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MMQ handle over temp differently and hash longer

nfactor-troky
Kano 12 years ago
parent
commit
f3f8b4fdb4
  1. 138
      driver-modminer.c
  2. 8
      miner.h

138
driver-modminer.c

@ -29,11 +29,16 @@
#define MODMINER_CUTOFF_TEMP 60.0 #define MODMINER_CUTOFF_TEMP 60.0
#define MODMINER_OVERHEAT_TEMP 50.0 #define MODMINER_OVERHEAT_TEMP 50.0
#define MODMINER_TEMP_UP_LIMIT 48.0 #define MODMINER_RECOVER_TEMP 46.5
#define MODMINER_OVERHEAT_CLOCK -10 #define MODMINER_TEMP_UP_LIMIT 47.0
#define MODMINER_HW_ERROR_PERCENT 0.75 #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 // N.B. in the latest firmware the limit is 250
// however the voltage/temperature risks preclude that // however the voltage/temperature risks preclude that
#define MODMINER_MAX_CLOCK 230 #define MODMINER_MAX_CLOCK 230
@ -43,6 +48,8 @@
#define MODMINER_CLOCK_DOWN -2 #define MODMINER_CLOCK_DOWN -2
#define MODMINER_CLOCK_SET 0 #define MODMINER_CLOCK_SET 0
#define MODMINER_CLOCK_UP 2 #define MODMINER_CLOCK_UP 2
#define MODMINER_CLOCK_DEAD -6
#define MODMINER_CLOCK_CUTOFF -10
// Commands // Commands
#define MODMINER_PING "\x00" #define MODMINER_PING "\x00"
@ -568,8 +575,8 @@ static bool modminer_fpga_prepare(struct thr_info *thr)
/* /*
* Clocking rules: * Clocking rules:
* If device exceeds cutoff temp - TODO: ?stop sending work - * If device exceeds cutoff or overheat temp - stop sending work until it cools
* and decrease the clock by MODMINER_OVERHEAT_CLOCK * decrease the clock by MODMINER_CLOCK_CUTOFF/MODMINER_CLOCK_OVERHEAT
* for when it restarts * for when it restarts
* *
* When to clock down: * When to clock down:
@ -584,7 +591,7 @@ static bool modminer_fpga_prepare(struct thr_info *thr)
* *
* When to clock up: * When to clock up:
* If device gets shares_to_good good shares in a row * If device gets shares_to_good good shares in a row
* and temp <= MODMINER_TEMP_UP_LIMIT * and temp < MODMINER_TEMP_UP_LIMIT
* *
* N.B. clock must always be a multiple of 2 * N.B. clock must always be a multiple of 2
*/ */
@ -743,6 +750,12 @@ static bool modminer_start_work(struct thr_info *thr)
int err, amount; int err, amount;
bool sta; bool sta;
if (state->first_work.tv_sec == 0)
gettimeofday(&state->first_work, NULL);
if (state->last_nonce.tv_sec == 0)
gettimeofday(&state->last_nonce, NULL);
mutex_lock(modminer->modminer_mutex); mutex_lock(modminer->modminer_mutex);
if ((err = usb_write(modminer, (char *)(state->next_work_cmd), 46, &amount, C_SENDWORK)) < 0 || amount != 46) { if ((err = usb_write(modminer, (char *)(state->next_work_cmd), 46, &amount, C_SENDWORK)) < 0 || amount != 46) {
@ -777,7 +790,7 @@ static void check_temperature(struct thr_info *thr)
int tbytes, tamount; int tbytes, tamount;
int amount; int amount;
if (modminer->one_byte_temp) { if (state->one_byte_temp) {
cmd[0] = MODMINER_TEMP1; cmd[0] = MODMINER_TEMP1;
tbytes = 1; tbytes = 1;
} else { } else {
@ -788,50 +801,53 @@ static void check_temperature(struct thr_info *thr)
cmd[1] = modminer->fpgaid; cmd[1] = modminer->fpgaid;
mutex_lock(modminer->modminer_mutex); mutex_lock(modminer->modminer_mutex);
if (usb_write(modminer, (char *)cmd, 2, &amount, C_REQUESTTEMPERATURE) == 0 && amount == 2 if (usb_write(modminer, (char *)cmd, 2, &amount, C_REQUESTTEMPERATURE) == 0 && amount == 2 &&
&& usb_read(modminer, (char *)(&temperature), tbytes, &tamount, C_GETTEMPERATURE) == 0 && tamount == tbytes) usb_read(modminer, (char *)(&temperature), tbytes, &tamount, C_GETTEMPERATURE) == 0 && tamount == tbytes)
{ {
mutex_unlock(modminer->modminer_mutex); mutex_unlock(modminer->modminer_mutex);
if (modminer->one_byte_temp) if (state->one_byte_temp)
modminer->temp = temperature[0]; modminer->temp = temperature[0];
else { else {
// Only accurate to 2 and a bit places // Only accurate to 2 and a bit places
modminer->temp = roundf((temperature[1] * 256.0 + temperature[0]) / 0.128) / 1000.0; modminer->temp = roundf((temperature[1] * 256.0 + temperature[0]) / 0.128) / 1000.0;
modminer->tried_two_byte_temp = true; state->tried_two_byte_temp = true;
} }
if (state->overheated) { if (state->overheated) {
if (modminer->temp < MODMINER_OVERHEAT_TEMP) { // Limit recovery to lower than OVERHEAT so it doesn't just go straight over again
if (modminer->temp < MODMINER_RECOVER_TEMP) {
state->overheated = false; state->overheated = false;
applog(LOG_WARNING, "%s%u: Recovered, temp less than (%.1f) now %.3f", applog(LOG_WARNING, "%s%u: Recovered, temp less than (%.1f) now %.3f",
modminer->api->name, modminer->device_id, modminer->api->name, modminer->device_id,
MODMINER_OVERHEAT_TEMP, modminer->temp); MODMINER_RECOVER_TEMP, modminer->temp);
} }
} }
else if (modminer->temp >= MODMINER_OVERHEAT_TEMP) { else if (modminer->temp >= MODMINER_OVERHEAT_TEMP) {
if (modminer->temp >= MODMINER_CUTOFF_TEMP) { if (modminer->temp >= MODMINER_CUTOFF_TEMP) {
applog(LOG_WARNING, "%s%u: Hit thermal cutoff limit (%.1f) at %.3f, disabling!", applog(LOG_WARNING, "%s%u: Hit thermal cutoff limit! (%.1f) at %.3f",
modminer->api->name, modminer->device_id, modminer->api->name, modminer->device_id,
MODMINER_CUTOFF_TEMP, modminer->temp); MODMINER_CUTOFF_TEMP, modminer->temp);
modminer_delta_clock(thr, MODMINER_OVERHEAT_CLOCK, true); modminer_delta_clock(thr, MODMINER_CLOCK_CUTOFF, true);
state->overheated = true; state->overheated = true;
dev_error(modminer, REASON_DEV_THERMAL_CUTOFF); dev_error(modminer, REASON_DEV_THERMAL_CUTOFF);
} else { } else {
applog(LOG_WARNING, "%s%u: Overheat limit (%.1f) reached %.3f", applog(LOG_WARNING, "%s%u: Overheat limit (%.1f) reached %.3f",
modminer->api->name, modminer->device_id, modminer->api->name, modminer->device_id,
MODMINER_OVERHEAT_TEMP, modminer->temp); MODMINER_OVERHEAT_TEMP, modminer->temp);
modminer_delta_clock(thr, MODMINER_CLOCK_DOWN, true); modminer_delta_clock(thr, MODMINER_CLOCK_DOWN, true);
state->overheated = true;
dev_error(modminer, REASON_DEV_OVER_HEAT); dev_error(modminer, REASON_DEV_OVER_HEAT);
} }
} }
} else { } else {
mutex_unlock(modminer->modminer_mutex); mutex_unlock(modminer->modminer_mutex);
if (!modminer->tried_two_byte_temp) { if (!state->tried_two_byte_temp) {
modminer->tried_two_byte_temp = true; state->tried_two_byte_temp = true;
modminer->one_byte_temp = true; state->one_byte_temp = true;
} }
} }
} }
@ -843,28 +859,27 @@ static uint64_t modminer_process_results(struct thr_info *thr)
struct cgpu_info *modminer = thr->cgpu; struct cgpu_info *modminer = thr->cgpu;
struct modminer_fpga_state *state = thr->cgpu_data; struct modminer_fpga_state *state = thr->cgpu_data;
struct work *work = &state->running_work; struct work *work = &state->running_work;
struct timeval now;
char cmd[2]; char cmd[2];
uint32_t nonce; uint32_t nonce;
long iter;
uint32_t curr_hw_errors; uint32_t curr_hw_errors;
int err, amount; int err, amount;
int timeoutloop; int timeoutloop;
double processtime;
int temploop;
// 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); check_temperature(thr);
if (state->overheated == true) {
if (state->work_running)
state->work_running = false;
// Give it 5 seconds rest and wait for the next work
nmsleep(5000);
return 0;
}
cmd[0] = MODMINER_CHECK_WORK; cmd[0] = MODMINER_CHECK_WORK;
cmd[1] = modminer->fpgaid; cmd[1] = modminer->fpgaid;
iter = 200;
// 250Mhz is 17.17s
processtime = 17.0;
timeoutloop = 0; timeoutloop = 0;
temploop = 0;
while (1) { while (1) {
mutex_lock(modminer->modminer_mutex); mutex_lock(modminer->modminer_mutex);
if ((err = usb_write(modminer, cmd, 2, &amount, C_REQUESTWORKSTATUS)) < 0 || amount != 2) { if ((err = usb_write(modminer, cmd, 2, &amount, C_REQUESTWORKSTATUS)) < 0 || amount != 2) {
@ -898,39 +913,75 @@ static uint64_t modminer_process_results(struct thr_info *thr)
} }
if (memcmp(&nonce, "\xff\xff\xff\xff", 4)) { if (memcmp(&nonce, "\xff\xff\xff\xff", 4)) {
// found 'something' ...
state->shares++; state->shares++;
state->no_nonce_counter = 0;
curr_hw_errors = state->hw_errors; curr_hw_errors = state->hw_errors;
submit_nonce(thr, work, nonce); submit_nonce(thr, work, nonce);
if (state->hw_errors > curr_hw_errors) { if (state->hw_errors > curr_hw_errors) {
gettimeofday(&now, NULL);
// 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; state->shares_last_hw = state->shares;
if (modminer->clock > MODMINER_DEF_CLOCK || state->hw_errors > 1) { if (modminer->clock > MODMINER_DEF_CLOCK || state->hw_errors > 1) {
float pct = (state->hw_errors * 100.0 / (state->shares ? : 1.0)); float pct = (state->hw_errors * 100.0 / (state->shares ? : 1.0));
if (pct >= MODMINER_HW_ERROR_PERCENT) if (pct >= MODMINER_HW_ERROR_PERCENT)
modminer_delta_clock(thr, MODMINER_CLOCK_DOWN, false); modminer_delta_clock(thr, MODMINER_CLOCK_DOWN, false);
} }
}
} else { } else {
gettimeofday(&state->last_nonce, NULL);
state->death_stage_one = false;
// If we've reached the required good shares in a row then clock up // 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) && if (((state->shares - state->shares_last_hw) >= state->shares_to_good) &&
modminer->temp <= MODMINER_TEMP_UP_LIMIT) modminer->temp < MODMINER_TEMP_UP_LIMIT)
modminer_delta_clock(thr, MODMINER_CLOCK_UP, false); modminer_delta_clock(thr, MODMINER_CLOCK_UP, false);
} }
} else if (++state->no_nonce_counter > 18000) { } else {
// TODO: NFI what this is // on rare occasions - the MMQ can just stop returning valid nonces
state->no_nonce_counter = 0; double death = ITS_DEAD_JIM * (state->death_stage_one ? 2.0 : 1.0);
modminer_delta_clock(thr, MODMINER_CLOCK_DOWN, false); gettimeofday(&now, NULL);
if (tdiff(&now, &state->last_nonce) >= death) {
if (state->death_stage_one) {
modminer_delta_clock(thr, MODMINER_CLOCK_DEAD, false);
applog(LOG_ERR, "%s%u: DEATH clock down",
modminer->api->name, modminer->device_id);
applog(LOG_ERR, "%s%u: 18000 clock down", // 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);
applog(LOG_ERR, "%s%u: death clock down",
modminer->api->name, modminer->device_id); modminer->api->name, modminer->device_id);
state->death_stage_one = true;
}
}
} }
tryagain: tryagain:
if (work_restart(thr)) if (work_restart(thr))
break; break;
gettimeofday(&now, NULL);
if (tdiff(&now, &state->tv_workstart) > processtime)
break;
// don't check every time
if (state->overheated == true && ++temploop > 30) {
check_temperature(thr);
temploop = 0;
}
nmsleep(10); nmsleep(10);
if (work_restart(thr) || !--iter) if (work_restart(thr))
break; break;
} }
@ -938,6 +989,7 @@ tryagain:
gettimeofday(&tv_workend, NULL); gettimeofday(&tv_workend, NULL);
timersub(&tv_workend, &state->tv_workstart, &elapsed); 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); uint64_t hashes = (uint64_t)modminer->clock * (((uint64_t)elapsed.tv_sec * 1000000) + elapsed.tv_usec);
if (hashes > 0xffffffff) if (hashes > 0xffffffff)
hashes = 0xffffffff; hashes = 0xffffffff;
@ -955,17 +1007,27 @@ static int64_t modminer_scanhash(struct thr_info *thr, struct work *work, int64_
struct modminer_fpga_state *state = thr->cgpu_data; struct modminer_fpga_state *state = thr->cgpu_data;
int64_t hashes = 0; int64_t hashes = 0;
bool startwork; bool startwork;
struct timeval tv1, tv2;
// Don't start new work if overheated
if (state->overheated == true) { if (state->overheated == true) {
gettimeofday(&tv1, NULL);
if (state->work_running) if (state->work_running)
state->work_running = false; state->work_running = false;
while (state->overheated == true) {
check_temperature(thr); check_temperature(thr);
if (state->overheated == true) { if (state->overheated == true) {
// Give it 5 seconds rest and wait for the next work gettimeofday(&tv2, NULL);
nmsleep(5000);
// give up on this work item
if (work_restart(thr) || tdiff(&tv2, &tv1) > 30)
return 0; return 0;
// Give it 1s rest then check again
nmsleep(1000);
}
} }
} }

8
miner.h

@ -375,8 +375,6 @@ struct cgpu_info {
char fpgaid; char fpgaid;
unsigned char clock; unsigned char clock;
pthread_mutex_t *modminer_mutex; pthread_mutex_t *modminer_mutex;
bool tried_two_byte_temp;
bool one_byte_temp;
#endif #endif
#ifdef USE_BITFORCE #ifdef USE_BITFORCE
struct timeval work_start_tv; struct timeval work_start_tv;
@ -1028,7 +1026,11 @@ struct modminer_fpga_state {
uint32_t hw_errors; uint32_t hw_errors;
uint32_t shares_to_good; uint32_t shares_to_good;
struct timeval last_changed; struct timeval last_changed;
uint32_t no_nonce_counter; struct timeval last_nonce;
struct timeval first_work;
bool death_stage_one;
bool tried_two_byte_temp;
bool one_byte_temp;
}; };
#endif #endif

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