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driver-SPI-dragonmint-t1.c
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driver-SPI-dragonmint-t1.c
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/*
* cgminer SPI driver for Dragonmint T1 devices
*
* Copyright 2013, 2014 Zefir Kurtisi <[email protected]>
* Copyright 2018 Con Kolivas <[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.
*/
#include <stdlib.h>
#include <assert.h>
#include <fcntl.h>
#include <limits.h>
#include <unistd.h>
#include <stdbool.h>
#include <pthread.h>
#include "logging.h"
#include "miner.h"
#include "util.h"
#include "dragonmint_t1.h"
#include "dm_temp_ctrl.h"
#include "dm_fan_ctrl.h"
#include "sys/time.h"
#define T1_FANSPEED_INIT (opt_T1_target)
#define T1_TEMP_TARGET_INIT (60)
#define T1_TEMP_TARGET_RUN (75)
struct T1_chain *chain[MAX_CHAIN_NUM];
uint8_t chain_mask;
uint16_t T1Pll[MCOMPAT_CONFIG_MAX_CHAIN_NUM];
/* FAN CTRL */
//dragonmint_fan_temp_s g_fan_ctrl;
static volatile uint8_t g_debug_stats[MAX_CHAIN_NUM];
static int total_chains;
static int chains_tuned;
static dragonmint_reg_ctrl_t s_reg_ctrl;
hardware_version_e g_hwver;
//dragonmint_type_e g_type;
int g_reset_delay = 0xffff;
char volShowLog[MAX_CHAIN_NUM][256];
/* one global board_selector and spi context is enough */
//static struct board_selector *board_selector;
static int spi_status_err_cnt = 0;
static pthread_t fan_tid;
/*
* for now, we have one global config, defaulting values:
* - ref_clk 16MHz / sys_clk 800MHz
* - 2000 kHz SPI clock
*/
struct T1_config_options T1_config_options = {
.ref_clk_khz = 16000, .sys_clk_khz = 800000, .spi_clk_khz = 2000,
};
/* override values with --bitmine-t1-options ref:sys:spi: - use 0 for default */
static struct T1_config_options *parsed_config_options;
int chain_plug[MAX_CHAIN_NUM];
int chain_flag[MAX_CHAIN_NUM];
#define LOG_VOL_PREFIX "/tmp/log/volAnalys"
void dragonmint_log_record(int cid, void* log, int len)
{
FILE* fd;
char fileName[128] = {0};
sprintf(fileName, "%s%d.log", LOG_VOL_PREFIX, cid);
fd = fopen(fileName, "w+");
if (fd == NULL){
//applog(LOG_ERR, "Open log File%d Failed!%d", cid, errno);
applog(LOG_ERR, "Open log File%d Failed!%s", cid, strerror(errno));
return;
}
fwrite(log, len, 1, fd);
fflush(fd);
fclose(fd);
}
static void wq_enqueue(struct thr_info *thr, struct T1_chain *t1)
{
struct work *work = get_work(thr, thr->id);
struct work_queue *wq;
struct work_ent *we;
int rolls = 0;
wq = &t1->active_wq;
while (42) {
we = cgmalloc(sizeof(*we));
we->work = work;
INIT_LIST_HEAD(&we->head);
mutex_lock(&t1->lock);
list_add_tail(&we->head, &wq->head);
wq->num_elems++;
mutex_unlock(&t1->lock);
if (wq->num_elems >= t1->num_active_chips * 2) {
break;
}
if (rolls > work->drv_rolllimit) {
work = get_work(thr, thr->id);
continue;
}
work = make_clone(work);
roll_work(work);
}
}
static struct work *wq_dequeue(struct T1_chain *t1, bool sig)
{
struct work_ent *we;
struct work *work = NULL;
struct work_queue *wq = &t1->active_wq;
if (wq == NULL)
return NULL;
/* Sleep only a small duration if there is no work queued in case it's
* still refilling rather than we have no upstream work. */
if (unlikely(!wq->num_elems && sig))
cgsleep_ms(10);
mutex_lock(&t1->lock);
if (likely(wq->num_elems > 0)) {
we = list_entry(wq->head.next, struct work_ent, head);
work = we->work;
list_del(&we->head);
free(we);
wq->num_elems--;
}
if (sig)
pthread_cond_signal(&t1->cond);
mutex_unlock(&t1->lock);
return work;
}
/********** driver interface */
void exit_T1_chain(struct T1_chain *t1)
{
if (t1 == NULL)
return;
free(t1->chips);
t1->chips = NULL;
chain[t1->chain_id] = NULL;
chain_flag[t1->chain_id] = 0;
mcompat_set_led(t1->chain_id, LED_OFF);
mcompat_set_power_en(t1->chain_id, 0);
free(t1);
}
static void get_temperatures(struct T1_chain *t1)
{
int i;
int temp[MAX_CHIP_NUM] = {0};
mcompat_get_chip_temp(t1->chain_id, temp);
for (i = 0; i < t1->num_active_chips; i++)
t1->chips[i].temp = temp[i];
}
static void get_voltages(struct T1_chain *t1)
{
int i;
//configure for vsensor
mcompat_configure_tvsensor(t1->chain_id, CMD_ADDR_BROADCAST, 0);
for (i = 0; i < t1->num_active_chips; i++)
dragonmint_check_voltage(t1, i + 1, &s_reg_ctrl);
//configure for tsensor
mcompat_configure_tvsensor(t1->chain_id, CMD_ADDR_BROADCAST, 1);
dragonmint_get_voltage_stats(t1, &s_reg_ctrl);
}
static bool prechain_detect(struct T1_chain *t1, int idxpll)
{
int pll_lv_to_setspi;
int pll_lv_to_setvid;
int chain_id = t1->chain_id;
assert(pll_lv_to_setvid < idxpll);
cgsleep_us(1000);
t1->pll = 0;
t1->base_pll = idxpll;
if (opt_T1auto) {
/* Start tuning at a different voltage depending on tuning
* strategy. */
if (opt_T1_performance)
opt_T1Vol[chain_id] = TUNE_VOLT_START_PER;
else if (opt_T1_efficient)
opt_T1Vol[chain_id] = TUNE_VOLT_START_EFF;
else
opt_T1Vol[chain_id] = TUNE_VOLT_START_BAL;
}
pll_lv_to_setspi = T1_ConfigT1PLLClock(T1_PLL_SETSPI);
if (!t1_set_pll(t1, CMD_ADDR_BROADCAST, pll_lv_to_setspi))
return false;
/* Using 390K spi speed at first and raising to 1.5M at 310M PLL
* to avoid spi failure on 150M PLL */
applog(LOG_NOTICE, "chain%d: spi speed set to 1.5M", chain_id);
mcompat_set_spi_speed(chain_id, SPI_SPEED_1562K);
cgsleep_ms(10);
pll_lv_to_setvid = T1_ConfigT1PLLClock(T1_PLL_SETVID);
if (!t1_set_pll(t1, CMD_ADDR_BROADCAST, pll_lv_to_setvid))
return false;
/* Set voltage down at this point to avoid massive power draw as we
* increase frequency */
if (!opt_T1auto && opt_T1VID[chain_id]) {
/* If opt_T1VID values are set in non-auto mode, we use those
* from the config. */
mcompat_set_vid_by_step(chain_id, t1->iVid, opt_T1VID[chain_id]);
t1->iVid = opt_T1VID[chain_id];
} else {
t1->iVid = mcompat_find_chain_vid(chain_id, t1->num_active_chips,
STARTUP_VID, opt_T1Vol[chain_id]);
}
if (!t1_set_pll(t1, CMD_ADDR_BROADCAST, idxpll))
return false;
/* Now fine tune voltage to the target level as voltage will have
* changed due to changing frequency */
if (opt_T1auto || !opt_T1VID[chain_id]) {
t1->iVid = mcompat_find_chain_vid(chain_id, t1->num_active_chips,
t1->iVid, opt_T1Vol[chain_id]);
}
/* Read chip voltages */
get_voltages(t1);
applog(LOG_NOTICE, "chain%d: volt = %.1f, vid = %d after calibration", chain_id,
s_reg_ctrl.average_vol[chain_id], t1->iVid);
return true;
}
/*
* BIST_START works only once after HW reset, on subsequent calls it
* returns 0 as number of chips.
*/
static int chain_detect(struct T1_chain *t1)
{
int cid = t1->chain_id;
uint8_t n_chips = mcompat_cmd_bist_start(cid, CMD_ADDR_BROADCAST);
if (unlikely(n_chips == 0 || n_chips > MAX_CHIP_NUM)){
write_miner_ageing_status(AGEING_BIST_START_FAILED);
return 0;
}
applog(LOG_WARNING, "%d: detected %d chips", cid, n_chips);
cgsleep_ms(10);
/*
if (!mcompat_cmd_bist_collect(cid, CMD_ADDR_BROADCAST))
{
applog(LOG_WARNING, "bist collect fail");
return 0;
}
*/
applog(LOG_WARNING, "collect core success");
return n_chips;
}
static bool prepare_T1(struct T1_chain *t1, int chain_id)
{
uint8_t buffer[4] = {};
bool ret = false;
//spi speed init
applog(LOG_NOTICE, "chain%d: spi speed set to 390K", chain_id);
mcompat_set_spi_speed(chain_id, T1_SPI_SPEED_DEF);
cgsleep_ms(10);
if (!dm_cmd_resetall(chain_id, CMD_ADDR_BROADCAST, buffer)) {
applog(LOG_ERR, "failed to reset chain %d!", chain_id);
goto out;
}
if (CMD_TYPE_T1 != (buffer[0] & 0xf0)) {
applog(LOG_ERR, "incompatible chip type %02X for chain %d!", buffer[0] & 0xf0, chain_id);
goto out;
}
t1->num_chips = chain_detect(t1);
cgsleep_ms(10);
if ((t1->num_chips <= 0) || (t1->num_chips > MAX_CHIP_NUM)){
spi_status_err_cnt++;
if (chain_id == (MAX_CHAIN_NUM - 1)){
if (spi_status_err_cnt >= MAX_CHAIN_NUM){
write_miner_ageing_status(AGEING_ALL_SPI_STATUS_ERROR);
}
if ((spi_status_err_cnt >= 1) && (spi_status_err_cnt < MAX_CHAIN_NUM)){
write_miner_ageing_status(AGEING_SPI_STATUS_ERROR);
}
}
goto out;
}
if (chain_id == (MAX_CHAIN_NUM - 1)){
if (spi_status_err_cnt >= MAX_CHAIN_NUM){
write_miner_ageing_status(AGEING_ALL_SPI_STATUS_ERROR);
}
if ((spi_status_err_cnt >= 1) && (spi_status_err_cnt < MAX_CHAIN_NUM)){
write_miner_ageing_status(AGEING_SPI_STATUS_ERROR);
}
}
/* override max number of active chips if requested */
t1->num_active_chips = t1->num_chips;
if (T1_config_options.override_chip_num > 0 &&
t1->num_chips > T1_config_options.override_chip_num) {
t1->num_active_chips = T1_config_options.override_chip_num;
applog(LOG_WARNING, "%d: limiting chain to %d chips",
chain_id, t1->num_active_chips);
}
/* Free this in case we are re-initialising a chain */
free(t1->chips);
t1->chips = cgcalloc(t1->num_active_chips, sizeof(struct T1_chip));
ret = true;
out:
return ret;
}
static struct T1_chain *pre_init_T1_chain(int chain_id)
{
struct T1_chain *t1 = cgcalloc(sizeof(*t1), 1);
applog(LOG_INFO, "pre %d: T1 init chain", chain_id);
t1->chain_id = chain_id;
if (!prepare_T1(t1, chain_id)) {
exit_T1_chain(t1);
t1 = NULL;
}
return t1;
}
static bool init_T1_chain(struct T1_chain *t1)
{
int i;
uint8_t src_reg[REG_LENGTH] = {0};
uint8_t reg[REG_LENGTH] = {0};
int chain_id = t1->chain_id;
int num_chips;
bool ret = false;
applog(LOG_INFO, "%d: T1 init chain", chain_id);
applog(LOG_NOTICE, "chain%d: spi speed set to 6.25M", chain_id);
mcompat_set_spi_speed(chain_id, SPI_SPEED_6250K);
cgsleep_ms(1);
#ifdef USE_BISTMASK
dm_cmd_resetbist(chain_id, CMD_ADDR_BROADCAST, reg);
//cgsleep_ms(120);
sleep(1);
//bist mask
mcompat_cmd_read_register(chain_id, 0x01, reg, REG_LENGTH);
memcpy(src_reg, reg, REG_LENGTH);
src_reg[7] = src_reg[7] | 0x10;
mcompat_cmd_write_register(chain_id, CMD_ADDR_BROADCAST, src_reg, REG_LENGTH);
cgsleep_us(200);
#endif
applog(LOG_DEBUG, "%d: T1 init chain", chain_id);
num_chips = chain_detect(t1);
cgsleep_ms(10);
if (num_chips != 0 && num_chips != t1->num_chips) {
applog(LOG_WARNING, "T1 %d: Num chips failure", chain_id);
goto out;
}
if (!mcompat_cmd_bist_fix(chain_id, CMD_ADDR_BROADCAST)) {
write_miner_ageing_status(AGEING_BIST_FIX_FAILED);
goto out;
}
cgsleep_us(200);
#if 0
sprintf(volShowLog[chain_id], "+ %2d | %8f | %8f | %8f |",chain_id, \
s_reg_ctrl.highest_vol[chain_id],s_reg_ctrl.average_vol[chain_id],s_reg_ctrl.lowest_vol[chain_id]);
dragonmint_log_record(chain_id, volShowLog[chain_id], strlen(volShowLog[0]));
#endif
applog(LOG_WARNING,
"Chain %d Voltage information. Highest Vol:%.0f, Average Vol:%.0f, Lowest Vol:%.0f",
chain_id, s_reg_ctrl.highest_vol[chain_id], s_reg_ctrl.average_vol[chain_id],
s_reg_ctrl.lowest_vol[chain_id]);
/* Reset value in case we are re-initialising */
t1->num_cores = 0;
for (i = 0; i < t1->num_active_chips; i++)
check_chip(t1, i);
applog(LOG_WARNING, "%d: found %d chips with total %d active cores",
chain_id, t1->num_active_chips, t1->num_cores);
if (!opt_T1auto)
t1->VidOptimal = t1->pllOptimal = true;
ret = true;
out:
return ret;
}
/* Asynchronous work generation since get_work is a blocking function */
static void *T1_work_thread(void *arg)
{
struct cgpu_info *cgpu = arg;
struct T1_chain *t1 = cgpu->device_data;
char tname[16];
sprintf(tname, "T1_%dwork", t1->chain_id);
RenameThread(tname);
mutex_lock(&t1->lock);
while (!pthread_cond_wait(&t1->cond, &t1->lock)) {
mutex_unlock(&t1->lock);
/* Only start filling the queue once we're 1/3 empty */
if (t1->active_wq.num_elems < t1->num_active_chips * 4 / 3)
wq_enqueue(cgpu->thr[0], t1);
mutex_lock(&t1->lock);
}
return NULL;
}
static void start_T1_chain(int cid, int retries)
{
mcompat_set_reset(cid, 1);
sleep(retries);
mcompat_set_power_en(cid, 1);
sleep(retries);
mcompat_set_reset(cid, 0);
sleep(retries);
mcompat_set_start_en(cid, 1);
sleep(retries);
mcompat_set_reset(cid, 1);
sleep(retries);
}
static bool detect_T1_chain(void)
{
int i, retries, chain_num = 0, chip_num = 0, iPll;
c_temp_cfg tmp_cfg;
applog(LOG_NOTICE, "T1: checking T1 chain");
for(i = 0; i < MAX_CHAIN_NUM; i++) {
if (chain_plug[i] != 1)
continue;
chain_num++;
}
/* Go back and try chains that have failed after cycling through all of
* them. */
for (retries = 0; retries < 3; retries++) {
for (i = 0; i < MAX_CHAIN_NUM; i++) {
if (chain_plug[i] != 1)
continue;
if (chain[i])
continue;
start_T1_chain(i, retries);
/* pre-init chain */
if ((chain[i] = pre_init_T1_chain(i))) {
chain_flag[i] = 1;
if (chain[i]->num_chips > chip_num)
chip_num = chain[i]->num_chips;
}
}
}
// reinit platform with real chain number and chip number
applog(LOG_NOTICE, "platform re-init: chain_num(%d), chip_num(%d)", chain_num, chip_num);
sys_platform_exit();
sys_platform_init(PLATFORM_ZYNQ_HUB_G19, MCOMPAT_LIB_MINER_TYPE_T1, chain_num, chip_num);
for (i = 0; i < MAX_CHAIN_NUM; i++) {
if (chain_plug[i] != 1)
continue;
if (chain[i] == NULL){
applog(LOG_ERR, "init %d T1 chain fail", i);
continue;
}
// re-config spi speed after platform init
mcompat_set_spi_speed(i, T1_SPI_SPEED_DEF);
cgsleep_ms(10);
mcompat_cfg_tsadc_divider(i, PLL_Clk_12Mhz[0].speedMHz);
}
// init temp ctrl
dm_tempctrl_get_defcfg(&tmp_cfg);
/* Set initial target temperature lower for more reliable startup */
tmp_cfg.tmp_target = T1_TEMP_TARGET_INIT; // target temperature
dm_tempctrl_init(&tmp_cfg);
// start fan ctrl thread
c_fan_cfg fan_cfg;
dm_fanctrl_get_defcfg(&fan_cfg);
fan_cfg.preheat = false; // disable preheat
fan_cfg.fan_speed = T1_FANSPEED_INIT;
dm_fanctrl_init(&fan_cfg);
// dm_fanctrl_init(NULL); // using default cfg
pthread_create(&fan_tid, NULL, dm_fanctrl_thread, NULL);
for(i = 0; i < MAX_CHAIN_NUM; i++) {
if (chain_flag[i] != 1)
continue;
if (!prechain_detect(chain[i], T1Pll[i])) {
chain_flag[i] = 0;
exit_T1_chain(chain[i]);
}
}
for(i = 0; i < MAX_CHAIN_NUM; i++) {
if (chain_flag[i] != 1)
continue;
if (!init_T1_chain(chain[i])) {
exit_T1_chain(chain[i]);
applog(LOG_ERR, "init %d T1 chain fail", i);
chain_flag[i] = 0;
continue;
}
}
for(i = 0; i < MAX_CHAIN_NUM; i++) {
struct cgpu_info *cgpu;
struct T1_chain *t1;
pthread_t pth;
if (chain_flag[i] != 1)
continue;
total_chains++;
cgpu = cgcalloc(sizeof(*cgpu), 1);
cgpu->drv = &dragonmintT1_drv;
cgpu->name = "DragonmintT1.SingleChain";
cgpu->threads = 1;
cgpu->chainNum = i;
cgpu->device_data = t1 = chain[i];
cgtime(&cgpu->dev_start_tv);
t1->lastshare = cgpu->dev_start_tv.tv_sec;
iPll = T1Pll[i];
if ((chain[i]->num_chips <= MAX_CHIP_NUM) && (chain[i]->num_cores <= MAX_CORES)) {
cgpu->mhs_av = (double)PLL_Clk_12Mhz[iPll].speedMHz * 2ull * (chain[i]->num_cores);
} else {
cgpu->mhs_av = 0;
chain_flag[i] = 0;
}
chain[i]->cgpu = cgpu;
cgpu->device_id = i;
add_cgpu(cgpu);
mcompat_set_led(i, LED_ON);
applog(LOG_WARNING, "Detected the %d T1 chain with %d chips / %d cores",
i, chain[i]->num_active_chips, chain[i]->num_cores);
INIT_LIST_HEAD(&t1->active_wq.head);
mutex_init(&t1->lock);
pthread_cond_init(&t1->cond, NULL);
pthread_create(&pth, NULL, T1_work_thread, cgpu);
}
if (!total_chains)
return false;
/* Now adjust target temperature for runtime setting */
tmp_cfg.tmp_target = T1_TEMP_TARGET_RUN;
dm_tempctrl_set(&tmp_cfg);
return true;
}
/* Probe SPI channel and register chip chain */
void T1_detect(bool hotplug)
{
int i;
if (hotplug)
return;
/* parse bimine-t1-options */
if (opt_dragonmint_t1_options != NULL && parsed_config_options == NULL) {
int ref_clk = 0;
int sys_clk = 0;
int spi_clk = 0;
int override_chip_num = 0;
int wiper = 0;
sscanf(opt_dragonmint_t1_options, "%d:%d:%d:%d:%d",
&ref_clk, &sys_clk, &spi_clk, &override_chip_num,
&wiper);
if (ref_clk != 0)
T1_config_options.ref_clk_khz = ref_clk;
if (sys_clk != 0) {
if (sys_clk < 100000)
quit(1, "system clock must be above 100MHz");
T1_config_options.sys_clk_khz = sys_clk;
}
if (spi_clk != 0)
T1_config_options.spi_clk_khz = spi_clk;
if (override_chip_num != 0)
T1_config_options.override_chip_num = override_chip_num;
if (wiper != 0)
T1_config_options.wiper = wiper;
/* config options are global, scan them once */
parsed_config_options = &T1_config_options;
}
applog(LOG_DEBUG, "T1 detect");
memset(&s_reg_ctrl,0,sizeof(s_reg_ctrl));
g_hwver = dragonmint_get_hwver();
// g_type = dragonmint_get_miner_type();
// FIXME: get correct hwver and chain num to init platform
sys_platform_init(PLATFORM_ZYNQ_HUB_G19, MCOMPAT_LIB_MINER_TYPE_T1, MAX_CHAIN_NUM, MAX_CHIP_NUM);
applog(LOG_NOTICE, "vid type detected: %d", misc_get_vid_type());
// set fan speed high to get to a lower startup temperature
dm_fanctrl_set_fan_speed(T1_FANSPEED_INIT);
//dragonmint_miner_init_voltage_flag();
for (i = MAX_CHAIN_NUM - 1; i >= 0; i--) {
if (mcompat_get_plug(i) == 0) {
chain_plug[i] = 1;
applog(LOG_INFO, "chain:%d the plat is inserted", i);
} else {
applog(LOG_INFO, "chain:%d the plat is not inserted", i);
write_miner_ageing_status(AGEING_PLUG_STATUS_ERROR);
}
}
/* If hardware version is g19, continue init cgminer. Else power off*/
if (HARDWARE_VERSION_G19 == g_hwver) {
applog(LOG_INFO, "The hardware version is G19");
for (i = 0; i < MAX_CHAIN_NUM; i++) {
if (chain_plug[i] != 1)
continue;
/* Sets initial voltage to very high to get chips
* initialised. */
mcompat_set_vid(i, STARTUP_VID);
}
} else if (HARDWARE_VERSION_G9 == g_hwver) {
applog(LOG_INFO, "The hardware version is G9");
mcompat_set_vid(0, STARTUP_VID);
} else {
for(i = 0; i < MAX_CHAIN_NUM; i++) {
applog(LOG_ERR, "Unknown hwver, chain%d power down", i);
mcompat_chain_power_down(i);
}
write_miner_ageing_status(AGEING_HW_VERSION_ERROR);
return;
}
for(i = 0; i < MAX_CHAIN_NUM; ++i) {
int pll = DEFAULT_PLL;
/* Tune voltage to highest frequency in Performance mode, and
* lowest frequency in efficient mode. */
if (opt_T1auto) {
if (opt_T1_performance)
pll = MAX_PLL;
else if (opt_T1_efficient)
pll = MIN_PLL;
} else
pll = opt_T1Pll[i];
T1Pll[i] = T1_ConfigT1PLLClock(pll);
}
if (detect_T1_chain()) {
if (misc_get_vid_type() == MCOMPAT_LIB_VID_I2C_TYPE)
set_timeout_on_i2c(30);
applog(LOG_WARNING, "T1 detect finish");
}
}
/* Exit cgminer on failure, allowing systemd watchdog to restart */
static void reinit_T1_chain(struct T1_chain *t1, int cid)
{
bool success = false;
struct timeval now;
int i;
applog(LOG_WARNING, "T1: %d attempting to re-initialise!", cid);
for (i = 0; i < 3; i++) {
start_T1_chain(cid, i);
if (prepare_T1(t1, cid)) {
success = true;
break;
}
}
if (!success) {
applog(LOG_EMERG, "T1: %d FAILED TO PREPARE, SHUTTING DOWN", cid);
raise_cgminer();
}
if (!prechain_detect(t1, T1Pll[cid])) {
applog(LOG_EMERG, "T1: %d FAILED TO PRECHAIN DETECT, SHUTTING DOWN", cid);
raise_cgminer();
}
if (!init_T1_chain(t1)) {
applog(LOG_EMERG, "T1: %d FAILED TO INIT, SHUTTING DOWN", cid);
raise_cgminer();
}
cgtime(&now);
t1->lastshare = now.tv_sec;
}
#define VOLTAGE_UPDATE_INT 121
#define WRITE_CONFIG_TIME 60
#define CHECK_DISABLE_TIME 59
#if 0
char szShowLog[MAX_CHAIN_NUM][MAX_CHIP_NUM][256] = {0};
#define LOG_FILE_PREFIX "/tmp/log/analys"
char cLevelError1[3] = "!";
char cLevelError2[3] = "#";
char cLevelError3[3] = "$";
char cLevelError4[3] = "%";
char cLevelError5[3] = "*";
char cLevelNormal[3] = "+";
void Dragonmint_Log_Save(struct T1_chip *chip,int nChip,int nChain)
{
char szInNormal[8] = {};
if (chip->hw_errors > 0){
strcat(szInNormal,cLevelError1);
}
if (chip->stales > 0){
strcat(szInNormal,cLevelError2);
}
if (chip->num_cores < 32){
strcat(szInNormal,cLevelError4);
}
if ((chip->nVol > 440) || (chip->nVol < 360)){
strcat(szInNormal,cLevelError5);
}
if ((chip->hw_errors == 0) && (chip->stales == 0) && ((chip->nVol < 440) && (chip->nVol > 360)) && (chip->num_cores == 32)){
strcat(szInNormal,cLevelNormal);
}
sprintf(szShowLog[nChain][nChip], "\n%-8s|%32d|%8d|%8d|%8d|%8d|%8d|%8d|%8d",szInNormal,chip->nonces_found,
chip->hw_errors, chip->stales,chip->temp,chip->nVol,chip->num_cores,nChip,nChain);
}
void dragonmint_log_print(int cid, void* log, int len)
{
FILE* fd;
char fileName[128] = {0};
sprintf(fileName, "%s%d.log", LOG_FILE_PREFIX, cid);
fd = fopen(fileName, "w+");
if (fd == NULL){
applog(LOG_ERR, "Open log File%d Failed!", cid);
return;
}
fwrite(log, len, 1, fd);
fflush(fd);
fclose(fd);
}
#endif
/* Invalidate all statistics during buffer underruns and while hardware isn't
* running at its optimal temperature. */
static void reset_tune(struct T1_chain *t1)
{
struct timeval now;
cgtime(&now);
copy_time(&t1->cycle_start, &now);
t1->cycles = 0;
/* Reset last share time since the hardware could genuinely not be
* able to generate shares during extended underruns. */
t1->lastshare = now.tv_sec;
}
static void T1_set_optimal_vid(struct T1_chain *t1, int cid)
{
double best = 0, product[T1_VID_TUNE_RANGE] = {};
int i, vid = t1->iVid;
for (i = 0; i < T1_VID_TUNE_RANGE; i++) {
product[i] = t1->vidproduct[i];
/* In efficient mode divide by the square of the voltage */
if (opt_T1_efficient && t1->vidvol[i])
product[i] /= (double)(t1->vidvol[i] * t1->vidvol[i]);
}
for (i = 0; i < T1_VID_TUNE_RANGE; i++) {
if (!t1->vidproduct[i])
continue;
applog(LOG_ERR, "vid%d: product=%.5f, hwerr=%.5f",
i, t1->vidproduct[i], t1->vidhwerr[i]);
/* Allow up to 1% drop for the sake of lower voltage */
if (!best || (product[i] > best * 0.99 && t1->vidhwerr[i] < 0.2)) {
best = product[i];
vid = i;
}
/* Reset values for clean reuse */
t1->vidproduct[i] = 0;
}
t1->optimalVid = vid;
t1->VidOptimal = true;
mcompat_set_vid_by_step(cid, t1->iVid, vid);
t1->iVid = vid;
get_voltages(t1);
/* Store the optimal voltage for readjusting after PLL changes */
t1->optimal_vol = s_reg_ctrl.average_vol[cid];
/* Set opt_T1VID for saving to config file */
opt_T1VID[cid] = t1->iVid;
for (i = 0; i < T1_PLL_TUNE_RANGE; i++)
t1->pllvid[i] = t1->iVid;
}
/* This returns the best absolute product */
static double T1_best_vid_product(struct T1_chain *t1)
{
double best = 0;
int i;
for (i = 0; i < T1_VID_TUNE_RANGE; i++) {
if (t1->vidproduct[i] > best)
best = t1->vidproduct[i];
}
return best;
}
static void T1_set_optimal_pll(struct T1_chain *t1, int cid)
{
double best = 0, product[T1_PLL_TUNE_RANGE] = {};
int i, pll = t1->pll, best_offset = 0;
for (i = 0; i < T1_PLL_TUNE_RANGE; i++) {
product[i] = t1->pllproduct[i];
/* In efficient mode divide by the frequency */
if (opt_T1_efficient)
product[i] /= (double)PLL_Clk_12Mhz[i + T1_PLL_TUNE_MIN].speedMHz;
}
for (i = 0; i < T1_PLL_TUNE_RANGE; i++) {
if (!t1->pllproduct[i])
continue;
applog(LOG_ERR, "pll%d: product=%.5f, hwerr=%.5f",
i + T1_PLL_TUNE_MIN, t1->pllproduct[i], t1->pllhwerr[i]);
if (!best || (product[i] > best && t1->pllhwerr[i] < 0.2)) {
best = product[i];
pll = i + T1_PLL_TUNE_MIN;
best_offset = i;
}
t1->pllproduct[i] = 0;
}
t1->pllOptimal = true;
t1_set_pll(t1, CMD_ADDR_BROADCAST, pll);
t1->base_pll = t1->pll;
/* Set opt_T1Pll for saving to config file */
opt_T1Pll[cid] = PLL_Clk_12Mhz[t1->pll].speedMHz;
/* Readjust iVid if we changed it during tuning */
if (t1->iVid != t1->pllvid[best_offset]) {
mcompat_set_vid_by_step(cid, t1->iVid, t1->pllvid[best_offset]);
t1->iVid = t1->pllvid[best_offset];
opt_T1VID[cid] = t1->iVid;
}
}
static double T1_best_pll_product(struct T1_chain *t1)
{
double best = 0;
int i;
for (i = 0; i < T1_PLL_TUNE_RANGE; i++) {
if (t1->pllproduct[i] > best)
best = t1->pllproduct[i];
}
return best;
}
static void T1_save_config(void)
{
FILE *fcfg;
fcfg = fopen("/config/cgminer.conf", "w");
if (unlikely(fcfg == NULL)) {
applog(LOG_ERR, "Failed to open /config/cgminer.conf for writing!");
return;
}
write_config(fcfg);
fflush(fcfg);
fclose(fcfg);
}
static void T1_tune_complete(struct T1_chain *t1, int cid)
{
int i;
applog(LOG_WARNING, "T1 %d tuning complete, optimal VID %d PLL %d", cid,
t1->iVid, t1->pll);
t1->sampling = false;
/* Reset hw error count to ignore noise during tuning. */
for(i = 0; i < t1->num_active_chips; ++i)
t1->chips[i].hw_errors = 0;
if (++chains_tuned < total_chains)
return;
applog(LOG_WARNING, "Tuning complete, saving results to config file");
/* Change t1auto to false to save to config to disable tuning
* on next run. */
opt_T1auto = false;
T1_save_config();
/* Reset all stats after tuning */
zero_stats();
}
static void T1_tune(struct T1_chain *t1, int cid)
{
double product, tdiff, best, hw_rate;
int offset, i, hwerr, hw_diff;
struct timeval now;
cgtime(&now);
if (t1->pllOptimal)
return;
if (unlikely(!t1->cycle_start.tv_sec)) {
copy_time(&t1->cycle_start, &now);
t1->cycles = 0;
return;
}
if (t1->cycles < T1_CYCLES_CHAIN)
return;
tdiff = ms_tdiff(&now, &t1->cycle_start);