/*
* The MIT License (MIT)
*
* Copyright (c) 2014 Pavel Kirienko
*
* Permission is hereby granted, free of charge, to any person obtaining a copy of
* this software and associated documentation files (the "Software"), to deal in
* the Software without restriction, including without limitation the rights to
* use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
* the Software, and to permit persons to whom the Software is furnished to do so,
* subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
* FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
* COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
* IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
/*
* This file 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 file 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 .
*
* Code by Siddharth Bharat Purohit
*/
#pragma once
#include "AP_HAL_ChibiOS.h"
#if HAL_WITH_UAVCAN
#include "CANThread.h"
#include "fdcan.hpp"
class SLCANRouter;
namespace ChibiOS_CAN
{
/**
* Driver error codes.
* These values can be returned from driver functions negated.
*/
//static const uavcan::int16_t ErrUnknown = 1000; ///< Reserved for future use
static const uavcan::int16_t ErrNotImplemented = 1001; ///< Feature not implemented
static const uavcan::int16_t ErrInvalidBitRate = 1002; ///< Bit rate not supported
static const uavcan::int16_t ErrLogic = 1003; ///< Internal logic error
static const uavcan::int16_t ErrUnsupportedFrame = 1004; ///< Frame not supported (e.g. RTR, CAN FD, etc)
static const uavcan::int16_t ErrMsrInakNotSet = 1005; ///< INAK bit of the MSR register is not 1
static const uavcan::int16_t ErrMsrInakNotCleared = 1006; ///< INAK bit of the MSR register is not 0
static const uavcan::int16_t ErrBitRateNotDetected = 1007; ///< Auto bit rate detection could not be finished
static const uavcan::int16_t ErrFilterNumConfigs = 1008; ///< Number of filters is more than supported
/**
* RX queue item.
* The application shall not use this directly.
*/
struct CanRxItem {
uavcan::uint64_t utc_usec;
uavcan::CanFrame frame;
uavcan::CanIOFlags flags;
CanRxItem()
: utc_usec(0)
, flags(0)
{ }
};
/**
* Single CAN iface.
* The application shall not use this directly.
*/
class CanIface : public uavcan::ICanIface, uavcan::Noncopyable
{
#if AP_UAVCAN_SLCAN_ENABLED
friend class ::SLCANRouter;
static SLCANRouter _slcan_router;
#endif
class RxQueue
{
CanRxItem* const buf_;
const uavcan::uint8_t capacity_;
uavcan::uint8_t in_;
uavcan::uint8_t out_;
uavcan::uint8_t len_;
uavcan::uint32_t overflow_cnt_;
void registerOverflow();
public:
RxQueue(CanRxItem* buf, uavcan::uint8_t capacity)
: buf_(buf)
, capacity_(capacity)
, in_(0)
, out_(0)
, len_(0)
, overflow_cnt_(0)
{ }
void push(const uavcan::CanFrame& frame, const uint64_t& utc_usec, uavcan::CanIOFlags flags);
void pop(uavcan::CanFrame& out_frame, uavcan::uint64_t& out_utc_usec, uavcan::CanIOFlags& out_flags);
void reset();
unsigned getLength() const
{
return len_;
}
uavcan::uint32_t getOverflowCount() const
{
return overflow_cnt_;
}
};
struct MessageRAM {
uavcan::uint32_t StandardFilterSA;
uavcan::uint32_t ExtendedFilterSA;
uavcan::uint32_t RxFIFO0SA;
uavcan::uint32_t RxFIFO1SA;
uavcan::uint32_t TxFIFOQSA;
uavcan::uint32_t EndAddress;
} MessageRam_;
struct Timings {
uavcan::uint16_t prescaler;
uavcan::uint8_t sjw;
uavcan::uint8_t bs1;
uavcan::uint8_t bs2;
Timings()
: prescaler(0)
, sjw(0)
, bs1(0)
, bs2(0)
{ }
};
struct TxItem {
uavcan::MonotonicTime deadline;
uavcan::CanFrame frame;
bool loopback;
bool abort_on_error;
uint8_t index;
TxItem() :
loopback(false),
abort_on_error(false)
{ }
};
enum { NumTxMailboxes = 32 };
static const uavcan::uint32_t TSR_ABRQx[NumTxMailboxes];
static uint32_t FDCANMessageRAMOffset_;
RxQueue rx_queue_;
fdcan::CanType* const can_;
uavcan::uint64_t error_cnt_;
uavcan::uint32_t served_aborts_cnt_;
BusEvent& update_event_;
TxItem pending_tx_[NumTxMailboxes];
uavcan::uint8_t peak_tx_mailbox_index_;
const uavcan::uint8_t self_index_;
bool had_activity_;
int computeTimings(uavcan::uint32_t target_bitrate, Timings& out_timings);
virtual uavcan::int16_t send(const uavcan::CanFrame& frame, uavcan::MonotonicTime tx_deadline,
uavcan::CanIOFlags flags) override;
virtual uavcan::int16_t receive(uavcan::CanFrame& out_frame, uavcan::MonotonicTime& out_ts_monotonic,
uavcan::UtcTime& out_ts_utc, uavcan::CanIOFlags& out_flags) override;
virtual uavcan::int16_t configureFilters(const uavcan::CanFilterConfig* filter_configs,
uavcan::uint16_t num_configs) override;
virtual uavcan::uint16_t getNumFilters() const override;
void setupMessageRam(void);
static uint32_t FDCAN2MessageRAMOffset_;
public:
enum { MaxRxQueueCapacity = 254 };
enum OperatingMode {
NormalMode,
SilentMode
};
CanIface(fdcan::CanType* can, BusEvent& update_event, uavcan::uint8_t self_index,
CanRxItem* rx_queue_buffer, uavcan::uint8_t rx_queue_capacity);
/**
* Initializes the hardware CAN controller.
* Assumes:
* - Iface clock is enabled
* - Iface has been resetted via RCC
* - Caller will configure NVIC by itself
*/
int init(const uavcan::uint32_t bitrate, const OperatingMode mode);
void handleTxCompleteInterrupt(uavcan::uint64_t utc_usec);
void handleRxInterrupt(uavcan::uint8_t fifo_index);
bool readRxFIFO(uavcan::uint8_t fifo_index);
/**
* This method is used to count errors and abort transmission on error if necessary.
* This functionality used to be implemented in the SCE interrupt handler, but that approach was
* generating too much processing overhead, especially on disconnected interfaces.
*
* Should be called from RX ISR, TX ISR, and select(); interrupts must be enabled.
*/
void pollErrorFlagsFromISR();
void discardTimedOutTxMailboxes(uavcan::MonotonicTime current_time);
bool canAcceptNewTxFrame(const uavcan::CanFrame& frame) const;
bool isRxBufferEmpty() const;
/**
* Number of RX frames lost due to queue overflow.
* This is an atomic read, it doesn't require a critical section.
*/
uavcan::uint32_t getRxQueueOverflowCount() const
{
return rx_queue_.getOverflowCount();
}
/**
* 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 uavcan::uint64_t getErrorCount() const override;
/**
* Number of times the driver exercised library's requirement to abort transmission on first error.
* This is an atomic read, it doesn't require a critical section.
* See @ref uavcan::CanIOFlagAbortOnError.
*/
uavcan::uint32_t getVoluntaryTxAbortCount() const
{
return served_aborts_cnt_;
}
/**
* Returns the number of frames pending in the RX queue.
* This is intended for debug use only.
*/
unsigned getRxQueueLength() const;
/**
* Whether this iface had at least one successful IO since the previous call of this method.
* This is designed for use with iface activity LEDs.
*/
bool hadActivity();
/**
* Peak number of TX mailboxes used concurrently since initialization.
* Range is [1, 3].
* Value of 3 suggests that priority inversion could be taking place.
*/
uavcan::uint8_t getPeakNumTxMailboxesUsed() const
{
return uavcan::uint8_t(peak_tx_mailbox_index_ + 1);
}
fdcan::CanType* can_reg(void)
{
return can_;
}
#if AP_UAVCAN_SLCAN_ENABLED
static SLCANRouter &slcan_router() { return _slcan_router; }
#endif
};
/**
* CAN driver, incorporates all available CAN ifaces.
* Please avoid direct use, prefer @ref CanInitHelper instead.
*/
class CanDriver : public uavcan::ICanDriver, uavcan::Noncopyable
{
BusEvent update_event_;
static bool clock_init_;
CanIface if0_;
#if UAVCAN_STM32_NUM_IFACES > 1
CanIface if1_;
#endif
bool initialized_by_me_[UAVCAN_STM32_NUM_IFACES];
uavcan::uint8_t num_ifaces_;
uavcan::uint8_t if_int_to_gl_index_[UAVCAN_STM32_NUM_IFACES];
virtual uavcan::int16_t select(uavcan::CanSelectMasks& inout_masks,
const uavcan::CanFrame* (& pending_tx)[uavcan::MaxCanIfaces],
uavcan::MonotonicTime blocking_deadline) override;
static void initOnce();
static void initOnce(uavcan::uint8_t can_number, bool enable_irqs);
public:
template
CanDriver(CanRxItem(&rx_queue_storage)[UAVCAN_STM32_NUM_IFACES][RxQueueCapacity])
: update_event_(*this)
, if0_(fdcan::Can[0], update_event_, 0, rx_queue_storage[0], RxQueueCapacity)
#if UAVCAN_STM32_NUM_IFACES > 1
, if1_(fdcan::Can[1], update_event_, 1, rx_queue_storage[1], RxQueueCapacity)
#endif
{
uavcan::StaticAssert<(RxQueueCapacity <= CanIface::MaxRxQueueCapacity)>::check();
}
/**
* This function returns select masks indicating which interfaces are available for read/write.
*/
uavcan::CanSelectMasks makeSelectMasks(const uavcan::CanFrame* (& pending_tx)[uavcan::MaxCanIfaces]) const;
BusEvent* getUpdateEvent()
{
return &update_event_;
}
/**
* Whether there's at least one interface where receive() would return a frame.
*/
bool hasReadableInterfaces() const;
/**
* Returns zero if OK.
* Returns negative value if failed (e.g. invalid bitrate).
*/
int init(const uavcan::uint32_t bitrate, const CanIface::OperatingMode mode);
int init(const uavcan::uint32_t bitrate, const CanIface::OperatingMode mode, uavcan::uint8_t can_number);
virtual CanIface* getIface(uavcan::uint8_t iface_index) override;
virtual uavcan::uint8_t getNumIfaces() const override
{
return num_ifaces_;
}
/**
* 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();
};
/**
* Helper class.
* Normally only this class should be used by the application.
* 145 usec per Extended CAN frame @ 1 Mbps, e.g. 32 RX slots * 145 usec --> 4.6 msec before RX queue overruns.
*/
template
class CanInitHelper
{
CanRxItem queue_storage_[UAVCAN_STM32_NUM_IFACES][RxQueueCapacity];
public:
enum { BitRateAutoDetect = 0 };
CanDriver driver;
CanInitHelper() :
driver(queue_storage_)
{ }
/**
* This overload simply configures the provided bitrate.
* Auto bit rate detection will not be performed.
* Bitrate value must be positive.
* @return Negative value on error; non-negative on success. Refer to constants Err*.
*/
int init(uavcan::uint32_t bitrate)
{
return driver.init(bitrate, CanIface::NormalMode);
}
int init(const uavcan::uint32_t bitrate, const CanIface::OperatingMode mode, uavcan::uint8_t can_number)
{
return driver.init(bitrate, mode, can_number);
}
/**
* This function can either initialize the driver at a fixed bit rate, or it can perform
* automatic bit rate detection. For theory please refer to the CiA application note #801.
*
* @param delay_callable A callable entity that suspends execution for strictly more than one second.
* The callable entity will be invoked without arguments.
* @ref getRecommendedListeningDelay().
*
* @param inout_bitrate Fixed bit rate or zero. Zero invokes the bit rate detection process.
* If auto detection was used, the function will update the argument
* with established bit rate. In case of an error the value will be undefined.
*
* @return Negative value on error; non-negative on success. Refer to constants Err*.
*/
template
int init(DelayCallable delay_callable, uavcan::uint32_t& inout_bitrate = BitRateAutoDetect)
{
if (inout_bitrate > 0) {
return driver.init(inout_bitrate, CanIface::NormalMode);
} else {
static const uavcan::uint32_t StandardBitRates[] = {
1000000,
500000,
250000,
125000
};
for (uavcan::uint8_t br = 0; br < sizeof(StandardBitRates) / sizeof(StandardBitRates[0]); br++) {
inout_bitrate = StandardBitRates[br];
const int res = driver.init(inout_bitrate, CanIface::SilentMode);
delay_callable();
if (res >= 0) {
for (uavcan::uint8_t iface = 0; iface < driver.getNumIfaces(); iface++) {
if (!driver.getIface(iface)->isRxBufferEmpty()) {
// Re-initializing in normal mode
return driver.init(inout_bitrate, CanIface::NormalMode);
}
}
}
}
return -ErrBitRateNotDetected;
}
}
/**
* Use this value for listening delay during automatic bit rate detection.
*/
static uavcan::MonotonicDuration getRecommendedListeningDelay()
{
return uavcan::MonotonicDuration::fromMSec(1050);
}
};
}
#include "CANSerialRouter.h"
#endif //HAL_WITH_UAVCAN