Andriy Makukha
football_project_wo_output
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football_project
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MZJ
main.cpp
- Committer:
- AntonLS
- Date:
- 2016-01-09
- Revision:
- 45:1eb335c00cb2
- Parent:
- 37:8f15b14d6994
- Child:
- 46:28c29ef61276
File content as of revision 45:1eb335c00cb2:
/*
* TA test
*
* Updated for New TA Baseboard (rev Aug-Nov 2015.)
*
* TODO maybe have a mode where the serial port I/O can be swapped,
* such that what the nRF generates is sent out the serial port,
* and what comes in the serial port goes into the nRF.
* Maybe could use the now-unused CTS pin for that.
*
* Using
* rev 327 of BLE_API
* rev 102 of nRF51822 w/ modification--See below
* rev 97 of mbed lib
* corresponding to:
* rev 493 of mbed-src w/ modification to targets/hal/TARGET_NORDIC/TARGET_MCU_NRF51822/serial_api.c
* so things compile properly.*
* * Now using $Sub$$UART0_IRQHandler to override UART0_IRQHandler without needing to use lib source.
*
* *** Now using mbed-src again to modify startup code to use full 32k RAM on QFAC part 20160104 ALS
* while still using RBL BLE Nano as a target:
* Copied files nRF51822.sct and startup_nRF51822.s
* from targets/cmsis/TARGET_NORDIC/TARGET_MCU_NRF51822/TOOLCHAIN_ARM_STD/TARGET_MCU_NORDIC_32K
* to targets/cmsis/TARGET_NORDIC/TARGET_MCU_NRF51822/TOOLCHAIN_ARM_STD/TARGET_MCU_NORDIC_16K
* (Stomping the 16k settings w/ 32k settings.)
*
* Changed
* nRF51822/nordic/pstorage_platform.h PSTORAGE_MIN_BLOCK_SIZE changed from 0x010 to 4.
*/
/* mbed Microcontroller Library
* Copyright (c) 2006-2013 ARM Limited
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <cstdarg>
#include <cstdio>
#include "mbed.h"
// #include "rtos.h"
#include "BLEDevice.h"
#include "DFUService.h"
#include "UARTService.h"
#include "DeviceInformationService.h"
#include "BatteryService.h"
#include "MTSSerialFlowControl.h"
#include "PhoneAppIO.h"
#include "types.h"
#include "TA.h"
#define NEED_CONSOLE_OUTPUT 1 /* Set this if you need debug messages on the console;
* it will have an impact on code-size and power consumption. */
#define LOOPBACK_MODE 0 // Loopback mode
#if NEED_CONSOLE_OUTPUT
#define DEBUG(...) { printf(__VA_ARGS__); }
#else
#define DEBUG(...) /* nothing */
#endif /* #if NEED_CONSOLE_OUTPUT */
void loop();
void setup();
void getRadioInput(char *ibuffer, int size);
#define BLENANO 0 // BLE Nano vs. TA New Baseboard (rev Aug-Nov 2015.)
#if BLENANO
#define SERTX USBTX
#define SERRX USBRX
#else // Same RTS pin used by all (P0_08) and unused CTS (P0_10)
#define SERTX P0_18
#define SERRX P0_17
#endif
static Timer tmr;
unsigned long millis()
{
return tmr.read_ms();
}
unsigned long micros()
{
return tmr.read_us();
}
extern "C"
{
#include "softdevice_handler.h" // Attempt to get pstorage enqueued cmd callbacks.
#include "app_timer.h"
#include "pstorage.h"
// void My_UART0_IRQHandler();
void pin_mode( PinName, PinMode );
}
#if BLENANO
#define ADC_IN_BATT P0_6
#define CHARGING_IN P0_29
#else
#define ADC_IN_BATT P0_4
#define CHARGING_IN P0_2
#endif
AnalogIn batt( ADC_IN_BATT );
// DigitalOut rts( RTS_PIN_NUMBER );
DigitalIn cts( CTS_PIN_NUMBER, PullDown ); // We'll use as a mode switch for serial data source. TODO
// Check if we should swap serial Rx/Tx for early rev of "Little Brain"
DigitalIn trSwp( P0_30, PullUp );
// Wait to settle.
int foo = (wait( 0.1 ), 0);
// Not using "LED" or "LED1" because target NRF51822 for FOTA uses different pins.
static DigitalOut led0( P0_19, 1 ); // TA New Baseboard LED High=On ("STATUS") (OK on Nano: LED Low=On)
static DigitalOut led1( P0_21, 0 ); // TA New Baseboard High=On (OK on Nano: NC)
DigitalOut led2( P0_22, 1 ); // TA New Baseboard High=On (OK on Nano: NC)
// DigitalOut led1( P0_3, 0 ); // TA Baseboard High=On (OK on Nano: Alt RxD)
// DigitalOut led1( (trSwp ? P0_4 : P0_3), 0 ); // TA Baseboard High=On (And don't use P0_4 on Nano)
// DigitalOut buzz( P0_20, 1 ); // TA New Baseboard Low=On (OK on Nano: NC)
int tickTock = 0; // Counter used by periodicCallback().
class ChgChg : public InterruptIn
{
public:
ChgChg( PinName pin, PinMode pull=PullUp ) : InterruptIn( pin )
{
mode( pull ); // Set pull mode
fall( this, &ChgChg::chargeStart ); // Attach ISR for fall
rise( this, &ChgChg::chargeStop ); // Attach ISR for rise
led0 = !read();
}
void chargeStart()
{
led0 = 1;
tickTock = 0; // Trigger batt level update.
}
void chargeStop()
{
led0 = 0;
tickTock = 0; // Trigger batt level update.
}
};
ChgChg notcharge( CHARGING_IN, PullUp );
// App timer, app scheduler, and pstorage are already setup by bootloader.
static BLEDevice ble;
// Note: From the datasheet:
// PSELRXD, PSELRTS, PSELTRTS and PSELTXD must only be configured when the UART is disabled.
// But a version of serial_init() erroneously enabled the uart before the setting of those,
// which messed up flow control. Apparently the setting is ONCE per ON mode. ARGH!
// So we made our own versions of Serial and SerialBase (MySerial and MySerialBase)
// to not use serial_init() in serial_api.c, so flow control is setup correctly *
// MTSSerial now uses our MySerial instead of Serial, and now uses hw flow control by default *
// [* We can't change the uart interrupt vector, so we comment-out the handler in
// serial_api.c, and rebuild the mbed lib for low-level hw flow control to work.] - No need now.
// * Now using $Sub$$UART0_IRQHandler to override UART0_IRQHandler without needing to use lib source.
// NVIC_SetVector( UART0_IRQn, (uint32_t)My_UART0_IRQHandler ); // Might have worked--No need.
//
// MTSSerialFlowControl uses "manual" (non-hardware-low-level) flow control based on its
// internal buffer--Rx servicing usually is fast enough not to need hw flow control, so it's okay.
//
// mts::MTSSerialFlowControl pcfc( (trSwp ? SERRX : SERTX), (trSwp ? SERTX : SERRX), RTS_PIN_NUMBER, CTS_PIN_NUMBER, 384, 2688 );
//mts::MTSSerial pcfc( (trSwp ? SERRX : SERTX), (trSwp ? SERTX : SERRX), 128, 64, RTS_PIN_NUMBER, NC ); // 256, 1280 // 256, 2560
uint8_t txPayload[TXRX_BUF_LEN] = { 0 };
char deviceName[6]; // "TAF00";
Gap::address_t macAddr;
Gap::addr_type_t *pAdType;
static const uint16_t uuid16_list[] = { GattService::UUID_DEVICE_INFORMATION_SERVICE,
GattService::UUID_BATTERY_SERVICE };
static uint8_t batt_and_id[] = { GattService::UUID_BATTERY_SERVICE & 0xff,
GattService::UUID_BATTERY_SERVICE >> 8,
99, // Batt level
'T', 'X' }; // Custom ID trick
UARTService *uartServicePtr;
PhoneAppIO *phoneP;
BatteryService *battServiceP;
// Buffer for holding data from the phone
// to the device
static char phoneToDev[MAX_LEN] = {0};
extern TA ta;
extern void radio_init();
extern void radio_loop();
void setAdvData()
{
ble.accumulateAdvertisingPayload( GapAdvertisingData::BREDR_NOT_SUPPORTED |
GapAdvertisingData::LE_GENERAL_DISCOVERABLE );
ble.setAdvertisingType( GapAdvertisingParams::ADV_CONNECTABLE_UNDIRECTED );
// Get MAC addr so we can create a device name using it.
ble.getAddress( pAdType, macAddr );
#ifdef MASTER
sprintf( deviceName, "T%02X%02X", macAddr[1], macAddr[0] );
#else
sprintf( deviceName, "S%02X%02X", macAddr[1], macAddr[0] );
#endif
ble.accumulateAdvertisingPayload( GapAdvertisingData::COMPLETE_LOCAL_NAME,
(const uint8_t *)deviceName, strlen(deviceName) );
// Moved to scan response packet to give more room in AD packet...
// ble.accumulateAdvertisingPayload( GapAdvertisingData::INCOMPLETE_LIST_128BIT_SERVICE_IDS,
// (const uint8_t *)UARTServiceUUID_reversed, sizeof(UARTServiceUUID_reversed) );
ble.accumulateAdvertisingPayload( GapAdvertisingData::COMPLETE_LIST_16BIT_SERVICE_IDS,
(uint8_t *)uuid16_list, sizeof( uuid16_list ) );
ble.accumulateAdvertisingPayload( GapAdvertisingData::SERVICE_DATA,
(uint8_t *)batt_and_id, sizeof( batt_and_id ) ); // Batt lev + "TX"
ble.accumulateScanResponse( GapAdvertisingData::INCOMPLETE_LIST_128BIT_SERVICE_IDS,
(const uint8_t *)UARTServiceUUID_reversed, sizeof( UARTServiceUUID_reversed ) );
}
void updateBatt( uint8_t pct )
{
static uint8_t prev;
static bool wasCharging;
if( notcharge )
{
if( wasCharging ) ta.beep_off(); // Alarm Clock TMP TODO remove once hardware is fixed.
if( pct > 100 ) pct = 100;
if( wasCharging )
{
pct = 102; // Show 102% at charger unplug.
tickTock = 25; // Cause another normal update in 5 seconds.
} else
{
// Use if we update quite often.
// if( abs( (int)prev -(int)pct ) < 3 ) return; // Don't register change of less than 3%.
}
prev = pct;
wasCharging = false;
} else // Charging
{
// Plugged-in seems to add ~23% to level, so checking for 99% is like 76% unplugged.
// But I had a failure with a smaller gap, so reduced another 8%.
if( pct >= 91 ) ta.beep( 15000 ); // Alarm Clock TMP TODO remove once hardware is fixed.
if( !wasCharging )
pct = 101; // Show 101% at start of charging.
wasCharging = true; // Force show when done charging.
}
batt_and_id[2] = pct;
ble.clearAdvertisingPayload();
setAdvData();
ble.setAdvertisingPayload();
if( NULL != battServiceP ) battServiceP->updateBatteryLevel( pct );
}
#define BAT_TOP 793 // 3250 // 52000
#define BAT_BOT 684 // 2800 // 44800
uint8_t getBattLevel()
{
int battI = (int)(batt * 1000.f);
// Normalize to usable range...
// Note: These levels should also give 0% if powered by programmer.
if( battI > BAT_TOP ) battI = BAT_TOP; // Fully charged reading ~3.85V
if( battI < BAT_BOT ) battI = BAT_BOT; // Device failing reading ~3.32V
battI-= BAT_BOT;
return (uint8_t)(battI*100 / (BAT_TOP-BAT_BOT));
}
// True when connected to a phone
bool connected = false;
void connectionCallback( Gap::Handle_t, Gap::addr_type_t peerAddrType,
const Gap::address_t peerAddr, const Gap::ConnectionParams_t *connParams )
{
connected = true;
// DEBUG( "Connected!\n\r" );
// char dummy;
// writeToPhone( "Hi. Curr stack bot: 0x%08X\r\n", &dummy );
}
void disconnectionCallback( Gap::Handle_t handle, Gap::DisconnectionReason_t reason )
{
connected = false;
updateBatt( getBattLevel() );
// DEBUG( "Disconnected!\n\r" );
// DEBUG( "Restarting the advertising process\n\r" );
// #ifdef MASTER
ble.startAdvertising();
// #endif
ta.post_color(0);
}
bool updateCharacteristic( GattAttribute::Handle_t handle, const uint8_t *data, uint16_t bytesRead )
{
ble_error_t err = ble.updateCharacteristicValue( handle, data, bytesRead );
if( (err == BLE_ERROR_BUFFER_OVERFLOW) ||
(err == BLE_ERROR_PARAM_OUT_OF_RANGE ) )
{
// pcfc.printf( "\r\nBLE %d! ", err );
} else if ( err == BLE_STACK_BUSY )
{
// Common error when pumping data.
}
return (err != BLE_ERROR_NONE);
}
extern "C" void writeToPhone(char *format, ...)
{
va_list arg;
va_start(arg, format );
/**/phoneP->vprintf( format, arg );
/**/// Also write same to serial port... TODO
/**/ // pcfc.vprintf( format, arg );
va_end(arg);
}
/**/ // Byte bits to ASCII - Use until we convert protocol to ASCII-hex.
extern "C" void writeBitsToPhone( uint8_t byte, uint8_t minbits )
{
static char ascbits[9] = { 0 };
int pos = 0;
if( 0 == minbits ) minbits = 1;
uint16_t ibyt = byte & 0xFF;
bool leading0 = true;
for( short b=7; b >= 0; b-- )
{
ibyt<<=1;
if( ibyt & 0x100 )
{
leading0 = false;
ascbits[pos++] = '1';
} else if( !leading0 || (b < minbits) )
{
ascbits[pos++] = '0';
}
}
ascbits[pos] = '\0';
writeToPhone( "%s", ascbits );
}
void onDataWritten( const GattCharacteristicWriteCBParams *params )
{
if( phoneP != NULL )
{
uint16_t bytesRead = phoneP->maybeHandleRead( params ); // Also writes to txPayload
if( 0 != bytesRead )
{
/*
DEBUG( "received %u bytes\n\r", bytesRead );
// Also write to serial port...
// pcfc.printf( "From app: " );
pcfc.write( (char *)txPayload, bytesRead );
// pcfc.printf( "\r\n" );
*/
return;
}
}
}
void onDataSent( unsigned count )
{
}
void toPhoneChk( void )
{
if( phoneP != NULL )
{
/*
char ch;
// Get any data from serial port buffer--Full lines if avail--Last line after >= 20 chars.
for( int cnt=1; 0 != pcfc.atomicRead( ch ); cnt++ )
{
/// For from-serial straight to-phone.
/// if( 0 > phoneP->putchar( ch ) )
/// {
/// pcfc.printf( " * " );
/// break;
/// }
// For from-serial inject-to-dev as-if from phone.
phoneP->injectHandleRead( &ch, 1 );
if( (cnt >= 20) && ('\n' == ch) ) break;
}
*/
// Write to outgoing characteristic if anything is pending.
if( 0 != phoneP->maybeHandleWrite() )
{
// pcfc.printf( "ToPhoneHandler \r\n" );
}
}
}
static uint32_t boot_cnt_data = 0;
static uint16_t data_block = 9*20 +75; // Last block -- Use for app-start count.
static uint16_t data_size = 4;
static uint16_t data_offset = 0; // 12 for 16-byte blocks.
static bool data_loaded = false;
static bool data_cleared = false;
static bool data_stored = false;
static pstorage_handle_t pstorage_id;
static uint32_t pstorage_read_test()
{
uint32_t err_code;
pstorage_handle_t p_block_id;
do
{
err_code = pstorage_block_identifier_get( &pstorage_id, data_block, &p_block_id );
if( NRF_SUCCESS != err_code ) break;
err_code = pstorage_load( (uint8_t *)&boot_cnt_data, &p_block_id, data_size, data_offset );
if( NRF_SUCCESS != err_code ) break;
} while( 0 );
return err_code;
}
static uint32_t pstorage_clear_test()
{
uint32_t err_code;
pstorage_handle_t p_block_id;
do
{
err_code = pstorage_block_identifier_get( &pstorage_id, data_block, &p_block_id );
if( NRF_SUCCESS != err_code ) break;
err_code = pstorage_clear( &p_block_id, PSTORAGE_MIN_BLOCK_SIZE );
if( NRF_SUCCESS != err_code ) break;
} while( 0 );
return err_code;
}
static uint32_t pstorage_write_test()
{
uint32_t err_code;
pstorage_handle_t p_block_id;
do
{
err_code = pstorage_block_identifier_get( &pstorage_id, data_block, &p_block_id );
if( NRF_SUCCESS != err_code ) break;
err_code = pstorage_store( &p_block_id, (uint8_t *)&boot_cnt_data, data_size, data_offset );
} while( 0 );
return err_code;
}
static void pstorage_cb_handler( pstorage_handle_t *handle, uint8_t op_code, uint32_t result, uint8_t *p_data, uint32_t data_len )
{
switch( op_code )
{
case PSTORAGE_LOAD_OP_CODE:
if( NRF_SUCCESS == result )
{
// Load operation successful.
data_loaded = true; // Flag to signal load is done.
} else
{
// Load operation failed.
//pcfc.printf( "\r\nWarn: pstorage load operation error: %x\r\n", result );
}
break;
case PSTORAGE_UPDATE_OP_CODE:
case PSTORAGE_STORE_OP_CODE:
if( NRF_SUCCESS == result )
{
// Store operation successful.
data_stored = true; // Flag to signal store is done.
} else
{
// Store operation failed.
//pcfc.printf( "\r\nWarn: pstorage store operation error: %x\r\n", result );
}
// Source memory can now be reused or freed.
break;
case PSTORAGE_CLEAR_OP_CODE:
if( NRF_SUCCESS == result )
{
// Clear operation successful.
data_cleared = true; // Flag to store to the same data area.
} else
{
// Clear operation failed.
//pcfc.printf( "\r\nWarn: pstorage clear operation error: %x\r\n", result );
}
break;
//default:
//pcfc.printf( "\r\nWarn: pstorage unknown op: %x error: %x\r\n", op_code, result );
}
}
static uint32_t pstorage_setup()
{
pstorage_module_param_t pstorage_param;
// Setup pstorage with 9*20 +76 blocks of 4 bytes each. (or 9*20/4 + 19 for 16 byte blocks)
pstorage_param.block_size = 4; // Recommended to be >= 4 bytes.
pstorage_param.block_count = 9*20 +76; // 9 Sequences x 20 Stations + 76 blocks to fill out to 1k.
pstorage_param.cb = pstorage_cb_handler;
return pstorage_register( &pstorage_param, &pstorage_id );
}
void periodicCallback( void )
{
static int callCnt;
if( (callCnt++ % 5) != 0 ) return;
callCnt = 1;
#if BLENANO
led0 = !led0;
#endif
led1 = !led1;
led2 = !led2;
// rts = !rts;
// Check battery level every 30s.
if( 0 == (tickTock % 30) ) updateBatt( getBattLevel() );
tickTock++;
}
/*
void led_thread( void const *args )
{
while( true )
{
led0 = !led0;
led1 = !led1;
Thread::wait( 1000 );
}
}
*/
int main( void )
{
Ticker ticker;
ticker.attach( periodicCallback, 0.2 /** 0.5 **/ /* 1 */ );
/*
// Thread thread( led_thread );
*/
/////pcfc.baud( 57600 );
/*
DEBUG( "Initialising the nRF51822\n\r" );
*/
ble.init();
ble.onConnection( connectionCallback );
ble.onDisconnection( disconnectionCallback );
ble.onDataWritten( onDataWritten );
ble.onDataSent( onDataSent );
/* setup advertising */
setAdvData();
/////pcfc.printf( "\r\nNano nano! I am \"%s\"\r\n", deviceName );
/*
#if LOOPBACK_MODE
pcfc.printf( "\r\nIn BLE Loopback mode.\r\n" );
#endif
*/
uint32_t p_count;
uint32_t pstorageErr = pstorage_init(); // This needs to be called, even though apparently called in bootloader--Check other stuff.
pstorage_access_status_get( &p_count );
// pcfc.printf( "\r\nInitial pstorage count: %d\r\n", p_count );
if( NRF_SUCCESS != pstorageErr )
{
// pcfc.printf( "\r\nWarn: pstorage init error: %x\r\n", pstorageErr );
/// writeToPhone( "\r\nWarn: pstorage init error: %x\r\n", pstorageErr );
} else
{
pstorageErr = pstorage_setup();
if( NRF_SUCCESS != pstorageErr )
{
// pcfc.printf( "\r\nWarn: pstorage setup error: %x\r\n", pstorageErr );
/// writeToPhone( "\r\nWarn: pstorage setup error: %x\r\n", pstorageErr );
} else
{
pstorageErr = pstorage_read_test();
if( NRF_SUCCESS != pstorageErr )
{
// pcfc.printf( "\r\nWarn: pstorage read attempt error: %x\r\n", pstorageErr );
/// writeToPhone( "\r\nWarn: pstorage read attempt error: %x\r\n", pstorageErr );
} else
{
// In this test setup, we use the load callback to signal start to clear,
// then we use the clear callback to signal start to write.
}
}
}
DeviceInformationService deviceInfo( ble, "TRX", "TrueAgility", "SN0001", "hw-rev1", "fw-rev1" );
BatteryService battService( ble );
battServiceP = &battService;
updateBatt( getBattLevel() );
/* Enable over-the-air firmware updates. Instantiating DFUService introduces a
* control characteristic which can be used to trigger the application to
* handover control to a resident bootloader. */
DFUService dfu( ble );
UARTService uartService( ble );
uartServicePtr = &uartService;
ble.setAdvertisingInterval( Gap::MSEC_TO_ADVERTISEMENT_DURATION_UNITS( 132 ) );
// #ifdef MASTER
ble.startAdvertising();
// #endif
PhoneAppIO *phone = new PhoneAppIO( ble,
uartServicePtr->getRXCharacteristicHandle(),
uartServicePtr->getTXCharacteristicHandle() );
phone->loopbackMode = LOOPBACK_MODE;
phoneP = phone;
setup();
radio_init();
tmr.start();
// Main Loop
while( true ) // for( uint32_t loop=1; ;loop++ )
{
ble.waitForEvent();
/**/ toPhoneChk(); // Write any pending data to phone.
/*
while( 0 <= phone.getchar() ); // Eat input.
// if( !(loop % 50) ) phone.printf( "Post: %d\r\n", tmr.read_ms() );
app_sched_execute(); // Attempt to get pstorage enqueued cmd callbacks.
*/
#ifdef MASTER
/**/int bytes = MIN( MAX_LEN, phoneP->readable() );
getRadioInput( phoneToDev, phoneP->read( phoneToDev, bytes, 1 ) );
#endif
loop();
//radio_loop();
}
}
/**@brief Function for error handling, which is called when an error has occurred.
*
* @warning This handler is an example only and does not fit a final product. You need to analyze
* how your product is supposed to react in case of error.
*
* @param[in] error_code Error code supplied to the handler.
* @param[in] line_num Line number where the handler is called.
* @param[in] p_file_name Pointer to the file name.
*/
void $Sub$$app_error_handler( uint32_t error_code, uint32_t line_num, const uint8_t * p_file_name )
{
// nrf_gpio_pin_set( ASSERT_LED_PIN_NO );
//led1 = 1;
// This call can be used for debug purposes during application development.
// @note CAUTION: Activating this code will write the stack to flash on an error.
// This function should NOT be used in a final product.
// It is intended STRICTLY for development/debugging purposes.
// The flash write will happen EVEN if the radio is active, thus interrupting
// any communication.
// Use with care. Uncomment the line below to use.
// ble_debug_assert_handler(error_code, line_num, p_file_name);
// On assert, the system can only recover with a reset.
NVIC_SystemReset();
}
/* EOF */