OpenCL GPU miner
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/*
* Copyright 2012-2013 Andrew Smith
* Copyright 2012 Luke Dashjr
*
* 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 <stdarg.h>
#include <stdio.h>
#include <unistd.h>
#include <math.h>
#include "logging.h"
#include "miner.h"
#include "usbutils.h"
#include "fpgautils.h"
#include "util.h"
#define BITSTREAM_FILENAME "fpgaminer_top_fixed7_197MHz.ncd"
#define BISTREAM_USER_ID "\2\4$B"
#define BITSTREAM_MAGIC_0 0
#define BITSTREAM_MAGIC_1 9
#define MODMINER_CUTOFF_TEMP 60.0
#define MODMINER_OVERHEAT_TEMP 50.0
#define MODMINER_RECOVER_TEMP 46.5
#define MODMINER_TEMP_UP_LIMIT 47.0
#define MODMINER_HW_ERROR_PERCENT 0.75
// How many seconds of no nonces means there's something wrong
// First time - drop the clock and see if it revives
// Second time - (and it didn't revive) disable it
#define ITS_DEAD_JIM 300
// N.B. in the latest firmware the limit is 250
// however the voltage/temperature risks preclude that
#define MODMINER_MAX_CLOCK 230
#define MODMINER_DEF_CLOCK 200
#define MODMINER_MIN_CLOCK 160
#define MODMINER_CLOCK_UP 2
#define MODMINER_CLOCK_SET 0
#define MODMINER_CLOCK_DOWN -2
// = 0 means OVERHEAT doesn't affect the clock
#define MODMINER_CLOCK_OVERHEAT 0
#define MODMINER_CLOCK_DEAD -6
#define MODMINER_CLOCK_CUTOFF -10
// Commands
#define MODMINER_PING "\x00"
#define MODMINER_GET_VERSION "\x01"
#define MODMINER_FPGA_COUNT "\x02"
// Commands + require FPGAid
#define MODMINER_GET_IDCODE '\x03'
#define MODMINER_GET_USERCODE '\x04'
#define MODMINER_PROGRAM '\x05'
#define MODMINER_SET_CLOCK '\x06'
#define MODMINER_READ_CLOCK '\x07'
#define MODMINER_SEND_WORK '\x08'
#define MODMINER_CHECK_WORK '\x09'
// One byte temperature reply
#define MODMINER_TEMP1 '\x0a'
// Two byte temperature reply
#define MODMINER_TEMP2 '\x0d'
// +6 bytes
#define MODMINER_SET_REG '\x0b'
// +2 bytes
#define MODMINER_GET_REG '\x0c'
#define FPGAID_ALL 4
// Maximum how many good shares in a row means clock up
// 96 is ~34m22s at 200MH/s
#define MODMINER_TRY_UP 96
// Initially how many good shares in a row means clock up
// This is doubled each down clock until it reaches MODMINER_TRY_UP
// 6 is ~2m9s at 200MH/s
#define MODMINER_EARLY_UP 6
// Limit when reducing shares_to_good
#define MODMINER_MIN_BACK 12
struct device_drv modminer_drv;
// 45 noops sent when detecting, in case the device was left in "start job" reading
static const char NOOP[] = MODMINER_PING "\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff";
static void do_ping(struct cgpu_info *modminer)
{
char buf[0x100+1];
int err, amount;
// Don't care if it fails
err = usb_write(modminer, (char *)NOOP, sizeof(NOOP)-1, &amount, C_PING);
applog(LOG_DEBUG, "%s%u: flush noop got %d err %d",
modminer->drv->name, modminer->fpgaid, amount, err);
// Clear any outstanding data
while ((err = usb_read_once(modminer, buf, sizeof(buf)-1, &amount, C_CLEAR)) == 0 && amount > 0)
applog(LOG_DEBUG, "%s%u: clear got %d",
modminer->drv->name, modminer->fpgaid, amount);
applog(LOG_DEBUG, "%s%u: final clear got %d err %d",
modminer->drv->name, modminer->fpgaid, amount, err);
}
static bool modminer_detect_one(struct libusb_device *dev, struct usb_find_devices *found)
{
char buf[0x100+1];
char *devname = NULL;
char devpath[32];
int err, i, amount;
bool added = false;
struct cgpu_info *modminer = usb_alloc_cgpu(&modminer_drv, 1);
modminer->modminer_mutex = calloc(1, sizeof(*(modminer->modminer_mutex)));
mutex_init(modminer->modminer_mutex);
modminer->fpgaid = (char)0;
if (!usb_init(modminer, dev, found))
goto shin;
usb_set_cps(modminer, 11520);
usb_enable_cps(modminer);
do_ping(modminer);
if ((err = usb_write(modminer, MODMINER_GET_VERSION, 1, &amount, C_REQUESTVERSION)) < 0 || amount != 1) {
applog(LOG_ERR, "%s detect (%s) send version request failed (%d:%d)",
modminer->drv->dname, modminer->device_path, amount, err);
goto unshin;
}
if ((err = usb_read_once(modminer, buf, sizeof(buf)-1, &amount, C_GETVERSION)) < 0 || amount < 1) {
if (err < 0)
applog(LOG_ERR, "%s detect (%s) no version reply (%d)",
modminer->drv->dname, modminer->device_path, err);
else
applog(LOG_ERR, "%s detect (%s) empty version reply (%d)",
modminer->drv->dname, modminer->device_path, amount);
applog(LOG_DEBUG, "%s detect (%s) check the firmware",
modminer->drv->dname, modminer->device_path);
goto unshin;
}
buf[amount] = '\0';
devname = strdup(buf);
applog(LOG_DEBUG, "%s (%s) identified as: %s", modminer->drv->dname, modminer->device_path, devname);
if ((err = usb_write(modminer, MODMINER_FPGA_COUNT, 1, &amount, C_REQUESTFPGACOUNT) < 0 || amount != 1)) {
applog(LOG_ERR, "%s detect (%s) FPGA count request failed (%d:%d)",
modminer->drv->dname, modminer->device_path, amount, err);
goto unshin;
}
if ((err = usb_read(modminer, buf, 1, &amount, C_GETFPGACOUNT)) < 0 || amount != 1) {
applog(LOG_ERR, "%s detect (%s) no FPGA count reply (%d:%d)",
modminer->drv->dname, modminer->device_path, amount, err);
goto unshin;
}
// TODO: flag it use 1 byte temp if it is an old firmware
// can detect with modminer->cgusb->serial ?
if (buf[0] == 0) {
applog(LOG_ERR, "%s detect (%s) zero FPGA count from %s",
modminer->drv->dname, modminer->device_path, devname);
goto unshin;
}
if (buf[0] < 1 || buf[0] > 4) {
applog(LOG_ERR, "%s detect (%s) invalid FPGA count (%u) from %s",
modminer->drv->dname, modminer->device_path, buf[0], devname);
goto unshin;
}
applog(LOG_DEBUG, "%s (%s) %s has %u FPGAs",
modminer->drv->dname, modminer->device_path, devname, buf[0]);
modminer->name = devname;
// TODO: test with 1 board missing in the middle and each end
// to see how that affects the sequence numbers
for (i = 0; i < buf[0]; i++) {
struct cgpu_info *tmp = usb_copy_cgpu(modminer);
sprintf(devpath, "%d:%d:%d",
(int)(modminer->usbinfo.bus_number),
(int)(modminer->usbinfo.device_address),
i);
tmp->device_path = strdup(devpath);
// Only the first copy gets the already used stats
if (added)
tmp->usbinfo.usbstat = USB_NOSTAT;
tmp->fpgaid = (char)i;
tmp->modminer_mutex = modminer->modminer_mutex;
if (!add_cgpu(tmp)) {
tmp = usb_free_cgpu_devlock(tmp, !added);
goto unshin;
}
update_usb_stats(tmp);
added = true;
}
modminer = usb_free_cgpu_devlock(modminer, !added);
return true;
unshin:
if (!added)
usb_uninit(modminer);
shin:
if (!added) {
free(modminer->modminer_mutex);
modminer->modminer_mutex = NULL;
}
modminer = usb_free_cgpu_devlock(modminer, !added);
if (added)
return true;
else
return false;
}
static void modminer_detect()
{
usb_detect(&modminer_drv, modminer_detect_one);
}
static bool get_expect(struct cgpu_info *modminer, FILE *f, char c)
{
char buf;
if (fread(&buf, 1, 1, f) != 1) {
applog(LOG_ERR, "%s%u: Error (%d) reading bitstream (%c)",
modminer->drv->name, modminer->device_id, errno, c);
return false;
}
if (buf != c) {
applog(LOG_ERR, "%s%u: bitstream code mismatch (%c)",
modminer->drv->name, modminer->device_id, c);
return false;
}
return true;
}
static bool get_info(struct cgpu_info *modminer, FILE *f, char *buf, int bufsiz, const char *name)
{
unsigned char siz[2];
int len;
if (fread(siz, 2, 1, f) != 1) {
applog(LOG_ERR, "%s%u: Error (%d) reading bitstream '%s' len",
modminer->drv->name, modminer->device_id, errno, name);
return false;
}
len = siz[0] * 256 + siz[1];
if (len >= bufsiz) {
applog(LOG_ERR, "%s%u: Bitstream '%s' len too large (%d)",
modminer->drv->name, modminer->device_id, name, len);
return false;
}
if (fread(buf, len, 1, f) != 1) {
applog(LOG_ERR, "%s%u: Error (%d) reading bitstream '%s'",
modminer->drv->name, modminer->device_id, errno, name);
return false;
}
buf[len] = '\0';
return true;
}
#define USE_DEFAULT_TIMEOUT 0
// mutex must always be locked before calling
static bool get_status_timeout(struct cgpu_info *modminer, char *msg, unsigned int timeout, enum usb_cmds cmd)
{
int err, amount;
char buf[1];
if (timeout == USE_DEFAULT_TIMEOUT)
err = usb_read(modminer, buf, 1, &amount, cmd);
else
err = usb_read_timeout(modminer, buf, 1, &amount, timeout, cmd);
if (err < 0 || amount != 1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error (%d:%d) getting %s reply",
modminer->drv->name, modminer->device_id, amount, err, msg);
return false;
}
if (buf[0] != 1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error, invalid %s reply (was %d should be 1)",
modminer->drv->name, modminer->device_id, msg, buf[0]);
return false;
}
return true;
}
// mutex must always be locked before calling
static bool get_status(struct cgpu_info *modminer, char *msg, enum usb_cmds cmd)
{
return get_status_timeout(modminer, msg, USE_DEFAULT_TIMEOUT, cmd);
}
static bool modminer_fpga_upload_bitstream(struct cgpu_info *modminer)
{
const char *bsfile = BITSTREAM_FILENAME;
char buf[0x100], *p;
char devmsg[64];
unsigned char *ubuf = (unsigned char *)buf;
unsigned long totlen, len;
size_t buflen, remaining;
float nextmsg, upto;
char fpgaid = FPGAID_ALL;
int err, amount, tries;
char *ptr;
FILE *f = open_bitstream("modminer", bsfile);
if (!f) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error (%d) opening bitstream file %s",
modminer->drv->name, modminer->device_id, errno, bsfile);
return false;
}
if (fread(buf, 2, 1, f) != 1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error (%d) reading bitstream magic",
modminer->drv->name, modminer->device_id, errno);
goto dame;
}
if (buf[0] != BITSTREAM_MAGIC_0 || buf[1] != BITSTREAM_MAGIC_1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: bitstream has incorrect magic (%u,%u) instead of (%u,%u)",
modminer->drv->name, modminer->device_id,
buf[0], buf[1],
BITSTREAM_MAGIC_0, BITSTREAM_MAGIC_1);
goto dame;
}
if (fseek(f, 11L, SEEK_CUR)) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error (%d) bitstream seek failed",
modminer->drv->name, modminer->device_id, errno);
goto dame;
}
if (!get_expect(modminer, f, 'a'))
goto undame;
if (!get_info(modminer, f, buf, sizeof(buf), "Design name"))
goto undame;
applog(LOG_DEBUG, "%s%u: bitstream file '%s' info:",
modminer->drv->name, modminer->device_id, bsfile);
applog(LOG_DEBUG, " Design name: '%s'", buf);
p = strrchr(buf, ';') ? : buf;
p = strrchr(buf, '=') ? : p;
if (p[0] == '=')
p++;
unsigned long fwusercode = (unsigned long)strtoll(p, &p, 16);
if (p[0] != '\0') {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Bad usercode in bitstream file",
modminer->drv->name, modminer->device_id);
goto dame;
}
if (fwusercode == 0xffffffff) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: bitstream doesn't support user code",
modminer->drv->name, modminer->device_id);
goto dame;
}
applog(LOG_DEBUG, " Version: %lu, build %lu", (fwusercode >> 8) & 0xff, fwusercode & 0xff);
if (!get_expect(modminer, f, 'b'))
goto undame;
if (!get_info(modminer, f, buf, sizeof(buf), "Part number"))
goto undame;
applog(LOG_DEBUG, " Part number: '%s'", buf);
if (!get_expect(modminer, f, 'c'))
goto undame;
if (!get_info(modminer, f, buf, sizeof(buf), "Build date"))
goto undame;
applog(LOG_DEBUG, " Build date: '%s'", buf);
if (!get_expect(modminer, f, 'd'))
goto undame;
if (!get_info(modminer, f, buf, sizeof(buf), "Build time"))
goto undame;
applog(LOG_DEBUG, " Build time: '%s'", buf);
if (!get_expect(modminer, f, 'e'))
goto undame;
if (fread(buf, 4, 1, f) != 1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error (%d) reading bitstream data len",
modminer->drv->name, modminer->device_id, errno);
goto dame;
}
len = ((unsigned long)ubuf[0] << 24) | ((unsigned long)ubuf[1] << 16) | (ubuf[2] << 8) | ubuf[3];
applog(LOG_DEBUG, " Bitstream size: %lu", len);
strcpy(devmsg, modminer->device_path);
ptr = strrchr(devmsg, ':');
if (ptr)
*ptr = '\0';
applog(LOG_WARNING, "%s%u: Programming all FPGA on %s ... Mining will not start until complete",
modminer->drv->name, modminer->device_id, devmsg);
buf[0] = MODMINER_PROGRAM;
buf[1] = fpgaid;
buf[2] = (len >> 0) & 0xff;
buf[3] = (len >> 8) & 0xff;
buf[4] = (len >> 16) & 0xff;
buf[5] = (len >> 24) & 0xff;
if ((err = usb_write(modminer, buf, 6, &amount, C_STARTPROGRAM)) < 0 || amount != 6) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Program init failed (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
goto dame;
}
if (!get_status(modminer, "initialise", C_STARTPROGRAMSTATUS))
goto undame;
// It must be 32 bytes according to MCU legacy.c
#define WRITE_SIZE 32
totlen = len;
nextmsg = 0.1;
while (len > 0) {
buflen = len < WRITE_SIZE ? len : WRITE_SIZE;
if (fread(buf, buflen, 1, f) != 1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: bitstream file read error %d (%lu bytes left)",
modminer->drv->name, modminer->device_id, errno, len);
goto dame;
}
tries = 0;
ptr = buf;
remaining = buflen;
while ((err = usb_write(modminer, ptr, remaining, &amount, C_PROGRAM)) < 0 || amount != (int)remaining) {
if (err == LIBUSB_ERROR_TIMEOUT && amount > 0 && ++tries < 4) {
remaining -= amount;
ptr += amount;
if (opt_debug)
applog(LOG_DEBUG, "%s%u: Program timeout (%d:%d) sent %d tries %d",
modminer->drv->name, modminer->device_id,
amount, err, (int)remaining, tries);
if (!get_status(modminer, "write status", C_PROGRAMSTATUS2))
goto dame;
} else {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Program failed (%d:%d) sent %d",
modminer->drv->name, modminer->device_id, amount, err, (int)remaining);
goto dame;
}
}
if (!get_status(modminer, "write status", C_PROGRAMSTATUS))
goto dame;
len -= buflen;
upto = (float)(totlen - len) / (float)(totlen);
if (upto >= nextmsg) {
applog(LOG_WARNING,
"%s%u: Programming %.1f%% (%lu out of %lu)",
modminer->drv->name, modminer->device_id, upto*100, (totlen - len), totlen);
nextmsg += 0.1;
}
}
if (!get_status(modminer, "final status", C_FINALPROGRAMSTATUS))
goto undame;
applog(LOG_WARNING, "%s%u: Programming completed for all FPGA on %s",
modminer->drv->name, modminer->device_id, devmsg);
// Give it a 2/3s delay after programming
cgsleep_ms(666);
usb_set_dev_start(modminer);
return true;
undame:
;
mutex_unlock(modminer->modminer_mutex);
;
dame:
fclose(f);
return false;
}
static bool modminer_fpga_prepare(struct thr_info *thr)
{
// struct cgpu_info *modminer = thr->cgpu;
struct modminer_fpga_state *state;
state = thr->cgpu_data = calloc(1, sizeof(struct modminer_fpga_state));
state->shares_to_good = MODMINER_EARLY_UP;
state->overheated = false;
return true;
}
/*
* Clocking rules:
* If device exceeds cutoff or overheat temp - stop sending work until it cools
* decrease the clock by MODMINER_CLOCK_CUTOFF/MODMINER_CLOCK_OVERHEAT
* for when it restarts
* with MODMINER_CLOCK_OVERHEAT=0 basically says that temp shouldn't
* affect the clock unless we reach CUTOFF
*
* If device overheats
* set shares_to_good back to MODMINER_MIN_BACK
* to speed up clock recovery if temp drop doesnt help
*
* When to clock down:
* If device gets MODMINER_HW_ERROR_PERCENT errors since last clock up or down
* if clock is <= default it requires 2 HW to do this test
* if clock is > default it only requires 1 HW to do this test
* also double shares_to_good
*
* When to clock up:
* If device gets shares_to_good good shares in a row
* and temp < MODMINER_TEMP_UP_LIMIT
*
* N.B. clock must always be a multiple of 2
*/
static const char *clocknodev = "clock failed - no device";
static const char *clockoldwork = "clock already changed for this work";
static const char *clocktoolow = "clock too low";
static const char *clocktoohi = "clock too high";
static const char *clocksetfail = "clock set command failed";
static const char *clockreplyfail = "clock reply failed";
static const char *modminer_delta_clock(struct thr_info *thr, int delta, bool temp, bool force)
{
struct cgpu_info *modminer = thr->cgpu;
struct modminer_fpga_state *state = thr->cgpu_data;
unsigned char cmd[6], buf[1];
int err, amount;
// Device is gone
if (modminer->usbinfo.nodev)
return clocknodev;
// Only do once if multiple shares per work or multiple reasons
if (!state->new_work && !force)
return clockoldwork;
state->new_work = false;
state->shares = 0;
state->shares_last_hw = 0;
state->hw_errors = 0;
// FYI clock drop has little effect on temp
if (delta < 0 && (modminer->clock + delta) < MODMINER_MIN_CLOCK)
return clocktoolow;
if (delta > 0 && (modminer->clock + delta) > MODMINER_MAX_CLOCK)
return clocktoohi;
if (delta < 0) {
if (temp)
state->shares_to_good = MODMINER_MIN_BACK;
else {
if ((state->shares_to_good * 2) < MODMINER_TRY_UP)
state->shares_to_good *= 2;
else
state->shares_to_good = MODMINER_TRY_UP;
}
}
modminer->clock += delta;
cmd[0] = MODMINER_SET_CLOCK;
cmd[1] = modminer->fpgaid;
cmd[2] = modminer->clock;
cmd[3] = cmd[4] = cmd[5] = '\0';
mutex_lock(modminer->modminer_mutex);
if ((err = usb_write(modminer, (char *)cmd, 6, &amount, C_SETCLOCK)) < 0 || amount != 6) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error writing set clock speed (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
return clocksetfail;
}
if ((err = usb_read(modminer, (char *)(&buf), 1, &amount, C_REPLYSETCLOCK)) < 0 || amount != 1) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error reading set clock speed (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
return clockreplyfail;
}
mutex_unlock(modminer->modminer_mutex);
applog(LOG_WARNING, "%s%u: Set clock speed %sto %u",
modminer->drv->name, modminer->device_id,
(delta < 0) ? "down " : (delta > 0 ? "up " : ""),
modminer->clock);
return NULL;
}
static bool modminer_fpga_init(struct thr_info *thr)
{
struct cgpu_info *modminer = thr->cgpu;
unsigned char cmd[2], buf[4];
int err, amount;
mutex_lock(modminer->modminer_mutex);
cmd[0] = MODMINER_GET_USERCODE;
cmd[1] = modminer->fpgaid;
if ((err = usb_write(modminer, (char *)cmd, 2, &amount, C_REQUESTUSERCODE)) < 0 || amount != 2) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error requesting USER code (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
return false;
}
if ((err = usb_read(modminer, (char *)buf, 4, &amount, C_GETUSERCODE)) < 0 || amount != 4) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Error reading USER code (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
return false;
}
if (memcmp(buf, BISTREAM_USER_ID, 4)) {
applog(LOG_ERR, "%s%u: FPGA not programmed",
modminer->drv->name, modminer->device_id);
if (!modminer_fpga_upload_bitstream(modminer))
return false;
mutex_unlock(modminer->modminer_mutex);
} else {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_DEBUG, "%s%u: FPGA is already programmed :)",
modminer->drv->name, modminer->device_id);
}
modminer->clock = MODMINER_DEF_CLOCK;
modminer_delta_clock(thr, MODMINER_CLOCK_SET, false, false);
thr->primary_thread = true;
return true;
}
static void get_modminer_statline_before(char *buf, size_t bufsiz, struct cgpu_info *modminer)
{
tailsprintf(buf, bufsiz, " %s%.1fC %3uMHz | ",
(modminer->temp < 10) ? " " : "",
modminer->temp,
(unsigned int)(modminer->clock));
}
static bool modminer_start_work(struct thr_info *thr, struct work *work)
{
struct cgpu_info *modminer = thr->cgpu;
struct modminer_fpga_state *state = thr->cgpu_data;
int err, amount;
char cmd[48];
bool sta;
cmd[0] = MODMINER_SEND_WORK;
cmd[1] = modminer->fpgaid;
memcpy(&cmd[2], work->midstate, 32);
memcpy(&cmd[34], work->data + 64, 12);
if (state->first_work.tv_sec == 0)
cgtime(&state->first_work);
if (state->last_nonce.tv_sec == 0)
cgtime(&state->last_nonce);
mutex_lock(modminer->modminer_mutex);
if ((err = usb_write(modminer, cmd, 46, &amount, C_SENDWORK)) < 0 || amount != 46) {
mutex_unlock(modminer->modminer_mutex);
applog(LOG_ERR, "%s%u: Start work failed (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
return false;
}
cgtime(&state->tv_workstart);
sta = get_status(modminer, "start work", C_SENDWORKSTATUS);
if (sta) {
mutex_unlock(modminer->modminer_mutex);
state->new_work = true;
}
return sta;
}
static void check_temperature(struct thr_info *thr)
{
struct cgpu_info *modminer = thr->cgpu;
struct modminer_fpga_state *state = thr->cgpu_data;
char cmd[2], temperature[2];
int tbytes, tamount;
int amount;
// Device is gone
if (modminer->usbinfo.nodev)
return;
if (state->one_byte_temp) {
cmd[0] = MODMINER_TEMP1;
tbytes = 1;
} else {
cmd[0] = MODMINER_TEMP2;
tbytes = 2;
}
cmd[1] = modminer->fpgaid;
mutex_lock(modminer->modminer_mutex);
if (usb_write(modminer, (char *)cmd, 2, &amount, C_REQUESTTEMPERATURE) == 0 && amount == 2 &&
12 years ago
usb_read(modminer, (char *)(&temperature), tbytes, &tamount, C_GETTEMPERATURE) == 0 && tamount == tbytes) {
mutex_unlock(modminer->modminer_mutex);
if (state->one_byte_temp)
modminer->temp = temperature[0];
else {
// Only accurate to 2 and a bit places
modminer->temp = roundf((temperature[1] * 256.0 + temperature[0]) / 0.128) / 1000.0;
state->tried_two_byte_temp = true;
}
if (state->overheated) {
// Limit recovery to lower than OVERHEAT so it doesn't just go straight over again
if (modminer->temp < MODMINER_RECOVER_TEMP) {
state->overheated = false;
applog(LOG_WARNING, "%s%u: Recovered, temp less than (%.1f) now %.3f",
modminer->drv->name, modminer->device_id,
MODMINER_RECOVER_TEMP, modminer->temp);
}
}
else if (modminer->temp >= MODMINER_OVERHEAT_TEMP) {
if (modminer->temp >= MODMINER_CUTOFF_TEMP) {
applog(LOG_WARNING, "%s%u: Hit thermal cutoff limit! (%.1f) at %.3f",
modminer->drv->name, modminer->device_id,
MODMINER_CUTOFF_TEMP, modminer->temp);
modminer_delta_clock(thr, MODMINER_CLOCK_CUTOFF, true, false);
state->overheated = true;
dev_error(modminer, REASON_DEV_THERMAL_CUTOFF);
} else {
applog(LOG_WARNING, "%s%u: Overheat limit (%.1f) reached %.3f",
modminer->drv->name, modminer->device_id,
MODMINER_OVERHEAT_TEMP, modminer->temp);
// If it's defined to be 0 then don't call modminer_delta_clock()
if (MODMINER_CLOCK_OVERHEAT != 0)
modminer_delta_clock(thr, MODMINER_CLOCK_OVERHEAT, true, false);
state->overheated = true;
dev_error(modminer, REASON_DEV_OVER_HEAT);
}
}
} else {
mutex_unlock(modminer->modminer_mutex);
if (!state->tried_two_byte_temp) {
state->tried_two_byte_temp = true;
state->one_byte_temp = true;
}
}
}
#define work_restart(thr) thr->work_restart
// 250Mhz is 17.17s - ensure we don't go idle
static const double processtime = 17.0;
// 160Mhz is 26.84 - when overheated ensure we don't throw away shares
static const double overheattime = 26.9;
static uint64_t modminer_process_results(struct thr_info *thr, struct work *work)
{
struct cgpu_info *modminer = thr->cgpu;
struct modminer_fpga_state *state = thr->cgpu_data;
struct timeval now;
char cmd[2];
uint32_t nonce;
uint32_t curr_hw_errors;
int err, amount, amount2;
int timeoutloop;
double timeout;
int temploop;
// Device is gone
if (modminer->usbinfo.nodev)
return -1;
// If we are overheated it will just keep checking for results
// since we can't stop the work
// The next work will not start until the temp drops
check_temperature(thr);
cmd[0] = MODMINER_CHECK_WORK;
cmd[1] = modminer->fpgaid;
timeoutloop = 0;
temploop = 0;
while (0x80085) {
mutex_lock(modminer->modminer_mutex);
if ((err = usb_write(modminer, cmd, 2, &amount, C_REQUESTWORKSTATUS)) < 0 || amount != 2) {
mutex_unlock(modminer->modminer_mutex);
// timeoutloop never resets so the timeouts can't
// accumulate much during a single item of work
if (err == LIBUSB_ERROR_TIMEOUT && ++timeoutloop < 5) {
state->timeout_fail++;
goto tryagain;
}
applog(LOG_ERR, "%s%u: Error sending (get nonce) (%d:%d)",
modminer->drv->name, modminer->device_id, amount, err);
return -1;
}
err = usb_read(modminer, (char *)(&nonce), 4, &amount, C_GETWORKSTATUS);
while (err == LIBUSB_SUCCESS && amount < 4) {
size_t remain = 4 - amount;
char *pos = ((char *)(&nonce)) + amount;
state->success_more++;
err = usb_read(modminer, pos, remain, &amount2, C_GETWORKSTATUS);
amount += amount2;
}
mutex_unlock(modminer->modminer_mutex);
if (err < 0 || amount < 4) {
// timeoutloop never resets so the timeouts can't
// accumulate much during a single item of work
if (err == LIBUSB_ERROR_TIMEOUT && ++timeoutloop < 10) {
state->timeout_fail++;
goto tryagain;
}
applog(LOG_ERR, "%s%u: Error reading (get nonce) (%d:%d)",
modminer->drv->name, modminer->device_id, amount+amount2, err);
}
if (memcmp(&nonce, "\xff\xff\xff\xff", 4)) {
// found 'something' ...
state->shares++;
curr_hw_errors = state->hw_errors;
submit_nonce(thr, work, nonce);
if (state->hw_errors > curr_hw_errors) {
cgtime(&now);
// Ignore initial errors that often happen
if (tdiff(&now, &state->first_work) < 2.0) {
state->shares = 0;
state->shares_last_hw = 0;
state->hw_errors = 0;
} else {
state->shares_last_hw = state->shares;
if (modminer->clock > MODMINER_DEF_CLOCK || state->hw_errors > 1) {
float pct = (state->hw_errors * 100.0 / (state->shares ? : 1.0));
if (pct >= MODMINER_HW_ERROR_PERCENT)
modminer_delta_clock(thr, MODMINER_CLOCK_DOWN, false, false);
}
}
} else {
cgtime(&state->last_nonce);
state->death_stage_one = false;
// If we've reached the required good shares in a row then clock up
if (((state->shares - state->shares_last_hw) >= state->shares_to_good) &&
modminer->temp < MODMINER_TEMP_UP_LIMIT)
modminer_delta_clock(thr, MODMINER_CLOCK_UP, false, false);
}
} else {
// on rare occasions - the MMQ can just stop returning valid nonces
double death = ITS_DEAD_JIM * (state->death_stage_one ? 2.0 : 1.0);
cgtime(&now);
if (tdiff(&now, &state->last_nonce) >= death) {
if (state->death_stage_one) {
modminer_delta_clock(thr, MODMINER_CLOCK_DEAD, false, true);
applog(LOG_ERR, "%s%u: DEATH clock down",
modminer->drv->name, modminer->device_id);
// reset the death info and DISABLE it
state->last_nonce.tv_sec = 0;
state->last_nonce.tv_usec = 0;
state->death_stage_one = false;
return -1;
} else {
modminer_delta_clock(thr, MODMINER_CLOCK_DEAD, false, true);
applog(LOG_ERR, "%s%u: death clock down",
modminer->drv->name, modminer->device_id);
state->death_stage_one = true;
}
}
}
tryagain:
if (work_restart(thr))
break;
12 years ago
if (state->overheated == true) {
// don't check every time (every ~1/2 sec)
if (++temploop > 4) {
check_temperature(thr);
temploop = 0;
}
}
if (state->overheated == true)
timeout = overheattime;
else
timeout = processtime;
cgtime(&now);
if (tdiff(&now, &state->tv_workstart) > timeout)
break;
// 1/10th sec to lower CPU usage
cgsleep_ms(100);
if (work_restart(thr))
break;
}
struct timeval tv_workend, elapsed;
cgtime(&tv_workend);
timersub(&tv_workend, &state->tv_workstart, &elapsed);
// Not exact since the clock may have changed ... but close enough I guess
uint64_t hashes = (uint64_t)modminer->clock * (((uint64_t)elapsed.tv_sec * 1000000) + elapsed.tv_usec);
// Overheat will complete the nonce range
if (hashes > 0xffffffff)
hashes = 0xffffffff;
work->blk.nonce = 0xffffffff;
return hashes;
}
static int64_t modminer_scanhash(struct thr_info *thr, struct work *work, int64_t __maybe_unused max_nonce)
{
struct modminer_fpga_state *state = thr->cgpu_data;
struct timeval tv1, tv2;
int64_t hashes;
// Device is gone
if (thr->cgpu->usbinfo.nodev)
return -1;
// Don't start new work if overheated
if (state->overheated == true) {
cgtime(&tv1);
while (state->overheated == true) {
check_temperature(thr);
// Device is gone
if (thr->cgpu->usbinfo.nodev)
return -1;
if (state->overheated == true) {
cgtime(&tv2);
// give up on this work item after 30s
if (work_restart(thr) || tdiff(&tv2, &tv1) > 30)
return 0;
// Give it 1s rest then check again
cgsleep_ms(1000);
}
}
}
if (!modminer_start_work(thr, work))
return -1;
hashes = modminer_process_results(thr, work);
if (hashes == -1)
return hashes;
return hashes;
}
static void modminer_hw_error(struct thr_info *thr)
{
struct modminer_fpga_state *state = thr->cgpu_data;
state->hw_errors++;
}
static void modminer_fpga_shutdown(struct thr_info *thr)
{
free(thr->cgpu_data);
thr->cgpu_data = NULL;
}
static char *modminer_set_device(struct cgpu_info *modminer, char *option, char *setting, char *replybuf)
{
const char *ret;
int val;
if (strcasecmp(option, "help") == 0) {
sprintf(replybuf, "clock: range %d-%d and a multiple of 2",
MODMINER_MIN_CLOCK, MODMINER_MAX_CLOCK);
return replybuf;
}
if (strcasecmp(option, "clock") == 0) {
if (!setting || !*setting) {
sprintf(replybuf, "missing clock setting");
return replybuf;
}
val = atoi(setting);
if (val < MODMINER_MIN_CLOCK || val > MODMINER_MAX_CLOCK || (val & 1) != 0) {
sprintf(replybuf, "invalid clock: '%s' valid range %d-%d and a multiple of 2",
setting, MODMINER_MIN_CLOCK, MODMINER_MAX_CLOCK);
return replybuf;
}
val -= (int)(modminer->clock);
ret = modminer_delta_clock(modminer->thr[0], val, false, true);
if (ret) {
sprintf(replybuf, "Set clock failed: %s", ret);
return replybuf;
} else
return NULL;
}
sprintf(replybuf, "Unknown option: %s", option);
return replybuf;
}
struct device_drv modminer_drv = {
.drv_id = DRIVER_MODMINER,
.dname = "ModMiner",
.name = "MMQ",
.drv_detect = modminer_detect,
.get_statline_before = get_modminer_statline_before,
.set_device = modminer_set_device,
.thread_prepare = modminer_fpga_prepare,
.thread_init = modminer_fpga_init,
.scanhash = modminer_scanhash,
.hw_error = modminer_hw_error,
.thread_shutdown = modminer_fpga_shutdown,
};