/***************************************************************************** * Product: DPP with lwIP application, preemptive QK kernel * Last Updated for Version: 4.5.00 * Date of the Last Update: May 18, 2012 * * Q u a n t u m L e a P s * --------------------------- * innovating embedded systems * * Copyright (C) 2002-2012 Quantum Leaps, LLC. All rights reserved. * * This program is open source 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 2 of the License, or * (at your option) any later version. * * Alternatively, this program may be distributed and modified under the * terms of Quantum Leaps commercial licenses, which expressly supersede * the GNU General Public License and are specifically designed for * licensees interested in retaining the proprietary status of their code. * * This program 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 this program. If not, see . * * Contact information: * Quantum Leaps Web sites: http://www.quantum-leaps.com * http://www.state-machine.com * e-mail: info@quantum-leaps.com *****************************************************************************/ #include "qp_port.h" /* QP port header file */ #include "dpp.h" /* application events and active objects */ #include "bsp.h" /* Board Support Package header file */ #include "lm3s_cmsis.h" Q_DEFINE_THIS_FILE #define USER_LED (1 << 0) #define USER_BTN (1 << 1) #define ETH0_LED (1 << 3) #define ETH1_LED (1 << 2) static uint32_t l_nTicks; enum ISR_Priorities { /* ISR priorities starting from the highest urgency */ SYSTICK_PRIO, ETHERNET_PRIO, /* ... */ }; #ifdef Q_SPY QSTimeCtr QS_tickTime_; QSTimeCtr QS_tickPeriod_; static uint8_t l_SysTick_Handler; #define UART_BAUD_RATE 115200 #define UART_TXFIFO_DEPTH 16 #define UART_FR_TXFE (1 << 7) #endif /*..........................................................................*/ void SysTick_Handler(void) { static uint32_t btn_debounced = 0; static uint8_t debounce_state = 0; uint32_t volatile tmp; QK_ISR_ENTRY(); /* inform QK about ISR entry */ ++l_nTicks; /* count the number of clock ticks */ #ifdef Q_SPY tmp = SysTick->CTRL; /* clear SysTick_CTRL_COUNTFLAG */ QS_tickTime_ += QS_tickPeriod_; /* account for the clock rollover */ #endif QF_TICK(&l_SysTick_Handler); /* process all armed time events */ tmp = GPIOF->DATA_Bits[USER_BTN]; /* read the User Button */ switch (debounce_state) { case 0: if (tmp != btn_debounced) { debounce_state = 1; /* transition to the next state */ } break; case 1: if (tmp != btn_debounced) { debounce_state = 2; /* transition to the next state */ } else { debounce_state = 0; /* transition back to state 0 */ } break; case 2: if (tmp != btn_debounced) { debounce_state = 3; /* transition to the next state */ } else { debounce_state = 0; /* transition back to state 0 */ } break; case 3: if (tmp != btn_debounced) { btn_debounced = tmp; /* save the debounced button value */ if (tmp == 0) { /* is the button depressed? */ static QEvt const bd = { BTN_DOWN_SIG, 0 }; QF_PUBLISH(&bd, &l_SysTick_Handler); } else { static QEvt const bu = { BTN_UP_SIG, 0 }; QF_PUBLISH(&bu, &l_SysTick_Handler); } } debounce_state = 0; /* transition back to state 0 */ break; } QK_ISR_EXIT(); /* inform QK about ISR exit */ } /*..........................................................................*/ void BSP_init(void) { /* set the system clock as specified in lm3s_config.h (20MHz from PLL) */ SystemInit(); SYSCTL->RCGC2 |= (1 << 5); /* enable clock to GPIOF (User and Eth LEDs)*/ __NOP(); __NOP(); /* configure the pin driving the Ethernet LED */ GPIOF->DIR &= ~(ETH0_LED | ETH1_LED); /* set direction: hardware */ GPIOF->AFSEL |= (ETH0_LED | ETH1_LED); GPIOF->DR2R |= (ETH0_LED | ETH1_LED); GPIOF->ODR &= ~(ETH0_LED | ETH1_LED); GPIOF->PUR |= (ETH0_LED | ETH1_LED); GPIOF->PDR &= ~(ETH0_LED | ETH1_LED); GPIOF->DEN |= (ETH0_LED | ETH1_LED); GPIOF->AMSEL &= ~(ETH0_LED | ETH1_LED); /* configure the pin driving the User LED */ GPIOF->DIR |= USER_LED; /* set direction: output */ GPIOF->DR2R |= USER_LED; GPIOF->DEN |= USER_LED; GPIOF->AMSEL &= ~USER_LED; GPIOF->DATA_Bits[USER_LED] = 0; /* turn the LED off */ /* configure the pin connected to the Buttons */ GPIOF->DIR &= ~USER_BTN; /* set direction: input */ GPIOF->DR2R |= USER_BTN; GPIOF->ODR &= ~USER_BTN; GPIOF->PUR |= USER_BTN; GPIOF->PDR &= ~USER_BTN; GPIOF->DEN |= USER_BTN; GPIOF->AMSEL &= ~USER_BTN; 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 the SysTick timer to fire at BSP_TICKS_PER_SEC rate */ SysTick_Config(SystemFrequency / BSP_TICKS_PER_SEC); /* set priorities of all interrupts in the system... */ NVIC_SetPriority(SysTick_IRQn, SYSTICK_PRIO); NVIC_SetPriority(Ethernet_IRQn, ETHERNET_PRIO); NVIC_EnableIRQ(Ethernet_IRQn); /* enable the Ethernet Interrupt */ } /*..........................................................................*/ void QF_onCleanup(void) { } /*..........................................................................*/ void QK_onIdle(void) { /* toggle the User LED on and then off, see NOTE01 */ QF_INT_DISABLE(); GPIOF->DATA_Bits[USER_LED] = USER_LED; /* turn the User LED on */ GPIOF->DATA_Bits[USER_LED] = 0; /* turn the User LED off */ QF_INT_ENABLE(); #ifdef Q_SPY if ((UART0->FR & UART_FR_TXFE) != 0) { /* TX done? */ uint16_t fifo = UART_TXFIFO_DEPTH; /* max bytes we can accept */ uint8_t const *block; QF_INT_DISABLE(); block = QS_getBlock(&fifo); /* try to get next block to transmit */ QF_INT_ENABLE(); while (fifo-- != 0) { /* any bytes in the block? */ UART0->DR = *block++; /* put into the FIFO */ } } #elif defined NDEBUG /* Put the CPU and peripherals to the low-power mode. * you might need to customize the clock management for your application, * see the datasheet for your particular MCU. */ __WFI(); /* Wait-For-Interrupt */ #endif } /*..........................................................................*/ void Q_onAssert(char const Q_ROM * const Q_ROM_VAR 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 */ } } /*..........................................................................*/ /* sys_now() is used in the lwIP stack */ uint32_t sys_now(void) { return l_nTicks * (1000 / BSP_TICKS_PER_SEC); } /*--------------------------------------------------------------------------*/ #ifdef Q_SPY /*..........................................................................*/ uint8_t QS_onStartup(void const *arg) { static uint8_t qsBuf[6*256]; /* buffer for Quantum Spy */ uint32_t tmp; QS_initBuf(qsBuf, sizeof(qsBuf)); /* enable the peripherals used by the UART0 */ SYSCTL->RCGC1 |= (1 << 0); /* enable clock to UART0 */ SYSCTL->RCGC2 |= (1 << 0); /* enable clock to GPIOA */ __NOP(); /* wait after enabling clocks */ __NOP(); __NOP(); /* configure UART0 pins for UART operation */ tmp = (1 << 0) | (1 << 1); GPIOA->DIR &= ~tmp; GPIOA->AFSEL |= tmp; GPIOA->DR2R |= tmp; /* set 2mA drive, DR4R and DR8R are cleared */ GPIOA->SLR &= ~tmp; GPIOA->ODR &= ~tmp; GPIOA->PUR &= ~tmp; GPIOA->PDR &= ~tmp; GPIOA->DEN |= tmp; GPIOA->AMSEL &= ~tmp; /* configure the UART for the desired baud rate, 8-N-1 operation */ tmp = (((SystemFrequency * 8) / UART_BAUD_RATE) + 1) / 2; UART0->IBRD = tmp / 64; UART0->FBRD = tmp % 64; UART0->LCRH = 0x60; /* configure 8-bit operation */ UART0->LCRH |= 0x10; /* enable FIFOs */ UART0->CTL |= (1 << 0) | (1 << 8) | (1 << 9); QS_tickPeriod_ = SystemFrequency / 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); return (uint8_t)1; /* return success */ } /*..........................................................................*/ void QS_onCleanup(void) { } /*..........................................................................*/ QSTimeCtr QS_onGetTime(void) { /* invoked with interrupts locked */ if ((SysTick->CTRL & SysTick_CTRL_COUNTFLAG_Msk) == 0) { /* not 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 fifo = UART_TXFIFO_DEPTH; /* Tx FIFO depth */ uint8_t const *block; QF_INT_DISABLE(); while ((block = QS_getBlock(&fifo)) != (uint8_t *)0) { QF_INT_ENABLE(); /* busy-wait until TX FIFO empty */ while ((UART0->FR & UART_FR_TXFE) == 0) { } while (fifo-- != 0) { /* any bytes in the block? */ UART0->DR = *block++; /* put into the TX FIFO */ } fifo = UART_TXFIFO_DEPTH; /* re-load the Tx FIFO depth */ QF_INT_DISABLE(); } QF_INT_ENABLE(); } #endif /* Q_SPY */ /*--------------------------------------------------------------------------*/ /***************************************************************************** * NOTE01: * The User 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. */