/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License, v.1,  (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://opensource.org/licenses/CDDL-1.0.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/

/*
* Copyright 2014-2017 Cavium, Inc. 
* The contents of this file are subject to the terms of the Common Development 
* and Distribution License, v.1,  (the "License").

* You may not use this file except in compliance with the License.

* You can obtain a copy of the License at available 
* at http://opensource.org/licenses/CDDL-1.0

* See the License for the specific language governing permissions and 
* limitations under the License.
*/

#include "bcm_osal.h"
#include "reg_addr.h"
#include "common_hsi.h"
#include "ecore_hsi_common.h"
#include "ecore_hsi_eth.h"
#include "tcp_common.h"
#include "ecore_hsi_iscsi.h"
#include "ecore_hsi_fcoe.h"
#include "ecore_hsi_roce.h"
#include "ecore_hsi_iwarp.h"
#include "ecore_rt_defs.h"
#include "ecore_status.h"
#include "ecore.h"
#include "ecore_init_ops.h"
#include "ecore_init_fw_funcs.h"
#include "ecore_cxt.h"
#include "ecore_hw.h"
#include "ecore_dev_api.h"
#include "ecore_sriov.h"
#include "ecore_roce.h"
#include "ecore_mcp.h"

/* Max number of connection types in HW (DQ/CDU etc.) */
#define MAX_CONN_TYPES          PROTOCOLID_COMMON
#define NUM_TASK_TYPES          2
#define NUM_TASK_PF_SEGMENTS    4
#define NUM_TASK_VF_SEGMENTS    1

/* Doorbell-Queue constants */
#define DQ_RANGE_SHIFT  4
#define DQ_RANGE_ALIGN  (1 << DQ_RANGE_SHIFT)

/* Searcher constants */
#define SRC_MIN_NUM_ELEMS 256

/* Timers constants */
#define TM_SHIFT        7
#define TM_ALIGN        (1 << TM_SHIFT)
#define TM_ELEM_SIZE    4

/* ILT constants */
/* If for some reason, HW P size is modified to be less than 32K,
 * special handling needs to be made for CDU initialization
 */
#ifdef CONFIG_ECORE_ROCE
/* For RoCE we configure to 64K to cover for RoCE max tasks 256K purpose. Can be
 * optimized with resource management scheme
 */
#define ILT_DEFAULT_HW_P_SIZE   4
#else
#define ILT_DEFAULT_HW_P_SIZE   3
#endif

#define ILT_PAGE_IN_BYTES(hw_p_size)    (1U << ((hw_p_size) + 12))
#define ILT_CFG_REG(cli, reg)           PSWRQ2_REG_##cli##_##reg##_RT_OFFSET

/* ILT entry structure */
#define ILT_ENTRY_PHY_ADDR_MASK         0x000FFFFFFFFFFFULL
#define ILT_ENTRY_PHY_ADDR_SHIFT        0
#define ILT_ENTRY_VALID_MASK            0x1ULL
#define ILT_ENTRY_VALID_SHIFT           52
#define ILT_ENTRY_IN_REGS               2
#define ILT_REG_SIZE_IN_BYTES           4

/* connection context union */
union conn_context {
        struct core_conn_context  core_ctx;
        struct eth_conn_context   eth_ctx;
        struct iscsi_conn_context iscsi_ctx;
        struct fcoe_conn_context  fcoe_ctx;
        struct roce_conn_context  roce_ctx;
};

/* TYPE-0 task context - iSCSI, FCOE */
union type0_task_context {
        struct iscsi_task_context iscsi_ctx;
        struct fcoe_task_context  fcoe_ctx;
};

/* TYPE-1 task context - ROCE */
union type1_task_context {
        struct rdma_task_context roce_ctx;
};

struct src_ent {
        u8  opaque[56];
        u64 next;
};

#define CDUT_SEG_ALIGNMET 3 /* in 4k chunks */
#define CDUT_SEG_ALIGNMET_IN_BYTES (1 << (CDUT_SEG_ALIGNMET + 12))

#define CONN_CXT_SIZE(p_hwfn) \
        ALIGNED_TYPE_SIZE(union conn_context, p_hwfn)

#define SRQ_CXT_SIZE (sizeof(struct rdma_srq_context))

#define TYPE0_TASK_CXT_SIZE(p_hwfn) \
        ALIGNED_TYPE_SIZE(union type0_task_context, p_hwfn)

/* Alignment is inherent to the type1_task_context structure */
#define TYPE1_TASK_CXT_SIZE(p_hwfn) sizeof(union type1_task_context)

/* PF per protocl configuration object */
#define TASK_SEGMENTS   (NUM_TASK_PF_SEGMENTS + NUM_TASK_VF_SEGMENTS)
#define TASK_SEGMENT_VF (NUM_TASK_PF_SEGMENTS)

struct ecore_tid_seg {
        u32     count;
        u8      type;
        bool    has_fl_mem;
};

struct ecore_conn_type_cfg {
        u32                     cid_count;
        u32                     cids_per_vf;
        struct ecore_tid_seg    tid_seg[TASK_SEGMENTS];
};

/* ILT Client configuration,
 * Per connection type (protocol) resources (cids, tis, vf cids etc.)
 * 1 - for connection context (CDUC) and for each task context we need two
 * values, for regular task context and for force load memory
 */
#define ILT_CLI_PF_BLOCKS       (1 + NUM_TASK_PF_SEGMENTS * 2)
#define ILT_CLI_VF_BLOCKS       (1 + NUM_TASK_VF_SEGMENTS * 2)
#define CDUC_BLK                (0)
#define SRQ_BLK                 (0)
#define CDUT_SEG_BLK(n)         (1 + (u8)(n))
#define CDUT_FL_SEG_BLK(n, X)   (1 + (n) + NUM_TASK_##X##_SEGMENTS)

enum ilt_clients {
        ILT_CLI_CDUC,
        ILT_CLI_CDUT,
        ILT_CLI_QM,
        ILT_CLI_TM,
        ILT_CLI_SRC,
        ILT_CLI_TSDM,
        ILT_CLI_MAX
};

struct ilt_cfg_pair {
        u32 reg;
        u32 val;
};

struct ecore_ilt_cli_blk {
        u32 total_size; /* 0 means not active */
        u32 real_size_in_page;
        u32 start_line;
        u32 dynamic_line_cnt;
};

struct ecore_ilt_client_cfg {
        bool                            active;

        /* ILT boundaries */
        struct ilt_cfg_pair             first;
        struct ilt_cfg_pair             last;
        struct ilt_cfg_pair             p_size;

        /* ILT client blocks for PF */
        struct ecore_ilt_cli_blk        pf_blks[ILT_CLI_PF_BLOCKS];
        u32                             pf_total_lines;

        /* ILT client blocks for VFs */
        struct ecore_ilt_cli_blk        vf_blks[ILT_CLI_VF_BLOCKS];
        u32                             vf_total_lines;
};

/* Per Path -
 *      ILT shadow table
 *      Protocol acquired CID lists
 *      PF start line in ILT
 */
struct ecore_dma_mem {
        dma_addr_t      p_phys;
        void            *p_virt;
        osal_size_t     size;
};

#define MAP_WORD_SIZE           sizeof(unsigned long)
#define BITS_PER_MAP_WORD       (MAP_WORD_SIZE * 8)

struct ecore_cid_acquired_map {
        u32             start_cid;
        u32             max_count;
        unsigned long   *cid_map;
};

struct ecore_cxt_mngr {
        /* Per protocl configuration */
        struct ecore_conn_type_cfg      conn_cfg[MAX_CONN_TYPES];

        /* computed ILT structure */
        struct ecore_ilt_client_cfg     clients[ILT_CLI_MAX];

        /* Task type sizes */
        u32                             task_type_size[NUM_TASK_TYPES];

        /* total number of VFs for this hwfn -
         * ALL VFs are symmetric in terms of HW resources
         */
        u32                             vf_count;

        /* Acquired CIDs */
        struct ecore_cid_acquired_map acquired[MAX_CONN_TYPES];
        /* TBD - do we want this allocated to reserve space? */
        struct ecore_cid_acquired_map acquired_vf[MAX_CONN_TYPES][COMMON_MAX_NUM_VFS];

        /* ILT shadow table */
        struct ecore_dma_mem            *ilt_shadow;
        u32                             pf_start_line;

        /* Mutex for a dynamic ILT allocation */
        osal_mutex_t                    mutex;

        /* SRC T2 */
        struct ecore_dma_mem            *t2;
        u32                             t2_num_pages;
        u64                             first_free;
        u64                             last_free;

        /* The infrastructure originally was very generic and context/task
         * oriented - per connection-type we would set how many of those
         * are needed, and later when determining how much memory we're
         * needing for a given block we'd iterate over all the relevant
         * connection-types.
         * But since then we've had some additional resources, some of which
         * require memory which is indepent of the general context/task
         * scheme. We add those here explicitly per-feature.
         */

        /* total number of SRQ's for this hwfn */
        u32                             srq_count;

        /* Maximal number of L2 steering filters */
        u32                             arfs_count;

        /* TODO - VF arfs filters ? */
};

/* check if resources/configuration is required according to protocol type */
static bool src_proto(struct ecore_hwfn *p_hwfn,
                      enum protocol_type type)
{
        return  type == PROTOCOLID_ISCSI        ||
                type == PROTOCOLID_FCOE         ||
                type == PROTOCOLID_TOE          ||
                type == PROTOCOLID_IWARP;
}

static bool tm_cid_proto(enum protocol_type type)
{
        return type == PROTOCOLID_ISCSI ||
               type == PROTOCOLID_FCOE  ||
               type == PROTOCOLID_ROCE  ||
               type == PROTOCOLID_IWARP;
}

static bool tm_tid_proto(enum protocol_type type)
{
        return type == PROTOCOLID_FCOE;
}

/* counts the iids for the CDU/CDUC ILT client configuration */
struct ecore_cdu_iids {
        u32 pf_cids;
        u32 per_vf_cids;
};

static void ecore_cxt_cdu_iids(struct ecore_cxt_mngr   *p_mngr,
                               struct ecore_cdu_iids    *iids)
{
        u32 type;

        for (type = 0; type < MAX_CONN_TYPES; type++) {
                iids->pf_cids += p_mngr->conn_cfg[type].cid_count;
                iids->per_vf_cids += p_mngr->conn_cfg[type].cids_per_vf;
        }
}

/* counts the iids for the Searcher block configuration */
struct ecore_src_iids {
        u32                     pf_cids;
        u32                     per_vf_cids;
};

static void ecore_cxt_src_iids(struct ecore_hwfn *p_hwfn,
                               struct ecore_cxt_mngr *p_mngr,
                               struct ecore_src_iids *iids)
{
        u32 i;

        for (i = 0; i < MAX_CONN_TYPES; i++) {
                if (!src_proto(p_hwfn, i))
                        continue;

                iids->pf_cids += p_mngr->conn_cfg[i].cid_count;
                iids->per_vf_cids += p_mngr->conn_cfg[i].cids_per_vf;
        }

        /* Add L2 filtering filters in addition */
        iids->pf_cids += p_mngr->arfs_count;
}

/* counts the iids for the Timers block configuration */
struct ecore_tm_iids {
        u32 pf_cids;
        u32 pf_tids[NUM_TASK_PF_SEGMENTS]; /* per segment */
        u32 pf_tids_total;
        u32 per_vf_cids;
        u32 per_vf_tids;
};

static void ecore_cxt_tm_iids(struct ecore_hwfn *p_hwfn,
                              struct ecore_cxt_mngr *p_mngr,
                              struct ecore_tm_iids *iids)
{
        bool tm_vf_required = false;
        bool tm_required = false;
        int i, j;

        /* Timers is a special case -> we don't count how many cids require
         * timers but what's the max cid that will be used by the timer block.
         * therefore we traverse in reverse order, and once we hit a protocol
         * that requires the timers memory, we'll sum all the protocols up
         * to that one.
         */
        for (i = MAX_CONN_TYPES - 1; i >= 0; i--) {
                struct ecore_conn_type_cfg *p_cfg = &p_mngr->conn_cfg[i];

                if (tm_cid_proto(i) || tm_required) {
                        if (p_cfg->cid_count)
                                tm_required = true;

                        iids->pf_cids += p_cfg->cid_count;
                }

                if (tm_cid_proto(i) || tm_vf_required) {
                        if (p_cfg->cids_per_vf)
                                tm_vf_required = true;

                        iids->per_vf_cids += p_cfg->cids_per_vf;
                }

                if (tm_tid_proto(i)) {
                        struct ecore_tid_seg *segs = p_cfg->tid_seg;

                        /* for each segment there is at most one
                         * protocol for which count is not 0.
                         */
                        for (j = 0; j < NUM_TASK_PF_SEGMENTS; j++)
                                iids->pf_tids[j] += segs[j].count;

                        /* The last array elelment is for the VFs. As for PF
                         * segments there can be only one protocol for
                         * which this value is not 0.
                         */
                        iids->per_vf_tids += segs[NUM_TASK_PF_SEGMENTS].count;
                }
        }

        iids->pf_cids = ROUNDUP(iids->pf_cids, TM_ALIGN);
        iids->per_vf_cids = ROUNDUP(iids->per_vf_cids, TM_ALIGN);
        iids->per_vf_tids = ROUNDUP(iids->per_vf_tids, TM_ALIGN);

        for (iids->pf_tids_total = 0, j = 0; j < NUM_TASK_PF_SEGMENTS; j++) {
                iids->pf_tids[j] = ROUNDUP(iids->pf_tids[j], TM_ALIGN);
                iids->pf_tids_total += iids->pf_tids[j];
        }
}

static void ecore_cxt_qm_iids(struct ecore_hwfn *p_hwfn,
                              struct ecore_qm_iids *iids)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_tid_seg *segs;
        u32 vf_cids = 0, type, j;
        u32 vf_tids = 0;

        for (type = 0; type < MAX_CONN_TYPES; type++) {
                iids->cids += p_mngr->conn_cfg[type].cid_count;
                vf_cids += p_mngr->conn_cfg[type].cids_per_vf;

                segs = p_mngr->conn_cfg[type].tid_seg;
                /* for each segment there is at most one
                 * protocol for which count is not 0.
                 */
                for (j = 0; j < NUM_TASK_PF_SEGMENTS; j++)
                        iids->tids += segs[j].count;

                /* The last array elelment is for the VFs. As for PF
                 * segments there can be only one protocol for
                 * which this value is not 0.
                 */
                vf_tids += segs[NUM_TASK_PF_SEGMENTS].count;
        }

        iids->vf_cids += vf_cids * p_mngr->vf_count;
        iids->tids += vf_tids * p_mngr->vf_count;

        DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                   "iids: CIDS %08x vf_cids %08x tids %08x vf_tids %08x\n",
                   iids->cids, iids->vf_cids, iids->tids, vf_tids);
}

static struct ecore_tid_seg *ecore_cxt_tid_seg_info(struct ecore_hwfn   *p_hwfn,
                                                    u32                 seg)
{
        struct ecore_cxt_mngr *p_cfg = p_hwfn->p_cxt_mngr;
        u32 i;

        /* Find the protocol with tid count > 0 for this segment.
           Note: there can only be one and this is already validated.
         */
        for (i = 0; i < MAX_CONN_TYPES; i++) {
                if (p_cfg->conn_cfg[i].tid_seg[seg].count)
                        return &p_cfg->conn_cfg[i].tid_seg[seg];
        }
        return OSAL_NULL;
}

/* set the iids (cid/tid) count per protocol */
static void ecore_cxt_set_proto_cid_count(struct ecore_hwfn *p_hwfn,
                                          enum protocol_type type,
                                          u32 cid_count, u32 vf_cid_cnt)
{
        struct ecore_cxt_mngr *p_mgr = p_hwfn->p_cxt_mngr;
        struct ecore_conn_type_cfg *p_conn = &p_mgr->conn_cfg[type];

        p_conn->cid_count = ROUNDUP(cid_count, DQ_RANGE_ALIGN);
        p_conn->cids_per_vf = ROUNDUP(vf_cid_cnt, DQ_RANGE_ALIGN);

        if (type == PROTOCOLID_ROCE) {
                u32 page_sz = p_mgr->clients[ILT_CLI_CDUC].p_size.val;
                u32 cxt_size = CONN_CXT_SIZE(p_hwfn);
                u32 elems_per_page = ILT_PAGE_IN_BYTES(page_sz) / cxt_size;
                u32 align = elems_per_page * DQ_RANGE_ALIGN;

                p_conn->cid_count = ROUNDUP(p_conn->cid_count, align);
        }
}

u32 ecore_cxt_get_proto_cid_count(struct ecore_hwfn     *p_hwfn,
                                  enum protocol_type    type,
                                  u32                   *vf_cid)
{
        if (vf_cid)
                *vf_cid = p_hwfn->p_cxt_mngr->conn_cfg[type].cids_per_vf;

        return p_hwfn->p_cxt_mngr->conn_cfg[type].cid_count;
}

u32 ecore_cxt_get_proto_cid_start(struct ecore_hwfn     *p_hwfn,
                                  enum protocol_type    type)
{
        return p_hwfn->p_cxt_mngr->acquired[type].start_cid;
}

u32 ecore_cxt_get_proto_tid_count(struct ecore_hwfn *p_hwfn,
                                  enum protocol_type type)
{
        u32 cnt = 0;
        int i;

        for (i = 0; i < TASK_SEGMENTS; i++)
                cnt += p_hwfn->p_cxt_mngr->conn_cfg[type].tid_seg[i].count;

        return cnt;
}

static void ecore_cxt_set_proto_tid_count(struct ecore_hwfn *p_hwfn,
                                          enum protocol_type proto,
                                          u8 seg,
                                          u8 seg_type,
                                          u32 count,
                                          bool has_fl)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_tid_seg *p_seg = &p_mngr->conn_cfg[proto].tid_seg[seg];

        p_seg->count = count;
        p_seg->has_fl_mem = has_fl;
        p_seg->type = seg_type;
}

/* the *p_line parameter must be either 0 for the first invocation or the
   value returned in the previous invocation.
 */
static void ecore_ilt_cli_blk_fill(struct ecore_ilt_client_cfg  *p_cli,
                                   struct ecore_ilt_cli_blk     *p_blk,
                                   u32                          start_line,
                                   u32                          total_size,
                                   u32                          elem_size)
{
        u32 ilt_size = ILT_PAGE_IN_BYTES(p_cli->p_size.val);

        /* verify that it's called once for each block */
        if (p_blk->total_size)
                return;

        p_blk->total_size = total_size;
        p_blk->real_size_in_page = 0;
        if (elem_size)
                p_blk->real_size_in_page = (ilt_size / elem_size) * elem_size;
        p_blk->start_line = start_line;
}

static void ecore_ilt_cli_adv_line(struct ecore_hwfn            *p_hwfn,
                                    struct ecore_ilt_client_cfg *p_cli,
                                    struct ecore_ilt_cli_blk    *p_blk,
                                    u32                         *p_line,
                                    enum ilt_clients            client_id)
{
        if (!p_blk->total_size)
                return;

        if (!p_cli->active)
                p_cli->first.val = *p_line;

        p_cli->active = true;
        *p_line += DIV_ROUND_UP(p_blk->total_size, p_blk->real_size_in_page);
        p_cli->last.val = *p_line-1;

        DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                   "ILT[Client %d] - Lines: [%08x - %08x]. Block - Size %08x [Real %08x] Start line %d\n",
                   client_id, p_cli->first.val, p_cli->last.val,
                   p_blk->total_size, p_blk->real_size_in_page,
                   p_blk->start_line);
}

static u32 ecore_ilt_get_dynamic_line_cnt(struct ecore_hwfn *p_hwfn,
                                          enum ilt_clients ilt_client)
{
        u32 cid_count = p_hwfn->p_cxt_mngr->conn_cfg[PROTOCOLID_ROCE].cid_count;
        struct ecore_ilt_client_cfg *p_cli;
        u32 lines_to_skip = 0;
        u32 cxts_per_p;

        /* TBD MK: ILT code should be simplified once PROTO enum is changed */

        if (ilt_client == ILT_CLI_CDUC) {
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUC];

                cxts_per_p = ILT_PAGE_IN_BYTES(p_cli->p_size.val) /
                             (u32)CONN_CXT_SIZE(p_hwfn);

                lines_to_skip = cid_count / cxts_per_p;
        }

        return lines_to_skip;
}

static struct ecore_ilt_client_cfg *
ecore_cxt_set_cli(struct ecore_ilt_client_cfg *p_cli)
{
        p_cli->active = false;
        p_cli->first.val = 0;
        p_cli->last.val = 0;
        return p_cli;
}

static struct ecore_ilt_cli_blk *
ecore_cxt_set_blk(struct ecore_ilt_cli_blk *p_blk)
{
        p_blk->total_size = 0;
        return p_blk;
}

enum _ecore_status_t ecore_cxt_cfg_ilt_compute(struct ecore_hwfn *p_hwfn,
                                               u32 *line_count)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 curr_line, total, i, task_size, line;
        struct ecore_ilt_client_cfg *p_cli;
        struct ecore_ilt_cli_blk *p_blk;
        struct ecore_cdu_iids cdu_iids;
        struct ecore_src_iids src_iids;
        struct ecore_qm_iids qm_iids;
        struct ecore_tm_iids tm_iids;
        struct ecore_tid_seg *p_seg;

        OSAL_MEM_ZERO(&qm_iids, sizeof(qm_iids));
        OSAL_MEM_ZERO(&cdu_iids, sizeof(cdu_iids));
        OSAL_MEM_ZERO(&src_iids, sizeof(src_iids));
        OSAL_MEM_ZERO(&tm_iids, sizeof(tm_iids));

        p_mngr->pf_start_line = RESC_START(p_hwfn, ECORE_ILT);

        DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                   "hwfn [%d] - Set context manager starting line to be 0x%08x\n",
                   p_hwfn->my_id, p_hwfn->p_cxt_mngr->pf_start_line);

        /* CDUC */
        p_cli = ecore_cxt_set_cli(&p_mngr->clients[ILT_CLI_CDUC]);

        curr_line = p_mngr->pf_start_line;

        /* CDUC PF */
        p_cli->pf_total_lines = 0;

        /* get the counters for the CDUC,CDUC and QM clients  */
        ecore_cxt_cdu_iids(p_mngr, &cdu_iids);

        p_blk = ecore_cxt_set_blk(&p_cli->pf_blks[CDUC_BLK]);

        total = cdu_iids.pf_cids * CONN_CXT_SIZE(p_hwfn);

        ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line,
                               total, CONN_CXT_SIZE(p_hwfn));

        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line, ILT_CLI_CDUC);
        p_cli->pf_total_lines = curr_line - p_blk->start_line;

        p_blk->dynamic_line_cnt = ecore_ilt_get_dynamic_line_cnt(p_hwfn,
                                                                 ILT_CLI_CDUC);

        /* CDUC VF */
        p_blk = ecore_cxt_set_blk(&p_cli->vf_blks[CDUC_BLK]);
        total = cdu_iids.per_vf_cids * CONN_CXT_SIZE(p_hwfn);

        ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line,
                               total, CONN_CXT_SIZE(p_hwfn));

        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line, ILT_CLI_CDUC);
        p_cli->vf_total_lines = curr_line - p_blk->start_line;

        for (i = 1; i < p_mngr->vf_count; i++)
                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_CDUC);

        /* CDUT PF */
        p_cli = ecore_cxt_set_cli(&p_mngr->clients[ILT_CLI_CDUT]);
        p_cli->first.val = curr_line;

        /* first the 'working' task memory */
        for (i = 0; i < NUM_TASK_PF_SEGMENTS; i++) {
                p_seg = ecore_cxt_tid_seg_info(p_hwfn, i);
                if (!p_seg || p_seg->count == 0)
                        continue;

                p_blk = ecore_cxt_set_blk(&p_cli->pf_blks[CDUT_SEG_BLK(i)]);
                total = p_seg->count * p_mngr->task_type_size[p_seg->type];
                ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line, total,
                                       p_mngr->task_type_size[p_seg->type]);

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_CDUT);
        }

        /* next the 'init' task memory (forced load memory) */
        for (i = 0; i < NUM_TASK_PF_SEGMENTS; i++) {
                p_seg = ecore_cxt_tid_seg_info(p_hwfn, i);
                if (!p_seg || p_seg->count == 0)
                        continue;

                p_blk = ecore_cxt_set_blk(
                                &p_cli->pf_blks[CDUT_FL_SEG_BLK(i, PF)]);

                if (!p_seg->has_fl_mem) {
                        /* The segment is active (total size pf 'working'
                         * memory is > 0) but has no FL (forced-load, Init)
                         * memory. Thus:
                         *
                         * 1.   The total-size in the corrsponding FL block of
                         *      the ILT client is set to 0 - No ILT line are
                         *      provisioned and no ILT memory allocated.
                         *
                         * 2.   The start-line of said block is set to the
                         *      start line of the matching working memory
                         *      block in the ILT client. This is later used to
                         *      configure the CDU segment offset registers and
                         *      results in an FL command for TIDs of this
                         *      segement behaves as regular load commands
                         *      (loading TIDs from the working memory).
                         */
                        line = p_cli->pf_blks[CDUT_SEG_BLK(i)].start_line;

                        ecore_ilt_cli_blk_fill(p_cli, p_blk, line, 0, 0);
                        continue;
                }
                total = p_seg->count * p_mngr->task_type_size[p_seg->type];

                ecore_ilt_cli_blk_fill(p_cli, p_blk,
                                       curr_line, total,
                                       p_mngr->task_type_size[p_seg->type]);

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_CDUT);
        }
        p_cli->pf_total_lines = curr_line - p_cli->pf_blks[0].start_line;

        /* CDUT VF */
        p_seg = ecore_cxt_tid_seg_info(p_hwfn, TASK_SEGMENT_VF);
        if (p_seg && p_seg->count) {
                /* Stricly speaking we need to iterate over all VF
                 * task segment types, but a VF has only 1 segment
                 */

                /* 'working' memory */
                total = p_seg->count * p_mngr->task_type_size[p_seg->type];

                p_blk = ecore_cxt_set_blk(&p_cli->vf_blks[CDUT_SEG_BLK(0)]);
                ecore_ilt_cli_blk_fill(p_cli, p_blk,
                                       curr_line, total,
                                       p_mngr->task_type_size[p_seg->type]);

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_CDUT);

                /* 'init' memory */
                p_blk = ecore_cxt_set_blk(
                                &p_cli->vf_blks[CDUT_FL_SEG_BLK(0, VF)]);
                if (!p_seg->has_fl_mem) {
                        /* see comment above */
                        line = p_cli->vf_blks[CDUT_SEG_BLK(0)].start_line;
                        ecore_ilt_cli_blk_fill(p_cli, p_blk, line, 0, 0);
                } else {
                        task_size = p_mngr->task_type_size[p_seg->type];
                        ecore_ilt_cli_blk_fill(p_cli, p_blk,
                                               curr_line, total,
                                               task_size);
                        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                               ILT_CLI_CDUT);
                }
                p_cli->vf_total_lines = curr_line -
                                        p_cli->vf_blks[0].start_line;

                /* Now for the rest of the VFs */
                for (i = 1; i < p_mngr->vf_count; i++) {
                        /* don't set p_blk i.e. don't clear total_size */
                        p_blk = &p_cli->vf_blks[CDUT_SEG_BLK(0)];
                        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                               ILT_CLI_CDUT);

                        /* don't set p_blk i.e. don't clear total_size */
                        p_blk = &p_cli->vf_blks[CDUT_FL_SEG_BLK(0, VF)];
                        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                               ILT_CLI_CDUT);
                }
        }

        /* QM */
        p_cli = ecore_cxt_set_cli(&p_mngr->clients[ILT_CLI_QM]);
        p_blk = ecore_cxt_set_blk(&p_cli->pf_blks[0]);

        ecore_cxt_qm_iids(p_hwfn, &qm_iids);
        total = ecore_qm_pf_mem_size(p_hwfn->rel_pf_id, qm_iids.cids,
                                     qm_iids.vf_cids, qm_iids.tids,
                                     p_hwfn->qm_info.num_pqs,
                                     p_hwfn->qm_info.num_vf_pqs);

        DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                   "QM ILT Info, (cids=%d, vf_cids=%d, tids=%d, num_pqs=%d, num_vf_pqs=%d, memory_size=%d)\n",
                   qm_iids.cids, qm_iids.vf_cids, qm_iids.tids,
                   p_hwfn->qm_info.num_pqs, p_hwfn->qm_info.num_vf_pqs, total);

        ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line, total * 0x1000,
                               QM_PQ_ELEMENT_SIZE);

        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line, ILT_CLI_QM);
        p_cli->pf_total_lines = curr_line - p_blk->start_line;

        /* SRC */
        p_cli = ecore_cxt_set_cli(&p_mngr->clients[ILT_CLI_SRC]);
        ecore_cxt_src_iids(p_hwfn, p_mngr, &src_iids);

        /* Both the PF and VFs searcher connections are stored in the per PF
         * database. Thus sum the PF searcher cids and all the VFs searcher
         * cids.
         */
        total = src_iids.pf_cids + src_iids.per_vf_cids * p_mngr->vf_count;
        if (total) {
                u32 local_max = OSAL_MAX_T(u32, total,
                                           SRC_MIN_NUM_ELEMS);

                total = OSAL_ROUNDUP_POW_OF_TWO(local_max);

                p_blk = ecore_cxt_set_blk(&p_cli->pf_blks[0]);
                ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line,
                                       total * sizeof(struct src_ent),
                                       sizeof(struct src_ent));

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_SRC);
                p_cli->pf_total_lines = curr_line - p_blk->start_line;
        }

        /* TM PF */
        p_cli = ecore_cxt_set_cli(&p_mngr->clients[ILT_CLI_TM]);
        ecore_cxt_tm_iids(p_hwfn, p_mngr, &tm_iids);
        total = tm_iids.pf_cids + tm_iids.pf_tids_total;
        if (total) {
                p_blk = ecore_cxt_set_blk(&p_cli->pf_blks[0]);
                ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line,
                                       total * TM_ELEM_SIZE,
                                       TM_ELEM_SIZE);

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_TM);
                p_cli->pf_total_lines = curr_line - p_blk->start_line;
        }

        /* TM VF */
        total = tm_iids.per_vf_cids + tm_iids.per_vf_tids;
        if (total) {
                p_blk = ecore_cxt_set_blk(&p_cli->vf_blks[0]);
                ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line,
                                       total * TM_ELEM_SIZE,
                                       TM_ELEM_SIZE);

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_TM);

                p_cli->vf_total_lines = curr_line - p_blk->start_line;
                for (i = 1; i < p_mngr->vf_count; i++) {
                        ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                               ILT_CLI_TM);
                }
        }

        /* TSDM (SRQ CONTEXT) */
        total = ecore_cxt_get_srq_count(p_hwfn);

        if (total) {
                p_cli = ecore_cxt_set_cli(&p_mngr->clients[ILT_CLI_TSDM]);
                p_blk = ecore_cxt_set_blk(&p_cli->pf_blks[SRQ_BLK]);
                ecore_ilt_cli_blk_fill(p_cli, p_blk, curr_line,
                                       total * SRQ_CXT_SIZE, SRQ_CXT_SIZE);

                ecore_ilt_cli_adv_line(p_hwfn, p_cli, p_blk, &curr_line,
                                       ILT_CLI_TSDM);
                p_cli->pf_total_lines = curr_line - p_blk->start_line;
        }

        *line_count = curr_line - p_hwfn->p_cxt_mngr->pf_start_line;

        if (curr_line - p_hwfn->p_cxt_mngr->pf_start_line >
            RESC_NUM(p_hwfn, ECORE_ILT)) {
                return ECORE_INVAL;
        }

        return ECORE_SUCCESS;
}

u32 ecore_cxt_cfg_ilt_compute_excess(struct ecore_hwfn *p_hwfn, u32 used_lines)
{
        struct ecore_ilt_client_cfg *p_cli;
        u32 excess_lines, available_lines;
        struct ecore_cxt_mngr *p_mngr;
        u32 ilt_page_size, elem_size;
        struct ecore_tid_seg *p_seg;
        int i;

        available_lines = RESC_NUM(p_hwfn, ECORE_ILT);
        excess_lines = used_lines - available_lines;

        if (!excess_lines)
                return 0;

        if (!ECORE_IS_RDMA_PERSONALITY(p_hwfn))
                return 0;

        p_mngr = p_hwfn->p_cxt_mngr;
        p_cli = &p_mngr->clients[ILT_CLI_CDUT];
        ilt_page_size = ILT_PAGE_IN_BYTES(p_cli->p_size.val);

        for (i = 0; i < NUM_TASK_PF_SEGMENTS; i++) {
                p_seg = ecore_cxt_tid_seg_info(p_hwfn, i);
                if (!p_seg || p_seg->count == 0)
                        continue;

                elem_size = p_mngr->task_type_size[p_seg->type];
                if (!elem_size)
                        continue;

                return (ilt_page_size / elem_size) * excess_lines;
        }

        DP_ERR(p_hwfn, "failed computing excess ILT lines\n");
        return 0;
}

static void ecore_cxt_src_t2_free(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 i;

        if (!p_mngr->t2)
                return;

        for (i = 0; i < p_mngr->t2_num_pages; i++)
                if (p_mngr->t2[i].p_virt)
                        OSAL_DMA_FREE_COHERENT(p_hwfn->p_dev,
                                               p_mngr->t2[i].p_virt,
                                               p_mngr->t2[i].p_phys,
                                               p_mngr->t2[i].size);

        OSAL_FREE(p_hwfn->p_dev, p_mngr->t2);
        p_mngr->t2 = OSAL_NULL;
}

static enum _ecore_status_t ecore_cxt_src_t2_alloc(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr  = p_hwfn->p_cxt_mngr;
        u32 conn_num, total_size, ent_per_page, psz, i;
        struct ecore_ilt_client_cfg *p_src;
        struct ecore_src_iids src_iids;
        struct ecore_dma_mem *p_t2;
        enum _ecore_status_t rc;

        OSAL_MEM_ZERO(&src_iids, sizeof(src_iids));

        /* if the SRC ILT client is inactive - there are no connection
         * requiring the searcer, leave.
         */
        p_src = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_SRC];
        if (!p_src->active)
                return ECORE_SUCCESS;

        ecore_cxt_src_iids(p_hwfn, p_mngr, &src_iids);
        conn_num = src_iids.pf_cids + src_iids.per_vf_cids * p_mngr->vf_count;
        total_size = conn_num * sizeof(struct src_ent);

        /* use the same page size as the SRC ILT client */
        psz = ILT_PAGE_IN_BYTES(p_src->p_size.val);
        p_mngr->t2_num_pages = DIV_ROUND_UP(total_size, psz);

        /* allocate t2 */
        p_mngr->t2 = OSAL_ZALLOC(p_hwfn->p_dev, GFP_KERNEL,
                                 p_mngr->t2_num_pages *
                                 sizeof(struct ecore_dma_mem));
        if (!p_mngr->t2) {
                DP_NOTICE(p_hwfn, true, "Failed to allocate t2 table\n");
                rc = ECORE_NOMEM;
                goto t2_fail;
        }

        /* allocate t2 pages */
        for (i = 0; i < p_mngr->t2_num_pages; i++) {
                u32 size = OSAL_MIN_T(u32, total_size, psz);
                void **p_virt = &p_mngr->t2[i].p_virt;

                *p_virt = OSAL_DMA_ALLOC_COHERENT(p_hwfn->p_dev,
                                                  &p_mngr->t2[i].p_phys,
                                                  size);
                if (!p_mngr->t2[i].p_virt) {
                        rc = ECORE_NOMEM;
                        goto t2_fail;
                }
                OSAL_MEM_ZERO(*p_virt, size);
                p_mngr->t2[i].size = size;
                total_size -= size;
        }

        /* Set the t2 pointers */

        /* entries per page - must be a power of two */
        ent_per_page = psz / sizeof(struct src_ent);

        p_mngr->first_free = (u64)p_mngr->t2[0].p_phys;

        p_t2 = &p_mngr->t2[(conn_num - 1) / ent_per_page];
        p_mngr->last_free = (u64)p_t2->p_phys +
                                 ((conn_num - 1) & (ent_per_page - 1)) *
                                 sizeof(struct src_ent);

        for (i = 0; i < p_mngr->t2_num_pages; i++) {
                u32 ent_num = OSAL_MIN_T(u32, ent_per_page, conn_num);
                struct src_ent *entries = p_mngr->t2[i].p_virt;
                u64 p_ent_phys = (u64)p_mngr->t2[i].p_phys, val;
                u32 j;

                for (j = 0; j < ent_num - 1; j++) {
                        val = p_ent_phys +
                              (j + 1) * sizeof(struct src_ent);
                        entries[j].next = OSAL_CPU_TO_BE64(val);
                }

                if (i < p_mngr->t2_num_pages - 1)
                        val = (u64)p_mngr->t2[i + 1].p_phys;
                else
                        val = 0;
                entries[j].next = OSAL_CPU_TO_BE64(val);

                conn_num -= ent_num;
        }

        return ECORE_SUCCESS;

t2_fail:
        ecore_cxt_src_t2_free(p_hwfn);
        return rc;
}

#define for_each_ilt_valid_client(pos, clients) \
        for (pos = 0; pos < ILT_CLI_MAX; pos++) \
                if (!clients[pos].active) {     \
                        continue;               \
                } else                          \


/* Total number of ILT lines used by this PF */
static u32 ecore_cxt_ilt_shadow_size(struct ecore_ilt_client_cfg *ilt_clients)
{
        u32 size = 0;
        u32 i;

        for_each_ilt_valid_client(i, ilt_clients)
                size += (ilt_clients[i].last.val -
                         ilt_clients[i].first.val + 1);

        return size;
}

static void ecore_ilt_shadow_free(struct ecore_hwfn *p_hwfn)
{
        struct ecore_ilt_client_cfg *p_cli = p_hwfn->p_cxt_mngr->clients;
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 ilt_size, i;

        ilt_size = ecore_cxt_ilt_shadow_size(p_cli);

        for (i = 0; p_mngr->ilt_shadow && i < ilt_size; i++) {
                struct ecore_dma_mem *p_dma = &p_mngr->ilt_shadow[i];

                if (p_dma->p_virt)
                        OSAL_DMA_FREE_COHERENT(p_hwfn->p_dev,
                                               p_dma->p_virt,
                                               p_dma->p_phys,
                                               p_dma->size);
                p_dma->p_virt = OSAL_NULL;
        }
        OSAL_FREE(p_hwfn->p_dev, p_mngr->ilt_shadow);
}

static enum _ecore_status_t ecore_ilt_blk_alloc(struct ecore_hwfn *p_hwfn,
                                                struct ecore_ilt_cli_blk *p_blk,
                                                enum ilt_clients ilt_client,
                                                u32 start_line_offset)
{
        struct ecore_dma_mem *ilt_shadow = p_hwfn->p_cxt_mngr->ilt_shadow;
        u32 lines, line, sz_left, lines_to_skip = 0;

        /* Special handling for RoCE that supports dynamic allocation */
        if (ECORE_IS_RDMA_PERSONALITY(p_hwfn) &&
            ((ilt_client == ILT_CLI_CDUT) || ilt_client == ILT_CLI_TSDM))
                return ECORE_SUCCESS;

        lines_to_skip = p_blk->dynamic_line_cnt;

        if (!p_blk->total_size)
                return ECORE_SUCCESS;

        sz_left = p_blk->total_size;
        lines = DIV_ROUND_UP(sz_left, p_blk->real_size_in_page) -
                lines_to_skip;
        line = p_blk->start_line + start_line_offset -
               p_hwfn->p_cxt_mngr->pf_start_line + lines_to_skip;

        for (; lines; lines--) {
                dma_addr_t p_phys;
                void *p_virt;
                u32 size;

                size = OSAL_MIN_T(u32, sz_left, p_blk->real_size_in_page);
                p_virt = OSAL_DMA_ALLOC_COHERENT(p_hwfn->p_dev,
                                                 &p_phys, size);
                if (!p_virt)
                        return ECORE_NOMEM;
                OSAL_MEM_ZERO(p_virt, size);

                ilt_shadow[line].p_phys = p_phys;
                ilt_shadow[line].p_virt = p_virt;
                ilt_shadow[line].size = size;

                DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                           "ILT shadow: Line [%d] Physical 0x%llx Virtual %p Size %d\n",
                           line, (u64)p_phys, p_virt, size);

                sz_left -= size;
                line++;
        }

        return ECORE_SUCCESS;
}

static enum _ecore_status_t ecore_ilt_shadow_alloc(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr  = p_hwfn->p_cxt_mngr;
        struct ecore_ilt_client_cfg *clients = p_mngr->clients;
        struct ecore_ilt_cli_blk *p_blk;
        u32 size, i, j, k;
        enum _ecore_status_t rc;

        size = ecore_cxt_ilt_shadow_size(clients);
        p_mngr->ilt_shadow = OSAL_ZALLOC(p_hwfn->p_dev, GFP_KERNEL,
                                         size * sizeof(struct ecore_dma_mem));

        if (!p_mngr->ilt_shadow) {
                DP_NOTICE(p_hwfn, true, "Failed to allocate ilt shadow table\n");
                rc = ECORE_NOMEM;
                goto ilt_shadow_fail;
        }

        DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                   "Allocated 0x%x bytes for ilt shadow\n",
                   (u32)(size * sizeof(struct ecore_dma_mem)));

        for_each_ilt_valid_client(i, clients) {
                for (j = 0; j < ILT_CLI_PF_BLOCKS; j++) {
                        p_blk = &clients[i].pf_blks[j];
                        rc = ecore_ilt_blk_alloc(p_hwfn, p_blk, i, 0);
                        if (rc != ECORE_SUCCESS)
                                goto ilt_shadow_fail;
                }
                for (k = 0; k < p_mngr->vf_count; k++) {
                        for (j = 0; j < ILT_CLI_VF_BLOCKS; j++) {
                                u32 lines = clients[i].vf_total_lines * k;

                                p_blk = &clients[i].vf_blks[j];
                                rc = ecore_ilt_blk_alloc(p_hwfn, p_blk,
                                                         i, lines);
                                if (rc != ECORE_SUCCESS)
                                        goto ilt_shadow_fail;
                        }
                }
        }

        return ECORE_SUCCESS;

ilt_shadow_fail:
        ecore_ilt_shadow_free(p_hwfn);
        return rc;
}

static void ecore_cid_map_free(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 type, vf;

        for (type = 0; type < MAX_CONN_TYPES; type++) {
                OSAL_FREE(p_hwfn->p_dev, p_mngr->acquired[type].cid_map);
                p_mngr->acquired[type].max_count = 0;
                p_mngr->acquired[type].start_cid = 0;

                for (vf = 0; vf < COMMON_MAX_NUM_VFS; vf++) {
                        OSAL_FREE(p_hwfn->p_dev,
                                  p_mngr->acquired_vf[type][vf].cid_map);
                        p_mngr->acquired_vf[type][vf].max_count = 0;
                        p_mngr->acquired_vf[type][vf].start_cid = 0;
                }
        }
}

static enum _ecore_status_t
ecore_cid_map_alloc_single(struct ecore_hwfn *p_hwfn, u32 type,
                           u32 cid_start, u32 cid_count,
                           struct ecore_cid_acquired_map *p_map)
{
        u32 size;

        if (!cid_count)
                return ECORE_SUCCESS;

        size = MAP_WORD_SIZE * DIV_ROUND_UP(cid_count, BITS_PER_MAP_WORD);
        p_map->cid_map = OSAL_ZALLOC(p_hwfn->p_dev, GFP_KERNEL, size);
        if (p_map->cid_map == OSAL_NULL)
                return ECORE_NOMEM;

        p_map->max_count = cid_count;
        p_map->start_cid = cid_start;

        DP_VERBOSE(p_hwfn, ECORE_MSG_CXT,
                   "Type %08x start: %08x count %08x\n",
                   type, p_map->start_cid, p_map->max_count);

        return ECORE_SUCCESS;
}

static enum _ecore_status_t ecore_cid_map_alloc(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 start_cid = 0, vf_start_cid = 0;
        u32 type, vf;

        for (type = 0; type < MAX_CONN_TYPES; type++) {
                struct ecore_conn_type_cfg *p_cfg = &p_mngr->conn_cfg[type];
                struct ecore_cid_acquired_map *p_map;

                /* Handle PF maps */
                p_map = &p_mngr->acquired[type];
                if (ecore_cid_map_alloc_single(p_hwfn, type, start_cid,
                                               p_cfg->cid_count, p_map))
                        goto cid_map_fail;

                /* Handle VF maps */
                for (vf = 0; vf < COMMON_MAX_NUM_VFS; vf++) {
                        p_map = &p_mngr->acquired_vf[type][vf];
                        if (ecore_cid_map_alloc_single(p_hwfn, type,
                                                       vf_start_cid,
                                                       p_cfg->cids_per_vf,
                                                       p_map))
                                goto cid_map_fail;
                }

                start_cid += p_cfg->cid_count;
                vf_start_cid += p_cfg->cids_per_vf;
        }

        return ECORE_SUCCESS;

cid_map_fail:
        ecore_cid_map_free(p_hwfn);
        return ECORE_NOMEM;
}

enum _ecore_status_t ecore_cxt_mngr_alloc(struct ecore_hwfn *p_hwfn)
{
        struct ecore_ilt_client_cfg *clients;
        struct ecore_cxt_mngr *p_mngr;
        u32 i;

        p_mngr = OSAL_ZALLOC(p_hwfn->p_dev, GFP_KERNEL, sizeof(*p_mngr));
        if (!p_mngr) {
                DP_NOTICE(p_hwfn, true, "Failed to allocate `struct ecore_cxt_mngr'\n");
                return ECORE_NOMEM;
        }

        /* Initialize ILT client registers */
        clients = p_mngr->clients;
        clients[ILT_CLI_CDUC].first.reg = ILT_CFG_REG(CDUC, FIRST_ILT);
        clients[ILT_CLI_CDUC].last.reg  = ILT_CFG_REG(CDUC, LAST_ILT);
        clients[ILT_CLI_CDUC].p_size.reg = ILT_CFG_REG(CDUC, P_SIZE);

        clients[ILT_CLI_QM].first.reg   = ILT_CFG_REG(QM, FIRST_ILT);
        clients[ILT_CLI_QM].last.reg    = ILT_CFG_REG(QM, LAST_ILT);
        clients[ILT_CLI_QM].p_size.reg  = ILT_CFG_REG(QM, P_SIZE);

        clients[ILT_CLI_TM].first.reg   = ILT_CFG_REG(TM, FIRST_ILT);
        clients[ILT_CLI_TM].last.reg    = ILT_CFG_REG(TM, LAST_ILT);
        clients[ILT_CLI_TM].p_size.reg  = ILT_CFG_REG(TM, P_SIZE);

        clients[ILT_CLI_SRC].first.reg  = ILT_CFG_REG(SRC, FIRST_ILT);
        clients[ILT_CLI_SRC].last.reg   = ILT_CFG_REG(SRC, LAST_ILT);
        clients[ILT_CLI_SRC].p_size.reg = ILT_CFG_REG(SRC, P_SIZE);

        clients[ILT_CLI_CDUT].first.reg = ILT_CFG_REG(CDUT, FIRST_ILT);
        clients[ILT_CLI_CDUT].last.reg  = ILT_CFG_REG(CDUT, LAST_ILT);
        clients[ILT_CLI_CDUT].p_size.reg = ILT_CFG_REG(CDUT, P_SIZE);

        clients[ILT_CLI_TSDM].first.reg = ILT_CFG_REG(TSDM, FIRST_ILT);
        clients[ILT_CLI_TSDM].last.reg  = ILT_CFG_REG(TSDM, LAST_ILT);
        clients[ILT_CLI_TSDM].p_size.reg = ILT_CFG_REG(TSDM, P_SIZE);

        /* default ILT page size for all clients is 32K */
        for (i = 0; i < ILT_CLI_MAX; i++)
                p_mngr->clients[i].p_size.val = ILT_DEFAULT_HW_P_SIZE;

        /* Initialize task sizes */
        p_mngr->task_type_size[0] = TYPE0_TASK_CXT_SIZE(p_hwfn);
        p_mngr->task_type_size[1] = TYPE1_TASK_CXT_SIZE(p_hwfn);

        if (p_hwfn->p_dev->p_iov_info)
                p_mngr->vf_count = p_hwfn->p_dev->p_iov_info->total_vfs;

        /* Initialize the dynamic ILT allocation mutex */
        OSAL_MUTEX_ALLOC(p_hwfn, &p_mngr->mutex);
        OSAL_MUTEX_INIT(&p_mngr->mutex);

        /* Set the cxt mangr pointer priori to further allocations */
        p_hwfn->p_cxt_mngr = p_mngr;

        return ECORE_SUCCESS;
}

enum _ecore_status_t ecore_cxt_tables_alloc(struct ecore_hwfn *p_hwfn)
{
        enum _ecore_status_t    rc;

        /* Allocate the ILT shadow table */
        rc = ecore_ilt_shadow_alloc(p_hwfn);
        if (rc) {
                DP_NOTICE(p_hwfn, true, "Failed to allocate ilt memory\n");
                goto tables_alloc_fail;
        }

        /* Allocate the T2  table */
        rc = ecore_cxt_src_t2_alloc(p_hwfn);
        if (rc) {
                DP_NOTICE(p_hwfn, true, "Failed to allocate T2 memory\n");
                goto tables_alloc_fail;
        }

        /* Allocate and initalize the acquired cids bitmaps */
        rc = ecore_cid_map_alloc(p_hwfn);
        if (rc) {
                DP_NOTICE(p_hwfn, true, "Failed to allocate cid maps\n");
                goto tables_alloc_fail;
        }

        return ECORE_SUCCESS;

tables_alloc_fail:
        ecore_cxt_mngr_free(p_hwfn);
        return rc;
}
void ecore_cxt_mngr_free(struct ecore_hwfn *p_hwfn)
{
        if (!p_hwfn->p_cxt_mngr)
                return;

        ecore_cid_map_free(p_hwfn);
        ecore_cxt_src_t2_free(p_hwfn);
        ecore_ilt_shadow_free(p_hwfn);
        OSAL_MUTEX_DEALLOC(&p_hwfn->p_cxt_mngr->mutex);
        OSAL_FREE(p_hwfn->p_dev, p_hwfn->p_cxt_mngr);

        p_hwfn->p_cxt_mngr = OSAL_NULL;
}

void ecore_cxt_mngr_setup(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_cid_acquired_map *p_map;
        struct ecore_conn_type_cfg *p_cfg;
        int type;
        u32 len;

        /* Reset acquired cids */
        for (type = 0; type < MAX_CONN_TYPES; type++) {
                u32 vf;

                p_cfg = &p_mngr->conn_cfg[type];
                if (p_cfg->cid_count) {
                        p_map = &p_mngr->acquired[type];
                        len = DIV_ROUND_UP(p_map->max_count,
                                           BITS_PER_MAP_WORD) *
                              MAP_WORD_SIZE;
                        OSAL_MEM_ZERO(p_map->cid_map, len);
                }

                if (!p_cfg->cids_per_vf)
                        continue;

                for (vf = 0; vf < COMMON_MAX_NUM_VFS; vf++) {
                        p_map = &p_mngr->acquired_vf[type][vf];
                        len = DIV_ROUND_UP(p_map->max_count,
                                           BITS_PER_MAP_WORD) *
                              MAP_WORD_SIZE;
                        OSAL_MEM_ZERO(p_map->cid_map, len);
                }
        }
}

/* HW initialization helper (per Block, per phase) */

/* CDU Common */
#define CDUC_CXT_SIZE_SHIFT                                             \
        CDU_REG_CID_ADDR_PARAMS_CONTEXT_SIZE_SHIFT

#define CDUC_CXT_SIZE_MASK                                              \
        (CDU_REG_CID_ADDR_PARAMS_CONTEXT_SIZE >> CDUC_CXT_SIZE_SHIFT)

#define CDUC_BLOCK_WASTE_SHIFT                                          \
        CDU_REG_CID_ADDR_PARAMS_BLOCK_WASTE_SHIFT

#define CDUC_BLOCK_WASTE_MASK                                           \
        (CDU_REG_CID_ADDR_PARAMS_BLOCK_WASTE >> CDUC_BLOCK_WASTE_SHIFT)

#define CDUC_NCIB_SHIFT                                                 \
        CDU_REG_CID_ADDR_PARAMS_NCIB_SHIFT

#define CDUC_NCIB_MASK                                                  \
        (CDU_REG_CID_ADDR_PARAMS_NCIB >> CDUC_NCIB_SHIFT)

#define CDUT_TYPE0_CXT_SIZE_SHIFT                                       \
        CDU_REG_SEGMENT0_PARAMS_T0_TID_SIZE_SHIFT

#define CDUT_TYPE0_CXT_SIZE_MASK                                        \
        (CDU_REG_SEGMENT0_PARAMS_T0_TID_SIZE >>                         \
        CDUT_TYPE0_CXT_SIZE_SHIFT)

#define CDUT_TYPE0_BLOCK_WASTE_SHIFT                                    \
        CDU_REG_SEGMENT0_PARAMS_T0_TID_BLOCK_WASTE_SHIFT

#define CDUT_TYPE0_BLOCK_WASTE_MASK                                     \
        (CDU_REG_SEGMENT0_PARAMS_T0_TID_BLOCK_WASTE >>                  \
        CDUT_TYPE0_BLOCK_WASTE_SHIFT)

#define CDUT_TYPE0_NCIB_SHIFT                                           \
        CDU_REG_SEGMENT0_PARAMS_T0_NUM_TIDS_IN_BLOCK_SHIFT

#define CDUT_TYPE0_NCIB_MASK                                            \
        (CDU_REG_SEGMENT0_PARAMS_T0_NUM_TIDS_IN_BLOCK >>                \
        CDUT_TYPE0_NCIB_SHIFT)

#define CDUT_TYPE1_CXT_SIZE_SHIFT                                       \
        CDU_REG_SEGMENT1_PARAMS_T1_TID_SIZE_SHIFT

#define CDUT_TYPE1_CXT_SIZE_MASK                                        \
        (CDU_REG_SEGMENT1_PARAMS_T1_TID_SIZE >>                         \
        CDUT_TYPE1_CXT_SIZE_SHIFT)

#define CDUT_TYPE1_BLOCK_WASTE_SHIFT                                    \
        CDU_REG_SEGMENT1_PARAMS_T1_TID_BLOCK_WASTE_SHIFT

#define CDUT_TYPE1_BLOCK_WASTE_MASK                                     \
        (CDU_REG_SEGMENT1_PARAMS_T1_TID_BLOCK_WASTE >>                  \
        CDUT_TYPE1_BLOCK_WASTE_SHIFT)

#define CDUT_TYPE1_NCIB_SHIFT                                           \
        CDU_REG_SEGMENT1_PARAMS_T1_NUM_TIDS_IN_BLOCK_SHIFT

#define CDUT_TYPE1_NCIB_MASK                                            \
        (CDU_REG_SEGMENT1_PARAMS_T1_NUM_TIDS_IN_BLOCK >>                \
        CDUT_TYPE1_NCIB_SHIFT)

static void ecore_cdu_init_common(struct ecore_hwfn *p_hwfn)
{
        u32 page_sz, elems_per_page, block_waste,  cxt_size, cdu_params = 0;

        /* CDUC - connection configuration */
        page_sz = p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUC].p_size.val;
        cxt_size = CONN_CXT_SIZE(p_hwfn);
        elems_per_page = ILT_PAGE_IN_BYTES(page_sz) / cxt_size;
        block_waste = ILT_PAGE_IN_BYTES(page_sz) - elems_per_page * cxt_size;

        SET_FIELD(cdu_params, CDUC_CXT_SIZE, cxt_size);
        SET_FIELD(cdu_params, CDUC_BLOCK_WASTE, block_waste);
        SET_FIELD(cdu_params, CDUC_NCIB, elems_per_page);
        STORE_RT_REG(p_hwfn, CDU_REG_CID_ADDR_PARAMS_RT_OFFSET, cdu_params);

        /* CDUT - type-0 tasks configuration */
        page_sz = p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUT].p_size.val;
        cxt_size = p_hwfn->p_cxt_mngr->task_type_size[0];
        elems_per_page = ILT_PAGE_IN_BYTES(page_sz) / cxt_size;
        block_waste = ILT_PAGE_IN_BYTES(page_sz) - elems_per_page * cxt_size;

        /* cxt size and block-waste are multipes of 8 */
        cdu_params = 0;
        SET_FIELD(cdu_params, CDUT_TYPE0_CXT_SIZE, (cxt_size >> 3));
        SET_FIELD(cdu_params, CDUT_TYPE0_BLOCK_WASTE, (block_waste >> 3));
        SET_FIELD(cdu_params, CDUT_TYPE0_NCIB, elems_per_page);
        STORE_RT_REG(p_hwfn, CDU_REG_SEGMENT0_PARAMS_RT_OFFSET, cdu_params);

        /* CDUT - type-1 tasks configuration */
        cxt_size = p_hwfn->p_cxt_mngr->task_type_size[1];
        elems_per_page = ILT_PAGE_IN_BYTES(page_sz) / cxt_size;
        block_waste = ILT_PAGE_IN_BYTES(page_sz) - elems_per_page * cxt_size;

        /* cxt size and block-waste are multipes of 8 */
        cdu_params = 0;
        SET_FIELD(cdu_params, CDUT_TYPE1_CXT_SIZE, (cxt_size >> 3));
        SET_FIELD(cdu_params, CDUT_TYPE1_BLOCK_WASTE, (block_waste >> 3));
        SET_FIELD(cdu_params, CDUT_TYPE1_NCIB, elems_per_page);
        STORE_RT_REG(p_hwfn, CDU_REG_SEGMENT1_PARAMS_RT_OFFSET, cdu_params);
}

/* CDU PF */
#define CDU_SEG_REG_TYPE_SHIFT          CDU_SEG_TYPE_OFFSET_REG_TYPE_SHIFT
#define CDU_SEG_REG_TYPE_MASK           0x1
#define CDU_SEG_REG_OFFSET_SHIFT        0
#define CDU_SEG_REG_OFFSET_MASK         CDU_SEG_TYPE_OFFSET_REG_OFFSET_MASK

static void ecore_cdu_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_ilt_client_cfg *p_cli;
        struct ecore_tid_seg *p_seg;
        u32 cdu_seg_params, offset;
        int i;

        static const u32 rt_type_offset_arr[] = {
                CDU_REG_PF_SEG0_TYPE_OFFSET_RT_OFFSET,
                CDU_REG_PF_SEG1_TYPE_OFFSET_RT_OFFSET,
                CDU_REG_PF_SEG2_TYPE_OFFSET_RT_OFFSET,
                CDU_REG_PF_SEG3_TYPE_OFFSET_RT_OFFSET
        };

        static const u32 rt_type_offset_fl_arr[] = {
                CDU_REG_PF_FL_SEG0_TYPE_OFFSET_RT_OFFSET,
                CDU_REG_PF_FL_SEG1_TYPE_OFFSET_RT_OFFSET,
                CDU_REG_PF_FL_SEG2_TYPE_OFFSET_RT_OFFSET,
                CDU_REG_PF_FL_SEG3_TYPE_OFFSET_RT_OFFSET
        };

        p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUT];

        /* There are initializations only for CDUT during pf Phase */
        for (i = 0; i < NUM_TASK_PF_SEGMENTS; i++) {
                /* Segment 0*/
                p_seg = ecore_cxt_tid_seg_info(p_hwfn, i);
                if (!p_seg)
                        continue;

                /* Note: start_line is already adjusted for the CDU
                 * segment register granularity, so we just need to
                 * divide. Adjustment is implicit as we assume ILT
                 * Page size is larger than 32K!
                 */
                offset = (ILT_PAGE_IN_BYTES(p_cli->p_size.val) *
                         (p_cli->pf_blks[CDUT_SEG_BLK(i)].start_line -
                          p_cli->first.val)) / CDUT_SEG_ALIGNMET_IN_BYTES;

                cdu_seg_params = 0;
                SET_FIELD(cdu_seg_params, CDU_SEG_REG_TYPE, p_seg->type);
                SET_FIELD(cdu_seg_params, CDU_SEG_REG_OFFSET, offset);
                STORE_RT_REG(p_hwfn, rt_type_offset_arr[i],
                             cdu_seg_params);

                offset = (ILT_PAGE_IN_BYTES(p_cli->p_size.val) *
                         (p_cli->pf_blks[CDUT_FL_SEG_BLK(i, PF)].start_line -
                          p_cli->first.val)) / CDUT_SEG_ALIGNMET_IN_BYTES;

                cdu_seg_params = 0;
                SET_FIELD(cdu_seg_params, CDU_SEG_REG_TYPE, p_seg->type);
                SET_FIELD(cdu_seg_params, CDU_SEG_REG_OFFSET, offset);
                STORE_RT_REG(p_hwfn, rt_type_offset_fl_arr[i],
                             cdu_seg_params);

        }
}

void ecore_qm_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_qm_info *qm_info = &p_hwfn->qm_info;
        struct ecore_qm_iids iids;

        OSAL_MEM_ZERO(&iids, sizeof(iids));
        ecore_cxt_qm_iids(p_hwfn, &iids);

        ecore_qm_pf_rt_init(p_hwfn, p_hwfn->p_main_ptt, p_hwfn->port_id,
                            p_hwfn->rel_pf_id, qm_info->max_phys_tcs_per_port,
                            p_hwfn->first_on_engine,
                            iids.cids, iids.vf_cids, iids.tids,
                            qm_info->start_pq,
                            qm_info->num_pqs - qm_info->num_vf_pqs,
                            qm_info->num_vf_pqs,
                            qm_info->start_vport,
                            qm_info->num_vports, qm_info->pf_wfq, qm_info->pf_rl,
                            p_hwfn->qm_info.qm_pq_params,
                            p_hwfn->qm_info.qm_vport_params);
}

/* CM PF */
void ecore_cm_init_pf(struct ecore_hwfn *p_hwfn)
{
        STORE_RT_REG(p_hwfn, XCM_REG_CON_PHY_Q3_RT_OFFSET, ecore_get_cm_pq_idx(p_hwfn, PQ_FLAGS_LB));
}

/* DQ PF */
static void ecore_dq_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 dq_pf_max_cid = 0, dq_vf_max_cid = 0;

        dq_pf_max_cid += (p_mngr->conn_cfg[0].cid_count >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_0_RT_OFFSET, dq_pf_max_cid);

        dq_vf_max_cid += (p_mngr->conn_cfg[0].cids_per_vf >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_0_RT_OFFSET, dq_vf_max_cid);

        dq_pf_max_cid += (p_mngr->conn_cfg[1].cid_count >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_1_RT_OFFSET, dq_pf_max_cid);

        dq_vf_max_cid += (p_mngr->conn_cfg[1].cids_per_vf >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_1_RT_OFFSET, dq_vf_max_cid);

        dq_pf_max_cid += (p_mngr->conn_cfg[2].cid_count >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_2_RT_OFFSET, dq_pf_max_cid);

        dq_vf_max_cid += (p_mngr->conn_cfg[2].cids_per_vf >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_2_RT_OFFSET, dq_vf_max_cid);

        dq_pf_max_cid += (p_mngr->conn_cfg[3].cid_count >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_3_RT_OFFSET, dq_pf_max_cid);

        dq_vf_max_cid += (p_mngr->conn_cfg[3].cids_per_vf >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_3_RT_OFFSET, dq_vf_max_cid);

        dq_pf_max_cid += (p_mngr->conn_cfg[4].cid_count >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_4_RT_OFFSET, dq_pf_max_cid);

        dq_vf_max_cid += (p_mngr->conn_cfg[4].cids_per_vf >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_4_RT_OFFSET, dq_vf_max_cid);

        dq_pf_max_cid += (p_mngr->conn_cfg[5].cid_count >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_5_RT_OFFSET, dq_pf_max_cid);

        dq_vf_max_cid += (p_mngr->conn_cfg[5].cids_per_vf >> DQ_RANGE_SHIFT);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_5_RT_OFFSET, dq_vf_max_cid);

        /* Connection types 6 & 7 are not in use, yet they must be configured
         * as the highest possible connection. Not configuring them means the
         * defaults will be  used, and with a large number of cids a bug may
         * occur, if the defaults will be smaller than dq_pf_max_cid /
         * dq_vf_max_cid.
         */
        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_6_RT_OFFSET, dq_pf_max_cid);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_6_RT_OFFSET, dq_vf_max_cid);

        STORE_RT_REG(p_hwfn, DORQ_REG_PF_MAX_ICID_7_RT_OFFSET, dq_pf_max_cid);
        STORE_RT_REG(p_hwfn, DORQ_REG_VF_MAX_ICID_7_RT_OFFSET, dq_vf_max_cid);
}

static void ecore_ilt_bounds_init(struct ecore_hwfn *p_hwfn)
{
        struct ecore_ilt_client_cfg *ilt_clients;
        int i;

        ilt_clients = p_hwfn->p_cxt_mngr->clients;
        for_each_ilt_valid_client(i, ilt_clients) {
                STORE_RT_REG(p_hwfn,
                             ilt_clients[i].first.reg,
                             ilt_clients[i].first.val);
                STORE_RT_REG(p_hwfn,
                             ilt_clients[i].last.reg,
                             ilt_clients[i].last.val);
                STORE_RT_REG(p_hwfn,
                             ilt_clients[i].p_size.reg,
                             ilt_clients[i].p_size.val);
        }
}

static void ecore_ilt_vf_bounds_init(struct ecore_hwfn *p_hwfn)
{
        struct ecore_ilt_client_cfg *p_cli;
        u32 blk_factor;

        /* For simplicty  we set the 'block' to be an ILT page */
        if (p_hwfn->p_dev->p_iov_info) {
                struct ecore_hw_sriov_info *p_iov = p_hwfn->p_dev->p_iov_info;

                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_VF_BASE_RT_OFFSET,
                             p_iov->first_vf_in_pf);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_VF_LAST_ILT_RT_OFFSET,
                             p_iov->first_vf_in_pf + p_iov->total_vfs);
        }

        p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUC];
        blk_factor = OSAL_LOG2(ILT_PAGE_IN_BYTES(p_cli->p_size.val) >> 10);
        if (p_cli->active) {
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_CDUC_BLOCKS_FACTOR_RT_OFFSET,
                             blk_factor);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_CDUC_NUMBER_OF_PF_BLOCKS_RT_OFFSET,
                             p_cli->pf_total_lines);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_CDUC_VF_BLOCKS_RT_OFFSET,
                             p_cli->vf_total_lines);
        }

        p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUT];
        blk_factor = OSAL_LOG2(ILT_PAGE_IN_BYTES(p_cli->p_size.val) >> 10);
        if (p_cli->active) {
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_CDUT_BLOCKS_FACTOR_RT_OFFSET,
                             blk_factor);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_CDUT_NUMBER_OF_PF_BLOCKS_RT_OFFSET,
                             p_cli->pf_total_lines);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_CDUT_VF_BLOCKS_RT_OFFSET,
                             p_cli->vf_total_lines);
        }

        p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_TM];
        blk_factor = OSAL_LOG2(ILT_PAGE_IN_BYTES(p_cli->p_size.val) >> 10);
        if (p_cli->active) {
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_TM_BLOCKS_FACTOR_RT_OFFSET,
                             blk_factor);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_TM_NUMBER_OF_PF_BLOCKS_RT_OFFSET,
                             p_cli->pf_total_lines);
                STORE_RT_REG(p_hwfn,
                             PSWRQ2_REG_TM_VF_BLOCKS_RT_OFFSET,
                             p_cli->vf_total_lines);
        }
}

/* ILT (PSWRQ2) PF */
static void ecore_ilt_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_ilt_client_cfg *clients;
        struct ecore_cxt_mngr *p_mngr;
        struct ecore_dma_mem *p_shdw;
        u32 line, rt_offst, i;

        ecore_ilt_bounds_init(p_hwfn);
        ecore_ilt_vf_bounds_init(p_hwfn);

        p_mngr  = p_hwfn->p_cxt_mngr;
        p_shdw  = p_mngr->ilt_shadow;
        clients = p_hwfn->p_cxt_mngr->clients;

        for_each_ilt_valid_client(i, clients) {
                /* Client's 1st val and RT array are absolute, ILT shadows'
                 * lines are relative.
                 */
                line = clients[i].first.val - p_mngr->pf_start_line;
                rt_offst = PSWRQ2_REG_ILT_MEMORY_RT_OFFSET +
                           clients[i].first.val * ILT_ENTRY_IN_REGS;

                for (; line <= clients[i].last.val - p_mngr->pf_start_line;
                     line++, rt_offst += ILT_ENTRY_IN_REGS) {
                        u64 ilt_hw_entry = 0;

                        /** p_virt could be OSAL_NULL incase of dynamic
                         *  allocation
                         */
                        if (p_shdw[line].p_virt != OSAL_NULL) {
                                SET_FIELD(ilt_hw_entry, ILT_ENTRY_VALID, 1ULL);
                                SET_FIELD(ilt_hw_entry, ILT_ENTRY_PHY_ADDR,
                                          (p_shdw[line].p_phys >> 12));

                                DP_VERBOSE(
                                        p_hwfn, ECORE_MSG_ILT,
                                        "Setting RT[0x%08x] from ILT[0x%08x] [Client is %d] to Physical addr: 0x%llx\n",
                                        rt_offst, line, i,
                                        (u64)(p_shdw[line].p_phys >> 12));
                        }

                        STORE_RT_REG_AGG(p_hwfn, rt_offst, ilt_hw_entry);
                }
        }
}

/* SRC (Searcher) PF */
static void ecore_src_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 rounded_conn_num, conn_num, conn_max;
        struct ecore_src_iids src_iids;

        OSAL_MEM_ZERO(&src_iids, sizeof(src_iids));
        ecore_cxt_src_iids(p_hwfn, p_mngr, &src_iids);
        conn_num = src_iids.pf_cids + src_iids.per_vf_cids * p_mngr->vf_count;
        if (!conn_num)
                return;

        conn_max = OSAL_MAX_T(u32, conn_num, SRC_MIN_NUM_ELEMS);
        rounded_conn_num = OSAL_ROUNDUP_POW_OF_TWO(conn_max);

        STORE_RT_REG(p_hwfn, SRC_REG_COUNTFREE_RT_OFFSET, conn_num);
        STORE_RT_REG(p_hwfn, SRC_REG_NUMBER_HASH_BITS_RT_OFFSET,
                     OSAL_LOG2(rounded_conn_num));

        STORE_RT_REG_AGG(p_hwfn, SRC_REG_FIRSTFREE_RT_OFFSET,
                         p_hwfn->p_cxt_mngr->first_free);
        STORE_RT_REG_AGG(p_hwfn, SRC_REG_LASTFREE_RT_OFFSET,
                         p_hwfn->p_cxt_mngr->last_free);
        DP_VERBOSE(p_hwfn, ECORE_MSG_ILT,
                   "Configured SEARCHER for 0x%08x connections\n",
                   conn_num);
}

/* Timers PF */
#define TM_CFG_NUM_IDS_SHIFT            0
#define TM_CFG_NUM_IDS_MASK             0xFFFFULL
#define TM_CFG_PRE_SCAN_OFFSET_SHIFT    16
#define TM_CFG_PRE_SCAN_OFFSET_MASK     0x1FFULL
#define TM_CFG_PARENT_PF_SHIFT          25
#define TM_CFG_PARENT_PF_MASK           0x7ULL

#define TM_CFG_CID_PRE_SCAN_ROWS_SHIFT  30
#define TM_CFG_CID_PRE_SCAN_ROWS_MASK   0x1FFULL

#define TM_CFG_TID_OFFSET_SHIFT         30
#define TM_CFG_TID_OFFSET_MASK          0x7FFFFULL
#define TM_CFG_TID_PRE_SCAN_ROWS_SHIFT  49
#define TM_CFG_TID_PRE_SCAN_ROWS_MASK   0x1FFULL

static void ecore_tm_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 active_seg_mask = 0, tm_offset, rt_reg;
        struct ecore_tm_iids tm_iids;
        u64 cfg_word;
        u8 i;

        OSAL_MEM_ZERO(&tm_iids, sizeof(tm_iids));
        ecore_cxt_tm_iids(p_hwfn, p_mngr, &tm_iids);

        /* @@@TBD No pre-scan for now */

        /* Note: We assume consecutive VFs for a PF */
        for (i = 0; i < p_mngr->vf_count; i++) {
                cfg_word = 0;
                SET_FIELD(cfg_word, TM_CFG_NUM_IDS, tm_iids.per_vf_cids);
                SET_FIELD(cfg_word, TM_CFG_PRE_SCAN_OFFSET, 0);
                SET_FIELD(cfg_word, TM_CFG_PARENT_PF, p_hwfn->rel_pf_id);
                SET_FIELD(cfg_word, TM_CFG_CID_PRE_SCAN_ROWS, 0); /* scan all */

                rt_reg = TM_REG_CONFIG_CONN_MEM_RT_OFFSET +
                         (sizeof(cfg_word) / sizeof(u32)) *
                         (p_hwfn->p_dev->p_iov_info->first_vf_in_pf + i);
                STORE_RT_REG_AGG(p_hwfn, rt_reg, cfg_word);
        }

        cfg_word = 0;
        SET_FIELD(cfg_word, TM_CFG_NUM_IDS, tm_iids.pf_cids);
        SET_FIELD(cfg_word, TM_CFG_PRE_SCAN_OFFSET, 0);
        SET_FIELD(cfg_word, TM_CFG_PARENT_PF, 0);         /* n/a for PF */
        SET_FIELD(cfg_word, TM_CFG_CID_PRE_SCAN_ROWS, 0); /* scan all   */

        rt_reg = TM_REG_CONFIG_CONN_MEM_RT_OFFSET +
                 (sizeof(cfg_word) / sizeof(u32)) *
                 (NUM_OF_VFS(p_hwfn->p_dev) + p_hwfn->rel_pf_id);
        STORE_RT_REG_AGG(p_hwfn, rt_reg, cfg_word);

        /* enale scan */
        STORE_RT_REG(p_hwfn, TM_REG_PF_ENABLE_CONN_RT_OFFSET,
                     tm_iids.pf_cids  ? 0x1 : 0x0);

        /* @@@TBD how to enable the scan for the VFs */

        tm_offset = tm_iids.per_vf_cids;

        /* Note: We assume consecutive VFs for a PF */
        for (i = 0; i < p_mngr->vf_count; i++) {
                cfg_word = 0;
                SET_FIELD(cfg_word, TM_CFG_NUM_IDS, tm_iids.per_vf_tids);
                SET_FIELD(cfg_word, TM_CFG_PRE_SCAN_OFFSET, 0);
                SET_FIELD(cfg_word, TM_CFG_PARENT_PF, p_hwfn->rel_pf_id);
                SET_FIELD(cfg_word, TM_CFG_TID_OFFSET, tm_offset);
                SET_FIELD(cfg_word, TM_CFG_TID_PRE_SCAN_ROWS, (u64)0);

                rt_reg = TM_REG_CONFIG_TASK_MEM_RT_OFFSET +
                         (sizeof(cfg_word) / sizeof(u32)) *
                         (p_hwfn->p_dev->p_iov_info->first_vf_in_pf + i);

                STORE_RT_REG_AGG(p_hwfn, rt_reg, cfg_word);
        }

        tm_offset = tm_iids.pf_cids;
        for (i = 0; i < NUM_TASK_PF_SEGMENTS; i++) {
                cfg_word = 0;
                SET_FIELD(cfg_word, TM_CFG_NUM_IDS, tm_iids.pf_tids[i]);
                SET_FIELD(cfg_word, TM_CFG_PRE_SCAN_OFFSET, 0);
                SET_FIELD(cfg_word, TM_CFG_PARENT_PF, 0);
                SET_FIELD(cfg_word, TM_CFG_TID_OFFSET, tm_offset);
                SET_FIELD(cfg_word, TM_CFG_TID_PRE_SCAN_ROWS, (u64)0);

                rt_reg = TM_REG_CONFIG_TASK_MEM_RT_OFFSET +
                         (sizeof(cfg_word) / sizeof(u32)) *
                         (NUM_OF_VFS(p_hwfn->p_dev) +
                         p_hwfn->rel_pf_id * NUM_TASK_PF_SEGMENTS + i);

                STORE_RT_REG_AGG(p_hwfn, rt_reg, cfg_word);
                active_seg_mask |= (tm_iids.pf_tids[i] ? (1 << i) : 0);

                tm_offset += tm_iids.pf_tids[i];
        }

        if (ECORE_IS_RDMA_PERSONALITY(p_hwfn))
                active_seg_mask = 0;

        STORE_RT_REG(p_hwfn, TM_REG_PF_ENABLE_TASK_RT_OFFSET, active_seg_mask);

        /* @@@TBD how to enable the scan for the VFs */
}

static void ecore_prs_init_common(struct ecore_hwfn *p_hwfn)
{
        if ((p_hwfn->hw_info.personality == ECORE_PCI_FCOE) &&
            p_hwfn->pf_params.fcoe_pf_params.is_target)
                STORE_RT_REG(p_hwfn, PRS_REG_SEARCH_RESP_INITIATOR_TYPE_RT_OFFSET, 0);
}

static void ecore_prs_init_pf(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_conn_type_cfg *p_fcoe = &p_mngr->conn_cfg[PROTOCOLID_FCOE];
        struct ecore_tid_seg *p_tid;

        /* If FCoE is active set the MAX OX_ID (tid) in the Parser */
        if (!p_fcoe->cid_count)
                return;

        p_tid = &p_fcoe->tid_seg[ECORE_CXT_FCOE_TID_SEG];
        if (p_hwfn->pf_params.fcoe_pf_params.is_target) {
                STORE_RT_REG_AGG(p_hwfn,
                                 PRS_REG_TASK_ID_MAX_TARGET_PF_RT_OFFSET,
                                 p_tid->count);
        } else {
                STORE_RT_REG_AGG(p_hwfn,
                                PRS_REG_TASK_ID_MAX_INITIATOR_PF_RT_OFFSET,
                                p_tid->count);
        }
}

void ecore_cxt_hw_init_common(struct ecore_hwfn *p_hwfn)
{
        /* CDU configuration */
        ecore_cdu_init_common(p_hwfn);
        ecore_prs_init_common(p_hwfn);
}

void ecore_cxt_hw_init_pf(struct ecore_hwfn *p_hwfn)
{
        ecore_qm_init_pf(p_hwfn);
        ecore_cm_init_pf(p_hwfn);
        ecore_dq_init_pf(p_hwfn);
        ecore_cdu_init_pf(p_hwfn);
        ecore_ilt_init_pf(p_hwfn);
        ecore_src_init_pf(p_hwfn);
        ecore_tm_init_pf(p_hwfn);
        ecore_prs_init_pf(p_hwfn);
}

enum _ecore_status_t _ecore_cxt_acquire_cid(struct ecore_hwfn *p_hwfn,
                                            enum protocol_type type,
                                            u32 *p_cid, u8 vfid)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_cid_acquired_map *p_map;
        u32 rel_cid;

        if (type >= MAX_CONN_TYPES) {
                DP_NOTICE(p_hwfn, true, "Invalid protocol type %d", type);
                return ECORE_INVAL;
        }

        if (vfid >= COMMON_MAX_NUM_VFS && vfid != ECORE_CXT_PF_CID) {
                DP_NOTICE(p_hwfn, true, "VF [%02x] is out of range\n", vfid);
                return ECORE_INVAL;
        }

        /* Determine the right map to take this CID from */
        if (vfid == ECORE_CXT_PF_CID)
                p_map = &p_mngr->acquired[type];
        else
                p_map = &p_mngr->acquired_vf[type][vfid];

        if (p_map->cid_map == OSAL_NULL) {
                DP_NOTICE(p_hwfn, true, "Invalid protocol type %d", type);
                return ECORE_INVAL;
        }

        rel_cid = OSAL_FIND_FIRST_ZERO_BIT(p_map->cid_map,
                                           p_map->max_count);

        if (rel_cid >= p_map->max_count) {
                DP_NOTICE(p_hwfn, false, "no CID available for protocol %d\n",
                          type);
                return ECORE_NORESOURCES;
        }

        OSAL_SET_BIT(rel_cid, p_map->cid_map);

        *p_cid = rel_cid + p_map->start_cid;

        DP_VERBOSE(p_hwfn, ECORE_MSG_CXT,
                   "Acquired cid 0x%08x [rel. %08x] vfid %02x type %d\n",
                   *p_cid, rel_cid, vfid, type);

        return ECORE_SUCCESS;
}

enum _ecore_status_t ecore_cxt_acquire_cid(struct ecore_hwfn *p_hwfn,
                                           enum protocol_type type,
                                           u32 *p_cid)
{
        return _ecore_cxt_acquire_cid(p_hwfn, type, p_cid, ECORE_CXT_PF_CID);
}

static bool ecore_cxt_test_cid_acquired(struct ecore_hwfn *p_hwfn,
                                        u32 cid, u8 vfid,
                                        enum protocol_type *p_type,
                                        struct ecore_cid_acquired_map **pp_map)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 rel_cid;

        /* Iterate over protocols and find matching cid range */
        for (*p_type = 0; *p_type < MAX_CONN_TYPES; (*p_type)++) {
                if (vfid == ECORE_CXT_PF_CID)
                        *pp_map = &p_mngr->acquired[*p_type];
                else
                        *pp_map = &p_mngr->acquired_vf[*p_type][vfid];

                if (!((*pp_map)->cid_map))
                        continue;
                if (cid >= (*pp_map)->start_cid &&
                    cid < (*pp_map)->start_cid + (*pp_map)->max_count) {
                        break;
                }
        }

        if (*p_type == MAX_CONN_TYPES) {
                DP_NOTICE(p_hwfn, true, "Invalid CID %d vfid %02x", cid, vfid);
                goto fail;
        }

        rel_cid = cid - (*pp_map)->start_cid;
        if (!OSAL_TEST_BIT(rel_cid, (*pp_map)->cid_map)) {
                DP_NOTICE(p_hwfn, true,
                          "CID %d [vifd %02x] not acquired", cid, vfid);
                goto fail;
        }

        return true;
fail:
        *p_type = MAX_CONN_TYPES;
        *pp_map = OSAL_NULL;
        return false;
}

void _ecore_cxt_release_cid(struct ecore_hwfn *p_hwfn, u32 cid, u8 vfid)
{
        struct ecore_cid_acquired_map *p_map = OSAL_NULL;
        enum protocol_type type;
        bool b_acquired;
        u32 rel_cid;

        if (vfid != ECORE_CXT_PF_CID && vfid > COMMON_MAX_NUM_VFS) {
                DP_NOTICE(p_hwfn, true,
                          "Trying to return incorrect CID belonging to VF %02x\n",
                          vfid);
                return;
        }

        /* Test acquired and find matching per-protocol map */
        b_acquired = ecore_cxt_test_cid_acquired(p_hwfn, cid, vfid,
                                                 &type, &p_map);

        if (!b_acquired)
                return;

        rel_cid = cid - p_map->start_cid;
        OSAL_CLEAR_BIT(rel_cid, p_map->cid_map);

        DP_VERBOSE(p_hwfn, ECORE_MSG_CXT,
                   "Released CID 0x%08x [rel. %08x] vfid %02x type %d\n",
                   cid, rel_cid, vfid, type);
}

void ecore_cxt_release_cid(struct ecore_hwfn *p_hwfn, u32 cid)
{
        _ecore_cxt_release_cid(p_hwfn, cid, ECORE_CXT_PF_CID);
}

enum _ecore_status_t ecore_cxt_get_cid_info(struct ecore_hwfn *p_hwfn,
                                            struct ecore_cxt_info *p_info)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_cid_acquired_map *p_map = OSAL_NULL;
        u32 conn_cxt_size, hw_p_size, cxts_per_p, line;
        enum protocol_type type;
        bool b_acquired;

        /* Test acquired and find matching per-protocol map */
        b_acquired = ecore_cxt_test_cid_acquired(p_hwfn, p_info->iid,
                                                 ECORE_CXT_PF_CID,
                                                 &type, &p_map);

        if (!b_acquired)
                return ECORE_INVAL;

        /* set the protocl type */
        p_info->type = type;

        /* compute context virtual pointer */
        hw_p_size = p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUC].p_size.val;

        conn_cxt_size = CONN_CXT_SIZE(p_hwfn);
        cxts_per_p = ILT_PAGE_IN_BYTES(hw_p_size) / conn_cxt_size;
        line = p_info->iid / cxts_per_p;

        /* Make sure context is allocated (dynamic allocation) */
        if (!p_mngr->ilt_shadow[line].p_virt)
                return ECORE_INVAL;

        p_info->p_cxt = (u8 *)p_mngr->ilt_shadow[line].p_virt +
                              p_info->iid % cxts_per_p * conn_cxt_size;

        DP_VERBOSE(p_hwfn, (ECORE_MSG_ILT | ECORE_MSG_CXT),
                   "Accessing ILT shadow[%d]: CXT pointer is at %p (for iid %d)\n",
                   (p_info->iid / cxts_per_p), p_info->p_cxt, p_info->iid);

        return ECORE_SUCCESS;
}

static void ecore_cxt_set_srq_count(struct ecore_hwfn *p_hwfn, u32 num_srqs)
{
        struct ecore_cxt_mngr *p_mgr = p_hwfn->p_cxt_mngr;

        p_mgr->srq_count = num_srqs;
}

u32 ecore_cxt_get_srq_count(struct ecore_hwfn *p_hwfn)
{
        struct ecore_cxt_mngr *p_mgr = p_hwfn->p_cxt_mngr;

        return p_mgr->srq_count;
}

static void ecore_rdma_set_pf_params(struct ecore_hwfn *p_hwfn,
                                     struct ecore_rdma_pf_params *p_params,
                                     u32 num_tasks)
{
        u32 num_cons, num_qps, num_srqs;
        enum protocol_type proto;

        /* Override personality with rdma flavor */
        num_srqs = OSAL_MIN_T(u32, ECORE_RDMA_MAX_SRQS, p_params->num_srqs);

        /* The only case RDMA personality can be overriden is if NVRAM is
         * configured with ETH_RDMA or if no rdma protocol was requested
         */
        switch (p_params->rdma_protocol) {
        case ECORE_RDMA_PROTOCOL_DEFAULT:
                if (p_hwfn->mcp_info->func_info.protocol ==
                    ECORE_PCI_ETH_RDMA) {
                        DP_NOTICE(p_hwfn, false,
                                  "Current day drivers don't support RoCE & iWARP. Default to RoCE-only\n");
                        p_hwfn->hw_info.personality = ECORE_PCI_ETH_ROCE;
                }
                break;
        case ECORE_RDMA_PROTOCOL_NONE:
                p_hwfn->hw_info.personality = ECORE_PCI_ETH;
                return; /* intentional... nothing left to do... */
        case ECORE_RDMA_PROTOCOL_ROCE:
                if (p_hwfn->mcp_info->func_info.protocol == ECORE_PCI_ETH_RDMA)
                        p_hwfn->hw_info.personality = ECORE_PCI_ETH_ROCE;
                break;
        case ECORE_RDMA_PROTOCOL_IWARP:
                if (p_hwfn->mcp_info->func_info.protocol == ECORE_PCI_ETH_RDMA)
                        p_hwfn->hw_info.personality = ECORE_PCI_ETH_IWARP;
                break;
        }

        switch (p_hwfn->hw_info.personality) {
        case ECORE_PCI_ETH_IWARP:
                /* Each QP requires one connection */
                num_cons = OSAL_MIN_T(u32, IWARP_MAX_QPS, p_params->num_qps);
#ifdef CONFIG_ECORE_IWARP /* required for the define */
                /* additional connections required for passive tcp handling */
                num_cons += ECORE_IWARP_PREALLOC_CNT;
#endif
                proto = PROTOCOLID_IWARP;
                p_params->roce_edpm_mode = false;
                break;
        case ECORE_PCI_ETH_ROCE:
                num_qps = OSAL_MIN_T(u32, ROCE_MAX_QPS, p_params->num_qps);
                num_cons = num_qps * 2; /* each QP requires two connections */
                proto = PROTOCOLID_ROCE;
                break;
        default:
                return;
        }

        if (num_cons && num_tasks) {
                ecore_cxt_set_proto_cid_count(p_hwfn, proto,
                                              num_cons, 0);

                /* Deliberatly passing ROCE for tasks id. This is because
                 * iWARP / RoCE share the task id.
                 */
                ecore_cxt_set_proto_tid_count(p_hwfn, PROTOCOLID_ROCE,
                                              ECORE_CXT_ROCE_TID_SEG,
                                              1, /* RoCE segment type */
                                              num_tasks,
                                              false); /* !force load */
                ecore_cxt_set_srq_count(p_hwfn, num_srqs);

        } else {
                DP_INFO(p_hwfn->p_dev,
                        "RDMA personality used without setting params!\n");
        }
}

enum _ecore_status_t ecore_cxt_set_pf_params(struct ecore_hwfn *p_hwfn,
                                             u32 rdma_tasks)
{
        /* Set the number of required CORE connections */
        u32 core_cids = 1; /* SPQ */

        if (p_hwfn->using_ll2)
                core_cids += 4; /* @@@TBD Use the proper #define */

        ecore_cxt_set_proto_cid_count(p_hwfn, PROTOCOLID_CORE, core_cids, 0);

        switch (p_hwfn->hw_info.personality) {
        case ECORE_PCI_ETH_RDMA:
        case ECORE_PCI_ETH_IWARP:
        case ECORE_PCI_ETH_ROCE:
                ecore_rdma_set_pf_params(p_hwfn,
                                         &p_hwfn->pf_params.rdma_pf_params,
                                         rdma_tasks);

                /* no need for break since RoCE coexist with Ethernet */
                /* FALLTHROUGH */
        case ECORE_PCI_ETH:
        {
                struct ecore_eth_pf_params *p_params =
                                        &p_hwfn->pf_params.eth_pf_params;

                if (!p_params->num_vf_cons)
                        p_params->num_vf_cons = ETH_PF_PARAMS_VF_CONS_DEFAULT;
                ecore_cxt_set_proto_cid_count(p_hwfn, PROTOCOLID_ETH,
                                              p_params->num_cons,
                                              p_params->num_vf_cons);
                p_hwfn->p_cxt_mngr->arfs_count = p_params->num_arfs_filters;

                break;
        }
        case ECORE_PCI_FCOE:
        {
                struct ecore_fcoe_pf_params *p_params;

                p_params = &p_hwfn->pf_params.fcoe_pf_params;

                if (p_params->num_cons && p_params->num_tasks) {
                        ecore_cxt_set_proto_cid_count(p_hwfn, PROTOCOLID_FCOE,
                                                      p_params->num_cons, 0);

                        ecore_cxt_set_proto_tid_count(p_hwfn, PROTOCOLID_FCOE,
                                                      ECORE_CXT_FCOE_TID_SEG,
                                                      0, /* segment type */
                                                      p_params->num_tasks,
                                                      true);
                } else {
                        DP_INFO(p_hwfn->p_dev,
                                "Fcoe personality used without setting params!\n");
                }
                break;
        }
        case ECORE_PCI_ISCSI:
        {
                struct ecore_iscsi_pf_params *p_params;

                p_params = &p_hwfn->pf_params.iscsi_pf_params;

                if (p_params->num_cons && p_params->num_tasks) {
                        ecore_cxt_set_proto_cid_count(p_hwfn, PROTOCOLID_ISCSI,
                                                      p_params->num_cons, 0);

                        ecore_cxt_set_proto_tid_count(p_hwfn, PROTOCOLID_ISCSI,
                                                      ECORE_CXT_ISCSI_TID_SEG,
                                                      0, /* segment type */
                                                      p_params->num_tasks,
                                                      true);
                } else {
                        DP_INFO(p_hwfn->p_dev,
                                "Iscsi personality used without setting params!\n");
                }
                break;
        }
        default:
                return ECORE_INVAL;
        }

        return ECORE_SUCCESS;
}

enum _ecore_status_t ecore_cxt_get_tid_mem_info(struct ecore_hwfn *p_hwfn,
                                                struct ecore_tid_mem *p_info)
{
        struct ecore_cxt_mngr *p_mngr = p_hwfn->p_cxt_mngr;
        u32 proto, seg, total_lines, i, shadow_line;
        struct ecore_ilt_client_cfg *p_cli;
        struct ecore_ilt_cli_blk *p_fl_seg;
        struct ecore_tid_seg *p_seg_info;

        /* Verify the personality */
        switch (p_hwfn->hw_info.personality) {
        case ECORE_PCI_FCOE:
                proto = PROTOCOLID_FCOE;
                seg = ECORE_CXT_FCOE_TID_SEG;
                break;
        case ECORE_PCI_ISCSI:
                proto = PROTOCOLID_ISCSI;
                seg = ECORE_CXT_ISCSI_TID_SEG;
                break;
        default:
                return ECORE_INVAL;
        }

        p_cli = &p_mngr->clients[ILT_CLI_CDUT];
        if (!p_cli->active) {
                return ECORE_INVAL;
        }

        p_seg_info = &p_mngr->conn_cfg[proto].tid_seg[seg];
        if (!p_seg_info->has_fl_mem)
                return ECORE_INVAL;

        p_fl_seg = &p_cli->pf_blks[CDUT_FL_SEG_BLK(seg, PF)];
        total_lines = DIV_ROUND_UP(p_fl_seg->total_size,
                                   p_fl_seg->real_size_in_page);

        for (i = 0; i < total_lines; i++) {
                shadow_line = i + p_fl_seg->start_line -
                              p_hwfn->p_cxt_mngr->pf_start_line;
                p_info->blocks[i] = p_mngr->ilt_shadow[shadow_line].p_virt;
        }
        p_info->waste = ILT_PAGE_IN_BYTES(p_cli->p_size.val) -
                        p_fl_seg->real_size_in_page;
        p_info->tid_size = p_mngr->task_type_size[p_seg_info->type];
        p_info->num_tids_per_block = p_fl_seg->real_size_in_page /
                                     p_info->tid_size;

        return ECORE_SUCCESS;
}

/* This function is very RoCE oriented, if another protocol in the future
 * will want this feature we'll need to modify the function to be more generic
 */
enum _ecore_status_t
ecore_cxt_dynamic_ilt_alloc(struct ecore_hwfn *p_hwfn,
                            enum ecore_cxt_elem_type elem_type,
                            u32 iid)
{
        u32 reg_offset, shadow_line, elem_size, hw_p_size, elems_per_p, line;
        struct ecore_ilt_client_cfg *p_cli;
        struct ecore_ilt_cli_blk *p_blk;
        struct ecore_ptt *p_ptt;
        dma_addr_t p_phys;
        u64 ilt_hw_entry;
        void *p_virt;
        enum _ecore_status_t rc = ECORE_SUCCESS;

        switch (elem_type) {
        case ECORE_ELEM_CXT:
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUC];
                elem_size = CONN_CXT_SIZE(p_hwfn);
                p_blk = &p_cli->pf_blks[CDUC_BLK];
                break;
        case ECORE_ELEM_SRQ:
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_TSDM];
                elem_size = SRQ_CXT_SIZE;
                p_blk = &p_cli->pf_blks[SRQ_BLK];
                break;
        case ECORE_ELEM_TASK:
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUT];
                elem_size = TYPE1_TASK_CXT_SIZE(p_hwfn);
                p_blk = &p_cli->pf_blks[CDUT_SEG_BLK(ECORE_CXT_ROCE_TID_SEG)];
                break;
        default:
                DP_NOTICE(p_hwfn, false,
                          "ECORE_INVALID elem type = %d", elem_type);
                return ECORE_INVAL;
        }

        /* Calculate line in ilt */
        hw_p_size = p_cli->p_size.val;
        elems_per_p = ILT_PAGE_IN_BYTES(hw_p_size) / elem_size;
        line = p_blk->start_line + (iid / elems_per_p);
        shadow_line = line - p_hwfn->p_cxt_mngr->pf_start_line;

        /* If line is already allocated, do nothing, otherwise allocate it and
         * write it to the PSWRQ2 registers.
         * This section can be run in parallel from different contexts and thus
         * a mutex protection is needed.
         */

        OSAL_MUTEX_ACQUIRE(&p_hwfn->p_cxt_mngr->mutex);

        if (p_hwfn->p_cxt_mngr->ilt_shadow[shadow_line].p_virt)
                goto out0;

        p_ptt = ecore_ptt_acquire(p_hwfn);
        if (!p_ptt) {
                DP_NOTICE(p_hwfn, false,
                          "ECORE_TIME_OUT on ptt acquire - dynamic allocation");
                rc = ECORE_TIMEOUT;
                goto out0;
        }

        p_virt = OSAL_DMA_ALLOC_COHERENT(p_hwfn->p_dev,
                                         &p_phys,
                                         p_blk->real_size_in_page);
        if (!p_virt) {
                rc = ECORE_NOMEM;
                goto out1;
        }
        OSAL_MEM_ZERO(p_virt, p_blk->real_size_in_page);

        /* configuration of refTagMask to 0xF is required for RoCE DIF MR only,
         * to compensate for a HW bug, but it is configured even if DIF is not
         * enabled. This is harmless and allows us to avoid a dedicated API. We
         * configure the field for all of the contexts on the newly allocated
         * page.
         */
        if (elem_type == ECORE_ELEM_TASK) {
                u32 elem_i;
                u8 *elem_start = (u8 *)p_virt;
                union type1_task_context *elem;

                for (elem_i = 0; elem_i < elems_per_p; elem_i++) {
                        elem = (union type1_task_context *)elem_start;
                        SET_FIELD(elem->roce_ctx.tdif_context.flags1,
                                  TDIF_TASK_CONTEXT_REFTAGMASK , 0xf);
                        elem_start += TYPE1_TASK_CXT_SIZE(p_hwfn);
                }
        }

        p_hwfn->p_cxt_mngr->ilt_shadow[shadow_line].p_virt = p_virt;
        p_hwfn->p_cxt_mngr->ilt_shadow[shadow_line].p_phys = p_phys;
        p_hwfn->p_cxt_mngr->ilt_shadow[shadow_line].size =
                p_blk->real_size_in_page;

        /* compute absolute offset */
        reg_offset = PSWRQ2_REG_ILT_MEMORY +
                     (line * ILT_REG_SIZE_IN_BYTES * ILT_ENTRY_IN_REGS);

        ilt_hw_entry = 0;
        SET_FIELD(ilt_hw_entry, ILT_ENTRY_VALID, 1ULL);
        SET_FIELD(ilt_hw_entry,
                  ILT_ENTRY_PHY_ADDR,
                  (p_hwfn->p_cxt_mngr->ilt_shadow[shadow_line].p_phys >> 12));

        /* Write via DMAE since the PSWRQ2_REG_ILT_MEMORY line is a wide-bus */
        ecore_dmae_host2grc(p_hwfn, p_ptt, (u64)(osal_uintptr_t)&ilt_hw_entry,
                            reg_offset, sizeof(ilt_hw_entry) / sizeof(u32),
                            0 /* no flags */);

        if (elem_type == ECORE_ELEM_CXT) {
                u32 last_cid_allocated = (1 + (iid / elems_per_p)) *
                                         elems_per_p;

                /* Update the relevant register in the parser */
                ecore_wr(p_hwfn, p_ptt, PRS_REG_ROCE_DEST_QP_MAX_PF,
                         last_cid_allocated - 1);

                /* RoCE w/a -> we don't write to the prs search reg until first
                 * cid is allocated. This is because the prs checks
                 * last_cid-1 >=0 making 0 a valid value... this will cause
                 * the a context load to occur on a RoCE packet received with
                 * cid=0 even before context was initialized, can happen with a
                 * stray packet from switch or a packet with crc-error
                 */

                if (!p_hwfn->b_rdma_enabled_in_prs) {
                        /* Enable Rdma search */
                        ecore_wr(p_hwfn, p_ptt, p_hwfn->rdma_prs_search_reg, 1);
                        p_hwfn->b_rdma_enabled_in_prs = true;
                }
        }

out1:
        ecore_ptt_release(p_hwfn, p_ptt);
out0:
        OSAL_MUTEX_RELEASE(&p_hwfn->p_cxt_mngr->mutex);

        return rc;
}

/* This function is very RoCE oriented, if another protocol in the future
 * will want this feature we'll need to modify the function to be more generic
 */
enum _ecore_status_t
ecore_cxt_free_ilt_range(struct ecore_hwfn *p_hwfn,
                         enum ecore_cxt_elem_type elem_type,
                         u32 start_iid, u32 count)
{
        u32 start_line, end_line, shadow_start_line, shadow_end_line;
        u32 reg_offset, elem_size, hw_p_size, elems_per_p;
        struct ecore_ilt_client_cfg *p_cli;
        struct ecore_ilt_cli_blk *p_blk;
        u32 end_iid = start_iid + count;
        struct ecore_ptt *p_ptt;
        u64 ilt_hw_entry = 0;
        u32 i;

        switch (elem_type) {
        case ECORE_ELEM_CXT:
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUC];
                elem_size = CONN_CXT_SIZE(p_hwfn);
                p_blk = &p_cli->pf_blks[CDUC_BLK];
                break;
        case ECORE_ELEM_SRQ:
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_TSDM];
                elem_size = SRQ_CXT_SIZE;
                p_blk = &p_cli->pf_blks[SRQ_BLK];
                break;
        case ECORE_ELEM_TASK:
                p_cli = &p_hwfn->p_cxt_mngr->clients[ILT_CLI_CDUT];
                elem_size = TYPE1_TASK_CXT_SIZE(p_hwfn);
                p_blk = &p_cli->pf_blks[CDUT_SEG_BLK(ECORE_CXT_ROCE_TID_SEG)];
                break;
        default:
                DP_NOTICE(p_hwfn, false,
                          "ECORE_INVALID elem type = %d", elem_type);
                return ECORE_INVAL;
        }

        /* Calculate line in ilt */
        hw_p_size = p_cli->p_size.val;
        elems_per_p = ILT_PAGE_IN_BYTES(hw_p_size) / elem_size;
        start_line = p_blk->start_line + (start_iid / elems_per_p);
        end_line = p_blk->start_line + (end_iid / elems_per_p);
        if (((end_iid + 1) / elems_per_p) != (end_iid / elems_per_p))
                end_line--;

        shadow_start_line = start_line - p_hwfn->p_cxt_mngr->pf_start_line;
        shadow_end_line = end_line - p_hwfn->p_cxt_mngr->pf_start_line;

        p_ptt = ecore_ptt_acquire(p_hwfn);
        if (!p_ptt) {
                DP_NOTICE(p_hwfn, false, "ECORE_TIME_OUT on ptt acquire - dynamic allocation");
                return ECORE_TIMEOUT;
        }

        for (i = shadow_start_line; i < shadow_end_line; i++) {
                if (!p_hwfn->p_cxt_mngr->ilt_shadow[i].p_virt)
                        continue;

                OSAL_DMA_FREE_COHERENT(p_hwfn->p_dev,
                                       p_hwfn->p_cxt_mngr->ilt_shadow[i].p_virt,
                                       p_hwfn->p_cxt_mngr->ilt_shadow[i].p_phys,
                                       p_hwfn->p_cxt_mngr->ilt_shadow[i].size);

                p_hwfn->p_cxt_mngr->ilt_shadow[i].p_virt = OSAL_NULL;
                p_hwfn->p_cxt_mngr->ilt_shadow[i].p_phys = 0;
                p_hwfn->p_cxt_mngr->ilt_shadow[i].size = 0;

                /* compute absolute offset */
                reg_offset = PSWRQ2_REG_ILT_MEMORY +
                             ((start_line++) * ILT_REG_SIZE_IN_BYTES *
                              ILT_ENTRY_IN_REGS);

                /* Write via DMAE since the PSWRQ2_REG_ILT_MEMORY line is a
                 * wide-bus.
                 */
                ecore_dmae_host2grc(p_hwfn, p_ptt,
                                    (u64)(osal_uintptr_t)&ilt_hw_entry,
                                    reg_offset,
                                    sizeof(ilt_hw_entry) / sizeof(u32),
                                    0 /* no flags */);
        }

        ecore_ptt_release(p_hwfn, p_ptt);

        return ECORE_SUCCESS;
}

enum _ecore_status_t ecore_cxt_get_task_ctx(struct ecore_hwfn *p_hwfn,
                                            u32 tid,
                                            u8 ctx_type,
                                            void **pp_task_ctx)
{
        struct ecore_cxt_mngr           *p_mngr = p_hwfn->p_cxt_mngr;
        struct ecore_ilt_client_cfg     *p_cli;
        struct ecore_ilt_cli_blk        *p_seg;
        struct ecore_tid_seg            *p_seg_info;
        u32                             proto, seg;
        u32                             total_lines;
        u32                             tid_size, ilt_idx;
        u32                             num_tids_per_block;

        /* Verify the personality */
        switch (p_hwfn->hw_info.personality) {
        case ECORE_PCI_FCOE:
                proto = PROTOCOLID_FCOE;
                seg = ECORE_CXT_FCOE_TID_SEG;
                break;
        case ECORE_PCI_ISCSI:
                proto = PROTOCOLID_ISCSI;
                seg = ECORE_CXT_ISCSI_TID_SEG;
                break;
        default:
                return ECORE_INVAL;
        }

        p_cli = &p_mngr->clients[ILT_CLI_CDUT];
        if (!p_cli->active) {
                return ECORE_INVAL;
        }

        p_seg_info = &p_mngr->conn_cfg[proto].tid_seg[seg];

        if (ctx_type == ECORE_CTX_WORKING_MEM) {
                p_seg = &p_cli->pf_blks[CDUT_SEG_BLK(seg)];
        } else if (ctx_type == ECORE_CTX_FL_MEM) {
                if (!p_seg_info->has_fl_mem) {
                        return ECORE_INVAL;
                }
                p_seg = &p_cli->pf_blks[CDUT_FL_SEG_BLK(seg, PF)];
        } else {
                return ECORE_INVAL;
        }
        total_lines = DIV_ROUND_UP(p_seg->total_size,
                                   p_seg->real_size_in_page);
        tid_size = p_mngr->task_type_size[p_seg_info->type];
        num_tids_per_block = p_seg->real_size_in_page / tid_size;

        if (total_lines < tid/num_tids_per_block)
                return ECORE_INVAL;

        ilt_idx = tid / num_tids_per_block + p_seg->start_line -
                  p_mngr->pf_start_line;
        *pp_task_ctx = (u8 *)p_mngr->ilt_shadow[ilt_idx].p_virt +
                             (tid % num_tids_per_block) * tid_size;

        return ECORE_SUCCESS;
}