drivers/net/ethernet/intel/idpf/idpf_controlq.c - third_party/kernel - Git at Google

 // SPDX-License-Identifier: GPL-2.0-only
 /* Copyright (C) 2023 Intel Corporation */

 #include "idpf_controlq.h"

 /**
  * idpf_ctlq_setup_regs - initialize control queue registers
  * @cq: pointer to the specific control queue
  * @q_create_info: structs containing info for each queue to be initialized
  */
 static void idpf_ctlq_setup_regs(struct idpf_ctlq_info *cq,
 				 struct idpf_ctlq_create_info *q_create_info)
 {
 	/* set control queue registers in our local struct */
 	cq->reg.head = q_create_info->reg.head;
 	cq->reg.tail = q_create_info->reg.tail;
 	cq->reg.len = q_create_info->reg.len;
 	cq->reg.bah = q_create_info->reg.bah;
 	cq->reg.bal = q_create_info->reg.bal;
 	cq->reg.len_mask = q_create_info->reg.len_mask;
 	cq->reg.len_ena_mask = q_create_info->reg.len_ena_mask;
 	cq->reg.head_mask = q_create_info->reg.head_mask;
 }

 /**
  * idpf_ctlq_init_regs - Initialize control queue registers
  * @hw: pointer to hw struct
  * @cq: pointer to the specific Control queue
  * @is_rxq: true if receive control queue, false otherwise
  *
  * Initialize registers. The caller is expected to have already initialized the
  * descriptor ring memory and buffer memory
  */
 static void idpf_ctlq_init_regs(struct idpf_hw *hw, struct idpf_ctlq_info *cq,
 				bool is_rxq)
 {
 	/* Update tail to post pre-allocated buffers for rx queues */
 	if (is_rxq)
 		wr32(hw, cq->reg.tail, (u32)(cq->ring_size - 1));

 	/* For non-Mailbox control queues only TAIL need to be set */
 	if (cq->q_id != -1)
 		return;

 	/* Clear Head for both send or receive */
 	wr32(hw, cq->reg.head, 0);

 	/* set starting point */
 	wr32(hw, cq->reg.bal, lower_32_bits(cq->desc_ring.pa));
 	wr32(hw, cq->reg.bah, upper_32_bits(cq->desc_ring.pa));
 	wr32(hw, cq->reg.len, (cq->ring_size | cq->reg.len_ena_mask));
 }

 /**
  * idpf_ctlq_init_rxq_bufs - populate receive queue descriptors with buf
  * @cq: pointer to the specific Control queue
  *
  * Record the address of the receive queue DMA buffers in the descriptors.
  * The buffers must have been previously allocated.
  */
 static void idpf_ctlq_init_rxq_bufs(struct idpf_ctlq_info *cq)
 {
 	int i;

 	for (i = 0; i < cq->ring_size; i++) {
 		struct idpf_ctlq_desc *desc = IDPF_CTLQ_DESC(cq, i);
 		struct idpf_dma_mem *bi = cq->bi.rx_buff[i];

 		/* No buffer to post to descriptor, continue */
 		if (!bi)
 			continue;

 		desc->flags =
 			cpu_to_le16(IDPF_CTLQ_FLAG_BUF | IDPF_CTLQ_FLAG_RD);
 		desc->opcode = 0;
 		desc->datalen = cpu_to_le16(bi->size);
 		desc->ret_val = 0;
 		desc->v_opcode_dtype = 0;
 		desc->v_retval = 0;
 		desc->params.indirect.addr_high =
 			cpu_to_le32(upper_32_bits(bi->pa));
 		desc->params.indirect.addr_low =
 			cpu_to_le32(lower_32_bits(bi->pa));
 		desc->params.indirect.param0 = 0;
 		desc->params.indirect.sw_cookie = 0;
 		desc->params.indirect.v_flags = 0;
 	}
 }

 /**
  * idpf_ctlq_shutdown - shutdown the CQ
  * @hw: pointer to hw struct
  * @cq: pointer to the specific Control queue
  *
  * The main shutdown routine for any controq queue
  */
 static void idpf_ctlq_shutdown(struct idpf_hw *hw, struct idpf_ctlq_info *cq)
 {
 	mutex_lock(&cq->cq_lock);

 	/* free ring buffers and the ring itself */
 	idpf_ctlq_dealloc_ring_res(hw, cq);

 	/* Set ring_size to 0 to indicate uninitialized queue */
 	cq->ring_size = 0;

 	mutex_unlock(&cq->cq_lock);
 	mutex_destroy(&cq->cq_lock);
 }

 /**
  * idpf_ctlq_add - add one control queue
  * @hw: pointer to hardware struct
  * @qinfo: info for queue to be created
  * @cq_out: (output) double pointer to control queue to be created
  *
  * Allocate and initialize a control queue and add it to the control queue list.
  * The cq parameter will be allocated/initialized and passed back to the caller
  * if no errors occur.
  *
  * Note: idpf_ctlq_init must be called prior to any calls to idpf_ctlq_add
  */
 int idpf_ctlq_add(struct idpf_hw *hw,
 		  struct idpf_ctlq_create_info *qinfo,
 		  struct idpf_ctlq_info **cq_out)
 {
 	struct idpf_ctlq_info *cq;
 	bool is_rxq = false;
 	int err;

 	cq = kzalloc(sizeof(*cq), GFP_KERNEL);
 	if (!cq)
 		return -ENOMEM;

 	cq->cq_type = qinfo->type;
 	cq->q_id = qinfo->id;
 	cq->buf_size = qinfo->buf_size;
 	cq->ring_size = qinfo->len;

 	cq->next_to_use = 0;
 	cq->next_to_clean = 0;
 	cq->next_to_post = cq->ring_size - 1;

 	switch (qinfo->type) {
 	case IDPF_CTLQ_TYPE_MAILBOX_RX:
 		is_rxq = true;
 		fallthrough;
 	case IDPF_CTLQ_TYPE_MAILBOX_TX:
 		err = idpf_ctlq_alloc_ring_res(hw, cq);
 		break;
 	default:
 		err = -EBADR;
 		break;
 	}

 	if (err)
 		goto init_free_q;

 	if (is_rxq) {
 		idpf_ctlq_init_rxq_bufs(cq);
 	} else {
 		/* Allocate the array of msg pointers for TX queues */
 		cq->bi.tx_msg = kcalloc(qinfo->len,
 					sizeof(struct idpf_ctlq_msg *),
 					GFP_KERNEL);
 		if (!cq->bi.tx_msg) {
 			err = -ENOMEM;
 			goto init_dealloc_q_mem;
 		}
 	}

 	idpf_ctlq_setup_regs(cq, qinfo);

 	idpf_ctlq_init_regs(hw, cq, is_rxq);

 	mutex_init(&cq->cq_lock);

 	list_add(&cq->cq_list, &hw->cq_list_head);

 	*cq_out = cq;

 	return 0;

 init_dealloc_q_mem:
 	/* free ring buffers and the ring itself */
 	idpf_ctlq_dealloc_ring_res(hw, cq);
 init_free_q:
 	kfree(cq);

 	return err;
 }

 /**
  * idpf_ctlq_remove - deallocate and remove specified control queue
  * @hw: pointer to hardware struct
  * @cq: pointer to control queue to be removed
  */
 void idpf_ctlq_remove(struct idpf_hw *hw,
 		      struct idpf_ctlq_info *cq)
 {
 	list_del(&cq->cq_list);
 	idpf_ctlq_shutdown(hw, cq);
 	kfree(cq);
 }

 /**
  * idpf_ctlq_init - main initialization routine for all control queues
  * @hw: pointer to hardware struct
  * @num_q: number of queues to initialize
  * @q_info: array of structs containing info for each queue to be initialized
  *
  * This initializes any number and any type of control queues. This is an all
  * or nothing routine; if one fails, all previously allocated queues will be
  * destroyed. This must be called prior to using the individual add/remove
  * APIs.
  */
 int idpf_ctlq_init(struct idpf_hw *hw, u8 num_q,
 		   struct idpf_ctlq_create_info *q_info)
 {
 	struct idpf_ctlq_info *cq, *tmp;
 	int err;
 	int i;

 	INIT_LIST_HEAD(&hw->cq_list_head);

 	for (i = 0; i < num_q; i++) {
 		struct idpf_ctlq_create_info *qinfo = q_info + i;

 		err = idpf_ctlq_add(hw, qinfo, &cq);
 		if (err)
 			goto init_destroy_qs;
 	}

 	return 0;

 init_destroy_qs:
 	list_for_each_entry_safe(cq, tmp, &hw->cq_list_head, cq_list)
 		idpf_ctlq_remove(hw, cq);

 	return err;
 }

 /**
  * idpf_ctlq_deinit - destroy all control queues
  * @hw: pointer to hw struct
  */
 void idpf_ctlq_deinit(struct idpf_hw *hw)
 {
 	struct idpf_ctlq_info *cq, *tmp;

 	list_for_each_entry_safe(cq, tmp, &hw->cq_list_head, cq_list)
 		idpf_ctlq_remove(hw, cq);
 }

 /**
  * idpf_ctlq_send - send command to Control Queue (CTQ)
  * @hw: pointer to hw struct
  * @cq: handle to control queue struct to send on
  * @num_q_msg: number of messages to send on control queue
  * @q_msg: pointer to array of queue messages to be sent
  *
  * The caller is expected to allocate DMAable buffers and pass them to the
  * send routine via the q_msg struct / control queue specific data struct.
  * The control queue will hold a reference to each send message until
  * the completion for that message has been cleaned.
  */
 int idpf_ctlq_send(struct idpf_hw *hw, struct idpf_ctlq_info *cq,
 		   u16 num_q_msg, struct idpf_ctlq_msg q_msg[])
 {
 	struct idpf_ctlq_desc *desc;
 	int num_desc_avail;
 	int err = 0;
 	int i;

 	mutex_lock(&cq->cq_lock);

 	/* Ensure there are enough descriptors to send all messages */
 	num_desc_avail = IDPF_CTLQ_DESC_UNUSED(cq);
 	if (num_desc_avail == 0 || num_desc_avail < num_q_msg) {
 		err = -ENOSPC;
 		goto err_unlock;
 	}

 	for (i = 0; i < num_q_msg; i++) {
 		struct idpf_ctlq_msg *msg = &q_msg[i];

 		desc = IDPF_CTLQ_DESC(cq, cq->next_to_use);

 		desc->opcode = cpu_to_le16(msg->opcode);
 		desc->pfid_vfid = cpu_to_le16(msg->func_id);

 		desc->v_opcode_dtype = cpu_to_le32(msg->cookie.mbx.chnl_opcode);
 		desc->v_retval = cpu_to_le32(msg->cookie.mbx.chnl_retval);

 		desc->flags = cpu_to_le16((msg->host_id & IDPF_HOST_ID_MASK) <<
 					  IDPF_CTLQ_FLAG_HOST_ID_S);
 		if (msg->data_len) {
 			struct idpf_dma_mem *buff = msg->ctx.indirect.payload;

 			desc->datalen |= cpu_to_le16(msg->data_len);
 			desc->flags |= cpu_to_le16(IDPF_CTLQ_FLAG_BUF);
 			desc->flags |= cpu_to_le16(IDPF_CTLQ_FLAG_RD);

 			/* Update the address values in the desc with the pa
 			 * value for respective buffer
 			 */
 			desc->params.indirect.addr_high =
 				cpu_to_le32(upper_32_bits(buff->pa));
 			desc->params.indirect.addr_low =
 				cpu_to_le32(lower_32_bits(buff->pa));

 			memcpy(&desc->params, msg->ctx.indirect.context,
 			       IDPF_INDIRECT_CTX_SIZE);
 		} else {
 			memcpy(&desc->params, msg->ctx.direct,
 			       IDPF_DIRECT_CTX_SIZE);
 		}

 		/* Store buffer info */
 		cq->bi.tx_msg[cq->next_to_use] = msg;

 		(cq->next_to_use)++;
 		if (cq->next_to_use == cq->ring_size)
 			cq->next_to_use = 0;
 	}

 	/* Force memory write to complete before letting hardware
 	 * know that there are new descriptors to fetch.
 	 */
 	dma_wmb();

 	wr32(hw, cq->reg.tail, cq->next_to_use);

 err_unlock:
 	mutex_unlock(&cq->cq_lock);

 	return err;
 }

 /**
  * idpf_ctlq_clean_sq - reclaim send descriptors on HW write back for the
  * requested queue
  * @cq: pointer to the specific Control queue
  * @clean_count: (input|output) number of descriptors to clean as input, and
  * number of descriptors actually cleaned as output
  * @msg_status: (output) pointer to msg pointer array to be populated; needs
  * to be allocated by caller
  *
  * Returns an array of message pointers associated with the cleaned
  * descriptors. The pointers are to the original ctlq_msgs sent on the cleaned
  * descriptors.  The status will be returned for each; any messages that failed
  * to send will have a non-zero status. The caller is expected to free original
  * ctlq_msgs and free or reuse the DMA buffers.
  */
 int idpf_ctlq_clean_sq(struct idpf_ctlq_info *cq, u16 *clean_count,
 		       struct idpf_ctlq_msg *msg_status[])
 {
 	struct idpf_ctlq_desc *desc;
 	u16 i, num_to_clean;
 	u16 ntc, desc_err;

 	if (*clean_count == 0)
 		return 0;
 	if (*clean_count > cq->ring_size)
 		return -EBADR;

 	mutex_lock(&cq->cq_lock);

 	ntc = cq->next_to_clean;

 	num_to_clean = *clean_count;

 	for (i = 0; i < num_to_clean; i++) {
 		/* Fetch next descriptor and check if marked as done */
 		desc = IDPF_CTLQ_DESC(cq, ntc);
 		if (!(le16_to_cpu(desc->flags) & IDPF_CTLQ_FLAG_DD))
 			break;

 		/* strip off FW internal code */
 		desc_err = le16_to_cpu(desc->ret_val) & 0xff;

 		msg_status[i] = cq->bi.tx_msg[ntc];
 		msg_status[i]->status = desc_err;

 		cq->bi.tx_msg[ntc] = NULL;

 		/* Zero out any stale data */
 		memset(desc, 0, sizeof(*desc));

 		ntc++;
 		if (ntc == cq->ring_size)
 			ntc = 0;
 	}

 	cq->next_to_clean = ntc;

 	mutex_unlock(&cq->cq_lock);

 	/* Return number of descriptors actually cleaned */
 	*clean_count = i;

 	return 0;
 }

 /**
  * idpf_ctlq_post_rx_buffs - post buffers to descriptor ring
  * @hw: pointer to hw struct
  * @cq: pointer to control queue handle
  * @buff_count: (input|output) input is number of buffers caller is trying to
  * return; output is number of buffers that were not posted
  * @buffs: array of pointers to dma mem structs to be given to hardware
  *
  * Caller uses this function to return DMA buffers to the descriptor ring after
  * consuming them; buff_count will be the number of buffers.
  *
  * Note: this function needs to be called after a receive call even
  * if there are no DMA buffers to be returned, i.e. buff_count = 0,
  * buffs = NULL to support direct commands
  */
 int idpf_ctlq_post_rx_buffs(struct idpf_hw *hw, struct idpf_ctlq_info *cq,
 			    u16 *buff_count, struct idpf_dma_mem **buffs)
 {
 	struct idpf_ctlq_desc *desc;
 	u16 ntp = cq->next_to_post;
 	bool buffs_avail = false;
 	u16 tbp = ntp + 1;
 	int i = 0;

 	if (*buff_count > cq->ring_size)
 		return -EBADR;

 	if (*buff_count > 0)
 		buffs_avail = true;

 	mutex_lock(&cq->cq_lock);

 	if (tbp >= cq->ring_size)
 		tbp = 0;

 	if (tbp == cq->next_to_clean)
 		/* Nothing to do */
 		goto post_buffs_out;

 	/* Post buffers for as many as provided or up until the last one used */
 	while (ntp != cq->next_to_clean) {
 		desc = IDPF_CTLQ_DESC(cq, ntp);

 		if (cq->bi.rx_buff[ntp])
 			goto fill_desc;
 		if (!buffs_avail) {
 			/* If the caller hasn't given us any buffers or
 			 * there are none left, search the ring itself
 			 * for an available buffer to move to this
 			 * entry starting at the next entry in the ring
 			 */
 			tbp = ntp + 1;

 			/* Wrap ring if necessary */
 			if (tbp >= cq->ring_size)
 				tbp = 0;

 			while (tbp != cq->next_to_clean) {
 				if (cq->bi.rx_buff[tbp]) {
 					cq->bi.rx_buff[ntp] =
 						cq->bi.rx_buff[tbp];
 					cq->bi.rx_buff[tbp] = NULL;

 					/* Found a buffer, no need to
 					 * search anymore
 					 */
 					break;
 				}

 				/* Wrap ring if necessary */
 				tbp++;
 				if (tbp >= cq->ring_size)
 					tbp = 0;
 			}

 			if (tbp == cq->next_to_clean)
 				goto post_buffs_out;
 		} else {
 			/* Give back pointer to DMA buffer */
 			cq->bi.rx_buff[ntp] = buffs[i];
 			i++;

 			if (i >= *buff_count)
 				buffs_avail = false;
 		}

 fill_desc:
 		desc->flags =
 			cpu_to_le16(IDPF_CTLQ_FLAG_BUF | IDPF_CTLQ_FLAG_RD);

 		/* Post buffers to descriptor */
 		desc->datalen = cpu_to_le16(cq->bi.rx_buff[ntp]->size);
 		desc->params.indirect.addr_high =
 			cpu_to_le32(upper_32_bits(cq->bi.rx_buff[ntp]->pa));
 		desc->params.indirect.addr_low =
 			cpu_to_le32(lower_32_bits(cq->bi.rx_buff[ntp]->pa));

 		ntp++;
 		if (ntp == cq->ring_size)
 			ntp = 0;
 	}

 post_buffs_out:
 	/* Only update tail if buffers were actually posted */
 	if (cq->next_to_post != ntp) {
 		if (ntp)
 			/* Update next_to_post to ntp - 1 since current ntp
 			 * will not have a buffer
 			 */
 			cq->next_to_post = ntp - 1;
 		else
 			/* Wrap to end of end ring since current ntp is 0 */
 			cq->next_to_post = cq->ring_size - 1;

 		wr32(hw, cq->reg.tail, cq->next_to_post);
 	}

 	mutex_unlock(&cq->cq_lock);

 	/* return the number of buffers that were not posted */
 	*buff_count = *buff_count - i;

 	return 0;
 }

 /**
  * idpf_ctlq_recv - receive control queue message call back
  * @cq: pointer to control queue handle to receive on
  * @num_q_msg: (input|output) input number of messages that should be received;
  * output number of messages actually received
  * @q_msg: (output) array of received control queue messages on this q;
  * needs to be pre-allocated by caller for as many messages as requested
  *
  * Called by interrupt handler or polling mechanism. Caller is expected
  * to free buffers
  */
 int idpf_ctlq_recv(struct idpf_ctlq_info *cq, u16 *num_q_msg,
 		   struct idpf_ctlq_msg *q_msg)
 {
 	u16 num_to_clean, ntc, flags;
 	struct idpf_ctlq_desc *desc;
 	int err = 0;
 	u16 i;

 	if (*num_q_msg == 0)
 		return 0;
 	else if (*num_q_msg > cq->ring_size)
 		return -EBADR;

 	/* take the lock before we start messing with the ring */
 	mutex_lock(&cq->cq_lock);

 	ntc = cq->next_to_clean;

 	num_to_clean = *num_q_msg;

 	for (i = 0; i < num_to_clean; i++) {
 		/* Fetch next descriptor and check if marked as done */
 		desc = IDPF_CTLQ_DESC(cq, ntc);
 		flags = le16_to_cpu(desc->flags);

 		if (!(flags & IDPF_CTLQ_FLAG_DD))
 			break;

 		q_msg[i].vmvf_type = (flags &
 				      (IDPF_CTLQ_FLAG_FTYPE_VM |
 				       IDPF_CTLQ_FLAG_FTYPE_PF)) >>
 				       IDPF_CTLQ_FLAG_FTYPE_S;

 		if (flags & IDPF_CTLQ_FLAG_ERR)
 			err  = -EBADMSG;

 		q_msg[i].cookie.mbx.chnl_opcode =
 				le32_to_cpu(desc->v_opcode_dtype);
 		q_msg[i].cookie.mbx.chnl_retval =
 				le32_to_cpu(desc->v_retval);

 		q_msg[i].opcode = le16_to_cpu(desc->opcode);
 		q_msg[i].data_len = le16_to_cpu(desc->datalen);
 		q_msg[i].status = le16_to_cpu(desc->ret_val);

 		if (desc->datalen) {
 			memcpy(q_msg[i].ctx.indirect.context,
 			       &desc->params.indirect, IDPF_INDIRECT_CTX_SIZE);

 			/* Assign pointer to dma buffer to ctlq_msg array
 			 * to be given to upper layer
 			 */
 			q_msg[i].ctx.indirect.payload = cq->bi.rx_buff[ntc];

 			/* Zero out pointer to DMA buffer info;
 			 * will be repopulated by post buffers API
 			 */
 			cq->bi.rx_buff[ntc] = NULL;
 		} else {
 			memcpy(q_msg[i].ctx.direct, desc->params.raw,
 			       IDPF_DIRECT_CTX_SIZE);
 		}

 		/* Zero out stale data in descriptor */
 		memset(desc, 0, sizeof(struct idpf_ctlq_desc));

 		ntc++;
 		if (ntc == cq->ring_size)
 			ntc = 0;
 	}

 	cq->next_to_clean = ntc;

 	mutex_unlock(&cq->cq_lock);

 	*num_q_msg = i;
 	if (*num_q_msg == 0)
 		err = -ENOMSG;

 	return err;
 }
	// SPDX-License-Identifier: GPL-2.0-only
	/* Copyright (C) 2023 Intel Corporation */

	#include "idpf_controlq.h"

	/**
	* idpf_ctlq_setup_regs - initialize control queue registers
	* @cq: pointer to the specific control queue
	* @q_create_info: structs containing info for each queue to be initialized
	*/
	static void idpf_ctlq_setup_regs(struct idpf_ctlq_info *cq,
	struct idpf_ctlq_create_info *q_create_info)
	{
	/* set control queue registers in our local struct */
	cq->reg.head = q_create_info->reg.head;
	cq->reg.tail = q_create_info->reg.tail;
	cq->reg.len = q_create_info->reg.len;
	cq->reg.bah = q_create_info->reg.bah;
	cq->reg.bal = q_create_info->reg.bal;
	cq->reg.len_mask = q_create_info->reg.len_mask;
	cq->reg.len_ena_mask = q_create_info->reg.len_ena_mask;
	cq->reg.head_mask = q_create_info->reg.head_mask;
	}

	/**
	* idpf_ctlq_init_regs - Initialize control queue registers
	* @hw: pointer to hw struct
	* @cq: pointer to the specific Control queue
	* @is_rxq: true if receive control queue, false otherwise
	*
	* Initialize registers. The caller is expected to have already initialized the
	* descriptor ring memory and buffer memory
	*/
	static void idpf_ctlq_init_regs(struct idpf_hw hw, struct idpf_ctlq_info cq,
	bool is_rxq)
	{
	/* Update tail to post pre-allocated buffers for rx queues */
	if (is_rxq)
	wr32(hw, cq->reg.tail, (u32)(cq->ring_size - 1));

	/* For non-Mailbox control queues only TAIL need to be set */
	if (cq->q_id != -1)
	return;

	/* Clear Head for both send or receive */
	wr32(hw, cq->reg.head, 0);

	/* set starting point */
	wr32(hw, cq->reg.bal, lower_32_bits(cq->desc_ring.pa));
	wr32(hw, cq->reg.bah, upper_32_bits(cq->desc_ring.pa));
	wr32(hw, cq->reg.len, (cq->ring_size \| cq->reg.len_ena_mask));
	}

	/**
	* idpf_ctlq_init_rxq_bufs - populate receive queue descriptors with buf
	* @cq: pointer to the specific Control queue
	*
	* Record the address of the receive queue DMA buffers in the descriptors.
	* The buffers must have been previously allocated.
	*/
	static void idpf_ctlq_init_rxq_bufs(struct idpf_ctlq_info *cq)
	{
	int i;

	for (i = 0; i < cq->ring_size; i++) {
	struct idpf_ctlq_desc *desc = IDPF_CTLQ_DESC(cq, i);
	struct idpf_dma_mem *bi = cq->bi.rx_buff[i];

	/* No buffer to post to descriptor, continue */
	if (!bi)
	continue;

	desc->flags =
	cpu_to_le16(IDPF_CTLQ_FLAG_BUF \| IDPF_CTLQ_FLAG_RD);
	desc->opcode = 0;
	desc->datalen = cpu_to_le16(bi->size);
	desc->ret_val = 0;
	desc->v_opcode_dtype = 0;
	desc->v_retval = 0;
	desc->params.indirect.addr_high =
	cpu_to_le32(upper_32_bits(bi->pa));
	desc->params.indirect.addr_low =
	cpu_to_le32(lower_32_bits(bi->pa));
	desc->params.indirect.param0 = 0;
	desc->params.indirect.sw_cookie = 0;
	desc->params.indirect.v_flags = 0;
	}
	}

	/**
	* idpf_ctlq_shutdown - shutdown the CQ
	* @hw: pointer to hw struct
	* @cq: pointer to the specific Control queue
	*
	* The main shutdown routine for any controq queue
	*/
	static void idpf_ctlq_shutdown(struct idpf_hw hw, struct idpf_ctlq_info cq)
	{
	mutex_lock(&cq->cq_lock);

	/* free ring buffers and the ring itself */
	idpf_ctlq_dealloc_ring_res(hw, cq);

	/* Set ring_size to 0 to indicate uninitialized queue */
	cq->ring_size = 0;

	mutex_unlock(&cq->cq_lock);
	mutex_destroy(&cq->cq_lock);
	}

	/**
	* idpf_ctlq_add - add one control queue
	* @hw: pointer to hardware struct
	* @qinfo: info for queue to be created
	* @cq_out: (output) double pointer to control queue to be created
	*
	* Allocate and initialize a control queue and add it to the control queue list.
	* The cq parameter will be allocated/initialized and passed back to the caller
	* if no errors occur.
	*
	* Note: idpf_ctlq_init must be called prior to any calls to idpf_ctlq_add
	*/
	int idpf_ctlq_add(struct idpf_hw *hw,
	struct idpf_ctlq_create_info *qinfo,
	struct idpf_ctlq_info **cq_out)
	{
	struct idpf_ctlq_info *cq;
	bool is_rxq = false;
	int err;

	cq = kzalloc(sizeof(*cq), GFP_KERNEL);
	if (!cq)
	return -ENOMEM;

	cq->cq_type = qinfo->type;
	cq->q_id = qinfo->id;
	cq->buf_size = qinfo->buf_size;
	cq->ring_size = qinfo->len;

	cq->next_to_use = 0;
	cq->next_to_clean = 0;
	cq->next_to_post = cq->ring_size - 1;

	switch (qinfo->type) {
	case IDPF_CTLQ_TYPE_MAILBOX_RX:
	is_rxq = true;
	fallthrough;
	case IDPF_CTLQ_TYPE_MAILBOX_TX:
	err = idpf_ctlq_alloc_ring_res(hw, cq);
	break;
	default:
	err = -EBADR;
	break;
	}

	if (err)
	goto init_free_q;

	if (is_rxq) {
	idpf_ctlq_init_rxq_bufs(cq);
	} else {
	/* Allocate the array of msg pointers for TX queues */
	cq->bi.tx_msg = kcalloc(qinfo->len,
	sizeof(struct idpf_ctlq_msg *),
	GFP_KERNEL);
	if (!cq->bi.tx_msg) {
	err = -ENOMEM;
	goto init_dealloc_q_mem;
	}
	}

	idpf_ctlq_setup_regs(cq, qinfo);

	idpf_ctlq_init_regs(hw, cq, is_rxq);

	mutex_init(&cq->cq_lock);

	list_add(&cq->cq_list, &hw->cq_list_head);

	*cq_out = cq;

	return 0;

	init_dealloc_q_mem:
	/* free ring buffers and the ring itself */
	idpf_ctlq_dealloc_ring_res(hw, cq);
	init_free_q:
	kfree(cq);

	return err;
	}

	/**
	* idpf_ctlq_remove - deallocate and remove specified control queue
	* @hw: pointer to hardware struct
	* @cq: pointer to control queue to be removed
	*/
	void idpf_ctlq_remove(struct idpf_hw *hw,
	struct idpf_ctlq_info *cq)
	{
	list_del(&cq->cq_list);
	idpf_ctlq_shutdown(hw, cq);
	kfree(cq);
	}

	/**
	* idpf_ctlq_init - main initialization routine for all control queues
	* @hw: pointer to hardware struct
	* @num_q: number of queues to initialize
	* @q_info: array of structs containing info for each queue to be initialized
	*
	* This initializes any number and any type of control queues. This is an all
	* or nothing routine; if one fails, all previously allocated queues will be
	* destroyed. This must be called prior to using the individual add/remove
	* APIs.
	*/
	int idpf_ctlq_init(struct idpf_hw *hw, u8 num_q,
	struct idpf_ctlq_create_info *q_info)
	{
	struct idpf_ctlq_info cq, tmp;
	int err;
	int i;

	INIT_LIST_HEAD(&hw->cq_list_head);

	for (i = 0; i < num_q; i++) {
	struct idpf_ctlq_create_info *qinfo = q_info + i;

	err = idpf_ctlq_add(hw, qinfo, &cq);
	if (err)
	goto init_destroy_qs;
	}

	return 0;

	init_destroy_qs:
	list_for_each_entry_safe(cq, tmp, &hw->cq_list_head, cq_list)
	idpf_ctlq_remove(hw, cq);

	return err;
	}

	/**
	* idpf_ctlq_deinit - destroy all control queues
	* @hw: pointer to hw struct
	*/
	void idpf_ctlq_deinit(struct idpf_hw *hw)
	{
	struct idpf_ctlq_info cq, tmp;

	list_for_each_entry_safe(cq, tmp, &hw->cq_list_head, cq_list)
	idpf_ctlq_remove(hw, cq);
	}

	/**
	* idpf_ctlq_send - send command to Control Queue (CTQ)
	* @hw: pointer to hw struct
	* @cq: handle to control queue struct to send on
	* @num_q_msg: number of messages to send on control queue
	* @q_msg: pointer to array of queue messages to be sent
	*
	* The caller is expected to allocate DMAable buffers and pass them to the
	* send routine via the q_msg struct / control queue specific data struct.
	* The control queue will hold a reference to each send message until
	* the completion for that message has been cleaned.
	*/
	int idpf_ctlq_send(struct idpf_hw hw, struct idpf_ctlq_info cq,
	u16 num_q_msg, struct idpf_ctlq_msg q_msg[])
	{
	struct idpf_ctlq_desc *desc;
	int num_desc_avail;
	int err = 0;
	int i;

	mutex_lock(&cq->cq_lock);

	/* Ensure there are enough descriptors to send all messages */
	num_desc_avail = IDPF_CTLQ_DESC_UNUSED(cq);
	if (num_desc_avail == 0 \|\| num_desc_avail < num_q_msg) {
	err = -ENOSPC;
	goto err_unlock;
	}

	for (i = 0; i < num_q_msg; i++) {
	struct idpf_ctlq_msg *msg = &q_msg[i];

	desc = IDPF_CTLQ_DESC(cq, cq->next_to_use);

	desc->opcode = cpu_to_le16(msg->opcode);
	desc->pfid_vfid = cpu_to_le16(msg->func_id);

	desc->v_opcode_dtype = cpu_to_le32(msg->cookie.mbx.chnl_opcode);
	desc->v_retval = cpu_to_le32(msg->cookie.mbx.chnl_retval);

	desc->flags = cpu_to_le16((msg->host_id & IDPF_HOST_ID_MASK) <<
	IDPF_CTLQ_FLAG_HOST_ID_S);
	if (msg->data_len) {
	struct idpf_dma_mem *buff = msg->ctx.indirect.payload;

	desc->datalen \|= cpu_to_le16(msg->data_len);
	desc->flags \|= cpu_to_le16(IDPF_CTLQ_FLAG_BUF);
	desc->flags \|= cpu_to_le16(IDPF_CTLQ_FLAG_RD);

	/* Update the address values in the desc with the pa
	* value for respective buffer
	*/
	desc->params.indirect.addr_high =
	cpu_to_le32(upper_32_bits(buff->pa));
	desc->params.indirect.addr_low =
	cpu_to_le32(lower_32_bits(buff->pa));

	memcpy(&desc->params, msg->ctx.indirect.context,
	IDPF_INDIRECT_CTX_SIZE);
	} else {
	memcpy(&desc->params, msg->ctx.direct,
	IDPF_DIRECT_CTX_SIZE);
	}

	/* Store buffer info */
	cq->bi.tx_msg[cq->next_to_use] = msg;

	(cq->next_to_use)++;
	if (cq->next_to_use == cq->ring_size)
	cq->next_to_use = 0;
	}

	/* Force memory write to complete before letting hardware
	* know that there are new descriptors to fetch.
	*/
	dma_wmb();

	wr32(hw, cq->reg.tail, cq->next_to_use);

	err_unlock:
	mutex_unlock(&cq->cq_lock);

	return err;
	}

	/**
	* idpf_ctlq_clean_sq - reclaim send descriptors on HW write back for the
	* requested queue
	* @cq: pointer to the specific Control queue
	* @clean_count: (input\|output) number of descriptors to clean as input, and
	* number of descriptors actually cleaned as output
	* @msg_status: (output) pointer to msg pointer array to be populated; needs
	* to be allocated by caller
	*
	* Returns an array of message pointers associated with the cleaned
	* descriptors. The pointers are to the original ctlq_msgs sent on the cleaned
	* descriptors. The status will be returned for each; any messages that failed
	* to send will have a non-zero status. The caller is expected to free original
	* ctlq_msgs and free or reuse the DMA buffers.
	*/
	int idpf_ctlq_clean_sq(struct idpf_ctlq_info cq, u16 clean_count,
	struct idpf_ctlq_msg *msg_status[])
	{
	struct idpf_ctlq_desc *desc;
	u16 i, num_to_clean;
	u16 ntc, desc_err;

	if (*clean_count == 0)
	return 0;
	if (*clean_count > cq->ring_size)
	return -EBADR;

	mutex_lock(&cq->cq_lock);

	ntc = cq->next_to_clean;

	num_to_clean = *clean_count;

	for (i = 0; i < num_to_clean; i++) {
	/* Fetch next descriptor and check if marked as done */
	desc = IDPF_CTLQ_DESC(cq, ntc);
	if (!(le16_to_cpu(desc->flags) & IDPF_CTLQ_FLAG_DD))
	break;

	/* strip off FW internal code */
	desc_err = le16_to_cpu(desc->ret_val) & 0xff;

	msg_status[i] = cq->bi.tx_msg[ntc];
	msg_status[i]->status = desc_err;

	cq->bi.tx_msg[ntc] = NULL;

	/* Zero out any stale data */
	memset(desc, 0, sizeof(*desc));

	ntc++;
	if (ntc == cq->ring_size)
	ntc = 0;
	}

	cq->next_to_clean = ntc;

	mutex_unlock(&cq->cq_lock);

	/* Return number of descriptors actually cleaned */
	*clean_count = i;

	return 0;
	}

	/**
	* idpf_ctlq_post_rx_buffs - post buffers to descriptor ring
	* @hw: pointer to hw struct
	* @cq: pointer to control queue handle
	* @buff_count: (input\|output) input is number of buffers caller is trying to
	* return; output is number of buffers that were not posted
	* @buffs: array of pointers to dma mem structs to be given to hardware
	*
	* Caller uses this function to return DMA buffers to the descriptor ring after
	* consuming them; buff_count will be the number of buffers.
	*
	* Note: this function needs to be called after a receive call even
	* if there are no DMA buffers to be returned, i.e. buff_count = 0,
	* buffs = NULL to support direct commands
	*/
	int idpf_ctlq_post_rx_buffs(struct idpf_hw hw, struct idpf_ctlq_info cq,
	u16 buff_count, struct idpf_dma_mem *buffs)
	{
	struct idpf_ctlq_desc *desc;
	u16 ntp = cq->next_to_post;
	bool buffs_avail = false;
	u16 tbp = ntp + 1;
	int i = 0;

	if (*buff_count > cq->ring_size)
	return -EBADR;

	if (*buff_count > 0)
	buffs_avail = true;

	mutex_lock(&cq->cq_lock);

	if (tbp >= cq->ring_size)
	tbp = 0;

	if (tbp == cq->next_to_clean)
	/* Nothing to do */
	goto post_buffs_out;

	/* Post buffers for as many as provided or up until the last one used */
	while (ntp != cq->next_to_clean) {
	desc = IDPF_CTLQ_DESC(cq, ntp);

	if (cq->bi.rx_buff[ntp])
	goto fill_desc;
	if (!buffs_avail) {
	/* If the caller hasn't given us any buffers or
	* there are none left, search the ring itself
	* for an available buffer to move to this
	* entry starting at the next entry in the ring
	*/
	tbp = ntp + 1;

	/* Wrap ring if necessary */
	if (tbp >= cq->ring_size)
	tbp = 0;

	while (tbp != cq->next_to_clean) {
	if (cq->bi.rx_buff[tbp]) {
	cq->bi.rx_buff[ntp] =
	cq->bi.rx_buff[tbp];
	cq->bi.rx_buff[tbp] = NULL;

	/* Found a buffer, no need to
	* search anymore
	*/
	break;
	}

	/* Wrap ring if necessary */
	tbp++;
	if (tbp >= cq->ring_size)
	tbp = 0;
	}

	if (tbp == cq->next_to_clean)
	goto post_buffs_out;
	} else {
	/* Give back pointer to DMA buffer */
	cq->bi.rx_buff[ntp] = buffs[i];
	i++;

	if (i >= *buff_count)
	buffs_avail = false;
	}

	fill_desc:
	desc->flags =
	cpu_to_le16(IDPF_CTLQ_FLAG_BUF \| IDPF_CTLQ_FLAG_RD);

	/* Post buffers to descriptor */
	desc->datalen = cpu_to_le16(cq->bi.rx_buff[ntp]->size);
	desc->params.indirect.addr_high =
	cpu_to_le32(upper_32_bits(cq->bi.rx_buff[ntp]->pa));
	desc->params.indirect.addr_low =
	cpu_to_le32(lower_32_bits(cq->bi.rx_buff[ntp]->pa));

	ntp++;
	if (ntp == cq->ring_size)
	ntp = 0;
	}

	post_buffs_out:
	/* Only update tail if buffers were actually posted */
	if (cq->next_to_post != ntp) {
	if (ntp)
	/* Update next_to_post to ntp - 1 since current ntp
	* will not have a buffer
	*/
	cq->next_to_post = ntp - 1;
	else
	/* Wrap to end of end ring since current ntp is 0 */
	cq->next_to_post = cq->ring_size - 1;

	wr32(hw, cq->reg.tail, cq->next_to_post);
	}

	mutex_unlock(&cq->cq_lock);

	/* return the number of buffers that were not posted */
	buff_count = buff_count - i;

	return 0;
	}

	/**
	* idpf_ctlq_recv - receive control queue message call back
	* @cq: pointer to control queue handle to receive on
	* @num_q_msg: (input\|output) input number of messages that should be received;
	* output number of messages actually received
	* @q_msg: (output) array of received control queue messages on this q;
	* needs to be pre-allocated by caller for as many messages as requested
	*
	* Called by interrupt handler or polling mechanism. Caller is expected
	* to free buffers
	*/
	int idpf_ctlq_recv(struct idpf_ctlq_info cq, u16 num_q_msg,
	struct idpf_ctlq_msg *q_msg)
	{
	u16 num_to_clean, ntc, flags;
	struct idpf_ctlq_desc *desc;
	int err = 0;
	u16 i;

	if (*num_q_msg == 0)
	return 0;
	else if (*num_q_msg > cq->ring_size)
	return -EBADR;

	/* take the lock before we start messing with the ring */
	mutex_lock(&cq->cq_lock);

	ntc = cq->next_to_clean;

	num_to_clean = *num_q_msg;

	for (i = 0; i < num_to_clean; i++) {
	/* Fetch next descriptor and check if marked as done */
	desc = IDPF_CTLQ_DESC(cq, ntc);
	flags = le16_to_cpu(desc->flags);

	if (!(flags & IDPF_CTLQ_FLAG_DD))
	break;

	q_msg[i].vmvf_type = (flags &
	(IDPF_CTLQ_FLAG_FTYPE_VM \|
	IDPF_CTLQ_FLAG_FTYPE_PF)) >>
	IDPF_CTLQ_FLAG_FTYPE_S;

	if (flags & IDPF_CTLQ_FLAG_ERR)
	err = -EBADMSG;

	q_msg[i].cookie.mbx.chnl_opcode =
	le32_to_cpu(desc->v_opcode_dtype);
	q_msg[i].cookie.mbx.chnl_retval =
	le32_to_cpu(desc->v_retval);

	q_msg[i].opcode = le16_to_cpu(desc->opcode);
	q_msg[i].data_len = le16_to_cpu(desc->datalen);
	q_msg[i].status = le16_to_cpu(desc->ret_val);

	if (desc->datalen) {
	memcpy(q_msg[i].ctx.indirect.context,
	&desc->params.indirect, IDPF_INDIRECT_CTX_SIZE);

	/* Assign pointer to dma buffer to ctlq_msg array
	* to be given to upper layer
	*/
	q_msg[i].ctx.indirect.payload = cq->bi.rx_buff[ntc];

	/* Zero out pointer to DMA buffer info;
	* will be repopulated by post buffers API
	*/
	cq->bi.rx_buff[ntc] = NULL;
	} else {
	memcpy(q_msg[i].ctx.direct, desc->params.raw,
	IDPF_DIRECT_CTX_SIZE);
	}

	/* Zero out stale data in descriptor */
	memset(desc, 0, sizeof(struct idpf_ctlq_desc));

	ntc++;
	if (ntc == cq->ring_size)
	ntc = 0;
	}

	cq->next_to_clean = ntc;

	mutex_unlock(&cq->cq_lock);

	*num_q_msg = i;
	if (*num_q_msg == 0)
	err = -ENOMSG;

	return err;
	}