public
/
modern-embedded-programming-course
mirror of https://github.com/QuantumLeaps/modern-embedded-programming-course.git
1
0
Fork 0
Code Issues Packages Projects Releases Wiki Activity
You cannot select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
main
Branches Tags
${ item.name }
Create tag ${ searchTerm }
Create branch ${ searchTerm }
from '53c9251ec9'
${ noResults }
modern-embedded-programming.../lesson-44/ek-tm4c123gxl/qutest/qutest_cpp.cpp

234 lines
8.5 KiB
C++
Raw Blame History

//============================================================================
// Product: QUTEST port for EK-TM4C123GXL board
// Last updated for version 7.3.0
// Last updated on 2023-08-18
//
// Q u a n t u m L e a P s
// ------------------------
// Modern Embedded Software
//
// Copyright (C) 2005 Quantum Leaps, LLC. <state-machine.com>
//
// SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-QL-commercial
//
// This software is dual-licensed under the terms of the open source GNU
// General Public License version 3 (or any later version), or alternatively,
// under the terms of one of the closed source Quantum Leaps commercial
// licenses.
//
// The terms of the open source GNU General Public License version 3
// can be found at: <www.gnu.org/licenses/gpl-3.0>
//
// The terms of the closed source Quantum Leaps commercial licenses
// can be found at: <www.state-machine.com/licensing>
//
// Redistributions in source code must retain this top-level comment block.
// Plagiarizing this software to sidestep the license obligations is illegal.
//
// Contact information:
// <www.state-machine.com>
// <info@state-machine.com>
//============================================================================
#ifndef Q_SPY
#error "Q_SPY must be defined to compile qutest_cpp.cpp"
#endif // Q_SPY
#define QP_IMPL // this is QP implementation
#include "qp_port.hpp" // QP port
#include "qs_port.hpp" // QS port
#include "qs_pkg.hpp" // QS package-scope interface
#include "qsafe.h" // QP Functional Safety (FuSa) Subsystem
#include "TM4C123GH6PM.h" // the device specific header (TI)
#include "rom.h" // the built-in ROM functions (TI)
#include "sysctl.h" // system control driver (TI)
#include "gpio.h" // GPIO driver (TI)
// add other drivers if necessary...
//Q_DEFINE_THIS_MODULE("qutest_port")
using namespace QP;
// ISRs defined in this BSP --------------------------------------------------
extern "C" void UART0_IRQHandler(void); // prototype
// Local-scope objects -------------------------------------------------------
#define LED_RED (1U << 1)
#define LED_BLUE (1U << 2)
#define LED_GREEN (1U << 3)
#define BTN_SW1 (1U << 4)
#define BTN_SW2 (1U << 0)
#define UART_BAUD_RATE 115200U
#define UART_FR_TXFE (1U << 7)
#define UART_FR_RXFE (1U << 4)
#define UART_TXFIFO_DEPTH 16U
//............................................................................
extern "C" {
// ISR for receiving bytes from the QSPY Back-End
// NOTE: This ISR is "QF-unaware" meaning that it does not interact with
// the QF/QK and is not disabled. Such ISRs don't need to call QK_ISR_ENTRY/
// QK_ISR_EXIT and they cannot post or publish events.
//
void UART0_IRQHandler(void) {
// while RX FIFO NOT empty
while ((UART0->FR & UART_FR_RXFE) == 0) {
uint32_t b = UART0->DR;
QP::QS::rxPut(b);
}
}
void assert_failed(char const * const module, int_t const id); // prototype
void assert_failed(char const * const module, int_t const id) {
Q_onError(module, id);
}
} // extern "C"
// QS callbacks ==============================================================
bool QS::onStartup(void const *arg) {
Q_UNUSED_PAR(arg);
static uint8_t qsTxBuf[2*1024]; // buffer for QS-TX channel
initBuf (qsTxBuf, sizeof(qsTxBuf));
static uint8_t qsRxBuf[256]; // buffer for QS-RX channel
rxInitBuf(qsRxBuf, sizeof(qsRxBuf));
// NOTE: SystemInit() already called from the startup code
// but SystemCoreClock needs to be updated
//
SystemCoreClockUpdate();
// enable clock for to the peripherals used by this application...
SYSCTL->RCGCGPIO |= (1U << 5); // enable Run mode for GPIOF
// configure the LEDs and push buttons
GPIOF->DIR |= (LED_RED | LED_GREEN | LED_BLUE);// set direction: output
GPIOF->DEN |= (LED_RED | LED_GREEN | LED_BLUE); // digital enable
GPIOF->DATA_Bits[LED_RED] = 0U; // turn the LED off
GPIOF->DATA_Bits[LED_GREEN] = 0U; // turn the LED off
GPIOF->DATA_Bits[LED_BLUE] = 0U; // turn the LED off
// configure the Buttons
GPIOF->DIR &= ~(BTN_SW1 | BTN_SW2); // set direction: input
ROM_GPIOPadConfigSet(GPIOF_BASE, (BTN_SW1 | BTN_SW2),
GPIO_STRENGTH_2MA, GPIO_PIN_TYPE_STD_WPU);
// enable clock for UART0 and GPIOA (used by UART0 pins)
SYSCTL->RCGCUART |= (1U << 0); // enable Run mode for UART0
SYSCTL->RCGCGPIO |= (1U << 0); // enable Run mode for GPIOA
// configure UART0 pins for UART operation
std::uint32_t tmp = (1U << 0) | (1U << 1);
GPIOA->DIR &= ~tmp;
GPIOA->SLR &= ~tmp;
GPIOA->ODR &= ~tmp;
GPIOA->PUR &= ~tmp;
GPIOA->PDR &= ~tmp;
GPIOA->AMSEL &= ~tmp; // disable analog function on the pins
GPIOA->AFSEL |= tmp; // enable ALT function on the pins
GPIOA->DEN |= tmp; // enable digital I/O on the pins
GPIOA->PCTL &= ~0x00U;
GPIOA->PCTL |= 0x11U;
// configure the UART for the desired baud rate, 8-N-1 operation
tmp = (((SystemCoreClock * 8U) / UART_BAUD_RATE) + 1U) / 2U;
UART0->IBRD = tmp / 64U;
UART0->FBRD = tmp % 64U;
UART0->LCRH = (0x3U << 5); // configure 8-N-1 operation
UART0->LCRH |= (0x1U << 4); // enable FIFOs
UART0->CTL = (1U << 0) // UART enable
| (1U << 8) // UART TX enable
| (1U << 9); // UART RX enable
// configure UART interrupts (for the RX channel)
UART0->IM |= (1U << 4) | (1U << 6); // enable RX and RX-TO interrupt
UART0->IFLS |= (0x2U << 2); // interrupt on RX FIFO half-full
// explicitly set NVIC priorities of all Cortex-M interrupts used
NVIC_SetPriorityGrouping(0U);
NVIC_SetPriority(UART0_IRQn, 0U); // kernel unaware interrupt
// enable the UART RX interrupt...
NVIC_EnableIRQ(UART0_IRQn); // UART0 interrupt used for QS-RX
return true; // return success
}
//............................................................................
void QS::onCleanup(void) {
// wait as long as the UART is busy
while ((UART0->FR & UART_FR_TXFE) == 0) {
}
// delay before returning to allow all produced QS bytes to be received
for (std::uint32_t volatile dly_ctr = 100000U; dly_ctr > 0U; --dly_ctr) {
}
}
//............................................................................
void QS::onFlush(void) {
uint16_t fifo = UART_TXFIFO_DEPTH; // Tx FIFO depth
uint8_t const *block;
while ((block = getBlock(&fifo)) != (uint8_t *)0) {
GPIOF->DATA_Bits[LED_GREEN] = LED_GREEN;
// busy-wait as long as TX FIFO has data to transmit
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
GPIOF->DATA_Bits[LED_GREEN] = 0U;
}
}
//............................................................................
// callback function to reset the target (to be implemented in the BSP)
void QS::onReset(void) {
NVIC_SystemReset();
}
//............................................................................
void QS::doOutput(void) {
if ((UART0->FR & UART_FR_TXFE) != 0U) { // TX done?
uint16_t fifo = UART_TXFIFO_DEPTH; // max bytes we can accept
uint8_t const *block;
QF_INT_DISABLE();
block = 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
}
}
}
//............................................................................
void QS::onTestLoop() {
rxPriv_.inTestLoop = true;
while (rxPriv_.inTestLoop) {
// turn the LED1 on and off (glow)
GPIOF->DATA_Bits[LED_BLUE] = LED_BLUE; // turn the Blue LED on
GPIOF->DATA_Bits[LED_BLUE] = 0U; // turn the Blue LED off
rxParse(); // parse all the received bytes
if ((UART0->FR & UART_FR_TXFE) != 0U) { // TX done?
std::uint16_t fifo = UART_TXFIFO_DEPTH; // max bytes we can accept
std::uint8_t const *block;
block = getBlock(&fifo); // try to get next block to transmit
while (fifo-- != 0) { // any bytes in the block?
UART0->DR = *block++; // put into the FIFO
}
}
}
// set inTestLoop to true in case calls to QS_onTestLoop() nest,
// which can happen through the calls to QS_TEST_PAUSE().
rxPriv_.inTestLoop = true;
}
Reference in New Issue View Git Blame Copy Permalink