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dragonmint_t1.h
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dragonmint_t1.h
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#ifndef _DRAGONMINT_T1_
#define _DRAGONMINT_T1_
#include "stdint.h"
#include "stdbool.h"
#include "util.h"
#include "elist.h"
#include "dm_compat.h"
#define MAX_CHIP_NUM (68)
#define MAX_CHAIN_NUM (3)
#define MAX_CORE_NUM (32)
#define MAX_CORES (MAX_CHIP_NUM * MAX_CORE_NUM)
#define MAX_CMD_LENGTH (JOB_LENGTH + MAX_CHIP_NUM * 2 * 2)
#define CMD_TYPE_T1 (0x0)
#define JOB_LENGTH (162)
#define NONCE_LEN (6)
#define T1_PLL_LV_NUM (324)
#define T1_PLL_SETSPI (310)
#define T1_PLL_SETVID (1000)
#define T1_SPI_SPEED_DEF SPI_SPEED_390K
#define STARTUP_VID (0)
#define DEFAULT_PLL (1332)
#define MIN_PLL (1200)
#define MAX_PLL (1392)
#define DEFAULT_VOLT (404)
#define TUNE_VOLT_START_EFF (410)
#define TUNE_VOLT_START_BAL (415)
#define TUNE_VOLT_START_PER (420)
#define TUNE_VOLT_STOP (390)
#define CHIP_VOLT_MAX (445)
#define CHIP_VOLT_MIN (380)
#define USE_BISTMASK
//#define USE_AUTONONCE
#define USE_AUTOCMD0A
#define WEAK_CHIP_THRESHOLD 5
#define BROKEN_CHIP_THRESHOLD 5
#define DRAGONMINT_MINER_TYPE_FILE "/tmp/type"
#define DRAGONMINT_HARDWARE_VERSION_FILE "/tmp/hwver"
#define DRAGONMINT_CHIP_NUM_FILE "/tmp/chip_nums"
#define MINER_AGEING_STATUS_FILE "/tmp/ageingStatus"
#define T1_PLL(prediv,fbdiv,postdiv) ((prediv<<(89-64))|fbdiv<<(80-64)|0b010<<(77-64)|postdiv<<(70-64))
#define T1_PLL_MIN (0) // 120 MHz
#define T1_PLL_TUNE_MIN (290) // 1200 MHz
#define T1_PLL_TUNE_MAX (323) // 1596 MHz
#define T1_PLL_MAX (323) // 1596 MHz
#define T1_PLL_TUNE_RANGE (T1_PLL_TUNE_MAX - T1_PLL_TUNE_MIN + 1)
/* Low iVid corresponds with high voltage */
#define T1_VID_MIN (0)
#define T1_VID_MAX (31)
#define T1_VID_TUNE_RANGE (T1_VID_MAX - T1_VID_MIN + 1)
#define T1_CYCLES_CHAIN (666)
typedef enum {
HARDWARE_VERSION_NONE = 0x00,
HARDWARE_VERSION_G9 = 0x09,
HARDWARE_VERSION_G19 = 0x13,
} hardware_version_e;
typedef enum {
AGEING_BIST_START_FAILED = 1,
AGEING_BIST_FIX_FAILED,
AGEING_CONFIG_PLL_FAILED,
AGEING_PLUG_STATUS_ERROR,
AGEING_SPI_STATUS_ERROR,
AGEING_RUNNING_CONNECT_POOL_FAILED,
AGEING_INIT_CONNECT_POOL_FAILED,
AGEING_ALL_SPI_STATUS_ERROR,
AGEING_HW_VERSION_ERROR,
AGEING_TEMP_IS_OVERHEAT,
AGEING_STATUS_MAX,
} MINER_AGEING_STATUS;
typedef struct {
double highest_vol[MAX_CHAIN_NUM]; /* chip temp bits */;
double lowest_vol[MAX_CHAIN_NUM]; /* chip temp bits */;
double average_vol[MAX_CHAIN_NUM]; /* chip temp bits */;
int stat_val[MAX_CHAIN_NUM][MAX_CHIP_NUM];
int stat_cnt[MAX_CHAIN_NUM][MAX_CHIP_NUM];
} dragonmint_reg_ctrl_t;
struct work_ent {
struct work *work;
struct list_head head;
};
struct work_queue {
int num_elems;
struct list_head head;
};
struct T1_chip {
uint8_t reg[REG_LENGTH];
int num_cores;
int last_queued_id;
struct work *work[4];
/* stats */
int hw_errors;
int stales;
int dupes;
int nonces_found;
int nonce_ranges_done;
/* systime in ms when chip was disabled */
int cooldown_begin;
/* number of consecutive failures to access the chip */
int fail_count;
int fail_reset;
/* mark chip disabled, do not try to re-enable it */
bool disabled;
int temp;
int nVol;
uint32_t last_nonce;
};
struct T1_chain {
int chain_id;
struct cgpu_info *cgpu;
int num_chips;
int num_cores;
int num_active_chips;
int chain_skew;
struct spi_ctx *spi_ctx;
struct T1_chip *chips;
pthread_mutex_t lock;
pthread_cond_t cond;
struct work_queue active_wq;
/* mark chain disabled, do not try to re-enable it */
bool disabled;
bool throttle; /* Needs throttling */
struct timeval cycle_start;
int cycles; /* Cycles used for iVid tuning */
int hw_errors;
int pll; /* Current chain speed */
int base_pll; /* Initial chain speed */
int iVid; /* Current actual iVid */
int base_iVid; /* Initial iVid */
int optimalVid; /* Vid after last tune */
int optimal_vol; /* Optimal voltage found after VID tuning */
double vidproduct[T1_VID_TUNE_RANGE]; // Hashrate product vs vid level
double vidhwerr[T1_VID_TUNE_RANGE]; // hwerr vs vid level
/* Double may give more precision than int since it's an average voltage */
double vidvol[T1_VID_TUNE_RANGE]; // What the voltage is per vid level
double pllproduct[T1_PLL_TUNE_RANGE]; // Hashrate product vs pll level
double pllhwerr[T1_PLL_TUNE_RANGE]; // hwerr vs pll level
int pllvid[T1_PLL_TUNE_RANGE]; // Associated VID per pll
bool VidOptimal; // We've stopped tuning voltage
bool pllOptimal; // We've stopped tuning frequency
bool sampling; // Results are valid for tuning
time_t throttled; // Currently throttled time for heat
time_t lastshare;
cgtimer_t cgt; /* Main work loop reentrant timer */
};
struct PLL_Clock {
uint32_t num; // divider 1000
uint32_t speedMHz; // unit MHz
uint32_t pll_reg;
};
struct T1_config_options {
int ref_clk_khz;
int sys_clk_khz;
int spi_clk_khz;
/* limit chip chain to this number of chips (testing only) */
int override_chip_num;
int wiper;
};
unsigned short CRC16_2(unsigned char* pchMsg, unsigned short wDataLen);
void hexdump_error(char *prefix, uint8_t *buff, int len);
void hexdump(char *prefix, uint8_t *buff, int len);
bool dm_cmd_resetall(uint8_t chain_id, uint8_t chip_id, uint8_t *result);
bool dm_cmd_resetjob(uint8_t chain_id, uint8_t chip_id, uint8_t *result);
bool dm_cmd_resetbist(uint8_t chain_id, uint8_t chip_id, uint8_t *result);
bool dragonmint_check_voltage(struct T1_chain *t1, int chip_id, dragonmint_reg_ctrl_t *s_reg_ctrl);
bool check_chip(struct T1_chain *t1, int i);
bool abort_work(struct T1_chain *t1);
int get_current_ms(void);
bool is_chip_disabled(struct T1_chain *t1, uint8_t chip_id);
void disable_chip(struct T1_chain *t1, uint8_t chip_id);
bool get_nonce(struct T1_chain *t1, uint8_t *nonce, uint8_t *chip_id, uint8_t *job_id, uint8_t *micro_job_id);
bool set_work(struct T1_chain *t1, uint8_t chip_id, struct work *work, uint8_t queue_states);
uint8_t *create_job(uint8_t chip_id, uint8_t job_id, struct work *work);
void test_bench_pll_config(struct T1_chain *t1,uint32_t uiPll);
hardware_version_e dragonmint_get_hwver(void);
//dragonmint_type_e dragonmint_get_miner_type(void);
uint32_t dragonmint_get_chipnum(void);
void chain_all_exit(void);
void power_down_all_chain(void);
void write_miner_ageing_status(uint32_t statusCode);
int dragonmint_get_voltage_stats(struct T1_chain *t1, dragonmint_reg_ctrl_t *s_reg_ctrl);
bool t1_set_pll(struct T1_chain *t1, int chip_id, int target_pll);
bool T1_SetT1PLLClock(struct T1_chain *t1,int pllClkIdx, int chip_id);
int T1_ConfigT1PLLClock(uint32_t optPll);
extern const struct PLL_Clock PLL_Clk_12Mhz[T1_PLL_LV_NUM];
extern const uint8_t default_reg[T1_PLL_LV_NUM][REG_LENGTH];
#endif