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c_src/hal_stub.c

// SPDX-FileCopyrightText: 2018 Frank Hunleth, Mark Sebald, Matt Ludwigs
//
// SPDX-License-Identifier: Apache-2.0
#include "gpio_nif.h"
#include <string.h>
#define NUM_GPIOS 64
/**
* The stub hardware abstraction layer is suitable for some unit testing.
*
* gpiochip0 -> 32 GPIOs. GPIO 0 is connected to GPIO 1, 2 to 3, and so on.
* gpiochip1 -> 32 GPIOs. GPIO 0 is connected to GPIO 1, 2 to 3, and so on.
*/
struct stub_priv {
int value[NUM_GPIOS]; // -1, 0, 1 -> -1=hiZ
struct gpio_pin *gpio_pins[NUM_GPIOS];
ErlNifPid pid[NUM_GPIOS];
enum trigger_mode mode[NUM_GPIOS];
};
ERL_NIF_TERM hal_info(ErlNifEnv *env, void *hal_priv, ERL_NIF_TERM info)
{
(void) hal_priv;
enif_make_map_put(env, info, atom_name, enif_make_atom(env, "stub"), &info);
return info;
}
size_t hal_priv_size(void)
{
return sizeof(struct stub_priv);
}
int hal_load(void *hal_priv)
{
memset(hal_priv, 0, sizeof(struct stub_priv));
return 0;
}
void hal_unload(void *hal_priv)
{
(void) hal_priv;
}
int hal_open_gpio(struct gpio_pin *pin,
char *error_str,
ErlNifEnv *env)
{
struct stub_priv *hal_priv = pin->hal_priv;
int pin_base;
if (strcmp(pin->gpiochip, "gpiochip0") == 0 ||
strcmp(pin->gpiochip, "/dev/gpiochip0") == 0) {
pin_base = 0;
} else if (strcmp(pin->gpiochip, "gpiochip1") == 0 ||
strcmp(pin->gpiochip, "/dev/gpiochip1") == 0) {
pin_base = 32;
} else {
strcpy(error_str, "open_failed");
return -1;
}
if (pin->offset < 0 || pin->offset >= 32) {
strcpy(error_str, "invalid_pin");
return -1;
}
pin->pin_number = pin_base + pin->offset;
pin->fd = pin->pin_number;
hal_priv->gpio_pins[pin->pin_number] = pin;
if (pin->config.is_output) {
if (pin->config.initial_value >= 0) {
hal_write_gpio(pin, pin->config.initial_value, env);
} else if (hal_priv->value[pin->pin_number] == -1) {
// Default the pin to zero when hi impedance even
// when no initial value.
hal_write_gpio(pin, 0, env);
}
} else {
hal_priv->value[pin->pin_number] = -1;
}
*error_str = '\0';
return 0;
}
void hal_close_gpio(struct gpio_pin *pin)
{
if (pin->fd >= 0 && pin->fd < NUM_GPIOS) {
struct stub_priv *hal_priv = pin->hal_priv;
hal_priv->mode[pin->pin_number] = TRIGGER_NONE;
hal_priv->gpio_pins[pin->pin_number] = NULL;
pin->fd = -1;
}
}
int hal_read_gpio(struct gpio_pin *pin)
{
struct stub_priv *hal_priv = pin->hal_priv;
int our_pin = pin->pin_number;
int other_pin = our_pin ^ 1;
if (hal_priv->value[our_pin] != -1)
return hal_priv->value[our_pin];
if (hal_priv->value[other_pin] != -1)
return hal_priv->value[other_pin];
if (pin->config.pull == PULL_UP)
return 1;
if (pin->config.pull == PULL_DOWN)
return 0;
// Both the pin and the pin it's connected to are high impedance and pull mode
// isn't set. This should be random, but that might be more confusing so return 0.
return 0;
}
static void maybe_send_notification(ErlNifEnv *env, struct gpio_pin *pin, int value)
{
if (!pin)
return;
struct stub_priv *hal_priv = pin->hal_priv;
int send_it = 0;
switch (hal_priv->mode[pin->pin_number]) {
case TRIGGER_BOTH:
send_it = 1;
break;
case TRIGGER_FALLING:
send_it = (value == 0);
break;
case TRIGGER_RISING:
send_it = (value != 0);
break;
case TRIGGER_NONE:
send_it = 0;
break;
}
if (send_it) {
ErlNifTime now = enif_monotonic_time(ERL_NIF_NSEC);
send_gpio_message(env, pin->gpio_spec, &hal_priv->pid[pin->pin_number], now, value);
}
}
int hal_write_gpio(struct gpio_pin *pin, int value, ErlNifEnv *env)
{
struct stub_priv *hal_priv = pin->hal_priv;
int our_pin = pin->pin_number;
int other_pin = our_pin ^ 1;
if (hal_priv->value[our_pin] != value) {
hal_priv->value[our_pin] = value;
maybe_send_notification(env, hal_priv->gpio_pins[our_pin], value);
// Only notify other pin if it's not outputting a value.
if (hal_priv->value[other_pin] == -1)
maybe_send_notification(env, hal_priv->gpio_pins[other_pin], value);
}
return 0;
}
int hal_apply_interrupts(struct gpio_pin *pin, ErlNifEnv *env)
{
struct stub_priv *hal_priv = pin->hal_priv;
hal_priv->mode[pin->pin_number] = pin->config.trigger;
hal_priv->pid[pin->pin_number] = pin->config.pid;
hal_priv->gpio_pins[pin->pin_number] = pin;
return 0;
}
int hal_apply_direction(struct gpio_pin *pin)
{
struct stub_priv *hal_priv = pin->hal_priv;
if (pin->config.is_output) {
if (hal_priv->value[pin->pin_number] == -1) {
hal_priv->value[pin->pin_number] = 0;
}
} else {
hal_priv->value[pin->pin_number] = -1;
}
return 0;
}
int hal_apply_pull_mode(struct gpio_pin *pin)
{
(void) pin;
return 0;
}
ERL_NIF_TERM hal_enumerate(ErlNifEnv *env, void *hal_priv)
{
ERL_NIF_TERM gpio_list = enif_make_list(env, 0);
ERL_NIF_TERM chip_label = make_string_binary(env, "stub");
ERL_NIF_TERM chip_name0 = make_string_binary(env, "gpiochip0");
ERL_NIF_TERM chip_name1 = make_string_binary(env, "gpiochip1");
int j;
for (j = NUM_GPIOS - 1; j >= 0; j--) {
char line_name[32];
sprintf(line_name, "pair_%d_%d", j / 2, j % 2);
ERL_NIF_TERM chip_name = (j >= 32) ? chip_name1 : chip_name0;
ERL_NIF_TERM line_map = enif_make_new_map(env);
ERL_NIF_TERM line_label = make_string_binary(env, line_name);
ERL_NIF_TERM line_offset = enif_make_int(env, j % 32);
enif_make_map_put(env, line_map, atom_struct, atom_circuits_gpio_line, &line_map);
enif_make_map_put(env, line_map, atom_controller, chip_name, &line_map);
enif_make_map_put(env, line_map, atom_label, enif_make_tuple2(env, chip_label, line_label), &line_map);
enif_make_map_put(env, line_map, atom_gpio_spec, enif_make_tuple2(env, chip_name, line_offset), &line_map);
gpio_list = enif_make_list_cell(env, line_map, gpio_list);
}
return gpio_list;
}