/* * Copyright (c) 2020 Friedt Professional Engineering Services, Inc * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT zephyr_gpio_emul #include #include #include #include #include #include #include #define LOG_LEVEL CONFIG_GPIO_LOG_LEVEL #include LOG_MODULE_REGISTER(gpio_emul); #define GPIO_EMUL_INT_BITMASK \ (GPIO_INT_DISABLE | GPIO_INT_ENABLE | GPIO_INT_LEVELS_LOGICAL | \ GPIO_INT_EDGE | GPIO_INT_LOW_0 | GPIO_INT_HIGH_1) /** * @brief GPIO Emulator interrupt capabilities * * These enumerations are used as a bitmask and allow the GPIO Emulator to * model GPIO interrupt controllers with varying interrupt trigger support. * * For example, some controllers to not support level interrupts, * some controllers do not support rising and falling edge simultaneously, * etc. * * This primarily affects the behaviour of @ref gpio_pin_interrupt_configure. */ enum gpio_emul_interrupt_cap { GPIO_EMUL_INT_CAP_EDGE_RISING = 1, GPIO_EMUL_INT_CAP_EDGE_FALLING = 2, GPIO_EMUL_INT_CAP_LEVEL_HIGH = 16, GPIO_EMUL_INT_CAP_LEVEL_LOW = 32, }; /** * @brief Emulated GPIO controller configuration data * * This structure contains all of the state for a given emulated GPIO * controller as well as all of the pins associated with it. * * The @a flags member is a pointer to an array which is @a num_pins in size. * * @a num_pins must be in the range [1, @ref GPIO_MAX_PINS_PER_PORT]. * * Pin direction as well as other pin properties are set using * specific bits in @a flags. For more details, see @ref gpio_interface. * * Changes are synchronized using @ref gpio_emul_data.mu. */ struct gpio_emul_config { /** Common @ref gpio_driver_config */ const struct gpio_driver_config common; /** Number of pins available in the given GPIO controller instance */ const gpio_pin_t num_pins; /** Supported interrupts */ const enum gpio_emul_interrupt_cap interrupt_caps; }; /** * @brief Emulated GPIO controller data * * This structure contains data structures used by a emulated GPIO * controller. * * If the application wishes to specify a "wiring" for the emulated * GPIO, then a @ref gpio_callback_handler_t should be registered using * @ref gpio_add_callback. * * Changes are to @ref gpio_emul_data and @ref gpio_emul_config are * synchronized using @a k_spinlock. */ struct gpio_emul_data { /** Common @ref gpio_driver_data */ struct gpio_driver_data common; /** Pointer to an array of flags is @a num_pins in size */ gpio_flags_t *flags; /** Input values for each pin */ gpio_port_value_t input_vals; /** Output values for each pin */ gpio_port_value_t output_vals; /** Interrupt status for each pin */ gpio_port_pins_t interrupts; /** Spinlock to synchronize accesses to driver data and config */ struct k_spinlock lock; /** Is interrupt enabled for each pin */ gpio_port_pins_t enabled_interrupts; /** Singly-linked list of callbacks associated with the controller */ sys_slist_t callbacks; }; /** * @brief Obtain a mask of pins that match all of the provided @p flags * * Use this function to see which pins match the current GPIO configuration. * * The caller must ensure that @ref gpio_emul_data.lock is locked. * * @param port The emulated GPIO device pointer * @param mask A mask of flags to match * @param flags The flags to match * * @return a mask of the pins with matching @p flags */ static gpio_port_pins_t get_pins_with_flags(const struct device *port, gpio_port_pins_t mask, gpio_flags_t flags) { size_t i; gpio_port_pins_t matched = 0; struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; for (i = 0; i < config->num_pins; ++i) { if ((drv_data->flags[i] & mask) == flags) { matched |= BIT(i); } } return matched; } /** * @brief Obtain a mask of pins that are configured as @ref GPIO_INPUT * * The caller must ensure that @ref gpio_emul_data.lock is locked. * * @param port The emulated GPIO device pointer * * @return a mask of pins that are configured as @ref GPIO_INPUT */ static inline gpio_port_pins_t get_input_pins(const struct device *port) { return get_pins_with_flags(port, GPIO_INPUT, GPIO_INPUT); } /** * @brief Obtain a mask of pins that are configured as @ref GPIO_OUTPUT * * The caller must ensure that @ref gpio_emul_data.lock is locked. * * @param port The emulated GPIO device pointer * * @return a mask of pins that are configured as @ref GPIO_OUTPUT */ static inline gpio_port_pins_t get_output_pins(const struct device *port) { return get_pins_with_flags(port, GPIO_OUTPUT, GPIO_OUTPUT); } /** * Check if @p port has capabilities specified in @p caps * * @param port The emulated GPIO device pointer * @param caps A bitmask of @ref gpio_emul_interrupt_cap * * @return true if all @p caps are present, otherwise false */ static inline bool gpio_emul_config_has_caps(const struct device *port, int caps) { const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; return (caps & config->interrupt_caps) == caps; } /* * GPIO backend API (for setting input pin values) */ static void gpio_emul_gen_interrupt_bits(const struct device *port, gpio_port_pins_t mask, gpio_port_value_t prev_values, gpio_port_value_t values, gpio_port_pins_t *interrupts, bool detect_edge) { size_t i; bool bit; bool prev_bit; struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; for (i = 0, *interrupts = 0; mask && i < config->num_pins; ++i, mask >>= 1, prev_values >>= 1, values >>= 1) { if ((mask & 1) == 0) { continue; } prev_bit = ((prev_values & 1) != 0); bit = ((values & 1) != 0); switch (drv_data->flags[i] & GPIO_EMUL_INT_BITMASK) { case GPIO_INT_EDGE_RISING: if (gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_EDGE_RISING)) { if (detect_edge && !prev_bit && bit) { drv_data->interrupts |= BIT(i); *interrupts |= (BIT(i) & drv_data->enabled_interrupts); } } break; case GPIO_INT_EDGE_FALLING: if (gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_EDGE_FALLING)) { if (detect_edge && prev_bit && !bit) { drv_data->interrupts |= BIT(i); *interrupts |= (BIT(i) & drv_data->enabled_interrupts); } } break; case GPIO_INT_EDGE_BOTH: if (gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_EDGE_RISING | GPIO_EMUL_INT_CAP_EDGE_FALLING)) { if (detect_edge && prev_bit != bit) { drv_data->interrupts |= BIT(i); *interrupts |= (BIT(i) & drv_data->enabled_interrupts); } } break; case GPIO_INT_LEVEL_LOW: if (gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_LEVEL_LOW)) { if (!bit) { drv_data->interrupts |= BIT(i); *interrupts |= (BIT(i) & drv_data->enabled_interrupts); } } break; case GPIO_INT_LEVEL_HIGH: if (gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_LEVEL_HIGH)) { if (bit) { drv_data->interrupts |= BIT(i); *interrupts |= (BIT(i) & drv_data->enabled_interrupts); } } break; case 0: case GPIO_INT_DISABLE: break; default: LOG_DBG("unhandled case %u", drv_data->flags[i] & GPIO_EMUL_INT_BITMASK); break; } } } /** * @brief Trigger possible interrupt events after an input pin has changed * * For more information, see @ref gpio_interface. * * The caller must ensure that @ref gpio_emul_data.lock is locked. * * @param port The emulated GPIO port * @param mask The mask of pins that have changed * @param prev_values Previous pin values * @param values Current pin values */ static void gpio_emul_pend_interrupt(const struct device *port, gpio_port_pins_t mask, gpio_port_value_t prev_values, gpio_port_value_t values) { gpio_port_pins_t interrupts; struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; key = k_spin_lock(&drv_data->lock); gpio_emul_gen_interrupt_bits(port, mask, prev_values, values, &interrupts, true); while (interrupts != 0) { k_spin_unlock(&drv_data->lock, key); gpio_fire_callbacks(&drv_data->callbacks, port, interrupts); key = k_spin_lock(&drv_data->lock); /* Clear handled interrupts */ drv_data->interrupts &= ~interrupts; gpio_emul_gen_interrupt_bits(port, mask, prev_values, values, &interrupts, false); } k_spin_unlock(&drv_data->lock, key); } int gpio_emul_input_set_masked_int(const struct device *port, gpio_port_pins_t mask, gpio_port_value_t values) { gpio_port_pins_t input_mask; gpio_port_pins_t prev_values; struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; if (mask == 0) { return 0; } if (~config->common.port_pin_mask & mask) { LOG_ERR("Pin not supported port_pin_mask=%x mask=%x", config->common.port_pin_mask, mask); return -EINVAL; } input_mask = get_input_pins(port); if (~input_mask & mask) { LOG_ERR("Not input pin input_mask=%x mask=%x", input_mask, mask); return -EINVAL; } prev_values = drv_data->input_vals; drv_data->input_vals &= ~mask; drv_data->input_vals |= values & mask; return 0; } /* documented in drivers/gpio/gpio_emul.h */ int gpio_emul_input_set_masked(const struct device *port, gpio_port_pins_t mask, gpio_port_value_t values) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; gpio_port_pins_t prev_input_values; gpio_port_pins_t input_values; k_spinlock_key_t key; int rv; key = k_spin_lock(&drv_data->lock); prev_input_values = drv_data->input_vals; rv = gpio_emul_input_set_masked_int(port, mask, values); input_values = drv_data->input_vals; k_spin_unlock(&drv_data->lock, key); if (rv) { return rv; } gpio_emul_pend_interrupt(port, mask, prev_input_values, input_values); return 0; } /* documented in drivers/gpio/gpio_emul.h */ int gpio_emul_output_get_masked(const struct device *port, gpio_port_pins_t mask, gpio_port_value_t *values) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; k_spinlock_key_t key; if (mask == 0) { return 0; } if (~config->common.port_pin_mask & mask) { return -EINVAL; } key = k_spin_lock(&drv_data->lock); *values = drv_data->output_vals & get_output_pins(port); k_spin_unlock(&drv_data->lock, key); return 0; } /* documented in drivers/gpio/gpio_emul.h */ int gpio_emul_flags_get(const struct device *port, gpio_pin_t pin, gpio_flags_t *flags) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; k_spinlock_key_t key; if (flags == NULL) { return -EINVAL; } if ((config->common.port_pin_mask & BIT(pin)) == 0) { return -EINVAL; } key = k_spin_lock(&drv_data->lock); *flags = drv_data->flags[pin]; k_spin_unlock(&drv_data->lock, key); return 0; } /* * GPIO Driver API * * API is documented at drivers/gpio.h */ static int gpio_emul_pin_configure(const struct device *port, gpio_pin_t pin, gpio_flags_t flags) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; k_spinlock_key_t key; int rv; if (flags & GPIO_OPEN_DRAIN) { return -ENOTSUP; } if (flags & GPIO_OPEN_SOURCE) { return -ENOTSUP; } if ((config->common.port_pin_mask & BIT(pin)) == 0) { return -EINVAL; } key = k_spin_lock(&drv_data->lock); drv_data->flags[pin] = flags; if (flags & GPIO_OUTPUT) { if (flags & GPIO_OUTPUT_INIT_LOW) { drv_data->output_vals &= ~BIT(pin); if (flags & GPIO_INPUT) { /* for push-pull mode to generate interrupts */ rv = gpio_emul_input_set_masked_int( port, BIT(pin), drv_data->output_vals); __ASSERT_NO_MSG(rv == 0); } } else if (flags & GPIO_OUTPUT_INIT_HIGH) { drv_data->output_vals |= BIT(pin); if (flags & GPIO_INPUT) { /* for push-pull mode to generate interrupts */ rv = gpio_emul_input_set_masked_int( port, BIT(pin), drv_data->output_vals); __ASSERT_NO_MSG(rv == 0); } } } else if (flags & GPIO_INPUT) { if (flags & GPIO_PULL_UP) { rv = gpio_emul_input_set_masked_int(port, BIT(pin), BIT(pin)); __ASSERT_NO_MSG(rv == 0); } else if (flags & GPIO_PULL_DOWN) { rv = gpio_emul_input_set_masked_int( port, BIT(pin), 0); __ASSERT_NO_MSG(rv == 0); } } k_spin_unlock(&drv_data->lock, key); gpio_fire_callbacks(&drv_data->callbacks, port, BIT(pin)); /* GPIO pin configuration changed so clear the pending interrupt. */ drv_data->interrupts &= ~((gpio_port_pins_t)BIT(pin)); return 0; } #ifdef CONFIG_GPIO_GET_CONFIG static int gpio_emul_pin_get_config(const struct device *port, gpio_pin_t pin, gpio_flags_t *out_flags) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; key = k_spin_lock(&drv_data->lock); *out_flags = drv_data->flags[pin] & ~(GPIO_OUTPUT_INIT_LOW | GPIO_OUTPUT_INIT_HIGH | GPIO_OUTPUT_INIT_LOGICAL); if (drv_data->flags[pin] & GPIO_OUTPUT) { if (drv_data->output_vals & BIT(pin)) { *out_flags |= GPIO_OUTPUT_HIGH; } else { *out_flags |= GPIO_OUTPUT_LOW; } } k_spin_unlock(&drv_data->lock, key); return 0; } #endif static int gpio_emul_port_get_raw(const struct device *port, gpio_port_value_t *values) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; if (values == NULL) { return -EINVAL; } key = k_spin_lock(&drv_data->lock); *values = drv_data->input_vals & get_input_pins(port); k_spin_unlock(&drv_data->lock, key); return 0; } static int gpio_emul_port_set_masked_raw(const struct device *port, gpio_port_pins_t mask, gpio_port_value_t values) { gpio_port_pins_t output_mask; gpio_port_pins_t prev_values; gpio_port_pins_t prev_input_values; gpio_port_pins_t input_values; gpio_port_pins_t input_mask; struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; int rv; key = k_spin_lock(&drv_data->lock); output_mask = get_output_pins(port); mask &= output_mask; prev_values = drv_data->output_vals; prev_values &= output_mask; values &= mask; drv_data->output_vals &= ~mask; drv_data->output_vals |= values; /* in push-pull, set input values & fire interrupts */ prev_input_values = drv_data->input_vals; input_mask = mask & get_input_pins(port); rv = gpio_emul_input_set_masked_int(port, input_mask, drv_data->output_vals); input_values = drv_data->input_vals; k_spin_unlock(&drv_data->lock, key); __ASSERT_NO_MSG(rv == 0); gpio_emul_pend_interrupt(port, input_mask, prev_input_values, input_values); /* for output-wiring, so the user can take action based on output */ if (prev_values ^ values) { gpio_fire_callbacks(&drv_data->callbacks, port, mask & ~get_input_pins(port)); } return 0; } static int gpio_emul_port_set_bits_raw(const struct device *port, gpio_port_pins_t pins) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; gpio_port_pins_t prev_input_values; gpio_port_pins_t input_values; gpio_port_pins_t input_mask; int rv; key = k_spin_lock(&drv_data->lock); pins &= get_output_pins(port); drv_data->output_vals |= pins; prev_input_values = drv_data->input_vals; input_mask = pins & get_input_pins(port); rv = gpio_emul_input_set_masked_int(port, input_mask, drv_data->output_vals); input_values = drv_data->input_vals; k_spin_unlock(&drv_data->lock, key); __ASSERT_NO_MSG(rv == 0); gpio_emul_pend_interrupt(port, input_mask, prev_input_values, input_values); /* for output-wiring, so the user can take action based on output */ gpio_fire_callbacks(&drv_data->callbacks, port, pins & ~get_input_pins(port)); return 0; } static int gpio_emul_port_clear_bits_raw(const struct device *port, gpio_port_pins_t pins) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; gpio_port_pins_t prev_input_values; gpio_port_pins_t input_values; gpio_port_pins_t input_mask; int rv; key = k_spin_lock(&drv_data->lock); pins &= get_output_pins(port); drv_data->output_vals &= ~pins; prev_input_values = drv_data->input_vals; input_mask = pins & get_input_pins(port); rv = gpio_emul_input_set_masked_int(port, input_mask, drv_data->output_vals); input_values = drv_data->input_vals; k_spin_unlock(&drv_data->lock, key); __ASSERT_NO_MSG(rv == 0); gpio_emul_pend_interrupt(port, input_mask, prev_input_values, input_values); /* for output-wiring, so the user can take action based on output */ gpio_fire_callbacks(&drv_data->callbacks, port, pins & ~get_input_pins(port)); return 0; } static int gpio_emul_port_toggle_bits(const struct device *port, gpio_port_pins_t pins) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; k_spinlock_key_t key; int rv; key = k_spin_lock(&drv_data->lock); drv_data->output_vals ^= (pins & get_output_pins(port)); /* in push-pull, set input values but do not fire interrupts (yet) */ rv = gpio_emul_input_set_masked_int(port, pins & get_input_pins(port), drv_data->output_vals); k_spin_unlock(&drv_data->lock, key); __ASSERT_NO_MSG(rv == 0); /* for output-wiring, so the user can take action based on output */ gpio_fire_callbacks(&drv_data->callbacks, port, pins); return 0; } static bool gpio_emul_level_trigger_supported(const struct device *port, enum gpio_int_trig trig) { switch (trig) { case GPIO_INT_TRIG_LOW: return gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_LEVEL_LOW); case GPIO_INT_TRIG_HIGH: return gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_LEVEL_HIGH); case GPIO_INT_TRIG_BOTH: return gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_LEVEL_LOW | GPIO_EMUL_INT_CAP_LEVEL_HIGH); default: return false; } } static bool gpio_emul_edge_trigger_supported(const struct device *port, enum gpio_int_trig trig) { switch (trig) { case GPIO_INT_TRIG_LOW: return gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_EDGE_FALLING); case GPIO_INT_TRIG_HIGH: return gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_EDGE_RISING); case GPIO_INT_TRIG_BOTH: return gpio_emul_config_has_caps(port, GPIO_EMUL_INT_CAP_EDGE_FALLING | GPIO_EMUL_INT_CAP_EDGE_RISING); default: return false; } } static int gpio_emul_pin_interrupt_configure(const struct device *port, gpio_pin_t pin, enum gpio_int_mode mode, enum gpio_int_trig trig) { int ret; struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; k_spinlock_key_t key; if ((BIT(pin) & config->common.port_pin_mask) == 0) { return -EINVAL; } #ifdef CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT if (mode != GPIO_INT_MODE_DISABLED && !(mode & GPIO_INT_ENABLE_DISABLE_ONLY)) { #else if (mode != GPIO_INT_MODE_DISABLED) { #endif /* CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT */ switch (trig) { case GPIO_INT_TRIG_LOW: case GPIO_INT_TRIG_HIGH: case GPIO_INT_TRIG_BOTH: break; default: return -EINVAL; } } if (mode == GPIO_INT_MODE_LEVEL) { if (!gpio_emul_level_trigger_supported(port, trig)) { return -ENOTSUP; } } if (mode == GPIO_INT_MODE_EDGE) { if (!gpio_emul_edge_trigger_supported(port, trig)) { return -ENOTSUP; } } key = k_spin_lock(&drv_data->lock); #ifdef CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT /* According to the GPIO interrupt configuration flag documentation, * changes to the interrupt trigger properties should clear pending * interrupts. */ if (!(mode & GPIO_INT_ENABLE_DISABLE_ONLY)) { drv_data->interrupts &= ~((gpio_port_pins_t)BIT(pin)); } #else drv_data->interrupts &= ~((gpio_port_pins_t)BIT(pin)); #endif /* CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT */ switch (mode) { case GPIO_INT_MODE_DISABLED: drv_data->flags[pin] &= ~GPIO_EMUL_INT_BITMASK; drv_data->flags[pin] |= GPIO_INT_DISABLE; #ifdef CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT __fallthrough; case GPIO_INT_MODE_DISABLE_ONLY: #endif /* CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT */ drv_data->enabled_interrupts &= ~((gpio_port_pins_t)BIT(pin)); break; case GPIO_INT_MODE_LEVEL: case GPIO_INT_MODE_EDGE: drv_data->flags[pin] &= ~GPIO_EMUL_INT_BITMASK; drv_data->flags[pin] |= (mode | trig); #ifdef CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT __fallthrough; case GPIO_INT_MODE_ENABLE_ONLY: #endif /* CONFIG_GPIO_ENABLE_DISABLE_INTERRUPT */ drv_data->enabled_interrupts |= BIT(pin); break; default: ret = -EINVAL; goto unlock; } ret = 0; unlock: k_spin_unlock(&drv_data->lock, key); /* Trigger callback if this pin has pending interrupt */ if (BIT(pin) & (drv_data->interrupts & drv_data->enabled_interrupts)) { gpio_fire_callbacks(&drv_data->callbacks, port, BIT(pin)); drv_data->interrupts &= ~((gpio_port_pins_t)BIT(pin)); } return ret; } static int gpio_emul_manage_callback(const struct device *port, struct gpio_callback *cb, bool set) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)port->data; return gpio_manage_callback(&drv_data->callbacks, cb, set); } static gpio_port_pins_t gpio_emul_get_pending_int(const struct device *dev) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)dev->data; return drv_data->interrupts; } #ifdef CONFIG_GPIO_GET_DIRECTION static int gpio_emul_port_get_direction(const struct device *port, gpio_port_pins_t map, gpio_port_pins_t *inputs, gpio_port_pins_t *outputs) { int i; gpio_port_pins_t ip = 0; gpio_port_pins_t op = 0; struct gpio_emul_data *const drv_data = (struct gpio_emul_data *)port->data; const struct gpio_emul_config *config = (const struct gpio_emul_config *)port->config; map &= config->common.port_pin_mask; if (inputs != NULL) { for (i = find_lsb_set(map) - 1; map; map &= ~BIT(i), i = find_lsb_set(map) - 1) { ip |= !!(drv_data->flags[i] & GPIO_INPUT) * BIT(i); } *inputs = ip; } if (outputs != NULL) { for (i = find_lsb_set(map) - 1; map; map &= ~BIT(i), i = find_lsb_set(map) - 1) { op |= !!(drv_data->flags[i] & GPIO_OUTPUT) * BIT(i); } *outputs = op; } return 0; } #endif /* CONFIG_GPIO_GET_DIRECTION */ static const struct gpio_driver_api gpio_emul_driver = { .pin_configure = gpio_emul_pin_configure, #ifdef CONFIG_GPIO_GET_CONFIG .pin_get_config = gpio_emul_pin_get_config, #endif .port_get_raw = gpio_emul_port_get_raw, .port_set_masked_raw = gpio_emul_port_set_masked_raw, .port_set_bits_raw = gpio_emul_port_set_bits_raw, .port_clear_bits_raw = gpio_emul_port_clear_bits_raw, .port_toggle_bits = gpio_emul_port_toggle_bits, .pin_interrupt_configure = gpio_emul_pin_interrupt_configure, .manage_callback = gpio_emul_manage_callback, .get_pending_int = gpio_emul_get_pending_int, #ifdef CONFIG_GPIO_GET_DIRECTION .port_get_direction = gpio_emul_port_get_direction, #endif /* CONFIG_GPIO_GET_DIRECTION */ }; static int gpio_emul_init(const struct device *dev) { struct gpio_emul_data *drv_data = (struct gpio_emul_data *)dev->data; sys_slist_init(&drv_data->callbacks); return 0; } #ifdef CONFIG_PM_DEVICE static int gpio_emul_pm_device_pm_action(const struct device *dev, enum pm_device_action action) { ARG_UNUSED(dev); ARG_UNUSED(action); return 0; } #endif /* * Device Initialization */ #define GPIO_EMUL_INT_CAPS(_num) (0 \ + DT_INST_PROP(_num, rising_edge) \ * GPIO_EMUL_INT_CAP_EDGE_RISING \ + DT_INST_PROP(_num, falling_edge) \ * GPIO_EMUL_INT_CAP_EDGE_FALLING \ + DT_INST_PROP(_num, high_level) \ * GPIO_EMUL_INT_CAP_LEVEL_HIGH \ + DT_INST_PROP(_num, low_level) \ * GPIO_EMUL_INT_CAP_LEVEL_LOW \ ) #define DEFINE_GPIO_EMUL(_num) \ \ static gpio_flags_t \ gpio_emul_flags_##_num[DT_INST_PROP(_num, ngpios)]; \ \ static const struct gpio_emul_config gpio_emul_config_##_num = {\ .common = { \ .port_pin_mask = \ GPIO_PORT_PIN_MASK_FROM_DT_INST(_num), \ }, \ .num_pins = DT_INST_PROP(_num, ngpios), \ .interrupt_caps = GPIO_EMUL_INT_CAPS(_num) \ }; \ BUILD_ASSERT( \ DT_INST_PROP(_num, ngpios) <= GPIO_MAX_PINS_PER_PORT, \ "Too many ngpios"); \ \ static struct gpio_emul_data gpio_emul_data_##_num = { \ .flags = gpio_emul_flags_##_num, \ }; \ \ PM_DEVICE_DT_INST_DEFINE(_num, gpio_emul_pm_device_pm_action); \ \ DEVICE_DT_INST_DEFINE(_num, gpio_emul_init, \ PM_DEVICE_DT_INST_GET(_num), \ &gpio_emul_data_##_num, \ &gpio_emul_config_##_num, POST_KERNEL, \ CONFIG_GPIO_INIT_PRIORITY, \ &gpio_emul_driver); DT_INST_FOREACH_STATUS_OKAY(DEFINE_GPIO_EMUL)