drivers/wifi/esp_at/esp.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Tobias Svehagen
  * Copyright (c) 2020 Grinn
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #ifndef ZEPHYR_INCLUDE_DRIVERS_WIFI_ESP_AT_ESP_H_
 #define ZEPHYR_INCLUDE_DRIVERS_WIFI_ESP_AT_ESP_H_

 #include <zephyr/kernel.h>
 #include <zephyr/net/net_context.h>
 #include <zephyr/net/net_if.h>
 #include <zephyr/net/net_ip.h>
 #include <zephyr/net/net_pkt.h>
 #include <zephyr/net/wifi_mgmt.h>

 #include "modem_context.h"
 #include "modem_cmd_handler.h"
 #include "modem_iface_uart.h"

 #ifdef __cplusplus
 extern "C" {
 #endif

 /* Define the commands that differ between the AT versions */
 #if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
 #define _CWMODE "CWMODE_CUR"
 #define _CWSAP  "CWSAP_CUR"
 #define _CWJAP  "CWJAP_CUR"
 #define _CIPSTA "CIPSTA_CUR"
 #define _CIPSTAMAC "CIPSTAMAC_CUR"
 #define _CIPRECVDATA "+CIPRECVDATA,"
 #define _CIPRECVDATA_END ':'
 #else
 #define _CWMODE "CWMODE"
 #define _CWSAP  "CWSAP"
 #define _CWJAP  "CWJAP"
 #define _CIPSTA "CIPSTA"
 #define _CIPSTAMAC "CIPSTAMAC"
 #define _CIPRECVDATA "+CIPRECVDATA:"
 #define _CIPRECVDATA_END ','
 #endif

 /*
  * Passive mode differs a bit between firmware versions and the macro
  * ESP_PROTO_PASSIVE is therefore used to determine what protocol operates in
  * passive mode. For AT version 1.7 passive mode only affects TCP but in AT
  * version 2.0 it affects both TCP and UDP.
  */
 #if defined(CONFIG_WIFI_ESP_AT_PASSIVE_MODE)
 #if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
 #define ESP_PROTO_PASSIVE(proto) (proto == IPPROTO_TCP)
 #else
 #define ESP_PROTO_PASSIVE(proto) \
 	(proto == IPPROTO_TCP || proto == IPPROTO_UDP)
 #endif /* CONFIG_WIFI_ESP_AT_VERSION_1_7 */
 #else
 #define ESP_PROTO_PASSIVE(proto) 0
 #endif /* CONFIG_WIFI_ESP_AT_PASSIVE_MODE */

 #define ESP_BUS DT_INST_BUS(0)

 #if DT_PROP(ESP_BUS, hw_flow_control) == 1
 #define _FLOW_CONTROL "3"
 #else
 #define _FLOW_CONTROL "0"
 #endif

 #if DT_INST_NODE_HAS_PROP(0, target_speed)
 #define _UART_BAUD	DT_INST_PROP(0, target_speed)
 #else
 #define _UART_BAUD	DT_PROP(ESP_BUS, current_speed)
 #endif

 #define _UART_CUR \
 	STRINGIFY(_UART_BAUD)",8,1,0,"_FLOW_CONTROL

 #define CONN_CMD_MAX_LEN (sizeof("AT+"_CWJAP"=\"\",\"\"") + \
 			  WIFI_SSID_MAX_LEN + WIFI_PSK_MAX_LEN)

 #if defined(CONFIG_WIFI_ESP_AT_DNS_USE)
 #define ESP_MAX_DNS	MIN(3, CONFIG_DNS_RESOLVER_MAX_SERVERS)
 #endif

 #define ESP_MAX_SOCKETS 5

 /* Maximum amount that can be sent with CIPSEND and read with CIPRECVDATA */
 #define ESP_MTU		2048
 #define CIPRECVDATA_MAX_LEN	ESP_MTU

 #define INVALID_LINK_ID		255

 #define MDM_RING_BUF_SIZE	CONFIG_WIFI_ESP_AT_MDM_RING_BUF_SIZE
 #define MDM_RECV_MAX_BUF	CONFIG_WIFI_ESP_AT_MDM_RX_BUF_COUNT
 #define MDM_RECV_BUF_SIZE	CONFIG_WIFI_ESP_AT_MDM_RX_BUF_SIZE

 #define ESP_CMD_TIMEOUT		K_SECONDS(10)
 #define ESP_SCAN_TIMEOUT	K_SECONDS(10)
 #define ESP_CONNECT_TIMEOUT	K_SECONDS(20)
 #define ESP_INIT_TIMEOUT	K_SECONDS(10)

 #define ESP_MODE_NONE		0
 #define ESP_MODE_STA		1
 #define ESP_MODE_AP		2
 #define ESP_MODE_STA_AP		3

 #if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7) || defined(CONFIG_WIFI_ESP_AT_VERSION_2_0)
 #define ESP_CMD_CWMODE(mode) "AT+"_CWMODE"="STRINGIFY(_CONCAT(ESP_MODE_, mode))
 #else
 #define ESP_CMD_CWMODE(mode) "AT+"_CWMODE"="STRINGIFY(_CONCAT(ESP_MODE_, mode))",0"
 #endif

 #define ESP_CWDHCP_MODE_STATION		"1"
 #if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
 #define ESP_CWDHCP_MODE_SOFTAP		"0"
 #else
 #define ESP_CWDHCP_MODE_SOFTAP		"2"
 #endif

 #if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
 #define _ESP_CMD_DHCP_ENABLE(mode, enable) \
 			  "AT+CWDHCP_CUR=" mode "," STRINGIFY(enable)
 #else
 #define _ESP_CMD_DHCP_ENABLE(mode, enable) \
 			  "AT+CWDHCP=" STRINGIFY(enable) "," mode
 #endif

 #define ESP_CMD_DHCP_ENABLE(mode, enable) \
 	_ESP_CMD_DHCP_ENABLE(_CONCAT(ESP_CWDHCP_MODE_, mode), enable)

 #define ESP_CMD_SET_IP(ip, gateway, mask) "AT+"_CIPSTA"=\"" \
 			  ip "\",\""  gateway  "\",\""  mask "\""

 #if defined(CONFIG_WIFI_ESP_AT_SCAN_PASSIVE)
 #define ESP_CMD_CWLAP "AT+CWLAP=,,,1,,"
 #else
 #define ESP_CMD_CWLAP "AT+CWLAP"
 #endif

 #if defined(CONFIG_WIFI_ESP_AT_SCAN_RESULT_RSSI_ORDERED)
 #define ESP_CMD_CWLAPOPT_ORDERED "1"
 #else
 #define ESP_CMD_CWLAPOPT_ORDERED "0"
 #endif

 #if defined(CONFIG_WIFI_ESP_AT_SCAN_MAC_ADDRESS)
 /* We need ecn,ssid,rssi,mac,channel */
 #define ESP_CMD_CWLAPOPT_MASK "31"
 #else
 /* no mac: only need ecn,ssid,rssi,channel */
 #define ESP_CMD_CWLAPOPT_MASK "23"
 #endif

 #define ESP_CMD_CWLAPOPT(sort, mask) "AT+CWLAPOPT=" sort "," mask

 extern struct esp_data esp_driver_data;

 enum esp_socket_flags {
 	ESP_SOCK_IN_USE     = BIT(1),
 	ESP_SOCK_CONNECTING = BIT(2),
 	ESP_SOCK_CONNECTED  = BIT(3),
 	ESP_SOCK_CLOSE_PENDING = BIT(4),
 	ESP_SOCK_WORKQ_STOPPED = BIT(5),
 };

 struct esp_socket {
 	/* internal */
 	struct k_mutex lock;
 	atomic_t refcount;

 	uint8_t idx;
 	uint8_t link_id;
 	atomic_t flags;

 	/* socket info */
 	struct sockaddr dst;

 	/* sem */
 	union {
 		/* handles blocking receive */
 		struct k_sem sem_data_ready;

 		/* notifies about reaching 0 refcount */
 		struct k_sem sem_free;
 	};

 	/* work */
 	struct k_work connect_work;
 	struct k_work recvdata_work;
 	struct k_work send_work;
 	struct k_work close_work;

 	/* TX packets fifo */
 	struct k_fifo tx_fifo;

 	/* net context */
 	struct net_context *context;
 	net_context_connect_cb_t connect_cb;
 	net_context_recv_cb_t recv_cb;

 	/* callback data */
 	void *conn_user_data;
 	void *recv_user_data;
 };

 enum esp_data_flag {
 	EDF_STA_CONNECTING = BIT(1),
 	EDF_STA_CONNECTED  = BIT(2),
 	EDF_STA_LOCK       = BIT(3),
 	EDF_AP_ENABLED     = BIT(4),
 };

 /* driver data */
 struct esp_data {
 	struct net_if *net_iface;

 	uint8_t flags;
 	uint8_t mode;

 	char conn_cmd[CONN_CMD_MAX_LEN];

 	/* addresses  */
 	struct in_addr ip;
 	struct in_addr gw;
 	struct in_addr nm;
 	uint8_t mac_addr[6];
 #if defined(ESP_MAX_DNS)
 	struct sockaddr_in dns_addresses[ESP_MAX_DNS];
 #endif

 	/* modem context */
 	struct modem_context mctx;

 	/* modem interface */
 	struct modem_iface_uart_data iface_data;
 	uint8_t iface_rb_buf[MDM_RING_BUF_SIZE];

 	/* modem cmds */
 	struct modem_cmd_handler_data cmd_handler_data;
 	uint8_t cmd_match_buf[MDM_RECV_BUF_SIZE];

 	/* socket data */
 	struct esp_socket sockets[ESP_MAX_SOCKETS];
 	struct esp_socket *rx_sock;

 	/* work */
 	struct k_work_q workq;
 	struct k_work init_work;
 	struct k_work_delayable ip_addr_work;
 	struct k_work scan_work;
 	struct k_work connect_work;
 	struct k_work disconnect_work;
 	struct k_work mode_switch_work;
 	struct k_work dns_work;

 	scan_result_cb_t scan_cb;

 	/* semaphores */
 	struct k_sem sem_tx_ready;
 	struct k_sem sem_response;
 	struct k_sem sem_if_ready;
 };

 int esp_offload_init(struct net_if *iface);

 struct esp_socket *esp_socket_get(struct esp_data *data,
 				  struct net_context *context);
 int esp_socket_put(struct esp_socket *sock);
 void esp_socket_init(struct esp_data *data);
 void esp_socket_close(struct esp_socket *sock);
 void esp_socket_rx(struct esp_socket *sock, struct net_buf *buf,
 		   size_t offset, size_t len);
 void esp_socket_workq_stop_and_flush(struct esp_socket *sock);
 struct esp_socket *esp_socket_ref(struct esp_socket *sock);
 void esp_socket_unref(struct esp_socket *sock);

 static inline
 struct esp_socket *esp_socket_ref_from_link_id(struct esp_data *data,
 					       uint8_t link_id)
 {
 	if (link_id >= ARRAY_SIZE(data->sockets)) {
 		return NULL;
 	}

 	return esp_socket_ref(&data->sockets[link_id]);
 }

 static inline atomic_val_t esp_socket_flags_update(struct esp_socket *sock,
 						   atomic_val_t value,
 						   atomic_val_t mask)
 {
 	atomic_val_t flags;

 	do {
 		flags = atomic_get(&sock->flags);
 	} while (!atomic_cas(&sock->flags, flags, (flags & ~mask) | value));

 	return flags;
 }

 static inline
 atomic_val_t esp_socket_flags_clear_and_set(struct esp_socket *sock,
 					    atomic_val_t clear_flags,
 					    atomic_val_t set_flags)
 {
 	return esp_socket_flags_update(sock, set_flags,
 				       clear_flags | set_flags);
 }

 static inline atomic_val_t esp_socket_flags_set(struct esp_socket *sock,
 						atomic_val_t flags)
 {
 	return atomic_or(&sock->flags, flags);
 }

 static inline bool esp_socket_flags_test_and_clear(struct esp_socket *sock,
 						   atomic_val_t flags)
 {
 	return (atomic_and(&sock->flags, ~flags) & flags);
 }

 static inline bool esp_socket_flags_test_and_set(struct esp_socket *sock,
 						 atomic_val_t flags)
 {
 	return (atomic_or(&sock->flags, flags) & flags);
 }

 static inline atomic_val_t esp_socket_flags_clear(struct esp_socket *sock,
 						  atomic_val_t flags)
 {
 	return atomic_and(&sock->flags, ~flags);
 }

 static inline atomic_val_t esp_socket_flags(struct esp_socket *sock)
 {
 	return atomic_get(&sock->flags);
 }

 static inline struct esp_data *esp_socket_to_dev(struct esp_socket *sock)
 {
 	return CONTAINER_OF(sock - sock->idx, struct esp_data, sockets);
 }

 static inline void __esp_socket_work_submit(struct esp_socket *sock,
 					    struct k_work *work)
 {
 	struct esp_data *data = esp_socket_to_dev(sock);

 	k_work_submit_to_queue(&data->workq, work);
 }

 static inline int esp_socket_work_submit(struct esp_socket *sock,
 					  struct k_work *work)
 {
 	int ret = -EBUSY;

 	k_mutex_lock(&sock->lock, K_FOREVER);
 	if (!(esp_socket_flags(sock) & ESP_SOCK_WORKQ_STOPPED)) {
 		__esp_socket_work_submit(sock, work);
 		ret = 0;
 	}
 	k_mutex_unlock(&sock->lock);

 	return ret;
 }

 static inline int esp_socket_queue_tx(struct esp_socket *sock,
 				      struct net_pkt *pkt)
 {
 	int ret = -EBUSY;

 	k_mutex_lock(&sock->lock, K_FOREVER);
 	if (!(esp_socket_flags(sock) & ESP_SOCK_WORKQ_STOPPED)) {
 		k_fifo_put(&sock->tx_fifo, pkt);
 		__esp_socket_work_submit(sock, &sock->send_work);
 		ret = 0;
 	}
 	k_mutex_unlock(&sock->lock);

 	return ret;
 }

 static inline bool esp_socket_connected(struct esp_socket *sock)
 {
 	return (esp_socket_flags(sock) & ESP_SOCK_CONNECTED) != 0;
 }

 static inline void esp_flags_set(struct esp_data *dev, uint8_t flags)
 {
 	dev->flags |= flags;
 }

 static inline void esp_flags_clear(struct esp_data *dev, uint8_t flags)
 {
 	dev->flags &= (~flags);
 }

 static inline bool esp_flags_are_set(struct esp_data *dev, uint8_t flags)
 {
 	return (dev->flags & flags) != 0;
 }

 static inline enum net_sock_type esp_socket_type(struct esp_socket *sock)
 {
 	return net_context_get_type(sock->context);
 }

 static inline enum net_ip_protocol esp_socket_ip_proto(struct esp_socket *sock)
 {
 	return net_context_get_proto(sock->context);
 }

 static inline int esp_cmd_send(struct esp_data *data,
 			       const struct modem_cmd *handlers,
 			       size_t handlers_len, const char *buf,
 			       k_timeout_t timeout)
 {
 	return modem_cmd_send(&data->mctx.iface, &data->mctx.cmd_handler,
 			      handlers, handlers_len, buf, &data->sem_response,
 			      timeout);
 }

 void esp_connect_work(struct k_work *work);
 void esp_recvdata_work(struct k_work *work);
 void esp_close_work(struct k_work *work);
 void esp_send_work(struct k_work *work);

 #ifdef __cplusplus
 }
 #endif

 #endif /* ZEPHYR_INCLUDE_DRIVERS_WIFI_ESP_AT_ESP_H_ */
	/*
	* Copyright (c) 2019 Tobias Svehagen
	* Copyright (c) 2020 Grinn
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#ifndef ZEPHYR_INCLUDE_DRIVERS_WIFI_ESP_AT_ESP_H_
	#define ZEPHYR_INCLUDE_DRIVERS_WIFI_ESP_AT_ESP_H_

	#include <zephyr/kernel.h>
	#include <zephyr/net/net_context.h>
	#include <zephyr/net/net_if.h>
	#include <zephyr/net/net_ip.h>
	#include <zephyr/net/net_pkt.h>
	#include <zephyr/net/wifi_mgmt.h>

	#include "modem_context.h"
	#include "modem_cmd_handler.h"
	#include "modem_iface_uart.h"

	#ifdef __cplusplus
	extern "C" {
	#endif

	/* Define the commands that differ between the AT versions */
	#if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
	#define _CWMODE "CWMODE_CUR"
	#define _CWSAP "CWSAP_CUR"
	#define _CWJAP "CWJAP_CUR"
	#define _CIPSTA "CIPSTA_CUR"
	#define _CIPSTAMAC "CIPSTAMAC_CUR"
	#define _CIPRECVDATA "+CIPRECVDATA,"
	#define _CIPRECVDATA_END ':'
	#else
	#define _CWMODE "CWMODE"
	#define _CWSAP "CWSAP"
	#define _CWJAP "CWJAP"
	#define _CIPSTA "CIPSTA"
	#define _CIPSTAMAC "CIPSTAMAC"
	#define _CIPRECVDATA "+CIPRECVDATA:"
	#define _CIPRECVDATA_END ','
	#endif

	/*
	* Passive mode differs a bit between firmware versions and the macro
	* ESP_PROTO_PASSIVE is therefore used to determine what protocol operates in
	* passive mode. For AT version 1.7 passive mode only affects TCP but in AT
	* version 2.0 it affects both TCP and UDP.
	*/
	#if defined(CONFIG_WIFI_ESP_AT_PASSIVE_MODE)
	#if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
	#define ESP_PROTO_PASSIVE(proto) (proto == IPPROTO_TCP)
	#else
	#define ESP_PROTO_PASSIVE(proto) \
	(proto == IPPROTO_TCP \|\| proto == IPPROTO_UDP)
	#endif /* CONFIG_WIFI_ESP_AT_VERSION_1_7 */
	#else
	#define ESP_PROTO_PASSIVE(proto) 0
	#endif /* CONFIG_WIFI_ESP_AT_PASSIVE_MODE */

	#define ESP_BUS DT_INST_BUS(0)

	#if DT_PROP(ESP_BUS, hw_flow_control) == 1
	#define _FLOW_CONTROL "3"
	#else
	#define _FLOW_CONTROL "0"
	#endif

	#if DT_INST_NODE_HAS_PROP(0, target_speed)
	#define _UART_BAUD DT_INST_PROP(0, target_speed)
	#else
	#define _UART_BAUD DT_PROP(ESP_BUS, current_speed)
	#endif

	#define _UART_CUR \
	STRINGIFY(_UART_BAUD)",8,1,0,"_FLOW_CONTROL

	#define CONN_CMD_MAX_LEN (sizeof("AT+"_CWJAP"=\"\",\"\"") + \
	WIFI_SSID_MAX_LEN + WIFI_PSK_MAX_LEN)

	#if defined(CONFIG_WIFI_ESP_AT_DNS_USE)
	#define ESP_MAX_DNS MIN(3, CONFIG_DNS_RESOLVER_MAX_SERVERS)
	#endif

	#define ESP_MAX_SOCKETS 5

	/* Maximum amount that can be sent with CIPSEND and read with CIPRECVDATA */
	#define ESP_MTU 2048
	#define CIPRECVDATA_MAX_LEN ESP_MTU

	#define INVALID_LINK_ID 255

	#define MDM_RING_BUF_SIZE CONFIG_WIFI_ESP_AT_MDM_RING_BUF_SIZE
	#define MDM_RECV_MAX_BUF CONFIG_WIFI_ESP_AT_MDM_RX_BUF_COUNT
	#define MDM_RECV_BUF_SIZE CONFIG_WIFI_ESP_AT_MDM_RX_BUF_SIZE

	#define ESP_CMD_TIMEOUT K_SECONDS(10)
	#define ESP_SCAN_TIMEOUT K_SECONDS(10)
	#define ESP_CONNECT_TIMEOUT K_SECONDS(20)
	#define ESP_INIT_TIMEOUT K_SECONDS(10)

	#define ESP_MODE_NONE 0
	#define ESP_MODE_STA 1
	#define ESP_MODE_AP 2
	#define ESP_MODE_STA_AP 3

	#if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7) \|\| defined(CONFIG_WIFI_ESP_AT_VERSION_2_0)
	#define ESP_CMD_CWMODE(mode) "AT+"_CWMODE"="STRINGIFY(_CONCAT(ESP_MODE_, mode))
	#else
	#define ESP_CMD_CWMODE(mode) "AT+"_CWMODE"="STRINGIFY(_CONCAT(ESP_MODE_, mode))",0"
	#endif

	#define ESP_CWDHCP_MODE_STATION "1"
	#if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
	#define ESP_CWDHCP_MODE_SOFTAP "0"
	#else
	#define ESP_CWDHCP_MODE_SOFTAP "2"
	#endif

	#if defined(CONFIG_WIFI_ESP_AT_VERSION_1_7)
	#define _ESP_CMD_DHCP_ENABLE(mode, enable) \
	"AT+CWDHCP_CUR=" mode "," STRINGIFY(enable)
	#else
	#define _ESP_CMD_DHCP_ENABLE(mode, enable) \
	"AT+CWDHCP=" STRINGIFY(enable) "," mode
	#endif

	#define ESP_CMD_DHCP_ENABLE(mode, enable) \
	_ESP_CMD_DHCP_ENABLE(_CONCAT(ESP_CWDHCP_MODE_, mode), enable)

	#define ESP_CMD_SET_IP(ip, gateway, mask) "AT+"_CIPSTA"=\"" \
	ip "\",\"" gateway "\",\"" mask "\""

	#if defined(CONFIG_WIFI_ESP_AT_SCAN_PASSIVE)
	#define ESP_CMD_CWLAP "AT+CWLAP=,,,1,,"
	#else
	#define ESP_CMD_CWLAP "AT+CWLAP"
	#endif

	#if defined(CONFIG_WIFI_ESP_AT_SCAN_RESULT_RSSI_ORDERED)
	#define ESP_CMD_CWLAPOPT_ORDERED "1"
	#else
	#define ESP_CMD_CWLAPOPT_ORDERED "0"
	#endif

	#if defined(CONFIG_WIFI_ESP_AT_SCAN_MAC_ADDRESS)
	/* We need ecn,ssid,rssi,mac,channel */
	#define ESP_CMD_CWLAPOPT_MASK "31"
	#else
	/* no mac: only need ecn,ssid,rssi,channel */
	#define ESP_CMD_CWLAPOPT_MASK "23"
	#endif

	#define ESP_CMD_CWLAPOPT(sort, mask) "AT+CWLAPOPT=" sort "," mask

	extern struct esp_data esp_driver_data;

	enum esp_socket_flags {
	ESP_SOCK_IN_USE = BIT(1),
	ESP_SOCK_CONNECTING = BIT(2),
	ESP_SOCK_CONNECTED = BIT(3),
	ESP_SOCK_CLOSE_PENDING = BIT(4),
	ESP_SOCK_WORKQ_STOPPED = BIT(5),
	};

	struct esp_socket {
	/* internal */
	struct k_mutex lock;
	atomic_t refcount;

	uint8_t idx;
	uint8_t link_id;
	atomic_t flags;

	/* socket info */
	struct sockaddr dst;

	/* sem */
	union {
	/* handles blocking receive */
	struct k_sem sem_data_ready;

	/* notifies about reaching 0 refcount */
	struct k_sem sem_free;
	};

	/* work */
	struct k_work connect_work;
	struct k_work recvdata_work;
	struct k_work send_work;
	struct k_work close_work;

	/* TX packets fifo */
	struct k_fifo tx_fifo;

	/* net context */
	struct net_context *context;
	net_context_connect_cb_t connect_cb;
	net_context_recv_cb_t recv_cb;

	/* callback data */
	void *conn_user_data;
	void *recv_user_data;
	};

	enum esp_data_flag {
	EDF_STA_CONNECTING = BIT(1),
	EDF_STA_CONNECTED = BIT(2),
	EDF_STA_LOCK = BIT(3),
	EDF_AP_ENABLED = BIT(4),
	};

	/* driver data */
	struct esp_data {
	struct net_if *net_iface;

	uint8_t flags;
	uint8_t mode;

	char conn_cmd[CONN_CMD_MAX_LEN];

	/* addresses */
	struct in_addr ip;
	struct in_addr gw;
	struct in_addr nm;
	uint8_t mac_addr[6];
	#if defined(ESP_MAX_DNS)
	struct sockaddr_in dns_addresses[ESP_MAX_DNS];
	#endif

	/* modem context */
	struct modem_context mctx;

	/* modem interface */
	struct modem_iface_uart_data iface_data;
	uint8_t iface_rb_buf[MDM_RING_BUF_SIZE];

	/* modem cmds */
	struct modem_cmd_handler_data cmd_handler_data;
	uint8_t cmd_match_buf[MDM_RECV_BUF_SIZE];

	/* socket data */
	struct esp_socket sockets[ESP_MAX_SOCKETS];
	struct esp_socket *rx_sock;

	/* work */
	struct k_work_q workq;
	struct k_work init_work;
	struct k_work_delayable ip_addr_work;
	struct k_work scan_work;
	struct k_work connect_work;
	struct k_work disconnect_work;
	struct k_work mode_switch_work;
	struct k_work dns_work;

	scan_result_cb_t scan_cb;

	/* semaphores */
	struct k_sem sem_tx_ready;
	struct k_sem sem_response;
	struct k_sem sem_if_ready;
	};

	int esp_offload_init(struct net_if *iface);

	struct esp_socket esp_socket_get(struct esp_data data,
	struct net_context *context);
	int esp_socket_put(struct esp_socket *sock);
	void esp_socket_init(struct esp_data *data);
	void esp_socket_close(struct esp_socket *sock);
	void esp_socket_rx(struct esp_socket sock, struct net_buf buf,
	size_t offset, size_t len);
	void esp_socket_workq_stop_and_flush(struct esp_socket *sock);
	struct esp_socket esp_socket_ref(struct esp_socket sock);
	void esp_socket_unref(struct esp_socket *sock);

	static inline
	struct esp_socket esp_socket_ref_from_link_id(struct esp_data data,
	uint8_t link_id)
	{
	if (link_id >= ARRAY_SIZE(data->sockets)) {
	return NULL;
	}

	return esp_socket_ref(&data->sockets[link_id]);
	}

	static inline atomic_val_t esp_socket_flags_update(struct esp_socket *sock,
	atomic_val_t value,
	atomic_val_t mask)
	{
	atomic_val_t flags;

	do {
	flags = atomic_get(&sock->flags);
	} while (!atomic_cas(&sock->flags, flags, (flags & ~mask) \| value));

	return flags;
	}

	static inline
	atomic_val_t esp_socket_flags_clear_and_set(struct esp_socket *sock,
	atomic_val_t clear_flags,
	atomic_val_t set_flags)
	{
	return esp_socket_flags_update(sock, set_flags,
	clear_flags \| set_flags);
	}

	static inline atomic_val_t esp_socket_flags_set(struct esp_socket *sock,
	atomic_val_t flags)
	{
	return atomic_or(&sock->flags, flags);
	}

	static inline bool esp_socket_flags_test_and_clear(struct esp_socket *sock,
	atomic_val_t flags)
	{
	return (atomic_and(&sock->flags, ~flags) & flags);
	}

	static inline bool esp_socket_flags_test_and_set(struct esp_socket *sock,
	atomic_val_t flags)
	{
	return (atomic_or(&sock->flags, flags) & flags);
	}

	static inline atomic_val_t esp_socket_flags_clear(struct esp_socket *sock,
	atomic_val_t flags)
	{
	return atomic_and(&sock->flags, ~flags);
	}

	static inline atomic_val_t esp_socket_flags(struct esp_socket *sock)
	{
	return atomic_get(&sock->flags);
	}

	static inline struct esp_data esp_socket_to_dev(struct esp_socket sock)
	{
	return CONTAINER_OF(sock - sock->idx, struct esp_data, sockets);
	}

	static inline void __esp_socket_work_submit(struct esp_socket *sock,
	struct k_work *work)
	{
	struct esp_data *data = esp_socket_to_dev(sock);

	k_work_submit_to_queue(&data->workq, work);
	}

	static inline int esp_socket_work_submit(struct esp_socket *sock,
	struct k_work *work)
	{
	int ret = -EBUSY;

	k_mutex_lock(&sock->lock, K_FOREVER);
	if (!(esp_socket_flags(sock) & ESP_SOCK_WORKQ_STOPPED)) {
	__esp_socket_work_submit(sock, work);
	ret = 0;
	}
	k_mutex_unlock(&sock->lock);

	return ret;
	}

	static inline int esp_socket_queue_tx(struct esp_socket *sock,
	struct net_pkt *pkt)
	{
	int ret = -EBUSY;

	k_mutex_lock(&sock->lock, K_FOREVER);
	if (!(esp_socket_flags(sock) & ESP_SOCK_WORKQ_STOPPED)) {
	k_fifo_put(&sock->tx_fifo, pkt);
	__esp_socket_work_submit(sock, &sock->send_work);
	ret = 0;
	}
	k_mutex_unlock(&sock->lock);

	return ret;
	}

	static inline bool esp_socket_connected(struct esp_socket *sock)
	{
	return (esp_socket_flags(sock) & ESP_SOCK_CONNECTED) != 0;
	}

	static inline void esp_flags_set(struct esp_data *dev, uint8_t flags)
	{
	dev->flags \|= flags;
	}

	static inline void esp_flags_clear(struct esp_data *dev, uint8_t flags)
	{
	dev->flags &= (~flags);
	}

	static inline bool esp_flags_are_set(struct esp_data *dev, uint8_t flags)
	{
	return (dev->flags & flags) != 0;
	}

	static inline enum net_sock_type esp_socket_type(struct esp_socket *sock)
	{
	return net_context_get_type(sock->context);
	}

	static inline enum net_ip_protocol esp_socket_ip_proto(struct esp_socket *sock)
	{
	return net_context_get_proto(sock->context);
	}

	static inline int esp_cmd_send(struct esp_data *data,
	const struct modem_cmd *handlers,
	size_t handlers_len, const char *buf,
	k_timeout_t timeout)
	{
	return modem_cmd_send(&data->mctx.iface, &data->mctx.cmd_handler,
	handlers, handlers_len, buf, &data->sem_response,
	timeout);
	}

	void esp_connect_work(struct k_work *work);
	void esp_recvdata_work(struct k_work *work);
	void esp_close_work(struct k_work *work);
	void esp_send_work(struct k_work *work);

	#ifdef __cplusplus
	}
	#endif

	#endif /* ZEPHYR_INCLUDE_DRIVERS_WIFI_ESP_AT_ESP_H_ */