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qemu/tests/qtest/npcm7xx_adc-test.c

379 lines
11 KiB
C

/*
* QTests for Nuvoton NPCM7xx ADCModules.
*
* Copyright 2020 Google LLC
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*/
#include "qemu/osdep.h"
#include "qemu/bitops.h"
#include "qemu/timer.h"
#include "libqtest.h"
#include "qapi/qmp/qdict.h"
#define REF_HZ (25000000)
#define CON_OFFSET 0x0
#define DATA_OFFSET 0x4
#define NUM_INPUTS 8
#define DEFAULT_IREF 2000000
#define CONV_CYCLES 20
#define RESET_CYCLES 10
#define R0_INPUT 500000
#define R1_INPUT 1500000
#define MAX_RESULT 1023
#define DEFAULT_CLKDIV 5
#define FUSE_ARRAY_BA 0xf018a000
#define FCTL_OFFSET 0x14
#define FST_OFFSET 0x0
#define FADDR_OFFSET 0x4
#define FDATA_OFFSET 0x8
#define ADC_CALIB_ADDR 24
#define FUSE_READ 0x2
/* Register field definitions. */
#define CON_MUX(rv) ((rv) << 24)
#define CON_INT_EN BIT(21)
#define CON_REFSEL BIT(19)
#define CON_INT BIT(18)
#define CON_EN BIT(17)
#define CON_RST BIT(16)
#define CON_CONV BIT(13)
#define CON_DIV(rv) extract32(rv, 1, 8)
#define FST_RDST BIT(1)
#define FDATA_MASK 0xff
#define MAX_ERROR 10000
#define MIN_CALIB_INPUT 100000
#define MAX_CALIB_INPUT 1800000
static const uint32_t input_list[] = {
100000,
500000,
1000000,
1500000,
1800000,
2000000,
};
static const uint32_t vref_list[] = {
2000000,
2200000,
2500000,
};
static const uint32_t iref_list[] = {
1800000,
1900000,
2000000,
2100000,
2200000,
};
static const uint32_t div_list[] = {0, 1, 3, 7, 15};
typedef struct ADC {
int irq;
uint64_t base_addr;
} ADC;
ADC adc = {
.irq = 0,
.base_addr = 0xf000c000
};
static uint32_t adc_read_con(QTestState *qts, const ADC *adc)
{
return qtest_readl(qts, adc->base_addr + CON_OFFSET);
}
static void adc_write_con(QTestState *qts, const ADC *adc, uint32_t value)
{
qtest_writel(qts, adc->base_addr + CON_OFFSET, value);
}
static uint32_t adc_read_data(QTestState *qts, const ADC *adc)
{
return qtest_readl(qts, adc->base_addr + DATA_OFFSET);
}
static uint32_t adc_calibrate(uint32_t measured, uint32_t *rv)
{
return R0_INPUT + (R1_INPUT - R0_INPUT) * (int32_t)(measured - rv[0])
/ (int32_t)(rv[1] - rv[0]);
}
static void adc_qom_set(QTestState *qts, const ADC *adc,
const char *name, uint32_t value)
{
QDict *response;
const char *path = "/machine/soc/adc";
g_test_message("Setting properties %s of %s with value %u",
name, path, value);
response = qtest_qmp(qts, "{ 'execute': 'qom-set',"
" 'arguments': { 'path': %s, 'property': %s, 'value': %u}}",
path, name, value);
/* The qom set message returns successfully. */
g_assert_true(qdict_haskey(response, "return"));
qobject_unref(response);
}
static void adc_write_input(QTestState *qts, const ADC *adc,
uint32_t index, uint32_t value)
{
char name[100];
sprintf(name, "adci[%u]", index);
adc_qom_set(qts, adc, name, value);
}
static void adc_write_vref(QTestState *qts, const ADC *adc, uint32_t value)
{
adc_qom_set(qts, adc, "vref", value);
}
static uint32_t adc_calculate_output(uint32_t input, uint32_t ref)
{
uint32_t output;
g_assert_cmpuint(input, <=, ref);
output = (input * (MAX_RESULT + 1)) / ref;
if (output > MAX_RESULT) {
output = MAX_RESULT;
}
return output;
}
static uint32_t adc_prescaler(QTestState *qts, const ADC *adc)
{
uint32_t div = extract32(adc_read_con(qts, adc), 1, 8);
return 2 * (div + 1);
}
static int64_t adc_calculate_steps(uint32_t cycles, uint32_t prescale,
uint32_t clkdiv)
{
return (NANOSECONDS_PER_SECOND / (REF_HZ >> clkdiv)) * cycles * prescale;
}
static void adc_wait_conv_finished(QTestState *qts, const ADC *adc,
uint32_t clkdiv)
{
uint32_t prescaler = adc_prescaler(qts, adc);
/*
* ADC should takes roughly 20 cycles to convert one sample. So we assert it
* should take 10~30 cycles here.
*/
qtest_clock_step(qts, adc_calculate_steps(CONV_CYCLES / 2, prescaler,
clkdiv));
/* ADC is still converting. */
g_assert_true(adc_read_con(qts, adc) & CON_CONV);
qtest_clock_step(qts, adc_calculate_steps(CONV_CYCLES, prescaler, clkdiv));
/* ADC has finished conversion. */
g_assert_false(adc_read_con(qts, adc) & CON_CONV);
}
/* Check ADC can be reset to default value. */
static void test_init(gconstpointer adc_p)
{
const ADC *adc = adc_p;
QTestState *qts = qtest_init("-machine quanta-gsj");
adc_write_con(qts, adc, CON_REFSEL | CON_INT);
g_assert_cmphex(adc_read_con(qts, adc), ==, CON_REFSEL);
qtest_quit(qts);
}
/* Check ADC can convert from an internal reference. */
static void test_convert_internal(gconstpointer adc_p)
{
const ADC *adc = adc_p;
uint32_t index, input, output, expected_output;
QTestState *qts = qtest_init("-machine quanta-gsj");
qtest_irq_intercept_in(qts, "/machine/soc/a9mpcore/gic");
for (index = 0; index < NUM_INPUTS; ++index) {
for (size_t i = 0; i < ARRAY_SIZE(input_list); ++i) {
input = input_list[i];
expected_output = adc_calculate_output(input, DEFAULT_IREF);
adc_write_input(qts, adc, index, input);
adc_write_con(qts, adc, CON_MUX(index) | CON_REFSEL | CON_INT |
CON_EN | CON_CONV);
adc_wait_conv_finished(qts, adc, DEFAULT_CLKDIV);
g_assert_cmphex(adc_read_con(qts, adc), ==, CON_MUX(index) |
CON_REFSEL | CON_EN);
g_assert_false(qtest_get_irq(qts, adc->irq));
output = adc_read_data(qts, adc);
g_assert_cmpuint(output, ==, expected_output);
}
}
qtest_quit(qts);
}
/* Check ADC can convert from an external reference. */
static void test_convert_external(gconstpointer adc_p)
{
const ADC *adc = adc_p;
uint32_t index, input, vref, output, expected_output;
QTestState *qts = qtest_init("-machine quanta-gsj");
qtest_irq_intercept_in(qts, "/machine/soc/a9mpcore/gic");
for (index = 0; index < NUM_INPUTS; ++index) {
for (size_t i = 0; i < ARRAY_SIZE(input_list); ++i) {
for (size_t j = 0; j < ARRAY_SIZE(vref_list); ++j) {
input = input_list[i];
vref = vref_list[j];
expected_output = adc_calculate_output(input, vref);
adc_write_input(qts, adc, index, input);
adc_write_vref(qts, adc, vref);
adc_write_con(qts, adc, CON_MUX(index) | CON_INT | CON_EN |
CON_CONV);
adc_wait_conv_finished(qts, adc, DEFAULT_CLKDIV);
g_assert_cmphex(adc_read_con(qts, adc), ==,
CON_MUX(index) | CON_EN);
g_assert_false(qtest_get_irq(qts, adc->irq));
output = adc_read_data(qts, adc);
g_assert_cmpuint(output, ==, expected_output);
}
}
}
qtest_quit(qts);
}
/* Check ADC interrupt files if and only if CON_INT_EN is set. */
static void test_interrupt(gconstpointer adc_p)
{
const ADC *adc = adc_p;
uint32_t index, input, output, expected_output;
QTestState *qts = qtest_init("-machine quanta-gsj");
index = 1;
input = input_list[1];
expected_output = adc_calculate_output(input, DEFAULT_IREF);
qtest_irq_intercept_in(qts, "/machine/soc/a9mpcore/gic");
adc_write_input(qts, adc, index, input);
g_assert_false(qtest_get_irq(qts, adc->irq));
adc_write_con(qts, adc, CON_MUX(index) | CON_INT_EN | CON_REFSEL | CON_INT
| CON_EN | CON_CONV);
adc_wait_conv_finished(qts, adc, DEFAULT_CLKDIV);
g_assert_cmphex(adc_read_con(qts, adc), ==, CON_MUX(index) | CON_INT_EN
| CON_REFSEL | CON_INT | CON_EN);
g_assert_true(qtest_get_irq(qts, adc->irq));
output = adc_read_data(qts, adc);
g_assert_cmpuint(output, ==, expected_output);
qtest_quit(qts);
}
/* Check ADC is reset after setting ADC_RST for 10 ADC cycles. */
static void test_reset(gconstpointer adc_p)
{
const ADC *adc = adc_p;
QTestState *qts = qtest_init("-machine quanta-gsj");
for (size_t i = 0; i < ARRAY_SIZE(div_list); ++i) {
uint32_t div = div_list[i];
adc_write_con(qts, adc, CON_INT | CON_EN | CON_RST | CON_DIV(div));
qtest_clock_step(qts, adc_calculate_steps(RESET_CYCLES,
adc_prescaler(qts, adc), DEFAULT_CLKDIV));
g_assert_false(adc_read_con(qts, adc) & CON_EN);
}
qtest_quit(qts);
}
/* Check ADC Calibration works as desired. */
static void test_calibrate(gconstpointer adc_p)
{
int i, j;
const ADC *adc = adc_p;
for (j = 0; j < ARRAY_SIZE(iref_list); ++j) {
uint32_t iref = iref_list[j];
uint32_t expected_rv[] = {
adc_calculate_output(R0_INPUT, iref),
adc_calculate_output(R1_INPUT, iref),
};
char buf[100];
QTestState *qts;
sprintf(buf, "-machine quanta-gsj -global npcm7xx-adc.iref=%u", iref);
qts = qtest_init(buf);
/* Check the converted value is correct using the calibration value. */
for (i = 0; i < ARRAY_SIZE(input_list); ++i) {
uint32_t input;
uint32_t output;
uint32_t expected_output;
uint32_t calibrated_voltage;
uint32_t index = 0;
input = input_list[i];
/* Calibration only works for input range 0.1V ~ 1.8V. */
if (input < MIN_CALIB_INPUT || input > MAX_CALIB_INPUT) {
continue;
}
expected_output = adc_calculate_output(input, iref);
adc_write_input(qts, adc, index, input);
adc_write_con(qts, adc, CON_MUX(index) | CON_REFSEL | CON_INT |
CON_EN | CON_CONV);
adc_wait_conv_finished(qts, adc, DEFAULT_CLKDIV);
g_assert_cmphex(adc_read_con(qts, adc), ==,
CON_REFSEL | CON_MUX(index) | CON_EN);
output = adc_read_data(qts, adc);
g_assert_cmpuint(output, ==, expected_output);
calibrated_voltage = adc_calibrate(output, expected_rv);
g_assert_cmpuint(calibrated_voltage, >, input - MAX_ERROR);
g_assert_cmpuint(calibrated_voltage, <, input + MAX_ERROR);
}
qtest_quit(qts);
}
}
static void adc_add_test(const char *name, const ADC* wd,
GTestDataFunc fn)
{
g_autofree char *full_name = g_strdup_printf("npcm7xx_adc/%s", name);
qtest_add_data_func(full_name, wd, fn);
}
#define add_test(name, td) adc_add_test(#name, td, test_##name)
int main(int argc, char **argv)
{
g_test_init(&argc, &argv, NULL);
add_test(init, &adc);
add_test(convert_internal, &adc);
add_test(convert_external, &adc);
add_test(interrupt, &adc);
add_test(reset, &adc);
add_test(calibrate, &adc);
return g_test_run();
}