pls
Dependencies: BLE_API mbed nRF51822
Fork of zach_thresholding by
main.cpp
- Committer:
- nkosarek
- Date:
- 2017-05-02
- Revision:
- 15:d117591084ff
- Parent:
- 14:700ba072d1a0
- Child:
- 16:799397f0d3a8
File content as of revision 15:d117591084ff:
/* Copyright (c) 2012-2014 RedBearLab 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 "mbed.h" #include "ble/BLE.h" #include "wire.h" #include "ButtonService.h" #define BLE_Nano //#define nRF_51822 #define LIS331HH #ifdef nRF_51822 #define SCL 28 #define SDA 29 #endif #ifdef BLE_Nano #define SCL P0_8 #define SDA P0_10 #endif #ifdef LIS3DH #define ADDR_ONE 0x30 #define ADDR_TWO 0x32 #define AXIS_X 0x00 #define AXIS_Y 0x01 #define AXIS_Z 0x02 #define REG_OUT_X_L 0x28 #define REG_CTRL1 0x20 #define REG_CTRL4 0x23 #define REG_WHOAMI 0x0F #define RANGE_2G 0x00 #define DEVICE_ID 0x33 #define DATARATE_400HZ 0b0111 // 400Hz #define DATARATE_200HZ 0b0110 // 200Hz #define DATARATE_100HZ 0b0101 // 100Hz #define DATARATE_50HZ 0b0100 // 50Hz #define DATARATE_25HZ 0b0011 // 25Hz #define DATARATE_10HZ 0b0010 // 10Hz #define DATARATE_1HZ 0b0001 // 1Hz #define DATARATE_POWERDOWN 0 // Power down #define DATARATE_LOWPOWER_1K6HZ 0b1000 // Low power mode (1.6KHz) #define DATARATE_LOWPOWER_5KHZ 0b1001 // Low power mode (5KHz) / Normal power mode (1.25KHz) #endif #ifdef LIS331HH #define ADDR_ONE 0x30 #define ADDR_TWO 0x32 #define AXIS_X 0x00 #define AXIS_Y 0x01 #define AXIS_Z 0x02 #define REG_OUT_X_L 0x28 #define REG_CTRL1 0x20 #define REG_CTRL4 0x23 #define REG_WHOAMI 0x0F #define RANGE_2G 0x00 #define DEVICE_ID 0x33 #define DATARATE_1KHZ 0b11 // 1000Hz #define DATARATE_400HZ 0b10 // 400Hz #define DATARATE_100HZ 0b01 // 100Hz #define DATARATE_50HZ 0b00 // 50Hz #define DATARATE_POWERDOWN 0 // Power down #define DATARATE_NORMAL_MODE 0b001 #define DATARATE_LOWPOWER_0.5HZ 0b010 #define DATARATE_LOWPOWER_1HZ 0b011 #define DATARATE_LOWPOWER_2HZ 0b100 #define DATARATE_LOWPOWER_5HZ 0b101 #define DATARATE_LOWPOWER_10HZ 0b110 #endif #define PACKET_SIZE 20 #define QUEUE_SIZE 20 const static char DEVICE_NAME[] = "LUMBERJACK_NANO"; static const uint16_t uuid16_list[] = {ButtonService::BUTTON_SERVICE_UUID}; struct packetQueue { uint16_t size; uint16_t nextPacketToSend; uint16_t nextSampleToSave; uint16_t liveSamples; uint8_t packets[QUEUE_SIZE][PACKET_SIZE]; }; packetQueue pq; void addToQueue(uint8_t* packet) { for (int i = 0; i < PACKET_SIZE; i++) { pq.packets[pq.nextSampleToSave][i] = packet[i]; } if (pq.nextPacketToSend == pq.nextSampleToSave && pq.liveSamples > 0) { pq.nextSampleToSave = (pq.nextSampleToSave + 1) % QUEUE_SIZE; pq.nextPacketToSend = (pq.nextPacketToSend + 1) % QUEUE_SIZE; } else { pq.liveSamples += 1; pq.nextSampleToSave = (pq.nextSampleToSave + 1) % QUEUE_SIZE; } return; } uint8_t* removeFromQueue() { if (pq.nextSampleToSave != pq.nextPacketToSend && pq.liveSamples > 0) { pq.liveSamples -= 1; uint8_t* old = pq.packets[pq.nextPacketToSend]; pq.nextPacketToSend = (pq.nextPacketToSend + 1) % QUEUE_SIZE; return old; } else { return NULL; } } //Serial pc(USBTX, USBRX); TwoWire Wire = TwoWire(NRF_TWI0); static ButtonService *buttonServicePtr; bool isThereAConnection = false; void sleep(unsigned int mseconds) { clock_t goal = mseconds + clock(); while (goal > clock()); } void disconnectionCallback(const Gap::DisconnectionCallbackParams_t *params) { BLE::Instance().gap().startAdvertising(); isThereAConnection = false; } void connectionCallback(const Gap::ConnectionCallbackParams_t *params) { //pc.printf("Connection recieved!\r\n"); isThereAConnection = true; } /** * This function is called when the ble initialization process has failled */ void onBleInitError(BLE &ble, ble_error_t error) { /* Initialization error handling should go here */ } /** * Callback triggered when the ble initialization process has finished */ void bleInitComplete(BLE::InitializationCompleteCallbackContext *params) { BLE& ble = params->ble; ble_error_t error = params->error; if (error != BLE_ERROR_NONE) { /* In case of error, forward the error handling to onBleInitError */ onBleInitError(ble, error); return; } /* Ensure that it is the default instance of BLE */ if(ble.getInstanceID() != BLE::DEFAULT_INSTANCE) { return; } ble.gap().onDisconnection(disconnectionCallback); ble.gap().onConnection(connectionCallback); /* Setup primary service */ uint8_t initial_value[20] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; buttonServicePtr = new ButtonService(ble, initial_value); /* setup advertising */ ble.gap().accumulateAdvertisingPayload(GapAdvertisingData::BREDR_NOT_SUPPORTED | GapAdvertisingData::LE_GENERAL_DISCOVERABLE); ble.gap().accumulateAdvertisingPayload(GapAdvertisingData::COMPLETE_LIST_16BIT_SERVICE_IDS, (uint8_t *)uuid16_list, sizeof(uuid16_list)); ble.gap().accumulateAdvertisingPayload(GapAdvertisingData::COMPLETE_LOCAL_NAME, (uint8_t *)DEVICE_NAME, sizeof(DEVICE_NAME)); ble.gap().setAdvertisingType(GapAdvertisingParams::ADV_CONNECTABLE_UNDIRECTED); ble.gap().setAdvertisingInterval(1000); /* 1000ms. */ //pc.printf("start advertising now \r\n"); ble.gap().startAdvertising(); } void AT24C512_WriteBytes(uint16_t addr, uint8_t *pbuf, uint16_t length, uint16_t i2cAddr) { Wire.beginTransmission(i2cAddr); int err = Wire.write( (uint8_t)addr ); Wire.write(pbuf, length); if (err != 0) { //pc.printf("error on write write! %d\r\n", err); } uint8_t err8 = Wire.endTransmission(); if (err8 != 0) { //pc.printf("error on write end transmission! %d\r\n", err8); } } void AT24C512_ReadBytes(uint16_t addr, uint8_t *pbuf, uint16_t length, uint16_t i2cAddr) { Wire.beginTransmission(i2cAddr); int err= Wire.write( (uint8_t)addr ); if (err != 0) { //pc.printf("error on read write! %d\r\n", err); } uint8_t err8 = Wire.endTransmission(); if (err8 != 0) { //pc.printf("error on read end transmission! %d\r\n", err8); } err8 = Wire.requestFrom(i2cAddr+1, length); if (err != 0) { //pc.printf("error on read request from! %d\r\n", err8); } while( Wire.available() > 0 ) { *pbuf = Wire.read(); pbuf++; } } //Set the bit at index 'bit' to 'value' on 'input' and return uint8_t setBit(uint8_t input, uint8_t bit, uint8_t value) { uint8_t mask = 1 << bit; input &= ~mask; if (value == 1) { input |= mask; } return input; } uint16_t getAxis(uint16_t axis, uint16_t i2cAddr) { uint8_t base = REG_OUT_X_L + (2 * axis); uint8_t* low = new uint8_t[1]; uint8_t* high = new uint8_t[1]; AT24C512_ReadBytes(base, low, 1, i2cAddr); AT24C512_ReadBytes(base + 1, high, 1, i2cAddr); uint16_t res = low[0] | (high[0] << 8); delete[] low; delete[] high; return res; } void setRange(uint8_t range, uint16_t i2cAddr) { uint8_t* val = new uint8_t[1]; AT24C512_ReadBytes(REG_CTRL4, val, 1, i2cAddr);//get value from the register val[0] &= ~(0b110000); //zero out lowest 2 bits of top 4 bits val[0] |= (range << 4); // write in our new range //pc.printf("REG_CTRL4 after setRange: 0x%x\r\n", *val); AT24C512_WriteBytes(REG_CTRL4, val, 1, i2cAddr); delete[] val; } //Set whether we want to use high resolution or not void setHighResolution(bool highRes, uint16_t i2cAddr) { uint8_t* val = new uint8_t[1]; AT24C512_ReadBytes(REG_CTRL4, val, 1, i2cAddr);//get value from the register uint8_t final; if (highRes) { final = setBit(val[0], 3, 1); } else { final = setBit(val[0], 3, 0); } val[0] = final; //pc.printf("REG_CTRL4 after setHiRes: 0x%x\r\n", *val); AT24C512_WriteBytes(REG_CTRL4, val, 1, i2cAddr); delete[] val; } void setAxisStatus(uint8_t axis, bool enable, uint16_t i2cAddr) { uint8_t* current = new uint8_t[1]; AT24C512_ReadBytes(REG_CTRL1, current, 1, i2cAddr);//get value from the register uint8_t final; if (enable == 1) { final = setBit(current[0], axis, 1); } else { final = setBit(current[0], axis, 0); } current[0] = final; AT24C512_WriteBytes(REG_CTRL1, current, 1, i2cAddr); AT24C512_ReadBytes(REG_CTRL1, current, 1, i2cAddr); //pc.printf("REG_CTRL1 after setAxisStatus: 0x%x\r\n", *current); delete[] current; } void setDataRate(uint8_t dataRate, uint16_t i2cAddr) { uint8_t* val = new uint8_t[1]; AT24C512_ReadBytes(REG_CTRL1, val, 1, i2cAddr); //pc.printf("REG_CTRL1 before data rate set: 0x%x\r\n", *val); val[0] &= 0b11100111; //d val[0] |= (dataRate << 3); AT24C512_WriteBytes(REG_CTRL1, val, 1, i2cAddr); AT24C512_ReadBytes(REG_CTRL1, val, 1, i2cAddr); //pc.printf("REG_CTRL1 after data rate set: 0x%x\r\n", *val); delete[] val; } void setPowerMode(uint8_t powerMode, uint16_t i2cAddr) { uint8_t* val = new uint8_t[1]; AT24C512_ReadBytes(REG_CTRL1, val, 1, i2cAddr); val[0] &= 0b11111; val[0] |= (powerMode << 5); //pc.printf("writing this to REG_CTRL1: 0x%x\r\n", *val); AT24C512_WriteBytes(REG_CTRL1, val, 1, i2cAddr); AT24C512_ReadBytes(REG_CTRL1, val, 1, i2cAddr); //pc.printf("REG_CTRL1 after power mode set: 0x%x\r\n", *val); delete[] val; } void setBDU(bool bdu, uint16_t i2cAddr) { uint8_t* val = new uint8_t[1]; AT24C512_ReadBytes(REG_CTRL4, val, 1, i2cAddr);//get value from the register //pc.printf("REG_CTRL4: 0x%x\r\n", *val); uint8_t final; if (bdu) { final = setBit(val[0], 7, 1); } else { final = setBit(val[0], 7, 0); } val[0] = final; //pc.printf("REG_CTRL4 after setBDU: 0x%x\r\n", *val); AT24C512_WriteBytes(REG_CTRL4, val, 1, i2cAddr); delete[] val; } uint16_t getX(uint16_t i2cAddr) { return getAxis(AXIS_X, i2cAddr); } uint16_t getY(uint16_t i2cAddr) { return getAxis(AXIS_Y, i2cAddr); } uint16_t getZ(uint16_t i2cAddr) { return getAxis(AXIS_Z, i2cAddr); } int main(void) { //pc.baud(9600); wait(5); //Wire.begin(); Wire.begin(SCL, SDA, TWI_FREQUENCY_100K); //pc.printf("\r\n\r\n\r\nStarting...\r\n"); wait(5); setAxisStatus(AXIS_X, true, ADDR_ONE); setAxisStatus(AXIS_Y, true, ADDR_ONE); setAxisStatus(AXIS_Z, true, ADDR_ONE); setDataRate(DATARATE_400HZ, ADDR_ONE); setPowerMode(DATARATE_NORMAL_MODE, ADDR_ONE); //setHighResolution(true, ADDR_ONE); setBDU(true, ADDR_ONE); //setRange(RANGE_2G, ADDR_ONE); setAxisStatus(AXIS_X, true, ADDR_TWO); setAxisStatus(AXIS_Y, true, ADDR_TWO); setAxisStatus(AXIS_Z, true, ADDR_TWO); setDataRate(DATARATE_400HZ, ADDR_TWO); setPowerMode(DATARATE_NORMAL_MODE, ADDR_TWO); //setHighResolution(true, ADDR_TWO); setBDU(true, ADDR_TWO); //setRange(RANGE_2G, ADDR_TWO); uint8_t* val = new uint8_t[1]; *val = 0x80; AT24C512_WriteBytes(REG_CTRL4, val, 1, ADDR_ONE); AT24C512_WriteBytes(REG_CTRL4, val, 1, ADDR_TWO); AT24C512_ReadBytes(REG_CTRL4, val, 1, ADDR_ONE); //pc.printf("REG_CTRL4, should be 0x80: 0x%x\r\n", *val); uint8_t* whoami = new uint8_t[1]; AT24C512_ReadBytes(REG_WHOAMI, whoami, 1, ADDR_ONE); //pc.printf("REG_WHOAMI should be 0x32: 0x%x\r\n", *whoami); AT24C512_ReadBytes(REG_WHOAMI, whoami, 1, ADDR_TWO); //pc.printf("REG_WHOAMI should be 0x32: 0x%x\r\n", *whoami); AT24C512_ReadBytes(0x1F, whoami, 1, ADDR_ONE); BLE &ble = BLE::Instance(); ble.init(bleInitComplete); //pc.printf("entering spin loop\r\n"); /* SpinWait for initialization to complete. This is necessary because the * BLE object is used in the main loop below. */ while (ble.hasInitialized() == false) { /* spin loop */ } //pc.printf("leaving spin loop\r\n"); pq.size = QUEUE_SIZE; pq.nextPacketToSend = 0; pq.nextSampleToSave = 0; pq.liveSamples = 0; while(1) { //pc.printf("Read data from AT24C512\r\n"); uint16_t x1 = getX(ADDR_ONE); uint16_t y1 = getY(ADDR_ONE); uint16_t z1 = getZ(ADDR_ONE); uint16_t x2 = getX(ADDR_TWO); uint16_t y2 = getY(ADDR_TWO); uint16_t z2 = getZ(ADDR_TWO); //pc.printf("Accel one: x %d y %d z %d\r\n", (int16_t)x1, (int16_t)y1, (int16_t)z1); //pc.printf("Accel two: x %d y %d z %d\r\n", (int16_t)x2, (int16_t)y2, (int16_t)z2); //pc.printf("\r\n"); if(isThereAConnection) { //pc.printf("sending Notification\r\n"); uint8_t values[20] = {(uint8_t)x1, (uint8_t)(x1 >> 8), (uint8_t)y1, (uint8_t)(y1 >> 8), (uint8_t)z1, (uint8_t)(z1 >> 8), (uint8_t)x2, (uint8_t)(x2 >> 8), (uint8_t)y2, (uint8_t)(y2 >> 8), (uint8_t)z2, (uint8_t)(z2 >> 8), 0, 0, 0, 0, 0, 0, 0, 0}; buttonServicePtr->updateButtonState(values); } wait(1); } }