_reinit(bitfury, info)) goto out; ret = true; if (!add_cgpu(bitfury)) quit(1, "Failed to add_cgpu in nfu_detect_one"); update_usb_stats(bitfury); applog(LOG_INFO, "%s %d: Successfully initialised %s", bitfury->drv->name, bitfury->device_id, bitfury->device_path); spi_clear_buf(info); info->total_nonces = info->chips; out: if (!ret) nfu_close(bitfury); return ret; } static bool bxm_purge_buffers(struct cgpu_info *bitfury) { int err; err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_RESET_REQUEST, SIO_RESET_PURGE_RX, 1, C_BXM_PURGERX); if (err) return false; err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_RESET_REQUEST, SIO_RESET_PURGE_TX, 1, C_BXM_PURGETX); if (err) return false; return true; } /* Calculate required divisor for desired frequency see FTDI AN_108 page 19*/ static uint16_t calc_divisor(uint32_t system_clock, uint32_t freq) { uint16_t divisor = system_clock / freq; divisor /= 2; divisor -= 1; return divisor; } static void bxm_shutdown(struct cgpu_info *bitfury, struct bitfury_info *info) { int chip_n; for (chip_n = 0; chip_n < 2; chip_n++) { spi_clear_buf(info); spi_add_break(info); spi_add_fasync(info, chip_n); spi_config_reg(info, 4, 0); info->spi_txrx(bitfury, info); } } static void bxm_close(struct cgpu_info *bitfury, struct bitfury_info *info) { unsigned char bitmask = 0; unsigned char mode = BITMODE_RESET; unsigned short usb_val = bitmask; bxm_shutdown(bitfury, info); //Need to do BITMODE_RESET before usb close per FTDI usb_val |= (mode << 8); usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_SET_BITMODE_REQUEST, usb_val, 1, C_BXM_SETBITMODE); } static bool bxm_open(struct cgpu_info *bitfury) { unsigned char mode = BITMODE_RESET; unsigned char bitmask = 0; unsigned short usb_val = bitmask; uint32_t system_clock = TWELVE_MHZ; uint32_t freq = 200000; uint16_t divisor = calc_divisor(system_clock,freq); int amount, err; char buf[4]; /* Enable the transaction translator emulator for these devices * otherwise we may write to them too quickly. */ bitfury->usbdev->tt = true; err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_RESET_REQUEST, SIO_RESET_SIO, 1, C_BXM_SRESET); if (err) return false; err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_SET_LATENCY_TIMER_REQUEST, BXM_LATENCY_MS, 1, C_BXM_SETLATENCY); if (err) return false; err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_SET_EVENT_CHAR_REQUEST, 0x00, 1, C_BXM_SECR); if (err) return false; //Do a BITMODE_RESET usb_val |= (mode << 8); err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_SET_BITMODE_REQUEST, usb_val, 1, C_BXM_SETBITMODE); if (err) return false; //Now set to MPSSE mode bitmask = 0; mode = BITMODE_MPSSE; usb_val = bitmask; usb_val |= (mode << 8); err = usb_transfer(bitfury, FTDI_TYPE_OUT, SIO_SET_BITMODE_REQUEST, usb_val, 1, C_BXM_SETBITMODE); if (err) return false; //Now set the clock divisor //First send just the 0x8B command to set the system clock to 12MHz memset(buf, 0, 4); buf[0] = TCK_D5; err = usb_write(bitfury, buf, 1, &amount, C_BXM_CLOCK); if (err || amount != 1) return false; buf[0] = TCK_DIVISOR; buf[1] = (divisor & 0xFF); buf[2] = ((divisor >> 8) & 0xFF); err = usb_write(bitfury, buf, 3, &amount, C_BXM_CLOCKDIV); if (err || amount != 3) return false; //Disable internal loopback buf[0] = LOOPBACK_END; err = usb_write(bitfury, buf, 1, &amount, C_BXM_LOOP); if (err || amount != 1) return false; //Now set direction and idle (initial) states for the pins buf[0] = SET_OUT_ADBUS; buf[1] = DEFAULT_STATE; //Bitmask for LOW_PORT buf[2] = DEFAULT_DIR; err = usb_write(bitfury, buf, 3, &amount, C_BXM_ADBUS); if (err || amount != 3) return false; //Set the pin states for the HIGH_BITS port as all outputs, all low buf[0] = SET_OUT_ACBUS; buf[1] = 0x00; //Bitmask for HIGH_PORT buf[2] = 0xFF; err = usb_write(bitfury, buf, 3, &amount, C_BXM_ACBUS); if (err || amount != 3) return false; return true; } static bool bxm_set_CS_low(struct cgpu_info *bitfury) { char buf[4] = { 0 }; int err, amount; buf[0] = SET_OUT_ADBUS; buf[1] &= ~DEFAULT_STATE; //Bitmask for LOW_PORT buf[2] = DEFAULT_DIR; err = usb_write(bitfury, buf, 3, &amount, C_BXM_CSLOW); if (err || amount != 3) return false; return true; } static bool bxm_set_CS_high(struct cgpu_info *bitfury) { char buf[4] = { 0 }; int err, amount; buf[0] = SET_OUT_ADBUS; buf[1] = DEFAULT_STATE; //Bitmask for LOW_PORT buf[2] = DEFAULT_DIR; err = usb_write(bitfury, buf, 3, &amount, C_BXM_CSHIGH); if (err || amount != 3) return false; return true; } static bool bxm_reset_bitfury(struct cgpu_info *bitfury) { char buf[20] = { 0 }; char rst_buf[8] = {0xFF, 0x00, 0xFF, 0x00, 0xFF, 0x00, 0xFF, 0x00}; int err, amount; //Set the FTDI CS pin HIGH. This will gate the clock to the Bitfury chips so we can send the reset sequence. if (!bxm_set_CS_high(bitfury)) return false; buf[0] = WRITE_BYTES_SPI0; buf[1] = (uint8_t)16 - (uint8_t)1; buf[2] = 0; cg_memcpy(&buf[3], rst_buf, 8); cg_memcpy(&buf[11], rst_buf, 8); err = usb_write(bitfury, buf, 19, &amount, C_BXM_RESET); if (err || amount != 19) return false; if (!bxm_set_CS_low(bitfury)) return false; return true; } static bool bxm_reinit(struct cgpu_info *bitfury, struct bitfury_info *info) { bool ret; int i; for (i = 0; i < 2; i++) { spi_clear_buf(info); spi_add_break(info); spi_add_fasync(info, i); spi_set_freq(info); spi_send_conf(info); spi_send_init(info); ret = info->spi_txrx(bitfury, info); if (!ret) break; } return ret; } static bool bxm_detect_one(struct cgpu_info *bitfury, struct bitfury_info *info) { bool ret; info->spi_txrx = &ftdi_spi_txrx; ret = bxm_open(bitfury); if (!ret) goto out; ret = bxm_purge_buffers(bitfury); if (!ret) goto out; ret = bxm_reset_bitfury(bitfury); if (!ret) goto out; ret = bxm_purge_buffers(bitfury); if (!ret) goto out; /* Do a dummy read */ memset(info->spibuf, 0, 80); info->spibufsz = 80; ret = info->spi_txrx(bitfury, info); if (!ret) goto out; info->osc6_bits = opt_bxm_bits; /* Only have 2 chip devices for now */ info->chips = 2; nfu_alloc_arrays(info); ret = bxm_reinit(bitfury, info); if (!ret) goto out; if (!add_cgpu(bitfury)) quit(1, "Failed to add_cgpu in bxm_detect_one"); update_usb_stats(bitfury); applog(LOG_INFO, "%s %d: Successfully initialised %s", bitfury->drv->name, bitfury->device_id, bitfury->device_path); spi_clear_buf(info); info->total_nonces = 1; out: if (!ret) bxm_close(bitfury, info); return ret; } static struct cgpu_info *bitfury_detect_one(struct libusb_device *dev, struct usb_find_devices *found) { struct cgpu_info *bitfury; struct bitfury_info *info; enum sub_ident ident; bool ret = false; bitfury = usb_alloc_cgpu(&bitfury_drv, 1); if (!usb_init(bitfury, dev, found)) goto out; applog(LOG_INFO, "%s %d: Found at %s", bitfury->drv->name, bitfury->device_id, bitfury->device_path); info = cgcalloc(sizeof(struct bitfury_info), 1); bitfury->device_data = info; info->ident = ident = usb_ident(bitfury); switch (ident) { case IDENT_BF1: ret = bf1_detect_one(bitfury, info); break; case IDENT_BXF: case IDENT_OSM: ret = bxf_detect_one(bitfury, info); break; case IDENT_NFU: ret = nfu_detect_one(bitfury, info); break; case IDENT_BXM: ret = bxm_detect_one(bitfury, info); break; default: applog(LOG_INFO, "%s %d: Unrecognised bitfury device", bitfury->drv->name, bitfury->device_id); break; } if (!ret) { free(info); usb_uninit(bitfury); out: bitfury = usb_free_cgpu(bitfury); } return bitfury; } static void bitfury_detect(bool __maybe_unused hotplug) { usb_detect(&bitfury_drv, bitfury_detect_one); } static void adjust_bxf_chips(struct cgpu_info *bitfury, struct bitfury_info *info, int chip) { int chips = chip + 1; size_t old, new; if (likely(chips <= info->chips)) return; if (chips > 999) return; old = sizeof(int) * info->chips; new = sizeof(int) * chips; applog(LOG_INFO, "%s %d: Adjust chip size to %d", bitfury->drv->name, bitfury->device_id, chips); recalloc(info->filtered_hw, old, new); recalloc(info->job, old, new); recalloc(info->submits, old, new); if (info->chips == 2 && chips <= 6 && info->ident == IDENT_BXF) bitfury->drv->name = "HXF"; else if (info->chips <= 6 && chips > 6 && info->ident == IDENT_BXF) bitfury->drv->name = "MXF"; info->chips = chips; } static void parse_bxf_submit(struct cgpu_info *bitfury, struct bitfury_info *info, char *buf) { struct work *match_work, *tmp, *work = NULL; struct thr_info *thr = info->thr; uint32_t nonce, timestamp; int workid, chip = -1; if (!sscanf(&buf[7], "%x %x %x %d", &nonce, &workid, ×tamp, &chip)) { applog(LOG_WARNING, "%s %d: Failed to parse submit response", bitfury->drv->name, bitfury->device_id); return; } adjust_bxf_chips(bitfury, info, chip); if (unlikely(chip >= info->chips || chip < 0)) { applog(LOG_INFO, "%s %d: Invalid submit chip number %d", bitfury->drv->name, bitfury->device_id, chip); } else info->submits[chip]++; applog(LOG_DEBUG, "%s %d: Parsed nonce %u workid %d timestamp %u", bitfury->drv->name, bitfury->device_id, nonce, workid, timestamp); rd_lock(&bitfury->qlock); HASH_ITER(hh, bitfury->queued_work, match_work, tmp) { if (match_work->subid == workid) { work = copy_work(match_work); break; } } rd_unlock(&bitfury->qlock); if (!work) { /* Discard first results from any previous run */ if (unlikely(!info->valid)) return; applog(LOG_INFO, "%s %d: No matching work", bitfury->drv->name, bitfury->device_id); mutex_lock(&info->lock); info->no_matching_work++; mutex_unlock(&info->lock); inc_hw_errors(thr); return; } /* Set the device start time from when we first get valid results */ if (unlikely(!info->valid)) { info->valid = true; cgtime(&bitfury->dev_start_tv); } set_work_ntime(work, timestamp); if (submit_nonce(thr, work, nonce)) { mutex_lock(&info->lock); info->nonces++; mutex_unlock(&info->lock); } free_work(work); } static bool bxf_send_clock(struct cgpu_info *bitfury, struct bitfury_info *info, uint8_t clockspeed) { char buf[64]; info->clocks = clockspeed; sprintf(buf, "clock %d %d\n", clockspeed, clockspeed); return bxf_send_msg(bitfury, buf, C_BXF_CLOCK); } static void parse_bxf_temp(struct cgpu_info *bitfury, struct bitfury_info *info, char *buf) { uint8_t clockspeed = info->clocks; int decitemp; if (!sscanf(&buf[5], "%d", &decitemp)) { applog(LOG_INFO, "%s %d: Failed to parse temperature", bitfury->drv->name, bitfury->device_id); return; } mutex_lock(&info->lock); bitfury->temp = (double)decitemp / 10; if (decitemp > info->max_decitemp) { info->max_decitemp = decitemp; applog(LOG_DEBUG, "%s %d: New max decitemp %d", bitfury->drv->name, bitfury->device_id, decitemp); } mutex_unlock(&info->lock); if (decitemp > info->temp_target + BXF_TEMP_HYSTERESIS) { if (info->clocks <= BXF_CLOCK_MIN) goto out; applog(LOG_WARNING, "%s %d: Hit overheat temperature of %d, throttling!", bitfury->drv->name, bitfury->device_id, decitemp); clockspeed = BXF_CLOCK_MIN; goto out; } if (decitemp > info->temp_target) { if (info->clocks <= BXF_CLOCK_MIN) goto out; if (decitemp < info->last_decitemp) goto out; applog(LOG_INFO, "%s %d: Temp %d over target and not falling, decreasing clock", bitfury->drv->name, bitfury->device_id, decitemp); clockspeed = info->clocks - 1; goto out; } if (decitemp <= info->temp_target && decitemp >= info->temp_target - BXF_TEMP_HYSTERESIS) { if (decitemp == info->last_decitemp) goto out; if (decitemp > info->last_decitemp) { if (info->clocks <= BXF_CLOCK_MIN) goto out; applog(LOG_DEBUG, "%s %d: Temp %d in target and rising, decreasing clock", bitfury->drv->name, bitfury->device_id, decitemp); clockspeed = info->clocks - 1; goto out; } /* implies: decitemp < info->last_decitemp */ if (info->clocks >= opt_bxf_bits) goto out; applog(LOG_DEBUG, "%s %d: Temp %d in target and falling, increasing clock", bitfury->drv->name, bitfury->device_id, decitemp); clockspeed = info->clocks + 1; goto out; } /* implies: decitemp < info->temp_target - BXF_TEMP_HYSTERESIS */ if (info->clocks >= opt_bxf_bits) goto out; applog(LOG_DEBUG, "%s %d: Temp %d below target, increasing clock", bitfury->drv->name, bitfury->device_id, decitemp); clockspeed = info->clocks + 1; out: bxf_send_clock(bitfury, info, clockspeed); info->last_decitemp = decitemp; } static void bxf_update_work(struct cgpu_info *bitfury, struct bitfury_info *info); static void parse_bxf_needwork(struct cgpu_info *bitfury, struct bitfury_info *info, char *buf) { int needed; if (!sscanf(&buf[9], "%d", &needed)) { applog(LOG_INFO, "%s %d: Failed to parse needwork", bitfury->drv->name, bitfury->device_id); return; } while (needed-- > 0) bxf_update_work(bitfury, info); } static void parse_bxf_job(struct cgpu_info *bitfury, struct bitfury_info *info, char *buf) { int job_id, timestamp, chip; if (sscanf(&buf[4], "%x %x %x", &job_id, ×tamp, &chip) != 3) { applog(LOG_INFO, "%s %d: Failed to parse job", bitfury->drv->name, bitfury->device_id); return; } adjust_bxf_chips(bitfury, info, chip); if (chip >= info->chips || chip < 0) { applog(LOG_INFO, "%s %d: Invalid job chip number %d", bitfury->drv->name, bitfury->device_id, chip); return; } ++info->job[chip]; } static void parse_bxf_hwerror(struct cgpu_info *bitfury, struct bitfury_info *info, char *buf) { int chip; if (!sscanf(&buf[8], "%d", &chip)) { applog(LOG_INFO, "%s %d: Failed to parse hwerror", bitfury->drv->name, bitfury->device_id); return; } adjust_bxf_chips(bitfury, info, chip); if (chip >= info->chips || chip < 0) { applog(LOG_INFO, "%s %d: Invalid hwerror chip number %d", bitfury->drv->name, bitfury->device_id, chip); return; } ++info->filtered_hw[chip]; } #define PARSE_BXF_MSG(MSG) \ msg = strstr(buf, #MSG); \ if (msg) { \ parse_bxf_##MSG(bitfury, info, msg); \ continue; \ } static void *bxf_get_results(void *userdata) { struct cgpu_info *bitfury = userdata; struct bitfury_info *info = bitfury->device_data; char threadname[24], buf[512]; snprintf(threadname, 24, "bxf_recv/%d", bitfury->device_id); /* We operate the device at lowest diff since it's not a lot of results * to process and gives us a better indicator of the nonce return rate * and hardware errors. */ sprintf(buf, "target ffffffff\n"); if (!bxf_send_msg(bitfury, buf, C_BXF_TARGET)) goto out; /* Read thread sends the first work item to get the device started * since it will roll ntime and make work itself from there on. */ bxf_update_work(bitfury, info); bxf_update_work(bitfury, info); while (likely(!bitfury->shutdown)) { char *msg, *strbuf; int err; if (unlikely(bitfury->usbinfo.nodev)) break; err = bxf_recv_msg(bitfury, buf); if (err < 0) { if (err != LIBUSB_ERROR_TIMEOUT) break; continue; } if (!err) continue; if (opt_bxf_debug) { strbuf = str_text(buf); applog(LOG_ERR, "%s %d: < [%s]", bitfury->drv->name, bitfury->device_id, strbuf); free(strbuf); } PARSE_BXF_MSG(submit); PARSE_BXF_MSG(temp); PARSE_BXF_MSG(needwork); PARSE_BXF_MSG(job); PARSE_BXF_MSG(hwerror); if (buf[0] != '#') { strbuf = str_text(buf); applog(LOG_DEBUG, "%s %d: Unrecognised string %s", bitfury->drv->name, bitfury->device_id, strbuf); free(strbuf); } } out: return NULL; } static bool bxf_prepare(struct cgpu_info *bitfury, struct bitfury_info *info) { bxf_send_ledmode(bitfury); bxf_send_debugmode(bitfury); mutex_init(&info->lock); if (pthread_create(&info->read_thr, NULL, bxf_get_results, (void *)bitfury)) quit(1, "Failed to create bxf read_thr"); return bxf_send_clock(bitfury, info, opt_bxf_bits); } static bool bitfury_prepare(struct thr_info *thr) { struct cgpu_info *bitfury = thr->cgpu; struct bitfury_info *info = bitfury->device_data; info->thr = thr; switch(info->ident) { case IDENT_BXF: case IDENT_OSM: return bxf_prepare(bitfury, info); break; case IDENT_BF1: default: return true; } } static int64_t bitfury_rate(struct bitfury_info *info) { double nonce_rate; int64_t ret = 0; info->cycles++; info->total_nonces += info->nonces; info->saved_nonces += info->nonces; info->nonces = 0; nonce_rate = (double)info->total_nonces / (double)info->cycles; if (info->saved_nonces >= nonce_rate) { info->saved_nonces -= nonce_rate; ret = (double)0xffffffff * nonce_rate; } return ret; } static int64_t bf1_scan(struct thr_info *thr, struct cgpu_info *bitfury, struct bitfury_info *info) { int amount, i, aged, total = 0, ms_diff; char readbuf[512], buf[45]; struct work *work, *tmp; struct timeval tv_now; int64_t ret = 0; work = get_queue_work(thr, bitfury, thr->id); if (unlikely(thr->work_restart)) { work_completed(bitfury, work); goto out; } buf[0] = 'W'; cg_memcpy(buf + 1, work->midstate, 32); cg_memcpy(buf + 33, work->data + 64, 12); /* New results may spill out from the latest work, making us drop out * too early so read whatever we get for the first half nonce and then * look for the results to prev work. */ cgtime(&tv_now); ms_diff = 600 - ms_tdiff(&tv_now, &info->tv_start); if (ms_diff > 0) { usb_read_timeout_cancellable(bitfury, readbuf, 512, &amount, ms_diff, C_BF1_GETRES); total += amount; } /* Now look for the bulk of the previous work results, they will come * in a batch following the first data. */ cgtime(&tv_now); ms_diff = BF1WAIT - ms_tdiff(&tv_now, &info->tv_start); /* If a work restart was sent, just empty the buffer. */ if (unlikely(ms_diff < 10 || thr->work_restart)) ms_diff = 10; usb_read_once_timeout_cancellable(bitfury, readbuf + total, BF1MSGSIZE, &amount, ms_diff, C_BF1_GETRES); total += amount; while (amount) { usb_read_once_timeout(bitfury, readbuf + total, 512 - total, &amount, 10, C_BF1_GETRES); total += amount; }; /* Don't send whatever work we've stored if we got a restart */ if (unlikely(thr->work_restart)) goto out; /* Send work */ cgtime(&work->tv_work_start); usb_write(bitfury, buf, 45, &amount, C_BF1_REQWORK); cgtime(&info->tv_start); /* Get response acknowledging work */ usb_read(bitfury, buf, BF1MSGSIZE, &amount, C_BF1_GETWORK); out: /* Search for what work the nonce matches in order of likelihood. Last * entry is end of result marker. */ for (i = 0; i < total - BF1MSGSIZE; i += BF1MSGSIZE) { bool found = false; uint32_t nonce; /* Ignore state & switched data in results for now. */ cg_memcpy(&nonce, readbuf + i + 3, 4); nonce = decnonce(nonce); rd_lock(&bitfury->qlock); HASH_ITER(hh, bitfury->queued_work, work, tmp) { if (bitfury_checkresults(thr, work, nonce)) { info->nonces++; found = true; break; } } rd_unlock(&bitfury->qlock); if (!found) { if (likely(info->valid)) inc_hw_errors(thr); } else if (unlikely(!info->valid)) { info->valid = true; cgtime(&bitfury->dev_start_tv); } } cgtime(&tv_now); /* This iterates over the hashlist finding work started more than 6 * seconds ago. */ aged = age_queued_work(bitfury, 6.0); if (aged) { applog(LOG_DEBUG, "%s %d: Aged %d work items", bitfury->drv->name, bitfury->device_id, aged); } ret = bitfury_rate(info); if (unlikely(bitfury->usbinfo.nodev)) { applog(LOG_WARNING, "%s %d: Device disappeared, disabling thread", bitfury->drv->name, bitfury->device_id); ret = -1; } return ret; } static int64_t bxf_scan(struct cgpu_info *bitfury, struct bitfury_info *info) { int ms, aged; int64_t ret; bxf_update_work(bitfury, info); ms = 1200 / info->chips; if (ms < 100) ms = 100; cgsleep_ms(ms); mutex_lock(&info->lock); ret = bitfury_rate(info); mutex_unlock(&info->lock); /* Keep no more than the last 90 seconds worth of work items in the * hashlist */ aged = age_queued_work(bitfury, 90.0); if (aged) { applog(LOG_DEBUG, "%s %d: Aged %d work items", bitfury->drv->name, bitfury->device_id, aged); } if (unlikely(bitfury->usbinfo.nodev)) { applog(LOG_WARNING, "%s %d: Device disappeared, disabling thread", bitfury->drv->name, bitfury->device_id); ret = -1; } return ret; } static void bitfury_check_work(struct thr_info *thr, struct cgpu_info *bitfury, struct bitfury_info *info, int chip_n) { if (!info->work[chip_n]) { info->work[chip_n] = get_work(thr, thr->id); if (unlikely(thr->work_restart)) { free_work(info->work[chip_n]); info->work[chip_n] = NULL; return; } bitfury_work_to_payload(&info->payload[chip_n], info->work[chip_n]); } if (unlikely(bitfury->usbinfo.nodev)) return; if (!libbitfury_sendHashData(thr, bitfury, info, chip_n)) usb_nodev(bitfury); if (info->job_switched[chip_n]) { if (likely(info->owork[chip_n])) free_work(info->owork[chip_n]); info->owork[chip_n] = info->work[chip_n]; info->work[chip_n] = NULL; } } static int64_t nfu_scan(struct thr_info *thr, struct cgpu_info *bitfury, struct bitfury_info *info) { int64_t ret = 0; int i; for (i = 0; i < info->chips; i++) bitfury_check_work(thr, bitfury, info, i); ret = bitfury_rate(info); if (unlikely(bitfury->usbinfo.nodev)) { applog(LOG_WARNING, "%s %d: Device disappeared, disabling thread", bitfury->drv->name, bitfury->device_id); ret = -1; } return ret; } static int64_t bitfury_scanwork(struct thr_info *thr) { struct cgpu_info *bitfury = thr->cgpu; struct bitfury_info *info = bitfury->device_data; int64_t ret = -1; if (unlikely(share_work_tdiff(bitfury) > 60)) { if (info->failing) { if (share_work_tdiff(bitfury) > 120) { applog(LOG_ERR, "%s %d: Device failed to respond to restart", bitfury->drv->name, bitfury->device_id); return ret; } } else { applog(LOG_WARNING, "%s %d: No valid hashes for over 1 minute, attempting to reset", bitfury->drv->name, bitfury->device_id); usb_reset(bitfury); info->failing = true; } } if (unlikely(bitfury->usbinfo.nodev)) return ret; switch(info->ident) { case IDENT_BF1: ret = bf1_scan(thr, bitfury, info); break; case IDENT_BXF: case IDENT_OSM: ret = bxf_scan(bitfury, info); break; case IDENT_NFU: case IDENT_BXM: ret = nfu_scan(thr, bitfury, info); break; default: ret = 0; break; } if (ret > 0) info->failing = false; return ret; } static void bxf_send_maxroll(struct cgpu_info *bitfury, int maxroll) { char buf[20]; sprintf(buf, "maxroll %d\n", maxroll); bxf_send_msg(bitfury, buf, C_BXF_MAXROLL); } static bool bxf_send_work(struct cgpu_info *bitfury, struct work *work) { char buf[512], hexwork[156]; __bin2hex(hexwork, work->data, 76); sprintf(buf, "work %s %x\n", hexwork, work->subid); return bxf_send_msg(bitfury, buf, C_BXF_WORK); } static void bxf_update_work(struct cgpu_info *bitfury, struct bitfury_info *info) { struct thr_info *thr = info->thr; struct work *work; if (unlikely(bitfury->usbinfo.nodev)) return; work = get_queue_work(thr, bitfury, thr->id); if (work->drv_rolllimit != info->maxroll) { info->maxroll = work->drv_rolllimit; bxf_send_maxroll(bitfury, info->maxroll); } mutex_lock(&info->lock); work->subid = ++info->work_id; mutex_unlock(&info->lock); cgtime(&work->tv_work_start); bxf_send_work(bitfury, work); } static void bitfury_flush_work(struct cgpu_info *bitfury) { struct bitfury_info *info = bitfury->device_data; switch(info->ident) { case IDENT_BXF: case IDENT_OSM: bxf_send_flush(bitfury); bxf_update_work(bitfury, info); bxf_update_work(bitfury, info); case IDENT_BF1: default: break; } } static void bitfury_update_work(struct cgpu_info *bitfury) { struct bitfury_info *info = bitfury->device_data; switch(info->ident) { case IDENT_BXF: case IDENT_OSM: bxf_update_work(bitfury, info); case IDENT_BF1: default: break; } } static struct api_data *bf1_api_stats(struct bitfury_info *info) { struct api_data *root = NULL; double nonce_rate; char serial[16]; int version; version = info->version; root = api_add_int(root, "Version", &version, true); root = api_add_string(root, "Product", info->product, false); sprintf(serial, "%08x", info->serial); root = api_add_string(root, "Serial", serial, true); nonce_rate = (double)info->total_nonces / (double)info->cycles; root = api_add_double(root, "NonceRate", &nonce_rate, true); return root; } static struct api_data *bxf_api_stats(struct cgpu_info *bitfury, struct bitfury_info *info) { struct api_data *root = NULL; double nonce_rate; char buf[32]; int i; sprintf(buf, "%d.%d", info->ver_major, info->ver_minor); root = api_add_string(root, "Version", buf, true); root = api_add_int(root, "Revision", &info->hw_rev, false); root = api_add_int(root, "Chips", &info->chips, false); nonce_rate = (double)info->total_nonces / (double)info->cycles; root = api_add_double(root, "NonceRate", &nonce_rate, true); root = api_add_int(root, "NoMatchingWork", &info->no_matching_work, false); root = api_add_double(root, "Temperature", &bitfury->temp, false); root = api_add_int(root, "Max DeciTemp", &info->max_decitemp, false); root = api_add_uint8(root, "Clock", &info->clocks, false); for (i = 0; i < info->chips; i++) { sprintf(buf, "Core%d hwerror", i); root = api_add_int(root, buf, &info->filtered_hw[i], false); sprintf(buf, "Core%d jobs", i); root = api_add_int(root, buf, &info->job[i], false); sprintf(buf, "Core%d submits", i); root = api_add_int(root, buf, &info->submits[i], false); } return root; } static struct api_data *nfu_api_stats(struct bitfury_info *info) { struct api_data *root = NULL; char buf[32]; int i; root = api_add_int(root, "Chips", &info->chips, false); for (i = 0; i < info->chips; i++) { sprintf(buf, "Core%d submits", i); root = api_add_int(root, buf, &info->submits[i], false); } return root; } static struct api_data *bitfury_api_stats(struct cgpu_info *cgpu) { struct bitfury_info *info = cgpu->device_data; switch(info->ident) { case IDENT_BF1: return bf1_api_stats(info); break; case IDENT_BXF: case IDENT_OSM: return bxf_api_stats(cgpu, info); break; case IDENT_NFU: case IDENT_BXM: return nfu_api_stats(info); break; default: break; } return NULL; } static void bitfury_get_statline_before(char *buf, size_t bufsiz, struct cgpu_info *cgpu) { struct bitfury_info *info = cgpu->device_data; switch(info->ident) { case IDENT_BXF: case IDENT_OSM: tailsprintf(buf, bufsiz, "%5.1fC", cgpu->temp); break; default: break; } } static void bf1_init(struct cgpu_info *bitfury) { bf1_close(bitfury); bf1_open(bitfury); bf1_reset(bitfury); } static void bitfury_init(struct cgpu_info *bitfury) { struct bitfury_info *info = bitfury->device_data; switch(info->ident) { case IDENT_BF1: bf1_init(bitfury); break; default: break; } } static void bxf_close(struct bitfury_info *info) { pthread_join(info->read_thr, NULL); mutex_destroy(&info->lock); } static void bitfury_shutdown(struct thr_info *thr) { struct cgpu_info *bitfury = thr->cgpu; struct bitfury_info *info = bitfury->device_data; switch(info->ident) { case IDENT_BF1: bf1_close(bitfury); break; case IDENT_BXF: case IDENT_OSM: bxf_close(info); break; case IDENT_NFU: nfu_close(bitfury); break; case IDENT_BXM: bxm_close(bitfury, info); break; default: break; } usb_nodev(bitfury); } /* Currently hardcoded to BF1 devices */ struct device_drv bitfury_drv = { .drv_id = DRIVER_bitfury, .dname = "bitfury", .name = "BF1", .drv_detect = bitfury_detect, .thread_prepare = bitfury_prepare, .hash_work = &hash_driver_work, .scanwork = bitfury_scanwork, .flush_work = bitfury_flush_work, .update_work = bitfury_update_work, .get_api_stats = bitfury_api_stats, .get_statline_before = bitfury_get_statline_before, .reinit_device = bitfury_init, .thread_shutdown = bitfury_shutdown, .identify_device = bitfury_identify };