qpcpp/examples/arm-cortex/vanilla/gnu/dpp-lpcxpresso-1114/bsp.cpp

//////////////////////////////////////////////////////////////////////////////
// Product: DPP example, LPCXpresso-1114 board, Vanilla kernel
// Last Updated for Version: 4.3.00
// Date of the Last Update:  Nov 03, 2011
//
//                    Q u a n t u m     L e a P s
//                    ---------------------------
//                    innovating embedded systems
//
// Copyright (C) 2002-2011 Quantum Leaps, LLC. All rights reserved.
//
// This software may be distributed and modified under the terms of the GNU
// General Public License version 2 (GPL) as published by the Free Software
// Foundation and appearing in the file GPL.TXT included in the packaging of
// this file. Please note that GPL Section 2[b] requires that all works based
// on this software must also be made publicly available under the terms of
// the GPL ("Copyleft").
//
// Alternatively, this software may be distributed and modified under the
// terms of Quantum Leaps commercial licenses, which expressly supersede
// the GPL and are specifically designed for licensees interested in
// retaining the proprietary status of their code.
//
// Contact information:
// Quantum Leaps Web site:  http://www.quantum-leaps.com
// e-mail:                  info@quantum-leaps.com
//////////////////////////////////////////////////////////////////////////////
#include "qp_port.h"
#include "dpp.h"
#include "bsp.h"

Q_DEFINE_THIS_FILE

extern "C" {
    #include "LPC11xx.h"                                // LPC11xx definitions
    #include "timer16.h"
    #include "clkconfig.h"
    #include "gpio.h"
}

#define LED_PORT    0
#define LED_BIT     7
#define LED_ON      1
#define LED_OFF     0

enum ISR_Priorities {   /* ISR priorities starting from the highest urgency */
    SYSTICK_PRIO,
    // ...
};

static uint32_t l_delay = 0UL;    // limit for the loop counter in busyDelay()

#ifdef Q_SPY

    extern "C" {
        #include "uart.h"
    }

    QSTimeCtr QS_tickTime_;
    QSTimeCtr QS_tickPeriod_;
    static uint8_t l_SysTick_Handler;

    #define QS_BUF_SIZE   (2*1024)
    #define QS_BAUD_RATE  115200

    enum AppRecords {                    // application-specific trace records
        PHILO_STAT = QS_USER
    };
#endif

//............................................................................
extern "C" void SysTick_Handler(void) __attribute__((__interrupt__));
extern "C" void SysTick_Handler(void) {
#ifdef Q_SPY
    uint32_t dummy = SysTick->CTRL;           // clear NVIC_ST_CTRL_COUNT flag
    QS_tickTime_ += QS_tickPeriod_;          // account for the clock rollover
#endif

    QF::TICK(&l_SysTick_Handler);             // process all armed time events
}

//............................................................................
void BSP_init(void) {
    SystemInit();                            // initialize the clocking system

    GPIOInit();                             // initialize GPIO (sets up clock)
    GPIOSetDir(LED_PORT, LED_BIT, 1);            // set port for LED to output

    if (QS_INIT((void *)0) == 0) {       // initialize the QS software tracing
        Q_ERROR();
    }

    QS_OBJ_DICTIONARY(&l_SysTick_Handler);
}
//............................................................................
void QF::onStartup(void) {
    // Set up and enable the SysTick timer. It will be used as a reference
    // for delay loops in the interrupt handlers. The SysTick timer period
    // will be set up for BSP_TICKS_PER_SEC.
    //
    SysTick_Config(SystemCoreClock / BSP_TICKS_PER_SEC);

                          // set priorities of all interrupts in the system...
    NVIC_SetPriority(SysTick_IRQn, SYSTICK_PRIO);
}
//............................................................................
void QF::onCleanup(void) {
}
//............................................................................
void QF::onIdle(void) {          // entered with interrupts LOCKED, see NOTE01

    // toggle the User LED on and then off, see NOTE02
    //GPIOSetValue(LED_PORT, LED_BIT, LED_ON);                        // LED on
    //GPIOSetValue(LED_PORT, LED_BIT, LED_OFF);                      // LED off

#ifdef Q_SPY
    QF_INT_ENABLE();
    if ((LPC_UART->LSR & LSR_THRE) != 0) {                    // is THR empty?

        QF_INT_DISABLE();
        uint16_t b = QS::getByte();
        QF_INT_ENABLE();

        if (b != QS_EOD) {                                 // not End-Of-Data?
           LPC_UART->THR = (b & 0xFF);            // put into the THR register
        }
    }

#elif defined NDEBUG
    // put the CPU and peripherals to the low-power mode
    __WFI();                   // stop clocking the CPU and wait for interrupt
    QF_INT_ENABLE();
#else
    QF_INT_ENABLE();
#endif
}
//............................................................................
// error routine that is called if the STM32 library encounters an error
extern "C" void assert_failed(char const *file, int line) {
    Q_onAssert(file, line);
}
//............................................................................
extern "C" void Q_onAssert(char const * const file, int line) {
    (void)file;                                      // avoid compiler warning
    (void)line;                                      // avoid compiler warning
    QF_INT_DISABLE();            // make sure that all interrupts are disabled
    for (;;) {          // NOTE: replace the loop with reset for final version
    }
}
//............................................................................
void BSP_displyPhilStat(uint8_t n, char const *stat) {
    if (stat[0] == 'e') {
        GPIOSetValue(LED_PORT, LED_BIT, LED_ON);                 /* LED on  */
    }
    else {
        GPIOSetValue(LED_PORT, LED_BIT, LED_OFF);                /* LED off */
    }

    QS_BEGIN(PHILO_STAT, AO_Philo[n])     // application-specific record begin
        QS_U8(1, n);                                     // Philosopher number
        QS_STR(stat);                                    // Philosopher status
    QS_END()
}
//............................................................................
void BSP_busyDelay(void) {
    uint32_t volatile i = l_delay;
    while (i-- > 0UL) {                                      // busy-wait loop
    }
}

//----------------------------------------------------------------------------
#ifdef Q_SPY
//............................................................................
uint8_t QS::onStartup(void const *arg) {
    static uint8_t qsBuf[QS_BUF_SIZE];               // buffer for Quantum Spy
    initBuf(qsBuf, sizeof(qsBuf));

    UARTInit(QS_BAUD_RATE);  // initialize the UART with the desired baud rate
    NVIC_DisableIRQ(UART_IRQn); // do not use the interrupts (QS uses polling)
    LPC_UART->IER = 0;

    QS_tickPeriod_ = (QSTimeCtr)(SystemCoreClock / BSP_TICKS_PER_SEC);
    QS_tickTime_ = QS_tickPeriod_;           // to start the timestamp at zero

                                                 /* setup the QS filters... */
    QS_FILTER_ON(QS_ALL_RECORDS);

//    QS_FILTER_OFF(QS_QEP_STATE_EMPTY);
//    QS_FILTER_OFF(QS_QEP_STATE_ENTRY);
//    QS_FILTER_OFF(QS_QEP_STATE_EXIT);
//    QS_FILTER_OFF(QS_QEP_STATE_INIT);
//    QS_FILTER_OFF(QS_QEP_INIT_TRAN);
//    QS_FILTER_OFF(QS_QEP_INTERN_TRAN);
//    QS_FILTER_OFF(QS_QEP_TRAN);
//    QS_FILTER_OFF(QS_QEP_IGNORED);

    QS_FILTER_OFF(QS_QF_ACTIVE_ADD);
    QS_FILTER_OFF(QS_QF_ACTIVE_REMOVE);
    QS_FILTER_OFF(QS_QF_ACTIVE_SUBSCRIBE);
    QS_FILTER_OFF(QS_QF_ACTIVE_UNSUBSCRIBE);
    QS_FILTER_OFF(QS_QF_ACTIVE_POST_FIFO);
    QS_FILTER_OFF(QS_QF_ACTIVE_POST_LIFO);
    QS_FILTER_OFF(QS_QF_ACTIVE_GET);
    QS_FILTER_OFF(QS_QF_ACTIVE_GET_LAST);
    QS_FILTER_OFF(QS_QF_EQUEUE_INIT);
    QS_FILTER_OFF(QS_QF_EQUEUE_POST_FIFO);
    QS_FILTER_OFF(QS_QF_EQUEUE_POST_LIFO);
    QS_FILTER_OFF(QS_QF_EQUEUE_GET);
    QS_FILTER_OFF(QS_QF_EQUEUE_GET_LAST);
    QS_FILTER_OFF(QS_QF_MPOOL_INIT);
    QS_FILTER_OFF(QS_QF_MPOOL_GET);
    QS_FILTER_OFF(QS_QF_MPOOL_PUT);
    QS_FILTER_OFF(QS_QF_PUBLISH);
    QS_FILTER_OFF(QS_QF_NEW);
    QS_FILTER_OFF(QS_QF_GC_ATTEMPT);
    QS_FILTER_OFF(QS_QF_GC);
//    QS_FILTER_OFF(QS_QF_TICK);
    QS_FILTER_OFF(QS_QF_TIMEEVT_ARM);
    QS_FILTER_OFF(QS_QF_TIMEEVT_AUTO_DISARM);
    QS_FILTER_OFF(QS_QF_TIMEEVT_DISARM_ATTEMPT);
    QS_FILTER_OFF(QS_QF_TIMEEVT_DISARM);
    QS_FILTER_OFF(QS_QF_TIMEEVT_REARM);
    QS_FILTER_OFF(QS_QF_TIMEEVT_POST);
    QS_FILTER_OFF(QS_QF_CRIT_ENTRY);
    QS_FILTER_OFF(QS_QF_CRIT_EXIT);
    QS_FILTER_OFF(QS_QF_ISR_ENTRY);
    QS_FILTER_OFF(QS_QF_ISR_EXIT);

//    QS_FILTER_OFF(QS_QK_MUTEX_LOCK);
//    QS_FILTER_OFF(QS_QK_MUTEX_UNLOCK);
    QS_FILTER_OFF(QS_QK_SCHEDULE);

    return (uint8_t)1;                                       // return success
}
//............................................................................
void QS::onCleanup(void) {
}
//............................................................................
QSTimeCtr QS::onGetTime(void) {              // invoked with interrupts locked
    if ((SysTick->CTRL & 0x00010000) == 0) {                  // COUNT no set?
        return QS_tickTime_ - (QSTimeCtr)SysTick->VAL;
    }
    else {        // the rollover occured, but the SysTick_ISR did not run yet
        return QS_tickTime_ + QS_tickPeriod_ - (QSTimeCtr)SysTick->VAL;
    }
}
//............................................................................
void QS::onFlush(void) {
    uint16_t b;
    while ((b = getByte()) != QS_EOD) {            // while not End-Of-Data...
        while ((LPC_UART->LSR & LSR_THRE) == 0) {       // while TXE not empty
        }
        LPC_UART->THR = (b & 0xFF);               // put into the THR register
    }
}
#endif                                                                // Q_SPY
//----------------------------------------------------------------------------

//////////////////////////////////////////////////////////////////////////////
// NOTE01:
// The QF::onIdle() callback is called with interrupts locked, because the
// determination of the idle condition might change by any interrupt posting
// an event. QF::onIdle() must internally unlock interrupts, ideally
// atomically with putting the CPU to the power-saving mode.
//
// NOTE02:
// The blue LED is used to visualize the idle loop activity. The brightness
// of the LED is proportional to the frequency of invcations of the idle loop.
// Please note that the LED is toggled with interrupts locked, so no interrupt
// execution time contributes to the brightness of the User LED.
//
4.5.01 2012-08-14 18:00:48 -04:00			`//////////////////////////////////////////////////////////////////////////////`
			`// Product: DPP example, LPCXpresso-1114 board, Vanilla kernel`
			`// Last Updated for Version: 4.3.00`
			`// Date of the Last Update: Nov 03, 2011`
			`//`
			`// Q u a n t u m L e a P s`
			`// ---------------------------`
			`// innovating embedded systems`
			`//`
			`// Copyright (C) 2002-2011 Quantum Leaps, LLC. All rights reserved.`
			`//`
			`// This software may be distributed and modified under the terms of the GNU`
			`// General Public License version 2 (GPL) as published by the Free Software`
			`// Foundation and appearing in the file GPL.TXT included in the packaging of`
			`// this file. Please note that GPL Section 2[b] requires that all works based`
			`// on this software must also be made publicly available under the terms of`
			`// the GPL ("Copyleft").`
			`//`
			`// Alternatively, this software may be distributed and modified under the`
			`// terms of Quantum Leaps commercial licenses, which expressly supersede`
			`// the GPL and are specifically designed for licensees interested in`
			`// retaining the proprietary status of their code.`
			`//`
			`// Contact information:`
			`// Quantum Leaps Web site: http://www.quantum-leaps.com`
			`// e-mail: info@quantum-leaps.com`
			`//////////////////////////////////////////////////////////////////////////////`
			`#include "qp_port.h"`
			`#include "dpp.h"`
			`#include "bsp.h"`

			`Q_DEFINE_THIS_FILE`

			`extern "C" {`
			`#include "LPC11xx.h" // LPC11xx definitions`
			`#include "timer16.h"`
			`#include "clkconfig.h"`
			`#include "gpio.h"`
			`}`

			`#define LED_PORT 0`
			`#define LED_BIT 7`
			`#define LED_ON 1`
			`#define LED_OFF 0`

			`enum ISR_Priorities { /* ISR priorities starting from the highest urgency */`
			`SYSTICK_PRIO,`
			`// ...`
			`};`

			`static uint32_t l_delay = 0UL; // limit for the loop counter in busyDelay()`

			`#ifdef Q_SPY`

			`extern "C" {`
			`#include "uart.h"`
			`}`

			`QSTimeCtr QS_tickTime_;`
			`QSTimeCtr QS_tickPeriod_;`
			`static uint8_t l_SysTick_Handler;`

			`#define QS_BUF_SIZE (2*1024)`
			`#define QS_BAUD_RATE 115200`

			`enum AppRecords { // application-specific trace records`
			`PHILO_STAT = QS_USER`
			`};`
			`#endif`

			`//............................................................................`
			`extern "C" void SysTick_Handler(void) __attribute__((__interrupt__));`
			`extern "C" void SysTick_Handler(void) {`
			`#ifdef Q_SPY`
			`uint32_t dummy = SysTick->CTRL; // clear NVIC_ST_CTRL_COUNT flag`
			`QS_tickTime_ += QS_tickPeriod_; // account for the clock rollover`
			`#endif`

			`QF::TICK(&l_SysTick_Handler); // process all armed time events`
			`}`

			`//............................................................................`
			`void BSP_init(void) {`
			`SystemInit(); // initialize the clocking system`

			`GPIOInit(); // initialize GPIO (sets up clock)`
			`GPIOSetDir(LED_PORT, LED_BIT, 1); // set port for LED to output`

			`if (QS_INIT((void *)0) == 0) { // initialize the QS software tracing`
			`Q_ERROR();`
			`}`

			`QS_OBJ_DICTIONARY(&l_SysTick_Handler);`
			`}`
			`//............................................................................`
			`void QF::onStartup(void) {`
			`// Set up and enable the SysTick timer. It will be used as a reference`
			`// for delay loops in the interrupt handlers. The SysTick timer period`
			`// will be set up for BSP_TICKS_PER_SEC.`
			`//`
			`SysTick_Config(SystemCoreClock / BSP_TICKS_PER_SEC);`

			`// set priorities of all interrupts in the system...`
			`NVIC_SetPriority(SysTick_IRQn, SYSTICK_PRIO);`
			`}`
			`//............................................................................`
			`void QF::onCleanup(void) {`
			`}`
			`//............................................................................`
			`void QF::onIdle(void) { // entered with interrupts LOCKED, see NOTE01`

			`// toggle the User LED on and then off, see NOTE02`
			`//GPIOSetValue(LED_PORT, LED_BIT, LED_ON); // LED on`
			`//GPIOSetValue(LED_PORT, LED_BIT, LED_OFF); // LED off`

			`#ifdef Q_SPY`
			`QF_INT_ENABLE();`
			`if ((LPC_UART->LSR & LSR_THRE) != 0) { // is THR empty?`

			`QF_INT_DISABLE();`
			`uint16_t b = QS::getByte();`
			`QF_INT_ENABLE();`

			`if (b != QS_EOD) { // not End-Of-Data?`
			`LPC_UART->THR = (b & 0xFF); // put into the THR register`
			`}`
			`}`

			`#elif defined NDEBUG`
			`// put the CPU and peripherals to the low-power mode`
			`__WFI(); // stop clocking the CPU and wait for interrupt`
			`QF_INT_ENABLE();`
			`#else`
			`QF_INT_ENABLE();`
			`#endif`
			`}`
			`//............................................................................`
			`// error routine that is called if the STM32 library encounters an error`
			`extern "C" void assert_failed(char const *file, int line) {`
			`Q_onAssert(file, line);`
			`}`
			`//............................................................................`
			`extern "C" void Q_onAssert(char const * const file, int line) {`
			`(void)file; // avoid compiler warning`
			`(void)line; // avoid compiler warning`
			`QF_INT_DISABLE(); // make sure that all interrupts are disabled`
			`for (;;) { // NOTE: replace the loop with reset for final version`
			`}`
			`}`
			`//............................................................................`
			`void BSP_displyPhilStat(uint8_t n, char const *stat) {`
			`if (stat[0] == 'e') {`
			`GPIOSetValue(LED_PORT, LED_BIT, LED_ON); /* LED on */`
			`}`
			`else {`
			`GPIOSetValue(LED_PORT, LED_BIT, LED_OFF); /* LED off */`
			`}`

			`QS_BEGIN(PHILO_STAT, AO_Philo[n]) // application-specific record begin`
			`QS_U8(1, n); // Philosopher number`
			`QS_STR(stat); // Philosopher status`
			`QS_END()`
			`}`
			`//............................................................................`
			`void BSP_busyDelay(void) {`
			`uint32_t volatile i = l_delay;`
			`while (i-- > 0UL) { // busy-wait loop`
			`}`
			`}`

			`//----------------------------------------------------------------------------`
			`#ifdef Q_SPY`
			`//............................................................................`
			`uint8_t QS::onStartup(void const *arg) {`
			`static uint8_t qsBuf[QS_BUF_SIZE]; // buffer for Quantum Spy`
			`initBuf(qsBuf, sizeof(qsBuf));`

			`UARTInit(QS_BAUD_RATE); // initialize the UART with the desired baud rate`
			`NVIC_DisableIRQ(UART_IRQn); // do not use the interrupts (QS uses polling)`
			`LPC_UART->IER = 0;`

			`QS_tickPeriod_ = (QSTimeCtr)(SystemCoreClock / BSP_TICKS_PER_SEC);`
			`QS_tickTime_ = QS_tickPeriod_; // to start the timestamp at zero`

			`/* setup the QS filters... */`
			`QS_FILTER_ON(QS_ALL_RECORDS);`

			`// QS_FILTER_OFF(QS_QEP_STATE_EMPTY);`
			`// QS_FILTER_OFF(QS_QEP_STATE_ENTRY);`
			`// QS_FILTER_OFF(QS_QEP_STATE_EXIT);`
			`// QS_FILTER_OFF(QS_QEP_STATE_INIT);`
			`// QS_FILTER_OFF(QS_QEP_INIT_TRAN);`
			`// QS_FILTER_OFF(QS_QEP_INTERN_TRAN);`
			`// QS_FILTER_OFF(QS_QEP_TRAN);`
			`// QS_FILTER_OFF(QS_QEP_IGNORED);`

			`QS_FILTER_OFF(QS_QF_ACTIVE_ADD);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_REMOVE);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_SUBSCRIBE);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_UNSUBSCRIBE);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_POST_FIFO);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_POST_LIFO);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_GET);`
			`QS_FILTER_OFF(QS_QF_ACTIVE_GET_LAST);`
			`QS_FILTER_OFF(QS_QF_EQUEUE_INIT);`
			`QS_FILTER_OFF(QS_QF_EQUEUE_POST_FIFO);`
			`QS_FILTER_OFF(QS_QF_EQUEUE_POST_LIFO);`
			`QS_FILTER_OFF(QS_QF_EQUEUE_GET);`
			`QS_FILTER_OFF(QS_QF_EQUEUE_GET_LAST);`
			`QS_FILTER_OFF(QS_QF_MPOOL_INIT);`
			`QS_FILTER_OFF(QS_QF_MPOOL_GET);`
			`QS_FILTER_OFF(QS_QF_MPOOL_PUT);`
			`QS_FILTER_OFF(QS_QF_PUBLISH);`
			`QS_FILTER_OFF(QS_QF_NEW);`
			`QS_FILTER_OFF(QS_QF_GC_ATTEMPT);`
			`QS_FILTER_OFF(QS_QF_GC);`
			`// QS_FILTER_OFF(QS_QF_TICK);`
			`QS_FILTER_OFF(QS_QF_TIMEEVT_ARM);`
			`QS_FILTER_OFF(QS_QF_TIMEEVT_AUTO_DISARM);`
			`QS_FILTER_OFF(QS_QF_TIMEEVT_DISARM_ATTEMPT);`
			`QS_FILTER_OFF(QS_QF_TIMEEVT_DISARM);`
			`QS_FILTER_OFF(QS_QF_TIMEEVT_REARM);`
			`QS_FILTER_OFF(QS_QF_TIMEEVT_POST);`
			`QS_FILTER_OFF(QS_QF_CRIT_ENTRY);`
			`QS_FILTER_OFF(QS_QF_CRIT_EXIT);`
			`QS_FILTER_OFF(QS_QF_ISR_ENTRY);`
			`QS_FILTER_OFF(QS_QF_ISR_EXIT);`

			`// QS_FILTER_OFF(QS_QK_MUTEX_LOCK);`
			`// QS_FILTER_OFF(QS_QK_MUTEX_UNLOCK);`
			`QS_FILTER_OFF(QS_QK_SCHEDULE);`

			`return (uint8_t)1; // return success`
			`}`
			`//............................................................................`
			`void QS::onCleanup(void) {`
			`}`
			`//............................................................................`
			`QSTimeCtr QS::onGetTime(void) { // invoked with interrupts locked`
			`if ((SysTick->CTRL & 0x00010000) == 0) { // COUNT no set?`
			`return QS_tickTime_ - (QSTimeCtr)SysTick->VAL;`
			`}`
			`else { // the rollover occured, but the SysTick_ISR did not run yet`
			`return QS_tickTime_ + QS_tickPeriod_ - (QSTimeCtr)SysTick->VAL;`
			`}`
			`}`
			`//............................................................................`
			`void QS::onFlush(void) {`
			`uint16_t b;`
			`while ((b = getByte()) != QS_EOD) { // while not End-Of-Data...`
			`while ((LPC_UART->LSR & LSR_THRE) == 0) { // while TXE not empty`
			`}`
			`LPC_UART->THR = (b & 0xFF); // put into the THR register`
			`}`
			`}`
			`#endif // Q_SPY`
			`//----------------------------------------------------------------------------`

			`//////////////////////////////////////////////////////////////////////////////`
			`// NOTE01:`
			`// The QF::onIdle() callback is called with interrupts locked, because the`
			`// determination of the idle condition might change by any interrupt posting`
			`// an event. QF::onIdle() must internally unlock interrupts, ideally`
			`// atomically with putting the CPU to the power-saving mode.`
			`//`
			`// NOTE02:`
			`// The blue LED is used to visualize the idle loop activity. The brightness`
			`// of the LED is proportional to the frequency of invcations of the idle loop.`
			`// Please note that the LED is toggled with interrupts locked, so no interrupt`
			`// execution time contributes to the brightness of the User LED.`
			`//`