Nuvoton
NuMaker NuWicam sample on NUC472
Dependencies: Modbus nvt_rs485
NuWicam for NuMaker-PFM-NUC472 board. Please refer document before executing it. More details, please refer https://github.com/OpenNuvoton/NuMaker_NuWicam_Samples/
main.cpp
- Committer:
- cyliang
- Date:
- 2017-10-06
- Revision:
- 13:da3c6fafcb97
- Parent:
- 11:9d35473bab9c
File content as of revision 13:da3c6fafcb97:
/*
* The program is a sample code.
* It needs run with NuMaker NuWicam board.
*/
/* ----------------------- System includes --------------------------------*/
#include "mbed.h"
#include "rtos.h"
/*----------------------- Modbus includes ----------------------------------*/
#include "mb.h"
#include "mbport.h"
/* ----------------------- Defines ------------------------------------------*/
// Sharing buffer index
enum {
eData_MBInCounter,
eData_MBOutCounter,
eData_MBError,
eData_DI,
eData_DO,
eData_RGB,
eData_MBResistorVar,
eData_TemperatureSensor,
eData_Cnt
} E_DATA_TYPE;
#define REG_INPUT_START 1
#define REG_INPUT_NREGS eData_Cnt
#define SLAVE_ID 0x01
/* ----------------------- Static variables ---------------------------------*/
static USHORT usRegInputStart = REG_INPUT_START;
static USHORT usRegInputBuf[REG_INPUT_NREGS];
DigitalOut led1(LED1); // For temperature worker.
DigitalOut led2(LED2); // For Modbus worker.
DigitalOut led3(LED3); // For Holder CB
AnalogIn LM35(A0);
#define DEF_LED_NUM 6
#if defined(TARGET_NUMAKER_PFM_NUC472)
DigitalOut LED[DEF_LED_NUM] = { PF_9, PF_10, PC_10, PC_11, PA_10, PA_9 } ;
#elif defined(TARGET_NUMAKER_PFM_M453)
DigitalOut LED[DEF_LED_NUM] = { PC_6, PC_7, PC_11, PC_12, PC_13, PC_14 } ;
#elif defined(TARGET_NUMAKER_PFM_M487)
DigitalOut LED[DEF_LED_NUM] = { PH_9, PH_8, PB_9, PF_11, PG_4, PC_11 } ;
#endif
void light_leds()
{
int i=0;
USHORT usOutValue = ~usRegInputBuf[eData_DO];
for ( i=0; i<DEF_LED_NUM ; i++)
LED[i].write( (usOutValue&(0x1<<i)) >> i );
}
void get_temp(void)
{
float tempC, a[10], avg;
int i;
#define DEF_ADC_READTIMES 10
avg=0;
for(i=0;i<DEF_ADC_READTIMES;i++)
{
a[i] = LM35.read();
Thread::wait(1);
}
for ( i=0; i<DEF_ADC_READTIMES; i++ )
avg += a[i];
avg /= DEF_ADC_READTIMES;
tempC=(avg*3.685503686*100);
usRegInputBuf[eData_TemperatureSensor] = (USHORT)tempC;
//printf("[%s %d] %f %d\r\n", __func__, __LINE__, avg, usRegInputBuf[eData_TemperatureSensor] );
}
void worker_get_temperature(void const *args)
{
// Poll temperature sensor per 1 second.
while (true) {
get_temp();
led1 = !led1;
Thread::wait(1000);
}
}
#if 0
void worker_uart(void const *args)
{
// For UART-SERIAL Tx/Rx Service.
while (true)
xMBPortSerialPolling();
}
#endif
/* ----------------------- Start implementation -----------------------------*/
int
main( void )
{
eMBErrorCode eStatus;
Thread temperature_thread(worker_get_temperature);
//Thread uart_thread(worker_uart);
// Initialise some registers
for (int i=0; i<REG_INPUT_NREGS; i++)
usRegInputBuf[i] = 0x0;
light_leds(); // Control LEDs
/* Enable the Modbus Protocol Stack. */
if ( (eStatus = eMBInit( MB_RTU, SLAVE_ID, 0, 115200, MB_PAR_NONE )) != MB_ENOERR )
goto FAIL_MB;
else if ( (eStatus = eMBEnable( ) ) != MB_ENOERR )
goto FAIL_MB_1;
else {
for( ;; )
{
xMBPortSerialPolling();
if ( eMBPoll( ) != MB_ENOERR ) break;
}
}
FAIL_MB_1:
eMBClose();
FAIL_MB:
for( ;; )
{
led2 = !led2;
Thread::wait(200);
}
}
eMBErrorCode
eMBRegInputCB( UCHAR * pucRegBuffer, USHORT usAddress, USHORT usNRegs )
{
eMBErrorCode eStatus = MB_ENOERR;
int iRegIndex;
if( ( usAddress >= REG_INPUT_START )
&& ( usAddress + usNRegs <= REG_INPUT_START + REG_INPUT_NREGS ) )
{
iRegIndex = ( int )( usAddress - usRegInputStart );
while( usNRegs > 0 )
{
*pucRegBuffer++ =
( unsigned char )( usRegInputBuf[iRegIndex] >> 8 );
*pucRegBuffer++ =
( unsigned char )( usRegInputBuf[iRegIndex] & 0xFF );
iRegIndex++;
usNRegs--;
}
}
else
{
eStatus = MB_ENOREG;
}
return eStatus;
}
eMBErrorCode
eMBRegHoldingCB( UCHAR * pucRegBuffer, USHORT usAddress, USHORT usNRegs, eMBRegisterMode eMode )
{
eMBErrorCode eStatus = MB_ENOERR;
int iRegIndex;
usRegInputBuf[eData_MBInCounter]++;
usRegInputBuf[eData_MBOutCounter]++;
if (eMode == MB_REG_READ)
{
if( ( usAddress >= REG_INPUT_START )
&& ( usAddress + usNRegs <= REG_INPUT_START + REG_INPUT_NREGS ) )
{
iRegIndex = ( int )( usAddress - usRegInputStart );
while( usNRegs > 0 )
{
*pucRegBuffer++ =
( unsigned char )( usRegInputBuf[iRegIndex] >> 8 );
*pucRegBuffer++ =
( unsigned char )( usRegInputBuf[iRegIndex] & 0xFF );
iRegIndex++;
usNRegs--;
}
}
}
if (eMode == MB_REG_WRITE)
{
if( ( usAddress >= REG_INPUT_START )
&& ( usAddress + usNRegs <= REG_INPUT_START + REG_INPUT_NREGS ) )
{
iRegIndex = ( int )( usAddress - usRegInputStart );
while( usNRegs > 0 )
{
usRegInputBuf[iRegIndex] = ((unsigned int) *pucRegBuffer << 8) | ((unsigned int) *(pucRegBuffer+1));
pucRegBuffer+=2;
iRegIndex++;
usNRegs--;
}
light_leds(); // Control LEDs
}
}
led3=!led3;
return eStatus;
}
eMBErrorCode
eMBRegCoilsCB( UCHAR * pucRegBuffer, USHORT usAddress, USHORT usNCoils,
eMBRegisterMode eMode )
{
return MB_ENOREG;
}
eMBErrorCode
eMBRegDiscreteCB( UCHAR * pucRegBuffer, USHORT usAddress, USHORT usNDiscrete )
{
return MB_ENOREG;
}