ipsend/in_var.h - net/ipfilter - Rivoreo Source Code Repositories

 /*	@(#)in_var.h 1.3 88/08/19 SMI; from UCB 7.1 6/5/86	*/

 /*
  * Copyright (c) 1985, 1986 Regents of the University of California.
  * All rights reserved.  The Berkeley software License Agreement
  * specifies the terms and conditions for redistribution.
  */

 /*
  * Interface address, Internet version.  One of these structures
  * is allocated for each interface with an Internet address.
  * The ifaddr structure contains the protocol-independent part
  * of the structure and is assumed to be first.
  */

 #ifndef _netinet_in_var_h
 #define _netinet_in_var_h

 struct in_ifaddr {
 	struct	ifaddr ia_ifa;		/* protocol-independent info */
 #define	ia_addr	ia_ifa.ifa_addr
 #define	ia_broadaddr	ia_ifa.ifa_broadaddr
 #define	ia_dstaddr	ia_ifa.ifa_dstaddr
 #define	ia_ifp		ia_ifa.ifa_ifp
 	u_long	ia_net;			/* network number of interface */
 	u_long	ia_netmask;		/* mask of net part */
 	u_long	ia_subnet;		/* subnet number, including net */
 	u_long	ia_subnetmask;		/* mask of net + subnet */
 	struct	in_addr ia_netbroadcast; /* broadcast addr for (logical) net */
 	int	ia_flags;
 	struct	in_ifaddr *ia_next;	/* next in list of internet addresses */
 	struct	in_multi *ia_multiaddrs;/* list of multicast addresses */
 };
 /*
  * Given a pointer to an in_ifaddr (ifaddr),
  * return a pointer to the addr as a sockadd_in.
  */
 #define	IA_SIN(ia) ((struct sockaddr_in *)(&((struct in_ifaddr *)ia)->ia_addr))
 /*
  * ia_flags
  */
 #define	IFA_ROUTE	0x01		/* routing entry installed */

 #ifdef	KERNEL
 struct	in_ifaddr *in_ifaddr;
 struct	in_ifaddr *in_iaonnetof();
 struct	ifqueue	ipintrq;		/* ip packet input queue */
 #endif

 #ifdef KERNEL
 /*
  * Macro for finding the interface (ifnet structure) corresponding to one
  * of our IP addresses.
  */
 #define INADDR_TO_IFP(addr, ifp)					  \
 	/* struct in_addr addr; */					  \
 	/* struct ifnet  *ifp;  */					  \
 {									  \
 	register struct in_ifaddr *ia;					  \
 									  \
 	for (ia = in_ifaddr;						  \
 	     ia != NULL && IA_SIN(ia)->sin_addr.s_addr != (addr).s_addr;  \
 	     ia = ia->ia_next);						  \
 	(ifp) = (ia == NULL) ? NULL : ia->ia_ifp;			  \
 }

 /*
  * Macro for finding the internet address structure (in_ifaddr) corresponding
  * to a given interface (ifnet structure).
  */
 #define IFP_TO_IA(ifp, ia)						  \
 	/* struct ifnet     *ifp; */					  \
 	/* struct in_ifaddr *ia;  */					  \
 {									  \
 	for ((ia) = in_ifaddr;						  \
 	     (ia) != NULL && (ia)->ia_ifp != (ifp);			  \
 	     (ia) = (ia)->ia_next);					  \
 }
 #endif KERNEL

 /*
  * Per-interface router version information is kept in this list.
  * This information should be part of the ifnet structure but we don't wish
  * to change that - as it might break a number of things
  */

 struct router_info {
 	struct ifnet *ifp;
 	int    type; /* type of router which is querier on this interface */
 	int    time; /* # of slow timeouts since last old query */
 	struct router_info *next;
 };

 /*
  * Internet multicast address structure.  There is one of these for each IP
  * multicast group to which this host belongs on a given network interface.
  * They are kept in a linked list, rooted in the interface's in_ifaddr
  * structure.
  */

 struct in_multi {
 	struct in_addr	   inm_addr;	/* IP multicast address             */
 	struct ifnet      *inm_ifp;	/* back pointer to ifnet            */
 	struct in_ifaddr  *inm_ia;	/* back pointer to in_ifaddr        */
 	u_int		   inm_refcount;/* no. membership claims by sockets */
 	u_int		   inm_timer;	/* IGMP membership report timer     */
 	struct in_multi   *inm_next;	/* ptr to next multicast address    */
 	u_int              inm_state;   /*  state of the membership */
 	struct router_info *inm_rti;     /* router info*/
 };

 #ifdef KERNEL
 /*
  * Structure used by macros below to remember position when stepping through
  * all of the in_multi records.
  */
 struct in_multistep {
 	struct in_ifaddr *i_ia;
 	struct in_multi  *i_inm;
 };

 /*
  * Macro for looking up the in_multi record for a given IP multicast address
  * on a given interface.  If no matching record is found, "inm" returns NULL.
  */
 #define IN_LOOKUP_MULTI(addr, ifp, inm)					    \
 	/* struct in_addr  addr; */					    \
 	/* struct ifnet    *ifp; */					    \
 	/* struct in_multi *inm; */					    \
 {									    \
 	register struct in_ifaddr *ia;					    \
 									    \
 	IFP_TO_IA((ifp), ia);						    \
 	if (ia == NULL)							    \
 		(inm) = NULL;						    \
 	else								    \
 	    for ((inm) = ia->ia_multiaddrs;				    \
 		 (inm) != NULL && (inm)->inm_addr.s_addr != (addr).s_addr;  \
 		 (inm) = inm->inm_next);				    \
 }

 /*
  * Macro to step through all of the in_multi records, one at a time.
  * The current position is remembered in "step", which the caller must
  * provide.  IN_FIRST_MULTI(), below, must be called to initialize "step"
  * and get the first record.  Both macros return a NULL "inm" when there
  * are no remaining records.
  */
 #define IN_NEXT_MULTI(step, inm)					\
 	/* struct in_multistep  step; */				\
 	/* struct in_multi     *inm;  */				\
 {									\
 	if (((inm) = (step).i_inm) != NULL) {				\
 		(step).i_inm = (inm)->inm_next;				\
 	}								\
 	else while ((step).i_ia != NULL) {				\
 		(inm) = (step).i_ia->ia_multiaddrs;			\
 		(step).i_ia = (step).i_ia->ia_next;			\
 		if ((inm) != NULL) {					\
 			(step).i_inm = (inm)->inm_next;			\
 			break;						\
 		}							\
 	}								\
 }

 #define IN_FIRST_MULTI(step, inm)					\
 	/* struct in_multistep  step; */				\
 	/* struct in_multi     *inm;  */				\
 {									\
 	(step).i_ia  = in_ifaddr;					\
 	(step).i_inm = NULL;						\
 	IN_NEXT_MULTI((step), (inm));					\
 }

 struct in_multi *in_addmulti();
 #endif KERNEL
 #endif /*!_netinet_in_var_h*/
	/* @(#)in_var.h 1.3 88/08/19 SMI; from UCB 7.1 6/5/86 */

	/*
	* Copyright (c) 1985, 1986 Regents of the University of California.
	* All rights reserved. The Berkeley software License Agreement
	* specifies the terms and conditions for redistribution.
	*/

	/*
	* Interface address, Internet version. One of these structures
	* is allocated for each interface with an Internet address.
	* The ifaddr structure contains the protocol-independent part
	* of the structure and is assumed to be first.
	*/

	#ifndef _netinet_in_var_h
	#define _netinet_in_var_h

	struct in_ifaddr {
	struct ifaddr ia_ifa; /* protocol-independent info */
	#define ia_addr ia_ifa.ifa_addr
	#define ia_broadaddr ia_ifa.ifa_broadaddr
	#define ia_dstaddr ia_ifa.ifa_dstaddr
	#define ia_ifp ia_ifa.ifa_ifp
	u_long ia_net; /* network number of interface */
	u_long ia_netmask; /* mask of net part */
	u_long ia_subnet; /* subnet number, including net */
	u_long ia_subnetmask; /* mask of net + subnet */
	struct in_addr ia_netbroadcast; /* broadcast addr for (logical) net */
	int ia_flags;
	struct in_ifaddr ia_next; / next in list of internet addresses */
	struct in_multi ia_multiaddrs;/ list of multicast addresses */
	};
	/*
	* Given a pointer to an in_ifaddr (ifaddr),
	* return a pointer to the addr as a sockadd_in.
	*/
	#define IA_SIN(ia) ((struct sockaddr_in )(&((struct in_ifaddr )ia)->ia_addr))
	/*
	* ia_flags
	*/
	#define IFA_ROUTE 0x01 /* routing entry installed */

	#ifdef KERNEL
	struct in_ifaddr *in_ifaddr;
	struct in_ifaddr *in_iaonnetof();
	struct ifqueue ipintrq; /* ip packet input queue */
	#endif

	#ifdef KERNEL
	/*
	* Macro for finding the interface (ifnet structure) corresponding to one
	* of our IP addresses.
	*/
	#define INADDR_TO_IFP(addr, ifp) \
	/* struct in_addr addr; */ \
	/* struct ifnet ifp; / \
	{ \
	register struct in_ifaddr *ia; \
	\
	for (ia = in_ifaddr; \
	ia != NULL && IA_SIN(ia)->sin_addr.s_addr != (addr).s_addr; \
	ia = ia->ia_next); \
	(ifp) = (ia == NULL) ? NULL : ia->ia_ifp; \
	}

	/*
	* Macro for finding the internet address structure (in_ifaddr) corresponding
	* to a given interface (ifnet structure).
	*/
	#define IFP_TO_IA(ifp, ia) \
	/* struct ifnet ifp; / \
	/* struct in_ifaddr ia; / \
	{ \
	for ((ia) = in_ifaddr; \
	(ia) != NULL && (ia)->ia_ifp != (ifp); \
	(ia) = (ia)->ia_next); \
	}
	#endif KERNEL

	/*
	* Per-interface router version information is kept in this list.
	* This information should be part of the ifnet structure but we don't wish
	* to change that - as it might break a number of things
	*/

	struct router_info {
	struct ifnet *ifp;
	int type; /* type of router which is querier on this interface */
	int time; /* # of slow timeouts since last old query */
	struct router_info *next;
	};

	/*
	* Internet multicast address structure. There is one of these for each IP
	* multicast group to which this host belongs on a given network interface.
	* They are kept in a linked list, rooted in the interface's in_ifaddr
	* structure.
	*/

	struct in_multi {
	struct in_addr inm_addr; /* IP multicast address */
	struct ifnet inm_ifp; / back pointer to ifnet */
	struct in_ifaddr inm_ia; / back pointer to in_ifaddr */
	u_int inm_refcount;/* no. membership claims by sockets */
	u_int inm_timer; /* IGMP membership report timer */
	struct in_multi inm_next; / ptr to next multicast address */
	u_int inm_state; /* state of the membership */
	struct router_info inm_rti; / router info*/
	};

	#ifdef KERNEL
	/*
	* Structure used by macros below to remember position when stepping through
	* all of the in_multi records.
	*/
	struct in_multistep {
	struct in_ifaddr *i_ia;
	struct in_multi *i_inm;
	};

	/*
	* Macro for looking up the in_multi record for a given IP multicast address
	* on a given interface. If no matching record is found, "inm" returns NULL.
	*/
	#define IN_LOOKUP_MULTI(addr, ifp, inm) \
	/* struct in_addr addr; */ \
	/* struct ifnet ifp; / \
	/* struct in_multi inm; / \
	{ \
	register struct in_ifaddr *ia; \
	\
	IFP_TO_IA((ifp), ia); \
	if (ia == NULL) \
	(inm) = NULL; \
	else \
	for ((inm) = ia->ia_multiaddrs; \
	(inm) != NULL && (inm)->inm_addr.s_addr != (addr).s_addr; \
	(inm) = inm->inm_next); \
	}

	/*
	* Macro to step through all of the in_multi records, one at a time.
	* The current position is remembered in "step", which the caller must
	* provide. IN_FIRST_MULTI(), below, must be called to initialize "step"
	* and get the first record. Both macros return a NULL "inm" when there
	* are no remaining records.
	*/
	#define IN_NEXT_MULTI(step, inm) \
	/* struct in_multistep step; */ \
	/* struct in_multi inm; / \
	{ \
	if (((inm) = (step).i_inm) != NULL) { \
	(step).i_inm = (inm)->inm_next; \
	} \
	else while ((step).i_ia != NULL) { \
	(inm) = (step).i_ia->ia_multiaddrs; \
	(step).i_ia = (step).i_ia->ia_next; \
	if ((inm) != NULL) { \
	(step).i_inm = (inm)->inm_next; \
	break; \
	} \
	} \
	}

	#define IN_FIRST_MULTI(step, inm) \
	/* struct in_multistep step; */ \
	/* struct in_multi inm; / \
	{ \
	(step).i_ia = in_ifaddr; \
	(step).i_inm = NULL; \
	IN_NEXT_MULTI((step), (inm)); \
	}

	struct in_multi *in_addmulti();
	#endif KERNEL
	#endif /!_netinet_in_var_h/