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swuart/: use a hardware timer and allow full-duplex operation

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This commit is contained in:
Werner Almesberger 2012-12-17 12:20:14 -03:00
parent 4689882497
commit 8816dcfa3c
2 changed files with 218 additions and 43 deletions
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2
swuart/Makefile
View File

@ -1,5 +1,5 @@
CC = mipsel-openwrt-linux-gcc
CFLAGS = -g -Wall -I../libubb/include
CFLAGS = -g -Wall -O9 -I../libubb/include
LDFLAGS = -static
LDLIBS = -L../libubb -lubb

259
swuart/swuart.c
View File

@ -1,5 +1,5 @@
/*
* swuart/swuart.c - Software-implemented half-duplex UART for UBB
* swuart/swuart.c - Software-implemented UART for UBB
*
* Written 2012 by Werner Almesberger
* Copyright 2012 Werner Almesberger
@ -11,38 +11,221 @@
*/
#include <stdbool.h>
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <string.h>
#include <ubb/ubb.h>
#include <ubb/regs4740.h>
#define TX UBB_DAT2
#define RX UBB_DAT0
#define TX UBB_DAT1
#define TIMER 7
static uint32_t tx_mask, rx_mask;
static int loops;
static uint32_t ticks;
/* ----- Hardware timer ---------------------------------------------------- */
/*
* TX bit timing:
*
* bps loops nominal estimated measured error
* 1152200 202 8.696 us 8.673 us 8.67 us -0.3%
* 38400 619 26.042 us 26.062 us 26.04 us n/a
* 9600 2494 104.167 us 104.250 us 104.16 us n/a
*
* Estimated loop timing: 0.25+0.0417*loops
* We run the hardware timer at PCLK/16 = 7 MHz. This gives us 60 cycles at
* 115200 bps and sets the lowest data rate to 106.8 bps.
*/
#define PCLK (112*1000*1000) /* 112 MHz */
#define TCLK (PCLK/16) /* 7 MHz */
static void get_timer(uint32_t cycle)
{
TSCR = 1 << TIMER; /* enable clock to timer */
TDFR(TIMER) = cycle-1; /* cycle = one bit time */
TCSR(TIMER) = (2 << 3) | 1; /* count at PCLK/16 */
}
static void reset_timer(void)
{
TECR = 1 << TIMER; /* disable timer */
TCNT(TIMER) = 0; /* reset timer */
TFCR = 0x10001 << TIMER; /* clear flags */
TESR = 1 << TIMER; /* enable timer */
}
static void set_half_cycle(uint32_t cycle)
{
uint32_t t;
t = (uint16_t) TCNT(TIMER)+(cycle >> 1);
/* TCNT+cycle/2 mod cycle-1 */
if (t >= cycle-1)
t -= cycle-1;
TDHR(TIMER) = t;
TFCR = 0x10000 << TIMER; /* clear half flags */
}
static void release_timer(void)
{
TECR = 1 << TIMER; /* disable timer */
TFCR = 0x10001 << TIMER; /* clear flags */
TSSR = 1 << TIMER; /* disable clock to timer */
}
static inline bool timer_full(void)
{
if (!(TFR & (1 << TIMER)))
return 0;
TFCR = 1 << TIMER;
return 1;
}
static inline bool timer_half(void)
{
if (!(TFR & (0x10000 << TIMER)))
return 0;
TFCR = 0x10000 << TIMER;
return 1;
}
/* ----- Enable/disable interrupts ----------------------------------------- */
static uint32_t old_icmr;
static void disable_interrupts(void)
{
old_icmr = ICMR;
ICMSR = 0xffffffff;
}
static void enable_interrupts(void)
{
ICMCR = ~old_icmr;
}
/* ----- Transmit a block -------------------------------------------------- */
struct rx_err {
unsigned glitch; /* unstable start bit */
unsigned framing; /* stop bit wasn't "1" */
unsigned overflow; /* buffer overflow */
} rx_err;
static int trx(uint8_t *out, int out_size, uint8_t *in, int in_size,
unsigned wait_bits, unsigned idle_bits)
{
unsigned tx, rx = 0, idle = 0;
int tx_bits = 0, rx_bits = 0;
int in_len = 0;
reset_timer();
while (1) {
full:
/* timer has just crossed FULL */
if (tx_bits) {
if (tx & 1)
SET(tx_mask);
else
CLR(tx_mask);
tx >>= 1;
tx_bits--;
} else {
if (out_size) {
CLR(tx_mask);
tx = *out++ | 0x100;
out_size--;
tx_bits = 9;
} else {
if (idle++ == wait_bits)
return in_len;
}
}
/* wait for reception (if any) */
if (rx_bits) {
while (!timer_half());
} else {
while (!timer_full())
if (!PIN(rx_mask)) {
set_half_cycle(ticks);
rx_bits = 10;
break;
}
if (!rx_bits)
continue;
while (!timer_half())
if (timer_full())
goto full;
}
/* timer has just crossed HALF */
rx = (rx >> 1) | (PIN(rx_mask) ? 0x200 : 0);
if (!--rx_bits) {
if (rx & 1) {
rx_err.glitch++;
} else if (!(rx & 0x200)) {
rx_err.framing++;
} else if (in_len == in_size) {
rx_err.overflow++;
} else {
*in++ = rx >> 1;
in_len++;
idle = 0;
wait_bits = idle_bits;
}
}
while (!timer_full());
}
}
int swuart_trx(void *out, int out_size, void *in, int in_size,
int wait_bits, int idle_bits)
{
int got;
disable_interrupts();
get_timer(ticks);
got = trx(out, out_size, in, in_size, wait_bits, idle_bits);
release_timer();
enable_interrupts();
return got;
}
/* ----- Open/close the software UART -------------------------------------- */
int swuart_open(uint32_t tx, uint32_t rx, int bps)
{
if (ubb_open(0))
return -1;
loops = 24000000/bps-6;
ticks = TCLK/bps-1;
tx_mask = tx;
rx_mask = rx;
@ -55,47 +238,39 @@ int swuart_open(uint32_t tx, uint32_t rx, int bps)
}
static void send(uint8_t *out, int out_size)
void swuart_close(void)
{
const uint8_t *end = out+out_size;
unsigned pattern;
int i, j;
while (out != end) {
pattern = 0x200 | (*out++ << 1);
for (i = 0; i != 10; i++) {
if (pattern & 1)
SET(tx_mask);
else
CLR(tx_mask);
pattern >>= 1;
for (j = 0; j != loops; j++);
}
}
ubb_close(0);
}
int swuart_trx(void *out, int out_size, void *in, int in_size, int bit_wait)
/* ----- Main -------------------------------------------------------------- */
static void at_exit(void)
{
uint32_t icmr;
icmr = ICMR;
ICMSR = 0xffffffff;
send(out, out_size);
ICMCR = ~icmr;
return 0;
swuart_close();
}
int main(int argc, char **argv)
{
swuart_open(TX, 0, atoi(argv[1]));
uint8_t buf[40];
int got, i;
swuart_open(TX, RX, atoi(argv[1]));
atexit(at_exit);
while (1) {
swuart_trx("U ", 2, NULL, 0, 0);
got = swuart_trx(argv[2], strlen(argv[2]), buf, sizeof(buf),
10000, 100);
printf("%d (%d %d %d): ", got,
rx_err.glitch, rx_err.framing, rx_err.overflow);
for (i = 0; i != got; i++)
if (buf[i] >= ' ' && buf[i] <= '~')
printf("%c", buf[i]);
else
printf("\\%02o", buf[i]);
printf("\n");
usleep(100);
}
ubb_close(0);
}