IoT Challenge 1
source/MicroBit.cpp
- Committer:
- Jonathan Austin
- Date:
- 2016-04-07
- Revision:
- 1:af427e419320
- Child:
- 5:8052323b72d2
File content as of revision 1:af427e419320:
/* The MIT License (MIT) Copyright (c) 2016 British Broadcasting Corporation. This software is provided by Lancaster University by arrangement with the BBC. 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. */ #include "MicroBitConfig.h" /* * The underlying Nordic libraries that support BLE do not compile cleanly with the stringent GCC settings we employ * If we're compiling under GCC, then we suppress any warnings generated from this code (but not the rest of the DAL) * The ARM cc compiler is more tolerant. We don't test __GNUC__ here to detect GCC as ARMCC also typically sets this * as a compatability option, but does not support the options used... */ #if !defined(__arm) #pragma GCC diagnostic ignored "-Wunused-function" #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-parameter" #endif #include "MicroBit.h" #include "nrf_soc.h" /* * Return to our predefined compiler settings. */ #if !defined(__arm) #pragma GCC diagnostic pop #endif #if CONFIG_ENABLED(MICROBIT_DBG) // We create and initialize to NULL here, but MicroBitSerial will automatically update this as needed in its constructor. RawSerial* SERIAL_DEBUG = NULL; #endif /** * Constructor. * * Create a representation of a MicroBit device, which includes member variables * that represent various device drivers used to control aspects of the micro:bit. */ MicroBit::MicroBit() : serial(USBTX, USBRX), resetButton(MICROBIT_PIN_BUTTON_RESET), storage(), i2c(I2C_SDA0, I2C_SCL0), messageBus(), display(), buttonA(MICROBIT_PIN_BUTTON_A, MICROBIT_ID_BUTTON_A), buttonB(MICROBIT_PIN_BUTTON_B, MICROBIT_ID_BUTTON_B), buttonAB(MICROBIT_ID_BUTTON_A,MICROBIT_ID_BUTTON_B, MICROBIT_ID_BUTTON_AB), accelerometer(i2c), compass(i2c, accelerometer, storage), compassCalibrator(compass, accelerometer, display), thermometer(storage), io(MICROBIT_ID_IO_P0,MICROBIT_ID_IO_P1,MICROBIT_ID_IO_P2, MICROBIT_ID_IO_P3,MICROBIT_ID_IO_P4,MICROBIT_ID_IO_P5, MICROBIT_ID_IO_P6,MICROBIT_ID_IO_P7,MICROBIT_ID_IO_P8, MICROBIT_ID_IO_P9,MICROBIT_ID_IO_P10,MICROBIT_ID_IO_P11, MICROBIT_ID_IO_P12,MICROBIT_ID_IO_P13,MICROBIT_ID_IO_P14, MICROBIT_ID_IO_P15,MICROBIT_ID_IO_P16,MICROBIT_ID_IO_P19, MICROBIT_ID_IO_P20), bleManager(storage), radio(), ble(NULL) { // Clear our status status = 0; // Bring up soft reset functionality as soon as possible. resetButton.mode(PullUp); resetButton.fall(this, &MicroBit::reset); } /** * Post constructor initialisation method. * * This call will initialised the scheduler, memory allocator and Bluetooth stack. * * This is required as the Bluetooth stack can't be brought up in a * static context i.e. in a constructor. * * @code * uBit.init(); * @endcode * * @note This method must be called before user code utilises any functionality * contained by uBit. */ void MicroBit::init() { if (status & MICROBIT_INITIALIZED) return; #if CONFIG_ENABLED(MICROBIT_HEAP_ALLOCATOR) // Bring up a nested heap allocator. microbit_create_nested_heap(MICROBIT_NESTED_HEAP_SIZE); #endif // Bring up fiber scheduler. scheduler_init(messageBus); // Seed our random number generator seedRandom(); // Create an event handler to trap any handlers being created for I2C services. // We do this to enable initialisation of those services only when they're used, // which saves processor time, memeory and battery life. messageBus.listen(MICROBIT_ID_MESSAGE_BUS_LISTENER, MICROBIT_EVT_ANY, this, &MicroBit::onListenerRegisteredEvent); status |= MICROBIT_INITIALIZED; #if CONFIG_ENABLED(MICROBIT_BLE_PAIRING_MODE) // Test if we need to enter BLE pairing mode... int i=0; sleep(100); while (buttonA.isPressed() && buttonB.isPressed() && i<10) { sleep(100); i++; if (i == 10) { #if CONFIG_ENABLED(MICROBIT_HEAP_ALLOCATOR) && CONFIG_ENABLED(MICROBIT_HEAP_REUSE_SD) microbit_create_heap(MICROBIT_SD_GATT_TABLE_START + MICROBIT_SD_GATT_TABLE_SIZE, MICROBIT_SD_LIMIT); #endif // Start the BLE stack, if it isn't already running. if (!ble) { bleManager.init(getName(), getSerial(), messageBus, true); ble = bleManager.ble; } // Enter pairing mode, using the LED matrix for any necessary pairing operations bleManager.pairingMode(display, buttonA); } } #endif // Attempt to bring up a second heap region, using unused memory normally reserved for Soft Device. #if CONFIG_ENABLED(MICROBIT_HEAP_ALLOCATOR) && CONFIG_ENABLED(MICROBIT_HEAP_REUSE_SD) #if CONFIG_ENABLED(MICROBIT_BLE_ENABLED) microbit_create_heap(MICROBIT_SD_GATT_TABLE_START + MICROBIT_SD_GATT_TABLE_SIZE, MICROBIT_SD_LIMIT); #else microbit_create_heap(MICROBIT_SRAM_BASE, MICROBIT_SD_LIMIT); #endif #endif #if CONFIG_ENABLED(MICROBIT_BLE_ENABLED) // Start the BLE stack, if it isn't already running. if (!ble) { bleManager.init(getName(), getSerial(), messageBus, false); ble = bleManager.ble; } #endif } /** * A listener to perform actions as a result of Message Bus reflection. * * In some cases we want to perform lazy instantiation of components, such as * the compass and the accelerometer, where we only want to add them to the idle * fiber when someone has the intention of using these components. */ void MicroBit::onListenerRegisteredEvent(MicroBitEvent evt) { switch(evt.value) { case MICROBIT_ID_BUTTON_AB: // A user has registered to receive events from the buttonAB multibutton. // Disable click events from being generated by ButtonA and ButtonB, and defer the // control of this to the multibutton handler. // // This way, buttons look independent unless a buttonAB is requested, at which // point button A+B clicks can be correclty handled without breaking // causal ordering. buttonA.setEventConfiguration(MICROBIT_BUTTON_SIMPLE_EVENTS); buttonB.setEventConfiguration(MICROBIT_BUTTON_SIMPLE_EVENTS); buttonAB.setEventConfiguration(MICROBIT_BUTTON_ALL_EVENTS); break; case MICROBIT_ID_COMPASS: // A listener has been registered for the compass. // The compass uses lazy instantiation, we just need to read the data once to start it running. // Touch the compass through the heading() function to ensure it is calibrated. if it isn't this will launch any associated calibration algorithms. compass.heading(); break; case MICROBIT_ID_ACCELEROMETER: // A listener has been registered for the accelerometer. // The accelerometer uses lazy instantiation, we just need to read the data once to start it running. accelerometer.updateSample(); break; case MICROBIT_ID_THERMOMETER: // A listener has been registered for the thermometer. // The thermometer uses lazy instantiation, we just need to read the data once to start it running. thermometer.updateSample(); break; } }