LPC11U35 ADC Tick & USBSerial
Dependents: SmallDoseMeter_SingleCH_AE_lpc11u35_V1_00
mbed/CAN.h
- Committer:
- H_Tsunemoto
- Date:
- 2018-02-19
- Revision:
- 0:871ab6846b18
File content as of revision 0:871ab6846b18:
/* mbed Microcontroller Library * Copyright (c) 2006-2013 ARM Limited * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef MBED_CAN_H #define MBED_CAN_H #include "platform.h" #if DEVICE_CAN #include "can_api.h" #include "can_helper.h" #include "FunctionPointer.h" namespace mbed { /** CANMessage class */ class CANMessage : public CAN_Message { public: /** Creates empty CAN message. */ CANMessage() : CAN_Message() { len = 8; type = CANData; format = CANStandard; id = 0; memset(data, 0, 8); } /** Creates CAN message with specific content. */ CANMessage(int _id, const char *_data, char _len = 8, CANType _type = CANData, CANFormat _format = CANStandard) { len = _len & 0xF; type = _type; format = _format; id = _id; memcpy(data, _data, _len); } /** Creates CAN remote message. */ CANMessage(int _id, CANFormat _format = CANStandard) { len = 0; type = CANRemote; format = _format; id = _id; memset(data, 0, 8); } }; /** A can bus client, used for communicating with can devices */ class CAN { public: /** Creates an CAN interface connected to specific pins. * * @param rd read from transmitter * @param td transmit to transmitter * * Example: * @code * #include "mbed.h" * * Ticker ticker; * DigitalOut led1(LED1); * DigitalOut led2(LED2); * CAN can1(p9, p10); * CAN can2(p30, p29); * * char counter = 0; * * void send() { * if(can1.write(CANMessage(1337, &counter, 1))) { * printf("Message sent: %d\n", counter); * counter++; * } * led1 = !led1; * } * * int main() { * ticker.attach(&send, 1); * CANMessage msg; * while(1) { * if(can2.read(msg)) { * printf("Message received: %d\n\n", msg.data[0]); * led2 = !led2; * } * wait(0.2); * } * } * @endcode */ CAN(PinName rd, PinName td); virtual ~CAN(); /** Set the frequency of the CAN interface * * @param hz The bus frequency in hertz * * @returns * 1 if successful, * 0 otherwise */ int frequency(int hz); /** Write a CANMessage to the bus. * * @param msg The CANMessage to write. * * @returns * 0 if write failed, * 1 if write was successful */ int write(CANMessage msg); /** Read a CANMessage from the bus. * * @param msg A CANMessage to read to. * @param handle message filter handle (0 for any message) * * @returns * 0 if no message arrived, * 1 if message arrived */ int read(CANMessage &msg, int handle = 0); /** Reset CAN interface. * * To use after error overflow. */ void reset(); /** Puts or removes the CAN interface into silent monitoring mode * * @param silent boolean indicating whether to go into silent mode or not */ void monitor(bool silent); enum Mode { Reset = 0, Normal, Silent, LocalTest, GlobalTest, SilentTest }; /** Change CAN operation to the specified mode * * @param mode The new operation mode (CAN::Normal, CAN::Silent, CAN::LocalTest, CAN::GlobalTest, CAN::SilentTest) * * @returns * 0 if mode change failed or unsupported, * 1 if mode change was successful */ int mode(Mode mode); /** Filter out incomming messages * * @param id the id to filter on * @param mask the mask applied to the id * @param format format to filter on (Default CANAny) * @param handle message filter handle (Optional) * * @returns * 0 if filter change failed or unsupported, * new filter handle if successful */ int filter(unsigned int id, unsigned int mask, CANFormat format = CANAny, int handle = 0); /** Returns number of read errors to detect read overflow errors. */ unsigned char rderror(); /** Returns number of write errors to detect write overflow errors. */ unsigned char tderror(); enum IrqType { RxIrq = 0, TxIrq, EwIrq, DoIrq, WuIrq, EpIrq, AlIrq, BeIrq, IdIrq }; /** Attach a function to call whenever a CAN frame received interrupt is * generated. * * @param fptr A pointer to a void function, or 0 to set as none * @param event Which CAN interrupt to attach the member function to (CAN::RxIrq for message received, CAN::TxIrq for transmitted or aborted, CAN::EwIrq for error warning, CAN::DoIrq for data overrun, CAN::WuIrq for wake-up, CAN::EpIrq for error passive, CAN::AlIrq for arbitration lost, CAN::BeIrq for bus error) */ void attach(void (*fptr)(void), IrqType type=RxIrq); /** Attach a member function to call whenever a CAN frame received interrupt * is generated. * * @param tptr pointer to the object to call the member function on * @param mptr pointer to the member function to be called * @param event Which CAN interrupt to attach the member function to (CAN::RxIrq for message received, TxIrq for transmitted or aborted, EwIrq for error warning, DoIrq for data overrun, WuIrq for wake-up, EpIrq for error passive, AlIrq for arbitration lost, BeIrq for bus error) */ template<typename T> void attach(T* tptr, void (T::*mptr)(void), IrqType type=RxIrq) { if((mptr != NULL) && (tptr != NULL)) { _irq[type].attach(tptr, mptr); can_irq_set(&_can, (CanIrqType)type, 1); } else { can_irq_set(&_can, (CanIrqType)type, 0); } } static void _irq_handler(uint32_t id, CanIrqType type); protected: can_t _can; FunctionPointer _irq[9]; }; } // namespace mbed #endif #endif // MBED_CAN_H