/*
* Copyright 2011-2022 Andrew Smith
* Copyright 2011-2018 Con Kolivas
* Copyright 2011-2012 Luke Dashjr
* Copyright 2010 Jeff Garzik
*
* 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"
#ifdef __GNUC__
#if __GNUC__ >= 7
#pragma GCC diagnostic ignored "-Wcast-function-type"
#pragma GCC diagnostic ignored "-Wstringop-truncation"
#endif
#endif
#ifdef HAVE_CURSES
#include <curses.h>
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdbool.h>
#include <stdint.h>
#include <unistd.h>
#include <sys/time.h>
#include <time.h>
#include <math.h>
#include <stdarg.h>
#include <assert.h>
#include <signal.h>
#include <limits.h>
#ifdef USE_USBUTILS
#include <semaphore.h>
#endif
#ifdef USE_LIBSYSTEMD
#include <systemd/sd-daemon.h>
#endif
#include <sys/stat.h>
#include <sys/types.h>
#ifndef WIN32
#include <sys/resource.h>
#else
#include <winsock2.h>
#include <windows.h>
#endif
#include <ccan/opt/opt.h>
#include <jansson.h>
#ifdef HAVE_LIBCURL
#include <curl/curl.h>
#else
char *curly = ":D";
#endif
#include <libgen.h>
#include <sha2.h>
#include "compat.h"
#include "miner.h"
#include "bench_block.h"
#ifdef USE_USBUTILS
#include "usbutils.h"
#endif
#if defined(unix) || defined(__APPLE__)
#include <errno.h>
#include <fcntl.h>
#include <sys/wait.h>
#endif
#ifdef USE_AVALON
#include "driver-avalon.h"
#endif
#ifdef USE_AVALON2
#include "driver-avalon2.h"
#endif
#ifdef USE_AVALON4
#include "driver-avalon4.h"
#endif
#ifdef USE_AVALON7
#include "driver-avalon7.h"
#include "libssplus.h"
#endif
#ifdef USE_AVALON8
#include "driver-avalon8.h"
#endif
#ifdef USE_AVALON9
#include "driver-avalon9.h"
#endif
#ifdef USE_AVALONLC3
#include "driver-avalonlc3.h"
#endif
#ifdef USE_AVALON_MINER
#include "driver-avalon-miner.h"
#endif
#ifdef USE_BFLSC
#include "driver-bflsc.h"
#endif
#ifdef USE_SP10
#include "driver-spondoolies-sp10.h"
#endif
#ifdef USE_SP30
#include "driver-spondoolies-sp30.h"
#endif
#ifdef USE_BLOCK_ERUPTER
#include "driver-blockerupter.h"
#endif
#ifdef USE_BITFURY
#include "driver-bitfury.h"
#endif
#ifdef USE_BITFURY16
#include "driver-bitfury16.h"
#endif
#ifdef USE_BITMAIN_SOC
#include <sys/sysinfo.h>
#include "driver-btm-soc.h"
#endif
#ifdef USE_COINTERRA
#include "driver-cointerra.h"
#endif
#ifdef USE_GEKKO
#include "driver-gekko.h"
#endif
#ifdef USE_HASHFAST
#include "driver-hashfast.h"
#endif
#if defined(USE_ANT_S1) || defined(USE_ANT_S2) || defined(USE_ANT_S3)
#include "driver-bitmain.h"
#endif
#if defined(USE_BITFORCE) || defined(USE_ICARUS) || defined(USE_AVALON) || defined(USE_AVALON2) || defined(USE_MODMINER)
# define USE_FPGA
#endif
struct strategies strategies[] = {
{ "Failover" },
{ "Round Robin" },
{ "Rotate" },
{ "Load Balance" },
{ "Balance" },
};
static char packagename[256];
bool opt_work_update;
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined(USE_AVALONLC3)
bool opt_clean_jobs = false;
#endif
bool opt_protocol;
static struct benchfile_layout {
int length;
char *name;
} benchfile_data[] = {
{ 1, "Version" },
{ 64, "MerkleRoot" },
{ 64, "PrevHash" },
{ 8, "DifficultyBits" },
{ 10, "NonceTime" } // 10 digits
};
enum benchwork {
BENCHWORK_VERSION = 0,
BENCHWORK_MERKLEROOT,
BENCHWORK_PREVHASH,
BENCHWORK_DIFFBITS,
BENCHWORK_NONCETIME,
BENCHWORK_COUNT
};
#ifdef HAVE_LIBCURL
static char *opt_btc_address;
static char *opt_btc_sig;
#endif
struct pool *opt_btcd;
static char *opt_benchfile;
static bool opt_benchfile_display;
static FILE *benchfile_in;
static int benchfile_line;
static int benchfile_work;
static bool opt_benchmark;
static bool opt_blockcheck;
bool have_longpoll;
bool want_per_device_stats;
bool use_syslog;
bool opt_quiet;
bool opt_realquiet;
bool opt_loginput;
bool opt_compact;
bool opt_decode;
const int opt_cutofftemp = 95;
int opt_log_interval = 5;
static const int max_queue = 1;
const int max_scantime = 60;
const int max_expiry = 600;
uint64_t global_hashrate;
unsigned long global_quota_gcd = 1;
time_t last_getwork;
int opt_pool_fallback = 120;
#if defined(USE_USBUTILS)
int nDevs;
#endif
bool opt_restart = true;
bool opt_nogpu;
struct list_head scan_devices;
static bool opt_display_devs;
int total_devices;
int zombie_devs;
static int most_devices;
struct cgpu_info **devices;
int mining_threads;
int num_processors;
#ifdef HAVE_CURSES
bool use_curses = true;
#else
bool use_curses;
#endif
bool opt_mac_yield;
bool opt_widescreen;
static bool alt_status;
static bool switch_status;
static bool opt_submit_stale = true;
static int opt_shares;
static bool opt_fix_protocol;
bool opt_lowmem;
bool opt_autofan;
bool opt_autoengine;
bool opt_noadl;
char *opt_api_allow = NULL;
char *opt_api_groups;
char *opt_api_description = PACKAGE_STRING;
int opt_api_port = 4028;
char *opt_api_host = API_LISTEN_ADDR;
bool opt_api_listen;
bool opt_api_mcast;
char *opt_api_mcast_addr = API_MCAST_ADDR;
char *opt_api_mcast_code = API_MCAST_CODE;
char *opt_api_mcast_des = "";
int opt_api_mcast_port = 4028;
bool opt_api_network;
bool opt_delaynet;
bool opt_disable_pool;
static bool no_work;
#ifdef USE_ICARUS
char *opt_icarus_options = NULL;
char *opt_icarus_timing = NULL;
float opt_anu_freq = 250;
float opt_au3_freq = 225;
int opt_au3_volt = 775;
float opt_rock_freq = 270;
#endif
bool opt_worktime;
#ifdef USE_AVALON
char *opt_avalon_options;
char *opt_bitburner_fury_options;
static char *opt_set_avalon_fan;
static char *opt_set_avalon_freq;
#endif
#ifdef USE_AVALON2
static char *opt_set_avalon2_freq;
static char *opt_set_avalon2_fan;
static char *opt_set_avalon2_voltage;
#endif
#ifdef USE_AVALON4
static char *opt_set_avalon4_fan;
static char *opt_set_avalon4_voltage;
static char *opt_set_avalon4_freq;
#endif
#ifdef USE_AVALON7
static char *opt_set_avalon7_fan;
static char *opt_set_avalon7_voltage;
static char *opt_set_avalon7_voltage_level;
static char *opt_set_avalon7_voltage_offset;
static char *opt_set_avalon7_freq;
#endif
#ifdef USE_AVALON8
static char *opt_set_avalon8_fan;
static char *opt_set_avalon8_voltage_level;
static char *opt_set_avalon8_voltage_level_offset;
static char *opt_set_avalon8_freq;
static char *opt_set_avalon8_asic_otp;
#endif
#ifdef USE_AVALON9
static char *opt_set_avalon9_fan;
static char *opt_set_avalon9_voltage_level;
static char *opt_set_avalon9_voltage_level_offset;
static char *opt_set_avalon9_freq;
static char *opt_set_avalon9_adjust_volt_info;
#endif
#ifdef USE_AVALONLC3
static char *opt_set_avalonlc3_fan;
static char *opt_set_avalonlc3_voltage_level;
static char *opt_set_avalonlc3_voltage_level_offset;
static char *opt_set_avalonlc3_freq;
static char *opt_set_avalonlc3_asic_otp;
#endif
#ifdef USE_AVALON_MINER
static char *opt_set_avalonm_voltage;
static char *opt_set_avalonm_freq;
#endif
#ifdef USE_BLOCKERUPTER
int opt_bet_clk = 0;
#endif
#ifdef USE_GEKKO
char *opt_gekko_serial = NULL;
bool opt_gekko_noboost = 0;
bool opt_gekko_lowboost = 0;
bool opt_gekko_gsc_detect = 0;
bool opt_gekko_gsd_detect = 0;
bool opt_gekko_gse_detect = 0;
bool opt_gekko_gsh_detect = 0;
bool opt_gekko_bax_detect = 0;
bool opt_gekko_gsi_detect = 0;
bool opt_gekko_gsf_detect = 0;
bool opt_gekko_r909_detect = 0;
float opt_gekko_gsc_freq = 150;
float opt_gekko_gsd_freq = 100;
float opt_gekko_gse_freq = 150;
float opt_gekko_tune_up = 97;
float opt_gekko_tune_down = 95;
#if defined(__APPLE__)
float opt_gekko_wait_factor = 0.3;
#elif defined (WIN32)
float opt_gekko_wait_factor = 0.4;
#else
float opt_gekko_wait_factor = 0.5;
#endif
float opt_gekko_step_freq = 6.25;
int opt_gekko_gsh_freq = 100;
int opt_gekko_bax_freq = 100;
int opt_gekko_gsi_freq = 550;
int opt_gekko_gsf_freq = 200;
int opt_gekko_r909_freq = 450;
int opt_gekko_bauddiv = 0;
int opt_gekko_gsh_vcore = 400;
int opt_gekko_bax_vcore = 400;
int opt_gekko_start_freq = 100;
int opt_gekko_step_delay = 15;
bool opt_gekko_mine2 = false; // gekko code ignores it
int opt_gekko_tune2 = 0;
#endif
#ifdef USE_HASHRATIO
#include "driver-hashratio.h"
#endif
#ifdef USE_KLONDIKE
char *opt_klondike_options = NULL;
#endif
#ifdef USE_DRILLBIT
char *opt_drillbit_options = NULL;
char *opt_drillbit_auto = NULL;
#endif
char *opt_bab_options = NULL;
#ifdef USE_BITMINE_A1
char *opt_bitmine_a1_options = NULL;
#endif
#ifdef USE_DRAGONMINT_T1
#include "dragonmint_t1.h"
char *opt_dragonmint_t1_options = NULL;
int opt_T1Pll[MCOMPAT_CONFIG_MAX_CHAIN_NUM] = {
DEFAULT_PLL, DEFAULT_PLL, DEFAULT_PLL, DEFAULT_PLL,
DEFAULT_PLL, DEFAULT_PLL, DEFAULT_PLL, DEFAULT_PLL
};
int opt_T1Vol[MCOMPAT_CONFIG_MAX_CHAIN_NUM] = {
DEFAULT_VOLT, DEFAULT_VOLT, DEFAULT_VOLT, DEFAULT_VOLT,
DEFAULT_VOLT, DEFAULT_VOLT, DEFAULT_VOLT, DEFAULT_VOLT
};
int opt_T1VID[MCOMPAT_CONFIG_MAX_CHAIN_NUM] = {};
bool opt_T1auto = true;
bool opt_T1_efficient;
bool opt_T1_performance;
int opt_T1_target = 100;
#endif
#if defined(USE_ANT_S1) || defined(USE_ANT_S2)
char *opt_bitmain_options;
char *opt_set_bitmain_fan;
char *opt_bitmain_freq;
// Ignored
bool opt_bitmain_nobeeper;
bool opt_bitmain_notempoverctrl;
bool opt_bitmain_homemode;
#endif
#ifdef USE_ANT_S2
#ifndef USE_ANT_S3
char *opt_bitmain_dev;
#endif
char *opt_bitmain_voltage = BITMAIN_VOLTAGE_DEF;
#endif
#ifdef USE_HASHFAST
static char *opt_set_hfa_fan;
#endif
static char *opt_set_null;
#ifdef USE_MINION
int opt_minion_chipreport;
char *opt_minion_cores;
bool opt_minion_extra;
char *opt_minion_freq;
int opt_minion_freqchange = 1000;
int opt_minion_freqpercent = 70;
bool opt_minion_idlecount;
int opt_minion_ledcount;
int opt_minion_ledlimit = 98;
bool opt_minion_noautofreq;
bool opt_minion_overheat;
int opt_minion_spidelay;
char *opt_minion_spireset;
int opt_minion_spisleep = 200;
int opt_minion_spiusec;
char *opt_minion_temp;
#endif
#ifdef USE_USBUTILS
char *opt_usb_select = NULL;
int opt_usbdump = -1;
bool opt_usb_list_all;
cgsem_t usb_resource_sem;
static pthread_t usb_poll_thread;
static bool usb_polling;
static bool polling_usb;
static bool usb_reinit;
#endif
char *opt_kernel_path;
char *cgminer_path;
bool opt_gen_stratum_work;
#if defined(USE_BITFORCE)
bool opt_bfl_noncerange;
#endif
#define QUIET (opt_quiet || opt_realquiet)
struct thr_info *control_thr;
struct thr_info **mining_thr;
static int gwsched_thr_id;
static int watchpool_thr_id;
static int watchdog_thr_id;
#ifdef HAVE_CURSES
static int input_thr_id;
#endif
int gpur_thr_id;
static int api_thr_id;
#ifdef USE_USBUTILS
static int usbres_thr_id;
static int hotplug_thr_id;
#endif
static int total_control_threads;
bool hotplug_mode;
static int new_devices;
static int new_threads;
int hotplug_time = 5;
#if LOCK_TRACKING
pthread_mutex_t lockstat_lock;
#endif
pthread_mutex_t hash_lock;
static pthread_mutex_t *stgd_lock;
pthread_mutex_t console_lock;
cglock_t ch_lock;
static pthread_rwlock_t blk_lock;
static pthread_mutex_t sshare_lock;
pthread_rwlock_t netacc_lock;
pthread_rwlock_t mining_thr_lock;
pthread_rwlock_t devices_lock;
static pthread_mutex_t lp_lock;
static pthread_cond_t lp_cond;
pthread_mutex_t restart_lock;
pthread_cond_t restart_cond;
pthread_cond_t gws_cond;
double rolling1, rolling5, rolling15;
double total_rolling;
double total_mhashes_done;
#ifdef USE_BITMAIN_SOC
char *opt_version_path = NULL;
char displayed_hash_rate[16] = {0};
char nonce_num10_string[NONCE_BUFF];
char nonce_num30_string[NONCE_BUFF];
char nonce_num60_string[NONCE_BUFF];
char g_miner_version[256] = {0};
char g_miner_compiletime[256] = {0};
char g_miner_type[256] = {0};
double new_total_mhashes_done;
double new_total_secs = 1.0;
// only used for total_secs, because we need use system info time, instead of real data time.
time_t total_tv_start_sys;
time_t total_tv_end_sys;
#endif
static struct timeval total_tv_start, total_tv_end;
static struct timeval restart_tv_start, update_tv_start;
cglock_t control_lock;
pthread_mutex_t stats_lock;
int hw_errors;
int64_t total_accepted, total_rejected, total_diff1;
int64_t total_getworks, total_stale, total_discarded;
double total_diff_accepted, total_diff_rejected, total_diff_stale;
static int staged_rollable;
unsigned int new_blocks;
static unsigned int work_block;
unsigned int found_blocks;
unsigned int local_work;
unsigned int total_go, total_ro;
struct pool **pools;
static struct pool *currentpool = NULL;
int total_pools, enabled_pools;
enum pool_strategy pool_strategy = POOL_FAILOVER;
int opt_rotate_period;
#ifdef USE_XTRANONCE
static int total_urls, total_users, total_passes, total_userpasses, total_extranonce;
#else
static int total_urls, total_users, total_passes, total_userpasses;
#endif
static
#ifndef HAVE_CURSES
const
#endif
bool curses_active;
/* Protected by ch_lock */
char current_hash[68];
static char prev_block[12];
static char current_block[32];
static char datestamp[40];
static char blocktime[32];
struct timeval block_timeval;
static char best_share[8] = "0";
double current_diff = 0xFFFFFFFFFFFFFFFFULL;
static char block_diff[8];
uint64_t best_diff = 0;
struct block {
char hash[68];
UT_hash_handle hh;
int block_no;
};
static struct block *blocks = NULL;
int swork_id;
/* For creating a hash database of stratum shares submitted that have not had
* a response yet */
struct stratum_share {
UT_hash_handle hh;
bool block;
struct work *work;
int id;
time_t sshare_time;
time_t sshare_sent;
};
static struct stratum_share *stratum_shares = NULL;
char *opt_socks_proxy = NULL;
int opt_suggest_diff;
#if defined(USE_AVALON7) || defined (USE_AVALON8) || defined(USE_AVALON9) ||defined(USE_AVALONLC3)
int opt_force_clean_jobs = 20;
#endif
static const char def_conf[] = "cgminer.conf";
static char *default_config;
static bool config_loaded;
static int include_count;
#define JSON_INCLUDE_CONF "include"
#define JSON_LOAD_ERROR "JSON decode of file '%s' failed\n %s"
#define JSON_LOAD_ERROR_LEN strlen(JSON_LOAD_ERROR)
#define JSON_MAX_DEPTH 10
#define JSON_MAX_DEPTH_ERR "Too many levels of JSON includes (limit 10) or a loop"
#define JSON_WEB_ERROR "WEB config err"
#if defined(unix) || defined(__APPLE__)
static char *opt_stderr_cmd = NULL;
static int forkpid;
#endif // defined(unix)
struct sigaction termhandler, inthandler, abrthandler;
struct thread_q *getq;
static uint32_t total_work;
struct work *staged_work = NULL;
struct schedtime {
bool enable;
struct tm tm;
};
struct schedtime schedstart;
struct schedtime schedstop;
bool sched_paused;
static bool time_before(struct tm *tm1, struct tm *tm2)
{
if (tm1->tm_hour < tm2->tm_hour)
return true;
if (tm1->tm_hour == tm2->tm_hour && tm1->tm_min < tm2->tm_min)
return true;
return false;
}
static bool should_run(void)
{
struct timeval tv;
struct tm *tm;
if (!schedstart.enable && !schedstop.enable)
return true;
cgtime(&tv);
const time_t tmp_time = tv.tv_sec;
tm = localtime(&tmp_time);
if (schedstart.enable) {
if (!schedstop.enable) {
if (time_before(tm, &schedstart.tm))
return false;
/* This is a once off event with no stop time set */
schedstart.enable = false;
return true;
}
if (time_before(&schedstart.tm, &schedstop.tm)) {
if (time_before(tm, &schedstop.tm) && !time_before(tm, &schedstart.tm))
return true;
return false;
} /* Times are reversed */
if (time_before(tm, &schedstart.tm)) {
if (time_before(tm, &schedstop.tm))
return true;
return false;
}
return true;
}
/* only schedstop.enable == true */
if (!time_before(tm, &schedstop.tm))
return false;
return true;
}
void get_datestamp(char *f, size_t fsiz, struct timeval *tv)
{
struct tm *tm;
const time_t tmp_time = tv->tv_sec;
int ms = (int)(tv->tv_usec / 1000);
tm = localtime(&tmp_time);
snprintf(f, fsiz, "[%d-%02d-%02d %02d:%02d:%02d.%03d]",
tm->tm_year + 1900,
tm->tm_mon + 1,
tm->tm_mday,
tm->tm_hour,
tm->tm_min,
tm->tm_sec, ms);
}
static void get_timestamp(char *f, size_t fsiz, struct timeval *tv)
{
struct tm *tm;
const time_t tmp_time = tv->tv_sec;
int ms = (int)(tv->tv_usec / 1000);
tm = localtime(&tmp_time);
snprintf(f, fsiz, "[%02d:%02d:%02d.%03d]",
tm->tm_hour,
tm->tm_min,
tm->tm_sec, ms);
}
static char exit_buf[512];
static void applog_and_exit(const char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
vsnprintf(exit_buf, sizeof(exit_buf), fmt, ap);
va_end(ap);
_applog(LOG_ERR, exit_buf, true);
exit(1);
}
static pthread_mutex_t sharelog_lock;
static FILE *sharelog_file = NULL;
static struct thr_info *__get_thread(int thr_id)
{
return mining_thr[thr_id];
}
struct thr_info *get_thread(int thr_id)
{
struct thr_info *thr;
rd_lock(&mining_thr_lock);
thr = __get_thread(thr_id);
rd_unlock(&mining_thr_lock);
return thr;
}
static struct cgpu_info *get_thr_cgpu(int thr_id)
{
struct thr_info *thr = get_thread(thr_id);
return thr->cgpu;
}
struct cgpu_info *get_devices(int id)
{
struct cgpu_info *cgpu;
rd_lock(&devices_lock);
cgpu = devices[id];
rd_unlock(&devices_lock);
return cgpu;
}
static void sharelog(const char*disposition, const struct work*work)
{
char *target, *hash, *data;
struct cgpu_info *cgpu;
unsigned long int t;
struct pool *pool;
int thr_id, rv;
char s[1024];
size_t ret;
if (!sharelog_file)
return;
thr_id = work->thr_id;
cgpu = get_thr_cgpu(thr_id);
pool = work->pool;
t = (unsigned long int)(work->tv_work_found.tv_sec);
target = bin2hex(work->target, sizeof(work->target));
hash = bin2hex(work->hash, sizeof(work->hash));
data = bin2hex(work->data, sizeof(work->data));
// timestamp,disposition,target,pool,dev,thr,sharehash,sharedata
rv = snprintf(s, sizeof(s), "%lu,%s,%s,%s,%s%u,%u,%s,%s\n", t, disposition, target, pool->rpc_url, cgpu->drv->name, cgpu->device_id, thr_id, hash, data);
free(target);
free(hash);
free(data);
if (rv >= (int)(sizeof(s)))
s[sizeof(s) - 1] = '\0';
else if (rv < 0) {
applog(LOG_ERR, "sharelog printf error");
return;
}
mutex_lock(&sharelog_lock);
ret = fwrite(s, rv, 1, sharelog_file);
fflush(sharelog_file);
mutex_unlock(&sharelog_lock);
if (ret != 1)
applog(LOG_ERR, "sharelog fwrite error");
}
static char *gbt_req = "{\"id\": 0, \"method\": \"getblocktemplate\", \"params\": [{\"capabilities\": [\"coinbasetxn\", \"workid\", \"coinbase/append\"]}]}\n";
static char *gbt_solo_req = "{\"id\": 0, \"method\": \"getblocktemplate\", \"params\": [{\"rules\" : [\"segwit\"]}]}\n";
static const char *gbt_understood_rules[1] = { NULL };
static const char *gbt_solo_understood_rules[2] = {"segwit", NULL};
static bool gbt_check_required_rule(const char* rule, const char** understood_rules)
{
const char *understood_rule;
if (!understood_rules || !rule)
return false;
while ((understood_rule = *understood_rules++)) {
if (strcmp(understood_rule, rule) == 0)
return true;
}
return false;
}
static bool gbt_check_rules(json_t* rules_arr, const char** understood_rules)
{
int i, rule_count;
const char *rule;
if (!rules_arr)
return true;
rule_count = json_array_size(rules_arr);
for (i = 0; i < rule_count; i++) {
rule = json_string_value(json_array_get(rules_arr, i));
if (rule && *rule++ == '!' && !gbt_check_required_rule(rule, understood_rules))
return false;
}
return true;
}
/* Adjust all the pools' quota to the greatest common denominator after a pool
* has been added or the quotas changed. */
void adjust_quota_gcd(void)
{
unsigned long gcd, lowest_quota = ~0UL, quota;
struct pool *pool;
int i;
for (i = 0; i < total_pools; i++) {
pool = pools[i];
quota = pool->quota;
if (!quota)
continue;
if (quota < lowest_quota)
lowest_quota = quota;
}
if (likely(lowest_quota < ~0UL)) {
gcd = lowest_quota;
for (i = 0; i < total_pools; i++) {
pool = pools[i];
quota = pool->quota;
if (!quota)
continue;
while (quota % gcd)
gcd--;
}
} else
gcd = 1;
for (i = 0; i < total_pools; i++) {
pool = pools[i];
pool->quota_used *= global_quota_gcd;
pool->quota_used /= gcd;
pool->quota_gcd = pool->quota / gcd;
}
global_quota_gcd = gcd;
applog(LOG_DEBUG, "Global quota greatest common denominator set to %lu", gcd);
}
/* Return value is ignored if not called from input_pool */
struct pool *add_pool(void)
{
struct pool *pool;
pool = cgcalloc(sizeof(struct pool), 1);
pool->pool_no = pool->prio = total_pools;
pools = cgrealloc(pools, sizeof(struct pool *) * (total_pools + 2));
pools[total_pools++] = pool;
mutex_init(&pool->pool_lock);
if (unlikely(pthread_cond_init(&pool->cr_cond, NULL)))
quit(1, "Failed to pthread_cond_init in add_pool");
cglock_init(&pool->data_lock);
mutex_init(&pool->stratum_lock);
cglock_init(&pool->gbt_lock);
INIT_LIST_HEAD(&pool->curlring);
/* Make sure the pool doesn't think we've been idle since time 0 */
pool->tv_idle.tv_sec = ~0UL;
pool->rpc_req = gbt_req;
pool->rpc_proxy = NULL;
pool->quota = 1;
adjust_quota_gcd();
#ifdef USE_XTRANONCE
pool->extranonce_subscribe = false;
#endif
return pool;
}
/* Pool variant of test and set */
static bool pool_tset(struct pool *pool, bool *var)
{
bool ret;
mutex_lock(&pool->pool_lock);
ret = *var;
*var = true;
mutex_unlock(&pool->pool_lock);
return ret;
}
bool pool_tclear(struct pool *pool, bool *var)
{
bool ret;
mutex_lock(&pool->pool_lock);
ret = *var;
*var = false;
mutex_unlock(&pool->pool_lock);
return ret;
}
struct pool *current_pool(void)
{
struct pool *pool;
cg_rlock(&control_lock);
pool = currentpool;
cg_runlock(&control_lock);
return pool;
}
char *set_int_range(const char *arg, int *i, int min, int max)
{
char *err = opt_set_intval(arg, i);
if (err)
return err;
if (*i < min || *i > max)
return "Value out of range";
return NULL;
}
static char *set_int_0_to_65535(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 65535);
}
static char *set_int_0_to_9999(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 9999);
}
static char *set_int_1_to_65535(const char *arg, int *i)
{
return set_int_range(arg, i, 1, 65535);
}
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined (USE_AVALONLC3)
static char *set_int_0_to_1(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 1);
}
static char *set_int_0_to_7(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 7);
}
static char *set_int_0_to_32767(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 32767);
}
#endif
static char *set_int_0_to_5(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 5);
}
static char *set_int_0_to_10(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 10);
}
#ifdef USE_DRAGONMINT_T1
static char *set_int_voltage(const char *arg, int *i)
{
return set_int_range(arg, i, CHIP_VOLT_MIN, CHIP_VOLT_MAX);
}
/* Intentionally does NOT accept zero so that zero means the value is NOT set
* and has no effect. */
static char *set_int_1_to_31(const char *arg, int *i)
{
return set_int_range(arg, i, 1, 31);
}
#endif
static char *set_int_0_to_100(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 100);
}
static char *set_int_0_to_255(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 255);
}
static char *set_int_1_to_255(const char *arg, int *i)
{
return set_int_range(arg, i, 1, 255);
}
static char *set_int_0_to_7680(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 7680);
}
#if defined(USE_AVALON4)
static char *set_int_1_to_60(const char *arg, int *i)
{
return set_int_range(arg, i, 1, 60);
}
#endif
static char *set_int_0_to_200(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 200);
}
static char *set_int_32_to_63(const char *arg, int *i)
{
return set_int_range(arg, i, 32, 63);
}
static char *set_int_22_to_75(const char *arg, int *i)
{
return set_int_range(arg, i, 22, 75);
}
static char *set_int_42_to_85(const char *arg, int *i)
{
return set_int_range(arg, i, 42, 85);
}
static char *set_int_1_to_10(const char *arg, int *i)
{
return set_int_range(arg, i, 1, 10);
}
static char *set_int_24_to_32(const char *arg, int *i)
{
return set_int_range(arg, i, 24, 32);
}
static char __maybe_unused *set_int_0_to_2(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 2);
}
static char __maybe_unused *set_int_0_to_3(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 3);
}
static char __maybe_unused *set_int_0_to_4(const char *arg, int *i)
{
return set_int_range(arg, i, 0, 4);
}
#ifdef USE_FPGA_SERIAL
static char *opt_add_serial;
static char *add_serial(char *arg)
{
string_elist_add(arg, &scan_devices);
return NULL;
}
#endif
void get_intrange(char *arg, int *val1, int *val2)
{
if (sscanf(arg, "%d-%d", val1, val2) == 1)
*val2 = *val1;
}
static char *set_balance(enum pool_strategy *strategy)
{
*strategy = POOL_BALANCE;
return NULL;
}
static char *set_loadbalance(enum pool_strategy *strategy)
{
*strategy = POOL_LOADBALANCE;
return NULL;
}
static char *set_rotate(const char *arg, char __maybe_unused *i)
{
pool_strategy = POOL_ROTATE;
return set_int_range(arg, &opt_rotate_period, 0, 9999);
}
static char *set_rr(enum pool_strategy *strategy)
{
*strategy = POOL_ROUNDROBIN;
return NULL;
}
/* Detect that url is for a stratum protocol either via the presence of
* stratum+tcp or by detecting a stratum server response */
bool detect_stratum(struct pool *pool, char *url)
{
bool ret = false;
if (!extract_sockaddr(url, &pool->sockaddr_url, &pool->stratum_port))
goto out;
if (!strncasecmp(url, "stratum+tcp://", 14)) {
pool->rpc_url = strdup(url);
pool->has_stratum = true;
pool->stratum_url = pool->sockaddr_url;
ret = true;
}
out:
if (!ret) {
free(pool->sockaddr_url);
free(pool->stratum_port);
pool->stratum_port = pool->sockaddr_url = NULL;
}
return ret;
}
static struct pool *add_url(void)
{
total_urls++;
if (total_urls > total_pools)
add_pool();
return pools[total_urls - 1];
}
static char *setup_url(struct pool *pool, char *arg)
{
arg = get_proxy(arg, pool);
if (detect_stratum(pool, arg))
goto out;
opt_set_charp(arg, &pool->rpc_url);
if (strncmp(arg, "http://", 7) &&
strncmp(arg, "https://", 8)) {
char httpinput[256];
strcpy(httpinput, "stratum+tcp://");
strncat(httpinput, arg, 242);
detect_stratum(pool, httpinput);
}
out:
return pool->rpc_url;
}
static char *set_url(char *arg)
{
struct pool *pool = add_url();
setup_url(pool, arg);
#ifdef USE_XTRANONCE
if (strstr(pool->rpc_url, ".nicehash.com") || strstr(pool->rpc_url, "#xnsub")) {
pool->extranonce_subscribe = true;
applog(LOG_DEBUG, "Pool %d extranonce subscribing enabled.", pool->pool_no);
}
#endif
return NULL;
}
static char *set_quota(char *arg)
{
char *semicolon = strchr(arg, ';'), *url;
int len, qlen, quota;
struct pool *pool;
if (!semicolon)
return "No semicolon separated quota;URL pair found";
len = strlen(arg);
*semicolon = '\0';
qlen = strlen(arg);
if (!qlen)
return "No parameter for quota found";
len -= qlen + 1;
if (len < 1)
return "No parameter for URL found";
quota = atoi(arg);
if (quota < 0)
return "Invalid negative parameter for quota set";
url = arg + qlen + 1;
pool = add_url();
setup_url(pool, url);
pool->quota = quota;
applog(LOG_INFO, "Setting pool %d to quota %d", pool->pool_no, pool->quota);
adjust_quota_gcd();
return NULL;
}
static char *set_user(const char *arg)
{
struct pool *pool;
if (total_userpasses)
return "Use only user + pass or userpass, but not both";
total_users++;
if (total_users > total_pools)
add_pool();
pool = pools[total_users - 1];
opt_set_charp(arg, &pool->rpc_user);
return NULL;
}
static char *set_pass(const char *arg)
{
struct pool *pool;
if (total_userpasses)
return "Use only user + pass or userpass, but not both";
total_passes++;
if (total_passes > total_pools)
add_pool();
pool = pools[total_passes - 1];
opt_set_charp(arg, &pool->rpc_pass);
return NULL;
}
static char *set_userpass(const char *arg)
{
struct pool *pool;
char *updup;
if (total_users || total_passes)
return "Use only user + pass or userpass, but not both";
total_userpasses++;
if (total_userpasses > total_pools)
add_pool();
pool = pools[total_userpasses - 1];
updup = strdup(arg);
opt_set_charp(arg, &pool->rpc_userpass);
pool->rpc_user = strtok(updup, ":");
if (!pool->rpc_user)
return "Failed to find : delimited user info";
pool->rpc_pass = strtok(NULL, ":");
if (!pool->rpc_pass)
pool->rpc_pass = strdup("");
return NULL;
}
#ifdef USE_XTRANONCE
static char *set_extranonce_subscribe(char *arg)
{
struct pool *pool;
total_extranonce++;
if (total_extranonce > total_pools)
add_pool();
pool = pools[total_extranonce - 1];
applog(LOG_DEBUG, "Enable extranonce subscribe on %d", pool->pool_no);
opt_set_bool(&pool->extranonce_subscribe);
return NULL;
}
#endif
static char *enable_debug(bool *flag)
{
*flag = true;
/* Turn on verbose output, too. */
opt_log_output = true;
return NULL;
}
static char *opt_set_sched_start;
static char *opt_set_sched_stop;
static char *set_schedtime(const char *arg, struct schedtime *st)
{
if (sscanf(arg, "%d:%d", &st->tm.tm_hour, &st->tm.tm_min) != 2)
return "Invalid time set, should be HH:MM";
if (st->tm.tm_hour > 23 || st->tm.tm_min > 59 || st->tm.tm_hour < 0 || st->tm.tm_min < 0)
return "Invalid time set.";
st->enable = true;
return NULL;
}
static char *set_sched_start(const char *arg)
{
return set_schedtime(arg, &schedstart);
}
static char *set_sched_stop(const char *arg)
{
return set_schedtime(arg, &schedstop);
}
static char *opt_set_sharelog;
static char* set_sharelog(char *arg)
{
char *r = "";
long int i = strtol(arg, &r, 10);
if ((!*r) && i >= 0 && i <= INT_MAX) {
sharelog_file = fdopen((int)i, "a");
if (!sharelog_file)
applog(LOG_ERR, "Failed to open fd %u for share log", (unsigned int)i);
} else if (!strcmp(arg, "-")) {
sharelog_file = stdout;
if (!sharelog_file)
applog(LOG_ERR, "Standard output missing for share log");
} else {
sharelog_file = fopen(arg, "a");
if (!sharelog_file)
applog(LOG_ERR, "Failed to open %s for share log", arg);
}
return NULL;
}
static char *temp_cutoff_str = NULL;
static char __maybe_unused *opt_set_temp_cutoff;
char *set_temp_cutoff(char *arg)
{
int val;
if (!(arg && arg[0]))
return "Invalid parameters for set temp cutoff";
val = atoi(arg);
if (val < 0 || val > 200)
return "Invalid value passed to set temp cutoff";
temp_cutoff_str = arg;
return NULL;
}
static void load_temp_cutoffs()
{
int i, val = 0, device = 0;
char *nextptr;
if (temp_cutoff_str) {
for (device = 0, nextptr = strtok(temp_cutoff_str, ","); nextptr; ++device, nextptr = strtok(NULL, ",")) {
if (device >= total_devices)
quit(1, "Too many values passed to set temp cutoff");
val = atoi(nextptr);
if (val < 0 || val > 200)
quit(1, "Invalid value passed to set temp cutoff");
rd_lock(&devices_lock);
devices[device]->cutofftemp = val;
rd_unlock(&devices_lock);
}
} else {
rd_lock(&devices_lock);
for (i = device; i < total_devices; ++i) {
if (!devices[i]->cutofftemp)
devices[i]->cutofftemp = opt_cutofftemp;
}
rd_unlock(&devices_lock);
return;
}
if (device <= 1) {
rd_lock(&devices_lock);
for (i = device; i < total_devices; ++i)
devices[i]->cutofftemp = val;
rd_unlock(&devices_lock);
}
}
static char *set_float_0_to_500(const char *arg, float *i)
{
char *err = opt_set_floatval(arg, i);
if (err)
return err;
if (*i < 0 || *i > 500)
return "Value out of range";
return NULL;
}
static char *set_float_100_to_500(const char *arg, float *i)
{
char *err = opt_set_floatval(arg, i);
if (err)
return err;
if (*i < 100 || *i > 500)
return "Value out of range";
return NULL;
}
static char *set_float_125_to_500(const char *arg, float *i)
{
char *err = opt_set_floatval(arg, i);
if (err)
return err;
if (*i < 125 || *i > 500)
return "Value out of range";
return NULL;
}
static char *set_float_100_to_250(const char *arg, float *i)
{
char *err = opt_set_floatval(arg, i);
if (err)
return err;
if (*i < 100 || *i > 250)
return "Value out of range";
return NULL;
}
static char *set_null(const char __maybe_unused *arg)
{
return NULL;
}
#ifdef USE_BITMAIN_SOC
static char *set_version_path(const char *arg)
{
opt_set_charp(arg, &opt_version_path);
return NULL;
}
#endif
/* These options are available from config file or commandline */
static struct opt_table opt_config_table[] = {
#ifdef USE_ICARUS
OPT_WITH_ARG("--anu-freq",
set_float_125_to_500, &opt_show_floatval, &opt_anu_freq,
"Set AntminerU1/2 frequency in MHz, range 125-500"),
#endif
OPT_WITH_ARG("--api-allow",
opt_set_charp, NULL, &opt_api_allow,
"Allow API access only to the given list of [G:]IP[/Prefix] addresses[/subnets]"),
OPT_WITH_ARG("--api-description",
opt_set_charp, NULL, &opt_api_description,
"Description placed in the API status header, default: cgminer version"),
OPT_WITH_ARG("--api-groups",
opt_set_charp, NULL, &opt_api_groups,
"API one letter groups G:cmd:cmd[,P:cmd:*...] defining the cmds a groups can use"),
OPT_WITHOUT_ARG("--api-listen",
opt_set_bool, &opt_api_listen,
"Enable API, default: disabled"),
OPT_WITHOUT_ARG("--api-mcast",
opt_set_bool, &opt_api_mcast,
"Enable API Multicast listener, default: disabled"),
OPT_WITH_ARG("--api-mcast-addr",
opt_set_charp, NULL, &opt_api_mcast_addr,
"API Multicast listen address"),
OPT_WITH_ARG("--api-mcast-code",
opt_set_charp, NULL, &opt_api_mcast_code,
"Code expected in the API Multicast message, don't use '-'"),
OPT_WITH_ARG("--api-mcast-des",
opt_set_charp, NULL, &opt_api_mcast_des,
"Description appended to the API Multicast reply, default: ''"),
OPT_WITH_ARG("--api-mcast-port",
set_int_1_to_65535, opt_show_intval, &opt_api_mcast_port,
"API Multicast listen port"),
OPT_WITHOUT_ARG("--api-network",
opt_set_bool, &opt_api_network,
"Allow API (if enabled) to listen on/for any address, default: only 127.0.0.1"),
OPT_WITH_ARG("--api-port",
set_int_1_to_65535, opt_show_intval, &opt_api_port,
"Port number of miner API"),
OPT_WITH_ARG("--api-host",
opt_set_charp, NULL, &opt_api_host,
"Specify API listen address, default: 0.0.0.0"),
#ifdef USE_ICARUS
OPT_WITH_ARG("--au3-freq",
set_float_100_to_250, &opt_show_floatval, &opt_au3_freq,
"Set AntminerU3 frequency in MHz, range 100-250"),
OPT_WITH_ARG("--au3-volt",
set_int_0_to_9999, &opt_show_intval, &opt_au3_volt,
"Set AntminerU3 voltage in mv, range 725-850, 0 to not set"),
#endif
#ifdef USE_AVALON
OPT_WITHOUT_ARG("--avalon-auto",
opt_set_bool, &opt_avalon_auto,
"Adjust avalon overclock frequency dynamically for best hashrate"),
OPT_WITH_ARG("--avalon-cutoff",
set_int_0_to_100, opt_show_intval, &opt_avalon_overheat,
"Set avalon overheat cut off temperature"),
OPT_WITH_CBARG("--avalon-fan",
set_avalon_fan, NULL, &opt_set_avalon_fan,
"Set fanspeed percentage for avalon, single value or range (default: 20-100)"),
OPT_WITH_CBARG("--avalon-freq",
set_avalon_freq, NULL, &opt_set_avalon_freq,
"Set frequency range for avalon-auto, single value or range"),
OPT_WITH_ARG("--avalon-options",
opt_set_charp, NULL, &opt_avalon_options,
"Set avalon options baud:miners:asic:timeout:freq:tech"),
OPT_WITH_ARG("--avalon-temp",
set_int_0_to_100, opt_show_intval, &opt_avalon_temp,
"Set avalon target temperature"),
#endif
#ifdef USE_AVALON2
OPT_WITH_CBARG("--avalon2-freq",
set_avalon2_freq, NULL, &opt_set_avalon2_freq,
"Set frequency range for Avalon2, single value or range, step: 25"),
OPT_WITH_CBARG("--avalon2-voltage",
set_avalon2_voltage, NULL, &opt_set_avalon2_voltage,
"Set Avalon2 core voltage, in millivolts, step: 125"),
OPT_WITH_CBARG("--avalon2-fan",
set_avalon2_fan, NULL, &opt_set_avalon2_fan,
"Set Avalon2 target fan speed"),
OPT_WITH_ARG("--avalon2-cutoff",
set_int_0_to_100, opt_show_intval, &opt_avalon2_overheat,
"Set Avalon2 overheat cut off temperature"),
OPT_WITHOUT_ARG("--avalon2-fixed-speed",
set_avalon2_fixed_speed, &opt_avalon2_fan_fixed,
"Set Avalon2 fan to fixed speed"),
OPT_WITH_ARG("--avalon2-polling-delay",
set_int_1_to_65535, opt_show_intval, &opt_avalon2_polling_delay,
"Set Avalon2 polling delay value (ms)"),
#endif
#ifdef USE_AVALON4
OPT_WITHOUT_ARG("--avalon4-automatic-voltage",
opt_set_bool, &opt_avalon4_autov,
"Automatic adjust voltage base on module DH"),
OPT_WITH_CBARG("--avalon4-voltage",
set_avalon4_voltage, NULL, &opt_set_avalon4_voltage,
"Set Avalon4 core voltage, in millivolts, step: 125"),
OPT_WITH_CBARG("--avalon4-freq",
set_avalon4_freq, NULL, &opt_set_avalon4_freq,
"Set frequency for Avalon4, 1 to 3 values, example: 445:385:370"),
OPT_WITH_CBARG("--avalon4-fan",
set_avalon4_fan, NULL, &opt_set_avalon4_fan,
"Set Avalon4 target fan speed range"),
OPT_WITH_ARG("--avalon4-temp",
set_int_22_to_75, opt_show_intval, &opt_avalon4_temp_target,
"Set Avalon4 target temperature"),
OPT_WITH_ARG("--avalon4-cutoff",
set_int_42_to_85, opt_show_intval, &opt_avalon4_overheat,
"Set Avalon4 overheat cut off temperature"),
OPT_WITH_ARG("--avalon4-polling-delay",
set_int_1_to_65535, opt_show_intval, &opt_avalon4_polling_delay,
"Set Avalon4 polling delay value (ms)"),
OPT_WITH_ARG("--avalon4-ntime-offset",
opt_set_intval, opt_show_intval, &opt_avalon4_ntime_offset,
"Set Avalon4 MM ntime rolling max offset"),
OPT_WITH_ARG("--avalon4-aucspeed",
opt_set_intval, opt_show_intval, &opt_avalon4_aucspeed,
"Set Avalon4 AUC IIC bus speed"),
OPT_WITH_ARG("--avalon4-aucxdelay",
opt_set_intval, opt_show_intval, &opt_avalon4_aucxdelay,
"Set Avalon4 AUC IIC xfer read delay, 4800 ~= 1ms"),
OPT_WITH_ARG("--avalon4-miningmode",
opt_set_intval, opt_show_intval, &opt_avalon4_miningmode,
"Set Avalon4 mining mode(0:custom, 1:eco, 2:normal, 3:turbo"),
OPT_WITHOUT_ARG("--avalon4-freezesafe",
opt_set_bool, &opt_avalon4_freezesafe,
"Make Avalon4 running as a radiator when stratum server failed"),
OPT_WITH_ARG("--avalon4-ntcb",
opt_set_intval, opt_show_intval, &opt_avalon4_ntcb,
"Set Avalon4 MM NTC B value"),
OPT_WITH_ARG("--avalon4-freq-min",
opt_set_intval, opt_show_intval, &opt_avalon4_freq_min,
"Set minimum frequency for Avalon4"),
OPT_WITH_ARG("--avalon4-freq-max",
opt_set_intval, opt_show_intval, &opt_avalon4_freq_max,
"Set maximum frequency for Avalon4"),
OPT_WITHOUT_ARG("--avalon4-noncecheck-off",
opt_set_invbool, &opt_avalon4_noncecheck,
"Disable A3218 inside nonce check function"),
OPT_WITH_ARG("--avalon4-smart-speed",
opt_set_intval, opt_show_intval, &opt_avalon4_smart_speed,
"Set smart speed, range 0-3. 0 means Disable"),
OPT_WITH_ARG("--avalon4-speed-bingo",
set_int_1_to_255, opt_show_intval, &opt_avalon4_speed_bingo,
"Set A3218 speed bingo for smart speed mode 1"),
OPT_WITH_ARG("--avalon4-speed-error",
set_int_1_to_255, opt_show_intval, &opt_avalon4_speed_error,
"Set A3218 speed error for smart speed mode 1"),
OPT_WITH_ARG("--avalon4-least-pll",
set_int_0_to_7680, opt_show_intval, &opt_avalon4_least_pll_check,
"Set least pll check threshold for smart speed mode 2"),
OPT_WITH_ARG("--avalon4-most-pll",
set_int_0_to_7680, opt_show_intval, &opt_avalon4_most_pll_check,
"Set most pll check threshold for smart speed mode 2"),
OPT_WITHOUT_ARG("--avalon4-iic-detect",
opt_set_bool, &opt_avalon4_iic_detect,
"Enable miner detect through iic controller"),
OPT_WITH_ARG("--avalon4-freqadj-time",
set_int_1_to_60, opt_show_intval, &opt_avalon4_freqadj_time,
"Set Avalon4 check interval when run in AVA4_FREQ_TEMPADJ_MODE"),
OPT_WITH_ARG("--avalon4-delta-temp",
opt_set_intval, opt_show_intval, &opt_avalon4_delta_temp,
"Set Avalon4 delta temperature when reset freq in AVA4_FREQ_TEMPADJ_MODE"),
OPT_WITH_ARG("--avalon4-delta-freq",
opt_set_intval, opt_show_intval, &opt_avalon4_delta_freq,
"Set Avalon4 delta freq when adjust freq in AVA4_FREQ_TEMPADJ_MODE"),
OPT_WITH_ARG("--avalon4-freqadj-temp",
opt_set_intval, opt_show_intval, &opt_avalon4_freqadj_temp,
"Set Avalon4 check temperature when run into AVA4_FREQ_TEMPADJ_MODE"),
#endif
#ifdef USE_AVALON7
OPT_WITH_CBARG("--avalon7-voltage",
set_avalon7_voltage, NULL, &opt_set_avalon7_voltage,
"Set Avalon7 default core voltage, in millivolts, step: 78"),
OPT_WITH_CBARG("--avalon7-voltage-level",
set_avalon7_voltage_level, NULL, &opt_set_avalon7_voltage_level,
"Set Avalon7 default level of core voltage, range:[0, 15], step: 1"),
OPT_WITH_CBARG("--avalon7-voltage-offset",
set_avalon7_voltage_offset, NULL, &opt_set_avalon7_voltage_offset,
"Set Avalon7 default offset of core voltage, range:[-2, 1], step: 1"),
OPT_WITH_CBARG("--avalon7-freq",
set_avalon7_freq, NULL, &opt_set_avalon7_freq,
"Set Avalon7 default frequency, range:[24, 1404], step: 12, example: 500"),
OPT_WITH_ARG("--avalon7-freq-sel",
set_int_0_to_5, opt_show_intval, &opt_avalon7_freq_sel,
"Set Avalon7 default frequency select, range:[0, 5], step: 1, example: 3"),
OPT_WITH_CBARG("--avalon7-fan",
set_avalon7_fan, NULL, &opt_set_avalon7_fan,
"Set Avalon7 target fan speed, range:[0, 100], step: 1, example: 0-100"),
OPT_WITH_ARG("--avalon7-temp",
set_int_0_to_100, opt_show_intval, &opt_avalon7_temp_target,
"Set Avalon7 target temperature, range:[0, 100]"),
OPT_WITH_ARG("--avalon7-polling-delay",
set_int_1_to_65535, opt_show_intval, &opt_avalon7_polling_delay,
"Set Avalon7 polling delay value (ms)"),
OPT_WITH_ARG("--avalon7-aucspeed",
opt_set_intval, opt_show_intval, &opt_avalon7_aucspeed,
"Set AUC3 IIC bus speed"),
OPT_WITH_ARG("--avalon7-aucxdelay",
opt_set_intval, opt_show_intval, &opt_avalon7_aucxdelay,
"Set AUC3 IIC xfer read delay, 4800 ~= 1ms"),
OPT_WITH_ARG("--avalon7-smart-speed",
opt_set_intval, opt_show_intval, &opt_avalon7_smart_speed,
"Set Avalon7 smart speed, range 0-1. 0 means Disable"),
OPT_WITH_ARG("--avalon7-th-pass",
set_int_0_to_65535, opt_show_intval, &opt_avalon7_th_pass,
"Set A3212 th pass value"),
OPT_WITH_ARG("--avalon7-th-fail",
set_int_0_to_65535, opt_show_intval, &opt_avalon7_th_fail,
"Set A3212 th fail value"),
OPT_WITH_ARG("--avalon7-th-init",
set_int_0_to_65535, opt_show_intval, &opt_avalon7_th_init,
"Set A3212 th init value"),
OPT_WITH_ARG("--avalon7-th-ms",
set_int_0_to_65535, opt_show_intval, &opt_avalon7_th_ms,
"Set A3212 th ms value"),
OPT_WITH_ARG("--avalon7-th-timeout",
opt_set_uintval, opt_show_uintval, &opt_avalon7_th_timeout,
"Set A3212 th timeout value"),
OPT_WITHOUT_ARG("--avalon7-iic-detect",
opt_set_bool, &opt_avalon7_iic_detect,
"Enable Avalon7 detect through iic controller"),
OPT_WITH_ARG("--avalon7-nonce-mask",
set_int_24_to_32, opt_show_intval, &opt_avalon7_nonce_mask,
"Set A3212 nonce mask, range 24-32."),
OPT_WITHOUT_ARG("--no-avalon7-asic-debug",
opt_set_invbool, &opt_avalon7_asic_debug,
"Disable A3212 debug."),
OPT_WITHOUT_ARG("--avalon7-ssplus-enable",
opt_set_bool, &opt_avalon7_ssplus_enable,
"Enable avalon7 smart speed plus."),
#endif
#ifdef USE_AVALON8
OPT_WITH_CBARG("--avalon8-voltage-level",
set_avalon8_voltage_level, NULL, &opt_set_avalon8_voltage_level,
"Set Avalon8 default level of core voltage, range:[0, 15], step: 1"),
OPT_WITH_CBARG("--avalon8-voltage-level-offset",
set_avalon8_voltage_level_offset, NULL, &opt_set_avalon8_voltage_level_offset,
"Set Avalon8 default offset of core voltage level, range:[-2, 1], step: 1"),
OPT_WITH_CBARG("--avalon8-freq",
set_avalon8_freq, NULL, &opt_set_avalon8_freq,
"Set Avalon8 default frequency, range:[25, 1200], step: 25, example: 800"),
OPT_WITH_ARG("--avalon8-freq-sel",
set_int_0_to_7, opt_show_intval, &opt_avalon8_freq_sel,
"Set Avalon8 default frequency select, range:[0, 7], step: 1, example: 7"),
OPT_WITH_CBARG("--avalon8-fan",
set_avalon8_fan, NULL, &opt_set_avalon8_fan,
"Set Avalon8 target fan speed, range:[0, 100], step: 1, example: 0-100"),
OPT_WITH_ARG("--avalon8-temp",
set_int_0_to_100, opt_show_intval, &opt_avalon8_temp_target,
"Set Avalon8 target temperature, range:[0, 100]"),
OPT_WITH_ARG("--avalon8-polling-delay",
set_int_1_to_65535, opt_show_intval, &opt_avalon8_polling_delay,
"Set Avalon8 polling delay value (ms)"),
OPT_WITH_ARG("--avalon8-aucspeed",
opt_set_intval, opt_show_intval, &opt_avalon8_aucspeed,
"Set AUC3 IIC bus speed"),
OPT_WITH_ARG("--avalon8-aucxdelay",
opt_set_intval, opt_show_intval, &opt_avalon8_aucxdelay,
"Set AUC3 IIC xfer read delay, 4800 ~= 1ms"),
OPT_WITH_ARG("--avalon8-smart-speed",
opt_set_intval, opt_show_intval, &opt_avalon8_smart_speed,
"Set Avalon8 smart speed, range 0-1. 0 means Disable"),
OPT_WITH_ARG("--avalon8-th-pass",
set_int_0_to_65535, opt_show_intval, &opt_avalon8_th_pass,
"Set A3210 th pass value"),
OPT_WITH_ARG("--avalon8-th-fail",
set_int_0_to_65535, opt_show_intval, &opt_avalon8_th_fail,
"Set A3210 th fail value"),
OPT_WITH_ARG("--avalon8-th-init",
set_int_0_to_65535, opt_show_intval, &opt_avalon8_th_init,
"Set A3210 th init value"),
OPT_WITH_ARG("--avalon8-th-ms",
set_int_0_to_65535, opt_show_intval, &opt_avalon8_th_ms,
"Set A3210 th ms value"),
OPT_WITH_ARG("--avalon8-th-timeout",
opt_set_uintval, opt_show_uintval, &opt_avalon8_th_timeout,
"Set A3210 th timeout value"),
OPT_WITH_ARG("--avalon8-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_th_add,
"Set A3210 th add value"),
OPT_WITH_ARG("--avalon8-th-mssel",
set_int_0_to_1, opt_show_intval, &opt_avalon8_th_mssel,
"Set A3210 th mssel value"),
OPT_WITH_ARG("--avalon8-lv2-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_lv2_th_add,
"Set A3210 lv2 th add value"),
OPT_WITH_ARG("--avalon8-lv2-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon8_lv2_th_ms,
"Set A3210 lv2 th ms value"),
OPT_WITH_ARG("--avalon8-lv3-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_lv3_th_add,
"Set A3210 lv3 th add value"),
OPT_WITH_ARG("--avalon8-lv3-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon8_lv3_th_ms,
"Set A3210 lv3 th ms value"),
OPT_WITH_ARG("--avalon8-lv4-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_lv4_th_add,
"Set A3210 lv4 th add value"),
OPT_WITH_ARG("--avalon8-lv4-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon8_lv4_th_ms,
"Set A3210 lv4 th ms value"),
OPT_WITH_ARG("--avalon8-lv5-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_lv5_th_add,
"Set A3210 lv5 th add value"),
OPT_WITH_ARG("--avalon8-lv5-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon8_lv5_th_ms,
"Set A3210 lv5 th ms value"),
OPT_WITH_ARG("--avalon8-lv6-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_lv6_th_add,
"Set A3210 lv6 th add value"),
OPT_WITH_ARG("--avalon8-lv6-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon8_lv6_th_ms,
"Set A3210 lv6 th ms value"),
OPT_WITH_ARG("--avalon8-lv7-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon8_lv7_th_add,
"Set A3210 lv7 th add value"),
OPT_WITH_ARG("--avalon8-lv7-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon8_lv7_th_ms,
"Set A3210 lv7 th ms value"),
OPT_WITHOUT_ARG("--avalon8-iic-detect",
opt_set_bool, &opt_avalon8_iic_detect,
"Enable Avalon8 detect through iic controller"),
OPT_WITH_ARG("--avalon8-nonce-mask",
set_int_24_to_32, opt_show_intval, &opt_avalon8_nonce_mask,
"Set A3210 nonce mask, range 24-32."),
OPT_WITH_ARG("--avalon8-nonce-check",
set_int_0_to_1, opt_show_intval, &opt_avalon8_nonce_check,
"Set A3210 nonce check, range 0-1."),
OPT_WITH_ARG("--avalon8-roll-enable",
set_int_0_to_1, opt_show_intval, &opt_avalon8_roll_enable,
"Set A3210 roll enable, range 0-1."),
OPT_WITH_ARG("--avalon8-mux-l2h",
set_int_0_to_2, opt_show_intval, &opt_avalon8_mux_l2h,
"Set Avalon8 mux l2h, range 0-2."),
OPT_WITH_ARG("--avalon8-mux-h2l",
set_int_0_to_1, opt_show_intval, &opt_avalon8_mux_h2l,
"Set Avalon8 mux h2l, range 0-1."),
OPT_WITH_ARG("--avalon8-h2ltime0-spd",
set_int_0_to_255, opt_show_intval, &opt_avalon8_h2ltime0_spd,
"Set Avalon8 h2ltime0 spd, range 0-255."),
#endif
#ifdef USE_AVALON9
OPT_WITH_CBARG("--avalon9-voltage-level",
set_avalon9_voltage_level, NULL, &opt_set_avalon9_voltage_level,
"Set Avalon9 default level of core voltage, range:[0, 15], step: 1"),
OPT_WITH_CBARG("--avalon9-voltage-level-offset",
set_avalon9_voltage_level_offset, NULL, &opt_set_avalon9_voltage_level_offset,
"Set Avalon9 default offset of core voltage level, range:[-2, 1], step: 1"),
OPT_WITH_CBARG("--avalon9-freq",
set_avalon9_freq, NULL, &opt_set_avalon9_freq,
"Set Avalon9 default frequency, range:[25, 1200], step: 25, example: 800"),
OPT_WITH_ARG("--avalon9-freq-sel",
set_int_0_to_7, opt_show_intval, &opt_avalon9_freq_sel,
"Set Avalon9 default frequency select, range:[0, 7], step: 1, example: 7"),
OPT_WITH_CBARG("--avalon9-fan",
set_avalon9_fan, NULL, &opt_set_avalon9_fan,
"Set Avalon9 target fan speed, range:[0, 100], step: 1, example: 0-100"),
OPT_WITH_ARG("--avalon9-temp",
set_int_0_to_100, opt_show_intval, &opt_avalon9_temp_target,
"Set Avalon9 target temperature, range:[0, 100]"),
OPT_WITH_ARG("--avalon9-polling-delay",
set_int_1_to_65535, opt_show_intval, &opt_avalon9_polling_delay,
"Set Avalon9 polling delay value (ms)"),
OPT_WITH_ARG("--avalon9-aucspeed",
opt_set_intval, opt_show_intval, &opt_avalon9_aucspeed,
"Set AUC3 IIC bus speed"),
OPT_WITH_ARG("--avalon9-aucxdelay",
opt_set_intval, opt_show_intval, &opt_avalon9_aucxdelay,
"Set AUC3 IIC xfer read delay, 4800 ~= 1ms"),
OPT_WITH_ARG("--avalon9-smart-speed",
opt_set_intval, opt_show_intval, &opt_avalon9_smart_speed,
"Set Avalon9 smart speed, range 0-1. 0 means Disable"),
OPT_WITH_ARG("--avalon9-th-pass",
set_int_0_to_65535, opt_show_intval, &opt_avalon9_th_pass,
"Set A3206 th pass value"),
OPT_WITH_ARG("--avalon9-th-fail",
set_int_0_to_65535, opt_show_intval, &opt_avalon9_th_fail,
"Set A3206 th fail value"),
OPT_WITH_ARG("--avalon9-th-init",
set_int_0_to_65535, opt_show_intval, &opt_avalon9_th_init,
"Set A3206 th init value"),
OPT_WITH_ARG("--avalon9-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_th_ms,
"Set A3206 th ms value"),
OPT_WITH_ARG("--avalon9-th-timeout",
opt_set_uintval, opt_show_uintval, &opt_avalon9_th_timeout,
"Set A3206 th timeout value"),
OPT_WITH_ARG("--avalon9-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_th_add,
"Set A3206 th add value"),
OPT_WITH_ARG("--avalon9-th-mssel",
set_int_0_to_1, opt_show_intval, &opt_avalon9_th_mssel,
"Set A3206 th mssel value"),
OPT_WITH_ARG("--avalon9-lv2-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_lv2_th_add,
"Set A3206 lv2 th add value"),
OPT_WITH_ARG("--avalon9-lv2-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_lv2_th_ms,
"Set A3206 lv2 th ms value"),
OPT_WITH_ARG("--avalon9-lv3-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_lv3_th_add,
"Set A3206 lv3 th add value"),
OPT_WITH_ARG("--avalon9-lv3-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_lv3_th_ms,
"Set A3206 lv3 th ms value"),
OPT_WITH_ARG("--avalon9-lv4-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_lv4_th_add,
"Set A3206 lv4 th add value"),
OPT_WITH_ARG("--avalon9-lv4-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_lv4_th_ms,
"Set A3206 lv4 th ms value"),
OPT_WITH_ARG("--avalon9-lv5-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_lv5_th_add,
"Set A3206 lv5 th add value"),
OPT_WITH_ARG("--avalon9-lv5-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_lv5_th_ms,
"Set A3206 lv5 th ms value"),
OPT_WITH_ARG("--avalon9-lv6-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_lv6_th_add,
"Set A3206 lv6 th add value"),
OPT_WITH_ARG("--avalon9-lv6-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_lv6_th_ms,
"Set A3206 lv6 th ms value"),
OPT_WITH_ARG("--avalon9-lv7-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalon9_lv7_th_add,
"Set A3206 lv7 th add value"),
OPT_WITH_ARG("--avalon9-lv7-th-ms",
set_int_0_to_32767, opt_show_intval, &opt_avalon9_lv7_th_ms,
"Set A3206 lv7 th ms value"),
OPT_WITHOUT_ARG("--avalon9-iic-detect",
opt_set_bool, &opt_avalon9_iic_detect,
"Enable Avalon9 detect through iic controller"),
OPT_WITH_ARG("--avalon9-nonce-mask",
set_int_24_to_32, opt_show_intval, &opt_avalon9_nonce_mask,
"Set A3206 nonce mask, range 24-32."),
OPT_WITH_ARG("--avalon9-nonce-check",
set_int_0_to_1, opt_show_intval, &opt_avalon9_nonce_check,
"Set A3206 nonce check, range 0-1."),
OPT_WITH_ARG("--avalon9-roll-enable",
set_int_0_to_1, opt_show_intval, &opt_avalon9_roll_enable,
"Set A3206 roll enable, range 0-1."),
OPT_WITH_ARG("--avalon9-mux-l2h",
set_int_0_to_2, opt_show_intval, &opt_avalon9_mux_l2h,
"Set Avalon9 mux l2h, range 0-2."),
OPT_WITH_ARG("--avalon9-mux-h2l",
set_int_0_to_1, opt_show_intval, &opt_avalon9_mux_h2l,
"Set Avalon9 mux h2l, range 0-1."),
OPT_WITH_ARG("--avalon9-h2ltime0-spd",
set_int_0_to_255, opt_show_intval, &opt_avalon9_h2ltime0_spd,
"Set Avalon9 h2ltime0 spd, range 0-255."),
OPT_WITH_ARG("--avalon9-spdlow",
set_int_0_to_7, opt_show_intval, &opt_avalon9_spdlow,
"Set Avalon9 spdlow, range 0-7."),
OPT_WITH_ARG("--avalon9-spdhigh",
set_int_0_to_7, opt_show_intval, &opt_avalon9_spdhigh,
"Set Avalon9 spdhigh, range 0-7."),
OPT_WITH_ARG("--avalon9-tbase",
set_int_0_to_255, opt_show_intval, &opt_avalon9_tbase,
"Set Avalon9 tbase and use (0-8) bits, range 0-255."),
OPT_WITH_ARG("--avalon9-pid-p",
set_int_0_to_9999, opt_show_intval, &opt_avalon9_pid_p,
"Set Avalon9 pid-p, range 0-9999."),
OPT_WITH_ARG("--avalon9-pid-i",
set_int_0_to_9999, opt_show_intval, &opt_avalon9_pid_i,
"Set Avalon9 pid-i, range 0-9999."),
OPT_WITH_ARG("--avalon9-pid-d",
set_int_0_to_9999, opt_show_intval, &opt_avalon9_pid_d,
"Set Avalon9 pid-d, range 0-9999."),
OPT_WITH_CBARG("--avalon9-adjust-volt-info",
set_avalon9_adjust_volt_info, NULL, &opt_set_avalon9_adjust_volt_info,
"Set Avalon9 adjust volt info, range 0-9999"),
#endif
#ifdef USE_AVALONLC3
OPT_WITH_CBARG("--avalonlc3-voltage-level",
set_avalonlc3_voltage_level, NULL, &opt_set_avalonlc3_voltage_level,
"Set Avalonlc3 default level of core voltage, range:[0, 31], step: 1"),
OPT_WITH_CBARG("--avalonlc3-voltage-level-offset",
set_avalonlc3_voltage_level_offset, NULL, &opt_set_avalonlc3_voltage_level_offset,
"Set Avalonlc3 default offset of core voltage level, range:[-2, 1], step: 1"),
OPT_WITH_CBARG("--avalonlc3-freq",
set_avalonlc3_freq, NULL, &opt_set_avalonlc3_freq,
"Set Avalonlc3 default frequency, range:[25, 1200], step: 25, example: 800"),
OPT_WITH_ARG("--avalonlc3-freq-sel",
set_int_0_to_4, opt_show_intval, &opt_avalonlc3_freq_sel,
"Set Avalonlc3 default frequency select, range:[0, 4], step: 1, example: 3"),
OPT_WITH_CBARG("--avalonlc3-fan",
set_avalonlc3_fan, NULL, &opt_set_avalonlc3_fan,
"Set Avalonlc3 target fan speed, range:[0, 100], step: 1, example: 0-100"),
OPT_WITH_ARG("--avalonlc3-temp",
set_int_0_to_100, opt_show_intval, &opt_avalonlc3_temp_target,
"Set Avalonlc3 target temperature, range:[0, 100]"),
OPT_WITH_ARG("--avalonlc3-polling-delay",
set_int_1_to_65535, opt_show_intval, &opt_avalonlc3_polling_delay,
"Set Avalonlc3 polling delay value (ms)"),
OPT_WITH_ARG("--avalonlc3-aucspeed",
opt_set_intval, opt_show_intval, &opt_avalonlc3_aucspeed,
"Set AUC3 IIC bus speed"),
OPT_WITH_ARG("--avalonlc3-aucxdelay",
opt_set_intval, opt_show_intval, &opt_avalonlc3_aucxdelay,
"Set AUC3 IIC xfer read delay, 4800 ~= 1ms"),
OPT_WITH_ARG("--avalonlc3-smart-speed",
opt_set_intval, opt_show_intval, &opt_avalonlc3_smart_speed,
"Set Avalonlc3 smart speed, range 0-1. 0 means Disable"),
OPT_WITH_ARG("--avalonlc3-th-pass",
set_int_0_to_65535, opt_show_intval, &opt_avalonlc3_th_pass,
"Set A3210M th pass value"),
OPT_WITH_ARG("--avalonlc3-th-fail",
set_int_0_to_65535, opt_show_intval, &opt_avalonlc3_th_fail,
"Set A3210M th fail value"),
OPT_WITH_ARG("--avalonlc3-th-init",
set_int_0_to_65535, opt_show_intval, &opt_avalonlc3_th_init,
"Set A3210M th init value"),
OPT_WITH_ARG("--avalonlc3-th-ms",
set_int_0_to_65535, opt_show_intval, &opt_avalonlc3_th_ms,
"Set A3210M th ms value"),
OPT_WITH_ARG("--avalonlc3-th-timeout",
opt_set_uintval, opt_show_uintval, &opt_avalonlc3_th_timeout,
"Set A3210M th timeout value"),
OPT_WITH_ARG("--avalonlc3-th-add",
set_int_0_to_1, opt_show_intval, &opt_avalonlc3_th_add,
"Set A3210M th add value"),
OPT_WITHOUT_ARG("--avalonlc3-iic-detect",
opt_set_bool, &opt_avalonlc3_iic_detect,
"Enable Avalonlc3 detect through iic controller"),
OPT_WITH_ARG("--avalonlc3-nonce-mask",
set_int_24_to_32, opt_show_intval, &opt_avalonlc3_nonce_mask,
"Set A3210M nonce mask, range 24-32."),
OPT_WITH_ARG("--avalonlc3-nonce-check",
set_int_0_to_1, opt_show_intval, &opt_avalonlc3_nonce_check,
"Set A3210M nonce check, range 0-1."),
OPT_WITH_ARG("--avalonlc3-roll-enable",
set_int_0_to_1, opt_show_intval, &opt_avalonlc3_roll_enable,
"Set A3210M roll enable, range 0-1."),
OPT_WITH_ARG("--avalonlc3-mux-l2h",
set_int_0_to_2, opt_show_intval, &opt_avalonlc3_mux_l2h,
"Set Avalonlc3 mux l2h, range 0-2."),
OPT_WITH_ARG("--avalonlc3-mux-h2l",
set_int_0_to_1, opt_show_intval, &opt_avalonlc3_mux_h2l,
"Set Avalonlc3 mux h2l, range 0-1."),
OPT_WITH_ARG("--avalonlc3-h2ltime0-spd",
set_int_0_to_255, opt_show_intval, &opt_avalonlc3_h2ltime0_spd,
"Set Avalonlc3 h2ltime0 spd, range 0-255."),
OPT_WITH_ARG("--avalonlc3-spdlow",
set_int_0_to_3, opt_show_intval, &opt_avalonlc3_spdlow,
"Set Avalonlc3 spdlow, range 0-3."),
OPT_WITH_ARG("--avalonlc3-spdhigh",
set_int_0_to_3, opt_show_intval, &opt_avalonlc3_spdhigh,
"Set Avalonlc3 spdhigh, range 0-3."),
OPT_WITH_ARG("--avalonlc3-tbase",
set_int_0_to_255, opt_show_intval, &opt_avalonlc3_tbase,
"Set Avalonlc3 tbase and use (0-8) bits, range 0-255."),
OPT_WITH_CBARG("--avalonlc3-cinfo-asic",
set_avalonlc3_asic_otp, NULL, &opt_set_avalonlc3_asic_otp,
"Set Avalonlc3 cinfo asic index, range:[0, 25], step: 1"),
OPT_WITH_ARG("--avalonlc3-pid-p",
set_int_0_to_9999, opt_show_intval, &opt_avalonlc3_pid_p,
"Set Avalonlc3 pid-p, range 0-9999."),
OPT_WITH_ARG("--avalonlc3-pid-i",
set_int_0_to_9999, opt_show_intval, &opt_avalonlc3_pid_i,
"Set Avalonlc3 pid-i, range 0-9999."),
OPT_WITH_ARG("--avalonlc3-pid-d",
set_int_0_to_9999, opt_show_intval, &opt_avalonlc3_pid_d,
"Set Avalonlc3 pid-d, range 0-9999."),
#endif
#ifdef USE_AVALON_MINER
OPT_WITH_CBARG("--avalonm-voltage",
set_avalonm_voltage, NULL, &opt_set_avalonm_voltage,
"Set Avalon miner core voltage, in millivolts, step: 125"),
OPT_WITH_CBARG("--avalonm-freq",
set_avalonm_freq, NULL, &opt_set_avalonm_freq,
"Set frequency for Avalon miner, 1 to 3 values, example: 275:250:200"),
OPT_WITH_ARG("--avalonm-ntime-offset",
opt_set_intval, opt_show_intval, &opt_avalonm_ntime_offset,
"Set Avalon miner ntime rolling max offset, range 0-4"),
OPT_WITH_ARG("--avalonm-spispeed",
opt_set_intval, opt_show_intval, &opt_avalonm_spispeed,
"Set spi speed for Avalon miner"),
OPT_WITHOUT_ARG("--avalonm-automatic-freq",
opt_set_bool, &opt_avalonm_autof,
"Automatic adjust frequency base on chip HW"),
#endif
#ifdef USE_BAB
OPT_WITH_ARG("--bab-options",
opt_set_charp, NULL, &opt_bab_options,
"Set bab options max:def:min:up:down:hz:delay:trf"),
#endif
OPT_WITHOUT_ARG("--balance",
set_balance, &pool_strategy,
"Change multipool strategy from failover to even share balance"),
OPT_WITH_ARG("--benchfile",
opt_set_charp, NULL, &opt_benchfile,
"Run cgminer in benchmark mode using a work file - produces no shares"),
OPT_WITHOUT_ARG("--benchfile-display",
opt_set_bool, &opt_benchfile_display,
"Display each benchfile nonce found"),
OPT_WITHOUT_ARG("--benchmark",
opt_set_bool, &opt_benchmark,
"Run cgminer in benchmark mode - produces no shares"),
#if defined(USE_BITFORCE)
OPT_WITHOUT_ARG("--bfl-range",
opt_set_bool, &opt_bfl_noncerange,
"Use nonce range on bitforce devices if supported"),
#endif
#ifdef USE_BFLSC
OPT_WITH_ARG("--bflsc-overheat",
set_int_0_to_200, opt_show_intval, &opt_bflsc_overheat,
"Set overheat temperature where BFLSC devices throttle, 0 to disable"),
#endif
#ifdef USE_AVALON
OPT_WITH_ARG("--bitburner-voltage",
opt_set_intval, NULL, &opt_bitburner_core_voltage,
"Set BitBurner (Avalon) core voltage, in millivolts"),
OPT_WITH_ARG("--bitburner-fury-voltage",
opt_set_intval, NULL, &opt_bitburner_fury_core_voltage,
"Set BitBurner Fury core voltage, in millivolts"),
OPT_WITH_ARG("--bitburner-fury-options",
opt_set_charp, NULL, &opt_bitburner_fury_options,
"Override avalon-options for BitBurner Fury boards baud:miners:asic:timeout:freq"),
#endif
#if defined(USE_ANT_S1) || defined(USE_ANT_S2)
OPT_WITH_ARG("--bitmain-cutoff",
set_int_0_to_100, opt_show_intval, &opt_bitmain_overheat,
"Set bitmain overheat cut off temperature"),
OPT_WITH_CBARG("--bitmain-fan",
set_bitmain_fan, NULL, &opt_set_bitmain_fan,
"Set fanspeed percentage for bitmain, single value or range (default: 20-100)"),
OPT_WITH_CBARG("--bitmain-freq",
opt_set_charp, NULL, &opt_bitmain_freq,
"Set bitmain freq options timeout:freq:regdata"),
OPT_WITHOUT_ARG("--bitmain-hwerror",
opt_set_bool, &opt_bitmain_hwerror,
"Set bitmain device detect hardware error"),
OPT_WITH_ARG("--bitmain-options",
opt_set_charp, NULL, &opt_bitmain_options,
#ifdef USE_ANT_S1
"Set bitmain options baud:miners:asic:timeout:freq:regdata"
#else
"Set bitmain options baud:miners:asic:ignored..."
#endif
),
OPT_WITH_ARG("--bitmain-temp",
set_int_0_to_100, opt_show_intval, &opt_bitmain_temp,
"Set bitmain target temperature"),
OPT_WITH_ARG("--bitmain-workdelay",
set_int_0_to_100, opt_show_intval, &opt_bitmain_workdelay,
"Set bitmain work delay (ms) 0-100"),
// Ignored
OPT_WITHOUT_ARG("--bitmain-auto",
opt_set_bool, &opt_bitmain_auto,
opt_hidden),
OPT_WITHOUT_ARG("--bitmain-nobeeper",
opt_set_bool, &opt_bitmain_nobeeper,
opt_hidden),
OPT_WITHOUT_ARG("--bitmain-notempoverctrl",
opt_set_bool, &opt_bitmain_notempoverctrl,
opt_hidden),
#ifdef USE_ANT_S1
// S1 has no effect
OPT_WITHOUT_ARG("--bitmainbeeper",
opt_set_bool, &opt_bitmain_beeper,
opt_hidden),
OPT_WITHOUT_ARG("--bitmaintempoverctrl",
opt_set_bool, &opt_bitmain_tempoverctrl,
opt_hidden),
OPT_WITHOUT_ARG("--bitmain-homemode",
opt_set_bool, &opt_bitmain_homemode,
opt_hidden),
#endif
#endif
#ifdef USE_ANT_S2
OPT_WITH_ARG("--bitmain-voltage",
opt_set_charp, NULL, &opt_bitmain_voltage,
"Set bitmain voltage (default: "BITMAIN_VOLTAGE_DEF")"),
#ifndef USE_ANT_S3
OPT_WITH_ARG("--bitmain-dev",
opt_set_charp, NULL, &opt_bitmain_dev,
"Set bitmain device"),
#endif
OPT_WITHOUT_ARG("--bitmainbeeper",
opt_set_bool, &opt_bitmain_beeper,
"Set bitmain beeper ringing"),
OPT_WITHOUT_ARG("--bitmain-checkall",
opt_set_bool, &opt_bitmain_checkall,
opt_hidden),
OPT_WITHOUT_ARG("--bitmain-checkn2diff",
opt_set_bool, &opt_bitmain_checkn2diff,
opt_hidden),
OPT_WITHOUT_ARG("--bitmaintempoverctrl",
opt_set_bool, &opt_bitmain_tempoverctrl,
"Set bitmain stop runing when temprerature is over 80 degree Celsius"),
OPT_WITHOUT_ARG("--bitmain-homemode",
opt_set_bool, &opt_bitmain_homemode,
"Set bitmain miner to home mode"),
#endif
#ifdef USE_BITMINE_A1
OPT_WITH_ARG("--bitmine-a1-options",
opt_set_charp, NULL, &opt_bitmine_a1_options,
"Bitmine A1 options ref_clk_khz:sys_clk_khz:spi_clk_khz:override_chip_num"),
#endif
OPT_WITHOUT_ARG("--block-check",
opt_set_bool, &opt_blockcheck,
"Run a block diff check of the binary then exit"),
#ifdef USE_BITFURY
OPT_WITH_ARG("--bxf-bits",
set_int_32_to_63, opt_show_intval, &opt_bxf_bits,
"Set max BXF/HXF bits for overclocking"),
OPT_WITH_ARG("--bxf-debug",
set_int_0_to_4, opt_show_intval, &opt_bxf_debug,
"BXF: Debug all USB I/O, > is to the board(s), < is from the board(s)"),
OPT_WITH_ARG("--bxf-temp-target",
set_int_0_to_200, opt_show_intval, &opt_bxf_temp_target,
"Set target temperature for BXF/HXF devices"),
OPT_WITH_ARG("--bxm-bits",
set_int_0_to_100, opt_show_intval, &opt_bxm_bits,
"Set BXM bits for overclocking"),
#endif
#ifdef USE_BITFURY16
OPT_WITHOUT_ARG("--bf16-set-clock",
opt_set_bool, &opt_bf16_set_clock,
"Set clock to all chips"),
OPT_WITH_ARG("--bf16-test-chip",
opt_set_charp, NULL, &opt_bf16_test_chip,
"Test BF16 chip communication: [board_id:bcm250_id:chip_id]"),
OPT_WITH_ARG("--bf16-clock",
opt_set_charp, NULL, &opt_bf16_clock,
"BF16 chips clock value"),
OPT_WITH_ARG("--bf16-renonce-clock",
opt_set_charp, NULL, &opt_bf16_renonce_clock,
"BF16 renonce chip clock value"),
OPT_WITHOUT_ARG("--bf16-enable-stats",
opt_set_bool, &opt_bf16_stats_enabled,
"Enable statistics thread"),
OPT_WITHOUT_ARG("--bf16-disable-power-management",
opt_set_bool, &opt_bf16_power_management_disabled,
"Disable automatic power management"),
OPT_WITH_ARG("--bf16-renonce",
set_int_0_to_2, NULL, &opt_bf16_renonce,
"Renonce functionality: 0 - disabled, 1 - one chip, 2 - chip per board"),
#ifdef MINER_X5
OPT_WITHOUT_ARG("--bf16-manual-pid-enable",
opt_set_bool, &opt_bf16_manual_pid_enabled,
"Enable manual PID regulator"),
#endif
#ifdef MINER_X6
OPT_WITHOUT_ARG("--bf16-manual-pid-disable",
opt_set_bool, &opt_bf16_manual_pid_disabled,
"Disable manual PID regulator"),
#endif
OPT_WITH_ARG("--bf16-fan-speed",
set_int_0_to_100, NULL, &opt_bf16_fan_speed,
"Set fan speed in '%' range (0 - 100)"),
OPT_WITH_ARG("--bf16-target-temp",
set_int_0_to_100, NULL, &opt_bf16_target_temp,
"Set control board target temperature range (0 - 100)"),
OPT_WITH_ARG("--bf16-alarm-temp",
set_int_0_to_100, NULL, &opt_bf16_alarm_temp,
"Set control board alarm temperature range (0 - 100)"),
#endif
#ifdef USE_BITMAIN_SOC
OPT_WITH_ARG("--version-file",
set_version_path, NULL, opt_hidden,
"Set miner version file"),
OPT_WITHOUT_ARG("--bitmain-fan-ctrl",
opt_set_bool, &opt_bitmain_fan_ctrl,
"Enable bitmain miner fan controlling"),
OPT_WITH_ARG("--bitmain-fan-pwm",
set_int_0_to_100, opt_show_intval, &opt_bitmain_fan_pwm,
"Set bitmain fan pwm percentage 0~100"),
OPT_WITH_ARG("--bitmain-freq",
set_int_0_to_9999,opt_show_intval, &opt_bitmain_soc_freq,
"Set frequency"),
OPT_WITH_ARG("--bitmain-voltage",
set_int_0_to_9999,opt_show_intval, &opt_bitmain_soc_voltage,
"Set voltage"),
OPT_WITHOUT_ARG("--fixed-freq",
opt_set_bool, &opt_fixed_freq,
"Set bitmain miner use fixed freq"),
OPT_WITHOUT_ARG("--no-pre-heat",
opt_set_false, &opt_pre_heat,
"Set bitmain miner doesn't pre heat"),
OPT_WITH_ARG("--multi-version",
opt_set_intval, NULL, &opt_multi_version,
"Multi version mining!"),
#endif
#ifdef USE_BLOCKERUPTER
OPT_WITH_ARG("--bet-clk",
opt_set_intval, opt_show_intval, &opt_bet_clk,
"Set Block Erupter clock"),
#endif
#ifdef USE_GEKKO
OPT_WITH_ARG("--gekko-serial",
opt_set_charp, NULL, &opt_gekko_serial,
"Detect GekkoScience Device by Serial Number"),
OPT_WITHOUT_ARG("--gekko-compac-detect",
opt_set_bool, &opt_gekko_gsc_detect,
"Detect GekkoScience Compac BM1384"),
OPT_WITHOUT_ARG("--gekko-2pac-detect",
opt_set_bool, &opt_gekko_gsd_detect,
"Detect GekkoScience 2Pac BM1384"),
OPT_WITHOUT_ARG("--gekko-terminus-detect",
opt_set_bool, &opt_gekko_gse_detect,
"Detect GekkoScience Terminus BM1384"),
OPT_WITHOUT_ARG("--gekko-newpac-detect",
opt_set_bool, &opt_gekko_gsh_detect,
"Detect GekkoScience NewPac BM1387"),
OPT_WITHOUT_ARG("--gekko-bitaxe-detect",
opt_set_bool, &opt_gekko_bax_detect,
"Detect GekkoScience NewPac BM1387"),
OPT_WITHOUT_ARG("--gekko-r606-detect",
opt_set_bool, &opt_gekko_gsi_detect,
"Detect GekkoScience Terminus BM1387"),
OPT_WITHOUT_ARG("--gekko-compacf-detect",
opt_set_bool, &opt_gekko_gsf_detect,
"Detect GekkoScience CompacF BM1397"),
OPT_WITHOUT_ARG("--gekko-r909-detect",
opt_set_bool, &opt_gekko_r909_detect,
"Detect GekkoScience Terminus R909 BM1397"),
OPT_WITHOUT_ARG("--gekko-noboost",
opt_set_bool, &opt_gekko_noboost,
"Disable GekkoScience NewPac/R606/CompacF AsicBoost"),
OPT_WITHOUT_ARG("--gekko-lowboost",
opt_set_bool, &opt_gekko_lowboost,
"GekkoScience NewPac/R606 AsicBoost - 2 midstate"),
OPT_WITH_ARG("--gekko-terminus-freq",
set_float_0_to_500, opt_show_floatval, &opt_gekko_gse_freq,
"Set GekkoScience Terminus BM1384 frequency in MHz, range 6.25-500"),
OPT_WITH_ARG("--gekko-2pac-freq",
set_float_0_to_500, opt_show_floatval, &opt_gekko_gsd_freq,
"Set GekkoScience 2Pac BM1384 frequency in MHz, range 6.25-500"),
OPT_WITH_ARG("--gekko-compac-freq",
set_float_0_to_500, opt_show_floatval, &opt_gekko_gsc_freq,
"Set GekkoScience Compac BM1384 frequency in MHz, range 6.25-500"),
OPT_WITH_ARG("--gekko-tune-down",
set_float_0_to_500, opt_show_floatval, &opt_gekko_tune_down,
"Set GekkoScience miner minimum hash quality, range 0-100"),
OPT_WITH_ARG("--gekko-tune-up",
set_float_0_to_500, opt_show_floatval, &opt_gekko_tune_up,
"Set GekkoScience miner ramping hash threshold, rante 0-99"),
OPT_WITH_ARG("--gekko-wait-factor",
set_float_0_to_500, opt_show_floatval, &opt_gekko_wait_factor,
"Set GekkoScience miner task send wait factor, range 0.01-2.00"),
OPT_WITH_ARG("--gekko-bauddiv",
set_int_0_to_9999, opt_show_intval, &opt_gekko_bauddiv,
"Set GekkoScience BM1387 baud divider {0: auto, 1: 1.5M, 7: 375K, 13: 214K, 25: 115K}"),
OPT_WITH_ARG("--gekko-newpac-freq",
set_int_0_to_9999, opt_show_intval, &opt_gekko_gsh_freq,
"Set GekkoScience NewPac BM1387 frequency in MHz, range 50-900"),
OPT_WITH_ARG("--gekko-bitaxe-freq",
set_int_0_to_9999, opt_show_intval, &opt_gekko_bax_freq,
"Set GekkoScience Bitaxe BM1387 frequency in MHz, range 50-900"),
OPT_WITH_ARG("--gekko-r606-freq",
set_int_0_to_9999, opt_show_intval, &opt_gekko_gsi_freq,
"Set GekkoScience Terminus R606 frequency in MHz, range 50-900"),
OPT_WITH_ARG("--gekko-compacf-freq",
set_int_0_to_9999, opt_show_intval, &opt_gekko_gsf_freq,
"Set GekkoScience CompacF BM1397 frequency in MHz, range 100-800"),
OPT_WITH_ARG("--gekko-r909-freq",
set_int_0_to_9999, opt_show_intval, &opt_gekko_r909_freq,
"Set GekkoScience Terminus R909 BM1397 frequency in MHz, range 100-800"),
OPT_WITH_ARG("--gekko-start-freq",
set_int_0_to_9999, opt_show_intval, &opt_gekko_start_freq,
"Ramp start frequency MHz 25-500"),
OPT_WITH_ARG("--gekko-step-freq",
set_float_0_to_500, opt_show_intval, &opt_gekko_step_freq,
"Ramp frequency step MHz 1-100"),
OPT_WITH_ARG("--gekko-step-delay",
set_int_0_to_9999, opt_show_intval, &opt_gekko_step_delay,
"Ramp step interval range 1-600"),
OPT_WITHOUT_ARG("--gekko-mine2",
opt_set_bool, &opt_gekko_mine2, opt_hidden), // ignored
OPT_WITH_ARG("--gekko-tune2",
set_int_0_to_9999, opt_show_intval, &opt_gekko_tune2,
"Tune up mine2 mins 30-9999, default 0=never"),
#endif
#ifdef HAVE_LIBCURL
OPT_WITH_ARG("--btc-address",
opt_set_charp, NULL, &opt_btc_address,
"Set bitcoin target address when solo mining to bitcoind (mandatory)"),
OPT_WITH_ARG("--btc-sig",
opt_set_charp, NULL, &opt_btc_sig,
"Set signature to add to coinbase when solo mining (optional)"),
#endif
#ifdef HAVE_CURSES
OPT_WITHOUT_ARG("--compact",
opt_set_bool, &opt_compact,
"Use compact display without per device statistics"),
#endif
#ifdef USE_COINTERRA
OPT_WITH_ARG("--cta-load",
set_int_0_to_255, opt_show_intval, &opt_cta_load,
"Set load for CTA devices, 0-255 range"),
OPT_WITH_ARG("--ps-load",
set_int_0_to_100, opt_show_intval, &opt_ps_load,
"Set power supply load for CTA devices, 0-100 range"),
#endif
OPT_WITHOUT_ARG("--debug|-D",
enable_debug, &opt_debug,
"Enable debug output"),
#ifdef HAVE_CURSES
OPT_WITHOUT_ARG("--decode",
opt_set_bool, &opt_decode,
"Decode 2nd pool stratum coinbase transactions (1st must be bitcoind) and exit"),
#endif
OPT_WITHOUT_ARG("--disable-rejecting",
opt_set_bool, &opt_disable_pool,
"Automatically disable pools that continually reject shares"),
#ifdef USE_DRAGONMINT_T1
OPT_WITH_ARG("--dragonmint-t1-options",
opt_set_charp, NULL, &opt_dragonmint_t1_options,
"Dragonmint T1 options ref_clk_khz:sys_clk_khz:spi_clk_khz:override_chip_num"),
OPT_WITHOUT_ARG("--T1efficient",
opt_set_bool, &opt_T1_efficient,
"Tune Dragonmint T1 per chain voltage and frequency for optimal efficiency"),
OPT_WITHOUT_ARG("--T1factory",
opt_set_invbool, &opt_T1auto,
opt_hidden),
OPT_WITHOUT_ARG("--T1noauto",
opt_set_invbool, &opt_T1auto,
"Disable Dragonmint T1 per chain auto voltage and frequency tuning"),
OPT_WITHOUT_ARG("--T1performance",
opt_set_bool, &opt_T1_performance,
"Tune Dragonmint T1 per chain voltage and frequency for maximum performance"),
OPT_WITH_ARG("--T1fantarget",
opt_set_intval, opt_show_intval, &opt_T1_target,
"Throttle T1 frequency to keep fan less than target fan speed"),
OPT_WITH_ARG("--T1Pll1",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[0],
"Set PLL Clock 1 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll2",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[1],
"Set PLL Clock 2 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll3",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[2],
"Set PLL Clock 3 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll4",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[3],
"Set PLL Clock 4 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll5",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[4],
"Set PLL Clock 5 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll6",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[5],
"Set PLL Clock 6 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll7",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[6],
"Set PLL Clock 7 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Pll8",
set_int_0_to_9999, opt_show_intval, &opt_T1Pll[7],
"Set PLL Clock 8 in Dragonmint T1 broad 1 chip (-1: 1000MHz, >0:Lookup PLL table)"),
OPT_WITH_ARG("--T1Volt1",
set_int_voltage, opt_show_intval, &opt_T1Vol[0],
"Dragonmint T1 set voltage 1 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt2",
set_int_voltage, opt_show_intval, &opt_T1Vol[1],
"Dragonmint T1 set voltage 2 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt3",
set_int_voltage, opt_show_intval, &opt_T1Vol[2],
"Dragonmint T1 set voltage 3 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt4",
set_int_voltage, opt_show_intval, &opt_T1Vol[3],
"Dragonmint T1 set voltage 4 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt5",
set_int_voltage, opt_show_intval, &opt_T1Vol[4],
"Dragonmint T1 set voltage 5 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt6",
set_int_voltage, opt_show_intval, &opt_T1Vol[5],
"Dragonmint T1 set voltage 6 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt7",
set_int_voltage, opt_show_intval, &opt_T1Vol[6],
"Dragonmint T1 set voltage 7 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1Volt8",
set_int_voltage, opt_show_intval, &opt_T1Vol[7],
"Dragonmint T1 set voltage 8 - VID overrides if set (390-425)"),
OPT_WITH_ARG("--T1VID1",
set_int_1_to_31, opt_show_intval, &opt_T1VID[0],
"Dragonmint T1 set VID 1 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID2",
set_int_1_to_31, opt_show_intval, &opt_T1VID[1],
"Dragonmint T1 set VID 2 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID3",
set_int_1_to_31, opt_show_intval, &opt_T1VID[2],
"Dragonmint T1 set VID 3 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID4",
set_int_1_to_31, opt_show_intval, &opt_T1VID[3],
"Dragonmint T1 set VID 4 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID5",
set_int_1_to_31, opt_show_intval, &opt_T1VID[4],
"Dragonmint T1 set VID 5 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID6",
set_int_1_to_31, opt_show_intval, &opt_T1VID[5],
"Dragonmint T1 set VID 6 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID7",
set_int_1_to_31, opt_show_intval, &opt_T1VID[6],
"Dragonmint T1 set VID 7 in noauto - Overrides voltage if set (1-31)"),
OPT_WITH_ARG("--T1VID8",
set_int_1_to_31, opt_show_intval, &opt_T1VID[7],
"Dragonmint T1 set VID 8 in noauto - Overrides voltage if set (1-31)"),
#endif
#ifdef USE_DRILLBIT
OPT_WITH_ARG("--drillbit-options",
opt_set_charp, NULL, &opt_drillbit_options,
"Set drillbit options <int|ext>:clock[:clock_divider][:voltage]"),
OPT_WITH_ARG("--drillbit-auto",
opt_set_charp, NULL, &opt_drillbit_auto,
"Enable drillbit automatic tuning <every>:[<gooderr>:<baderr>:<maxerr>]"),
#endif
OPT_WITH_ARG("--expiry|-E",
set_null, NULL, &opt_set_null,
opt_hidden),
#ifdef USE_XTRANONCE
OPT_WITHOUT_ARG("--extranonce-subscribe",
set_extranonce_subscribe, NULL,
"Enable 'extranonce' stratum subscribe"),
#endif
OPT_WITHOUT_ARG("--failover-only",
set_null, &opt_set_null,
opt_hidden),
OPT_WITH_ARG("--fallback-time",
opt_set_intval, opt_show_intval, &opt_pool_fallback,
"Set time in seconds to fall back to a higher priority pool after period of instability"),
OPT_WITHOUT_ARG("--fix-protocol",
opt_set_bool, &opt_fix_protocol,
"Do not redirect to stratum protocol from GBT"),
#ifdef USE_HASHFAST
OPT_WITHOUT_ARG("--hfa-dfu-boot",
opt_set_bool, &opt_hfa_dfu_boot,
opt_hidden),
OPT_WITH_ARG("--hfa-hash-clock",
set_int_0_to_9999, opt_show_intval, &opt_hfa_hash_clock,
"Set hashfast clock speed"),
OPT_WITH_ARG("--hfa-fail-drop",
set_int_0_to_100, opt_show_intval, &opt_hfa_fail_drop,
"Set how many MHz to drop clockspeed each failure on an overlocked hashfast device"),
OPT_WITH_CBARG("--hfa-fan",
set_hfa_fan, NULL, &opt_set_hfa_fan,
"Set fanspeed percentage for hashfast, single value or range (default: 10-85)"),
OPT_WITH_ARG("--hfa-name",
opt_set_charp, NULL, &opt_hfa_name,
"Set a unique name for a single hashfast device specified with --usb or the first device found"),
OPT_WITHOUT_ARG("--hfa-noshed",
opt_set_bool, &opt_hfa_noshed,
"Disable hashfast dynamic core disabling feature"),
OPT_WITH_ARG("--hfa-ntime-roll",
opt_set_intval, NULL, &opt_hfa_ntime_roll,
opt_hidden),
OPT_WITH_ARG("--hfa-options",
opt_set_charp, NULL, &opt_hfa_options,
"Set hashfast options name:clock (comma separated)"),
OPT_WITHOUT_ARG("--hfa-pll-bypass",
opt_set_bool, &opt_hfa_pll_bypass,
opt_hidden),
OPT_WITH_ARG("--hfa-temp-overheat",
set_int_0_to_200, opt_show_intval, &opt_hfa_overheat,
"Set the hashfast overheat throttling temperature"),
OPT_WITH_ARG("--hfa-temp-target",
set_int_0_to_200, opt_show_intval, &opt_hfa_target,
"Set the hashfast target temperature (0 to disable)"),
#endif
#ifdef USE_HASHRATIO
OPT_WITH_CBARG("--hro-freq",
set_hashratio_freq, NULL, &opt_hashratio_freq,
"Set the hashratio clock frequency"),
#endif
OPT_WITH_ARG("--hotplug",
set_int_0_to_9999, NULL, &hotplug_time,
#ifdef USE_USBUTILS
"Seconds between hotplug checks (0 means never check)"
#else
opt_hidden
#endif
),
#ifdef USE_ICARUS
OPT_WITH_ARG("--icarus-options",
opt_set_charp, NULL, &opt_icarus_options,
opt_hidden),
OPT_WITH_ARG("--icarus-timing",
opt_set_charp, NULL, &opt_icarus_timing,
opt_hidden),
#endif
#if defined(HAVE_MODMINER)
OPT_WITH_ARG("--kernel-path|-K",
opt_set_charp, opt_show_charp, &opt_kernel_path,
"Specify a path to where bitstream files are"),
#endif
#ifdef USE_KLONDIKE
OPT_WITH_ARG("--klondike-options",
opt_set_charp, NULL, &opt_klondike_options,
"Set klondike options clock:temptarget"),
#endif
OPT_WITHOUT_ARG("--load-balance",
set_loadbalance, &pool_strategy,
"Change multipool strategy from failover to quota based balance"),
OPT_WITH_ARG("--log|-l",
set_int_0_to_9999, opt_show_intval, &opt_log_interval,
"Interval in seconds between log output"),
OPT_WITHOUT_ARG("--lowmem",
opt_set_bool, &opt_lowmem,
"Minimise caching of shares for low memory applications"),
OPT_WITHOUT_ARG("--mac-yield",
opt_set_bool, &opt_mac_yield,
"Allow yield on old macs (default dont)"),
#ifdef USE_MINION
OPT_WITH_ARG("--minion-chipreport",
set_int_0_to_100, opt_show_intval, &opt_minion_chipreport,
"Seconds to report chip 5min hashrate, range 0-100 (default: 0=disabled)"),
OPT_WITH_ARG("--minion-cores",
opt_set_charp, NULL, &opt_minion_cores,
opt_hidden),
OPT_WITHOUT_ARG("--minion-extra",
opt_set_bool, &opt_minion_extra,
opt_hidden),
OPT_WITH_ARG("--minion-freq",
opt_set_charp, NULL, &opt_minion_freq,
"Set minion chip frequencies in MHz, single value or comma list, range 100-1400 (default: 1200)"),
OPT_WITH_ARG("--minion-freqchange",
set_int_0_to_9999, opt_show_intval, &opt_minion_freqchange,
"Millisecond total time to do frequency changes (default: 1000)"),
OPT_WITH_ARG("--minion-freqpercent",
set_int_0_to_100, opt_show_intval, &opt_minion_freqpercent,
"Percentage to use when starting up a chip (default: 70%)"),
OPT_WITHOUT_ARG("--minion-idlecount",
opt_set_bool, &opt_minion_idlecount,
"Report when IdleCount is >0 or changes"),
OPT_WITH_ARG("--minion-ledcount",
set_int_0_to_100, opt_show_intval, &opt_minion_ledcount,
"Turn off led when more than this many chips below the ledlimit (default: 0)"),
OPT_WITH_ARG("--minion-ledlimit",
set_int_0_to_200, opt_show_intval, &opt_minion_ledlimit,
"Turn off led when chips GHs are below this (default: 90)"),
OPT_WITHOUT_ARG("--minion-noautofreq",
opt_set_bool, &opt_minion_noautofreq,
"Disable automatic frequency adjustment"),
OPT_WITHOUT_ARG("--minion-overheat",
opt_set_bool, &opt_minion_overheat,
"Enable directly halting any chip when the status exceeds 100C"),
OPT_WITH_ARG("--minion-spidelay",
set_int_0_to_9999, opt_show_intval, &opt_minion_spidelay,
"Add a delay in microseconds after each SPI I/O"),
OPT_WITH_ARG("--minion-spireset",
opt_set_charp, NULL, &opt_minion_spireset,
"SPI regular reset: iNNN for I/O count or sNNN for seconds - 0 means none"),
OPT_WITH_ARG("--minion-spisleep",
set_int_0_to_9999, opt_show_intval, &opt_minion_spisleep,
"Sleep time in milliseconds when doing an SPI reset"),
OPT_WITH_ARG("--minion-spiusec",
set_int_0_to_9999, NULL, &opt_minion_spiusec,
opt_hidden),
OPT_WITH_ARG("--minion-temp",
opt_set_charp, NULL, &opt_minion_temp,
"Set minion chip temperature threshold, single value or comma list, range 120-160 (default: 135C)"),
#endif
#if defined(unix) || defined(__APPLE__)
OPT_WITH_ARG("--monitor|-m",
opt_set_charp, NULL, &opt_stderr_cmd,
"Use custom pipe cmd for output messages"),
#endif // defined(unix)
#ifdef USE_BITFURY
OPT_WITH_ARG("--nfu-bits",
set_int_32_to_63, opt_show_intval, &opt_nfu_bits,
"Set nanofury bits for overclocking, range 32-63"),
#endif
OPT_WITHOUT_ARG("--net-delay",
opt_set_bool, &opt_delaynet,
"Impose small delays in networking to not overload slow routers"),
OPT_WITHOUT_ARG("--no-pool-disable",
opt_set_invbool, &opt_disable_pool,
opt_hidden),
OPT_WITHOUT_ARG("--no-submit-stale",
opt_set_invbool, &opt_submit_stale,
"Don't submit shares if they are detected as stale"),
#ifdef USE_BITFURY
OPT_WITH_ARG("--osm-led-mode",
set_int_0_to_4, opt_show_intval, &opt_osm_led_mode,
"Set LED mode for OneStringMiner devices"),
#endif
OPT_WITH_ARG("--pass|-p",
set_pass, NULL, &opt_set_null,
"Password for bitcoin JSON-RPC server"),
OPT_WITHOUT_ARG("--per-device-stats",
opt_set_bool, &want_per_device_stats,
"Force verbose mode and output per-device statistics"),
OPT_WITH_ARG("--pools",
opt_set_bool, NULL, &opt_set_null, opt_hidden),
OPT_WITHOUT_ARG("--protocol-dump|-P",
opt_set_bool, &opt_protocol,
"Verbose dump of protocol-level activities"),
OPT_WITH_ARG("--queue|-Q",
set_null, NULL, &opt_set_null,
opt_hidden),
OPT_WITHOUT_ARG("--quiet|-q",
opt_set_bool, &opt_quiet,
"Disable logging output, display status and errors"),
OPT_WITH_ARG("--quota|-U",
set_quota, NULL, &opt_set_null,
"quota;URL combination for server with load-balance strategy quotas"),
OPT_WITHOUT_ARG("--real-quiet",
opt_set_bool, &opt_realquiet,
"Disable all output"),
OPT_WITH_ARG("--retries",
set_null, NULL, &opt_set_null,
opt_hidden),
OPT_WITH_ARG("--retry-pause",
set_null, NULL, &opt_set_null,
opt_hidden),
#ifdef USE_ICARUS
OPT_WITH_ARG("--rock-freq",
set_float_125_to_500, &opt_show_floatval, &opt_rock_freq,
"Set RockMiner frequency in MHz, range 125-500"),
#endif
OPT_WITH_ARG("--rotate",
set_rotate, NULL, &opt_set_null,
"Change multipool strategy from failover to regularly rotate at N minutes"),
OPT_WITHOUT_ARG("--round-robin",
set_rr, &pool_strategy,
"Change multipool strategy from failover to round robin on failure"),
#ifdef USE_FPGA_SERIAL
OPT_WITH_CBARG("--scan-serial|-S",
add_serial, NULL, &opt_add_serial,
"Serial port to probe for Serial FPGA Mining device"),
#endif
OPT_WITH_ARG("--scan-time|-s",
set_null, NULL, &opt_set_null,
opt_hidden),
OPT_WITH_CBARG("--sched-start",
set_sched_start, NULL, &opt_set_sched_start,
"Set a time of day in HH:MM to start mining (a once off without a stop time)"),
OPT_WITH_CBARG("--sched-stop",
set_sched_stop, NULL, &opt_set_sched_stop,
"Set a time of day in HH:MM to stop mining (will quit without a start time)"),
OPT_WITH_CBARG("--sharelog",
set_sharelog, NULL, &opt_set_sharelog,
"Append share log to file"),
OPT_WITH_ARG("--shares",
opt_set_intval, NULL, &opt_shares,
"Quit after mining N shares (default: unlimited)"),
OPT_WITH_ARG("--socks-proxy",
opt_set_charp, NULL, &opt_socks_proxy,
"Set socks4 proxy (host:port)"),
OPT_WITH_ARG("--suggest-diff",
opt_set_intval, NULL, &opt_suggest_diff,
"Suggest miner difficulty for pool to user (default: none)"),
#ifdef HAVE_SYSLOG_H
OPT_WITHOUT_ARG("--syslog",
opt_set_bool, &use_syslog,
"Use system log for output messages (default: standard error)"),
#endif
#if defined(USE_BITFORCE) || defined(USE_MODMINER) || defined(USE_BFLSC)
OPT_WITH_CBARG("--temp-cutoff",
set_temp_cutoff, opt_show_intval, &opt_set_temp_cutoff,
"Temperature where a device will be automatically disabled, one value or comma separated list"),
#endif
OPT_WITHOUT_ARG("--text-only|-T",
opt_set_invbool, &use_curses,
#ifdef HAVE_CURSES
"Disable ncurses formatted screen output"
#else
opt_hidden
#endif
),
OPT_WITH_ARG("--url|-o",
set_url, NULL, &opt_set_null,
"URL for bitcoin JSON-RPC server"),
#ifdef USE_USBUTILS
OPT_WITH_ARG("--usb",
opt_set_charp, NULL, &opt_usb_select,
"USB device selection"),
OPT_WITH_ARG("--usb-dump",
set_int_0_to_10, opt_show_intval, &opt_usbdump,
opt_hidden),
OPT_WITHOUT_ARG("--usb-list-all",
opt_set_bool, &opt_usb_list_all,
opt_hidden),
#endif
OPT_WITH_ARG("--user|-u",
set_user, NULL, &opt_set_null,
"Username for bitcoin JSON-RPC server"),
OPT_WITH_ARG("--userpass|-O",
set_userpass, NULL, &opt_set_null,
"Username:Password pair for bitcoin JSON-RPC server"),
OPT_WITHOUT_ARG("--verbose",
opt_set_bool, &opt_log_output,
"Log verbose output to stderr as well as status output"),
OPT_WITHOUT_ARG("--widescreen",
opt_set_bool, &opt_widescreen,
"Use extra wide display without toggling"),
OPT_WITHOUT_ARG("--worktime",
opt_set_bool, &opt_worktime,
"Display extra work time debug information"),
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined(USE_AVALONLC3)
OPT_WITH_ARG("--force-clean-jobs",
opt_set_intval, NULL, &opt_force_clean_jobs,
"Force clean jobs to miners (default: 20)"),
#endif
OPT_ENDTABLE
};
static char *load_config(const char *arg, void __maybe_unused *unused);
static int fileconf_load;
static char *parse_config(json_t *config, bool fileconf)
{
static char err_buf[200];
struct opt_table *opt;
const char *str;
json_t *val;
if (fileconf && !fileconf_load)
fileconf_load = 1;
for (opt = opt_config_table; opt->type != OPT_END; opt++) {
char *p, *saved, *name;
/* We don't handle subtables. */
assert(!(opt->type & OPT_SUBTABLE));
if (!opt->names || !strlen(opt->names))
continue;
/* Pull apart the option name(s). */
name = strdup(opt->names);
for (p = strtok_r(name, "|", &saved); p != NULL; p = strtok_r(NULL, "|", &saved)) {
char *err = NULL;
if (strlen(p) < 3)
continue;
/* Ignore short options. */
if (p[1] != '-')
continue;
val = json_object_get(config, p+2);
if (!val)
continue;
if ((opt->type & (OPT_HASARG | OPT_PROCESSARG)) && json_is_string(val)) {
str = json_string_value(val);
err = opt->cb_arg(str, opt->u.arg);
if (opt->type == OPT_PROCESSARG)
opt_set_charp(str, opt->u.arg);
} else if ((opt->type & (OPT_HASARG | OPT_PROCESSARG)) && json_is_array(val)) {
json_t *arr_val;
size_t index;
json_array_foreach(val, index, arr_val) {
if (json_is_string(arr_val)) {
str = json_string_value(arr_val);
err = opt->cb_arg(str, opt->u.arg);
if (opt->type == OPT_PROCESSARG)
opt_set_charp(str, opt->u.arg);
} else if (json_is_object(arr_val))
err = parse_config(arr_val, false);
if (err)
break;
}
} else if ((opt->type & OPT_NOARG) && json_is_true(val))
err = opt->cb(opt->u.arg);
else
err = "Invalid value";
if (err) {
/* Allow invalid values to be in configuration
* file, just skipping over them provided the
* JSON is still valid after that. */
if (fileconf) {
applog(LOG_ERR, "Invalid config option %s: %s", p, err);
fileconf_load = -1;
} else {
snprintf(err_buf, sizeof(err_buf), "Parsing JSON option %s: %s",
p, err);
return err_buf;
}
}
}
free(name);
}
val = json_object_get(config, JSON_INCLUDE_CONF);
if (val && json_is_string(val))
return load_config(json_string_value(val), NULL);
return NULL;
}
char *cnfbuf = NULL;
#ifdef HAVE_LIBCURL
char conf_web1[] = "http://";
char conf_web2[] = "https://";
static char *load_web_config(const char *arg)
{
json_t *val = json_web_config(arg);
if (!val || !json_is_object(val))
return JSON_WEB_ERROR;
if (!cnfbuf)
cnfbuf = strdup(arg);
config_loaded = true;
return parse_config(val, true);
}
#endif
static char *load_config(const char *arg, void __maybe_unused *unused)
{
json_error_t err;
json_t *config;
char *json_error;
size_t siz;
#ifdef HAVE_LIBCURL
if (strncasecmp(arg, conf_web1, sizeof(conf_web1)-1) == 0 ||
strncasecmp(arg, conf_web2, sizeof(conf_web2)-1) == 0)
return load_web_config(arg);
#endif
if (!cnfbuf)
cnfbuf = strdup(arg);
if (++include_count > JSON_MAX_DEPTH)
return JSON_MAX_DEPTH_ERR;
config = json_load_file(arg, 0, &err);
if (!json_is_object(config)) {
siz = JSON_LOAD_ERROR_LEN + strlen(arg) + strlen(err.text);
json_error = cgmalloc(siz);
snprintf(json_error, siz, JSON_LOAD_ERROR, arg, err.text);
return json_error;
}
config_loaded = true;
/* Parse the config now, so we can override it. That can keep pointers
* so don't free config object. */
return parse_config(config, true);
}
static char *set_default_config(const char *arg)
{
opt_set_charp(arg, &default_config);
return NULL;
}
void default_save_file(char *filename);
static void load_default_config(void)
{
cnfbuf = cgmalloc(PATH_MAX);
default_save_file(cnfbuf);
if (!access(cnfbuf, R_OK))
load_config(cnfbuf, NULL);
else {
free(cnfbuf);
cnfbuf = NULL;
}
}
extern const char *opt_argv0;
static char *opt_verusage_and_exit(const char *extra)
{
printf("%s\nBuilt with "
#ifdef USE_ANT_S1
"ant.S1 "
#endif
#ifdef USE_ANT_S2
#ifdef USE_ANT_S3
"ant.S3 "
#else
"ant.S2 "
#endif
#endif
#ifdef USE_AVALON
"avalon "
#endif
#ifdef USE_AVALON2
"avalon2 "
#endif
#ifdef USE_AVALON4
"avalon4 "
#endif
#ifdef USE_AVALON7
"avalon7 "
#endif
#ifdef USE_AVALON8
"avalon8 "
#endif
#ifdef USE_AVALON9
"avalon9 "
#endif
#ifdef USE_AVALONLC3
"avalonlc3 "
#endif
#ifdef USE_AVALON_MINER
"avalon miner"
#endif
#ifdef USE_BAB
"BaB "
#endif
#ifdef USE_BFLSC
"bflsc "
#endif
#ifdef USE_BITFORCE
"bitforce "
#endif
#ifdef USE_BITFURY
"bitfury "
#endif
#ifdef USE_BITFURY16
"bitfury16 "
#endif
#ifdef USE_BITMINE_A1
"Bitmine.A1 "
#endif
#ifdef USE_BLOCKERUPTER
"Blockerupter "
#endif
#ifdef USE_COINTERRA
"cointerra "
#endif
#ifdef USE_DRILLBIT
"drillbit "
#endif
#ifdef USE_DRAGONMINT_T1
"dragonmint_t1 "
#endif
#ifdef USE_GEKKO
"gekko "
#endif
#ifdef USE_HASHFAST
"hashfast "
#endif
#ifdef USE_ICARUS
"icarus "
#endif
#ifdef USE_KLONDIKE
"klondike "
#endif
#ifdef USE_KNC
"KnC "
#endif
#ifdef USE_MINION
"minion "
#endif
#ifdef USE_MODMINER
"modminer "
#endif
#ifdef USE_BITMINE_A1
"Bitmine.A1 "
#endif
#ifdef USE_SP10
"spondoolies "
#endif
#ifdef USE_SP30
"sp30 "
#endif
#ifdef USE_XTRANONCE
"xnsub "
#endif
"mining support.\n"
, packagename);
printf("%s", opt_usage(opt_argv0, extra));
fflush(stdout);
exit(0);
}
#if defined(USE_USBUTILS)
char *display_devs(int *ndevs)
{
*ndevs = 0;
usb_all(0);
exit(*ndevs);
}
#endif
/* These options are available from commandline only */
static struct opt_table opt_cmdline_table[] = {
OPT_WITH_ARG("--config|-c",
load_config, NULL, &opt_set_null,
"Load a JSON-format configuration file\n"
"See example.conf for an example configuration."),
OPT_WITH_ARG("--default-config",
set_default_config, NULL, &opt_set_null,
"Specify the filename of the default config file\n"
"Loaded at start and used when saving without a name."),
OPT_WITHOUT_ARG("--help|-h",
opt_verusage_and_exit, NULL,
"Print this message"),
#if defined(USE_USBUTILS)
OPT_WITHOUT_ARG("--ndevs|-n",
display_devs, &nDevs,
"Display all USB devices and exit"),
#endif
OPT_WITHOUT_ARG("--version|-V",
opt_version_and_exit, packagename,
"Display version and exit"),
OPT_ENDTABLE
};
static void calc_midstate(struct pool *pool, struct work *work)
{
unsigned char data[64];
uint32_t *data32 = (uint32_t *)data;
sha256_ctx ctx;
if (pool->vmask) {
/* This would only be set if the driver requested a vmask and
* the pool has a valid version mask. */
memcpy(work->data, &(pool->vmask_001[2]), 4);
flip64(data32, work->data);
sha256_init(&ctx);
sha256_update(&ctx, data, 64);
cg_memcpy(work->midstate1, ctx.h, 32);
endian_flip32(work->midstate1, work->midstate1);
memcpy(work->data, &(pool->vmask_001[4]), 4);
flip64(data32, work->data);
sha256_init(&ctx);
sha256_update(&ctx, data, 64);
cg_memcpy(work->midstate2, ctx.h, 32);
endian_flip32(work->midstate2, work->midstate2);
memcpy(work->data, &(pool->vmask_001[8]), 4);
flip64(data32, work->data);
sha256_init(&ctx);
sha256_update(&ctx, data, 64);
cg_memcpy(work->midstate3, ctx.h, 32);
endian_flip32(work->midstate3, work->midstate3);
memcpy(work->data, &(pool->vmask_001[0]), 4);
}
flip64(data32, work->data);
sha256_init(&ctx);
sha256_update(&ctx, data, 64);
cg_memcpy(work->midstate, ctx.h, 32);
endian_flip32(work->midstate, work->midstate);
}
/* Returns the current value of total_work and increments it */
static int total_work_inc(void)
{
int ret;
cg_wlock(&control_lock);
ret = total_work++;
cg_wunlock(&control_lock);
return ret;
}
static struct work *make_work(void)
{
struct work *work = cgcalloc(1, sizeof(struct work));
work->id = total_work_inc();
return work;
}
/* This is the central place all work that is about to be retired should be
* cleaned to remove any dynamically allocated arrays within the struct */
void clean_work(struct work *work)
{
free(work->job_id);
free(work->ntime);
free(work->coinbase);
free(work->nonce1);
memset(work, 0, sizeof(struct work));
}
/* All dynamically allocated work structs should be freed here to not leak any
* ram from arrays allocated within the work struct. Null the actual pointer
* used to call free_work. */
void _free_work(struct work **workptr, const char *file, const char *func, const int line)
{
struct work *work = *workptr;
if (unlikely(!work)) {
applog(LOG_ERR, "Free work called with null work from %s %s:%d",
file, func, line);
return;
}
clean_work(work);
free(work);
*workptr = NULL;
}
static void gen_hash(unsigned char *data, unsigned char *hash, int len);
static void calc_diff(struct work *work, double known);
char *workpadding = "000000800000000000000000000000000000000000000000000000000000000000000000000000000000000080020000";
#ifdef HAVE_LIBCURL
/* Process transactions with GBT by storing the binary value of the first
* transaction, and the hashes of the remaining transactions since these
* remain constant with an altered coinbase when generating work. Must be
* entered under gbt_lock */
static void gbt_merkle_bins(struct pool *pool, json_t *transaction_arr);
static void __build_gbt_txns(struct pool *pool, json_t *res_val)
{
json_t *txn_array;
txn_array = json_object_get(res_val, "transactions");
gbt_merkle_bins(pool, txn_array);
}
static void __gbt_merkleroot(struct pool *pool, unsigned char *merkle_root)
{
unsigned char merkle_sha[64];
int i;
gen_hash(pool->coinbase, merkle_root, pool->coinbase_len);
cg_memcpy(merkle_sha, merkle_root, 32);
for (i = 0; i < pool->merkles; i++) {
cg_memcpy(merkle_sha + 32, pool->merklebin + i * 32, 32);
gen_hash(merkle_sha, merkle_root, 64);
cg_memcpy(merkle_sha, merkle_root, 32);
}
}
static bool work_decode(struct pool *pool, struct work *work, json_t *val);
static void update_gbt(struct pool *pool)
{
int rolltime;
json_t *val;
CURL *curl;
curl = curl_easy_init();
if (unlikely(!curl))
quit (1, "CURL initialisation failed in update_gbt");
val = json_rpc_call(curl, pool->rpc_url, pool->rpc_userpass,
pool->rpc_req, true, false, &rolltime, pool, false);
if (val) {
struct work *work = make_work();
bool rc = work_decode(pool, work, val);
total_getworks++;
pool->getwork_requested++;
if (rc) {
applog(LOG_DEBUG, "Successfully retrieved and updated GBT from pool %u %s",
pool->pool_no, pool->rpc_url);
if (pool == current_pool())
opt_work_update = true;
} else {
applog(LOG_DEBUG, "Successfully retrieved but FAILED to decipher GBT from pool %u %s",
pool->pool_no, pool->rpc_url);
}
json_decref(val);
free_work(work);
} else {
applog(LOG_DEBUG, "FAILED to update GBT from pool %u %s",
pool->pool_no, pool->rpc_url);
}
curl_easy_cleanup(curl);
}
static void gen_gbt_work(struct pool *pool, struct work *work)
{
unsigned char merkleroot[32];
struct timeval now;
uint64_t nonce2le;
cgtime(&now);
if (now.tv_sec - pool->tv_lastwork.tv_sec > 60)
update_gbt(pool);
cg_wlock(&pool->gbt_lock);
nonce2le = htole64(pool->nonce2);
cg_memcpy(pool->coinbase + pool->nonce2_offset, &nonce2le, pool->n2size);
pool->nonce2++;
cg_dwlock(&pool->gbt_lock);
__gbt_merkleroot(pool, merkleroot);
cg_memcpy(work->data, &pool->gbt_version, 4);
cg_memcpy(work->data + 4, pool->previousblockhash, 32);
cg_memcpy(work->data + 4 + 32 + 32, &pool->curtime, 4);
cg_memcpy(work->data + 4 + 32 + 32 + 4, &pool->gbt_bits, 4);
cg_memcpy(work->target, pool->gbt_target, 32);
work->coinbase = bin2hex(pool->coinbase, pool->coinbase_len);
/* For encoding the block data on submission */
work->gbt_txns = pool->gbt_txns + 1;
if (pool->gbt_workid)
work->job_id = strdup(pool->gbt_workid);
cg_runlock(&pool->gbt_lock);
flip32(work->data + 4 + 32, merkleroot);
memset(work->data + 4 + 32 + 32 + 4 + 4, 0, 4); /* nonce */
hex2bin(work->data + 4 + 32 + 32 + 4 + 4 + 4, workpadding, 48);
if (opt_debug) {
char *header = bin2hex(work->data, 128);
applog(LOG_DEBUG, "Generated GBT header %s", header);
applog(LOG_DEBUG, "Work coinbase %s", work->coinbase);
free(header);
}
calc_midstate(pool, work);
local_work++;
work->pool = pool;
work->gbt = true;
work->longpoll = false;
work->getwork_mode = GETWORK_MODE_GBT;
work->work_block = work_block;
/* Nominally allow a driver to ntime roll 60 seconds */
work->drv_rolllimit = 60;
calc_diff(work, 0);
cgtime(&work->tv_staged);
}
static bool gbt_decode(struct pool *pool, json_t *res_val)
{
const char *previousblockhash;
const char *target;
const char *coinbasetxn;
const char *longpollid;
unsigned char hash_swap[32];
int expires;
int version;
int curtime;
bool submitold;
const char *bits;
const char *workid;
int cbt_len, orig_len;
uint8_t *extra_len;
size_t cal_len;
previousblockhash = json_string_value(json_object_get(res_val, "previousblockhash"));
target = json_string_value(json_object_get(res_val, "target"));
coinbasetxn = json_string_value(json_object_get(json_object_get(res_val, "coinbasetxn"), "data"));
longpollid = json_string_value(json_object_get(res_val, "longpollid"));
expires = json_integer_value(json_object_get(res_val, "expires"));
version = json_integer_value(json_object_get(res_val, "version"));
curtime = json_integer_value(json_object_get(res_val, "curtime"));
submitold = json_is_true(json_object_get(res_val, "submitold"));
bits = json_string_value(json_object_get(res_val, "bits"));
workid = json_string_value(json_object_get(res_val, "workid"));
if (!previousblockhash || !target || !coinbasetxn || !longpollid ||
!expires || !version || !curtime || !bits) {
applog(LOG_ERR, "JSON failed to decode GBT");
return false;
}
applog(LOG_DEBUG, "previousblockhash: %s", previousblockhash);
applog(LOG_DEBUG, "target: %s", target);
applog(LOG_DEBUG, "coinbasetxn: %s", coinbasetxn);
applog(LOG_DEBUG, "longpollid: %s", longpollid);
applog(LOG_DEBUG, "expires: %d", expires);
applog(LOG_DEBUG, "version: %d", version);
applog(LOG_DEBUG, "curtime: %d", curtime);
applog(LOG_DEBUG, "submitold: %s", submitold ? "true" : "false");
applog(LOG_DEBUG, "bits: %s", bits);
if (workid)
applog(LOG_DEBUG, "workid: %s", workid);
cg_wlock(&pool->gbt_lock);
free(pool->coinbasetxn);
pool->coinbasetxn = strdup(coinbasetxn);
cbt_len = strlen(pool->coinbasetxn) / 2;
/* We add 8 bytes of extra data corresponding to nonce2 */
pool->n2size = 8;
pool->coinbase_len = cbt_len + pool->n2size;
cal_len = pool->coinbase_len + 1;
free(pool->coinbase);
pool->coinbase = cgcalloc(cal_len, 1);
hex2bin(pool->coinbase, pool->coinbasetxn, 42);
extra_len = (uint8_t *)(pool->coinbase + 41);
orig_len = *extra_len;
hex2bin(pool->coinbase + 42, pool->coinbasetxn + 84, orig_len);
*extra_len += pool->n2size;
hex2bin(pool->coinbase + 42 + *extra_len, pool->coinbasetxn + 84 + (orig_len * 2),
cbt_len - orig_len - 42);
pool->nonce2_offset = orig_len + 42;
free(pool->longpollid);
pool->longpollid = strdup(longpollid);
free(pool->gbt_workid);
if (workid)
pool->gbt_workid = strdup(workid);
else
pool->gbt_workid = NULL;
hex2bin(hash_swap, previousblockhash, 32);
swap256(pool->previousblockhash, hash_swap);
hex2bin(hash_swap, target, 32);
swab256(pool->gbt_target, hash_swap);
pool->gbt_expires = expires;
pool->gbt_version = htobe32(version);
pool->curtime = htobe32(curtime);
pool->submit_old = submitold;
hex2bin((unsigned char *)&pool->gbt_bits, bits, 4);
__build_gbt_txns(pool, res_val);
if (pool->transactions < 3)
pool->bad_work++;
cg_wunlock(&pool->gbt_lock);
return true;
}
static void gbt_merkle_bins(struct pool *pool, json_t *transaction_arr)
{
unsigned char *hashbin;
json_t *arr_val;
int i, j, binleft, binlen;
free(pool->txn_data);
pool->txn_data = NULL;
pool->transactions = 0;
pool->merkles = 0;
pool->transactions = json_array_size(transaction_arr);
binlen = pool->transactions * 32 + 32;
hashbin = alloca(binlen + 32);
memset(hashbin, 0, 32);
binleft = binlen / 32;
if (pool->transactions) {
int len = 0, ofs = 0;
const char *txn;
for (i = 0; i < pool->transactions; i++) {
arr_val = json_array_get(transaction_arr, i);
txn = json_string_value(json_object_get(arr_val, "data"));
if (!txn) {
applog(LOG_ERR, "Pool %d json_string_value fail - cannot find transaction data",
pool->pool_no);
return;
}
len += strlen(txn);
}
pool->txn_data = cgmalloc(len + 1);
pool->txn_data[len] = '\0';
for (i = 0; i < pool->transactions; i++) {
unsigned char binswap[32];
const char *hash;
const char *txid;
arr_val = json_array_get(transaction_arr, i);
txid = json_string_value(json_object_get(arr_val, "txid"));
hash = json_string_value(json_object_get(arr_val, "hash"));
if(!txid)
txid = hash;
txn = json_string_value(json_object_get(arr_val, "data"));
len = strlen(txn);
cg_memcpy(pool->txn_data + ofs, txn, len);
ofs += len;
#if 0
// This logic no longer works post-segwit. The txids will always need to be sent,
// as the full txns will also contain witness data that must be omitted in these
// hashes.
if (!hash) {
unsigned char *txn_bin;
int txn_len;
txn_len = len / 2;
txn_bin = cgmalloc(txn_len);
hex2bin(txn_bin, txn, txn_len);
/* This is needed for pooled mining since only
* transaction data and not hashes are sent */
gen_hash(txn_bin, hashbin + 32 + 32 * i, txn_len);
continue;
}
#endif
if (!txid) {
applog(LOG_ERR, "missing txid in gbt_merkle_bins");
return;
}
if (!hex2bin(binswap, txid, 32)) {
applog(LOG_ERR, "Failed to hex2bin txid in gbt_merkle_bins");
return;
}
swab256(hashbin + 32 + 32 * i, binswap);
}
}
if (binleft > 1) {
while (42) {
if (binleft == 1)
break;
cg_memcpy(pool->merklebin + (pool->merkles * 32), hashbin + 32, 32);
pool->merkles++;
if (binleft % 2) {
cg_memcpy(hashbin + binlen, hashbin + binlen - 32, 32);
binlen += 32;
binleft++;
}
for (i = 32, j = 64; j < binlen; i += 32, j += 64) {
gen_hash(hashbin + j, hashbin + i, 64);
}
binleft /= 2;
binlen = binleft * 32;
}
}
if (opt_debug) {
char hashhex[68];
for (i = 0; i < pool->merkles; i++) {
__bin2hex(hashhex, pool->merklebin + i * 32, 32);
applog(LOG_DEBUG, "MH%d %s",i, hashhex);
}
}
applog(LOG_INFO, "Stored %d transactions from pool %d", pool->transactions,
pool->pool_no);
}
static const unsigned char witness_nonce[32] = {0};
static const int witness_nonce_size = sizeof(witness_nonce);
static const unsigned char witness_header[] = {0xaa, 0x21, 0xa9, 0xed};
static const int witness_header_size = sizeof(witness_header);
static bool gbt_witness_data(json_t *transaction_arr, unsigned char* witnessdata, int avail_size)
{
int i, binlen, txncount = json_array_size(transaction_arr);
unsigned char *hashbin;
const char *hash;
json_t *arr_val;
binlen = txncount * 32 + 32;
hashbin = alloca(binlen + 32);
memset(hashbin, 0, 32);
if (avail_size < witness_header_size + 32)
return false;
for (i = 0; i < txncount; i++) {
unsigned char binswap[32];
arr_val = json_array_get(transaction_arr, i);
hash = json_string_value(json_object_get(arr_val, "hash"));
if (unlikely(!hash)) {
applog(LOG_ERR, "Hash missing for transaction");
return false;
}
if (!hex2bin(binswap, hash, 32)) {
applog(LOG_ERR, "Failed to hex2bin hash in gbt_witness_data");
return false;
}
swab256(hashbin + 32 + 32 * i, binswap);
}
// Build merkle root (copied from libblkmaker)
for (txncount++ ; txncount > 1 ; txncount /= 2) {
if (txncount % 2) {
// Odd number, duplicate the last
memcpy(hashbin + 32 * txncount, hashbin + 32 * (txncount - 1), 32);
txncount++;
}
for (i = 0; i < txncount; i += 2) {
// We overlap input and output here, on the first pair
gen_hash(hashbin + 32 * i, hashbin + 32 * (i / 2), 64);
}
}
memcpy(witnessdata, witness_header, witness_header_size);
memcpy(hashbin + 32, &witness_nonce, witness_nonce_size);
gen_hash(hashbin, witnessdata + witness_header_size, 32 + witness_nonce_size);
return true;
}
static double diff_from_target(void *target);
static const char scriptsig_header[] = "01000000010000000000000000000000000000000000000000000000000000000000000000ffffffff";
static unsigned char scriptsig_header_bin[41];
static bool gbt_solo_decode(struct pool *pool, json_t *res_val)
{
json_t *transaction_arr, *rules_arr, *coinbase_aux;
const char *previousblockhash;
unsigned char hash_swap[32];
struct timeval now;
const char *target;
uint64_t coinbasevalue;
const char *flags;
const char *bits;
char header[260];
int ofs = 0, len;
uint64_t *u64;
uint32_t *u32;
int version;
int curtime;
int height;
int witness_txout_len = 0;
int witnessdata_size = 0;
bool insert_witness = false;
unsigned char witnessdata[36] = {};
const char *default_witness_commitment;
previousblockhash = json_string_value(json_object_get(res_val, "previousblockhash"));
target = json_string_value(json_object_get(res_val, "target"));
transaction_arr = json_object_get(res_val, "transactions");
rules_arr = json_object_get(res_val, "rules");
version = json_integer_value(json_object_get(res_val, "version"));
curtime = json_integer_value(json_object_get(res_val, "curtime"));
bits = json_string_value(json_object_get(res_val, "bits"));
height = json_integer_value(json_object_get(res_val, "height"));
coinbasevalue = json_integer_value(json_object_get(res_val, "coinbasevalue"));
coinbase_aux = json_object_get(res_val, "coinbaseaux");
flags = json_string_value(json_object_get(coinbase_aux, "flags"));
default_witness_commitment = json_string_value(json_object_get(res_val, "default_witness_commitment"));
if (!previousblockhash || !target || !version || !curtime || !bits || !coinbase_aux || !flags) {
applog(LOG_ERR, "Pool %d JSON failed to decode GBT", pool->pool_no);
return false;
}
if (rules_arr) {
int i;
int rule_count = json_array_size(rules_arr);
const char *rule;
for (i = 0; i < rule_count; i++) {
rule = json_string_value(json_array_get(rules_arr, i));
if (!rule)
continue;
if (*rule == '!')
rule++;
if (strncmp(rule, "segwit", 6)) {
insert_witness = true;
break;
}
}
}
applog(LOG_DEBUG, "previousblockhash: %s", previousblockhash);
applog(LOG_DEBUG, "target: %s", target);
applog(LOG_DEBUG, "version: %d", version);
applog(LOG_DEBUG, "curtime: %d", curtime);
applog(LOG_DEBUG, "bits: %s", bits);
applog(LOG_DEBUG, "height: %d", height);
applog(LOG_DEBUG, "flags: %s", flags);
cg_wlock(&pool->gbt_lock);
hex2bin(hash_swap, previousblockhash, 32);
swap256(pool->previousblockhash, hash_swap);
__bin2hex(pool->prev_hash, pool->previousblockhash, 32);
hex2bin(hash_swap, target, 32);
swab256(pool->gbt_target, hash_swap);
pool->sdiff = diff_from_target(pool->gbt_target);
pool->gbt_version = htobe32(version);
pool->curtime = htobe32(curtime);
snprintf(pool->ntime, 9, "%08x", curtime);
snprintf(pool->bbversion, 9, "%08x", version);
snprintf(pool->nbit, 9, "%s", bits);
pool->nValue = coinbasevalue;
hex2bin((unsigned char *)&pool->gbt_bits, bits, 4);
gbt_merkle_bins(pool, transaction_arr);
if (insert_witness) {
char witness_str[sizeof(witnessdata) * 2];
witnessdata_size = sizeof(witnessdata);
if (!gbt_witness_data(transaction_arr, witnessdata, witnessdata_size)) {
applog(LOG_ERR, "error calculating witness data");
return false;
}
__bin2hex(witness_str, witnessdata, witnessdata_size);
applog(LOG_DEBUG, "calculated witness data: %s", witness_str);
if (default_witness_commitment) {
if (strncmp(witness_str, default_witness_commitment + 4, witnessdata_size * 2) != 0) {
applog(LOG_ERR, "bad witness data. %s != %s", default_witness_commitment + 4, witness_str);
return false;
}
}
}
if (pool->transactions < 3)
pool->bad_work++;
pool->height = height;
memset(pool->scriptsig_base, 0, 42);
ofs++; // Leave room for template length
/* Put block height at start of template. */
ofs += ser_number(pool->scriptsig_base + ofs, height); // max 5
/* Followed by flags */
if (flags) {
len = strlen(flags) / 2;
pool->scriptsig_base[ofs++] = len;
hex2bin(pool->scriptsig_base + ofs, flags, len);
ofs += len;
}
/* Followed by timestamp */
cgtime(&now);
pool->scriptsig_base[ofs++] = 0xfe; // Encode seconds as u32
u32 = (uint32_t *)&pool->scriptsig_base[ofs];
*u32 = htole32(now.tv_sec);
ofs += 4; // sizeof uint32_t
pool->scriptsig_base[ofs++] = 0xfe; // Encode usecs as u32
u32 = (uint32_t *)&pool->scriptsig_base[ofs];
*u32 = htole32(now.tv_usec);
ofs += 4; // sizeof uint32_t
cg_memcpy(pool->scriptsig_base + ofs, "\x09\x63\x67\x6d\x69\x6e\x65\x72\x34\x32", 10);
ofs += 10;
/* Followed by extranonce size, fixed at 8 */
pool->scriptsig_base[ofs++] = 8;
pool->nonce2_offset = 41 + ofs;
ofs += 8;
if (opt_btc_sig) {
len = strlen(opt_btc_sig);
if (len > 32)
len = 32;
pool->scriptsig_base[ofs++] = len;
cg_memcpy(pool->scriptsig_base + ofs, opt_btc_sig, len);
ofs += len;
}
pool->scriptsig_base[0] = ofs++; // Template length
pool->n1_len = ofs;
len = 41 // prefix
+ ofs // Template length
+ 4 // txin sequence no
+ 1 // txouts
+ 8 // value
+ 1 + 25 // txout
+ 4; // lock
if (insert_witness) {
len += 8 //value
+ 1 + 2 + witnessdata_size; // total scriptPubKey size + OP_RETURN + push size + data
}
free(pool->coinbase);
pool->coinbase = cgcalloc(len, 1);
cg_memcpy(pool->coinbase + 41, pool->scriptsig_base, ofs);
cg_memcpy(pool->coinbase + 41 + ofs, "\xff\xff\xff\xff", 4);
pool->coinbase[41 + ofs + 4] = insert_witness ? 2 : 1;
u64 = (uint64_t *)&(pool->coinbase[41 + ofs + 4 + 1]);
*u64 = htole64(coinbasevalue);
if (insert_witness) {
unsigned char *witness = &pool->coinbase[41 + ofs + 4 + 1 + 8 + 1 + 25];
memset(witness, 0, 8);
witness_txout_len += 8;
witness[witness_txout_len++] = witnessdata_size + 2; // total scriptPubKey size
witness[witness_txout_len++] = 0x6a; // OP_RETURN
witness[witness_txout_len++] = witnessdata_size;
memcpy(&witness[witness_txout_len], witnessdata, witnessdata_size);
witness_txout_len += witnessdata_size;
}
pool->nonce2 = 0;
pool->n2size = 4;
pool->coinbase_len = 41 + ofs + 4 + 1 + 8 + 1 + 25 + witness_txout_len + 4;
cg_wunlock(&pool->gbt_lock);
snprintf(header, 257, "%s%s%s%s%s%s%s",
pool->bbversion,
pool->prev_hash,
"0000000000000000000000000000000000000000000000000000000000000000",
pool->ntime,
pool->nbit,
"00000000", /* nonce */
workpadding);
if (unlikely(!hex2bin(pool->header_bin, header, 128)))
quit(1, "Failed to hex2bin header in gbt_solo_decode");
return true;
}
static bool work_decode(struct pool *pool, struct work *work, json_t *val)
{
json_t *res_val = json_object_get(val, "result");
bool ret = false;
cgtime(&pool->tv_lastwork);
if (!res_val || json_is_null(res_val)) {
applog(LOG_ERR, "JSON Failed to decode result");
goto out;
}
if (pool->gbt_solo) {
if (unlikely(!gbt_solo_decode(pool, res_val)))
goto out;
goto out_true;
}
if (unlikely(!gbt_decode(pool, res_val)))
goto out;
work->gbt = true;
memset(work->hash, 0, sizeof(work->hash));
cgtime(&work->tv_staged);
out_true:
ret = true;
out:
return ret;
}
#else /* HAVE_LIBCURL */
#define json_rpc_call(curl, url, userpass, rpc_req, probe, longpoll, rolltime, pool, share) (NULL)
#define work_decode(pool, work, val) (false)
#define gen_gbt_work(pool, work) {}
#endif /* HAVE_LIBCURL */
int dev_from_id(int thr_id)
{
struct cgpu_info *cgpu = get_thr_cgpu(thr_id);
return cgpu->device_id;
}
/* Create an exponentially decaying average over the opt_log_interval */
void decay_time(double *f, double fadd, double fsecs, double interval)
{
double ftotal, fprop;
if (fsecs <= 0)
return;
fprop = 1.0 - 1 / (exp(fsecs / interval));
ftotal = 1.0 + fprop;
*f += (fadd / fsecs * fprop);
*f /= ftotal;
}
static int __total_staged(void)
{
return HASH_COUNT(staged_work);
}
#if defined(HAVE_LIBCURL) || defined(HAVE_CURSES)
static int total_staged(void)
{
int ret;
mutex_lock(stgd_lock);
ret = __total_staged();
mutex_unlock(stgd_lock);
return ret;
}
#endif
#ifdef HAVE_CURSES
WINDOW *mainwin, *statuswin, *logwin;
#endif
double total_secs = 1.0;
static char statusline[256];
/* logstart is where the log window should start */
static int devcursor, logstart, logcursor;
#ifdef HAVE_CURSES
/* statusy is where the status window goes up to in cases where it won't fit at startup */
static int statusy;
#endif
#ifdef HAVE_CURSES
static inline void unlock_curses(void)
{
mutex_unlock(&console_lock);
}
static inline void lock_curses(void)
{
mutex_lock(&console_lock);
}
static bool curses_active_locked(void)
{
bool ret;
lock_curses();
ret = curses_active;
if (!ret)
unlock_curses();
return ret;
}
#endif
/* Convert a uint64_t value into a truncated string for displaying with its
* associated suitable for Mega, Giga etc. Buf array needs to be long enough */
static void suffix_string(uint64_t val, char *buf, size_t bufsiz, int sigdigits)
{
const double dkilo = 1000.0;
const uint64_t kilo = 1000ull;
const uint64_t mega = 1000000ull;
const uint64_t giga = 1000000000ull;
const uint64_t tera = 1000000000000ull;
const uint64_t peta = 1000000000000000ull;
const uint64_t exa = 1000000000000000000ull;
char suffix[2] = "";
bool decimal = true;
double dval;
if (val >= exa) {
val /= peta;
dval = (double)val / dkilo;
strcpy(suffix, "E");
} else if (val >= peta) {
val /= tera;
dval = (double)val / dkilo;
strcpy(suffix, "P");
} else if (val >= tera) {
val /= giga;
dval = (double)val / dkilo;
strcpy(suffix, "T");
} else if (val >= giga) {
val /= mega;
dval = (double)val / dkilo;
strcpy(suffix, "G");
} else if (val >= mega) {
val /= kilo;
dval = (double)val / dkilo;
strcpy(suffix, "M");
} else if (val >= kilo) {
dval = (double)val / dkilo;
strcpy(suffix, "K");
} else {
dval = val;
decimal = false;
}
if (!sigdigits) {
if (decimal)
snprintf(buf, bufsiz, "%.3g%s", dval, suffix);
else
snprintf(buf, bufsiz, "%d%s", (unsigned int)dval, suffix);
} else {
/* Always show sigdigits + 1, padded on right with zeroes
* followed by suffix */
int ndigits = sigdigits - 1 - (dval > 0.0 ? floor(log10(dval)) : 0);
snprintf(buf, bufsiz, "%*.*f%s", sigdigits + 1, ndigits, dval, suffix);
}
}
double cgpu_runtime(struct cgpu_info *cgpu)
{
struct timeval now;
double dev_runtime;
if (cgpu->dev_start_tv.tv_sec == 0)
dev_runtime = total_secs;
else {
cgtime(&now);
dev_runtime = tdiff(&now, &(cgpu->dev_start_tv));
}
if (dev_runtime < 1.0)
dev_runtime = 1.0;
return dev_runtime;
}
double tsince_restart(void)
{
struct timeval now;
cgtime(&now);
return tdiff(&now, &restart_tv_start);
}
double tsince_update(void)
{
struct timeval now;
cgtime(&now);
return tdiff(&now, &update_tv_start);
}
static void get_statline(char *buf, size_t bufsiz, struct cgpu_info *cgpu)
{
char displayed_hashes[16], displayed_rolling[16];
double dev_runtime, wu;
uint64_t dh64, dr64;
dev_runtime = cgpu_runtime(cgpu);
wu = cgpu->diff1 / dev_runtime * 60.0;
dh64 = (double)cgpu->total_mhashes / dev_runtime * 1000000ull;
dr64 = (double)cgpu->rolling * 1000000ull;
suffix_string(dh64, displayed_hashes, sizeof(displayed_hashes), 4);
suffix_string(dr64, displayed_rolling, sizeof(displayed_rolling), 4);
snprintf(buf, bufsiz, "%s %d ", cgpu->drv->name, cgpu->device_id);
cgpu->drv->get_statline_before(buf, bufsiz, cgpu);
tailsprintf(buf, bufsiz, "(%ds):%s (avg):%sh/s | A:%.0f R:%.0f HW:%d WU:%.1f/m",
opt_log_interval,
displayed_rolling,
displayed_hashes,
cgpu->diff_accepted,
cgpu->diff_rejected,
cgpu->hw_errors,
wu);
cgpu->drv->get_statline(buf, bufsiz, cgpu);
}
static bool shared_strategy(void)
{
return (pool_strategy == POOL_LOADBALANCE || pool_strategy == POOL_BALANCE);
}
#ifdef HAVE_CURSES
#define CURBUFSIZ 256
#define cg_mvwprintw(win, y, x, fmt, ...) do { \
char tmp42[CURBUFSIZ]; \
snprintf(tmp42, sizeof(tmp42), fmt, ##__VA_ARGS__); \
mvwprintw(win, y, x, "%s", tmp42); \
} while (0)
#define cg_wprintw(win, fmt, ...) do { \
char tmp42[CURBUFSIZ]; \
snprintf(tmp42, sizeof(tmp42), fmt, ##__VA_ARGS__); \
wprintw(win, "%s", tmp42); \
} while (0)
/* Must be called with curses mutex lock held and curses_active */
static void curses_print_status(void)
{
struct pool *pool = current_pool();
int linewidth = opt_widescreen ? 100 : 80;
wattron(statuswin, A_BOLD);
cg_mvwprintw(statuswin, 0, 0, " " PACKAGE " version " VERSION " - Started: %s", datestamp);
wattroff(statuswin, A_BOLD);
mvwhline(statuswin, 1, 0, '-', linewidth);
cg_mvwprintw(statuswin, 2, 0, " %s", statusline);
wclrtoeol(statuswin);
if (opt_widescreen) {
cg_mvwprintw(statuswin, 3, 0, " A:%.0f R:%.0f HW:%d WU:%.1f/m |"
" ST: %d SS: %"PRId64" NB: %d LW: %d GF: %d RF: %d",
total_diff_accepted, total_diff_rejected, hw_errors,
total_diff1 / total_secs * 60,
total_staged(), total_stale, new_blocks, local_work, total_go, total_ro);
} else if (alt_status) {
cg_mvwprintw(statuswin, 3, 0, " ST: %d SS: %"PRId64" NB: %d LW: %d GF: %d RF: %d",
total_staged(), total_stale, new_blocks, local_work, total_go, total_ro);
} else {
cg_mvwprintw(statuswin, 3, 0, " A:%.0f R:%.0f HW:%d WU:%.1f/m",
total_diff_accepted, total_diff_rejected, hw_errors,
total_diff1 / total_secs * 60);
}
wclrtoeol(statuswin);
if (shared_strategy() && total_pools > 1) {
cg_mvwprintw(statuswin, 4, 0, " Connected to multiple pools with%s block change notify",
have_longpoll ? "": "out");
} else if (pool->has_stratum) {
cg_mvwprintw(statuswin, 4, 0, " Connected to %s diff %s with stratum as user %s",
pool->sockaddr_url, pool->diff, pool->rpc_user);
} else {
cg_mvwprintw(statuswin, 4, 0, " Connected to %s diff %s with%s %s as user %s",
pool->sockaddr_url, pool->diff, have_longpoll ? "": "out",
pool->has_gbt ? "GBT" : "LP", pool->rpc_user);
}
wclrtoeol(statuswin);
cg_mvwprintw(statuswin, 5, 0, " Block: %s... Diff:%s Started: %s Best share: %s ",
prev_block, block_diff, blocktime, best_share);
mvwhline(statuswin, 6, 0, '-', linewidth);
mvwhline(statuswin, statusy - 1, 0, '-', linewidth);
#ifdef USE_USBUTILS
cg_mvwprintw(statuswin, devcursor - 1, 1, "[U]SB management [P]ool management [S]ettings [D]isplay options [Q]uit");
#else
cg_mvwprintw(statuswin, devcursor - 1, 1, "[P]ool management [S]ettings [D]isplay options [Q]uit");
#endif
}
static void adj_width(int var, int *length)
{
if ((int)(log10(var) + 1) > *length)
(*length)++;
}
static void adj_fwidth(float var, int *length)
{
if ((int)(log10(var) + 1) > *length)
(*length)++;
}
#define STATBEFORELEN 23
const char blanks[] = " ";
static void curses_print_devstatus(struct cgpu_info *cgpu, int devno, int count)
{
static int devno_width = 1, dawidth = 1, drwidth = 1, hwwidth = 1, wuwidth = 1;
char logline[256], unique_id[12];
struct timeval now;
double dev_runtime, wu;
unsigned int devstatlen;
if (opt_compact)
return;
if (devcursor + count > LINES - 2)
return;
if (count >= most_devices)
return;
if (cgpu->dev_start_tv.tv_sec == 0)
dev_runtime = total_secs;
else {
cgtime(&now);
dev_runtime = tdiff(&now, &(cgpu->dev_start_tv));
}
if (dev_runtime < 1.0)
dev_runtime = 1.0;
cgpu->utility = cgpu->accepted / dev_runtime * 60;
wu = cgpu->diff1 / dev_runtime * 60;
wmove(statuswin,devcursor + count, 0);
adj_width(devno, &devno_width);
if (cgpu->unique_id) {
unique_id[8] = '\0';
cg_memcpy(unique_id, blanks, 8);
strncpy(unique_id, cgpu->unique_id, 8);
} else
sprintf(unique_id, "%-8d", cgpu->device_id);
cg_wprintw(statuswin, " %*d: %s %-8s: ", devno_width, devno, cgpu->drv->name,
unique_id);
logline[0] = '\0';
cgpu->drv->get_statline_before(logline, sizeof(logline), cgpu);
devstatlen = strlen(logline);
if (devstatlen < STATBEFORELEN)
strncat(logline, blanks, STATBEFORELEN - devstatlen);
cg_wprintw(statuswin, "%s | ", logline);
#ifdef USE_USBUTILS
if (cgpu->usbinfo.nodev)
cg_wprintw(statuswin, "ZOMBIE");
else
#endif
if (cgpu->status == LIFE_DEAD)
cg_wprintw(statuswin, "DEAD ");
else if (cgpu->status == LIFE_SICK)
cg_wprintw(statuswin, "SICK ");
else if (cgpu->deven == DEV_DISABLED)
cg_wprintw(statuswin, "OFF ");
else if (cgpu->deven == DEV_RECOVER)
cg_wprintw(statuswin, "REST ");
else if (opt_widescreen) {
char displayed_hashes[16], displayed_rolling[16];
uint64_t d64;
d64 = (double)cgpu->total_mhashes / dev_runtime * 1000000ull;
suffix_string(d64, displayed_hashes, sizeof(displayed_hashes), 4);
d64 = (double)cgpu->rolling * 1000000ull;
suffix_string(d64, displayed_rolling, sizeof(displayed_rolling), 4);
adj_width(wu, &wuwidth);
adj_fwidth(cgpu->diff_accepted, &dawidth);
adj_fwidth(cgpu->diff_rejected, &drwidth);
adj_width(cgpu->hw_errors, &hwwidth);
cg_wprintw(statuswin, "%6s / %6sh/s WU:%*.1f/m "
"A:%*.0f R:%*.0f HW:%*d",
displayed_rolling,
displayed_hashes, wuwidth + 2, wu,
dawidth, cgpu->diff_accepted,
drwidth, cgpu->diff_rejected,
hwwidth, cgpu->hw_errors);
} else if (!alt_status) {
char displayed_hashes[16], displayed_rolling[16];
uint64_t d64;
d64 = (double)cgpu->total_mhashes / dev_runtime * 1000000ull;
suffix_string(d64, displayed_hashes, sizeof(displayed_hashes), 4);
d64 = (double)cgpu->rolling * 1000000ull;
suffix_string(d64, displayed_rolling, sizeof(displayed_rolling), 4);
adj_width(wu, &wuwidth);
cg_wprintw(statuswin, "%6s / %6sh/s WU:%*.1f/m", displayed_rolling,
displayed_hashes, wuwidth + 2, wu);
} else {
adj_fwidth(cgpu->diff_accepted, &dawidth);
adj_fwidth(cgpu->diff_rejected, &drwidth);
adj_width(cgpu->hw_errors, &hwwidth);
cg_wprintw(statuswin, "A:%*.0f R:%*.0f HW:%*d",
dawidth, cgpu->diff_accepted,
drwidth, cgpu->diff_rejected,
hwwidth, cgpu->hw_errors);
}
logline[0] = '\0';
cgpu->drv->get_statline(logline, sizeof(logline), cgpu);
cg_wprintw(statuswin, "%s", logline);
wclrtoeol(statuswin);
}
#endif
#ifdef HAVE_CURSES
/* Check for window resize. Called with curses mutex locked */
static inline void change_logwinsize(void)
{
int x, y, logx, logy;
getmaxyx(mainwin, y, x);
if (x < 80 || y < 25)
return;
if (y > statusy + 2 && statusy < logstart) {
if (y - 2 < logstart)
statusy = y - 2;
else
statusy = logstart;
logcursor = statusy + 1;
mvwin(logwin, logcursor, 0);
wresize(statuswin, statusy, x);
}
y -= logcursor;
getmaxyx(logwin, logy, logx);
/* Detect screen size change */
if (x != logx || y != logy)
wresize(logwin, y, x);
}
static void check_winsizes(void)
{
if (!use_curses)
return;
if (curses_active_locked()) {
int y, x;
erase();
x = getmaxx(statuswin);
if (logstart > LINES - 2)
statusy = LINES - 2;
else
statusy = logstart;
logcursor = statusy;
wresize(statuswin, statusy, x);
getmaxyx(mainwin, y, x);
y -= logcursor;
wresize(logwin, y, x);
mvwin(logwin, logcursor, 0);
unlock_curses();
}
}
static void disable_curses_windows(void);
static void enable_curses_windows(void);
static void switch_logsize(bool __maybe_unused newdevs)
{
if (curses_active_locked()) {
#ifdef WIN32
if (newdevs)
disable_curses_windows();
#endif
if (opt_compact) {
logstart = devcursor + 1;
logcursor = logstart + 1;
} else {
logstart = devcursor + most_devices + 1;
logcursor = logstart + 1;
}
#ifdef WIN32
if (newdevs)
enable_curses_windows();
#endif
unlock_curses();
check_winsizes();
}
}
/* For mandatory printing when mutex is already locked */
void _wlog(const char *str)
{
wprintw(logwin, "%s", str);
}
/* Mandatory printing */
void _wlogprint(const char *str)
{
if (curses_active_locked()) {
wprintw(logwin, "%s", str);
unlock_curses();
}
}
#endif
#ifdef HAVE_CURSES
bool log_curses_only(int prio, const char *datetime, const char *str)
{
bool high_prio;
high_prio = (prio == LOG_WARNING || prio == LOG_ERR);
if (curses_active_locked()) {
if (!opt_loginput || high_prio) {
wprintw(logwin, "%s%s\n", datetime, str);
if (high_prio) {
touchwin(logwin);
wrefresh(logwin);
}
}
unlock_curses();
return true;
}
return false;
}
void clear_logwin(void)
{
if (curses_active_locked()) {
erase();
wclear(logwin);
unlock_curses();
}
}
void logwin_update(void)
{
if (curses_active_locked()) {
touchwin(logwin);
wrefresh(logwin);
unlock_curses();
}
}
#endif
static void enable_pool(struct pool *pool)
{
if (pool->enabled != POOL_ENABLED) {
enabled_pools++;
pool->enabled = POOL_ENABLED;
}
}
#ifdef HAVE_CURSES
static void disable_pool(struct pool *pool)
{
if (pool->enabled == POOL_ENABLED)
enabled_pools--;
pool->enabled = POOL_DISABLED;
}
#endif
static void reject_pool(struct pool *pool)
{
if (pool->enabled == POOL_ENABLED)
enabled_pools--;
pool->enabled = POOL_REJECTING;
}
static void restart_threads(void);
/* Theoretically threads could race when modifying accepted and
* rejected values but the chance of two submits completing at the
* same time is zero so there is no point adding extra locking */
static void
share_result(json_t *val, json_t *res, json_t *err, const struct work *work,
char *hashshow, bool resubmit, char *worktime)
{
struct pool *pool = work->pool;
struct cgpu_info *cgpu;
cgpu = get_thr_cgpu(work->thr_id);
if (json_is_true(res) || (work->gbt && json_is_null(res))) {
mutex_lock(&stats_lock);
cgpu->accepted++;
total_accepted++;
pool->accepted++;
cgpu->diff_accepted += work->work_difficulty;
total_diff_accepted += work->work_difficulty;
pool->diff_accepted += work->work_difficulty;
mutex_unlock(&stats_lock);
pool->seq_rejects = 0;
cgpu->last_share_pool = pool->pool_no;
cgpu->last_share_pool_time = time(NULL);
cgpu->last_share_diff = work->work_difficulty;
pool->last_share_time = cgpu->last_share_pool_time;
pool->last_share_diff = work->work_difficulty;
applog(LOG_DEBUG, "PROOF OF WORK RESULT: true (yay!!!)");
if (!QUIET) {
if (total_pools > 1)
applog(LOG_NOTICE, "Accepted %s %s %d pool %d %s%s",
hashshow, cgpu->drv->name, cgpu->device_id, work->pool->pool_no, resubmit ? "(resubmit)" : "", worktime);
else
applog(LOG_NOTICE, "Accepted %s %s %d %s%s",
hashshow, cgpu->drv->name, cgpu->device_id, resubmit ? "(resubmit)" : "", worktime);
}
sharelog("accept", work);
if (opt_shares && total_diff_accepted >= opt_shares) {
applog(LOG_WARNING, "Successfully mined %d accepted shares as requested and exiting.", opt_shares);
kill_work();
return;
}
/* Detect if a pool that has been temporarily disabled for
* continually rejecting shares has started accepting shares.
* This will only happen with the work returned from a
* longpoll */
if (unlikely(pool->enabled == POOL_REJECTING)) {
applog(LOG_WARNING, "Rejecting pool %d now accepting shares, re-enabling!", pool->pool_no);
enable_pool(pool);
switch_pools(NULL);
}
/* If we know we found the block we know better than anyone
* that new work is needed. */
if (unlikely(work->block))
restart_threads();
} else {
mutex_lock(&stats_lock);
cgpu->rejected++;
total_rejected++;
pool->rejected++;
cgpu->diff_rejected += work->work_difficulty;
total_diff_rejected += work->work_difficulty;
pool->diff_rejected += work->work_difficulty;
pool->seq_rejects++;
mutex_unlock(&stats_lock);
applog(LOG_DEBUG, "PROOF OF WORK RESULT: false (booooo)");
if (!QUIET) {
char where[20];
char disposition[36] = "reject";
char reason[32];
strcpy(reason, "");
if (total_pools > 1)
snprintf(where, sizeof(where), "pool %d", work->pool->pool_no);
else
strcpy(where, "");
if (!work->gbt)
res = json_object_get(val, "reject-reason");
if (res) {
const char *reasontmp = json_string_value(res);
size_t reasonLen = strlen(reasontmp);
if (reasonLen > 28)
reasonLen = 28;
reason[0] = ' '; reason[1] = '(';
cg_memcpy(2 + reason, reasontmp, reasonLen);
reason[reasonLen + 2] = ')'; reason[reasonLen + 3] = '\0';
cg_memcpy(disposition + 7, reasontmp, reasonLen);
disposition[6] = ':'; disposition[reasonLen + 7] = '\0';
} else if (work->stratum && err) {
if (json_is_array(err)) {
json_t *reason_val = json_array_get(err, 1);
char *reason_str;
if (reason_val && json_is_string(reason_val)) {
reason_str = (char *)json_string_value(reason_val);
snprintf(reason, 31, " (%s)", reason_str);
}
} else if (json_is_string(err)) {
const char *s = json_string_value(err);
snprintf(reason, 31, " (%s)", s);
}
}
applog(LOG_NOTICE, "Rejected %s %s %d %s%s %s%s",
hashshow, cgpu->drv->name, cgpu->device_id, where, reason, resubmit ? "(resubmit)" : "", worktime);
sharelog(disposition, work);
}
/* Once we have more than a nominal amount of sequential rejects,
* at least 10 and more than 3 mins at the current utility,
* disable the pool because some pool error is likely to have
* ensued. Do not do this if we know the share just happened to
* be stale due to networking delays.
*/
if (pool->seq_rejects > 10 && !work->stale && opt_disable_pool && enabled_pools > 1) {
double utility = total_accepted / total_secs * 60;
if (pool->seq_rejects > utility * 3 && enabled_pools > 1) {
applog(LOG_WARNING, "Pool %d rejected %d sequential shares, disabling!",
pool->pool_no, pool->seq_rejects);
reject_pool(pool);
if (pool == current_pool())
switch_pools(NULL);
pool->seq_rejects = 0;
}
}
}
}
static void show_hash(struct work *work, char *hashshow)
{
unsigned char rhash[32];
char diffdisp[16];
unsigned long h32;
uint32_t *hash32;
uint64_t uintdiff;
int ofs;
swab256(rhash, work->hash);
for (ofs = 0; ofs <= 28; ofs ++) {
if (rhash[ofs])
break;
}
hash32 = (uint32_t *)(rhash + ofs);
h32 = be32toh(*hash32);
uintdiff = round(work->work_difficulty);
suffix_string(work->share_diff, diffdisp, sizeof (diffdisp), 0);
snprintf(hashshow, 64, "%08lx Diff %s/%"PRIu64"%s", h32, diffdisp, uintdiff,
work->block? " BLOCK!" : "");
}
#ifdef HAVE_LIBCURL
static void text_print_status(int thr_id)
{
struct cgpu_info *cgpu;
char logline[256];
cgpu = get_thr_cgpu(thr_id);
if (cgpu) {
get_statline(logline, sizeof(logline), cgpu);
printf("%s\n", logline);
}
}
static void print_status(int thr_id)
{
if (!curses_active)
text_print_status(thr_id);
}
static bool submit_upstream_work(struct work *work, CURL *curl, bool resubmit)
{
json_t *val, *res, *err;
char *s;
bool rc = false;
int thr_id = work->thr_id;
struct cgpu_info *cgpu = get_thr_cgpu(thr_id);
struct pool *pool = work->pool;
int rolltime;
struct timeval tv_submit, tv_submit_reply;
char hashshow[64 + 4] = "";
char worktime[200] = "";
struct timeval now;
double dev_runtime;
char gbt_block[1024], varint[12];
unsigned char data[80];
/* build JSON-RPC request */
flip80(data, work->data);
__bin2hex(gbt_block, data, 80); // 160 length
if (work->gbt_txns < 0xfd) {
uint8_t val8 = work->gbt_txns;
__bin2hex(varint, (const unsigned char *)&val8, 1);
} else if (work->gbt_txns <= 0xffff) {
uint16_t val16 = htole16(work->gbt_txns);
strcat(gbt_block, "fd"); // +2
__bin2hex(varint, (const unsigned char *)&val16, 2);
} else {
uint32_t val32 = htole32(work->gbt_txns);
strcat(gbt_block, "fe"); // +2
__bin2hex(varint, (const unsigned char *)&val32, 4);
}
strcat(gbt_block, varint); // +8 max
strcat(gbt_block, work->coinbase);
s = cgmalloc(1024);
sprintf(s, "{\"id\": 0, \"method\": \"submitblock\", \"params\": [\"%s", gbt_block);
/* Has submit/coinbase support */
if (!pool->has_gbt) {
cg_rlock(&pool->gbt_lock);
if (pool->txn_data)
s = realloc_strcat(s, pool->txn_data);
cg_runlock(&pool->gbt_lock);
}
if (work->job_id) {
s = realloc_strcat(s, "\", {\"workid\": \"");
s = realloc_strcat(s, work->job_id);
s = realloc_strcat(s, "\"}]}");
} else
s = realloc_strcat(s, "\"]}");
applog(LOG_DEBUG, "DBG: sending %s submit RPC call: %s", pool->rpc_url, s);
s = realloc_strcat(s, "\n");
cgtime(&tv_submit);
/* issue JSON-RPC request */
val = json_rpc_call(curl, pool->rpc_url, pool->rpc_userpass, s, false, false, &rolltime, pool, true);
cgtime(&tv_submit_reply);
free(s);
if (unlikely(!val)) {
applog(LOG_INFO, "submit_upstream_work json_rpc_call failed");
if (!pool_tset(pool, &pool->submit_fail)) {
total_ro++;
pool->remotefail_occasions++;
if (opt_lowmem) {
applog(LOG_WARNING, "Pool %d communication failure, discarding shares", pool->pool_no);
goto out;
}
applog(LOG_WARNING, "Pool %d communication failure, caching submissions", pool->pool_no);
}
cgsleep_ms(5000);
goto out;
} else if (pool_tclear(pool, &pool->submit_fail))
applog(LOG_WARNING, "Pool %d communication resumed, submitting work", pool->pool_no);
res = json_object_get(val, "result");
err = json_object_get(val, "error");
if (!QUIET) {
show_hash(work, hashshow);
if (opt_worktime) {
char workclone[20];
struct tm *tm, tm_getwork, tm_submit_reply;
double getwork_time = tdiff((struct timeval *)&(work->tv_getwork_reply),
(struct timeval *)&(work->tv_getwork));
double getwork_to_work = tdiff((struct timeval *)&(work->tv_work_start),
(struct timeval *)&(work->tv_getwork_reply));
double work_time = tdiff((struct timeval *)&(work->tv_work_found),
(struct timeval *)&(work->tv_work_start));
double work_to_submit = tdiff(&tv_submit,
(struct timeval *)&(work->tv_work_found));
double submit_time = tdiff(&tv_submit_reply, &tv_submit);
int diffplaces = 3;
time_t tmp_time = work->tv_getwork.tv_sec;
tm = localtime(&tmp_time);
cg_memcpy(&tm_getwork, tm, sizeof(struct tm));
tmp_time = tv_submit_reply.tv_sec;
tm = localtime(&tmp_time);
cg_memcpy(&tm_submit_reply, tm, sizeof(struct tm));
if (work->clone) {
snprintf(workclone, sizeof(workclone), "C:%1.3f",
tdiff((struct timeval *)&(work->tv_cloned),
(struct timeval *)&(work->tv_getwork_reply)));
}
else
strcpy(workclone, "O");
if (work->work_difficulty < 1)
diffplaces = 6;
snprintf(worktime, sizeof(worktime),
" <-%08lx.%08lx M:%c D:%1.*f G:%02d:%02d:%02d:%1.3f %s (%1.3f) W:%1.3f (%1.3f) S:%1.3f R:%02d:%02d:%02d",
(unsigned long)be32toh(*(uint32_t *)&(work->data[28])),
(unsigned long)be32toh(*(uint32_t *)&(work->data[24])),
work->getwork_mode, diffplaces, work->work_difficulty,
tm_getwork.tm_hour, tm_getwork.tm_min,
tm_getwork.tm_sec, getwork_time, workclone,
getwork_to_work, work_time, work_to_submit, submit_time,
tm_submit_reply.tm_hour, tm_submit_reply.tm_min,
tm_submit_reply.tm_sec);
}
}
share_result(val, res, err, work, hashshow, resubmit, worktime);
if (cgpu->dev_start_tv.tv_sec == 0)
dev_runtime = total_secs;
else {
cgtime(&now);
dev_runtime = tdiff(&now, &(cgpu->dev_start_tv));
}
if (dev_runtime < 1.0)
dev_runtime = 1.0;
cgpu->utility = cgpu->accepted / dev_runtime * 60;
if (!opt_realquiet)
print_status(thr_id);
if (!want_per_device_stats) {
char logline[256];
get_statline(logline, sizeof(logline), cgpu);
applog(LOG_INFO, "%s", logline);
}
json_decref(val);
rc = true;
out:
return rc;
}
#endif /* HAVE_LIBCURL */
/* Specifies whether we can use this pool for work or not. */
static bool pool_unusable(struct pool *pool)
{
if (pool->idle)
return true;
if (pool->enabled != POOL_ENABLED)
return true;
if (pool->has_stratum && (!pool->stratum_active || !pool->stratum_notify))
return true;
return false;
}
/* In balanced mode, the amount of diff1 solutions per pool is monitored as a
* rolling average per 10 minutes and if pools start getting more, it biases
* away from them to distribute work evenly. The share count is reset to the
* rolling average every 10 minutes to not send all work to one pool after it
* has been disabled/out for an extended period. */
static struct pool *select_balanced(struct pool *cp)
{
int i, lowest = cp->shares;
struct pool *ret = cp;
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
if (pool_unusable(pool))
continue;
if (pool->shares < lowest) {
lowest = pool->shares;
ret = pool;
}
}
ret->shares++;
return ret;
}
static struct pool *priority_pool(int choice);
/* Select any active pool in a rotating fashion when loadbalance is chosen if
* it has any quota left. */
static inline struct pool *select_pool(void)
{
static int rotating_pool = 0;
struct pool *pool, *cp;
bool avail = false;
int tested, i;
cp = current_pool();
if (pool_strategy == POOL_BALANCE) {
pool = select_balanced(cp);
goto out;
}
if (pool_strategy != POOL_LOADBALANCE) {
pool = cp;
goto out;
} else
pool = NULL;
for (i = 0; i < total_pools; i++) {
struct pool *tp = pools[i];
if (tp->quota_used < tp->quota_gcd) {
avail = true;
break;
}
}
/* There are no pools with quota, so reset them. */
if (!avail) {
for (i = 0; i < total_pools; i++)
pools[i]->quota_used = 0;
if (++rotating_pool >= total_pools)
rotating_pool = 0;
}
/* Try to find the first pool in the rotation that is usable */
tested = 0;
while (!pool && tested++ < total_pools) {
pool = pools[rotating_pool];
if (pool->quota_used++ < pool->quota_gcd) {
if (!pool_unusable(pool))
break;
}
pool = NULL;
if (++rotating_pool >= total_pools)
rotating_pool = 0;
}
/* If there are no alive pools with quota, choose according to
* priority. */
if (!pool) {
for (i = 0; i < total_pools; i++) {
struct pool *tp = priority_pool(i);
if (!pool_unusable(tp)) {
pool = tp;
break;
}
}
}
/* If still nothing is usable, use the current pool */
if (!pool)
pool = cp;
out:
applog(LOG_DEBUG, "Selecting pool %d for work", pool->pool_no);
return pool;
}
/* truediffone == 0x00000000FFFF0000000000000000000000000000000000000000000000000000
* Generate a 256 bit binary LE target by cutting up diff into 64 bit sized
* portions or vice versa. */
static const double truediffone = 26959535291011309493156476344723991336010898738574164086137773096960.0;
static const double bits192 = 6277101735386680763835789423207666416102355444464034512896.0;
static const double bits128 = 340282366920938463463374607431768211456.0;
static const double bits64 = 18446744073709551616.0;
/* Converts a little endian 256 bit value to a double */
static double le256todouble(const void *target)
{
uint64_t *data64;
double dcut64;
data64 = (uint64_t *)(target + 24);
dcut64 = le64toh(*data64) * bits192;
data64 = (uint64_t *)(target + 16);
dcut64 += le64toh(*data64) * bits128;
data64 = (uint64_t *)(target + 8);
dcut64 += le64toh(*data64) * bits64;
data64 = (uint64_t *)(target);
dcut64 += le64toh(*data64);
return dcut64;
}
static double diff_from_target(void *target)
{
double d64, dcut64;
d64 = truediffone;
dcut64 = le256todouble(target);
if (unlikely(!dcut64))
dcut64 = 1;
return d64 / dcut64;
}
/*
* Calculate the work->work_difficulty based on the work->target
*/
static void calc_diff(struct work *work, double known)
{
struct cgminer_pool_stats *pool_stats = &(work->pool->cgminer_pool_stats);
double difficulty;
uint64_t uintdiff;
if (known)
work->work_difficulty = known;
else
work->work_difficulty = diff_from_target(work->target);
difficulty = work->work_difficulty;
pool_stats->last_diff = difficulty;
uintdiff = round(difficulty);
suffix_string(uintdiff, work->pool->diff, sizeof(work->pool->diff), 0);
if (difficulty == pool_stats->min_diff)
pool_stats->min_diff_count++;
else if (difficulty < pool_stats->min_diff || pool_stats->min_diff == 0) {
pool_stats->min_diff = difficulty;
pool_stats->min_diff_count = 1;
}
if (difficulty == pool_stats->max_diff)
pool_stats->max_diff_count++;
else if (difficulty > pool_stats->max_diff) {
pool_stats->max_diff = difficulty;
pool_stats->max_diff_count = 1;
}
}
static unsigned char bench_hidiff_bins[16][160];
static unsigned char bench_lodiff_bins[16][160];
static unsigned char bench_target[32];
/* Iterate over the lo and hi diff benchmark work items such that we find one
* diff 32+ share every 32 work items. */
static void get_benchmark_work(struct work *work)
{
work->work_difficulty = 32;
cg_memcpy(work->target, bench_target, 32);
work->drv_rolllimit = 0;
work->mandatory = true;
work->pool = pools[0];
cgtime(&work->tv_getwork);
copy_time(&work->tv_getwork_reply, &work->tv_getwork);
work->getwork_mode = GETWORK_MODE_BENCHMARK;
}
static void benchfile_dspwork(struct work *work, uint32_t nonce)
{
char buf[1024];
uint32_t dn;
int i;
dn = 0;
for (i = 0; i < 4; i++) {
dn *= 0x100;
dn += nonce & 0xff;
nonce /= 0x100;
}
if ((sizeof(work->data) * 2 + 1) > sizeof(buf))
quithere(1, "BENCHFILE Invalid buf size");
__bin2hex(buf, work->data, sizeof(work->data));
applog(LOG_ERR, "BENCHFILE nonce %u=0x%08x for work=%s",
(unsigned int)dn, (unsigned int)dn, buf);
}
static bool benchfile_get_work(struct work *work)
{
char buf[1024];
char item[1024];
bool got = false;
if (!benchfile_in) {
if (opt_benchfile)
benchfile_in = fopen(opt_benchfile, "r");
else
quit(1, "BENCHFILE Invalid benchfile NULL");
if (!benchfile_in)
quit(1, "BENCHFILE Failed to open benchfile '%s'", opt_benchfile);
benchfile_line = 0;
if (!fgets(buf, 1024, benchfile_in))
quit(1, "BENCHFILE Failed to read benchfile '%s'", opt_benchfile);
got = true;
benchfile_work = 0;
}
if (!got) {
if (!fgets(buf, 1024, benchfile_in)) {
if (benchfile_work == 0)
quit(1, "BENCHFILE No work in benchfile '%s'", opt_benchfile);
fclose(benchfile_in);
benchfile_in = NULL;
return benchfile_get_work(work);
}
}
do {
benchfile_line++;
// Empty lines and lines starting with '#' or '/' are ignored
if (*buf != '\0' && *buf != '#' && *buf != '/') {
char *commas[BENCHWORK_COUNT];
int i, j, len;
long nonce_time;
commas[0] = buf;
for (i = 1; i < BENCHWORK_COUNT; i++) {
commas[i] = strchr(commas[i-1], ',');
if (!commas[i]) {
quit(1, "BENCHFILE Invalid input file line %d"
" - field count is %d but should be %d",
benchfile_line, i, BENCHWORK_COUNT);
}
len = commas[i] - commas[i-1];
if (benchfile_data[i-1].length &&
(len != benchfile_data[i-1].length)) {
quit(1, "BENCHFILE Invalid input file line %d "
"field %d (%s) length is %d but should be %d",
benchfile_line, i,
benchfile_data[i-1].name,
len, benchfile_data[i-1].length);
}
*(commas[i]++) = '\0';
}
// NonceTime may have LF's etc
len = strlen(commas[BENCHWORK_NONCETIME]);
if (len < benchfile_data[BENCHWORK_NONCETIME].length) {
quit(1, "BENCHFILE Invalid input file line %d field %d"
" (%s) length is %d but should be least %d",
benchfile_line, BENCHWORK_NONCETIME+1,
benchfile_data[BENCHWORK_NONCETIME].name, len,
benchfile_data[BENCHWORK_NONCETIME].length);
}
sprintf(item, "0000000%c", commas[BENCHWORK_VERSION][0]);
j = strlen(item);
for (i = benchfile_data[BENCHWORK_PREVHASH].length-8; i >= 0; i -= 8) {
sprintf(&(item[j]), "%.8s", &commas[BENCHWORK_PREVHASH][i]);
j += 8;
}
for (i = benchfile_data[BENCHWORK_MERKLEROOT].length-8; i >= 0; i -= 8) {
sprintf(&(item[j]), "%.8s", &commas[BENCHWORK_MERKLEROOT][i]);
j += 8;
}
nonce_time = atol(commas[BENCHWORK_NONCETIME]);
sprintf(&(item[j]), "%08lx", nonce_time);
j += 8;
strcpy(&(item[j]), commas[BENCHWORK_DIFFBITS]);
j += benchfile_data[BENCHWORK_DIFFBITS].length;
memset(work, 0, sizeof(*work));
hex2bin(work->data, item, j >> 1);
calc_midstate(work->pool, work);
benchfile_work++;
return true;
}
} while (fgets(buf, 1024, benchfile_in));
if (benchfile_work == 0)
quit(1, "BENCHFILE No work in benchfile '%s'", opt_benchfile);
fclose(benchfile_in);
benchfile_in = NULL;
return benchfile_get_work(work);
}
static void get_benchfile_work(struct work *work)
{
benchfile_get_work(work);
work->mandatory = true;
work->pool = pools[0];
cgtime(&work->tv_getwork);
copy_time(&work->tv_getwork_reply, &work->tv_getwork);
work->getwork_mode = GETWORK_MODE_BENCHMARK;
calc_diff(work, 0);
}
#ifdef HAVE_CURSES
static void disable_curses_windows(void)
{
leaveok(logwin, false);
leaveok(statuswin, false);
leaveok(mainwin, false);
nocbreak();
echo();
delwin(logwin);
delwin(statuswin);
}
/* Force locking of curses console_lock on shutdown since a dead thread might
* have grabbed the lock. */
static bool curses_active_forcelocked(void)
{
bool ret;
mutex_trylock(&console_lock);
ret = curses_active;
if (!ret)
unlock_curses();
return ret;
}
static void disable_curses(void)
{
if (curses_active_forcelocked()) {
use_curses = false;
curses_active = false;
disable_curses_windows();
delwin(mainwin);
endwin();
#ifdef WIN32
// Move the cursor to after curses output.
HANDLE hout = GetStdHandle(STD_OUTPUT_HANDLE);
CONSOLE_SCREEN_BUFFER_INFO csbi;
COORD coord;
if (GetConsoleScreenBufferInfo(hout, &csbi)) {
coord.X = 0;
coord.Y = csbi.dwSize.Y - 1;
SetConsoleCursorPosition(hout, coord);
}
#endif
unlock_curses();
}
}
#endif
static void kill_timeout(struct thr_info *thr)
{
cg_completion_timeout(&thr_info_cancel, thr, 1000);
}
static void kill_mining(void)
{
struct thr_info *thr;
int i;
forcelog(LOG_DEBUG, "Killing off mining threads");
/* Kill the mining threads*/
for (i = 0; i < mining_threads; i++) {
pthread_t *pth = NULL;
thr = get_thread(i);
if (thr && PTH(thr) != 0L)
pth = &thr->pth;
thr_info_cancel(thr);
#if !defined __MINGW32__ || __WINPTHREADS_VERSION >= 0x00050000
if (pth && *pth)
pthread_join(*pth, NULL);
#else
if (pth && pth->p)
pthread_join(*pth, NULL);
#endif
}
}
static void wait_mining(void)
{
struct thr_info *thr;
int i;
forcelog(LOG_DEBUG, "Waiting on mining threads");
/* Kill the mining threads*/
for (i = 0; i < mining_threads; i++) {
pthread_t *pth = NULL;
thr = get_thread(i);
if (thr && PTH(thr) != 0L)
pth = &thr->pth;
if (pth && *pth)
pthread_join(*pth, NULL);
}
}
static void __kill_work(void)
{
struct thr_info *thr;
int i;
if (!successful_connect)
return;
forcelog(LOG_INFO, "Received kill message");
#ifdef USE_USBUTILS
/* Best to get rid of it first so it doesn't
* try to create any new devices */
forcelog(LOG_DEBUG, "Killing off HotPlug thread");
thr = &control_thr[hotplug_thr_id];
kill_timeout(thr);
#endif
forcelog(LOG_DEBUG, "Killing off watchpool thread");
/* Kill the watchpool thread */
thr = &control_thr[watchpool_thr_id];
kill_timeout(thr);
forcelog(LOG_DEBUG, "Killing off watchdog thread");
/* Kill the watchdog thread */
thr = &control_thr[watchdog_thr_id];
kill_timeout(thr);
forcelog(LOG_DEBUG, "Shutting down mining threads");
for (i = 0; i < mining_threads; i++) {
struct cgpu_info *cgpu;
thr = get_thread(i);
if (!thr)
continue;
cgpu = thr->cgpu;
if (!cgpu)
continue;
cgpu->shutdown = true;
}
/* Give the threads a chance to shut down gracefully */
cg_completion_timeout(&wait_mining, NULL, 5000);
/* Kill the threads and wait for them to return if not */
cg_completion_timeout(&kill_mining, NULL, 5000);
/* Stop the others */
forcelog(LOG_DEBUG, "Killing off API thread");
thr = &control_thr[api_thr_id];
kill_timeout(thr);
#ifdef USE_USBUTILS
/* Release USB resources in case it's a restart
* and not a QUIT */
forcelog(LOG_DEBUG, "Releasing all USB devices");
cg_completion_timeout(&usb_cleanup, NULL, 1000);
forcelog(LOG_DEBUG, "Killing off usbres thread");
thr = &control_thr[usbres_thr_id];
kill_timeout(thr);
#endif
}
/* This should be the common exit path */
void kill_work(void)
{
cg_completion_timeout(&__kill_work, NULL, 10000);
quit(0, "Shutdown signal received.");
}
static
#ifdef WIN32
const
#endif
char **initial_args;
static void *raise_thread(void __maybe_unused *arg)
{
raise(SIGTERM);
return NULL;
}
/* This provides a mechanism for driver threads to initiate a shutdown without
* the cyclical problem of the shutdown path being cancelled while the driver
* thread shuts down.*/
void raise_cgminer(void)
{
pthread_t pth;
pthread_create(&pth, NULL, raise_thread, NULL);
}
static void clean_up(bool restarting);
void app_restart(void)
{
applog(LOG_WARNING, "Attempting to restart %s", packagename);
#ifdef USE_LIBSYSTEMD
sd_notify(false, "RELOADING=1\n"
"STATUS=Restarting...");
#endif
cg_completion_timeout(&__kill_work, NULL, 5000);
clean_up(true);
#if defined(unix) || defined(__APPLE__)
if (forkpid > 0) {
kill(forkpid, SIGTERM);
forkpid = 0;
}
#endif
execv(initial_args[0], (EXECV_2ND_ARG_TYPE)initial_args);
applog(LOG_WARNING, "Failed to restart application");
}
static void sighandler(int __maybe_unused sig)
{
/* Restore signal handlers so we can still quit if kill_work fails */
sigaction(SIGTERM, &termhandler, NULL);
sigaction(SIGINT, &inthandler, NULL);
sigaction(SIGABRT, &abrthandler, NULL);
kill_work();
}
static void _stage_work(struct work *work);
#define stage_work(WORK) do { \
_stage_work(WORK); \
WORK = NULL; \
} while (0)
/* Adjust an existing char ntime field with a relative noffset */
static void modify_ntime(char *ntime, int noffset)
{
unsigned char bin[4];
uint32_t h32, *be32 = (uint32_t *)bin;
hex2bin(bin, ntime, 4);
h32 = be32toh(*be32) + noffset;
*be32 = htobe32(h32);
__bin2hex(ntime, bin, 4);
}
void roll_work(struct work *work)
{
uint32_t *work_ntime;
uint32_t ntime;
work_ntime = (uint32_t *)(work->data + 68);
ntime = be32toh(*work_ntime);
ntime++;
*work_ntime = htobe32(ntime);
local_work++;
work->rolls++;
work->nonce = 0;
applog(LOG_DEBUG, "Successfully rolled work");
/* Change the ntime field if this is stratum work */
if (work->ntime)
modify_ntime(work->ntime, 1);
/* This is now a different work item so it needs a different ID for the
* hashtable */
work->id = total_work_inc();
}
void roll_work_ntime(struct work *work, int noffset)
{
uint32_t *work_ntime;
uint32_t ntime;
work_ntime = (uint32_t *)(work->data + 68);
ntime = be32toh(*work_ntime);
ntime += noffset;
*work_ntime = htobe32(ntime);
local_work++;
work->rolls += noffset;
work->nonce = 0;
applog(LOG_DEBUG, "Successfully rolled work");
/* Change the ntime field if this is stratum work */
if (work->ntime)
modify_ntime(work->ntime, noffset);
/* This is now a different work item so it needs a different ID for the
* hashtable */
work->id = total_work_inc();
}
struct work *make_clone(struct work *work)
{
struct work *work_clone = copy_work(work);
work_clone->clone = true;
cgtime((struct timeval *)&(work_clone->tv_cloned));
work_clone->longpoll = false;
work_clone->mandatory = false;
/* Make cloned work appear slightly older to bias towards keeping the
* master work item which can be further rolled */
work_clone->tv_staged.tv_sec -= 1;
return work_clone;
}
#ifdef HAVE_LIBCURL
/* Called with pool_lock held. Recruit an extra curl if none are available for
* this pool. */
static void recruit_curl(struct pool *pool)
{
struct curl_ent *ce = cgcalloc(sizeof(struct curl_ent), 1);
ce->curl = curl_easy_init();
if (unlikely(!ce->curl))
quit(1, "Failed to init in recruit_curl");
list_add(&ce->node, &pool->curlring);
pool->curls++;
}
/* Grab an available curl if there is one. If not, then recruit extra curls
* unless we are in a submit_fail situation, or we have opt_delaynet enabled
* and there are already 5 curls in circulation. Limit total number to the
* number of mining threads per pool as well to prevent blasting a pool during
* network delays/outages. */
static struct curl_ent *pop_curl_entry(struct pool *pool)
{
int curl_limit = opt_delaynet ? 5 : (mining_threads + max_queue) * 2;
bool recruited = false;
struct curl_ent *ce;
mutex_lock(&pool->pool_lock);
retry:
if (!pool->curls) {
recruit_curl(pool);
recruited = true;
} else if (list_empty(&pool->curlring)) {
if (pool->curls >= curl_limit) {
pthread_cond_wait(&pool->cr_cond, &pool->pool_lock);
goto retry;
} else {
recruit_curl(pool);
recruited = true;
}
}
ce = list_entry(pool->curlring.next, struct curl_ent, node);
list_del(&ce->node);
mutex_unlock(&pool->pool_lock);
if (recruited)
applog(LOG_DEBUG, "Recruited curl for pool %d", pool->pool_no);
return ce;
}
static void push_curl_entry(struct curl_ent *ce, struct pool *pool)
{
mutex_lock(&pool->pool_lock);
list_add_tail(&ce->node, &pool->curlring);
cgtime(&ce->tv);
pthread_cond_broadcast(&pool->cr_cond);
mutex_unlock(&pool->pool_lock);
}
static bool stale_work(struct work *work, bool share);
static inline bool should_roll(struct work *work)
{
struct timeval now;
time_t expiry;
if (work->pool != current_pool() && pool_strategy != POOL_LOADBALANCE && pool_strategy != POOL_BALANCE)
return false;
if (work->rolltime > max_scantime)
expiry = work->rolltime;
else
expiry = max_scantime;
expiry = expiry * 2 / 3;
/* We shouldn't roll if we're unlikely to get one shares' duration
* work out of doing so */
cgtime(&now);
if (now.tv_sec - work->tv_staged.tv_sec > expiry)
return false;
return true;
}
/* Limit rolls to 7000 to not beyond 2 hours in the future where bitcoind will
* reject blocks as invalid. */
static inline bool can_roll(struct work *work)
{
return (!work->stratum && work->pool && work->rolltime && !work->clone &&
work->rolls < 7000 && !stale_work(work, false));
}
static void *submit_work_thread(void *userdata)
{
struct work *work = (struct work *)userdata;
struct pool *pool = work->pool;
bool resubmit = false;
struct curl_ent *ce;
pthread_detach(pthread_self());
RenameThread("SubmitWork");
applog(LOG_DEBUG, "Creating extra submit work thread");
ce = pop_curl_entry(pool);
/* submit solution to bitcoin via JSON-RPC */
while (!submit_upstream_work(work, ce->curl, resubmit)) {
if (opt_lowmem) {
applog(LOG_NOTICE, "Pool %d share being discarded to minimise memory cache", pool->pool_no);
break;
}
resubmit = true;
if (stale_work(work, true)) {
applog(LOG_NOTICE, "Pool %d share became stale while retrying submit, discarding", pool->pool_no);
mutex_lock(&stats_lock);
total_stale++;
pool->stale_shares++;
total_diff_stale += work->work_difficulty;
pool->diff_stale += work->work_difficulty;
mutex_unlock(&stats_lock);
free_work(work);
break;
}
/* pause, then restart work-request loop */
applog(LOG_INFO, "json_rpc_call failed on submit_work, retrying");
}
push_curl_entry(ce, pool);
return NULL;
}
/* Clones work by rolling it if possible, and returning a clone instead of the
* original work item which gets staged again to possibly be rolled again in
* the future */
static struct work *clone_work(struct work *work)
{
int mrs = mining_threads + max_queue - total_staged();
struct work *work_clone;
bool cloned;
if (mrs < 1)
return work;
cloned = false;
work_clone = make_clone(work);
while (mrs-- > 0 && can_roll(work) && should_roll(work)) {
applog(LOG_DEBUG, "Pushing rolled converted work to stage thread");
stage_work(work_clone);
roll_work(work);
work_clone = make_clone(work);
/* Roll it again to prevent duplicates should this be used
* directly later on */
roll_work(work);
cloned = true;
}
if (cloned) {
stage_work(work);
return work_clone;
}
free_work(work_clone);
return work;
}
#else /* HAVE_LIBCURL */
static void *submit_work_thread(void __maybe_unused *userdata)
{
pthread_detach(pthread_self());
return NULL;
}
#endif /* HAVE_LIBCURL */
/* Return an adjusted ntime if we're submitting work that a device has
* internally offset the ntime. */
static char *offset_ntime(const char *ntime, int noffset)
{
unsigned char bin[4];
uint32_t h32, *be32 = (uint32_t *)bin;
hex2bin(bin, ntime, 4);
h32 = be32toh(*be32) + noffset;
*be32 = htobe32(h32);
return bin2hex(bin, 4);
}
/* Duplicates any dynamically allocated arrays within the work struct to
* prevent a copied work struct from freeing ram belonging to another struct */
static void _copy_work(struct work *work, const struct work *base_work, int noffset)
{
uint32_t id = work->id;
clean_work(work);
cg_memcpy(work, base_work, sizeof(struct work));
/* Keep the unique new id assigned during make_work to prevent copied
* work from having the same id. */
work->id = id;
if (base_work->job_id)
work->job_id = strdup(base_work->job_id);
if (base_work->nonce1)
work->nonce1 = strdup(base_work->nonce1);
if (base_work->ntime) {
/* If we are passed an noffset the binary work->data ntime and
* the work->ntime hex string need to be adjusted. */
if (noffset) {
uint32_t *work_ntime = (uint32_t *)(work->data + 68);
uint32_t ntime = be32toh(*work_ntime);
ntime += noffset;
*work_ntime = htobe32(ntime);
work->ntime = offset_ntime(base_work->ntime, noffset);
} else
work->ntime = strdup(base_work->ntime);
} else if (noffset) {
uint32_t *work_ntime = (uint32_t *)(work->data + 68);
uint32_t ntime = be32toh(*work_ntime);
ntime += noffset;
*work_ntime = htobe32(ntime);
}
if (base_work->coinbase)
work->coinbase = strdup(base_work->coinbase);
#ifdef USE_BITMAIN_SOC
work->version = base_work->version;
#endif
}
void set_work_ntime(struct work *work, int ntime)
{
uint32_t *work_ntime = (uint32_t *)(work->data + 68);
*work_ntime = htobe32(ntime);
if (work->ntime) {
free(work->ntime);
work->ntime = bin2hex((unsigned char *)work_ntime, 4);
}
}
/* Generates a copy of an existing work struct, creating fresh heap allocations
* for all dynamically allocated arrays within the struct. noffset is used for
* when a driver has internally rolled the ntime, noffset is a relative value.
* The macro copy_work() calls this function with an noffset of 0. */
struct work *copy_work_noffset(struct work *base_work, int noffset)
{
struct work *work = make_work();
_copy_work(work, base_work, noffset);
return work;
}
void pool_died(struct pool *pool)
{
if (!pool_tset(pool, &pool->idle)) {
cgtime(&pool->tv_idle);
if (pool == current_pool()) {
applog(LOG_WARNING, "Pool %d %s not responding!", pool->pool_no, pool->rpc_url);
switch_pools(NULL);
} else
applog(LOG_INFO, "Pool %d %s failed to return work", pool->pool_no, pool->rpc_url);
}
}
static bool stale_work(struct work *work, bool share)
{
struct timeval now;
time_t work_expiry;
struct pool *pool;
if (opt_benchmark || opt_benchfile)
return false;
if (work->work_block != work_block) {
applog(LOG_DEBUG, "Work stale due to block mismatch");
return true;
}
/* Technically the rolltime should be correct but some pools
* advertise a broken expire= that is lower than a meaningful
* scantime */
if (work->rolltime > max_scantime)
work_expiry = work->rolltime;
else
work_expiry = max_expiry;
pool = work->pool;
if (!share && pool->has_stratum) {
bool same_job;
if (!pool->stratum_active || !pool->stratum_notify) {
applog(LOG_DEBUG, "Work stale due to stratum inactive");
return true;
}
same_job = true;
cg_rlock(&pool->data_lock);
if (strcmp(work->job_id, pool->swork.job_id))
same_job = false;
cg_runlock(&pool->data_lock);
if (!same_job) {
applog(LOG_DEBUG, "Work stale due to stratum job_id mismatch");
return true;
}
}
if (unlikely(work_expiry < 5))
work_expiry = 5;
cgtime(&now);
if ((now.tv_sec - work->tv_staged.tv_sec) >= work_expiry) {
applog(LOG_DEBUG, "Work stale due to expiry");
return true;
}
return false;
}
uint64_t share_diff(const struct work *work)
{
bool new_best = false;
double d64, s64;
uint64_t ret;
d64 = truediffone;
s64 = le256todouble(work->hash);
if (unlikely(!s64))
s64 = 0;
ret = round(d64 / s64);
cg_wlock(&control_lock);
if (unlikely(ret > best_diff)) {
new_best = true;
best_diff = ret;
suffix_string(best_diff, best_share, sizeof(best_share), 0);
}
if (unlikely(ret > work->pool->best_diff))
work->pool->best_diff = ret;
cg_wunlock(&control_lock);
if (unlikely(new_best))
applog(LOG_INFO, "New best share: %s", best_share);
return ret;
}
static void regen_hash(struct work *work)
{
uint32_t *data32 = (uint32_t *)(work->data);
unsigned char swap[80];
uint32_t *swap32 = (uint32_t *)swap;
unsigned char hash1[32];
flip80(swap32, data32);
sha256(swap, 80, hash1);
sha256(hash1, 32, (unsigned char *)(work->hash));
}
static bool cnx_needed(struct pool *pool);
/* Find the pool that currently has the highest priority */
static struct pool *priority_pool(int choice)
{
struct pool *ret = NULL;
int i;
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
if (pool->prio == choice) {
ret = pool;
break;
}
}
if (unlikely(!ret)) {
applog(LOG_ERR, "WTF No pool %d found!", choice);
return pools[choice];
}
return ret;
}
void switch_pools(struct pool *selected)
{
struct pool *pool, *last_pool;
int i, pool_no, next_pool;
cg_wlock(&control_lock);
last_pool = currentpool;
pool_no = currentpool->pool_no;
/* Switch selected to pool number 0 and move the rest down */
if (selected) {
if (selected->prio != 0) {
for (i = 0; i < total_pools; i++) {
pool = pools[i];
if (pool->prio < selected->prio)
pool->prio++;
}
selected->prio = 0;
}
}
switch (pool_strategy) {
/* All of these set to the master pool */
case POOL_BALANCE:
case POOL_FAILOVER:
case POOL_LOADBALANCE:
for (i = 0; i < total_pools; i++) {
pool = priority_pool(i);
if (pool_unusable(pool))
continue;
pool_no = pool->pool_no;
break;
}
break;
/* Both of these simply increment and cycle */
case POOL_ROUNDROBIN:
case POOL_ROTATE:
if (selected && !selected->idle) {
pool_no = selected->pool_no;
break;
}
next_pool = pool_no;
/* Select the next alive pool */
for (i = 1; i < total_pools; i++) {
next_pool++;
if (next_pool >= total_pools)
next_pool = 0;
pool = pools[next_pool];
if (pool_unusable(pool))
continue;
pool_no = next_pool;
break;
}
break;
default:
break;
}
currentpool = pools[pool_no];
pool = currentpool;
cg_wunlock(&control_lock);
if (pool != last_pool && pool_strategy != POOL_LOADBALANCE && pool_strategy != POOL_BALANCE) {
applog(LOG_WARNING, "Switching to pool %d %s", pool->pool_no, pool->rpc_url);
clear_pool_work(last_pool);
}
mutex_lock(&lp_lock);
pthread_cond_broadcast(&lp_cond);
mutex_unlock(&lp_lock);
}
void _discard_work(struct work **workptr, const char *file, const char *func, const int line)
{
struct work *work = *workptr;
if (unlikely(!work)) {
applog(LOG_ERR, "Discard work called with null work from %s %s:%d",
file, func, line);
return;
}
if (!work->clone && !work->rolls && !work->mined) {
if (work->pool) {
work->pool->discarded_work++;
work->pool->quota_used--;
work->pool->works--;
}
total_discarded++;
applog(LOG_DEBUG, "Discarded work");
} else
applog(LOG_DEBUG, "Discarded cloned or rolled work");
_free_work(workptr, file, func, line);
}
static void wake_gws(void)
{
mutex_lock(stgd_lock);
pthread_cond_signal(&gws_cond);
mutex_unlock(stgd_lock);
}
static void discard_stale(void)
{
struct work *work, *tmp;
int stale = 0;
mutex_lock(stgd_lock);
HASH_ITER(hh, staged_work, work, tmp) {
if (stale_work(work, false)) {
HASH_DEL(staged_work, work);
discard_work(work);
stale++;
}
}
pthread_cond_signal(&gws_cond);
mutex_unlock(stgd_lock);
if (stale)
applog(LOG_DEBUG, "Discarded %d stales that didn't match current hash", stale);
}
/* A generic wait function for threads that poll that will wait a specified
* time tdiff waiting on the pthread conditional that is broadcast when a
* work restart is required. Returns the value of pthread_cond_timedwait
* which is zero if the condition was met or ETIMEDOUT if not.
*/
int restart_wait(struct thr_info *thr, unsigned int mstime)
{
struct timespec abstime, tdiff;
int rc;
cgcond_time(&abstime);
ms_to_timespec(&tdiff, mstime);
timeraddspec(&abstime, &tdiff);
mutex_lock(&restart_lock);
if (thr->work_restart)
rc = 0;
else
rc = pthread_cond_timedwait(&restart_cond, &restart_lock, &abstime);
mutex_unlock(&restart_lock);
return rc;
}
static void *restart_thread(void __maybe_unused *arg)
{
struct cgpu_info *cgpu;
int i, mt;
pthread_detach(pthread_self());
/* Discard staged work that is now stale */
discard_stale();
rd_lock(&mining_thr_lock);
mt = mining_threads;
rd_unlock(&mining_thr_lock);
for (i = 0; i < mt; i++) {
cgpu = mining_thr[i]->cgpu;
if (unlikely(!cgpu))
continue;
if (cgpu->deven != DEV_ENABLED)
continue;
mining_thr[i]->work_restart = true;
flush_queue(cgpu);
cgpu->drv->flush_work(cgpu);
}
mutex_lock(&restart_lock);
pthread_cond_broadcast(&restart_cond);
mutex_unlock(&restart_lock);
#ifdef USE_USBUTILS
/* Cancels any cancellable usb transfers. Flagged as such it means they
* are usualy waiting on a read result and it's safe to abort the read
* early. */
cancel_usb_transfers();
#endif
return NULL;
}
/* In order to prevent a deadlock via the various drv->flush_work
* implementations we send the restart messages via a separate thread. */
static void restart_threads(void)
{
pthread_t rthread;
cgtime(&restart_tv_start);
if (unlikely(pthread_create(&rthread, NULL, restart_thread, NULL)))
quithere(1, "Failed to create restart thread errno=%d", errno);
}
static void signal_work_update(void)
{
int i;
applog(LOG_INFO, "Work update message received");
cgtime(&update_tv_start);
rd_lock(&mining_thr_lock);
for (i = 0; i < mining_threads; i++)
mining_thr[i]->work_update = true;
rd_unlock(&mining_thr_lock);
}
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined(USE_AVALONLC3)
static void signal_clean_jobs(void)
{
int i;
applog(LOG_NOTICE, "Job clean message received");
rd_lock(&mining_thr_lock);
for (i = 0; i < mining_threads; i++)
mining_thr[i]->clean_jobs = true;
rd_unlock(&mining_thr_lock);
}
#endif
static void set_curblock(const char *hexstr, const unsigned char *bedata)
{
int ofs;
cg_wlock(&ch_lock);
cgtime_real(&block_timeval);
strcpy(current_hash, hexstr);
cg_memcpy(current_block, bedata, 32);
get_timestamp(blocktime, sizeof(blocktime), &block_timeval);
cg_wunlock(&ch_lock);
for (ofs = 0; ofs <= 56; ofs++) {
if (memcmp(¤t_hash[ofs], "0", 1))
break;
}
strncpy(prev_block, ¤t_hash[ofs], 8);
prev_block[8] = '\0';
applog(LOG_INFO, "New block: %s... diff %s", current_hash, block_diff);
}
static int block_sort(struct block *blocka, struct block *blockb)
{
return blocka->block_no - blockb->block_no;
}
/* Decode the current block difficulty which is in packed form */
static void set_blockdiff(const struct work *work)
{
uint8_t pow = work->data[72];
int powdiff = (8 * (0x1d - 3)) - (8 * (pow - 3));
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined(USE_AVALONLC3)
if (powdiff < 8)
powdiff = 8;
#else
if (powdiff < 0)
powdiff = 0;
#endif
uint32_t diff32 = be32toh(*((uint32_t *)(work->data + 72))) & 0x00FFFFFF;
double numerator = 0xFFFFULL << powdiff;
double ddiff = numerator / (double)diff32;
if (unlikely(current_diff != ddiff)) {
suffix_string(ddiff, block_diff, sizeof(block_diff), 0);
current_diff = ddiff;
applog(LOG_NOTICE, "Network diff set to %s", block_diff);
}
}
/* Search to see if this string is from a block that has been seen before */
static bool block_exists(const char *hexstr, const unsigned char *bedata, const struct work *work)
{
int deleted_block = 0;
struct block *s;
bool ret = true;
wr_lock(&blk_lock);
HASH_FIND_STR(blocks, hexstr, s);
if (!s) {
s = cgcalloc(sizeof(struct block), 1);
if (unlikely(!s))
quit (1, "block_exists OOM");
strcpy(s->hash, hexstr);
s->block_no = new_blocks++;
ret = false;
/* Only keep the last hour's worth of blocks in memory since
* work from blocks before this is virtually impossible and we
* want to prevent memory usage from continually rising */
if (HASH_COUNT(blocks) > 6) {
struct block *oldblock;
HASH_SORT(blocks, block_sort);
oldblock = blocks;
deleted_block = oldblock->block_no;
HASH_DEL(blocks, oldblock);
free(oldblock);
}
HASH_ADD_STR(blocks, hash, s);
set_blockdiff(work);
if (deleted_block)
applog(LOG_DEBUG, "Deleted block %d from database", deleted_block);
}
wr_unlock(&blk_lock);
if (!ret)
set_curblock(hexstr, bedata);
if (deleted_block)
applog(LOG_DEBUG, "Deleted block %d from database", deleted_block);
return ret;
}
static bool test_work_current(struct work *work)
{
struct pool *pool = work->pool;
unsigned char bedata[32];
char hexstr[68];
bool ret = true;
unsigned char *bin_height = &pool->coinbase[43];
uint8_t cb_height_sz = bin_height[-1];
uint32_t height = 0;
if (work->mandatory)
return ret;
swap256(bedata, work->data + 4);
__bin2hex(hexstr, bedata, 32);
/* Calculate block height */
if (cb_height_sz <= 4) {
memcpy(&height, bin_height, cb_height_sz);
height = le32toh(height);
height--;
}
cg_wlock(&pool->data_lock);
if (pool->swork.clean) {
pool->swork.clean = false;
work->longpoll = true;
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined(USE_AVALONLC3)
opt_clean_jobs = true;
#endif
}
if (pool->current_height != height) {
pool->current_height = height;
}
cg_wunlock(&pool->data_lock);
/* Search to see if this block exists yet and if not, consider it a
* new block and set the current block details to this one */
if (!block_exists(hexstr, bedata, work)) {
/* Copy the information to this pool's prev_block since it
* knows the new block exists. */
cg_memcpy(pool->prev_block, bedata, 32);
if (unlikely(new_blocks == 1)) {
ret = false;
goto out;
}
work->work_block = ++work_block;
if (work->longpoll) {
if (work->stratum) {
applog(LOG_NOTICE, "Stratum from pool %d detected new block at height %d",
pool->pool_no, height);
} else {
applog(LOG_NOTICE, "%sLONGPOLL from pool %d detected new block at height %d",
work->gbt ? "GBT " : "", pool->pool_no, height);
}
} else if (have_longpoll && !pool->gbt_solo)
applog(LOG_NOTICE, "New block detected on network before pool notification from pool %d at height %d",
pool->pool_no, height);
else if (!pool->gbt_solo)
applog(LOG_NOTICE, "New block detected on network from pool %d at height %d",
pool->pool_no, height);
restart_threads();
} else {
if (memcmp(pool->prev_block, bedata, 32)) {
/* Work doesn't match what this pool has stored as
* prev_block. Let's see if the work is from an old
* block or the pool is just learning about a new
* block. */
if (memcmp(bedata, current_block, 32)) {
/* Doesn't match current block. It's stale */
applog(LOG_DEBUG, "Stale data from pool %d at height %d", pool->pool_no, height);
ret = false;
} else {
/* Work is from new block and pool is up now
* current. */
applog(LOG_INFO, "Pool %d now up to date at height %d", pool->pool_no, height);
cg_memcpy(pool->prev_block, bedata, 32);
}
}
#if 0
/* This isn't ideal, this pool is still on an old block but
* accepting shares from it. To maintain fair work distribution
* we work on it anyway. */
if (memcmp(bedata, current_block, 32))
applog(LOG_DEBUG, "Pool %d still on old block", pool->pool_no);
#endif
if (work->longpoll) {
work->work_block = ++work_block;
if (shared_strategy() || work->pool == current_pool()) {
if (work->stratum) {
applog(LOG_NOTICE, "Stratum from pool %d requested work restart",
pool->pool_no);
} else {
applog(LOG_NOTICE, "%sLONGPOLL from pool %d requested work restart",
work->gbt ? "GBT " : "", pool->pool_no);
}
restart_threads();
}
}
}
out:
work->longpoll = false;
return ret;
}
static int tv_sort(struct work *worka, struct work *workb)
{
return worka->tv_staged.tv_sec - workb->tv_staged.tv_sec;
}
static bool work_rollable(struct work *work)
{
return (!work->clone && work->rolltime);
}
static bool hash_push(struct work *work)
{
bool rc = true;
mutex_lock(stgd_lock);
if (work_rollable(work))
staged_rollable++;
if (likely(!getq->frozen)) {
HASH_ADD_INT(staged_work, id, work);
HASH_SORT(staged_work, tv_sort);
} else
rc = false;
pthread_cond_broadcast(&getq->cond);
mutex_unlock(stgd_lock);
return rc;
}
static void _stage_work(struct work *work)
{
applog(LOG_DEBUG, "Pushing work from pool %d to hash queue", work->pool->pool_no);
work->work_block = work_block;
test_work_current(work);
work->pool->works++;
hash_push(work);
}
#ifdef HAVE_CURSES
int curses_int(const char *query)
{
int ret;
char *cvar;
cvar = curses_input(query);
ret = atoi(cvar);
free(cvar);
return ret;
}
#endif
#ifdef HAVE_CURSES
static bool input_pool(bool live);
#endif
#ifdef HAVE_CURSES
static void display_pool_summary(struct pool *pool)
{
if (curses_active_locked()) {
wlog("Pool: %s\n", pool->rpc_url);
if (pool->solved)
wlog("SOLVED %d BLOCK%s!\n", pool->solved, pool->solved > 1 ? "S" : "");
if (!pool->has_stratum)
wlog("%s own long-poll support\n", pool->hdr_path ? "Has" : "Does not have");
wlog(" Work templates received: %d\n", pool->getwork_requested);
wlog(" Share submissions: %"PRId64"\n", pool->accepted + pool->rejected);
wlog(" Accepted shares: %"PRId64"\n", pool->accepted);
wlog(" Rejected shares: %"PRId64"\n", pool->rejected);
wlog(" Accepted difficulty shares: %1.f\n", pool->diff_accepted);
wlog(" Rejected difficulty shares: %1.f\n", pool->diff_rejected);
if (pool->accepted || pool->rejected)
wlog(" Reject ratio: %.1f%%\n", (double)(pool->rejected * 100) / (double)(pool->accepted + pool->rejected));
wlog(" Items worked on: %d\n", pool->works);
wlog(" Discarded work due to new blocks: %d\n", pool->discarded_work);
wlog(" Stale submissions discarded due to new blocks: %d\n", pool->stale_shares);
wlog(" Unable to get work from server occasions: %d\n", pool->getfail_occasions);
wlog(" Submitting work remotely delay occasions: %d\n\n", pool->remotefail_occasions);
unlock_curses();
}
}
#endif
/* We can't remove the memory used for this struct pool because there may
* still be work referencing it. We just remove it from the pools list */
void remove_pool(struct pool *pool)
{
int i, last_pool = total_pools - 1;
struct pool *other;
/* Boost priority of any lower prio than this one */
for (i = 0; i < total_pools; i++) {
other = pools[i];
if (other->prio > pool->prio)
other->prio--;
}
if (pool->pool_no < last_pool) {
/* Swap the last pool for this one */
(pools[last_pool])->pool_no = pool->pool_no;
pools[pool->pool_no] = pools[last_pool];
}
/* Give it an invalid number */
pool->pool_no = total_pools;
pool->removed = true;
total_pools--;
}
/* add a mutex if this needs to be thread safe in the future */
static struct JE {
char *buf;
struct JE *next;
} *jedata = NULL;
static void json_escape_free()
{
struct JE *jeptr = jedata;
struct JE *jenext;
jedata = NULL;
while (jeptr) {
jenext = jeptr->next;
free(jeptr->buf);
free(jeptr);
jeptr = jenext;
}
}
static char *json_escape(char *str)
{
struct JE *jeptr;
char *buf, *ptr;
/* 2x is the max, may as well just allocate that */
ptr = buf = cgmalloc(strlen(str) * 2 + 1);
jeptr = cgmalloc(sizeof(*jeptr));
jeptr->buf = buf;
jeptr->next = jedata;
jedata = jeptr;
while (*str) {
if (*str == '\\' || *str == '"')
*(ptr++) = '\\';
*(ptr++) = *(str++);
}
*ptr = '\0';
return buf;
}
void write_config(FILE *fcfg)
{
struct opt_table *opt;
int i;
/* Write pool values */
fputs("{\n\"pools\" : [", fcfg);
for(i = 0; i < total_pools; i++) {
struct pool *pool = priority_pool(i);
if (pool->quota != 1) {
fprintf(fcfg, "%s\n\t{\n\t\t\"quota\" : \"%s%s%s%d;%s\",", i > 0 ? "," : "",
pool->rpc_proxy ? json_escape((char *)proxytype(pool->rpc_proxytype)) : "",
pool->rpc_proxy ? json_escape(pool->rpc_proxy) : "",
pool->rpc_proxy ? "|" : "",
pool->quota,
json_escape(pool->rpc_url));
} else {
fprintf(fcfg, "%s\n\t{\n\t\t\"url\" : \"%s%s%s%s\",", i > 0 ? "," : "",
pool->rpc_proxy ? json_escape((char *)proxytype(pool->rpc_proxytype)) : "",
pool->rpc_proxy ? json_escape(pool->rpc_proxy) : "",
pool->rpc_proxy ? "|" : "",
json_escape(pool->rpc_url));
}
#ifdef USE_XTRANONCE
if (pool->extranonce_subscribe)
fputs("\n\t\t\"extranonce-subscribe\" : true,", fcfg);
#endif
fprintf(fcfg, "\n\t\t\"user\" : \"%s\",", json_escape(pool->rpc_user));
fprintf(fcfg, "\n\t\t\"pass\" : \"%s\"\n\t}", json_escape(pool->rpc_pass));
}
fputs("\n]\n", fcfg);
/* Simple bool,int and char options */
for (opt = opt_config_table; opt->type != OPT_END; opt++) {
char *p, *name = strdup(opt->names);
for (p = strtok(name, "|"); p; p = strtok(NULL, "|")) {
if (p[1] != '-')
continue;
if (opt->desc == opt_hidden)
continue;
if (opt->type & OPT_NOARG &&
((void *)opt->cb == (void *)opt_set_bool || (void *)opt->cb == (void *)opt_set_invbool) &&
(*(bool *)opt->u.arg == ((void *)opt->cb == (void *)opt_set_bool))) {
fprintf(fcfg, ",\n\"%s\" : true", p+2);
continue;
}
if (opt->type & OPT_HASARG &&
((void *)opt->cb_arg == (void *)opt_set_intval ||
(void *)opt->cb_arg == (void *)set_int_0_to_9999 ||
(void *)opt->cb_arg == (void *)set_int_0_to_65535 ||
(void *)opt->cb_arg == (void *)set_int_1_to_65535 ||
(void *)opt->cb_arg == (void *)set_int_0_to_5 ||
(void *)opt->cb_arg == (void *)set_int_0_to_10 ||
(void *)opt->cb_arg == (void *)set_int_1_to_10 ||
(void *)opt->cb_arg == (void *)set_int_24_to_32 ||
(void *)opt->cb_arg == (void *)set_int_0_to_100 ||
(void *)opt->cb_arg == (void *)set_int_0_to_255 ||
(void *)opt->cb_arg == (void *)set_int_1_to_255 ||
(void *)opt->cb_arg == (void *)set_int_0_to_7680 ||
(void *)opt->cb_arg == (void *)set_int_0_to_200 ||
(void *)opt->cb_arg == (void *)set_int_0_to_4 ||
(void *)opt->cb_arg == (void *)set_int_32_to_63 ||
(void *)opt->cb_arg == (void *)set_int_22_to_75 ||
#ifdef USE_DRAGONMINT_T1
(void *)opt->cb_arg == (void *)set_int_voltage ||
(void *)opt->cb_arg == (void *)set_int_1_to_31 ||
#endif
#ifdef USE_AVALON4
(void *)opt->cb_arg == (void *)set_int_1_to_60 ||
#endif
(void *)opt->cb_arg == (void *)set_int_42_to_85)) {
fprintf(fcfg, ",\n\"%s\" : \"%d\"", p+2, *(int *)opt->u.arg);
continue;
}
if (opt->type & OPT_HASARG &&
((void *)opt->cb_arg == (void *)set_float_0_to_500 ||
(void *)opt->cb_arg == (void *)set_float_125_to_500 ||
(void *)opt->cb_arg == (void *)set_float_100_to_250 ||
(void *)opt->cb_arg == (void *)set_float_100_to_500)) {
fprintf(fcfg, ",\n\"%s\" : \"%.1f\"", p+2, *(float *)opt->u.arg);
continue;
}
if (opt->type & (OPT_HASARG | OPT_PROCESSARG) &&
(opt->u.arg != &opt_set_null)) {
char *carg = *(char **)opt->u.arg;
if (carg)
fprintf(fcfg, ",\n\"%s\" : \"%s\"", p+2, json_escape(carg));
continue;
}
}
free(name);
}
/* Special case options */
if (pool_strategy == POOL_BALANCE)
fputs(",\n\"balance\" : true", fcfg);
if (pool_strategy == POOL_LOADBALANCE)
fputs(",\n\"load-balance\" : true", fcfg);
if (pool_strategy == POOL_ROUNDROBIN)
fputs(",\n\"round-robin\" : true", fcfg);
if (pool_strategy == POOL_ROTATE)
fprintf(fcfg, ",\n\"rotate\" : \"%d\"", opt_rotate_period);
fputs("\n}\n", fcfg);
json_escape_free();
}
void zero_bestshare(void)
{
int i;
best_diff = 0;
memset(best_share, 0, 8);
suffix_string(best_diff, best_share, sizeof(best_share), 0);
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
pool->best_diff = 0;
}
}
static struct timeval tv_hashmeter;
static time_t hashdisplay_t;
void zero_stats(void)
{
int i;
#ifdef USE_BITMAIN_SOC
struct sysinfo sInfo;
if (sysinfo(&sInfo))
{
applog(LOG_INFO, "Failed to get sysinfo, errno:%u, reason:%s\n",
errno, strerror(errno));
total_tv_start_sys=time(NULL);
}
else
{
total_tv_start_sys=sInfo.uptime;
}
#endif
cgtime(&total_tv_start);
copy_time(&tv_hashmeter, &total_tv_start);
total_rolling = 0;
rolling1 = 0;
rolling5 = 0;
rolling15 = 0;
total_mhashes_done = 0;
#ifdef USE_BITMAIN_SOC
new_total_mhashes_done = 0;
#endif
total_getworks = 0;
total_accepted = 0;
total_rejected = 0;
hw_errors = 0;
total_stale = 0;
total_discarded = 0;
local_work = 0;
total_go = 0;
total_ro = 0;
total_secs = 1.0;
#ifdef USE_BITMAIN_SOC
new_total_secs = 1.0;
#endif
total_diff1 = 0;
found_blocks = 0;
total_diff_accepted = 0;
total_diff_rejected = 0;
total_diff_stale = 0;
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
pool->getwork_requested = 0;
pool->accepted = 0;
pool->rejected = 0;
pool->stale_shares = 0;
pool->discarded_work = 0;
pool->getfail_occasions = 0;
pool->remotefail_occasions = 0;
pool->last_share_time = 0;
pool->diff1 = 0;
pool->diff_accepted = 0;
pool->diff_rejected = 0;
pool->diff_stale = 0;
pool->last_share_diff = 0;
}
zero_bestshare();
for (i = 0; i < total_devices; ++i) {
struct cgpu_info *cgpu = get_devices(i);
copy_time(&cgpu->dev_start_tv, &total_tv_start);
mutex_lock(&hash_lock);
cgpu->total_mhashes = 0;
cgpu->accepted = 0;
cgpu->rejected = 0;
cgpu->hw_errors = 0;
cgpu->utility = 0.0;
cgpu->last_share_pool_time = 0;
cgpu->diff1 = 0;
cgpu->diff_accepted = 0;
cgpu->diff_rejected = 0;
cgpu->last_share_diff = 0;
mutex_unlock(&hash_lock);
/* Don't take any locks in the driver zero stats function, as
* it's called async from everything else and we don't want to
* deadlock. */
cgpu->drv->zero_stats(cgpu);
}
}
static void __maybe_unused set_highprio(void)
{
#ifndef WIN32
int ret = nice(-10);
if (!ret)
applog(LOG_DEBUG, "Unable to set thread to high priority");
#else
SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_HIGHEST);
#endif
}
static void __maybe_unused set_lowprio(void)
{
#ifndef WIN32
int ret = nice(10);
if (!ret)
applog(LOG_INFO, "Unable to set thread to low priority");
#else
SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_LOWEST);
#endif
}
#ifdef HAVE_CURSES
static void display_pools(void)
{
struct pool *pool;
int selected, i;
char input;
opt_loginput = true;
immedok(logwin, true);
clear_logwin();
updated:
for (i = 0; i < total_pools; i++) {
pool = pools[i];
if (pool == current_pool())
wattron(logwin, A_BOLD);
if (pool->enabled != POOL_ENABLED)
wattron(logwin, A_DIM);
wlogprint("%d: ", pool->pool_no);
switch (pool->enabled) {
case POOL_ENABLED:
wlogprint("Enabled ");
break;
case POOL_DISABLED:
wlogprint("Disabled ");
break;
case POOL_REJECTING:
wlogprint("Rejecting ");
break;
}
wlogprint("%s Quota %d Prio %d: %s User:%s\n",
pool->idle? "Dead" : "Alive",
pool->quota,
pool->prio,
pool->rpc_url, pool->rpc_user);
wattroff(logwin, A_BOLD | A_DIM);
}
retry:
wlogprint("\nCurrent pool management strategy: %s\n",
strategies[pool_strategy].s);
if (pool_strategy == POOL_ROTATE)
wlogprint("Set to rotate every %d minutes\n", opt_rotate_period);
wlogprint("Pool [A]dd [R]emove [D]isable [E]nable [Q]uota change\n");
wlogprint("[C]hange management strategy [S]witch pool [I]nformation\n");
wlogprint("Or press any other key to continue\n");
logwin_update();
input = getch();
if (!strncasecmp(&input, "a", 1)) {
input_pool(true);
goto updated;
} else if (!strncasecmp(&input, "r", 1)) {
if (total_pools <= 1) {
wlogprint("Cannot remove last pool");
goto retry;
}
selected = curses_int("Select pool number");
if (selected < 0 || selected >= total_pools) {
wlogprint("Invalid selection\n");
goto retry;
}
pool = pools[selected];
if (pool == current_pool())
switch_pools(NULL);
if (pool == current_pool()) {
wlogprint("Unable to remove pool due to activity\n");
goto retry;
}
disable_pool(pool);
remove_pool(pool);
goto updated;
} else if (!strncasecmp(&input, "s", 1)) {
selected = curses_int("Select pool number");
if (selected < 0 || selected >= total_pools) {
wlogprint("Invalid selection\n");
goto retry;
}
pool = pools[selected];
enable_pool(pool);
switch_pools(pool);
goto updated;
} else if (!strncasecmp(&input, "d", 1)) {
if (enabled_pools <= 1) {
wlogprint("Cannot disable last pool");
goto retry;
}
selected = curses_int("Select pool number");
if (selected < 0 || selected >= total_pools) {
wlogprint("Invalid selection\n");
goto retry;
}
pool = pools[selected];
disable_pool(pool);
if (pool == current_pool())
switch_pools(NULL);
goto updated;
} else if (!strncasecmp(&input, "e", 1)) {
selected = curses_int("Select pool number");
if (selected < 0 || selected >= total_pools) {
wlogprint("Invalid selection\n");
goto retry;
}
pool = pools[selected];
enable_pool(pool);
if (pool->prio < current_pool()->prio)
switch_pools(pool);
goto updated;
} else if (!strncasecmp(&input, "c", 1)) {
for (i = 0; i <= TOP_STRATEGY; i++)
wlogprint("%d: %s\n", i, strategies[i].s);
selected = curses_int("Select strategy number type");
if (selected < 0 || selected > TOP_STRATEGY) {
wlogprint("Invalid selection\n");
goto retry;
}
if (selected == POOL_ROTATE) {
opt_rotate_period = curses_int("Select interval in minutes");
if (opt_rotate_period < 0 || opt_rotate_period > 9999) {
opt_rotate_period = 0;
wlogprint("Invalid selection\n");
goto retry;
}
}
pool_strategy = selected;
switch_pools(NULL);
goto updated;
} else if (!strncasecmp(&input, "i", 1)) {
selected = curses_int("Select pool number");
if (selected < 0 || selected >= total_pools) {
wlogprint("Invalid selection\n");
goto retry;
}
pool = pools[selected];
display_pool_summary(pool);
goto retry;
} else if (!strncasecmp(&input, "q", 1)) {
selected = curses_int("Select pool number");
if (selected < 0 || selected >= total_pools) {
wlogprint("Invalid selection\n");
goto retry;
}
pool = pools[selected];
selected = curses_int("Set quota");
if (selected < 0) {
wlogprint("Invalid negative quota\n");
goto retry;
}
pool->quota = selected;
adjust_quota_gcd();
goto updated;
} else
clear_logwin();
immedok(logwin, false);
opt_loginput = false;
}
static void display_options(void)
{
int selected;
char input;
opt_loginput = true;
immedok(logwin, true);
clear_logwin();
retry:
wlogprint("[N]ormal [C]lear [S]ilent mode (disable all output)\n");
wlogprint("[D]ebug:%s\n[P]er-device:%s\n[Q]uiet:%s\n[V]erbose:%s\n"
"[R]PC debug:%s\n[W]orkTime details:%s\nco[M]pact: %s\n"
"[T]oggle status switching:%s\n"
"w[I]descreen:%s\n"
"[Z]ero statistics\n"
"[L]og interval:%d\n",
opt_debug ? "on" : "off",
want_per_device_stats? "on" : "off",
opt_quiet ? "on" : "off",
opt_log_output ? "on" : "off",
opt_protocol ? "on" : "off",
opt_worktime ? "on" : "off",
opt_compact ? "on" : "off",
switch_status ? "enabled" : "disabled",
opt_widescreen ? "enabled" : "disabled",
opt_log_interval);
wlogprint("Select an option or any other key to return\n");
logwin_update();
input = getch();
if (!strncasecmp(&input, "q", 1)) {
opt_quiet ^= true;
wlogprint("Quiet mode %s\n", opt_quiet ? "enabled" : "disabled");
goto retry;
} else if (!strncasecmp(&input, "v", 1)) {
opt_log_output ^= true;
if (opt_log_output)
opt_quiet = false;
wlogprint("Verbose mode %s\n", opt_log_output ? "enabled" : "disabled");
goto retry;
} else if (!strncasecmp(&input, "n", 1)) {
opt_log_output = false;
opt_debug = false;
opt_quiet = false;
opt_protocol = false;
opt_compact = false;
want_per_device_stats = false;
wlogprint("Output mode reset to normal\n");
switch_logsize(false);
goto retry;
} else if (!strncasecmp(&input, "d", 1)) {
opt_debug ^= true;
opt_log_output = opt_debug;
if (opt_debug)
opt_quiet = false;
wlogprint("Debug mode %s\n", opt_debug ? "enabled" : "disabled");
goto retry;
} else if (!strncasecmp(&input, "m", 1)) {
opt_compact ^= true;
wlogprint("Compact mode %s\n", opt_compact ? "enabled" : "disabled");
switch_logsize(false);
goto retry;
} else if (!strncasecmp(&input, "p", 1)) {
want_per_device_stats ^= true;
opt_log_output = want_per_device_stats;
wlogprint("Per-device stats %s\n", want_per_device_stats ? "enabled" : "disabled");
goto retry;
} else if (!strncasecmp(&input, "r", 1)) {
opt_protocol ^= true;
if (opt_protocol)
opt_quiet = false;
wlogprint("RPC protocol debugging %s\n", opt_protocol ? "enabled" : "disabled");
goto retry;
} else if (!strncasecmp(&input, "c", 1))
clear_logwin();
else if (!strncasecmp(&input, "l", 1)) {
selected = curses_int("Interval in seconds");
if (selected < 0 || selected > 9999) {
wlogprint("Invalid selection\n");
goto retry;
}
opt_log_interval = selected;
wlogprint("Log interval set to %d seconds\n", opt_log_interval);
goto retry;
} else if (!strncasecmp(&input, "s", 1)) {
opt_realquiet = true;
} else if (!strncasecmp(&input, "w", 1)) {
opt_worktime ^= true;
wlogprint("WorkTime details %s\n", opt_worktime ? "enabled" : "disabled");
goto retry;
} else if (!strncasecmp(&input, "t", 1)) {
switch_status ^= true;
goto retry;
} else if (!strncasecmp(&input, "i", 1)) {
opt_widescreen ^= true;
goto retry;
} else if (!strncasecmp(&input, "z", 1)) {
zero_stats();
goto retry;
} else
clear_logwin();
immedok(logwin, false);
opt_loginput = false;
}
#endif
void default_save_file(char *filename)
{
if (default_config && *default_config) {
strcpy(filename, default_config);
return;
}
#if defined(unix) || defined(__APPLE__)
if (getenv("HOME") && *getenv("HOME")) {
strcpy(filename, getenv("HOME"));
strcat(filename, "/");
}
else
strcpy(filename, "");
strcat(filename, ".cgminer/");
mkdir(filename, 0777);
#else
strcpy(filename, "");
#endif
strcat(filename, def_conf);
}
#ifdef HAVE_CURSES
static void set_options(void)
{
char input;
opt_loginput = true;
immedok(logwin, true);
clear_logwin();
retry:
wlogprint("[W]rite config file\n[C]gminer restart\n");
wlogprint("Select an option or any other key to return\n");
logwin_update();
input = getch();
if (!strncasecmp(&input, "w", 1)) {
FILE *fcfg;
char *str, filename[PATH_MAX], prompt[PATH_MAX + 50];
default_save_file(filename);
snprintf(prompt, sizeof(prompt), "Config filename to write (Enter for default) [%s]", filename);
str = curses_input(prompt);
if (strcmp(str, "-1")) {
struct stat statbuf;
strcpy(filename, str);
free(str);
if (!stat(filename, &statbuf)) {
wlogprint("File exists, overwrite?\n");
input = getch();
if (strncasecmp(&input, "y", 1))
goto retry;
}
}
else
free(str);
fcfg = fopen(filename, "w");
if (!fcfg) {
wlogprint("Cannot open or create file\n");
goto retry;
}
write_config(fcfg);
fclose(fcfg);
goto retry;
} else if (!strncasecmp(&input, "c", 1)) {
wlogprint("Are you sure?\n");
input = getch();
if (!strncasecmp(&input, "y", 1))
app_restart();
else
clear_logwin();
} else
clear_logwin();
immedok(logwin, false);
opt_loginput = false;
}
#ifdef USE_USBUTILS
static void mt_enable(struct thr_info *mythr)
{
cgsem_post(&mythr->sem);
}
static void set_usb(void)
{
int selected, i, mt, enabled, disabled, zombie, total, blacklisted;
struct cgpu_info *cgpu;
struct thr_info *thr;
double val;
char input;
opt_loginput = true;
immedok(logwin, true);
clear_logwin();
retry:
enabled = 0;
disabled = 0;
zombie = 0;
total = 0;
blacklisted = 0;
rd_lock(&mining_thr_lock);
mt = mining_threads;
rd_unlock(&mining_thr_lock);
for (i = 0; i < mt; i++) {
cgpu = mining_thr[i]->cgpu;
if (unlikely(!cgpu))
continue;
if (cgpu->usbinfo.nodev)
zombie++;
else if (cgpu->deven == DEV_DISABLED)
disabled++;
else
enabled++;
if (cgpu->blacklisted)
blacklisted++;
total++;
}
wlogprint("Hotplug interval:%d\n", hotplug_time);
wlogprint("%d USB devices, %d enabled, %d disabled, %d zombie\n",
total, enabled, disabled, zombie);
wlogprint("[S]ummary of device information\n");
wlogprint("[E]nable device\n");
wlogprint("[D]isable device\n");
wlogprint("[U]nplug to allow hotplug restart\n");
wlogprint("[R]eset device USB\n");
wlogprint("[L]ist all known devices\n");
wlogprint("[B]lacklist current device from current instance of cgminer\n");
wlogprint("[W]hitelist previously blacklisted device\n");
wlogprint("[H]otplug interval (0 to disable)\n");
wlogprint("Select an option or any other key to return\n");
logwin_update();
input = getch();
if (!strncasecmp(&input, "s", 1)) {
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
wlogprint("Device %03u:%03u\n", cgpu->usbinfo.bus_number, cgpu->usbinfo.device_address);
wlogprint("Name %s\n", cgpu->drv->name);
wlogprint("ID %d\n", cgpu->device_id);
wlogprint("Enabled: %s\n", cgpu->deven != DEV_DISABLED ? "Yes" : "No");
wlogprint("Temperature %.1f\n", cgpu->temp);
wlogprint("MHS av %.0f\n", cgpu->total_mhashes / cgpu_runtime(cgpu));
wlogprint("Accepted %d\n", cgpu->accepted);
wlogprint("Rejected %d\n", cgpu->rejected);
wlogprint("Hardware Errors %d\n", cgpu->hw_errors);
wlogprint("Last Share Pool %d\n", cgpu->last_share_pool_time > 0 ? cgpu->last_share_pool : -1);
wlogprint("Total MH %.1f\n", cgpu->total_mhashes);
wlogprint("Diff1 Work %"PRId64"\n", cgpu->diff1);
wlogprint("Difficulty Accepted %.1f\n", cgpu->diff_accepted);
wlogprint("Difficulty Rejected %.1f\n", cgpu->diff_rejected);
wlogprint("Last Share Difficulty %.1f\n", cgpu->last_share_diff);
wlogprint("No Device: %s\n", cgpu->usbinfo.nodev ? "True" : "False");
wlogprint("Last Valid Work %"PRIu64"\n", (uint64_t)cgpu->last_device_valid_work);
val = 0;
if (cgpu->hw_errors + cgpu->diff1)
val = cgpu->hw_errors / (cgpu->hw_errors + cgpu->diff1);
wlogprint("Device Hardware %.1f%%\n", val);
val = 0;
if (cgpu->diff1)
val = cgpu->diff_rejected / cgpu->diff1;
wlogprint("Device Rejected %.1f%%\n", val);
goto retry;
} else if (!strncasecmp(&input, "e", 1)) {
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
if (cgpu->usbinfo.nodev) {
wlogprint("Device removed, unable to re-enable!\n");
goto retry;
}
thr = get_thread(selected);
cgpu->deven = DEV_ENABLED;
mt_enable(thr);
goto retry;
} else if (!strncasecmp(&input, "d", 1)) {
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
cgpu->deven = DEV_DISABLED;
goto retry;
} else if (!strncasecmp(&input, "u", 1)) {
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
if (cgpu->usbinfo.nodev) {
wlogprint("Device already removed, unable to unplug!\n");
goto retry;
}
usb_nodev(cgpu);
goto retry;
} else if (!strncasecmp(&input, "r", 1)) {
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
if (cgpu->usbinfo.nodev) {
wlogprint("Device already removed, unable to reset!\n");
goto retry;
}
usb_reset(cgpu);
goto retry;
} else if (!strncasecmp(&input, "b", 1)) {
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
if (cgpu->usbinfo.nodev) {
wlogprint("Device already removed, unable to blacklist!\n");
goto retry;
}
blacklist_cgpu(cgpu);
goto retry;
} else if (!strncasecmp(&input, "w", 1)) {
if (!blacklisted) {
wlogprint("No blacklisted devices!\n");
goto retry;
}
wlogprint("Blacklisted devices:\n");
for (i = 0; i < mt; i++) {
cgpu = mining_thr[i]->cgpu;
if (unlikely(!cgpu))
continue;
if (cgpu->blacklisted) {
wlogprint("%d: %s %d %03u:%03u\n", i, cgpu->drv->name,
cgpu->device_id, cgpu->usbinfo.bus_number,
cgpu->usbinfo.device_address);
}
}
selected = curses_int("Select device number");
if (selected < 0 || selected >= mt) {
wlogprint("Invalid selection\n");
goto retry;
}
cgpu = mining_thr[selected]->cgpu;
if (!cgpu->blacklisted) {
wlogprint("Device not blacklisted, unable to whitelist\n");
goto retry;
}
whitelist_cgpu(cgpu);
goto retry;
} else if (!strncasecmp(&input, "h", 1)) {
selected = curses_int("Select hotplug interval in seconds (0 to disable)");
if (selected < 0 || selected > 9999) {
wlogprint("Invalid value\n");
goto retry;
}
hotplug_time = selected;
goto retry;
} else if (!strncasecmp(&input, "l", 1)) {
usb_list();
goto retry;
} else
clear_logwin();
immedok(logwin, false);
opt_loginput = false;
}
#endif
static void *input_thread(void __maybe_unused *userdata)
{
pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
RenameThread("Input");
if (!curses_active)
return NULL;
while (1) {
char input;
input = getch();
if (!strncasecmp(&input, "q", 1)) {
kill_work();
return NULL;
} else if (!strncasecmp(&input, "d", 1))
display_options();
else if (!strncasecmp(&input, "p", 1))
display_pools();
else if (!strncasecmp(&input, "s", 1))
set_options();
#ifdef USE_USBUTILS
else if (!strncasecmp(&input, "u", 1))
set_usb();
#endif
if (opt_realquiet) {
disable_curses();
break;
}
}
return NULL;
}
#endif
static void *api_thread(void *userdata)
{
struct thr_info *mythr = userdata;
pthread_detach(pthread_self());
pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
RenameThread("API");
set_lowprio();
api(api_thr_id);
PTH(mythr) = 0L;
return NULL;
}
/* Sole work devices are serialised wrt calling get_work so they report in on
* each pass through their scanhash function as well as in get_work whereas
* queued work devices work asynchronously so get them to report in and out
* only across get_work. */
static void thread_reportin(struct thr_info *thr)
{
thr->getwork = false;
cgtime(&thr->last);
thr->cgpu->status = LIFE_WELL;
thr->cgpu->device_last_well = time(NULL);
}
/* Tell the watchdog thread this thread is waiting on get work and should not
* be restarted */
static void thread_reportout(struct thr_info *thr)
{
thr->getwork = true;
cgtime(&thr->last);
thr->cgpu->status = LIFE_WELL;
thr->cgpu->device_last_well = time(NULL);
}
static void hashmeter(int thr_id, uint64_t hashes_done)
{
bool showlog = false;
double tv_tdiff;
time_t now_t;
int diff_t;
#ifdef USE_BITMAIN_SOC
struct sysinfo sInfo;
if (sysinfo(&sInfo))
{
applog(LOG_INFO, "Failed to get sysinfo, errno:%u, reason:%s\n",
errno, strerror(errno));
total_tv_end_sys=time(NULL);
}
else
{
total_tv_end_sys=sInfo.uptime;
}
#endif
cgtime(&total_tv_end);
tv_tdiff = tdiff(&total_tv_end, &tv_hashmeter);
now_t = total_tv_end.tv_sec;
diff_t = now_t - hashdisplay_t;
if (diff_t >= opt_log_interval) {
alt_status ^= switch_status;
hashdisplay_t = now_t;
showlog = true;
} else if (thr_id < 0) {
/* hashmeter is called by non-mining threads in case nothing
* has reported in to allow hashrate to converge to zero , but
* we only update if it has been more than opt_log_interval */
return;
}
copy_time(&tv_hashmeter, &total_tv_end);
if (thr_id >= 0) {
struct thr_info *thr = get_thread(thr_id);
struct cgpu_info *cgpu = thr->cgpu;
double device_tdiff, thr_mhs;
/* Update the last time this thread reported in */
copy_time(&thr->last, &total_tv_end);
cgpu->device_last_well = now_t;
device_tdiff = tdiff(&total_tv_end, &cgpu->last_message_tv);
copy_time(&cgpu->last_message_tv, &total_tv_end);
thr_mhs = (double)hashes_done / device_tdiff / 1000000;
applog(LOG_DEBUG, "[thread %d: %"PRIu64" hashes, %.1f mhash/sec]",
thr_id, hashes_done, thr_mhs);
hashes_done /= 1000000;
mutex_lock(&hash_lock);
cgpu->total_mhashes += hashes_done;
decay_time(&cgpu->rolling, hashes_done, device_tdiff, opt_log_interval);
decay_time(&cgpu->rolling1, hashes_done, device_tdiff, 60.0);
decay_time(&cgpu->rolling5, hashes_done, device_tdiff, 300.0);
decay_time(&cgpu->rolling15, hashes_done, device_tdiff, 900.0);
mutex_unlock(&hash_lock);
if (want_per_device_stats && showlog) {
char logline[256];
get_statline(logline, sizeof(logline), cgpu);
if (!curses_active) {
printf("%s \r", logline);
fflush(stdout);
} else
applog(LOG_INFO, "%s", logline);
}
} else {
/* No device has reported in, we have been called from the
* watchdog thread so decay all the hashrates */
mutex_lock(&hash_lock);
for (thr_id = 0; thr_id < mining_threads; thr_id++) {
struct thr_info *thr = get_thread(thr_id);
struct cgpu_info *cgpu = thr->cgpu;
double device_tdiff = tdiff(&total_tv_end, &cgpu->last_message_tv);
copy_time(&cgpu->last_message_tv, &total_tv_end);
decay_time(&cgpu->rolling, 0, device_tdiff, opt_log_interval);
decay_time(&cgpu->rolling1, 0, device_tdiff, 60.0);
decay_time(&cgpu->rolling5, 0, device_tdiff, 300.0);
decay_time(&cgpu->rolling15, 0, device_tdiff, 900.0);
}
mutex_unlock(&hash_lock);
}
mutex_lock(&hash_lock);
total_mhashes_done += hashes_done;
decay_time(&total_rolling, hashes_done, tv_tdiff, opt_log_interval);
decay_time(&rolling1, hashes_done, tv_tdiff, 60.0);
decay_time(&rolling5, hashes_done, tv_tdiff, 300.0);
decay_time(&rolling15, hashes_done, tv_tdiff, 900.0);
global_hashrate = llround(total_rolling) * 1000000;
#ifndef USE_BITMAIN_SOC
total_secs = tdiff(&total_tv_end, &total_tv_start);
#else
total_secs = total_tv_end_sys*1.0-total_tv_start_sys*1.0;
#endif
if (showlog) {
char displayed_hashes[16], displayed_rolling[16];
char displayed_r1[16], displayed_r5[16], displayed_r15[16];
uint64_t d64;
d64 = (double)total_mhashes_done / total_secs * 1000000ull;
suffix_string(d64, displayed_hashes, sizeof(displayed_hashes), 4);
d64 = (double)total_rolling * 1000000ull;
suffix_string(d64, displayed_rolling, sizeof(displayed_rolling), 4);
d64 = (double)rolling1 * 1000000ull;
suffix_string(d64, displayed_r1, sizeof(displayed_rolling), 4);
d64 = (double)rolling5 * 1000000ull;
suffix_string(d64, displayed_r5, sizeof(displayed_rolling), 4);
d64 = (double)rolling15 * 1000000ull;
suffix_string(d64, displayed_r15, sizeof(displayed_rolling), 4);
snprintf(statusline, sizeof(statusline),
"(%ds):%s (1m):%s (5m):%s (15m):%s (avg):%sh/s",
opt_log_interval, displayed_rolling, displayed_r1, displayed_r5,
displayed_r15, displayed_hashes);
}
mutex_unlock(&hash_lock);
#ifdef USE_LIBSYSTEMD
sd_notifyf(false, "STATUS=%s", statusline);
#endif
if (showlog) {
if (!curses_active) {
printf("%s \r", statusline);
fflush(stdout);
} else
applog(LOG_INFO, "%s", statusline);
}
}
static void stratum_share_result(json_t *val, json_t *res_val, json_t *err_val,
struct stratum_share *sshare)
{
struct work *work = sshare->work;
time_t now_t = time(NULL);
char hashshow[64];
int srdiff;
srdiff = now_t - sshare->sshare_sent;
if (opt_debug || srdiff > 0) {
applog(LOG_INFO, "Pool %d stratum share result lag time %d seconds",
work->pool->pool_no, srdiff);
}
show_hash(work, hashshow);
share_result(val, res_val, err_val, work, hashshow, false, "");
}
/* Parses stratum json responses and tries to find the id that the request
* matched to and treat it accordingly. */
static bool parse_stratum_response(struct pool *pool, char *s)
{
json_t *val = NULL, *err_val, *res_val, *id_val;
struct stratum_share *sshare;
json_error_t err;
bool ret = false;
int id;
val = JSON_LOADS(s, &err);
if (!val) {
applog(LOG_INFO, "JSON decode failed(%d): %s", err.line, err.text);
goto out;
}
res_val = json_object_get(val, "result");
err_val = json_object_get(val, "error");
id_val = json_object_get(val, "id");
if (json_is_null(id_val) || !id_val) {
char *ss;
if (err_val)
ss = json_dumps(err_val, JSON_INDENT(3));
else
ss = strdup("(unknown reason)");
applog(LOG_INFO, "JSON-RPC non method decode failed: %s", ss);
free(ss);
goto out;
}
id = json_integer_value(id_val);
mutex_lock(&sshare_lock);
HASH_FIND_INT(stratum_shares, &id, sshare);
if (sshare) {
HASH_DEL(stratum_shares, sshare);
pool->sshares--;
}
mutex_unlock(&sshare_lock);
if (!sshare) {
double pool_diff;
if (!res_val)
goto out;
/* Since the share is untracked, we can only guess at what the
* work difficulty is based on the current pool diff. */
cg_rlock(&pool->data_lock);
pool_diff = pool->sdiff;
cg_runlock(&pool->data_lock);
if (json_is_true(res_val)) {
applog(LOG_NOTICE, "Accepted untracked stratum share from pool %d", pool->pool_no);
/* We don't know what device this came from so we can't
* attribute the work to the relevant cgpu */
mutex_lock(&stats_lock);
total_accepted++;
pool->accepted++;
total_diff_accepted += pool_diff;
pool->diff_accepted += pool_diff;
mutex_unlock(&stats_lock);
} else {
applog(LOG_NOTICE, "Rejected untracked stratum share from pool %d", pool->pool_no);
mutex_lock(&stats_lock);
total_rejected++;
pool->rejected++;
total_diff_rejected += pool_diff;
pool->diff_rejected += pool_diff;
mutex_unlock(&stats_lock);
}
goto out;
}
stratum_share_result(val, res_val, err_val, sshare);
free_work(sshare->work);
free(sshare);
ret = true;
out:
if (val)
json_decref(val);
return ret;
}
void clear_stratum_shares(struct pool *pool)
{
struct stratum_share *sshare, *tmpshare;
double diff_cleared = 0;
int cleared = 0;
mutex_lock(&sshare_lock);
HASH_ITER(hh, stratum_shares, sshare, tmpshare) {
if (sshare->work->pool == pool) {
HASH_DEL(stratum_shares, sshare);
diff_cleared += sshare->work->work_difficulty;
free_work(sshare->work);
pool->sshares--;
free(sshare);
cleared++;
}
}
mutex_unlock(&sshare_lock);
if (cleared) {
applog(LOG_WARNING, "Lost %d shares due to stratum disconnect on pool %d", cleared, pool->pool_no);
pool->stale_shares += cleared;
total_stale += cleared;
pool->diff_stale += diff_cleared;
total_diff_stale += diff_cleared;
}
}
void clear_pool_work(struct pool *pool)
{
struct work *work, *tmp;
int cleared = 0;
mutex_lock(stgd_lock);
HASH_ITER(hh, staged_work, work, tmp) {
if (work->pool == pool) {
HASH_DEL(staged_work, work);
free_work(work);
cleared++;
}
}
mutex_unlock(stgd_lock);
if (cleared)
applog(LOG_INFO, "Cleared %d work items due to stratum disconnect on pool %d", cleared, pool->pool_no);
}
static int cp_prio(void)
{
int prio;
cg_rlock(&control_lock);
prio = currentpool->prio;
cg_runlock(&control_lock);
return prio;
}
/* We only need to maintain a secondary pool connection when we need the
* capacity to get work from the backup pools while still on the primary */
static bool cnx_needed(struct pool *pool)
{
struct pool *cp;
if (pool->enabled != POOL_ENABLED)
return false;
/* Balance strategies need all pools online */
if (pool_strategy == POOL_BALANCE)
return true;
if (pool_strategy == POOL_LOADBALANCE)
return true;
/* Idle stratum pool needs something to kick it alive again */
if (pool->has_stratum && pool->idle)
return true;
cp = current_pool();
if (cp == pool)
return true;
/* If we're waiting for a response from shares submitted, keep the
* connection open. */
if (pool->sshares)
return true;
/* If the pool has only just come to life and is higher priority than
* the current pool keep the connection open so we can fail back to
* it. */
if (pool_strategy == POOL_FAILOVER && pool->prio < cp_prio())
return true;
/* We've run out of work, bring anything back to life. */
if (no_work)
return true;
return false;
}
static void wait_lpcurrent(struct pool *pool);
static void pool_resus(struct pool *pool);
static void gen_stratum_work(struct pool *pool, struct work *work);
void stratum_resumed(struct pool *pool)
{
if (pool_tclear(pool, &pool->idle)) {
applog(LOG_INFO, "Stratum connection to pool %d resumed", pool->pool_no);
pool_resus(pool);
}
}
static bool supports_resume(struct pool *pool)
{
bool ret;
cg_rlock(&pool->data_lock);
ret = (pool->sessionid != NULL);
cg_runlock(&pool->data_lock);
return ret;
}
/* One stratum receive thread per pool that has stratum waits on the socket
* checking for new messages and for the integrity of the socket connection. We
* reset the connection based on the integrity of the receive side only as the
* send side will eventually expire data it fails to send. */
static void *stratum_rthread(void *userdata)
{
struct pool *pool = (struct pool *)userdata;
char threadname[16];
pthread_detach(pthread_self());
snprintf(threadname, sizeof(threadname), "%d/RStratum", pool->pool_no);
RenameThread(threadname);
while (42) {
struct timeval timeout;
int sel_ret;
fd_set rd;
char *s;
if (unlikely(pool->removed)) {
suspend_stratum(pool);
break;
}
/* Check to see whether we need to maintain this connection
* indefinitely or just bring it up when we switch to this
* pool */
if (!sock_full(pool) && !cnx_needed(pool)) {
suspend_stratum(pool);
clear_stratum_shares(pool);
clear_pool_work(pool);
wait_lpcurrent(pool);
while (!restart_stratum(pool)) {
pool_died(pool);
if (pool->removed)
goto out;
cgsleep_ms(5000);
}
}
FD_ZERO(&rd);
FD_SET(pool->sock, &rd);
timeout.tv_sec = 90;
timeout.tv_usec = 0;
/* The protocol specifies that notify messages should be sent
* every minute so if we fail to receive any for 90 seconds we
* assume the connection has been dropped and treat this pool
* as dead */
if (!sock_full(pool) && (sel_ret = select(pool->sock + 1, &rd, NULL, NULL, &timeout)) < 1) {
applog(LOG_DEBUG, "Stratum select failed on pool %d with value %d", pool->pool_no, sel_ret);
s = NULL;
} else
s = recv_line(pool);
if (!s) {
applog(LOG_NOTICE, "Stratum connection to pool %d interrupted", pool->pool_no);
pool->getfail_occasions++;
total_go++;
/* If the socket to our stratum pool disconnects, all
* tracked submitted shares are lost and we will leak
* the memory if we don't discard their records. */
if (!supports_resume(pool) || opt_lowmem)
clear_stratum_shares(pool);
clear_pool_work(pool);
if (pool == current_pool())
restart_threads();
while (!restart_stratum(pool)) {
pool_died(pool);
if (pool->removed)
goto out;
cgsleep_ms(5000);
}
continue;
}
/* Check this pool hasn't died while being a backup pool and
* has not had its idle flag cleared */
stratum_resumed(pool);
if (!parse_method(pool, s) && !parse_stratum_response(pool, s))
applog(LOG_INFO, "Unknown stratum msg: %s", s);
else if (pool->swork.clean) {
struct work *work = make_work();
/* Generate a single work item to update the current
* block database */
gen_stratum_work(pool, work);
/* Return value doesn't matter. We're just informing
* that we may need to restart. */
test_work_current(work);
free_work(work);
}
free(s);
}
out:
return NULL;
}
/* Each pool has one stratum send thread for sending shares to avoid many
* threads being created for submission since all sends need to be serialised
* anyway. */
static void *stratum_sthread(void *userdata)
{
struct pool *pool = (struct pool *)userdata;
uint64_t last_nonce2 = 0;
uint32_t last_nonce = 0;
char threadname[16];
pthread_detach(pthread_self());
snprintf(threadname, sizeof(threadname), "%d/SStratum", pool->pool_no);
RenameThread(threadname);
pool->stratum_q = tq_new();
if (!pool->stratum_q)
quit(1, "Failed to create stratum_q in stratum_sthread");
while (42) {
char noncehex[12], nonce2hex[20], s[1024];
struct stratum_share *sshare;
uint32_t *hash32, nonce;
unsigned char nonce2[8];
uint64_t *nonce2_64;
struct work *work;
bool submitted;
if (unlikely(pool->removed))
break;
#if defined (USE_AVALON2) || defined (USE_AVALON4) || defined (USE_AVALON7) || defined (USE_AVALON8) || defined (USE_AVALON9) || defined (USE_AVALON_MINER) || defined (USE_HASHRATIO)
work = tq_pop(pool->stratum_q, NULL);
#else
work = tq_pop(pool->stratum_q);
#endif
if (unlikely(!work))
quit(1, "Stratum q returned empty work");
if (unlikely(work->nonce2_len > 8)) {
applog(LOG_ERR, "Pool %d asking for inappropriately long nonce2 length %d",
pool->pool_no, (int)work->nonce2_len);
applog(LOG_ERR, "Not attempting to submit shares");
free_work(work);
continue;
}
nonce = *((uint32_t *)(work->data + 76));
nonce2_64 = (uint64_t *)nonce2;
*nonce2_64 = htole64(work->nonce2);
/* Filter out duplicate shares */
if (unlikely(nonce == last_nonce && *nonce2_64 == last_nonce2)) {
applog(LOG_INFO, "Filtering duplicate share to pool %d",
pool->pool_no);
free_work(work);
continue;
}
last_nonce = nonce;
last_nonce2 = *nonce2_64;
__bin2hex(noncehex, (const unsigned char *)&nonce, 4);
__bin2hex(nonce2hex, nonce2, work->nonce2_len);
sshare = cgcalloc(sizeof(struct stratum_share), 1);
hash32 = (uint32_t *)work->hash;
submitted = false;
sshare->sshare_time = time(NULL);
/* This work item is freed in parse_stratum_response */
sshare->work = work;
memset(s, 0, 1024);
mutex_lock(&sshare_lock);
/* Give the stratum share a unique id */
sshare->id = swork_id++;
mutex_unlock(&sshare_lock);
if (pool->vmask) {
snprintf(s, sizeof(s),
"{\"params\": [\"%s\", \"%s\", \"%s\", \"%s\", \"%s\", \"%s\"], \"id\": %d, \"method\": \"mining.submit\"}",
pool->rpc_user, work->job_id, nonce2hex, work->ntime, noncehex, pool->vmask_002[work->micro_job_id], sshare->id);
} else {
snprintf(s, sizeof(s),
"{\"params\": [\"%s\", \"%s\", \"%s\", \"%s\", \"%s\"], \"id\": %d, \"method\": \"mining.submit\"}",
pool->rpc_user, work->job_id, nonce2hex, work->ntime, noncehex, sshare->id);
}
applog(LOG_INFO, "Submitting share %08lx to pool %d",
(long unsigned int)htole32(hash32[6]), pool->pool_no);
/* Try resubmitting for up to 2 minutes if we fail to submit
* once and the stratum pool nonce1 still matches suggesting
* we may be able to resume. */
while (time(NULL) < sshare->sshare_time + 120) {
bool sessionid_match;
if (likely(stratum_send(pool, s, strlen(s)))) {
mutex_lock(&sshare_lock);
HASH_ADD_INT(stratum_shares, id, sshare);
pool->sshares++;
mutex_unlock(&sshare_lock);
if (pool_tclear(pool, &pool->submit_fail))
applog(LOG_WARNING, "Pool %d communication resumed, submitting work", pool->pool_no);
applog(LOG_DEBUG, "Successfully submitted, adding to stratum_shares db");
submitted = true;
break;
}
if (!pool_tset(pool, &pool->submit_fail) && cnx_needed(pool)) {
applog(LOG_WARNING, "Pool %d stratum share submission failure", pool->pool_no);
total_ro++;
pool->remotefail_occasions++;
}
if (opt_lowmem) {
applog(LOG_DEBUG, "Lowmem option prevents resubmitting stratum share");
break;
}
cg_rlock(&pool->data_lock);
sessionid_match = (pool->nonce1 && !strcmp(work->nonce1, pool->nonce1));
cg_runlock(&pool->data_lock);
if (!sessionid_match) {
applog(LOG_DEBUG, "No matching session id for resubmitting stratum share");
break;
}
/* Retry every 5 seconds */
sleep(5);
}
if (unlikely(!submitted)) {
applog(LOG_DEBUG, "Failed to submit stratum share, discarding");
free_work(work);
free(sshare);
pool->stale_shares++;
total_stale++;
} else {
int ssdiff;
sshare->sshare_sent = time(NULL);
ssdiff = sshare->sshare_sent - sshare->sshare_time;
if (opt_debug || ssdiff > 0) {
applog(LOG_INFO, "Pool %d stratum share submission lag time %d seconds",
pool->pool_no, ssdiff);
}
}
}
/* Freeze the work queue but don't free up its memory in case there is
* work still trying to be submitted to the removed pool. */
tq_freeze(pool->stratum_q);
return NULL;
}
static void init_stratum_threads(struct pool *pool)
{
have_longpoll = true;
if (unlikely(pthread_create(&pool->stratum_sthread, NULL, stratum_sthread, (void *)pool)))
quit(1, "Failed to create stratum sthread");
if (unlikely(pthread_create(&pool->stratum_rthread, NULL, stratum_rthread, (void *)pool)))
quit(1, "Failed to create stratum rthread");
}
static void *longpoll_thread(void *userdata);
static bool stratum_works(struct pool *pool)
{
applog(LOG_INFO, "Testing pool %d stratum %s", pool->pool_no, pool->stratum_url);
if (!extract_sockaddr(pool->stratum_url, &pool->sockaddr_url, &pool->stratum_port))
return false;
if (!initiate_stratum(pool))
return false;
return true;
}
#ifdef HAVE_LIBCURL
static void __setup_gbt_solo(struct pool *pool)
{
cg_wlock(&pool->gbt_lock);
cg_memcpy(pool->coinbase, scriptsig_header_bin, 41);
pool->coinbase[41 + pool->n1_len + 4 + 1 + 8] = 25;
cg_memcpy(pool->coinbase + 41 + pool->n1_len + 4 + 1 + 8 + 1, pool->script_pubkey, 25);
cg_wunlock(&pool->gbt_lock);
}
static bool setup_gbt_solo(CURL *curl, struct pool *pool)
{
char s[256];
int uninitialised_var(rolltime);
bool ret = false;
json_t *val = NULL, *res_val, *valid_val;
if (!opt_btc_address) {
if (!opt_decode) {
applog(LOG_ERR, "No BTC address specified, unable to mine solo on %s",
pool->rpc_url);
}
goto out;
}
if (opt_btc_address[0] != '1')
{
applog(LOG_ERR, "Bitcoin address must start with 1");
goto out;
}
snprintf(s, 256, "{\"id\": 1, \"method\": \"validateaddress\", \"params\": [\"%s\"]}\n", opt_btc_address);
val = json_rpc_call(curl, pool->rpc_url, pool->rpc_userpass, s, true,
false, &rolltime, pool, false);
if (!val)
goto out;
res_val = json_object_get(val, "result");
if (!res_val)
goto out;
valid_val = json_object_get(res_val, "isvalid");
if (!valid_val)
goto out;
if (!json_is_true(valid_val)) {
applog(LOG_ERR, "Bitcoin address %s is NOT valid", opt_btc_address);
goto out;
}
applog(LOG_NOTICE, "Solo mining to valid address: %s", opt_btc_address);
ret = true;
address_to_pubkeyhash(pool->script_pubkey, opt_btc_address);
hex2bin(scriptsig_header_bin, scriptsig_header, 41);
__setup_gbt_solo(pool);
if (opt_debug) {
char *cb = bin2hex(pool->coinbase, pool->coinbase_len);
applog(LOG_DEBUG, "Pool %d coinbase %s", pool->pool_no, cb);
free(cb);
}
out:
if (val)
json_decref(val);
return ret;
}
#else
static bool setup_gbt_solo(CURL __maybe_unused *curl, struct pool __maybe_unused *pool)
{
return false;
}
#endif
static void pool_start_lp(struct pool *pool)
{
if (!pool->lp_started) {
pool->lp_started = true;
if (unlikely(pthread_create(&pool->longpoll_thread, NULL, longpoll_thread, (void *)pool)))
quit(1, "Failed to create pool longpoll thread");
}
}
static bool pool_active(struct pool *pool, bool pinging)
{
struct timeval tv_getwork, tv_getwork_reply;
json_t *val = NULL;
bool ret = false;
CURL *curl;
int uninitialised_var(rolltime);
if (pool->has_gbt)
applog(LOG_DEBUG, "Retrieving block template from pool %s", pool->rpc_url);
else
applog(LOG_INFO, "Testing pool %s", pool->rpc_url);
/* This is the central point we activate stratum when we can */
retry_stratum:
if (pool->has_stratum) {
/* We create the stratum thread for each pool just after
* successful authorisation. Once the init flag has been set
* we never unset it and the stratum thread is responsible for
* setting/unsetting the active flag */
bool init = pool_tset(pool, &pool->stratum_init);
if (!init) {
#ifdef USE_XTRANONCE
bool ret = initiate_stratum(pool) && (!pool->extranonce_subscribe || subscribe_extranonce(pool)) && auth_stratum(pool);
#else
bool ret = initiate_stratum(pool) && auth_stratum(pool);
#endif
if (ret)
init_stratum_threads(pool);
else
pool_tclear(pool, &pool->stratum_init);
return ret;
}
return pool->stratum_active;
}
curl = curl_easy_init();
if (unlikely(!curl)) {
applog(LOG_ERR, "CURL initialisation failed");
return false;
}
/* Probe for GBT support on first pass */
if (!pool->probed) {
applog(LOG_DEBUG, "Probing for GBT support");
val = json_rpc_call(curl, pool->rpc_url, pool->rpc_userpass,
gbt_req, true, false, &rolltime, pool, false);
if (val) {
json_t *rules_arr = json_object_get(val, "rules");
if (!gbt_check_rules(rules_arr, gbt_understood_rules)) {
applog(LOG_DEBUG, "Not all rules understood for GBT");
json_decref(val);
val = NULL;
}
}
if (!val) {
json_t *rules_arr;
applog(LOG_DEBUG, "Probing for GBT solo support");
val = json_rpc_call(curl, pool->rpc_url, pool->rpc_userpass,
gbt_solo_req, true, false, &rolltime, pool, false);
rules_arr = json_object_get(val, "rules");
if (!gbt_check_rules(rules_arr, gbt_solo_understood_rules)) {
applog(LOG_DEBUG, "Not all rules understood for GBT solo");
json_decref(val);
val = NULL;
}
}
if (val) {
bool append = false, submit = false, transactions = false;
json_t *res_val, *mutables;
int i, mutsize = 0;
res_val = json_object_get(val, "result");
if (res_val) {
mutables = json_object_get(res_val, "mutable");
mutsize = json_array_size(mutables);
}
for (i = 0; i < mutsize; i++) {
json_t *arrval = json_array_get(mutables, i);
if (json_is_string(arrval)) {
const char *mutable = json_string_value(arrval);
if (!strncasecmp(mutable, "coinbase/append", 15))
append = true;
else if (!strncasecmp(mutable, "submit/coinbase", 15))
submit = true;
else if (!strncasecmp(mutable, "transactions", 12))
transactions = true;
}
}
json_decref(val);
/* Only use GBT if it supports coinbase append and
* submit coinbase */
if (append && submit) {
pool->has_gbt = true;
pool->rpc_req = gbt_req;
} else if (transactions) {
pool->rpc_req = gbt_solo_req;
/* Set up gbt_curl before setting gbt_solo
* flag to prevent longpoll thread from
* trying to use an un'inited gbt_curl */
pool->gbt_curl = curl_easy_init();
if (unlikely(!pool->gbt_curl))
quit(1, "GBT CURL initialisation failed");
pool->gbt_solo = true;
if (!opt_btcd)
opt_btcd = pool;
}
}
/* Reset this so we can probe fully just after this. It will be
* set to true that time.*/
pool->probed = false;
if (pool->has_gbt)
applog(LOG_DEBUG, "GBT coinbase + append support found, switching to GBT protocol");
else if (pool->gbt_solo)
applog(LOG_DEBUG, "GBT coinbase without append found, switching to GBT solo protocol");
else
applog(LOG_DEBUG, "No GBT coinbase + append support found, pool unusable if it has no stratum");
}
cgtime(&tv_getwork);
val = json_rpc_call(curl, pool->rpc_url, pool->rpc_userpass,
pool->rpc_req, true, false, &rolltime, pool, false);
cgtime(&tv_getwork_reply);
/* Detect if a http pool has an X-Stratum header at startup,
* and if so, switch to that in preference to gbt if it works */
if (pool->stratum_url && !opt_fix_protocol && stratum_works(pool)) {
applog(LOG_NOTICE, "Switching pool %d %s to %s", pool->pool_no, pool->rpc_url, pool->stratum_url);
if (!pool->rpc_url)
pool->rpc_url = strdup(pool->stratum_url);
pool->has_stratum = true;
curl_easy_cleanup(curl);
goto retry_stratum;
}
if (!pool->has_stratum && !pool->gbt_solo && !pool->has_gbt) {
applog(LOG_WARNING, "No Stratum, GBT or Solo support in pool %d %s unable to use", pool->pool_no, pool->rpc_url);
return false;
}
if (val) {
struct work *work = make_work();
bool rc;
rc = work_decode(pool, work, val);
if (rc) {
applog(LOG_DEBUG, "Successfully retrieved and deciphered work from pool %u %s",
pool->pool_no, pool->rpc_url);
if (pool->gbt_solo) {
ret = setup_gbt_solo(curl, pool);
if (ret)
pool_start_lp(pool);
free_work(work);
goto out;
}
work->pool = pool;
work->rolltime = rolltime;
copy_time(&work->tv_getwork, &tv_getwork);
copy_time(&work->tv_getwork_reply, &tv_getwork_reply);
work->getwork_mode = GETWORK_MODE_TESTPOOL;
calc_diff(work, 0);
applog(LOG_DEBUG, "Pushing pooltest work to base pool");
stage_work(work);
total_getworks++;
pool->getwork_requested++;
ret = true;
} else {
applog(LOG_DEBUG, "Successfully retrieved but FAILED to decipher work from pool %u %s",
pool->pool_no, pool->rpc_url);
free_work(work);
}
if (pool->lp_url)
goto out;
/* Decipher the longpoll URL, if any, and store it in ->lp_url */
if (pool->hdr_path) {
char *copy_start, *hdr_path;
bool need_slash = false;
size_t siz;
hdr_path = pool->hdr_path;
if (strstr(hdr_path, "://")) {
pool->lp_url = hdr_path;
hdr_path = NULL;
} else {
/* absolute path, on current server */
copy_start = (*hdr_path == '/') ? (hdr_path + 1) : hdr_path;
if (pool->rpc_url[strlen(pool->rpc_url) - 1] != '/')
need_slash = true;
siz = strlen(pool->rpc_url) + strlen(copy_start) + 2;
pool->lp_url = cgmalloc(siz);
snprintf(pool->lp_url, siz, "%s%s%s", pool->rpc_url, need_slash ? "/" : "", copy_start);
}
} else
pool->lp_url = NULL;
pool_start_lp(pool);
} else {
applog(LOG_DEBUG, "FAILED to retrieve work from pool %u %s",
pool->pool_no, pool->rpc_url);
if (!pinging && !pool->idle)
applog(LOG_WARNING, "Pool %u slow/down or URL or credentials invalid", pool->pool_no);
}
out:
if (val)
json_decref(val);
curl_easy_cleanup(curl);
return ret;
}
static void pool_resus(struct pool *pool)
{
pool->seq_getfails = 0;
if (pool_strategy == POOL_FAILOVER && pool->prio < cp_prio())
applog(LOG_WARNING, "Pool %d %s alive, testing stability", pool->pool_no, pool->rpc_url);
else
applog(LOG_INFO, "Pool %d %s alive", pool->pool_no, pool->rpc_url);
}
static bool work_filled;
static bool work_emptied;
/* If this is called non_blocking, it will return NULL for work so that must
* be handled. */
static struct work *hash_pop(bool blocking)
{
struct work *work = NULL, *tmp;
int hc;
mutex_lock(stgd_lock);
if (!HASH_COUNT(staged_work)) {
work_emptied = true;
if (!blocking)
goto out_unlock;
do {
struct timespec abstime, tdiff = {10, 0};
int rc;
cgcond_time(&abstime);
timeraddspec(&abstime, &tdiff);
pthread_cond_signal(&gws_cond);
rc = pthread_cond_timedwait(&getq->cond, stgd_lock, &abstime);
/* Check again for !no_work as multiple threads may be
* waiting on this condition and another may set the
* bool separately. */
if (rc && !no_work) {
no_work = true;
applog(LOG_WARNING, "Waiting for work to be available from pools.");
}
} while (!HASH_COUNT(staged_work));
}
if (no_work) {
applog(LOG_WARNING, "Work available from pools, resuming.");
no_work = false;
}
hc = HASH_COUNT(staged_work);
/* Find clone work if possible, to allow masters to be reused */
if (hc > staged_rollable) {
HASH_ITER(hh, staged_work, work, tmp) {
if (!work_rollable(work))
break;
}
} else
work = staged_work;
HASH_DEL(staged_work, work);
if (work_rollable(work))
staged_rollable--;
/* Signal the getwork scheduler to look for more work */
pthread_cond_signal(&gws_cond);
/* Signal hash_pop again in case there are mutliple hash_pop waiters */
pthread_cond_signal(&getq->cond);
/* Keep track of last getwork grabbed */
last_getwork = time(NULL);
out_unlock:
mutex_unlock(stgd_lock);
return work;
}
static void gen_hash(unsigned char *data, unsigned char *hash, int len)
{
unsigned char hash1[32];
sha256(data, len, hash1);
sha256(hash1, 32, hash);
}
void set_target(unsigned char *dest_target, double diff)
{
unsigned char target[32];
uint64_t *data64, h64;
double d64, dcut64;
if (unlikely(diff == 0.0)) {
/* This shouldn't happen but best we check to prevent a crash */
applog(LOG_ERR, "Diff zero passed to set_target");
diff = 1.0;
}
d64 = truediffone;
d64 /= diff;
dcut64 = d64 / bits192;
h64 = dcut64;
data64 = (uint64_t *)(target + 24);
*data64 = htole64(h64);
dcut64 = h64;
dcut64 *= bits192;
d64 -= dcut64;
dcut64 = d64 / bits128;
h64 = dcut64;
data64 = (uint64_t *)(target + 16);
*data64 = htole64(h64);
dcut64 = h64;
dcut64 *= bits128;
d64 -= dcut64;
dcut64 = d64 / bits64;
h64 = dcut64;
data64 = (uint64_t *)(target + 8);
*data64 = htole64(h64);
dcut64 = h64;
dcut64 *= bits64;
d64 -= dcut64;
h64 = d64;
data64 = (uint64_t *)(target);
*data64 = htole64(h64);
if (opt_debug) {
char *htarget = bin2hex(target, 32);
applog(LOG_DEBUG, "Generated target %s", htarget);
free(htarget);
}
cg_memcpy(dest_target, target, 32);
}
#if defined (USE_AVALON2) || defined (USE_AVALON4) || defined (USE_AVALON7) || defined (USE_AVALON8) || defined (USE_AVALON9) \
|| defined (USE_AVALON_MINER) || defined (USE_HASHRATIO) || defined (USE_AVALONLC3)
bool submit_nonce2_nonce(struct thr_info *thr, struct pool *pool, struct pool *real_pool,
uint32_t nonce2, uint32_t nonce, uint32_t ntime)
{
const int thr_id = thr->id;
struct cgpu_info *cgpu = thr->cgpu;
struct device_drv *drv = cgpu->drv;
struct work *work = make_work();
bool ret;
cg_wlock(&pool->data_lock);
pool->nonce2 = nonce2;
cg_wunlock(&pool->data_lock);
gen_stratum_work(pool, work);
roll_work_ntime(work, ntime);
work->pool = real_pool;
/* Inherit the sdiff from the original stratum */
work->sdiff = pool->sdiff;
work->thr_id = thr_id;
work->work_block = work_block;
work->pool->works++;
work->mined = true;
work->device_diff = MIN(drv->max_diff, work->work_difficulty);
work->device_diff = MAX(drv->min_diff, work->device_diff);
ret = submit_nonce(thr, work, nonce);
free_work(work);
return ret;
}
uint32_t gen_merkle_root(struct pool *pool, uint64_t nonce2)
{
unsigned char merkle_root[32], merkle_sha[64];
uint32_t *data32, *swap32, tail;
uint64_t nonce2le;
int i;
/* Update coinbase. Always use an LE encoded nonce2 to fill in values
* from left to right and prevent overflow errors with small n2sizes */
nonce2le = htole64(nonce2);
cg_memcpy(pool->coinbase + pool->nonce2_offset, &nonce2le, pool->n2size);
/* Generate merkle root */
gen_hash(pool->coinbase, merkle_root, pool->coinbase_len);
cg_memcpy(merkle_sha, merkle_root, 32);
for (i = 0; i < pool->merkles; i++) {
cg_memcpy(merkle_sha + 32, pool->swork.merkle_bin[i], 32);
gen_hash(merkle_sha, merkle_root, 64);
cg_memcpy(merkle_sha, merkle_root, 32);
}
data32 = (uint32_t *)merkle_sha;
swap32 = (uint32_t *)merkle_root;
flip32(swap32, data32);
{
char *merkle_hash;
merkle_hash = bin2hex((const unsigned char *)merkle_root, 32);
applog(LOG_DEBUG, "[M-N2]: %s-%08x-%08x", merkle_hash, (uint32_t)nonce2le, (uint32_t)nonce2);
free(merkle_hash);
}
cg_memcpy(&tail, merkle_root + 28, 4);
return tail;
}
#endif
#ifdef USE_BITMAIN_SOC
void get_work_by_nonce2(struct thr_info *thr,
struct work **work,
struct pool *pool,
struct pool *real_pool,
uint64_t nonce2,
uint32_t version)
{
*work = make_work();
const int thr_id = thr->id;
struct cgpu_info *cgpu = thr->cgpu;
struct device_drv *drv = cgpu->drv;
cg_wlock(&pool->data_lock);
pool->nonce2 = nonce2;
//if(pool->support_vil) // comment as default
version = Swap32(version);
cg_memcpy(pool->header_bin, &version, 4);
cg_wunlock(&pool->data_lock);
gen_stratum_work(pool, *work);
(*work)->pool = real_pool;
(*work)->thr_id = thr_id;
(*work)->work_block = work_block;
(*work)->pool->works++;
(*work)->mined = true;
(*work)->version = version;
}
#endif
#if STRATUM_WORK_TIMING
cglock_t swt_lock;
uint64_t stratum_work_count;
uint64_t stratum_work_time;
uint64_t stratum_work_min;
uint64_t stratum_work_max;
uint64_t stratum_work_time0;
uint64_t stratum_work_time10;
uint64_t stratum_work_time100;
#endif
/* Generates stratum based work based on the most recent notify information
* from the pool. This will keep generating work while a pool is down so we use
* other means to detect when the pool has died in stratum_thread */
static void gen_stratum_work(struct pool *pool, struct work *work)
{
unsigned char merkle_root[32], merkle_sha[64];
uint32_t *data32, *swap32;
#if STRATUM_WORK_TIMING
struct timeval stt;
double usec;
#endif
uint64_t nonce2le;
int i;
#if STRATUM_WORK_TIMING
cgtime(&stt);
#endif
cg_wlock(&pool->data_lock);
/* Update coinbase. Always use an LE encoded nonce2 to fill in values
* from left to right and prevent overflow errors with small n2sizes */
nonce2le = htole64(pool->nonce2);
cg_memcpy(pool->coinbase + pool->nonce2_offset, &nonce2le, pool->n2size);
work->nonce2 = pool->nonce2++;
work->nonce2_len = pool->n2size;
/* Downgrade to a read lock to read off the pool variables */
cg_dwlock(&pool->data_lock);
/* Generate merkle root */
gen_hash(pool->coinbase, merkle_root, pool->coinbase_len);
cg_memcpy(merkle_sha, merkle_root, 32);
for (i = 0; i < pool->merkles; i++) {
cg_memcpy(merkle_sha + 32, pool->swork.merkle_bin[i], 32);
gen_hash(merkle_sha, merkle_root, 64);
cg_memcpy(merkle_sha, merkle_root, 32);
}
data32 = (uint32_t *)merkle_sha;
swap32 = (uint32_t *)merkle_root;
flip32(swap32, data32);
/* Copy the data template from header_bin */
cg_memcpy(work->data, pool->header_bin, 112);
cg_memcpy(work->data + 36, merkle_root, 32);
/* Store the stratum work diff to check it still matches the pool's
* stratum diff when submitting shares */
work->sdiff = pool->sdiff;
/* Copy parameters required for share submission */
work->job_id = strdup(pool->swork.job_id);
work->nonce1 = strdup(pool->nonce1);
work->ntime = strdup(pool->ntime);
cg_runlock(&pool->data_lock);
if (opt_debug) {
char *header, *merkle_hash;
header = bin2hex(work->data, 112);
merkle_hash = bin2hex((const unsigned char *)merkle_root, 32);
applog(LOG_DEBUG, "Generated stratum merkle %s", merkle_hash);
applog(LOG_DEBUG, "Generated stratum header %s", header);
applog(LOG_DEBUG, "Work job_id %s nonce2 %"PRIu64" ntime %s", work->job_id,
work->nonce2, work->ntime);
free(header);
free(merkle_hash);
}
calc_midstate(pool, work);
set_target(work->target, work->sdiff);
local_work++;
work->pool = pool;
work->stratum = true;
work->nonce = 0;
work->longpoll = false;
work->getwork_mode = GETWORK_MODE_STRATUM;
work->work_block = work_block;
/* Nominally allow a driver to ntime roll 60 seconds */
work->drv_rolllimit = 60;
calc_diff(work, work->sdiff);
cgtime(&work->tv_staged);
#if STRATUM_WORK_TIMING
usec = us_tdiff(&work->tv_staged, &stt);
cg_wlock(&swt_lock);
stratum_work_count++;
stratum_work_time += usec;
if (stratum_work_min == 0 || stratum_work_min > usec)
stratum_work_min = usec;
if (stratum_work_max < usec)
stratum_work_max = usec;
if (usec == 0)
stratum_work_time0++;
else
{
if (usec >= 10)
{
stratum_work_time10++;
if (usec >= 100)
stratum_work_time100++;
}
}
cg_wunlock(&swt_lock);
#endif
}
#ifdef HAVE_LIBCURL
static void gen_solo_work(struct pool *pool, struct work *work);
/* Use the one instance of gbt_curl, protecting the bool with the gbt_lock but
* avoiding holding the lock once we've set the bool. */
static void get_gbt_curl(struct pool *pool, int poll)
{
cg_ilock(&pool->gbt_lock);
while (pool->gbt_curl_inuse) {
cg_uilock(&pool->gbt_lock);
cgsleep_ms(poll);
cg_ilock(&pool->gbt_lock);
}
cg_ulock(&pool->gbt_lock);
pool->gbt_curl_inuse = true;
cg_wunlock(&pool->gbt_lock);
}
/* No need for locking here */
static inline void release_gbt_curl(struct pool *pool)
{
pool->gbt_curl_inuse = false;
}
static void update_gbt_solo(struct pool *pool)
{
struct work *work = make_work();
int rolltime;
json_t *val;
get_gbt_curl(pool, 10);
retry:
/* Bitcoind doesn't like many open RPC connections. */
curl_easy_setopt(pool->gbt_curl, CURLOPT_FORBID_REUSE, 1);
val = json_rpc_call(pool->gbt_curl, pool->rpc_url, pool->rpc_userpass, pool->rpc_req,
true, false, &rolltime, pool, false);
if (likely(val)) {
bool rc = work_decode(pool, work, val);
if (rc) {
__setup_gbt_solo(pool);
gen_solo_work(pool, work);
stage_work(work);
} else
free_work(work);
json_decref(val);
} else {
applog(LOG_DEBUG, "Pool %d json_rpc_call failed on get gbt, retrying in 5s",
pool->pool_no);
if (++pool->seq_getfails > 5) {
pool_died(pool);
goto out;
}
cgsleep_ms(5000);
goto retry;
}
out:
release_gbt_curl(pool);
}
static void gen_solo_work(struct pool *pool, struct work *work)
{
unsigned char merkle_root[32], merkle_sha[64];
uint32_t *data32, *swap32;
struct timeval now;
uint64_t nonce2le;
int i;
cgtime(&now);
if (now.tv_sec - pool->tv_lastwork.tv_sec > 60)
update_gbt_solo(pool);
cg_wlock(&pool->gbt_lock);
/* Update coinbase. Always use an LE encoded nonce2 to fill in values
* from left to right and prevent overflow errors with small n2sizes */
nonce2le = htole64(pool->nonce2);
cg_memcpy(pool->coinbase + pool->nonce2_offset, &nonce2le, pool->n2size);
work->nonce2 = pool->nonce2++;
work->nonce2_len = pool->n2size;
work->gbt_txns = pool->transactions + 1;
/* Downgrade to a read lock to read off the pool variables */
cg_dwlock(&pool->gbt_lock);
work->coinbase = bin2hex(pool->coinbase, pool->coinbase_len);
/* Generate merkle root */
gen_hash(pool->coinbase, merkle_root, pool->coinbase_len);
cg_memcpy(merkle_sha, merkle_root, 32);
for (i = 0; i < pool->merkles; i++) {
unsigned char *merkle_bin;
merkle_bin = pool->merklebin + (i * 32);
cg_memcpy(merkle_sha + 32, merkle_bin, 32);
gen_hash(merkle_sha, merkle_root, 64);
cg_memcpy(merkle_sha, merkle_root, 32);
}
data32 = (uint32_t *)merkle_sha;
swap32 = (uint32_t *)merkle_root;
flip32(swap32, data32);
/* Copy the data template from header_bin */
cg_memcpy(work->data, pool->header_bin, 112);
cg_memcpy(work->data + 36, merkle_root, 32);
work->sdiff = pool->sdiff;
/* Copy parameters required for share submission */
work->ntime = strdup(pool->ntime);
cg_memcpy(work->target, pool->gbt_target, 32);
cg_runlock(&pool->gbt_lock);
if (opt_debug) {
char *header, *merkle_hash;
header = bin2hex(work->data, 112);
merkle_hash = bin2hex((const unsigned char *)merkle_root, 32);
applog(LOG_DEBUG, "Generated GBT solo merkle %s", merkle_hash);
applog(LOG_DEBUG, "Generated GBT solo header %s", header);
applog(LOG_DEBUG, "Work nonce2 %"PRIu64" ntime %s", work->nonce2,
work->ntime);
free(header);
free(merkle_hash);
}
calc_midstate(pool, work);
local_work++;
work->gbt = true;
work->pool = pool;
work->nonce = 0;
work->longpoll = false;
work->getwork_mode = GETWORK_MODE_SOLO;
work->work_block = work_block;
/* Nominally allow a driver to ntime roll 60 seconds */
work->drv_rolllimit = 60;
calc_diff(work, work->sdiff);
cgtime(&work->tv_staged);
}
#endif
/* The time difference in seconds between when this device last got work via
* get_work() and generated a valid share. */
int share_work_tdiff(struct cgpu_info *cgpu)
{
return last_getwork - cgpu->last_device_valid_work;
}
static void set_benchmark_work(struct cgpu_info *cgpu, struct work *work)
{
cgpu->lodiff += cgpu->direction;
if (cgpu->lodiff < 1)
cgpu->direction = 1;
if (cgpu->lodiff > 15) {
cgpu->direction = -1;
if (++cgpu->hidiff > 15)
cgpu->hidiff = 0;
cg_memcpy(work, &bench_hidiff_bins[cgpu->hidiff][0], 160);
} else
cg_memcpy(work, &bench_lodiff_bins[cgpu->lodiff][0], 160);
}
struct work *get_work(struct thr_info *thr, const int thr_id)
{
struct cgpu_info *cgpu = thr->cgpu;
struct work *work = NULL;
time_t diff_t;
thread_reportout(thr);
applog(LOG_DEBUG, "Popping work from get queue to get work");
diff_t = time(NULL);
while (!work) {
work = hash_pop(true);
if (stale_work(work, false)) {
discard_work(work);
wake_gws();
}
}
diff_t = time(NULL) - diff_t;
/* Since this is a blocking function, we need to add grace time to
* the device's last valid work to not make outages appear to be
* device failures. */
if (diff_t > 0) {
applog(LOG_DEBUG, "Get work blocked for %d seconds", (int)diff_t);
cgpu->last_device_valid_work += diff_t;
}
applog(LOG_DEBUG, "Got work from get queue to get work for thread %d", thr_id);
work->thr_id = thr_id;
if (opt_benchmark)
set_benchmark_work(cgpu, work);
thread_reportin(thr);
work->mined = true;
work->device_diff = MIN(cgpu->drv->max_diff, work->work_difficulty);
work->device_diff = MAX(cgpu->drv->min_diff, work->device_diff);
return work;
}
/* Submit a copy of the tested, statistic recorded work item asynchronously */
static void submit_work_async(struct work *work)
{
struct pool *pool = work->pool;
pthread_t submit_thread;
cgtime(&work->tv_work_found);
if (opt_benchmark) {
struct cgpu_info *cgpu = get_thr_cgpu(work->thr_id);
mutex_lock(&stats_lock);
cgpu->accepted++;
total_accepted++;
pool->accepted++;
cgpu->diff_accepted += work->work_difficulty;
total_diff_accepted += work->work_difficulty;
pool->diff_accepted += work->work_difficulty;
mutex_unlock(&stats_lock);
applog(LOG_NOTICE, "Accepted %s %d benchmark share nonce %08x",
cgpu->drv->name, cgpu->device_id, *(uint32_t *)(work->data + 64 + 12));
return;
}
if (stale_work(work, true)) {
if (opt_submit_stale)
applog(LOG_NOTICE, "Pool %d stale share detected, submitting as user requested", pool->pool_no);
else if (pool->submit_old)
applog(LOG_NOTICE, "Pool %d stale share detected, submitting as pool requested", pool->pool_no);
else {
applog(LOG_NOTICE, "Pool %d stale share detected, discarding", pool->pool_no);
sharelog("discard", work);
mutex_lock(&stats_lock);
total_stale++;
pool->stale_shares++;
total_diff_stale += work->work_difficulty;
pool->diff_stale += work->work_difficulty;
mutex_unlock(&stats_lock);
free_work(work);
return;
}
work->stale = true;
}
if (work->stratum) {
applog(LOG_DEBUG, "Pushing pool %d work to stratum queue", pool->pool_no);
if (unlikely(!pool->stratum_q || !tq_push(pool->stratum_q, work))) {
applog(LOG_DEBUG, "Discarding work from removed pool");
free_work(work);
}
} else {
applog(LOG_DEBUG, "Pushing submit work to work thread");
if (unlikely(pthread_create(&submit_thread, NULL, submit_work_thread, (void *)work)))
quit(1, "Failed to create submit_work_thread");
}
}
void inc_hw_errors_n(struct thr_info *thr, int n)
{
applog(LOG_INFO, "%s %d: invalid nonce - HW error", thr->cgpu->drv->name,
thr->cgpu->device_id);
mutex_lock(&stats_lock);
hw_errors += n;
thr->cgpu->hw_errors += n;
mutex_unlock(&stats_lock);
thr->cgpu->drv->hw_error(thr);
}
void inc_hw_errors(struct thr_info *thr)
{
inc_hw_errors_n(thr, 1);
}
/* Fills in the work nonce and builds the output data in work->hash */
static void rebuild_nonce(struct work *work, uint32_t nonce)
{
uint32_t *work_nonce = (uint32_t *)(work->data + 64 + 12);
*work_nonce = htole32(nonce);
regen_hash(work);
}
/* For testing a nonce against diff 1 */
bool test_nonce(struct work *work, uint32_t nonce)
{
uint32_t *hash_32 = (uint32_t *)(work->hash + 28);
rebuild_nonce(work, nonce);
return (*hash_32 == 0);
}
/* For testing a nonce against an arbitrary diff */
bool test_nonce_diff(struct work *work, uint32_t nonce, double diff)
{
uint64_t *hash64 = (uint64_t *)(work->hash + 24), diff64;
rebuild_nonce(work, nonce);
diff64 = 0x00000000ffff0000ULL;
diff64 /= diff;
return (le64toh(*hash64) <= diff64);
}
/* testing a nonce and return the diff - 0 means invalid */
double test_nonce_value(struct work *work, uint32_t nonce)
{
uint32_t *hash_32 = (uint32_t *)(work->hash + 28);
double d64, s64, ds;
rebuild_nonce(work, nonce);
if (*hash_32 != 0)
return 0.0;
d64 = truediffone;
s64 = le256todouble(work->hash);
ds = d64 / s64;
return ds;
}
static void update_work_stats(struct thr_info *thr, struct work *work)
{
double test_diff = current_diff;
work->share_diff = share_diff(work);
if (unlikely(work->share_diff >= test_diff)) {
work->block = true;
work->pool->solved++;
found_blocks++;
work->mandatory = true;
applog(LOG_NOTICE, "Found block for pool %d!", work->pool->pool_no);
}
mutex_lock(&stats_lock);
total_diff1 += work->device_diff;
thr->cgpu->diff1 += work->device_diff;
work->pool->diff1 += work->device_diff;
thr->cgpu->last_device_valid_work = time(NULL);
mutex_unlock(&stats_lock);
}
/* To be used once the work has been tested to be meet diff1 and has had its
* nonce adjusted. Returns true if the work target is met. */
bool submit_tested_work(struct thr_info *thr, struct work *work)
{
struct work *work_out;
update_work_stats(thr, work);
// dev testing logging the difficulty of all nonces
//double diff = truediffone / le256todouble(work->hash);
//applog(LOG_ERR, "%s() %s %d: diff=%.1f", __func__,
// thr->cgpu->drv->name, thr->cgpu->device_id, diff);
if (!fulltest(work->hash, work->target)) {
applog(LOG_INFO, "%s %d: Share above target", thr->cgpu->drv->name,
thr->cgpu->device_id);
return false;
}
work_out = copy_work(work);
submit_work_async(work_out);
return true;
}
/* Rudimentary test to see if cgpu has returned the same nonce twice in a row which is
* always going to be a duplicate which should be reported as a hw error. */
static bool new_nonce(struct thr_info *thr, uint32_t nonce)
{
struct cgpu_info *cgpu = thr->cgpu;
if (unlikely(cgpu->last_nonce == nonce)) {
applog(LOG_INFO, "%s %d duplicate share detected as HW error",
cgpu->drv->name, cgpu->device_id);
return false;
}
cgpu->last_nonce = nonce;
return true;
}
/* Returns true if nonce for work was a valid share and not a dupe of the very last
* nonce submitted by this device. */
bool submit_nonce(struct thr_info *thr, struct work *work, uint32_t nonce)
{
if (new_nonce(thr, nonce) && test_nonce(work, nonce))
submit_tested_work(thr, work);
else {
inc_hw_errors(thr);
return false;
}
if (opt_benchfile && opt_benchfile_display)
benchfile_dspwork(work, nonce);
return true;
}
/* Allows drivers to submit work items where the driver has changed the ntime
* value by noffset. Must be only used with a work protocol that does not ntime
* roll itself intrinsically to generate work (eg stratum). We do not touch
* the original work struct, but the copy of it only. */
bool submit_noffset_nonce(struct thr_info *thr, struct work *work_in, uint32_t nonce,
int noffset)
{
struct work *work = make_work();
bool ret = false;
_copy_work(work, work_in, noffset);
if (!test_nonce(work, nonce)) {
free_work(work);
inc_hw_errors(thr);
goto out;
}
update_work_stats(thr, work);
if (opt_benchfile && opt_benchfile_display)
benchfile_dspwork(work, nonce);
ret = true;
if (!fulltest(work->hash, work->target)) {
free_work(work);
applog(LOG_INFO, "%s %d: Share above target", thr->cgpu->drv->name,
thr->cgpu->device_id);
goto out;
}
submit_work_async(work);
out:
return ret;
}
static inline bool abandon_work(struct work *work, struct timeval *wdiff, uint64_t hashes)
{
if (wdiff->tv_sec > max_scantime || hashes >= 0xfffffffe ||
stale_work(work, false))
return true;
return false;
}
static void mt_disable(struct thr_info *mythr, const int thr_id,
struct device_drv *drv)
{
applog(LOG_WARNING, "Thread %d being disabled", thr_id);
mythr->cgpu->rolling = 0;
applog(LOG_DEBUG, "Waiting on sem in miner thread");
cgsem_wait(&mythr->sem);
applog(LOG_WARNING, "Thread %d being re-enabled", thr_id);
drv->thread_enable(mythr);
}
/* The main hashing loop for devices that are slow enough to work on one work
* item at a time, without a queue, aborting work before the entire nonce
* range has been hashed if needed. */
static void hash_sole_work(struct thr_info *mythr)
{
const int thr_id = mythr->id;
struct cgpu_info *cgpu = mythr->cgpu;
struct device_drv *drv = cgpu->drv;
struct timeval getwork_start, tv_start, *tv_end, tv_workstart, tv_lastupdate;
struct cgminer_stats *dev_stats = &(cgpu->cgminer_stats);
struct cgminer_stats *pool_stats;
/* Try to cycle approximately 5 times before each log update */
const long cycle = opt_log_interval / 5 ? : 1;
const bool primary = (!mythr->device_thread) || mythr->primary_thread;
struct timeval diff, sdiff, wdiff = {0, 0};
uint32_t max_nonce = drv->can_limit_work(mythr);
int64_t hashes_done = 0;
tv_end = &getwork_start;
cgtime(&getwork_start);
sdiff.tv_sec = sdiff.tv_usec = 0;
cgtime(&tv_lastupdate);
while (likely(!cgpu->shutdown)) {
struct work *work = get_work(mythr, thr_id);
int64_t hashes;
mythr->work_restart = false;
cgpu->new_work = true;
cgtime(&tv_workstart);
work->nonce = 0;
cgpu->max_hashes = 0;
if (!drv->prepare_work(mythr, work)) {
applog(LOG_ERR, "work prepare failed, exiting "
"mining thread %d", thr_id);
break;
}
work->device_diff = MIN(drv->max_diff, work->work_difficulty);
work->device_diff = MAX(drv->min_diff, work->device_diff);
do {
cgtime(&tv_start);
subtime(&tv_start, &getwork_start);
addtime(&getwork_start, &dev_stats->getwork_wait);
if (time_more(&getwork_start, &dev_stats->getwork_wait_max))
copy_time(&dev_stats->getwork_wait_max, &getwork_start);
if (time_less(&getwork_start, &dev_stats->getwork_wait_min))
copy_time(&dev_stats->getwork_wait_min, &getwork_start);
dev_stats->getwork_calls++;
pool_stats = &(work->pool->cgminer_stats);
addtime(&getwork_start, &pool_stats->getwork_wait);
if (time_more(&getwork_start, &pool_stats->getwork_wait_max))
copy_time(&pool_stats->getwork_wait_max, &getwork_start);
if (time_less(&getwork_start, &pool_stats->getwork_wait_min))
copy_time(&pool_stats->getwork_wait_min, &getwork_start);
pool_stats->getwork_calls++;
cgtime(&(work->tv_work_start));
/* Only allow the mining thread to be cancelled when
* it is not in the driver code. */
pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, NULL);
thread_reportin(mythr);
hashes = drv->scanhash(mythr, work, work->nonce + max_nonce);
thread_reportout(mythr);
pthread_setcancelstate(PTHREAD_CANCEL_ENABLE, NULL);
pthread_testcancel();
/* tv_end is == &getwork_start */
cgtime(&getwork_start);
if (unlikely(hashes == -1)) {
applog(LOG_ERR, "%s %d failure, disabling!", drv->name, cgpu->device_id);
cgpu->deven = DEV_DISABLED;
dev_error(cgpu, REASON_THREAD_ZERO_HASH);
cgpu->shutdown = true;
break;
}
hashes_done += hashes;
if (hashes > cgpu->max_hashes)
cgpu->max_hashes = hashes;
timersub(tv_end, &tv_start, &diff);
sdiff.tv_sec += diff.tv_sec;
sdiff.tv_usec += diff.tv_usec;
if (sdiff.tv_usec > 1000000) {
++sdiff.tv_sec;
sdiff.tv_usec -= 1000000;
}
timersub(tv_end, &tv_workstart, &wdiff);
if (unlikely((long)sdiff.tv_sec < cycle)) {
int mult;
if (likely(max_nonce == 0xffffffff))
continue;
mult = 1000000 / ((sdiff.tv_usec + 0x400) / 0x400) + 0x10;
mult *= cycle;
if (max_nonce > (0xffffffff * 0x400) / mult)
max_nonce = 0xffffffff;
else
max_nonce = (max_nonce * mult) / 0x400;
} else if (unlikely(sdiff.tv_sec > cycle))
max_nonce = max_nonce * cycle / sdiff.tv_sec;
else if (unlikely(sdiff.tv_usec > 100000))
max_nonce = max_nonce * 0x400 / (((cycle * 1000000) + sdiff.tv_usec) / (cycle * 1000000 / 0x400));
timersub(tv_end, &tv_lastupdate, &diff);
/* Update the hashmeter at most 5 times per second */
if ((hashes_done && (diff.tv_sec > 0 || diff.tv_usec > 200000)) ||
diff.tv_sec >= opt_log_interval) {
hashmeter(thr_id, hashes_done);
hashes_done = 0;
copy_time(&tv_lastupdate, tv_end);
}
if (unlikely(mythr->work_restart)) {
/* Apart from device_thread 0, we stagger the
* starting of every next thread to try and get
* all devices busy before worrying about
* getting work for their extra threads */
if (!primary) {
struct timespec rgtp;
rgtp.tv_sec = 0;
rgtp.tv_nsec = 250 * mythr->device_thread * 1000000;
nanosleep(&rgtp, NULL);
}
break;
}
if (unlikely(mythr->pause || cgpu->deven != DEV_ENABLED))
mt_disable(mythr, thr_id, drv);
sdiff.tv_sec = sdiff.tv_usec = 0;
} while (!abandon_work(work, &wdiff, cgpu->max_hashes));
free_work(work);
}
cgpu->deven = DEV_DISABLED;
}
/* Put a new unqueued work item in cgpu->unqueued_work under cgpu->qlock till
* the driver tells us it's full so that it may extract the work item using
* the get_queued() function which adds it to the hashtable on
* cgpu->queued_work. */
static void fill_queue(struct thr_info *mythr, struct cgpu_info *cgpu, struct device_drv *drv, const int thr_id)
{
do {
bool need_work;
/* Do this lockless just to know if we need more unqueued work. */
need_work = (!cgpu->unqueued_work);
/* get_work is a blocking function so do it outside of lock
* to prevent deadlocks with other locks. */
if (need_work) {
struct work *work = get_work(mythr, thr_id);
wr_lock(&cgpu->qlock);
/* Check we haven't grabbed work somehow between
* checking and picking up the lock. */
if (likely(!cgpu->unqueued_work))
cgpu->unqueued_work = work;
else
need_work = false;
wr_unlock(&cgpu->qlock);
if (unlikely(!need_work))
discard_work(work);
}
/* The queue_full function should be used by the driver to
* actually place work items on the physical device if it
* does have a queue. */
} while (!drv->queue_full(cgpu));
}
/* Add a work item to a cgpu's queued hashlist */
void __add_queued(struct cgpu_info *cgpu, struct work *work)
{
cgpu->queued_count++;
HASH_ADD_INT(cgpu->queued_work, id, work);
}
struct work *__get_queued(struct cgpu_info *cgpu)
{
struct work *work = NULL;
if (cgpu->unqueued_work) {
work = cgpu->unqueued_work;
if (unlikely(stale_work(work, false))) {
discard_work(work);
} else
__add_queued(cgpu, work);
cgpu->unqueued_work = NULL;
wake_gws();
}
return work;
}
/* This function is for retrieving one work item from the unqueued pointer and
* adding it to the hashtable of queued work. Code using this function must be
* able to handle NULL as a return which implies there is no work available. */
struct work *get_queued(struct cgpu_info *cgpu)
{
struct work *work;
wr_lock(&cgpu->qlock);
work = __get_queued(cgpu);
wr_unlock(&cgpu->qlock);
return work;
}
void add_queued(struct cgpu_info *cgpu, struct work *work)
{
wr_lock(&cgpu->qlock);
__add_queued(cgpu, work);
wr_unlock(&cgpu->qlock);
}
/* Get fresh work and add it to cgpu's queued hashlist */
struct work *get_queue_work(struct thr_info *thr, struct cgpu_info *cgpu, int thr_id)
{
struct work *work = get_work(thr, thr_id);
add_queued(cgpu, work);
return work;
}
/* This function is for finding an already queued work item in the
* given que hashtable. Code using this function must be able
* to handle NULL as a return which implies there is no matching work.
* The calling function must lock access to the que if it is required.
* The common values for midstatelen, offset, datalen are 32, 64, 12 */
struct work *__find_work_bymidstate(struct work *que, char *midstate, size_t midstatelen, char *data, int offset, size_t datalen)
{
struct work *work, *tmp, *ret = NULL;
HASH_ITER(hh, que, work, tmp) {
if (memcmp(work->midstate, midstate, midstatelen) == 0 &&
memcmp(work->data + offset, data, datalen) == 0) {
ret = work;
break;
}
}
return ret;
}
/* This function is for finding an already queued work item in the
* device's queued_work hashtable. Code using this function must be able
* to handle NULL as a return which implies there is no matching work.
* The common values for midstatelen, offset, datalen are 32, 64, 12 */
struct work *find_queued_work_bymidstate(struct cgpu_info *cgpu, char *midstate, size_t midstatelen, char *data, int offset, size_t datalen)
{
struct work *ret;
rd_lock(&cgpu->qlock);
ret = __find_work_bymidstate(cgpu->queued_work, midstate, midstatelen, data, offset, datalen);
rd_unlock(&cgpu->qlock);
return ret;
}
struct work *clone_queued_work_bymidstate(struct cgpu_info *cgpu, char *midstate, size_t midstatelen, char *data, int offset, size_t datalen)
{
struct work *work, *ret = NULL;
rd_lock(&cgpu->qlock);
work = __find_work_bymidstate(cgpu->queued_work, midstate, midstatelen, data, offset, datalen);
if (work)
ret = copy_work(work);
rd_unlock(&cgpu->qlock);
return ret;
}
/* This function is for finding an already queued work item in the
* given que hashtable. Code using this function must be able
* to handle NULL as a return which implies there is no matching work.
* The calling function must lock access to the que if it is required. */
struct work *__find_work_byid(struct work *queue, uint32_t id)
{
struct work *ret = NULL;
HASH_FIND_INT(queue, &id, ret);
return ret;
}
struct work *find_queued_work_byid(struct cgpu_info *cgpu, uint32_t id)
{
struct work *ret;
rd_lock(&cgpu->qlock);
ret = __find_work_byid(cgpu->queued_work, id);
rd_unlock(&cgpu->qlock);
return ret;
}
struct work *clone_queued_work_byid(struct cgpu_info *cgpu, uint32_t id)
{
struct work *work, *ret = NULL;
rd_lock(&cgpu->qlock);
work = __find_work_byid(cgpu->queued_work, id);
if (work)
ret = copy_work(work);
rd_unlock(&cgpu->qlock);
return ret;
}
void __work_completed(struct cgpu_info *cgpu, struct work *work)
{
cgpu->queued_count--;
HASH_DEL(cgpu->queued_work, work);
}
/* This iterates over a queued hashlist finding work started more than secs
* seconds ago and discards the work as completed. The driver must set the
* work->tv_work_start value appropriately. Returns the number of items aged. */
int age_queued_work(struct cgpu_info *cgpu, double secs)
{
struct work *work, *tmp;
struct timeval tv_now;
int aged = 0;
cgtime(&tv_now);
wr_lock(&cgpu->qlock);
HASH_ITER(hh, cgpu->queued_work, work, tmp) {
if (tdiff(&tv_now, &work->tv_work_start) > secs) {
__work_completed(cgpu, work);
free_work(work);
aged++;
}
}
wr_unlock(&cgpu->qlock);
return aged;
}
/* This function should be used by queued device drivers when they're sure
* the work struct is no longer in use. */
void work_completed(struct cgpu_info *cgpu, struct work *work)
{
wr_lock(&cgpu->qlock);
__work_completed(cgpu, work);
wr_unlock(&cgpu->qlock);
free_work(work);
}
/* Combines find_queued_work_bymidstate and work_completed in one function
* withOUT destroying the work so the driver must free it. */
struct work *take_queued_work_bymidstate(struct cgpu_info *cgpu, char *midstate, size_t midstatelen, char *data, int offset, size_t datalen)
{
struct work *work;
wr_lock(&cgpu->qlock);
work = __find_work_bymidstate(cgpu->queued_work, midstate, midstatelen, data, offset, datalen);
if (work)
__work_completed(cgpu, work);
wr_unlock(&cgpu->qlock);
return work;
}
void flush_queue(struct cgpu_info *cgpu)
{
struct work *work = NULL;
if (unlikely(!cgpu))
return;
/* Use only a trylock in case we get into a deadlock with a queueing
* function holding the read lock when we're called. */
if (wr_trylock(&cgpu->qlock))
return;
work = cgpu->unqueued_work;
cgpu->unqueued_work = NULL;
wr_unlock(&cgpu->qlock);
if (work) {
free_work(work);
applog(LOG_DEBUG, "Discarded queued work item");
}
}
/* This version of hash work is for devices that are fast enough to always
* perform a full nonce range and need a queue to maintain the device busy.
* Work creation and destruction is not done from within this function
* directly. */
void hash_queued_work(struct thr_info *mythr)
{
struct timeval tv_start = {0, 0}, tv_end;
struct cgpu_info *cgpu = mythr->cgpu;
struct device_drv *drv = cgpu->drv;
const int thr_id = mythr->id;
int64_t hashes_done = 0;
while (likely(!cgpu->shutdown)) {
struct timeval diff;
int64_t hashes;
fill_queue(mythr, cgpu, drv, thr_id);
hashes = drv->scanwork(mythr);
/* Reset the bool here in case the driver looks for it
* synchronously in the scanwork loop. */
mythr->work_restart = false;
if (unlikely(hashes == -1 )) {
applog(LOG_ERR, "%s %d failure, disabling!", drv->name, cgpu->device_id);
cgpu->deven = DEV_DISABLED;
dev_error(cgpu, REASON_THREAD_ZERO_HASH);
break;
}
hashes_done += hashes;
cgtime(&tv_end);
timersub(&tv_end, &tv_start, &diff);
/* Update the hashmeter at most 5 times per second */
if ((hashes_done && (diff.tv_sec > 0 || diff.tv_usec > 200000)) ||
diff.tv_sec >= opt_log_interval) {
hashmeter(thr_id, hashes_done);
hashes_done = 0;
copy_time(&tv_start, &tv_end);
}
if (unlikely(mythr->pause || cgpu->deven != DEV_ENABLED))
mt_disable(mythr, thr_id, drv);
if (mythr->work_update) {
drv->update_work(cgpu);
mythr->work_update = false;
}
}
cgpu->deven = DEV_DISABLED;
}
/* This version of hash_work is for devices drivers that want to do their own
* work management entirely, usually by using get_work(). Note that get_work
* is a blocking function and will wait indefinitely if no work is available
* so this must be taken into consideration in the driver. */
void hash_driver_work(struct thr_info *mythr)
{
struct timeval tv_start = {0, 0}, tv_end;
struct cgpu_info *cgpu = mythr->cgpu;
struct device_drv *drv = cgpu->drv;
const int thr_id = mythr->id;
int64_t hashes_done = 0;
while (likely(!cgpu->shutdown)) {
struct timeval diff;
int64_t hashes;
hashes = drv->scanwork(mythr);
/* Reset the bool here in case the driver looks for it
* synchronously in the scanwork loop. */
mythr->work_restart = false;
if (unlikely(hashes == -1 )) {
applog(LOG_ERR, "%s %d failure, disabling!", drv->name, cgpu->device_id);
cgpu->deven = DEV_DISABLED;
dev_error(cgpu, REASON_THREAD_ZERO_HASH);
break;
}
hashes_done += hashes;
cgtime(&tv_end);
timersub(&tv_end, &tv_start, &diff);
/* Update the hashmeter at most 5 times per second */
if ((hashes_done && (diff.tv_sec > 0 || diff.tv_usec > 200000)) ||
diff.tv_sec >= opt_log_interval) {
hashmeter(thr_id, hashes_done);
hashes_done = 0;
copy_time(&tv_start, &tv_end);
}
if (unlikely(mythr->pause || cgpu->deven != DEV_ENABLED))
mt_disable(mythr, thr_id, drv);
if (mythr->work_update) {
drv->update_work(cgpu);
mythr->work_update = false;
}
}
cgpu->deven = DEV_DISABLED;
}
void *miner_thread(void *userdata)
{
struct thr_info *mythr = userdata;
const int thr_id = mythr->id;
struct cgpu_info *cgpu = mythr->cgpu;
struct device_drv *drv = cgpu->drv;
char threadname[16];
snprintf(threadname, sizeof(threadname), "%d/Miner", thr_id);
RenameThread(threadname);
thread_reportout(mythr);
if (!drv->thread_init(mythr)) {
dev_error(cgpu, REASON_THREAD_FAIL_INIT);
goto out;
}
applog(LOG_DEBUG, "Waiting on sem in miner thread");
cgsem_wait(&mythr->sem);
cgpu->last_device_valid_work = time(NULL);
drv->hash_work(mythr);
drv->thread_shutdown(mythr);
out:
return NULL;
}
enum {
STAT_SLEEP_INTERVAL = 1,
STAT_CTR_INTERVAL = 10000000,
FAILURE_INTERVAL = 30,
};
#ifdef HAVE_LIBCURL
/* Stage another work item from the work returned in a longpoll */
static void convert_to_work(json_t *val, int rolltime, struct pool *pool, struct timeval *tv_lp, struct timeval *tv_lp_reply)
{
struct work *work;
bool rc;
work = make_work();
rc = work_decode(pool, work, val);
if (unlikely(!rc)) {
applog(LOG_ERR, "Could not convert longpoll data to work");
free_work(work);
return;
}
total_getworks++;
pool->getwork_requested++;
work->pool = pool;
work->rolltime = rolltime;
copy_time(&work->tv_getwork, tv_lp);
copy_time(&work->tv_getwork_reply, tv_lp_reply);
calc_diff(work, 0);
if (pool->enabled == POOL_REJECTING)
work->mandatory = true;
if (pool->has_gbt)
gen_gbt_work(pool, work);
work->longpoll = true;
work->getwork_mode = GETWORK_MODE_LP;
/* We'll be checking this work item twice, but we already know it's
* from a new block so explicitly force the new block detection now
* rather than waiting for it to hit the stage thread. This also
* allows testwork to know whether LP discovered the block or not. */
test_work_current(work);
work = clone_work(work);
applog(LOG_DEBUG, "Pushing converted work to stage thread");
stage_work(work);
applog(LOG_DEBUG, "Converted longpoll data to work");
}
/* If we want longpoll, enable it for the chosen default pool, or, if
* the pool does not support longpoll, find the first one that does
* and use its longpoll support */
static struct pool *select_longpoll_pool(struct pool *cp)
{
int i;
if (cp->hdr_path || cp->has_gbt || cp->gbt_solo)
return cp;
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
if (pool->has_stratum || pool->hdr_path)
return pool;
}
return NULL;
}
#endif /* HAVE_LIBCURL */
/* This will make the longpoll thread wait till it's the current pool, or it
* has been flagged as rejecting, before attempting to open any connections.
*/
static void wait_lpcurrent(struct pool *pool)
{
while (!cnx_needed(pool) && (pool->enabled == POOL_DISABLED ||
(pool != current_pool() && pool_strategy != POOL_LOADBALANCE &&
pool_strategy != POOL_BALANCE))) {
mutex_lock(&lp_lock);
pthread_cond_wait(&lp_cond, &lp_lock);
mutex_unlock(&lp_lock);
}
}
#ifdef HAVE_LIBCURL
static void *longpoll_thread(void *userdata)
{
struct pool *cp = (struct pool *)userdata;
/* This *pool is the source of the actual longpoll, not the pool we've
* tied it to */
struct timeval start, reply, end;
struct pool *pool = NULL;
char threadname[16];
CURL *curl = NULL;
int failures = 0;
char lpreq[1024];
char *lp_url;
int rolltime;
snprintf(threadname, sizeof(threadname), "%d/Longpoll", cp->pool_no);
RenameThread(threadname);
retry_pool:
pool = select_longpoll_pool(cp);
if (!pool) {
applog(LOG_WARNING, "No suitable long-poll found for %s", cp->rpc_url);
while (!pool) {
cgsleep_ms(60000);
pool = select_longpoll_pool(cp);
}
}
if (pool->has_stratum) {
applog(LOG_WARNING, "Block change for %s detection via %s stratum",
cp->rpc_url, pool->rpc_url);
goto out;
}
if (pool->gbt_solo) {
applog(LOG_WARNING, "Block change for %s detection via getblockcount polling",
cp->rpc_url);
while (42) {
json_t *val, *res_val = NULL;
if (unlikely(pool->removed))
return NULL;
cgtime(&start);
wait_lpcurrent(cp);
sprintf(lpreq, "{\"id\": 0, \"method\": \"getblockcount\"}\n");
/* We will be making another call immediately after this
* one to get the height so allow this curl to be reused.*/
get_gbt_curl(pool, 500);
curl_easy_setopt(pool->gbt_curl, CURLOPT_FORBID_REUSE, 0);
val = json_rpc_call(pool->gbt_curl, pool->rpc_url, pool->rpc_userpass, lpreq, true,
false, &rolltime, pool, false);
release_gbt_curl(pool);
if (likely(val))
res_val = json_object_get(val, "result");
if (likely(res_val)) {
int height = json_integer_value(res_val);
const char *prev_hash;
failures = 0;
json_decref(val);
if (height >= cp->height) {
applog(LOG_WARNING, "Block height change to %d detected on pool %d",
height, cp->pool_no);
update_gbt_solo(pool);
continue;
}
sprintf(lpreq, "{\"id\": 0, \"method\": \"getblockhash\", \"params\": [%d]}\n", height);
get_gbt_curl(pool, 500);
curl_easy_setopt(pool->gbt_curl, CURLOPT_FORBID_REUSE, 1);
val = json_rpc_call(pool->gbt_curl, pool->rpc_url, pool->rpc_userpass,
lpreq, true, false, &rolltime, pool, false);
release_gbt_curl(pool);
if (val) {
/* Do a comparison on a short stretch of
* the hash to make sure it hasn't changed
* due to mining on an orphan branch. */
prev_hash = json_string_value(json_object_get(val, "result"));
if (unlikely(prev_hash && strncasecmp(prev_hash + 56, pool->prev_hash, 8))) {
applog(LOG_WARNING, "Mining on orphan branch detected, switching!");
update_gbt_solo(pool);
}
json_decref(val);
}
cgsleep_ms(500);
} else {
if (val)
json_decref(val);
cgtime(&end);
if (end.tv_sec - start.tv_sec > 30)
continue;
if (failures == 1)
applog(LOG_WARNING, "longpoll failed for %s, retrying every 30s", lp_url);
cgsleep_ms(30000);
}
}
}
curl = curl_easy_init();
if (unlikely(!curl))
quit (1, "Longpoll CURL initialisation failed");
/* Any longpoll from any pool is enough for this to be true */
have_longpoll = true;
wait_lpcurrent(cp);
lp_url = pool->rpc_url;
applog(LOG_WARNING, "GBT longpoll ID activated for %s", lp_url);
while (42) {
json_t *val, *soval;
wait_lpcurrent(cp);
cgtime(&start);
/* Update the longpollid every time, but do it under lock to
* avoid races */
if (pool->has_gbt) {
cg_rlock(&pool->gbt_lock);
snprintf(lpreq, sizeof(lpreq),
"{\"id\": 0, \"method\": \"getblocktemplate\", \"params\": "
"[{\"capabilities\": [\"coinbasetxn\", \"workid\", \"coinbase/append\"], "
"\"longpollid\": \"%s\"}]}\n", pool->longpollid);
cg_runlock(&pool->gbt_lock);
}
/* Longpoll connections can be persistent for a very long time
* and any number of issues could have come up in the meantime
* so always establish a fresh connection instead of relying on
* a persistent one. */
curl_easy_setopt(curl, CURLOPT_FRESH_CONNECT, 1);
val = json_rpc_call(curl, lp_url, pool->rpc_userpass,
lpreq, false, true, &rolltime, pool, false);
cgtime(&reply);
if (likely(val)) {
soval = json_object_get(json_object_get(val, "result"), "submitold");
if (soval)
pool->submit_old = json_is_true(soval);
else
pool->submit_old = false;
convert_to_work(val, rolltime, pool, &start, &reply);
failures = 0;
json_decref(val);
} else {
/* Some pools regularly drop the longpoll request so
* only see this as longpoll failure if it happens
* immediately and just restart it the rest of the
* time. */
cgtime(&end);
if (end.tv_sec - start.tv_sec > 30)
continue;
if (failures == 1)
applog(LOG_WARNING, "longpoll failed for %s, retrying every 30s", lp_url);
cgsleep_ms(30000);
}
if (pool != cp) {
pool = select_longpoll_pool(cp);
if (pool->has_stratum) {
applog(LOG_WARNING, "Block change for %s detection via %s stratum",
cp->rpc_url, pool->rpc_url);
break;
}
if (unlikely(!pool))
goto retry_pool;
}
if (unlikely(pool->removed))
break;
}
out:
curl_easy_cleanup(curl);
return NULL;
}
#else /* HAVE_LIBCURL */
static void *longpoll_thread(void __maybe_unused *userdata)
{
pthread_detach(pthread_self());
return NULL;
}
#endif /* HAVE_LIBCURL */
void reinit_device(struct cgpu_info *cgpu)
{
if (cgpu->deven == DEV_DISABLED)
return;
#ifdef USE_USBUTILS
/* Attempt a usb device reset if the device has gone sick */
if (cgpu->usbdev && cgpu->usbdev->handle)
libusb_reset_device(cgpu->usbdev->handle);
#endif
cgpu->drv->reinit_device(cgpu);
}
static struct timeval rotate_tv;
/* We reap curls if they are unused for over a minute */
static void reap_curl(struct pool *pool)
{
struct curl_ent *ent, *iter;
struct timeval now;
int reaped = 0;
cgtime(&now);
mutex_lock(&pool->pool_lock);
list_for_each_entry_safe(ent, iter, &pool->curlring, node) {
if (pool->curls < 2)
break;
if (now.tv_sec - ent->tv.tv_sec > 300) {
reaped++;
pool->curls--;
list_del(&ent->node);
curl_easy_cleanup(ent->curl);
free(ent);
}
}
mutex_unlock(&pool->pool_lock);
if (reaped)
applog(LOG_DEBUG, "Reaped %d curl%s from pool %d", reaped, reaped > 1 ? "s" : "", pool->pool_no);
}
/* Prune old shares we haven't had a response about for over 2 minutes in case
* the pool never plans to respond and we're just leaking memory. If we get a
* response beyond that time they will be seen as untracked shares. */
static void prune_stratum_shares(struct pool *pool)
{
struct stratum_share *sshare, *tmpshare;
time_t current_time = time(NULL);
int cleared = 0;
mutex_lock(&sshare_lock);
HASH_ITER(hh, stratum_shares, sshare, tmpshare) {
if (sshare->work->pool == pool && current_time > sshare->sshare_time + 120) {
HASH_DEL(stratum_shares, sshare);
free_work(sshare->work);
free(sshare);
cleared++;
}
}
mutex_unlock(&sshare_lock);
if (cleared) {
applog(LOG_WARNING, "Lost %d shares due to no stratum share response from pool %d",
cleared, pool->pool_no);
pool->stale_shares += cleared;
total_stale += cleared;
}
}
static void *watchpool_thread(void __maybe_unused *userdata)
{
int intervals = 0;
cgtimer_t cgt;
pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
RenameThread("Watchpool");
set_lowprio();
cgtimer_time(&cgt);
while (42) {
struct timeval now;
int i;
if (++intervals > 120)
intervals = 0;
cgtime(&now);
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
if (!opt_benchmark && !opt_benchfile) {
reap_curl(pool);
prune_stratum_shares(pool);
}
/* Get a rolling utility per pool over 10 mins */
if (intervals > 119) {
double shares = pool->diff1 - pool->last_shares;
pool->last_shares = pool->diff1;
pool->utility = (pool->utility + shares * 0.63) / 1.63;
pool->shares = pool->utility;
}
if (pool->enabled == POOL_DISABLED)
continue;
/* Don't start testing a pool if its test thread
* from startup is still doing its first attempt. */
if (unlikely(pool->testing))
continue;
if (pool_active(pool, true)) {
if (pool_tclear(pool, &pool->idle))
pool_resus(pool);
} else
cgtime(&pool->tv_idle);
/* Only switch pools if the failback pool has been
* alive for more than 5 minutes to prevent
* intermittently failing pools from being used. */
if (!pool->idle && pool_strategy == POOL_FAILOVER && pool->prio < cp_prio() &&
now.tv_sec - pool->tv_idle.tv_sec > opt_pool_fallback) {
applog(LOG_WARNING, "Pool %d %s stable for >%d seconds",
pool->pool_no, pool->rpc_url, opt_pool_fallback);
switch_pools(NULL);
}
}
if (current_pool()->idle)
switch_pools(NULL);
if (pool_strategy == POOL_ROTATE && now.tv_sec - rotate_tv.tv_sec > 60 * opt_rotate_period) {
cgtime(&rotate_tv);
switch_pools(NULL);
}
cgsleep_ms_r(&cgt, 5000);
cgtimer_time(&cgt);
}
return NULL;
}
/* Makes sure the hashmeter keeps going even if mining threads stall, updates
* the screen at regular intervals, and restarts threads if they appear to have
* died. */
#define WATCHDOG_INTERVAL 2
#define WATCHDOG_SICK_TIME 120
#define WATCHDOG_DEAD_TIME 600
#define WATCHDOG_SICK_COUNT (WATCHDOG_SICK_TIME/WATCHDOG_INTERVAL)
#define WATCHDOG_DEAD_COUNT (WATCHDOG_DEAD_TIME/WATCHDOG_INTERVAL)
static void *watchdog_thread(void __maybe_unused *userdata)
{
const unsigned int interval = WATCHDOG_INTERVAL;
struct timeval zero_tv;
#ifdef USE_LIBSYSTEMD
uint64_t notify_usec;
struct timeval notify_interval, notify_tv;
memset(¬ify_interval, 0, sizeof(struct timeval));
memset(¬ify_tv, 0, sizeof(struct timeval));
if (sd_watchdog_enabled(false, ¬ify_usec)) {
notify_usec = notify_usec / 2;
us_to_timeval(¬ify_interval, notify_usec);
cgtime(¬ify_tv);
addtime(¬ify_interval, ¬ify_tv);
applog(LOG_DEBUG, "Watchdog notify interval: %.3gs",
notify_usec / 1000000.0);
}
#endif
pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
RenameThread("Watchdog");
set_lowprio();
memset(&zero_tv, 0, sizeof(struct timeval));
cgtime(&rotate_tv);
while (1) {
int i;
struct timeval now;
sleep(interval);
discard_stale();
hashmeter(-1, 0);
#ifdef HAVE_CURSES
if (curses_active_locked()) {
struct cgpu_info *cgpu;
int count;
change_logwinsize();
curses_print_status();
count = 0;
for (i = 0; i < total_devices; i++) {
cgpu = get_devices(i);
#ifndef USE_USBUTILS
if (cgpu)
#else
if (cgpu && !cgpu->usbinfo.nodev)
#endif
curses_print_devstatus(cgpu, i, count++);
}
#ifdef USE_USBUTILS
for (i = 0; i < total_devices; i++) {
cgpu = get_devices(i);
if (cgpu && cgpu->usbinfo.nodev)
curses_print_devstatus(cgpu, i, count++);
}
#endif
touchwin(statuswin);
wrefresh(statuswin);
touchwin(logwin);
wrefresh(logwin);
unlock_curses();
}
#endif
cgtime(&now);
#if USE_LIBSYSTEMD
if (notify_usec && !time_more(¬ify_tv, &now)) {
sd_notify(false, "WATCHDOG=1");
copy_time(¬ify_tv, &now);
addtime(¬ify_interval, ¬ify_tv);
applog(LOG_DEBUG, "Notified watchdog");
}
#endif
if (!sched_paused && !should_run()) {
applog(LOG_WARNING, "Pausing execution as per stop time %02d:%02d scheduled",
schedstop.tm.tm_hour, schedstop.tm.tm_min);
if (!schedstart.enable) {
quit(0, "Terminating execution as planned");
break;
}
applog(LOG_WARNING, "Will restart execution as scheduled at %02d:%02d",
schedstart.tm.tm_hour, schedstart.tm.tm_min);
sched_paused = true;
rd_lock(&mining_thr_lock);
for (i = 0; i < mining_threads; i++)
mining_thr[i]->pause = true;
rd_unlock(&mining_thr_lock);
} else if (sched_paused && should_run()) {
applog(LOG_WARNING, "Restarting execution as per start time %02d:%02d scheduled",
schedstart.tm.tm_hour, schedstart.tm.tm_min);
if (schedstop.enable)
applog(LOG_WARNING, "Will pause execution as scheduled at %02d:%02d",
schedstop.tm.tm_hour, schedstop.tm.tm_min);
sched_paused = false;
for (i = 0; i < mining_threads; i++) {
struct thr_info *thr;
thr = get_thread(i);
/* Don't touch disabled devices */
if (thr->cgpu->deven == DEV_DISABLED)
continue;
thr->pause = false;
applog(LOG_DEBUG, "Pushing sem post to thread %d", thr->id);
cgsem_post(&thr->sem);
}
}
for (i = 0; i < total_devices; ++i) {
struct cgpu_info *cgpu = get_devices(i);
struct thr_info *thr = cgpu->thr[0];
enum dev_enable *denable;
char dev_str[8];
if (!thr)
continue;
cgpu->drv->get_stats(cgpu);
denable = &cgpu->deven;
snprintf(dev_str, sizeof(dev_str), "%s %d", cgpu->drv->name, cgpu->device_id);
/* Thread is waiting on getwork or disabled */
if (thr->getwork || *denable == DEV_DISABLED || thr->pause)
continue;
if (cgpu->status != LIFE_WELL && (now.tv_sec - thr->last.tv_sec < WATCHDOG_SICK_TIME)) {
if (cgpu->status != LIFE_INIT)
applog(LOG_ERR, "%s: Recovered, declaring WELL!", dev_str);
cgpu->status = LIFE_WELL;
cgpu->device_last_well = time(NULL);
} else if (cgpu->status == LIFE_WELL && (now.tv_sec - thr->last.tv_sec > WATCHDOG_SICK_TIME)) {
cgpu->rolling = 0;
cgpu->status = LIFE_SICK;
applog(LOG_ERR, "%s: Idle for more than 60 seconds, declaring SICK!", dev_str);
cgtime(&thr->sick);
dev_error(cgpu, REASON_DEV_SICK_IDLE_60);
if (opt_restart) {
applog(LOG_ERR, "%s: Attempting to restart", dev_str);
reinit_device(cgpu);
}
} else if (cgpu->status == LIFE_SICK && (now.tv_sec - thr->last.tv_sec > WATCHDOG_DEAD_TIME)) {
cgpu->status = LIFE_DEAD;
applog(LOG_ERR, "%s: Not responded for more than 10 minutes, declaring DEAD!", dev_str);
cgtime(&thr->sick);
dev_error(cgpu, REASON_DEV_DEAD_IDLE_600);
} else if (now.tv_sec - thr->sick.tv_sec > 60 &&
(cgpu->status == LIFE_SICK || cgpu->status == LIFE_DEAD)) {
/* Attempt to restart a GPU that's sick or dead once every minute */
cgtime(&thr->sick);
if (opt_restart)
reinit_device(cgpu);
}
}
}
return NULL;
}
static void log_print_status(struct cgpu_info *cgpu)
{
char logline[255];
get_statline(logline, sizeof(logline), cgpu);
applog(LOG_WARNING, "%s", logline);
}
static void noop_get_statline(char __maybe_unused *buf, size_t __maybe_unused bufsiz, struct cgpu_info __maybe_unused *cgpu);
void blank_get_statline_before(char *buf, size_t bufsiz, struct cgpu_info __maybe_unused *cgpu);
void print_summary(void)
{
struct timeval diff;
int hours, mins, secs, i;
double utility, displayed_hashes, work_util;
timersub(&total_tv_end, &total_tv_start, &diff);
hours = diff.tv_sec / 3600;
mins = (diff.tv_sec % 3600) / 60;
secs = diff.tv_sec % 60;
utility = total_accepted / total_secs * 60;
work_util = total_diff1 / total_secs * 60;
applog(LOG_WARNING, "\nSummary of runtime statistics:\n");
applog(LOG_WARNING, "Started at %s", datestamp);
if (total_pools == 1)
applog(LOG_WARNING, "Pool: %s", pools[0]->rpc_url);
applog(LOG_WARNING, "Runtime: %d hrs : %d mins : %d secs", hours, mins, secs);
displayed_hashes = total_mhashes_done / total_secs;
applog(LOG_WARNING, "Average hashrate: %.1f Mhash/s", displayed_hashes);
applog(LOG_WARNING, "Solved blocks: %d", found_blocks);
applog(LOG_WARNING, "Best share difficulty: %s", best_share);
applog(LOG_WARNING, "Share submissions: %"PRId64, total_accepted + total_rejected);
applog(LOG_WARNING, "Accepted shares: %"PRId64, total_accepted);
applog(LOG_WARNING, "Rejected shares: %"PRId64, total_rejected);
applog(LOG_WARNING, "Accepted difficulty shares: %1.f", total_diff_accepted);
applog(LOG_WARNING, "Rejected difficulty shares: %1.f", total_diff_rejected);
if (total_accepted || total_rejected)
applog(LOG_WARNING, "Reject ratio: %.1f%%", (double)(total_rejected * 100) / (double)(total_accepted + total_rejected));
applog(LOG_WARNING, "Hardware errors: %d", hw_errors);
applog(LOG_WARNING, "Utility (accepted shares / min): %.2f/min", utility);
applog(LOG_WARNING, "Work Utility (diff1 shares solved / min): %.2f/min\n", work_util);
applog(LOG_WARNING, "Stale submissions discarded due to new blocks: %"PRId64, total_stale);
applog(LOG_WARNING, "Unable to get work from server occasions: %d", total_go);
applog(LOG_WARNING, "Work items generated locally: %d", local_work);
applog(LOG_WARNING, "Submitting work remotely delay occasions: %d", total_ro);
applog(LOG_WARNING, "New blocks detected on network: %d\n", new_blocks);
if (total_pools > 1) {
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
applog(LOG_WARNING, "Pool: %s", pool->rpc_url);
if (pool->solved)
applog(LOG_WARNING, "SOLVED %d BLOCK%s!", pool->solved, pool->solved > 1 ? "S" : "");
applog(LOG_WARNING, " Share submissions: %"PRId64, pool->accepted + pool->rejected);
applog(LOG_WARNING, " Accepted shares: %"PRId64, pool->accepted);
applog(LOG_WARNING, " Rejected shares: %"PRId64, pool->rejected);
applog(LOG_WARNING, " Accepted difficulty shares: %1.f", pool->diff_accepted);
applog(LOG_WARNING, " Rejected difficulty shares: %1.f", pool->diff_rejected);
if (pool->accepted || pool->rejected)
applog(LOG_WARNING, " Reject ratio: %.1f%%", (double)(pool->rejected * 100) / (double)(pool->accepted + pool->rejected));
applog(LOG_WARNING, " Items worked on: %d", pool->works);
applog(LOG_WARNING, " Stale submissions discarded due to new blocks: %d", pool->stale_shares);
applog(LOG_WARNING, " Unable to get work from server occasions: %d", pool->getfail_occasions);
applog(LOG_WARNING, " Submitting work remotely delay occasions: %d\n", pool->remotefail_occasions);
}
}
applog(LOG_WARNING, "Summary of per device statistics:\n");
for (i = 0; i < total_devices; ++i) {
struct cgpu_info *cgpu = get_devices(i);
cgpu->drv->get_statline_before = &blank_get_statline_before;
cgpu->drv->get_statline = &noop_get_statline;
log_print_status(cgpu);
}
if (opt_shares) {
applog(LOG_WARNING, "Mined %.0f accepted shares of %d requested\n", total_diff_accepted, opt_shares);
if (opt_shares > total_diff_accepted)
applog(LOG_WARNING, "WARNING - Mined only %.0f shares of %d requested.", total_diff_accepted, opt_shares);
}
applog(LOG_WARNING, " ");
fflush(stderr);
fflush(stdout);
}
static void clean_up(bool restarting)
{
#ifdef USE_BITMAIN_SOC
struct sysinfo sInfo;
if (sysinfo(&sInfo))
{
applog(LOG_INFO, "Failed to get sysinfo, errno:%u, reason:%s\n",
errno, strerror(errno));
total_tv_end_sys=time(NULL);
}
else
{
total_tv_end_sys=sInfo.uptime;
}
#endif
#ifdef USE_USBUTILS
usb_polling = false;
pthread_join(usb_poll_thread, NULL);
libusb_exit(NULL);
#endif
cgtime(&total_tv_end);
#ifdef WIN32
timeEndPeriod(1);
#endif
#ifdef HAVE_CURSES
disable_curses();
#endif
if (!restarting && !opt_realquiet && successful_connect)
print_summary();
curl_global_cleanup();
}
/* Should all else fail and we're unable to clean up threads due to locking
* issues etc, just silently exit. */
static void *killall_thread(void __maybe_unused *arg)
{
pthread_detach(pthread_self());
pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
sleep(5);
exit(1);
return NULL;
}
void __quit(int status, bool clean)
{
pthread_t killall_t;
#ifdef USE_LIBSYSTEMD
sd_notify(false, "STOPPING=1\n"
"STATUS=Shutting down...");
#endif
if (unlikely(pthread_create(&killall_t, NULL, killall_thread, NULL)))
exit(1);
if (clean)
clean_up(false);
#ifdef HAVE_CURSES
else
disable_curses();
#endif
#if defined(unix) || defined(__APPLE__)
if (forkpid > 0) {
kill(forkpid, SIGTERM);
forkpid = 0;
}
#endif
pthread_cancel(killall_t);
exit(status);
}
void _quit(int status)
{
__quit(status, true);
}
#ifdef HAVE_CURSES
char *curses_input(const char *query)
{
char *input;
echo();
input = cgmalloc(255);
leaveok(logwin, false);
wlogprint("%s:\n", query);
wgetnstr(logwin, input, 255);
if (!strlen(input))
strcpy(input, "-1");
leaveok(logwin, true);
noecho();
return input;
}
#endif
static bool pools_active = false;
static void *test_pool_thread(void *arg)
{
struct pool *pool = (struct pool *)arg;
if (!pool->blocking)
pthread_detach(pthread_self());
retry:
if (pool->removed)
goto out;
if (pool_active(pool, false)) {
pool_tclear(pool, &pool->idle);
bool first_pool = false;
cg_wlock(&control_lock);
if (!pools_active) {
currentpool = pool;
if (pool->pool_no != 0)
first_pool = true;
pools_active = true;
}
cg_wunlock(&control_lock);
if (unlikely(first_pool))
applog(LOG_NOTICE, "Switching to pool %d %s - first alive pool", pool->pool_no, pool->rpc_url);
pool_resus(pool);
switch_pools(NULL);
} else {
pool_died(pool);
if (!pool->blocking) {
sleep(5);
goto retry;
}
}
pool->testing = false;
out:
return NULL;
}
/* Always returns true that the pool details were added unless we are not
* live, implying this is the only pool being added, so if no pools are
* active it returns false. */
bool add_pool_details(struct pool *pool, bool live, char *url, char *user, char *pass)
{
size_t siz;
pool->rpc_url = url;
pool->rpc_user = user;
pool->rpc_pass = pass;
siz = strlen(pool->rpc_user) + strlen(pool->rpc_pass) + 2;
pool->rpc_userpass = cgmalloc(siz);
snprintf(pool->rpc_userpass, siz, "%s:%s", pool->rpc_user, pool->rpc_pass);
pool->testing = true;
pool->idle = true;
pool->blocking = !live;
enable_pool(pool);
pthread_create(&pool->test_thread, NULL, test_pool_thread, (void *)pool);
if (!live) {
pthread_join(pool->test_thread, NULL);
return pools_active;
}
return true;
}
#ifdef HAVE_CURSES
static bool input_pool(bool live)
{
char *url, *user, *pass;
struct pool *pool;
bool ret = false;
immedok(logwin, true);
wlogprint("Input server details.\n");
retry:
url = NULL;
user = NULL;
pass = NULL;
url = curses_input("URL");
if (!strcmp(url, "-1")) {
wlogprint("Invalid input\n");
goto out;
}
user = curses_input("Username");
if (!strcmp(user, "-1")) {
wlogprint("Invalid input\n");
goto out;
}
pass = curses_input("Password [enter for none]");
if (!strcmp(pass, "-1")) {
free(pass);
pass = strdup("");
}
pool = add_pool();
url = setup_url(pool, url);
ret = add_pool_details(pool, live, url, user, pass);
if (!ret) {
remove_pool(pool);
wlogprint("URL %s failed alive testing, reinput details\n", url);
free(url);
free(user);
free(pass);
goto retry;
}
out:
immedok(logwin, false);
if (!ret) {
free(url);
free(user);
free(pass);
}
return ret;
}
#endif
#if defined(unix) || defined(__APPLE__)
static void fork_monitor()
{
// Make a pipe: [readFD, writeFD]
int pfd[2];
int r = pipe(pfd);
if (r < 0) {
perror("pipe - failed to create pipe for --monitor");
exit(1);
}
// Make stderr write end of pipe
fflush(stderr);
r = dup2(pfd[1], 2);
if (r < 0) {
perror("dup2 - failed to alias stderr to write end of pipe for --monitor");
exit(1);
}
r = close(pfd[1]);
if (r < 0) {
perror("close - failed to close write end of pipe for --monitor");
exit(1);
}
// Don't allow a dying monitor to kill the main process
sighandler_t sr0 = signal(SIGPIPE, SIG_IGN);
sighandler_t sr1 = signal(SIGPIPE, SIG_IGN);
if (SIG_ERR == sr0 || SIG_ERR == sr1) {
perror("signal - failed to edit signal mask for --monitor");
exit(1);
}
// Fork a child process
forkpid = fork();
if (forkpid < 0) {
perror("fork - failed to fork child process for --monitor");
exit(1);
}
// Child: launch monitor command
if (0 == forkpid) {
// Make stdin read end of pipe
r = dup2(pfd[0], 0);
if (r < 0) {
perror("dup2 - in child, failed to alias read end of pipe to stdin for --monitor");
exit(1);
}
close(pfd[0]);
if (r < 0) {
perror("close - in child, failed to close read end of pipe for --monitor");
exit(1);
}
// Launch user specified command
execl("/bin/bash", "/bin/bash", "-c", opt_stderr_cmd, (char*)NULL);
perror("execl - in child failed to exec user specified command for --monitor");
exit(1);
}
// Parent: clean up unused fds and bail
r = close(pfd[0]);
if (r < 0) {
perror("close - failed to close read end of pipe for --monitor");
exit(1);
}
}
#endif // defined(unix)
#ifdef HAVE_CURSES
static void enable_curses_windows(void)
{
int x,y;
getmaxyx(mainwin, y, x);
statuswin = newwin(logstart, x, 0, 0);
leaveok(statuswin, true);
logwin = newwin(y - logcursor, 0, logcursor, 0);
idlok(logwin, true);
scrollok(logwin, true);
leaveok(logwin, true);
cbreak();
noecho();
}
void enable_curses(void) {
lock_curses();
if (curses_active) {
unlock_curses();
return;
}
mainwin = initscr();
enable_curses_windows();
curses_active = true;
statusy = logstart;
unlock_curses();
}
#endif
static int cgminer_id_count = 0;
/* Various noop functions for drivers that don't support or need their
* variants. */
static void noop_reinit_device(struct cgpu_info __maybe_unused *cgpu)
{
}
void blank_get_statline_before(char __maybe_unused *buf,size_t __maybe_unused bufsiz, struct cgpu_info __maybe_unused *cgpu)
{
}
static void noop_get_statline(char __maybe_unused *buf, size_t __maybe_unused bufsiz, struct cgpu_info __maybe_unused *cgpu)
{
}
static bool noop_get_stats(struct cgpu_info __maybe_unused *cgpu)
{
return true;
}
static bool noop_thread_prepare(struct thr_info __maybe_unused *thr)
{
return true;
}
static uint64_t noop_can_limit_work(struct thr_info __maybe_unused *thr)
{
return 0xffffffff;
}
static bool noop_thread_init(struct thr_info __maybe_unused *thr)
{
return true;
}
static bool noop_prepare_work(struct thr_info __maybe_unused *thr, struct work __maybe_unused *work)
{
return true;
}
static void noop_hw_error(struct thr_info __maybe_unused *thr)
{
}
static void noop_thread_shutdown(struct thr_info __maybe_unused *thr)
{
}
static void noop_thread_enable(struct thr_info __maybe_unused *thr)
{
}
static void noop_detect(bool __maybe_unused hotplug)
{
}
static struct api_data *noop_get_api_stats(struct cgpu_info __maybe_unused *cgpu)
{
return NULL;
}
static void noop_hash_work(struct thr_info __maybe_unused *thr)
{
}
static void generic_zero_stats(struct cgpu_info *cgpu)
{
cgpu->diff_accepted =
cgpu->diff_rejected =
cgpu->hw_errors = 0;
}
#define noop_flush_work noop_reinit_device
#define noop_update_work noop_reinit_device
#define noop_queue_full noop_get_stats
#define noop_identify_device noop_reinit_device
/* Fill missing driver drv functions with noops */
void fill_device_drv(struct device_drv *drv)
{
if (!drv->drv_detect)
drv->drv_detect = &noop_detect;
if (!drv->reinit_device)
drv->reinit_device = &noop_reinit_device;
if (!drv->get_statline_before)
drv->get_statline_before = &blank_get_statline_before;
if (!drv->get_statline)
drv->get_statline = &noop_get_statline;
if (!drv->get_stats)
drv->get_stats = &noop_get_stats;
if (!drv->thread_prepare)
drv->thread_prepare = &noop_thread_prepare;
if (!drv->can_limit_work)
drv->can_limit_work = &noop_can_limit_work;
if (!drv->thread_init)
drv->thread_init = &noop_thread_init;
if (!drv->prepare_work)
drv->prepare_work = &noop_prepare_work;
if (!drv->hw_error)
drv->hw_error = &noop_hw_error;
if (!drv->thread_shutdown)
drv->thread_shutdown = &noop_thread_shutdown;
if (!drv->thread_enable)
drv->thread_enable = &noop_thread_enable;
if (!drv->hash_work)
drv->hash_work = &hash_sole_work;
if (!drv->flush_work)
drv->flush_work = &noop_flush_work;
if (!drv->update_work)
drv->update_work = &noop_update_work;
if (!drv->queue_full)
drv->queue_full = &noop_queue_full;
if (!drv->zero_stats)
drv->zero_stats = &generic_zero_stats;
/* If drivers support internal diff they should set a max_diff or
* we will assume they don't and set max to 1. */
if (!drv->max_diff)
drv->max_diff = 1;
if (!drv->genwork)
opt_gen_stratum_work = true;
}
void null_device_drv(struct device_drv *drv)
{
drv->drv_detect = &noop_detect;
drv->reinit_device = &noop_reinit_device;
drv->get_statline_before = &blank_get_statline_before;
drv->get_statline = &noop_get_statline;
drv->get_api_stats = &noop_get_api_stats;
drv->get_stats = &noop_get_stats;
drv->identify_device = &noop_identify_device;
drv->set_device = NULL;
drv->thread_prepare = &noop_thread_prepare;
drv->can_limit_work = &noop_can_limit_work;
drv->thread_init = &noop_thread_init;
drv->prepare_work = &noop_prepare_work;
/* This should make the miner thread just exit */
drv->hash_work = &noop_hash_work;
drv->hw_error = &noop_hw_error;
drv->thread_shutdown = &noop_thread_shutdown;
drv->thread_enable = &noop_thread_enable;
drv->zero_stats = &generic_zero_stats;
drv->hash_work = &noop_hash_work;
drv->queue_full = &noop_queue_full;
drv->flush_work = &noop_flush_work;
drv->update_work = &noop_update_work;
drv->max_diff = 1;
drv->min_diff = 1;
}
void enable_device(struct cgpu_info *cgpu)
{
cgpu->deven = DEV_ENABLED;
wr_lock(&devices_lock);
devices[cgpu->cgminer_id = cgminer_id_count++] = cgpu;
wr_unlock(&devices_lock);
if (hotplug_mode)
new_threads += cgpu->threads;
else
mining_threads += cgpu->threads;
rwlock_init(&cgpu->qlock);
cgpu->queued_work = NULL;
}
struct _cgpu_devid_counter {
char name[4];
int lastid;
UT_hash_handle hh;
};
static void adjust_mostdevs(void)
{
if (total_devices - zombie_devs > most_devices)
most_devices = total_devices - zombie_devs;
}
#ifdef USE_ICARUS
bool icarus_get_device_id(struct cgpu_info *cgpu)
{
static struct _cgpu_devid_counter *devids = NULL;
struct _cgpu_devid_counter *d;
HASH_FIND_STR(devids, cgpu->drv->name, d);
if (d)
return (d->lastid + 1);
else
return 0;
}
#endif
bool add_cgpu(struct cgpu_info *cgpu)
{
static struct _cgpu_devid_counter *devids = NULL;
struct _cgpu_devid_counter *d;
HASH_FIND_STR(devids, cgpu->drv->name, d);
if (d)
cgpu->device_id = ++d->lastid;
else {
d = cgmalloc(sizeof(*d));
cg_memcpy(d->name, cgpu->drv->name, sizeof(d->name));
cgpu->device_id = d->lastid = 0;
HASH_ADD_STR(devids, name, d);
}
wr_lock(&devices_lock);
devices = cgrealloc(devices, sizeof(struct cgpu_info *) * (total_devices + new_devices + 2));
wr_unlock(&devices_lock);
mutex_lock(&stats_lock);
cgpu->last_device_valid_work = time(NULL);
mutex_unlock(&stats_lock);
if (hotplug_mode)
devices[total_devices + new_devices++] = cgpu;
else
devices[total_devices++] = cgpu;
adjust_mostdevs();
#ifdef USE_USBUTILS
if (cgpu->usbdev && !cgpu->unique_id && cgpu->usbdev->serial_string &&
strlen(cgpu->usbdev->serial_string) > 4)
cgpu->unique_id = str_text(cgpu->usbdev->serial_string);
#endif
return true;
}
struct device_drv *copy_drv(struct device_drv *drv)
{
struct device_drv *copy;
copy = cgmalloc(sizeof(*copy));
cg_memcpy(copy, drv, sizeof(*copy));
copy->copy = true;
return copy;
}
#ifdef USE_USBUTILS
static void hotplug_process(void)
{
struct thr_info *thr;
int i, j;
for (i = 0; i < new_devices; i++) {
struct cgpu_info *cgpu;
int dev_no = total_devices + i;
cgpu = devices[dev_no];
enable_device(cgpu);
cgpu->cgminer_stats.getwork_wait_min.tv_sec = MIN_SEC_UNSET;
cgpu->rolling = cgpu->total_mhashes = 0;
}
wr_lock(&mining_thr_lock);
mining_thr = cgrealloc(mining_thr, sizeof(thr) * (mining_threads + new_threads + 1));
for (i = 0; i < new_threads; i++)
mining_thr[mining_threads + i] = cgcalloc(1, sizeof(*thr));
// Start threads
for (i = 0; i < new_devices; ++i) {
struct cgpu_info *cgpu = devices[total_devices];
cgpu->thr = cgmalloc(sizeof(*cgpu->thr) * (cgpu->threads+1));
cgpu->thr[cgpu->threads] = NULL;
cgpu->status = LIFE_INIT;
cgtime(&(cgpu->dev_start_tv));
for (j = 0; j < cgpu->threads; ++j) {
thr = __get_thread(mining_threads);
thr->id = mining_threads;
thr->cgpu = cgpu;
thr->device_thread = j;
if (!cgpu->drv->thread_prepare(thr)) {
null_device_drv(cgpu->drv);
cgpu->deven = DEV_DISABLED;
continue;
}
if (unlikely(thr_info_create(thr, NULL, miner_thread, thr)))
quit(1, "hotplug thread %d create failed", thr->id);
cgpu->thr[j] = thr;
/* Enable threads for devices set not to mine but disable
* their queue in case we wish to enable them later */
if (cgpu->deven != DEV_DISABLED) {
applog(LOG_DEBUG, "Pushing sem post to thread %d", thr->id);
cgsem_post(&thr->sem);
}
mining_threads++;
}
total_devices++;
applog(LOG_WARNING, "Hotplug: %s added %s %i", cgpu->drv->dname, cgpu->drv->name, cgpu->device_id);
}
wr_unlock(&mining_thr_lock);
adjust_mostdevs();
#ifdef HAVE_CURSES
switch_logsize(true);
#endif
}
#define DRIVER_DRV_DETECT_HOTPLUG(X) X##_drv.drv_detect(true);
static void reinit_usb(void)
{
int err;
usb_reinit = true;
/* Wait till libusb_poll_thread is no longer polling */
while (polling_usb)
cgsleep_ms(100);
applog(LOG_DEBUG, "Reinitialising libusb");
libusb_exit(NULL);
err = libusb_init(NULL);
if (err)
quit(1, "Reinit of libusb failed err %d:%s", err, libusb_error_name(err));
usb_reinit = false;
}
static void *hotplug_thread(void __maybe_unused *userdata)
{
pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
RenameThread("Hotplug");
hotplug_mode = true;
cgsleep_ms(5000);
while (0x2a) {
// Version 0.1 just add the devices on - worry about using nodev later
if (hotplug_time == 0)
cgsleep_ms(5000);
else {
new_devices = 0;
new_threads = 0;
/* Use the DRIVER_PARSE_COMMANDS macro to detect all
* devices */
DRIVER_PARSE_COMMANDS(DRIVER_DRV_DETECT_HOTPLUG)
if (new_devices)
hotplug_process();
/* If we have no active devices, libusb may need to
* be re-initialised to work properly */
if (total_devices == zombie_devs)
reinit_usb();
// hotplug_time >0 && <=9999
cgsleep_ms(hotplug_time * 1000);
}
}
return NULL;
}
#endif
static void probe_pools(void)
{
int i;
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
pool->testing = true;
pthread_create(&pool->test_thread, NULL, test_pool_thread, (void *)pool);
}
}
#define DRIVER_FILL_DEVICE_DRV(X) fill_device_drv(&X##_drv);
#define DRIVER_DRV_DETECT_ALL(X) X##_drv.drv_detect(false);
#ifdef USE_USBUTILS
static void *libusb_poll_thread(void __maybe_unused *arg)
{
struct timeval tv_end;
RenameThread("USBPoll");
while (likely(usb_polling)) {
tv_end.tv_sec = 0;
tv_end.tv_usec = 100000;
while (usb_reinit) {
polling_usb = false;
cgsleep_ms(100);
}
polling_usb = true;
libusb_handle_events_timeout_completed(NULL, &tv_end, NULL);
}
/* Cancel any cancellable usb transfers */
cancel_usb_transfers();
/* Keep event handling going until there are no async transfers in
* flight. */
while (async_usb_transfers()) {
tv_end.tv_sec = 0;
tv_end.tv_usec = 0;
libusb_handle_events_timeout_completed(NULL, &tv_end, NULL);
};
return NULL;
}
static void initialise_usb(void) {
int err = libusb_init(NULL);
if (err) {
fprintf(stderr, "libusb_init() failed err %d", err);
fflush(stderr);
quit(1, "libusb_init() failed");
}
initialise_usblocks();
usb_polling = true;
pthread_create(&usb_poll_thread, NULL, libusb_poll_thread, NULL);
}
#else
#define initialise_usb() {}
#endif
#ifdef USE_BITMAIN_SOC
void setStartTimePoint()
{
char logstr[256];
struct sysinfo sInfo;
if (sysinfo(&sInfo))
{
sprintf(logstr, "Failed to get sysinfo, errno:%u, reason:%s\n",
errno, strerror(errno));
writeInitLogFile(logstr);
total_tv_start_sys=time(NULL);
total_tv_end_sys=total_tv_start_sys+1;
}
else
{
total_tv_start_sys=sInfo.uptime;
total_tv_end_sys=total_tv_start_sys+1;
sprintf(logstr, "setStartTimePoint total_tv_start_sys=%d total_tv_end_sys=%d\n",total_tv_start_sys, total_tv_end_sys);
writeInitLogFile(logstr);
}
}
#endif
int main(int argc, char *argv[])
{
struct sigaction handler;
struct work *work = NULL;
bool pool_msg = false;
struct thr_info *thr;
struct block *block;
int i, j, slept = 0;
unsigned int k;
char *s;
/* This dangerous functions tramples random dynamically allocated
* variables so do it before anything at all */
if (unlikely(curl_global_init(CURL_GLOBAL_ALL)))
early_quit(1, "Failed to curl_global_init");
#ifdef USE_LIBSYSTEMD
sd_notify(false, "STATUS=Starting up...");
#endif
# ifdef __linux
/* If we're on a small lowspec platform with only one CPU, we should
* yield after dropping a lock to allow a thread waiting for it to be
* able to get CPU time to grab the lock. */
if (sysconf(_SC_NPROCESSORS_ONLN) == 1)
selective_yield = &sched_yield;
#endif
#if LOCK_TRACKING
// Must be first
if (unlikely(pthread_mutex_init(&lockstat_lock, NULL)))
quithere(1, "Failed to pthread_mutex_init lockstat_lock errno=%d", errno);
#endif
initial_args = cgmalloc(sizeof(char *) * (argc + 1));
for (i = 0; i < argc; i++)
initial_args[i] = strdup(argv[i]);
initial_args[argc] = NULL;
mutex_init(&hash_lock);
mutex_init(&console_lock);
cglock_init(&control_lock);
mutex_init(&stats_lock);
mutex_init(&sharelog_lock);
cglock_init(&ch_lock);
mutex_init(&sshare_lock);
rwlock_init(&blk_lock);
rwlock_init(&netacc_lock);
rwlock_init(&mining_thr_lock);
rwlock_init(&devices_lock);
#if STRATUM_WORK_TIMING
cglock_init(&swt_lock);
#endif
mutex_init(&lp_lock);
if (unlikely(pthread_cond_init(&lp_cond, NULL)))
early_quit(1, "Failed to pthread_cond_init lp_cond");
mutex_init(&restart_lock);
if (unlikely(pthread_cond_init(&restart_cond, NULL)))
early_quit(1, "Failed to pthread_cond_init restart_cond");
if (unlikely(pthread_cond_init(&gws_cond, NULL)))
early_quit(1, "Failed to pthread_cond_init gws_cond");
/* Create a unique get work queue */
getq = tq_new();
if (!getq)
early_quit(1, "Failed to create getq");
/* We use the getq mutex as the staged lock */
stgd_lock = &getq->mutex;
initialise_usb();
snprintf(packagename, sizeof(packagename), "%s %s", PACKAGE, VERSION);
handler.sa_handler = &sighandler;
handler.sa_flags = 0;
sigemptyset(&handler.sa_mask);
sigaction(SIGTERM, &handler, &termhandler);
sigaction(SIGINT, &handler, &inthandler);
sigaction(SIGABRT, &handler, &abrthandler);
#ifndef WIN32
signal(SIGPIPE, SIG_IGN);
#else
timeBeginPeriod(1);
#endif
opt_kernel_path = alloca(PATH_MAX);
strcpy(opt_kernel_path, CGMINER_PREFIX);
cgminer_path = alloca(PATH_MAX);
s = strdup(argv[0]);
strcpy(cgminer_path, dirname(s));
free(s);
strcat(cgminer_path, "/");
devcursor = 8;
logstart = devcursor + 1;
logcursor = logstart + 1;
block = cgcalloc(sizeof(struct block), 1);
for (i = 0; i < 36; i++)
strcat(block->hash, "0");
HASH_ADD_STR(blocks, hash, block);
strcpy(current_hash, block->hash);
INIT_LIST_HEAD(&scan_devices);
/* parse command line */
opt_register_table(opt_config_table,
"Options for both config file and command line");
opt_register_table(opt_cmdline_table,
"Options for command line only");
opt_parse(&argc, argv, applog_and_exit);
if (argc != 1)
early_quit(1, "Unexpected extra commandline arguments");
if (!config_loaded)
load_default_config();
// use this to test diff value handing on various builds and architectures.
// since share submission depends on the difficulty calculated vs the pool
// work requirement, if this test fails, cgminer could discard a block due
// to the difficulty calculation being wrong and too low vs the pool work
if (opt_blockcheck)
{
// how many bits are skipped for diffone
#define BC_DIFF1_BITS 32
// number of bits in a hash
#define BC_MAX_BITS 256
// number of bits set to 1 for diffone
#define BC_TEST_BITS 16
#define HEX_BYTE 8
// ratio limits on the difference between actual and test
#define BC_DELTA_PLUS_LIM 0.00000001
#define BC_DELTA_MINUS_LIM (-0.00000001)
struct work test_work;
#define ASSERTbc(condition) __maybe_unused static char sizeof_work_hash_must_be_32[(condition)?1:-1]
ASSERTbc(sizeof(test_work.hash) == (BC_MAX_BITS / HEX_BYTE));
double test, delta, ratio, change, powval, powdelta, powratio;
double diff = 1.0, prevdiff = 0.0, prevtest = 0.0;
bool deltabad, diffbad, fail = false;
int i, byte, j;
for (i = BC_DIFF1_BITS; i < BC_MAX_BITS - BC_TEST_BITS; i += HEX_BYTE)
{
byte = ((BC_MAX_BITS - 1) - i) / HEX_BYTE;
// set the hash value to 0000...00ffff00...0000
for (j = 0; j < (BC_MAX_BITS / HEX_BYTE); j++)
test_work.hash[j] = 0;
// BC_TEST_BITS
test_work.hash[byte] = 0xff;
test_work.hash[byte - 1] = 0xff;
// Of course MUST use the same calculation as all diff value tests
// use to decide when to submit shares
test = truediffone / le256todouble(test_work.hash);
delta = diff - test;
ratio = delta / diff;
if (ratio < BC_DELTA_MINUS_LIM || ratio > BC_DELTA_PLUS_LIM)
{
deltabad = true;
fail = true;
}
else
deltabad = false;
powval = pow(2.0, (double)(i - BC_DIFF1_BITS));
powdelta = diff - powval;
powratio = powdelta / powval;
if (powratio < BC_DELTA_MINUS_LIM || powratio > BC_DELTA_PLUS_LIM)
{
diffbad = true;
fail = true;
}
else
diffbad = false;
if (diff < prevdiff || test < prevtest)
fail = true;
printf("%3d%s%s real=%.8E calc=%.8E delta=%.8E%s pow=%.8E powdelta=%.8E%s\n",
i, (diff < prevdiff) ? " FATAL DROP IN DIFF:": "",
(test < prevtest) ? " FATAL DROP IN TEST:": "", diff,
test, delta, deltabad ? " DELTA TOO LARGE!" : "",
powval, powdelta, diffbad ? " POW DELTA TOO LARGE!" : "");
prevtest = test;
prevdiff = diff;
diff *= (1 << HEX_BYTE);
change = diff / prevdiff;
if (change != (1 << HEX_BYTE))
{
fail = true;
printf("FATAL for %d double size doesn't handle above %.8E\n", i, prevdiff);
}
}
if (fail)
printf("\nTEST FAILED! See above.\n");
else
printf("\nTest succeeded.\n");
return 0;
}
if (opt_benchmark || opt_benchfile) {
struct pool *pool;
pool = add_pool();
pool->rpc_url = cgmalloc(255);
if (opt_benchfile)
strcpy(pool->rpc_url, "Benchfile");
else
strcpy(pool->rpc_url, "Benchmark");
pool->rpc_user = pool->rpc_url;
pool->rpc_pass = pool->rpc_url;
pool->rpc_userpass = pool->rpc_url;
pool->sockaddr_url = pool->rpc_url;
strncpy(pool->diff, "?", sizeof(pool->diff)-1);
pool->diff[sizeof(pool->diff)-1] = '\0';
enable_pool(pool);
pool->idle = false;
successful_connect = true;
for (i = 0; i < 16; i++) {
hex2bin(&bench_hidiff_bins[i][0], &bench_hidiffs[i][0], 160);
hex2bin(&bench_lodiff_bins[i][0], &bench_lodiffs[i][0], 160);
}
set_target(bench_target, 32);
}
#ifdef USE_BITMAIN_SOC
if(opt_version_path)
{
FILE * fpversion = fopen(opt_version_path, "rb");
char tmp[256] = {0};
int len = 0;
char * start = 0;
if(fpversion == NULL)
{
applog(LOG_ERR, "Open miner version file %s error", opt_version_path);
}
else
{
len = fread(tmp, 1, 256, fpversion);
if(len <= 0)
{
applog(LOG_ERR, "Read miner version file %s error %d", opt_version_path, len);
}
else
{
start = strstr(tmp, "\n");
if(start == NULL)
{
strcpy(g_miner_compiletime, tmp);
}
else
{
cg_memcpy(g_miner_compiletime, tmp, start-tmp);
strcpy(g_miner_type, start+1);
}
if(g_miner_compiletime[strlen(g_miner_compiletime)-1] == '\n')
{
g_miner_compiletime[strlen(g_miner_compiletime)-1] = 0;
}
if(g_miner_compiletime[strlen(g_miner_compiletime)-1] == '\r')
{
g_miner_compiletime[strlen(g_miner_compiletime)-1] = 0;
}
if(g_miner_type[strlen(g_miner_type)-1] == '\n')
{
g_miner_type[strlen(g_miner_type)-1] = 0;
}
if(g_miner_type[strlen(g_miner_type)-1] == '\r')
{
g_miner_type[strlen(g_miner_type)-1] = 0;
}
}
}
applog(LOG_ERR, "Miner compile time: %s type: %s", g_miner_compiletime, g_miner_type);
}
#endif
#ifdef HAVE_CURSES
if (opt_realquiet || opt_display_devs || opt_decode)
use_curses = false;
if (use_curses)
enable_curses();
#endif
applog(LOG_WARNING, "Started %s", packagename);
if (cnfbuf) {
applog(LOG_NOTICE, "Loaded configuration file %s", cnfbuf);
switch (fileconf_load) {
case 0:
applog(LOG_WARNING, "Fatal JSON error in configuration file.");
applog(LOG_WARNING, "Configuration file could not be used.");
break;
case -1:
applog(LOG_WARNING, "Error in configuration file, partially loaded.");
if (use_curses)
applog(LOG_WARNING, "Start cgminer with -T to see what failed to load.");
break;
default:
break;
}
free(cnfbuf);
cnfbuf = NULL;
}
strcat(opt_kernel_path, "/");
if (want_per_device_stats)
opt_log_output = true;
#ifdef HAVE_SYSLOG_H
if (opt_log_output)
setlogmask(LOG_UPTO(LOG_DEBUG));
else
setlogmask(LOG_UPTO(LOG_NOTICE));
#endif
total_control_threads = 8;
control_thr = cgcalloc(total_control_threads, sizeof(*thr));
gwsched_thr_id = 0;
#ifdef USE_AVALON7
if (opt_avalon7_ssplus_enable) {
ssp_sorter_init(HT_SIZE, HT_PRB_LMT, HT_PRB_C1, HT_PRB_C2);
ssp_hasher_init();
}
#endif
#ifdef USE_USBUTILS
usb_initialise();
// before device detection
cgsem_init(&usb_resource_sem);
usbres_thr_id = 1;
thr = &control_thr[usbres_thr_id];
if (thr_info_create(thr, NULL, usb_resource_thread, thr))
early_quit(1, "usb resource thread create failed");
pthread_detach(thr->pth);
#endif
/* Use the DRIVER_PARSE_COMMANDS macro to fill all the device_drvs */
DRIVER_PARSE_COMMANDS(DRIVER_FILL_DEVICE_DRV)
if (!total_pools) {
applog(LOG_WARNING, "Need to specify at least one pool server.");
#ifdef HAVE_CURSES
if (!use_curses || !input_pool(false))
#endif
early_quit(1, "Pool setup failed");
}
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
size_t siz;
pool->cgminer_stats.getwork_wait_min.tv_sec = MIN_SEC_UNSET;
pool->cgminer_pool_stats.getwork_wait_min.tv_sec = MIN_SEC_UNSET;
if (!pool->rpc_userpass) {
if (!pool->rpc_pass)
pool->rpc_pass = strdup("");
if (!pool->rpc_user)
early_quit(1, "No login credentials supplied for pool %u %s", i, pool->rpc_url);
siz = strlen(pool->rpc_user) + strlen(pool->rpc_pass) + 2;
pool->rpc_userpass = cgmalloc(siz);
snprintf(pool->rpc_userpass, siz, "%s:%s", pool->rpc_user, pool->rpc_pass);
}
}
/* Set the currentpool to pool 0 */
currentpool = pools[0];
#ifdef HAVE_SYSLOG_H
if (use_syslog)
openlog(PACKAGE, LOG_PID, LOG_USER);
#endif
#if defined(unix) || defined(__APPLE__)
if (opt_stderr_cmd)
fork_monitor();
#endif // defined(unix)
mining_thr = cgcalloc(mining_threads, sizeof(thr));
for (i = 0; i < mining_threads; i++)
mining_thr[i] = cgcalloc(1, sizeof(*thr));
// Start threads
k = 0;
for (i = 0; i < total_devices; ++i) {
struct cgpu_info *cgpu = devices[i];
cgpu->thr = cgmalloc(sizeof(*cgpu->thr) * (cgpu->threads+1));
cgpu->thr[cgpu->threads] = NULL;
cgpu->status = LIFE_INIT;
for (j = 0; j < cgpu->threads; ++j, ++k) {
thr = get_thread(k);
thr->id = k;
thr->cgpu = cgpu;
thr->device_thread = j;
if (!cgpu->drv->thread_prepare(thr))
continue;
if (unlikely(thr_info_create(thr, NULL, miner_thread, thr)))
early_quit(1, "thread %d create failed", thr->id);
cgpu->thr[j] = thr;
/* Enable threads for devices set not to mine but disable
* their queue in case we wish to enable them later */
if (cgpu->deven != DEV_DISABLED) {
applog(LOG_DEBUG, "Pushing sem post to thread %d", thr->id);
cgsem_post(&thr->sem);
}
}
}
if (opt_benchmark || opt_benchfile)
goto begin_bench;
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
enable_pool(pool);
pool->idle = true;
}
/* Look for at least one active pool before starting */
applog(LOG_NOTICE, "Probing for an alive pool");
probe_pools();
do {
sleep(1);
slept++;
} while (!pools_active && slept < 60);
while (!pools_active) {
if (!pool_msg) {
applog(LOG_ERR, "No servers were found that could be used to get work from.");
applog(LOG_ERR, "Please check the details from the list below of the servers you have input");
applog(LOG_ERR, "Most likely you have input the wrong URL, forgotten to add a port, or have not set up workers");
for (i = 0; i < total_pools; i++) {
struct pool *pool = pools[i];
applog(LOG_WARNING, "Pool: %d URL: %s User: %s Password: %s",
i, pool->rpc_url, pool->rpc_user, pool->rpc_pass);
}
pool_msg = true;
if (use_curses)
applog(LOG_ERR, "Press any key to exit, or cgminer will wait indefinitely for an alive pool.");
}
if (!use_curses)
early_quit(0, "No servers could be used! Exiting.");
#ifdef HAVE_CURSES
touchwin(logwin);
wrefresh(logwin);
halfdelay(10);
if (getch() != ERR)
early_quit(0, "No servers could be used! Exiting.");
cbreak();
#endif
};
begin_bench:
/* Use the DRIVER_PARSE_COMMANDS macro to detect all devices */
DRIVER_PARSE_COMMANDS(DRIVER_DRV_DETECT_ALL)
if (opt_display_devs) {
applog(LOG_ERR, "Devices detected:");
for (i = 0; i < total_devices; ++i) {
struct cgpu_info *cgpu = devices[i];
if (cgpu->name)
applog(LOG_ERR, " %2d. %s %d: %s (driver: %s)", i, cgpu->drv->name, cgpu->device_id, cgpu->name, cgpu->drv->dname);
else
applog(LOG_ERR, " %2d. %s %d (driver: %s)", i, cgpu->drv->name, cgpu->device_id, cgpu->drv->dname);
}
early_quit(0, "%d devices listed", total_devices);
}
mining_threads = 0;
for (i = 0; i < total_devices; ++i)
enable_device(devices[i]);
mining_thr = cgcalloc(mining_threads, sizeof(thr));
for (i = 0; i < mining_threads; i++)
mining_thr[i] = cgcalloc(1, sizeof(*thr));
if (!opt_decode) {
#ifdef USE_USBUTILS
if (!total_devices) {
applog(LOG_WARNING, "No devices detected!");
applog(LOG_WARNING, "Waiting for USB hotplug devices or press q to quit");
}
#else
if (!total_devices)
early_quit(1, "All devices disabled, cannot mine!");
#endif
}
most_devices = total_devices;
load_temp_cutoffs();
for (i = 0; i < total_devices; ++i)
devices[i]->cgminer_stats.getwork_wait_min.tv_sec = MIN_SEC_UNSET;
if (!opt_compact) {
logstart += most_devices;
logcursor = logstart + 1;
#ifdef HAVE_CURSES
check_winsizes();
#endif
}
// Start threads
k = 0;
for (i = 0; i < total_devices; ++i) {
struct cgpu_info *cgpu = devices[i];
cgpu->thr = cgmalloc(sizeof(*cgpu->thr) * (cgpu->threads+1));
cgpu->thr[cgpu->threads] = NULL;
cgpu->status = LIFE_INIT;
for (j = 0; j < cgpu->threads; ++j, ++k) {
thr = get_thread(k);
thr->id = k;
thr->cgpu = cgpu;
thr->device_thread = j;
if (!cgpu->drv->thread_prepare(thr))
continue;
if (unlikely(thr_info_create(thr, NULL, miner_thread, thr)))
early_quit(1, "thread %d create failed", thr->id);
cgpu->thr[j] = thr;
/* Enable threads for devices set not to mine but disable
* their queue in case we wish to enable them later */
if (cgpu->deven != DEV_DISABLED) {
applog(LOG_DEBUG, "Pushing sem post to thread %d", thr->id);
cgsem_post(&thr->sem);
}
}
}
total_mhashes_done = 0;
for (i = 0; i < total_devices; i++) {
struct cgpu_info *cgpu = devices[i];
cgpu->rolling = cgpu->total_mhashes = 0;
}
cgtime_real(&total_tv_start);
get_datestamp(datestamp, sizeof(datestamp), &total_tv_start);
#ifdef USE_BITMAIN_SOC
struct sysinfo sInfo;
if (sysinfo(&sInfo))
{
applog(LOG_INFO, "Failed to get sysinfo, errno:%u, reason:%s\n",
errno, strerror(errno));
total_tv_end_sys=time(NULL);
total_tv_start_sys=time(NULL);
}
else
{
total_tv_end_sys=sInfo.uptime;
total_tv_start_sys=sInfo.uptime;
}
#endif
cgtime(&total_tv_start);
cgtime(&total_tv_end);
cgtime(&tv_hashmeter);
watchpool_thr_id = 2;
thr = &control_thr[watchpool_thr_id];
/* start watchpool thread */
if (thr_info_create(thr, NULL, watchpool_thread, NULL))
early_quit(1, "watchpool thread create failed");
pthread_detach(thr->pth);
watchdog_thr_id = 3;
thr = &control_thr[watchdog_thr_id];
/* start watchdog thread */
if (thr_info_create(thr, NULL, watchdog_thread, NULL))
early_quit(1, "watchdog thread create failed");
pthread_detach(thr->pth);
/* Create API socket thread */
api_thr_id = 5;
thr = &control_thr[api_thr_id];
if (thr_info_create(thr, NULL, api_thread, thr))
early_quit(1, "API thread create failed");
#ifdef USE_USBUTILS
hotplug_thr_id = 6;
thr = &control_thr[hotplug_thr_id];
if (thr_info_create(thr, NULL, hotplug_thread, thr))
early_quit(1, "hotplug thread create failed");
pthread_detach(thr->pth);
#endif
#ifdef HAVE_CURSES
/* Create curses input thread for keyboard input. Create this last so
* that we know all threads are created since this can call kill_work
* to try and shut down all previous threads. */
input_thr_id = 7;
thr = &control_thr[input_thr_id];
if (thr_info_create(thr, NULL, input_thread, thr))
early_quit(1, "input thread create failed");
pthread_detach(thr->pth);
#endif
/* Just to be sure */
if (total_control_threads != 8)
early_quit(1, "incorrect total_control_threads (%d) should be 8", total_control_threads);
#ifdef USE_GEKKO
set_lowprio();
#else
set_highprio();
#endif
#ifdef USE_LIBSYSTEMD
sd_notify(false, "READY=1\n"
"STATUS=Started");
#endif
/* Once everything is set up, main() becomes the getwork scheduler */
while (42) {
int ts, max_staged = max_queue;
struct pool *pool;
if (opt_work_update)
signal_work_update();
opt_work_update = false;
#if defined(USE_AVALON7) || defined(USE_AVALON8) || defined(USE_AVALON9) || defined(USE_AVALONLC3)
if (opt_clean_jobs) {
signal_clean_jobs();
opt_clean_jobs = false;
}
#endif
mutex_lock(stgd_lock);
ts = __total_staged();
/* Wait until hash_pop tells us we need to create more work */
if (ts > max_staged) {
work_filled = true;
pthread_cond_wait(&gws_cond, stgd_lock);
ts = __total_staged();
}
mutex_unlock(stgd_lock);
if (ts > max_staged) {
/* Keeps slowly generating work even if it's not being
* used to keep last_getwork incrementing and to see
* if pools are still alive. */
work_filled = true;
work = hash_pop(false);
if (work)
discard_work(work);
continue;
}
if (work)
discard_work(work);
work = make_work();
while (42) {
pool = select_pool();
if (!pool_unusable(pool))
break;
switch_pools(NULL);
pool = select_pool();
if (pool_unusable(pool))
cgsleep_ms(5);
};
if (pool->has_stratum) {
if (opt_gen_stratum_work) {
gen_stratum_work(pool, work);
applog(LOG_DEBUG, "Generated stratum work");
stage_work(work);
}
continue;
}
#ifdef HAVE_LIBCURL
if (pool->gbt_solo) {
gen_solo_work(pool, work);
applog(LOG_DEBUG, "Generated GBT SOLO work");
stage_work(work);
continue;
}
if (pool->has_gbt) {
gen_gbt_work(pool, work);
applog(LOG_DEBUG, "Generated GBT work");
stage_work(work);
continue;
}
#endif
if (opt_benchfile) {
get_benchfile_work(work);
applog(LOG_DEBUG, "Generated benchfile work");
stage_work(work);
continue;
} else if (opt_benchmark) {
get_benchmark_work(work);
applog(LOG_DEBUG, "Generated benchmark work");
stage_work(work);
continue;
}
}
return 0;
}