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NAME

     multicast — Multicast Routing

SYNOPSIS

     options MROUTING

     #include <sys/types.h>
     #include <sys/socket.h>
     #include <netinet/in.h>
     #include <netinet/ip_mroute.h>
     #include <netinet6/ip6_mroute.h>

     int
     getsockopt(int s, IPPROTO_IP, MRT_INIT, void *optval, socklen_t *optlen);

     int
     setsockopt(int s, IPPROTO_IP, MRT_INIT, const void *optval, socklen_t optlen);

     int
     getsockopt(int s, IPPROTO_IPV6, MRT6_INIT, void *optval, socklen_t *optlen);

     int
     setsockopt(int s, IPPROTO_IPV6, MRT6_INIT, const void *optval, socklen_t optlen);

DESCRIPTION

     Multicast routing is used to efficiently propagate data packets to a set of multicast
     listeners in multipoint networks.  If unicast is used to replicate the data to all
     listeners, then some of the network links may carry multiple copies of the same data
     packets.  With multicast routing, the overhead is reduced to one copy (at most) per network
     link.

     All multicast-capable routers must run a common multicast routing protocol.  It is
     recommended that either Protocol Independent Multicast - Sparse Mode (PIM-SM), or Protocol
     Independent Multicast - Dense Mode (PIM-DM) are used, as these are now the generally
     accepted protocols in the Internet community.  The HISTORY section discusses previous
     multicast routing protocols.

     To start multicast routing, the user must enable multicast forwarding in the kernel (see
     SYNOPSIS about the kernel configuration options), and must run a multicast routing capable
     user-level process.  From developer's point of view, the programming guide described in the
     Programming Guide section should be used to control the multicast forwarding in the kernel.

   Programming Guide
     This section provides information about the basic multicast routing API.  The so-called
     “advanced multicast API” is described in the Advanced Multicast API Programming Guide
     section.

     First, a multicast routing socket must be open.  That socket would be used to control the
     multicast forwarding in the kernel.  Note that most operations below require certain
     privilege (i.e., root privilege):

     /* IPv4 */
     int mrouter_s4;
     mrouter_s4 = socket(AF_INET, SOCK_RAW, IPPROTO_IGMP);

     int mrouter_s6;
     mrouter_s6 = socket(AF_INET6, SOCK_RAW, IPPROTO_ICMPV6);

     Note that if the router needs to open an IGMP or ICMPv6 socket (in case of IPv4 and IPv6
     respectively) for sending or receiving of IGMP or MLD multicast group membership messages,
     then the same mrouter_s4 or mrouter_s6 sockets should be used for sending and receiving
     respectively IGMP or MLD messages.  In case of BSD-derived kernel, it may be possible to
     open separate sockets for IGMP or MLD messages only.  However, some other kernels (e.g.,
     Linux) require that the multicast routing socket must be used for sending and receiving of
     IGMP or MLD messages.  Therefore, for portability reason the multicast routing socket should
     be reused for IGMP and MLD messages as well.

     After the multicast routing socket is open, it can be used to enable or disable multicast
     forwarding in the kernel:

     /* IPv4 */
     int v = 1;        /* 1 to enable, or 0 to disable */
     setsockopt(mrouter_s4, IPPROTO_IP, MRT_INIT, (void *)&v, sizeof(v));

     /* IPv6 */
     int v = 1;        /* 1 to enable, or 0 to disable */
     setsockopt(mrouter_s6, IPPROTO_IPV6, MRT6_INIT, (void *)&v, sizeof(v));
     ...
     /* If necessary, filter all ICMPv6 messages */
     struct icmp6_filter filter;
     ICMP6_FILTER_SETBLOCKALL(&filter);
     setsockopt(mrouter_s6, IPPROTO_ICMPV6, ICMP6_FILTER, (void *)&filter,
                sizeof(filter));

     After multicast forwarding is enabled, the multicast routing socket can be used to enable
     PIM processing in the kernel if we are running PIM-SM or PIM-DM (see pim(4)).

     For each network interface (e.g., physical or a virtual tunnel) that would be used for
     multicast forwarding, a corresponding multicast interface must be added to the kernel:

     /* IPv4 */
     struct vifctl vc;
     memset(&vc, 0, sizeof(vc));
     /* Assign all vifctl fields as appropriate */
     vc.vifc_vifi = vif_index;
     vc.vifc_flags = vif_flags;
     vc.vifc_threshold = min_ttl_threshold;
     vc.vifc_rate_limit = 0;
     memcpy(&vc.vifc_lcl_addr, &vif_local_address, sizeof(vc.vifc_lcl_addr));
     setsockopt(mrouter_s4, IPPROTO_IP, MRT_ADD_VIF, (void *)&vc,
                sizeof(vc));

     The vif_index must be unique per vif.  The vif_flags contains the VIFF_* flags as defined in
     <netinet/ip_mroute.h>.  The VIFF_TUNNEL flag is no longer supported by FreeBSD.  Users who
     wish to forward multicast datagrams over a tunnel should consider configuring a gif(4) or
     gre(4) tunnel and using it as a physical interface.

     The min_ttl_threshold contains the minimum TTL a multicast data packet must have to be
     forwarded on that vif.  Typically, it would have value of 1.

     The max_rate_limit argument is no longer supported in FreeBSD and should be set to 0.  Users
     who wish to rate-limit multicast datagrams should consider the use of dummynet(4) or
     altq(4).

     The vif_local_address contains the local IP address of the corresponding local interface.
     The vif_remote_address contains the remote IP address in case of DVMRP multicast tunnels.

     /* IPv6 */
     struct mif6ctl mc;
     memset(&mc, 0, sizeof(mc));
     /* Assign all mif6ctl fields as appropriate */
     mc.mif6c_mifi = mif_index;
     mc.mif6c_flags = mif_flags;
     mc.mif6c_pifi = pif_index;
     setsockopt(mrouter_s6, IPPROTO_IPV6, MRT6_ADD_MIF, (void *)&mc,
                sizeof(mc));

     The mif_index must be unique per vif.  The mif_flags contains the MIFF_* flags as defined in
     <netinet6/ip6_mroute.h>.  The pif_index is the physical interface index of the corresponding
     local interface.

     A multicast interface is deleted by:

     /* IPv4 */
     vifi_t vifi = vif_index;
     setsockopt(mrouter_s4, IPPROTO_IP, MRT_DEL_VIF, (void *)&vifi,
                sizeof(vifi));

     /* IPv6 */
     mifi_t mifi = mif_index;
     setsockopt(mrouter_s6, IPPROTO_IPV6, MRT6_DEL_MIF, (void *)&mifi,
                sizeof(mifi));

     After the multicast forwarding is enabled, and the multicast virtual interfaces are added,
     the kernel may deliver upcall messages (also called signals later in this text) on the
     multicast routing socket that was open earlier with MRT_INIT or MRT6_INIT.  The IPv4 upcalls
     have struct igmpmsg header (see <netinet/ip_mroute.h>) with field im_mbz set to zero.  Note
     that this header follows the structure of struct ip with the protocol field ip_p set to
     zero.  The IPv6 upcalls have struct mrt6msg header (see <netinet6/ip6_mroute.h>) with field
     im6_mbz set to zero.  Note that this header follows the structure of struct ip6_hdr with the
     next header field ip6_nxt set to zero.

     The upcall header contains field im_msgtype and im6_msgtype with the type of the upcall
     IGMPMSG_* and MRT6MSG_* for IPv4 and IPv6 respectively.  The values of the rest of the
     upcall header fields and the body of the upcall message depend on the particular upcall
     type.

     If the upcall message type is IGMPMSG_NOCACHE or MRT6MSG_NOCACHE, this is an indication that
     a multicast packet has reached the multicast router, but the router has no forwarding state
     for that packet.  Typically, the upcall would be a signal for the multicast routing user-
     level process to install the appropriate Multicast Forwarding Cache (MFC) entry in the
     kernel.

     An MFC entry is added by:

     /* IPv4 */
     struct mfcctl mc;
     memset(&mc, 0, sizeof(mc));
     memcpy(&mc.mfcc_origin, &source_addr, sizeof(mc.mfcc_origin));
     memcpy(&mc.mfcc_mcastgrp, &group_addr, sizeof(mc.mfcc_mcastgrp));
     mc.mfcc_parent = iif_index;
     for (i = 0; i < maxvifs; i++)
         mc.mfcc_ttls[i] = oifs_ttl[i];
     setsockopt(mrouter_s4, IPPROTO_IP, MRT_ADD_MFC,
                (void *)&mc, sizeof(mc));

     /* IPv6 */
     struct mf6cctl mc;
     memset(&mc, 0, sizeof(mc));
     memcpy(&mc.mf6cc_origin, &source_addr, sizeof(mc.mf6cc_origin));
     memcpy(&mc.mf6cc_mcastgrp, &group_addr, sizeof(mf6cc_mcastgrp));
     mc.mf6cc_parent = iif_index;
     for (i = 0; i < maxvifs; i++)
         if (oifs_ttl[i] > 0)
             IF_SET(i, &mc.mf6cc_ifset);
     setsockopt(mrouter_s6, IPPROTO_IPV6, MRT6_ADD_MFC,
                (void *)&mc, sizeof(mc));

     The source_addr and group_addr are the source and group address of the multicast packet (as
     set in the upcall message).  The iif_index is the virtual interface index of the multicast
     interface the multicast packets for this specific source and group address should be
     received on.  The oifs_ttl[] array contains the minimum TTL (per interface) a multicast
     packet should have to be forwarded on an outgoing interface.  If the TTL value is zero, the
     corresponding interface is not included in the set of outgoing interfaces.  Note that in
     case of IPv6 only the set of outgoing interfaces can be specified.

     An MFC entry is deleted by:

     /* IPv4 */
     struct mfcctl mc;
     memset(&mc, 0, sizeof(mc));
     memcpy(&mc.mfcc_origin, &source_addr, sizeof(mc.mfcc_origin));
     memcpy(&mc.mfcc_mcastgrp, &group_addr, sizeof(mc.mfcc_mcastgrp));
     setsockopt(mrouter_s4, IPPROTO_IP, MRT_DEL_MFC,
                (void *)&mc, sizeof(mc));

     /* IPv6 */
     struct mf6cctl mc;
     memset(&mc, 0, sizeof(mc));
     memcpy(&mc.mf6cc_origin, &source_addr, sizeof(mc.mf6cc_origin));
     memcpy(&mc.mf6cc_mcastgrp, &group_addr, sizeof(mf6cc_mcastgrp));
     setsockopt(mrouter_s6, IPPROTO_IPV6, MRT6_DEL_MFC,
                (void *)&mc, sizeof(mc));

     The following method can be used to get various statistics per installed MFC entry in the
     kernel (e.g., the number of forwarded packets per source and group address):

     /* IPv4 */
     struct sioc_sg_req sgreq;
     memset(&sgreq, 0, sizeof(sgreq));
     memcpy(&sgreq.src, &source_addr, sizeof(sgreq.src));
     memcpy(&sgreq.grp, &group_addr, sizeof(sgreq.grp));
     ioctl(mrouter_s4, SIOCGETSGCNT, &sgreq);

     /* IPv6 */
     struct sioc_sg_req6 sgreq;
     memset(&sgreq, 0, sizeof(sgreq));
     memcpy(&sgreq.src, &source_addr, sizeof(sgreq.src));
     memcpy(&sgreq.grp, &group_addr, sizeof(sgreq.grp));
     ioctl(mrouter_s6, SIOCGETSGCNT_IN6, &sgreq);

     The following method can be used to get various statistics per multicast virtual interface
     in the kernel (e.g., the number of forwarded packets per interface):

     /* IPv4 */
     struct sioc_vif_req vreq;
     memset(&vreq, 0, sizeof(vreq));
     vreq.vifi = vif_index;
     ioctl(mrouter_s4, SIOCGETVIFCNT, &vreq);

     /* IPv6 */
     struct sioc_mif_req6 mreq;
     memset(&mreq, 0, sizeof(mreq));
     mreq.mifi = vif_index;
     ioctl(mrouter_s6, SIOCGETMIFCNT_IN6, &mreq);

   Advanced Multicast API Programming Guide
     If we want to add new features in the kernel, it becomes difficult to preserve backward
     compatibility (binary and API), and at the same time to allow user-level processes to take
     advantage of the new features (if the kernel supports them).

     One of the mechanisms that allows us to preserve the backward compatibility is a sort of
     negotiation between the user-level process and the kernel:

     1.   The user-level process tries to enable in the kernel the set of new features (and the
          corresponding API) it would like to use.

     2.   The kernel returns the (sub)set of features it knows about and is willing to be
          enabled.

     3.   The user-level process uses only that set of features the kernel has agreed on.

     To support backward compatibility, if the user-level process does not ask for any new
     features, the kernel defaults to the basic multicast API (see the Programming Guide
     section).  Currently, the advanced multicast API exists only for IPv4; in the future there
     will be IPv6 support as well.

     Below is a summary of the expandable API solution.  Note that all new options and structures
     are defined in <netinet/ip_mroute.h> and <netinet6/ip6_mroute.h>, unless stated otherwise.

     The user-level process uses new getsockopt()/setsockopt() options to perform the API
     features negotiation with the kernel.  This negotiation must be performed right after the
     multicast routing socket is open.  The set of desired/allowed features is stored in a bitset
     (currently, in uint32_t; i.e., maximum of 32 new features).  The new
     getsockopt()/setsockopt() options are MRT_API_SUPPORT and MRT_API_CONFIG.  Example:

     uint32_t v;
     getsockopt(sock, IPPROTO_IP, MRT_API_SUPPORT, (void *)&v, sizeof(v));

     would set in v the pre-defined bits that the kernel API supports.  The eight least
     significant bits in uint32_t are same as the eight possible flags MRT_MFC_FLAGS_* that can
     be used in mfcc_flags as part of the new definition of struct mfcctl (see below about those
     flags), which leaves 24 flags for other new features.  The value returned by
     getsockopt(MRT_API_SUPPORT) is read-only; in other words, setsockopt(MRT_API_SUPPORT) would
     fail.

     To modify the API, and to set some specific feature in the kernel, then:

     uint32_t v = MRT_MFC_FLAGS_DISABLE_WRONGVIF;
     if (setsockopt(sock, IPPROTO_IP, MRT_API_CONFIG, (void *)&v, sizeof(v))
         != 0) {
         return (ERROR);
     }
     if (v & MRT_MFC_FLAGS_DISABLE_WRONGVIF)
         return (OK);        /* Success */
     else
         return (ERROR);

     In other words, when setsockopt(MRT_API_CONFIG) is called, the argument to it specifies the
     desired set of features to be enabled in the API and the kernel.  The return value in v is
     the actual (sub)set of features that were enabled in the kernel.  To obtain later the same
     set of features that were enabled, then:

     getsockopt(sock, IPPROTO_IP, MRT_API_CONFIG, (void *)&v, sizeof(v));

     The set of enabled features is global.  In other words, setsockopt(MRT_API_CONFIG) should be
     called right after setsockopt(MRT_INIT).

     Currently, the following set of new features is defined:

     #define MRT_MFC_FLAGS_DISABLE_WRONGVIF (1 << 0) /* disable WRONGVIF signals */
     #define MRT_MFC_FLAGS_BORDER_VIF   (1 << 1)  /* border vif              */
     #define MRT_MFC_RP                 (1 << 8)  /* enable RP address       */
     #define MRT_MFC_BW_UPCALL          (1 << 9)  /* enable bw upcalls       */

     The advanced multicast API uses a newly defined struct mfcctl2 instead of the traditional
     struct mfcctl.  The original struct mfcctl is kept as is.  The new struct mfcctl2 is:

     /*
      * The new argument structure for MRT_ADD_MFC and MRT_DEL_MFC overlays
      * and extends the old struct mfcctl.
      */
     struct mfcctl2 {
             /* the mfcctl fields */
             struct in_addr  mfcc_origin;       /* ip origin of mcasts       */
             struct in_addr  mfcc_mcastgrp;     /* multicast group associated*/
             vifi_t          mfcc_parent;       /* incoming vif              */
             u_char          mfcc_ttls[MAXVIFS];/* forwarding ttls on vifs   */

             /* extension fields */
             uint8_t         mfcc_flags[MAXVIFS];/* the MRT_MFC_FLAGS_* flags*/
             struct in_addr  mfcc_rp;            /* the RP address           */
     };

     The new fields are mfcc_flags[MAXVIFS] and mfcc_rp.  Note that for compatibility reasons
     they are added at the end.

     The mfcc_flags[MAXVIFS] field is used to set various flags per interface per (S,G) entry.
     Currently, the defined flags are:

     #define MRT_MFC_FLAGS_DISABLE_WRONGVIF (1 << 0) /* disable WRONGVIF signals */
     #define MRT_MFC_FLAGS_BORDER_VIF       (1 << 1) /* border vif          */

     The MRT_MFC_FLAGS_DISABLE_WRONGVIF flag is used to explicitly disable the IGMPMSG_WRONGVIF
     kernel signal at the (S,G) granularity if a multicast data packet arrives on the wrong
     interface.  Usually, this signal is used to complete the shortest-path switch in case of
     PIM-SM multicast routing, or to trigger a PIM assert message.  However, it should not be
     delivered for interfaces that are not in the outgoing interface set, and that are not
     expecting to become an incoming interface.  Hence, if the MRT_MFC_FLAGS_DISABLE_WRONGVIF
     flag is set for some of the interfaces, then a data packet that arrives on that interface
     for that MFC entry will NOT trigger a WRONGVIF signal.  If that flag is not set, then a
     signal is triggered (the default action).

     The MRT_MFC_FLAGS_BORDER_VIF flag is used to specify whether the Border-bit in PIM Register
     messages should be set (in case when the Register encapsulation is performed inside the
     kernel).  If it is set for the special PIM Register kernel virtual interface (see pim(4)),
     the Border-bit in the Register messages sent to the RP will be set.

     The remaining six bits are reserved for future usage.

     The mfcc_rp field is used to specify the RP address (in case of PIM-SM multicast routing)
     for a multicast group G if we want to perform kernel-level PIM Register encapsulation.  The
     mfcc_rp field is used only if the MRT_MFC_RP advanced API flag/capability has been
     successfully set by setsockopt(MRT_API_CONFIG).

     If the MRT_MFC_RP flag was successfully set by setsockopt(MRT_API_CONFIG), then the kernel
     will attempt to perform the PIM Register encapsulation itself instead of sending the
     multicast data packets to user level (inside IGMPMSG_WHOLEPKT upcalls) for user-level
     encapsulation.  The RP address would be taken from the mfcc_rp field inside the new struct
     mfcctl2.  However, even if the MRT_MFC_RP flag was successfully set, if the mfcc_rp field
     was set to INADDR_ANY, then the kernel will still deliver an IGMPMSG_WHOLEPKT upcall with
     the multicast data packet to the user-level process.

     In addition, if the multicast data packet is too large to fit within a single IP packet
     after the PIM Register encapsulation (e.g., if its size was on the order of 65500 bytes),
     the data packet will be fragmented, and then each of the fragments will be encapsulated
     separately.  Note that typically a multicast data packet can be that large only if it was
     originated locally from the same hosts that performs the encapsulation; otherwise the
     transmission of the multicast data packet over Ethernet for example would have fragmented it
     into much smaller pieces.

     Typically, a multicast routing user-level process would need to know the forwarding
     bandwidth for some data flow.  For example, the multicast routing process may want to
     timeout idle MFC entries, or in case of PIM-SM it can initiate (S,G) shortest-path switch if
     the bandwidth rate is above a threshold for example.

     The original solution for measuring the bandwidth of a dataflow was that a user-level
     process would periodically query the kernel about the number of forwarded packets/bytes per
     (S,G), and then based on those numbers it would estimate whether a source has been idle, or
     whether the source's transmission bandwidth is above a threshold.  That solution is far from
     being scalable, hence the need for a new mechanism for bandwidth monitoring.

     Below is a description of the bandwidth monitoring mechanism.

        If the bandwidth of a data flow satisfies some pre-defined filter, the kernel delivers
         an upcall on the multicast routing socket to the multicast routing process that has
         installed that filter.

        The bandwidth-upcall filters are installed per (S,G).  There can be more than one filter
         per (S,G).

        Instead of supporting all possible comparison operations (i.e., < <= == != > >= ), there
         is support only for the <= and >= operations, because this makes the kernel-level
         implementation simpler, and because practically we need only those two.  Further, the
         missing operations can be simulated by secondary user-level filtering of those <= and >=
         filters.  For example, to simulate !=, then we need to install filter “bw <=
         0xffffffff”, and after an upcall is received, we need to check whether “measured_bw !=
         expected_bw”.

        The bandwidth-upcall mechanism is enabled by setsockopt(MRT_API_CONFIG) for the
         MRT_MFC_BW_UPCALL flag.

        The bandwidth-upcall filters are added/deleted by the new setsockopt(MRT_ADD_BW_UPCALL)
         and setsockopt(MRT_DEL_BW_UPCALL) respectively (with the appropriate struct bw_upcall
         argument of course).

     From application point of view, a developer needs to know about the following:

     /*
      * Structure for installing or delivering an upcall if the
      * measured bandwidth is above or below a threshold.
      *
      * User programs (e.g. daemons) may have a need to know when the
      * bandwidth used by some data flow is above or below some threshold.
      * This interface allows the userland to specify the threshold (in
      * bytes and/or packets) and the measurement interval. Flows are
      * all packet with the same source and destination IP address.
      * At the moment the code is only used for multicast destinations
      * but there is nothing that prevents its use for unicast.
      *
      * The measurement interval cannot be shorter than some Tmin (currently, 3s).
      * The threshold is set in packets and/or bytes per_interval.
      *
      * Measurement works as follows:
      *
      * For >= measurements:
      * The first packet marks the start of a measurement interval.
      * During an interval we count packets and bytes, and when we
      * pass the threshold we deliver an upcall and we are done.
      * The first packet after the end of the interval resets the
      * count and restarts the measurement.
      *
      * For <= measurement:
      * We start a timer to fire at the end of the interval, and
      * then for each incoming packet we count packets and bytes.
      * When the timer fires, we compare the value with the threshold,
      * schedule an upcall if we are below, and restart the measurement
      * (reschedule timer and zero counters).
      */

     struct bw_data {
             struct timeval  b_time;
             uint64_t        b_packets;
             uint64_t        b_bytes;
     };

     struct bw_upcall {
             struct in_addr  bu_src;         /* source address            */
             struct in_addr  bu_dst;         /* destination address       */
             uint32_t        bu_flags;       /* misc flags (see below)    */
     #define BW_UPCALL_UNIT_PACKETS (1 << 0) /* threshold (in packets)    */
     #define BW_UPCALL_UNIT_BYTES   (1 << 1) /* threshold (in bytes)      */
     #define BW_UPCALL_GEQ          (1 << 2) /* upcall if bw >= threshold */
     #define BW_UPCALL_LEQ          (1 << 3) /* upcall if bw <= threshold */
     #define BW_UPCALL_DELETE_ALL   (1 << 4) /* delete all upcalls for s,d*/
             struct bw_data  bu_threshold;   /* the bw threshold          */
             struct bw_data  bu_measured;    /* the measured bw           */
     };

     /* max. number of upcalls to deliver together */
     #define BW_UPCALLS_MAX                          128
     /* min. threshold time interval for bandwidth measurement */
     #define BW_UPCALL_THRESHOLD_INTERVAL_MIN_SEC    3
     #define BW_UPCALL_THRESHOLD_INTERVAL_MIN_USEC   0

     The bw_upcall structure is used as an argument to setsockopt(MRT_ADD_BW_UPCALL) and
     setsockopt(MRT_DEL_BW_UPCALL).  Each setsockopt(MRT_ADD_BW_UPCALL) installs a filter in the
     kernel for the source and destination address in the bw_upcall argument, and that filter
     will trigger an upcall according to the following pseudo-algorithm:

      if (bw_upcall_oper IS ">=") {
         if (((bw_upcall_unit & PACKETS == PACKETS) &&
              (measured_packets >= threshold_packets)) ||
             ((bw_upcall_unit & BYTES == BYTES) &&
              (measured_bytes >= threshold_bytes)))
            SEND_UPCALL("measured bandwidth is >= threshold");
       }
       if (bw_upcall_oper IS "<=" && measured_interval >= threshold_interval) {
         if (((bw_upcall_unit & PACKETS == PACKETS) &&
              (measured_packets <= threshold_packets)) ||
             ((bw_upcall_unit & BYTES == BYTES) &&
              (measured_bytes <= threshold_bytes)))
            SEND_UPCALL("measured bandwidth is <= threshold");
       }

     In the same bw_upcall the unit can be specified in both BYTES and PACKETS.  However, the GEQ
     and LEQ flags are mutually exclusive.

     Basically, an upcall is delivered if the measured bandwidth is >= or <= the threshold
     bandwidth (within the specified measurement interval).  For practical reasons, the smallest
     value for the measurement interval is 3 seconds.  If smaller values are allowed, then the
     bandwidth estimation may be less accurate, or the potentially very high frequency of the
     generated upcalls may introduce too much overhead.  For the >= operation, the answer may be
     known before the end of threshold_interval, therefore the upcall may be delivered earlier.
     For the <= operation however, we must wait until the threshold interval has expired to know
     the answer.

     Example of usage:

     struct bw_upcall bw_upcall;
     /* Assign all bw_upcall fields as appropriate */
     memset(&bw_upcall, 0, sizeof(bw_upcall));
     memcpy(&bw_upcall.bu_src, &source, sizeof(bw_upcall.bu_src));
     memcpy(&bw_upcall.bu_dst, &group, sizeof(bw_upcall.bu_dst));
     bw_upcall.bu_threshold.b_data = threshold_interval;
     bw_upcall.bu_threshold.b_packets = threshold_packets;
     bw_upcall.bu_threshold.b_bytes = threshold_bytes;
     if (is_threshold_in_packets)
         bw_upcall.bu_flags |= BW_UPCALL_UNIT_PACKETS;
     if (is_threshold_in_bytes)
         bw_upcall.bu_flags |= BW_UPCALL_UNIT_BYTES;
     do {
         if (is_geq_upcall) {
             bw_upcall.bu_flags |= BW_UPCALL_GEQ;
             break;
         }
         if (is_leq_upcall) {
             bw_upcall.bu_flags |= BW_UPCALL_LEQ;
             break;
         }
         return (ERROR);
     } while (0);
     setsockopt(mrouter_s4, IPPROTO_IP, MRT_ADD_BW_UPCALL,
               (void *)&bw_upcall, sizeof(bw_upcall));

     To delete a single filter, then use MRT_DEL_BW_UPCALL, and the fields of bw_upcall must be
     set exactly same as when MRT_ADD_BW_UPCALL was called.

     To delete all bandwidth filters for a given (S,G), then only the bu_src and bu_dst fields in
     struct bw_upcall need to be set, and then just set only the BW_UPCALL_DELETE_ALL flag inside
     field bw_upcall.bu_flags.

     The bandwidth upcalls are received by aggregating them in the new upcall message:

     #define IGMPMSG_BW_UPCALL  4  /* BW monitoring upcall */

     This message is an array of struct bw_upcall elements (up to BW_UPCALLS_MAX = 128).  The
     upcalls are delivered when there are 128 pending upcalls, or when 1 second has expired since
     the previous upcall (whichever comes first).  In an struct upcall element, the bu_measured
     field is filled-in to indicate the particular measured values.  However, because of the way
     the particular intervals are measured, the user should be careful how bu_measured.b_time is
     used.  For example, if the filter is installed to trigger an upcall if the number of packets
     is >= 1, then bu_measured may have a value of zero in the upcalls after the first one,
     because the measured interval for >= filters is “clocked” by the forwarded packets.  Hence,
     this upcall mechanism should not be used for measuring the exact value of the bandwidth of
     the forwarded data.  To measure the exact bandwidth, the user would need to get the
     forwarded packets statistics with the ioctl(SIOCGETSGCNT) mechanism (see the Programming
     Guide section) .

     Note that the upcalls for a filter are delivered until the specific filter is deleted, but
     no more frequently than once per bu_threshold.b_time.  For example, if the filter is
     specified to deliver a signal if bw >= 1 packet, the first packet will trigger a signal, but
     the next upcall will be triggered no earlier than bu_threshold.b_time after the previous
     upcall.

SEE ALSO

     altq(4), dummynet(4), getsockopt(2), gif(4), gre(4), recvfrom(2), recvmsg(2), setsockopt(2),
     socket(2), sourcefilter(3), icmp6(4), igmp(4), inet(4), inet6(4), intro(4), ip(4), ip6(4),
     mld(4), pim(4)

HISTORY

     The Distance Vector Multicast Routing Protocol (DVMRP) was the first developed multicast
     routing protocol.  Later, other protocols such as Multicast Extensions to OSPF (MOSPF) and
     Core Based Trees (CBT), were developed as well.  Routers at autonomous system boundaries may
     now exchange multicast routes with peers via the Border Gateway Protocol (BGP).  Many other
     routing protocols are able to redistribute multicast routes for use with PIM-SM and PIM-DM.

AUTHORS

     The original multicast code was written by David Waitzman (BBN Labs), and later modified by
     the following individuals: Steve Deering (Stanford), Mark J. Steiglitz (Stanford), Van
     Jacobson (LBL), Ajit Thyagarajan (PARC), Bill Fenner (PARC).  The IPv6 multicast support was
     implemented by the KAME project (http://www.kame.net), and was based on the IPv4 multicast
     code.  The advanced multicast API and the multicast bandwidth monitoring were implemented by
     Pavlin Radoslavov (ICSI) in collaboration with Chris Brown (NextHop).  The IGMPv3 and MLDv2
     multicast support was implemented by Bruce Simpson.

     This manual page was written by Pavlin Radoslavov (ICSI).