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/*
* Copyright © 2012 Keith Packard <keithp@keithp.com>
*
* 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.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
*/
#include <ao.h>
#include <ao_pad.h>
#include <ao_74hc165.h>
#include <ao_radio_cmac.h>
static __xdata uint8_t ao_pad_ignite;
static __xdata struct ao_pad_command command;
static __xdata struct ao_pad_query query;
static __pdata uint8_t ao_pad_armed;
static __pdata uint16_t ao_pad_arm_time;
static __pdata uint8_t ao_pad_box;
static __xdata uint8_t ao_pad_disabled;
static __pdata uint16_t ao_pad_packet_time;
#ifndef AO_PAD_RSSI_MINIMUM
#define AO_PAD_RSSI_MINIMUM -90
#endif
#define DEBUG 1
#if DEBUG
static __pdata uint8_t ao_pad_debug;
#define PRINTD(...) (ao_pad_debug ? (printf(__VA_ARGS__), 0) : 0)
#define FLUSHD() (ao_pad_debug ? (flush(), 0) : 0)
#else
#define PRINTD(...)
#define FLUSHD()
#endif
static void
ao_siren(uint8_t v)
{
#ifdef AO_SIREN
ao_gpio_set(AO_SIREN_PORT, AO_SIREN_PIN, AO_SIREN, v);
#else
#if HAS_BEEP
ao_beep(v ? AO_BEEP_MID : 0);
#else
(void) v;
#endif
#endif
}
static void
ao_strobe(uint8_t v)
{
#ifdef AO_STROBE
ao_gpio_set(AO_STROBE_PORT, AO_STROBE_PIN, AO_STROBE, v);
#else
(void) v;
#endif
}
static void
ao_pad_run(void)
{
AO_PORT_TYPE pins;
for (;;) {
while (!ao_pad_ignite)
ao_sleep(&ao_pad_ignite);
/*
* Actually set the pad bits
*/
pins = 0;
#if AO_PAD_NUM > 0
if (ao_pad_ignite & (1 << 0))
pins |= (1 << AO_PAD_PIN_0);
#endif
#if AO_PAD_NUM > 1
if (ao_pad_ignite & (1 << 1))
pins |= (1 << AO_PAD_PIN_1);
#endif
#if AO_PAD_NUM > 2
if (ao_pad_ignite & (1 << 2))
pins |= (1 << AO_PAD_PIN_2);
#endif
#if AO_PAD_NUM > 3
if (ao_pad_ignite & (1 << 3))
pins |= (1 << AO_PAD_PIN_3);
#endif
PRINTD("ignite pins 0x%x\n", pins);
ao_gpio_set_bits(AO_PAD_PORT, pins);
while (ao_pad_ignite) {
ao_pad_ignite = 0;
ao_delay(AO_PAD_FIRE_TIME);
}
ao_gpio_clr_bits(AO_PAD_PORT, pins);
PRINTD("turn off pins 0x%x\n", pins);
}
}
#define AO_PAD_ARM_SIREN_INTERVAL 200
#ifndef AO_PYRO_R_PYRO_SENSE
#define AO_PYRO_R_PYRO_SENSE 100
#define AO_PYRO_R_SENSE_GND 27
#define AO_FIRE_R_POWER_FET 100
#define AO_FIRE_R_FET_SENSE 100
#define AO_FIRE_R_SENSE_GND 27
#endif
static void
ao_pad_monitor(void)
{
uint8_t c;
uint8_t sample;
__pdata uint8_t prev = 0, cur = 0;
__pdata uint8_t beeping = 0;
__xdata volatile struct ao_data *packet;
__pdata uint16_t arm_beep_time = 0;
sample = ao_data_head;
for (;;) {
__pdata int16_t pyro;
ao_arch_critical(
while (sample == ao_data_head)
ao_sleep((void *) DATA_TO_XDATA(&ao_data_head));
);
packet = &ao_data_ring[sample];
sample = ao_data_ring_next(sample);
pyro = packet->adc.pyro;
#define VOLTS_TO_PYRO(x) ((int16_t) ((x) * ((1.0 * AO_PYRO_R_SENSE_GND) / \
(1.0 * (AO_PYRO_R_SENSE_GND + AO_PYRO_R_PYRO_SENSE)) / 3.3 * AO_ADC_MAX)))
#define VOLTS_TO_FIRE(x) ((int16_t) ((x) * ((1.0 * AO_FIRE_R_SENSE_GND) / \
(1.0 * (AO_FIRE_R_SENSE_GND + AO_FIRE_R_FET_SENSE)) / 3.3 * AO_ADC_MAX)))
/* convert ADC value to voltage in tenths, then add .2 for the diode drop */
query.battery = (packet->adc.batt + 96) / 192 + 2;
cur = 0;
if (pyro > VOLTS_TO_PYRO(10)) {
query.arm_status = AO_PAD_ARM_STATUS_ARMED;
cur |= AO_LED_ARMED;
#if AO_FIRE_R_POWER_FET
} else if (pyro > VOLTS_TO_PYRO(5)) {
if ((ao_time() % 100) < 50)
cur |= AO_LED_ARMED;
query.arm_status = AO_PAD_ARM_STATUS_UNKNOWN;
arm_beep_time = 0;
#endif
} else {
query.arm_status = AO_PAD_ARM_STATUS_DISARMED;
arm_beep_time = 0;
}
if ((ao_time() - ao_pad_packet_time) > AO_SEC_TO_TICKS(2))
cur |= AO_LED_RED;
else if (ao_radio_cmac_rssi < AO_PAD_RSSI_MINIMUM)
cur |= AO_LED_AMBER;
else
cur |= AO_LED_GREEN;
for (c = 0; c < AO_PAD_NUM; c++) {
int16_t sense = packet->adc.sense[c];
uint8_t status = AO_PAD_IGNITER_STATUS_UNKNOWN;
/*
* pyro is run through a divider, so pyro = v_pyro * 27 / 127 ~= v_pyro / 20
* v_pyro = pyro * 127 / 27
*
* v_pyro \
* 100k igniter
* output /
* 100k \
* sense relay
* 27k /
* gnd ---
*
* v_pyro \
* 200k igniter
* output /
* 200k \
* sense relay
* 22k /
* gnd ---
*
* If the relay is closed, then sense will be 0
* If no igniter is present, then sense will be v_pyro * 27k/227k = pyro * 127 / 227 ~= pyro/2
* If igniter is present, then sense will be v_pyro * 27k/127k ~= v_pyro / 20 = pyro
*/
#if AO_FIRE_R_POWER_FET
if (sense <= pyro / 8) {
status = AO_PAD_IGNITER_STATUS_NO_IGNITER_RELAY_CLOSED;
if ((ao_time() % 100) < 50)
cur |= AO_LED_CONTINUITY(c);
} else
if (pyro / 8 * 3 <= sense && sense <= pyro / 8 * 5)
status = AO_PAD_IGNITER_STATUS_NO_IGNITER_RELAY_OPEN;
else if (pyro / 8 * 7 <= sense) {
status = AO_PAD_IGNITER_STATUS_GOOD_IGNITER_RELAY_OPEN;
cur |= AO_LED_CONTINUITY(c);
}
#else
if (sense >= pyro / 8 * 5) {
status = AO_PAD_IGNITER_STATUS_GOOD_IGNITER_RELAY_OPEN;
cur |= AO_LED_CONTINUITY(c);
} else {
status = AO_PAD_IGNITER_STATUS_NO_IGNITER_RELAY_OPEN;
}
#endif
query.igniter_status[c] = status;
}
if (cur != prev) {
PRINTD("change leds from %02x to %02x\n",
prev, cur);
FLUSHD();
ao_led_set(cur);
prev = cur;
}
if (ao_pad_armed && (int16_t) (ao_time() - ao_pad_arm_time) > AO_PAD_ARM_TIME)
ao_pad_armed = 0;
if (ao_pad_armed) {
ao_strobe(1);
ao_siren(1);
beeping = 1;
} else if (query.arm_status == AO_PAD_ARM_STATUS_ARMED && !beeping) {
if (arm_beep_time == 0) {
arm_beep_time = AO_PAD_ARM_SIREN_INTERVAL;
beeping = 1;
ao_siren(1);
}
--arm_beep_time;
} else if (beeping) {
beeping = 0;
ao_siren(0);
ao_strobe(0);
}
}
}
void
ao_pad_disable(void)
{
if (!ao_pad_disabled) {
ao_pad_disabled = 1;
ao_radio_recv_abort();
}
}
void
ao_pad_enable(void)
{
ao_pad_disabled = 0;
ao_wakeup (&ao_pad_disabled);
}
#if HAS_74HC165
static uint8_t
ao_pad_read_box(void)
{
uint8_t byte = ao_74hc165_read();
uint8_t h, l;
h = byte >> 4;
l = byte & 0xf;
return h * 10 + l;
}
#endif
#if HAS_FIXED_PAD_BOX
#define ao_pad_read_box() ao_config.pad_box
#endif
#ifdef PAD_BOX
#define ao_pad_read_box() PAD_BOX
#endif
static void
ao_pad(void)
{
int16_t time_difference;
int8_t ret;
ao_pad_box = 0;
ao_led_set(0);
for (;;) {
FLUSHD();
while (ao_pad_disabled)
ao_sleep(&ao_pad_disabled);
ret = ao_radio_cmac_recv(&command, sizeof (command), 0);
PRINTD ("cmac_recv %d %d\n", ret, ao_radio_cmac_rssi);
if (ret != AO_RADIO_CMAC_OK)
continue;
ao_pad_packet_time = ao_time();
ao_pad_box = ao_pad_read_box();
PRINTD ("tick %d box %d (me %d) cmd %d channels %02x\n",
command.tick, command.box, ao_pad_box, command.cmd, command.channels);
switch (command.cmd) {
case AO_PAD_ARM:
if (command.box != ao_pad_box) {
PRINTD ("box number mismatch\n");
break;
}
if (command.channels & ~(AO_PAD_ALL_CHANNELS))
break;
time_difference = command.tick - ao_time();
PRINTD ("arm tick %d local tick %d\n", command.tick, ao_time());
if (time_difference < 0)
time_difference = -time_difference;
if (time_difference > 10) {
PRINTD ("time difference too large %d\n", time_difference);
break;
}
PRINTD ("armed\n");
ao_pad_armed = command.channels;
ao_pad_arm_time = ao_time();
break;
case AO_PAD_QUERY:
if (command.box != ao_pad_box) {
PRINTD ("box number mismatch\n");
break;
}
query.tick = ao_time();
query.box = ao_pad_box;
query.channels = AO_PAD_ALL_CHANNELS;
query.armed = ao_pad_armed;
PRINTD ("query tick %d box %d channels %02x arm %d arm_status %d igniter %d,%d,%d,%d\n",
query.tick, query.box, query.channels, query.armed,
query.arm_status,
query.igniter_status[0],
query.igniter_status[1],
query.igniter_status[2],
query.igniter_status[3]);
ao_radio_cmac_send(&query, sizeof (query));
break;
case AO_PAD_FIRE:
if (!ao_pad_armed) {
PRINTD ("not armed\n");
break;
}
if ((uint16_t) (ao_time() - ao_pad_arm_time) > AO_SEC_TO_TICKS(20)) {
PRINTD ("late pad arm_time %d time %d\n",
ao_pad_arm_time, ao_time());
break;
}
PRINTD ("ignite\n");
ao_pad_ignite = ao_pad_armed;
ao_pad_arm_time = ao_time();
ao_wakeup(&ao_pad_ignite);
break;
case AO_PAD_STATIC:
if (!ao_pad_armed) {
PRINTD ("not armed\n");
break;
}
#ifdef HAS_LOG
if (!ao_log_running) ao_log_start();
#endif
if ((uint16_t) (ao_time() - ao_pad_arm_time) > AO_SEC_TO_TICKS(20)) {
PRINTD ("late pad arm_time %d time %d\n",
ao_pad_arm_time, ao_time());
break;
}
PRINTD ("ignite\n");
ao_pad_ignite = ao_pad_armed;
ao_pad_arm_time = ao_time();
ao_wakeup(&ao_pad_ignite);
break;
case AO_PAD_ENDSTATIC:
#ifdef HAS_LOG
ao_log_stop();
#endif
break;
}
}
}
void
ao_pad_test(void)
{
uint8_t c;
printf ("Arm switch: ");
switch (query.arm_status) {
case AO_PAD_ARM_STATUS_ARMED:
printf ("Armed\n");
break;
case AO_PAD_ARM_STATUS_DISARMED:
printf ("Disarmed\n");
break;
case AO_PAD_ARM_STATUS_UNKNOWN:
printf ("Unknown\n");
break;
}
for (c = 0; c < AO_PAD_NUM; c++) {
printf ("Pad %d: ", c);
switch (query.igniter_status[c]) {
case AO_PAD_IGNITER_STATUS_NO_IGNITER_RELAY_CLOSED: printf ("No igniter. Relay closed\n"); break;
case AO_PAD_IGNITER_STATUS_NO_IGNITER_RELAY_OPEN: printf ("No igniter. Relay open\n"); break;
case AO_PAD_IGNITER_STATUS_GOOD_IGNITER_RELAY_OPEN: printf ("Good igniter. Relay open\n"); break;
case AO_PAD_IGNITER_STATUS_UNKNOWN: printf ("Unknown\n"); break;
}
}
}
void
ao_pad_manual(void)
{
uint8_t ignite;
int repeat;
ao_cmd_white();
if (!ao_match_word("DoIt"))
return;
ao_cmd_decimal();
if (ao_cmd_status != ao_cmd_success)
return;
ignite = 1 << ao_cmd_lex_i;
ao_cmd_decimal();
if (ao_cmd_status != ao_cmd_success) {
repeat = 1;
ao_cmd_status = ao_cmd_success;
} else
repeat = ao_cmd_lex_i;
while (repeat-- > 0) {
ao_pad_ignite = ignite;
ao_wakeup(&ao_pad_ignite);
ao_delay(AO_PAD_FIRE_TIME>>1);
}
}
static __xdata struct ao_task ao_pad_task;
static __xdata struct ao_task ao_pad_ignite_task;
static __xdata struct ao_task ao_pad_monitor_task;
#if DEBUG
void
ao_pad_set_debug(void)
{
ao_cmd_decimal();
if (ao_cmd_status == ao_cmd_success)
ao_pad_debug = ao_cmd_lex_i != 0;
}
static void
ao_pad_alarm_debug(void)
{
uint8_t which, value;
ao_cmd_decimal();
if (ao_cmd_status != ao_cmd_success)
return;
which = ao_cmd_lex_i;
ao_cmd_decimal();
if (ao_cmd_status != ao_cmd_success)
return;
value = ao_cmd_lex_i;
printf ("Set %s to %d\n", which ? "siren" : "strobe", value);
if (which)
ao_siren(value);
else
ao_strobe(value);
}
#endif
__code struct ao_cmds ao_pad_cmds[] = {
{ ao_pad_test, "t\0Test pad continuity" },
{ ao_pad_manual, "i <key> <n>\0Fire igniter. <key> is doit with D&I" },
#if DEBUG
{ ao_pad_set_debug, "D <0 off, 1 on>\0Debug" },
{ ao_pad_alarm_debug, "S <0 strobe, 1 siren> <0 off, 1 on>\0Set alarm output" },
#endif
{ 0, NULL }
};
void
ao_pad_init(void)
{
#if AO_PAD_NUM > 0
ao_enable_output(AO_PAD_PORT, AO_PAD_PIN_0, AO_PAD_0, 0);
#endif
#if AO_PAD_NUM > 1
ao_enable_output(AO_PAD_PORT, AO_PAD_PIN_1, AO_PAD_1, 0);
#endif
#if AO_PAD_NUM > 2
ao_enable_output(AO_PAD_PORT, AO_PAD_PIN_2, AO_PAD_2, 0);
#endif
#if AO_PAD_NUM > 3
ao_enable_output(AO_PAD_PORT, AO_PAD_PIN_3, AO_PAD_3, 0);
#endif
#ifdef AO_STROBE
ao_enable_output(AO_STROBE_PORT, AO_STROBE_PIN, AO_STROBE, 0);
#endif
#ifdef AO_SIREN
ao_enable_output(AO_SIREN_PORT, AO_SIREN_PIN, AO_SIREN, 0);
#endif
ao_cmd_register(&ao_pad_cmds[0]);
ao_add_task(&ao_pad_task, ao_pad, "pad listener");
ao_add_task(&ao_pad_ignite_task, ao_pad_run, "pad igniter");
ao_add_task(&ao_pad_monitor_task, ao_pad_monitor, "pad monitor");
}
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