void InstructionPrinter::print_value(Value value) {
if (value == NULL) {
tty->print("NULL");
} else {
print_temp(value);
}
}
//**************************************************************
// main()
//**************************************************************
int main(){
#define Adresse 0x9E // evtl 9F für schreiben?
#define Read 1
#define Write 0
unsigned char ucTemp1,ucTemp2; // Deklaration der Variablen
display_init(); // Initialisiere Display
int i;
while(1) {
signed int avg = 0;
for(i = 0; i < 64; i++) {
// Setzen der Startbedingung und warten bis slave antwortet mit ACK0
while(i2c_start(Adresse+Read));
ucTemp1 = i2c_rbyte(0); // Erstes Byte einlesen
ucTemp2 = i2c_rbyte(1); // Zweites Byte einlesen
i2c_stop(); // I2C wieder freigeben
// Ausgabe der gelesenen Werte
display_set_cursor(0, 0);
print_temp(tempwert(ucTemp1, ucTemp2));
avg += tempwert(ucTemp1, ucTemp2);
delay5ms(100); // Verzögerung 100 ms
}
display_set_cursor(0, 1);
print_temp(avg >> 6);
}
while(1); // Endlosschleife
}
static int wil_temp_debugfs_show(struct seq_file *s, void *data)
{
struct wil6210_priv *wil = s->private;
u32 t_m, t_r;
int rc = wmi_get_temperature(wil, &t_m, &t_r);
if (rc) {
seq_printf(s, "Failed\n");
return 0;
}
print_temp(s, "MAC temperature :", t_m);
print_temp(s, "Radio temperature :", t_r);
return 0;
}
void print_readings(void) {
for (uint8_t i=0; i<nSensors; i++ ) {
logs_P("Sensor# ");
logi((int) i+1);
logs_P(" = ");
print_temp(readings[i].subzero, readings[i].cel, readings[i].cel_frac_bits);
logs_P("\r\n");
}
}
/*
* Intel specific log pages from
* http://www.intel.com/content/dam/www/public/us/en/documents/product-specifications/ssd-dc-p3700-spec.pdf
*
* Though the version as of this date has a typo for the size of log page 0xca,
* offset 147: it is only 1 byte, not 6.
*/
static void
print_intel_temp_stats(void *buf, uint32_t size __unused)
{
struct intel_log_temp_stats *temp = buf;
printf("Intel Temperature Log\n");
printf("=====================\n");
printf("Current: ");
print_temp(temp->current);
printf("Overtemp Last Flags %#jx\n", (uintmax_t)temp->overtemp_flag_last);
printf("Overtemp Lifetime Flags %#jx\n", (uintmax_t)temp->overtemp_flag_life);
printf("Max Temperature ");
print_temp(temp->max_temp);
printf("Min Temperature ");
print_temp(temp->min_temp);
printf("Max Operating Temperature ");
print_temp(temp->max_oper_temp);
printf("Min Operating Temperature ");
print_temp(temp->min_oper_temp);
printf("Estimated Temperature Offset: %ju C/K\n", (uintmax_t)temp->est_offset);
}
//*******************************************************************************************
//
// Function : standby_display
// Description : display board status such as AVR ip, server ip, countdown time, temparature
//
//*******************************************************************************************
void standby_display ( void )
{
BYTE generic_buf[64];
// update lcd display flag not set, exit from function
if ( flag1.bits.update_display == 0 )
return;
flag1.bits.update_display = 0;
// lcd display is displaying other information, wait until busy flag clear
if ( flag1.bits.lcd_busy )
return;
// now displaying menu information, wait until exit from menu
if ( menu_index )
return;
// display status on lcd line 1
lcd_putc ( '\f' );
lcd_print ( (BYTE*)standby_list[ standby_cursor - 1 ] );
// display status devices on lcd line 2
lcd_putc ( '\n' );
if ( standby_cursor == 1 )
{
print_devices (generic_buf,ind_device_cur);
}
// display avr ip
if ( standby_cursor == 2 )
{
print_ip ( generic_buf, (BYTE*)&avr_ip, 0 );
}
// display server ip
else if ( standby_cursor == 3 )
{
print_ip ( generic_buf, (BYTE*)&server_ip, 0 );
}
// display countdown timer
else if ( standby_cursor == 4 )
{
print_time ( generic_buf, count_time, 0 );
}
// display current temparature
else if ( standby_cursor == 5 )
{
print_temp ( generic_buf );
}
lcd_print ( generic_buf );
}
void InstructionPrinter::print_line(Instruction* instr) {
// print instruction data on one line
if (instr->is_pinned()) tty->put('.');
fill_to(bci_pos ); tty->print("%d", instr->bci());
fill_to(use_pos ); tty->print("%d", instr->use_count());
fill_to(temp_pos ); print_temp(instr);
fill_to(instr_pos); print_instr(instr);
tty->cr();
// add a line for StateSplit instructions w/ non-empty stacks
// (make it robust so we can print incomplete instructions)
StateSplit* split = instr->as_StateSplit();
if (split != NULL && split->state() != NULL && !split->state()->stack_is_empty()) {
fill_to(instr_pos); print_stack(split->state());
tty->cr();
}
}
void dump_waves(void) {
int i,j;
serial_puts("{\n");
for(i=0;i<8;i++) {
const struct wave_s *wv = waves+i;
char ebuf[] = "] },\n";
serial_puts(" \"");
serial_puts(wv->name);
serial_puts("\": {\n \"desc\": \"");
serial_puts(wv->desc);
serial_puts("\",\n \"pts\": [");
for(j=0;(j<48) && (wv->pt[j]);j++) {
char buf[]="123, ";
print_temp(buf,wv->pt[j]);
buf[3] = ((j<47) && (wv->pt[j+1])) ? ',' : 0;
serial_puts(buf);
}
ebuf[3] = i<7 ? ',' : ' ';
serial_puts(ebuf);
}
serial_puts("}\n");
}
/**
* \brief ADC interrupt handler.
*/
void ADC_Handler(void)
{
uint32_t ul_counter;
int32_t l_vol;
float f_temp;
uint32_t ul_value = 0;
uint32_t ul_temp_value = 0;
if ((adc_get_status(ADC) & ADC_ISR_RXBUFF) == ADC_ISR_RXBUFF) {
/* Multisample */
for (ul_counter = 0; ul_counter < BUFFER_SIZE; ul_counter++) {
ul_value += gs_s_adc_values[ul_counter];
}
/* Averaging */
ul_temp_value = ul_value / 10;
ul_value = ul_value / 100;
ul_temp_value -= (ul_value * 10);
/* Round for last decimal */
if (ul_temp_value > 4) {
ul_value++;
}
l_vol = ul_value * VOLT_REF / MAX_DIGITAL;
#if SAM3S | SAM3XA
/* Using multiplication (*0.37736) instead of division (/2.65). */
f_temp = (float)(l_vol - 800) * 0.37736 + 27.0;
#else
/* Using multiplication (*0.21186) instead of division (/4.72). */
f_temp = (float)(l_vol - 1440) * 0.21186 + 27.0;
#endif
print_temp(f_temp);
/* Clear the buffer. */
memset(gs_s_adc_values, 0x0, sizeof(gs_s_adc_values));
/* Start new pdc transfer. */
adc_read_buffer(ADC, gs_s_adc_values, BUFFER_SIZE);
}
}
static int wil_bf_debugfs_show(struct seq_file *s, void *data)
{
int rc;
int i;
struct wil6210_priv *wil = s->private;
struct wil6210_vif *vif = ndev_to_vif(wil->main_ndev);
struct wmi_notify_req_cmd cmd = {
.interval_usec = 0,
};
struct {
struct wmi_cmd_hdr wmi;
struct wmi_notify_req_done_event evt;
} __packed reply;
for (i = 0; i < ARRAY_SIZE(wil->sta); i++) {
u32 status;
cmd.cid = i;
rc = wmi_call(wil, WMI_NOTIFY_REQ_CMDID, vif->mid,
&cmd, sizeof(cmd),
WMI_NOTIFY_REQ_DONE_EVENTID, &reply,
sizeof(reply), 20);
/* if reply is all-0, ignore this CID */
if (rc || is_all_zeros(&reply.evt, sizeof(reply.evt)))
continue;
status = le32_to_cpu(reply.evt.status);
seq_printf(s, "CID %d {\n"
" TSF = 0x%016llx\n"
" TxMCS = %2d TxTpt = %4d\n"
" SQI = %4d\n"
" RSSI = %4d\n"
" Status = 0x%08x %s\n"
" Sectors(rx:tx) my %2d:%2d peer %2d:%2d\n"
" Goodput(rx:tx) %4d:%4d\n"
"}\n",
i,
le64_to_cpu(reply.evt.tsf),
le16_to_cpu(reply.evt.bf_mcs),
le32_to_cpu(reply.evt.tx_tpt),
reply.evt.sqi,
reply.evt.rssi,
status, wil_bfstatus_str(status),
le16_to_cpu(reply.evt.my_rx_sector),
le16_to_cpu(reply.evt.my_tx_sector),
le16_to_cpu(reply.evt.other_rx_sector),
le16_to_cpu(reply.evt.other_tx_sector),
le32_to_cpu(reply.evt.rx_goodput),
le32_to_cpu(reply.evt.tx_goodput));
}
return 0;
}
static int wil_bf_seq_open(struct inode *inode, struct file *file)
{
return single_open(file, wil_bf_debugfs_show, inode->i_private);
}
static const struct file_operations fops_bf = {
.open = wil_bf_seq_open,
.release = single_release,
.read = seq_read,
.llseek = seq_lseek,
};
/*---------temp------------*/
static void print_temp(struct seq_file *s, const char *prefix, u32 t)
{
switch (t) {
case 0:
case ~(u32)0:
seq_printf(s, "%s N/A\n", prefix);
break;
default:
seq_printf(s, "%s %d.%03d\n", prefix, t / 1000, t % 1000);
break;
}
}
static int wil_temp_debugfs_show(struct seq_file *s, void *data)
{
struct wil6210_priv *wil = s->private;
u32 t_m, t_r;
int rc = wmi_get_temperature(wil, &t_m, &t_r);
if (rc) {
seq_puts(s, "Failed\n");
return 0;
}
print_temp(s, "T_mac =", t_m);
print_temp(s, "T_radio =", t_r);
return 0;
}
static int wil_temp_seq_open(struct inode *inode, struct file *file)
{
return single_open(file, wil_temp_debugfs_show, inode->i_private);
}
static const struct file_operations fops_temp = {
.open = wil_temp_seq_open,
.release = single_release,
.read = seq_read,
.llseek = seq_lseek,
};
/*---------freq------------*/
static int wil_freq_debugfs_show(struct seq_file *s, void *data)
{
struct wil6210_priv *wil = s->private;
struct wireless_dev *wdev = wil->main_ndev->ieee80211_ptr;
u16 freq = wdev->chandef.chan ? wdev->chandef.chan->center_freq : 0;
seq_printf(s, "Freq = %d\n", freq);
return 0;
}
static int wil_freq_seq_open(struct inode *inode, struct file *file)
{
return single_open(file, wil_freq_debugfs_show, inode->i_private);
}
static const struct file_operations fops_freq = {
.open = wil_freq_seq_open,
.release = single_release,
.read = seq_read,
.llseek = seq_lseek,
};
/*---------link------------*/
static int wil_link_debugfs_show(struct seq_file *s, void *data)
{
struct wil6210_priv *wil = s->private;
struct station_info sinfo;
int i, rc;
for (i = 0; i < ARRAY_SIZE(wil->sta); i++) {
struct wil_sta_info *p = &wil->sta[i];
char *status = "unknown";
struct wil6210_vif *vif;
u8 mid;
switch (p->status) {
case wil_sta_unused:
status = "unused ";
break;
case wil_sta_conn_pending:
status = "pending ";
break;
case wil_sta_connected:
status = "connected";
break;
}
mid = (p->status != wil_sta_unused) ? p->mid : U8_MAX;
seq_printf(s, "[%d][MID %d] %pM %s\n",
i, mid, p->addr, status);
if (p->status != wil_sta_connected)
continue;
vif = (mid < wil->max_vifs) ? wil->vifs[mid] : NULL;
if (vif) {
rc = wil_cid_fill_sinfo(vif, i, &sinfo);
if (rc)
return rc;
seq_printf(s, " Tx_mcs = %d\n", sinfo.txrate.mcs);
seq_printf(s, " Rx_mcs = %d\n", sinfo.rxrate.mcs);
seq_printf(s, " SQ = %d\n", sinfo.signal);
} else {
seq_puts(s, " INVALID MID\n");
}
}
return 0;
}
static int wil_link_seq_open(struct inode *inode, struct file *file)
{
return single_open(file, wil_link_debugfs_show, inode->i_private);
}
static const struct file_operations fops_link = {
.open = wil_link_seq_open,
.release = single_release,
.read = seq_read,
.llseek = seq_lseek,
};
/*---------info------------*/
static int wil_info_debugfs_show(struct seq_file *s, void *data)
{
struct wil6210_priv *wil = s->private;
struct net_device *ndev = wil->main_ndev;
int is_ac = power_supply_is_system_supplied();
int rx = atomic_xchg(&wil->isr_count_rx, 0);
int tx = atomic_xchg(&wil->isr_count_tx, 0);
static ulong rxf_old, txf_old;
ulong rxf = ndev->stats.rx_packets;
ulong txf = ndev->stats.tx_packets;
unsigned int i;
/* >0 : AC; 0 : battery; <0 : error */
seq_printf(s, "AC powered : %d\n", is_ac);
seq_printf(s, "Rx irqs:packets : %8d : %8ld\n", rx, rxf - rxf_old);
seq_printf(s, "Tx irqs:packets : %8d : %8ld\n", tx, txf - txf_old);
rxf_old = rxf;
txf_old = txf;
#define CHECK_QSTATE(x) (state & BIT(__QUEUE_STATE_ ## x)) ? \
" " __stringify(x) : ""
for (i = 0; i < ndev->num_tx_queues; i++) {
struct netdev_queue *txq = netdev_get_tx_queue(ndev, i);
unsigned long state = txq->state;
seq_printf(s, "Tx queue[%i] state : 0x%lx%s%s%s\n", i, state,
CHECK_QSTATE(DRV_XOFF),
CHECK_QSTATE(STACK_XOFF),
CHECK_QSTATE(FROZEN)
);
}
#undef CHECK_QSTATE
return 0;
}
static int wil_info_seq_open(struct inode *inode, struct file *file)
{
return single_open(file, wil_info_debugfs_show, inode->i_private);
}
static const struct file_operations fops_info = {
.open = wil_info_seq_open,
.release = single_release,
.read = seq_read,
.llseek = seq_lseek,
};
/*---------recovery------------*/
/* mode = [manual|auto]
* state = [idle|pending|running]
*/
static ssize_t wil_read_file_recovery(struct file *file, char __user *user_buf,
size_t count, loff_t *ppos)
{
struct wil6210_priv *wil = file->private_data;
char buf[80];
int n;
static const char * const sstate[] = {"idle", "pending", "running"};
n = snprintf(buf, sizeof(buf), "mode = %s\nstate = %s\n",
no_fw_recovery ? "manual" : "auto",
sstate[wil->recovery_state]);
n = min_t(int, n, sizeof(buf));
return simple_read_from_buffer(user_buf, count, ppos,
buf, n);
}
static ssize_t wil_write_file_recovery(struct file *file,
const char __user *buf_,
size_t count, loff_t *ppos)
{
struct wil6210_priv *wil = file->private_data;
static const char run_command[] = "run";
char buf[sizeof(run_command) + 1]; /* to detect "runx" */
ssize_t rc;
if (wil->recovery_state != fw_recovery_pending) {
wil_err(wil, "No recovery pending\n");
return -EINVAL;
}
if (*ppos != 0) {
wil_err(wil, "Offset [%d]\n", (int)*ppos);
return -EINVAL;
}
if (count > sizeof(buf)) {
wil_err(wil, "Input too long, len = %d\n", (int)count);
return -EINVAL;
}
rc = simple_write_to_buffer(buf, sizeof(buf) - 1, ppos, buf_, count);
if (rc < 0)
return rc;
buf[rc] = '\0';
if (0 == strcmp(buf, run_command))
wil_set_recovery_state(wil, fw_recovery_running);
else
wil_err(wil, "Bad recovery command \"%s\"\n", buf);
return rc;
}
static const struct file_operations fops_recovery = {
.read = wil_read_file_recovery,
.write = wil_write_file_recovery,
.open = simple_open,
};
/*---------Station matrix------------*/
static void wil_print_rxtid(struct seq_file *s, struct wil_tid_ampdu_rx *r)
{
int i;
u16 index = ((r->head_seq_num - r->ssn) & 0xfff) % r->buf_size;
unsigned long long drop_dup = r->drop_dup, drop_old = r->drop_old;
seq_printf(s, "([%2d] %3d TU) 0x%03x [", r->buf_size, r->timeout,
r->head_seq_num);
for (i = 0; i < r->buf_size; i++) {
if (i == index)
seq_printf(s, "%c", r->reorder_buf[i] ? 'O' : '|');
else
seq_printf(s, "%c", r->reorder_buf[i] ? '*' : '_');
}
seq_printf(s,
"] total %llu drop %llu (dup %llu + old %llu) last 0x%03x\n",
r->total, drop_dup + drop_old, drop_dup, drop_old,
r->ssn_last_drop);
}
static void
print_log_health(void *buf, uint32_t size __unused)
{
struct nvme_health_information_page *health = buf;
char cbuf[UINT128_DIG + 1];
int i;
printf("SMART/Health Information Log\n");
printf("============================\n");
printf("Critical Warning State: 0x%02x\n",
health->critical_warning.raw);
printf(" Available spare: %d\n",
health->critical_warning.bits.available_spare);
printf(" Temperature: %d\n",
health->critical_warning.bits.temperature);
printf(" Device reliability: %d\n",
health->critical_warning.bits.device_reliability);
printf(" Read only: %d\n",
health->critical_warning.bits.read_only);
printf(" Volatile memory backup: %d\n",
health->critical_warning.bits.volatile_memory_backup);
printf("Temperature: ");
print_temp(health->temperature);
printf("Available spare: %u\n",
health->available_spare);
printf("Available spare threshold: %u\n",
health->available_spare_threshold);
printf("Percentage used: %u\n",
health->percentage_used);
printf("Data units (512,000 byte) read: %s\n",
uint128_to_str(to128(health->data_units_read), cbuf, sizeof(cbuf)));
printf("Data units written: %s\n",
uint128_to_str(to128(health->data_units_written), cbuf, sizeof(cbuf)));
printf("Host read commands: %s\n",
uint128_to_str(to128(health->host_read_commands), cbuf, sizeof(cbuf)));
printf("Host write commands: %s\n",
uint128_to_str(to128(health->host_write_commands), cbuf, sizeof(cbuf)));
printf("Controller busy time (minutes): %s\n",
uint128_to_str(to128(health->controller_busy_time), cbuf, sizeof(cbuf)));
printf("Power cycles: %s\n",
uint128_to_str(to128(health->power_cycles), cbuf, sizeof(cbuf)));
printf("Power on hours: %s\n",
uint128_to_str(to128(health->power_on_hours), cbuf, sizeof(cbuf)));
printf("Unsafe shutdowns: %s\n",
uint128_to_str(to128(health->unsafe_shutdowns), cbuf, sizeof(cbuf)));
printf("Media errors: %s\n",
uint128_to_str(to128(health->media_errors), cbuf, sizeof(cbuf)));
printf("No. error info log entries: %s\n",
uint128_to_str(to128(health->num_error_info_log_entries), cbuf, sizeof(cbuf)));
printf("Warning Temp Composite Time: %d\n", health->warning_temp_time);
printf("Error Temp Composite Time: %d\n", health->error_temp_time);
for (i = 0; i < 7; i++) {
if (health->temp_sensor[i] == 0)
continue;
printf("Temperature Sensor %d: ", i + 1);
print_temp(health->temp_sensor[i]);
}
}
int main(void) {
uint32_t ui32ADC0Value[4];
ui32TempSet = 25;
// Set System CLock
SysCtlClockSet(SYSCTL_SYSDIV_5 | SYSCTL_USE_PLL | SYSCTL_OSC_MAIN | SYSCTL_XTAL_16MHZ);
// Enaable UART
SysCtlPeripheralEnable(SYSCTL_PERIPH_UART0);
// Enable GPIO
SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOA);
// Enable ADC Peripheral
SysCtlPeripheralEnable(SYSCTL_PERIPH_ADC0);
//Allow the ADC12 to run at its default rate of 1Msps.
ADCSequenceConfigure(ADC0_BASE, 1, ADC_TRIGGER_PROCESSOR, 0);
//our code will average all four samples of temperature sensor data ta on sequencer 1 to calculate the temperature, so all four sequencer steps will measure the temperature sensor
ADCSequenceStepConfigure(ADC0_BASE, 1, 0, ADC_CTL_TS);
ADCSequenceStepConfigure(ADC0_BASE, 1, 1, ADC_CTL_TS);
ADCSequenceStepConfigure(ADC0_BASE, 1, 2, ADC_CTL_TS);
ADCSequenceStepConfigure(ADC0_BASE,1,3,ADC_CTL_TS|ADC_CTL_IE|ADC_CTL_END);
//enable ADC sequencer 1.
ADCSequenceEnable(ADC0_BASE, 1);
GPIOPinConfigure(GPIO_PA0_U0RX);
GPIOPinConfigure(GPIO_PA1_U0TX);
GPIOPinTypeUART(GPIO_PORTA_BASE, GPIO_PIN_0 | GPIO_PIN_1);
IntMasterEnable();
IntEnable(INT_UART0);
UARTIntEnable(UART0_BASE, UART_INT_RX | UART_INT_RT);
SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOF);
GPIOPinTypeGPIOOutput(GPIO_PORTF_BASE, GPIO_PIN_2|GPIO_PIN_1|GPIO_PIN_3);
// Set bit rate fr serial communication
UARTConfigSetExpClk(UART0_BASE, SysCtlClockGet(), 115200,(UART_CONFIG_WLEN_8 | UART_CONFIG_STOP_ONE | UART_CONFIG_PAR_NONE));
while (1)
{
//indication that the ADC conversion process is complete
ADCIntClear(ADC0_BASE, 1);
//trigger the ADC conversion with software
ADCProcessorTrigger(ADC0_BASE, 1);
//wait for the conversion to complete
while(!ADCIntStatus(ADC0_BASE, 1, false))
{
}
//read the ADC value from the ADC Sample Sequencer 1 FIFO
ADCSequenceDataGet(ADC0_BASE, 1, ui32ADC0Value);
ui32TempAvg = (ui32ADC0Value[0] + ui32ADC0Value[1] + ui32ADC0Value[2] + ui32ADC0Value[3] + 2)/4;
ui32TempValueC = (1475 - ((2475 * ui32TempAvg)) / 4096)/10;
ui32TempValueF = ((ui32TempValueC * 9) + 160) / 5;
print_temp(ui32TempValueC);
SysCtlDelay(SysCtlClockGet() / 3); //delay ~1 sec
if(ui32TempValueC < ui32TempSet)
GPIOPinWrite(GPIO_PORTF_BASE, GPIO_PIN_1|GPIO_PIN_2|GPIO_PIN_3, 8);
else
GPIOPinWrite(GPIO_PORTF_BASE, GPIO_PIN_1|GPIO_PIN_2|GPIO_PIN_3, 2);
}
}
int main(void)
{
char str[] = "123 123\n";
uint32_t adc[2];
serial_init(19200); /* baud rate setting */
T0PR = (Fosc/1000)-1; /* 1ms granularity for both timers */
T1PR = (Fosc/1000)-1;
T0TCR = 1;
T1TCR = 0;
T1TC = 0;
// AD0.1, AD0.2
PINSEL1 = (1 << 24) | (1 << 26);
IODIR0 = FAN_BIT | LAMP_BIT | BEEP_BIT;
IOSET0 = FAN_BIT | LAMP_BIT | BEEP_BIT;
delay_ms(100);
BEEP_OFF;
delay_ms(100);
BEEP_ON;
delay_ms(100);
BEEP_OFF;
do {
uint8_t rb=0;
for(; U0LSR & 0x01; rb=U0RBR) {}
if ((rb >= '0') && (rb <= '3')) {
T1TC = 0;
if (rb & 1) {
LAMP_ON;
T1TCR = 1;
} else {
LAMP_OFF;
}
if (rb & 2) {
FAN_ON;
T1TCR = 1;
} else {
FAN_OFF;
}
}
else if(rb == 'W')
dump_waves();
// 3 seconds timeout
if ((T1TCR) && (T1TC >= 3000)) {
IOSET0 = LAMP_BIT | FAN_BIT;
T1TCR = 0;
T1TC = 0;
}
adc[0] = read_adc(1);
adc[1] = read_adc(2);
if((rb) && (rb!='W')) {
print_temp(str, adc[0]);
print_temp(str + 4, adc[1]);
serial_puts(str);
}
} while ((adc[0] < MAXTEMP) && (adc[1] < MAXTEMP));
/* safeguard */
IODIR0 = LAMP_BIT | FAN_BIT | BEEP_BIT;
// lamp off, beeper on, fan on
IOSET0 = LAMP_BIT | BEEP_BIT;
IOCLR0 = FAN_BIT;
while (1) {
}
return 0; /* never reached */
}
int main(void)
{
CURL *curl_handle;
CURLcode res;
char *townName = (char *) secure_malloc(1);
char readKeyBoard_char=' ';
size_t townName_size=1;
int choice=TOWN_NAME;
char *name_validity_pointer=NULL;
int query_strin_Size=strlen(initValue_queryValue)+1;
char *query_string=(char *)secure_malloc(query_strin_Size);
struct MemoryStruct chunk;
secure_strcpy(query_string,initValue_queryValue);
////////////////////////////////begin big while LOOP
while(1)
{
switch(choice)
{
case PRINT_TEMPERATURE:
system("cls");
print_temp(chunk.memory);
printf("\nPress anything to go back..");
_getch();
break;
case PRINT_HUMIDITY:
system("cls");
print_humidity(chunk.memory);
printf("\nPress anything to back..");
_getch();
break;
case TOWN_NAME:
name_validity_pointer= NULL;
while(name_validity_pointer==NULL){
chunk.memory =(char*) secure_malloc(1); /* will be grown as needed by the realloc above */
chunk.size = 0; /* no data at this point */
curl_global_init(CURL_GLOBAL_ALL);
/* init the curl session */
curl_handle = curl_easy_init();
/* specify URL to get */
printf("\nplease enter townName:");
if(townName)
{
free(townName);
townName=NULL;
}
townName_size=1;
readKeyBoard_char=' ';
townName=(char *) secure_malloc(1);
while(1)
{
readKeyBoard_char=_getch();
if((int)readKeyBoard_char == ASCII_Code_ENTER)
break;
printf("%c",readKeyBoard_char);
townName[townName_size-1]=readKeyBoard_char;
townName[townName_size]='\0';
townName_size++;
townName=(char *) realloc(townName,townName_size+1);
}
townName[townName_size]='\0';
secure_strcpy(query_string,initValue_queryValue);
query_strin_Size = strlen(initValue_queryValue)+townName_size+strlen(lastPart_queryValue)+1;
query_string=(char *) realloc(query_string,query_strin_Size);
strcat_s(query_string,townName_size,townName);
strcat_s(query_string,strlen(lastPart_queryValue),lastPart_queryValue);
query_string[query_strin_Size]='\0';
curl_easy_setopt(curl_handle, CURLOPT_URL, query_string);
/* send all data to this function */
curl_easy_setopt(curl_handle, CURLOPT_WRITEFUNCTION, WriteMemoryCallback);
/* we pass our 'chunk' struct to the callback function */
curl_easy_setopt(curl_handle, CURLOPT_WRITEDATA, (void *)&chunk);
/* some servers don't like requests that are made without a user-agent
field, so we provide one */
curl_easy_setopt(curl_handle, CURLOPT_USERAGENT, "libcurl-agent/1.0");
/* get it! */
res = curl_easy_perform(curl_handle);
/* check for errors */
if(res != CURLE_OK) {
fprintf(stderr, "Connection to the server failed: %s\n", curl_easy_strerror(res));
}
else {
/*
* Now, our chunk.memory points to a memory block that is chunk.size
* bytes big and contains the remote file.*/
name_validity_pointer=strstr(chunk.memory,"Error: Not found city");
if(name_validity_pointer!=NULL)
{
printf("please enter a valid town name ,you have entered %s\n",townName);
free_dynamicVar(chunk.memory);
name_validity_pointer=NULL;
}
else{
name_validity_pointer = (char *) !NULL;
}
}
}
printf("\nThe town name %s is accepted",townName);
Sleep(SECOND);
break;
case ABOUT_APPLICATION:
system("cls");
printAbout();
printf("\nPress anything to back..");
_getch();
break;
case EXIT:
printf("Please enter any key to exit the Weather Application..");
_getch();
break;
}
if(choice == EXIT)
break;
system("cls");
printf("Welcome to Embedded Weather Station !\n");
printf("************The Menu ***************\n");
printf("1) Consult the temperature\n");
printf("2) Consult the humidity\n");
printf("3) change the town's name\n");
printf("4) About the application\n");
printf("5) exit the application\n");
printf("\nPlease enter a valid choice: (between 1 and 5):");
choice = DEFAULT;
choice = (int)_getch() - ASCII_Code_0;
while((choice < PRINT_TEMPERATURE) || (choice > EXIT))
{
choice=(int)getchar()-ASCII_Code_0;
}
}
///////////////////////////////end big while
/* cleanup curl stuff */
curl_easy_cleanup(curl_handle);
free_dynamicVar(chunk.memory);
free_dynamicVar(query_string);
/* we're done with libcurl, so clean it up */
curl_global_cleanup();
return 0;
}
