OpenCL GPU miner
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/*
* Copyright 2013 Andrew Smith
* Copyright 2013 Con Kolivas
* Copyright 2013 Chris Savery
*
* 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 <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 <math.h>
#include "config.h"
#ifdef WIN32
#include <windows.h>
#endif
#include "compat.h"
#include "miner.h"
#include "usbutils.h"
#define K1 "K1"
#define K16 "K16"
#define K64 "K64"
#define MIDSTATE_BYTES 32
#define MERKLE_OFFSET 64
#define MERKLE_BYTES 12
#define REPLY_SIZE 15 // adequate for all types of replies
#define MAX_KLINES 1024 // unhandled reply limit
#define REPLY_WAIT_TIME 100 // poll interval for a cmd waiting it's reply
#define CMD_REPLY_RETRIES 8 // how many retries for cmds
#define MAX_WORK_COUNT 4 // for now, must be binary multiple and match firmware
#define TACH_FACTOR 87890 // fan rpm divisor
struct device_drv klondike_drv;
typedef struct klondike_header {
uint8_t cmd;
uint8_t dev;
uint8_t buf[REPLY_SIZE-2];
} HEADER;
#define K_2(_bytes) ((int)(_bytes[0]) + \
((int)(_bytes[1]) << 8))
#define K_4(_bytes) ((uint64_t)(_bytes[0]) + \
((uint64_t)(_bytes[1]) << 8) + \
((uint64_t)(_bytes[2]) << 16) + \
((uint64_t)(_bytes[3]) << 24))
#define K_SERIAL(_serial) K_4(_serial)
#define K_HASHCOUNT(_hashcount) K_2(_hashcount)
#define K_MAXCOUNT(_maxcount) K_2(_maxcount)
#define K_NONCE(_nonce) K_4(_nonce)
#define K_HASHCLOCK(_hashclock) K_2(_hashclock)
#define SET_HASHCLOCK(_hashclock, _value) do { \
(_hashclock)[0] = (uint8_t)((_value) & 0xff); \
(_hashclock)[1] = (uint8_t)(((_value) >> 8) & 0xff); \
} while(0)
#define KSENDHD(_add) (sizeof(char) + sizeof(uint8_t) + _add)
typedef struct klondike_id {
uint8_t cmd;
uint8_t dev;
uint8_t version;
uint8_t product[7];
uint8_t serial[4];
} IDENTITY;
typedef struct klondike_status {
uint8_t cmd;
uint8_t dev;
uint8_t state;
uint8_t chipcount;
uint8_t slavecount;
uint8_t workqc;
uint8_t workid;
uint8_t temp;
uint8_t fanspeed;
uint8_t errorcount;
uint8_t hashcount[2];
uint8_t maxcount[2];
uint8_t noise;
} WORKSTATUS;
typedef struct _worktask {
uint8_t cmd;
uint8_t dev;
uint8_t workid;
uint8_t midstate[32];
uint8_t merkle[12];
} WORKTASK;
typedef struct _workresult {
uint8_t cmd;
uint8_t dev;
uint8_t workid;
uint8_t nonce[4];
} WORKRESULT;
typedef struct klondike_cfg {
uint8_t cmd;
uint8_t dev;
uint8_t hashclock[2];
uint8_t temptarget;
uint8_t tempcritical;
uint8_t fantarget;
uint8_t pad2;
} WORKCFG;
typedef struct kline {
union {
HEADER hd;
IDENTITY id;
WORKSTATUS ws;
WORKTASK wt;
WORKRESULT wr;
WORKCFG cfg;
};
} KLINE;
typedef struct device_info {
uint32_t noncecount;
uint32_t nextworkid;
uint16_t lasthashcount;
uint64_t totalhashcount;
uint32_t rangesize;
uint32_t *chipstats;
} DEVINFO;
typedef struct klist {
struct klist *prev;
struct klist *next;
KLINE kline;
struct timeval tv_when;
int block_seq;
bool ready;
bool working;
} KLIST;
struct klondike_info {
bool shutdown;
pthread_rwlock_t stat_lock;
struct thr_info replies_thr;
cglock_t klist_lock;
KLIST *used;
KLIST *free;
int kline_count;
int used_count;
int block_seq;
KLIST *status;
DEVINFO *devinfo;
KLIST *cfg;
int noncecount;
uint64_t hashcount;
uint64_t errorcount;
uint64_t noisecount;
// us Delay from USB reply to being processed
double delay_count;
double delay_total;
double delay_min;
double delay_max;
struct timeval tv_last_nonce_received;
// Time from recieving one nonce to the next
double nonce_count;
double nonce_total;
double nonce_min;
double nonce_max;
};
static KLIST *new_klist_set(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *klist = NULL;
int i;
klist = calloc(MAX_KLINES, sizeof(*klist));
if (!klist)
quit(1, "Failed to calloc klist - when old count=%d", klninfo->kline_count);
klninfo->kline_count += MAX_KLINES;
klist[0].prev = NULL;
klist[0].next = &(klist[1]);
for (i = 1; i < MAX_KLINES-1; i++) {
klist[i].prev = &klist[i-1];
klist[i].next = &klist[i+1];
}
klist[MAX_KLINES-1].prev = &(klist[MAX_KLINES-2]);
klist[MAX_KLINES-1].next = NULL;
return klist;
}
static KLIST *allocate_kitem(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem = NULL;
int ran_out = 0;
char errbuf[1024];
cg_wlock(&klninfo->klist_lock);
if (klninfo->free == NULL) {
ran_out = klninfo->kline_count;
klninfo->free = new_klist_set(klncgpu);
snprintf(errbuf, sizeof(errbuf),
"%s%i: KLINE count exceeded %d, now %d",
klncgpu->drv->name, klncgpu->device_id,
ran_out, klninfo->kline_count);
}
kitem = klninfo->free;
klninfo->free = klninfo->free->next;
if (klninfo->free)
klninfo->free->prev = NULL;
kitem->next = klninfo->used;
kitem->prev = NULL;
if (kitem->next)
kitem->next->prev = kitem;
klninfo->used = kitem;
kitem->ready = false;
kitem->working = false;
memset((void *)&(kitem->kline), 0, sizeof(kitem->kline));
klninfo->used_count++;
cg_wunlock(&klninfo->klist_lock);
if (ran_out > 0)
applog(LOG_ERR, "%s", errbuf);
return kitem;
}
static void release_kitem(struct cgpu_info *klncgpu, KLIST *kitem)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
cg_wlock(&klninfo->klist_lock);
if (kitem == klninfo->used)
klninfo->used = kitem->next;
if (kitem->next)
kitem->next->prev = kitem->prev;
if (kitem->prev)
kitem->prev->next = kitem->next;
kitem->next = klninfo->free;
if (klninfo->free)
klninfo->free->prev = kitem;
kitem->prev = NULL;
klninfo->free = kitem;
klninfo->used_count--;
cg_wunlock(&klninfo->klist_lock);
}
static double cvtKlnToC(uint8_t temp)
{
double Rt, stein, celsius;
if (temp == 0)
return 0.0;
Rt = 1000.0 * 255.0 / (double)temp - 1000.0;
stein = log(Rt / 2200.0) / 3987.0;
stein += 1.0 / (double)(25.0 + 273.15);
celsius = (1.0 / stein) - 273.15;
// For display of bad data
if (celsius < 0.0)
celsius = 0.0;
if (celsius > 200.0)
celsius = 200.0;
return celsius;
}
static int cvtCToKln(double deg)
{
double Rt, stein, temp;
if (deg < 0.0)
deg = 0.0;
stein = 1.0 / (deg + 273.15);
stein -= 1.0 / (double)(25.0 + 273.15);
Rt = exp(stein * 3987.0) * 2200.0;
if (Rt == -1000.0)
Rt++;
temp = 1000.0 * 256.0 / (Rt + 1000.0);
if (temp > 255)
temp = 255;
if (temp < 0)
temp = 0;
return (int)temp;
}
// Change this to LOG_WARNING if you wish to always see the replies
#define READ_DEBUG LOG_DEBUG
//#define READ_DEBUG LOG_ERR
static void display_kline(struct cgpu_info *klncgpu, KLINE *kline)
{
char *hexdata;
switch (kline->hd.cmd) {
case '=':
applog(READ_DEBUG,
"%s (%s) work [%c] dev=%d workid=%d"
" nonce=0x%08x",
klncgpu->drv->dname, klncgpu->device_path,
kline->wr.cmd,
(int)(kline->wr.dev),
(int)(kline->wr.workid),
(unsigned int)K_NONCE(kline->wr.nonce));
break;
case 'S':
case 'W':
case 'A':
case 'E':
applog(READ_DEBUG,
"%s (%s) status [%c] dev=%d chips=%d"
" slaves=%d workcq=%d workid=%d temp=%d fan=%d"
" errors=%d hashes=%d max=%d noise=%d",
klncgpu->drv->dname, klncgpu->device_path,
kline->ws.cmd,
(int)(kline->ws.dev),
(int)(kline->ws.chipcount),
(int)(kline->ws.slavecount),
(int)(kline->ws.workqc),
(int)(kline->ws.workid),
(int)(kline->ws.temp),
(int)(kline->ws.fanspeed),
(int)(kline->ws.errorcount),
K_HASHCOUNT(kline->ws.hashcount),
K_MAXCOUNT(kline->ws.maxcount),
(int)(kline->ws.noise));
break;
case 'C':
applog(READ_DEBUG,
"%s (%s) config [%c] dev=%d clock=%d"
" temptarget=%d tempcrit=%d fan=%d",
klncgpu->drv->dname, klncgpu->device_path,
kline->cfg.cmd,
(int)(kline->cfg.dev),
K_HASHCLOCK(kline->cfg.hashclock),
(int)(kline->cfg.temptarget),
(int)(kline->cfg.tempcritical),
(int)(kline->cfg.fantarget));
break;
case 'I':
applog(READ_DEBUG,
"%s (%s) info [%c] version=0x%02x prod=%.7s"
" serial=0x%08x",
klncgpu->drv->dname, klncgpu->device_path,
kline->hd.cmd,
(int)(kline->id.version),
kline->id.product,
(unsigned int)K_SERIAL(kline->id.serial));
break;
default:
hexdata = bin2hex((unsigned char *)&(kline->hd.dev), REPLY_SIZE - 1);
applog(LOG_ERR,
"%s (%s) [%c:%s] unknown and ignored",
klncgpu->drv->dname, klncgpu->device_path,
kline->hd.cmd, hexdata);
free(hexdata);
break;
}
}
static KLIST *SendCmdGetReply(struct cgpu_info *klncgpu, KLINE *kline, int datalen)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem;
int retries = CMD_REPLY_RETRIES;
int err, amt, writ;
if (klncgpu->usbinfo.nodev)
return NULL;
writ = KSENDHD(datalen);
err = usb_write(klncgpu, (char *)kline, writ, &amt, C_REQUESTRESULTS);
if (err < 0 || amt != writ) {
applog(LOG_ERR, "%s (%s) Cmd:%c Dev:%d, write failed (%d:%d:%d)",
klncgpu->drv->dname, klncgpu->device_path,
kline->hd.cmd, (int)kline->hd.dev,
writ, amt, err);
}
while (retries-- > 0 && klninfo->shutdown == false) {
cgsleep_ms(REPLY_WAIT_TIME);
cg_rlock(&klninfo->klist_lock);
kitem = klninfo->used;
while (kitem) {
if (kitem->kline.hd.cmd == kline->hd.cmd &&
kitem->kline.hd.dev == kline->hd.dev &&
kitem->ready == true && kitem->working == false) {
kitem->working = true;
cg_runlock(&klninfo->klist_lock);
return kitem;
}
kitem = kitem->next;
}
cg_runlock(&klninfo->klist_lock);
}
return NULL;
}
static bool klondike_get_stats(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem;
KLINE kline;
int slaves, dev;
if (klncgpu->usbinfo.nodev || klninfo->status == NULL)
return false;
applog(LOG_DEBUG, "Klondike getting status");
slaves = klninfo->status[0].kline.ws.slavecount;
// loop thru devices and get status for each
for (dev = 0; dev <= slaves; dev++) {
kline.hd.cmd = 'S';
kline.hd.dev = dev;
kitem = SendCmdGetReply(klncgpu, &kline, 0);
if (kitem != NULL) {
wr_lock(&(klninfo->stat_lock));
memcpy((void *)(&(klninfo->status[dev])),
(void *)kitem,
sizeof(klninfo->status[dev]));
wr_unlock(&(klninfo->stat_lock));
release_kitem(klncgpu, kitem);
kitem = NULL;
}
}
// todo: detect slavecount change and realloc space
return true;
}
static bool klondike_init(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem;
KLINE kline;
int slaves, dev;
kline.hd.cmd = 'S';
kline.hd.dev = 0;
kitem = SendCmdGetReply(klncgpu, &kline, 0);
if (kitem == NULL)
return false;
slaves = kitem->kline.ws.slavecount;
release_kitem(klncgpu, kitem);
kitem = NULL;
if (klninfo->status == NULL) {
applog(LOG_DEBUG, "Klondike initializing data");
// alloc space for status, devinfo and cfg for master and slaves
klninfo->status = calloc(slaves+1, sizeof(KLIST));
if (unlikely(!klninfo->status))
quit(1, "Failed to calloc status array in klondke_get_stats");
klninfo->devinfo = calloc(slaves+1, sizeof(DEVINFO));
if (unlikely(!klninfo->devinfo))
quit(1, "Failed to calloc devinfo array in klondke_get_stats");
klninfo->cfg = calloc(slaves+1, sizeof(KLIST));
if (unlikely(!klninfo->cfg))
quit(1, "Failed to calloc cfg array in klondke_get_stats");
}
// zero init triggers read back only
memset(&(kline.cfg), 0, sizeof(kline.cfg));
kline.cfg.cmd = 'C';
int size = 2;
// boundaries are checked by device, with valid values returned
if (opt_klondike_options != NULL) {
int hashclock;
double temp1, temp2;
sscanf(opt_klondike_options, "%d:%lf:%lf:%"SCNu8,
&hashclock,
&temp1, &temp2,
&kline.cfg.fantarget);
SET_HASHCLOCK(kline.cfg.hashclock, hashclock);
kline.cfg.temptarget = cvtCToKln(temp1);
kline.cfg.tempcritical = cvtCToKln(temp2);
kline.cfg.fantarget = (int)255*kline.cfg.fantarget/100;
size = sizeof(kline.cfg) - 2;
}
for (dev = 0; dev <= slaves; dev++) {
kline.cfg.dev = dev;
kitem = SendCmdGetReply(klncgpu, &kline, size);
if (kitem != NULL) {
memcpy((void *)&(klninfo->cfg[dev]), kitem, sizeof(klninfo->cfg[dev]));
applog(LOG_WARNING, "Klondike config (%d: Clk: %d, T:%.0lf, C:%.0lf, F:%d)",
dev, K_HASHCLOCK(klninfo->cfg[dev].kline.cfg.hashclock),
cvtKlnToC(klninfo->cfg[dev].kline.cfg.temptarget),
cvtKlnToC(klninfo->cfg[dev].kline.cfg.tempcritical),
(int)100*klninfo->cfg[dev].kline.cfg.fantarget/256);
release_kitem(klncgpu, kitem);
kitem = NULL;
}
}
klondike_get_stats(klncgpu);
for (dev = 0; dev <= slaves; dev++) {
klninfo->devinfo[dev].rangesize = ((uint64_t)1<<32) / klninfo->status[dev].kline.ws.chipcount;
klninfo->devinfo[dev].chipstats = calloc(klninfo->status[dev].kline.ws.chipcount*2 , sizeof(uint32_t));
}
int tries = 2;
bool ok = false;
kline.hd.cmd = 'E';
kline.hd.dev = 0;
kline.hd.buf[0] = '1';
while (tries-- > 0) {
kitem = SendCmdGetReply(klncgpu, &kline, 1);
if (kitem) {
release_kitem(klncgpu, kitem);
kitem = NULL;
ok = true;
break;
}
}
if (!ok)
applog(LOG_ERR, "%s%i: failed to enable", klncgpu->drv->name, klncgpu->device_id);
return ok;
}
static bool klondike_detect_one(struct libusb_device *dev, struct usb_find_devices *found)
{
struct cgpu_info *klncgpu = usb_alloc_cgpu(&klondike_drv, 1);
struct klondike_info *klninfo = NULL;
if (unlikely(!klncgpu))
quit(1, "Failed to calloc klncgpu in klondike_detect_one");
klninfo = calloc(1, sizeof(*klninfo));
if (unlikely(!klninfo))
quit(1, "Failed to calloc klninfo in klondke_detect_one");
klncgpu->device_data = (void *)klninfo;
klninfo->free = new_klist_set(klncgpu);
if (usb_init(klncgpu, dev, found)) {
int sent, recd, err;
KLIST kitem;
int attempts = 0;
while (attempts++ < 3) {
err = usb_write(klncgpu, "I", 2, &sent, C_REQUESTRESULTS);
if (err < 0 || sent != 2) {
applog(LOG_ERR, "%s (%s) detect write failed (%d:%d)",
klncgpu->drv->dname,
klncgpu->device_path,
sent, err);
}
cgsleep_ms(REPLY_WAIT_TIME*10);
err = usb_read(klncgpu, (char *)&(kitem.kline), REPLY_SIZE, &recd, C_GETRESULTS);
if (err < 0) {
applog(LOG_ERR, "%s (%s) detect read failed (%d:%d)",
klncgpu->drv->dname,
klncgpu->device_path,
recd, err);
} else if (recd < 1) {
applog(LOG_ERR, "%s (%s) detect empty reply (%d)",
klncgpu->drv->dname,
klncgpu->device_path,
recd);
} else if (kitem.kline.hd.cmd == 'I' && kitem.kline.hd.dev == 0) {
display_kline(klncgpu, &kitem.kline);
applog(LOG_DEBUG, "%s (%s) detect successful",
klncgpu->drv->dname,
klncgpu->device_path);
if (!add_cgpu(klncgpu))
break;
update_usb_stats(klncgpu);
applog(LOG_DEBUG, "Klondike cgpu added");
cglock_init(&klninfo->klist_lock);
return true;
}
}
usb_uninit(klncgpu);
}
free(klninfo->free);
free(klninfo);
free(klncgpu);
return false;
}
static void klondike_detect(bool __maybe_unused hotplug)
{
usb_detect(&klondike_drv, klondike_detect_one);
}
static void klondike_identify(__maybe_unused struct cgpu_info *klncgpu)
{
/*
KLINE kline;
kline.hd.cmd = 'I';
kline.hd.dev = 0;
SendCmdGetReply(klncgpu, &kline, KSENDHD(0));
*/
}
static void klondike_check_nonce(struct cgpu_info *klncgpu, KLIST *kitem)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
struct work *work, *tmp;
KLINE *kline = &(kitem->kline);
struct timeval tv_now;
double us_diff;
uint32_t nonce = K_NONCE(kline->wr.nonce) - 0xC0;
applog(LOG_DEBUG, "Klondike FOUND NONCE (%02x:%08x)",
kline->wr.workid, (unsigned int)nonce);
HASH_ITER(hh, klncgpu->queued_work, work, tmp) {
if (work->queued && (work->subid == (kline->wr.dev*256 + kline->wr.workid))) {
wr_lock(&(klninfo->stat_lock));
klninfo->devinfo[kline->wr.dev].noncecount++;
klninfo->noncecount++;
wr_unlock(&(klninfo->stat_lock));
// kline->wr.nonce = le32toh(kline->wr.nonce - 0xC0);
applog(LOG_DEBUG, "Klondike SUBMIT NONCE (%02x:%08x)",
kline->wr.workid, (unsigned int)nonce);
cgtime(&tv_now);
bool ok = submit_nonce(klncgpu->thr[0], work, nonce);
applog(LOG_DEBUG, "Klondike chip stats %d, %08x, %d, %d",
kline->wr.dev, (unsigned int)nonce,
klninfo->devinfo[kline->wr.dev].rangesize,
klninfo->status[kline->wr.dev].kline.ws.chipcount);
klninfo->devinfo[kline->wr.dev].chipstats[(nonce / klninfo->devinfo[kline->wr.dev].rangesize) + (ok ? 0 : klninfo->status[kline->wr.dev].kline.ws.chipcount)]++;
us_diff = us_tdiff(&tv_now, &(kitem->tv_when));
if (klninfo->delay_count == 0) {
klninfo->delay_min = us_diff;
klninfo->delay_max = us_diff;
} else {
if (klninfo->delay_min > us_diff)
klninfo->delay_min = us_diff;
if (klninfo->delay_max < us_diff)
klninfo->delay_max = us_diff;
}
klninfo->delay_count++;
klninfo->delay_total += us_diff;
if (klninfo->nonce_count > 0) {
us_diff = us_tdiff(&(kitem->tv_when), &(klninfo->tv_last_nonce_received));
if (klninfo->nonce_count == 1) {
klninfo->nonce_min = us_diff;
klninfo->nonce_max = us_diff;
} else {
if (klninfo->nonce_min > us_diff)
klninfo->nonce_min = us_diff;
if (klninfo->nonce_max < us_diff)
klninfo->nonce_max = us_diff;
}
klninfo->nonce_total += us_diff;
}
klninfo->nonce_count++;
memcpy(&(klninfo->tv_last_nonce_received), &(kitem->tv_when),
sizeof(klninfo->tv_last_nonce_received));
return;
}
}
applog(LOG_ERR, "%s%i:%d unknown work (%02x:%08x) - ignored",
klncgpu->drv->name, klncgpu->device_id,
kline->wr.dev, kline->wr.workid, (unsigned int)nonce);
//inc_hw_errors(klncgpu->thr[0]);
}
// thread to keep looking for replies
static void *klondike_get_replies(void *userdata)
{
struct cgpu_info *klncgpu = (struct cgpu_info *)userdata;
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem = NULL;
char *hexdata;
int err, recd;
applog(LOG_ERR, "Klondike listening for replies");
while (klninfo->shutdown == false) {
if (klncgpu->usbinfo.nodev)
return NULL;
if (kitem == NULL)
kitem = allocate_kitem(klncgpu);
else
memset((void *)&(kitem->kline), 0, sizeof(kitem->kline));
err = usb_read(klncgpu, (char *)&(kitem->kline), REPLY_SIZE, &recd, C_GETRESULTS);
if (!err && recd == REPLY_SIZE) {
cgtime(&(kitem->tv_when));
kitem->block_seq = klninfo->block_seq;
if (opt_log_level <= READ_DEBUG) {
hexdata = bin2hex((unsigned char *)&(kitem->kline.hd.dev), recd-1);
applog(READ_DEBUG, "%s (%s) reply [%c:%s]",
klncgpu->drv->dname, klncgpu->device_path,
kitem->kline.hd.cmd, hexdata);
free(hexdata);
}
switch (kitem->kline.hd.cmd) {
case '=':
klondike_check_nonce(klncgpu, kitem);
display_kline(klncgpu, &kitem->kline);
break;
case 'S':
case 'W':
case 'A':
case 'E':
wr_lock(&(klninfo->stat_lock));
klninfo->errorcount += kitem->kline.ws.errorcount;
klninfo->noisecount += kitem->kline.ws.noise;
wr_unlock(&(klninfo->stat_lock));
display_kline(klncgpu, &kitem->kline);
kitem->ready = true;
kitem = NULL;
break;
case 'C':
display_kline(klncgpu, &kitem->kline);
kitem->ready = true;
kitem = NULL;
break;
case 'I':
display_kline(klncgpu, &kitem->kline);
kitem->ready = true;
kitem = NULL;
break;
default:
display_kline(klncgpu, &kitem->kline);
break;
}
}
}
return NULL;
}
static void klondike_flush_work(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem;
KLINE kline;
int slaves, dev;
klninfo->block_seq++;
applog(LOG_DEBUG, "Klondike flushing work");
slaves = klninfo->status[0].kline.ws.slavecount;
kline.hd.cmd = 'A';
for (dev = 0; dev <= slaves; dev++) {
kline.hd.dev = dev;
kitem = SendCmdGetReply(klncgpu, &kline, KSENDHD(0));
if (kitem != NULL) {
wr_lock(&(klninfo->stat_lock));
memcpy((void *)&(klninfo->status[dev]),
kitem,
sizeof(klninfo->status[dev]));
wr_unlock(&(klninfo->stat_lock));
release_kitem(klncgpu, kitem);
kitem = NULL;
}
}
}
static bool klondike_thread_prepare(struct thr_info *thr)
{
struct cgpu_info *klncgpu = thr->cgpu;
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
if (thr_info_create(&(klninfo->replies_thr), NULL, klondike_get_replies, (void *)klncgpu)) {
applog(LOG_ERR, "%s%i: thread create failed", klncgpu->drv->name, klncgpu->device_id);
return false;
}
pthread_detach(klninfo->replies_thr.pth);
// let the listening get started
cgsleep_ms(100);
return klondike_init(klncgpu);
}
static bool klondike_thread_init(struct thr_info *thr)
{
struct cgpu_info *klncgpu = thr->cgpu;
if (klncgpu->usbinfo.nodev)
return false;
klondike_flush_work(klncgpu);
return true;
}
static void klondike_shutdown(struct thr_info *thr)
{
struct cgpu_info *klncgpu = thr->cgpu;
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
KLIST *kitem;
KLINE kline;
int dev;
applog(LOG_DEBUG, "Klondike shutting down work");
kline.hd.cmd = 'E';
for (dev = 0; dev <= klninfo->status[0].kline.ws.slavecount; dev++) {
kline.hd.dev = dev;
kline.hd.buf[0] = '0';
kitem = SendCmdGetReply(klncgpu, &kline, KSENDHD(1));
if (kitem)
release_kitem(klncgpu, kitem);
}
klncgpu->shutdown = klninfo->shutdown = true;
}
static void klondike_thread_enable(struct thr_info *thr)
{
struct cgpu_info *klncgpu = thr->cgpu;
if (klncgpu->usbinfo.nodev)
return;
/*
KLINE kline;
kline.hd.cmd = 'E';
kline.hd.dev = dev;
kline.hd.buf[0] = '0';
kitem = SendCmdGetReply(klncgpu, &kline, KSENDHD(1));
*/
}
static bool klondike_send_work(struct cgpu_info *klncgpu, int dev, struct work *work)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
struct work *tmp;
KLINE kline;
if (klncgpu->usbinfo.nodev)
return false;
kline.wt.cmd = 'W';
kline.wt.dev = dev;
memcpy(kline.wt.midstate, work->midstate, MIDSTATE_BYTES);
memcpy(kline.wt.merkle, work->data + MERKLE_OFFSET, MERKLE_BYTES);
kline.wt.workid = (uint8_t)(klninfo->devinfo[dev].nextworkid++ & 0xFF);
work->subid = dev*256 + kline.wt.workid;
if (opt_log_level <= LOG_DEBUG) {
char *hexdata = bin2hex((void *)&kline.wt, sizeof(kline.wt));
applog(LOG_DEBUG, "WORKDATA: %s", hexdata);
free(hexdata);
}
applog(LOG_DEBUG, "Klondike sending work (%d:%02x)", dev, kline.wt.workid);
KLIST *kitem = SendCmdGetReply(klncgpu, &kline, sizeof(kline.wt));
if (kitem != NULL) {
wr_lock(&(klninfo->stat_lock));
memcpy((void *)&(klninfo->status[dev]), kitem, sizeof(klninfo->status[dev]));
wr_unlock(&(klninfo->stat_lock));
release_kitem(klncgpu, kitem);
kitem = NULL;
// remove old work
HASH_ITER(hh, klncgpu->queued_work, work, tmp) {
if (work->queued && (work->subid == (int)(dev*256 + ((klninfo->devinfo[dev].nextworkid-2*MAX_WORK_COUNT) & 0xFF))))
work_completed(klncgpu, work);
}
return true;
}
return false;
}
static bool klondike_queue_full(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
struct work *work = NULL;
int dev, queued, slaves;
slaves = klninfo->status[0].kline.ws.slavecount;
for (queued = 0; queued < MAX_WORK_COUNT-1; queued++)
for (dev = 0; dev <= slaves; dev++)
if (klninfo->status[dev].kline.ws.workqc <= queued) {
if (!work)
work = get_queued(klncgpu);
if (unlikely(!work))
return false;
if (klondike_send_work(klncgpu, dev, work)) {
work = NULL;
break;
}
}
return true;
}
static int64_t klondike_scanwork(struct thr_info *thr)
{
struct cgpu_info *klncgpu = thr->cgpu;
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
int64_t newhashcount = 0;
int dev, slaves;
if (klncgpu->usbinfo.nodev)
return -1;
restart_wait(thr, 200);
if (klninfo->status != NULL) {
rd_lock(&(klninfo->stat_lock));
slaves = klninfo->status[0].kline.ws.slavecount;
for (dev = 0; dev <= slaves; dev++) {
uint64_t newhashdev = 0, hashcount;
int maxcount;
hashcount = K_HASHCOUNT(klninfo->status[dev].kline.ws.hashcount);
maxcount = K_MAXCOUNT(klninfo->status[dev].kline.ws.maxcount);
if (klninfo->devinfo[dev].lasthashcount > hashcount) // todo: chg this to check workid for wrapped instead
newhashdev += maxcount; // hash counter wrapped
newhashdev += hashcount - klninfo->devinfo[dev].lasthashcount;
klninfo->devinfo[dev].lasthashcount = hashcount;
if (maxcount != 0)
klninfo->hashcount += (newhashdev << 32) / maxcount;
// todo: check stats for critical conditions
}
newhashcount += 0xffffffffull * (uint64_t)klninfo->noncecount;
klninfo->noncecount = 0;
rd_unlock(&(klninfo->stat_lock));
}
return newhashcount;
}
static void get_klondike_statline_before(char *buf, size_t siz, struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
uint8_t temp = 0xFF;
uint16_t fan = 0;
uint16_t clock = 0;
int dev, slaves;
char tmp[16];
if (klninfo->status == NULL) {
blank_get_statline_before(buf, siz, klncgpu);
return;
}
rd_lock(&(klninfo->stat_lock));
slaves = klninfo->status[0].kline.ws.slavecount;
for (dev = 0; dev <= slaves; dev++) {
if (klninfo->status[dev].kline.ws.temp < temp)
temp = klninfo->status[dev].kline.ws.temp;
fan += klninfo->cfg[dev].kline.cfg.fantarget;
clock += (uint16_t)K_HASHCLOCK(klninfo->cfg[dev].kline.cfg.hashclock);
}
fan /= slaves + 1;
clock /= slaves + 1;
rd_unlock(&(klninfo->stat_lock));
snprintf(tmp, sizeof(tmp), "%2.0fC", cvtKlnToC(temp));
if (strlen(tmp) < 4)
strcat(tmp, " ");
tailsprintf(buf, siz, "%3dMHz %3d%% %s| ", (int)clock, fan*100/255, tmp);
}
static struct api_data *klondike_api_stats(struct cgpu_info *klncgpu)
{
struct klondike_info *klninfo = (struct klondike_info *)(klncgpu->device_data);
struct api_data *root = NULL;
char buf[32];
int dev, slaves;
if (klninfo->status == NULL)
return NULL;
rd_lock(&(klninfo->stat_lock));
slaves = klninfo->status[0].kline.ws.slavecount;
for (dev = 0; dev <= slaves; dev++) {
float fTemp = cvtKlnToC(klninfo->status[dev].kline.ws.temp);
sprintf(buf, "Temp %d", dev);
root = api_add_temp(root, buf, &fTemp, true);
double dClk = (double)K_HASHCLOCK(klninfo->cfg[dev].kline.cfg.hashclock);
sprintf(buf, "Clock %d", dev);
root = api_add_freq(root, buf, &dClk, true);
unsigned int iFan = (unsigned int)100 * klninfo->cfg[dev].kline.cfg.fantarget / 255;
sprintf(buf, "Fan Percent %d", dev);
root = api_add_int(root, buf, (int *)(&iFan), true);
iFan = 0;
if (klninfo->status[dev].kline.ws.fanspeed > 0)
iFan = (unsigned int)TACH_FACTOR / klninfo->status[dev].kline.ws.fanspeed;
sprintf(buf, "Fan RPM %d", dev);
root = api_add_int(root, buf, (int *)(&iFan), true);
if (klninfo->devinfo[dev].chipstats != NULL) {
char data[2048];
char one[32];
int n;
sprintf(buf, "Nonces / Chip %d", dev);
data[0] = '\0';
for (n = 0; n < klninfo->status[dev].kline.ws.chipcount; n++) {
snprintf(one, sizeof(one), "%07d ", klninfo->devinfo[dev].chipstats[n]);
strcat(data, one);
}
root = api_add_string(root, buf, data, true);
sprintf(buf, "Errors / Chip %d", dev);
data[0] = '\0';
for (n = 0; n < klninfo->status[dev].kline.ws.chipcount; n++) {
snprintf(one, sizeof(one), "%07d ", klninfo->devinfo[dev].chipstats[n + klninfo->status[dev].kline.ws.chipcount]);
strcat(data, one);
}
root = api_add_string(root, buf, data, true);
}
}
root = api_add_uint64(root, "Hash Count", &(klninfo->hashcount), true);
root = api_add_uint64(root, "Error Count", &(klninfo->errorcount), true);
root = api_add_uint64(root, "Noise Count", &(klninfo->noisecount), true);
root = api_add_int(root, "KLine Limit", &(klninfo->kline_count), true);
root = api_add_int(root, "KLine Used", &(klninfo->used_count), true);
root = api_add_elapsed(root, "KQue Delay Count", &(klninfo->delay_count), true);
root = api_add_elapsed(root, "KQue Delay Total", &(klninfo->delay_total), true);
root = api_add_elapsed(root, "KQue Delay Min", &(klninfo->delay_min), true);
root = api_add_elapsed(root, "KQue Delay Max", &(klninfo->delay_max), true);
double avg;
if (klninfo->delay_count == 0)
avg = 0;
else
avg = klninfo->delay_total / klninfo->delay_count;
root = api_add_diff(root, "KQue Delay Avg", &avg, true);
root = api_add_elapsed(root, "KQue Nonce Count", &(klninfo->nonce_count), true);
root = api_add_elapsed(root, "KQue Nonce Total", &(klninfo->nonce_total), true);
root = api_add_elapsed(root, "KQue Nonce Min", &(klninfo->nonce_min), true);
root = api_add_elapsed(root, "KQue Nonce Max", &(klninfo->nonce_max), true);
if (klninfo->nonce_count == 0)
avg = 0;
else
avg = klninfo->nonce_total / klninfo->nonce_count;
root = api_add_diff(root, "KQue Nonce Avg", &avg, true);
rd_unlock(&(klninfo->stat_lock));
return root;
}
struct device_drv klondike_drv = {
.drv_id = DRIVER_klondike,
.dname = "Klondike",
.name = "KLN",
.drv_detect = klondike_detect,
.get_api_stats = klondike_api_stats,
.get_statline_before = get_klondike_statline_before,
.get_stats = klondike_get_stats,
.identify_device = klondike_identify,
.thread_prepare = klondike_thread_prepare,
.thread_init = klondike_thread_init,
.hash_work = hash_queued_work,
.scanwork = klondike_scanwork,
.queue_full = klondike_queue_full,
.flush_work = klondike_flush_work,
.thread_shutdown = klondike_shutdown,
.thread_enable = klondike_thread_enable
};