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ben-blinkenlights/ubb-patgen/ubb-patgen.c

887 lines
18 KiB
C

/*
* ubb-patgen.c - UBB pattern generator
*
* Written 2013 by Werner Almesberger
* Copyright 2013 Werner Almesberger
*
* 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 2 of the License, or
* (at your option) any later version.
*/
#include <stdint.h>
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <ctype.h>
#include <string.h>
#include <math.h>
#include <time.h>
#include <sched.h>
#include <assert.h>
#include <sys/mman.h>
#include <ubb/ubb.h>
#include <ubb/regs4740.h>
#include <ubb/mmcclk.h>
#include <ubb/physmem.h>
#define DMA 5
/* ----- List available bus clock frequencies ------------------------------ */
static int cmp(const void *a, const void *b)
{
const struct mmcclk *ma = a, *mb = b;
if (ma->bus_clk_hz < mb->bus_clk_hz)
return -1;
if (ma->bus_clk_hz > mb->bus_clk_hz)
return 1;
return mb->clkdiv-ma->clkdiv;
}
static struct mmcclk *frequencies(int *n)
{
struct mmcclk mmc;
struct mmcclk *clks = malloc(sizeof(struct mmcclk));
int n_clks = 1;
if (!clks) {
perror("malloc");
exit(1);
}
mmcclk_first(&mmc, 0);
clks[0] = mmc;
while (mmcclk_next(&mmc)) {
clks = realloc(clks, sizeof(struct mmcclk)*(n_clks+1));
if (!clks) {
perror("realloc");
exit(1);
}
clks[n_clks] = mmc;
n_clks++;
}
qsort(clks, n_clks, sizeof(*clks), cmp);
*n = n_clks;
return clks;
}
static void print_freq(FILE *file, double f)
{
const char *prefix = "";
if (f >= 1000000) {
f /= 1000000;
prefix = "M";
} else if (f >= 1000) {
f /= 1000;
prefix = "k";
}
fprintf(file, "%g %sHz", f, prefix);
}
static void show_frequencies(int quiet)
{
const struct mmcclk *clks;
int n, i;
double last = 0;
clks = frequencies(&n);
for (i = 0; i != n; i++) {
if (quiet) {
if (clks[i].bus_clk_hz != last)
printf("%f\n", clks[i].bus_clk_hz);
last = clks[i].bus_clk_hz;
} else {
printf("clkdiv = %u, clkrt = %u, bus_clk = ",
clks[i].clkdiv, clks[i].clkrt);
print_freq(stdout, clks[i].bus_clk_hz);
putchar('\n');
}
}
free((void *) clks);
}
static int select_freq(struct mmcclk *res, int hz, int rel, int quiet)
{
const struct mmcclk *clks, *p, *best = NULL;
double d, best_d = 0;
int n;
double err;
clks = frequencies(&n);
for (p = clks; p != clks+n; p++) {
if (rel > 0 && p->bus_clk_hz < hz)
continue;
if (rel < 0 && p->bus_clk_hz > hz)
continue;
d = fabs(p->bus_clk_hz-hz);
if (!best || d < best_d) {
best = p;
best_d = d;
}
}
if (!best)
return 0;
*res = *best;
free((void *) clks);
if (quiet)
return 1;
if (res->bus_clk_hz != hz) {
fprintf(stderr, "bus clk = ");
print_freq(stderr, res->bus_clk_hz);
err = (res->bus_clk_hz-hz)/hz;
if (err <= -0.0001 || err >= 0.0001)
fprintf(stderr, " (%+.2g%%)\n", err*100);
else
fprintf(stderr, " (%+d ppm)\n", (int) (err*1000000));
}
return 1;
}
/* ----- Pattern parser ---------------------------------------------------- */
static void *parse_pattern(const char *s, int *nibbles)
{
uint8_t *buf = physmem_malloc(4095); /* maximum block size */
int n = 0;
uint8_t v = 0;
char *end;
unsigned long i;
memset(buf, 0, 4095);
while (*s) {
char ch[2] = { *s, 0 };
v = strtoul(ch, &end, 16);
if (*end) {
fprintf(stderr, "\"%c\" is not a hex digit\n", *s);
exit(1);
}
if (s[1] == '{') {
i = strtoul(s+2, &end, 0);
if (!*end) {
fprintf(stderr, "unterminated range\n");
exit(1);
}
if (*end != '}' || end == s+2) {
fprintf(stderr, "invalid range \"%.*s\"\n",
end-s, s+1);
exit(1);
}
s = end+1;
} else {
i = 1;
s++;
}
while (i) {
if (n == 8192-64-1) {
fprintf(stderr, "pattern is too long\n");
exit(1);
}
buf[n >> 1] |= v << 4*(~n & 1);
n++;
i--;
}
}
/* pad to multiples of 32 bytes */
while (n & 63) {
buf[n >> 1] |= v << 4*(~n & 1);
n++;
}
*nibbles = n;
return buf;
}
static const char *load_pattern(const char *s)
{
static char buf[20000]; /* more than enough :) */
FILE *file;
char *p = buf;
int comment = 0;
int c;
if (!strcmp(s, "-")) {
file = stdin;
} else {
file = fopen(s, "r");
if (!file)
return s;
}
while ((c = fgetc(file)) != EOF) {
if (comment) {
comment = c != '\n';
continue;
}
if (c == '#') {
comment = 1;
continue;
}
if (isspace(c))
continue;
if (buf+sizeof(buf)-1 == p) {
fprintf(stderr, "%s: file is too big\n", s);
exit(1);
}
*p++ = c;
}
if (file != stdin)
fclose(file);
*p = 0;
return buf;
}
/* ----- Real-time mode ---------------------------------------------------- */
void realtimize(void)
{
struct sched_param prm;
prm.sched_priority = sched_get_priority_max(SCHED_FIFO);
if (prm.sched_priority < 0) {
perror("sched_get_priority_max SCHED_FIFO");
exit(1);
}
if (sched_setscheduler(0, SCHED_FIFO, &prm) < 0) {
perror("sched_setscheduler SCHED_FIFO");
exit(1);
}
}
void unrealtime(void)
{
struct sched_param prm = { .sched_priority = 0 };
if (sched_setscheduler(0, SCHED_OTHER, &prm) < 0) {
perror("sched_setscheduler SCHED_OTHER");
exit(1);
}
}
/* ----- DMA control ------------------------------------------------------- */
static uint32_t old_dmac;
static void dma_stop(void)
{
DCS(DMA) =
DCS_TT | /* Transfer terminated */
DCS_HLT; /* DMA halt */
DCS(DMA) = 0; /* reset DMA channel */
}
static void dma_init(void)
{
old_dmac = DMAC;
DMAC = DMAC_DMAE; /* activate the DMA controller (in case it's off) */
dma_stop();
DCM(DMA) =
DCM_SAI | /* source address increment */
(DCM_TSZ_32BYTE << DCM_TSZ_SHIFT);
/* transfer size is 32 bytes */
DRT(DMA) = DRT_MSC_TX; /* MSC transmit-fifo-empty transfer request */
}
static void dma_cleanup(void)
{
DMAC = old_dmac;
dma_stop();
}
static void dma_setup(unsigned long buf, int nibbles)
{
assert(!(nibbles & 63));
DCS(DMA) = DCS_NDES; /* no-descriptor transfer */
DSA(DMA) = buf; /* source */
DTA(DMA) = REG_PADDR(MSC_TXFIFO); /* MUST set this each time */
DTC(DMA) = nibbles >> 6; /* 32 bytes per transfer */
}
static void wait_dma_done(void)
{
while (!(DCS(DMA) & DCS_TT));
}
/* ----- Send pattern using MSC and DMA ------------------------------------ */
static void wait_response(void)
{
while (!(MSC_STAT & MSC_STAT_END_CMD_RES));
}
static void wait_fifo_empty(void)
{
while (!(MSC_STAT & MSC_STAT_DATA_FIFO_EMPTY));
}
static void wait_shifted(const struct mmcclk *clk)
{
/* 8 nibbles */
double us = 8*1000000.0/clk->bus_clk_hz;
usleep((int) us+1);
}
static void wait_trigger(const char *trigger, int debounce,
const struct timespec *debounce_ns)
{
struct timespec end, now;
/*
* @@@ could also try to use POSIX per-process timers here. May be
* slightly cleaner but could increase deviations.
*/
while (*trigger) {
while (PIN(UBB_CLK) != *trigger-'0');
if (!debounce)
goto next;
again:
if (clock_gettime(CLOCK_REALTIME, &end)) {
perror("clock_gettime");
exit(1);
}
end.tv_sec += debounce_ns->tv_sec;
end.tv_nsec += debounce_ns->tv_nsec;
if (end.tv_nsec > 999999999) {
end.tv_nsec -= 1000000000;
end.tv_sec++;
}
while (PIN(UBB_CLK) == *trigger-'0') {
if (clock_gettime(CLOCK_REALTIME, &now)) {
perror("clock_gettime");
exit(1);
}
if (now.tv_sec > end.tv_sec)
goto next;
if (now.tv_sec == end.tv_sec &&
now.tv_nsec >= end.tv_nsec)
goto next;
}
goto again;
next:
trigger++;
}
}
static void mmc_buffer(const struct mmcclk *clk,
uint8_t first, unsigned long buf, int nibbles, uint32_t mask,
const char *trigger, int debounce, const struct timespec *debounce_ns,
const struct timespec *wait_ns)
{
/*
* If under control of the MMC controller, DATx tri-state until we
* actually send data. That's why they have been set up as GPIOs and
* we'll only switch them to function when the MMC controller is in a
* well-defined state.
*/
dma_setup(buf, nibbles);
MSC_STRPCL = MSC_STRPCRL_START_CLOCK; /* start the bus clock */
MSC_RESTO = MSC_RESTO_MASK; /* maximum response time-out */
MSC_BLKLEN = MSC_BLKLEN_MASK; /* never reach the end (with CRC) */
MSC_CMDAT =
MSC_CMDAT_BUS_WIDTH_4 << MSC_CMDAT_BUS_WIDTH_SHIFT |
MSC_CMDAT_DMA_EN | /* DMA */
MSC_CMDAT_WRITE_READ | /* write */
MSC_CMDAT_DATA_EN | /* with data transfer */
MSC_CMDAT_RESPONSE_FORMAT_R1; /* R1 response */
MSC_STRPCL = MSC_STRPCRL_START_OP;
/*
* Make sure we've reached the end of the command and then send the
* first pattern (eight times, since this is the smallest amount we
* can send.
*/
wait_response();
MSC_TXFIFO = first*0x11111111;
wait_fifo_empty();
wait_shifted(clk);
/*
* Since the transfer (of nominally 4095 bytes) is not done yet, the
* MMC controller will hold the bus at the last value sent. It's now
* safe to switch from GPIO to function.
*/
PDFUNS = mask;
realtimize();
if (trigger)
wait_trigger(trigger, debounce, debounce_ns);
if (wait_ns->tv_sec || wait_ns->tv_nsec)
if (nanosleep(wait_ns, NULL))
perror("nanosleep");
/*
* Send the pattern with DMA. Note that we still have to send the first
* pattern, since the static state we begin from may not have been
* present long enough.
*/
DCS(DMA) =
DCS_NDES | /* no descriptor */
DCS_CTE; /* enable channel */
unrealtime();
wait_dma_done();
wait_fifo_empty();
wait_shifted(clk);
/*
* We're done. As far as the MMC controller is concerned, the transfer
* is still not finished (i.e., we haven't sent 4095 bytes) and will
* therefore just hold the bus. We can now return the bus to GPIO.
* This form of handover also prevents the MMC controller from sending
* a CRC, which may confuse the recipient of the pattern.
*/
}
static void send_buffer(const struct mmcclk *clk,
const uint8_t *buf, int nibbles, uint32_t mask,
const char *trigger, int debounce, const struct timespec *debounce_ns,
const struct timespec *wait_ns)
{
struct physmem_vec vec;
int n;
if (physmem_flush(buf, nibbles)) {
perror("physmem_flush");
exit(1);
}
n = physmem_xlat((void *) buf, nibbles >> 1, &vec, 1);
if (n < 0) {
perror("physmem_xlat_vec");
exit(1);
}
if (n != 1) {
fprintf(stderr, "physmem_xlat_vec: expected 1, got %d\n", n);
exit(1);
}
mmc_buffer(clk, buf[0] >> 4, vec.addr, nibbles, mask,
trigger, debounce, debounce_ns, wait_ns);
}
static void dma_pattern(const struct mmcclk *clk,
const char *pattern, uint32_t mask, const char *trigger,
int debounce, const struct timespec *debounce_ns,
const struct timespec *wait_ns)
{
const uint8_t *buf;
int n;
if (!*pattern) {
fprintf(stderr, "pattern is empty\n");
exit(1);
}
buf = parse_pattern(pattern, &n);
if (mlockall(MCL_CURRENT | MCL_FUTURE)) {
perror("mlockall");
exit(1);
}
if (trigger) {
PDFUNC = UBB_CLK;
IN(UBB_CLK);
}
dma_init();
/* Initial static state: the first pattern. */
PDFUNS = UBB_CMD;
PDDATC = ~((buf[0] >> 4) << 10) & mask;
PDDATS = (buf[0] >> 4) << 10;
PDDIRS = mask;
send_buffer(clk, buf, n, mask,
trigger, debounce, debounce_ns, wait_ns);
/* Final static state: the last pattern. */
PDDATC = ~((buf[(n >> 1)-1] & 0xf) << 10) & mask;
PDDATS = (buf[(n >> 1)-1] & 0xf) << 10;
PDFUNC = mask;
dma_cleanup();
}
/* ----- Command-line processing ------------------------------------------- */
static int frequency(const char *s, int *hz, int *rel)
{
char *end;
double f;
f = strtod(s, &end);
if (end == s || f < 0)
return 0;
switch (*end) {
case 'M':
case 'm':
*hz = f*1000000;
end++;
break;
case 'K':
case 'k':
*hz = f*1000;
end++;
break;
default:
*hz = f;
break;
}
if ((end[0] == 'H' || end[0] == 'h') &&
(end[1] == 'Z' || end[1] == 'z'))
end += 2;
switch (*end) {
case '+':
*rel = 1;
end++;
break;
case '-':
*rel = -1;
end++;
break;
default:
*rel = 0;
break;
}
return !*end;
}
static int duration(const char *s, double *res, int *rel)
{
char *end;
double d;
d = strtod(s, &end);
if (end == s || d < 0)
return 0;
switch (*end) {
case 'M':
case 'm':
d /= 1e3;
end++;
break;
case 'U':
case 'u':
d /= 1e6;
end++;
break;
case 'N':
case 'n':
d /= 1e9;
end++;
break;
default:
break;
}
if (*end == 'S' || *end == 's')
end++;
switch (*end) {
case '+':
*rel = 1;
end++;
break;
case '-':
*rel = -1;
end++;
break;
default:
*rel = 0;
break;
}
if (*end)
return 0;
*res = d;
return 1;
}
static int duration_timespec(const char *s, struct timespec *res, int *rel)
{
double d;
if (!duration(s, &d, rel))
return 0;
res->tv_sec = d;
res->tv_nsec = (d-res->tv_sec)*1e9;
return 1;
}
static int interval(const char *s, int *hz, int *rel)
{
double d;
if (!duration(s, &d, rel))
return 0;
*hz = 1/d;
*rel = -*rel;
return 1;
}
static void usage(const char *name)
{
fprintf(stderr,
"usage: %s\n"
" %s [-q] -f freq_hz|-i interval_s\n"
" %s [-q] [-f freq_hz|-i interval_s] -c [active_s]\n"
" %s [-q] [-f freq_hz|-i interval_s] [-C|-t 0|1... [-d debounce_s]]\n"
" [-w wait_s] [-m mask] [-p] file|pattern\n\n"
" -c output bus clock on CLK without sending a pattern\n"
" -C temporarily output bus clock on CLK (for debugging)\n"
" -d deb_s trigger debounce time (default: no debouncing)\n"
" -f freq_hz set bus clock to the specified frequency (default: 1 MHz)\n"
" -i inter_s set bus clock such that one cycle equals the specified "
"interval\n"
" -m mask use only the DATx lines specified in the mask (default: 0xf)\n"
" -p force interpretation of argument as pattern (and not file)\n"
" -q quiet. Don't pretty-print frequencies; don't report clock\n"
" differences.\n"
" -t 0|1... start pattern when trigger/CLK has passed through the sequence\n"
" (default: start pattern immediately)\n"
" -w wait_s wait between trigger and sending the pattern\n\n"
" active_s keep running that many seconds after setting the clock\n"
" (default: exit immediately but leave the clock on)\n"
" file file containing the pattern\n"
" pattern send the specified pattern on DAT0 through DAT3\n\n"
"Frequency: the frequency in hertz, optionally followed by \"M\" or \"k\",\n"
" optionally followed by \"Hz\", optionally followed by \"+\" or \"-\".\n"
" \"+\" selects a frequency >= the specified one, \"-\" one <=.\n"
" Without +/-, the closest available frequency is selected.\n"
"Duration: the duration in seconds, optionally followed by \"m\", \"u\", or\n"
" \"n\", optionally followed by \"s\", optionally followed by \"+\" or \"-\"."
"\n"
"Pattern: hex digits corresponding to 1 for DAT0, 2 for DAT1, etc.\n"
" {n} repeats the preceding digit n times, e.g., 1{3} is equivalent to 111.\n"
, name, name, name, name);
exit(1);
}
int main(int argc, char **argv)
{
struct mmcclk clk;
int bus_hz = 0, clk_only = 0, clkout = 0, bus_rel = 0;
const char *pattern = NULL;
int quiet = 0, force_pattern = 0;
struct timespec active_ns;
int active_rel;
int keep_clk = 1;
uint8_t mask = 0xf;
const char *trigger = NULL;
struct timespec debounce_ns;
int debounce = 0, debounce_rel;
struct timespec wait_ns = { 0, 0 };
int wait_rel;
char *end;
int c;
unsigned long tmp;
const char *p;
while ((c = getopt(argc, argv, "cCd:f:i:m:pqt:w:")) != EOF)
switch (c) {
case 'c':
clk_only = 1;
break;
case 'C':
clkout = 1;
break;
case 'd':
if (!duration_timespec(optarg,
&debounce_ns, &debounce_rel))
usage(*argv);
if (debounce_rel < 0)
usage(*argv);
debounce = 1;
break;
case 'f':
if (!frequency(optarg, &bus_hz, &bus_rel))
usage(*argv);
break;
case 'i':
if (!interval(optarg, &bus_hz, &bus_rel))
usage(*argv);
break;
case 'm':
tmp = strtoul(optarg, &end, 0);
if (*end)
usage(*argv);
if (tmp & ~0xfUL) {
fprintf(stderr, "mask is too large\n");
exit(1);
}
mask = tmp;
break;
case 'p':
force_pattern = 1;
break;
case 'q':
quiet = 1;
break;
case 't':
trigger = optarg;
if (!*trigger)
usage(*argv);
for (p = trigger; *p; p++)
if (*p != '0' && *p != '1')
usage(*argv);
break;
case 'w':
if (!duration_timespec(optarg,
&wait_ns, &wait_rel))
usage(*argv);
if (wait_rel < 0)
usage(*argv);
break;
default:
usage(*argv);
}
if (clkout && clk_only)
usage(*argv);
if ((clkout || clk_only) && trigger)
usage(*argv);
switch (argc-optind) {
case 0:
if (clk_only)
break;
if (clkout || force_pattern || trigger)
usage(*argv);
ubb_open(UBB_ALL);
if (bus_hz) {
if (!select_freq(&clk, bus_hz, bus_rel, quiet)) {
fprintf(stderr,
"no suitable frequency found\n");
exit(1);
}
printf("%f\n", clk.bus_clk_hz);
} else {
show_frequencies(quiet);
}
return 0;
case 1:
if (clk_only) {
if (force_pattern)
usage(*argv);
if (!duration_timespec(argv[optind],
&active_ns, &active_rel))
usage(*argv);
if (active_rel < 0)
usage(*argv);
keep_clk = 0;
} else {
pattern = argv[optind];
}
break;
default:
usage(*argv);
}
if (pattern && !force_pattern)
pattern = load_pattern(pattern);
ubb_open(UBB_ALL);
PDFUNS = UBB_CMD;
if (!bus_hz)
bus_hz = 1000000;
if (!select_freq(&clk, bus_hz, bus_rel, quiet)) {
fprintf(stderr, "no suitable frequency found\n");
exit(1);
}
if (clkout || clk_only)
PDFUNS = UBB_CLK;
mmcclk_start(&clk);
if (pattern)
dma_pattern(&clk, pattern, mask << 10,
trigger, debounce, &debounce_ns, &wait_ns);
if (!keep_clk)
if (nanosleep(&active_ns, NULL))
perror("nanosleep");
if (pattern) {
mmcclk_stop();
ubb_close(mask << 10 | (trigger ? UBB_CLK : 0));
} else if (keep_clk) {
ubb_close(UBB_CLK);
} else {
mmcclk_stop();
ubb_close(0);
}
return 0;
}