forked from bitmaintech/bmminer-mix
-
Notifications
You must be signed in to change notification settings - Fork 0
/
hf_protocol_be.h
283 lines (244 loc) · 12.9 KB
/
hf_protocol_be.h
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
//
// 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.
//
// Big endian versions of packed structures
//
// Version 1.0
//
#ifndef _HF_PROTOCOL_BE_H_
#define _HF_PROTOCOL_BE_H_
// 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_reset:1;
uint8_t pll_bypass:1;
uint8_t pll_divr:6;
uint8_t pll_divf;
uint8_t pll_fse:1; // Must always be 1
uint8_t pll_range:3;
uint8_t pll_divq:3;
uint8_t spare1:1; // Must always be 0
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
// This is usually internal data only, for serial drivers only
// Users shouldn't normally need to interpret this, but in the event a Big Endian
// user requires access to this data, the following structure will get all
// the fields in the right place, but byte swaps will be required for the
// uint16_t's and the uint32_t.
struct hf_config_data
{
uint16_t forward_all_privileged_packets:1; // Forward priv pkts -- diagnostic
uint16_t pwm_active_level:1; // Active level of PWM outputs, if used
uint16_t send_status_on_pending_empty:1; // Schedule status whenever core pending goes idle
uint16_t send_status_on_core_idle:1; // Schedule status whenever core goes idle
uint16_t enable_periodic_status:1; // Send periodic status
uint16_t status_period:11; // Periodic status time, msec
uint8_t status_batch_delay; // Batching delay, time to wait before sending status
uint8_t disable_sensors:1; // Diagnostic
uint8_t watchdog:7; // Watchdog timeout, seconds
uint8_t rx_ignore_header_crc:1; // Ignore rx header crc's (diagnostic)
uint8_t rx_header_timeout:7; // Header timeout in char times
uint8_t rx_ignore_data_crc:1; // Ignore rx data crc's (diagnostic)
uint8_t rx_data_timeout:7; // Data timeout in char times / 16
uint8_t stat_diagnostic:1; // Never set this
uint8_t stats_interval:7; // Minimum interval to report statistics (seconds)
uint8_t measure_interval; // Die temperature measurement interval (msec)
uint32_t forward_all_packets:1; // Forward everything - diagnostic.
uint32_t clock_diagnostic:1; // Never set this
uint32_t trim:4; // Trim value for temperature measurements
uint32_t pwm_phases:2; // phases - 1
uint32_t voltage_sample_points:8; // Bit mask for sample points (up to 5 bits set)
uint32_t max_nonces_per_frame:4; // Maximum # of nonces to combine in a single frame
uint32_t one_usec:12; // How many LF clocks per usec.
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 shed_supported:1; // Host supports gwq status shed_count
uint8_t do_atspeed_core_tests:1; // Do core tests at speed, return second bitmap
uint8_t no_asic_initialization:1; // Do not perform automatic ASIC initialization
uint8_t pll_bypass:1; // Force PLL bypass, hash clock = ref clock
uint8_t user_configuration:1; // Use the following configuration data
uint8_t protocol:3; // Which protocol to use
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