xref: /linux/drivers/infiniband/hw/bnxt_re/qplib_sp.c (revision 643e2e259c2b25a2af0ae4c23c6e16586d9fd19c)

/*
 * Broadcom NetXtreme-E RoCE driver.
 *
 * Copyright (c) 2016 - 2017, Broadcom. All rights reserved.  The term
 * Broadcom refers to Broadcom Limited and/or its subsidiaries.
 *
 * This software is available to you under a choice of one of two
 * licenses.  You may choose to be licensed under the terms of the GNU
 * General Public License (GPL) Version 2, available from the file
 * COPYING in the main directory of this source tree, or the
 * BSD license below:
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in
 *    the documentation and/or other materials provided with the
 *    distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS''
 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
 * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS
 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
 * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
 * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
 * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
 * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 *
 * Description: Slow Path Operators
 */

#define dev_fmt(fmt) "QPLIB: " fmt

#include <linux/interrupt.h>
#include <linux/spinlock.h>
#include <linux/sched.h>
#include <linux/pci.h>

#include "roce_hsi.h"

#include "qplib_res.h"
#include "qplib_rcfw.h"
#include "qplib_sp.h"
#include "qplib_tlv.h"

const struct bnxt_qplib_gid bnxt_qplib_gid_zero = {{ 0, 0, 0, 0, 0, 0, 0, 0,
						     0, 0, 0, 0, 0, 0, 0, 0 } };

/* Device */

static bool bnxt_qplib_is_atomic_cap(struct bnxt_qplib_rcfw *rcfw)
{
	u16 pcie_ctl2 = 0;

	if (!bnxt_qplib_is_chip_gen_p5_p7(rcfw->res->cctx))
		return false;

	pcie_capability_read_word(rcfw->pdev, PCI_EXP_DEVCTL2, &pcie_ctl2);
	return (pcie_ctl2 & PCI_EXP_DEVCTL2_ATOMIC_REQ);
}

static void bnxt_qplib_query_version(struct bnxt_qplib_rcfw *rcfw,
				     char *fw_ver)
{
	struct creq_query_version_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_query_version req = {};
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_QUERY_VERSION,
				 sizeof(req));

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req), sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		return;
	fw_ver[0] = resp.fw_maj;
	fw_ver[1] = resp.fw_minor;
	fw_ver[2] = resp.fw_bld;
	fw_ver[3] = resp.fw_rsvd;
}

int bnxt_qplib_get_dev_attr(struct bnxt_qplib_rcfw *rcfw,
			    struct bnxt_qplib_dev_attr *attr)
{
	struct creq_query_func_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct creq_query_func_resp_sb *sb;
	struct bnxt_qplib_rcfw_sbuf sbuf;
	struct bnxt_qplib_chip_ctx *cctx;
	struct cmdq_query_func req = {};
	u8 *tqm_alloc;
	int i, rc;
	u32 temp;

	cctx = rcfw->res->cctx;
	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_QUERY_FUNC,
				 sizeof(req));

	sbuf.size = ALIGN(sizeof(*sb), BNXT_QPLIB_CMDQE_UNITS);
	sbuf.sb = dma_alloc_coherent(&rcfw->pdev->dev, sbuf.size,
				     &sbuf.dma_addr, GFP_KERNEL);
	if (!sbuf.sb)
		return -ENOMEM;
	sb = sbuf.sb;
	req.resp_size = sbuf.size / BNXT_QPLIB_CMDQE_UNITS;
	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, &sbuf, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		goto bail;

	/* Extract the context from the side buffer */
	attr->max_qp = le32_to_cpu(sb->max_qp);
	/* max_qp value reported by FW doesn't include the QP1 */
	attr->max_qp += 1;
	attr->max_qp_rd_atom =
		sb->max_qp_rd_atom > BNXT_QPLIB_MAX_OUT_RD_ATOM ?
		BNXT_QPLIB_MAX_OUT_RD_ATOM : sb->max_qp_rd_atom;
	attr->max_qp_init_rd_atom =
		sb->max_qp_init_rd_atom > BNXT_QPLIB_MAX_OUT_RD_ATOM ?
		BNXT_QPLIB_MAX_OUT_RD_ATOM : sb->max_qp_init_rd_atom;
	attr->max_qp_wqes = le16_to_cpu(sb->max_qp_wr) - 1;
	if (!bnxt_qplib_is_chip_gen_p5_p7(rcfw->res->cctx)) {
		/*
		 * 128 WQEs needs to be reserved for the HW (8916). Prevent
		 * reporting the max number on legacy devices
		 */
		attr->max_qp_wqes -= BNXT_QPLIB_RESERVED_QP_WRS + 1;
	}

	/* Adjust for max_qp_wqes for variable wqe */
	if (cctx->modes.wqe_mode == BNXT_QPLIB_WQE_MODE_VARIABLE)
		attr->max_qp_wqes = BNXT_VAR_MAX_WQE - 1;

	attr->max_qp_sges = cctx->modes.wqe_mode == BNXT_QPLIB_WQE_MODE_VARIABLE ?
			    min_t(u32, sb->max_sge_var_wqe, BNXT_VAR_MAX_SGE) : 6;
	attr->max_cq = le32_to_cpu(sb->max_cq);
	attr->max_cq_wqes = le32_to_cpu(sb->max_cqe);
	if (!bnxt_qplib_is_chip_gen_p7(rcfw->res->cctx))
		attr->max_cq_wqes = min_t(u32, BNXT_QPLIB_MAX_CQ_WQES, attr->max_cq_wqes);
	attr->max_cq_sges = attr->max_qp_sges;
	attr->max_mr = le32_to_cpu(sb->max_mr);
	attr->max_mw = le32_to_cpu(sb->max_mw);

	attr->max_mr_size = le64_to_cpu(sb->max_mr_size);
	attr->max_pd = 64 * 1024;
	attr->max_raw_ethy_qp = le32_to_cpu(sb->max_raw_eth_qp);
	attr->max_ah = le32_to_cpu(sb->max_ah);

	attr->max_srq = le16_to_cpu(sb->max_srq);
	attr->max_srq_wqes = le32_to_cpu(sb->max_srq_wr) - 1;
	attr->max_srq_sges = sb->max_srq_sge;
	attr->max_pkey = 1;
	attr->max_inline_data = le32_to_cpu(sb->max_inline_data);
	if (!bnxt_qplib_is_chip_gen_p7(rcfw->res->cctx))
		attr->l2_db_size = (sb->l2_db_space_size + 1) *
				    (0x01 << RCFW_DBR_BASE_PAGE_SHIFT);
	/*
	 * Read the max gid supported by HW.
	 * For each entry in HW  GID in HW table, we consume 2
	 * GID entries in the kernel GID table.  So max_gid reported
	 * to stack can be up to twice the value reported by the HW, up to 256 gids.
	 */
	attr->max_sgid = le32_to_cpu(sb->max_gid);
	attr->max_sgid = min_t(u32, BNXT_QPLIB_NUM_GIDS_SUPPORTED, 2 * attr->max_sgid);
	attr->dev_cap_flags = le16_to_cpu(sb->dev_cap_flags);
	attr->dev_cap_flags2 = le16_to_cpu(sb->dev_cap_ext_flags_2);

	bnxt_qplib_query_version(rcfw, attr->fw_ver);

	for (i = 0; i < MAX_TQM_ALLOC_REQ / 4; i++) {
		temp = le32_to_cpu(sb->tqm_alloc_reqs[i]);
		tqm_alloc = (u8 *)&temp;
		attr->tqm_alloc_reqs[i * 4] = *tqm_alloc;
		attr->tqm_alloc_reqs[i * 4 + 1] = *(++tqm_alloc);
		attr->tqm_alloc_reqs[i * 4 + 2] = *(++tqm_alloc);
		attr->tqm_alloc_reqs[i * 4 + 3] = *(++tqm_alloc);
	}

	if (rcfw->res->cctx->hwrm_intf_ver >= HWRM_VERSION_DEV_ATTR_MAX_DPI)
		attr->max_dpi = le32_to_cpu(sb->max_dpi);

	attr->is_atomic = bnxt_qplib_is_atomic_cap(rcfw);
bail:
	dma_free_coherent(&rcfw->pdev->dev, sbuf.size,
			  sbuf.sb, sbuf.dma_addr);
	return rc;
}

int bnxt_qplib_set_func_resources(struct bnxt_qplib_res *res,
				  struct bnxt_qplib_rcfw *rcfw,
				  struct bnxt_qplib_ctx *ctx)
{
	struct creq_set_func_resources_resp resp = {};
	struct cmdq_set_func_resources req = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_SET_FUNC_RESOURCES,
				 sizeof(req));

	req.number_of_qp = cpu_to_le32(ctx->qpc_count);
	req.number_of_mrw = cpu_to_le32(ctx->mrw_count);
	req.number_of_srq =  cpu_to_le32(ctx->srqc_count);
	req.number_of_cq = cpu_to_le32(ctx->cq_count);

	req.max_qp_per_vf = cpu_to_le32(ctx->vf_res.max_qp_per_vf);
	req.max_mrw_per_vf = cpu_to_le32(ctx->vf_res.max_mrw_per_vf);
	req.max_srq_per_vf = cpu_to_le32(ctx->vf_res.max_srq_per_vf);
	req.max_cq_per_vf = cpu_to_le32(ctx->vf_res.max_cq_per_vf);
	req.max_gid_per_vf = cpu_to_le32(ctx->vf_res.max_gid_per_vf);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc) {
		dev_err(&res->pdev->dev, "Failed to set function resources\n");
	}
	return rc;
}

/* SGID */
int bnxt_qplib_get_sgid(struct bnxt_qplib_res *res,
			struct bnxt_qplib_sgid_tbl *sgid_tbl, int index,
			struct bnxt_qplib_gid *gid)
{
	if (index >= sgid_tbl->max) {
		dev_err(&res->pdev->dev,
			"Index %d exceeded SGID table max (%d)\n",
			index, sgid_tbl->max);
		return -EINVAL;
	}
	memcpy(gid, &sgid_tbl->tbl[index].gid, sizeof(*gid));
	return 0;
}

int bnxt_qplib_del_sgid(struct bnxt_qplib_sgid_tbl *sgid_tbl,
			struct bnxt_qplib_gid *gid, u16 vlan_id, bool update)
{
	struct bnxt_qplib_res *res = to_bnxt_qplib(sgid_tbl,
						   struct bnxt_qplib_res,
						   sgid_tbl);
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	int index;

	/* Do we need a sgid_lock here? */
	if (!sgid_tbl->active) {
		dev_err(&res->pdev->dev, "SGID table has no active entries\n");
		return -ENOMEM;
	}
	for (index = 0; index < sgid_tbl->max; index++) {
		if (!memcmp(&sgid_tbl->tbl[index].gid, gid, sizeof(*gid)) &&
		    vlan_id == sgid_tbl->tbl[index].vlan_id)
			break;
	}
	if (index == sgid_tbl->max) {
		dev_warn(&res->pdev->dev, "GID not found in the SGID table\n");
		return 0;
	}
	/* Remove GID from the SGID table */
	if (update) {
		struct creq_delete_gid_resp resp = {};
		struct bnxt_qplib_cmdqmsg msg = {};
		struct cmdq_delete_gid req = {};
		int rc;

		bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
					 CMDQ_BASE_OPCODE_DELETE_GID,
					 sizeof(req));
		if (sgid_tbl->hw_id[index] == 0xFFFF) {
			dev_err(&res->pdev->dev,
				"GID entry contains an invalid HW id\n");
			return -EINVAL;
		}
		req.gid_index = cpu_to_le16(sgid_tbl->hw_id[index]);
		bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
					sizeof(resp), 0);
		rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
		if (rc)
			return rc;
	}
	memcpy(&sgid_tbl->tbl[index].gid, &bnxt_qplib_gid_zero,
	       sizeof(bnxt_qplib_gid_zero));
	sgid_tbl->tbl[index].vlan_id = 0xFFFF;
	sgid_tbl->vlan[index] = 0;
	sgid_tbl->active--;
	dev_dbg(&res->pdev->dev,
		"SGID deleted hw_id[0x%x] = 0x%x active = 0x%x\n",
		 index, sgid_tbl->hw_id[index], sgid_tbl->active);
	sgid_tbl->hw_id[index] = (u16)-1;

	/* unlock */
	return 0;
}

int bnxt_qplib_add_sgid(struct bnxt_qplib_sgid_tbl *sgid_tbl,
			struct bnxt_qplib_gid *gid, const u8 *smac,
			u16 vlan_id, bool update, u32 *index)
{
	struct bnxt_qplib_res *res = to_bnxt_qplib(sgid_tbl,
						   struct bnxt_qplib_res,
						   sgid_tbl);
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	int i, free_idx;

	/* Do we need a sgid_lock here? */
	if (sgid_tbl->active == sgid_tbl->max) {
		dev_err(&res->pdev->dev, "SGID table is full\n");
		return -ENOMEM;
	}
	free_idx = sgid_tbl->max;
	for (i = 0; i < sgid_tbl->max; i++) {
		if (!memcmp(&sgid_tbl->tbl[i], gid, sizeof(*gid)) &&
		    sgid_tbl->tbl[i].vlan_id == vlan_id) {
			dev_dbg(&res->pdev->dev,
				"SGID entry already exist in entry %d!\n", i);
			*index = i;
			return -EALREADY;
		} else if (!memcmp(&sgid_tbl->tbl[i], &bnxt_qplib_gid_zero,
				   sizeof(bnxt_qplib_gid_zero)) &&
			   free_idx == sgid_tbl->max) {
			free_idx = i;
		}
	}
	if (free_idx == sgid_tbl->max) {
		dev_err(&res->pdev->dev,
			"SGID table is FULL but count is not MAX??\n");
		return -ENOMEM;
	}
	if (update) {
		struct creq_add_gid_resp resp = {};
		struct bnxt_qplib_cmdqmsg msg = {};
		struct cmdq_add_gid req = {};
		int rc;

		bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
					 CMDQ_BASE_OPCODE_ADD_GID,
					 sizeof(req));

		req.gid[0] = cpu_to_be32(((u32 *)gid->data)[3]);
		req.gid[1] = cpu_to_be32(((u32 *)gid->data)[2]);
		req.gid[2] = cpu_to_be32(((u32 *)gid->data)[1]);
		req.gid[3] = cpu_to_be32(((u32 *)gid->data)[0]);
		/*
		 * driver should ensure that all RoCE traffic is always VLAN
		 * tagged if RoCE traffic is running on non-zero VLAN ID or
		 * RoCE traffic is running on non-zero Priority.
		 */
		if ((vlan_id != 0xFFFF) || res->prio) {
			if (vlan_id != 0xFFFF)
				req.vlan = cpu_to_le16
				(vlan_id & CMDQ_ADD_GID_VLAN_VLAN_ID_MASK);
			req.vlan |= cpu_to_le16
					(CMDQ_ADD_GID_VLAN_TPID_TPID_8100 |
					 CMDQ_ADD_GID_VLAN_VLAN_EN);
		}

		/* MAC in network format */
		req.src_mac[0] = cpu_to_be16(((u16 *)smac)[0]);
		req.src_mac[1] = cpu_to_be16(((u16 *)smac)[1]);
		req.src_mac[2] = cpu_to_be16(((u16 *)smac)[2]);

		bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
					sizeof(resp), 0);
		rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
		if (rc)
			return rc;
		sgid_tbl->hw_id[free_idx] = le32_to_cpu(resp.xid);
	}
	/* Add GID to the sgid_tbl */
	memcpy(&sgid_tbl->tbl[free_idx], gid, sizeof(*gid));
	sgid_tbl->tbl[free_idx].vlan_id = vlan_id;
	sgid_tbl->active++;
	if (vlan_id != 0xFFFF)
		sgid_tbl->vlan[free_idx] = 1;

	dev_dbg(&res->pdev->dev,
		"SGID added hw_id[0x%x] = 0x%x active = 0x%x\n",
		 free_idx, sgid_tbl->hw_id[free_idx], sgid_tbl->active);

	*index = free_idx;
	/* unlock */
	return 0;
}

int bnxt_qplib_update_sgid(struct bnxt_qplib_sgid_tbl *sgid_tbl,
			   struct bnxt_qplib_gid *gid, u16 gid_idx,
			   const u8 *smac)
{
	struct bnxt_qplib_res *res = to_bnxt_qplib(sgid_tbl,
						   struct bnxt_qplib_res,
						   sgid_tbl);
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct creq_modify_gid_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_modify_gid req = {};
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_MODIFY_GID,
				 sizeof(req));

	req.gid[0] = cpu_to_be32(((u32 *)gid->data)[3]);
	req.gid[1] = cpu_to_be32(((u32 *)gid->data)[2]);
	req.gid[2] = cpu_to_be32(((u32 *)gid->data)[1]);
	req.gid[3] = cpu_to_be32(((u32 *)gid->data)[0]);
	if (res->prio) {
		req.vlan |= cpu_to_le16
			(CMDQ_ADD_GID_VLAN_TPID_TPID_8100 |
			 CMDQ_ADD_GID_VLAN_VLAN_EN);
	}

	/* MAC in network format */
	req.src_mac[0] = cpu_to_be16(((u16 *)smac)[0]);
	req.src_mac[1] = cpu_to_be16(((u16 *)smac)[1]);
	req.src_mac[2] = cpu_to_be16(((u16 *)smac)[2]);

	req.gid_index = cpu_to_le16(gid_idx);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	return rc;
}

/* AH */
int bnxt_qplib_create_ah(struct bnxt_qplib_res *res, struct bnxt_qplib_ah *ah,
			 bool block)
{
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct creq_create_ah_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_create_ah req = {};
	u32 temp32[4];
	u16 temp16[3];
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_CREATE_AH,
				 sizeof(req));

	memcpy(temp32, ah->dgid.data, sizeof(struct bnxt_qplib_gid));
	req.dgid[0] = cpu_to_le32(temp32[0]);
	req.dgid[1] = cpu_to_le32(temp32[1]);
	req.dgid[2] = cpu_to_le32(temp32[2]);
	req.dgid[3] = cpu_to_le32(temp32[3]);

	req.type = ah->nw_type;
	req.hop_limit = ah->hop_limit;
	req.sgid_index = cpu_to_le16(res->sgid_tbl.hw_id[ah->sgid_index]);
	req.dest_vlan_id_flow_label = cpu_to_le32((ah->flow_label &
					CMDQ_CREATE_AH_FLOW_LABEL_MASK) |
					CMDQ_CREATE_AH_DEST_VLAN_ID_MASK);
	req.pd_id = cpu_to_le32(ah->pd->id);
	req.traffic_class = ah->traffic_class;

	/* MAC in network format */
	memcpy(temp16, ah->dmac, 6);
	req.dest_mac[0] = cpu_to_le16(temp16[0]);
	req.dest_mac[1] = cpu_to_le16(temp16[1]);
	req.dest_mac[2] = cpu_to_le16(temp16[2]);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), block);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		return rc;

	ah->id = le32_to_cpu(resp.xid);
	return 0;
}

int bnxt_qplib_destroy_ah(struct bnxt_qplib_res *res, struct bnxt_qplib_ah *ah,
			  bool block)
{
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct creq_destroy_ah_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_destroy_ah req = {};
	int rc;

	/* Clean up the AH table in the device */
	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_DESTROY_AH,
				 sizeof(req));

	req.ah_cid = cpu_to_le32(ah->id);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), block);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	return rc;
}

/* MRW */
int bnxt_qplib_free_mrw(struct bnxt_qplib_res *res, struct bnxt_qplib_mrw *mrw)
{
	struct creq_deallocate_key_resp resp = {};
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct cmdq_deallocate_key req = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	int rc;

	if (mrw->lkey == 0xFFFFFFFF) {
		dev_info(&res->pdev->dev, "SP: Free a reserved lkey MRW\n");
		return 0;
	}

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_DEALLOCATE_KEY,
				 sizeof(req));

	req.mrw_flags = mrw->type;

	if ((mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE1)  ||
	    (mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2A) ||
	    (mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2B))
		req.key = cpu_to_le32(mrw->rkey);
	else
		req.key = cpu_to_le32(mrw->lkey);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		return rc;

	/* Free the qplib's MRW memory */
	if (mrw->hwq.max_elements)
		bnxt_qplib_free_hwq(res, &mrw->hwq);

	return 0;
}

int bnxt_qplib_alloc_mrw(struct bnxt_qplib_res *res, struct bnxt_qplib_mrw *mrw)
{
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct creq_allocate_mrw_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_allocate_mrw req = {};
	unsigned long tmp;
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_ALLOCATE_MRW,
				 sizeof(req));

	req.pd_id = cpu_to_le32(mrw->pd->id);
	req.mrw_flags = mrw->type;
	if ((mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_PMR &&
	     mrw->access_flags & BNXT_QPLIB_FR_PMR) ||
	    mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2A ||
	    mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2B)
		req.access = CMDQ_ALLOCATE_MRW_ACCESS_CONSUMER_OWNED_KEY;
	tmp = (unsigned long)mrw;
	req.mrw_handle = cpu_to_le64(tmp);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		return rc;

	if ((mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE1)  ||
	    (mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2A) ||
	    (mrw->type == CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2B))
		mrw->rkey = le32_to_cpu(resp.xid);
	else
		mrw->lkey = le32_to_cpu(resp.xid);
	return 0;
}

int bnxt_qplib_dereg_mrw(struct bnxt_qplib_res *res, struct bnxt_qplib_mrw *mrw,
			 bool block)
{
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct creq_deregister_mr_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_deregister_mr req = {};
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_DEREGISTER_MR,
				 sizeof(req));

	req.lkey = cpu_to_le32(mrw->lkey);
	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), block);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		return rc;

	/* Free the qplib's MR memory */
	if (mrw->hwq.max_elements) {
		mrw->va = 0;
		mrw->total_size = 0;
		bnxt_qplib_free_hwq(res, &mrw->hwq);
	}

	return 0;
}

int bnxt_qplib_reg_mr(struct bnxt_qplib_res *res, struct bnxt_qplib_mrw *mr,
		      struct ib_umem *umem, int num_pbls, u32 buf_pg_size)
{
	struct bnxt_qplib_rcfw *rcfw = res->rcfw;
	struct bnxt_qplib_hwq_attr hwq_attr = {};
	struct bnxt_qplib_sg_info sginfo = {};
	struct creq_register_mr_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_register_mr req = {};
	int pages, rc;
	u32 pg_size;
	u16 level;

	if (num_pbls) {
		pages = roundup_pow_of_two(num_pbls);
		/* Allocate memory for the non-leaf pages to store buf ptrs.
		 * Non-leaf pages always uses system PAGE_SIZE
		 */
		/* Free the hwq if it already exist, must be a rereg */
		if (mr->hwq.max_elements)
			bnxt_qplib_free_hwq(res, &mr->hwq);
		hwq_attr.res = res;
		hwq_attr.depth = pages;
		hwq_attr.stride = sizeof(dma_addr_t);
		hwq_attr.type = HWQ_TYPE_MR;
		hwq_attr.sginfo = &sginfo;
		hwq_attr.sginfo->umem = umem;
		hwq_attr.sginfo->npages = pages;
		hwq_attr.sginfo->pgsize = buf_pg_size;
		hwq_attr.sginfo->pgshft = ilog2(buf_pg_size);
		rc = bnxt_qplib_alloc_init_hwq(&mr->hwq, &hwq_attr);
		if (rc) {
			dev_err(&res->pdev->dev,
				"SP: Reg MR memory allocation failed\n");
			return -ENOMEM;
		}
	}

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_REGISTER_MR,
				 sizeof(req));

	/* Configure the request */
	if (mr->hwq.level == PBL_LVL_MAX) {
		/* No PBL provided, just use system PAGE_SIZE */
		level = 0;
		req.pbl = 0;
		pg_size = PAGE_SIZE;
	} else {
		level = mr->hwq.level;
		req.pbl = cpu_to_le64(mr->hwq.pbl[PBL_LVL_0].pg_map_arr[0]);
	}
	pg_size = buf_pg_size ? buf_pg_size : PAGE_SIZE;
	req.log2_pg_size_lvl = (level << CMDQ_REGISTER_MR_LVL_SFT) |
			       ((ilog2(pg_size) <<
				 CMDQ_REGISTER_MR_LOG2_PG_SIZE_SFT) &
				CMDQ_REGISTER_MR_LOG2_PG_SIZE_MASK);
	req.log2_pbl_pg_size = cpu_to_le16(((ilog2(PAGE_SIZE) <<
				 CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_SFT) &
				CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_MASK));
	req.access = (mr->access_flags & 0xFFFF);
	req.va = cpu_to_le64(mr->va);
	req.key = cpu_to_le32(mr->lkey);
	if (_is_alloc_mr_unified(res->dattr->dev_cap_flags))
		req.key = cpu_to_le32(mr->pd->id);
	req.flags = cpu_to_le16(mr->flags);
	req.mr_size = cpu_to_le64(mr->total_size);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, NULL, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		goto fail;

	if (_is_alloc_mr_unified(res->dattr->dev_cap_flags)) {
		mr->lkey = le32_to_cpu(resp.xid);
		mr->rkey = mr->lkey;
	}

	return 0;

fail:
	if (mr->hwq.max_elements)
		bnxt_qplib_free_hwq(res, &mr->hwq);
	return rc;
}

int bnxt_qplib_alloc_fast_reg_page_list(struct bnxt_qplib_res *res,
					struct bnxt_qplib_frpl *frpl,
					int max_pg_ptrs)
{
	struct bnxt_qplib_hwq_attr hwq_attr = {};
	struct bnxt_qplib_sg_info sginfo = {};
	int pg_ptrs, pages, rc;

	/* Re-calculate the max to fit the HWQ allocation model */
	pg_ptrs = roundup_pow_of_two(max_pg_ptrs);
	pages = pg_ptrs >> MAX_PBL_LVL_1_PGS_SHIFT;
	if (!pages)
		pages++;

	if (pages > MAX_PBL_LVL_1_PGS)
		return -ENOMEM;

	sginfo.pgsize = PAGE_SIZE;
	sginfo.nopte = true;

	hwq_attr.res = res;
	hwq_attr.depth = pg_ptrs;
	hwq_attr.stride = PAGE_SIZE;
	hwq_attr.sginfo = &sginfo;
	hwq_attr.type = HWQ_TYPE_CTX;
	rc = bnxt_qplib_alloc_init_hwq(&frpl->hwq, &hwq_attr);
	if (!rc)
		frpl->max_pg_ptrs = pg_ptrs;

	return rc;
}

int bnxt_qplib_free_fast_reg_page_list(struct bnxt_qplib_res *res,
				       struct bnxt_qplib_frpl *frpl)
{
	bnxt_qplib_free_hwq(res, &frpl->hwq);
	return 0;
}

int bnxt_qplib_get_roce_stats(struct bnxt_qplib_rcfw *rcfw,
			      struct bnxt_qplib_roce_stats *stats)
{
	struct creq_query_roce_stats_resp resp = {};
	struct creq_query_roce_stats_resp_sb *sb;
	struct cmdq_query_roce_stats req = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct bnxt_qplib_rcfw_sbuf sbuf;
	int rc;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_QUERY_ROCE_STATS,
				 sizeof(req));

	sbuf.size = ALIGN(sizeof(*sb), BNXT_QPLIB_CMDQE_UNITS);
	sbuf.sb = dma_alloc_coherent(&rcfw->pdev->dev, sbuf.size,
				     &sbuf.dma_addr, GFP_KERNEL);
	if (!sbuf.sb)
		return -ENOMEM;
	sb = sbuf.sb;

	req.resp_size = sbuf.size / BNXT_QPLIB_CMDQE_UNITS;
	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, &sbuf, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		goto bail;
	/* Extract the context from the side buffer */
	stats->to_retransmits = le64_to_cpu(sb->to_retransmits);
	stats->seq_err_naks_rcvd = le64_to_cpu(sb->seq_err_naks_rcvd);
	stats->max_retry_exceeded = le64_to_cpu(sb->max_retry_exceeded);
	stats->rnr_naks_rcvd = le64_to_cpu(sb->rnr_naks_rcvd);
	stats->missing_resp = le64_to_cpu(sb->missing_resp);
	stats->unrecoverable_err = le64_to_cpu(sb->unrecoverable_err);
	stats->bad_resp_err = le64_to_cpu(sb->bad_resp_err);
	stats->local_qp_op_err = le64_to_cpu(sb->local_qp_op_err);
	stats->local_protection_err = le64_to_cpu(sb->local_protection_err);
	stats->mem_mgmt_op_err = le64_to_cpu(sb->mem_mgmt_op_err);
	stats->remote_invalid_req_err = le64_to_cpu(sb->remote_invalid_req_err);
	stats->remote_access_err = le64_to_cpu(sb->remote_access_err);
	stats->remote_op_err = le64_to_cpu(sb->remote_op_err);
	stats->dup_req = le64_to_cpu(sb->dup_req);
	stats->res_exceed_max = le64_to_cpu(sb->res_exceed_max);
	stats->res_length_mismatch = le64_to_cpu(sb->res_length_mismatch);
	stats->res_exceeds_wqe = le64_to_cpu(sb->res_exceeds_wqe);
	stats->res_opcode_err = le64_to_cpu(sb->res_opcode_err);
	stats->res_rx_invalid_rkey = le64_to_cpu(sb->res_rx_invalid_rkey);
	stats->res_rx_domain_err = le64_to_cpu(sb->res_rx_domain_err);
	stats->res_rx_no_perm = le64_to_cpu(sb->res_rx_no_perm);
	stats->res_rx_range_err = le64_to_cpu(sb->res_rx_range_err);
	stats->res_tx_invalid_rkey = le64_to_cpu(sb->res_tx_invalid_rkey);
	stats->res_tx_domain_err = le64_to_cpu(sb->res_tx_domain_err);
	stats->res_tx_no_perm = le64_to_cpu(sb->res_tx_no_perm);
	stats->res_tx_range_err = le64_to_cpu(sb->res_tx_range_err);
	stats->res_irrq_oflow = le64_to_cpu(sb->res_irrq_oflow);
	stats->res_unsup_opcode = le64_to_cpu(sb->res_unsup_opcode);
	stats->res_unaligned_atomic = le64_to_cpu(sb->res_unaligned_atomic);
	stats->res_rem_inv_err = le64_to_cpu(sb->res_rem_inv_err);
	stats->res_mem_error = le64_to_cpu(sb->res_mem_error);
	stats->res_srq_err = le64_to_cpu(sb->res_srq_err);
	stats->res_cmp_err = le64_to_cpu(sb->res_cmp_err);
	stats->res_invalid_dup_rkey = le64_to_cpu(sb->res_invalid_dup_rkey);
	stats->res_wqe_format_err = le64_to_cpu(sb->res_wqe_format_err);
	stats->res_cq_load_err = le64_to_cpu(sb->res_cq_load_err);
	stats->res_srq_load_err = le64_to_cpu(sb->res_srq_load_err);
	stats->res_tx_pci_err = le64_to_cpu(sb->res_tx_pci_err);
	stats->res_rx_pci_err = le64_to_cpu(sb->res_rx_pci_err);
	if (!rcfw->init_oos_stats) {
		rcfw->oos_prev = le64_to_cpu(sb->res_oos_drop_count);
		rcfw->init_oos_stats = 1;
	} else {
		stats->res_oos_drop_count +=
				(le64_to_cpu(sb->res_oos_drop_count) -
				 rcfw->oos_prev) & BNXT_QPLIB_OOS_COUNT_MASK;
		rcfw->oos_prev = le64_to_cpu(sb->res_oos_drop_count);
	}

bail:
	dma_free_coherent(&rcfw->pdev->dev, sbuf.size,
			  sbuf.sb, sbuf.dma_addr);
	return rc;
}

int bnxt_qplib_qext_stat(struct bnxt_qplib_rcfw *rcfw, u32 fid,
			 struct bnxt_qplib_ext_stat *estat)
{
	struct creq_query_roce_stats_ext_resp resp = {};
	struct creq_query_roce_stats_ext_resp_sb *sb;
	struct cmdq_query_roce_stats_ext req = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct bnxt_qplib_rcfw_sbuf sbuf;
	int rc;

	sbuf.size = ALIGN(sizeof(*sb), BNXT_QPLIB_CMDQE_UNITS);
	sbuf.sb = dma_alloc_coherent(&rcfw->pdev->dev, sbuf.size,
				     &sbuf.dma_addr, GFP_KERNEL);
	if (!sbuf.sb)
		return -ENOMEM;

	sb = sbuf.sb;
	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_QUERY_ROCE_STATS_EXT_OPCODE_QUERY_ROCE_STATS,
				 sizeof(req));

	req.resp_size = sbuf.size / BNXT_QPLIB_CMDQE_UNITS;
	req.resp_addr = cpu_to_le64(sbuf.dma_addr);
	req.function_id = cpu_to_le32(fid);
	req.flags = cpu_to_le16(CMDQ_QUERY_ROCE_STATS_EXT_FLAGS_FUNCTION_ID);

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, &sbuf, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		goto bail;

	estat->tx_atomic_req = le64_to_cpu(sb->tx_atomic_req_pkts);
	estat->tx_read_req = le64_to_cpu(sb->tx_read_req_pkts);
	estat->tx_read_res = le64_to_cpu(sb->tx_read_res_pkts);
	estat->tx_write_req = le64_to_cpu(sb->tx_write_req_pkts);
	estat->tx_send_req = le64_to_cpu(sb->tx_send_req_pkts);
	estat->tx_roce_pkts = le64_to_cpu(sb->tx_roce_pkts);
	estat->tx_roce_bytes = le64_to_cpu(sb->tx_roce_bytes);
	estat->rx_atomic_req = le64_to_cpu(sb->rx_atomic_req_pkts);
	estat->rx_read_req = le64_to_cpu(sb->rx_read_req_pkts);
	estat->rx_read_res = le64_to_cpu(sb->rx_read_res_pkts);
	estat->rx_write_req = le64_to_cpu(sb->rx_write_req_pkts);
	estat->rx_send_req = le64_to_cpu(sb->rx_send_req_pkts);
	estat->rx_roce_pkts = le64_to_cpu(sb->rx_roce_pkts);
	estat->rx_roce_bytes = le64_to_cpu(sb->rx_roce_bytes);
	estat->rx_roce_good_pkts = le64_to_cpu(sb->rx_roce_good_pkts);
	estat->rx_roce_good_bytes = le64_to_cpu(sb->rx_roce_good_bytes);
	estat->rx_out_of_buffer = le64_to_cpu(sb->rx_out_of_buffer_pkts);
	estat->rx_out_of_sequence = le64_to_cpu(sb->rx_out_of_sequence_pkts);
	estat->tx_cnp = le64_to_cpu(sb->tx_cnp_pkts);
	estat->rx_cnp = le64_to_cpu(sb->rx_cnp_pkts);
	estat->rx_ecn_marked = le64_to_cpu(sb->rx_ecn_marked_pkts);

bail:
	dma_free_coherent(&rcfw->pdev->dev, sbuf.size,
			  sbuf.sb, sbuf.dma_addr);
	return rc;
}

static void bnxt_qplib_fill_cc_gen1(struct cmdq_modify_roce_cc_gen1_tlv *ext_req,
				    struct bnxt_qplib_cc_param_ext *cc_ext)
{
	ext_req->modify_mask = cpu_to_le64(cc_ext->ext_mask);
	cc_ext->ext_mask = 0;
	ext_req->inactivity_th_hi = cpu_to_le16(cc_ext->inact_th_hi);
	ext_req->min_time_between_cnps = cpu_to_le16(cc_ext->min_delta_cnp);
	ext_req->init_cp = cpu_to_le16(cc_ext->init_cp);
	ext_req->tr_update_mode = cc_ext->tr_update_mode;
	ext_req->tr_update_cycles = cc_ext->tr_update_cyls;
	ext_req->fr_num_rtts = cc_ext->fr_rtt;
	ext_req->ai_rate_increase = cc_ext->ai_rate_incr;
	ext_req->reduction_relax_rtts_th = cpu_to_le16(cc_ext->rr_rtt_th);
	ext_req->additional_relax_cr_th = cpu_to_le16(cc_ext->ar_cr_th);
	ext_req->cr_min_th = cpu_to_le16(cc_ext->cr_min_th);
	ext_req->bw_avg_weight = cc_ext->bw_avg_weight;
	ext_req->actual_cr_factor = cc_ext->cr_factor;
	ext_req->max_cp_cr_th = cpu_to_le16(cc_ext->cr_th_max_cp);
	ext_req->cp_bias_en = cc_ext->cp_bias_en;
	ext_req->cp_bias = cc_ext->cp_bias;
	ext_req->cnp_ecn = cc_ext->cnp_ecn;
	ext_req->rtt_jitter_en = cc_ext->rtt_jitter_en;
	ext_req->link_bytes_per_usec = cpu_to_le16(cc_ext->bytes_per_usec);
	ext_req->reset_cc_cr_th = cpu_to_le16(cc_ext->cc_cr_reset_th);
	ext_req->cr_width = cc_ext->cr_width;
	ext_req->quota_period_min = cc_ext->min_quota;
	ext_req->quota_period_max = cc_ext->max_quota;
	ext_req->quota_period_abs_max = cc_ext->abs_max_quota;
	ext_req->tr_lower_bound = cpu_to_le16(cc_ext->tr_lb);
	ext_req->cr_prob_factor = cc_ext->cr_prob_fac;
	ext_req->tr_prob_factor = cc_ext->tr_prob_fac;
	ext_req->fairness_cr_th = cpu_to_le16(cc_ext->fair_cr_th);
	ext_req->red_div = cc_ext->red_div;
	ext_req->cnp_ratio_th = cc_ext->cnp_ratio_th;
	ext_req->exp_ai_rtts = cpu_to_le16(cc_ext->ai_ext_rtt);
	ext_req->exp_ai_cr_cp_ratio = cc_ext->exp_crcp_ratio;
	ext_req->use_rate_table = cc_ext->low_rate_en;
	ext_req->cp_exp_update_th = cpu_to_le16(cc_ext->cpcr_update_th);
	ext_req->high_exp_ai_rtts_th1 = cpu_to_le16(cc_ext->ai_rtt_th1);
	ext_req->high_exp_ai_rtts_th2 = cpu_to_le16(cc_ext->ai_rtt_th2);
	ext_req->actual_cr_cong_free_rtts_th = cpu_to_le16(cc_ext->cf_rtt_th);
	ext_req->severe_cong_cr_th1 = cpu_to_le16(cc_ext->sc_cr_th1);
	ext_req->severe_cong_cr_th2 = cpu_to_le16(cc_ext->sc_cr_th2);
	ext_req->link64B_per_rtt = cpu_to_le32(cc_ext->l64B_per_rtt);
	ext_req->cc_ack_bytes = cc_ext->cc_ack_bytes;
}

int bnxt_qplib_modify_cc(struct bnxt_qplib_res *res,
			 struct bnxt_qplib_cc_param *cc_param)
{
	struct bnxt_qplib_tlv_modify_cc_req tlv_req = {};
	struct creq_modify_roce_cc_resp resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_modify_roce_cc *req;
	int req_size;
	void *cmd;
	int rc;

	/* Prepare the older base command */
	req = &tlv_req.base_req;
	cmd = req;
	req_size = sizeof(*req);
	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)req, CMDQ_BASE_OPCODE_MODIFY_ROCE_CC,
				 sizeof(*req));
	req->modify_mask = cpu_to_le32(cc_param->mask);
	req->enable_cc = cc_param->enable;
	req->g = cc_param->g;
	req->num_phases_per_state = cc_param->nph_per_state;
	req->time_per_phase = cc_param->time_pph;
	req->pkts_per_phase = cc_param->pkts_pph;
	req->init_cr = cpu_to_le16(cc_param->init_cr);
	req->init_tr = cpu_to_le16(cc_param->init_tr);
	req->tos_dscp_tos_ecn = (cc_param->tos_dscp << CMDQ_MODIFY_ROCE_CC_TOS_DSCP_SFT) |
				(cc_param->tos_ecn & CMDQ_MODIFY_ROCE_CC_TOS_ECN_MASK);
	req->alt_vlan_pcp = cc_param->alt_vlan_pcp;
	req->alt_tos_dscp = cpu_to_le16(cc_param->alt_tos_dscp);
	req->rtt = cpu_to_le16(cc_param->rtt);
	req->tcp_cp = cpu_to_le16(cc_param->tcp_cp);
	req->cc_mode = cc_param->cc_mode;
	req->inactivity_th = cpu_to_le16(cc_param->inact_th);

	/* For chip gen P5 onwards fill extended cmd and header */
	if (bnxt_qplib_is_chip_gen_p5_p7(res->cctx)) {
		struct roce_tlv *hdr;
		u32 payload;
		u32 chunks;

		cmd = &tlv_req;
		req_size = sizeof(tlv_req);
		/* Prepare primary tlv header */
		hdr = &tlv_req.tlv_hdr;
		chunks = CHUNKS(sizeof(struct bnxt_qplib_tlv_modify_cc_req));
		payload = sizeof(struct cmdq_modify_roce_cc);
		__roce_1st_tlv_prep(hdr, chunks, payload, true);
		/* Prepare secondary tlv header */
		hdr = (struct roce_tlv *)&tlv_req.ext_req;
		payload = sizeof(struct cmdq_modify_roce_cc_gen1_tlv) -
			  sizeof(struct roce_tlv);
		__roce_ext_tlv_prep(hdr, TLV_TYPE_MODIFY_ROCE_CC_GEN1, payload, false, true);
		bnxt_qplib_fill_cc_gen1(&tlv_req.ext_req, &cc_param->cc_ext);
	}

	bnxt_qplib_fill_cmdqmsg(&msg, cmd, &resp, NULL, req_size,
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(res->rcfw, &msg);
	return rc;
}

int bnxt_qplib_read_context(struct bnxt_qplib_rcfw *rcfw, u8 res_type,
			    u32 xid, u32 resp_size, void *resp_va)
{
	struct creq_read_context resp = {};
	struct bnxt_qplib_cmdqmsg msg = {};
	struct cmdq_read_context req = {};
	struct bnxt_qplib_rcfw_sbuf sbuf;
	int rc;

	sbuf.size = resp_size;
	sbuf.sb = dma_alloc_coherent(&rcfw->pdev->dev, sbuf.size,
				     &sbuf.dma_addr, GFP_KERNEL);
	if (!sbuf.sb)
		return -ENOMEM;

	bnxt_qplib_rcfw_cmd_prep((struct cmdq_base *)&req,
				 CMDQ_BASE_OPCODE_READ_CONTEXT, sizeof(req));
	req.resp_addr = cpu_to_le64(sbuf.dma_addr);
	req.resp_size = resp_size / BNXT_QPLIB_CMDQE_UNITS;

	req.xid = cpu_to_le32(xid);
	req.type = res_type;

	bnxt_qplib_fill_cmdqmsg(&msg, &req, &resp, &sbuf, sizeof(req),
				sizeof(resp), 0);
	rc = bnxt_qplib_rcfw_send_message(rcfw, &msg);
	if (rc)
		goto free_mem;

	memcpy(resp_va, sbuf.sb, resp_size);
free_mem:
	dma_free_coherent(&rcfw->pdev->dev, sbuf.size, sbuf.sb, sbuf.dma_addr);
	return rc;
}