thodg/cgminer/driver-hashfast.h

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• Hash : 45c8d607
  Author :
  Date : 2013-09-19T17:34:26
  

  Add crc initialisation tables and helper functions for hashfast driver.

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• driver-hashfast.h

• /*
   * Copyright 2013 Con Kolivas <kernel@kolivas.org>
   * Copyright 2013 Hashfast
   *
   * 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.
   */
  
  #ifndef HASHFAST_H
  #define HASHFAST_H
  
  #ifdef USE_HASHFAST
  #include "miner.h"
  #include "elist.h"
  
  #define HASHFAST_MINER_THREADS      1
  
  // Some serial protocol definitions
  #define DEFAULT_BAUD_RATE	    115200
  
  #define HF_PREAMBLE             (uint8_t) 0xaa
  #define HF_BROADCAST_ADDRESS    (uint8_t) 0xff
  
  // Operation codes (Second header byte)
  #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
  
  // All packets begin with a standard 8 byte 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
  
  // Body of packet for an OP_HASH operation
  struct hf_hash {
  	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:12;                // How many times to roll timestamp, or 0
  	uint16_t spare1:4;
  	uint8_t  search_difficulty;             // Search difficulty to use, number of leading '0' bits required
  	uint8_t  spare2;
  	uint32_t spare3;
  	uint32_t crc32;                         // Computed across all preceding data fields
  } __attribute__((packed,aligned(4)));           // 64 bytes total, including CRC
  
  // How nonces are returned in OP_NONCE packets
  struct hf_candidate_nonce {
  	uint32_t nonce;                         // Candidate nonce
  	uint16_t sequence;                      // Sequence number from corresponding OP_HASH
  	uint16_t ntime:12;                      // ntime offset, if ntime roll occurred
  	uint16_t search:1;                      // Search forward next 128 nonces to find solution
  	uint16_t spare:3;
  } __attribute__((packed,aligned(4)));
  
  // Body of packet for an OP_CONFIG operation
  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 actually 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 measurment 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)));
  
  // What comes back in the body of an OP_STATISTICS frame
  struct hf_statistics {
  	uint8_t rx_header_crc;                      // Header CRC's
  	uint8_t rx_body_crc;                        // Data CRC'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)));
  
  
  // Not really necessary (could just link directly to CGMiner's work structures), but these are
  // here as an internal place to stage split jobs in the future, e.g. ntime rolling across
  // multiple cores.
  typedef struct hf_work_t {
  	struct work     *work;                      // Finally out to cgminer's work
  
  	uint8_t         data[128];                  // XXX These are only replicated here to help de-couple the
  	uint8_t         midstate[32];               // XXX driver code from cgminer's specifics, since this is
  	uint8_t         target[32];                 // XXX a sample driver. There's no other reason.
  
  	int             split_count;                // How many cores this is split between
  } hf_work_t;
  
  // Internal representation of a "job". Each core should normally have one active job and one pending job queued to it.
  // This is where the ALL IMPORTANT sequence number is kept. When jobs are created, this structure is put in the "active"
  // list (unique to the asic/core), and an incrementing sequence number is assigned to the job. Only when a sequence number
  // that matches or exceeds (modulo <max sequence>) this number in a returned OP_STATUS, do we know that the "busy" bits
  // associated with this same core represent the job status, i.e. the associated OP_HASH is no longer in flight.
  typedef struct hf_job_t {
  	struct list_head l;
  
  	uint8_t chip;                               // Chip address
  	uint8_t core;                               // Core address
  	uint16_t sequence;                          // Copy of the active sequence number
  
  	hf_work_t *work;                            // Pointer to the work block
  
  } hf_job_t;
  
  // Per-core structure
  typedef struct hf_core_t {
  	hf_job_t *active;                           // Active job on this core, NULL if none
  	hf_job_t *pending;                          // Pending job on this core, NULL if none
  	uint8_t enabled;                            // 1 = enabled, 0 = disabled
  	uint8_t inflight;                           // How many jobs are "inflight": 0, 1 or 2
  	uint8_t seen_allbusy;                       // We've seen both active and pending queues busy
  } hf_core_t;                                        // since the last OP_HASH was queued
  
  // Per device structure. This is found by looking up an array, which is indexed
  // by CGMiner's cgpu_info.device_id field.
  typedef struct hf_info_t {
  	int miner_count;
  	int timeout;
  	int baud_rate;                          // Baud rate, if applicable
  	int ref_frequency;                      // Reference clock rate
  	int asic_count;                         // # of chips in the chain
  	int core_count;                         // # of cores per chip
  	int device_type;                        // What sort of device this is
  	int max_search_difficulty;              // # of bits set to 0 in hash
  	int inflight_target;                    // Set to chips * cores * 2 (1 active, 1 pending each core)
  	int hash_sequence;                      // The last hash sequence #
  	int num_sequence;                       // A power of 2. What the sequence number range is.
  	int num_work;                           // Number of "work" entries in work queue
  	int max_work;                           // Target maximum number of "work" entries in work queue
  						// If work is split between cores, then max_work < inflight_target.
  	int last_log;                           // Last OP_STATUS log time in seconds
  
  	float thermal_trip_temperature;         // Thermal trip temperature in degrees C
  	int thermal_trip_limit;                 // Thermal trip limit in raw device adc counts (derived from above)
  	int tacho_enable;                       // Set if there is a tacho to be read
  
  	uint64_t hash_loops;                    // XXX Temp. How many nonces to cycle through (range limited for FPGA emulation)
  
  	int no_matching_work;
  
  	struct list_head active;                  // Double linked list through all ACTIVE in-flight jobs (hf_job_t's)
  	struct list_head inactive;                // Double linked list through all INACTIVE job blocks (hf_job_t's)
  
  	int active_count;                       // How many active hf_job_t's are out there
  	int inactive_count;                     // How many inactive hf_job_t's are out there
  
  	hf_core_t **cores;                      // Points to array of chips, which each point to array of cores
  	hf_work_t *work;                        // Points to array of work
  } hf_info_t;
  
  // The sequence distance between a sent and received sequence number.
  #define SEQUENCE_DISTANCE(tx,rx)        ((tx)>=(rx)?((tx)-(rx)):(info->num_sequence+(tx)-(rx)))
  
  // Values info->device_type can take, comes from a completed OP_ADDRESS cycle
  #define HFD_G1                          1       /* A real G-1 ASIC */
  #define HFD_VC709                       128     /* FPGA Emulation */
  #define HFD_ExpressAGX                  129     /* FPGA Emulation */
  
  // Some USB defines
  #define HASHFAST_USB_PACKETSIZE         512     /* XXX Fix this. */
  
  // Some low level serial defines
  #define HASHFAST_READ_TIME(baud) ((double)HASHFAST_READ_SIZE * (double)8.0 / (double)(baud))
  
  #define ASSERT1(condition) __maybe_unused static char sizeof_uint32_t_must_be_4[(condition)?1:-1]
  ASSERT1(sizeof(uint32_t) == 4);
  
  hf_info_t **hashfast_info;
  
  void hf_init_crc8(void);
  void hf_init_crc32(void);
  
  #endif /* USE_HASHFAST */
  #endif	/* HASHFAST_H */
  

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