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//
// Copyright 2013, 2014 HashFast Technologies LLC
//
// 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.
//
// Useful data structures and values for interfacing with HashFast products
//
// Version 1.1
//
#ifndef _HF_PROTOCOL_H_
#define _HF_PROTOCOL_H_
#define HF_PROTOCOL_VERSION ((0<<8)|1)
#define HF_PREAMBLE (uint8_t) 0xaa
#define HF_BROADCAST_ADDRESS (uint8_t) 0xff
#define HF_GWQ_ADDRESS (uint8_t) 254
// Serial protocol operation codes (Second header byte)
#define OP_NULL 0
#define OP_ROOT 1
#define OP_RESET 2
#define OP_PLL_CONFIG 3
#define OP_ADDRESS 4
#define OP_READDRESS 5
#define OP_HIGHEST 6
#define OP_BAUD 7
#define OP_UNROOT 8
#define OP_HASH 9
#define OP_NONCE 10
#define OP_ABORT 11
#define OP_STATUS 12
#define OP_GPIO 13
#define OP_CONFIG 14
#define OP_STATISTICS 15
#define OP_GROUP 16
#define OP_CLOCKGATE 17
// Conversions for the ADC readings from GN on-chip sensors
#define GN_CORE_VOLTAGE(a) ((float)(a)/256*1.2)
#define GN_DIE_TEMPERATURE(a) ((((float)(a)*240)/4096.0)-61.5)
// What to use in an OP_CONFIG hdata field to set thermal overload point to a given temp in degrees C
#define GN_THERMAL_CUTOFF(temp) ((uint16_t)(((temp)+61.5)*4096/240))
// The sequence distance between a sent and received sequence number.
#define HF_SEQUENCE_DISTANCE(tx,rx) ((tx)>=(rx)?((tx)-(rx)):(info->num_sequence+(tx)-(rx)))
// Values the protocol field in the above structure may take
#define PROTOCOL_USB_MAPPED_SERIAL 0
#define PROTOCOL_GLOBAL_WORK_QUEUE 1
// Conversions for the board/module level sensors
#define M_VOLTAGE(a) ((float)(a)*19.0734e-6)
#define M_PHASE_CURRENT(a) ((float)(a)*0.794728597e-3)
// Values info->device_type can take
#define HFD_G1 1 // HashFast G-1 GN ASIC
#define HFD_VC709 128
#define HFD_ExpressAGX 129
// USB interface specific operation codes
#define OP_USB_INIT 128 // Initialize USB interface details
#define OP_GET_TRACE 129 // Send back the trace buffer if present
#define OP_LOOPBACK_USB 130
#define OP_LOOPBACK_UART 131
#define OP_DFU 132 // Jump into the boot loader
#define OP_USB_SHUTDOWN 133 // Initialize USB interface details
#define OP_DIE_STATUS 134 // Die status. There are 4 die per ASIC
#define OP_GWQ_STATUS 135 // Global Work Queue protocol status
#define OP_WORK_RESTART 136 // Stratum work restart regime
#define OP_USB_STATS1 137 // Statistics class 1
#define OP_USB_GWQSTATS 138 // GWQ protocol statistics
#define OP_USB_NOTICE 139 // Asynchronous notification event
#define OP_PING 140 // Echo
#define OP_CORE_MAP 141 // Return core map
#define OP_VERSION 142 // Version information
#define OP_FAN 143 // Set Fan Speed
#define OP_NAME 144 // System name write/read
#define OP_USB_DEBUG 255
// HashFast vendor and product ID's
#define HF_USB_VENDOR_ID 0x297c
#define HF_USB_PRODUCT_ID_G1 0x0001
// If this bit is set, search forward for other nonce(s)
#define HF_NTIME_MASK 0xfff // Mask for for ntime
#define HF_NONCE_SEARCH 0x1000 // Search bit in candidate_nonce -> ntime
//
// Fault codes that can be returned in struct hf_usb_init_base.operation_status
//
#define E_RESET_TIMEOUT 1
#define E_ADDRESS_TIMEOUT 2
#define E_CLOCKGATE_TIMEOUT 3
#define E_CONFIG_TIMEOUT 4
#define E_EXCESS_CORE_FAILURES 5
#define E_TOTAL_CORE_FAILURES 6
#define E_TOO_MANY_GROUPS 7
#define E_NO_SLAVES 8
#define E_SLAVE_COMM 9
#define E_MAIN_POWER_BAD 10
#define E_SECONDARY_POWER_BAD 11
#define E_BOARD_1 12
#define E_BOARD_2 13
#define E_BOARD_3 14
#define E_BOARD_4 15
#define E_BOARD_5 16
#define E_CORE_POWER_FAULT 17
#define E_BAUD_TIMEOUT 18
#define E_ADDRESS_FAILURE 19
#define E_IR_PROG_FAILURE 20
#define E_MIXED_MISMATCH 21
#define E_MIXED_TIMEOUT 22
#define U32SIZE(x) (sizeof(x)/sizeof(uint32_t))
// Baud rate vs. code for gpi[7:5] coming out of reset
#define BAUD_RATE_PWRUP_0 115200
#define BAUD_RATE_PWRUP_1 9600
#define BAUD_RATE_PWRUP_2 38400
#define BAUD_RATE_PWRUP_3 57600
#define BAUD_RATE_PWRUP_4 230400
#define BAUD_RATE_PWRUP_5 576000
#define BAUD_RATE_PWRUP_6 921600
#define BAUD_RATE_PWRUP_7 1152000
// OP_WORK_RESTART hash clock change methods.
//
// May be issued *infrequently* by the host to adjust hash clock rate for thermal control
// The "hdata" field, if non zero, contains adjustment instructions. Bits 15:12 of "hdata"
// contain the adjustment type according to the following code, and bits 11:0 contain the
// associated value. Examples:
// hdata = (1<<12)|550 = Set hash clock rate to 550 Mhz
// hdata = (4<<12)|1 = Increase hash clock rate by 1%
// hdata = (6<<12) = Go back to whatever the "original" OP_USB_INIT settings were
//
// Finally, if 4 bytes of "data" follows the OP_WORK_RESTART header, then that data is taken
// as a little endian bitmap, bit set = enable clock change to that die, bit clear = don't
// change clock on that die, i.e. considered as a uint32_t, then 0x1 = die 0, 0x2 = die 1 etc.
#define WR_NO_CHANGE 0
#define WR_CLOCK_VALUE 1
#define WR_MHZ_INCREASE 2
#define WR_MHZ_DECREASE 3
#define WR_PERCENT_INCREASE 4
#define WR_PERCENT_DECREASE 5
#define WR_REVERT 6
#define WR_COMMAND_SHIFT 12
// Structure definitions, LE platforms
#if __BYTE_ORDER == __BIG_ENDIAN && !defined(WIN32)
#include "hf_protocol_be.h"
#else
// Generic header
struct hf_header {
uint8_t preamble; // Always 0xaa
uint8_t operation_code;
uint8_t chip_address;
uint8_t core_address;
uint16_t hdata; // Header specific data
uint8_t data_length; // .. of data frame to follow, in 4 byte blocks, 0=no data
uint8_t crc8; // Computed across bytes 1-6 inclusive
} __attribute__((packed,aligned(4))); // 8 bytes total
// Header specific to OP_PLL_CONFIG
struct hf_pll_config {
uint8_t preamble;
uint8_t operation_code;
uint8_t chip_address;
uint8_t pll_divr:6;
uint8_t pll_bypass:1;
uint8_t pll_reset:1;
uint8_t pll_divf;
uint8_t spare1:1; // Must always be 0
uint8_t pll_divq:3;
uint8_t pll_range:3;
uint8_t pll_fse:1; // Must always be 1
uint8_t data_length; // Always 0
uint8_t crc8; // Computed across bytes 1-6 inclusive
} __attribute__((packed,aligned(4))); // 8 bytes total
// OP_HASH serial data
struct hf_hash_serial {
uint8_t midstate[32]; // Computed from first half of block header
uint8_t merkle_residual[4]; // From block header
uint32_t timestamp; // From block header
uint32_t bits; // Actual difficulty target for block header
uint32_t starting_nonce; // Usually set to 0
uint32_t nonce_loops; // How many nonces to search, or 0 for 2^32
uint16_t ntime_loops; // How many times to roll timestamp, or 0
uint8_t search_difficulty; // Search difficulty to use, # of '0' digits required
uint8_t option;
uint8_t group;
uint8_t spare3[3];
} __attribute__((packed,aligned(4)));
// OP_HASH usb data - header+data = 64 bytes
struct hf_hash_usb {
uint8_t midstate[32]; // Computed from first half of block header
uint8_t merkle_residual[4]; // From block header
uint32_t timestamp; // From block header
uint32_t bits; // Actual difficulty target for block header
uint32_t starting_nonce; // Usually set to 0
uint32_t nonce_loops; // How many nonces to search, or 0 for 2^32
uint16_t ntime_loops; // How many times to roll timestamp, or 0
uint8_t search_difficulty; // Search difficulty to use, # of '0' digits required
uint8_t group; // Non-zero for valid group
} __attribute__((packed,aligned(4)));
// OP_NONCE data
struct hf_candidate_nonce {
uint32_t nonce; // Candidate nonce
uint16_t sequence; // Sequence number from corresponding OP_HASH
uint16_t ntime; // ntime offset, if ntime roll occurred, in LS 12 bits
// If b12 set, search forward next 128 nonces to find solution(s)
} __attribute__((packed,aligned(4)));
// OP_CONFIG data
struct hf_config_data {
uint16_t status_period:11; // Periodic status time, msec
uint16_t enable_periodic_status:1; // Send periodic status
uint16_t send_status_on_core_idle:1; // Schedule status whenever core goes idle
uint16_t send_status_on_pending_empty:1; // Schedule status whenever core pending goes idle
uint16_t pwm_active_level:1; // Active level of PWM outputs, if used
uint16_t forward_all_privileged_packets:1; // Forward priv pkts -- diagnostic
uint8_t status_batch_delay; // Batching delay, time to wait before sending status
uint8_t watchdog:7; // Watchdog timeout, seconds
uint8_t disable_sensors:1; // Diagnostic
uint8_t rx_header_timeout:7; // Header timeout in char times
uint8_t rx_ignore_header_crc:1; // Ignore rx header crc's (diagnostic)
uint8_t rx_data_timeout:7; // Data timeout in char times / 16
uint8_t rx_ignore_data_crc:1; // Ignore rx data crc's (diagnostic)
uint8_t stats_interval:7; // Minimum interval to report statistics (seconds)
uint8_t stat_diagnostic:1; // Never set this
uint8_t measure_interval; // Die temperature measurement interval (msec)
uint32_t one_usec:12; // How many LF clocks per usec.
uint32_t max_nonces_per_frame:4; // Maximum # of nonces to combine in a single frame
uint32_t voltage_sample_points:8; // Bit mask for sample points (up to 5 bits set)
uint32_t pwm_phases:2; // phases - 1
uint32_t trim:4; // Trim value for temperature measurements
uint32_t clock_diagnostic:1; // Never set this
uint32_t forward_all_packets:1; // Forward everything - diagnostic.
uint16_t pwm_period; // Period of PWM outputs, in reference clock cycles
uint16_t pwm_pulse_period; // Initial count, phase 0
} __attribute__((packed,aligned(4)));
// OP_GROUP data
struct hf_group_data {
uint16_t nonce_msoffset; // This value << 16 added to starting nonce
uint16_t ntime_offset; // This value added to timestamp
} __attribute__((packed,aligned(4)));
// Structure of the monitor fields for G-1, returned in OP_STATUS, core bitmap follows this
struct hf_g1_monitor {
uint16_t die_temperature; // Die temperature ADC count
uint8_t core_voltage[6]; // Core voltage
// [0] = main sensor
// [1]-[5] = other positions
} __attribute__((packed,aligned(4)));
// What comes back in the body of an OP_STATISTICS frame (On die statistics)
struct hf_statistics {
uint8_t rx_header_crc; // Header CRC error's
uint8_t rx_body_crc; // Data CRC error's
uint8_t rx_header_timeouts; // Header timeouts
uint8_t rx_body_timeouts; // Data timeouts
uint8_t core_nonce_fifo_full; // Core nonce Q overrun events
uint8_t array_nonce_fifo_full; // System nonce Q overrun events
uint8_t stats_overrun; // Overrun in statistics reporting
uint8_t spare;
} __attribute__((packed,aligned(4)));
////////////////////////////////////////////////////////////////////////////////
// USB protocol data structures
////////////////////////////////////////////////////////////////////////////////
// Convenience header specific to OP_USB_INIT
struct hf_usb_init_header {
uint8_t preamble; // Always 0xaa
uint8_t operation_code;
uint8_t spare1;
uint8_t protocol:3; // Which protocol to use
uint8_t user_configuration:1; // Use the following configuration data
uint8_t pll_bypass:1; // Force PLL bypass, hash clock = ref clock
uint8_t no_asic_initialization:1; // Do not perform automatic ASIC initialization
uint8_t do_atspeed_core_tests:1; // Do core tests at speed, return second bitmap
uint8_t shed_supported:1; // Host supports gwq status shed_count
uint16_t hash_clock; // Requested hash clock frequency
uint8_t data_length; // .. of data frame to follow, in 4 byte blocks
uint8_t crc8; // Computed across bytes 1-6 inclusive
} __attribute__((packed,aligned(4))); // 8 bytes total
// Options (only if present) that may be appended to the above header
// Each option involving a numerical value will only be in effect if the value is non-zero
// This allows the user to select only those options desired for modification. Do not
// use this facility unless you are an expert - loading inconsistent settings will not work.
struct hf_usb_init_options {
uint16_t group_ntime_roll; // Total ntime roll amount per group
uint16_t core_ntime_roll; // Total core ntime roll amount
uint8_t low_operating_temp_limit; // Lowest normal operating limit
uint8_t high_operating_temp_limit; // Highest normal operating limit
uint16_t spare;
} __attribute__((packed,aligned(4)));
// Base item returned from device for OP_USB_INIT
struct hf_usb_init_base {
uint16_t firmware_rev; // Firmware revision #
uint16_t hardware_rev; // Hardware revision #
uint32_t serial_number; // Board serial number
uint8_t operation_status; // Reply status for OP_USB_INIT (0 = success)
uint8_t extra_status_1; // Extra reply status information, code specific
uint16_t sequence_modulus; // Sequence numbers are to be modulo this
uint16_t hash_clockrate; // Actual hash clock rate used (nearest Mhz)
uint16_t inflight_target; // Target inflight amount for GWQ protocol
} __attribute__((packed,aligned(4)));
// The above base item (16 bytes) is followed by the struct hf_config_data (16 bytes) actually
// used internally (so users may modify non-critical fields by doing subsequent
// OP_CONFIG operations). This is followed by a device specific "core good" bitmap (unless the
// user disabled initialization), and optionally by an at-speed "core good" bitmap.
// Information in an OP_DIE_STATUS frame. This is for one die - there are four per ASIC.
// Board level phase current and voltage sensors are likely to disappear in later production models.
struct hf_g1_die_data {
struct hf_g1_monitor die; // Die sensors - 8 bytes
uint16_t phase_currents[4]; // Phase currents (0 if unavailable)
uint16_t voltage; // Voltage at device boundary (0 if unavailable)
uint16_t temperature; // Regulator temp sensor
uint16_t tacho; // See documentation
uint16_t spare;
} __attribute__((packed,aligned(4))); // 24 bytes total
// Information for an OP_GWQ_STATUS frame
// If sequence_head == sequence_tail, then there is no active work and sequence_head is invalid
struct hf_gwq_data {
uint64_t hash_count; // Add this to host's cumulative hash count
uint16_t sequence_head; // The latest, internal, active sequence #
uint16_t sequence_tail; // The latest, internal, inactive sequence #
uint16_t shed_count; // # of cores have been shedded for thermal control
uint16_t spare;
} __attribute__((packed,aligned(4)));
// Information for an OP_USB_STATS1 frame - Communication statistics
struct hf_usb_stats1 {
// USB incoming
uint16_t usb_rx_preambles;
uint16_t usb_rx_receive_byte_errors;
uint16_t usb_rx_bad_hcrc;
// USB outgoing
uint16_t usb_tx_attempts;
uint16_t usb_tx_packets;
uint16_t usb_tx_timeouts;
uint16_t usb_tx_incompletes;
uint16_t usb_tx_endpointstalled;
uint16_t usb_tx_disconnected;
uint16_t usb_tx_suspended;
// Internal UART transmit
uint16_t uart_tx_queue_dma;
uint16_t uart_tx_interrupts;
// Internal UART receive
uint16_t uart_rx_preamble_ints;
uint16_t uart_rx_missed_preamble_ints;
uint16_t uart_rx_header_done;
uint16_t uart_rx_data_done;
uint16_t uart_rx_bad_hcrc;
//uint16_t uart_rx_bad_crc32;
uint16_t uart_rx_bad_dma;
uint16_t uart_rx_short_dma;
uint16_t uart_rx_buffers_full;
uint8_t max_tx_buffers; // Maximum # of send buffers ever used
uint8_t max_rx_buffers; // Maximum # of receive buffers ever used
} __attribute__((packed,aligned(4)));
// Information for an OP_USB_NOTICE frame
struct hf_usb_notice_data {
uint32_t extra_data; // Depends on notification code
char message[]; // NULL terminated, little endian byte order
};
#endif
#endif