int main(void)
{
qm_rtc_config_t rtc_cfg;
unsigned int count = 0;
/* loop_max : Maximum number of iterations.
* A value of 50 will run the application for roughly 30s.
*/
const unsigned int loop_max = 50;
gpio_init();
pin_mux_setup();
gpio_set_out(BOARD_LED_PIN, 0); /* Configure the onboard LED pin. */
/* Clear Screen. */
QM_PUTS("Starting: Power Profiler");
QM_PUTS("Low power mode example.");
QM_PRINTF("Increment = %d\n", QM_RTC_ALARM_SECOND(CLK_RTC_DIV_1));
clk_periph_enable(CLK_PERIPH_RTC_REGISTER | CLK_PERIPH_CLK);
/* Initialise RTC configuration: Run, but don't interrupt. */
rtc_cfg.init_val = 0;
rtc_cfg.alarm_en = 0;
rtc_cfg.alarm_val = QM_RTC_ALARM_SECOND(CLK_RTC_DIV_1);
rtc_cfg.callback = rtc_example_callback;
rtc_cfg.prescaler = CLK_RTC_DIV_1;
qm_rtc_set_config(QM_RTC_0, &rtc_cfg);
QM_IR_UNMASK_INT(QM_IRQ_RTC_0_INT);
QM_IRQ_REQUEST(QM_IRQ_RTC_0_INT, qm_rtc_0_isr);
#if (!QM_SENSOR)
test_clock_rates();
#endif
/* Enable the RTC Interrupt. */
rtc_cfg.alarm_en = 1;
qm_rtc_set_config(QM_RTC_0, &rtc_cfg);
count = 0;
while (++count < loop_max) {
QM_PRINTF("\nC:%d R:%d => ", count, rtc_tick);
slow_mode_test();
halt_test();
core_sleep_test();
/* TODO : Enable soc_sleep test for c1000. */
soc_sleep_test();
/* TODO : Enable soc_deep_sleep test for d2000 and c1000. */
soc_deep_sleep_test();
}
SOC_WATCH_TRIGGER_FLUSH();
QM_PUTS("Finished: Power Profiler");
return 0;
}
int main(void)
{
qm_rtc_config_t rtc_cfg;
unsigned int count = 0;
/* Maximum number of 3-second iterations. */
const unsigned int loop_max = 5;
gpio_init();
gpio_set_out(BOARD_LED_PIN, 0); /* Configure the onboard LED pin. */
/* Clear Screen. */
QM_PUTS("Starting: Power Profiler");
QM_PUTS("Low power mode example.");
QM_PRINTF("Increment = %d\n", QM_RTC_ALARM_SECOND(CLK_RTC_DIV_1));
clk_periph_enable(CLK_PERIPH_RTC_REGISTER | CLK_PERIPH_CLK);
/* Initialise RTC configuration: Run, but don't interrupt. */
rtc_cfg.init_val = 0;
rtc_cfg.alarm_en = 0;
rtc_cfg.alarm_val = QM_RTC_ALARM_SECOND(CLK_RTC_DIV_1);
rtc_cfg.callback = rtc_example_callback;
rtc_cfg.prescaler = CLK_RTC_DIV_1;
qm_rtc_set_config(QM_RTC_0, &rtc_cfg);
qm_irq_request(QM_IRQ_RTC_0_INT, qm_rtc_0_isr);
test_clock_rates();
/* Enable the RTC Interrupt. */
rtc_cfg.alarm_en = 1;
qm_rtc_set_config(QM_RTC_0, &rtc_cfg);
count = 0;
while (++count < loop_max) {
QM_PRINTF("\nC:%d R:%d => ", count, rtc_tick);
slow_mode_test();
halt_test();
sleep_test();
#if DEEP_SLEEP
deep_sleep_test();
#endif
}
QM_PUTS("Finished: Power Profiler");
return 0;
}
extern void
socle_cmd_power_manage ()
{
int ch;
while(1){
printf("=========================\n");
printf("Power Management Test\n");
printf("0.Stop mode test\n");
printf("1.Sleep mode test\n");
printf("2.Slow mode test\n");
printf("3.IP/PHY clock test\n");
printf("4.Test mode test (Disable all IP clock except sdram)\n");
printf("x.exit\n");
printf("PM>");
ch = getc();
printf("%c\n", ch);
switch(ch){
case '0':
stop_mode_test();
break;
case '1':
sleep_mode_test();
break;
case '2':
slow_mode_test();
break;
case '3':
ip_phy_clock_test();
break;
case '4':
test_mode_test();
break;
case 'x':
printf("exit power management test\n");
return ;
break;
default :
printf("error choose\n");
break;
}
}
return ;
}
