esp-idf/examples/system/ulp_adc/main/ulp/adc.S
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ArmAsm

/* ULP Example: using ADC in deep sleep
This example code is in the Public Domain (or CC0 licensed, at your option.)
Unless required by applicable law or agreed to in writing, this
software is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR
CONDITIONS OF ANY KIND, either express or implied.
This file contains assembly code which runs on the ULP.
ULP wakes up to run this code at a certain period, determined by the values
in SENS_ULP_CP_SLEEP_CYCx_REG registers. On each wake up, the program
measures input voltage on the given ADC channel 'adc_oversampling_factor'
times. Measurements are accumulated and average value is calculated.
Average value is compared to the two thresholds: 'low_thr' and 'high_thr'.
If the value is less than 'low_thr' or more than 'high_thr', ULP wakes up
the chip from deep sleep.
*/
/* ULP assembly files are passed through C preprocessor first, so include directives
and C macros may be used in these files
*/
#include "soc/rtc_cntl_reg.h"
#include "soc/soc_ulp.h"
/* ADC1 channel 6, GPIO34 */
.set adc_channel, 6
/* Configure the number of ADC samples to average on each measurement.
For convenience, make it a power of 2. */
.set adc_oversampling_factor_log, 2
.set adc_oversampling_factor, (1 << adc_oversampling_factor_log)
/* Define variables, which go into .bss section (zero-initialized data) */
.bss
/* Low threshold of ADC reading.
Set by the main program. */
.global low_thr
low_thr:
.long 0
/* High threshold of ADC reading.
Set by the main program. */
.global high_thr
high_thr:
.long 0
/* Counter of measurements done */
.global sample_counter
sample_counter:
.long 0
.global last_result
last_result:
.long 0
/* Code goes into .text section */
.text
.global entry
entry:
/* increment sample counter */
move r3, sample_counter
ld r2, r3, 0
add r2, r2, 1
st r2, r3, 0
/* do measurements using ADC */
/* r0 will be used as accumulator */
move r0, 0
/* initialize the loop counter */
stage_rst
measure:
/* measure and add value to accumulator */
adc r1, 0, adc_channel + 1
add r0, r0, r1
/* increment loop counter and check exit condition */
stage_inc 1
jumps measure, adc_oversampling_factor, lt
/* divide accumulator by adc_oversampling_factor.
Since it is chosen as a power of two, use right shift */
rsh r0, r0, adc_oversampling_factor_log
/* averaged value is now in r0; store it into last_result */
move r3, last_result
st r0, r3, 0
/* compare with low_thr; wake up if value < low_thr */
move r3, low_thr
ld r3, r3, 0
sub r3, r0, r3
jump wake_up, ov
/* compare with high_thr; wake up if value > high_thr */
move r3, high_thr
ld r3, r3, 0
sub r3, r3, r0
jump wake_up, ov
/* value within range, end the program */
.global exit
exit:
halt
.global wake_up
wake_up:
/* Check if the system can be woken up */
READ_RTC_FIELD(RTC_CNTL_LOW_POWER_ST_REG, RTC_CNTL_RDY_FOR_WAKEUP)
and r0, r0, 1
jump exit, eq
/* Wake up the SoC, end program */
wake
WRITE_RTC_FIELD(RTC_CNTL_STATE0_REG, RTC_CNTL_ULP_CP_SLP_TIMER_EN, 0)
halt