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/*
* gre.h: types/functions for gre.
*
* Copyright (c) 2012 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef included_gre_h
#define included_gre_h
#include <vnet/vnet.h>
#include <vnet/gre/packet.h>
#include <vnet/ip/ip.h>
#include <vnet/pg/pg.h>
#include <vnet/ip/format.h>
#include <vnet/adj/adj_types.h>
extern vnet_hw_interface_class_t gre_hw_interface_class;
extern vnet_hw_interface_class_t mgre_hw_interface_class;
typedef enum
{
#define gre_error(n,s) GRE_ERROR_##n,
#include <vnet/gre/error.def>
#undef gre_error
GRE_N_ERROR,
} gre_error_t;
/**
* L3: GRE (i.e. this tunnel is in L3 mode)
* TEB: Transparent Ethernet Bridging - the tunnel is in L2 mode
* ERSPAN: type 2 - the tunnel is for port mirror SPAN output. Each tunnel is
* associated with a session ID and expected to be used for encap
* and output of mirrored packet from a L2 network only. There is
* no support for receiving ERSPAN packets from a GRE ERSPAN tunnel
*/
#define foreach_gre_tunnel_type \
_(L3, "L3") \
_(TEB, "TEB") \
_(ERSPAN, "ERSPAN") \
/**
* @brief The GRE tunnel type
*/
typedef enum gre_tunnel_type_t_
{
#define _(n, s) GRE_TUNNEL_TYPE_##n,
foreach_gre_tunnel_type
#undef _
} __clib_packed gre_tunnel_type_t;
extern u8 *format_gre_tunnel_type (u8 * s, va_list * args);
#define foreach_gre_tunnel_mode \
_(P2P, "point-to-point") \
_(MP, "multi-point") \
typedef enum gre_tunnel_mode_t_
{
#define _(n, s) GRE_TUNNEL_MODE_##n,
foreach_gre_tunnel_mode
#undef _
} __clib_packed gre_tunnel_mode_t;
extern u8 *format_gre_tunnel_mode (u8 * s, va_list * args);
/**
* A GRE payload protocol registration
*/
typedef struct
{
/** Name (a c string). */
char *name;
/** GRE protocol type in host byte order. */
gre_protocol_t protocol;
/** GRE tunnel type */
gre_tunnel_type_t tunnel_type;
/** Node which handles this type. */
u32 node_index;
/** Next index for this type. */
u32 next_index;
} gre_protocol_info_t;
/**
* @brief Key for a IPv4 GRE Tunnel
*/
typedef struct gre_tunnel_key4_t_
{
/**
* Source and destination IP addresses
*/
union
{
struct
{
ip4_address_t gtk_src;
ip4_address_t gtk_dst;
};
u64 gtk_as_u64;
};
/**
* FIB table index, ERSPAN session ID and tunnel type in u32 bit fields:
* - The FIB table index the src,dst addresses are in, top 20 bits
* - The Session ID for ERSPAN tunnel type and 0 otherwise, next 10 bits
* - Tunnel type, bottom 2 bits
*/
u32 gtk_fidx_ssid_type;
} __attribute__ ((packed)) gre_tunnel_key4_t;
/**
* @brief Key for a IPv6 GRE Tunnel
* We use a different type so that the V4 key hash is as small as possible
*/
typedef struct gre_tunnel_key6_t_
{
/**
* Source and destination IP addresses
*/
ip6_address_t gtk_src;
ip6_address_t gtk_dst;
/**
* FIB table index, ERSPAN session ID and tunnel type in u32 bit fields:
* - The FIB table index the src,dst addresses are in, top 20 bits
* - The Session ID for ERSPAN tunnel type and 0 otherwise, next 10 bits
* - Tunnel type, bottom 2 bits
*/
u32 gtk_fidx_ssid_type;
} __attribute__ ((packed)) gre_tunnel_key6_t;
#define GTK_FIB_INDEX_SHIFT 12
#define GTK_FIB_INDEX_MASK 0xfffff000
#define GTK_TYPE_SHIFT 0
#define GTK_TYPE_MASK 0x3
#define GTK_SESSION_ID_SHIFT 2
#define GTK_SESSION_ID_MASK 0xffc
#define GTK_SESSION_ID_MAX (GTK_SESSION_ID_MASK >> GTK_SESSION_ID_SHIFT)
/**
* Union of the two possible key types
*/
typedef union gre_tunnel_key_t_
{
gre_tunnel_key4_t gtk_v4;
gre_tunnel_key6_t gtk_v6;
} gre_tunnel_key_t;
/**
* Used for GRE header seq number generation for ERSPAN encap
*/
typedef struct
{
u32 seq_num;
u32 ref_count;
} gre_sn_t;
/**
* Hash key for GRE header seq number generation for ERSPAN encap
*/
typedef struct
{
ip46_address_t src;
ip46_address_t dst;
u32 fib_index;
} gre_sn_key_t;
/**
* @brief A representation of a GRE tunnel
*/
typedef struct
{
/**
* Required for pool_get_aligned
*/
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
/**
* The hash table's key stored in separate memory since the tunnel_t
* memory can realloc.
*/
gre_tunnel_key_t *key;
/**
* The tunnel's source/local address
*/
ip46_address_t tunnel_src;
/**
* The tunnel's destination/remote address
*/
fib_prefix_t tunnel_dst;
/**
* The FIB in which the src.dst address are present
*/
u32 outer_fib_index;
u32 hw_if_index;
u32 sw_if_index;
gre_tunnel_type_t type;
gre_tunnel_mode_t mode;
/**
* an L2 tunnel always rquires an L2 midchain. cache here for DP.
*/
adj_index_t l2_adj_index;
/**
* ERSPAN type 2 session ID, least significant 10 bits of u16
*/
u16 session_id;
/**
* GRE header sequence number (SN) used for ERSPAN type 2 header, must be
* bumped automically to be thread safe. As multiple GRE tunnels are created
* for the same fib-idx/DIP/SIP with different ERSPAN session number, they all
* share the same SN which is kept per FIB/DIP/SIP, as specified by RFC2890.
*/
gre_sn_t *gre_sn;
u32 dev_instance; /* Real device instance in tunnel vector */
u32 user_instance; /* Instance name being shown to user */
} gre_tunnel_t;
typedef struct
{
u8 next_index;
u8 tunnel_type;
} next_info_t;
/**
* @brief GRE related global data
*/
typedef struct
{
/**
* pool of tunnel instances
*/
gre_tunnel_t *tunnels;
/**
* GRE payload protocol registrations
*/
gre_protocol_info_t *protocol_infos;
/**
* Hash tables mapping name/protocol to protocol info index.
*/
uword *protocol_info_by_name, *protocol_info_by_protocol;
/**
* Hash mapping to tunnels with ipv4 src/dst addr
*/
uword *tunnel_by_key4;
/**
* Hash mapping to tunnels with ipv6 src/dst addr
*/
uword *tunnel_by_key6;
/**
* Hash mapping tunnel src/dst addr and fib-idx to sequence number
*/
uword *seq_num_by_key;
/**
* Mapping from sw_if_index to tunnel index
*/
u32 *tunnel_index_by_sw_if_index;
/* Sparse vector mapping gre protocol in network byte order
to next index. */
next_info_t *next_by_protocol;
/* convenience */
vlib_main_t *vlib_main;
vnet_main_t *vnet_main;
/* Record used instances */
uword *instance_used;
} gre_main_t;
/**
* @brief IPv4 and GRE header.
*/
/* *INDENT-OFF* */
typedef CLIB_PACKED (struct {
ip4_header_t ip4;
gre_header_t gre;
}) ip4_and_gre_header_t;
/* *INDENT-ON* */
/**
* @brief IPv6 and GRE header.
*/
/* *INDENT-OFF* */
typedef CLIB_PACKED (struct {
ip6_header_t ip6;
gre_header_t gre;
}) ip6_and_gre_header_t;
/* *INDENT-ON* */
always_inline gre_protocol_info_t *
gre_get_protocol_info (gre_main_t * em, gre_protocol_t protocol)
{
uword *p = hash_get (em->protocol_info_by_protocol, protocol);
return p ? vec_elt_at_index (em->protocol_infos, p[0]) : 0;
}
extern gre_main_t gre_main;
extern clib_error_t *gre_interface_admin_up_down (vnet_main_t * vnm,
u32 hw_if_index, u32 flags);
extern void gre_tunnel_stack (adj_index_t ai);
extern void gre_update_adj (vnet_main_t * vnm,
u32 sw_if_index, adj_index_t ai);
format_function_t format_gre_protocol;
format_function_t format_gre_header;
format_function_t format_gre_header_with_length;
extern vlib_node_registration_t gre4_input_node;
extern vlib_node_registration_t gre6_input_node;
extern vlib_node_registration_t gre_encap_node;
extern vnet_device_class_t gre_device_class;
/* Parse gre protocol as 0xXXXX or protocol name.
In either host or network byte order. */
unformat_function_t unformat_gre_protocol_host_byte_order;
unformat_function_t unformat_gre_protocol_net_byte_order;
/* Parse gre header. */
unformat_function_t unformat_gre_header;
unformat_function_t unformat_pg_gre_header;
void
gre_register_input_protocol (vlib_main_t * vm, gre_protocol_t protocol,
u32 node_index, gre_tunnel_type_t tunnel_type);
/* manually added to the interface output node in gre.c */
#define GRE_OUTPUT_NEXT_LOOKUP 1
typedef struct
{
u8 is_add;
gre_tunnel_type_t type;
gre_tunnel_mode_t mode;
u8 is_ipv6;
u32 instance;
ip46_address_t src, dst;
u32 outer_table_id;
u16 session_id;
} vnet_gre_tunnel_add_del_args_t;
extern int vnet_gre_tunnel_add_del (vnet_gre_tunnel_add_del_args_t * a,
u32 * sw_if_indexp);
static inline void
gre_mk_key4 (ip4_address_t src,
ip4_address_t dst,
u32 fib_index, u8 ttype, u16 session_id, gre_tunnel_key4_t * key)
{
key->gtk_src = src;
key->gtk_dst = dst;
key->gtk_fidx_ssid_type = ttype |
(fib_index << GTK_FIB_INDEX_SHIFT) | (session_id << GTK_SESSION_ID_SHIFT);
}
static inline int
gre_match_key4 (const gre_tunnel_key4_t * key1,
const gre_tunnel_key4_t * key2)
{
return ((key1->gtk_as_u64 == key2->gtk_as_u64) &&
(key1->gtk_fidx_ssid_type == key2->gtk_fidx_ssid_type));
}
static inline void
gre_mk_key6 (const ip6_address_t * src,
const ip6_address_t * dst,
u32 fib_index, u8 ttype, u16 session_id, gre_tunnel_key6_t * key)
{
key->gtk_src = *src;
key->gtk_dst = *dst;
key->gtk_fidx_ssid_type = ttype |
(fib_index << GTK_FIB_INDEX_SHIFT) | (session_id << GTK_SESSION_ID_SHIFT);
}
static inline int
gre_match_key6 (const gre_tunnel_key6_t * key1,
const gre_tunnel_key6_t * key2)
{
return ((key1->gtk_src.as_u64[0] == key2->gtk_src.as_u64[0]) &&
(key1->gtk_src.as_u64[1] == key2->gtk_src.as_u64[1]) &&
(key1->gtk_dst.as_u64[0] == key2->gtk_dst.as_u64[0]) &&
(key1->gtk_dst.as_u64[1] == key2->gtk_dst.as_u64[1]) &&
(key1->gtk_fidx_ssid_type == key2->gtk_fidx_ssid_type));
}
static inline void
gre_mk_sn_key (const gre_tunnel_t * gt, gre_sn_key_t * key)
{
key->src = gt->tunnel_src;
key->dst = gt->tunnel_dst.fp_addr;
key->fib_index = gt->outer_fib_index;
}
#endif /* included_gre_h */
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/