include/linux/netfilter_ipv4/ip_conntrack_tuple.h - pub/scm/linux/kernel/git/iwlwifi/iwlwifi-next - Git at Google

 #ifndef _IP_CONNTRACK_TUPLE_H
 #define _IP_CONNTRACK_TUPLE_H

 /* A `tuple' is a structure containing the information to uniquely
   identify a connection.  ie. if two packets have the same tuple, they
   are in the same connection; if not, they are not.

   We divide the structure along "manipulatable" and
   "non-manipulatable" lines, for the benefit of the NAT code.
 */

 /* The protocol-specific manipulable parts of the tuple: always in
    network order! */
 union ip_conntrack_manip_proto
 {
 	/* Add other protocols here. */
 	u_int16_t all;

 	struct {
 		u_int16_t port;
 	} tcp;
 	struct {
 		u_int16_t port;
 	} udp;
 	struct {
 		u_int16_t id;
 	} icmp;
 	struct {
 		u_int16_t port;
 	} sctp;
 };

 /* The manipulable part of the tuple. */
 struct ip_conntrack_manip
 {
 	u_int32_t ip;
 	union ip_conntrack_manip_proto u;
 };

 /* This contains the information to distinguish a connection. */
 struct ip_conntrack_tuple
 {
 	struct ip_conntrack_manip src;

 	/* These are the parts of the tuple which are fixed. */
 	struct {
 		u_int32_t ip;
 		union {
 			/* Add other protocols here. */
 			u_int16_t all;

 			struct {
 				u_int16_t port;
 			} tcp;
 			struct {
 				u_int16_t port;
 			} udp;
 			struct {
 				u_int8_t type, code;
 			} icmp;
 			struct {
 				u_int16_t port;
 			} sctp;
 		} u;

 		/* The protocol. */
 		u_int8_t protonum;

 		/* The direction (for tuplehash) */
 		u_int8_t dir;
 	} dst;
 };

 /* This is optimized opposed to a memset of the whole structure.  Everything we
  * really care about is the  source/destination unions */
 #define IP_CT_TUPLE_U_BLANK(tuple) 				\
 	do {							\
 		(tuple)->src.u.all = 0;				\
 		(tuple)->dst.u.all = 0;				\
 	} while (0)

 enum ip_conntrack_dir
 {
 	IP_CT_DIR_ORIGINAL,
 	IP_CT_DIR_REPLY,
 	IP_CT_DIR_MAX
 };

 #ifdef __KERNEL__

 #define DUMP_TUPLE(tp)						\
 DEBUGP("tuple %p: %u %u.%u.%u.%u:%hu -> %u.%u.%u.%u:%hu\n",	\
        (tp), (tp)->dst.protonum,				\
        NIPQUAD((tp)->src.ip), ntohs((tp)->src.u.all),		\
        NIPQUAD((tp)->dst.ip), ntohs((tp)->dst.u.all))

 #define CTINFO2DIR(ctinfo) ((ctinfo) >= IP_CT_IS_REPLY ? IP_CT_DIR_REPLY : IP_CT_DIR_ORIGINAL)

 /* If we're the first tuple, it's the original dir. */
 #define DIRECTION(h) ((enum ip_conntrack_dir)(h)->tuple.dst.dir)

 /* Connections have two entries in the hash table: one for each way */
 struct ip_conntrack_tuple_hash
 {
 	struct list_head list;

 	struct ip_conntrack_tuple tuple;
 };

 #endif /* __KERNEL__ */

 static inline int ip_ct_tuple_src_equal(const struct ip_conntrack_tuple *t1,
 				        const struct ip_conntrack_tuple *t2)
 {
 	return t1->src.ip == t2->src.ip
 		&& t1->src.u.all == t2->src.u.all;
 }

 static inline int ip_ct_tuple_dst_equal(const struct ip_conntrack_tuple *t1,
 				        const struct ip_conntrack_tuple *t2)
 {
 	return t1->dst.ip == t2->dst.ip
 		&& t1->dst.u.all == t2->dst.u.all
 		&& t1->dst.protonum == t2->dst.protonum;
 }

 static inline int ip_ct_tuple_equal(const struct ip_conntrack_tuple *t1,
 				    const struct ip_conntrack_tuple *t2)
 {
 	return ip_ct_tuple_src_equal(t1, t2) && ip_ct_tuple_dst_equal(t1, t2);
 }

 static inline int ip_ct_tuple_mask_cmp(const struct ip_conntrack_tuple *t,
 				       const struct ip_conntrack_tuple *tuple,
 				       const struct ip_conntrack_tuple *mask)
 {
 	return !(((t->src.ip ^ tuple->src.ip) & mask->src.ip)
 		 || ((t->dst.ip ^ tuple->dst.ip) & mask->dst.ip)
 		 || ((t->src.u.all ^ tuple->src.u.all) & mask->src.u.all)
 		 || ((t->dst.u.all ^ tuple->dst.u.all) & mask->dst.u.all)
 		 || ((t->dst.protonum ^ tuple->dst.protonum)
 		     & mask->dst.protonum));
 }

 #endif /* _IP_CONNTRACK_TUPLE_H */
	#ifndef _IP_CONNTRACK_TUPLE_H
	#define _IP_CONNTRACK_TUPLE_H

	/* A `tuple' is a structure containing the information to uniquely
	identify a connection. ie. if two packets have the same tuple, they
	are in the same connection; if not, they are not.

	We divide the structure along "manipulatable" and
	"non-manipulatable" lines, for the benefit of the NAT code.
	*/

	/* The protocol-specific manipulable parts of the tuple: always in
	network order! */
	union ip_conntrack_manip_proto
	{
	/* Add other protocols here. */
	u_int16_t all;

	struct {
	u_int16_t port;
	} tcp;
	struct {
	u_int16_t port;
	} udp;
	struct {
	u_int16_t id;
	} icmp;
	struct {
	u_int16_t port;
	} sctp;
	};

	/* The manipulable part of the tuple. */
	struct ip_conntrack_manip
	{
	u_int32_t ip;
	union ip_conntrack_manip_proto u;
	};

	/* This contains the information to distinguish a connection. */
	struct ip_conntrack_tuple
	{
	struct ip_conntrack_manip src;

	/* These are the parts of the tuple which are fixed. */
	struct {
	u_int32_t ip;
	union {
	/* Add other protocols here. */
	u_int16_t all;

	struct {
	u_int16_t port;
	} tcp;
	struct {
	u_int16_t port;
	} udp;
	struct {
	u_int8_t type, code;
	} icmp;
	struct {
	u_int16_t port;
	} sctp;
	} u;

	/* The protocol. */
	u_int8_t protonum;

	/* The direction (for tuplehash) */
	u_int8_t dir;
	} dst;
	};

	/* This is optimized opposed to a memset of the whole structure. Everything we
	* really care about is the source/destination unions */
	#define IP_CT_TUPLE_U_BLANK(tuple) \
	do { \
	(tuple)->src.u.all = 0; \
	(tuple)->dst.u.all = 0; \
	} while (0)

	enum ip_conntrack_dir
	{
	IP_CT_DIR_ORIGINAL,
	IP_CT_DIR_REPLY,
	IP_CT_DIR_MAX
	};

	#ifdef __KERNEL__

	#define DUMP_TUPLE(tp) \
	DEBUGP("tuple %p: %u %u.%u.%u.%u:%hu -> %u.%u.%u.%u:%hu\n", \
	(tp), (tp)->dst.protonum, \
	NIPQUAD((tp)->src.ip), ntohs((tp)->src.u.all), \
	NIPQUAD((tp)->dst.ip), ntohs((tp)->dst.u.all))

	#define CTINFO2DIR(ctinfo) ((ctinfo) >= IP_CT_IS_REPLY ? IP_CT_DIR_REPLY : IP_CT_DIR_ORIGINAL)

	/* If we're the first tuple, it's the original dir. */
	#define DIRECTION(h) ((enum ip_conntrack_dir)(h)->tuple.dst.dir)

	/* Connections have two entries in the hash table: one for each way */
	struct ip_conntrack_tuple_hash
	{
	struct list_head list;

	struct ip_conntrack_tuple tuple;
	};

	#endif /* __KERNEL__ */

	static inline int ip_ct_tuple_src_equal(const struct ip_conntrack_tuple *t1,
	const struct ip_conntrack_tuple *t2)
	{
	return t1->src.ip == t2->src.ip
	&& t1->src.u.all == t2->src.u.all;
	}

	static inline int ip_ct_tuple_dst_equal(const struct ip_conntrack_tuple *t1,
	const struct ip_conntrack_tuple *t2)
	{
	return t1->dst.ip == t2->dst.ip
	&& t1->dst.u.all == t2->dst.u.all
	&& t1->dst.protonum == t2->dst.protonum;
	}

	static inline int ip_ct_tuple_equal(const struct ip_conntrack_tuple *t1,
	const struct ip_conntrack_tuple *t2)
	{
	return ip_ct_tuple_src_equal(t1, t2) && ip_ct_tuple_dst_equal(t1, t2);
	}

	static inline int ip_ct_tuple_mask_cmp(const struct ip_conntrack_tuple *t,
	const struct ip_conntrack_tuple *tuple,
	const struct ip_conntrack_tuple *mask)
	{
	return !(((t->src.ip ^ tuple->src.ip) & mask->src.ip)
	\|\| ((t->dst.ip ^ tuple->dst.ip) & mask->dst.ip)
	\|\| ((t->src.u.all ^ tuple->src.u.all) & mask->src.u.all)
	\|\| ((t->dst.u.all ^ tuple->dst.u.all) & mask->dst.u.all)
	\|\| ((t->dst.protonum ^ tuple->dst.protonum)
	& mask->dst.protonum));
	}

	#endif /* _IP_CONNTRACK_TUPLE_H */