/* * © 2021, Neil McKechnie. All rights reserved. * * This file is part of CommandStation-EX * * This 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. * * It 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 CommandStation. If not, see . */ #ifndef I2CMANAGER_H #define I2CMANAGER_H #include #include "FSH.h" /* * Manager for I2C communications. For portability, it allows use * of the Wire class, but also has a native implementation for AVR * which supports non-blocking queued I/O requests. * * Helps to avoid calling Wire.begin() multiple times (which is not) * entirely benign as it reinitialises). * * Also helps to avoid the Wire clock from being set, by another device * driver, to a speed which is higher than a device supports. * * Thirdly, it provides a convenient way to check whether there is a * device on a particular I2C address. * * Non-blocking requests are issued by creating an I2C Request Block * (I2CRB) which is then added to the I2C manager's queue. The * application refers to this block to check for completion of the * operation, and for reading completion status. * * Examples: * I2CRB rb; * uint8_t status = I2CManager.write(address, buffer, sizeof(buffer), &rb); * ... * if (!rb.isBusy()) { * status = rb.status; * // Repeat write * I2CManager.queueRequest(&rb); * ... * status = rb.wait(); // Wait for completion and read status * } * ... * I2CRB rb2; * outbuffer[0] = 12; // Register number in I2C device to be read * rb2.setRequestParams(address, inBuffer, 1, outBuffer, 1); * status = I2CManager.queueRequest(&rb2); * if (status == I2C_STATUS_OK) { * status = rb2.wait(); * if (status == I2C_STATUS_OK) { * registerValue = inBuffer[0]; * } * } * ... * * Synchronous (blocking) calls are also possible, e.g. * status = I2CManager.write(address, buffer, sizeof(buffer)); * * When using non-blocking requests, neither the I2CRB nor the input or output * buffers should be modified until the I2CRB is complete (not busy). * * Timeout monitoring is possible, but requires that the following call is made * reasonably frequently in the program's loop() function: * I2CManager.loop(); * */ /* * Future enhancement possibility: * * I2C Multiplexer (e.g. TCA9547, TCA9548) * * A multiplexer offers a way of extending the address range of I2C devices. For example, GPIO extenders use address range 0x20-0x27 * to are limited to 8 on a bus. By adding a multiplexer, the limit becomes 8 for each of the multiplexer's 8 sub-buses, i.e. 64. * And a single I2C bus can have up to 8 multiplexers, giving up to 64 sub-buses and, in theory, up to 512 I/O extenders; that's * as many as 8192 input/output pins! * Secondly, the capacitance of the bus is an electrical limiting factor of the length of the bus, speed and number of devices. * The multiplexer isolates each sub-bus from the others, and so reduces the capacitance of the bus. For example, with one * multiplexer and 64 GPIO extenders, only 9 devices are connected to the bus at any time (multiplexer plus 8 extenders). * Thirdly, the multiplexer offers the ability to use mixed-speed devices more effectively, by allowing high-speed devices to be * put on a different bus to low-speed devices, enabling the software to switch the I2C speed on-the-fly between I2C transactions. * * Changes required: Increase the size of the I2CAddress field in the IODevice class from uint8_t to uint16_t. * The most significant byte would contain a '1' bit flag, the multiplexer number (0-7) and bus number (0-7). Then, when performing * an I2C operation, the I2CManager would check this byte and, if zero, do what it currently does. If the byte is non-zero, then * that means the device is connected via a multiplexer so the I2C transaction should be preceded by a select command issued to the * relevant multiplexer. * * Non-interrupting I2C: * * I2C may be operated without interrupts (undefine I2C_USE_INTERRUPTS). Instead, the I2C state * machine handler, currently invoked from the interrupt service routine, is invoked from the loop() function. * The speed at which I2C operations can be performed then becomes highly dependent on the frequency that * the loop() function is called, and may be adequate under some circumstances. * The advantage of NOT using interrupts is that the impact of I2C upon the DCC waveform (when accurate timing mode isn't in use) * becomes almost zero. * This mechanism is under evaluation and should not be relied upon as yet. * */ //#define I2C_USE_WIRE #ifndef I2C_NO_INTERRUPTS #define I2C_USE_INTERRUPTS #endif // Status codes for I2CRB structures. enum : uint8_t { I2C_STATUS_OK=0, I2C_STATUS_TRUNCATED=1, I2C_STATUS_DEVICE_NOT_PRESENT=2, I2C_STATUS_TRANSMIT_ERROR=3, I2C_STATUS_NEGATIVE_ACKNOWLEDGE=4, I2C_STATUS_TIMEOUT=5, I2C_STATUS_ARBITRATION_LOST=6, I2C_STATUS_BUS_ERROR=7, I2C_STATUS_UNEXPECTED_ERROR=8, I2C_STATUS_PENDING=253, }; // Status codes for the state machine (not returned to caller). enum : uint8_t { I2C_STATE_ACTIVE=253, I2C_STATE_FREE=254, I2C_STATE_CLOSING=255, }; typedef enum : uint8_t { OPERATION_READ = 1, OPERATION_REQUEST = 2, OPERATION_SEND = 3, OPERATION_SEND_P = 4, } OperationEnum; // Default I2C frequency #ifndef I2C_FREQ #define I2C_FREQ 400000L #endif // Struct defining a request context for an I2C operation. struct I2CRB { volatile uint8_t status; // Completion status, or pending flag (updated from IRC) volatile uint8_t nBytes; // Number of bytes read (updated from IRC) uint8_t wait(); bool isBusy(); inline void init() { status = I2C_STATUS_OK; }; void setReadParams(uint8_t i2cAddress, uint8_t *readBuffer, uint8_t readLen); void setRequestParams(uint8_t i2cAddress, uint8_t *readBuffer, uint8_t readLen, const uint8_t *writeBuffer, uint8_t writeLen); void setWriteParams(uint8_t i2cAddress, const uint8_t *writeBuffer, uint8_t writeLen); uint8_t writeLen; uint8_t readLen; uint8_t operation; uint8_t i2cAddress; uint8_t *readBuffer; const uint8_t *writeBuffer; #if !defined(I2C_USE_WIRE) I2CRB *nextRequest; #endif }; // I2C Manager class I2CManagerClass { public: // If not already initialised, initialise I2C (wire). void begin(void); // Set clock speed to the lowest requested one. void setClock(uint32_t speed); // Force clock speed void forceClock(uint32_t speed); // Check if specified I2C address is responding. uint8_t checkAddress(uint8_t address); inline bool exists(uint8_t address) { return checkAddress(address)==I2C_STATUS_OK; } // Write a complete transmission to I2C from an array in RAM uint8_t write(uint8_t address, const uint8_t buffer[], uint8_t size); uint8_t write(uint8_t address, const uint8_t buffer[], uint8_t size, I2CRB *rb); // Write a complete transmission to I2C from an array in Flash uint8_t write_P(uint8_t address, const uint8_t buffer[], uint8_t size); uint8_t write_P(uint8_t address, const uint8_t buffer[], uint8_t size, I2CRB *rb); // Write a transmission to I2C from a list of bytes. uint8_t write(uint8_t address, uint8_t nBytes, ...); // Write a command from an array in RAM and read response uint8_t read(uint8_t address, uint8_t readBuffer[], uint8_t readSize, const uint8_t writeBuffer[]=NULL, uint8_t writeSize=0); uint8_t read(uint8_t address, uint8_t readBuffer[], uint8_t readSize, const uint8_t writeBuffer[], uint8_t writeSize, I2CRB *rb); // Write a command from an arbitrary list of bytes and read response uint8_t read(uint8_t address, uint8_t readBuffer[], uint8_t readSize, uint8_t writeSize, ...); void queueRequest(I2CRB *req); // Function to abort long-running operations. void checkForTimeout(); // Loop method void loop(); private: bool _beginCompleted = false; bool _clockSpeedFixed = false; uint32_t _clockSpeed = 400000L; // 400kHz max on Arduino. // Finish off request block by waiting for completion and posting status. uint8_t finishRB(I2CRB *rb, uint8_t status); void _initialise(); void _setClock(unsigned long); #if !defined(I2C_USE_WIRE) // I2CRB structs are queued on the following two links. // If there are no requests, both are NULL. // If there is only one request, then queueHead and queueTail both point to it. // Otherwise, queueHead is the pointer to the first request in the queue and // queueTail is the pointer to the last request in the queue. // Within the queue, each request's nextRequest field points to the // next request, or NULL. // Mark volatile as they are updated by IRC and read/written elsewhere. static I2CRB * volatile queueHead; static I2CRB * volatile queueTail; static volatile uint8_t status; static I2CRB * volatile currentRequest; static volatile uint8_t txCount; static volatile uint8_t rxCount; static volatile uint8_t bytesToSend; static volatile uint8_t bytesToReceive; static volatile uint8_t operation; static volatile unsigned long startTime; static unsigned long timeout; // Transaction timeout in microseconds. 0=disabled. void startTransaction(); // Low-level hardware manipulation functions. static void I2C_init(); static void I2C_setClock(unsigned long i2cClockSpeed); static void I2C_handleInterrupt(); static void I2C_sendStart(); static void I2C_sendStop(); static void I2C_close(); public: void setTimeout(unsigned long value) { timeout = value;}; // handleInterrupt needs to be public to be called from the ISR function! static void handleInterrupt(); #endif }; extern I2CManagerClass I2CManager; #endif