thodg/cgminer/driver-icarus.c

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• Hash : 330e6428
  Author :
  Date : 2013-10-15T10:03:03
  

  Convert icarus driver to hash_driver_work model.

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• driver-icarus.c

• /*
   * Copyright 2012-2013 Andrew Smith
   * Copyright 2012 Xiangfu <xiangfu@openmobilefree.com>
   * Copyright 2013 Con Kolivas <kernel@kolivas.org>
   *
   * 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.
   */
  
  /*
   * Those code should be works fine with V2 and V3 bitstream of Icarus.
   * Operation:
   *   No detection implement.
   *   Input: 64B = 32B midstate + 20B fill bytes + last 12 bytes of block head.
   *   Return: send back 32bits immediately when Icarus found a valid nonce.
   *           no query protocol implemented here, if no data send back in ~11.3
   *           seconds (full cover time on 32bit nonce range by 380MH/s speed)
   *           just send another work.
   * Notice:
   *   1. Icarus will start calculate when you push a work to them, even they
   *      are busy.
   *   2. The 2 FPGAs on Icarus will distribute the job, one will calculate the
   *      0 ~ 7FFFFFFF, another one will cover the 80000000 ~ FFFFFFFF.
   *   3. It's possible for 2 FPGAs both find valid nonce in the meantime, the 2
   *      valid nonce will all be send back.
   *   4. Icarus will stop work when: a valid nonce has been found or 32 bits
   *      nonce range is completely calculated.
   */
  
  
  #include <float.h>
  #include <limits.h>
  #include <pthread.h>
  #include <stdint.h>
  #include <stdio.h>
  #include <strings.h>
  #include <sys/time.h>
  #include <unistd.h>
  
  #include "config.h"
  
  #ifdef WIN32
  #include <windows.h>
  #endif
  
  #include "compat.h"
  #include "miner.h"
  #include "usbutils.h"
  
  // The serial I/O speed - Linux uses a define 'B115200' in bits/termios.h
  #define ICARUS_IO_SPEED 115200
  
  // The size of a successful nonce read
  #define ICARUS_READ_SIZE 4
  
  #define AMU_PREF_PACKET 256
  #define BLT_PREF_PACKET 512
  #define ICA_PREF_PACKET 256
  
  // Ensure the sizes are correct for the Serial read
  #if (ICARUS_READ_SIZE != 4)
  #error ICARUS_READ_SIZE must be 4
  #endif
  #define ASSERT1(condition) __maybe_unused static char sizeof_uint32_t_must_be_4[(condition)?1:-1]
  ASSERT1(sizeof(uint32_t) == 4);
  
  // TODO: USB? Different calculation? - see usbstats to work it out e.g. 1/2 of normal send time
  //  or even use that number? 1/2
  // #define ICARUS_READ_TIME(baud) ((double)ICARUS_READ_SIZE * (double)8.0 / (double)(baud))
  // maybe 1ms?
  #define ICARUS_READ_TIME(baud) (0.001)
  
  // USB ms timeout to wait - user specified timeouts are multiples of this
  #define ICARUS_WAIT_TIMEOUT 100
  #define ICARUS_CMR2_TIMEOUT 1
  
  // Defined in multiples of ICARUS_WAIT_TIMEOUT
  // Must of course be greater than ICARUS_READ_COUNT_TIMING/ICARUS_WAIT_TIMEOUT
  // There's no need to have this bigger, since the overhead/latency of extra work
  // is pretty small once you get beyond a 10s nonce range time and 10s also
  // means that nothing slower than 429MH/s can go idle so most icarus devices
  // will always mine without idling
  #define ICARUS_READ_TIME_LIMIT_MAX 100
  
  // In timing mode: Default starting value until an estimate can be obtained
  // 5000 ms allows for up to a ~840MH/s device
  #define ICARUS_READ_COUNT_TIMING	5000
  #define ICARUS_READ_COUNT_MIN		ICARUS_WAIT_TIMEOUT
  #define SECTOMS(s)	((int)((s) * 1000))
  // How many ms below the expected completion time to abort work
  // extra in case the last read is delayed
  #define ICARUS_READ_REDUCE	((int)(ICARUS_WAIT_TIMEOUT * 1.5))
  
  // For a standard Icarus REV3 (to 5 places)
  // Since this rounds up a the last digit - it is a slight overestimate
  // Thus the hash rate will be a VERY slight underestimate
  // (by a lot less than the displayed accuracy)
  // Minor inaccuracy of these numbers doesn't affect the work done,
  // only the displayed MH/s
  #define ICARUS_REV3_HASH_TIME 0.0000000026316
  #define LANCELOT_HASH_TIME 0.0000000025000
  #define ASICMINERUSB_HASH_TIME 0.0000000029761
  // TODO: What is it?
  #define CAIRNSMORE1_HASH_TIME 0.0000000027000
  // Per FPGA
  #define CAIRNSMORE2_HASH_TIME 0.0000000066600
  #define NANOSEC 1000000000.0
  
  #define CAIRNSMORE2_INTS 4
  
  // Icarus Rev3 doesn't send a completion message when it finishes
  // the full nonce range, so to avoid being idle we must abort the
  // work (by starting a new work item) shortly before it finishes
  //
  // Thus we need to estimate 2 things:
  //	1) How many hashes were done if the work was aborted
  //	2) How high can the timeout be before the Icarus is idle,
  //		to minimise the number of work items started
  //	We set 2) to 'the calculated estimate' - ICARUS_READ_REDUCE
  //	to ensure the estimate ends before idle
  //
  // The simple calculation used is:
  //	Tn = Total time in seconds to calculate n hashes
  //	Hs = seconds per hash
  //	Xn = number of hashes
  //	W  = code/usb overhead per work
  //
  // Rough but reasonable estimate:
  //	Tn = Hs * Xn + W	(of the form y = mx + b)
  //
  // Thus:
  //	Line of best fit (using least squares)
  //
  //	Hs = (n*Sum(XiTi)-Sum(Xi)*Sum(Ti))/(n*Sum(Xi^2)-Sum(Xi)^2)
  //	W = Sum(Ti)/n - (Hs*Sum(Xi))/n
  //
  // N.B. W is less when aborting work since we aren't waiting for the reply
  //	to be transferred back (ICARUS_READ_TIME)
  //	Calculating the hashes aborted at n seconds is thus just n/Hs
  //	(though this is still a slight overestimate due to code delays)
  //
  
  // Both below must be exceeded to complete a set of data
  // Minimum how long after the first, the last data point must be
  #define HISTORY_SEC 60
  // Minimum how many points a single ICARUS_HISTORY should have
  #define MIN_DATA_COUNT 5
  // The value MIN_DATA_COUNT used is doubled each history until it exceeds:
  #define MAX_MIN_DATA_COUNT 100
  
  static struct timeval history_sec = { HISTORY_SEC, 0 };
  
  // Store the last INFO_HISTORY data sets
  // [0] = current data, not yet ready to be included as an estimate
  // Each new data set throws the last old set off the end thus
  // keeping a ongoing average of recent data
  #define INFO_HISTORY 10
  
  struct ICARUS_HISTORY {
  	struct timeval finish;
  	double sumXiTi;
  	double sumXi;
  	double sumTi;
  	double sumXi2;
  	uint32_t values;
  	uint32_t hash_count_min;
  	uint32_t hash_count_max;
  };
  
  enum timing_mode { MODE_DEFAULT, MODE_SHORT, MODE_LONG, MODE_VALUE };
  
  static const char *MODE_DEFAULT_STR = "default";
  static const char *MODE_SHORT_STR = "short";
  static const char *MODE_SHORT_STREQ = "short=";
  static const char *MODE_LONG_STR = "long";
  static const char *MODE_LONG_STREQ = "long=";
  static const char *MODE_VALUE_STR = "value";
  static const char *MODE_UNKNOWN_STR = "unknown";
  
  struct ICARUS_INFO {
  	enum sub_ident ident;
  	int intinfo;
  
  	// time to calculate the golden_ob
  	uint64_t golden_hashes;
  	struct timeval golden_tv;
  
  	struct ICARUS_HISTORY history[INFO_HISTORY+1];
  	uint32_t min_data_count;
  
  	int timeout;
  
  	// seconds per Hash
  	double Hs;
  	// ms til we abort
  	int read_time;
  	// ms limit for (short=/long=) read_time
  	int read_time_limit;
  
  	enum timing_mode timing_mode;
  	bool do_icarus_timing;
  
  	double fullnonce;
  	int count;
  	double W;
  	uint32_t values;
  	uint64_t hash_count_range;
  
  	// Determine the cost of history processing
  	// (which will only affect W)
  	uint64_t history_count;
  	struct timeval history_time;
  
  	// icarus-options
  	int baud;
  	int work_division;
  	int fpga_count;
  	uint32_t nonce_mask;
  
  	uint8_t cmr2_speed;
  	bool speed_next_work;
  	bool flash_next_work;
  };
  
  #define ICARUS_MIDSTATE_SIZE 32
  #define ICARUS_UNUSED_SIZE 16
  #define ICARUS_WORK_SIZE 12
  
  #define ICARUS_WORK_DATA_OFFSET 64
  
  #define ICARUS_CMR2_SPEED_FACTOR 2.5
  #define ICARUS_CMR2_SPEED_MIN_INT 100
  #define ICARUS_CMR2_SPEED_DEF_INT 180
  #define ICARUS_CMR2_SPEED_MAX_INT 220
  #define CMR2_INT_TO_SPEED(_speed) ((uint8_t)((float)_speed / ICARUS_CMR2_SPEED_FACTOR))
  #define ICARUS_CMR2_SPEED_MIN CMR2_INT_TO_SPEED(ICARUS_CMR2_SPEED_MIN_INT)
  #define ICARUS_CMR2_SPEED_DEF CMR2_INT_TO_SPEED(ICARUS_CMR2_SPEED_DEF_INT)
  #define ICARUS_CMR2_SPEED_MAX CMR2_INT_TO_SPEED(ICARUS_CMR2_SPEED_MAX_INT)
  #define ICARUS_CMR2_SPEED_INC 1
  #define ICARUS_CMR2_SPEED_DEC -1
  #define ICARUS_CMR2_SPEED_FAIL -10
  
  #define ICARUS_CMR2_PREFIX ((uint8_t)0xB7)
  #define ICARUS_CMR2_CMD_SPEED ((uint8_t)0)
  #define ICARUS_CMR2_CMD_FLASH ((uint8_t)1)
  #define ICARUS_CMR2_DATA_FLASH_OFF ((uint8_t)0)
  #define ICARUS_CMR2_DATA_FLASH_ON ((uint8_t)1)
  #define ICARUS_CMR2_CHECK ((uint8_t)0x6D)
  
  struct ICARUS_WORK {
  	uint8_t midstate[ICARUS_MIDSTATE_SIZE];
  	// These 4 bytes are for CMR2 bitstreams that handle MHz adjustment
  	uint8_t check;
  	uint8_t data;
  	uint8_t cmd;
  	uint8_t prefix;
  	uint8_t unused[ICARUS_UNUSED_SIZE];
  	uint8_t work[ICARUS_WORK_SIZE];
  };
  
  #define END_CONDITION 0x0000ffff
  
  // Looking for options in --icarus-timing and --icarus-options:
  //
  // Code increments this each time we start to look at a device
  // However, this means that if other devices are checked by
  // the Icarus code (e.g. Avalon only as at 20130517)
  // they will count in the option offset
  //
  // This, however, is deterministic so that's OK
  //
  // If we were to increment after successfully finding an Icarus
  // that would be random since an Icarus may fail and thus we'd
  // not be able to predict the option order
  //
  // Devices are checked in the order libusb finds them which is ?
  //
  static int option_offset = -1;
  
  /*
  #define ICA_BUFSIZ (0x200)
  
  static void transfer_read(struct cgpu_info *icarus, uint8_t request_type, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, char *buf, int bufsiz, int *amount, enum usb_cmds cmd)
  {
  	int err;
  
  	err = usb_transfer_read(icarus, request_type, bRequest, wValue, wIndex, buf, bufsiz, amount, cmd);
  
  	applog(LOG_DEBUG, "%s: cgid %d %s got err %d",
  			icarus->drv->name, icarus->cgminer_id,
  			usb_cmdname(cmd), err);
  }
  */
  
  static void _transfer(struct cgpu_info *icarus, uint8_t request_type, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, uint32_t *data, int siz, enum usb_cmds cmd)
  {
  	int err;
  
  	err = usb_transfer_data(icarus, request_type, bRequest, wValue, wIndex, data, siz, cmd);
  
  	applog(LOG_DEBUG, "%s: cgid %d %s got err %d",
  			icarus->drv->name, icarus->cgminer_id,
  			usb_cmdname(cmd), err);
  }
  
  #define transfer(icarus, request_type, bRequest, wValue, wIndex, cmd) \
  		_transfer(icarus, request_type, bRequest, wValue, wIndex, NULL, 0, cmd)
  
  static void icarus_initialise(struct cgpu_info *icarus, int baud)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(icarus->device_data);
  	uint16_t wValue, wIndex;
  	enum sub_ident ident;
  	int interface;
  
  	if (icarus->usbinfo.nodev)
  		return;
  
  	usb_set_cps(icarus, baud / 10);
  	usb_enable_cps(icarus);
  
  	interface = _usb_interface(icarus, info->intinfo);
  	ident = usb_ident(icarus);
  
  	switch (ident) {
  		case IDENT_BLT:
  		case IDENT_LLT:
  		case IDENT_CMR1:
  		case IDENT_CMR2:
  			usb_set_pps(icarus, BLT_PREF_PACKET);
  
  			// Reset
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_RESET, FTDI_VALUE_RESET,
  				 interface, C_RESET);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Latency
  			_usb_ftdi_set_latency(icarus, info->intinfo);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Set data control
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_DATA, FTDI_VALUE_DATA_BLT,
  				 interface, C_SETDATA);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// default to BLT/LLT 115200
  			wValue = FTDI_VALUE_BAUD_BLT;
  			wIndex = FTDI_INDEX_BAUD_BLT;
  
  			if (ident == IDENT_CMR1 || ident == IDENT_CMR2) {
  				switch (baud) {
  					case 115200:
  						wValue = FTDI_VALUE_BAUD_CMR_115;
  						wIndex = FTDI_INDEX_BAUD_CMR_115;
  						break;
  					case 57600:
  						wValue = FTDI_VALUE_BAUD_CMR_57;
  						wIndex = FTDI_INDEX_BAUD_CMR_57;
  						break;
  					default:
  						quit(1, "icarus_intialise() invalid baud (%d) for Cairnsmore1", baud);
  						break;
  				}
  			}
  
  			// Set the baud
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_BAUD, wValue,
  				 (wIndex & 0xff00) | interface, C_SETBAUD);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Set Modem Control
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_MODEM, FTDI_VALUE_MODEM,
  				 interface, C_SETMODEM);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Set Flow Control
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_FLOW, FTDI_VALUE_FLOW,
  				 interface, C_SETFLOW);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Clear any sent data
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_RESET, FTDI_VALUE_PURGE_TX,
  				 interface, C_PURGETX);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Clear any received data
  			transfer(icarus, FTDI_TYPE_OUT, FTDI_REQUEST_RESET, FTDI_VALUE_PURGE_RX,
  				 interface, C_PURGERX);
  			break;
  		case IDENT_ICA:
  			usb_set_pps(icarus, ICA_PREF_PACKET);
  
  			// Set Data Control
  			transfer(icarus, PL2303_CTRL_OUT, PL2303_REQUEST_CTRL, PL2303_VALUE_CTRL,
  				 interface, C_SETDATA);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Set Line Control
  			uint32_t ica_data[2] = { PL2303_VALUE_LINE0, PL2303_VALUE_LINE1 };
  			_transfer(icarus, PL2303_CTRL_OUT, PL2303_REQUEST_LINE, PL2303_VALUE_LINE,
  				 interface, &ica_data[0], PL2303_VALUE_LINE_SIZE, C_SETLINE);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Vendor
  			transfer(icarus, PL2303_VENDOR_OUT, PL2303_REQUEST_VENDOR, PL2303_VALUE_VENDOR,
  				 interface, C_VENDOR);
  			break;
  		case IDENT_AMU:
  			usb_set_pps(icarus, AMU_PREF_PACKET);
  
  			// Enable the UART
  			transfer(icarus, CP210X_TYPE_OUT, CP210X_REQUEST_IFC_ENABLE,
  				 CP210X_VALUE_UART_ENABLE,
  				 interface, C_ENABLE_UART);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Set data control
  			transfer(icarus, CP210X_TYPE_OUT, CP210X_REQUEST_DATA, CP210X_VALUE_DATA,
  				 interface, C_SETDATA);
  
  			if (icarus->usbinfo.nodev)
  				return;
  
  			// Set the baud
  			uint32_t data = CP210X_DATA_BAUD;
  			_transfer(icarus, CP210X_TYPE_OUT, CP210X_REQUEST_BAUD, 0,
  				 interface, &data, sizeof(data), C_SETBAUD);
  			break;
  		default:
  			quit(1, "icarus_intialise() called with invalid %s cgid %i ident=%d",
  				icarus->drv->name, icarus->cgminer_id, ident);
  	}
  }
  
  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;
  	}
  }
  
  #define ICA_NONCE_ERROR -1
  #define ICA_NONCE_OK 0
  #define ICA_NONCE_RESTART 1
  #define ICA_NONCE_TIMEOUT 2
  
  static int icarus_get_nonce(struct cgpu_info *icarus, unsigned char *buf, struct timeval *tv_start, struct timeval *tv_finish, struct thr_info *thr, int read_time)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(icarus->device_data);
  	struct timeval read_start, read_finish;
  	int err, amt;
  	int rc = 0, delay;
  	int read_amount = ICARUS_READ_SIZE;
  	bool first = true;
  
  	cgtime(tv_start);
  	while (true) {
  		if (icarus->usbinfo.nodev)
  			return ICA_NONCE_ERROR;
  
  		cgtime(&read_start);
  		err = usb_read_ii_timeout(icarus, info->intinfo,
  					  (char *)buf, read_amount, &amt,
  					  info->timeout, C_GETRESULTS);
  		cgtime(&read_finish);
  		if (err < 0 && err != LIBUSB_ERROR_TIMEOUT) {
  			applog(LOG_ERR, "%s%i: Comms error (rerr=%d amt=%d)",
  					icarus->drv->name, icarus->device_id, err, amt);
  			dev_error(icarus, REASON_DEV_COMMS_ERROR);
  			return ICA_NONCE_ERROR;
  		}
  
  		if (first)
  			copy_time(tv_finish, &read_finish);
  
  		if (amt >= read_amount)
  			return ICA_NONCE_OK;
  
  		rc = SECTOMS(tdiff(&read_finish, tv_start));
  		if (rc >= read_time) {
  			if (amt > 0)
  				applog(LOG_DEBUG, "Icarus Read: Timeout reading for %d ms", rc);
  			else
  				applog(LOG_DEBUG, "Icarus Read: No data for %d ms", rc);
  			return ICA_NONCE_TIMEOUT;
  		}
  
  		if (thr && thr->work_restart) {
  			applog(LOG_DEBUG, "Icarus Read: Work restart at %d ms", rc);
  			return ICA_NONCE_RESTART;
  		}
  
  		if (amt > 0) {
  			buf += amt;
  			read_amount -= amt;
  			first = false;
  		}
  
  		if (info->timeout < ICARUS_WAIT_TIMEOUT) {
  			delay = ICARUS_WAIT_TIMEOUT - rc;
  			if (delay > 0) {
  				cgsleep_ms(delay);
  
  				if (thr && thr->work_restart) {
  					applog(LOG_DEBUG, "Icarus Read: Work restart at %d ms", rc);
  					return ICA_NONCE_RESTART;
  				}
  			}
  		}
  	}
  }
  
  static const char *timing_mode_str(enum timing_mode timing_mode)
  {
  	switch(timing_mode) {
  	case MODE_DEFAULT:
  		return MODE_DEFAULT_STR;
  	case MODE_SHORT:
  		return MODE_SHORT_STR;
  	case MODE_LONG:
  		return MODE_LONG_STR;
  	case MODE_VALUE:
  		return MODE_VALUE_STR;
  	default:
  		return MODE_UNKNOWN_STR;
  	}
  }
  
  static void set_timing_mode(int this_option_offset, struct cgpu_info *icarus)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(icarus->device_data);
  	enum sub_ident ident;
  	double Hs;
  	char buf[BUFSIZ+1];
  	char *ptr, *comma, *eq;
  	size_t max;
  	int i;
  
  	if (opt_icarus_timing == NULL)
  		buf[0] = '\0';
  	else {
  		ptr = opt_icarus_timing;
  		for (i = 0; i < this_option_offset; i++) {
  			comma = strchr(ptr, ',');
  			if (comma == NULL)
  				break;
  			ptr = comma + 1;
  		}
  
  		comma = strchr(ptr, ',');
  		if (comma == NULL)
  			max = strlen(ptr);
  		else
  			max = comma - ptr;
  
  		if (max > BUFSIZ)
  			max = BUFSIZ;
  		strncpy(buf, ptr, max);
  		buf[max] = '\0';
  	}
  
  	ident = usb_ident(icarus);
  	switch (ident) {
  		case IDENT_ICA:
  			info->Hs = ICARUS_REV3_HASH_TIME;
  			break;
  		case IDENT_BLT:
  		case IDENT_LLT:
  			info->Hs = LANCELOT_HASH_TIME;
  			break;
  		case IDENT_AMU:
  			info->Hs = ASICMINERUSB_HASH_TIME;
  			break;
  		case IDENT_CMR1:
  			info->Hs = CAIRNSMORE1_HASH_TIME;
  			break;
  		case IDENT_CMR2:
  			info->Hs = CAIRNSMORE2_HASH_TIME;
  			break;
  		default:
  			quit(1, "Icarus get_options() called with invalid %s ident=%d",
  				icarus->drv->name, ident);
  	}
  
  	info->read_time = 0;
  	info->read_time_limit = 0; // 0 = no limit
  
  	if (strcasecmp(buf, MODE_SHORT_STR) == 0) {
  		// short
  		info->read_time = ICARUS_READ_COUNT_TIMING;
  
  		info->timing_mode = MODE_SHORT;
  		info->do_icarus_timing = true;
  	} else if (strncasecmp(buf, MODE_SHORT_STREQ, strlen(MODE_SHORT_STREQ)) == 0) {
  		// short=limit
  		info->read_time = ICARUS_READ_COUNT_TIMING;
  
  		info->timing_mode = MODE_SHORT;
  		info->do_icarus_timing = true;
  
  		info->read_time_limit = atoi(&buf[strlen(MODE_SHORT_STREQ)]);
  		if (info->read_time_limit < 0)
  			info->read_time_limit = 0;
  		if (info->read_time_limit > ICARUS_READ_TIME_LIMIT_MAX)
  			info->read_time_limit = ICARUS_READ_TIME_LIMIT_MAX;
  	} else if (strcasecmp(buf, MODE_LONG_STR) == 0) {
  		// long
  		info->read_time = ICARUS_READ_COUNT_TIMING;
  
  		info->timing_mode = MODE_LONG;
  		info->do_icarus_timing = true;
  	} else if (strncasecmp(buf, MODE_LONG_STREQ, strlen(MODE_LONG_STREQ)) == 0) {
  		// long=limit
  		info->read_time = ICARUS_READ_COUNT_TIMING;
  
  		info->timing_mode = MODE_LONG;
  		info->do_icarus_timing = true;
  
  		info->read_time_limit = atoi(&buf[strlen(MODE_LONG_STREQ)]);
  		if (info->read_time_limit < 0)
  			info->read_time_limit = 0;
  		if (info->read_time_limit > ICARUS_READ_TIME_LIMIT_MAX)
  			info->read_time_limit = ICARUS_READ_TIME_LIMIT_MAX;
  	} else if ((Hs = atof(buf)) != 0) {
  		// ns[=read_time]
  		info->Hs = Hs / NANOSEC;
  		info->fullnonce = info->Hs * (((double)0xffffffff) + 1);
  
  		if ((eq = strchr(buf, '=')) != NULL)
  			info->read_time = atoi(eq+1) * ICARUS_WAIT_TIMEOUT;
  
  		if (info->read_time < ICARUS_READ_COUNT_MIN)
  			info->read_time = SECTOMS(info->fullnonce) - ICARUS_READ_REDUCE;
  
  		if (unlikely(info->read_time < ICARUS_READ_COUNT_MIN))
  			info->read_time = ICARUS_READ_COUNT_MIN;
  
  		info->timing_mode = MODE_VALUE;
  		info->do_icarus_timing = false;
  	} else {
  		// Anything else in buf just uses DEFAULT mode
  
  		info->fullnonce = info->Hs * (((double)0xffffffff) + 1);
  
  		if ((eq = strchr(buf, '=')) != NULL)
  			info->read_time = atoi(eq+1) * ICARUS_WAIT_TIMEOUT;
  
  		if (info->read_time < ICARUS_READ_COUNT_MIN)
  			info->read_time = SECTOMS(info->fullnonce) - ICARUS_READ_REDUCE;
  
  		if (unlikely(info->read_time < ICARUS_READ_COUNT_MIN))
  			info->read_time = ICARUS_READ_COUNT_MIN;
  
  		info->timing_mode = MODE_DEFAULT;
  		info->do_icarus_timing = false;
  	}
  
  	info->min_data_count = MIN_DATA_COUNT;
  
  	// All values are in multiples of ICARUS_WAIT_TIMEOUT
  	info->read_time_limit *= ICARUS_WAIT_TIMEOUT;
  
  	applog(LOG_DEBUG, "%s: cgid %d Init: mode=%s read_time=%dms limit=%dms Hs=%e",
  			icarus->drv->name, icarus->cgminer_id,
  			timing_mode_str(info->timing_mode),
  			info->read_time, info->read_time_limit, info->Hs);
  }
  
  static uint32_t mask(int work_division)
  {
  	uint32_t nonce_mask = 0x7fffffff;
  
  	// yes we can calculate these, but this way it's easy to see what they are
  	switch (work_division) {
  	case 1:
  		nonce_mask = 0xffffffff;
  		break;
  	case 2:
  		nonce_mask = 0x7fffffff;
  		break;
  	case 4:
  		nonce_mask = 0x3fffffff;
  		break;
  	case 8:
  		nonce_mask = 0x1fffffff;
  		break;
  	default:
  		quit(1, "Invalid2 icarus-options for work_division (%d) must be 1, 2, 4 or 8", work_division);
  	}
  
  	return nonce_mask;
  }
  
  static void get_options(int this_option_offset, struct cgpu_info *icarus, int *baud, int *work_division, int *fpga_count)
  {
  	char buf[BUFSIZ+1];
  	char *ptr, *comma, *colon, *colon2;
  	enum sub_ident ident;
  	size_t max;
  	int i, tmp;
  
  	if (opt_icarus_options == NULL)
  		buf[0] = '\0';
  	else {
  		ptr = opt_icarus_options;
  		for (i = 0; i < this_option_offset; i++) {
  			comma = strchr(ptr, ',');
  			if (comma == NULL)
  				break;
  			ptr = comma + 1;
  		}
  
  		comma = strchr(ptr, ',');
  		if (comma == NULL)
  			max = strlen(ptr);
  		else
  			max = comma - ptr;
  
  		if (max > BUFSIZ)
  			max = BUFSIZ;
  		strncpy(buf, ptr, max);
  		buf[max] = '\0';
  	}
  
  	ident = usb_ident(icarus);
  	switch (ident) {
  		case IDENT_ICA:
  		case IDENT_BLT:
  		case IDENT_LLT:
  			*baud = ICARUS_IO_SPEED;
  			*work_division = 2;
  			*fpga_count = 2;
  			break;
  		case IDENT_AMU:
  			*baud = ICARUS_IO_SPEED;
  			*work_division = 1;
  			*fpga_count = 1;
  			break;
  		case IDENT_CMR1:
  			*baud = ICARUS_IO_SPEED;
  			*work_division = 2;
  			*fpga_count = 2;
  			break;
  		case IDENT_CMR2:
  			*baud = ICARUS_IO_SPEED;
  			*work_division = 1;
  			*fpga_count = 1;
  			break;
  		default:
  			quit(1, "Icarus get_options() called with invalid %s ident=%d",
  				icarus->drv->name, ident);
  	}
  
  	if (*buf) {
  		colon = strchr(buf, ':');
  		if (colon)
  			*(colon++) = '\0';
  
  		if (*buf) {
  			tmp = atoi(buf);
  			switch (tmp) {
  			case 115200:
  				*baud = 115200;
  				break;
  			case 57600:
  				*baud = 57600;
  				break;
  			default:
  				quit(1, "Invalid icarus-options for baud (%s) must be 115200 or 57600", buf);
  			}
  		}
  
  		if (colon && *colon) {
  			colon2 = strchr(colon, ':');
  			if (colon2)
  				*(colon2++) = '\0';
  
  			if (*colon) {
  				tmp = atoi(colon);
  				if (tmp == 1 || tmp == 2 || tmp == 4 || tmp == 8) {
  					*work_division = tmp;
  					*fpga_count = tmp;	// default to the same
  				} else {
  					quit(1, "Invalid icarus-options for work_division (%s) must be 1, 2, 4 or 8", colon);
  				}
  			}
  
  			if (colon2 && *colon2) {
  				tmp = atoi(colon2);
  				if (tmp > 0 && tmp <= *work_division)
  					*fpga_count = tmp;
  				else {
  					quit(1, "Invalid icarus-options for fpga_count (%s) must be >0 and <=work_division (%d)", colon2, *work_division);
  				}
  			}
  		}
  	}
  }
  
  static bool icarus_detect_one(struct libusb_device *dev, struct usb_find_devices *found)
  {
  	int this_option_offset = ++option_offset;
  	struct ICARUS_INFO *info;
  	struct timeval tv_start, tv_finish;
  
  	// Block 171874 nonce = (0xa2870100) = 0x000187a2
  	// N.B. golden_ob MUST take less time to calculate
  	//	than the timeout set in icarus_open()
  	//	This one takes ~0.53ms on Rev3 Icarus
  	const char golden_ob[] =
  		"4679ba4ec99876bf4bfe086082b40025"
  		"4df6c356451471139a3afa71e48f544a"
  		"00000000000000000000000000000000"
  		"0000000087320b1a1426674f2fa722ce";
  
  	const char golden_nonce[] = "000187a2";
  	const uint32_t golden_nonce_val = 0x000187a2;
  	unsigned char nonce_bin[ICARUS_READ_SIZE];
  	struct ICARUS_WORK workdata;
  	char *nonce_hex;
  	int baud, uninitialised_var(work_division), uninitialised_var(fpga_count);
  	struct cgpu_info *icarus;
  	int ret, err, amount, tries, i;
  	bool ok;
  	bool cmr2_ok[CAIRNSMORE2_INTS];
  	int cmr2_count;
  
  	if ((sizeof(workdata) << 1) != (sizeof(golden_ob) - 1))
  		quithere(1, "Data and golden_ob sizes don't match");
  
  	icarus = usb_alloc_cgpu(&icarus_drv, 1);
  
  	if (!usb_init(icarus, dev, found))
  		goto shin;
  
  	usb_buffer_enable(icarus);
  
  	get_options(this_option_offset, icarus, &baud, &work_division, &fpga_count);
  
  	hex2bin((void *)(&workdata), golden_ob, sizeof(workdata));
  
  	info = (struct ICARUS_INFO *)calloc(1, sizeof(struct ICARUS_INFO));
  	if (unlikely(!info))
  		quit(1, "Failed to malloc ICARUS_INFO");
  	icarus->device_data = (void *)info;
  
  	info->ident = usb_ident(icarus);
  	switch (info->ident) {
  		case IDENT_ICA:
  		case IDENT_BLT:
  		case IDENT_LLT:
  		case IDENT_AMU:
  		case IDENT_CMR1:
  			info->timeout = ICARUS_WAIT_TIMEOUT;
  			break;
  		case IDENT_CMR2:
  			if (found->intinfo_count != CAIRNSMORE2_INTS) {
  				quithere(1, "CMR2 Interface count (%d) isn't expected: %d",
  						found->intinfo_count,
  						CAIRNSMORE2_INTS);
  			}
  			info->timeout = ICARUS_CMR2_TIMEOUT;
  			cmr2_count = 0;
  			for (i = 0; i < CAIRNSMORE2_INTS; i++)
  				cmr2_ok[i] = false;
  			break;
  		default:
  			quit(1, "%s icarus_detect_one() invalid %s ident=%d",
  				icarus->drv->dname, icarus->drv->dname, info->ident);
  	}
  
  // For CMR2 test each USB Interface
  
  cmr2_retry:
  
  	tries = 2;
  	ok = false;
  	while (!ok && tries-- > 0) {
  		icarus_initialise(icarus, baud);
  
  		err = usb_write_ii(icarus, info->intinfo,
  				   (char *)(&workdata), sizeof(workdata), &amount, C_SENDWORK);
  
  		if (err != LIBUSB_SUCCESS || amount != sizeof(workdata))
  			continue;
  
  		memset(nonce_bin, 0, sizeof(nonce_bin));
  		ret = icarus_get_nonce(icarus, nonce_bin, &tv_start, &tv_finish, NULL, 100);
  		if (ret != ICA_NONCE_OK)
  			continue;
  
  		nonce_hex = bin2hex(nonce_bin, sizeof(nonce_bin));
  		if (strncmp(nonce_hex, golden_nonce, 8) == 0)
  			ok = true;
  		else {
  			if (tries < 0 && info->ident != IDENT_CMR2) {
  				applog(LOG_ERR,
  					"Icarus Detect: "
  					"Test failed at %s: get %s, should: %s",
  					icarus->device_path, nonce_hex, golden_nonce);
  			}
  		}
  		free(nonce_hex);
  	}
  
  	if (!ok) {
  		if (info->ident != IDENT_CMR2)
  			goto unshin;
  
  		if (info->intinfo < CAIRNSMORE2_INTS-1) {
  			info->intinfo++;
  			goto cmr2_retry;
  		}
  	} else {
  		if (info->ident == IDENT_CMR2) {
  			applog(LOG_DEBUG,
  				"Icarus Detect: "
  				"Test succeeded at %s i%d: got %s",
  					icarus->device_path, info->intinfo, golden_nonce);
  
  			cmr2_ok[info->intinfo] = true;
  			cmr2_count++;
  			if (info->intinfo < CAIRNSMORE2_INTS-1) {
  				info->intinfo++;
  				goto cmr2_retry;
  			}
  		}
  	}
  
  	if (info->ident == IDENT_CMR2) {
  		if (cmr2_count == 0) {
  			applog(LOG_ERR,
  				"Icarus Detect: Test failed at %s: for all %d CMR2 Interfaces",
  				icarus->device_path, CAIRNSMORE2_INTS);
  			goto unshin;
  		}
  
  		// set the interface to the first one that succeeded
  		for (i = 0; i < CAIRNSMORE2_INTS; i++)
  			if (cmr2_ok[i]) {
  				info->intinfo = i;
  				break;
  			}
  	} else {
  		applog(LOG_DEBUG,
  			"Icarus Detect: "
  			"Test succeeded at %s: got %s",
  				icarus->device_path, golden_nonce);
  	}
  
  	/* We have a real Icarus! */
  	if (!add_cgpu(icarus))
  		goto unshin;
  
  	update_usb_stats(icarus);
  
  	applog(LOG_INFO, "%s%d: Found at %s",
  		icarus->drv->name, icarus->device_id, icarus->device_path);
  
  	if (info->ident == IDENT_CMR2) {
  		applog(LOG_INFO, "%s%d: with %d Interface%s",
  				icarus->drv->name, icarus->device_id,
  				cmr2_count, cmr2_count > 1 ? "s" : "");
  
  		// Assume 1 or 2 are running FPGA pairs
  		if (cmr2_count < 3) {
  			work_division = fpga_count = 2;
  			info->Hs /= 2;
  		}
  	}
  
  	applog(LOG_DEBUG, "%s%d: Init baud=%d work_division=%d fpga_count=%d",
  		icarus->drv->name, icarus->device_id, baud, work_division, fpga_count);
  
  	info->baud = baud;
  	info->work_division = work_division;
  	info->fpga_count = fpga_count;
  	info->nonce_mask = mask(work_division);
  
  	info->golden_hashes = (golden_nonce_val & info->nonce_mask) * fpga_count;
  	timersub(&tv_finish, &tv_start, &(info->golden_tv));
  
  	set_timing_mode(this_option_offset, icarus);
  	
  	if (info->ident == IDENT_CMR2) {
  		int i;
  		for (i = info->intinfo + 1; i < icarus->usbdev->found->intinfo_count; i++) {
  			struct cgpu_info *cgtmp;
  			struct ICARUS_INFO *intmp;
  
  			if (!cmr2_ok[i])
  				continue;
  
  			cgtmp = usb_copy_cgpu(icarus);
  			if (!cgtmp) {
  				applog(LOG_ERR, "%s%d: Init failed initinfo %d",
  						icarus->drv->name, icarus->device_id, i);
  				continue;
  			}
  
  			cgtmp->usbinfo.usbstat = USB_NOSTAT;
  
  			intmp = (struct ICARUS_INFO *)malloc(sizeof(struct ICARUS_INFO));
  			if (unlikely(!intmp))
  				quit(1, "Failed2 to malloc ICARUS_INFO");
  
  			cgtmp->device_data = (void *)intmp;
  
  			// Initialise everything to match
  			memcpy(intmp, info, sizeof(struct ICARUS_INFO));
  
  			intmp->intinfo = i;
  
  			icarus_initialise(cgtmp, baud);
  
  			if (!add_cgpu(cgtmp)) {
  				usb_uninit(cgtmp);
  				free(intmp);
  				continue;
  			}
  
  			update_usb_stats(cgtmp);
  		}
  	}
  
  	return true;
  
  unshin:
  
  	usb_uninit(icarus);
  	free(info);
  	icarus->device_data = NULL;
  
  shin:
  
  	icarus = usb_free_cgpu(icarus);
  
  	return false;
  }
  
  static void icarus_detect(bool __maybe_unused hotplug)
  {
  	usb_detect(&icarus_drv, icarus_detect_one);
  }
  
  static bool icarus_prepare(__maybe_unused struct thr_info *thr)
  {
  //	struct cgpu_info *icarus = thr->cgpu;
  
  	return true;
  }
  
  static void cmr2_command(struct cgpu_info *icarus, uint8_t cmd, uint8_t data)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(icarus->device_data);
  	struct ICARUS_WORK workdata;
  	int amount;
  
  	memset((void *)(&workdata), 0, sizeof(workdata));
  
  	workdata.prefix = ICARUS_CMR2_PREFIX;
  	workdata.cmd = cmd;
  	workdata.data = data;
  	workdata.check = workdata.data ^ workdata.cmd ^ workdata.prefix ^ ICARUS_CMR2_CHECK;
  
  	usb_write_ii(icarus, info->intinfo, (char *)(&workdata), sizeof(workdata), &amount, C_SENDWORK);
  }
  
  static void cmr2_commands(struct cgpu_info *icarus)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(icarus->device_data);
  
  	if (info->speed_next_work) {
  		info->speed_next_work = false;
  		cmr2_command(icarus, ICARUS_CMR2_CMD_SPEED, info->cmr2_speed);
  		return;
  	}
  
  	if (info->flash_next_work) {
  		info->flash_next_work = false;
  		cmr2_command(icarus, ICARUS_CMR2_CMD_FLASH, ICARUS_CMR2_DATA_FLASH_ON);
  		cgsleep_ms(250);
  		cmr2_command(icarus, ICARUS_CMR2_CMD_FLASH, ICARUS_CMR2_DATA_FLASH_OFF);
  		cgsleep_ms(250);
  		cmr2_command(icarus, ICARUS_CMR2_CMD_FLASH, ICARUS_CMR2_DATA_FLASH_ON);
  		cgsleep_ms(250);
  		cmr2_command(icarus, ICARUS_CMR2_CMD_FLASH, ICARUS_CMR2_DATA_FLASH_OFF);
  		return;
  	}
  }
  
  static int64_t icarus_scanwork(struct thr_info *thr)
  {
  	struct cgpu_info *icarus = thr->cgpu;
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(icarus->device_data);
  	int ret, err, amount;
  	unsigned char nonce_bin[ICARUS_READ_SIZE];
  	struct ICARUS_WORK workdata;
  	char *ob_hex;
  	uint32_t nonce;
  	int64_t hash_count = 0;
  	struct timeval tv_start, tv_finish, elapsed;
  	struct timeval tv_history_start, tv_history_finish;
  	double Ti, Xi;
  	int curr_hw_errors, i;
  	bool was_hw_error;
  	struct work *work;
  
  	struct ICARUS_HISTORY *history0, *history;
  	int count;
  	double Hs, W, fullnonce;
  	int read_time;
  	bool limited;
  	int64_t estimate_hashes;
  	uint32_t values;
  	int64_t hash_count_range;
  
  	// Device is gone
  	if (icarus->usbinfo.nodev)
  		return -1;
  
  	elapsed.tv_sec = elapsed.tv_usec = 0;
  
  	work = get_work(thr, thr->id);
  	memset((void *)(&workdata), 0, sizeof(workdata));
  	memcpy(&(workdata.midstate), work->midstate, ICARUS_MIDSTATE_SIZE);
  	memcpy(&(workdata.work), work->data + ICARUS_WORK_DATA_OFFSET, ICARUS_WORK_SIZE);
  	rev((void *)(&(workdata.midstate)), ICARUS_MIDSTATE_SIZE);
  	rev((void *)(&(workdata.work)), ICARUS_WORK_SIZE);
  
  	if (info->speed_next_work || info->flash_next_work)
  		cmr2_commands(icarus);
  
  	// We only want results for the work we are about to send
  	usb_buffer_clear(icarus);
  
  	err = usb_write_ii(icarus, info->intinfo, (char *)(&workdata), sizeof(workdata), &amount, C_SENDWORK);
  	if (err < 0 || amount != sizeof(workdata)) {
  		applog(LOG_ERR, "%s%i: Comms error (werr=%d amt=%d)",
  				icarus->drv->name, icarus->device_id, err, amount);
  		dev_error(icarus, REASON_DEV_COMMS_ERROR);
  		icarus_initialise(icarus, info->baud);
  		goto out;
  	}
  
  	if (opt_debug) {
  		ob_hex = bin2hex((void *)(&workdata), sizeof(workdata));
  		applog(LOG_DEBUG, "%s%d: sent %s",
  			icarus->drv->name, icarus->device_id, ob_hex);
  		free(ob_hex);
  	}
  
  	/* Icarus will return 4 bytes (ICARUS_READ_SIZE) nonces or nothing */
  	memset(nonce_bin, 0, sizeof(nonce_bin));
  	ret = icarus_get_nonce(icarus, nonce_bin, &tv_start, &tv_finish, thr, info->read_time);
  	if (ret == ICA_NONCE_ERROR)
  		goto out;
  
  	work->blk.nonce = 0xffffffff;
  
  	// aborted before becoming idle, get new work
  	if (ret == ICA_NONCE_TIMEOUT || ret == ICA_NONCE_RESTART) {
  		timersub(&tv_finish, &tv_start, &elapsed);
  
  		// ONLY up to just when it aborted
  		// We didn't read a reply so we don't subtract ICARUS_READ_TIME
  		estimate_hashes = ((double)(elapsed.tv_sec)
  					+ ((double)(elapsed.tv_usec))/((double)1000000)) / info->Hs;
  
  		// If some Serial-USB delay allowed the full nonce range to
  		// complete it can't have done more than a full nonce
  		if (unlikely(estimate_hashes > 0xffffffff))
  			estimate_hashes = 0xffffffff;
  
  		applog(LOG_DEBUG, "%s%d: no nonce = 0x%08lX hashes (%ld.%06lds)",
  				icarus->drv->name, icarus->device_id,
  				(long unsigned int)estimate_hashes,
  				elapsed.tv_sec, elapsed.tv_usec);
  
  		hash_count = estimate_hashes;
  		goto out;
  	}
  
  	memcpy((char *)&nonce, nonce_bin, sizeof(nonce_bin));
  	nonce = htobe32(nonce);
  	curr_hw_errors = icarus->hw_errors;
  	submit_nonce(thr, work, nonce);
  	was_hw_error = (curr_hw_errors > icarus->hw_errors);
  
  	hash_count = (nonce & info->nonce_mask);
  	hash_count++;
  	hash_count *= info->fpga_count;
  
  #if 0
  	// This appears to only return zero nonce values
  	if (usb_buffer_size(icarus) > 3) {
  		memcpy((char *)&nonce, icarus->usbdev->buffer, sizeof(nonce_bin));
  		nonce = htobe32(nonce);
  		applog(LOG_WARNING, "%s%d: attempting to submit 2nd nonce = 0x%08lX",
  				icarus->drv->name, icarus->device_id,
  				(long unsigned int)nonce);
  		curr_hw_errors = icarus->hw_errors;
  		submit_nonce(thr, work, nonce);
  		was_hw_error = (curr_hw_errors > icarus->hw_errors);
  	}
  #endif
  
  	if (opt_debug || info->do_icarus_timing)
  		timersub(&tv_finish, &tv_start, &elapsed);
  
  	applog(LOG_DEBUG, "%s%d: nonce = 0x%08x = 0x%08lX hashes (%ld.%06lds)",
  			icarus->drv->name, icarus->device_id,
  			nonce, (long unsigned int)hash_count,
  			elapsed.tv_sec, elapsed.tv_usec);
  
  	// Ignore possible end condition values ... and hw errors
  	// TODO: set limitations on calculated values depending on the device
  	// to avoid crap values caused by CPU/Task Switching/Swapping/etc
  	if (info->do_icarus_timing
  	&&  !was_hw_error
  	&&  ((nonce & info->nonce_mask) > END_CONDITION)
  	&&  ((nonce & info->nonce_mask) < (info->nonce_mask & ~END_CONDITION))) {
  		cgtime(&tv_history_start);
  
  		history0 = &(info->history[0]);
  
  		if (history0->values == 0)
  			timeradd(&tv_start, &history_sec, &(history0->finish));
  
  		Ti = (double)(elapsed.tv_sec)
  			+ ((double)(elapsed.tv_usec))/((double)1000000)
  			- ((double)ICARUS_READ_TIME(info->baud));
  		Xi = (double)hash_count;
  		history0->sumXiTi += Xi * Ti;
  		history0->sumXi += Xi;
  		history0->sumTi += Ti;
  		history0->sumXi2 += Xi * Xi;
  
  		history0->values++;
  
  		if (history0->hash_count_max < hash_count)
  			history0->hash_count_max = hash_count;
  		if (history0->hash_count_min > hash_count || history0->hash_count_min == 0)
  			history0->hash_count_min = hash_count;
  
  		if (history0->values >= info->min_data_count
  		&&  timercmp(&tv_start, &(history0->finish), >)) {
  			for (i = INFO_HISTORY; i > 0; i--)
  				memcpy(&(info->history[i]),
  					&(info->history[i-1]),
  					sizeof(struct ICARUS_HISTORY));
  
  			// Initialise history0 to zero for summary calculation
  			memset(history0, 0, sizeof(struct ICARUS_HISTORY));
  
  			// We just completed a history data set
  			// So now recalc read_time based on the whole history thus we will
  			// initially get more accurate until it completes INFO_HISTORY
  			// total data sets
  			count = 0;
  			for (i = 1 ; i <= INFO_HISTORY; i++) {
  				history = &(info->history[i]);
  				if (history->values >= MIN_DATA_COUNT) {
  					count++;
  
  					history0->sumXiTi += history->sumXiTi;
  					history0->sumXi += history->sumXi;
  					history0->sumTi += history->sumTi;
  					history0->sumXi2 += history->sumXi2;
  					history0->values += history->values;
  
  					if (history0->hash_count_max < history->hash_count_max)
  						history0->hash_count_max = history->hash_count_max;
  					if (history0->hash_count_min > history->hash_count_min || history0->hash_count_min == 0)
  						history0->hash_count_min = history->hash_count_min;
  				}
  			}
  
  			// All history data
  			Hs = (history0->values*history0->sumXiTi - history0->sumXi*history0->sumTi)
  				/ (history0->values*history0->sumXi2 - history0->sumXi*history0->sumXi);
  			W = history0->sumTi/history0->values - Hs*history0->sumXi/history0->values;
  			hash_count_range = history0->hash_count_max - history0->hash_count_min;
  			values = history0->values;
  			
  			// Initialise history0 to zero for next data set
  			memset(history0, 0, sizeof(struct ICARUS_HISTORY));
  
  			fullnonce = W + Hs * (((double)0xffffffff) + 1);
  			read_time = SECTOMS(fullnonce) - ICARUS_READ_REDUCE;
  			if (info->read_time_limit > 0 && read_time > info->read_time_limit) {
  				read_time = info->read_time_limit;
  				limited = true;
  			} else
  				limited = false;
  
  			info->Hs = Hs;
  			info->read_time = read_time;
  
  			info->fullnonce = fullnonce;
  			info->count = count;
  			info->W = W;
  			info->values = values;
  			info->hash_count_range = hash_count_range;
  
  			if (info->min_data_count < MAX_MIN_DATA_COUNT)
  				info->min_data_count *= 2;
  			else if (info->timing_mode == MODE_SHORT)
  				info->do_icarus_timing = false;
  
  			applog(LOG_WARNING, "%s%d Re-estimate: Hs=%e W=%e read_time=%dms%s fullnonce=%.3fs",
  					icarus->drv->name, icarus->device_id, Hs, W, read_time,
  					limited ? " (limited)" : "", fullnonce);
  		}
  		info->history_count++;
  		cgtime(&tv_history_finish);
  
  		timersub(&tv_history_finish, &tv_history_start, &tv_history_finish);
  		timeradd(&tv_history_finish, &(info->history_time), &(info->history_time));
  	}
  out:
  	free_work(work);
  	return hash_count;
  }
  
  static struct api_data *icarus_api_stats(struct cgpu_info *cgpu)
  {
  	struct api_data *root = NULL;
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(cgpu->device_data);
  
  	// Warning, access to these is not locked - but we don't really
  	// care since hashing performance is way more important than
  	// locking access to displaying API debug 'stats'
  	// If locking becomes an issue for any of them, use copy_data=true also
  	root = api_add_int(root, "read_time", &(info->read_time), false);
  	root = api_add_int(root, "read_time_limit", &(info->read_time_limit), false);
  	root = api_add_double(root, "fullnonce", &(info->fullnonce), false);
  	root = api_add_int(root, "count", &(info->count), false);
  	root = api_add_hs(root, "Hs", &(info->Hs), false);
  	root = api_add_double(root, "W", &(info->W), false);
  	root = api_add_uint(root, "total_values", &(info->values), false);
  	root = api_add_uint64(root, "range", &(info->hash_count_range), false);
  	root = api_add_uint64(root, "history_count", &(info->history_count), false);
  	root = api_add_timeval(root, "history_time", &(info->history_time), false);
  	root = api_add_uint(root, "min_data_count", &(info->min_data_count), false);
  	root = api_add_uint(root, "timing_values", &(info->history[0].values), false);
  	root = api_add_const(root, "timing_mode", timing_mode_str(info->timing_mode), false);
  	root = api_add_bool(root, "is_timing", &(info->do_icarus_timing), false);
  	root = api_add_int(root, "baud", &(info->baud), false);
  	root = api_add_int(root, "work_division", &(info->work_division), false);
  	root = api_add_int(root, "fpga_count", &(info->fpga_count), false);
  
  	return root;
  }
  
  static void icarus_statline_before(char *buf, size_t bufsiz, struct cgpu_info *cgpu)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(cgpu->device_data);
  
  	if (info->ident == IDENT_CMR2 && info->cmr2_speed > 0)
  		tailsprintf(buf, bufsiz, "%5.1fMhz", (float)(info->cmr2_speed) * ICARUS_CMR2_SPEED_FACTOR);
  	else
  		tailsprintf(buf, bufsiz, "        ");
  
  	tailsprintf(buf, bufsiz, "        | ");
  }
  
  static void icarus_shutdown(__maybe_unused struct thr_info *thr)
  {
  	// TODO: ?
  }
  
  static void icarus_identify(struct cgpu_info *cgpu)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(cgpu->device_data);
  
  	if (info->ident == IDENT_CMR2)
  		info->flash_next_work = true;
  }
  
  static char *icarus_set(struct cgpu_info *cgpu, char *option, char *setting, char *replybuf)
  {
  	struct ICARUS_INFO *info = (struct ICARUS_INFO *)(cgpu->device_data);
  	int val;
  
  	if (info->ident != IDENT_CMR2) {
  		strcpy(replybuf, "no set options available");
  		return replybuf;
  	}
  
  	if (strcasecmp(option, "help") == 0) {
  		sprintf(replybuf, "clock: range %d-%d",
  				  ICARUS_CMR2_SPEED_MIN_INT, ICARUS_CMR2_SPEED_MAX_INT);
  		return replybuf;
  	}
  
  	if (strcasecmp(option, "clock") == 0) {
  		if (!setting || !*setting) {
  			sprintf(replybuf, "missing clock setting");
  			return replybuf;
  		}
  
  		val = atoi(setting);
  		if (val < ICARUS_CMR2_SPEED_MIN_INT || val > ICARUS_CMR2_SPEED_MAX_INT) {
  			sprintf(replybuf, "invalid clock: '%s' valid range %d-%d",
  					  setting,
  					  ICARUS_CMR2_SPEED_MIN_INT,
  					  ICARUS_CMR2_SPEED_MAX_INT);
  		}
  
  		info->cmr2_speed = CMR2_INT_TO_SPEED(val);
  		info->speed_next_work = true;
  
  		return NULL;
  	}
  
  	sprintf(replybuf, "Unknown option: %s", option);
  	return replybuf;
  }
  
  struct device_drv icarus_drv = {
  	.drv_id = DRIVER_icarus,
  	.dname = "Icarus",
  	.name = "ICA",
  	.drv_detect = icarus_detect,
  	.hash_work = &hash_driver_work,
  	.get_api_stats = icarus_api_stats,
  	.get_statline_before = icarus_statline_before,
  	.set_device = icarus_set,
  	.identify_device = icarus_identify,
  	.thread_prepare = icarus_prepare,
  	.scanwork = icarus_scanwork,
  	.thread_shutdown = icarus_shutdown,
  };
  

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