drivers/wifi/nrfwifi/src/shim.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2024 Nordic Semiconductor ASA
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @brief Header containing OS specific definitions for the
  * Zephyr OS layer of the Wi-Fi driver.
  */

 #include <stdio.h>
 #include <string.h>
 #include <sys/time.h>

 #include <zephyr/kernel.h>
 #include <zephyr/sys/printk.h>
 #include <zephyr/drivers/gpio.h>
 #include <zephyr/logging/log.h>
 #include <zephyr/sys/__assert.h>

 #include "rpu_hw_if.h"
 #include "shim.h"
 #include "work.h"
 #include "timer.h"
 #include "osal_ops.h"
 #include "qspi_if.h"

 LOG_MODULE_REGISTER(wifi_nrf, CONFIG_WIFI_NRF70_LOG_LEVEL);

 struct zep_shim_intr_priv *intr_priv;

 static void *zep_shim_mem_alloc(size_t size)
 {
 	size_t size_aligned = ROUND_UP(size, 4);

 	return k_malloc(size_aligned);
 }

 static void *zep_shim_mem_zalloc(size_t size)
 {
 	size_t size_aligned = ROUND_UP(size, 4);

 	return k_calloc(size_aligned, sizeof(char));
 }

 static void *zep_shim_mem_cpy(void *dest, const void *src, size_t count)
 {
 	return memcpy(dest, src, count);
 }

 static void *zep_shim_mem_set(void *start, int val, size_t size)
 {
 	return memset(start, val, size);
 }

 static int zep_shim_mem_cmp(const void *addr1,
 			    const void *addr2,
 			    size_t size)
 {
 	return memcmp(addr1, addr2, size);
 }

 static unsigned int zep_shim_qspi_read_reg32(void *priv, unsigned long addr)
 {
 	unsigned int val;
 	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
 	struct qspi_dev *dev;

 	dev = qspi_priv->qspi_dev;

 	if (addr < 0x0C0000) {
 		dev->hl_read(addr, &val, 4);
 	} else {
 		dev->read(addr, &val, 4);
 	}

 	return val;
 }

 static void zep_shim_qspi_write_reg32(void *priv, unsigned long addr, unsigned int val)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
 	struct qspi_dev *dev;

 	dev = qspi_priv->qspi_dev;

 	dev->write(addr, &val, 4);
 }

 static void zep_shim_qspi_cpy_from(void *priv, void *dest, unsigned long addr, size_t count)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
 	struct qspi_dev *dev;
 	size_t count_aligned = ROUND_UP(count, 4);

 	dev = qspi_priv->qspi_dev;

 	if (addr < 0x0C0000) {
 		dev->hl_read(addr, dest, count_aligned);
 	} else {
 		dev->read(addr, dest, count_aligned);
 	}
 }

 static void zep_shim_qspi_cpy_to(void *priv, unsigned long addr, const void *src, size_t count)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
 	struct qspi_dev *dev;
 	size_t count_aligned = ROUND_UP(count, 4);

 	dev = qspi_priv->qspi_dev;

 	dev->write(addr, src, count_aligned);
 }

 static void *zep_shim_spinlock_alloc(void)
 {
 	struct k_sem *lock = NULL;

 	lock = k_malloc(sizeof(*lock));

 	if (!lock) {
 		LOG_ERR("%s: Unable to allocate memory for spinlock", __func__);
 	}

 	return lock;
 }

 static void zep_shim_spinlock_free(void *lock)
 {
 	k_free(lock);
 }

 static void zep_shim_spinlock_init(void *lock)
 {
 	k_sem_init(lock, 1, 1);
 }

 static void zep_shim_spinlock_take(void *lock)
 {
 	k_sem_take(lock, K_FOREVER);
 }

 static void zep_shim_spinlock_rel(void *lock)
 {
 	k_sem_give(lock);
 }

 static void zep_shim_spinlock_irq_take(void *lock, unsigned long *flags)
 {
 	k_sem_take(lock, K_FOREVER);
 }

 static void zep_shim_spinlock_irq_rel(void *lock, unsigned long *flags)
 {
 	k_sem_give(lock);
 }

 static int zep_shim_pr_dbg(const char *fmt, va_list args)
 {
 	static char buf[80];

 	vsnprintf(buf, sizeof(buf), fmt, args);

 	LOG_DBG("%s", buf);

 	return 0;
 }

 static int zep_shim_pr_info(const char *fmt, va_list args)
 {
 	static char buf[80];

 	vsnprintf(buf, sizeof(buf), fmt, args);

 	LOG_INF("%s", buf);

 	return 0;
 }

 static int zep_shim_pr_err(const char *fmt, va_list args)
 {
 	static char buf[256];

 	vsnprintf(buf, sizeof(buf), fmt, args);

 	LOG_ERR("%s", buf);

 	return 0;
 }

 struct nwb {
 	unsigned char *data;
 	unsigned char *tail;
 	int len;
 	int headroom;
 	void *next;
 	void *priv;
 	int iftype;
 	void *ifaddr;
 	void *dev;
 	int hostbuffer;
 	void *cleanup_ctx;
 	void (*cleanup_cb)();
 	unsigned char priority;
 	bool chksum_done;
 };

 static void *zep_shim_nbuf_alloc(unsigned int size)
 {
 	struct nwb *nbuff;

 	nbuff = (struct nwb *)k_calloc(sizeof(struct nwb), sizeof(char));

 	if (!nbuff)
 		return NULL;

 	nbuff->priv = k_calloc(size, sizeof(char));

 	if (!nbuff->priv) {
 		k_free(nbuff);
 		return NULL;
 	}

 	nbuff->data = (unsigned char *)nbuff->priv;
 	nbuff->tail = nbuff->data;
 	nbuff->len = 0;
 	nbuff->headroom = 0;
 	nbuff->next = NULL;

 	return nbuff;
 }

 static void zep_shim_nbuf_free(void *nbuf)
 {
 	k_free(((struct nwb *)nbuf)->priv);
 	k_free(nbuf);
 }

 static void zep_shim_nbuf_headroom_res(void *nbuf, unsigned int size)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;

 	nwb->data += size;
 	nwb->tail += size;
 	nwb->headroom += size;
 }

 static unsigned int zep_shim_nbuf_headroom_get(void *nbuf)
 {
 	return ((struct nwb *)nbuf)->headroom;
 }

 static unsigned int zep_shim_nbuf_data_size(void *nbuf)
 {
 	return ((struct nwb *)nbuf)->len;
 }

 static void *zep_shim_nbuf_data_get(void *nbuf)
 {
 	return ((struct nwb *)nbuf)->data;
 }

 static void *zep_shim_nbuf_data_put(void *nbuf, unsigned int size)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;
 	unsigned char *data = nwb->tail;

 	nwb->tail += size;
 	nwb->len += size;

 	return data;
 }

 static void *zep_shim_nbuf_data_push(void *nbuf, unsigned int size)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;

 	nwb->data -= size;
 	nwb->headroom -= size;
 	nwb->len += size;

 	return nwb->data;
 }

 static void *zep_shim_nbuf_data_pull(void *nbuf, unsigned int size)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;

 	nwb->data += size;
 	nwb->headroom += size;
 	nwb->len -= size;

 	return nwb->data;
 }

 static unsigned char zep_shim_nbuf_get_priority(void *nbuf)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;

 	return nwb->priority;
 }

 static unsigned char zep_shim_nbuf_get_chksum_done(void *nbuf)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;

 	return nwb->chksum_done;
 }

 static void zep_shim_nbuf_set_chksum_done(void *nbuf, unsigned char chksum_done)
 {
 	struct nwb *nwb = (struct nwb *)nbuf;

 	nwb->chksum_done = (bool)chksum_done;
 }

 #include <zephyr/net/ethernet.h>
 #include <zephyr/net/net_core.h>

 void *net_pkt_to_nbuf(struct net_pkt *pkt)
 {
 	struct nwb *nbuff;
 	unsigned char *data;
 	unsigned int len;

 	len = net_pkt_get_len(pkt);

 	nbuff = zep_shim_nbuf_alloc(len + 100);

 	if (!nbuff) {
 		return NULL;
 	}

 	zep_shim_nbuf_headroom_res(nbuff, 100);

 	data = zep_shim_nbuf_data_put(nbuff, len);

 	net_pkt_read(pkt, data, len);

 	nbuff->priority = net_pkt_priority(pkt);
 	nbuff->chksum_done = (bool)net_pkt_is_chksum_done(pkt);

 	return nbuff;
 }

 void *net_pkt_from_nbuf(void *iface, void *frm)
 {
 	struct net_pkt *pkt = NULL;
 	unsigned char *data;
 	unsigned int len;
 	struct nwb *nwb = frm;

 	if (!nwb) {
 		return NULL;
 	}

 	len = zep_shim_nbuf_data_size(nwb);

 	data = zep_shim_nbuf_data_get(nwb);

 	pkt = net_pkt_rx_alloc_with_buffer(iface, len, AF_UNSPEC, 0, K_MSEC(100));

 	if (!pkt) {
 		goto out;
 	}

 	if (net_pkt_write(pkt, data, len)) {
 		net_pkt_unref(pkt);
 		pkt = NULL;
 		goto out;
 	}

 out:
 	zep_shim_nbuf_free(nwb);
 	return pkt;
 }

 #if defined(CONFIG_NRF70_RAW_DATA_RX) || defined(CONFIG_NRF70_PROMISC_DATA_RX)
 void *net_raw_pkt_from_nbuf(void *iface, void *frm,
 			    unsigned short raw_hdr_len,
 			    void *raw_rx_hdr,
 			    bool pkt_free)
 {
 	struct net_pkt *pkt = NULL;
 	unsigned char *nwb_data;
 	unsigned char *data =  NULL;
 	unsigned int nwb_len;
 	unsigned int total_len;
 	struct nwb *nwb = frm;

 	if (!nwb) {
 		LOG_ERR("%s: Received network buffer is NULL", __func__);
 		return NULL;
 	}

 	nwb_len = zep_shim_nbuf_data_size(nwb);
 	nwb_data = zep_shim_nbuf_data_get(nwb);
 	total_len = raw_hdr_len + nwb_len;

 	data = (unsigned char *)k_malloc(total_len);
 	if (!data) {
 		LOG_ERR("%s: Unable to allocate memory for sniffer data packet", __func__);
 		goto out;
 	}

 	pkt = net_pkt_rx_alloc_with_buffer(iface, total_len, AF_PACKET, ETH_P_ALL, K_MSEC(100));
 	if (!pkt) {
 		LOG_ERR("%s: Unable to allocate net packet buffer", __func__);
 		goto out;
 	}

 	memcpy(data, raw_rx_hdr, raw_hdr_len);
 	memcpy((data+raw_hdr_len), nwb_data, nwb_len);

 	if (net_pkt_write(pkt, data, total_len)) {
 		net_pkt_unref(pkt);
 		pkt = NULL;
 		goto out;
 	}
 out:
 	if (data != NULL) {
 		k_free(data);
 	}

 	if (pkt_free) {
 		zep_shim_nbuf_free(nwb);
 	}

 	return pkt;
 }
 #endif /* CONFIG_NRF70_RAW_DATA_RX || CONFIG_NRF70_PROMISC_DATA_RX */

 static void *zep_shim_llist_node_alloc(void)
 {
 	struct zep_shim_llist_node *llist_node = NULL;

 	llist_node = k_calloc(sizeof(*llist_node), sizeof(char));

 	if (!llist_node) {
 		LOG_ERR("%s: Unable to allocate memory for linked list node", __func__);
 		return NULL;
 	}

 	sys_dnode_init(&llist_node->head);

 	return llist_node;
 }

 static void zep_shim_llist_node_free(void *llist_node)
 {
 	k_free(llist_node);
 }

 static void *zep_shim_llist_node_data_get(void *llist_node)
 {
 	struct zep_shim_llist_node *zep_llist_node = NULL;

 	zep_llist_node = (struct zep_shim_llist_node *)llist_node;

 	return zep_llist_node->data;
 }

 static void zep_shim_llist_node_data_set(void *llist_node, void *data)
 {
 	struct zep_shim_llist_node *zep_llist_node = NULL;

 	zep_llist_node = (struct zep_shim_llist_node *)llist_node;

 	zep_llist_node->data = data;
 }

 static void *zep_shim_llist_alloc(void)
 {
 	struct zep_shim_llist *llist = NULL;

 	llist = k_calloc(sizeof(*llist), sizeof(char));

 	if (!llist) {
 		LOG_ERR("%s: Unable to allocate memory for linked list", __func__);
 	}

 	return llist;
 }

 static void zep_shim_llist_free(void *llist)
 {
 	k_free(llist);
 }

 static void zep_shim_llist_init(void *llist)
 {
 	struct zep_shim_llist *zep_llist = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;

 	sys_dlist_init(&zep_llist->head);
 }

 static void zep_shim_llist_add_node_tail(void *llist, void *llist_node)
 {
 	struct zep_shim_llist *zep_llist = NULL;
 	struct zep_shim_llist_node *zep_node = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;
 	zep_node = (struct zep_shim_llist_node *)llist_node;

 	sys_dlist_append(&zep_llist->head, &zep_node->head);

 	zep_llist->len += 1;
 }

 static void zep_shim_llist_add_node_head(void *llist, void *llist_node)
 {
 	struct zep_shim_llist *zep_llist = NULL;
 	struct zep_shim_llist_node *zep_node = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;
 	zep_node = (struct zep_shim_llist_node *)llist_node;

 	sys_dlist_prepend(&zep_llist->head, &zep_node->head);

 	zep_llist->len += 1;
 }

 static void *zep_shim_llist_get_node_head(void *llist)
 {
 	struct zep_shim_llist_node *zep_head_node = NULL;
 	struct zep_shim_llist *zep_llist = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;

 	if (!zep_llist->len) {
 		return NULL;
 	}

 	zep_head_node = (struct zep_shim_llist_node *)sys_dlist_peek_head(&zep_llist->head);

 	return zep_head_node;
 }

 static void *zep_shim_llist_get_node_nxt(void *llist, void *llist_node)
 {
 	struct zep_shim_llist_node *zep_node = NULL;
 	struct zep_shim_llist_node *zep_nxt_node = NULL;
 	struct zep_shim_llist *zep_llist = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;
 	zep_node = (struct zep_shim_llist_node *)llist_node;

 	zep_nxt_node = (struct zep_shim_llist_node *)sys_dlist_peek_next(&zep_llist->head,
 									 &zep_node->head);

 	return zep_nxt_node;
 }

 static void zep_shim_llist_del_node(void *llist, void *llist_node)
 {
 	struct zep_shim_llist_node *zep_node = NULL;
 	struct zep_shim_llist *zep_llist = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;
 	zep_node = (struct zep_shim_llist_node *)llist_node;

 	sys_dlist_remove(&zep_node->head);

 	zep_llist->len -= 1;
 }

 static unsigned int zep_shim_llist_len(void *llist)
 {
 	struct zep_shim_llist *zep_llist = NULL;

 	zep_llist = (struct zep_shim_llist *)llist;

 	return zep_llist->len;
 }

 static void *zep_shim_work_alloc(int type)
 {
 	return work_alloc(type);
 }

 static void zep_shim_work_free(void *item)
 {
 	return work_free(item);
 }

 static void zep_shim_work_init(void *item, void (*callback)(unsigned long data),
 				  unsigned long data)
 {
 	work_init(item, callback, data);
 }

 static void zep_shim_work_schedule(void *item)
 {
 	work_schedule(item);
 }

 static void zep_shim_work_kill(void *item)
 {
 	work_kill(item);
 }

 static unsigned long zep_shim_time_get_curr_us(void)
 {
 	return k_uptime_get() * USEC_PER_MSEC;
 }

 static unsigned int zep_shim_time_elapsed_us(unsigned long start_time_us)
 {
 	unsigned long curr_time_us = 0;

 	curr_time_us = zep_shim_time_get_curr_us();

 	return curr_time_us - start_time_us;
 }

 static enum nrf_wifi_status zep_shim_bus_qspi_dev_init(void *os_qspi_dev_ctx)
 {
 	ARG_UNUSED(os_qspi_dev_ctx);

 	return NRF_WIFI_STATUS_SUCCESS;
 }

 static void zep_shim_bus_qspi_dev_deinit(void *priv)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
 	volatile struct qspi_dev *dev = qspi_priv->qspi_dev;

 	dev->deinit();
 }

 static void *zep_shim_bus_qspi_dev_add(void *os_qspi_priv, void *osal_qspi_dev_ctx)
 {
 	struct zep_shim_bus_qspi_priv *zep_qspi_priv = os_qspi_priv;
 	struct qspi_dev *dev = qspi_dev();
 	int ret;
 	enum nrf_wifi_status status;

 	ret = rpu_init();
 	if (ret) {
 		LOG_ERR("%s: RPU init failed with error %d", __func__, ret);
 		return NULL;
 	}

 	status = dev->init(qspi_defconfig());
 	if (status != NRF_WIFI_STATUS_SUCCESS) {
 		LOG_ERR("%s: QSPI device init failed", __func__);
 		return NULL;
 	}

 	ret = rpu_enable();
 	if (ret) {
 		LOG_ERR("%s: RPU enable failed with error %d", __func__, ret);
 		return NULL;
 	}
 	zep_qspi_priv->qspi_dev = dev;
 	zep_qspi_priv->dev_added = true;

 	return zep_qspi_priv;
 }

 static void zep_shim_bus_qspi_dev_rem(void *priv)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
 	struct qspi_dev *dev = qspi_priv->qspi_dev;

 	ARG_UNUSED(dev);

 	/* TODO: Make qspi_dev a dynamic instance and remove it here */
 	rpu_disable();
 }

 static void *zep_shim_bus_qspi_init(void)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = NULL;

 	qspi_priv = k_calloc(sizeof(*qspi_priv), sizeof(char));

 	if (!qspi_priv) {
 		LOG_ERR("%s: Unable to allocate memory for qspi_priv", __func__);
 		goto out;
 	}
 out:
 	return qspi_priv;
 }

 static void zep_shim_bus_qspi_deinit(void *os_qspi_priv)
 {
 	struct zep_shim_bus_qspi_priv *qspi_priv = NULL;

 	qspi_priv = os_qspi_priv;

 	k_free(qspi_priv);
 }

 #ifdef CONFIG_NRF_WIFI_LOW_POWER
 static int zep_shim_bus_qspi_ps_sleep(void *os_qspi_priv)
 {
 	rpu_sleep();

 	return 0;
 }

 static int zep_shim_bus_qspi_ps_wake(void *os_qspi_priv)
 {
 	rpu_wakeup();

 	return 0;
 }

 static int zep_shim_bus_qspi_ps_status(void *os_qspi_priv)
 {
 	return rpu_sleep_status();
 }
 #endif /* CONFIG_NRF_WIFI_LOW_POWER */

 static void zep_shim_bus_qspi_dev_host_map_get(void *os_qspi_dev_ctx,
 					       struct nrf_wifi_osal_host_map *host_map)
 {
 	if (!os_qspi_dev_ctx || !host_map) {
 		LOG_ERR("%s: Invalid parameters", __func__);
 		return;
 	}

 	host_map->addr = 0;
 }

 static void irq_work_handler(struct k_work *work)
 {
 	int ret = 0;

 	ret = intr_priv->callbk_fn(intr_priv->callbk_data);

 	if (ret) {
 		LOG_ERR("%s: Interrupt callback failed", __func__);
 	}
 }


 extern struct k_work_q zep_wifi_intr_q;

 static void zep_shim_irq_handler(const struct device *dev, struct gpio_callback *cb, uint32_t pins)
 {
 	ARG_UNUSED(cb);
 	ARG_UNUSED(pins);

 	k_work_schedule_for_queue(&zep_wifi_intr_q, &intr_priv->work, K_NO_WAIT);
 }

 static enum nrf_wifi_status zep_shim_bus_qspi_intr_reg(void *os_dev_ctx, void *callbk_data,
 						       int (*callbk_fn)(void *callbk_data))
 {
 	enum nrf_wifi_status status = NRF_WIFI_STATUS_FAIL;
 	int ret = -1;

 	ARG_UNUSED(os_dev_ctx);

 	intr_priv = k_calloc(sizeof(*intr_priv), sizeof(char));

 	if (!intr_priv) {
 		LOG_ERR("%s: Unable to allocate memory for intr_priv", __func__);
 		goto out;
 	}

 	intr_priv->callbk_data = callbk_data;
 	intr_priv->callbk_fn = callbk_fn;

 	k_work_init_delayable(&intr_priv->work, irq_work_handler);

 	ret = rpu_irq_config(&intr_priv->gpio_cb_data, zep_shim_irq_handler);

 	if (ret) {
 		LOG_ERR("%s: request_irq failed", __func__);
 		k_free(intr_priv);
 		intr_priv = NULL;
 		goto out;
 	}

 	status = NRF_WIFI_STATUS_SUCCESS;

 out:
 	return status;
 }

 static void zep_shim_bus_qspi_intr_unreg(void *os_qspi_dev_ctx)
 {
 	struct k_work_sync sync;
 	int ret;

 	ARG_UNUSED(os_qspi_dev_ctx);

 	ret = rpu_irq_remove(&intr_priv->gpio_cb_data);
 	if (ret) {
 		LOG_ERR("%s: rpu_irq_remove failed", __func__);
 		return;
 	}

 	k_work_cancel_delayable_sync(&intr_priv->work, &sync);

 	k_free(intr_priv);
 	intr_priv = NULL;
 }

 #ifdef CONFIG_NRF_WIFI_LOW_POWER
 static void *zep_shim_timer_alloc(void)
 {
 	struct timer_list *timer = NULL;

 	timer = k_malloc(sizeof(*timer));

 	if (!timer)
 		LOG_ERR("%s: Unable to allocate memory for work", __func__);

 	return timer;
 }

 static void zep_shim_timer_init(void *timer, void (*callback)(unsigned long), unsigned long data)
 {
 	((struct timer_list *)timer)->function = callback;
 	((struct timer_list *)timer)->data = data;

 	init_timer(timer);
 }

 static void zep_shim_timer_free(void *timer)
 {
 	k_free(timer);
 }

 static void zep_shim_timer_schedule(void *timer, unsigned long duration)
 {
 	mod_timer(timer, duration);
 }

 static void zep_shim_timer_kill(void *timer)
 {
 	del_timer_sync(timer);
 }
 #endif /* CONFIG_NRF_WIFI_LOW_POWER */

 static void zep_shim_assert(int test_val, int val, enum nrf_wifi_assert_op_type op, char *msg)
 {
 	switch (op) {
 	case NRF_WIFI_ASSERT_EQUAL_TO:
 		NET_ASSERT(test_val == val, "%s", msg);
 	break;
 	case NRF_WIFI_ASSERT_NOT_EQUAL_TO:
 		NET_ASSERT(test_val != val, "%s", msg);
 	break;
 	case NRF_WIFI_ASSERT_LESS_THAN:
 		NET_ASSERT(test_val < val, "%s", msg);
 	break;
 	case NRF_WIFI_ASSERT_LESS_THAN_EQUAL_TO:
 		NET_ASSERT(test_val <= val, "%s", msg);
 	break;
 	case NRF_WIFI_ASSERT_GREATER_THAN:
 		NET_ASSERT(test_val > val, "%s", msg);
 	break;
 	case NRF_WIFI_ASSERT_GREATER_THAN_EQUAL_TO:
 		NET_ASSERT(test_val >= val, "%s", msg);
 	break;
 	default:
 		LOG_ERR("%s: Invalid assertion operation", __func__);
 	}
 }

 static unsigned int zep_shim_strlen(const void *str)
 {
 	return strlen(str);
 }

 const struct nrf_wifi_osal_ops nrf_wifi_os_zep_ops = {
 	.mem_alloc = zep_shim_mem_alloc,
 	.mem_zalloc = zep_shim_mem_zalloc,
 	.mem_free = k_free,
 	.mem_cpy = zep_shim_mem_cpy,
 	.mem_set = zep_shim_mem_set,
 	.mem_cmp = zep_shim_mem_cmp,

 	.qspi_read_reg32 = zep_shim_qspi_read_reg32,
 	.qspi_write_reg32 = zep_shim_qspi_write_reg32,
 	.qspi_cpy_from = zep_shim_qspi_cpy_from,
 	.qspi_cpy_to = zep_shim_qspi_cpy_to,

 	.spinlock_alloc = zep_shim_spinlock_alloc,
 	.spinlock_free = zep_shim_spinlock_free,
 	.spinlock_init = zep_shim_spinlock_init,
 	.spinlock_take = zep_shim_spinlock_take,
 	.spinlock_rel = zep_shim_spinlock_rel,

 	.spinlock_irq_take = zep_shim_spinlock_irq_take,
 	.spinlock_irq_rel = zep_shim_spinlock_irq_rel,

 	.log_dbg = zep_shim_pr_dbg,
 	.log_info = zep_shim_pr_info,
 	.log_err = zep_shim_pr_err,

 	.llist_node_alloc = zep_shim_llist_node_alloc,
 	.llist_node_free = zep_shim_llist_node_free,
 	.llist_node_data_get = zep_shim_llist_node_data_get,
 	.llist_node_data_set = zep_shim_llist_node_data_set,

 	.llist_alloc = zep_shim_llist_alloc,
 	.llist_free = zep_shim_llist_free,
 	.llist_init = zep_shim_llist_init,
 	.llist_add_node_tail = zep_shim_llist_add_node_tail,
 	.llist_add_node_head = zep_shim_llist_add_node_head,
 	.llist_get_node_head = zep_shim_llist_get_node_head,
 	.llist_get_node_nxt = zep_shim_llist_get_node_nxt,
 	.llist_del_node = zep_shim_llist_del_node,
 	.llist_len = zep_shim_llist_len,

 	.nbuf_alloc = zep_shim_nbuf_alloc,
 	.nbuf_free = zep_shim_nbuf_free,
 	.nbuf_headroom_res = zep_shim_nbuf_headroom_res,
 	.nbuf_headroom_get = zep_shim_nbuf_headroom_get,
 	.nbuf_data_size = zep_shim_nbuf_data_size,
 	.nbuf_data_get = zep_shim_nbuf_data_get,
 	.nbuf_data_put = zep_shim_nbuf_data_put,
 	.nbuf_data_push = zep_shim_nbuf_data_push,
 	.nbuf_data_pull = zep_shim_nbuf_data_pull,
 	.nbuf_get_priority = zep_shim_nbuf_get_priority,
 	.nbuf_get_chksum_done = zep_shim_nbuf_get_chksum_done,
 	.nbuf_set_chksum_done = zep_shim_nbuf_set_chksum_done,

 	.tasklet_alloc = zep_shim_work_alloc,
 	.tasklet_free = zep_shim_work_free,
 	.tasklet_init = zep_shim_work_init,
 	.tasklet_schedule = zep_shim_work_schedule,
 	.tasklet_kill = zep_shim_work_kill,

 	.sleep_ms = k_msleep,
 	.delay_us = k_usleep,
 	.time_get_curr_us = zep_shim_time_get_curr_us,
 	.time_elapsed_us = zep_shim_time_elapsed_us,

 	.bus_qspi_init = zep_shim_bus_qspi_init,
 	.bus_qspi_deinit = zep_shim_bus_qspi_deinit,
 	.bus_qspi_dev_add = zep_shim_bus_qspi_dev_add,
 	.bus_qspi_dev_rem = zep_shim_bus_qspi_dev_rem,
 	.bus_qspi_dev_init = zep_shim_bus_qspi_dev_init,
 	.bus_qspi_dev_deinit = zep_shim_bus_qspi_dev_deinit,
 	.bus_qspi_dev_intr_reg = zep_shim_bus_qspi_intr_reg,
 	.bus_qspi_dev_intr_unreg = zep_shim_bus_qspi_intr_unreg,
 	.bus_qspi_dev_host_map_get = zep_shim_bus_qspi_dev_host_map_get,

 #ifdef CONFIG_NRF_WIFI_LOW_POWER
 	.timer_alloc = zep_shim_timer_alloc,
 	.timer_init = zep_shim_timer_init,
 	.timer_free = zep_shim_timer_free,
 	.timer_schedule = zep_shim_timer_schedule,
 	.timer_kill = zep_shim_timer_kill,

 	.bus_qspi_ps_sleep = zep_shim_bus_qspi_ps_sleep,
 	.bus_qspi_ps_wake = zep_shim_bus_qspi_ps_wake,
 	.bus_qspi_ps_status = zep_shim_bus_qspi_ps_status,
 #endif /* CONFIG_NRF_WIFI_LOW_POWER */

 	.assert = zep_shim_assert,
 	.strlen = zep_shim_strlen,
 };
	/*
	* Copyright (c) 2024 Nordic Semiconductor ASA
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @brief Header containing OS specific definitions for the
	* Zephyr OS layer of the Wi-Fi driver.
	*/

	#include <stdio.h>
	#include <string.h>
	#include <sys/time.h>

	#include <zephyr/kernel.h>
	#include <zephyr/sys/printk.h>
	#include <zephyr/drivers/gpio.h>
	#include <zephyr/logging/log.h>
	#include <zephyr/sys/__assert.h>

	#include "rpu_hw_if.h"
	#include "shim.h"
	#include "work.h"
	#include "timer.h"
	#include "osal_ops.h"
	#include "qspi_if.h"

	LOG_MODULE_REGISTER(wifi_nrf, CONFIG_WIFI_NRF70_LOG_LEVEL);

	struct zep_shim_intr_priv *intr_priv;

	static void *zep_shim_mem_alloc(size_t size)
	{
	size_t size_aligned = ROUND_UP(size, 4);

	return k_malloc(size_aligned);
	}

	static void *zep_shim_mem_zalloc(size_t size)
	{
	size_t size_aligned = ROUND_UP(size, 4);

	return k_calloc(size_aligned, sizeof(char));
	}

	static void zep_shim_mem_cpy(void dest, const void *src, size_t count)
	{
	return memcpy(dest, src, count);
	}

	static void zep_shim_mem_set(void start, int val, size_t size)
	{
	return memset(start, val, size);
	}

	static int zep_shim_mem_cmp(const void *addr1,
	const void *addr2,
	size_t size)
	{
	return memcmp(addr1, addr2, size);
	}

	static unsigned int zep_shim_qspi_read_reg32(void *priv, unsigned long addr)
	{
	unsigned int val;
	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
	struct qspi_dev *dev;

	dev = qspi_priv->qspi_dev;

	if (addr < 0x0C0000) {
	dev->hl_read(addr, &val, 4);
	} else {
	dev->read(addr, &val, 4);
	}

	return val;
	}

	static void zep_shim_qspi_write_reg32(void *priv, unsigned long addr, unsigned int val)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
	struct qspi_dev *dev;

	dev = qspi_priv->qspi_dev;

	dev->write(addr, &val, 4);
	}

	static void zep_shim_qspi_cpy_from(void priv, void dest, unsigned long addr, size_t count)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
	struct qspi_dev *dev;
	size_t count_aligned = ROUND_UP(count, 4);

	dev = qspi_priv->qspi_dev;

	if (addr < 0x0C0000) {
	dev->hl_read(addr, dest, count_aligned);
	} else {
	dev->read(addr, dest, count_aligned);
	}
	}

	static void zep_shim_qspi_cpy_to(void priv, unsigned long addr, const void src, size_t count)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
	struct qspi_dev *dev;
	size_t count_aligned = ROUND_UP(count, 4);

	dev = qspi_priv->qspi_dev;

	dev->write(addr, src, count_aligned);
	}

	static void *zep_shim_spinlock_alloc(void)
	{
	struct k_sem *lock = NULL;

	lock = k_malloc(sizeof(*lock));

	if (!lock) {
	LOG_ERR("%s: Unable to allocate memory for spinlock", __func__);
	}

	return lock;
	}

	static void zep_shim_spinlock_free(void *lock)
	{
	k_free(lock);
	}

	static void zep_shim_spinlock_init(void *lock)
	{
	k_sem_init(lock, 1, 1);
	}

	static void zep_shim_spinlock_take(void *lock)
	{
	k_sem_take(lock, K_FOREVER);
	}

	static void zep_shim_spinlock_rel(void *lock)
	{
	k_sem_give(lock);
	}

	static void zep_shim_spinlock_irq_take(void lock, unsigned long flags)
	{
	k_sem_take(lock, K_FOREVER);
	}

	static void zep_shim_spinlock_irq_rel(void lock, unsigned long flags)
	{
	k_sem_give(lock);
	}

	static int zep_shim_pr_dbg(const char *fmt, va_list args)
	{
	static char buf[80];

	vsnprintf(buf, sizeof(buf), fmt, args);

	LOG_DBG("%s", buf);

	return 0;
	}

	static int zep_shim_pr_info(const char *fmt, va_list args)
	{
	static char buf[80];

	vsnprintf(buf, sizeof(buf), fmt, args);

	LOG_INF("%s", buf);

	return 0;
	}

	static int zep_shim_pr_err(const char *fmt, va_list args)
	{
	static char buf[256];

	vsnprintf(buf, sizeof(buf), fmt, args);

	LOG_ERR("%s", buf);

	return 0;
	}

	struct nwb {
	unsigned char *data;
	unsigned char *tail;
	int len;
	int headroom;
	void *next;
	void *priv;
	int iftype;
	void *ifaddr;
	void *dev;
	int hostbuffer;
	void *cleanup_ctx;
	void (*cleanup_cb)();
	unsigned char priority;
	bool chksum_done;
	};

	static void *zep_shim_nbuf_alloc(unsigned int size)
	{
	struct nwb *nbuff;

	nbuff = (struct nwb *)k_calloc(sizeof(struct nwb), sizeof(char));

	if (!nbuff)
	return NULL;

	nbuff->priv = k_calloc(size, sizeof(char));

	if (!nbuff->priv) {
	k_free(nbuff);
	return NULL;
	}

	nbuff->data = (unsigned char *)nbuff->priv;
	nbuff->tail = nbuff->data;
	nbuff->len = 0;
	nbuff->headroom = 0;
	nbuff->next = NULL;

	return nbuff;
	}

	static void zep_shim_nbuf_free(void *nbuf)
	{
	k_free(((struct nwb *)nbuf)->priv);
	k_free(nbuf);
	}

	static void zep_shim_nbuf_headroom_res(void *nbuf, unsigned int size)
	{
	struct nwb nwb = (struct nwb )nbuf;

	nwb->data += size;
	nwb->tail += size;
	nwb->headroom += size;
	}

	static unsigned int zep_shim_nbuf_headroom_get(void *nbuf)
	{
	return ((struct nwb *)nbuf)->headroom;
	}

	static unsigned int zep_shim_nbuf_data_size(void *nbuf)
	{
	return ((struct nwb *)nbuf)->len;
	}

	static void zep_shim_nbuf_data_get(void nbuf)
	{
	return ((struct nwb *)nbuf)->data;
	}

	static void zep_shim_nbuf_data_put(void nbuf, unsigned int size)
	{
	struct nwb nwb = (struct nwb )nbuf;
	unsigned char *data = nwb->tail;

	nwb->tail += size;
	nwb->len += size;

	return data;
	}

	static void zep_shim_nbuf_data_push(void nbuf, unsigned int size)
	{
	struct nwb nwb = (struct nwb )nbuf;

	nwb->data -= size;
	nwb->headroom -= size;
	nwb->len += size;

	return nwb->data;
	}

	static void zep_shim_nbuf_data_pull(void nbuf, unsigned int size)
	{
	struct nwb nwb = (struct nwb )nbuf;

	nwb->data += size;
	nwb->headroom += size;
	nwb->len -= size;

	return nwb->data;
	}

	static unsigned char zep_shim_nbuf_get_priority(void *nbuf)
	{
	struct nwb nwb = (struct nwb )nbuf;

	return nwb->priority;
	}

	static unsigned char zep_shim_nbuf_get_chksum_done(void *nbuf)
	{
	struct nwb nwb = (struct nwb )nbuf;

	return nwb->chksum_done;
	}

	static void zep_shim_nbuf_set_chksum_done(void *nbuf, unsigned char chksum_done)
	{
	struct nwb nwb = (struct nwb )nbuf;

	nwb->chksum_done = (bool)chksum_done;
	}

	#include <zephyr/net/ethernet.h>
	#include <zephyr/net/net_core.h>

	void net_pkt_to_nbuf(struct net_pkt pkt)
	{
	struct nwb *nbuff;
	unsigned char *data;
	unsigned int len;

	len = net_pkt_get_len(pkt);

	nbuff = zep_shim_nbuf_alloc(len + 100);

	if (!nbuff) {
	return NULL;
	}

	zep_shim_nbuf_headroom_res(nbuff, 100);

	data = zep_shim_nbuf_data_put(nbuff, len);

	net_pkt_read(pkt, data, len);

	nbuff->priority = net_pkt_priority(pkt);
	nbuff->chksum_done = (bool)net_pkt_is_chksum_done(pkt);

	return nbuff;
	}

	void net_pkt_from_nbuf(void iface, void *frm)
	{
	struct net_pkt *pkt = NULL;
	unsigned char *data;
	unsigned int len;
	struct nwb *nwb = frm;

	if (!nwb) {
	return NULL;
	}

	len = zep_shim_nbuf_data_size(nwb);

	data = zep_shim_nbuf_data_get(nwb);

	pkt = net_pkt_rx_alloc_with_buffer(iface, len, AF_UNSPEC, 0, K_MSEC(100));

	if (!pkt) {
	goto out;
	}

	if (net_pkt_write(pkt, data, len)) {
	net_pkt_unref(pkt);
	pkt = NULL;
	goto out;
	}

	out:
	zep_shim_nbuf_free(nwb);
	return pkt;
	}

	#if defined(CONFIG_NRF70_RAW_DATA_RX) \|\| defined(CONFIG_NRF70_PROMISC_DATA_RX)
	void net_raw_pkt_from_nbuf(void iface, void *frm,
	unsigned short raw_hdr_len,
	void *raw_rx_hdr,
	bool pkt_free)
	{
	struct net_pkt *pkt = NULL;
	unsigned char *nwb_data;
	unsigned char *data = NULL;
	unsigned int nwb_len;
	unsigned int total_len;
	struct nwb *nwb = frm;

	if (!nwb) {
	LOG_ERR("%s: Received network buffer is NULL", __func__);
	return NULL;
	}

	nwb_len = zep_shim_nbuf_data_size(nwb);
	nwb_data = zep_shim_nbuf_data_get(nwb);
	total_len = raw_hdr_len + nwb_len;

	data = (unsigned char *)k_malloc(total_len);
	if (!data) {
	LOG_ERR("%s: Unable to allocate memory for sniffer data packet", __func__);
	goto out;
	}

	pkt = net_pkt_rx_alloc_with_buffer(iface, total_len, AF_PACKET, ETH_P_ALL, K_MSEC(100));
	if (!pkt) {
	LOG_ERR("%s: Unable to allocate net packet buffer", __func__);
	goto out;
	}

	memcpy(data, raw_rx_hdr, raw_hdr_len);
	memcpy((data+raw_hdr_len), nwb_data, nwb_len);

	if (net_pkt_write(pkt, data, total_len)) {
	net_pkt_unref(pkt);
	pkt = NULL;
	goto out;
	}
	out:
	if (data != NULL) {
	k_free(data);
	}

	if (pkt_free) {
	zep_shim_nbuf_free(nwb);
	}

	return pkt;
	}
	#endif /* CONFIG_NRF70_RAW_DATA_RX \|\| CONFIG_NRF70_PROMISC_DATA_RX */

	static void *zep_shim_llist_node_alloc(void)
	{
	struct zep_shim_llist_node *llist_node = NULL;

	llist_node = k_calloc(sizeof(*llist_node), sizeof(char));

	if (!llist_node) {
	LOG_ERR("%s: Unable to allocate memory for linked list node", __func__);
	return NULL;
	}

	sys_dnode_init(&llist_node->head);

	return llist_node;
	}

	static void zep_shim_llist_node_free(void *llist_node)
	{
	k_free(llist_node);
	}

	static void zep_shim_llist_node_data_get(void llist_node)
	{
	struct zep_shim_llist_node *zep_llist_node = NULL;

	zep_llist_node = (struct zep_shim_llist_node *)llist_node;

	return zep_llist_node->data;
	}

	static void zep_shim_llist_node_data_set(void llist_node, void data)
	{
	struct zep_shim_llist_node *zep_llist_node = NULL;

	zep_llist_node = (struct zep_shim_llist_node *)llist_node;

	zep_llist_node->data = data;
	}

	static void *zep_shim_llist_alloc(void)
	{
	struct zep_shim_llist *llist = NULL;

	llist = k_calloc(sizeof(*llist), sizeof(char));

	if (!llist) {
	LOG_ERR("%s: Unable to allocate memory for linked list", __func__);
	}

	return llist;
	}

	static void zep_shim_llist_free(void *llist)
	{
	k_free(llist);
	}

	static void zep_shim_llist_init(void *llist)
	{
	struct zep_shim_llist *zep_llist = NULL;

	zep_llist = (struct zep_shim_llist *)llist;

	sys_dlist_init(&zep_llist->head);
	}

	static void zep_shim_llist_add_node_tail(void llist, void llist_node)
	{
	struct zep_shim_llist *zep_llist = NULL;
	struct zep_shim_llist_node *zep_node = NULL;

	zep_llist = (struct zep_shim_llist *)llist;
	zep_node = (struct zep_shim_llist_node *)llist_node;

	sys_dlist_append(&zep_llist->head, &zep_node->head);

	zep_llist->len += 1;
	}

	static void zep_shim_llist_add_node_head(void llist, void llist_node)
	{
	struct zep_shim_llist *zep_llist = NULL;
	struct zep_shim_llist_node *zep_node = NULL;

	zep_llist = (struct zep_shim_llist *)llist;
	zep_node = (struct zep_shim_llist_node *)llist_node;

	sys_dlist_prepend(&zep_llist->head, &zep_node->head);

	zep_llist->len += 1;
	}

	static void zep_shim_llist_get_node_head(void llist)
	{
	struct zep_shim_llist_node *zep_head_node = NULL;
	struct zep_shim_llist *zep_llist = NULL;

	zep_llist = (struct zep_shim_llist *)llist;

	if (!zep_llist->len) {
	return NULL;
	}

	zep_head_node = (struct zep_shim_llist_node *)sys_dlist_peek_head(&zep_llist->head);

	return zep_head_node;
	}

	static void zep_shim_llist_get_node_nxt(void llist, void *llist_node)
	{
	struct zep_shim_llist_node *zep_node = NULL;
	struct zep_shim_llist_node *zep_nxt_node = NULL;
	struct zep_shim_llist *zep_llist = NULL;

	zep_llist = (struct zep_shim_llist *)llist;
	zep_node = (struct zep_shim_llist_node *)llist_node;

	zep_nxt_node = (struct zep_shim_llist_node *)sys_dlist_peek_next(&zep_llist->head,
	&zep_node->head);

	return zep_nxt_node;
	}

	static void zep_shim_llist_del_node(void llist, void llist_node)
	{
	struct zep_shim_llist_node *zep_node = NULL;
	struct zep_shim_llist *zep_llist = NULL;

	zep_llist = (struct zep_shim_llist *)llist;
	zep_node = (struct zep_shim_llist_node *)llist_node;

	sys_dlist_remove(&zep_node->head);

	zep_llist->len -= 1;
	}

	static unsigned int zep_shim_llist_len(void *llist)
	{
	struct zep_shim_llist *zep_llist = NULL;

	zep_llist = (struct zep_shim_llist *)llist;

	return zep_llist->len;
	}

	static void *zep_shim_work_alloc(int type)
	{
	return work_alloc(type);
	}

	static void zep_shim_work_free(void *item)
	{
	return work_free(item);
	}

	static void zep_shim_work_init(void item, void (callback)(unsigned long data),
	unsigned long data)
	{
	work_init(item, callback, data);
	}

	static void zep_shim_work_schedule(void *item)
	{
	work_schedule(item);
	}

	static void zep_shim_work_kill(void *item)
	{
	work_kill(item);
	}

	static unsigned long zep_shim_time_get_curr_us(void)
	{
	return k_uptime_get() * USEC_PER_MSEC;
	}

	static unsigned int zep_shim_time_elapsed_us(unsigned long start_time_us)
	{
	unsigned long curr_time_us = 0;

	curr_time_us = zep_shim_time_get_curr_us();

	return curr_time_us - start_time_us;
	}

	static enum nrf_wifi_status zep_shim_bus_qspi_dev_init(void *os_qspi_dev_ctx)
	{
	ARG_UNUSED(os_qspi_dev_ctx);

	return NRF_WIFI_STATUS_SUCCESS;
	}

	static void zep_shim_bus_qspi_dev_deinit(void *priv)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
	volatile struct qspi_dev *dev = qspi_priv->qspi_dev;

	dev->deinit();
	}

	static void zep_shim_bus_qspi_dev_add(void os_qspi_priv, void *osal_qspi_dev_ctx)
	{
	struct zep_shim_bus_qspi_priv *zep_qspi_priv = os_qspi_priv;
	struct qspi_dev *dev = qspi_dev();
	int ret;
	enum nrf_wifi_status status;

	ret = rpu_init();
	if (ret) {
	LOG_ERR("%s: RPU init failed with error %d", __func__, ret);
	return NULL;
	}

	status = dev->init(qspi_defconfig());
	if (status != NRF_WIFI_STATUS_SUCCESS) {
	LOG_ERR("%s: QSPI device init failed", __func__);
	return NULL;
	}

	ret = rpu_enable();
	if (ret) {
	LOG_ERR("%s: RPU enable failed with error %d", __func__, ret);
	return NULL;
	}
	zep_qspi_priv->qspi_dev = dev;
	zep_qspi_priv->dev_added = true;

	return zep_qspi_priv;
	}

	static void zep_shim_bus_qspi_dev_rem(void *priv)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = priv;
	struct qspi_dev *dev = qspi_priv->qspi_dev;

	ARG_UNUSED(dev);

	/* TODO: Make qspi_dev a dynamic instance and remove it here */
	rpu_disable();
	}

	static void *zep_shim_bus_qspi_init(void)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = NULL;

	qspi_priv = k_calloc(sizeof(*qspi_priv), sizeof(char));

	if (!qspi_priv) {
	LOG_ERR("%s: Unable to allocate memory for qspi_priv", __func__);
	goto out;
	}
	out:
	return qspi_priv;
	}

	static void zep_shim_bus_qspi_deinit(void *os_qspi_priv)
	{
	struct zep_shim_bus_qspi_priv *qspi_priv = NULL;

	qspi_priv = os_qspi_priv;

	k_free(qspi_priv);
	}

	#ifdef CONFIG_NRF_WIFI_LOW_POWER
	static int zep_shim_bus_qspi_ps_sleep(void *os_qspi_priv)
	{
	rpu_sleep();

	return 0;
	}

	static int zep_shim_bus_qspi_ps_wake(void *os_qspi_priv)
	{
	rpu_wakeup();

	return 0;
	}

	static int zep_shim_bus_qspi_ps_status(void *os_qspi_priv)
	{
	return rpu_sleep_status();
	}
	#endif /* CONFIG_NRF_WIFI_LOW_POWER */

	static void zep_shim_bus_qspi_dev_host_map_get(void *os_qspi_dev_ctx,
	struct nrf_wifi_osal_host_map *host_map)
	{
	if (!os_qspi_dev_ctx \|\| !host_map) {
	LOG_ERR("%s: Invalid parameters", __func__);
	return;
	}

	host_map->addr = 0;
	}

	static void irq_work_handler(struct k_work *work)
	{
	int ret = 0;

	ret = intr_priv->callbk_fn(intr_priv->callbk_data);

	if (ret) {
	LOG_ERR("%s: Interrupt callback failed", __func__);
	}
	}


	extern struct k_work_q zep_wifi_intr_q;

	static void zep_shim_irq_handler(const struct device dev, struct gpio_callback cb, uint32_t pins)
	{
	ARG_UNUSED(cb);
	ARG_UNUSED(pins);

	k_work_schedule_for_queue(&zep_wifi_intr_q, &intr_priv->work, K_NO_WAIT);
	}

	static enum nrf_wifi_status zep_shim_bus_qspi_intr_reg(void os_dev_ctx, void callbk_data,
	int (callbk_fn)(void callbk_data))
	{
	enum nrf_wifi_status status = NRF_WIFI_STATUS_FAIL;
	int ret = -1;

	ARG_UNUSED(os_dev_ctx);

	intr_priv = k_calloc(sizeof(*intr_priv), sizeof(char));

	if (!intr_priv) {
	LOG_ERR("%s: Unable to allocate memory for intr_priv", __func__);
	goto out;
	}

	intr_priv->callbk_data = callbk_data;
	intr_priv->callbk_fn = callbk_fn;

	k_work_init_delayable(&intr_priv->work, irq_work_handler);

	ret = rpu_irq_config(&intr_priv->gpio_cb_data, zep_shim_irq_handler);

	if (ret) {
	LOG_ERR("%s: request_irq failed", __func__);
	k_free(intr_priv);
	intr_priv = NULL;
	goto out;
	}

	status = NRF_WIFI_STATUS_SUCCESS;

	out:
	return status;
	}

	static void zep_shim_bus_qspi_intr_unreg(void *os_qspi_dev_ctx)
	{
	struct k_work_sync sync;
	int ret;

	ARG_UNUSED(os_qspi_dev_ctx);

	ret = rpu_irq_remove(&intr_priv->gpio_cb_data);
	if (ret) {
	LOG_ERR("%s: rpu_irq_remove failed", __func__);
	return;
	}

	k_work_cancel_delayable_sync(&intr_priv->work, &sync);

	k_free(intr_priv);
	intr_priv = NULL;
	}

	#ifdef CONFIG_NRF_WIFI_LOW_POWER
	static void *zep_shim_timer_alloc(void)
	{
	struct timer_list *timer = NULL;

	timer = k_malloc(sizeof(*timer));

	if (!timer)
	LOG_ERR("%s: Unable to allocate memory for work", __func__);

	return timer;
	}

	static void zep_shim_timer_init(void timer, void (callback)(unsigned long), unsigned long data)
	{
	((struct timer_list *)timer)->function = callback;
	((struct timer_list *)timer)->data = data;

	init_timer(timer);
	}

	static void zep_shim_timer_free(void *timer)
	{
	k_free(timer);
	}

	static void zep_shim_timer_schedule(void *timer, unsigned long duration)
	{
	mod_timer(timer, duration);
	}

	static void zep_shim_timer_kill(void *timer)
	{
	del_timer_sync(timer);
	}
	#endif /* CONFIG_NRF_WIFI_LOW_POWER */

	static void zep_shim_assert(int test_val, int val, enum nrf_wifi_assert_op_type op, char *msg)
	{
	switch (op) {
	case NRF_WIFI_ASSERT_EQUAL_TO:
	NET_ASSERT(test_val == val, "%s", msg);
	break;
	case NRF_WIFI_ASSERT_NOT_EQUAL_TO:
	NET_ASSERT(test_val != val, "%s", msg);
	break;
	case NRF_WIFI_ASSERT_LESS_THAN:
	NET_ASSERT(test_val < val, "%s", msg);
	break;
	case NRF_WIFI_ASSERT_LESS_THAN_EQUAL_TO:
	NET_ASSERT(test_val <= val, "%s", msg);
	break;
	case NRF_WIFI_ASSERT_GREATER_THAN:
	NET_ASSERT(test_val > val, "%s", msg);
	break;
	case NRF_WIFI_ASSERT_GREATER_THAN_EQUAL_TO:
	NET_ASSERT(test_val >= val, "%s", msg);
	break;
	default:
	LOG_ERR("%s: Invalid assertion operation", __func__);
	}
	}

	static unsigned int zep_shim_strlen(const void *str)
	{
	return strlen(str);
	}

	const struct nrf_wifi_osal_ops nrf_wifi_os_zep_ops = {
	.mem_alloc = zep_shim_mem_alloc,
	.mem_zalloc = zep_shim_mem_zalloc,
	.mem_free = k_free,
	.mem_cpy = zep_shim_mem_cpy,
	.mem_set = zep_shim_mem_set,
	.mem_cmp = zep_shim_mem_cmp,

	.qspi_read_reg32 = zep_shim_qspi_read_reg32,
	.qspi_write_reg32 = zep_shim_qspi_write_reg32,
	.qspi_cpy_from = zep_shim_qspi_cpy_from,
	.qspi_cpy_to = zep_shim_qspi_cpy_to,

	.spinlock_alloc = zep_shim_spinlock_alloc,
	.spinlock_free = zep_shim_spinlock_free,
	.spinlock_init = zep_shim_spinlock_init,
	.spinlock_take = zep_shim_spinlock_take,
	.spinlock_rel = zep_shim_spinlock_rel,

	.spinlock_irq_take = zep_shim_spinlock_irq_take,
	.spinlock_irq_rel = zep_shim_spinlock_irq_rel,

	.log_dbg = zep_shim_pr_dbg,
	.log_info = zep_shim_pr_info,
	.log_err = zep_shim_pr_err,

	.llist_node_alloc = zep_shim_llist_node_alloc,
	.llist_node_free = zep_shim_llist_node_free,
	.llist_node_data_get = zep_shim_llist_node_data_get,
	.llist_node_data_set = zep_shim_llist_node_data_set,

	.llist_alloc = zep_shim_llist_alloc,
	.llist_free = zep_shim_llist_free,
	.llist_init = zep_shim_llist_init,
	.llist_add_node_tail = zep_shim_llist_add_node_tail,
	.llist_add_node_head = zep_shim_llist_add_node_head,
	.llist_get_node_head = zep_shim_llist_get_node_head,
	.llist_get_node_nxt = zep_shim_llist_get_node_nxt,
	.llist_del_node = zep_shim_llist_del_node,
	.llist_len = zep_shim_llist_len,

	.nbuf_alloc = zep_shim_nbuf_alloc,
	.nbuf_free = zep_shim_nbuf_free,
	.nbuf_headroom_res = zep_shim_nbuf_headroom_res,
	.nbuf_headroom_get = zep_shim_nbuf_headroom_get,
	.nbuf_data_size = zep_shim_nbuf_data_size,
	.nbuf_data_get = zep_shim_nbuf_data_get,
	.nbuf_data_put = zep_shim_nbuf_data_put,
	.nbuf_data_push = zep_shim_nbuf_data_push,
	.nbuf_data_pull = zep_shim_nbuf_data_pull,
	.nbuf_get_priority = zep_shim_nbuf_get_priority,
	.nbuf_get_chksum_done = zep_shim_nbuf_get_chksum_done,
	.nbuf_set_chksum_done = zep_shim_nbuf_set_chksum_done,

	.tasklet_alloc = zep_shim_work_alloc,
	.tasklet_free = zep_shim_work_free,
	.tasklet_init = zep_shim_work_init,
	.tasklet_schedule = zep_shim_work_schedule,
	.tasklet_kill = zep_shim_work_kill,

	.sleep_ms = k_msleep,
	.delay_us = k_usleep,
	.time_get_curr_us = zep_shim_time_get_curr_us,
	.time_elapsed_us = zep_shim_time_elapsed_us,

	.bus_qspi_init = zep_shim_bus_qspi_init,
	.bus_qspi_deinit = zep_shim_bus_qspi_deinit,
	.bus_qspi_dev_add = zep_shim_bus_qspi_dev_add,
	.bus_qspi_dev_rem = zep_shim_bus_qspi_dev_rem,
	.bus_qspi_dev_init = zep_shim_bus_qspi_dev_init,
	.bus_qspi_dev_deinit = zep_shim_bus_qspi_dev_deinit,
	.bus_qspi_dev_intr_reg = zep_shim_bus_qspi_intr_reg,
	.bus_qspi_dev_intr_unreg = zep_shim_bus_qspi_intr_unreg,
	.bus_qspi_dev_host_map_get = zep_shim_bus_qspi_dev_host_map_get,

	#ifdef CONFIG_NRF_WIFI_LOW_POWER
	.timer_alloc = zep_shim_timer_alloc,
	.timer_init = zep_shim_timer_init,
	.timer_free = zep_shim_timer_free,
	.timer_schedule = zep_shim_timer_schedule,
	.timer_kill = zep_shim_timer_kill,

	.bus_qspi_ps_sleep = zep_shim_bus_qspi_ps_sleep,
	.bus_qspi_ps_wake = zep_shim_bus_qspi_ps_wake,
	.bus_qspi_ps_status = zep_shim_bus_qspi_ps_status,
	#endif /* CONFIG_NRF_WIFI_LOW_POWER */

	.assert = zep_shim_assert,
	.strlen = zep_shim_strlen,
	};