#include <inttypes.h>
#include <math.h>
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include <sys/time.h>
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "freertos/queue.h"
#include "driver/gpio.h"
#include "esp_log.h"
#include "driver/gpio.h"
#include "esp_app_desc.h"
#include "esp_netif.h"
#include "esp_timer.h"
#include "esp_wifi.h"
#include "lwip/inet.h"
#include "system.h"
#include "i2c_bitaxe.h"
#include "INA260.h"
#include "adc.h"
#include "connect.h"
#include "nvs_config.h"
#include "display.h"
#include "input.h"
#include "screen.h"
#include "vcore.h"
#include "thermal.h"
static const char * TAG = "SystemModule";
static void _suffix_string(uint64_t, char *, size_t, int);
static esp_netif_t * netif;
//local function prototypes
static esp_err_t ensure_overheat_mode_config();
static void _check_for_best_diff(GlobalState * GLOBAL_STATE, double diff, uint8_t job_id);
static void _suffix_string(uint64_t val, char * buf, size_t bufsiz, int sigdigits);
void SYSTEM_init_system(GlobalState * GLOBAL_STATE)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
module->duration_start = 0;
module->historical_hashrate_rolling_index = 0;
module->historical_hashrate_init = 0;
module->current_hashrate = 0;
module->screen_page = 0;
module->shares_accepted = 0;
module->shares_rejected = 0;
module->best_nonce_diff = nvs_config_get_u64(NVS_CONFIG_BEST_DIFF, 0);
module->best_session_nonce_diff = 0;
module->start_time = esp_timer_get_time();
module->lastClockSync = 0;
module->FOUND_BLOCK = false;
// set the pool url
module->pool_url = nvs_config_get_string(NVS_CONFIG_STRATUM_URL, CONFIG_STRATUM_URL);
module->fallback_pool_url = nvs_config_get_string(NVS_CONFIG_FALLBACK_STRATUM_URL, CONFIG_FALLBACK_STRATUM_URL);
// set the pool port
module->pool_port = nvs_config_get_u16(NVS_CONFIG_STRATUM_PORT, CONFIG_STRATUM_PORT);
module->fallback_pool_port = nvs_config_get_u16(NVS_CONFIG_FALLBACK_STRATUM_PORT, CONFIG_FALLBACK_STRATUM_PORT);
// set the pool user
module->pool_user = nvs_config_get_string(NVS_CONFIG_STRATUM_USER, CONFIG_STRATUM_USER);
module->fallback_pool_user = nvs_config_get_string(NVS_CONFIG_FALLBACK_STRATUM_USER, CONFIG_FALLBACK_STRATUM_USER);
// set the pool password
module->pool_pass = nvs_config_get_string(NVS_CONFIG_STRATUM_PASS, CONFIG_STRATUM_PW);
module->fallback_pool_pass = nvs_config_get_string(NVS_CONFIG_FALLBACK_STRATUM_PASS, CONFIG_FALLBACK_STRATUM_PW);
// set fallback to false.
module->is_using_fallback = false;
// Initialize overheat_mode
module->overheat_mode = nvs_config_get_u16(NVS_CONFIG_OVERHEAT_MODE, 0);
ESP_LOGI(TAG, "Initial overheat_mode value: %d", module->overheat_mode);
// set the best diff string
_suffix_string(module->best_nonce_diff, module->best_diff_string, DIFF_STRING_SIZE, 0);
_suffix_string(module->best_session_nonce_diff, module->best_session_diff_string, DIFF_STRING_SIZE, 0);
// set the ssid string to blank
memset(module->ssid, 0, sizeof(module->ssid));
// set the wifi_status to blank
memset(module->wifi_status, 0, 20);
}
void SYSTEM_init_peripherals(GlobalState * GLOBAL_STATE) {
// Initialize the core voltage regulator
VCORE_init(GLOBAL_STATE);
VCORE_set_voltage(nvs_config_get_u16(NVS_CONFIG_ASIC_VOLTAGE, CONFIG_ASIC_VOLTAGE) / 1000.0, GLOBAL_STATE);
Thermal_init(GLOBAL_STATE->device_model, nvs_config_get_u16(NVS_CONFIG_INVERT_FAN_POLARITY, 1));
vTaskDelay(500 / portTICK_PERIOD_MS);
// Ensure overheat_mode config exists
esp_err_t ret = ensure_overheat_mode_config();
if (ret != ESP_OK) {
ESP_LOGE(TAG, "Failed to ensure overheat_mode config");
}
//Init the DISPLAY
switch (GLOBAL_STATE->device_model) {
case DEVICE_MAX:
case DEVICE_ULTRA:
case DEVICE_SUPRA:
case DEVICE_GAMMA:
case DEVICE_GAMMATURBO:
// display
if (display_init(GLOBAL_STATE) != ESP_OK || !GLOBAL_STATE->SYSTEM_MODULE.is_screen_active) {
ESP_LOGW(TAG, "OLED init failed!");
} else {
ESP_LOGI(TAG, "OLED init success!");
}
break;
default:
}
if (input_init(screen_next, toggle_wifi_softap) != ESP_OK) {
ESP_LOGW(TAG, "Input init failed!");
}
if (screen_start(GLOBAL_STATE) != ESP_OK) {
ESP_LOGW(TAG, "Screen init failed");
}
netif = esp_netif_get_handle_from_ifkey("WIFI_STA_DEF");
}
void SYSTEM_notify_accepted_share(GlobalState * GLOBAL_STATE)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
module->shares_accepted++;
}
static int compare_rejected_reason_stats(const void *a, const void *b) {
const RejectedReasonStat *ea = a;
const RejectedReasonStat *eb = b;
return (eb->count > ea->count) - (ea->count > eb->count);
}
void SYSTEM_notify_rejected_share(GlobalState * GLOBAL_STATE, char * error_msg)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
module->shares_rejected++;
for (int i = 0; i < module->rejected_reason_stats_count; i++) {
if (strncmp(module->rejected_reason_stats[i].message, error_msg, sizeof(module->rejected_reason_stats[i].message) - 1) == 0) {
module->rejected_reason_stats[i].count++;
return;
}
}
if (module->rejected_reason_stats_count < sizeof(module->rejected_reason_stats)) {
strncpy(module->rejected_reason_stats[module->rejected_reason_stats_count].message,
error_msg,
sizeof(module->rejected_reason_stats[module->rejected_reason_stats_count].message) - 1);
module->rejected_reason_stats[module->rejected_reason_stats_count].message[sizeof(module->rejected_reason_stats[module->rejected_reason_stats_count].message) - 1] = '\0'; // Ensure null termination
module->rejected_reason_stats[module->rejected_reason_stats_count].count = 1;
module->rejected_reason_stats_count++;
}
if (module->rejected_reason_stats_count > 1) {
qsort(module->rejected_reason_stats, module->rejected_reason_stats_count,
sizeof(module->rejected_reason_stats[0]), compare_rejected_reason_stats);
}
}
void SYSTEM_notify_mining_started(GlobalState * GLOBAL_STATE)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
module->duration_start = esp_timer_get_time();
}
void SYSTEM_notify_new_ntime(GlobalState * GLOBAL_STATE, uint32_t ntime)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
// Hourly clock sync
if (module->lastClockSync + (60 * 60) > ntime) {
return;
}
ESP_LOGI(TAG, "Syncing clock");
module->lastClockSync = ntime;
struct timeval tv;
tv.tv_sec = ntime;
tv.tv_usec = 0;
settimeofday(&tv, NULL);
}
void SYSTEM_notify_found_nonce(GlobalState * GLOBAL_STATE, double found_diff, uint8_t job_id)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
// Calculate the time difference in seconds with sub-second precision
// hashrate = (nonce_difficulty * 2^32) / time_to_find
module->historical_hashrate[module->historical_hashrate_rolling_index] = GLOBAL_STATE->ASIC_difficulty;
module->historical_hashrate_time_stamps[module->historical_hashrate_rolling_index] = esp_timer_get_time();
module->historical_hashrate_rolling_index = (module->historical_hashrate_rolling_index + 1) % HISTORY_LENGTH;
// ESP_LOGI(TAG, "nonce_diff %.1f, ttf %.1f, res %.1f", nonce_diff, duration,
// historical_hashrate[historical_hashrate_rolling_index]);
if (module->historical_hashrate_init < HISTORY_LENGTH) {
module->historical_hashrate_init++;
} else {
module->duration_start =
module->historical_hashrate_time_stamps[(module->historical_hashrate_rolling_index + 1) % HISTORY_LENGTH];
}
double sum = 0;
for (int i = 0; i < module->historical_hashrate_init; i++) {
sum += module->historical_hashrate[i];
}
double duration = (double) (esp_timer_get_time() - module->duration_start) / 1000000;
double rolling_rate = (sum * 4294967296) / (duration * 1000000000);
if (module->historical_hashrate_init < HISTORY_LENGTH) {
module->current_hashrate = rolling_rate;
} else {
// More smoothing
module->current_hashrate = ((module->current_hashrate * 9) + rolling_rate) / 10;
}
// logArrayContents(historical_hashrate, HISTORY_LENGTH);
// logArrayContents(historical_hashrate_time_stamps, HISTORY_LENGTH);
_check_for_best_diff(GLOBAL_STATE, found_diff, job_id);
}
static double _calculate_network_difficulty(uint32_t nBits)
{
uint32_t mantissa = nBits & 0x007fffff; // Extract the mantissa from nBits
uint8_t exponent = (nBits >> 24) & 0xff; // Extract the exponent from nBits
double target = (double) mantissa * pow(256, (exponent - 3)); // Calculate the target value
double difficulty = (pow(2, 208) * 65535) / target; // Calculate the difficulty
return difficulty;
}
static void _check_for_best_diff(GlobalState * GLOBAL_STATE, double diff, uint8_t job_id)
{
SystemModule * module = &GLOBAL_STATE->SYSTEM_MODULE;
if ((uint64_t) diff > module->best_session_nonce_diff) {
module->best_session_nonce_diff = (uint64_t) diff;
_suffix_string((uint64_t) diff, module->best_session_diff_string, DIFF_STRING_SIZE, 0);
}
if ((uint64_t) diff <= module->best_nonce_diff) {
return;
}
module->best_nonce_diff = (uint64_t) diff;
nvs_config_set_u64(NVS_CONFIG_BEST_DIFF, module->best_nonce_diff);
// make the best_nonce_diff into a string
_suffix_string((uint64_t) diff, module->best_diff_string, DIFF_STRING_SIZE, 0);
double network_diff = _calculate_network_difficulty(GLOBAL_STATE->ASIC_TASK_MODULE.active_jobs[job_id]->target);
if (diff > network_diff) {
module->FOUND_BLOCK = true;
ESP_LOGI(TAG, "FOUND BLOCK!!!!!!!!!!!!!!!!!!!!!! %f > %f", diff, network_diff);
}
ESP_LOGI(TAG, "Network diff: %f", network_diff);
}
/* 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);
}
}
static esp_err_t ensure_overheat_mode_config() {
uint16_t overheat_mode = nvs_config_get_u16(NVS_CONFIG_OVERHEAT_MODE, UINT16_MAX);
if (overheat_mode == UINT16_MAX) {
// Key doesn't exist or couldn't be read, set the default value
nvs_config_set_u16(NVS_CONFIG_OVERHEAT_MODE, 0);
ESP_LOGI(TAG, "Default value for overheat_mode set to 0");
} else {
// Key exists, log the current value
ESP_LOGI(TAG, "Existing overheat_mode value: %d", overheat_mode);
}
return ESP_OK;
}