#pragma once #include #if AP_UAVCAN_SLCAN_ENABLED #include #include "AP_HAL/utility/RingBuffer.h" #define SLCAN_BUFFER_SIZE 200 #define SLCAN_RX_QUEUE_SIZE 64 #define SLCAN_DRIVER_INDEX 2 class SLCANRouter; namespace SLCAN { /** * Driver error codes. * These values can be returned from driver functions negated. */ static const int16_t ErrUnknown = 1000; ///< Reserved for future use static const int16_t ErrNotImplemented = 1001; ///< Feature not implemented static const int16_t ErrInvalidBitRate = 1002; ///< Bit rate not supported static const int16_t ErrLogic = 1003; ///< Internal logic error static const int16_t ErrUnsupportedFrame = 1004; ///< Frame not supported (e.g. RTR, CAN FD, etc) static const int16_t ErrMsrInakNotSet = 1005; ///< INAK bit of the MSR register is not 1 static const int16_t ErrMsrInakNotCleared = 1006; ///< INAK bit of the MSR register is not 0 static const int16_t ErrBitRateNotDetected = 1007; ///< Auto bit rate detection could not be finished static const int16_t ErrFilterNumConfigs = 1008; ///< Auto bit rate detection could not be finished class CANManager; /** * RX queue item. * The application shall not use this directly. */ struct CanRxItem { uint64_t utc_usec; uavcan::CanFrame frame; uavcan::CanIOFlags flags; CanRxItem() : utc_usec(0), flags(0) { } }; class CAN: public AP_HAL::CAN { friend class CANManager; friend class ::SLCANRouter; struct TxItem { uavcan::MonotonicTime deadline; uavcan::CanFrame frame; bool pending; bool loopback; bool abort_on_error; TxItem() : pending(false), loopback(false), abort_on_error(false) { } }; enum { NumTxMailboxes = 3 }; enum { NumFilters = 14 }; uint32_t bitrate_; virtual int16_t send(const uavcan::CanFrame& frame, uavcan::MonotonicTime tx_deadline, uavcan::CanIOFlags flags) override; virtual int16_t receive(uavcan::CanFrame& out_frame, uavcan::MonotonicTime& out_ts_monotonic, uavcan::UtcTime& out_ts_utc, uavcan::CanIOFlags& out_flags) override; int16_t reportFrame(const uavcan::CanFrame& frame, bool loopback, uint64_t timestamp_usec); virtual int16_t configureFilters(const uavcan::CanFilterConfig* filter_configs, uint16_t num_configs) override { //TODO: possibly check at the first serial read return 0; } virtual uint16_t getNumFilters() const override { return NumFilters; } /** * Total number of hardware failures and other kinds of errors (e.g. queue overruns). * May increase continuously if the interface is not connected to the bus. */ virtual uint64_t getErrorCount() const override { return 0; } const char* processCommand(char* cmd); bool push_Frame(uavcan::CanFrame &frame); bool handle_FrameRTRStd(const char* cmd); bool handle_FrameRTRExt(const char* cmd); bool handle_FrameDataStd(const char* cmd); bool handle_FrameDataExt(const char* cmd); void reader(); inline void addByte(const uint8_t byte); bool initialized_; bool _port_initialised; char buf_[SLCAN_BUFFER_SIZE + 1]; int16_t pos_ = 0; AP_HAL::UARTDriver *_port = nullptr; ObjectBuffer rx_queue_; uint8_t self_index_; HAL_Semaphore rx_sem_; unsigned _pending_frame_size = 0; const uint32_t _serial_lock_key = 0x53494442; bool _close = true; public: CAN(uint8_t self_index, uint8_t rx_queue_capacity): self_index_(self_index), rx_queue_(rx_queue_capacity), _port_initialised(false) { UAVCAN_ASSERT(self_index_ < CAN_STM32_NUM_IFACES); } enum { MaxRxQueueCapacity = 254 }; enum OperatingMode { NormalMode, SilentMode }; int init(const uint32_t bitrate, const OperatingMode mode, AP_HAL::UARTDriver* port); bool begin(uint32_t bitrate) override { if (init(bitrate, OperatingMode::NormalMode, nullptr) == 0) { bitrate_ = bitrate; initialized_ = true; } else { initialized_ = false; } return initialized_; } void end() override { } void reset() override; int32_t tx_pending() override { return _port->tx_pending() ? 0:-1; } int32_t available() override { return _port->available() ? 0:-1; } bool is_initialized() override { return initialized_; } bool closed() { return _close; } bool pending_frame_sent(); bool isRxBufferEmpty(void); bool canAcceptNewTxFrame() const; }; class CANManager: public AP_HAL::CANManager, public uavcan::ICanDriver { bool initialized_; CAN driver_; uint8_t _ifaces_num = 1; virtual int16_t select(uavcan::CanSelectMasks& inout_masks, const uavcan::CanFrame* (&pending_tx)[uavcan::MaxCanIfaces], uavcan::MonotonicTime blocking_deadline) override; uavcan::CanSelectMasks makeSelectMasks(const uavcan::CanFrame* (&pending_tx)[uavcan::MaxCanIfaces]); thread_t *_irq_handler_ctx = nullptr; public: CANManager() : AP_HAL::CANManager(this), initialized_(false), driver_(SLCAN_DRIVER_INDEX, SLCAN_RX_QUEUE_SIZE) { } /** * Whether at least one iface had at least one successful IO since previous call of this method. * This is designed for use with iface activity LEDs. */ //bool hadActivity(); static CANManager *from(AP_HAL::CANManager *can) { return static_cast(can); } bool begin(uint32_t bitrate, uint8_t can_number) override; /* Test if CAN manager is ready and initialized return false - CAN manager not initialized true - CAN manager is initialized */ bool is_initialized() override; void initialized(bool val) override; virtual CAN* getIface(uint8_t iface_index) override { return &driver_; } virtual uint8_t getNumIfaces() const override { return _ifaces_num; } void reader_trampoline(void); }; } #include #endif // AP_UAVCAN_SLCAN_ENABLED