/* * © 2023, Neil McKechnie * © 2022 Paul M Antoine * 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_NONBLOCKING_H #define I2CMANAGER_NONBLOCKING_H #include #include "I2CManager.h" #if defined(I2C_USE_INTERRUPTS) // atomic.h isn't available on SAMD, and likely others too... #if defined(__AVR__) #include #elif defined(__arm__) // Helper assembly language functions static __inline__ uint8_t my_iSeiRetVal(void) { __asm__ __volatile__ ("cpsie i" ::); return 1; } static __inline__ uint8_t my_iCliRetVal(void) { __asm__ __volatile__ ("cpsid i" ::); return 1; } static __inline__ void my_iRestore(const uint32_t *__s) { uint32_t res = *__s; __asm__ __volatile__ ("MSR primask, %0" : : "r" (res) ); } static __inline__ uint32_t my_iGetIReg( void ) { uint32_t reg; __asm__ __volatile__ ("MRS %0, primask" : "=r" (reg) ); return reg; } // Macros for atomic isolation #define MY_ATOMIC_RESTORESTATE uint32_t _sa_saved \ __attribute__((__cleanup__(my_iRestore))) = my_iGetIReg() #define ATOMIC() \ for ( MY_ATOMIC_RESTORESTATE, _done = my_iCliRetVal(); \ _done; _done = 0 ) #define ATOMIC_BLOCK(x) ATOMIC() #define ATOMIC_RESTORESTATE #endif #else #define ATOMIC_BLOCK(x) #define ATOMIC_RESTORESTATE #endif // This module is only compiled if I2C_USE_WIRE is not defined, so undefine it here // to get intellisense to work correctly. #if defined(I2C_USE_WIRE) #undef I2C_USE_WIRE #endif /*************************************************************************** * Initialise the I2CManagerAsync class. ***************************************************************************/ void I2CManagerClass::_initialise() { queueHead = queueTail = NULL; state = I2C_STATE_FREE; I2C_init(); _setClock(_clockSpeed); } /*************************************************************************** * Set I2C clock speed. Normally 100000 (Standard) or 400000 (Fast) * on Arduino. Mega4809 supports 1000000 (Fast+) too. * This function saves the desired clock speed and the startTransaction * function acts on it before a new transaction, to avoid speed changes * during an I2C transaction. ***************************************************************************/ void I2CManagerClass::_setClock(unsigned long i2cClockSpeed) { pendingClockSpeed = i2cClockSpeed; } /*************************************************************************** * Helper function to start operations, if the I2C interface is free and * there is a queued request to be processed. * If there's an I2C clock speed change pending, then implement it before * starting the operation. ***************************************************************************/ void I2CManagerClass::startTransaction() { ATOMIC_BLOCK(ATOMIC_RESTORESTATE) { if ((state == I2C_STATE_FREE) && (queueHead != NULL)) { state = I2C_STATE_ACTIVE; // Check for pending clock speed change if (pendingClockSpeed) { // We're about to start a new I2C transaction, so set clock now. I2C_setClock(pendingClockSpeed); pendingClockSpeed = 0; } startTime = micros(); currentRequest = queueHead; rxCount = txCount = 0; // Copy key fields to static data for speed. operation = currentRequest->operation & OPERATION_MASK; // Start the I2C process going. I2C_sendStart(); } } } /*************************************************************************** * Function to queue a request block and initiate operations. ***************************************************************************/ void I2CManagerClass::queueRequest(I2CRB *req) { req->status = I2C_STATUS_PENDING; req->nextRequest = NULL; ATOMIC_BLOCK(ATOMIC_RESTORESTATE) { if (!queueTail) queueHead = queueTail = req; // Only item on queue else queueTail = queueTail->nextRequest = req; // Add to end startTransaction(); } } /*************************************************************************** * Initiate a write to an I2C device (non-blocking operation) ***************************************************************************/ uint8_t I2CManagerClass::write(uint8_t i2cAddress, const uint8_t *writeBuffer, uint8_t writeLen, I2CRB *req) { // Make sure previous request has completed. req->wait(); req->setWriteParams(i2cAddress, writeBuffer, writeLen); queueRequest(req); return I2C_STATUS_OK; } /*************************************************************************** * Initiate a write from PROGMEM (flash) to an I2C device (non-blocking operation) ***************************************************************************/ uint8_t I2CManagerClass::write_P(uint8_t i2cAddress, const uint8_t * writeBuffer, uint8_t writeLen, I2CRB *req) { // Make sure previous request has completed. req->wait(); req->setWriteParams(i2cAddress, writeBuffer, writeLen); req->operation = OPERATION_SEND_P; queueRequest(req); return I2C_STATUS_OK; } /*************************************************************************** * Initiate a read from the I2C device, optionally preceded by a write * (non-blocking operation) ***************************************************************************/ uint8_t I2CManagerClass::read(uint8_t i2cAddress, uint8_t *readBuffer, uint8_t readLen, const uint8_t *writeBuffer, uint8_t writeLen, I2CRB *req) { // Make sure previous request has completed. req->wait(); req->setRequestParams(i2cAddress, readBuffer, readLen, writeBuffer, writeLen); queueRequest(req); return I2C_STATUS_OK; } /*************************************************************************** * Set I2C timeout value in microseconds. The timeout applies to the entire * I2CRB request, e.g. where a write+read is performed, the timer is not * reset before the read. ***************************************************************************/ void I2CManagerClass::setTimeout(unsigned long value) { timeout = value; }; /*************************************************************************** * checkForTimeout() function, called from isBusy() and wait() to cancel * requests that are taking too long to complete. Such faults * may be caused by an I2C wire short for example. ***************************************************************************/ void I2CManagerClass::checkForTimeout() { ATOMIC_BLOCK(ATOMIC_RESTORESTATE) { I2CRB *t = queueHead; if (state==I2C_STATE_ACTIVE && t!=0 && t==currentRequest && timeout > 0) { // Check for timeout unsigned long elapsed = micros() - startTime; if (elapsed > timeout) { #ifdef DIAG_IO //DIAG(F("I2CManager Timeout on x%x, I2CRB=x%x"), t->i2cAddress, currentRequest); #endif // Excessive time. Dequeue request queueHead = t->nextRequest; if (!queueHead) queueTail = NULL; currentRequest = NULL; bytesToReceive = bytesToSend = 0; // Post request as timed out. t->status = I2C_STATUS_TIMEOUT; // Reset TWI interface so it is able to continue // Try close and init, not entirely satisfactory but sort of works... I2C_close(); // Shutdown and restart twi interface I2C_init(); _setClock(_clockSpeed); state = I2C_STATE_FREE; // I2C_sendStop(); // in case device is waiting for a stop condition // Initiate next queued request if any. startTransaction(); } } } } /*************************************************************************** * Loop function, for general background work ***************************************************************************/ void I2CManagerClass::loop() { #if !defined(I2C_USE_INTERRUPTS) handleInterrupt(); #endif // Call function to monitor for stuch I2C operations. checkForTimeout(); } /*************************************************************************** * Interupt handler. Call I2C state machine, and dequeue request * if completed. ***************************************************************************/ void I2CManagerClass::handleInterrupt() { // Update hardware state machine I2C_handleInterrupt(); // Check if current request has completed. If there's a current request // and state isn't active then state contains the completion status of the request. if (state != I2C_STATE_ACTIVE && currentRequest != NULL) { // Operation has completed. if (state == I2C_STATUS_OK || ++retryCounter > MAX_I2C_RETRIES || currentRequest->operation & OPERATION_NORETRY) { // Status is OK, or has failed and retry count exceeded, or retries disabled. // Remove completed request from head of queue I2CRB * t = queueHead; if (t == currentRequest) { queueHead = t->nextRequest; if (!queueHead) queueTail = queueHead; t->nBytes = rxCount; t->status = state; // I2C state machine is now free for next request currentRequest = NULL; state = I2C_STATE_FREE; } retryCounter = 0; } else { // Status is failed and retry permitted. // Retry previous request. state = I2C_STATE_FREE; } } if (state == I2C_STATE_FREE && queueHead != NULL) { // Allow any pending interrupts before starting the next request. interrupts(); // Start next request I2CManager.startTransaction(); } } // Fields in I2CManager class specific to Non-blocking implementation. I2CRB * volatile I2CManagerClass::queueHead = NULL; I2CRB * volatile I2CManagerClass::queueTail = NULL; I2CRB * volatile I2CManagerClass::currentRequest = NULL; volatile uint8_t I2CManagerClass::state = I2C_STATE_FREE; volatile uint8_t I2CManagerClass::txCount; volatile uint8_t I2CManagerClass::rxCount; volatile uint8_t I2CManagerClass::operation; volatile uint8_t I2CManagerClass::bytesToSend; volatile uint8_t I2CManagerClass::bytesToReceive; volatile unsigned long I2CManagerClass::startTime; uint8_t I2CManagerClass::retryCounter = 0; #endif