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sgminer/driver-knc-spi-fpga.c

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/* cgminer driver for KnCminer Jupiter */
#include <stdlib.h>
#include <assert.h>
#include <fcntl.h>
#include <limits.h>
#include <unistd.h>
#include <sys/ioctl.h>
#include <linux/types.h>
#include <linux/spi/spidev.h>
#include "logging.h"
#include "miner.h"
#define MAX_SPIS 1
#define MAX_BYTES_IN_SPI_XSFER 4096
/* /dev/spidevB.C, where B = bus, C = chipselect */
#define SPI_DEVICE_TEMPLATE "/dev/spidev%d.%d"
#define SPI_MODE (SPI_CPHA | SPI_CPOL | SPI_CS_HIGH)
#define SPI_BITS_PER_WORD 32
#define SPI_MAX_SPEED 3000000
#define SPI_DELAY_USECS 0
/* Max number of ASICs permitted on one SPI device */
#define MAX_ASICS 6
/* How many hardware errors in a row before disabling the core */
#define HW_ERR_LIMIT 10
#define DISA_ERR_LIMIT 3
#define MAX_ACTIVE_WORKS (192 * 2 * 6 * 2)
#define WORK_MIDSTATE_WORDS 8
#define WORK_DATA_WORDS 3
#define WORK_STALE_US 60000000
/* Keep core disabled for no longer than 15 minutes */
#define CORE_DISA_PERIOD_US (15 * 60 * 1000000)
struct spidev_context {
int fd;
uint32_t speed;
uint16_t delay;
uint8_t mode;
uint8_t bits;
};
struct spi_request {
#define CMD_NOP 0
#define CMD_GET_VERSION 1
#define CMD_SUBMIT_WORK 2
#define CMD_FLUSH_QUEUE 3
#define WORK_ID_MASK 0x7FFF
#if (__BYTE_ORDER__ == __ORDER_BIG_ENDIAN__)
uint32_t cmd :4;
uint32_t rsvd :1; /* set to zero */
uint32_t queue_id :12;
uint32_t work_id :15;
#else
uint32_t work_id :15;
uint32_t queue_id :12;
uint32_t rsvd :1; /* set to zero */
uint32_t cmd :4;
#endif
uint32_t midstate[WORK_MIDSTATE_WORDS];
uint32_t data[WORK_DATA_WORDS];
};
struct spi_response {
#define RESPONSE_TYPE_NOP 0
#define RESPONSE_TYPE_NONCE_FOUND 1
#define RESPONSE_TYPE_WORK_DONE 2
#if (__BYTE_ORDER__ == __ORDER_BIG_ENDIAN__)
uint32_t type :2;
uint32_t asic :3;
uint32_t queue_id :12;
uint32_t work_id :15;
#else
uint32_t work_id :15;
uint32_t queue_id :12;
uint32_t asic :3;
uint32_t type :2;
#endif
uint32_t nonce;
uint32_t core;
};
#define MAX_REQUESTS_IN_BATCH ( MAX_BYTES_IN_SPI_XSFER / \
sizeof(struct spi_request) \
)
static struct spi_request spi_txbuf[MAX_REQUESTS_IN_BATCH];
#define MAX_RESPONSES_IN_BATCH ( (sizeof(spi_txbuf) - 12) / \
sizeof(struct spi_response) \
)
struct spi_rx_t {
#if (__BYTE_ORDER__ == __ORDER_BIG_ENDIAN__)
uint32_t rsvd_1 :31;
uint32_t response_queue_full :1;
#else
uint32_t response_queue_full :1;
uint32_t rsvd_1 :31;
#endif
#if (__BYTE_ORDER__ == __ORDER_BIG_ENDIAN__)
uint32_t rsvd_2 :16;
uint32_t works_accepted :16;
#else
uint32_t works_accepted :16;
uint32_t rsvd_2 :16;
#endif
uint32_t rsvd_3;
struct spi_response responses[MAX_RESPONSES_IN_BATCH];
};
static struct spi_rx_t spi_rxbuf;
struct device_drv knc_drv;
struct active_work {
struct work *work;
uint32_t work_id;
struct timeval begin;
};
struct core_disa_data {
struct timeval disa_begin;
uint8_t asic;
uint8_t core;
};
struct knc_state {
struct spidev_context *ctx;
int devices;
uint32_t salt;
uint32_t next_work_id;
/* read - last read item, next is at (read + 1) mod BUFSIZE
* write - next write item, last written at (write - 1) mod BUFSIZE
* When buffer is empty, read + 1 == write
* Buffer full condition: read == write
*/
int read_q, write_q;
#define KNC_QUEUED_BUFFER_SIZE (MAX_REQUESTS_IN_BATCH + 1)
struct active_work queued_fifo[KNC_QUEUED_BUFFER_SIZE];
int read_a, write_a;
#define KNC_ACTIVE_BUFFER_SIZE (MAX_ACTIVE_WORKS + 1)
struct active_work active_fifo[KNC_ACTIVE_BUFFER_SIZE];
uint8_t hwerrs[MAX_ASICS * 256];
uint8_t disa_cnt[MAX_ASICS * 256];
uint32_t hwerr_work_id[MAX_ASICS * 256];
int read_d, write_d;
#define KNC_DISA_CORES_SIZE (MAX_ASICS * 256)
struct core_disa_data disa_cores_fifo[KNC_DISA_CORES_SIZE];
};
static inline bool knc_queued_fifo_full(struct knc_state *knc)
{
return (knc->read_q == knc->write_q);
}
static inline bool knc_active_fifo_full(struct knc_state *knc)
{
return (knc->read_a == knc->write_a);
}
static inline void knc_queued_fifo_inc_idx(int *idx)
{
if (unlikely(*idx >= ((int)KNC_QUEUED_BUFFER_SIZE - 1)))
*idx = 0;
else
++(*idx);
}
static inline void knc_active_fifo_inc_idx(int *idx)
{
if (unlikely(*idx >= (KNC_ACTIVE_BUFFER_SIZE - 1)))
*idx = 0;
else
++(*idx);
}
static inline void knc_disa_cores_fifo_inc_idx(int *idx)
{
if (unlikely(*idx >= (KNC_DISA_CORES_SIZE - 1)))
*idx = 0;
else
++(*idx);
}
/* Find SPI device with index idx, init it */
static struct spidev_context * spi_new(int idx)
{
struct spidev_context *ctx;
char dev_fname[PATH_MAX];
if(NULL == (ctx = malloc(sizeof(struct spidev_context)))) {
applog(LOG_ERR, "KnC spi: Out of memory");
goto l_exit_error;
}
ctx->mode = SPI_MODE;
ctx->bits = SPI_BITS_PER_WORD;
ctx->speed = SPI_MAX_SPEED;
ctx->delay = SPI_DELAY_USECS;
ctx->fd = -1;
sprintf(dev_fname, SPI_DEVICE_TEMPLATE,
idx, /* bus */
0 /* chipselect */
);
if (0 > (ctx->fd = open(dev_fname, O_RDWR))) {
applog(LOG_ERR, "KnC spi: Can not open SPI device %s: %m",
dev_fname);
goto l_free_exit_error;
}
/*
* spi mode
*/
if (0 > ioctl(ctx->fd, SPI_IOC_WR_MODE, &ctx->mode))
goto l_ioctl_error;
if (0 > ioctl(ctx->fd, SPI_IOC_RD_MODE, &ctx->mode))
goto l_ioctl_error;
/*
* bits per word
*/
if (0 > ioctl(ctx->fd, SPI_IOC_WR_BITS_PER_WORD, &ctx->bits))
goto l_ioctl_error;
if (0 > ioctl(ctx->fd, SPI_IOC_RD_BITS_PER_WORD, &ctx->bits))
goto l_ioctl_error;
/*
* max speed hz
*/
if (0 > ioctl(ctx->fd, SPI_IOC_WR_MAX_SPEED_HZ, &ctx->speed))
goto l_ioctl_error;
if (0 > ioctl(ctx->fd, SPI_IOC_RD_MAX_SPEED_HZ, &ctx->speed))
goto l_ioctl_error;
applog(LOG_INFO, "KnC spi: device %s uses mode %hhu, bits %hhu, speed %u",
dev_fname, ctx->mode, ctx->bits, ctx->speed);
return ctx;
l_ioctl_error:
applog(LOG_ERR, "KnC spi: ioctl error on SPI device %s: %m", dev_fname);
// l_close_free_exit_error:
close(ctx->fd);
l_free_exit_error:
free(ctx);
l_exit_error:
return NULL;
}
static void spi_free(struct spidev_context *ctx)
{
if (NULL == ctx)
return;
close(ctx->fd);
free(ctx);
}
static int spi_transfer(struct spidev_context *ctx, uint8_t *txbuf,
uint8_t *rxbuf, int len)
{
int ret;
struct spi_ioc_transfer xfr;
memset(rxbuf, 0xff, len);
ret = len;
xfr.tx_buf = (unsigned long)txbuf;
xfr.rx_buf = (unsigned long)rxbuf;
xfr.len = len;
xfr.speed_hz = ctx->speed;
xfr.delay_usecs = ctx->delay;
xfr.bits_per_word = ctx->bits;
xfr.cs_change = 0;
xfr.pad = 0;
if (1 > (ret = ioctl(ctx->fd, SPI_IOC_MESSAGE(1), &xfr))) {
applog(LOG_ERR, "KnC spi xfer: ioctl error on SPI device: %m");
}
return ret;
}
static void disable_core(uint8_t asic, uint8_t core)
{
char str[256];
snprintf(str, sizeof(str), "i2cset -y 2 0x2%hhu %hhu 0", asic, core);
if (0 != WEXITSTATUS(system(str)))
applog(LOG_ERR, "KnC: system call failed");
}
static void enable_core(uint8_t asic, uint8_t core)
{
char str[256];
snprintf(str, sizeof(str), "i2cset -y 2 0x2%hhu %hhu 1", asic, core);
if (0 != WEXITSTATUS(system(str)))
applog(LOG_ERR, "KnC: system call failed");
}
static int64_t timediff(const struct timeval *a, const struct timeval *b)
{
struct timeval diff;
timersub(a, b, &diff);
return diff.tv_sec * 1000000 + diff.tv_usec;
}
static void knc_check_disabled_cores(struct knc_state *knc)
{
int next_read_d;
struct timeval now;
int64_t us;
struct core_disa_data *core;
int cidx;
next_read_d = knc->read_d;
knc_disa_cores_fifo_inc_idx(&next_read_d);
if (next_read_d == knc->write_d)
return; /* queue empty */
core = &knc->disa_cores_fifo[next_read_d];
gettimeofday(&now, NULL);
us = timediff(&now, &core->disa_begin);
if ((us >= 0) && (us < CORE_DISA_PERIOD_US))
return; /* latest disabled core still not expired */
cidx = core->asic * 256 + core->core;
enable_core(core->asic, core->core);
knc->hwerrs[cidx] = 0;
applog(LOG_NOTICE,
"KnC: core %u-%u was enabled back from disabled state",
core->asic, core->core);
knc->read_d = next_read_d;
}
static void knc_work_from_queue_to_spi(struct knc_state *knc,
struct active_work *q_work,
struct spi_request *spi_req)
{
uint32_t *buf_from, *buf_to;
int i;
spi_req->cmd = CMD_SUBMIT_WORK;
spi_req->queue_id = 0; /* at the moment we have one and only queue #0 */
spi_req->work_id = (knc->next_work_id ^ knc->salt) & WORK_ID_MASK;
q_work->work_id = spi_req->work_id;
++(knc->next_work_id);
buf_to = spi_req->midstate;
buf_from = (uint32_t *)q_work->work->midstate;
for (i = 0; i < WORK_MIDSTATE_WORDS; ++i)
buf_to[i] = le32toh(buf_from[8 - i - 1]);
buf_to = spi_req->data;
buf_from = (uint32_t *)&(q_work->work->data[16 * 4]);
for (i = 0; i < WORK_DATA_WORDS; ++i)
buf_to[i] = le32toh(buf_from[3 - i - 1]);
}
static int64_t knc_process_response(struct thr_info *thr, struct cgpu_info *cgpu,
struct spi_rx_t *rxbuf, int __maybe_unused num)
{
struct knc_state *knc = cgpu->knc_state;
struct work *work;
int64_t us;
int submitted, completed, i, num_sent;
int next_read_q, next_read_a;
struct timeval now;
if (knc->write_q > knc->read_q)
num_sent = knc->write_q - knc->read_q - 1;
else
num_sent =
knc->write_q + KNC_QUEUED_BUFFER_SIZE - knc->read_q - 1;
/* Actually process SPI response */
if (rxbuf->works_accepted) {
applog(LOG_DEBUG, "KnC spi: raw response %08X %08X",
((uint32_t *)rxbuf)[0], ((uint32_t *)rxbuf)[1]);
applog(LOG_DEBUG,
"KnC spi: response, accepted %u (from %u), full %u",
rxbuf->works_accepted, num_sent,
rxbuf->response_queue_full);
}
/* move works_accepted number of items from queued_fifo to active_fifo */
gettimeofday(&now, NULL);
submitted = 0;
for (i = 0; i < rxbuf->works_accepted; ++i) {
next_read_q = knc->read_q;
knc_queued_fifo_inc_idx(&next_read_q);
if ((next_read_q == knc->write_q) || knc_active_fifo_full(knc))
break;
memcpy(&knc->active_fifo[knc->write_a],
&knc->queued_fifo[next_read_q],
sizeof(struct active_work));
knc->active_fifo[knc->write_a].begin = now;
knc->queued_fifo[next_read_q].work = NULL;
knc->read_q = next_read_q;
knc_active_fifo_inc_idx(&knc->write_a);
++submitted;
}
if (submitted != rxbuf->works_accepted)
applog(LOG_ERR,
"KnC: accepted by FPGA %u works, but only %d submitted",
rxbuf->works_accepted, submitted);
/* check for completed works and calculated nonces */
gettimeofday(&now, NULL);
completed = 0;
for (i = 0; i < (int)MAX_RESPONSES_IN_BATCH; ++i)
{
if ( (rxbuf->responses[i].type != RESPONSE_TYPE_NONCE_FOUND) &&
(rxbuf->responses[i].type != RESPONSE_TYPE_WORK_DONE)
)
continue;
applog(LOG_DEBUG, "KnC spi: raw response %08X %08X",
((uint32_t *)&rxbuf->responses[i])[0],
((uint32_t *)&rxbuf->responses[i])[1]);
applog(LOG_DEBUG, "KnC spi: response, T:%u C:%u-%u Q:%u W:%u",
rxbuf->responses[i].type,
rxbuf->responses[i].asic, rxbuf->responses[i].core,
rxbuf->responses[i].queue_id,
rxbuf->responses[i].work_id);
/* Find active work with matching ID */
next_read_a = knc->read_a;
knc_active_fifo_inc_idx(&next_read_a);
while (next_read_a != knc->write_a) {
if (knc->active_fifo[next_read_a].work_id ==
rxbuf->responses[i].work_id)
break;
/* check for stale works */
us = timediff(&now,
&knc->active_fifo[next_read_a].begin);
if ((us < 0) || (us >= WORK_STALE_US)) {
applog(LOG_DEBUG,
"KnC spi: remove stale work %u",
knc->active_fifo[next_read_a].work_id);
work = knc->active_fifo[next_read_a].work;
knc_active_fifo_inc_idx(&knc->read_a);
work_completed(cgpu, work);
if (next_read_a != knc->read_a)
memcpy(&(knc->active_fifo[next_read_a]),
&(knc->active_fifo[knc->read_a]),
sizeof(struct active_work));
knc->active_fifo[knc->read_a].work = NULL;
}
knc_active_fifo_inc_idx(&next_read_a);
}
if (next_read_a == knc->write_a)
continue;
applog(LOG_DEBUG, "KnC spi: response work %u found",
rxbuf->responses[i].work_id);
work = knc->active_fifo[next_read_a].work;
if (rxbuf->responses[i].type == RESPONSE_TYPE_NONCE_FOUND) {
if (NULL != thr) {
int cidx = rxbuf->responses[i].asic * 256 +
rxbuf->responses[i].core;
if (submit_nonce(thr, work,
rxbuf->responses[i].nonce)) {
if (cidx < (int)sizeof(knc->hwerrs)) {
knc->hwerrs[cidx] = 0;
knc->disa_cnt[cidx] = 0;
knc->hwerr_work_id[cidx] = 0xFFFFFFFF;
}
} else {
if ((cidx < (int)sizeof(knc->hwerrs)) &&
(knc->hwerr_work_id[cidx] != rxbuf->responses[i].work_id)) {
knc->hwerr_work_id[cidx] = rxbuf->responses[i].work_id;
if (++(knc->hwerrs[cidx]) >= HW_ERR_LIMIT) {
struct core_disa_data *core;
core = &knc->disa_cores_fifo[knc->write_d];
core->disa_begin = now;
core->asic = rxbuf->responses[i].asic;
core->core = rxbuf->responses[i].core;
disable_core(core->asic, core->core);
if (++(knc->disa_cnt[cidx]) >= DISA_ERR_LIMIT) {
applog(LOG_WARNING,
"KnC: core %u-%u was disabled permanently", core->asic, core->core);
} else {
applog(LOG_WARNING,
"KnC: core %u-%u was disabled due to %u HW errors in a row",
core->asic, core->core, HW_ERR_LIMIT);
knc_disa_cores_fifo_inc_idx(&knc->write_d);
}
}
}
};
}
continue;
}
/* Work completed */
knc_active_fifo_inc_idx(&knc->read_a);
work_completed(cgpu, work);
if (next_read_a != knc->read_a)
memcpy(&(knc->active_fifo[next_read_a]),
&(knc->active_fifo[knc->read_a]),
sizeof(struct active_work));
knc->active_fifo[knc->read_a].work = NULL;
++completed;
}
return ((uint64_t)completed) * 0x100000000UL;
}
/* Send flush command via SPI */
static int _internal_knc_flush_fpga(struct knc_state *knc)
{
int len;
spi_txbuf[0].cmd = CMD_FLUSH_QUEUE;
spi_txbuf[0].queue_id = 0; /* at the moment we have one and only queue #0 */
len = spi_transfer(knc->ctx, (uint8_t *)spi_txbuf,
(uint8_t *)&spi_rxbuf, sizeof(struct spi_request));
if (len != sizeof(struct spi_request))
return -1;
len /= sizeof(struct spi_response);
return len;
}
static bool knc_detect_one(struct spidev_context *ctx)
{
/* Scan device for ASICs */
int chip_id;
int devices = 0;
for (chip_id = 0; chip_id < MAX_ASICS; ++chip_id) {
/* TODO: perform the ASIC test/detection */
++devices;
}
if (!devices) {
applog(LOG_INFO, "SPI detected, but not KnCminer ASICs");
return false;
}
applog(LOG_INFO, "Found a KnC miner with %d ASICs", devices);
struct cgpu_info *cgpu = calloc(1, sizeof(*cgpu));
struct knc_state *knc = calloc(1, sizeof(*knc));
if (!cgpu || !knc) {
applog(LOG_ERR, "KnC miner detected, but failed to allocate memory");
return false;
}
knc->ctx = ctx;
knc->devices = devices;
knc->read_q = 0;
knc->write_q = 1;
knc->read_a = 0;
knc->write_a = 1;
knc->read_d = 0;
knc->write_d = 1;
knc->salt = rand();
memset(knc->hwerr_work_id, 0xFF, sizeof(knc->hwerr_work_id));
_internal_knc_flush_fpga(knc);
cgpu->drv = &knc_drv;
cgpu->name = "KnCminer";
cgpu->threads = 1; // .. perhaps our number of devices?
cgpu->knc_state = knc;
add_cgpu(cgpu);
return true;
}
// http://www.concentric.net/~Ttwang/tech/inthash.htm
static unsigned long mix(unsigned long a, unsigned long b, unsigned long c)
{
a=a-b; a=a-c; a=a^(c >> 13);
b=b-c; b=b-a; b=b^(a << 8);
c=c-a; c=c-b; c=c^(b >> 13);
a=a-b; a=a-c; a=a^(c >> 12);
b=b-c; b=b-a; b=b^(a << 16);
c=c-a; c=c-b; c=c^(b >> 5);
a=a-b; a=a-c; a=a^(c >> 3);
b=b-c; b=b-a; b=b^(a << 10);
c=c-a; c=c-b; c=c^(b >> 15);
return c;
}
/* Probe devices and register with add_cgpu */
void knc_detect(bool __maybe_unused hotplug)
{
int idx;
srand(mix(clock(), time(NULL), getpid()));
/* Loop through all possible SPI interfaces */
for (idx = 0; idx < MAX_SPIS; ++idx) {
struct spidev_context *ctx = spi_new(idx + 1);
if (ctx != NULL) {
if (!knc_detect_one(ctx))
spi_free(ctx);
}
}
}
/* return value is number of nonces that have been checked since
* previous call
*/
static int64_t knc_scanwork(struct thr_info *thr)
{
struct cgpu_info *cgpu = thr->cgpu;
struct knc_state *knc = cgpu->knc_state;
int len, num;
int next_read_q;
applog(LOG_DEBUG, "KnC running scanwork");
knc_check_disabled_cores(knc);
/* Prepare tx buffer */
memset(spi_txbuf, 0, sizeof(spi_txbuf));
num = 0;
next_read_q = knc->read_q;
knc_queued_fifo_inc_idx(&next_read_q);
while (next_read_q != knc->write_q) {
knc_work_from_queue_to_spi(knc, &knc->queued_fifo[next_read_q],
&spi_txbuf[num]);
knc_queued_fifo_inc_idx(&next_read_q);
++num;
}
/* knc->read_q is advanced in knc_process_response, not here */
len = spi_transfer(knc->ctx, (uint8_t *)spi_txbuf,
(uint8_t *)&spi_rxbuf, sizeof(spi_txbuf));
if (len != sizeof(spi_rxbuf))
return -1;
len /= sizeof(struct spi_response);
applog(LOG_DEBUG, "KnC spi: %d works in request", num);
return knc_process_response(thr, cgpu, &spi_rxbuf, len);
}
static bool knc_queue_full(struct cgpu_info *cgpu)
{
struct knc_state *knc = cgpu->knc_state;
struct work *work;
int queue_full = true;
applog(LOG_DEBUG, "KnC running queue full");
while (!knc_queued_fifo_full(knc)) {
work = get_queued(cgpu);
if (!work) {
queue_full = false;
break;
}
knc->queued_fifo[knc->write_q].work = work;
knc_queued_fifo_inc_idx(&(knc->write_q));
}
return queue_full;
}
static void knc_flush_work(struct cgpu_info *cgpu)
{
struct knc_state *knc = cgpu->knc_state;
struct work *work;
int len;
int next_read_q, next_read_a;
applog(LOG_ERR, "KnC running flushwork");
/* Drain queued works */
next_read_q = knc->read_q;
knc_queued_fifo_inc_idx(&next_read_q);
while (next_read_q != knc->write_q) {
work = knc->queued_fifo[next_read_q].work;
work_completed(cgpu, work);
knc->queued_fifo[next_read_q].work = NULL;
knc->read_q = next_read_q;
knc_queued_fifo_inc_idx(&next_read_q);
}
/* Drain active works */
next_read_a = knc->read_a;
knc_active_fifo_inc_idx(&next_read_a);
while (next_read_a != knc->write_a) {
work = knc->active_fifo[next_read_a].work;
work_completed(cgpu, work);
knc->active_fifo[next_read_a].work = NULL;
knc->read_a = next_read_a;
knc_active_fifo_inc_idx(&next_read_a);
}
len = _internal_knc_flush_fpga(knc);
if (len > 0)
knc_process_response(NULL, cgpu, &spi_rxbuf, len);
}
struct device_drv knc_drv = {
.drv_id = DRIVER_knc,
.dname = "KnCminer",
.name = "KnC",
.drv_detect = knc_detect, // Probe for devices, add with add_cgpu
.hash_work = hash_queued_work,
.scanwork = knc_scanwork,
.queue_full = knc_queue_full,
.flush_work = knc_flush_work,
};