//debug code
int main(void){
char ch;
char string[20]; // global to assist in debugging
uint32_t n;
PLL_Init(Bus50MHz); // 50 MHz
UART_Init(); // initialize UART
OutCRLF();
for(ch='A'; ch<='Z'; ch=ch+1){// print the uppercase alphabet
UART_OutChar(ch);
}
OutCRLF();
UART_OutChar(' ');
for(ch='a'; ch<='z'; ch=ch+1){// print the lowercase alphabet
UART_OutChar(ch);
}
OutCRLF();
UART_OutChar('-');
UART_OutChar('-');
UART_OutChar('>');
while(1){
UART_OutString("InString: ");
UART_InString(string,19);
UART_OutString(" OutString="); UART_OutString(string); OutCRLF();
UART_OutString("InUDec: "); n=UART_InUDec();
UART_OutString(" OutUDec="); UART_OutUDec(n); OutCRLF();
UART_OutString("InUHex: "); n=UART_InUHex();
UART_OutString(" OutUHex="); UART_OutUHex(n); OutCRLF();
}
}
void UART_OutUDec(unsigned long n,int i){
if(n >= 10){
UART_OutUDec(n/10,i);
n = n%10;
}
switch(i)
{
case 1:
UART1_OutChar(n+'0'); /* n is between 0 and 9 */
break;
case 2:
UART2_OutChar(n+'0');
break;
case 3:
UART3_OutChar(n+'0');
break;
case 4:
UART4_OutChar(n+'0');
break;
case 5:
UART5_OutChar(n+'0');
break;
case 7:
UART7_OutChar(n+'0');
break;
}
}
//-----------------------UART_OutUDec-----------------------
// Output a 32-bit number in unsigned decimal format
// Input: 32-bit number to be transferred
// Output: none
// Variable format 1-10 digits with no space before or after
void UART_OutUDec(uint32_t n){
// This function uses recursion to convert decimal number
// of unspecified length as an ASCII string
if(n >= 10){
UART_OutUDec(n/10);
n = n%10;
}
UART_OutChar(n+'0'); /* n is between 0 and 9 */
}
// do not edit this main
// your job is to implement the UART_OutUDec UART_OutDistance functions
int main(void){ unsigned long n;
TExaS_Init(); // initialize grader, set system clock to 80 MHz
UART_Init(); // initialize UART
EnableInterrupts(); // needed for TExaS
UART_OutString("Running Lab 11");
while(1){
UART_OutString("\n\rInput:");
n = UART_InUDec();
UART_OutString(" UART_OutUDec = ");
UART_OutUDec(n); // your function
UART_OutString(", UART_OutDistance ~ ");
UART_OutDistance(n); // your function
}
}
void UART_OutUDec(long long n,int i)
{
if(n<0)
{
n=-n;
UART_OutChar('-',i);
}
if(n>=10)
{
UART_OutUDec(n/10,i);
n%=10;
}
UART_OutChar(n+'0',i);
}
int main(void){
PLL_Init();
SysTick_Init();
UART4_Init();
Edge_Detect_Init();
Timer_Capture_Init();
UART_OutUDec(1,4);
while(1)
{
SysTick_Wait10ms(100);
if(((1<<TIMER0_RIS_R)&(0x1)))
{
TIMER0_ICR_R|=(1<<1);
UART_OutUDec(TIMER0_TAR_R,4);
New_Line(4);
}
}
}
int main( void )
{
unsigned long * ptr;
unsigned char aux;
unsigned int tempo = 500;
IO_Init();
SysTick_Init_ms( tempo );
UART_Init_16MHz();
Nokia5110_Init();
Bluetooth_Init();
Nokia5110_OutString("SENAI");
for(;;)
{
if( UART_InCharAvailable() )
Bluetooth_OutChar( UART_InChar() );
if( Bluetooth_InCharAvailable() )
UART_OutChar ( aux = Bluetooth_InChar() );
if( SysTickRun() )
{
if( *ptr )
*ptr = 0x00;
else
*ptr = 0xFF;
}
switch( aux )
{
case 0:
case 'R': *ptr = 0x00; ptr = (unsigned long *)&LED_RED; break;
case 'B': *ptr = 0x00; ptr = (unsigned long *)&LED_BLUE; break;
case 'G': *ptr = 0x00; ptr = (unsigned long *)&LED_GREEN; break;
case 'Y': *ptr = 0x00; ptr = (unsigned long *)&LED_YELLOW; break;
case 'P': *ptr = 0x00; ptr = (unsigned long *)&LED_PINK; break;
case 'S': *ptr = 0x00; ptr = (unsigned long *)&LED_SKYBLUE; break;
case 'W': *ptr = 0x00; ptr = (unsigned long *)&LED_WHITE; break;
case 'D': *ptr = 0x00; ptr = (unsigned long *)&LED_DARK; break;
case 'T': DHT11_In( (unsigned long *) &sensor );
UART_OutString( "Temp: " );
UART_OutUDec( (unsigned long)sensor.temperatura );
UART_OutString( "\r\n" );
Bluetooth_OutString( "Temp: " );
Bluetooth_OutUDec( (unsigned long)sensor.temperatura );
Bluetooth_OutString( "\r\n" );
SysTick_Init_ms( tempo );
break;
case 'U': DHT11_In( (unsigned long *) &sensor );
UART_OutString( "Umidade: " );
UART_OutUDec( (unsigned long)sensor.umidade );
UART_OutString( "\r\n" );
Bluetooth_OutString( "Umidade: " );
Bluetooth_OutUDec( (unsigned long)sensor.umidade );
Bluetooth_OutString( "\r\n" );
SysTick_Init_ms( tempo );
break;
}
} //for(;;)
} //int main( void )
void Interpreter(void) // just a prototype, link to your interpreter
{
uint32_t stringSize;
uint32_t adcVoltage;
uint8_t deviceChosen;
uint8_t taskAddedBefore = 0;
uint8_t commandChosen = -1;
char message[MESSAGELENGTH] = "";
OutCRLF();
UART_OutString("Input Command: ");
while(1){
OutCRLF();
//UART_OutString("Commands: 0 - ADC, 1 - LCD, 2 - Time");
OutCRLF();
commandChosen = UART_InChar();
switch(commandChosen)
{
case '0':
OutCRLF();
UART_OutString("ADC Voltage = ");
//ADC_Open(4);
adcVoltage = (ADC_In() *3300) / 4095; //convert to mV
UART_OutUDec(adcVoltage);
OutCRLF();
break;
case '1':
OutCRLF();
UART_OutString("Enter LCD device 0 or 1: ");
deviceChosen = UART_InUDec();
OutCRLF();
UART_OutString("Enter message: ");
UART_InString(message, MESSAGELENGTH);
OutCRLF();
stringSize = strlen(message);
if(stringSize > 20)
{
OutCRLF();
UART_OutString("String too long...");
OutCRLF();
}
LCD_test(deviceChosen, message); //prints to lcd
OutCRLF();
break;
case '2':
if(!taskAddedBefore){
OS_AddPeriodicThread(dummy, 5, 1);
taskAddedBefore = 1;
}
OutCRLF();
UART_OutUDec(OS_ReadPeriodicTime());
OutCRLF();
break;
case '3':
UART_OutString("NumSamples: ");
UART_OutUDec(NumSamples);
OutCRLF();
break;
case '4':
UART_OutString("Jitter: ");
UART_OutUDec(MaxJitter);
OutCRLF();
break;
case '5':
UART_OutString("DataLost: ");
UART_OutUDec(DataLost);
OutCRLF();
break;
case '6':
UART_OutString("FilterWork: ");
UART_OutUDec(FilterWork);
OutCRLF();
break;
case '7':
UART_OutString("NumCreated: ");
UART_OutUDec(NumCreated);
OutCRLF();
break;
case '8':
for(int i = 0; i<64; i++)
{
UART_OutUDec(x[i]);
OutCRLF();
}
break;
default:
UART_OutString("Incorrect command!");
break;
}
//adcSample = ADC_In();
//ST7735_SetCursor(0,0);
//ST7735_OutUDec(adcSample);
}
}
//-----------------------UART_OutUDecNL-----------------------
// Runs UART_OutUDec() and adds a new line.
// Input: 32-bit number to be transferred
// Output: none
// Variable format 1-10 digits with no space before or after
void UART_OutUDecNL(uint32_t n){
UART_OutUDec(n);
UART_OutCRLF();
}
