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BRIDGE(4) Device Drivers Manual BRIDGE(4)

bridgeEthernet bridge interface

pseudo-device bridge


#include <sys/types.h>
#include <net/if.h>
#include <netinet/in.h>
#include <netinet/if_ether.h>
#include <net/if_bridge.h>

The bridge device creates a logical link between two or more Ethernet interfaces or encapsulation interfaces (see etherip(4)). This link between the interfaces selectively forwards frames from each interface on the bridge to every other interface on the bridge. A bridge can serve several services, including isolation of traffic between sets of machines so that traffic local to one set of machines is not available on the wire of another set of machines, and it can act as a transparent filter for ip(4) datagrams.

A bridge interface can be created at runtime using the ifconfig bridgeN create command or by setting up a hostname.if(5) configuration file for netstart(8).

The bridges provided by this interface are learning bridges with filtering; see pf(4). In general a bridge works like a hub, forwarding traffic from one interface to another. It differs from a hub in that it will "learn" which machines are on each of its attached segments by actively listening to incoming traffic and examining the headers of each frame. A table is built containing the MAC address and segment to which the MAC address is attached. This allows a bridge to be more selective about what it forwards, which can be used to reduce traffic on a set of segments and also to provide an IP firewall without changing the topology of the network.

The algorithm works as follows by default, but can be modified via ioctl(2) or the utility ifconfig(8). When a frame comes in, the origin segment and the source address are recorded. If the bridge has no knowledge about where the destination is to be found, the bridge will forward the frame to all attached segments. If the destination is known to be on a different segment from its origin, the bridge will forward the packet only to the destination segment. If the destination is on the same segment as the origin segment, the bridge will drop the packet because the receiver has already had a chance to see the frame. Before forwarding a frame, the bridge will check to see if the packet contains an ip(4) or ip6(4) datagram; if so, the datagram is run through the pf interface so that it can be filtered. See the NOTES section for details.

The bridge has support for 802.1D-2004 Spanning Tree Protocol (STP), which can be used to detect and remove loops in a network topology. Using the stp or -stp commands to bridge, STP can be enabled or disabled on each port.

The bridge will use the Rapid Spanning Tree Protocol (RSTP) by default to allow rapid transitions to the forwarding state. The proto command to bridge can be used to force operation in the common Spanning Tree Protocol without rapid state transitions. Note that RSTP will be compatible with remote bridges running common STP.

The bridge can have interfaces added to it as span ports. Span ports transmit a copy of every frame received by the bridge. This is most useful for snooping a bridged network passively on another host connected to one of the span ports of the bridge. Span ports cannot be bridge members; instead, the addspan and delspan commands are used to add and delete span ports to and from a bridge.

A bridge interface responds to all of the ioctl(2) calls specific to other interfaces listed in netintro(4). The following ioctl(2) calls are specific to bridge devices. They are defined in <sys/sockio.h>. Some ioctl(2) calls are used by switch(4) and tpmr(4) as well.

struct ifbifconf *
Retrieve member interface list from a bridge. This request takes an ifbifconf structure (see below) as a value-result parameter. The ifbic_len field should be initially set to the size of the buffer pointed to by ifbic_buf. On return it will contain the length, in bytes, of the configuration list.

Alternatively, if the ifbic_len passed in is set to 0, SIOCBRDGIFS will set ifbic_len to the size that ifbic_buf needs to be to fit the entire configuration list, and will not fill in the other parameters. This is useful for determining the exact size that ifbic_buf needs to be in advance.

The argument structure is defined as follows:

struct ifbreq {
	char	  ifbr_name[IFNAMSIZ];	 /* bridge ifs name */
	char	  ifbr_ifsname[IFNAMSIZ];/* member ifs name */
	u_int32_t ifbr_ifsflags;  /* member ifs flags */
	u_int8_t  ifbr_state;	  /* member stp state */
	u_int8_t  ifbr_priority;  /* member stp priority */
	u_int32_t ifbr_portno;	  /* member port number */
	u_int32_t ifbr_path_cost; /* member stp path cost */
};

/* ifbr_ifsflags flags about interfaces */
#define	IFBIF_LEARNING	 0x0001 /* ifs can learn */
#define	IFBIF_DISCOVER	 0x0002 /* sends packets w/unknown dst */
#define	IFBIF_BLOCKNONIP 0x0004 /* ifs blocks non-IP/ARP in/out */
#define	IFBIF_STP	 0x0008 /* participate in spanning tree*/
#define	IFBIF_SPAN	 0x0100 /* ifs is a span port (ro) */
#define	IFBIF_RO_MASK	 0xff00 /* read only bits */

struct ifbifconf {
	char	  ifbic_name[IFNAMSIZ];	/* bridge ifs name */
	u_int32_t ifbic_len;		/* buffer size */
	union {
		caddr_t	ifbicu_buf;
		struct	ifbreq *ifbicu_req;
	} ifbic_ifbicu;
#define	ifbic_buf	ifbic_ifbicu.ifbicu_buf
#define	ifbic_req	ifbic_ifbicu.ifbicu_req
};
struct ifbreq *
Add the interface named in ifbr_ifsname to the bridge named in ifbr_name.
struct ifbreq *
Delete the interface named in ifbr_ifsname from the bridge named in ifbr_name.
struct ifbreq *
Add the interface named in ifbr_ifsname as a span port to the bridge named in ifbr_name.
struct ifbreq *
Delete the interface named in ifbr_ifsname from the list of span ports of the bridge named in ifbr_name.
struct ifbreq *
Set the bridge member interface flags for the interface named in ifbr_ifsname attached to the bridge ifbr_name. If the flag IFBIF_LEARNING is set on an interface, source addresses from frames received on the interface are recorded in the address cache. If the flag IFBIF_DISCOVER is set, the interface will receive packets destined for unknown destinations, otherwise a frame that has a destination not found in the address cache is not forwarded to this interface. The default for newly added interfaces has both flags set. If the flag IFBIF_BLOCKNONIP is set, only ip(4), ip6(4), arp(4), and Reverse ARP packets will be bridged from and to the interface.
struct ifbreq *
Retrieve the bridge member interface flags for the interface named in ifbr_ifsname attached to the bridge ifbr_name.
struct ifbaconf *
Retrieve the address cache of the bridge named in ifbac_name. This request takes an ifbaconf structure (see below) as a value-result parameter. The ifbac_len field should be initially set to the size of the buffer pointed to by ifbac_buf. On return, it will contain the length, in bytes, of the configuration list.

Alternatively, if the ifbac_len passed in is set to 0, SIOCBRDGRTS will set it to the size that ifbac_buf needs to be to fit the entire configuration list, and will not fill in the other parameters. As with SIOCBRDGIFS, this is useful for determining the exact size that ifbac_buf needs to be in advance.

The argument structure is defined as follows:

struct ifbareq {
	char	 ifba_name[IFNAMSIZ];	/* bridge name */
	char	 ifba_ifsname[IFNAMSIZ];/* destination ifs */
	u_int8_t ifba_age;		/* address age */
	u_int8_t ifba_flags;		/* address flags */
	struct ether_addr ifba_dst;	/* destination addr */
};

#define	IFBAF_TYPEMASK	0x03		/* address type mask */
#define	IFBAF_DYNAMIC	0x00		/* dynamically learned */
#define	IFBAF_STATIC	0x01		/* static address */

struct ifbaconf {
	char	  ifbac_name[IFNAMSIZ];	/* bridge ifs name */
	u_int32_t ifbac_len;		/* buffer size */
	union {
		caddr_t	ifbacu_buf;	/* buffer */
		struct ifbareq *ifbacu_req; /* request pointer */
	} ifbac_ifbacu;
#define	ifbac_buf	ifbac_ifbacu.ifbacu_buf
#define	ifbac_req	ifbac_ifbacu.ifbacu_req
};

Address cache entries with the type set to IFBAF_DYNAMIC in ifba_flags are entries learned by the bridge. Entries with the type set to IFBAF_STATIC are manually added entries.

struct ifbareq *
Add an entry, manually, to the address cache for the bridge named in ifba_name. The address and its associated interface and flags are set in the ifba_dst, ifba_ifsname, and ifba_flags fields, respectively.
struct ifbareq *
Delete an entry from the address cache of the bridge named in ifba_name. Entries are deleted strictly based on the address field ifba_dst.
struct ifbreq *
Flush addresses from the cache. ifbr_name contains the name of the bridge device, and ifbr_ifsflags should be set to IFBF_FLUSHALL to flush all addresses from the cache or IFBF_FLUSHDYN to flush only the dynamically learned addresses from the cache.
struct ifbrparam *
Set the maximum address cache size for the bridge named in ifbrp_name to ifbrp_csize entries.

The argument structure is as follows:

struct ifbrparam {
	char		  ifbrp_name[IFNAMSIZ];
	union {
		u_int32_t ifbrpu_csize;	    /* cache size */
		int	  ifbrpu_ctime;	    /* cache time */
		u_int16_t ifbrpu_prio;	    /* bridge priority */
		u_int8_t  ifbrpu_hellotime; /* hello time */
		u_int8_t  ifbrpu_fwddelay;  /* fwd delay */
		u_int8_t  ifbrpu_maxage;    /* max age */
		u_int64_t ifbrpu_datapath;  /* datapath-id */
		u_int32_t ifbrpu_maxgroup;  /* group size */
	} ifbrp_ifbrpu;
};
#define	ifbrp_csize	ifbrp_ifbrpu.ifbrpu_csize
#define	ifbrp_ctime	ifbrp_ifbrpu.ifbrpu_ctime
#define	ifbrp_prio	ifbrp_ifbrpu.ifbrpu_prio
#define	ifbrp_hellotime	ifbrp_ifbrpu.ifbrpu_hellotime
#define	ifbrp_fwddelay	ifbrp_ifbrpu.ifbrpu_fwddelay
#define	ifbrp_maxage	ifbrp_ifbrpu.ifbrpu_maxage
#define	ifbrp_datapath  ifbrp_ifbrpu.ifbrpu_datapath
#define	ifbrp_maxflow   ifbrp_ifbrpu.ifbrpu_csize
#define	ifbrp_maxgroup  ifbrp_ifbrpu.ifbrpu_maxgroup

Note that the ifbrp_ctime, ifbrp_hellotime, ifbrp_fwddelay and ifbrp_maxage fields are in seconds.

struct ifbrparam *
Retrieve the maximum size of the address cache for the bridge ifbrp_name.
struct ifbrparam *
Set the time, in seconds, for how long addresses which have not been seen on the network (i.e., have not transmitted a packet) will remain in the cache to the value ifbrp_ctime. If the time is set to zero, no aging is performed on the address cache.
struct ifbrparam *
Retrieve the address cache expiration time (see above).
struct ifbrlreq *
Add an Ethernet address filtering rule to the bridge on a specific interface. ifbr_name contains the name of the bridge device, and ifbr_ifsname contains the name of the bridge member interface.

Rules are applied in the order in which they were added to the bridge, and the first matching rule's action parameter determines the fate of the packet. The ifbr_action field is one of BRL_ACTION_PASS or BRL_ACTION_BLOCK, to pass or block matching frames, respectively. The ifbr_flags field specifies whether the rule should match on input, output, or both by using the flags BRL_FLAG_IN and BRL_FLAG_OUT. At least one of these flags must be set.

The ifbr_flags field also specifies whether either (or both) of the source and destination addresses should be matched by using the BRL_FLAG_SRCVALID and BRL_FLAG_DSTVALID flags. The ifbr_src field is the source address that triggers the rule (only considered if ifbr_flags has the BRL_FLAG_SRCVALID bit set). The ifbr_src field is the destination address that triggers the rule (only considered if ifbr_flags has the BRL_FLAG_DSTVALID bit set). If neither bit is set, the rule matches all frames.

The argument structure is as follows:

struct ifbrlreq {
	char	 ifbr_name[IFNAMSIZ];	 /* bridge ifs name */
	char	 ifbr_ifsname[IFNAMSIZ]; /* member ifs name */
	u_int8_t ifbr_action;		 /* disposition */
	u_int8_t ifbr_flags;		 /* flags */
	struct ether_addr ifbr_src;	 /* source mac */
	struct ether_addr ifbr_dst;	 /* destination mac */
	char	 ifbr_tagname[PF_TAG_NAME_SIZE]; /* pf tagname */
};
#define	BRL_ACTION_BLOCK	0x01	 /* block frame */
#define	BRL_ACTION_PASS		0x02	 /* pass frame */
#define	BRL_FLAG_IN		0x08	 /* input rule */
#define	BRL_FLAG_OUT		0x04	 /* output rule */
#define	BRL_FLAG_SRCVALID	0x02	 /* src valid */
#define	BRL_FLAG_DSTVALID	0x01	 /* dst valid */
struct ifbrlreq *
Remove all filtering rules from a bridge interface member. ifbr_name contains the name of the bridge device, and ifbr_ifsname contains the name of the bridge member interface.
struct ifbrlconf *
Retrieve all of the rules from the bridge, ifbrl_name, for the member interface, ifbrl_ifsname. This request takes an ifbrlconf structure (see below) as a value-result parameter. The ifbrl_len field should be initially set to the size of the buffer pointed to by ifbrl_buf. On return, it will contain the length, in bytes, of the configuration list.

Alternatively, if the ifbrl_len passed in is set to 0, SIOCBRDGGRL will set it to the size that ifbrl_buf needs to be to fit the entire configuration list, and will not fill in the other parameters. As with SIOCBRDGIFS, this is useful for determining the exact size that ifbrl_buf needs to be in advance.

The argument structure is defined as follows:

struct ifbrlconf {
	char	  ifbrl_name[IFNAMSIZ];	   /* bridge ifs name */
	char	  ifbrl_ifsname[IFNAMSIZ]; /* member ifs name */
	u_int32_t ifbrl_len;		   /* buffer size */
	union {
		caddr_t	ifbrlu_buf;
		struct	ifbrlreq *ifbrlu_req;
	} ifbrl_ifbrlu;
#define	ifbrl_buf ifbrl_ifbrlu.ifbrlu_buf
#define	ifbrl_req ifbrl_ifbrlu.ifbrlu_req
};
struct ifbrparam *
Retrieve the Spanning Tree Protocol (STP) priority parameter of the bridge into the ifbrp_prio field.
struct ifbrparam *
Set the STP priority parameter of the bridge to the value in ifbrp_prio.
struct ifbrparam *
Retrieve the STP hello time parameter, in seconds, of the bridge into the ifbrp_hellotime field.
struct ifbrparam *
Set the STP hello time parameter, in seconds, of the bridge to the value in ifbrp_hellotime. The value in ifbrp_hellotime cannot be zero.
struct ifbrparam *
Retrieve the STP forward delay parameter, in seconds, of the bridge into the ifbrp_fwddelay field.
struct ifbrparam *
Set the STP forward delay parameter, in seconds, of the bridge to the value in ifbrp_fwddelay. The value in ifbrp_fwddelay cannot be zero.
struct ifbrparam *
Retrieve the STP maximum age parameter, in seconds, of the bridge into the ifbrp_maxage field.
struct ifbrparam *
Set the STP maximum age parameter, in seconds, of the bridge to the value in ifbrp_maxage. The value in ifbrp_maxage cannot be zero.
struct ifbreq *
Set the STP priority parameter of the interface named in ifbr_ifsname to the value in ifbr_priority.
struct ifbreq *
Set the STP cost parameter of the interface named in ifbr_ifsname to the value in ifbr_path_cost. The value in ifbr_path_cost must be greater than or equal to one.
struct ifbreq *
Set the protection domain membership of the interface named in ifbr_ifsname to the value in ifbr_protected.

If the ioctl(2) call fails, errno(2) is set to one of the following values:

[]
For an add request, this means that the named interface is not configured into the system. For a delete operation, it means that the named interface is not a member of the bridge. For an address cache deletion, the address was not found in the table.
[]
Memory could not be allocated for an interface or cache entry to be added to the bridge.
[]
The named interface is already a member of the bridge.
[]
The named interface is already a member of another bridge.
[]
The named interface is not an Ethernet interface, or an invalid ioctl was performed on the bridge.
[]
Address cache operation (flush, add, or delete) on a bridge that is in the down state.
[]
Super-user privilege is required to add and delete interfaces to and from bridges and to set the bridge interface flags.
[]
The buffer used in a SIOCBRDGIFS or SIOCBRDGRTS request points outside of the process's allocated address space.
[]
No such member interface in the bridge.

Bridged packets pass through pf(4) filters once as input on the receiving interface and once as output on all interfaces on which they are forwarded. In order to pass through the bridge packets must pass any in rules on the input and any out rules on the output interface. Packets may be blocked either entering or leaving the bridge.

Return packets generated by pf itself are not routed using the kernel routing table. Instead, pf will send these replies back to the same Ethernet address that the original packet came from. This applies to rules with return, return-rst, return-icmp, return-icmp6, or synproxy defined. At the moment, only return-rst on IPv4 is implemented and the other packet generating rules are unsupported.

If an IP packet is too large for the outgoing interface, the bridge will perform IP fragmentation. This can happen when bridge members have different MTUs or when IP fragments are reassembled by pf. Non-IP packets which are too large for the outgoing interface will be dropped.

If the IFF_LINK2 flag is set on the bridge interface, the bridge will also perform transparent ipsec(4) processing on the packets (encrypt or decrypt them), according to the policies set with the ipsecctl(8) command by the administrator. If appropriate security associations (SAs) do not exist, any key management daemons such as isakmpd(8) that are running on the bridge will be invoked to establish the necessary SAs. These daemons have to be configured as if they were running on the host whose traffic they are protecting (i.e., they need to have the appropriate authentication and authorization material, such as keys and certificates, to impersonate the protected host(s)).

errno(2), ioctl(2), arp(4), etherip(4), ip(4), ip6(4), ipsec(4), netintro(4), pf(4), switch(4), tpmr(4), vether(4), hostname.if(5), ifconfig(8), ipsecctl(8), isakmpd(8), netstart(8)

The bridge kernel interface first appeared in OpenBSD 2.5.

The bridge kernel interface was written by Jason L. Wright <jason@thought.net> as part of an undergraduate independent study at the University of North Carolina at Greensboro.

Support for rapid spanning tree reconfigurations (RSTP) was added by
Andrew Thompson <thompsa@freebsd.org> and ported to OpenBSD by
Reyk Floeter <reyk@openbsd.org>.

There are some rather special network interface chipsets which will not work in a bridge configuration. Some chipsets have serious flaws when running in promiscuous mode, like the TI ThunderLAN (see tl(4)), which receives its own transmissions (this renders the address learning cache useless). Most other chipsets work fine though.

August 27, 2020 OpenBSD-6.9