void RCC_INIT(void)
{
CLK->ICKR |= CLK_ICKR_HSIEN;
// CLK_HSICmd(ENABLE);
CLK_SYSCLKConfig(CLK_PRESCALER_CPUDIV1);
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
// CLK_PeripheralClockConfig(CLK_PERIPHERAL_UART1,ENABLE); //串口1时钟开
// CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER1,ENABLE); //定时器时钟1开
// CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER2, ENABLE);
CLK->PCKENR1 |= (uint8_t)((uint8_t)1 << ((uint8_t)CLK_PERIPHERAL_UART1 & (uint8_t)0x0F));
CLK->PCKENR1 |= (uint8_t)((uint8_t)1 << ((uint8_t)CLK_PERIPHERAL_TIMER1 & (uint8_t)0x0F));
CLK->PCKENR1 |= (uint8_t)((uint8_t)1 << ((uint8_t)CLK_PERIPHERAL_TIMER2 & (uint8_t)0x0F));
}
int main()
{
__disable_interrupt();
//InitQueue(&uart_rx_cirqueue);
//InitQueue(&uart_tx_cirqueue);
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
//GPIO_Init(GPIOD, GPIO_PIN_3|GPIO_PIN_2|GPIO_PIN_0, GPIO_MODE_OUT_PP_LOW_SLOW);
GPIO_INIT();//led
GPIO_Init(GPIOD, GPIO_PIN_2,GPIO_MODE_OUT_PP_HIGH_FAST);//开启U10的控制引脚
pir_RI_io_init();//pir中断
T4_Init();
//Uart_Init();
CommInit();
/*AWU configuration --------------------------------------------*/
AWU_Config();
OSInit();
CommBufInit();//创建信号量的操作不能再OSInit();之前,也就是不能在OS_InitEventList();之前
OSTaskCreate( task0, (void *)OS_TASK_0_STK_SIZE, &Task0Stack[OS_TASK_0_STK_SIZE-1], OS_TASK_0_PRIO );
OSTaskCreate( task1, (void *)OS_TASK_1_STK_SIZE, &Task1Stack[OS_TASK_1_STK_SIZE-1], OS_TASK_1_PRIO );
//OSTaskCreate( task2, (void *)OS_TASK_2_STK_SIZE, &Task2Stack[OS_TASK_2_STK_SIZE-1], OS_TASK_2_PRIO );
OSStart();
return 0;
}
int main(void) {
// Initialise the clock to have a /1 prescaler and use the external crystal clock source for accuracy.
CLK_DeInit();
CLK_SYSCLKConfig(CLK_PRESCALER_CPUDIV1);
CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSE, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
// Reset ("de-initialise") GPIO port D.
GPIO_DeInit(GPIOD);
// Initialise pin 0 of port D by setting it as:
// - an output pin,
// - using a push-pull driver,
// - at a low logic level (0V), and
// - 10MHz.
GPIO_Init(GPIOD, GPIO_PIN_0, GPIO_MODE_OUT_PP_LOW_FAST);
LCDInit(); // Init the LCD
DecodeInit(); // Init the GPS decoding
DrawScreen(); // Setup Screen and Buffer
// Infinite loop.
for(;;) {
// Blink Debug LED
GPIO_WriteReverse(GPIOD, GPIO_PIN_0);
DrawDemo();
}
}
/**
* @brief Main program.
* @param None
* @retval None
*/
void main(void)
{
uint8_t i = 0;
/* Select fCPU = 16MHz */
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
/* Init the Eval board LCD */
STM8S_EVAL_LCD_Init();
/* Clear LCD */
LCD_Clear();
LCD_SetCursorPos(LCD_LINE1, 0);
LCD_Print("SPI-LCD example");
/* Display "moving" ST logo */
for (i = 1; i < 8; i++)
{
PrintLogo();
Delay(0xFFFF);
}
LCD_SetCursorPos(LCD_LINE2, 0);
LCD_Print(" ");
LCD_DisplayLogo(0x93);
Delay(600);
while(1)
{}
}
//设置内部时钟16M为主时钟
//输入参数:无
//输出参数:无
void Set_HSI(void)
{
//CLK_DeInit(); //恢复默认设置
CLK_HSICmd(ENABLE); //内部时钟开
while(SET != CLK_GetFlagStatus(CLK_FLAG_HSIRDY)); //等待内部时钟稳定
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1); //不分频,16M
CLK_ClockSwitchCmd(ENABLE); //时钟切换使能
//切换配置
CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO,CLK_SOURCE_HSI,DISABLE,CLK_CURRENTCLOCKSTATE_DISABLE);
}
void clockInit(void)
{
/* Turn on internal high speed clock and use it */
CLK_HSICmd(ENABLE);
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO,
CLK_SOURCE_HSI,
ENABLE,
CLK_CURRENTCLOCKSTATE_ENABLE);
CLK_LSICmd(DISABLE);
}
// 初始化系统时钟
void system_config_clk_init(void)
{
//clock_config(16); // 内部时钟16M
clock_config(8); // 内部时钟8M
#if 0
CLK_DeInit();
CLK_FastHaltWakeUpCmd(ENABLE);
CLK_HSECmd(DISABLE);
CLK_HSICmd(ENABLE);
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV4);
#endif
}
/**
* @brief Configure system clock to run at Maximum clock speed and output the
* system clock on CCO pin
* @param None
* @retval None
*/
static void CLK_Config(void)
{
ErrorStatus status = FALSE;
CLK_DeInit();
/* Configure the Fcpu to DIV1*/
CLK_SYSCLKConfig(CLK_PRESCALER_CPUDIV1);
/* Configure the HSI prescaler to the optimal value */
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
/* Output Fcpu on CLK_CCO pin */
CLK_CCOConfig(CLK_OUTPUT_CPU);
/* Configure the system clock to use HSE clock source and to run at 24Mhz */
status = CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSE, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
while (ButtonPressed == FALSE)
{
}
/* Configure the system clock to use HSI clock source and to run at 16Mhz */
status = CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSI, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
}
/**
* @brief Configure system clock to run at 16Mhz
* @param None
* @retval None
*/
void CLK_Config(void)
{
/* Initialization of the clock */
/* Clock divider to HSI/1 */
CLK_HSIPrescalerConfig(CLK_PRESCALER_HSIDIV1);
CLK_SYSCLKConfig(CLK_PRESCALER_CPUDIV1);
CLK_HSICmd(ENABLE);
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER1, ENABLE);
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER2, ENABLE);
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER3, ENABLE);
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER4, ENABLE);
CLK_PeripheralClockConfig(CLK_PERIPHERAL_UART1, ENABLE);
#ifdef __DEBUG__
CLK_PeripheralClockConfig(CLK_PERIPHERAL_UART3, ENABLE);
#endif
}
/********************************************************************************
* clk_setup *
********************************************************************************/
void _Device_System_clk_setup(void)
{
CLK_HSIPrescalerConfig(dSourceFreqDivided); // fMaster, speed 16MHz / 4 = 4MHz, for peripheral device
CLK_SYSCLKConfig(dMCUFreqDivided); // CPU speed, 4MHz / 1 = 4MHz
// I2C
//CLK_PeripheralClockConfig(CLK_PERIPHERAL_I2C, ENABLE);
// V_BAT, T_SENSOR, I_CHARGE, I_DISCHARGE
CLK_PeripheralClockConfig(CLK_PERIPHERAL_ADC, ENABLE);
// LED 1 ~ 4, PWM
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER1, ENABLE);
// LED 0, PWM
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER2, ENABLE);
// tick
CLK_PeripheralClockConfig(CLK_PERIPHERAL_TIMER4, ENABLE);
// UART
CLK_PeripheralClockConfig(CLK_PERIPHERAL_UART2, ENABLE);
// GPIO_Init(GPIOD, GPIO_PIN_0, GPIO_MODE_OUT_PP_LOW_FAST);
// CLK_CCOConfig(CLK_OUTPUT_CPUDIV8);
// CLK_CCOConfig(CLK_OUTPUT_CPU);
// CLK_CCOCmd(ENABLE);
/* Output Fcpu on CLK_CCO pin */
//CLK_CCOConfig(CLK_OUTPUT_CPU);
//
// //Lsi
// unsigned char status;
// CLK_ClockSwitchCmd(ENABLE);
// status = CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_LSI, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
//
// while(status == 0);
//CLK_ClockSwitchConfig(CLK_SWITCHMODE_MANUAL, CLK_SOURCE_LSI, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
//CLK_LSICmd(ENABLE);
//CLK_HSECmd(DISABLE);
// //hsi
// CLK_ClockSwitchCmd(ENABLE);
// CLK_HSICmd(ENABLE);
// CLK_LSICmd(DISABLE);
// CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSI, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
}
void dev_clkInit(void)
{
CLK_DeInit();
CLK_SYSCLKConfig(CLK_PRESCALER_CPUDIV1);
/*
#if (STM8_FREQ_MHZ > 16)
// Set High Speed External 24MHz
CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSE, DISABLE, DISABLE);
#else
// Set High Speed Internal 16MHz
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
#endif
*/
// tolto sopra
// usa HSE anche se = 16
// nel nostro caso quarzo esterno da 16 MHz
CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSE, DISABLE, DISABLE);
}
void main(void)
{
/* select Clock = 4 MHz */
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV4);
CLK_HSICmd(ENABLE);
/* The counter value is initialized to 0.*/
counter = 0;
LoadValueIntoSinStruct();
/* TIM1 configuration -----------------------------------------*/
TIM1_Config();
/* Enable interrupts*/
enableInterrupts();
while(1)
{}
}
void main(void)
{
//CFG->GCR |= 0x01; //disable swim pin
/* Configure the Fcpu to DIV1*/
CLK_SYSCLKConfig(CLK_PRESCALER_CPUDIV1);
/* select Clock = 16 MHz */
CLK_SYSCLKConfig(CLK_PRESCALER_HSIDIV1);
/* Configure the system clock to use HSI clock source and to run at 16Mhz */
CLK_ClockSwitchConfig(CLK_SWITCHMODE_AUTO, CLK_SOURCE_HSI, DISABLE, CLK_CURRENTCLOCKSTATE_DISABLE);
CLK_HSIPrescalerConfig(CLK_PRESCALER_HSIDIV1);
CLK_HSICmd(ENABLE);
FLASH_Config();
EXTI_DeInit();
//You should add:
// Define FLASH programming time
//FLASH_SetProgrammingTime(FLASH_PROGRAMTIME_STANDARD);
//optbyte1 = FLASH_ReadOptionByte(0x4803); //255 by def
//optbyte2 = FLASH_ReadOptionByte(0x4804); //255 by def
/*
if (optbyte != 765)
{
FLASH_Unlock(FLASH_MEMTYPE_DATA); // unlock data memory by passing the RASS key in the proper order
FLASH_ProgramOptionByte(0x4803, 0xFD); // byte OPT2 resides at address x4803, write a 1 to bit 7. This will also write to the NOPT2 complement byte
FLASH_Lock(FLASH_MEMTYPE_DATA); // re-lock data memory
}
*/
//General purpose timer
TIM4_Config();
#ifdef DFS_90
HotAir_Config();
#endif
#ifndef DFS_90
GPIO_Init(CONTROL_GPIO_PORT, CONTROL_GPIO_PIN, GPIO_MODE_OUT_PP_LOW_FAST);
#endif
Temperature_ADC_Config();
STM_EVAL_SEGInit(SEG1);
STM_EVAL_SEGInit(SEG2);
STM_EVAL_SEGInit(SEG3);
STM_EVAL_LEDInit(LEDA);
STM_EVAL_LEDInit(LEDB);
STM_EVAL_LEDInit(LEDC);
STM_EVAL_LEDInit(LEDD);
STM_EVAL_LEDInit(LEDE);
STM_EVAL_LEDInit(LEDF);
STM_EVAL_LEDInit(LEDG);
STM_EVAL_LEDInit(LEDP);
#ifndef SOLDERING_VAR2
//STM_EVAL_LEDInit(LEDP);
#endif
// STM_EVAL_SEGOn(SEG1);
// STM_EVAL_SEGOn(SEG2);
// STM_EVAL_SEGOn(SEG3);
//
// STM_EVAL_LEDOn(LEDA);
// STM_EVAL_LEDOn(LEDB);
// STM_EVAL_LEDOn(LEDC);
// STM_EVAL_LEDOn(LEDD);
// STM_EVAL_LEDOn(LEDE);
// STM_EVAL_LEDOn(LEDF);
// STM_EVAL_LEDOn(LEDG);
//
// STM_EVAL_LEDOff(LEDA);
// STM_EVAL_LEDOff(LEDB);
// STM_EVAL_LEDOff(LEDC);
// STM_EVAL_LEDOff(LEDD);
// STM_EVAL_LEDOff(LEDE);
// STM_EVAL_LEDOff(LEDF);
// STM_EVAL_LEDOff(LEDG);
// STM_EVAL_LEDOff(LEDP);
//
// STM_EVAL_SEGOff(SEG1);
// STM_EVAL_SEGOff(SEG2);
// STM_EVAL_SEGOff(SEG3);
//STM_EVAL_LEDOn(LEDP);
//GPIO_Init(ENC_DN_BUTTON_PORT, ENC_DN_BUTTON_PIN, GPIO_MODE_IN_PU_NO_IT);
//GPIO_Init(ENC_UP_BUTTON_PORT, ENC_UP_BUTTON_PIN, GPIO_MODE_IN_PU_NO_IT);
STM_EVAL_PBInit(BUTTON_KEY, BUTTON_MODE_GPIO);
STM_EVAL_PBInit(BUTTON_UP, BUTTON_MODE_GPIO);
STM_EVAL_PBInit(BUTTON_DOWN, BUTTON_MODE_GPIO);
STM_EVAL_PBInit(BUTTON_REED, BUTTON_MODE_GPIO);
ssegInit();
ssegWriteStr("1.0.1", 5, SEG1);
enableInterrupts();
#ifdef DFS_90
HotAir_Main();
#endif
#ifdef SOLDERING_HAKKO_A1321
Soldering_Main();
#endif
while(1)
{
/*
#if 0
for (level = 0; level < calUpperLimit; level +=5)
{
Delayms(1);
}
for (level = calUpperLimit; level > 0; level -=5)
{
Delayms(1);
}
#else
RawData = GetAdcValue(ADC_SOLDER_TEMP_CHANNEL);
SmoothData = SmoothData - (LPF_Beta * (SmoothData - RawData));
level = ((int)SmoothData)*26;
#endif
*/
}
}
