/* SPDX-License-Identifier: BSD-3-Clause * Copyright(c) 2014-2021 Broadcom * All rights reserved. */ #include "bnxt.h" #include "ulp_template_db_enum.h" #include "ulp_template_struct.h" #include "bnxt_ulp.h" #include "bnxt_tf_common.h" #include "bnxt_tf_pmd_shim.h" #include "ulp_rte_parser.h" #include "ulp_matcher.h" #include "ulp_utils.h" #include "tfp.h" #include "ulp_port_db.h" #include "ulp_flow_db.h" #include "ulp_mapper.h" #include "ulp_tun.h" #include "ulp_template_db_tbl.h" /* Local defines for the parsing functions */ #define ULP_VLAN_PRIORITY_SHIFT 13 /* First 3 bits */ #define ULP_VLAN_PRIORITY_MASK 0x700 #define ULP_VLAN_TAG_MASK 0xFFF /* Last 12 bits*/ #define ULP_UDP_PORT_VXLAN 4789 /* Utility function to skip the void items. */ static inline int32_t ulp_rte_item_skip_void(const struct rte_flow_item **item, uint32_t increment) { if (!*item) return 0; if (increment) (*item)++; while ((*item) && (*item)->type == RTE_FLOW_ITEM_TYPE_VOID) (*item)++; if (*item) return 1; return 0; } /* Utility function to copy field spec items */ static struct ulp_rte_hdr_field * ulp_rte_parser_fld_copy(struct ulp_rte_hdr_field *field, const void *buffer, uint32_t size) { field->size = size; memcpy(field->spec, buffer, field->size); field++; return field; } /* Utility function to update the field_bitmap */ static void ulp_rte_parser_field_bitmap_update(struct ulp_rte_parser_params *params, uint32_t idx, enum bnxt_ulp_prsr_action prsr_act) { struct ulp_rte_hdr_field *field; field = ¶ms->hdr_field[idx]; if (ulp_bitmap_notzero(field->mask, field->size)) { ULP_INDEX_BITMAP_SET(params->fld_bitmap.bits, idx); if (!(prsr_act & ULP_PRSR_ACT_MATCH_IGNORE)) ULP_INDEX_BITMAP_SET(params->fld_s_bitmap.bits, idx); /* Not exact match */ if (!ulp_bitmap_is_ones(field->mask, field->size)) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_WC_MATCH, 1); } else { ULP_INDEX_BITMAP_RESET(params->fld_bitmap.bits, idx); } } #define ulp_deference_struct(x, y) ((x) ? &((x)->y) : NULL) /* Utility function to copy field spec and masks items */ static void ulp_rte_prsr_fld_mask(struct ulp_rte_parser_params *params, uint32_t *idx, uint32_t size, const void *spec_buff, const void *mask_buff, enum bnxt_ulp_prsr_action prsr_act) { struct ulp_rte_hdr_field *field = ¶ms->hdr_field[*idx]; /* update the field size */ field->size = size; /* copy the mask specifications only if mask is not null */ if (!(prsr_act & ULP_PRSR_ACT_MASK_IGNORE) && mask_buff) { memcpy(field->mask, mask_buff, size); ulp_rte_parser_field_bitmap_update(params, *idx, prsr_act); } /* copy the protocol specifications only if mask is not null*/ if (spec_buff && mask_buff && ulp_bitmap_notzero(mask_buff, size)) memcpy(field->spec, spec_buff, size); /* Increment the index */ *idx = *idx + 1; } /* Utility function to copy field spec and masks items */ static int32_t ulp_rte_prsr_fld_size_validate(struct ulp_rte_parser_params *params, uint32_t *idx, uint32_t size) { if (params->field_idx + size >= BNXT_ULP_PROTO_HDR_MAX) { BNXT_TF_DBG(ERR, "OOB for field processing %u\n", *idx); return -EINVAL; } *idx = params->field_idx; params->field_idx += size; return 0; } /* * Function to handle the parsing of RTE Flows and placing * the RTE flow items into the ulp structures. */ int32_t bnxt_ulp_rte_parser_hdr_parse(const struct rte_flow_item pattern[], struct ulp_rte_parser_params *params) { const struct rte_flow_item *item = pattern; struct bnxt_ulp_rte_hdr_info *hdr_info; params->field_idx = BNXT_ULP_PROTO_HDR_SVIF_NUM; /* Set the computed flags for no vlan tags before parsing */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_NO_VTAG, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_NO_VTAG, 1); /* Parse all the items in the pattern */ while (item && item->type != RTE_FLOW_ITEM_TYPE_END) { if (item->type >= (typeof(item->type)) BNXT_RTE_FLOW_ITEM_TYPE_END) { if (item->type >= (typeof(item->type))BNXT_RTE_FLOW_ITEM_TYPE_LAST) goto hdr_parser_error; /* get the header information */ hdr_info = &ulp_vendor_hdr_info[item->type - BNXT_RTE_FLOW_ITEM_TYPE_END]; } else { if (item->type > RTE_FLOW_ITEM_TYPE_HIGIG2) goto hdr_parser_error; hdr_info = &ulp_hdr_info[item->type]; } if (hdr_info->hdr_type == BNXT_ULP_HDR_TYPE_NOT_SUPPORTED) { goto hdr_parser_error; } else if (hdr_info->hdr_type == BNXT_ULP_HDR_TYPE_SUPPORTED) { /* call the registered callback handler */ if (hdr_info->proto_hdr_func) { if (hdr_info->proto_hdr_func(item, params) != BNXT_TF_RC_SUCCESS) { return BNXT_TF_RC_ERROR; } } } item++; } /* update the implied SVIF */ return ulp_rte_parser_implicit_match_port_process(params); hdr_parser_error: BNXT_TF_DBG(ERR, "Truflow parser does not support type %d\n", item->type); return BNXT_TF_RC_PARSE_ERR; } /* * Function to handle the parsing of RTE Flows and placing * the RTE flow actions into the ulp structures. */ int32_t bnxt_ulp_rte_parser_act_parse(const struct rte_flow_action actions[], struct ulp_rte_parser_params *params) { const struct rte_flow_action *action_item = actions; struct bnxt_ulp_rte_act_info *hdr_info; /* Parse all the items in the pattern */ while (action_item && action_item->type != RTE_FLOW_ACTION_TYPE_END) { if (action_item->type >= (typeof(action_item->type))BNXT_RTE_FLOW_ACTION_TYPE_END) { if (action_item->type >= (typeof(action_item->type))BNXT_RTE_FLOW_ACTION_TYPE_LAST) goto act_parser_error; /* get the header information from bnxt actinfo table */ hdr_info = &ulp_vendor_act_info[action_item->type - BNXT_RTE_FLOW_ACTION_TYPE_END]; } else { if (action_item->type > RTE_FLOW_ACTION_TYPE_SHARED) goto act_parser_error; /* get the header information from the act info table */ hdr_info = &ulp_act_info[action_item->type]; } if (hdr_info->act_type == BNXT_ULP_ACT_TYPE_NOT_SUPPORTED) { goto act_parser_error; } else if (hdr_info->act_type == BNXT_ULP_ACT_TYPE_SUPPORTED) { /* call the registered callback handler */ if (hdr_info->proto_act_func) { if (hdr_info->proto_act_func(action_item, params) != BNXT_TF_RC_SUCCESS) { return BNXT_TF_RC_ERROR; } } } action_item++; } /* update the implied port details */ ulp_rte_parser_implicit_act_port_process(params); return BNXT_TF_RC_SUCCESS; act_parser_error: BNXT_TF_DBG(ERR, "Truflow parser does not support act %u\n", action_item->type); return BNXT_TF_RC_ERROR; } /* * Function to handle the post processing of the computed * fields for the interface. */ static void bnxt_ulp_comp_fld_intf_update(struct ulp_rte_parser_params *params) { uint32_t ifindex; uint16_t port_id, parif; uint32_t mtype; enum bnxt_ulp_direction_type dir; /* get the direction details */ dir = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_DIRECTION); /* read the port id details */ port_id = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_INCOMING_IF); if (ulp_port_db_dev_port_to_ulp_index(params->ulp_ctx, port_id, &ifindex)) { BNXT_TF_DBG(ERR, "ParseErr:Portid is not valid\n"); return; } if (dir == BNXT_ULP_DIR_INGRESS) { /* Set port PARIF */ if (ulp_port_db_parif_get(params->ulp_ctx, ifindex, BNXT_ULP_PHY_PORT_PARIF, &parif)) { BNXT_TF_DBG(ERR, "ParseErr:ifindex is not valid\n"); return; } ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_PHY_PORT_PARIF, parif); } else { /* Get the match port type */ mtype = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_MATCH_PORT_TYPE); if (mtype == BNXT_ULP_INTF_TYPE_VF_REP) { ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_MATCH_PORT_IS_VFREP, 1); /* Set VF func PARIF */ if (ulp_port_db_parif_get(params->ulp_ctx, ifindex, BNXT_ULP_VF_FUNC_PARIF, &parif)) { BNXT_TF_DBG(ERR, "ParseErr:ifindex is not valid\n"); return; } ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_VF_FUNC_PARIF, parif); } else { /* Set DRV func PARIF */ if (ulp_port_db_parif_get(params->ulp_ctx, ifindex, BNXT_ULP_DRV_FUNC_PARIF, &parif)) { BNXT_TF_DBG(ERR, "ParseErr:ifindex is not valid\n"); return; } ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_DRV_FUNC_PARIF, parif); } if (mtype == BNXT_ULP_INTF_TYPE_PF) { ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_MATCH_PORT_IS_PF, 1); } } } static int32_t ulp_post_process_normal_flow(struct ulp_rte_parser_params *params) { enum bnxt_ulp_intf_type match_port_type, act_port_type; enum bnxt_ulp_direction_type dir; uint32_t act_port_set; /* Get the computed details */ dir = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_DIRECTION); match_port_type = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_MATCH_PORT_TYPE); act_port_type = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_ACT_PORT_TYPE); act_port_set = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_ACT_PORT_IS_SET); /* set the flow direction in the proto and action header */ if (dir == BNXT_ULP_DIR_EGRESS) { ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_FLOW_DIR_BITMASK_EGR); ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_FLOW_DIR_BITMASK_EGR); } /* calculate the VF to VF flag */ if (act_port_set && act_port_type == BNXT_ULP_INTF_TYPE_VF_REP && match_port_type == BNXT_ULP_INTF_TYPE_VF_REP) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_VF_TO_VF, 1); /* Update the decrement ttl computational fields */ if (ULP_BITMAP_ISSET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_DEC_TTL)) { /* * Check that vxlan proto is included and vxlan decap * action is not set then decrement tunnel ttl. * Similarly add GRE and NVGRE in future. */ if ((ULP_BITMAP_ISSET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_T_VXLAN) && !ULP_BITMAP_ISSET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_VXLAN_DECAP))) { ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_T_DEC_TTL, 1); } else { ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_DEC_TTL, 1); } } /* Merge the hdr_fp_bit into the proto header bit */ params->hdr_bitmap.bits |= params->hdr_fp_bit.bits; /* Update the comp fld fid */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_FID, params->fid); /* Update the computed interface parameters */ bnxt_ulp_comp_fld_intf_update(params); /* TBD: Handle the flow rejection scenarios */ return 0; } /* * Function to handle the post processing of the parsing details */ void bnxt_ulp_rte_parser_post_process(struct ulp_rte_parser_params *params) { ulp_post_process_normal_flow(params); } /* * Function to compute the flow direction based on the match port details */ static void bnxt_ulp_rte_parser_direction_compute(struct ulp_rte_parser_params *params) { enum bnxt_ulp_intf_type match_port_type; /* Get the match port type */ match_port_type = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_MATCH_PORT_TYPE); /* If ingress flow and matchport is vf rep then dir is egress*/ if ((params->dir_attr & BNXT_ULP_FLOW_ATTR_INGRESS) && match_port_type == BNXT_ULP_INTF_TYPE_VF_REP) { ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_DIRECTION, BNXT_ULP_DIR_EGRESS); } else { /* Assign the input direction */ if (params->dir_attr & BNXT_ULP_FLOW_ATTR_INGRESS) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_DIRECTION, BNXT_ULP_DIR_INGRESS); else ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_DIRECTION, BNXT_ULP_DIR_EGRESS); } } /* Function to handle the parsing of RTE Flow item PF Header. */ static int32_t ulp_rte_parser_svif_set(struct ulp_rte_parser_params *params, uint32_t ifindex, uint16_t mask, enum bnxt_ulp_direction_type item_dir) { uint16_t svif; enum bnxt_ulp_direction_type dir; struct ulp_rte_hdr_field *hdr_field; enum bnxt_ulp_svif_type svif_type; enum bnxt_ulp_intf_type port_type; if (ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_SVIF_FLAG) != BNXT_ULP_INVALID_SVIF_VAL) { BNXT_TF_DBG(ERR, "SVIF already set,multiple source not support'd\n"); return BNXT_TF_RC_ERROR; } /* Get port type details */ port_type = ulp_port_db_port_type_get(params->ulp_ctx, ifindex); if (port_type == BNXT_ULP_INTF_TYPE_INVALID) { BNXT_TF_DBG(ERR, "Invalid port type\n"); return BNXT_TF_RC_ERROR; } /* Update the match port type */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_MATCH_PORT_TYPE, port_type); /* compute the direction */ bnxt_ulp_rte_parser_direction_compute(params); /* Get the computed direction */ dir = (item_dir != BNXT_ULP_DIR_INVALID) ? item_dir : ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_DIRECTION); if (dir == BNXT_ULP_DIR_INGRESS && port_type != BNXT_ULP_INTF_TYPE_VF_REP) { svif_type = BNXT_ULP_PHY_PORT_SVIF; } else { if (port_type == BNXT_ULP_INTF_TYPE_VF_REP && item_dir != BNXT_ULP_DIR_EGRESS) svif_type = BNXT_ULP_VF_FUNC_SVIF; else svif_type = BNXT_ULP_DRV_FUNC_SVIF; } ulp_port_db_svif_get(params->ulp_ctx, ifindex, svif_type, &svif); svif = rte_cpu_to_be_16(svif); hdr_field = ¶ms->hdr_field[BNXT_ULP_PROTO_HDR_FIELD_SVIF_IDX]; memcpy(hdr_field->spec, &svif, sizeof(svif)); memcpy(hdr_field->mask, &mask, sizeof(mask)); hdr_field->size = sizeof(svif); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_SVIF_FLAG, rte_be_to_cpu_16(svif)); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of the RTE port id */ int32_t ulp_rte_parser_implicit_match_port_process(struct ulp_rte_parser_params *params) { uint16_t port_id = 0; uint16_t svif_mask = 0xFFFF; uint32_t ifindex; int32_t rc = BNXT_TF_RC_ERROR; if (ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_SVIF_FLAG) != BNXT_ULP_INVALID_SVIF_VAL) return BNXT_TF_RC_SUCCESS; /* SVIF not set. So get the port id */ port_id = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_INCOMING_IF); if (ulp_port_db_dev_port_to_ulp_index(params->ulp_ctx, port_id, &ifindex)) { BNXT_TF_DBG(ERR, "ParseErr:Portid is not valid\n"); return rc; } /* Update the SVIF details */ rc = ulp_rte_parser_svif_set(params, ifindex, svif_mask, BNXT_ULP_DIR_INVALID); return rc; } /* Function to handle the implicit action port id */ int32_t ulp_rte_parser_implicit_act_port_process(struct ulp_rte_parser_params *params) { struct rte_flow_action action_item = {0}; struct rte_flow_action_port_id port_id = {0}; /* Read the action port set bit */ if (ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_ACT_PORT_IS_SET)) { /* Already set, so just exit */ return BNXT_TF_RC_SUCCESS; } port_id.id = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_INCOMING_IF); action_item.type = RTE_FLOW_ACTION_TYPE_PORT_ID; action_item.conf = &port_id; /* Update the action port based on incoming port */ ulp_rte_port_act_handler(&action_item, params); /* Reset the action port set bit */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_PORT_IS_SET, 0); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item PF Header. */ int32_t ulp_rte_pf_hdr_handler(const struct rte_flow_item *item __rte_unused, struct ulp_rte_parser_params *params) { uint16_t port_id = 0; uint16_t svif_mask = 0xFFFF; uint32_t ifindex; /* Get the implicit port id */ port_id = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_INCOMING_IF); /* perform the conversion from dpdk port to bnxt ifindex */ if (ulp_port_db_dev_port_to_ulp_index(params->ulp_ctx, port_id, &ifindex)) { BNXT_TF_DBG(ERR, "ParseErr:Portid is not valid\n"); return BNXT_TF_RC_ERROR; } /* Update the SVIF details */ return ulp_rte_parser_svif_set(params, ifindex, svif_mask, BNXT_ULP_DIR_INVALID); } /* Function to handle the parsing of RTE Flow item VF Header. */ int32_t ulp_rte_vf_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_vf *vf_spec = item->spec; const struct rte_flow_item_vf *vf_mask = item->mask; uint16_t mask = 0; uint32_t ifindex; int32_t rc = BNXT_TF_RC_PARSE_ERR; /* Get VF rte_flow_item for Port details */ if (!vf_spec) { BNXT_TF_DBG(ERR, "ParseErr:VF id is not valid\n"); return rc; } if (!vf_mask) { BNXT_TF_DBG(ERR, "ParseErr:VF mask is not valid\n"); return rc; } mask = vf_mask->id; /* perform the conversion from VF Func id to bnxt ifindex */ if (ulp_port_db_dev_func_id_to_ulp_index(params->ulp_ctx, vf_spec->id, &ifindex)) { BNXT_TF_DBG(ERR, "ParseErr:Portid is not valid\n"); return rc; } /* Update the SVIF details */ return ulp_rte_parser_svif_set(params, ifindex, mask, BNXT_ULP_DIR_INVALID); } /* Parse items PORT_ID, PORT_REPRESENTOR and REPRESENTED_PORT. */ int32_t ulp_rte_port_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { enum bnxt_ulp_direction_type item_dir; uint16_t ethdev_id; uint16_t mask = 0; int32_t rc = BNXT_TF_RC_PARSE_ERR; uint32_t ifindex; if (!item->spec) { BNXT_TF_DBG(ERR, "ParseErr:Port spec is not valid\n"); return rc; } if (!item->mask) { BNXT_TF_DBG(ERR, "ParseErr:Port mask is not valid\n"); return rc; } switch (item->type) { case RTE_FLOW_ITEM_TYPE_PORT_ID: { const struct rte_flow_item_port_id *port_spec = item->spec; const struct rte_flow_item_port_id *port_mask = item->mask; item_dir = BNXT_ULP_DIR_INVALID; ethdev_id = port_spec->id; mask = port_mask->id; break; } case RTE_FLOW_ITEM_TYPE_PORT_REPRESENTOR: { const struct rte_flow_item_ethdev *ethdev_spec = item->spec; const struct rte_flow_item_ethdev *ethdev_mask = item->mask; item_dir = BNXT_ULP_DIR_INGRESS; ethdev_id = ethdev_spec->port_id; mask = ethdev_mask->port_id; break; } case RTE_FLOW_ITEM_TYPE_REPRESENTED_PORT: { const struct rte_flow_item_ethdev *ethdev_spec = item->spec; const struct rte_flow_item_ethdev *ethdev_mask = item->mask; item_dir = BNXT_ULP_DIR_EGRESS; ethdev_id = ethdev_spec->port_id; mask = ethdev_mask->port_id; break; } default: BNXT_TF_DBG(ERR, "ParseErr:Unexpected item\n"); return rc; } /* perform the conversion from dpdk port to bnxt ifindex */ if (ulp_port_db_dev_port_to_ulp_index(params->ulp_ctx, ethdev_id, &ifindex)) { BNXT_TF_DBG(ERR, "ParseErr:Portid is not valid\n"); return rc; } /* Update the SVIF details */ return ulp_rte_parser_svif_set(params, ifindex, mask, item_dir); } /* Function to handle the parsing of RTE Flow item phy port Header. */ int32_t ulp_rte_phy_port_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_phy_port *port_spec = item->spec; const struct rte_flow_item_phy_port *port_mask = item->mask; uint16_t mask = 0; int32_t rc = BNXT_TF_RC_ERROR; uint16_t svif; enum bnxt_ulp_direction_type dir; struct ulp_rte_hdr_field *hdr_field; /* Copy the rte_flow_item for phy port into hdr_field */ if (!port_spec) { BNXT_TF_DBG(ERR, "ParseErr:Phy Port id is not valid\n"); return rc; } if (!port_mask) { BNXT_TF_DBG(ERR, "ParseErr:Phy Port mask is not valid\n"); return rc; } mask = port_mask->index; /* Update the match port type */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_MATCH_PORT_TYPE, BNXT_ULP_INTF_TYPE_PHY_PORT); /* Compute the Hw direction */ bnxt_ulp_rte_parser_direction_compute(params); /* Direction validation */ dir = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_DIRECTION); if (dir == BNXT_ULP_DIR_EGRESS) { BNXT_TF_DBG(ERR, "Parse Err:Phy ports are valid only for ingress\n"); return BNXT_TF_RC_PARSE_ERR; } /* Get the physical port details from port db */ rc = ulp_port_db_phy_port_svif_get(params->ulp_ctx, port_spec->index, &svif); if (rc) { BNXT_TF_DBG(ERR, "Failed to get port details\n"); return BNXT_TF_RC_PARSE_ERR; } /* Update the SVIF details */ svif = rte_cpu_to_be_16(svif); hdr_field = ¶ms->hdr_field[BNXT_ULP_PROTO_HDR_FIELD_SVIF_IDX]; memcpy(hdr_field->spec, &svif, sizeof(svif)); memcpy(hdr_field->mask, &mask, sizeof(mask)); hdr_field->size = sizeof(svif); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_SVIF_FLAG, rte_be_to_cpu_16(svif)); if (!mask) { uint32_t port_id = 0; uint16_t phy_port = 0; /* Validate the control port */ port_id = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_DEV_PORT_ID); if (ulp_port_db_phy_port_get(params->ulp_ctx, port_id, &phy_port) || (uint16_t)port_spec->index != phy_port) { BNXT_TF_DBG(ERR, "Mismatch of control and phy_port\n"); return BNXT_TF_RC_PARSE_ERR; } ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_SVIF_IGNORE); memset(hdr_field->mask, 0xFF, sizeof(mask)); } return BNXT_TF_RC_SUCCESS; } /* Function to handle the update of proto header based on field values */ static void ulp_rte_l2_proto_type_update(struct ulp_rte_parser_params *param, uint16_t type, uint32_t in_flag) { if (type == tfp_cpu_to_be_16(RTE_ETHER_TYPE_IPV4)) { if (in_flag) { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_I_IPV4); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_I_L3, 1); } else { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_O_IPV4); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_O_L3, 1); } } else if (type == tfp_cpu_to_be_16(RTE_ETHER_TYPE_IPV6)) { if (in_flag) { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_I_IPV6); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_I_L3, 1); } else { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_O_IPV6); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_O_L3, 1); } } } /* Internal Function to identify broadcast or multicast packets */ static int32_t ulp_rte_parser_is_bcmc_addr(const struct rte_ether_addr *eth_addr) { if (rte_is_multicast_ether_addr(eth_addr) || rte_is_broadcast_ether_addr(eth_addr)) { BNXT_TF_DBG(DEBUG, "No support for bcast or mcast addr offload\n"); return 1; } return 0; } /* Function to handle the parsing of RTE Flow item Ethernet Header. */ int32_t ulp_rte_eth_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_eth *eth_spec = item->spec; const struct rte_flow_item_eth *eth_mask = item->mask; uint32_t idx = 0, dmac_idx = 0; uint32_t size; uint16_t eth_type = 0; uint32_t inner_flag = 0; /* Perform validations */ if (eth_spec) { /* Todo: work around to avoid multicast and broadcast addr */ if (ulp_rte_parser_is_bcmc_addr(ð_spec->dst)) return BNXT_TF_RC_PARSE_ERR; if (ulp_rte_parser_is_bcmc_addr(ð_spec->src)) return BNXT_TF_RC_PARSE_ERR; eth_type = eth_spec->type; } if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_ETH_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for eth into hdr_field using ethernet * header fields */ dmac_idx = idx; size = sizeof(((struct rte_flow_item_eth *)NULL)->dst.addr_bytes); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(eth_spec, dst.addr_bytes), ulp_deference_struct(eth_mask, dst.addr_bytes), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_eth *)NULL)->src.addr_bytes); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(eth_spec, src.addr_bytes), ulp_deference_struct(eth_mask, src.addr_bytes), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_eth *)NULL)->type); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(eth_spec, type), ulp_deference_struct(eth_mask, type), ULP_PRSR_ACT_MATCH_IGNORE); /* Update the protocol hdr bitmap */ if (ULP_BITMAP_ISSET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_ETH) || ULP_BITMAP_ISSET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_IPV4) || ULP_BITMAP_ISSET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_IPV6) || ULP_BITMAP_ISSET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_UDP) || ULP_BITMAP_ISSET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_TCP)) { ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_I_ETH); inner_flag = 1; } else { ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_ETH); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_TUN_OFF_DMAC_ID, dmac_idx); } /* Update the field protocol hdr bitmap */ ulp_rte_l2_proto_type_update(params, eth_type, inner_flag); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item Vlan Header. */ int32_t ulp_rte_vlan_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_vlan *vlan_spec = item->spec; const struct rte_flow_item_vlan *vlan_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bit; uint32_t idx = 0; uint16_t vlan_tag = 0, priority = 0; uint16_t vlan_tag_mask = 0, priority_mask = 0; uint32_t outer_vtag_num; uint32_t inner_vtag_num; uint16_t eth_type = 0; uint32_t inner_flag = 0; uint32_t size; if (vlan_spec) { vlan_tag = ntohs(vlan_spec->tci); priority = htons(vlan_tag >> ULP_VLAN_PRIORITY_SHIFT); vlan_tag &= ULP_VLAN_TAG_MASK; vlan_tag = htons(vlan_tag); eth_type = vlan_spec->inner_type; } if (vlan_mask) { vlan_tag_mask = ntohs(vlan_mask->tci); priority_mask = htons(vlan_tag_mask >> ULP_VLAN_PRIORITY_SHIFT); vlan_tag_mask &= 0xfff; /* * the storage for priority and vlan tag is 2 bytes * The mask of priority which is 3 bits if it is all 1's * then make the rest bits 13 bits as 1's * so that it is matched as exact match. */ if (priority_mask == ULP_VLAN_PRIORITY_MASK) priority_mask |= ~ULP_VLAN_PRIORITY_MASK; if (vlan_tag_mask == ULP_VLAN_TAG_MASK) vlan_tag_mask |= ~ULP_VLAN_TAG_MASK; vlan_tag_mask = htons(vlan_tag_mask); } if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_S_VLAN_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for vlan into hdr_field using Vlan * header fields */ size = sizeof(((struct rte_flow_item_vlan *)NULL)->tci); /* * The priority field is ignored since OVS is setting it as * wild card match and it is not supported. This is a work * around and shall be addressed in the future. */ ulp_rte_prsr_fld_mask(params, &idx, size, &priority, (vlan_mask) ? &priority_mask : NULL, ULP_PRSR_ACT_MASK_IGNORE); ulp_rte_prsr_fld_mask(params, &idx, size, &vlan_tag, (vlan_mask) ? &vlan_tag_mask : NULL, ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_vlan *)NULL)->inner_type); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(vlan_spec, inner_type), ulp_deference_struct(vlan_mask, inner_type), ULP_PRSR_ACT_MATCH_IGNORE); /* Get the outer tag and inner tag counts */ outer_vtag_num = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_O_VTAG_NUM); inner_vtag_num = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_I_VTAG_NUM); /* Update the hdr_bitmap of the vlans */ hdr_bit = ¶ms->hdr_bitmap; if (ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_O_ETH) && !ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_I_ETH) && !outer_vtag_num) { /* Update the vlan tag num */ outer_vtag_num++; ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_VTAG_NUM, outer_vtag_num); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_NO_VTAG, 0); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_ONE_VTAG, 1); ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_OO_VLAN); if (vlan_mask && vlan_tag_mask) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_OO_VLAN_FB_VID, 1); } else if (ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_O_ETH) && !ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_I_ETH) && outer_vtag_num == 1) { /* update the vlan tag num */ outer_vtag_num++; ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_VTAG_NUM, outer_vtag_num); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_TWO_VTAGS, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_ONE_VTAG, 0); ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_OI_VLAN); if (vlan_mask && vlan_tag_mask) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_OI_VLAN_FB_VID, 1); } else if (ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_O_ETH) && ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_I_ETH) && !inner_vtag_num) { /* update the vlan tag num */ inner_vtag_num++; ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_VTAG_NUM, inner_vtag_num); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_NO_VTAG, 0); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_ONE_VTAG, 1); ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_IO_VLAN); if (vlan_mask && vlan_tag_mask) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_IO_VLAN_FB_VID, 1); inner_flag = 1; } else if (ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_O_ETH) && ULP_BITMAP_ISSET(hdr_bit->bits, BNXT_ULP_HDR_BIT_I_ETH) && inner_vtag_num == 1) { /* update the vlan tag num */ inner_vtag_num++; ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_VTAG_NUM, inner_vtag_num); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_TWO_VTAGS, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_ONE_VTAG, 0); ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_II_VLAN); if (vlan_mask && vlan_tag_mask) ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_II_VLAN_FB_VID, 1); inner_flag = 1; } else { BNXT_TF_DBG(ERR, "Error Parsing:Vlan hdr found without eth\n"); return BNXT_TF_RC_ERROR; } /* Update the field protocol hdr bitmap */ ulp_rte_l2_proto_type_update(params, eth_type, inner_flag); return BNXT_TF_RC_SUCCESS; } /* Function to handle the update of proto header based on field values */ static void ulp_rte_l3_proto_type_update(struct ulp_rte_parser_params *param, uint8_t proto, uint32_t in_flag) { if (proto == IPPROTO_UDP) { if (in_flag) { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_I_UDP); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_I_L4, 1); } else { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_O_UDP); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_O_L4, 1); } } else if (proto == IPPROTO_TCP) { if (in_flag) { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_I_TCP); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_I_L4, 1); } else { ULP_BITMAP_SET(param->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_O_TCP); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_O_L4, 1); } } else if (proto == IPPROTO_GRE) { ULP_BITMAP_SET(param->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_T_GRE); } else if (proto == IPPROTO_ICMP) { if (ULP_COMP_FLD_IDX_RD(param, BNXT_ULP_CF_IDX_L3_TUN)) ULP_BITMAP_SET(param->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_I_ICMP); else ULP_BITMAP_SET(param->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_ICMP); } if (proto) { if (in_flag) { ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_I_L3_FB_PROTO_ID, 1); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_I_L3_PROTO_ID, proto); } else { ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_O_L3_FB_PROTO_ID, 1); ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_O_L3_PROTO_ID, proto); } } } /* Function to handle the parsing of RTE Flow item IPV4 Header. */ int32_t ulp_rte_ipv4_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_ipv4 *ipv4_spec = item->spec; const struct rte_flow_item_ipv4 *ipv4_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0, dip_idx = 0; uint32_t size; uint8_t proto = 0; uint32_t inner_flag = 0; uint32_t cnt; /* validate there are no 3rd L3 header */ cnt = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L3_HDR_CNT); if (cnt == 2) { BNXT_TF_DBG(ERR, "Parse Err:Third L3 header not supported\n"); return BNXT_TF_RC_ERROR; } if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_IPV4_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for ipv4 into hdr_field using ipv4 * header fields */ size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.version_ihl); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.version_ihl), ulp_deference_struct(ipv4_mask, hdr.version_ihl), ULP_PRSR_ACT_DEFAULT); /* * The tos field is ignored since OVS is setting it as wild card * match and it is not supported. This is a work around and * shall be addressed in the future. */ size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.type_of_service); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.type_of_service), ulp_deference_struct(ipv4_mask, hdr.type_of_service), ULP_PRSR_ACT_MASK_IGNORE); size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.total_length); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.total_length), ulp_deference_struct(ipv4_mask, hdr.total_length), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.packet_id); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.packet_id), ulp_deference_struct(ipv4_mask, hdr.packet_id), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.fragment_offset); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.fragment_offset), ulp_deference_struct(ipv4_mask, hdr.fragment_offset), ULP_PRSR_ACT_MASK_IGNORE); size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.time_to_live); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.time_to_live), ulp_deference_struct(ipv4_mask, hdr.time_to_live), ULP_PRSR_ACT_DEFAULT); /* Ignore proto for matching templates */ size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.next_proto_id); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.next_proto_id), ulp_deference_struct(ipv4_mask, hdr.next_proto_id), ULP_PRSR_ACT_MATCH_IGNORE); if (ipv4_spec) proto = ipv4_spec->hdr.next_proto_id; size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.hdr_checksum); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.hdr_checksum), ulp_deference_struct(ipv4_mask, hdr.hdr_checksum), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.src_addr); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.src_addr), ulp_deference_struct(ipv4_mask, hdr.src_addr), ULP_PRSR_ACT_DEFAULT); dip_idx = idx; size = sizeof(((struct rte_flow_item_ipv4 *)NULL)->hdr.dst_addr); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv4_spec, hdr.dst_addr), ulp_deference_struct(ipv4_mask, hdr.dst_addr), ULP_PRSR_ACT_DEFAULT); /* Set the ipv4 header bitmap and computed l3 header bitmaps */ if (ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV4) || ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV6) || ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L3_TUN)) { ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_I_IPV4); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L3, 1); inner_flag = 1; } else { ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV4); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L3, 1); /* Update the tunnel offload dest ip offset */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_TUN_OFF_DIP_ID, dip_idx); } /* Some of the PMD applications may set the protocol field * in the IPv4 spec but don't set the mask. So, consider * the mask in the proto value calculation. */ if (ipv4_mask) proto &= ipv4_mask->hdr.next_proto_id; /* Update the field protocol hdr bitmap */ ulp_rte_l3_proto_type_update(params, proto, inner_flag); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L3_HDR_CNT, ++cnt); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item IPV6 Header */ int32_t ulp_rte_ipv6_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_ipv6 *ipv6_spec = item->spec; const struct rte_flow_item_ipv6 *ipv6_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0, dip_idx = 0; uint32_t size; uint32_t ver_spec = 0, ver_mask = 0; uint32_t tc_spec = 0, tc_mask = 0; uint32_t lab_spec = 0, lab_mask = 0; uint8_t proto = 0; uint32_t inner_flag = 0; uint32_t cnt; /* validate there are no 3rd L3 header */ cnt = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L3_HDR_CNT); if (cnt == 2) { BNXT_TF_DBG(ERR, "Parse Err:Third L3 header not supported\n"); return BNXT_TF_RC_ERROR; } if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_IPV6_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for ipv6 into hdr_field using ipv6 * header fields */ if (ipv6_spec) { ver_spec = BNXT_ULP_GET_IPV6_VER(ipv6_spec->hdr.vtc_flow); tc_spec = BNXT_ULP_GET_IPV6_TC(ipv6_spec->hdr.vtc_flow); lab_spec = BNXT_ULP_GET_IPV6_FLOWLABEL(ipv6_spec->hdr.vtc_flow); proto = ipv6_spec->hdr.proto; } if (ipv6_mask) { ver_mask = BNXT_ULP_GET_IPV6_VER(ipv6_mask->hdr.vtc_flow); tc_mask = BNXT_ULP_GET_IPV6_TC(ipv6_mask->hdr.vtc_flow); lab_mask = BNXT_ULP_GET_IPV6_FLOWLABEL(ipv6_mask->hdr.vtc_flow); /* Some of the PMD applications may set the protocol field * in the IPv6 spec but don't set the mask. So, consider * the mask in proto value calculation. */ proto &= ipv6_mask->hdr.proto; } size = sizeof(((struct rte_flow_item_ipv6 *)NULL)->hdr.vtc_flow); ulp_rte_prsr_fld_mask(params, &idx, size, &ver_spec, &ver_mask, ULP_PRSR_ACT_DEFAULT); /* * The TC and flow label field are ignored since OVS is * setting it for match and it is not supported. * This is a work around and * shall be addressed in the future. */ ulp_rte_prsr_fld_mask(params, &idx, size, &tc_spec, &tc_mask, ULP_PRSR_ACT_MASK_IGNORE); ulp_rte_prsr_fld_mask(params, &idx, size, &lab_spec, &lab_mask, ULP_PRSR_ACT_MASK_IGNORE); size = sizeof(((struct rte_flow_item_ipv6 *)NULL)->hdr.payload_len); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv6_spec, hdr.payload_len), ulp_deference_struct(ipv6_mask, hdr.payload_len), ULP_PRSR_ACT_DEFAULT); /* Ignore proto for template matching */ size = sizeof(((struct rte_flow_item_ipv6 *)NULL)->hdr.proto); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv6_spec, hdr.proto), ulp_deference_struct(ipv6_mask, hdr.proto), ULP_PRSR_ACT_MATCH_IGNORE); size = sizeof(((struct rte_flow_item_ipv6 *)NULL)->hdr.hop_limits); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv6_spec, hdr.hop_limits), ulp_deference_struct(ipv6_mask, hdr.hop_limits), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_ipv6 *)NULL)->hdr.src_addr); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv6_spec, hdr.src_addr), ulp_deference_struct(ipv6_mask, hdr.src_addr), ULP_PRSR_ACT_DEFAULT); dip_idx = idx; size = sizeof(((struct rte_flow_item_ipv6 *)NULL)->hdr.dst_addr); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(ipv6_spec, hdr.dst_addr), ulp_deference_struct(ipv6_mask, hdr.dst_addr), ULP_PRSR_ACT_DEFAULT); /* Set the ipv6 header bitmap and computed l3 header bitmaps */ if (ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV4) || ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV6) || ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L3_TUN)) { ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_I_IPV6); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L3, 1); inner_flag = 1; } else { ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV6); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L3, 1); /* Update the tunnel offload dest ip offset */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_TUN_OFF_DIP_ID, dip_idx); } /* Update the field protocol hdr bitmap */ ulp_rte_l3_proto_type_update(params, proto, inner_flag); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L3_HDR_CNT, ++cnt); return BNXT_TF_RC_SUCCESS; } /* Function to handle the update of proto header based on field values */ static void ulp_rte_l4_proto_type_update(struct ulp_rte_parser_params *params, uint16_t src_port, uint16_t src_mask, uint16_t dst_port, uint16_t dst_mask, enum bnxt_ulp_hdr_bit hdr_bit) { switch (hdr_bit) { case BNXT_ULP_HDR_BIT_I_UDP: case BNXT_ULP_HDR_BIT_I_TCP: ULP_BITMAP_SET(params->hdr_bitmap.bits, hdr_bit); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4_SRC_PORT, (uint64_t)rte_be_to_cpu_16(src_port)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4_DST_PORT, (uint64_t)rte_be_to_cpu_16(dst_port)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4_SRC_PORT_MASK, (uint64_t)rte_be_to_cpu_16(src_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4_DST_PORT_MASK, (uint64_t)rte_be_to_cpu_16(dst_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L3_FB_PROTO_ID, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4_FB_SRC_PORT, !!(src_port & src_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L4_FB_DST_PORT, !!(dst_port & dst_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_I_L3_PROTO_ID, (hdr_bit == BNXT_ULP_HDR_BIT_I_UDP) ? IPPROTO_UDP : IPPROTO_TCP); break; case BNXT_ULP_HDR_BIT_O_UDP: case BNXT_ULP_HDR_BIT_O_TCP: ULP_BITMAP_SET(params->hdr_bitmap.bits, hdr_bit); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4_SRC_PORT, (uint64_t)rte_be_to_cpu_16(src_port)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4_DST_PORT, (uint64_t)rte_be_to_cpu_16(dst_port)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4_SRC_PORT_MASK, (uint64_t)rte_be_to_cpu_16(src_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4_DST_PORT_MASK, (uint64_t)rte_be_to_cpu_16(dst_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L3_FB_PROTO_ID, 1); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4_FB_SRC_PORT, !!(src_port & src_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L4_FB_DST_PORT, !!(dst_port & dst_mask)); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_O_L3_PROTO_ID, (hdr_bit == BNXT_ULP_HDR_BIT_O_UDP) ? IPPROTO_UDP : IPPROTO_TCP); break; default: break; } if (hdr_bit == BNXT_ULP_HDR_BIT_O_UDP && dst_port == tfp_cpu_to_be_16(ULP_UDP_PORT_VXLAN)) { ULP_BITMAP_SET(params->hdr_fp_bit.bits, BNXT_ULP_HDR_BIT_T_VXLAN); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L3_TUN, 1); } } /* Function to handle the parsing of RTE Flow item UDP Header. */ int32_t ulp_rte_udp_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_udp *udp_spec = item->spec; const struct rte_flow_item_udp *udp_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0; uint32_t size; uint16_t dport = 0, sport = 0; uint16_t dport_mask = 0, sport_mask = 0; uint32_t cnt; enum bnxt_ulp_hdr_bit out_l4 = BNXT_ULP_HDR_BIT_O_UDP; cnt = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L4_HDR_CNT); if (cnt == 2) { BNXT_TF_DBG(ERR, "Parse Err:Third L4 header not supported\n"); return BNXT_TF_RC_ERROR; } if (udp_spec) { sport = udp_spec->hdr.src_port; dport = udp_spec->hdr.dst_port; } if (udp_mask) { sport_mask = udp_mask->hdr.src_port; dport_mask = udp_mask->hdr.dst_port; } if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_UDP_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for ipv4 into hdr_field using ipv4 * header fields */ size = sizeof(((struct rte_flow_item_udp *)NULL)->hdr.src_port); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(udp_spec, hdr.src_port), ulp_deference_struct(udp_mask, hdr.src_port), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_udp *)NULL)->hdr.dst_port); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(udp_spec, hdr.dst_port), ulp_deference_struct(udp_mask, hdr.dst_port), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_udp *)NULL)->hdr.dgram_len); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(udp_spec, hdr.dgram_len), ulp_deference_struct(udp_mask, hdr.dgram_len), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_udp *)NULL)->hdr.dgram_cksum); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(udp_spec, hdr.dgram_cksum), ulp_deference_struct(udp_mask, hdr.dgram_cksum), ULP_PRSR_ACT_DEFAULT); /* Set the udp header bitmap and computed l4 header bitmaps */ if (ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_UDP) || ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_TCP)) out_l4 = BNXT_ULP_HDR_BIT_I_UDP; ulp_rte_l4_proto_type_update(params, sport, sport_mask, dport, dport_mask, out_l4); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L4_HDR_CNT, ++cnt); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item TCP Header. */ int32_t ulp_rte_tcp_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_tcp *tcp_spec = item->spec; const struct rte_flow_item_tcp *tcp_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0; uint16_t dport = 0, sport = 0; uint16_t dport_mask = 0, sport_mask = 0; uint32_t size; uint32_t cnt; enum bnxt_ulp_hdr_bit out_l4 = BNXT_ULP_HDR_BIT_O_TCP; cnt = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L4_HDR_CNT); if (cnt == 2) { BNXT_TF_DBG(ERR, "Parse Err:Third L4 header not supported\n"); return BNXT_TF_RC_ERROR; } if (tcp_spec) { sport = tcp_spec->hdr.src_port; dport = tcp_spec->hdr.dst_port; } if (tcp_mask) { sport_mask = tcp_mask->hdr.src_port; dport_mask = tcp_mask->hdr.dst_port; } if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_TCP_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for ipv4 into hdr_field using ipv4 * header fields */ size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.src_port); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.src_port), ulp_deference_struct(tcp_mask, hdr.src_port), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.dst_port); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.dst_port), ulp_deference_struct(tcp_mask, hdr.dst_port), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.sent_seq); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.sent_seq), ulp_deference_struct(tcp_mask, hdr.sent_seq), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.recv_ack); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.recv_ack), ulp_deference_struct(tcp_mask, hdr.recv_ack), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.data_off); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.data_off), ulp_deference_struct(tcp_mask, hdr.data_off), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.tcp_flags); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.tcp_flags), ulp_deference_struct(tcp_mask, hdr.tcp_flags), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.rx_win); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.rx_win), ulp_deference_struct(tcp_mask, hdr.rx_win), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.cksum); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.cksum), ulp_deference_struct(tcp_mask, hdr.cksum), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_tcp *)NULL)->hdr.tcp_urp); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(tcp_spec, hdr.tcp_urp), ulp_deference_struct(tcp_mask, hdr.tcp_urp), ULP_PRSR_ACT_DEFAULT); /* Set the udp header bitmap and computed l4 header bitmaps */ if (ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_UDP) || ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_TCP)) out_l4 = BNXT_ULP_HDR_BIT_I_TCP; ulp_rte_l4_proto_type_update(params, sport, sport_mask, dport, dport_mask, out_l4); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L4_HDR_CNT, ++cnt); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item Vxlan Header. */ int32_t ulp_rte_vxlan_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_vxlan *vxlan_spec = item->spec; const struct rte_flow_item_vxlan *vxlan_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0; uint32_t size; if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_VXLAN_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } /* * Copy the rte_flow_item for vxlan into hdr_field using vxlan * header fields */ size = sizeof(((struct rte_flow_item_vxlan *)NULL)->flags); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(vxlan_spec, flags), ulp_deference_struct(vxlan_mask, flags), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_vxlan *)NULL)->rsvd0); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(vxlan_spec, rsvd0), ulp_deference_struct(vxlan_mask, rsvd0), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_vxlan *)NULL)->vni); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(vxlan_spec, vni), ulp_deference_struct(vxlan_mask, vni), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_vxlan *)NULL)->rsvd1); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(vxlan_spec, rsvd1), ulp_deference_struct(vxlan_mask, rsvd1), ULP_PRSR_ACT_DEFAULT); /* Update the hdr_bitmap with vxlan */ ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_T_VXLAN); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L3_TUN, 1); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item GRE Header. */ int32_t ulp_rte_gre_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_gre *gre_spec = item->spec; const struct rte_flow_item_gre *gre_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0; uint32_t size; if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_GRE_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } size = sizeof(((struct rte_flow_item_gre *)NULL)->c_rsvd0_ver); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(gre_spec, c_rsvd0_ver), ulp_deference_struct(gre_mask, c_rsvd0_ver), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_gre *)NULL)->protocol); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(gre_spec, protocol), ulp_deference_struct(gre_mask, protocol), ULP_PRSR_ACT_DEFAULT); /* Update the hdr_bitmap with GRE */ ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_T_GRE); ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L3_TUN, 1); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item ANY. */ int32_t ulp_rte_item_any_handler(const struct rte_flow_item *item __rte_unused, struct ulp_rte_parser_params *params __rte_unused) { return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item ICMP Header. */ int32_t ulp_rte_icmp_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_icmp *icmp_spec = item->spec; const struct rte_flow_item_icmp *icmp_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0; uint32_t size; if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_ICMP_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } size = sizeof(((struct rte_flow_item_icmp *)NULL)->hdr.icmp_type); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, hdr.icmp_type), ulp_deference_struct(icmp_mask, hdr.icmp_type), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_icmp *)NULL)->hdr.icmp_code); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, hdr.icmp_code), ulp_deference_struct(icmp_mask, hdr.icmp_code), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_icmp *)NULL)->hdr.icmp_cksum); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, hdr.icmp_cksum), ulp_deference_struct(icmp_mask, hdr.icmp_cksum), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_icmp *)NULL)->hdr.icmp_ident); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, hdr.icmp_ident), ulp_deference_struct(icmp_mask, hdr.icmp_ident), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_icmp *)NULL)->hdr.icmp_seq_nb); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, hdr.icmp_seq_nb), ulp_deference_struct(icmp_mask, hdr.icmp_seq_nb), ULP_PRSR_ACT_DEFAULT); /* Update the hdr_bitmap with ICMP */ if (ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L3_TUN)) ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_I_ICMP); else ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_ICMP); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item ICMP6 Header. */ int32_t ulp_rte_icmp6_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { const struct rte_flow_item_icmp6 *icmp_spec = item->spec; const struct rte_flow_item_icmp6 *icmp_mask = item->mask; struct ulp_rte_hdr_bitmap *hdr_bitmap = ¶ms->hdr_bitmap; uint32_t idx = 0; uint32_t size; if (ulp_rte_prsr_fld_size_validate(params, &idx, BNXT_ULP_PROTO_HDR_ICMP_NUM)) { BNXT_TF_DBG(ERR, "Error parsing protocol header\n"); return BNXT_TF_RC_ERROR; } size = sizeof(((struct rte_flow_item_icmp6 *)NULL)->type); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, type), ulp_deference_struct(icmp_mask, type), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_icmp6 *)NULL)->code); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, code), ulp_deference_struct(icmp_mask, code), ULP_PRSR_ACT_DEFAULT); size = sizeof(((struct rte_flow_item_icmp6 *)NULL)->checksum); ulp_rte_prsr_fld_mask(params, &idx, size, ulp_deference_struct(icmp_spec, checksum), ulp_deference_struct(icmp_mask, checksum), ULP_PRSR_ACT_DEFAULT); if (ULP_BITMAP_ISSET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_IPV4)) { BNXT_TF_DBG(ERR, "Error: incorrect icmp version\n"); return BNXT_TF_RC_ERROR; } /* Update the hdr_bitmap with ICMP */ if (ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_L3_TUN)) ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_I_ICMP); else ULP_BITMAP_SET(hdr_bitmap->bits, BNXT_ULP_HDR_BIT_O_ICMP); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item void Header */ int32_t ulp_rte_void_hdr_handler(const struct rte_flow_item *item __rte_unused, struct ulp_rte_parser_params *params __rte_unused) { return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action void Header. */ int32_t ulp_rte_void_act_handler(const struct rte_flow_action *action_item __rte_unused, struct ulp_rte_parser_params *params __rte_unused) { return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action Mark Header. */ int32_t ulp_rte_mark_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *param) { const struct rte_flow_action_mark *mark; struct ulp_rte_act_bitmap *act = ¶m->act_bitmap; uint32_t mark_id; mark = action_item->conf; if (mark) { mark_id = tfp_cpu_to_be_32(mark->id); memcpy(¶m->act_prop.act_details[BNXT_ULP_ACT_PROP_IDX_MARK], &mark_id, BNXT_ULP_ACT_PROP_SZ_MARK); /* Update the hdr_bitmap with vxlan */ ULP_BITMAP_SET(act->bits, BNXT_ULP_ACT_BIT_MARK); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: Mark arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action RSS Header. */ int32_t ulp_rte_rss_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *param) { const struct rte_flow_action_rss *rss; struct ulp_rte_act_prop *ap = ¶m->act_prop; if (action_item == NULL || action_item->conf == NULL) { BNXT_TF_DBG(ERR, "Parse Err: invalid rss configuration\n"); return BNXT_TF_RC_ERROR; } rss = action_item->conf; /* Copy the rss into the specific action properties */ memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_RSS_TYPES], &rss->types, BNXT_ULP_ACT_PROP_SZ_RSS_TYPES); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_RSS_LEVEL], &rss->level, BNXT_ULP_ACT_PROP_SZ_RSS_LEVEL); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_RSS_KEY_LEN], &rss->key_len, BNXT_ULP_ACT_PROP_SZ_RSS_KEY_LEN); if (rss->key_len > BNXT_ULP_ACT_PROP_SZ_RSS_KEY) { BNXT_TF_DBG(ERR, "Parse Err: RSS key too big\n"); return BNXT_TF_RC_ERROR; } memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_RSS_KEY], rss->key, rss->key_len); /* set the RSS action header bit */ ULP_BITMAP_SET(param->act_bitmap.bits, BNXT_ULP_ACT_BIT_RSS); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow item eth Header. */ static void ulp_rte_enc_eth_hdr_handler(struct ulp_rte_parser_params *params, const struct rte_flow_item_eth *eth_spec) { struct ulp_rte_hdr_field *field; uint32_t size; field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_ETH_DMAC]; size = sizeof(eth_spec->dst.addr_bytes); field = ulp_rte_parser_fld_copy(field, eth_spec->dst.addr_bytes, size); size = sizeof(eth_spec->src.addr_bytes); field = ulp_rte_parser_fld_copy(field, eth_spec->src.addr_bytes, size); size = sizeof(eth_spec->type); field = ulp_rte_parser_fld_copy(field, ð_spec->type, size); ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_ETH); } /* Function to handle the parsing of RTE Flow item vlan Header. */ static void ulp_rte_enc_vlan_hdr_handler(struct ulp_rte_parser_params *params, const struct rte_flow_item_vlan *vlan_spec, uint32_t inner) { struct ulp_rte_hdr_field *field; uint32_t size; if (!inner) { field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_O_VLAN_TCI]; ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_OO_VLAN); } else { field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_I_VLAN_TCI]; ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_OI_VLAN); } size = sizeof(vlan_spec->tci); field = ulp_rte_parser_fld_copy(field, &vlan_spec->tci, size); size = sizeof(vlan_spec->inner_type); field = ulp_rte_parser_fld_copy(field, &vlan_spec->inner_type, size); } /* Function to handle the parsing of RTE Flow item ipv4 Header. */ static void ulp_rte_enc_ipv4_hdr_handler(struct ulp_rte_parser_params *params, const struct rte_flow_item_ipv4 *ip) { struct ulp_rte_hdr_field *field; uint32_t size; uint8_t val8; field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_IPV4_IHL]; size = sizeof(ip->hdr.version_ihl); if (!ip->hdr.version_ihl) val8 = RTE_IPV4_VHL_DEF; else val8 = ip->hdr.version_ihl; field = ulp_rte_parser_fld_copy(field, &val8, size); size = sizeof(ip->hdr.type_of_service); field = ulp_rte_parser_fld_copy(field, &ip->hdr.type_of_service, size); size = sizeof(ip->hdr.packet_id); field = ulp_rte_parser_fld_copy(field, &ip->hdr.packet_id, size); size = sizeof(ip->hdr.fragment_offset); field = ulp_rte_parser_fld_copy(field, &ip->hdr.fragment_offset, size); size = sizeof(ip->hdr.time_to_live); if (!ip->hdr.time_to_live) val8 = BNXT_ULP_DEFAULT_TTL; else val8 = ip->hdr.time_to_live; field = ulp_rte_parser_fld_copy(field, &val8, size); size = sizeof(ip->hdr.next_proto_id); field = ulp_rte_parser_fld_copy(field, &ip->hdr.next_proto_id, size); size = sizeof(ip->hdr.src_addr); field = ulp_rte_parser_fld_copy(field, &ip->hdr.src_addr, size); size = sizeof(ip->hdr.dst_addr); field = ulp_rte_parser_fld_copy(field, &ip->hdr.dst_addr, size); ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_IPV4); } /* Function to handle the parsing of RTE Flow item ipv6 Header. */ static void ulp_rte_enc_ipv6_hdr_handler(struct ulp_rte_parser_params *params, const struct rte_flow_item_ipv6 *ip) { struct ulp_rte_hdr_field *field; uint32_t size; uint32_t val32; uint8_t val8; field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_IPV6_VTC_FLOW]; size = sizeof(ip->hdr.vtc_flow); if (!ip->hdr.vtc_flow) val32 = rte_cpu_to_be_32(BNXT_ULP_IPV6_DFLT_VER); else val32 = ip->hdr.vtc_flow; field = ulp_rte_parser_fld_copy(field, &val32, size); size = sizeof(ip->hdr.proto); field = ulp_rte_parser_fld_copy(field, &ip->hdr.proto, size); size = sizeof(ip->hdr.hop_limits); if (!ip->hdr.hop_limits) val8 = BNXT_ULP_DEFAULT_TTL; else val8 = ip->hdr.hop_limits; field = ulp_rte_parser_fld_copy(field, &val8, size); size = sizeof(ip->hdr.src_addr); field = ulp_rte_parser_fld_copy(field, &ip->hdr.src_addr, size); size = sizeof(ip->hdr.dst_addr); field = ulp_rte_parser_fld_copy(field, &ip->hdr.dst_addr, size); ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_IPV6); } /* Function to handle the parsing of RTE Flow item UDP Header. */ static void ulp_rte_enc_udp_hdr_handler(struct ulp_rte_parser_params *params, const struct rte_flow_item_udp *udp_spec) { struct ulp_rte_hdr_field *field; uint32_t size; uint8_t type = IPPROTO_UDP; field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_UDP_SPORT]; size = sizeof(udp_spec->hdr.src_port); field = ulp_rte_parser_fld_copy(field, &udp_spec->hdr.src_port, size); size = sizeof(udp_spec->hdr.dst_port); field = ulp_rte_parser_fld_copy(field, &udp_spec->hdr.dst_port, size); ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_O_UDP); /* Update thhe ip header protocol */ field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_IPV4_PROTO]; ulp_rte_parser_fld_copy(field, &type, sizeof(type)); field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_IPV6_PROTO]; ulp_rte_parser_fld_copy(field, &type, sizeof(type)); } /* Function to handle the parsing of RTE Flow item vxlan Header. */ static void ulp_rte_enc_vxlan_hdr_handler(struct ulp_rte_parser_params *params, struct rte_flow_item_vxlan *vxlan_spec) { struct ulp_rte_hdr_field *field; uint32_t size; field = ¶ms->enc_field[BNXT_ULP_ENC_FIELD_VXLAN_FLAGS]; size = sizeof(vxlan_spec->flags); field = ulp_rte_parser_fld_copy(field, &vxlan_spec->flags, size); size = sizeof(vxlan_spec->rsvd0); field = ulp_rte_parser_fld_copy(field, &vxlan_spec->rsvd0, size); size = sizeof(vxlan_spec->vni); field = ulp_rte_parser_fld_copy(field, &vxlan_spec->vni, size); size = sizeof(vxlan_spec->rsvd1); field = ulp_rte_parser_fld_copy(field, &vxlan_spec->rsvd1, size); ULP_BITMAP_SET(params->enc_hdr_bitmap.bits, BNXT_ULP_HDR_BIT_T_VXLAN); } /* Function to handle the parsing of RTE Flow action vxlan_encap Header. */ int32_t ulp_rte_vxlan_encap_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_vxlan_encap *vxlan_encap; const struct rte_flow_item *item; const struct rte_flow_item_ipv4 *ipv4_spec; const struct rte_flow_item_ipv6 *ipv6_spec; struct rte_flow_item_vxlan vxlan_spec; uint32_t vlan_num = 0, vlan_size = 0; uint32_t ip_size = 0, ip_type = 0; uint32_t vxlan_size = 0; struct ulp_rte_act_bitmap *act = ¶ms->act_bitmap; struct ulp_rte_act_prop *ap = ¶ms->act_prop; vxlan_encap = action_item->conf; if (!vxlan_encap) { BNXT_TF_DBG(ERR, "Parse Error: Vxlan_encap arg is invalid\n"); return BNXT_TF_RC_ERROR; } item = vxlan_encap->definition; if (!item) { BNXT_TF_DBG(ERR, "Parse Error: definition arg is invalid\n"); return BNXT_TF_RC_ERROR; } if (!ulp_rte_item_skip_void(&item, 0)) return BNXT_TF_RC_ERROR; /* must have ethernet header */ if (item->type != RTE_FLOW_ITEM_TYPE_ETH) { BNXT_TF_DBG(ERR, "Parse Error:vxlan encap does not have eth\n"); return BNXT_TF_RC_ERROR; } /* Parse the ethernet header */ if (item->spec) ulp_rte_enc_eth_hdr_handler(params, item->spec); /* Goto the next item */ if (!ulp_rte_item_skip_void(&item, 1)) return BNXT_TF_RC_ERROR; /* May have vlan header */ if (item->type == RTE_FLOW_ITEM_TYPE_VLAN) { vlan_num++; if (item->spec) ulp_rte_enc_vlan_hdr_handler(params, item->spec, 0); if (!ulp_rte_item_skip_void(&item, 1)) return BNXT_TF_RC_ERROR; } /* may have two vlan headers */ if (item->type == RTE_FLOW_ITEM_TYPE_VLAN) { vlan_num++; if (item->spec) ulp_rte_enc_vlan_hdr_handler(params, item->spec, 1); if (!ulp_rte_item_skip_void(&item, 1)) return BNXT_TF_RC_ERROR; } /* Update the vlan count and size of more than one */ if (vlan_num) { vlan_size = vlan_num * sizeof(struct rte_flow_item_vlan); vlan_num = tfp_cpu_to_be_32(vlan_num); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_VTAG_NUM], &vlan_num, sizeof(uint32_t)); vlan_size = tfp_cpu_to_be_32(vlan_size); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_VTAG_SZ], &vlan_size, sizeof(uint32_t)); } /* L3 must be IPv4, IPv6 */ if (item->type == RTE_FLOW_ITEM_TYPE_IPV4) { ipv4_spec = item->spec; ip_size = BNXT_ULP_ENCAP_IPV4_SIZE; /* Update the ip size details */ ip_size = tfp_cpu_to_be_32(ip_size); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_IP_SZ], &ip_size, sizeof(uint32_t)); /* update the ip type */ ip_type = rte_cpu_to_be_32(BNXT_ULP_ETH_IPV4); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_L3_TYPE], &ip_type, sizeof(uint32_t)); /* update the computed field to notify it is ipv4 header */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_ENCAP_IPV4_FLAG, 1); if (ipv4_spec) ulp_rte_enc_ipv4_hdr_handler(params, ipv4_spec); if (!ulp_rte_item_skip_void(&item, 1)) return BNXT_TF_RC_ERROR; } else if (item->type == RTE_FLOW_ITEM_TYPE_IPV6) { ipv6_spec = item->spec; ip_size = BNXT_ULP_ENCAP_IPV6_SIZE; /* Update the ip size details */ ip_size = tfp_cpu_to_be_32(ip_size); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_IP_SZ], &ip_size, sizeof(uint32_t)); /* update the ip type */ ip_type = rte_cpu_to_be_32(BNXT_ULP_ETH_IPV6); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_L3_TYPE], &ip_type, sizeof(uint32_t)); /* update the computed field to notify it is ipv6 header */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_ENCAP_IPV6_FLAG, 1); if (ipv6_spec) ulp_rte_enc_ipv6_hdr_handler(params, ipv6_spec); if (!ulp_rte_item_skip_void(&item, 1)) return BNXT_TF_RC_ERROR; } else { BNXT_TF_DBG(ERR, "Parse Error: Vxlan Encap expects L3 hdr\n"); return BNXT_TF_RC_ERROR; } /* L4 is UDP */ if (item->type != RTE_FLOW_ITEM_TYPE_UDP) { BNXT_TF_DBG(ERR, "vxlan encap does not have udp\n"); return BNXT_TF_RC_ERROR; } if (item->spec) ulp_rte_enc_udp_hdr_handler(params, item->spec); if (!ulp_rte_item_skip_void(&item, 1)) return BNXT_TF_RC_ERROR; /* Finally VXLAN */ if (item->type != RTE_FLOW_ITEM_TYPE_VXLAN) { BNXT_TF_DBG(ERR, "vxlan encap does not have vni\n"); return BNXT_TF_RC_ERROR; } vxlan_size = sizeof(struct rte_flow_item_vxlan); /* copy the vxlan details */ memcpy(&vxlan_spec, item->spec, vxlan_size); vxlan_spec.flags = 0x08; vxlan_size = tfp_cpu_to_be_32(vxlan_size); memcpy(&ap->act_details[BNXT_ULP_ACT_PROP_IDX_ENCAP_TUN_SZ], &vxlan_size, sizeof(uint32_t)); ulp_rte_enc_vxlan_hdr_handler(params, &vxlan_spec); /* update the hdr_bitmap with vxlan */ ULP_BITMAP_SET(act->bits, BNXT_ULP_ACT_BIT_VXLAN_ENCAP); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action vxlan_encap Header */ int32_t ulp_rte_vxlan_decap_act_handler(const struct rte_flow_action *action_item __rte_unused, struct ulp_rte_parser_params *params) { /* update the hdr_bitmap with vxlan */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_VXLAN_DECAP); /* Update computational field with tunnel decap info */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_L3_TUN_DECAP, 1); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action drop Header. */ int32_t ulp_rte_drop_act_handler(const struct rte_flow_action *action_item __rte_unused, struct ulp_rte_parser_params *params) { /* Update the hdr_bitmap with drop */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_DROP); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action count. */ int32_t ulp_rte_count_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_count *act_count; struct ulp_rte_act_prop *act_prop = ¶ms->act_prop; act_count = action_item->conf; if (act_count) { memcpy(&act_prop->act_details[BNXT_ULP_ACT_PROP_IDX_COUNT], &act_count->id, BNXT_ULP_ACT_PROP_SZ_COUNT); } /* Update the hdr_bitmap with count */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_COUNT); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of action ports. */ static int32_t ulp_rte_parser_act_port_set(struct ulp_rte_parser_params *param, uint32_t ifindex, enum bnxt_ulp_direction_type act_dir) { enum bnxt_ulp_direction_type dir; uint16_t pid_s; uint32_t pid; struct ulp_rte_act_prop *act = ¶m->act_prop; enum bnxt_ulp_intf_type port_type; uint32_t vnic_type; /* Get the direction */ /* If action implicitly specifies direction, use the specification. */ dir = (act_dir == BNXT_ULP_DIR_INVALID) ? ULP_COMP_FLD_IDX_RD(param, BNXT_ULP_CF_IDX_DIRECTION) : act_dir; port_type = ULP_COMP_FLD_IDX_RD(param, BNXT_ULP_CF_IDX_ACT_PORT_TYPE); if (dir == BNXT_ULP_DIR_EGRESS && port_type != BNXT_ULP_INTF_TYPE_VF_REP) { /* For egress direction, fill vport */ if (ulp_port_db_vport_get(param->ulp_ctx, ifindex, &pid_s)) return BNXT_TF_RC_ERROR; pid = pid_s; pid = rte_cpu_to_be_32(pid); memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_VPORT], &pid, BNXT_ULP_ACT_PROP_SZ_VPORT); } else { /* For ingress direction, fill vnic */ /* * Action Destination * ------------------------------------ * PORT_REPRESENTOR Driver Function * ------------------------------------ * REPRESENTED_PORT VF * ------------------------------------ * PORT_ID VF */ if (act_dir != BNXT_ULP_DIR_INGRESS && port_type == BNXT_ULP_INTF_TYPE_VF_REP) vnic_type = BNXT_ULP_VF_FUNC_VNIC; else vnic_type = BNXT_ULP_DRV_FUNC_VNIC; if (ulp_port_db_default_vnic_get(param->ulp_ctx, ifindex, vnic_type, &pid_s)) return BNXT_TF_RC_ERROR; pid = pid_s; pid = rte_cpu_to_be_32(pid); memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_VNIC], &pid, BNXT_ULP_ACT_PROP_SZ_VNIC); } /* Update the action port set bit */ ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_ACT_PORT_IS_SET, 1); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action PF. */ int32_t ulp_rte_pf_act_handler(const struct rte_flow_action *action_item __rte_unused, struct ulp_rte_parser_params *params) { uint32_t port_id; uint32_t ifindex; enum bnxt_ulp_intf_type intf_type; /* Get the port id of the current device */ port_id = ULP_COMP_FLD_IDX_RD(params, BNXT_ULP_CF_IDX_INCOMING_IF); /* Get the port db ifindex */ if (ulp_port_db_dev_port_to_ulp_index(params->ulp_ctx, port_id, &ifindex)) { BNXT_TF_DBG(ERR, "Invalid port id\n"); return BNXT_TF_RC_ERROR; } /* Check the port is PF port */ intf_type = ulp_port_db_port_type_get(params->ulp_ctx, ifindex); if (intf_type != BNXT_ULP_INTF_TYPE_PF) { BNXT_TF_DBG(ERR, "Port is not a PF port\n"); return BNXT_TF_RC_ERROR; } /* Update the action properties */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_PORT_TYPE, intf_type); return ulp_rte_parser_act_port_set(params, ifindex, BNXT_ULP_DIR_INVALID); } /* Function to handle the parsing of RTE Flow action VF. */ int32_t ulp_rte_vf_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_vf *vf_action; enum bnxt_ulp_intf_type intf_type; uint32_t ifindex; struct bnxt *bp; vf_action = action_item->conf; if (!vf_action) { BNXT_TF_DBG(ERR, "ParseErr: Invalid Argument\n"); return BNXT_TF_RC_PARSE_ERR; } if (vf_action->original) { BNXT_TF_DBG(ERR, "ParseErr:VF Original not supported\n"); return BNXT_TF_RC_PARSE_ERR; } bp = bnxt_pmd_get_bp(params->port_id); if (bp == NULL) { BNXT_TF_DBG(ERR, "Invalid bp\n"); return BNXT_TF_RC_ERROR; } /* vf_action->id is a logical number which in this case is an * offset from the first VF. So, to get the absolute VF id, the * offset must be added to the absolute first vf id of that port. */ if (ulp_port_db_dev_func_id_to_ulp_index(params->ulp_ctx, bp->first_vf_id + vf_action->id, &ifindex)) { BNXT_TF_DBG(ERR, "VF is not valid interface\n"); return BNXT_TF_RC_ERROR; } /* Check the port is VF port */ intf_type = ulp_port_db_port_type_get(params->ulp_ctx, ifindex); if (intf_type != BNXT_ULP_INTF_TYPE_VF && intf_type != BNXT_ULP_INTF_TYPE_TRUSTED_VF) { BNXT_TF_DBG(ERR, "Port is not a VF port\n"); return BNXT_TF_RC_ERROR; } /* Update the action properties */ ULP_COMP_FLD_IDX_WR(params, BNXT_ULP_CF_IDX_ACT_PORT_TYPE, intf_type); return ulp_rte_parser_act_port_set(params, ifindex, BNXT_ULP_DIR_INVALID); } /* Parse actions PORT_ID, PORT_REPRESENTOR and REPRESENTED_PORT. */ int32_t ulp_rte_port_act_handler(const struct rte_flow_action *act_item, struct ulp_rte_parser_params *param) { uint32_t ethdev_id; uint32_t ifindex; enum bnxt_ulp_intf_type intf_type; enum bnxt_ulp_direction_type act_dir; if (!act_item->conf) { BNXT_TF_DBG(ERR, "ParseErr: Invalid Argument\n"); return BNXT_TF_RC_PARSE_ERR; } switch (act_item->type) { case RTE_FLOW_ACTION_TYPE_PORT_ID: { const struct rte_flow_action_port_id *port_id = act_item->conf; if (port_id->original) { BNXT_TF_DBG(ERR, "ParseErr:Portid Original not supported\n"); return BNXT_TF_RC_PARSE_ERR; } ethdev_id = port_id->id; act_dir = BNXT_ULP_DIR_INVALID; break; } case RTE_FLOW_ACTION_TYPE_PORT_REPRESENTOR: { const struct rte_flow_action_ethdev *ethdev = act_item->conf; ethdev_id = ethdev->port_id; act_dir = BNXT_ULP_DIR_INGRESS; break; } case RTE_FLOW_ACTION_TYPE_REPRESENTED_PORT: { const struct rte_flow_action_ethdev *ethdev = act_item->conf; ethdev_id = ethdev->port_id; act_dir = BNXT_ULP_DIR_EGRESS; break; } default: BNXT_TF_DBG(ERR, "Unknown port action\n"); return BNXT_TF_RC_ERROR; } /* Get the port db ifindex */ if (ulp_port_db_dev_port_to_ulp_index(param->ulp_ctx, ethdev_id, &ifindex)) { BNXT_TF_DBG(ERR, "Invalid port id\n"); return BNXT_TF_RC_ERROR; } /* Get the intf type */ intf_type = ulp_port_db_port_type_get(param->ulp_ctx, ifindex); if (!intf_type) { BNXT_TF_DBG(ERR, "Invalid port type\n"); return BNXT_TF_RC_ERROR; } /* Set the action port */ ULP_COMP_FLD_IDX_WR(param, BNXT_ULP_CF_IDX_ACT_PORT_TYPE, intf_type); return ulp_rte_parser_act_port_set(param, ifindex, act_dir); } /* Function to handle the parsing of RTE Flow action phy_port. */ int32_t ulp_rte_phy_port_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *prm) { const struct rte_flow_action_phy_port *phy_port; uint32_t pid; int32_t rc; uint16_t pid_s; enum bnxt_ulp_direction_type dir; phy_port = action_item->conf; if (!phy_port) { BNXT_TF_DBG(ERR, "ParseErr: Invalid Argument\n"); return BNXT_TF_RC_PARSE_ERR; } if (phy_port->original) { BNXT_TF_DBG(ERR, "Parse Err:Port Original not supported\n"); return BNXT_TF_RC_PARSE_ERR; } dir = ULP_COMP_FLD_IDX_RD(prm, BNXT_ULP_CF_IDX_DIRECTION); if (dir != BNXT_ULP_DIR_EGRESS) { BNXT_TF_DBG(ERR, "Parse Err:Phy ports are valid only for egress\n"); return BNXT_TF_RC_PARSE_ERR; } /* Get the physical port details from port db */ rc = ulp_port_db_phy_port_vport_get(prm->ulp_ctx, phy_port->index, &pid_s); if (rc) { BNXT_TF_DBG(ERR, "Failed to get port details\n"); return -EINVAL; } pid = pid_s; pid = rte_cpu_to_be_32(pid); memcpy(&prm->act_prop.act_details[BNXT_ULP_ACT_PROP_IDX_VPORT], &pid, BNXT_ULP_ACT_PROP_SZ_VPORT); /* Update the action port set bit */ ULP_COMP_FLD_IDX_WR(prm, BNXT_ULP_CF_IDX_ACT_PORT_IS_SET, 1); ULP_COMP_FLD_IDX_WR(prm, BNXT_ULP_CF_IDX_ACT_PORT_TYPE, BNXT_ULP_INTF_TYPE_PHY_PORT); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action pop vlan. */ int32_t ulp_rte_of_pop_vlan_act_handler(const struct rte_flow_action *a __rte_unused, struct ulp_rte_parser_params *params) { /* Update the act_bitmap with pop */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_POP_VLAN); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action push vlan. */ int32_t ulp_rte_of_push_vlan_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_of_push_vlan *push_vlan; uint16_t ethertype; struct ulp_rte_act_prop *act = ¶ms->act_prop; push_vlan = action_item->conf; if (push_vlan) { ethertype = push_vlan->ethertype; if (tfp_cpu_to_be_16(ethertype) != RTE_ETHER_TYPE_VLAN) { BNXT_TF_DBG(ERR, "Parse Err: Ethertype not supported\n"); return BNXT_TF_RC_PARSE_ERR; } memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_PUSH_VLAN], ðertype, BNXT_ULP_ACT_PROP_SZ_PUSH_VLAN); /* Update the hdr_bitmap with push vlan */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_PUSH_VLAN); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: Push vlan arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action set vlan id. */ int32_t ulp_rte_of_set_vlan_vid_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_of_set_vlan_vid *vlan_vid; uint32_t vid; struct ulp_rte_act_prop *act = ¶ms->act_prop; vlan_vid = action_item->conf; if (vlan_vid && vlan_vid->vlan_vid) { vid = vlan_vid->vlan_vid; memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_SET_VLAN_VID], &vid, BNXT_ULP_ACT_PROP_SZ_SET_VLAN_VID); /* Update the hdr_bitmap with vlan vid */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SET_VLAN_VID); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: Vlan vid arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action set vlan pcp. */ int32_t ulp_rte_of_set_vlan_pcp_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_of_set_vlan_pcp *vlan_pcp; uint8_t pcp; struct ulp_rte_act_prop *act = ¶ms->act_prop; vlan_pcp = action_item->conf; if (vlan_pcp) { pcp = vlan_pcp->vlan_pcp; memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_SET_VLAN_PCP], &pcp, BNXT_ULP_ACT_PROP_SZ_SET_VLAN_PCP); /* Update the hdr_bitmap with vlan vid */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SET_VLAN_PCP); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: Vlan pcp arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action set ipv4 src.*/ int32_t ulp_rte_set_ipv4_src_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_set_ipv4 *set_ipv4; struct ulp_rte_act_prop *act = ¶ms->act_prop; set_ipv4 = action_item->conf; if (set_ipv4) { memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_SET_IPV4_SRC], &set_ipv4->ipv4_addr, BNXT_ULP_ACT_PROP_SZ_SET_IPV4_SRC); /* Update the hdr_bitmap with set ipv4 src */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SET_IPV4_SRC); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: set ipv4 src arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action set ipv4 dst.*/ int32_t ulp_rte_set_ipv4_dst_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_set_ipv4 *set_ipv4; struct ulp_rte_act_prop *act = ¶ms->act_prop; set_ipv4 = action_item->conf; if (set_ipv4) { memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_SET_IPV4_DST], &set_ipv4->ipv4_addr, BNXT_ULP_ACT_PROP_SZ_SET_IPV4_DST); /* Update the hdr_bitmap with set ipv4 dst */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SET_IPV4_DST); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: set ipv4 dst arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action set tp src.*/ int32_t ulp_rte_set_tp_src_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_set_tp *set_tp; struct ulp_rte_act_prop *act = ¶ms->act_prop; set_tp = action_item->conf; if (set_tp) { memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_SET_TP_SRC], &set_tp->port, BNXT_ULP_ACT_PROP_SZ_SET_TP_SRC); /* Update the hdr_bitmap with set tp src */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SET_TP_SRC); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: set tp src arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action set tp dst.*/ int32_t ulp_rte_set_tp_dst_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_set_tp *set_tp; struct ulp_rte_act_prop *act = ¶ms->act_prop; set_tp = action_item->conf; if (set_tp) { memcpy(&act->act_details[BNXT_ULP_ACT_PROP_IDX_SET_TP_DST], &set_tp->port, BNXT_ULP_ACT_PROP_SZ_SET_TP_DST); /* Update the hdr_bitmap with set tp dst */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SET_TP_DST); return BNXT_TF_RC_SUCCESS; } BNXT_TF_DBG(ERR, "Parse Error: set tp src arg is invalid\n"); return BNXT_TF_RC_ERROR; } /* Function to handle the parsing of RTE Flow action dec ttl.*/ int32_t ulp_rte_dec_ttl_act_handler(const struct rte_flow_action *act __rte_unused, struct ulp_rte_parser_params *params) { /* Update the act_bitmap with dec ttl */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_DEC_TTL); return BNXT_TF_RC_SUCCESS; } /* Function to handle the parsing of RTE Flow action JUMP */ int32_t ulp_rte_jump_act_handler(const struct rte_flow_action *action_item __rte_unused, struct ulp_rte_parser_params *params) { /* Update the act_bitmap with dec ttl */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_JUMP); return BNXT_TF_RC_SUCCESS; } int32_t ulp_rte_sample_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { const struct rte_flow_action_sample *sample; int ret; sample = action_item->conf; /* if SAMPLE bit is set it means this sample action is nested within the * actions of another sample action; this is not allowed */ if (ULP_BITMAP_ISSET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SAMPLE)) return BNXT_TF_RC_ERROR; /* a sample action is only allowed as a shared action */ if (!ULP_BITMAP_ISSET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SHARED)) return BNXT_TF_RC_ERROR; /* only a ratio of 1 i.e. 100% is supported */ if (sample->ratio != 1) return BNXT_TF_RC_ERROR; if (!sample->actions) return BNXT_TF_RC_ERROR; /* parse the nested actions for a sample action */ ret = bnxt_ulp_rte_parser_act_parse(sample->actions, params); if (ret == BNXT_TF_RC_SUCCESS) /* Update the act_bitmap with sample */ ULP_BITMAP_SET(params->act_bitmap.bits, BNXT_ULP_ACT_BIT_SAMPLE); return ret; } /* Function to handle the parsing of bnxt vendor Flow action vxlan Header. */ int32_t ulp_vendor_vxlan_decap_act_handler(const struct rte_flow_action *action_item, struct ulp_rte_parser_params *params) { /* Set the F1 flow header bit */ ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_F1); return ulp_rte_vxlan_decap_act_handler(action_item, params); } /* Function to handle the parsing of bnxt vendor Flow item vxlan Header. */ int32_t ulp_rte_vendor_vxlan_decap_hdr_handler(const struct rte_flow_item *item, struct ulp_rte_parser_params *params) { RTE_SET_USED(item); /* Set the F2 flow header bit */ ULP_BITMAP_SET(params->hdr_bitmap.bits, BNXT_ULP_HDR_BIT_F2); return ulp_rte_vxlan_decap_act_handler(NULL, params); }