ardupilot/libraries/AP_HAL_Linux/RCInput.cpp

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#include <errno.h>
#include <fcntl.h>
#include <poll.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <unistd.h>
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#include <AP_HAL/AP_HAL.h>
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#include <AP_HAL/utility/dsm.h>
#include <AP_HAL/utility/sumd.h>
#include <AP_HAL/utility/st24.h>
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#include <AP_HAL/utility/srxl.h>
#include <AP_RCProtocol/AP_RCProtocol_SBUS.h>
#include "RCInput.h"
#define MIN_NUM_CHANNELS 5
extern const AP_HAL::HAL& hal;
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using namespace Linux;
RCInput::RCInput()
{
ppm_state._channel_counter = -1;
}
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void RCInput::init()
{
}
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bool RCInput::new_input()
{
bool ret = rc_input_count != last_rc_input_count;
if (ret) {
last_rc_input_count.store(rc_input_count);
}
return ret;
}
uint8_t RCInput::num_channels()
{
return _num_channels;
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}
void RCInput::set_num_channels(uint8_t num)
{
_num_channels = num;
}
uint16_t RCInput::read(uint8_t ch)
{
if (ch >= _num_channels) {
return 0;
}
return _pwm_values[ch];
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}
uint8_t RCInput::read(uint16_t* periods, uint8_t len)
{
uint8_t i;
for (i=0; i<len; i++) {
periods[i] = read(i);
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}
return len;
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}
/*
process a PPM-sum pulse of the given width
*/
void RCInput::_process_ppmsum_pulse(uint16_t width_usec)
{
if (width_usec >= 2700) {
// a long pulse indicates the end of a frame. Reset the
// channel counter so next pulse is channel 0
if (ppm_state._channel_counter >= MIN_NUM_CHANNELS) {
for (uint8_t i=0; i<ppm_state._channel_counter; i++) {
_pwm_values[i] = ppm_state._pulse_capt[i];
}
_num_channels = ppm_state._channel_counter;
rc_input_count++;
}
ppm_state._channel_counter = 0;
return;
}
if (ppm_state._channel_counter == -1) {
// we are not synchronised
return;
}
/*
we limit inputs to between 700usec and 2300usec. This allows us
to decode SBUS on the same pin, as SBUS will have a maximum
pulse width of 100usec
*/
if (width_usec > 700 && width_usec < 2300) {
// take a reading for the current channel
// buffer these
ppm_state._pulse_capt[ppm_state._channel_counter] = width_usec;
// move to next channel
ppm_state._channel_counter++;
}
// if we have reached the maximum supported channels then
// mark as unsynchronised, so we wait for a wide pulse
if (ppm_state._channel_counter >= LINUX_RC_INPUT_NUM_CHANNELS) {
for (uint8_t i=0; i<ppm_state._channel_counter; i++) {
_pwm_values[i] = ppm_state._pulse_capt[i];
}
_num_channels = ppm_state._channel_counter;
rc_input_count++;
ppm_state._channel_counter = -1;
}
}
/*
process a SBUS input pulse of the given width
*/
void RCInput::_process_sbus_pulse(uint16_t width_s0, uint16_t width_s1)
{
// convert to bit widths, allowing for up to 1usec error, assuming 100000 bps
uint16_t bits_s0 = (width_s0+1) / 10;
uint16_t bits_s1 = (width_s1+1) / 10;
uint16_t nlow;
uint8_t byte_ofs = sbus_state.bit_ofs/12;
uint8_t bit_ofs = sbus_state.bit_ofs%12;
if (bits_s0 == 0 || bits_s1 == 0) {
// invalid data
goto reset;
}
if (bits_s0+bit_ofs > 10) {
// invalid data as last two bits must be stop bits
goto reset;
}
// pull in the high bits
sbus_state.bytes[byte_ofs] |= ((1U<<bits_s0)-1) << bit_ofs;
sbus_state.bit_ofs += bits_s0;
bit_ofs += bits_s0;
// pull in the low bits
nlow = bits_s1;
if (nlow + bit_ofs > 12) {
nlow = 12 - bit_ofs;
}
bits_s1 -= nlow;
sbus_state.bit_ofs += nlow;
if (sbus_state.bit_ofs == 25*12 && bits_s1 > 12) {
// we have a full frame
uint8_t bytes[25];
uint8_t i;
for (i=0; i<25; i++) {
// get inverted data
uint16_t v = ~sbus_state.bytes[i];
// check start bit
if ((v & 1) != 0) {
goto reset;
}
// check stop bits
if ((v & 0xC00) != 0xC00) {
goto reset;
}
// check parity
uint8_t parity = 0, j;
for (j=1; j<=8; j++) {
parity ^= (v & (1U<<j))?1:0;
}
if (parity != (v&0x200)>>9) {
goto reset;
}
bytes[i] = ((v>>1) & 0xFF);
}
uint16_t values[LINUX_RC_INPUT_NUM_CHANNELS];
uint16_t num_values=0;
bool sbus_failsafe=false;
if (AP_RCProtocol_SBUS::sbus_decode(bytes, values, &num_values,
sbus_failsafe,
LINUX_RC_INPUT_NUM_CHANNELS) &&
num_values >= MIN_NUM_CHANNELS) {
for (i=0; i<num_values; i++) {
_pwm_values[i] = values[i];
}
_num_channels = num_values;
if (!sbus_failsafe) {
rc_input_count++;
}
}
goto reset;
} else if (bits_s1 > 12) {
// break
goto reset;
}
return;
reset:
memset(&sbus_state, 0, sizeof(sbus_state));
}
void RCInput::_process_dsm_pulse(uint16_t width_s0, uint16_t width_s1)
{
// convert to bit widths, allowing for up to 1usec error, assuming 115200 bps
uint16_t bits_s0 = ((width_s0+4)*(uint32_t)115200) / 1000000;
uint16_t bits_s1 = ((width_s1+4)*(uint32_t)115200) / 1000000;
uint8_t bit_ofs, byte_ofs;
uint16_t nbits;
if (bits_s0 == 0 || bits_s1 == 0) {
// invalid data
goto reset;
}
byte_ofs = dsm_state.bit_ofs/10;
bit_ofs = dsm_state.bit_ofs%10;
if(byte_ofs > 15) {
// invalid data
goto reset;
}
// pull in the high bits
nbits = bits_s0;
if (nbits+bit_ofs > 10) {
nbits = 10 - bit_ofs;
}
dsm_state.bytes[byte_ofs] |= ((1U<<nbits)-1) << bit_ofs;
dsm_state.bit_ofs += nbits;
bit_ofs += nbits;
if (bits_s0 - nbits > 10) {
if (dsm_state.bit_ofs == 16*10) {
// we have a full frame
uint8_t bytes[16];
uint8_t i;
for (i=0; i<16; i++) {
// get raw data
uint16_t v = dsm_state.bytes[i];
// check start bit
if ((v & 1) != 0) {
goto reset;
}
// check stop bits
if ((v & 0x200) != 0x200) {
goto reset;
}
bytes[i] = ((v>>1) & 0xFF);
}
uint16_t values[8];
uint16_t num_values=0;
if (dsm_decode(AP_HAL::micros64(), bytes, values, &num_values, 8) &&
num_values >= MIN_NUM_CHANNELS) {
for (i=0; i<num_values; i++) {
_pwm_values[i] = values[i];
}
_num_channels = num_values;
rc_input_count++;
}
}
memset(&dsm_state, 0, sizeof(dsm_state));
}
byte_ofs = dsm_state.bit_ofs/10;
bit_ofs = dsm_state.bit_ofs%10;
if (bits_s1+bit_ofs > 10) {
// invalid data
goto reset;
}
// pull in the low bits
dsm_state.bit_ofs += bits_s1;
return;
reset:
memset(&dsm_state, 0, sizeof(dsm_state));
}
void RCInput::_process_pwm_pulse(uint16_t channel, uint16_t width_s0, uint16_t width_s1)
{
if (channel < _num_channels) {
_pwm_values[channel] = width_s1; // range: 700usec ~ 2300usec
rc_input_count++;
}
}
/*
process a RC input pulse of the given width
*/
void RCInput::_process_rc_pulse(uint16_t width_s0, uint16_t width_s1)
{
#if 0
// useful for debugging
static FILE *rclog;
if (rclog == nullptr) {
rclog = fopen("/tmp/rcin.log", "w");
}
if (rclog) {
fprintf(rclog, "%u %u\n", (unsigned)width_s0, (unsigned)width_s1);
}
#endif
// treat as PPM-sum
_process_ppmsum_pulse(width_s0 + width_s1);
// treat as SBUS
_process_sbus_pulse(width_s0, width_s1);
// treat as DSM
_process_dsm_pulse(width_s0, width_s1);
}
/*
* Update channel values directly
*/
void RCInput::_update_periods(uint16_t *periods, uint8_t len)
{
if (len > LINUX_RC_INPUT_NUM_CHANNELS) {
len = LINUX_RC_INPUT_NUM_CHANNELS;
}
for (unsigned int i=0; i < len; i++) {
_pwm_values[i] = periods[i];
}
_num_channels = len;
rc_input_count++;
}
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/*
add some bytes of input in DSM serial stream format, coping with partial packets
*/
bool RCInput::add_dsm_input(const uint8_t *bytes, size_t nbytes)
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{
if (nbytes == 0) {
return false;
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}
const uint8_t dsm_frame_size = sizeof(dsm.frame);
bool ret = false;
uint32_t now = AP_HAL::millis();
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if (now - dsm.last_input_ms > 5) {
// resync based on time
dsm.partial_frame_count = 0;
}
dsm.last_input_ms = now;
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while (nbytes > 0) {
size_t n = nbytes;
if (dsm.partial_frame_count + n > dsm_frame_size) {
n = dsm_frame_size - dsm.partial_frame_count;
}
if (n > 0) {
memcpy(&dsm.frame[dsm.partial_frame_count], bytes, n);
dsm.partial_frame_count += n;
nbytes -= n;
bytes += n;
}
if (dsm.partial_frame_count == dsm_frame_size) {
dsm.partial_frame_count = 0;
uint16_t values[16] {};
uint16_t num_values=0;
/*
we only accept input when nbytes==0 as dsm is highly
sensitive to framing, and extra bytes may be an
indication this is really SRXL
*/
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if (dsm_decode(AP_HAL::micros64(), dsm.frame, values, &num_values, 16) &&
num_values >= MIN_NUM_CHANNELS &&
nbytes == 0) {
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for (uint8_t i=0; i<num_values; i++) {
if (values[i] != 0) {
_pwm_values[i] = values[i];
}
}
/*
the apparent number of channels can change on DSM,
as they are spread across multiple frames. We just
use the max num_values we get
*/
if (num_values > _num_channels) {
_num_channels = num_values;
}
rc_input_count++;
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#if 0
printf("Decoded DSM %u channels %u %u %u %u %u %u %u %u\n",
(unsigned)num_values,
values[0], values[1], values[2], values[3], values[4], values[5], values[6], values[7]);
#endif
ret = true;
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}
}
}
return ret;
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}
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/*
add some bytes of input in SUMD serial stream format, coping with partial packets
*/
bool RCInput::add_sumd_input(const uint8_t *bytes, size_t nbytes)
{
uint16_t values[LINUX_RC_INPUT_NUM_CHANNELS];
uint8_t rssi;
uint8_t rx_count;
uint16_t channel_count;
bool ret = false;
while (nbytes > 0) {
if (sumd_decode(*bytes++, &rssi, &rx_count, &channel_count, values, LINUX_RC_INPUT_NUM_CHANNELS) == 0) {
if (channel_count > LINUX_RC_INPUT_NUM_CHANNELS) {
continue;
}
for (uint8_t i=0; i<channel_count; i++) {
if (values[i] != 0) {
_pwm_values[i] = values[i];
}
}
_num_channels = channel_count;
rc_input_count++;
ret = true;
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_rssi = rssi;
}
nbytes--;
}
return ret;
}
/*
add some bytes of input in ST24 serial stream format, coping with partial packets
*/
bool RCInput::add_st24_input(const uint8_t *bytes, size_t nbytes)
{
uint16_t values[LINUX_RC_INPUT_NUM_CHANNELS];
uint8_t rssi;
uint8_t rx_count;
uint16_t channel_count;
bool ret = false;
while (nbytes > 0) {
if (st24_decode(*bytes++, &rssi, &rx_count, &channel_count, values, LINUX_RC_INPUT_NUM_CHANNELS) == 0) {
if (channel_count > LINUX_RC_INPUT_NUM_CHANNELS) {
continue;
}
for (uint8_t i=0; i<channel_count; i++) {
if (values[i] != 0) {
_pwm_values[i] = values[i];
}
}
_num_channels = channel_count;
rc_input_count++;
ret = true;
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_rssi = rssi;
}
nbytes--;
}
return ret;
}
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/*
add some bytes of input in SRXL serial stream format, coping with partial packets
*/
bool RCInput::add_srxl_input(const uint8_t *bytes, size_t nbytes)
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{
uint16_t values[LINUX_RC_INPUT_NUM_CHANNELS];
uint8_t channel_count;
uint64_t now = AP_HAL::micros64();
bool ret = false;
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bool failsafe_state;
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while (nbytes > 0) {
if (srxl_decode(now, *bytes++, &channel_count, values, LINUX_RC_INPUT_NUM_CHANNELS, &failsafe_state) == 0) {
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if (channel_count > LINUX_RC_INPUT_NUM_CHANNELS) {
continue;
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}
for (uint8_t i=0; i<channel_count; i++) {
_pwm_values[i] = values[i];
}
_num_channels = channel_count;
if (failsafe_state == false) {
rc_input_count++;
}
ret = true;
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}
nbytes--;
}
return ret;
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}
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/*
add some bytes of input in SBUS serial stream format, coping with partial packets
*/
void RCInput::add_sbus_input(const uint8_t *bytes, size_t nbytes)
{
if (nbytes == 0) {
return;
}
const uint8_t sbus_frame_size = sizeof(sbus.frame);
uint32_t now = AP_HAL::millis();
if (now - sbus.last_input_ms > 5) {
// resync based on time
sbus.partial_frame_count = 0;
}
sbus.last_input_ms = now;
while (nbytes > 0) {
size_t n = nbytes;
if (sbus.partial_frame_count + n > sbus_frame_size) {
n = sbus_frame_size - sbus.partial_frame_count;
}
if (n > 0) {
memcpy(&sbus.frame[sbus.partial_frame_count], bytes, n);
sbus.partial_frame_count += n;
nbytes -= n;
bytes += n;
}
if (sbus.partial_frame_count == sbus_frame_size) {
sbus.partial_frame_count = 0;
uint16_t values[16] {};
uint16_t num_values=0;
bool sbus_failsafe;
if (AP_RCProtocol_SBUS::sbus_decode(sbus.frame, values, &num_values, sbus_failsafe, 16) &&
num_values >= MIN_NUM_CHANNELS) {
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for (uint8_t i=0; i<num_values; i++) {
if (values[i] != 0) {
_pwm_values[i] = values[i];
}
}
/*
the apparent number of channels can change on SBUS,
as they are spread across multiple frames. We just
use the max num_values we get
*/
if (num_values > _num_channels) {
_num_channels = num_values;
}
if (!sbus_failsafe) {
rc_input_count++;
}
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#if 0
printf("Decoded SBUS %u channels %u %u %u %u %u %u %u %u %s\n",
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(unsigned)num_values,
values[0], values[1], values[2], values[3], values[4], values[5], values[6], values[7],
sbus_failsafe?"FAIL":"OK");
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#endif
}
}
}
}