ardupilot/Tools/AP_Periph/can.cpp

2759 lines
96 KiB
C++

/*
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 3 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, see <http://www.gnu.org/licenses/>.
*/
/*
AP_Periph can support
*/
#include <AP_HAL/AP_HAL.h>
#include <AP_Math/AP_Math.h>
#include <AP_HAL/AP_HAL_Boards.h>
#include "AP_Periph.h"
#include <canard.h>
#include <AP_GPS/RTCM3_Parser.h>
#include <stdio.h>
#include <drivers/stm32/canard_stm32.h>
#include <AP_HAL/I2CDevice.h>
#include <AP_HAL/utility/RingBuffer.h>
#include <AP_Common/AP_FWVersion.h>
#include <dronecan_msgs.h>
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
#include <hal.h>
#include <AP_HAL_ChibiOS/CANIface.h>
#include <AP_HAL_ChibiOS/hwdef/common/stm32_util.h>
#include <AP_HAL_ChibiOS/hwdef/common/watchdog.h>
#elif CONFIG_HAL_BOARD == HAL_BOARD_SITL
#include <AP_HAL_SITL/CANSocketIface.h>
#endif
#define IFACE_ALL ((1U<<(HAL_NUM_CAN_IFACES+1U))-1U)
#include "i2c.h"
#include <utility>
#if HAL_NUM_CAN_IFACES >= 2
#include <AP_CANManager/AP_CANSensor.h>
#endif
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
extern const HAL_SITL &hal;
#else
extern const AP_HAL::HAL &hal;
#endif
extern AP_Periph_FW periph;
#ifndef HAL_CAN_POOL_SIZE
#if HAL_CANFD_SUPPORTED
#define HAL_CAN_POOL_SIZE 16000
#else
#define HAL_CAN_POOL_SIZE 4000
#endif
#endif
#ifndef HAL_PERIPH_LOOP_DELAY_US
// delay between can loop updates. This needs to be longer on F4
#if defined(STM32H7)
#define HAL_PERIPH_LOOP_DELAY_US 64
#else
#define HAL_PERIPH_LOOP_DELAY_US 1024
#endif
#endif
#ifndef AP_PERIPH_MAG_MAX_RATE
#define AP_PERIPH_MAG_MAX_RATE 25U
#endif
#define DEBUG_PRINTS 0
#define DEBUG_PKTS 0
#if DEBUG_PRINTS
# define Debug(fmt, args ...) do {can_printf(fmt "\n", ## args);} while(0)
#else
# define Debug(fmt, args ...)
#endif
#ifndef HAL_PERIPH_SUPPORT_LONG_CAN_PRINTF
// When enabled, can_printf() strings longer than the droneCAN max text length (90 chars)
// are split into multiple packets instead of truncating the string. This is
// especially helpful with HAL_GCS_ENABLED where libraries use the mavlink
// send_text() method where we support strings up to 256 chars by splitting them
// up into multiple 50 char mavlink packets.
#define HAL_PERIPH_SUPPORT_LONG_CAN_PRINTF (BOARD_FLASH_SIZE >= 1024)
#endif
static struct instance_t {
uint8_t index;
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
AP_HAL::CANIface* iface;
#elif CONFIG_HAL_BOARD == HAL_BOARD_SITL
HALSITL::CANIface* iface;
#endif
} instances[HAL_NUM_CAN_IFACES];
static struct dronecan_protocol_t {
CanardInstance canard;
uint32_t canard_memory_pool[HAL_CAN_POOL_SIZE/sizeof(uint32_t)];
struct tid_map {
uint32_t transfer_desc;
uint8_t tid;
tid_map *next;
} *tid_map_head;
/*
* Variables used for dynamic node ID allocation.
* RTFM at http://uavcan.org/Specification/6._Application_level_functions/#dynamic-node-id-allocation
*/
uint32_t send_next_node_id_allocation_request_at_ms; ///< When the next node ID allocation request should be sent
uint8_t node_id_allocation_unique_id_offset; ///< Depends on the stage of the next request
uint8_t tx_fail_count;
uint8_t dna_interface = 1;
} dronecan;
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS && defined(HAL_GPIO_PIN_TERMCAN1)
static ioline_t can_term_lines[] = {
HAL_GPIO_PIN_TERMCAN1
#if HAL_NUM_CAN_IFACES > 2
#ifdef HAL_GPIO_PIN_TERMCAN2
,HAL_GPIO_PIN_TERMCAN2
#else
#error "Only one Can Terminator defined with over two CAN Ifaces"
#endif
#endif
#if HAL_NUM_CAN_IFACES > 2
#ifdef HAL_GPIO_PIN_TERMCAN3
,HAL_GPIO_PIN_TERMCAN3
#else
#error "Only two Can Terminator defined with three CAN Ifaces"
#endif
#endif
};
#endif // CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS && defined(HAL_GPIO_PIN_TERMCAN1)
#ifndef CAN_APP_NODE_NAME
#define CAN_APP_NODE_NAME "org.ardupilot.ap_periph"
#endif
#ifndef HAL_CAN_DEFAULT_NODE_ID
#define HAL_CAN_DEFAULT_NODE_ID CANARD_BROADCAST_NODE_ID
#endif
uint8_t PreferredNodeID = HAL_CAN_DEFAULT_NODE_ID;
#ifndef AP_PERIPH_BATTERY_MODEL_NAME
#define AP_PERIPH_BATTERY_MODEL_NAME CAN_APP_NODE_NAME
#endif
#ifndef AP_PERIPH_PROBE_CONTINUOUS
#define AP_PERIPH_PROBE_CONTINUOUS 0
#endif
#ifndef AP_PERIPH_ENFORCE_AT_LEAST_ONE_PORT_IS_UAVCAN_1MHz
#define AP_PERIPH_ENFORCE_AT_LEAST_ONE_PORT_IS_UAVCAN_1MHz 1
#endif
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
ChibiOS::CANIface* AP_Periph_FW::can_iface_periph[HAL_NUM_CAN_IFACES];
#elif CONFIG_HAL_BOARD == HAL_BOARD_SITL
HALSITL::CANIface* AP_Periph_FW::can_iface_periph[HAL_NUM_CAN_IFACES];
#endif
#if AP_CAN_SLCAN_ENABLED
SLCAN::CANIface AP_Periph_FW::slcan_interface;
#endif
/*
* Node status variables
*/
static uavcan_protocol_NodeStatus node_status;
/**
* Returns a pseudo random integer in a given range
*/
static uint16_t get_random_range(uint16_t range)
{
return get_random16() % range;
}
/*
get cpu unique ID
*/
static void readUniqueID(uint8_t* out_uid)
{
uint8_t len = sizeof(uavcan_protocol_dynamic_node_id_Allocation::unique_id.data);
memset(out_uid, 0, len);
hal.util->get_system_id_unformatted(out_uid, len);
}
/*
handle a GET_NODE_INFO request
*/
static void handle_get_node_info(CanardInstance* ins,
CanardRxTransfer* transfer)
{
uint8_t buffer[UAVCAN_PROTOCOL_GETNODEINFO_RESPONSE_MAX_SIZE] {};
uavcan_protocol_GetNodeInfoResponse pkt {};
node_status.uptime_sec = AP_HAL::native_millis() / 1000U;
pkt.status = node_status;
pkt.software_version.major = AP::fwversion().major;
pkt.software_version.minor = AP::fwversion().minor;
pkt.software_version.optional_field_flags = UAVCAN_PROTOCOL_SOFTWAREVERSION_OPTIONAL_FIELD_FLAG_VCS_COMMIT | UAVCAN_PROTOCOL_SOFTWAREVERSION_OPTIONAL_FIELD_FLAG_IMAGE_CRC;
pkt.software_version.vcs_commit = app_descriptor.git_hash;
uint32_t *crc = (uint32_t *)&pkt.software_version.image_crc;
crc[0] = app_descriptor.image_crc1;
crc[1] = app_descriptor.image_crc2;
readUniqueID(pkt.hardware_version.unique_id);
// use hw major/minor for APJ_BOARD_ID so we know what fw is
// compatible with this hardware
pkt.hardware_version.major = APJ_BOARD_ID >> 8;
pkt.hardware_version.minor = APJ_BOARD_ID & 0xFF;
if (periph.g.serial_number > 0) {
hal.util->snprintf((char*)pkt.name.data, sizeof(pkt.name.data), "%s(%u)", CAN_APP_NODE_NAME, (unsigned)periph.g.serial_number);
} else {
hal.util->snprintf((char*)pkt.name.data, sizeof(pkt.name.data), "%s", CAN_APP_NODE_NAME);
}
pkt.name.len = strnlen((char*)pkt.name.data, sizeof(pkt.name.data));
uint16_t total_size = uavcan_protocol_GetNodeInfoResponse_encode(&pkt, buffer, !periph.canfdout());
const int16_t resp_res = canardRequestOrRespond(ins,
transfer->source_node_id,
UAVCAN_PROTOCOL_GETNODEINFO_SIGNATURE,
UAVCAN_PROTOCOL_GETNODEINFO_ID,
&transfer->transfer_id,
transfer->priority,
CanardResponse,
&buffer[0],
total_size
#if CANARD_MULTI_IFACE
, IFACE_ALL
#endif
#if HAL_CANFD_SUPPORTED
, periph.canfdout()
#endif
);
if (resp_res <= 0) {
printf("Could not respond to GetNodeInfo: %d\n", resp_res);
}
}
/*
handle parameter GetSet request
*/
static void handle_param_getset(CanardInstance* ins, CanardRxTransfer* transfer)
{
// param fetch all can take a long time, so pat watchdog
stm32_watchdog_pat();
uavcan_protocol_param_GetSetRequest req;
if (uavcan_protocol_param_GetSetRequest_decode(transfer, &req)) {
return;
}
uavcan_protocol_param_GetSetResponse pkt {};
AP_Param *vp;
enum ap_var_type ptype;
if (req.name.len != 0 && req.name.len > AP_MAX_NAME_SIZE) {
vp = nullptr;
} else if (req.name.len != 0 && req.name.len <= AP_MAX_NAME_SIZE) {
memcpy((char *)pkt.name.data, (char *)req.name.data, req.name.len);
vp = AP_Param::find((char *)pkt.name.data, &ptype);
} else {
AP_Param::ParamToken token {};
vp = AP_Param::find_by_index(req.index, &ptype, &token);
if (vp != nullptr) {
vp->copy_name_token(token, (char *)pkt.name.data, AP_MAX_NAME_SIZE+1, true);
}
}
if (vp != nullptr && req.name.len != 0 && req.value.union_tag != UAVCAN_PROTOCOL_PARAM_VALUE_EMPTY) {
// param set
switch (ptype) {
case AP_PARAM_INT8:
if (req.value.union_tag != UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE) {
return;
}
((AP_Int8 *)vp)->set_and_save_ifchanged(req.value.integer_value);
break;
case AP_PARAM_INT16:
if (req.value.union_tag != UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE) {
return;
}
((AP_Int16 *)vp)->set_and_save_ifchanged(req.value.integer_value);
break;
case AP_PARAM_INT32:
if (req.value.union_tag != UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE) {
return;
}
((AP_Int32 *)vp)->set_and_save_ifchanged(req.value.integer_value);
break;
case AP_PARAM_FLOAT:
if (req.value.union_tag != UAVCAN_PROTOCOL_PARAM_VALUE_REAL_VALUE) {
return;
}
((AP_Float *)vp)->set_and_save_ifchanged(req.value.real_value);
break;
default:
return;
}
}
if (vp != nullptr) {
switch (ptype) {
case AP_PARAM_INT8:
pkt.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE;
pkt.value.integer_value = ((AP_Int8 *)vp)->get();
break;
case AP_PARAM_INT16:
pkt.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE;
pkt.value.integer_value = ((AP_Int16 *)vp)->get();
break;
case AP_PARAM_INT32:
pkt.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_INTEGER_VALUE;
pkt.value.integer_value = ((AP_Int32 *)vp)->get();
break;
case AP_PARAM_FLOAT:
pkt.value.union_tag = UAVCAN_PROTOCOL_PARAM_VALUE_REAL_VALUE;
pkt.value.real_value = ((AP_Float *)vp)->get();
break;
default:
return;
}
pkt.name.len = strnlen((char *)pkt.name.data, sizeof(pkt.name.data));
}
uint8_t buffer[UAVCAN_PROTOCOL_PARAM_GETSET_RESPONSE_MAX_SIZE] {};
uint16_t total_size = uavcan_protocol_param_GetSetResponse_encode(&pkt, buffer, !periph.canfdout());
canardRequestOrRespond(ins,
transfer->source_node_id,
UAVCAN_PROTOCOL_PARAM_GETSET_SIGNATURE,
UAVCAN_PROTOCOL_PARAM_GETSET_ID,
&transfer->transfer_id,
transfer->priority,
CanardResponse,
&buffer[0],
total_size
#if CANARD_MULTI_IFACE
, IFACE_ALL
#endif
#if HAL_CANFD_SUPPORTED
,periph.canfdout()
#endif
);
}
/*
handle parameter executeopcode request
*/
static void handle_param_executeopcode(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_protocol_param_ExecuteOpcodeRequest req;
if (uavcan_protocol_param_ExecuteOpcodeRequest_decode(transfer, &req)) {
return;
}
if (req.opcode == UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_REQUEST_OPCODE_ERASE) {
StorageManager::erase();
AP_Param::erase_all();
AP_Param::load_all();
AP_Param::setup_sketch_defaults();
#ifdef HAL_PERIPH_ENABLE_GPS
AP_Param::setup_object_defaults(&periph.gps, periph.gps.var_info);
#endif
#ifdef HAL_PERIPH_ENABLE_BATTERY
AP_Param::setup_object_defaults(&periph.battery, periph.battery.lib.var_info);
#endif
#ifdef HAL_PERIPH_ENABLE_MAG
AP_Param::setup_object_defaults(&periph.compass, periph.compass.var_info);
#endif
#ifdef HAL_PERIPH_ENABLE_BARO
AP_Param::setup_object_defaults(&periph.baro, periph.baro.var_info);
#endif
#ifdef HAL_PERIPH_ENABLE_AIRSPEED
AP_Param::setup_object_defaults(&periph.airspeed, periph.airspeed.var_info);
#endif
#ifdef HAL_PERIPH_ENABLE_RANGEFINDER
AP_Param::setup_object_defaults(&periph.rangefinder, periph.rangefinder.var_info);
#endif
}
uavcan_protocol_param_ExecuteOpcodeResponse pkt {};
pkt.ok = true;
uint8_t buffer[UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_RESPONSE_MAX_SIZE] {};
uint16_t total_size = uavcan_protocol_param_ExecuteOpcodeResponse_encode(&pkt, buffer, !periph.canfdout());
canardRequestOrRespond(ins,
transfer->source_node_id,
UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_SIGNATURE,
UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_ID,
&transfer->transfer_id,
transfer->priority,
CanardResponse,
&buffer[0],
total_size
#if CANARD_MULTI_IFACE
, IFACE_ALL
#endif
#if HAL_CANFD_SUPPORTED
,periph.canfdout()
#endif
);
}
static void canard_broadcast(uint64_t data_type_signature,
uint16_t data_type_id,
uint8_t priority,
const void* payload,
uint16_t payload_len);
static void processTx(void);
static void processRx(void);
static void handle_begin_firmware_update(CanardInstance* ins, CanardRxTransfer* transfer)
{
#if HAL_RAM_RESERVE_START >= 256
// setup information on firmware request at start of ram
struct app_bootloader_comms *comms = (struct app_bootloader_comms *)HAL_RAM0_START;
memset(comms, 0, sizeof(struct app_bootloader_comms));
comms->magic = APP_BOOTLOADER_COMMS_MAGIC;
uavcan_protocol_file_BeginFirmwareUpdateRequest req;
if (uavcan_protocol_file_BeginFirmwareUpdateRequest_decode(transfer, &req)) {
return;
}
comms->server_node_id = req.source_node_id;
if (comms->server_node_id == 0) {
comms->server_node_id = transfer->source_node_id;
}
memcpy(comms->path, req.image_file_remote_path.path.data, req.image_file_remote_path.path.len);
comms->my_node_id = canardGetLocalNodeID(ins);
uint8_t buffer[UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_RESPONSE_MAX_SIZE] {};
uavcan_protocol_file_BeginFirmwareUpdateResponse reply {};
reply.error = UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_RESPONSE_ERROR_OK;
uint32_t total_size = uavcan_protocol_file_BeginFirmwareUpdateResponse_encode(&reply, buffer, !periph.canfdout());
canardRequestOrRespond(ins,
transfer->source_node_id,
UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_SIGNATURE,
UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_ID,
&transfer->transfer_id,
transfer->priority,
CanardResponse,
&buffer[0],
total_size
#if CANARD_MULTI_IFACE
,IFACE_ALL
#endif
#if HAL_CANFD_SUPPORTED
,periph.canfdout()
#endif
);
uint8_t count = 50;
while (count--) {
processTx();
hal.scheduler->delay(1);
}
#endif
// instant reboot, with backup register used to give bootloader
// the node_id
periph.prepare_reboot();
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
set_fast_reboot((rtc_boot_magic)(RTC_BOOT_CANBL | canardGetLocalNodeID(ins)));
NVIC_SystemReset();
#endif
}
static void handle_allocation_response(CanardInstance* ins, CanardRxTransfer* transfer)
{
// Rule C - updating the randomized time interval
dronecan.send_next_node_id_allocation_request_at_ms =
AP_HAL::native_millis() + UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_MIN_REQUEST_PERIOD_MS +
get_random_range(UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_MAX_FOLLOWUP_DELAY_MS);
if (transfer->source_node_id == CANARD_BROADCAST_NODE_ID)
{
printf("Allocation request from another allocatee\n");
dronecan.node_id_allocation_unique_id_offset = 0;
return;
}
// Copying the unique ID from the message
uavcan_protocol_dynamic_node_id_Allocation msg;
uavcan_protocol_dynamic_node_id_Allocation_decode(transfer, &msg);
// Obtaining the local unique ID
uint8_t my_unique_id[sizeof(msg.unique_id.data)];
readUniqueID(my_unique_id);
// Matching the received UID against the local one
if (memcmp(msg.unique_id.data, my_unique_id, msg.unique_id.len) != 0) {
printf("Mismatching allocation response\n");
dronecan.node_id_allocation_unique_id_offset = 0;
return; // No match, return
}
if (msg.unique_id.len < sizeof(msg.unique_id.data)) {
// The allocator has confirmed part of unique ID, switching to the next stage and updating the timeout.
dronecan.node_id_allocation_unique_id_offset = msg.unique_id.len;
dronecan.send_next_node_id_allocation_request_at_ms -= UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_MIN_REQUEST_PERIOD_MS;
printf("Matching allocation response: %d\n", msg.unique_id.len);
} else {
// Allocation complete - copying the allocated node ID from the message
canardSetLocalNodeID(ins, msg.node_id);
printf("IF%d Node ID allocated: %d\n", dronecan.dna_interface, msg.node_id);
#if defined(HAL_PERIPH_ENABLE_GPS) && (HAL_NUM_CAN_IFACES >= 2) && GPS_MOVING_BASELINE
if (periph.g.gps_mb_only_can_port) {
// we need to assign the unallocated port to be used for Moving Baseline only
periph.gps_mb_can_port = (dronecan.dna_interface+1)%HAL_NUM_CAN_IFACES;
if (canardGetLocalNodeID(&dronecan.canard) == CANARD_BROADCAST_NODE_ID) {
// copy node id from the primary iface
canardSetLocalNodeID(&dronecan.canard, msg.node_id);
#ifdef HAL_GPIO_PIN_TERMCAN1
// also terminate the line as we don't have any other device on this port
palWriteLine(can_term_lines[periph.gps_mb_can_port], 1);
#endif
}
}
#endif
}
}
#if defined(HAL_PERIPH_ENABLE_NOTIFY) || defined(HAL_PERIPH_ENABLE_BUZZER_WITHOUT_NOTIFY)
static uint32_t buzzer_start_ms;
static uint32_t buzzer_len_ms;
/*
handle BeepCommand
*/
static void handle_beep_command(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_equipment_indication_BeepCommand req;
if (uavcan_equipment_indication_BeepCommand_decode(transfer, &req)) {
return;
}
static bool initialised;
if (!initialised) {
initialised = true;
hal.rcout->init();
hal.util->toneAlarm_init(AP_Notify::Notify_Buzz_Builtin);
}
buzzer_start_ms = AP_HAL::native_millis();
buzzer_len_ms = req.duration*1000;
#ifdef HAL_PERIPH_ENABLE_BUZZER_WITHOUT_NOTIFY
float volume = constrain_float(periph.g.buzz_volume/100.0f, 0, 1);
#elif defined(HAL_PERIPH_ENABLE_NOTIFY)
float volume = constrain_float(periph.notify.get_buzz_volume()/100.0f, 0, 1);
#endif
hal.util->toneAlarm_set_buzzer_tone(req.frequency, volume, uint32_t(req.duration*1000));
}
/*
update buzzer
*/
static void can_buzzer_update(void)
{
if (buzzer_start_ms != 0) {
uint32_t now = AP_HAL::native_millis();
if (now - buzzer_start_ms > buzzer_len_ms) {
hal.util->toneAlarm_set_buzzer_tone(0, 0, 0);
buzzer_start_ms = 0;
}
}
}
#endif // (HAL_PERIPH_ENABLE_BUZZER_WITHOUT_NOTIFY) || (HAL_PERIPH_ENABLE_NOTIFY)
#if defined(HAL_GPIO_PIN_SAFE_LED) || defined(HAL_PERIPH_ENABLE_RC_OUT)
static uint8_t safety_state;
/*
handle SafetyState
*/
static void handle_safety_state(CanardInstance* ins, CanardRxTransfer* transfer)
{
ardupilot_indication_SafetyState req;
if (ardupilot_indication_SafetyState_decode(transfer, &req)) {
return;
}
safety_state = req.status;
#ifdef HAL_PERIPH_ENABLE_RC_OUT
periph.rcout_handle_safety_state(safety_state);
#endif
}
#endif // HAL_GPIO_PIN_SAFE_LED
/*
handle ArmingStatus
*/
static void handle_arming_status(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_equipment_safety_ArmingStatus req;
if (uavcan_equipment_safety_ArmingStatus_decode(transfer, &req)) {
return;
}
hal.util->set_soft_armed(req.status == UAVCAN_EQUIPMENT_SAFETY_ARMINGSTATUS_STATUS_FULLY_ARMED);
}
#ifdef HAL_PERIPH_ENABLE_GPS
/*
handle gnss::RTCMStream
*/
static void handle_RTCMStream(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_equipment_gnss_RTCMStream req;
if (uavcan_equipment_gnss_RTCMStream_decode(transfer, &req)) {
return;
}
periph.gps.handle_gps_rtcm_fragment(0, req.data.data, req.data.len);
}
/*
handle gnss::MovingBaselineData
*/
#if GPS_MOVING_BASELINE
static void handle_MovingBaselineData(CanardInstance* ins, CanardRxTransfer* transfer)
{
ardupilot_gnss_MovingBaselineData msg;
if (ardupilot_gnss_MovingBaselineData_decode(transfer, &msg)) {
return;
}
periph.gps.inject_MBL_data(msg.data.data, msg.data.len);
Debug("MovingBaselineData: len=%u\n", msg.data.len);
}
#endif // GPS_MOVING_BASELINE
#endif // HAL_PERIPH_ENABLE_GPS
#if defined(AP_PERIPH_HAVE_LED_WITHOUT_NOTIFY) || defined(HAL_PERIPH_ENABLE_NOTIFY)
static void set_rgb_led(uint8_t red, uint8_t green, uint8_t blue)
{
#ifdef HAL_PERIPH_ENABLE_NOTIFY
periph.notify.handle_rgb(red, green, blue);
#ifdef HAL_PERIPH_ENABLE_RC_OUT
periph.rcout_has_new_data_to_update = true;
#endif // HAL_PERIPH_ENABLE_RC_OUT
#endif // HAL_PERIPH_ENABLE_NOTIFY
#ifdef HAL_PERIPH_NEOPIXEL_COUNT_WITHOUT_NOTIFY
hal.rcout->set_serial_led_rgb_data(HAL_PERIPH_NEOPIXEL_CHAN_WITHOUT_NOTIFY, -1, red, green, blue);
hal.rcout->serial_led_send(HAL_PERIPH_NEOPIXEL_CHAN_WITHOUT_NOTIFY);
#endif // HAL_PERIPH_NEOPIXEL_COUNT_WITHOUT_NOTIFY
#ifdef HAL_PERIPH_ENABLE_NCP5623_LED_WITHOUT_NOTIFY
{
const uint8_t i2c_address = 0x38;
static AP_HAL::OwnPtr<AP_HAL::I2CDevice> dev;
if (!dev) {
dev = std::move(hal.i2c_mgr->get_device(0, i2c_address));
}
WITH_SEMAPHORE(dev->get_semaphore());
dev->set_retries(0);
uint8_t v = 0x3f; // enable LED
dev->transfer(&v, 1, nullptr, 0);
v = 0x40 | red >> 3; // red
dev->transfer(&v, 1, nullptr, 0);
v = 0x60 | green >> 3; // green
dev->transfer(&v, 1, nullptr, 0);
v = 0x80 | blue >> 3; // blue
dev->transfer(&v, 1, nullptr, 0);
}
#endif // HAL_PERIPH_ENABLE_NCP5623_LED_WITHOUT_NOTIFY
#ifdef HAL_PERIPH_ENABLE_NCP5623_BGR_LED_WITHOUT_NOTIFY
{
const uint8_t i2c_address = 0x38;
static AP_HAL::OwnPtr<AP_HAL::I2CDevice> dev;
if (!dev) {
dev = std::move(hal.i2c_mgr->get_device(0, i2c_address));
}
WITH_SEMAPHORE(dev->get_semaphore());
dev->set_retries(0);
uint8_t v = 0x3f; // enable LED
dev->transfer(&v, 1, nullptr, 0);
v = 0x40 | blue >> 3; // blue
dev->transfer(&v, 1, nullptr, 0);
v = 0x60 | green >> 3; // green
dev->transfer(&v, 1, nullptr, 0);
v = 0x80 | red >> 3; // red
dev->transfer(&v, 1, nullptr, 0);
}
#endif // HAL_PERIPH_ENABLE_NCP5623_BGR_LED_WITHOUT_NOTIFY
#ifdef HAL_PERIPH_ENABLE_TOSHIBA_LED_WITHOUT_NOTIFY
{
#define TOSHIBA_LED_PWM0 0x01 // pwm0 register
#define TOSHIBA_LED_ENABLE 0x04 // enable register
#define TOSHIBA_LED_I2C_ADDR 0x55 // default I2C bus address
static AP_HAL::OwnPtr<AP_HAL::I2CDevice> dev_toshiba;
if (!dev_toshiba) {
dev_toshiba = std::move(hal.i2c_mgr->get_device(0, TOSHIBA_LED_I2C_ADDR));
}
WITH_SEMAPHORE(dev_toshiba->get_semaphore());
dev_toshiba->set_retries(0); // use 0 because this is running on main thread.
// enable the led
dev_toshiba->write_register(TOSHIBA_LED_ENABLE, 0x03);
/* 4-bit for each color */
uint8_t val[4] = {
TOSHIBA_LED_PWM0,
(uint8_t)(blue >> 4),
(uint8_t)(green / 16),
(uint8_t)(red / 16)
};
dev_toshiba->transfer(val, sizeof(val), nullptr, 0);
}
#endif // HAL_PERIPH_ENABLE_TOSHIBA_LED_WITHOUT_NOTIFY
}
/*
handle lightscommand
*/
static void handle_lightscommand(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_equipment_indication_LightsCommand req;
if (uavcan_equipment_indication_LightsCommand_decode(transfer, &req)) {
return;
}
for (uint8_t i=0; i<req.commands.len; i++) {
uavcan_equipment_indication_SingleLightCommand &cmd = req.commands.data[i];
// to get the right color proportions we scale the green so that is uses the
// same number of bits as red and blue
uint8_t red = cmd.color.red<<3U;
uint8_t green = (cmd.color.green>>1U)<<3U;
uint8_t blue = cmd.color.blue<<3U;
#ifdef HAL_PERIPH_ENABLE_NOTIFY
const int8_t brightness = periph.notify.get_rgb_led_brightness_percent();
#elif defined(AP_PERIPH_HAVE_LED_WITHOUT_NOTIFY)
const int8_t brightness = periph.g.led_brightness;
#endif
if (brightness != 100 && brightness >= 0) {
const float scale = brightness * 0.01;
red = constrain_int16(red * scale, 0, 255);
green = constrain_int16(green * scale, 0, 255);
blue = constrain_int16(blue * scale, 0, 255);
}
set_rgb_led(red, green, blue);
}
}
#endif // AP_PERIPH_HAVE_LED_WITHOUT_NOTIFY
#ifdef HAL_PERIPH_ENABLE_RC_OUT
static void handle_esc_rawcommand(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_equipment_esc_RawCommand cmd;
if (uavcan_equipment_esc_RawCommand_decode(transfer, &cmd)) {
return;
}
periph.rcout_esc(cmd.cmd.data, cmd.cmd.len);
// Update internal copy for disabling output to ESC when CAN packets are lost
periph.last_esc_num_channels = cmd.cmd.len;
periph.last_esc_raw_command_ms = AP_HAL::millis();
}
static void handle_act_command(CanardInstance* ins, CanardRxTransfer* transfer)
{
uavcan_equipment_actuator_ArrayCommand cmd;
if (uavcan_equipment_actuator_ArrayCommand_decode(transfer, &cmd)) {
return;
}
for (uint8_t i=0; i < cmd.commands.len; i++) {
const auto &c = cmd.commands.data[i];
switch (c.command_type) {
case UAVCAN_EQUIPMENT_ACTUATOR_COMMAND_COMMAND_TYPE_UNITLESS:
periph.rcout_srv_unitless(c.actuator_id, c.command_value);
break;
case UAVCAN_EQUIPMENT_ACTUATOR_COMMAND_COMMAND_TYPE_PWM:
periph.rcout_srv_PWM(c.actuator_id, c.command_value);
break;
}
}
}
#endif // HAL_PERIPH_ENABLE_RC_OUT
#if defined(HAL_PERIPH_ENABLE_NOTIFY)
static void handle_notify_state(CanardInstance* ins, CanardRxTransfer* transfer)
{
ardupilot_indication_NotifyState msg;
if (ardupilot_indication_NotifyState_decode(transfer, &msg)) {
return;
}
if (msg.aux_data.len == 2 && msg.aux_data_type == ARDUPILOT_INDICATION_NOTIFYSTATE_VEHICLE_YAW_EARTH_CENTIDEGREES) {
uint16_t tmp = 0;
memcpy(&tmp, msg.aux_data.data, sizeof(tmp));
periph.yaw_earth = radians((float)tmp * 0.01f);
}
periph.vehicle_state = msg.vehicle_state;
periph.last_vehicle_state = AP_HAL::millis();
}
#endif // HAL_PERIPH_ENABLE_NOTIFY
#ifdef HAL_GPIO_PIN_SAFE_LED
/*
update safety LED
*/
static void can_safety_LED_update(void)
{
static uint32_t last_update_ms;
switch (safety_state) {
case ARDUPILOT_INDICATION_SAFETYSTATE_STATUS_SAFETY_OFF:
palWriteLine(HAL_GPIO_PIN_SAFE_LED, SAFE_LED_ON);
break;
case ARDUPILOT_INDICATION_SAFETYSTATE_STATUS_SAFETY_ON: {
uint32_t now = AP_HAL::native_millis();
if (now - last_update_ms > 100) {
last_update_ms = now;
static uint8_t led_counter;
const uint16_t led_pattern = 0x5500;
led_counter = (led_counter+1) % 16;
palWriteLine(HAL_GPIO_PIN_SAFE_LED, (led_pattern & (1U << led_counter))?!SAFE_LED_ON:SAFE_LED_ON);
}
break;
}
default:
palWriteLine(HAL_GPIO_PIN_SAFE_LED, !SAFE_LED_ON);
break;
}
}
#endif // HAL_GPIO_PIN_SAFE_LED
#ifdef HAL_GPIO_PIN_SAFE_BUTTON
#ifndef HAL_SAFE_BUTTON_ON
#define HAL_SAFE_BUTTON_ON 1
#endif
/*
update safety button
*/
static void can_safety_button_update(void)
{
static uint32_t last_update_ms;
static uint8_t counter;
uint32_t now = AP_HAL::native_millis();
// send at 10Hz when pressed
if (palReadLine(HAL_GPIO_PIN_SAFE_BUTTON) != HAL_SAFE_BUTTON_ON) {
counter = 0;
return;
}
if (now - last_update_ms < 100) {
return;
}
if (counter < 255) {
counter++;
}
last_update_ms = now;
ardupilot_indication_Button pkt {};
pkt.button = ARDUPILOT_INDICATION_BUTTON_BUTTON_SAFETY;
pkt.press_time = counter;
uint8_t buffer[ARDUPILOT_INDICATION_BUTTON_MAX_SIZE] {};
uint16_t total_size = ardupilot_indication_Button_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(ARDUPILOT_INDICATION_BUTTON_SIGNATURE,
ARDUPILOT_INDICATION_BUTTON_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
#endif // HAL_GPIO_PIN_SAFE_BUTTON
/**
* This callback is invoked by the library when a new message or request or response is received.
*/
static void onTransferReceived(CanardInstance* ins,
CanardRxTransfer* transfer)
{
#ifdef HAL_GPIO_PIN_LED_CAN1
palToggleLine(HAL_GPIO_PIN_LED_CAN1);
#endif
#if HAL_CANFD_SUPPORTED
// enable tao for decoding when not on CANFD
transfer->tao = !transfer->canfd;
#endif
/*
* Dynamic node ID allocation protocol.
* Taking this branch only if we don't have a node ID, ignoring otherwise.
*/
if (canardGetLocalNodeID(ins) == CANARD_BROADCAST_NODE_ID) {
if (transfer->transfer_type == CanardTransferTypeBroadcast &&
transfer->data_type_id == UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_ID) {
handle_allocation_response(ins, transfer);
}
return;
}
switch (transfer->data_type_id) {
case UAVCAN_PROTOCOL_GETNODEINFO_ID:
handle_get_node_info(ins, transfer);
break;
case UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_ID:
handle_begin_firmware_update(ins, transfer);
break;
case UAVCAN_PROTOCOL_RESTARTNODE_ID:
printf("RestartNode\n");
hal.scheduler->delay(10);
periph.prepare_reboot();
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
NVIC_SystemReset();
#elif CONFIG_HAL_BOARD == HAL_BOARD_SITL
HAL_SITL::actually_reboot();
#endif
break;
case UAVCAN_PROTOCOL_PARAM_GETSET_ID:
handle_param_getset(ins, transfer);
break;
case UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_ID:
handle_param_executeopcode(ins, transfer);
break;
#if defined(HAL_PERIPH_ENABLE_BUZZER_WITHOUT_NOTIFY) || defined (HAL_PERIPH_ENABLE_NOTIFY)
case UAVCAN_EQUIPMENT_INDICATION_BEEPCOMMAND_ID:
handle_beep_command(ins, transfer);
break;
#endif
#if defined(HAL_GPIO_PIN_SAFE_LED) || defined(HAL_PERIPH_ENABLE_RC_OUT)
case ARDUPILOT_INDICATION_SAFETYSTATE_ID:
handle_safety_state(ins, transfer);
break;
#endif
case UAVCAN_EQUIPMENT_SAFETY_ARMINGSTATUS_ID:
handle_arming_status(ins, transfer);
break;
#ifdef HAL_PERIPH_ENABLE_GPS
case UAVCAN_EQUIPMENT_GNSS_RTCMSTREAM_ID:
handle_RTCMStream(ins, transfer);
break;
#if GPS_MOVING_BASELINE
case ARDUPILOT_GNSS_MOVINGBASELINEDATA_ID:
handle_MovingBaselineData(ins, transfer);
break;
#endif
#endif
#if defined(AP_PERIPH_HAVE_LED_WITHOUT_NOTIFY) || defined(HAL_PERIPH_ENABLE_NOTIFY)
case UAVCAN_EQUIPMENT_INDICATION_LIGHTSCOMMAND_ID:
handle_lightscommand(ins, transfer);
break;
#endif
#ifdef HAL_PERIPH_ENABLE_RC_OUT
case UAVCAN_EQUIPMENT_ESC_RAWCOMMAND_ID:
handle_esc_rawcommand(ins, transfer);
break;
case UAVCAN_EQUIPMENT_ACTUATOR_ARRAYCOMMAND_ID:
handle_act_command(ins, transfer);
break;
#endif
#ifdef HAL_PERIPH_ENABLE_NOTIFY
case ARDUPILOT_INDICATION_NOTIFYSTATE_ID:
handle_notify_state(ins, transfer);
break;
#endif
}
}
/**
* This callback is invoked by the library when it detects beginning of a new transfer on the bus that can be received
* by the local node.
* If the callback returns true, the library will receive the transfer.
* If the callback returns false, the library will ignore the transfer.
* All transfers that are addressed to other nodes are always ignored.
*/
static bool shouldAcceptTransfer(const CanardInstance* ins,
uint64_t* out_data_type_signature,
uint16_t data_type_id,
CanardTransferType transfer_type,
uint8_t source_node_id)
{
(void)source_node_id;
if (canardGetLocalNodeID(ins) == CANARD_BROADCAST_NODE_ID)
{
/*
* If we're in the process of allocation of dynamic node ID, accept only relevant transfers.
*/
if ((transfer_type == CanardTransferTypeBroadcast) &&
(data_type_id == UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_ID))
{
*out_data_type_signature = UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_SIGNATURE;
return true;
}
return false;
}
switch (data_type_id) {
case UAVCAN_PROTOCOL_GETNODEINFO_ID:
*out_data_type_signature = UAVCAN_PROTOCOL_GETNODEINFO_SIGNATURE;
return true;
case UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_ID:
*out_data_type_signature = UAVCAN_PROTOCOL_FILE_BEGINFIRMWAREUPDATE_SIGNATURE;
return true;
case UAVCAN_PROTOCOL_RESTARTNODE_ID:
*out_data_type_signature = UAVCAN_PROTOCOL_RESTARTNODE_SIGNATURE;
return true;
case UAVCAN_PROTOCOL_PARAM_GETSET_ID:
*out_data_type_signature = UAVCAN_PROTOCOL_PARAM_GETSET_SIGNATURE;
return true;
case UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_ID:
*out_data_type_signature = UAVCAN_PROTOCOL_PARAM_EXECUTEOPCODE_SIGNATURE;
return true;
#if defined(HAL_PERIPH_ENABLE_BUZZER_WITHOUT_NOTIFY) || defined (HAL_PERIPH_ENABLE_NOTIFY)
case UAVCAN_EQUIPMENT_INDICATION_BEEPCOMMAND_ID:
*out_data_type_signature = UAVCAN_EQUIPMENT_INDICATION_BEEPCOMMAND_SIGNATURE;
return true;
#endif
#if defined(HAL_GPIO_PIN_SAFE_LED) || defined(HAL_PERIPH_ENABLE_RC_OUT)
case ARDUPILOT_INDICATION_SAFETYSTATE_ID:
*out_data_type_signature = ARDUPILOT_INDICATION_SAFETYSTATE_SIGNATURE;
return true;
#endif
case UAVCAN_EQUIPMENT_SAFETY_ARMINGSTATUS_ID:
*out_data_type_signature = UAVCAN_EQUIPMENT_SAFETY_ARMINGSTATUS_SIGNATURE;
return true;
#if defined(AP_PERIPH_HAVE_LED_WITHOUT_NOTIFY) || defined(HAL_PERIPH_ENABLE_NOTIFY)
case UAVCAN_EQUIPMENT_INDICATION_LIGHTSCOMMAND_ID:
*out_data_type_signature = UAVCAN_EQUIPMENT_INDICATION_LIGHTSCOMMAND_SIGNATURE;
return true;
#endif
#ifdef HAL_PERIPH_ENABLE_GPS
case UAVCAN_EQUIPMENT_GNSS_RTCMSTREAM_ID:
*out_data_type_signature = UAVCAN_EQUIPMENT_GNSS_RTCMSTREAM_SIGNATURE;
return true;
#if GPS_MOVING_BASELINE
case ARDUPILOT_GNSS_MOVINGBASELINEDATA_ID:
*out_data_type_signature = ARDUPILOT_GNSS_MOVINGBASELINEDATA_SIGNATURE;
return true;
#endif
#endif
#ifdef HAL_PERIPH_ENABLE_RC_OUT
case UAVCAN_EQUIPMENT_ESC_RAWCOMMAND_ID:
*out_data_type_signature = UAVCAN_EQUIPMENT_ESC_RAWCOMMAND_SIGNATURE;
return true;
case UAVCAN_EQUIPMENT_ACTUATOR_ARRAYCOMMAND_ID:
*out_data_type_signature = UAVCAN_EQUIPMENT_ACTUATOR_ARRAYCOMMAND_SIGNATURE;
return true;
#endif
#if defined(HAL_PERIPH_ENABLE_NOTIFY)
case ARDUPILOT_INDICATION_NOTIFYSTATE_ID:
*out_data_type_signature = ARDUPILOT_INDICATION_NOTIFYSTATE_SIGNATURE;
return true;
#endif
default:
break;
}
return false;
}
static void cleanup_stale_transactions(uint64_t &timestamp_usec)
{
canardCleanupStaleTransfers(&dronecan.canard, timestamp_usec);
}
#define MAKE_TRANSFER_DESCRIPTOR(data_type_id, transfer_type, src_node_id, dst_node_id) \
(((uint32_t)(data_type_id)) | (((uint32_t)(transfer_type)) << 16U) | \
(((uint32_t)(src_node_id)) << 18U) | (((uint32_t)(dst_node_id)) << 25U))
static uint8_t* get_tid_ptr(uint32_t transfer_desc)
{
// check head
if (!dronecan.tid_map_head) {
dronecan.tid_map_head = (dronecan_protocol_t::tid_map*)calloc(1, sizeof(dronecan_protocol_t::tid_map));
if (dronecan.tid_map_head == nullptr) {
return nullptr;
}
dronecan.tid_map_head->transfer_desc = transfer_desc;
dronecan.tid_map_head->next = nullptr;
return &dronecan.tid_map_head->tid;
} else if (dronecan.tid_map_head->transfer_desc == transfer_desc) {
return &dronecan.tid_map_head->tid;
}
// search through the list for an existing entry
dronecan_protocol_t::tid_map *tid_map_ptr = dronecan.tid_map_head;
while(tid_map_ptr->next) {
tid_map_ptr = tid_map_ptr->next;
if (tid_map_ptr->transfer_desc == transfer_desc) {
return &tid_map_ptr->tid;
}
}
// create a new entry, if not found
tid_map_ptr->next = (dronecan_protocol_t::tid_map*)calloc(1, sizeof(dronecan_protocol_t::tid_map));
if (tid_map_ptr->next == nullptr) {
return nullptr;
}
tid_map_ptr->next->transfer_desc = transfer_desc;
tid_map_ptr->next->next = nullptr;
return &tid_map_ptr->next->tid;
}
static void canard_broadcast(uint64_t data_type_signature,
uint16_t data_type_id,
uint8_t priority,
const void* payload,
uint16_t payload_len)
{
if (canardGetLocalNodeID(&dronecan.canard) == CANARD_BROADCAST_NODE_ID) {
return;
}
uint8_t *tid_ptr = get_tid_ptr(MAKE_TRANSFER_DESCRIPTOR(data_type_signature, data_type_id, 0, CANARD_BROADCAST_NODE_ID));
if (tid_ptr == nullptr) {
return;
}
#if DEBUG_PKTS
const int16_t res =
#endif
canardBroadcast(&dronecan.canard,
data_type_signature,
data_type_id,
tid_ptr,
priority,
payload,
payload_len
#if CANARD_MULTI_IFACE
, IFACE_ALL // send over all ifaces
#endif
#if HAL_CANFD_SUPPORTED
, periph.canfdout()
#endif
);
#if DEBUG_PKTS
if (res < 0) {
can_printf("Tx error %d\n", res);
}
#endif
}
static void processTx(void)
{
for (const CanardCANFrame* txf = NULL; (txf = canardPeekTxQueue(&dronecan.canard)) != NULL;) {
AP_HAL::CANFrame txmsg {};
txmsg.dlc = AP_HAL::CANFrame::dataLengthToDlc(txf->data_len);
memcpy(txmsg.data, txf->data, txf->data_len);
txmsg.id = (txf->id | AP_HAL::CANFrame::FlagEFF);
#if HAL_CANFD_SUPPORTED
txmsg.canfd = txf->canfd;
#endif
// push message with 1s timeout
bool sent = true;
const uint64_t deadline = AP_HAL::native_micros64() + 1000000;
// try sending to all interfaces
for (auto &ins : instances) {
if (ins.iface == NULL) {
continue;
}
#if CANARD_MULTI_IFACE
if (!(txf->iface_mask & (1U<<ins.index))) {
continue;
}
#endif
#if HAL_NUM_CAN_IFACES >= 2
if (periph.can_protocol_cached[ins.index] != AP_CAN::Protocol::DroneCAN) {
continue;
}
#endif
if (ins.iface->send(txmsg, deadline, 0) <= 0) {
sent = false;
}
}
if (sent) {
canardPopTxQueue(&dronecan.canard);
dronecan.tx_fail_count = 0;
} else {
// just exit and try again later. If we fail 8 times in a row
// then start discarding to prevent the pool filling up
if (dronecan.tx_fail_count < 8) {
dronecan.tx_fail_count++;
} else {
canardPopTxQueue(&dronecan.canard);
}
break;
}
}
}
static void processRx(void)
{
AP_HAL::CANFrame rxmsg;
for (auto &ins : instances) {
if (ins.iface == NULL) {
continue;
}
#if HAL_NUM_CAN_IFACES >= 2
if (periph.can_protocol_cached[ins.index] != AP_CAN::Protocol::DroneCAN) {
continue;
}
#endif
while (true) {
bool read_select = true;
bool write_select = false;
ins.iface->select(read_select, write_select, nullptr, 0);
if (!read_select) { // No data pending
break;
}
CanardCANFrame rx_frame {};
//palToggleLine(HAL_GPIO_PIN_LED);
uint64_t timestamp;
AP_HAL::CANIface::CanIOFlags flags;
if (ins.iface->receive(rxmsg, timestamp, flags) <= 0) {
break;
}
rx_frame.data_len = AP_HAL::CANFrame::dlcToDataLength(rxmsg.dlc);
memcpy(rx_frame.data, rxmsg.data, rx_frame.data_len);
#if HAL_CANFD_SUPPORTED
rx_frame.canfd = rxmsg.canfd;
#endif
rx_frame.id = rxmsg.id;
#if CANARD_MULTI_IFACE
rx_frame.iface_id = ins.index;
#endif
#if DEBUG_PKTS
const int16_t res =
#endif
canardHandleRxFrame(&dronecan.canard, &rx_frame, timestamp);
#if DEBUG_PKTS
if (res < 0 &&
res != -CANARD_ERROR_RX_NOT_WANTED &&
res != -CANARD_ERROR_RX_WRONG_ADDRESS &&
res != -CANARD_ERROR_RX_MISSED_START) {
printf("Rx error %d, IF%d %lx: ", res, ins.index, rx_frame.id);
for (uint8_t i = 0; i < rx_frame.data_len; i++) {
printf("%02x", rx_frame.data[i]);
}
printf("\n");
}
#endif
}
}
}
static uint16_t pool_peak_percent()
{
const CanardPoolAllocatorStatistics stats = canardGetPoolAllocatorStatistics(&dronecan.canard);
const uint16_t peak_percent = (uint16_t)(100U * stats.peak_usage_blocks / stats.capacity_blocks);
return peak_percent;
}
static void node_status_send(void)
{
uint8_t buffer[UAVCAN_PROTOCOL_NODESTATUS_MAX_SIZE];
node_status.uptime_sec = AP_HAL::millis() / 1000U;
node_status.vendor_specific_status_code = hal.util->available_memory();
uint32_t len = uavcan_protocol_NodeStatus_encode(&node_status, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_PROTOCOL_NODESTATUS_SIGNATURE,
UAVCAN_PROTOCOL_NODESTATUS_ID,
CANARD_TRANSFER_PRIORITY_LOW,
buffer,
len);
}
/**
* This function is called at 1 Hz rate from the main loop.
*/
static void process1HzTasks(uint64_t timestamp_usec)
{
/*
* Purging transfers that are no longer transmitted. This will occasionally free up some memory.
*/
cleanup_stale_transactions(timestamp_usec);
/*
* Printing the memory usage statistics.
*/
{
/*
* The recommended way to establish the minimal size of the memory pool is to stress-test the application and
* record the worst case memory usage.
*/
if (pool_peak_percent() > 70) {
printf("WARNING: ENLARGE MEMORY POOL\n");
}
}
/*
* Transmitting the node status message periodically.
*/
node_status_send();
#if !defined(HAL_NO_FLASH_SUPPORT) && !defined(HAL_NO_ROMFS_SUPPORT)
if (periph.g.flash_bootloader.get()) {
const uint8_t flash_bl = periph.g.flash_bootloader.get();
periph.g.flash_bootloader.set_and_save_ifchanged(0);
if (flash_bl == 42) {
// magic developer value to test watchdog support with main loop lockup
while (true) {
can_printf("entering lockup\n");
hal.scheduler->delay(100);
}
}
if (flash_bl == 43) {
// magic developer value to test watchdog support with hard fault
can_printf("entering fault\n");
void *foo = (void*)0xE000ED38;
typedef void (*fptr)();
fptr gptr = (fptr) (void *) foo;
gptr();
}
EXPECT_DELAY_MS(2000);
hal.scheduler->delay(1000);
AP_HAL::Util::FlashBootloader res = hal.util->flash_bootloader();
switch (res) {
case AP_HAL::Util::FlashBootloader::OK:
can_printf("Flash bootloader OK\n");
break;
case AP_HAL::Util::FlashBootloader::NO_CHANGE:
can_printf("Bootloader unchanged\n");
break;
#if AP_SIGNED_FIRMWARE
case AP_HAL::Util::FlashBootloader::NOT_SIGNED:
can_printf("Bootloader not signed\n");
break;
#endif
default:
can_printf("Flash bootloader FAILED\n");
break;
}
}
#endif
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
if (hal.run_in_maintenance_mode()) {
node_status.mode = UAVCAN_PROTOCOL_NODESTATUS_MODE_MAINTENANCE;
} else
#endif
{
node_status.mode = UAVCAN_PROTOCOL_NODESTATUS_MODE_OPERATIONAL;
}
#if 0
// test code for watchdog reset
if (AP_HAL::native_millis() > 15000) {
while (true) ;
}
#endif
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
if (AP_HAL::native_millis() > 30000) {
// use RTC to mark that we have been running fine for
// 30s. This is used along with watchdog resets to ensure the
// user has a chance to load a fixed firmware
set_fast_reboot(RTC_BOOT_FWOK);
}
#endif
}
/*
wait for dynamic allocation of node ID
*/
bool AP_Periph_FW::no_iface_finished_dna = true;
static bool can_do_dna()
{
if (canardGetLocalNodeID(&dronecan.canard) != CANARD_BROADCAST_NODE_ID) {
AP_Periph_FW::no_iface_finished_dna = false;
return true;
}
const uint32_t now = AP_HAL::native_millis();
static uint8_t node_id_allocation_transfer_id = 0;
if (AP_Periph_FW::no_iface_finished_dna) {
printf("Waiting for dynamic node ID allocation %x... (pool %u)\n", IFACE_ALL, pool_peak_percent());
}
dronecan.send_next_node_id_allocation_request_at_ms =
now + UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_MIN_REQUEST_PERIOD_MS +
get_random_range(UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_MAX_FOLLOWUP_DELAY_MS);
// Structure of the request is documented in the DSDL definition
// See http://uavcan.org/Specification/6._Application_level_functions/#dynamic-node-id-allocation
uint8_t allocation_request[CANARD_CAN_FRAME_MAX_DATA_LEN - 1];
allocation_request[0] = (uint8_t)(PreferredNodeID << 1U);
if (dronecan.node_id_allocation_unique_id_offset == 0) {
allocation_request[0] |= 1; // First part of unique ID
// set interface to try
dronecan.dna_interface++;
dronecan.dna_interface %= HAL_NUM_CAN_IFACES;
}
uint8_t my_unique_id[sizeof(uavcan_protocol_dynamic_node_id_Allocation::unique_id.data)];
readUniqueID(my_unique_id);
static const uint8_t MaxLenOfUniqueIDInRequest = 6;
uint8_t uid_size = (uint8_t)(sizeof(uavcan_protocol_dynamic_node_id_Allocation::unique_id.data) - dronecan.node_id_allocation_unique_id_offset);
if (uid_size > MaxLenOfUniqueIDInRequest) {
uid_size = MaxLenOfUniqueIDInRequest;
}
memmove(&allocation_request[1], &my_unique_id[dronecan.node_id_allocation_unique_id_offset], uid_size);
// Broadcasting the request
const int16_t bcast_res = canardBroadcast(&dronecan.canard,
UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_SIGNATURE,
UAVCAN_PROTOCOL_DYNAMIC_NODE_ID_ALLOCATION_ID,
&node_id_allocation_transfer_id,
CANARD_TRANSFER_PRIORITY_LOW,
&allocation_request[0],
(uint16_t) (uid_size + 1)
#if CANARD_MULTI_IFACE
,(1U << dronecan.dna_interface)
#endif
#if HAL_CANFD_SUPPORTED
// always send allocation request as non-FD
,false
#endif
);
if (bcast_res < 0) {
printf("Could not broadcast ID allocation req; error %d\n", bcast_res);
}
// Preparing for timeout; if response is received, this value will be updated from the callback.
dronecan.node_id_allocation_unique_id_offset = 0;
return false;
}
void AP_Periph_FW::can_start()
{
node_status.health = UAVCAN_PROTOCOL_NODESTATUS_HEALTH_OK;
node_status.mode = UAVCAN_PROTOCOL_NODESTATUS_MODE_INITIALIZATION;
node_status.uptime_sec = AP_HAL::native_millis() / 1000U;
if (g.can_node >= 0 && g.can_node < 128) {
PreferredNodeID = g.can_node;
}
#if !defined(HAL_NO_FLASH_SUPPORT) && !defined(HAL_NO_ROMFS_SUPPORT)
periph.g.flash_bootloader.set_and_save_ifchanged(0);
#endif
#if AP_PERIPH_ENFORCE_AT_LEAST_ONE_PORT_IS_UAVCAN_1MHz && HAL_NUM_CAN_IFACES >= 2
bool has_uavcan_at_1MHz = false;
for (uint8_t i=0; i<HAL_NUM_CAN_IFACES; i++) {
if (g.can_protocol[i] == AP_CAN::Protocol::DroneCAN && g.can_baudrate[i] == 1000000) {
has_uavcan_at_1MHz = true;
}
}
if (!has_uavcan_at_1MHz) {
g.can_protocol[0].set_and_save(uint8_t(AP_CAN::Protocol::DroneCAN));
g.can_baudrate[0].set_and_save(1000000);
}
#endif // HAL_PERIPH_ENFORCE_AT_LEAST_ONE_PORT_IS_UAVCAN_1MHz
for (uint8_t i=0; i<HAL_NUM_CAN_IFACES; i++) {
#if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
can_iface_periph[i] = new ChibiOS::CANIface();
#elif CONFIG_HAL_BOARD == HAL_BOARD_SITL
can_iface_periph[i] = new HALSITL::CANIface();
#endif
instances[i].iface = can_iface_periph[i];
instances[i].index = i;
#if HAL_NUM_CAN_IFACES >= 2
can_protocol_cached[i] = g.can_protocol[i];
CANSensor::set_periph(i, can_protocol_cached[i], can_iface_periph[i]);
#endif
if (can_iface_periph[i] != nullptr) {
#if HAL_CANFD_SUPPORTED
can_iface_periph[i]->init(g.can_baudrate[i], g.can_fdbaudrate[i]*1000000U, AP_HAL::CANIface::NormalMode);
#else
can_iface_periph[i]->init(g.can_baudrate[i], AP_HAL::CANIface::NormalMode);
#endif
}
}
#if AP_CAN_SLCAN_ENABLED
const uint8_t slcan_selected_index = g.can_slcan_cport - 1;
if (slcan_selected_index < HAL_NUM_CAN_IFACES) {
slcan_interface.set_can_iface(can_iface_periph[slcan_selected_index]);
instances[slcan_selected_index].iface = (AP_HAL::CANIface*)&slcan_interface;
// ensure there's a serial port mapped to SLCAN
if (!periph.serial_manager.have_serial(AP_SerialManager::SerialProtocol_SLCAN, 0)) {
periph.serial_manager.set_protocol_and_baud(SERIALMANAGER_NUM_PORTS-1, AP_SerialManager::SerialProtocol_SLCAN, 1500000);
}
}
#endif
canardInit(&dronecan.canard, (uint8_t *)dronecan.canard_memory_pool, sizeof(dronecan.canard_memory_pool),
onTransferReceived, shouldAcceptTransfer, NULL);
if (PreferredNodeID != CANARD_BROADCAST_NODE_ID) {
canardSetLocalNodeID(&dronecan.canard, PreferredNodeID);
}
}
#ifdef HAL_PERIPH_ENABLE_PWM_HARDPOINT
void AP_Periph_FW::pwm_hardpoint_init()
{
hal.gpio->attach_interrupt(
PWM_HARDPOINT_PIN,
FUNCTOR_BIND_MEMBER(&AP_Periph_FW::pwm_irq_handler, void, uint8_t, bool, uint32_t), AP_HAL::GPIO::INTERRUPT_BOTH);
}
/*
called on PWM pin transition
*/
void AP_Periph_FW::pwm_irq_handler(uint8_t pin, bool pin_state, uint32_t timestamp)
{
if (pin_state == 0 && pwm_hardpoint.last_state == 1 && pwm_hardpoint.last_ts_us != 0) {
uint32_t width = timestamp - pwm_hardpoint.last_ts_us;
if (width > 500 && width < 2500) {
pwm_hardpoint.pwm_value = width;
if (width > pwm_hardpoint.highest_pwm) {
pwm_hardpoint.highest_pwm = width;
}
}
}
pwm_hardpoint.last_state = pin_state;
pwm_hardpoint.last_ts_us = timestamp;
}
void AP_Periph_FW::pwm_hardpoint_update()
{
uint32_t now = AP_HAL::native_millis();
// send at 10Hz
void *save = hal.scheduler->disable_interrupts_save();
uint16_t value = pwm_hardpoint.highest_pwm;
pwm_hardpoint.highest_pwm = 0;
hal.scheduler->restore_interrupts(save);
float rate = g.hardpoint_rate;
rate = constrain_float(rate, 10, 100);
if (value > 0 && now - pwm_hardpoint.last_send_ms >= 1000U/rate) {
pwm_hardpoint.last_send_ms = now;
uavcan_equipment_hardpoint_Command cmd {};
cmd.hardpoint_id = g.hardpoint_id;
cmd.command = value;
uint8_t buffer[UAVCAN_EQUIPMENT_HARDPOINT_COMMAND_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_hardpoint_Command_encode(&cmd, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_HARDPOINT_COMMAND_SIGNATURE,
UAVCAN_EQUIPMENT_HARDPOINT_COMMAND_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
}
#endif // HAL_PERIPH_ENABLE_PWM_HARDPOINT
#ifdef HAL_PERIPH_ENABLE_HWESC
void AP_Periph_FW::hwesc_telem_update()
{
if (!hwesc_telem.update()) {
return;
}
const HWESC_Telem::HWESC &t = hwesc_telem.get_telem();
uavcan_equipment_esc_Status pkt {};
pkt.esc_index = g.esc_number[0]; // only supports a single ESC
pkt.voltage = t.voltage;
pkt.current = t.current;
pkt.temperature = C_TO_KELVIN(MAX(t.mos_temperature, t.cap_temperature));
pkt.rpm = t.rpm;
pkt.power_rating_pct = t.phase_current;
pkt.error_count = t.error_count;
uint8_t buffer[UAVCAN_EQUIPMENT_ESC_STATUS_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_esc_Status_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_ESC_STATUS_SIGNATURE,
UAVCAN_EQUIPMENT_ESC_STATUS_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
#endif // HAL_PERIPH_ENABLE_HWESC
#ifdef HAL_PERIPH_ENABLE_RC_OUT
#if HAL_WITH_ESC_TELEM
/*
send ESC status packets based on AP_ESC_Telem
*/
void AP_Periph_FW::esc_telem_update()
{
uint32_t mask = esc_telem.get_active_esc_mask();
while (mask != 0) {
int8_t i = __builtin_ffs(mask) - 1;
mask &= ~(1U<<i);
const float nan = nanf("");
uavcan_equipment_esc_Status pkt {};
const auto *channel = SRV_Channels::srv_channel(i);
// try to map the ESC number to a motor number. This is needed
// for when we have multiple CAN nodes, one for each ESC
if (channel == nullptr) {
pkt.esc_index = i;
} else {
const int8_t motor_num = channel->get_motor_num();
pkt.esc_index = motor_num==-1? i:motor_num;
}
if (!esc_telem.get_voltage(i, pkt.voltage)) {
pkt.voltage = nan;
}
if (!esc_telem.get_current(i, pkt.current)) {
pkt.current = nan;
}
int16_t temperature;
if (esc_telem.get_motor_temperature(i, temperature)) {
pkt.temperature = C_TO_KELVIN(temperature*0.01);
} else if (esc_telem.get_temperature(i, temperature)) {
pkt.temperature = C_TO_KELVIN(temperature*0.01);
} else {
pkt.temperature = nan;
}
float rpm;
if (esc_telem.get_raw_rpm(i, rpm)) {
pkt.rpm = rpm;
}
pkt.power_rating_pct = 0;
pkt.error_count = 0;
uint8_t buffer[UAVCAN_EQUIPMENT_ESC_STATUS_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_esc_Status_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_ESC_STATUS_SIGNATURE,
UAVCAN_EQUIPMENT_ESC_STATUS_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
}
#endif // HAL_WITH_ESC_TELEM
#ifdef HAL_PERIPH_ENABLE_ESC_APD
void AP_Periph_FW::apd_esc_telem_update()
{
for(uint8_t i = 0; i < ARRAY_SIZE(apd_esc_telem); i++) {
if (apd_esc_telem[i] == nullptr) {
continue;
}
ESC_APD_Telem &esc = *apd_esc_telem[i];
if (esc.update()) {
const ESC_APD_Telem::telem &t = esc.get_telem();
uavcan_equipment_esc_Status pkt {};
static_assert(APD_ESC_INSTANCES <= ARRAY_SIZE(g.esc_number), "There must be an ESC instance number for each APD ESC");
pkt.esc_index = g.esc_number[i];
pkt.voltage = t.voltage;
pkt.current = t.current;
pkt.temperature = t.temperature;
pkt.rpm = t.rpm;
pkt.power_rating_pct = t.power_rating_pct;
pkt.error_count = t.error_count;
uint8_t buffer[UAVCAN_EQUIPMENT_ESC_STATUS_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_esc_Status_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_ESC_STATUS_SIGNATURE,
UAVCAN_EQUIPMENT_ESC_STATUS_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
}
}
#endif // HAL_PERIPH_ENABLE_ESC_APD
#endif // HAL_PERIPH_ENABLE_RC_OUT
void AP_Periph_FW::can_update()
{
const uint32_t now = AP_HAL::native_millis();
const uint32_t led_pattern = 0xAAAA;
const uint32_t led_change_period = 50;
static uint8_t led_idx = 0;
static uint32_t last_led_change;
if ((now - last_led_change > led_change_period) && no_iface_finished_dna) {
// blink LED in recognisable pattern while waiting for DNA
#ifdef HAL_GPIO_PIN_LED
palWriteLine(HAL_GPIO_PIN_LED, (led_pattern & (1U<<led_idx))?1:0);
#elif defined(HAL_GPIO_PIN_SAFE_LED)
// or use safety LED if defined
palWriteLine(HAL_GPIO_PIN_SAFE_LED, (led_pattern & (1U<<led_idx))?1:0);
#else
(void)led_pattern;
(void)led_idx;
#endif
led_idx = (led_idx+1) % 32;
last_led_change = now;
}
if (AP_HAL::millis() > dronecan.send_next_node_id_allocation_request_at_ms) {
can_do_dna();
}
static uint32_t last_1Hz_ms;
if (now - last_1Hz_ms >= 1000) {
last_1Hz_ms = now;
process1HzTasks(AP_HAL::native_micros64());
}
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
if (!hal.run_in_maintenance_mode())
#endif
{
can_mag_update();
can_gps_update();
can_battery_update();
can_baro_update();
can_airspeed_update();
can_rangefinder_update();
can_proximity_update();
#if defined(HAL_PERIPH_ENABLE_BUZZER_WITHOUT_NOTIFY) || defined (HAL_PERIPH_ENABLE_NOTIFY)
can_buzzer_update();
#endif
#ifdef HAL_GPIO_PIN_SAFE_LED
can_safety_LED_update();
#endif
#ifdef HAL_GPIO_PIN_SAFE_BUTTON
can_safety_button_update();
#endif
#ifdef HAL_PERIPH_ENABLE_PWM_HARDPOINT
pwm_hardpoint_update();
#endif
#ifdef HAL_PERIPH_ENABLE_HWESC
hwesc_telem_update();
#endif
#ifdef HAL_PERIPH_ENABLE_ESC_APD
apd_esc_telem_update();
#endif
#ifdef HAL_PERIPH_ENABLE_MSP
msp_sensor_update();
#endif
#ifdef HAL_PERIPH_ENABLE_RC_OUT
rcout_update();
#endif
#ifdef HAL_PERIPH_ENABLE_EFI
can_efi_update();
#endif
}
const uint32_t now_us = AP_HAL::micros();
while ((AP_HAL::micros() - now_us) < 1000) {
hal.scheduler->delay_microseconds(HAL_PERIPH_LOOP_DELAY_US);
#if HAL_CANFD_SUPPORTED
// allow for user enabling/disabling CANFD at runtime
dronecan.canard.tao_disabled = periph.g.can_fdmode == 1;
#endif
processTx();
processRx();
}
}
/*
update CAN magnetometer
*/
void AP_Periph_FW::can_mag_update(void)
{
#ifdef HAL_PERIPH_ENABLE_MAG
if (!compass.available()) {
return;
}
#if AP_PERIPH_MAG_MAX_RATE > 0
// don't flood the bus with very high rate magnetometers
const uint32_t now_ms = AP_HAL::millis();
if (now_ms - last_mag_update_ms < (1000U / AP_PERIPH_MAG_MAX_RATE)) {
return;
}
#endif
compass.read();
#if AP_PERIPH_PROBE_CONTINUOUS
if (compass.get_count() == 0) {
static uint32_t last_probe_ms;
uint32_t now = AP_HAL::native_millis();
if (now - last_probe_ms >= 1000) {
last_probe_ms = now;
compass.init();
}
}
#endif
if (last_mag_update_ms == compass.last_update_ms()) {
return;
}
if (!compass.healthy()) {
return;
}
last_mag_update_ms = compass.last_update_ms();
const Vector3f &field = compass.get_field();
uavcan_equipment_ahrs_MagneticFieldStrength pkt {};
// the canard dsdl compiler doesn't understand float16
for (uint8_t i=0; i<3; i++) {
pkt.magnetic_field_ga[i] = field[i] * 0.001;
}
uint8_t buffer[UAVCAN_EQUIPMENT_AHRS_MAGNETICFIELDSTRENGTH_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_ahrs_MagneticFieldStrength_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_AHRS_MAGNETICFIELDSTRENGTH_SIGNATURE,
UAVCAN_EQUIPMENT_AHRS_MAGNETICFIELDSTRENGTH_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
#endif // HAL_PERIPH_ENABLE_MAG
}
/*
update CAN battery monitor
*/
void AP_Periph_FW::can_battery_update(void)
{
#ifdef HAL_PERIPH_ENABLE_BATTERY
const uint32_t now_ms = AP_HAL::native_millis();
if (now_ms - battery.last_can_send_ms < 100) {
return;
}
battery.last_can_send_ms = now_ms;
const uint8_t battery_instances = battery.lib.num_instances();
for (uint8_t i=0; i<battery_instances; i++) {
if (!battery.lib.healthy(i)) {
continue;
}
uavcan_equipment_power_BatteryInfo pkt {};
// if a battery serial number is assigned, use that as the ID. Else, use the index.
const int32_t serial_number = battery.lib.get_serial_number(i);
pkt.battery_id = (serial_number >= 0) ? serial_number : i+1;
pkt.voltage = battery.lib.voltage(i);
float current;
if (battery.lib.current_amps(current, i)) {
pkt.current = current;
}
float temperature;
if (battery.lib.get_temperature(temperature, i)) {
// Battery lib reports temperature in Celsius.
// Convert Celsius to Kelvin for transmission on CAN.
pkt.temperature = C_TO_KELVIN(temperature);
}
pkt.state_of_health_pct = UAVCAN_EQUIPMENT_POWER_BATTERYINFO_STATE_OF_HEALTH_UNKNOWN;
uint8_t percentage = 0;
if (battery.lib.capacity_remaining_pct(percentage, i)) {
pkt.state_of_charge_pct = percentage;
}
pkt.model_instance_id = i+1;
#if !defined(HAL_PERIPH_BATTERY_SKIP_NAME)
// example model_name: "org.ardupilot.ap_periph SN 123"
hal.util->snprintf((char*)pkt.model_name.data, sizeof(pkt.model_name.data), "%s %ld", AP_PERIPH_BATTERY_MODEL_NAME, (long int)serial_number);
pkt.model_name.len = strnlen((char*)pkt.model_name.data, sizeof(pkt.model_name.data));
#endif //defined(HAL_PERIPH_BATTERY_SKIP_NAME)
uint8_t buffer[UAVCAN_EQUIPMENT_POWER_BATTERYINFO_MAX_SIZE] {};
const uint16_t total_size = uavcan_equipment_power_BatteryInfo_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_POWER_BATTERYINFO_SIGNATURE,
UAVCAN_EQUIPMENT_POWER_BATTERYINFO_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
#endif
}
#ifdef HAL_PERIPH_ENABLE_GPS
/*
convert large values to NaN for float16
*/
static void check_float16_range(float *v, uint8_t len)
{
for (uint8_t i=0; i<len; i++) {
const float f16max = 65519;
if (isinf(v[i]) || v[i] <= -f16max || v[i] >= f16max) {
v[i] = nanf("");
}
}
}
#endif
/*
update CAN GPS
*/
void AP_Periph_FW::can_gps_update(void)
{
#ifdef HAL_PERIPH_ENABLE_GPS
if (gps.get_type(0) == AP_GPS::GPS_Type::GPS_TYPE_NONE) {
return;
}
gps.update();
send_moving_baseline_msg();
send_relposheading_msg();
if (last_gps_update_ms == gps.last_message_time_ms()) {
return;
}
last_gps_update_ms = gps.last_message_time_ms();
{
/*
send Fix2 packet
*/
uavcan_equipment_gnss_Fix2 pkt {};
const Location &loc = gps.location();
const Vector3f &vel = gps.velocity();
if (gps.status() < AP_GPS::GPS_OK_FIX_2D && !saw_gps_lock_once) {
pkt.timestamp.usec = AP_HAL::micros64();
pkt.gnss_timestamp.usec = 0;
} else {
saw_gps_lock_once = true;
pkt.timestamp.usec = gps.time_epoch_usec();
pkt.gnss_timestamp.usec = gps.last_message_epoch_usec();
}
if (pkt.gnss_timestamp.usec == 0) {
pkt.gnss_time_standard = UAVCAN_EQUIPMENT_GNSS_FIX_GNSS_TIME_STANDARD_NONE;
} else {
pkt.gnss_time_standard = UAVCAN_EQUIPMENT_GNSS_FIX_GNSS_TIME_STANDARD_UTC;
}
pkt.longitude_deg_1e8 = uint64_t(loc.lng) * 10ULL;
pkt.latitude_deg_1e8 = uint64_t(loc.lat) * 10ULL;
pkt.height_ellipsoid_mm = loc.alt * 10;
pkt.height_msl_mm = loc.alt * 10;
float undulation;
if (gps.get_undulation(undulation)) {
pkt.height_ellipsoid_mm -= undulation*1000;
}
for (uint8_t i=0; i<3; i++) {
pkt.ned_velocity[i] = vel[i];
}
pkt.sats_used = gps.num_sats();
switch (gps.status()) {
case AP_GPS::GPS_Status::NO_GPS:
case AP_GPS::GPS_Status::NO_FIX:
pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_NO_FIX;
pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_SINGLE;
pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_OTHER;
break;
case AP_GPS::GPS_Status::GPS_OK_FIX_2D:
pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_2D_FIX;
pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_SINGLE;
pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_OTHER;
break;
case AP_GPS::GPS_Status::GPS_OK_FIX_3D:
pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX;
pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_SINGLE;
pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_OTHER;
break;
case AP_GPS::GPS_Status::GPS_OK_FIX_3D_DGPS:
pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX;
pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_DGPS;
pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_DGPS_SBAS;
break;
case AP_GPS::GPS_Status::GPS_OK_FIX_3D_RTK_FLOAT:
pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX;
pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_RTK;
pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_RTK_FLOAT;
break;
case AP_GPS::GPS_Status::GPS_OK_FIX_3D_RTK_FIXED:
pkt.status = UAVCAN_EQUIPMENT_GNSS_FIX2_STATUS_3D_FIX;
pkt.mode = UAVCAN_EQUIPMENT_GNSS_FIX2_MODE_RTK;
pkt.sub_mode = UAVCAN_EQUIPMENT_GNSS_FIX2_SUB_MODE_RTK_FIXED;
break;
}
pkt.covariance.len = 6;
float hacc;
if (gps.horizontal_accuracy(hacc)) {
pkt.covariance.data[0] = pkt.covariance.data[1] = sq(hacc);
}
float vacc;
if (gps.vertical_accuracy(vacc)) {
pkt.covariance.data[2] = sq(vacc);
}
float sacc;
if (gps.speed_accuracy(sacc)) {
float vc3 = sq(sacc);
pkt.covariance.data[3] = pkt.covariance.data[4] = pkt.covariance.data[5] = vc3;
}
check_float16_range(pkt.covariance.data, pkt.covariance.len);
uint8_t buffer[UAVCAN_EQUIPMENT_GNSS_FIX2_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_gnss_Fix2_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_GNSS_FIX2_SIGNATURE,
UAVCAN_EQUIPMENT_GNSS_FIX2_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
/*
send aux packet
*/
{
uavcan_equipment_gnss_Auxiliary aux {};
aux.hdop = gps.get_hdop() * 0.01;
aux.vdop = gps.get_vdop() * 0.01;
uint8_t buffer[UAVCAN_EQUIPMENT_GNSS_AUXILIARY_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_gnss_Auxiliary_encode(&aux, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_GNSS_AUXILIARY_SIGNATURE,
UAVCAN_EQUIPMENT_GNSS_AUXILIARY_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
// send the gnss status packet
{
ardupilot_gnss_Status status {};
status.healthy = gps.is_healthy();
if (gps.logging_present() && gps.logging_enabled() && !gps.logging_failed()) {
status.status |= ARDUPILOT_GNSS_STATUS_STATUS_LOGGING;
}
uint8_t idx; // unused
if (status.healthy && !gps.first_unconfigured_gps(idx)) {
status.status |= ARDUPILOT_GNSS_STATUS_STATUS_ARMABLE;
}
uint32_t error_codes;
if (gps.get_error_codes(error_codes)) {
status.error_codes = error_codes;
}
uint8_t buffer[ARDUPILOT_GNSS_STATUS_MAX_SIZE] {};
const uint16_t total_size = ardupilot_gnss_Status_encode(&status, buffer, !periph.canfdout());
canard_broadcast(ARDUPILOT_GNSS_STATUS_SIGNATURE,
ARDUPILOT_GNSS_STATUS_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
// send Heading message if we are not sending RelPosHeading messages and have yaw
if (gps.have_gps_yaw() && last_relposheading_ms == 0) {
float yaw_deg, yaw_acc_deg;
uint32_t yaw_time_ms;
if (gps.gps_yaw_deg(yaw_deg, yaw_acc_deg, yaw_time_ms) && yaw_time_ms != last_gps_yaw_ms) {
last_gps_yaw_ms = yaw_time_ms;
ardupilot_gnss_Heading heading {};
heading.heading_valid = true;
heading.heading_accuracy_valid = is_positive(yaw_acc_deg);
heading.heading_rad = radians(yaw_deg);
heading.heading_accuracy_rad = radians(yaw_acc_deg);
uint8_t buffer[ARDUPILOT_GNSS_HEADING_MAX_SIZE] {};
const uint16_t total_size = ardupilot_gnss_Heading_encode(&heading, buffer, !periph.canfdout());
canard_broadcast(ARDUPILOT_GNSS_HEADING_SIGNATURE,
ARDUPILOT_GNSS_HEADING_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
}
#endif // HAL_PERIPH_ENABLE_GPS
}
void AP_Periph_FW::send_moving_baseline_msg()
{
#if defined(HAL_PERIPH_ENABLE_GPS) && GPS_MOVING_BASELINE
const uint8_t *data = nullptr;
uint16_t len = 0;
if (!gps.get_RTCMV3(data, len)) {
return;
}
if (len == 0 || data == nullptr) {
return;
}
// send the packet from Moving Base to be used RelPosHeading calc by GPS module
ardupilot_gnss_MovingBaselineData mbldata {};
// get the data from the moving base
static_assert(sizeof(ardupilot_gnss_MovingBaselineData::data.data) == RTCM3_MAX_PACKET_LEN, "Size of Moving Base data is wrong");
mbldata.data.len = len;
memcpy(mbldata.data.data, data, len);
uint8_t buffer[ARDUPILOT_GNSS_MOVINGBASELINEDATA_MAX_SIZE] {};
const uint16_t total_size = ardupilot_gnss_MovingBaselineData_encode(&mbldata, buffer, !periph.canfdout());
#if HAL_NUM_CAN_IFACES >= 2
if (gps_mb_can_port != -1 && (gps_mb_can_port < HAL_NUM_CAN_IFACES)) {
uint8_t *tid_ptr = get_tid_ptr(MAKE_TRANSFER_DESCRIPTOR(ARDUPILOT_GNSS_MOVINGBASELINEDATA_SIGNATURE, ARDUPILOT_GNSS_MOVINGBASELINEDATA_ID, 0, CANARD_BROADCAST_NODE_ID));
canardBroadcast(&dronecan.canard,
ARDUPILOT_GNSS_MOVINGBASELINEDATA_SIGNATURE,
ARDUPILOT_GNSS_MOVINGBASELINEDATA_ID,
tid_ptr,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size
#if CANARD_MULTI_IFACE
,(1U<<gps_mb_can_port)
#endif
#if HAL_CANFD_SUPPORTED
,canfdout()
#endif
);
} else
#endif
{
canard_broadcast(ARDUPILOT_GNSS_MOVINGBASELINEDATA_SIGNATURE,
ARDUPILOT_GNSS_MOVINGBASELINEDATA_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
gps.clear_RTCMV3();
#endif // HAL_PERIPH_ENABLE_GPS && GPS_MOVING_BASELINE
}
void AP_Periph_FW::send_relposheading_msg() {
#if defined(HAL_PERIPH_ENABLE_GPS) && GPS_MOVING_BASELINE
float reported_heading;
float relative_distance;
float relative_down_pos;
float reported_heading_acc;
uint32_t curr_timestamp = 0;
gps.get_RelPosHeading(curr_timestamp, reported_heading, relative_distance, relative_down_pos, reported_heading_acc);
if (last_relposheading_ms == curr_timestamp) {
return;
}
last_relposheading_ms = curr_timestamp;
ardupilot_gnss_RelPosHeading relpos {};
relpos.timestamp.usec = uint64_t(curr_timestamp)*1000LLU;
relpos.reported_heading_deg = reported_heading;
relpos.relative_distance_m = relative_distance;
relpos.relative_down_pos_m = relative_down_pos;
relpos.reported_heading_acc_deg = reported_heading_acc;
relpos.reported_heading_acc_available = !is_zero(relpos.reported_heading_acc_deg);
uint8_t buffer[ARDUPILOT_GNSS_RELPOSHEADING_MAX_SIZE] {};
const uint16_t total_size = ardupilot_gnss_RelPosHeading_encode(&relpos, buffer, !periph.canfdout());
canard_broadcast(ARDUPILOT_GNSS_RELPOSHEADING_SIGNATURE,
ARDUPILOT_GNSS_RELPOSHEADING_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
#endif // HAL_PERIPH_ENABLE_GPS && GPS_MOVING_BASELINE
}
/*
update CAN baro
*/
void AP_Periph_FW::can_baro_update(void)
{
#ifdef HAL_PERIPH_ENABLE_BARO
if (!periph.g.baro_enable) {
return;
}
baro.update();
if (last_baro_update_ms == baro.get_last_update()) {
return;
}
last_baro_update_ms = baro.get_last_update();
if (!baro.healthy()) {
// don't send any data
return;
}
const float press = baro.get_pressure();
const float temp = baro.get_temperature();
{
uavcan_equipment_air_data_StaticPressure pkt {};
pkt.static_pressure = press;
pkt.static_pressure_variance = 0; // should we make this a parameter?
uint8_t buffer[UAVCAN_EQUIPMENT_AIR_DATA_STATICPRESSURE_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_air_data_StaticPressure_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_AIR_DATA_STATICPRESSURE_SIGNATURE,
UAVCAN_EQUIPMENT_AIR_DATA_STATICPRESSURE_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
{
uavcan_equipment_air_data_StaticTemperature pkt {};
pkt.static_temperature = C_TO_KELVIN(temp);
pkt.static_temperature_variance = 0; // should we make this a parameter?
uint8_t buffer[UAVCAN_EQUIPMENT_AIR_DATA_STATICTEMPERATURE_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_air_data_StaticTemperature_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_AIR_DATA_STATICTEMPERATURE_SIGNATURE,
UAVCAN_EQUIPMENT_AIR_DATA_STATICTEMPERATURE_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
#endif // HAL_PERIPH_ENABLE_BARO
}
/*
update CAN airspeed
*/
void AP_Periph_FW::can_airspeed_update(void)
{
#ifdef HAL_PERIPH_ENABLE_AIRSPEED
if (!airspeed.enabled()) {
return;
}
#if AP_PERIPH_PROBE_CONTINUOUS
if (!airspeed.healthy()) {
uint32_t now = AP_HAL::native_millis();
static uint32_t last_probe_ms;
if (now - last_probe_ms >= 1000) {
last_probe_ms = now;
airspeed.allocate();
}
}
#endif
uint32_t now = AP_HAL::native_millis();
if (now - last_airspeed_update_ms < 50) {
// max 20Hz data
return;
}
last_airspeed_update_ms = now;
airspeed.update();
if (!airspeed.healthy()) {
// don't send any data
return;
}
const float press = airspeed.get_corrected_pressure();
float temp;
if (!airspeed.get_temperature(temp)) {
temp = nanf("");
} else {
temp = C_TO_KELVIN(temp);
}
uavcan_equipment_air_data_RawAirData pkt {};
pkt.differential_pressure = press;
pkt.static_air_temperature = temp;
// unfilled elements are NaN
pkt.static_pressure = nanf("");
pkt.static_pressure_sensor_temperature = nanf("");
pkt.differential_pressure_sensor_temperature = nanf("");
pkt.pitot_temperature = nanf("");
uint8_t buffer[UAVCAN_EQUIPMENT_AIR_DATA_RAWAIRDATA_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_air_data_RawAirData_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_AIR_DATA_RAWAIRDATA_SIGNATURE,
UAVCAN_EQUIPMENT_AIR_DATA_RAWAIRDATA_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
#endif // HAL_PERIPH_ENABLE_AIRSPEED
}
/*
update CAN rangefinder
*/
void AP_Periph_FW::can_rangefinder_update(void)
{
#ifdef HAL_PERIPH_ENABLE_RANGEFINDER
if (rangefinder.get_type(0) == RangeFinder::Type::NONE) {
return;
}
#if AP_PERIPH_PROBE_CONTINUOUS
if (rangefinder.num_sensors() == 0) {
uint32_t now = AP_HAL::native_millis();
static uint32_t last_probe_ms;
if (now - last_probe_ms >= 1000) {
last_probe_ms = now;
rangefinder.init(ROTATION_NONE);
}
}
#endif
uint32_t now = AP_HAL::native_millis();
static uint32_t last_update_ms;
if (g.rangefinder_max_rate > 0 &&
now - last_update_ms < 1000/g.rangefinder_max_rate) {
// limit to max rate
return;
}
last_update_ms = now;
rangefinder.update();
RangeFinder::Status status = rangefinder.status_orient(ROTATION_NONE);
if (status <= RangeFinder::Status::NoData) {
// don't send any data
return;
}
const uint32_t sample_ms = rangefinder.last_reading_ms(ROTATION_NONE);
if (last_sample_ms == sample_ms) {
return;
}
last_sample_ms = sample_ms;
uint16_t dist_cm = rangefinder.distance_cm_orient(ROTATION_NONE);
uavcan_equipment_range_sensor_Measurement pkt {};
pkt.sensor_id = rangefinder.get_address(0);
switch (status) {
case RangeFinder::Status::OutOfRangeLow:
pkt.reading_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_READING_TYPE_TOO_CLOSE;
break;
case RangeFinder::Status::OutOfRangeHigh:
pkt.reading_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_READING_TYPE_TOO_FAR;
break;
case RangeFinder::Status::Good:
pkt.reading_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_READING_TYPE_VALID_RANGE;
break;
default:
pkt.reading_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_READING_TYPE_UNDEFINED;
break;
}
switch (rangefinder.get_mav_distance_sensor_type_orient(ROTATION_NONE)) {
case MAV_DISTANCE_SENSOR_LASER:
pkt.sensor_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_SENSOR_TYPE_LIDAR;
break;
case MAV_DISTANCE_SENSOR_ULTRASOUND:
pkt.sensor_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_SENSOR_TYPE_SONAR;
break;
case MAV_DISTANCE_SENSOR_RADAR:
pkt.sensor_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_SENSOR_TYPE_RADAR;
break;
default:
pkt.sensor_type = UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_SENSOR_TYPE_UNDEFINED;
break;
}
pkt.range = dist_cm * 0.01;
uint8_t buffer[UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_MAX_SIZE] {};
uint16_t total_size = uavcan_equipment_range_sensor_Measurement_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_SIGNATURE,
UAVCAN_EQUIPMENT_RANGE_SENSOR_MEASUREMENT_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
#endif // HAL_PERIPH_ENABLE_RANGEFINDER
}
void AP_Periph_FW::can_proximity_update()
{
#if HAL_PROXIMITY_ENABLED
if (proximity.get_type(0) == AP_Proximity::Type::None) {
return;
}
uint32_t now = AP_HAL::native_millis();
static uint32_t last_update_ms;
if (g.proximity_max_rate > 0 &&
now - last_update_ms < 1000/g.proximity_max_rate) {
// limit to max rate
return;
}
last_update_ms = now;
proximity.update();
AP_Proximity::Status status = proximity.get_status();
if (status <= AP_Proximity::Status::NoData) {
// don't send any data
return;
}
ardupilot_equipment_proximity_sensor_Proximity pkt {};
const uint8_t obstacle_count = proximity.get_obstacle_count();
// if no objects return
if (obstacle_count == 0) {
return;
}
// calculate maximum roll, pitch values from objects
for (uint8_t i=0; i<obstacle_count; i++) {
if (!proximity.get_obstacle_info(i, pkt.yaw, pkt.pitch, pkt.distance)) {
// not a valid obstacle
continue;
}
pkt.sensor_id = proximity.get_address(0);
switch (status) {
case AP_Proximity::Status::NotConnected:
pkt.reading_type = ARDUPILOT_EQUIPMENT_PROXIMITY_SENSOR_PROXIMITY_READING_TYPE_NOT_CONNECTED;
break;
case AP_Proximity::Status::Good:
pkt.reading_type = ARDUPILOT_EQUIPMENT_PROXIMITY_SENSOR_PROXIMITY_READING_TYPE_GOOD;
break;
case AP_Proximity::Status::NoData:
default:
pkt.reading_type = ARDUPILOT_EQUIPMENT_PROXIMITY_SENSOR_PROXIMITY_READING_TYPE_NO_DATA;
break;
}
uint8_t buffer[ARDUPILOT_EQUIPMENT_PROXIMITY_SENSOR_PROXIMITY_MAX_SIZE] {};
uint16_t total_size = ardupilot_equipment_proximity_sensor_Proximity_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(ARDUPILOT_EQUIPMENT_PROXIMITY_SENSOR_PROXIMITY_SIGNATURE,
ARDUPILOT_EQUIPMENT_PROXIMITY_SENSOR_PROXIMITY_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
#endif
}
#ifdef HAL_PERIPH_ENABLE_ADSB
/*
map an ADSB_VEHICLE MAVLink message to a UAVCAN TrafficReport message
*/
void AP_Periph_FW::can_send_ADSB(struct __mavlink_adsb_vehicle_t &msg)
{
ardupilot_equipment_trafficmonitor_TrafficReport pkt {};
pkt.timestamp.usec = 0;
pkt.icao_address = msg.ICAO_address;
pkt.tslc = msg.tslc;
pkt.latitude_deg_1e7 = msg.lat;
pkt.longitude_deg_1e7 = msg.lon;
pkt.alt_m = msg.altitude * 1e-3;
pkt.heading = radians(msg.heading * 1e-2);
pkt.velocity[0] = cosf(pkt.heading) * msg.hor_velocity * 1e-2;
pkt.velocity[1] = sinf(pkt.heading) * msg.hor_velocity * 1e-2;
pkt.velocity[2] = -msg.ver_velocity * 1e-2;
pkt.squawk = msg.squawk;
memcpy(pkt.callsign, msg.callsign, MIN(sizeof(msg.callsign),sizeof(pkt.callsign)));
if (msg.flags & 0x8000) {
pkt.source = ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_SOURCE_ADSB_UAT;
} else {
pkt.source = ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_SOURCE_ADSB;
}
pkt.traffic_type = msg.emitter_type;
if ((msg.flags & ADSB_FLAGS_VALID_ALTITUDE) != 0 && msg.altitude_type == 0) {
pkt.alt_type = ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_ALT_TYPE_PRESSURE_AMSL;
} else if ((msg.flags & ADSB_FLAGS_VALID_ALTITUDE) != 0 && msg.altitude_type == 1) {
pkt.alt_type = ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_ALT_TYPE_WGS84;
} else {
pkt.alt_type = ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_ALT_TYPE_ALT_UNKNOWN;
}
pkt.lat_lon_valid = (msg.flags & ADSB_FLAGS_VALID_COORDS) != 0;
pkt.heading_valid = (msg.flags & ADSB_FLAGS_VALID_HEADING) != 0;
pkt.velocity_valid = (msg.flags & ADSB_FLAGS_VALID_VELOCITY) != 0;
pkt.callsign_valid = (msg.flags & ADSB_FLAGS_VALID_CALLSIGN) != 0;
pkt.ident_valid = (msg.flags & ADSB_FLAGS_VALID_SQUAWK) != 0;
pkt.simulated_report = (msg.flags & ADSB_FLAGS_SIMULATED) != 0;
// these flags are not in common.xml
pkt.vertical_velocity_valid = (msg.flags & 0x0080) != 0;
pkt.baro_valid = (msg.flags & 0x0100) != 0;
uint8_t buffer[ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_MAX_SIZE] {};
uint16_t total_size = ardupilot_equipment_trafficmonitor_TrafficReport_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_SIGNATURE,
ARDUPILOT_EQUIPMENT_TRAFFICMONITOR_TRAFFICREPORT_ID,
CANARD_TRANSFER_PRIORITY_LOWEST,
&buffer[0],
total_size);
}
#endif // HAL_PERIPH_ENABLE_ADSB
#ifdef HAL_PERIPH_ENABLE_EFI
/*
update CAN EFI
*/
void AP_Periph_FW::can_efi_update(void)
{
if (!efi.enabled()) {
return;
}
efi.update();
const uint32_t update_ms = efi.get_last_update_ms();
if (!efi.is_healthy() || efi_update_ms == update_ms) {
return;
}
efi_update_ms = update_ms;
EFI_State state;
efi.get_state(state);
{
/*
send status packet
*/
uavcan_equipment_ice_reciprocating_Status pkt {};
// state maps 1:1 from Engine_State
pkt.state = uint8_t(state.engine_state);
switch (state.crankshaft_sensor_status) {
case Crankshaft_Sensor_Status::NOT_SUPPORTED:
break;
case Crankshaft_Sensor_Status::OK:
pkt.flags |= UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_CRANKSHAFT_SENSOR_ERROR_SUPPORTED;
break;
case Crankshaft_Sensor_Status::ERROR:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_CRANKSHAFT_SENSOR_ERROR_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_CRANKSHAFT_SENSOR_ERROR;
break;
}
switch (state.temperature_status) {
case Temperature_Status::NOT_SUPPORTED:
break;
case Temperature_Status::OK:
pkt.flags |= UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_SUPPORTED;
break;
case Temperature_Status::BELOW_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_BELOW_NOMINAL;
break;
case Temperature_Status::ABOVE_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_ABOVE_NOMINAL;
break;
case Temperature_Status::OVERHEATING:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_OVERHEATING;
break;
case Temperature_Status::EGT_ABOVE_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_TEMPERATURE_EGT_ABOVE_NOMINAL;
break;
}
switch (state.fuel_pressure_status) {
case Fuel_Pressure_Status::NOT_SUPPORTED:
break;
case Fuel_Pressure_Status::OK:
pkt.flags |= UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_FUEL_PRESSURE_SUPPORTED;
break;
case Fuel_Pressure_Status::BELOW_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_FUEL_PRESSURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_FUEL_PRESSURE_BELOW_NOMINAL;
break;
case Fuel_Pressure_Status::ABOVE_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_FUEL_PRESSURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_FUEL_PRESSURE_ABOVE_NOMINAL;
break;
}
switch (state.oil_pressure_status) {
case Oil_Pressure_Status::NOT_SUPPORTED:
break;
case Oil_Pressure_Status::OK:
pkt.flags |= UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_OIL_PRESSURE_SUPPORTED;
break;
case Oil_Pressure_Status::BELOW_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_OIL_PRESSURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_OIL_PRESSURE_BELOW_NOMINAL;
break;
case Oil_Pressure_Status::ABOVE_NOMINAL:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_OIL_PRESSURE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_OIL_PRESSURE_ABOVE_NOMINAL;
break;
}
switch (state.detonation_status) {
case Detonation_Status::NOT_SUPPORTED:
break;
case Detonation_Status::NOT_OBSERVED:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_DETONATION_SUPPORTED;
break;
case Detonation_Status::OBSERVED:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_DETONATION_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_DETONATION_OBSERVED;
break;
}
switch (state.misfire_status) {
case Misfire_Status::NOT_SUPPORTED:
break;
case Misfire_Status::NOT_OBSERVED:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_MISFIRE_SUPPORTED;
break;
case Misfire_Status::OBSERVED:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_MISFIRE_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_MISFIRE_OBSERVED;
break;
}
switch (state.debris_status) {
case Debris_Status::NOT_SUPPORTED:
break;
case Debris_Status::NOT_DETECTED:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_DEBRIS_SUPPORTED;
break;
case Debris_Status::DETECTED:
pkt.flags |=
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_DEBRIS_SUPPORTED |
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_FLAG_DEBRIS_DETECTED;
break;
}
pkt.engine_load_percent = state.engine_load_percent;
pkt.engine_speed_rpm = state.engine_speed_rpm;
pkt.spark_dwell_time_ms = state.spark_dwell_time_ms;
pkt.atmospheric_pressure_kpa = state.atmospheric_pressure_kpa;
pkt.intake_manifold_pressure_kpa = state.intake_manifold_pressure_kpa;
pkt.intake_manifold_temperature = state.intake_manifold_temperature;
pkt.coolant_temperature = state.coolant_temperature;
pkt.oil_pressure = state.oil_pressure;
pkt.oil_temperature = state.oil_temperature;
pkt.fuel_pressure = state.fuel_pressure;
pkt.fuel_consumption_rate_cm3pm = state.fuel_consumption_rate_cm3pm;
pkt.estimated_consumed_fuel_volume_cm3 = state.estimated_consumed_fuel_volume_cm3;
pkt.throttle_position_percent = state.throttle_position_percent;
pkt.ecu_index = state.ecu_index;
pkt.spark_plug_usage = uint8_t(state.spark_plug_usage);
// assume single set of cylinder status
pkt.cylinder_status.len = 1;
auto &c = pkt.cylinder_status.data[0];
const auto &state_c = state.cylinder_status;
c.ignition_timing_deg = state_c.ignition_timing_deg;
c.injection_time_ms = state_c.injection_time_ms;
c.cylinder_head_temperature = state_c.cylinder_head_temperature;
c.exhaust_gas_temperature = state_c.exhaust_gas_temperature;
c.lambda_coefficient = state_c.lambda_coefficient;
uint8_t buffer[UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_MAX_SIZE] {};
const uint16_t total_size = uavcan_equipment_ice_reciprocating_Status_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_SIGNATURE,
UAVCAN_EQUIPMENT_ICE_RECIPROCATING_STATUS_ID,
CANARD_TRANSFER_PRIORITY_LOW,
&buffer[0],
total_size);
}
}
#endif // HAL_PERIPH_ENABLE_EFI
// printf to CAN LogMessage for debugging
void can_printf(const char *fmt, ...)
{
#if HAL_PERIPH_SUPPORT_LONG_CAN_PRINTF
const uint8_t packet_count_max = 4; // how many packets we're willing to break up an over-sized string into
const uint8_t packet_data_max = 90; // max single debug string length = sizeof(uavcan_protocol_debug_LogMessage.text.data)
uint8_t buffer_data[packet_count_max*packet_data_max] {};
va_list ap;
va_start(ap, fmt);
// strip off any negative return errors by treating result as 0
uint32_t char_count = MAX(vsnprintf((char*)buffer_data, sizeof(buffer_data), fmt, ap), 0);
va_end(ap);
// send multiple uavcan_protocol_debug_LogMessage packets if the fmt string is too long.
uint16_t buffer_offset = 0;
for (uint8_t i=0; i<packet_count_max && char_count > 0; i++) {
uavcan_protocol_debug_LogMessage pkt {};
pkt.text.len = MIN(char_count, sizeof(pkt.text.data));
char_count -= pkt.text.len;
memcpy(pkt.text.data, &buffer_data[buffer_offset], pkt.text.len);
buffer_offset += pkt.text.len;
uint8_t buffer_packet[UAVCAN_PROTOCOL_DEBUG_LOGMESSAGE_MAX_SIZE] {};
const uint32_t len = uavcan_protocol_debug_LogMessage_encode(&pkt, buffer_packet, !periph.canfdout());
canard_broadcast(UAVCAN_PROTOCOL_DEBUG_LOGMESSAGE_SIGNATURE,
UAVCAN_PROTOCOL_DEBUG_LOGMESSAGE_ID,
CANARD_TRANSFER_PRIORITY_LOW,
buffer_packet,
len);
}
#else
uavcan_protocol_debug_LogMessage pkt {};
uint8_t buffer[UAVCAN_PROTOCOL_DEBUG_LOGMESSAGE_MAX_SIZE] {};
va_list ap;
va_start(ap, fmt);
uint32_t n = vsnprintf((char*)pkt.text.data, sizeof(pkt.text.data), fmt, ap);
va_end(ap);
pkt.text.len = MIN(n, sizeof(pkt.text.data));
uint32_t len = uavcan_protocol_debug_LogMessage_encode(&pkt, buffer, !periph.canfdout());
canard_broadcast(UAVCAN_PROTOCOL_DEBUG_LOGMESSAGE_SIGNATURE,
UAVCAN_PROTOCOL_DEBUG_LOGMESSAGE_ID,
CANARD_TRANSFER_PRIORITY_LOW,
buffer,
len);
#endif
}