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CommandStation-EX/IODevice.cpp
Neil McKechnie b384d6c14d Move call to mySetup into IODevice::begin().
Ensure that HAL devices are created before use by moving the call to mySetup into IODevice::begin().  The need for this became evident when it was noted that RMFT (EX-RAIL) interacts with HAL devices during its initialisation, by enabling pull-ups on digital inputs.
Any
2021-11-12 00:05:16 +00:00

502 lines
17 KiB
C++

/*
* © 2021, Neil McKechnie. All rights reserved.
*
* This file is part of DCC++EX API
*
* 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 <https://www.gnu.org/licenses/>.
*/
#include <Arduino.h>
#include "IODevice.h"
#include "DIAG.h"
#include "FSH.h"
#include "IO_MCP23017.h"
#if defined(ARDUINO_ARCH_AVR) || defined(ARDUINO_ARCH_MEGAAVR)
#define USE_FAST_IO
#endif
// Link to mySetup function. If not defined, the function reference will be NULL.
extern __attribute__((weak)) void mySetup();
//==================================================================================================================
// Static methods
//------------------------------------------------------------------------------------------------------------------
// Static functions
// Static method to initialise the IODevice subsystem.
#if !defined(IO_NO_HAL)
// Create any standard device instances that may be required, such as the Arduino pins
// and PCA9685.
void IODevice::begin() {
// Initialise the IO subsystem
ArduinoPins::create(2, NUM_DIGITAL_PINS-2); // Reserve pins for direct access
// Predefine two PCA9685 modules 0x40-0x41
// Allocates 32 pins 100-131
PCA9685::create(100, 16, 0x40);
PCA9685::create(116, 16, 0x41);
// Predefine two MCP23017 module 0x20/0x21
// Allocates 32 pins 164-195
MCP23017::create(164, 16, 0x20);
MCP23017::create(180, 16, 0x21);
// Call the begin() methods of each configured device in turn
for (IODevice *dev=_firstDevice; dev!=NULL; dev = dev->_nextDevice) {
dev->_begin();
}
_initPhase = false;
// Call user's mySetup() function (if defined in the build in mySetup.cpp).
// The contents will depend on the user's system hardware configuration.
// The mySetup.cpp file is a standard C++ module so has access to all of the DCC++EX APIs.
if (mySetup) {
mySetup();
}
}
// Overarching static loop() method for the IODevice subsystem. Works through the
// list of installed devices and calls their individual _loop() method.
// Devices may or may not implement this, but if they do it is useful for things like animations
// or flashing LEDs.
// The current value of micros() is passed as a parameter, so the called loop function
// doesn't need to invoke it.
void IODevice::loop() {
unsigned long currentMicros = micros();
IODevice *lastLoopDevice = _nextLoopDevice; // So we know when to stop...
// Loop through devices until we find one ready to be serviced.
do {
if (!_nextLoopDevice) _nextLoopDevice = _firstDevice;
if (_nextLoopDevice) {
if (_nextLoopDevice->_deviceState != DEVSTATE_FAILED
&& ((long)(currentMicros - _nextLoopDevice->_nextEntryTime)) >= 0) {
// Found one ready to run, so invoke its _loop method.
_nextLoopDevice->_nextEntryTime = currentMicros;
_nextLoopDevice->_loop(currentMicros);
_nextLoopDevice = _nextLoopDevice->_nextDevice;
break;
}
// Not this one, move to next one
_nextLoopDevice = _nextLoopDevice->_nextDevice;
}
} while (_nextLoopDevice != lastLoopDevice); // Stop looking when we've done all.
// Report loop time if diags enabled
#if defined(DIAG_LOOPTIMES)
static unsigned long lastMicros = 0;
// Measure time since loop() method started.
unsigned long halElapsed = micros() - currentMicros;
// Measure time between loop() method entries.
unsigned long elapsed = currentMicros - lastMicros;
static unsigned long maxElapsed = 0, maxHalElapsed = 0;
static unsigned long lastOutputTime = 0;
static unsigned long halTotal = 0, total = 0;
static unsigned long count = 0;
const unsigned long interval = (unsigned long)5 * 1000 * 1000; // 5 seconds in microsec
// Ignore long loop counts while message is still outputting
if (currentMicros - lastOutputTime > 3000UL) {
if (elapsed > maxElapsed) maxElapsed = elapsed;
if (halElapsed > maxHalElapsed) maxHalElapsed = halElapsed;
halTotal += halElapsed;
total += elapsed;
count++;
}
if (currentMicros - lastOutputTime > interval) {
if (lastOutputTime > 0)
DIAG(F("Loop Total:%lus (%lus max) HAL:%lus (%lus max)"),
total/count, maxElapsed, halTotal/count, maxHalElapsed);
maxElapsed = maxHalElapsed = total = halTotal = count = 0;
lastOutputTime = currentMicros;
}
lastMicros = currentMicros;
#endif
}
// Display a list of all the devices on the diagnostic stream.
void IODevice::DumpAll() {
for (IODevice *dev = _firstDevice; dev != 0; dev = dev->_nextDevice) {
dev->_display();
}
}
// Determine if the specified vpin is allocated to a device.
bool IODevice::exists(VPIN vpin) {
return findDevice(vpin) != NULL;
}
// check whether the pin supports notification. If so, then regular _read calls are not required.
bool IODevice::hasCallback(VPIN vpin) {
IODevice *dev = findDevice(vpin);
if (!dev) return false;
return dev->_hasCallback;
}
// Display (to diagnostics) details of the device.
void IODevice::_display() {
DIAG(F("Unknown device Vpins:%d-%d %S"),
(int)_firstVpin, (int)_firstVpin+_nPins-1, _deviceState==DEVSTATE_FAILED ? F("OFFLINE") : F(""));
}
// Find device associated with nominated Vpin and pass configuration values on to it.
// Return false if not found.
bool IODevice::configure(VPIN vpin, ConfigTypeEnum configType, int paramCount, int params[]) {
IODevice *dev = findDevice(vpin);
if (dev) return dev->_configure(vpin, configType, paramCount, params);
#ifdef DIAG_IO
DIAG(F("IODevice::configure(): Vpin ID %d not found!"), (int)vpin);
#endif
return false;
}
// Read value from virtual pin.
int IODevice::read(VPIN vpin) {
for (IODevice *dev = _firstDevice; dev != 0; dev = dev->_nextDevice) {
if (dev->owns(vpin))
return dev->_read(vpin);
}
#ifdef DIAG_IO
DIAG(F("IODevice::read(): Vpin %d not found!"), (int)vpin);
#endif
return false;
}
// Read analogue value from virtual pin.
int IODevice::readAnalogue(VPIN vpin) {
for (IODevice *dev = _firstDevice; dev != 0; dev = dev->_nextDevice) {
if (dev->owns(vpin))
return dev->_readAnalogue(vpin);
}
#ifdef DIAG_IO
DIAG(F("IODevice::readAnalogue(): Vpin %d not found!"), (int)vpin);
#endif
return false;
}
// Write value to virtual pin(s). If multiple devices are allocated the same pin
// then only the first one found will be used.
void IODevice::write(VPIN vpin, int value) {
IODevice *dev = findDevice(vpin);
if (dev) {
dev->_write(vpin, value);
return;
}
#ifdef DIAG_IO
DIAG(F("IODevice::write(): Vpin ID %d not found!"), (int)vpin);
#endif
}
// Write analogue value to virtual pin(s). If multiple devices are allocated
// the same pin then only the first one found will be used.
//
// The significance of param1 and param2 may vary from device to device.
// For servo controllers, param1 is the profile of the transition and param2
// the duration, i.e. the time that the operation is to be animated over
// in deciseconds (0-3276 sec)
//
void IODevice::writeAnalogue(VPIN vpin, int value, uint8_t param1, uint16_t param2) {
IODevice *dev = findDevice(vpin);
if (dev) {
dev->_writeAnalogue(vpin, value, param1, param2);
return;
}
#ifdef DIAG_IO
DIAG(F("IODevice::writeAnalogue(): Vpin ID %d not found!"), (int)vpin);
#endif
}
// isBusy, when called for a device pin is always a digital output or analogue output,
// returns input feedback state of the pin, i.e. whether the pin is busy performing
// an animation or fade over a period of time.
bool IODevice::isBusy(VPIN vpin) {
IODevice *dev = findDevice(vpin);
if (dev)
return dev->_read(vpin);
else
return false;
}
void IODevice::setGPIOInterruptPin(int16_t pinNumber) {
if (pinNumber >= 0)
pinMode(pinNumber, INPUT_PULLUP);
_gpioInterruptPin = pinNumber;
}
// Private helper function to add a device to the chain of devices.
void IODevice::addDevice(IODevice *newDevice) {
// Link new object to the end of the chain. Thereby, the first devices to be declared/created
// will be located faster by findDevice than those which are created later.
// Ideally declare/create the digital IO pins first, then servos, then more esoteric devices.
IODevice *lastDevice;
if (_firstDevice == 0)
_firstDevice = newDevice;
else {
for (IODevice *dev = _firstDevice; dev != 0; dev = dev->_nextDevice)
lastDevice = dev;
lastDevice->_nextDevice = newDevice;
}
newDevice->_nextDevice = 0;
// If the IODevice::begin() method has already been called, initialise device here. If not,
// the device's _begin() method will be called by IODevice::begin().
if (!_initPhase)
newDevice->_begin();
}
// Private helper function to locate a device by VPIN. Returns NULL if not found.
// This is performance-critical, so minimises the calculation and function calls necessary.
IODevice *IODevice::findDevice(VPIN vpin) {
for (IODevice *dev = _firstDevice; dev != 0; dev = dev->_nextDevice) {
VPIN firstVpin = dev->_firstVpin;
if (vpin >= firstVpin && vpin < firstVpin+dev->_nPins)
return dev;
}
return NULL;
}
//==================================================================================================================
// Static data
//------------------------------------------------------------------------------------------------------------------
// Chain of callback blocks (identifying registered callback functions for state changes)
IONotifyCallback *IONotifyCallback::first = 0;
// Start of chain of devices.
IODevice *IODevice::_firstDevice = 0;
// Reference to next device to be called on _loop() method.
IODevice *IODevice::_nextLoopDevice = 0;
// Flag which is reset when IODevice::begin has been called.
bool IODevice::_initPhase = true;
//==================================================================================================================
// Instance members
//------------------------------------------------------------------------------------------------------------------
// Method to check whether the id corresponds to this device
bool IODevice::owns(VPIN id) {
return (id >= _firstVpin && id < _firstVpin + _nPins);
}
#else // !defined(IO_NO_HAL)
// Minimal implementations of public HAL interface, to support Arduino pin I/O and nothing more.
void IODevice::begin() { DIAG(F("NO HAL CONFIGURED!")); }
bool IODevice::configure(VPIN pin, ConfigTypeEnum, int, int p[]) {
#ifdef DIAG_IO
DIAG(F("Arduino _configurePullup Pin:%d Val:%d"), pin, p[0]);
#endif
if (p[0]) {
pinMode(pin, INPUT_PULLUP);
} else {
pinMode(pin, INPUT);
}
return true;
}
void IODevice::write(VPIN vpin, int value) {
digitalWrite(vpin, value);
pinMode(vpin, OUTPUT);
}
void IODevice::writeAnalogue(VPIN, int, uint8_t, uint16_t) {}
bool IODevice::isBusy(VPIN) { return false; }
bool IODevice::hasCallback(VPIN) { return false; }
int IODevice::read(VPIN vpin) {
return !digitalRead(vpin); // Return inverted state (5v=0, 0v=1)
}
int IODevice::readAnalogue(VPIN vpin) {
pinMode(vpin, INPUT);
noInterrupts();
int value = analogRead(vpin);
interrupts();
return value;
}
void IODevice::loop() {}
void IODevice::DumpAll() {
DIAG(F("NO HAL CONFIGURED!"));
}
bool IODevice::exists(VPIN vpin) { return (vpin > 2 && vpin < NUM_DIGITAL_PINS); }
void IODevice::setGPIOInterruptPin(int16_t) {}
// Chain of callback blocks (identifying registered callback functions for state changes)
// Not used in IO_NO_HAL but must be declared.
IONotifyCallback *IONotifyCallback::first = 0;
#endif // IO_NO_HAL
/////////////////////////////////////////////////////////////////////////////////////////////////////
// Constructor
ArduinoPins::ArduinoPins(VPIN firstVpin, int nPins) {
_firstVpin = firstVpin;
_nPins = nPins;
int arrayLen = (_nPins+7)/8;
_pinPullups = (uint8_t *)calloc(3, arrayLen);
_pinModes = (&_pinPullups[0]) + arrayLen;
_pinInUse = (&_pinPullups[0]) + 2*arrayLen;
for (int i=0; i<arrayLen; i++) {
_pinPullups[i] = 0xff; // default to pullup on, for inputs
_pinModes[i] = 0;
_pinInUse[i] = 0;
}
}
// Device-specific pin configuration. Configure should be called infrequently so simplify
// code by using the standard pinMode function.
bool ArduinoPins::_configure(VPIN vpin, ConfigTypeEnum configType, int paramCount, int params[]) {
if (configType != CONFIGURE_INPUT) return false;
if (paramCount != 1) return false;
bool pullup = params[0];
int pin = vpin;
#ifdef DIAG_IO
DIAG(F("Arduino _configurePullup Pin:%d Val:%d"), pin, pullup);
#endif
uint8_t mask = 1 << ((pin-_firstVpin) % 8);
uint8_t index = (pin-_firstVpin) / 8;
_pinModes[index] &= ~mask; // set to input mode
if (pullup) {
_pinPullups[index] |= mask;
pinMode(pin, INPUT_PULLUP);
} else {
_pinPullups[index] &= ~mask;
pinMode(pin, INPUT);
}
_pinInUse[index] |= mask;
return true;
}
// Device-specific write function.
void ArduinoPins::_write(VPIN vpin, int value) {
int pin = vpin;
#ifdef DIAG_IO
DIAG(F("Arduino Write Pin:%d Val:%d"), pin, value);
#endif
uint8_t mask = 1 << ((pin-_firstVpin) % 8);
uint8_t index = (pin-_firstVpin) / 8;
// First update the output state, then set into write mode if not already.
fastWriteDigital(pin, value);
if (!(_pinModes[index] & mask)) {
// Currently in read mode, change to write mode
_pinModes[index] |= mask;
// Since mode changes should be infrequent, use standard pinMode function
pinMode(pin, OUTPUT);
_pinInUse[index] |= mask;
}
}
// Device-specific read function (digital input).
int ArduinoPins::_read(VPIN vpin) {
int pin = vpin;
uint8_t mask = 1 << ((pin-_firstVpin) % 8);
uint8_t index = (pin-_firstVpin) / 8;
if ((_pinModes[index] | ~_pinInUse[index]) & mask) {
// Currently in write mode or not initialised, change to read mode
_pinModes[index] &= ~mask;
// Since mode changes should be infrequent, use standard pinMode function
if (_pinPullups[index] & mask)
pinMode(pin, INPUT_PULLUP);
else
pinMode(pin, INPUT);
_pinInUse[index] |= mask;
}
int value = !fastReadDigital(pin); // Invert (5v=0, 0v=1)
#ifdef DIAG_IO
//DIAG(F("Arduino Read Pin:%d Value:%d"), pin, value);
#endif
return value;
}
// Device-specific readAnalogue function (analogue input)
int ArduinoPins::_readAnalogue(VPIN vpin) {
int pin = vpin;
uint8_t mask = 1 << ((pin-_firstVpin) % 8);
uint8_t index = (pin-_firstVpin) / 8;
if (_pinModes[index] & mask) {
// Currently in write mode, change to read mode
_pinModes[index] &= ~mask;
// Since mode changes should be infrequent, use standard pinMode function
if (_pinPullups[index] & mask)
pinMode(pin, INPUT_PULLUP);
else
pinMode(pin, INPUT);
}
// Since AnalogRead is also called from interrupt code, disable interrupts
// while we're using it. There's only one ADC shared by all analogue inputs
// on the Arduino, so we don't want interruptions.
//******************************************************************************
// NOTE: If the HAL is running on a computer without the DCC signal generator,
// then interrupts needn't be disabled. Also, the DCC signal generator puts
// the ADC into fast mode, so if it isn't present, analogueRead calls will be much
// slower!!
//******************************************************************************
noInterrupts();
int value = analogRead(pin);
interrupts();
#ifdef DIAG_IO
DIAG(F("Arduino Read Pin:%d Value:%d"), pin, value);
#endif
return value;
}
void ArduinoPins::_display() {
DIAG(F("Arduino Vpins:%d-%d"), (int)_firstVpin, (int)_firstVpin+_nPins-1);
}
/////////////////////////////////////////////////////////////////////////////////////////////////////
void ArduinoPins::fastWriteDigital(uint8_t pin, uint8_t value) {
#if defined(USE_FAST_IO)
if (pin >= NUM_DIGITAL_PINS) return;
uint8_t mask = digitalPinToBitMask(pin);
uint8_t port = digitalPinToPort(pin);
volatile uint8_t *outPortAdr = portOutputRegister(port);
noInterrupts();
if (value)
*outPortAdr |= mask;
else
*outPortAdr &= ~mask;
interrupts();
#else
digitalWrite(pin, value);
#endif
}
bool ArduinoPins::fastReadDigital(uint8_t pin) {
#if defined(USE_FAST_IO)
if (pin >= NUM_DIGITAL_PINS) return false;
uint8_t mask = digitalPinToBitMask(pin);
uint8_t port = digitalPinToPort(pin);
volatile uint8_t *inPortAdr = portInputRegister(port);
// read input
bool result = (*inPortAdr & mask) != 0;
#else
bool result = digitalRead(pin);
#endif
return result;
}