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driver-bmsc.c
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driver-bmsc.c
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/*
* Copyright 2012-2013 Andrew Smith
* Copyright 2013 Con Kolivas <[email protected]>
* Copyright 2013 Lingchao Xu <[email protected]>
*
* 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 AntMiner U1 of Bmsc.
* Operation:
* No detection implement.
* Input: 64B = 32B midstate + 20B fill bytes + last 12 bytes of block head.
* Return: send back 40bits immediately when Bmsc 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. Bmsc will start calculate when you push a work to them, even they
* are busy.
* 2. Bmsc will stop work when: a valid nonce has been found or 40 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 BMSC_IO_SPEED 115200
#define BMSC_NONCE_ARRAY_SIZE 6
// The size of a successful nonce read
#define BMSC_READ_SIZE 5
// Ensure the sizes are correct for the Serial read
#if (BMSC_READ_SIZE != 5)
#error BMSC_READ_SIZE must be 5
#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 BMSC_READ_TIME(baud) ((double)BMSC_READ_SIZE * (double)8.0 / (double)(baud))
// maybe 1ms?
#define BMSC_READ_TIME(baud) (0.001)
// USB ms timeout to wait - user specified timeouts are multiples of this
#define BMSC_WAIT_TIMEOUT 100
#define BMSC_CMR2_TIMEOUT 1
#define BMSC_READ_BUF_LEN 8192
// Defined in multiples of BMSC_WAIT_TIMEOUT
// Must of course be greater than BMSC_READ_COUNT_TIMING/BMSC_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 bmsc devices
// will always mine without idling
#define BMSC_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 BMSC_READ_COUNT_TIMING 5000
#define BMSC_READ_COUNT_MIN BMSC_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 BMSC_READ_REDUCE ((int)(BMSC_WAIT_TIMEOUT * 1.5))
// For a standard Bmsc (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 BMSC_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
// Bmsc 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 Bmsc is idle,
// to minimise the number of work items started
// We set 2) to 'the calculated estimate' - BMSC_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 (BMSC_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 BMSC_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
#define BMSC_WORK_QUEUE_NUM 36
struct BMSC_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 BMSC_INFO {
enum sub_ident ident;
int intinfo;
// time to calculate the golden_ob
uint64_t golden_hashes;
struct timeval golden_tv;
struct BMSC_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_bmsc_timing;
bool start;
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;
// bmsc-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;
struct work * work_queue[BMSC_WORK_QUEUE_NUM];
int work_queue_index;
unsigned char nonce_bin[BMSC_NONCE_ARRAY_SIZE][BMSC_READ_SIZE+1];
int nonce_index;
};
#define BMSC_MIDSTATE_SIZE 32
#define BMSC_UNUSED_SIZE 15
#define BMSC_WORK_SIZE 12
#define BMSC_WORK_DATA_OFFSET 64
#define BMSC_CMR2_SPEED_FACTOR 2.5
#define BMSC_CMR2_SPEED_MIN_INT 100
#define BMSC_CMR2_SPEED_DEF_INT 180
#define BMSC_CMR2_SPEED_MAX_INT 220
#define CMR2_INT_TO_SPEED(_speed) ((uint8_t)((float)_speed / BMSC_CMR2_SPEED_FACTOR))
#define BMSC_CMR2_SPEED_MIN CMR2_INT_TO_SPEED(BMSC_CMR2_SPEED_MIN_INT)
#define BMSC_CMR2_SPEED_DEF CMR2_INT_TO_SPEED(BMSC_CMR2_SPEED_DEF_INT)
#define BMSC_CMR2_SPEED_MAX CMR2_INT_TO_SPEED(BMSC_CMR2_SPEED_MAX_INT)
#define BMSC_CMR2_SPEED_INC 1
#define BMSC_CMR2_SPEED_DEC -1
#define BMSC_CMR2_SPEED_FAIL -10
#define BMSC_CMR2_PREFIX ((uint8_t)0xB7)
#define BMSC_CMR2_CMD_SPEED ((uint8_t)0)
#define BMSC_CMR2_CMD_FLASH ((uint8_t)1)
#define BMSC_CMR2_DATA_FLASH_OFF ((uint8_t)0)
#define BMSC_CMR2_DATA_FLASH_ON ((uint8_t)1)
#define BMSC_CMR2_CHECK ((uint8_t)0x6D)
struct BMSC_WORK {
uint8_t midstate[BMSC_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[BMSC_UNUSED_SIZE];
uint8_t workid;
uint8_t work[BMSC_WORK_SIZE];
};
#define END_CONDITION 0x0000ffff
// Looking for options in --bmsc-timing and --bmsc-options:
//
// Code increments this each time we start to look at a device
// However, this means that if other devices are checked by
// the Bmsc 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 Bmsc
// that would be random since an Bmsc 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;
unsigned char CRC5(unsigned char *ptr, unsigned char len)
{
unsigned char i, j, k;
unsigned char crc = 0x1f;
unsigned char crcin[5] = {1, 1, 1, 1, 1};
unsigned char crcout[5] = {1, 1, 1, 1, 1};
unsigned char din = 0;
j = 0x80;
k = 0;
for (i = 0; i < len; i++)
{
if (*ptr & j) {
din = 1;
} else {
din = 0;
}
crcout[0] = crcin[4] ^ din;
crcout[1] = crcin[0];
crcout[2] = crcin[1] ^ crcin[4] ^ din;
crcout[3] = crcin[2];
crcout[4] = crcin[3];
j = j >> 1;
k++;
if (k == 8)
{
j = 0x80;
k = 0;
ptr++;
}
memcpy(crcin, crcout, 5);
}
crc = 0;
if(crcin[4]) {
crc |= 0x10;
}
if(crcin[3]) {
crc |= 0x08;
}
if(crcin[2]) {
crc |= 0x04;
}
if(crcin[1]) {
crc |= 0x02;
}
if(crcin[0]) {
crc |= 0x01;
}
return crc;
}
static void _transfer(struct cgpu_info *bmsc, 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(bmsc, request_type, bRequest, wValue, wIndex, data, siz, cmd);
applog(LOG_DEBUG, "%s: bmgid %d %s got err %d",
bmsc->drv->name, bmsc->cgminer_id,
usb_cmdname(cmd), err);
}
#define transfer(bmsc, request_type, bRequest, wValue, wIndex, cmd) \
_transfer(bmsc, request_type, bRequest, wValue, wIndex, NULL, 0, cmd)
static void bmsc_initialise(struct cgpu_info *bmsc, int baud)
{
struct BMSC_INFO *info = (struct BMSC_INFO *)(bmsc->device_data);
uint16_t wValue, wIndex;
enum sub_ident ident;
int interface;
if (bmsc->usbinfo.nodev)
return;
interface = _usb_interface(bmsc, info->intinfo);
ident = usb_ident(bmsc);
switch (ident) {
case IDENT_BLT:
case IDENT_LLT:
case IDENT_CMR1:
case IDENT_CMR2:
// Reset
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_RESET, FTDI_VALUE_RESET,
interface, C_RESET);
if (bmsc->usbinfo.nodev)
return;
// Latency
_usb_ftdi_set_latency(bmsc, info->intinfo);
if (bmsc->usbinfo.nodev)
return;
// Set data control
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_DATA, FTDI_VALUE_DATA_BLT,
interface, C_SETDATA);
if (bmsc->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, "bmsc_intialise() invalid baud (%d) for Cairnsmore1", baud);
break;
}
}
// Set the baud
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_BAUD, wValue,
(wIndex & 0xff00) | interface, C_SETBAUD);
if (bmsc->usbinfo.nodev)
return;
// Set Modem Control
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_MODEM, FTDI_VALUE_MODEM,
interface, C_SETMODEM);
if (bmsc->usbinfo.nodev)
return;
// Set Flow Control
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_FLOW, FTDI_VALUE_FLOW,
interface, C_SETFLOW);
if (bmsc->usbinfo.nodev)
return;
// Clear any sent data
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_RESET, FTDI_VALUE_PURGE_TX,
interface, C_PURGETX);
if (bmsc->usbinfo.nodev)
return;
// Clear any received data
transfer(bmsc, FTDI_TYPE_OUT, FTDI_REQUEST_RESET, FTDI_VALUE_PURGE_RX,
interface, C_PURGERX);
break;
case IDENT_ICA:
// Set Data Control
transfer(bmsc, PL2303_CTRL_OUT, PL2303_REQUEST_CTRL, PL2303_VALUE_CTRL,
interface, C_SETDATA);
if (bmsc->usbinfo.nodev)
return;
// Set Line Control
uint32_t ica_data[2] = { PL2303_VALUE_LINE0, PL2303_VALUE_LINE1 };
_transfer(bmsc, PL2303_CTRL_OUT, PL2303_REQUEST_LINE, PL2303_VALUE_LINE,
interface, &ica_data[0], PL2303_VALUE_LINE_SIZE, C_SETLINE);
if (bmsc->usbinfo.nodev)
return;
// Vendor
transfer(bmsc, PL2303_VENDOR_OUT, PL2303_REQUEST_VENDOR, PL2303_VALUE_VENDOR,
interface, C_VENDOR);
break;
case IDENT_AMU:
// Enable the UART
transfer(bmsc, CP210X_TYPE_OUT, CP210X_REQUEST_IFC_ENABLE,
CP210X_VALUE_UART_ENABLE,
interface, C_ENABLE_UART);
if (bmsc->usbinfo.nodev)
return;
// Set data control
transfer(bmsc, CP210X_TYPE_OUT, CP210X_REQUEST_DATA, CP210X_VALUE_DATA,
interface, C_SETDATA);
if (bmsc->usbinfo.nodev)
return;
// Set the baud
uint32_t data = CP210X_DATA_BAUD;
_transfer(bmsc, CP210X_TYPE_OUT, CP210X_REQUEST_BAUD, 0,
interface, &data, sizeof(data), C_SETBAUD);
break;
default:
quit(1, "bmsc_intialise() called with invalid %s cgid %i ident=%d",
bmsc->drv->name, bmsc->cgminer_id, ident);
}
}
#define BTM_NONCE_ERROR -1
#define BTM_NONCE_OK 0
#define BTM_NONCE_RESTART 1
#define BTM_NONCE_TIMEOUT 2
static int bmsc_get_nonce(struct cgpu_info *bmsc, unsigned char *buf, struct timeval *tv_start,
struct timeval *tv_finish, struct thr_info *thr, int read_time)
{
struct BMSC_INFO *info = (struct BMSC_INFO *)(bmsc->device_data);
int err, amt, rc;
if (bmsc->usbinfo.nodev)
return BTM_NONCE_ERROR;
cgtime(tv_start);
err = usb_read_ii_timeout_cancellable(bmsc, info->intinfo, (char *)buf,
BMSC_READ_SIZE, &amt, read_time,
C_GETRESULTS);
cgtime(tv_finish);
if (err < 0 && err != LIBUSB_ERROR_TIMEOUT) {
applog(LOG_ERR, "%s%i: Comms error (rerr=%d amt=%d)", bmsc->drv->name,
bmsc->device_id, err, amt);
dev_error(bmsc, REASON_DEV_COMMS_ERROR);
return BTM_NONCE_ERROR;
}
if (amt >= BMSC_READ_SIZE)
return BTM_NONCE_OK;
rc = SECTOMS(tdiff(tv_finish, tv_start));
if (thr && thr->work_restart) {
applog(LOG_DEBUG, "Bmsc Read: Work restart at %d ms", rc);
return BTM_NONCE_RESTART;
}
if (amt > 0)
applog(LOG_DEBUG, "Bmsc Read: Timeout reading for %d ms", rc);
else
applog(LOG_DEBUG, "Bmsc Read: No data for %d ms", rc);
return BTM_NONCE_TIMEOUT;
}
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 *bmsc, float readtimeout)
{
struct BMSC_INFO *info = (struct BMSC_INFO *)(bmsc->device_data);
enum sub_ident ident;
double Hs;
char buf[BUFSIZ+1];
char *ptr, *comma, *eq;
size_t max;
int i;
ident = usb_ident(bmsc);
switch (ident) {
case IDENT_ICA:
info->Hs = BMSC_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, "Bmsc get_options() called with invalid %s ident=%d",
bmsc->drv->name, ident);
}
info->read_time = 0;
info->read_time_limit = 0; // 0 = no limit
info->fullnonce = info->Hs * (((double) 0xffffffff) + 1);
info->read_time = (int)(readtimeout * BMSC_WAIT_TIMEOUT);
if(info->read_time < 0)
info->read_time = 1;
info->timing_mode = MODE_DEFAULT;
info->do_bmsc_timing = false;
info->min_data_count = MIN_DATA_COUNT;
// All values are in multiples of BMSC_WAIT_TIMEOUT
info->read_time_limit *= BMSC_WAIT_TIMEOUT;
applog(LOG_ERR, "%s%d Init: mode=%s read_time=%dms limit=%dms Hs=%e",
bmsc->drv->name, bmsc->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 bmsc-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 *bmsc, int *baud, float *readtimeout)
{
char buf[BUFSIZ+1];
char *ptr, *comma, *colon, *colon2;
enum sub_ident ident;
size_t max;
int i, tmp;
float tmpf;
if (opt_bmsc_options == NULL)
buf[0] = '\0';
else {
ptr = opt_bmsc_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(bmsc);
switch (ident) {
case IDENT_ICA:
case IDENT_BLT:
case IDENT_LLT:
*baud = BMSC_IO_SPEED;
break;
case IDENT_AMU:
*baud = BMSC_IO_SPEED;
break;
case IDENT_CMR1:
*baud = BMSC_IO_SPEED;
break;
case IDENT_CMR2:
*baud = BMSC_IO_SPEED;
break;
default:
quit(1, "Bmsc get_options() called with invalid %s ident=%d",
bmsc->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 bmsc-options for baud (%s) must be 115200 or 57600", buf);
}
}
if (colon && *colon) {
tmpf = atof(colon);
if (tmpf > 0) {
*readtimeout = tmpf;
} else {
quit(1, "Invalid bmsc-options for timeout (%s) must be > 0", colon);
}
}
}
}
static void get_bandops(unsigned char * core_buf, int *corenum, char *coreenable, int *coresleep)
{
char buf[512] = {0};
char *colon, *colon2, * colon3;
int i, len;
if (opt_bmsc_bandops) {
len = strlen(opt_bmsc_bandops);
if(len <= 0 || len >= 512) {
quit(1, "Invalid bmsc-bandops %s %d", opt_bmsc_bandops, len);
}
strcpy(buf, opt_bmsc_bandops);
colon = strchr(buf, ':');
if (colon)
*(colon++) = '\0';
if (*buf) {
if(strlen(buf) > 8 || strlen(buf)%2 != 0 || strlen(buf)/2 == 0) {
quit(1, "Invalid bitmain-options for core command, must be hex now: %s", buf);
}
memset(core_buf, 0, 4);
if(!hex2bin(core_buf, buf, strlen(buf)/2)) {
quit(1, "Invalid bitmain-options for core command, hex2bin error now: %s", buf);
}
}
if (colon && *colon) {
colon2 = strchr(colon, ':');
if (colon2)
*(colon2++) = '\0';
if (*colon) {
*corenum = atoi(colon);
if(*corenum <= 0 || *corenum >= 256) {
quit(1, "Invalid bitmain-bandops for asic core num, must %d be > 0 and < 256", *corenum);
}
}
if(colon2 && *colon2) {
colon3 = strchr(colon2, ':');
if (colon3)
*(colon3++) = '\0';
if(*colon2) {
strcpy(coreenable, colon2);
if(strlen(coreenable) != *corenum) {
quit(1, "Invalid bitmain-bandops for asic core enable, must be equal core num %d", *corenum);
}
}
if (colon3 && *colon3) {
*coresleep = atoi(colon3);
}
}
}
}
}
static struct cgpu_info *bmsc_detect_one(struct libusb_device *dev, struct usb_find_devices *found)
{
int this_option_offset = ++option_offset;
struct BMSC_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 bmsc_open()
// This one takes ~0.53ms on Rev3 Bmsc
const char golden_ob[] =
"4679ba4ec99876bf4bfe086082b40025"
"4df6c356451471139a3afa71e48f544a"
"00000000000000004000000000000000"
"0000001f87320b1a1426674f2fa722ce";
const char golden_ob1[] =
"e1eb393a50f6ae97e306ea87c1c47eae"
"1f9ad02d729d9f86bd48a213a4600144"
"00000000000000004000000000000000"
"0000001ffb0b0719aaf19752dd5e83a4";
const char golden_ob2[] =
"b65911ea2c4b0c52958cb408caebff32"
"8dece4e6a002fe2693ba9906ffde7e8a"
"00000000000000004000000000000000"
"0000001f20dc1c190642455201756658";
const char golden_ob3[] =
"c99da189374bcc69a1134d6f4953addc"
"7420499b132b7f8f999b0c71fe7efbf2"
"00000000000000004000000000000000"
"0000001f20dc1c198e4145526d74dee3";
const char golden_ob4[] =
"696af96144b6079c1b437fbc6e539e4d"
"996d25b027ea9eefdfaf4eff6add6986"
"00000000000000004000000000000000"
"0000001f20dc1c19f84e4552ac86dc14";
char bandops_ob[] =
"00000000000000000000000000000000"
"00000000000000000000000000000000"
"00000000000000000000000000000000"
"00000000000000000000000000000000";
const char golden_nonce[] = "000187a2";
const char golden_nonce1[] = "0345182b";
const char golden_nonce2[] = "466b30a5";
const char golden_nonce3[] = "857e65ee";
const char golden_nonce4[] = "c6f70284";
const uint32_t golden_nonce_val = 0x000187a2;
unsigned char nonce_bin[BMSC_READ_SIZE];
struct BMSC_WORK workdata;
char *nonce_hex;
int baud = 115200, work_division = 1, fpga_count = 1;
float readtimeout = 1.0;
struct cgpu_info *bmsc;
int ret, err, amount, tries, i;
bool ok;
bool cmr2_ok[CAIRNSMORE2_INTS];
int cmr2_count;
unsigned char cmd_buf[4] = {0};
unsigned char rdreg_buf[4] = {0};
unsigned char reg_data[4] = {0};
unsigned char voltage_data[2] = {0};
unsigned char rebuf[BMSC_READ_BUF_LEN] = {0};
int relen = 0;
int realllen = 0;
int nodata = 0;
char msg[10240] = {0};
int sendfreqstatus = 1;
int k = 0;
unsigned char core_cmd[4] = {0};
int corenum = 0;
char coreenable[256] = {0};
int coresleep = 0;
if (opt_bmsc_options == NULL)
return NULL;
if ((sizeof(workdata) << 1) != (sizeof(golden_ob) - 1))
quithere(1, "Data and golden_ob sizes don't match");
if ((sizeof(workdata) << 1) != (sizeof(bandops_ob) - 1))
quithere(1, "Data and bandops_ob sizes don't match");
bmsc = usb_alloc_cgpu(&bmsc_drv, 1);
if (!usb_init(bmsc, dev, found))
goto shin;
get_options(this_option_offset, bmsc, &baud, &readtimeout);
get_bandops(core_cmd, &corenum, coreenable, &coresleep);
info = (struct BMSC_INFO *)calloc(1, sizeof(struct BMSC_INFO));
if (unlikely(!info))
quit(1, "Failed to malloc BMSC_INFO");
bmsc->device_data = (void *)info;
info->ident = usb_ident(bmsc);
info->start = true;
switch (info->ident) {
case IDENT_ICA:
case IDENT_BLT:
case IDENT_LLT:
case IDENT_AMU:
case IDENT_CMR1:
info->timeout = BMSC_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 = BMSC_CMR2_TIMEOUT;
cmr2_count = 0;
for (i = 0; i < CAIRNSMORE2_INTS; i++)
cmr2_ok[i] = false;
break;
default:
quit(1, "%s bmsc_detect_one() invalid %s ident=%d",
bmsc->drv->dname, bmsc->drv->dname, info->ident);
}
// For CMR2 test each USB Interface
cmr2_retry:
tries = 2;
ok = false;
while (!ok && tries-- > 0) {
bmsc_initialise(bmsc, baud);
if(opt_bmsc_bootstart) {
applog(LOG_ERR, "---------------------start bootstart----------------------");
cmd_buf[0] = 0xbb;
cmd_buf[1] = 0x00;
cmd_buf[2] = 0x00;
cmd_buf[3] = 0x00; //0-7
cmd_buf[3] = CRC5(cmd_buf, 27);
cmd_buf[3] |= 0x80;
cgsleep_ms(500);
applog(LOG_ERR, "Send bootstart off %02x%02x%02x%02x", cmd_buf[0], cmd_buf[1], cmd_buf[2], cmd_buf[3]);
err = usb_write(bmsc, (char * )cmd_buf, 4, &amount, C_SENDTESTWORK);
if (err != LIBUSB_SUCCESS || amount != 4) {
applog(LOG_ERR, "Write bootstart Comms error (werr=%d amount=%d)", err, amount);
continue;
}
cmd_buf[0] = 0xbb;
cmd_buf[1] = 0x08;
cmd_buf[2] = 0x00;
cmd_buf[3] = 0x00; //0-7
cmd_buf[3] = CRC5(cmd_buf, 27);
cmd_buf[3] |= 0x80;
cgsleep_ms(500);
applog(LOG_ERR, "Send bootstart on %02x%02x%02x%02x", cmd_buf[0], cmd_buf[1], cmd_buf[2], cmd_buf[3]);
err = usb_write(bmsc, (char * )cmd_buf, 4, &amount, C_SENDTESTWORK);
if (err != LIBUSB_SUCCESS || amount != 4) {
applog(LOG_ERR, "Write bootstart Comms error (werr=%d amount=%d)", err, amount);
continue;
}
applog(LOG_ERR, "Send bootstart ok");
}
if(opt_bmsc_voltage) {
if(strlen(opt_bmsc_voltage) > 4 || strlen(opt_bmsc_voltage)%2 != 0 || strlen(opt_bmsc_voltage)/2 == 0) {
quit(1, "Invalid options for voltage data, must be hex now: %s", opt_bmsc_voltage);
}
memset(voltage_data, 0, 2);
if(!hex2bin(voltage_data, opt_bmsc_voltage, strlen(opt_bmsc_voltage)/2)) {
quit(1, "Invalid options for voltage data, hex2bin error now: %s", opt_bmsc_voltage);
}
cmd_buf[0] = 0xaa;
cmd_buf[1] = voltage_data[0];
cmd_buf[1] &=0x0f;
cmd_buf[1] |=0xb0;
cmd_buf[2] = voltage_data[1];
cmd_buf[3] = 0x00; //0-7
cmd_buf[3] = CRC5(cmd_buf, 4*8 - 5);
cmd_buf[3] |= 0xc0;
applog(LOG_ERR, "---------------------start voltage----------------------");
cgsleep_ms(500);
applog(LOG_ERR, "Send voltage %02x%02x%02x%02x", cmd_buf[0], cmd_buf[1], cmd_buf[2], cmd_buf[3]);
err = usb_write(bmsc, (char * )cmd_buf, 4, &amount, C_SENDTESTWORK);
if (err != LIBUSB_SUCCESS || amount != 4) {
applog(LOG_ERR, "Write voltage Comms error (werr=%d amount=%d)", err, amount);
continue;
}
applog(LOG_ERR, "Send voltage ok");
}
if (opt_bmsc_gray) {
cmd_buf[0] = 3;
cmd_buf[0] |= 0x80;
cmd_buf[1] = 0; //16-23
cmd_buf[2] = 0x80; //8-15
cmd_buf[3] = 0x80; //0-7
cmd_buf[3] = CRC5(cmd_buf, 27);
cmd_buf[3] |= 0x80;
applog(LOG_ERR, "-----------------start gray-------------------");
cgsleep_ms(500);
applog(LOG_ERR, "Send gray %02x%02x%02x%02x", cmd_buf[0], cmd_buf[1], cmd_buf[2], cmd_buf[3]);
err = usb_write_ii(bmsc, info->intinfo, (char * )cmd_buf, 4, &amount, C_SENDWORK);
if (err != LIBUSB_SUCCESS || amount != 4) {
applog(LOG_ERR, "%s%i: Write freq Comms error (werr=%d amount=%d)", bmsc->drv->name, bmsc->device_id, err, amount);
continue;
}
applog(LOG_DEBUG, "Send gray ok");
}
if (opt_bmsc_freq) {
if (strcmp(opt_bmsc_freq, "0") != 0) {
applog(LOG_DEBUG, "Device detect freq parameter=%s", opt_bmsc_freq);
if (strlen(opt_bmsc_freq) > 8 || strlen(opt_bmsc_freq) % 2 != 0 || strlen(opt_bmsc_freq) / 2 == 0) {
quit(1, "Invalid bmsc_freq for freq data, must be hex now: %s", opt_bmsc_freq);
}
memset(reg_data, 0, 4);
if (!hex2bin(reg_data, opt_bmsc_freq, strlen(opt_bmsc_freq) / 2)) {
quit(1, "Invalid bmsc_freq for freq data, hex2bin error now: %s", opt_bmsc_freq);
}
cmd_buf[0] = 2;
cmd_buf[0] |= 0x80;
cmd_buf[1] = reg_data[0]; //16-23
cmd_buf[2] = reg_data[1]; //8-15
cmd_buf[3] = 0;
cmd_buf[3] = CRC5(cmd_buf, 27);