net/sfc: support jump flows in tunnel offload

[dpdk.git] / drivers / net / sfc / sfc_mae.h

/* SPDX-License-Identifier: BSD-3-Clause
 *
 * Copyright(c) 2019-2021 Xilinx, Inc.
 * Copyright(c) 2019 Solarflare Communications Inc.
 *
 * This software was jointly developed between OKTET Labs (under contract
 * for Solarflare) and Solarflare Communications, Inc.
 */

#ifndef _SFC_MAE_H
#define _SFC_MAE_H

#include <stdbool.h>

#include <rte_spinlock.h>

#include "efx.h"

#include "sfc_stats.h"

#ifdef __cplusplus
extern "C" {
#endif

/** FW-allocatable resource context */
struct sfc_mae_fw_rsrc {
        unsigned int                    refcnt;
        RTE_STD_C11
        union {
                efx_mae_aset_id_t       aset_id;
                efx_mae_rule_id_t       rule_id;
                efx_mae_eh_id_t         eh_id;
        };
};

/** Outer rule registry entry */
struct sfc_mae_outer_rule {
        TAILQ_ENTRY(sfc_mae_outer_rule) entries;
        unsigned int                    refcnt;
        efx_mae_match_spec_t            *match_spec;
        efx_tunnel_protocol_t           encap_type;
        struct sfc_mae_fw_rsrc          fw_rsrc;
};

TAILQ_HEAD(sfc_mae_outer_rules, sfc_mae_outer_rule);

/** Encap. header registry entry */
struct sfc_mae_encap_header {
        TAILQ_ENTRY(sfc_mae_encap_header)       entries;
        unsigned int                            refcnt;
        uint8_t                                 *buf;
        size_t                                  size;
        efx_tunnel_protocol_t                   type;
        struct sfc_mae_fw_rsrc                  fw_rsrc;
};

TAILQ_HEAD(sfc_mae_encap_headers, sfc_mae_encap_header);

/* Counter ID */
struct sfc_mae_counter_id {
        /* ID of a counter in MAE */
        efx_counter_t                   mae_id;
        /* ID of a counter in RTE */
        uint32_t                        rte_id;
};

/** Action set registry entry */
struct sfc_mae_action_set {
        TAILQ_ENTRY(sfc_mae_action_set) entries;
        unsigned int                    refcnt;
        struct sfc_mae_counter_id       *counters;
        uint32_t                        n_counters;
        efx_mae_actions_t               *spec;
        struct sfc_mae_encap_header     *encap_header;
        struct sfc_mae_fw_rsrc          fw_rsrc;
};

TAILQ_HEAD(sfc_mae_action_sets, sfc_mae_action_set);

/** Options for MAE support status */
enum sfc_mae_status {
        SFC_MAE_STATUS_UNKNOWN = 0,
        SFC_MAE_STATUS_UNSUPPORTED,
        SFC_MAE_STATUS_SUPPORTED
};

/*
 * Encap. header bounce buffer. It is used to store header data
 * when parsing the header definition in the action VXLAN_ENCAP.
 */
struct sfc_mae_bounce_eh {
        uint8_t                         *buf;
        size_t                          buf_size;
        size_t                          size;
        efx_tunnel_protocol_t           type;
};

/** Counter collection entry */
struct sfc_mae_counter {
        bool                            inuse;
        uint32_t                        generation_count;
        union sfc_pkts_bytes            value;
        union sfc_pkts_bytes            reset;
};

struct sfc_mae_counters_xstats {
        uint64_t                        not_inuse_update;
        uint64_t                        realloc_update;
};

struct sfc_mae_counters {
        /** An array of all MAE counters */
        struct sfc_mae_counter          *mae_counters;
        /** Extra statistics for counters */
        struct sfc_mae_counters_xstats  xstats;
        /** Count of all MAE counters */
        unsigned int                    n_mae_counters;
};

struct sfc_mae_counter_registry {
        /* Common counter information */
        /** Counters collection */
        struct sfc_mae_counters         counters;

        /* Information used by counter update service */
        /** Callback to get packets from RxQ */
        eth_rx_burst_t                  rx_pkt_burst;
        /** Data for the callback to get packets */
        struct sfc_dp_rxq               *rx_dp;
        /** Number of buffers pushed to the RxQ */
        unsigned int                    pushed_n_buffers;
        /** Are credits used by counter stream */
        bool                            use_credits;

        /* Information used by configuration routines */
        /** Counter service core ID */
        uint32_t                        service_core_id;
        /** Counter service ID */
        uint32_t                        service_id;
};

/**
 * MAE rules used to capture traffic generated by VFs and direct it to
 * representors (one for each VF).
 */
#define SFC_MAE_NB_REPR_RULES_MAX       (64)

/** Rules to forward traffic from PHY port to PF and from PF to PHY port */
#define SFC_MAE_NB_SWITCHDEV_RULES      (2)
/** Maximum required internal MAE rules */
#define SFC_MAE_NB_RULES_MAX            (SFC_MAE_NB_SWITCHDEV_RULES + \
                                         SFC_MAE_NB_REPR_RULES_MAX)

struct sfc_mae_rule {
        efx_mae_match_spec_t            *spec;
        efx_mae_actions_t               *actions;
        efx_mae_aset_id_t               action_set;
        efx_mae_rule_id_t               rule_id;
};

struct sfc_mae_internal_rules {
        /*
         * Rules required to sustain switchdev mode or to provide
         * port representor functionality.
         */
        struct sfc_mae_rule             rules[SFC_MAE_NB_RULES_MAX];
};

struct sfc_mae {
        /** Assigned switch domain identifier */
        uint16_t                        switch_domain_id;
        /** Assigned switch port identifier */
        uint16_t                        switch_port_id;
        /** NIC support for MAE status */
        enum sfc_mae_status             status;
        /** Priority level limit for MAE outer rules */
        unsigned int                    nb_outer_rule_prios_max;
        /** Priority level limit for MAE action rules */
        unsigned int                    nb_action_rule_prios_max;
        /** Encapsulation support status */
        uint32_t                        encap_types_supported;
        /** Outer rule registry */
        struct sfc_mae_outer_rules      outer_rules;
        /** Encap. header registry */
        struct sfc_mae_encap_headers    encap_headers;
        /** Action set registry */
        struct sfc_mae_action_sets      action_sets;
        /** Encap. header bounce buffer */
        struct sfc_mae_bounce_eh        bounce_eh;
        /** Flag indicating whether counter-only RxQ is running */
        bool                            counter_rxq_running;
        /** Counter registry */
        struct sfc_mae_counter_registry counter_registry;
        /** Driver-internal flow rules */
        struct sfc_mae_internal_rules   internal_rules;
        /**
         * Switchdev default rules. They forward traffic from PHY port
         * to PF and vice versa.
         */
        struct sfc_mae_rule             *switchdev_rule_pf_to_ext;
        struct sfc_mae_rule             *switchdev_rule_ext_to_pf;
};

struct sfc_adapter;
struct sfc_flow_spec;

/** This implementation supports double-tagging */
#define SFC_MAE_MATCH_VLAN_MAX_NTAGS    (2)

/** It is possible to keep track of one item ETH and two items VLAN */
#define SFC_MAE_L2_MAX_NITEMS           (SFC_MAE_MATCH_VLAN_MAX_NTAGS + 1)

/** Auxiliary entry format to keep track of L2 "type" ("inner_type") */
struct sfc_mae_ethertype {
        rte_be16_t      value;
        rte_be16_t      mask;
};

struct sfc_mae_pattern_data {
        /**
         * Keeps track of "type" ("inner_type") mask and value for each
         * parsed L2 item in a pattern. These values/masks get filled
         * in MAE match specification at the end of parsing. Also, this
         * information is used to conduct consistency checks:
         *
         * - If an item ETH is followed by a single item VLAN,
         *   the former must have "type" set to one of supported
         *   TPID values (0x8100, 0x88a8, 0x9100, 0x9200, 0x9300),
         *   or 0x0000/0x0000.
         *
         * - If an item ETH is followed by two items VLAN, the
         *   item ETH must have "type" set to one of supported TPID
         *   values (0x88a8, 0x9100, 0x9200, 0x9300), or 0x0000/0x0000,
         *   and the outermost VLAN item must have "inner_type" set
         *   to TPID value 0x8100, or 0x0000/0x0000
         *
         * - If a L2 item is followed by a L3 one, the former must
         *   indicate "type" ("inner_type") which corresponds to
         *   the protocol used in the L3 item, or 0x0000/0x0000.
         *
         * In turn, mapping between RTE convention (above requirements) and
         * MAE fields is non-trivial. The following scheme indicates
         * which item EtherTypes go to which MAE fields in the case
         * of single tag:
         *
         * ETH  (0x8100)        --> VLAN0_PROTO_BE
         * VLAN (L3 EtherType)  --> ETHER_TYPE_BE
         *
         * Similarly, in the case of double tagging:
         *
         * ETH  (0x88a8)        --> VLAN0_PROTO_BE
         * VLAN (0x8100)        --> VLAN1_PROTO_BE
         * VLAN (L3 EtherType)  --> ETHER_TYPE_BE
         */
        struct sfc_mae_ethertype        ethertypes[SFC_MAE_L2_MAX_NITEMS];

        rte_be16_t                      tci_masks[SFC_MAE_MATCH_VLAN_MAX_NTAGS];

        unsigned int                    nb_vlan_tags;

        /**
         * L3 requirement for the innermost L2 item's "type" ("inner_type").
         * This contains one of:
         * - 0x0800/0xffff: IPV4
         * - 0x86dd/0xffff: IPV6
         * - 0x0000/0x0000: no L3 item
         */
        struct sfc_mae_ethertype        innermost_ethertype_restriction;

        /**
         * The following two fields keep track of L3 "proto" mask and value.
         * The corresponding fields get filled in MAE match specification
         * at the end of parsing. Also, the information is used by a
         * post-check to enforce consistency requirements:
         *
         * - If a L3 item is followed by an item TCP, the former has
         *   its "proto" set to either 0x06/0xff or 0x00/0x00.
         *
         * - If a L3 item is followed by an item UDP, the former has
         *   its "proto" set to either 0x11/0xff or 0x00/0x00.
         */
        uint8_t                         l3_next_proto_value;
        uint8_t                         l3_next_proto_mask;

        /*
         * L4 requirement for L3 item's "proto".
         * This contains one of:
         * - 0x06/0xff: TCP
         * - 0x11/0xff: UDP
         * - 0x00/0x00: no L4 item
         */
        uint8_t                         l3_next_proto_restriction_value;
        uint8_t                         l3_next_proto_restriction_mask;

        /* Projected state of EFX_MAE_FIELD_HAS_OVLAN match bit */
        bool                            has_ovlan_value;
        bool                            has_ovlan_mask;

        /* Projected state of EFX_MAE_FIELD_HAS_IVLAN match bit */
        bool                            has_ivlan_value;
        bool                            has_ivlan_mask;
};

struct sfc_mae_parse_ctx {
        struct sfc_adapter              *sa;
        efx_mae_match_spec_t            *match_spec_action;
        efx_mae_match_spec_t            *match_spec_outer;
        /*
         * This points to either of the above two specifications depending
         * on which part of the pattern is being parsed (outer / inner).
         */
        efx_mae_match_spec_t            *match_spec;
        /*
         * This points to either "field_ids_remap_to_encap"
         * or "field_ids_no_remap" (see sfc_mae.c) depending on
         * which part of the pattern is being parsed.
         */
        const efx_mae_field_id_t        *field_ids_remap;
        /* These two fields correspond to the tunnel-specific default mask. */
        size_t                          tunnel_def_mask_size;
        const void                      *tunnel_def_mask;
        bool                            match_mport_set;
        enum sfc_flow_tunnel_rule_type  ft_rule_type;
        struct sfc_mae_pattern_data     pattern_data;
        efx_tunnel_protocol_t           encap_type;
        unsigned int                    priority;
        struct sfc_flow_tunnel          *ft;
};

int sfc_mae_attach(struct sfc_adapter *sa);
void sfc_mae_detach(struct sfc_adapter *sa);
sfc_flow_cleanup_cb_t sfc_mae_flow_cleanup;
int sfc_mae_rule_parse_pattern(struct sfc_adapter *sa,
                               const struct rte_flow_item pattern[],
                               struct sfc_flow_spec_mae *spec,
                               struct rte_flow_error *error);
int sfc_mae_rule_parse_actions(struct sfc_adapter *sa,
                               const struct rte_flow_action actions[],
                               struct sfc_flow_spec_mae *spec_mae,
                               struct rte_flow_error *error);
sfc_flow_verify_cb_t sfc_mae_flow_verify;
sfc_flow_insert_cb_t sfc_mae_flow_insert;
sfc_flow_remove_cb_t sfc_mae_flow_remove;
sfc_flow_query_cb_t sfc_mae_flow_query;

/**
 * The value used to represent the lowest priority.
 * Used in MAE rule API.
 */
#define SFC_MAE_RULE_PRIO_LOWEST        (-1)

/**
 * Insert a driver-internal flow rule that matches traffic originating from
 * some m-port selector and redirects it to another one
 * (eg. PF --> PHY, PHY --> PF).
 *
 * If requested priority is negative, use the lowest priority.
 */
int sfc_mae_rule_add_mport_match_deliver(struct sfc_adapter *sa,
                                         const efx_mport_sel_t *mport_match,
                                         const efx_mport_sel_t *mport_deliver,
                                         int prio, struct sfc_mae_rule **rulep);
void sfc_mae_rule_del(struct sfc_adapter *sa, struct sfc_mae_rule *rule);
int sfc_mae_switchdev_init(struct sfc_adapter *sa);
void sfc_mae_switchdev_fini(struct sfc_adapter *sa);

#ifdef __cplusplus
}
#endif
#endif /* _SFC_MAE_H */