net/sched/em_meta.c - android_kernel_htc_msm8960 - Gitiles

 /*
  * net/sched/em_meta.c	Metadata ematch
  *
  *		This program is free software; you can redistribute it and/or
  *		modify it under the terms of the GNU General Public License
  *		as published by the Free Software Foundation; either version
  *		2 of the License, or (at your option) any later version.
  *
  * Authors:	Thomas Graf <tgraf@suug.ch>
  *
  * ==========================================================================
  *
  * 	The metadata ematch compares two meta objects where each object
  * 	represents either a meta value stored in the kernel or a static
  * 	value provided by userspace. The objects are not provided by
  * 	userspace itself but rather a definition providing the information
  * 	to build them. Every object is of a certain type which must be
  * 	equal to the object it is being compared to.
  *
  * 	The definition of a objects conists of the type (meta type), a
  * 	identifier (meta id) and additional type specific information.
  * 	The meta id is either TCF_META_TYPE_VALUE for values provided by
  * 	userspace or a index to the meta operations table consisting of
  * 	function pointers to type specific meta data collectors returning
  * 	the value of the requested meta value.
  *
  * 	         lvalue                                   rvalue
  * 	      +-----------+                           +-----------+
  * 	      | type: INT |                           | type: INT |
  * 	 def  | id: DEV   |                           | id: VALUE |
  * 	      | data:     |                           | data: 3   |
  * 	      +-----------+                           +-----------+
  * 	            |                                       |
  * 	            ---> meta_ops[INT][DEV](...)            |
  *	                      |                             |
  * 	            -----------                             |
  * 	            V                                       V
  * 	      +-----------+                           +-----------+
  * 	      | type: INT |                           | type: INT |
  * 	 obj  | id: DEV |                             | id: VALUE |
  * 	      | data: 2   |<--data got filled out     | data: 3   |
  * 	      +-----------+                           +-----------+
  * 	            |                                         |
  * 	            --------------> 2  equals 3 <--------------
  *
  * 	This is a simplified schema, the complexity varies depending
  * 	on the meta type. Obviously, the length of the data must also
  * 	be provided for non-numeric types.
  *
  * 	Additionaly, type dependant modifiers such as shift operators
  * 	or mask may be applied to extend the functionaliy. As of now,
  * 	the variable length type supports shifting the byte string to
  * 	the right, eating up any number of octets and thus supporting
  * 	wildcard interface name comparisons such as "ppp%" matching
  * 	ppp0..9.
  *
  * 	NOTE: Certain meta values depend on other subsystems and are
  * 	      only available if that subsytem is enabled in the kernel.
  */

 #include <linux/module.h>
 #include <linux/types.h>
 #include <linux/kernel.h>
 #include <linux/sched.h>
 #include <linux/string.h>
 #include <linux/skbuff.h>
 #include <linux/random.h>
 #include <linux/tc_ematch/tc_em_meta.h>
 #include <net/dst.h>
 #include <net/route.h>
 #include <net/pkt_cls.h>
 #include <net/sock.h>

 struct meta_obj
 {
 	unsigned long		value;
 	unsigned int		len;
 };

 struct meta_value
 {
 	struct tcf_meta_val	hdr;
 	unsigned long		val;
 	unsigned int		len;
 };

 struct meta_match
 {
 	struct meta_value	lvalue;
 	struct meta_value	rvalue;
 };

 static inline int meta_id(struct meta_value *v)
 {
 	return TCF_META_ID(v->hdr.kind);
 }

 static inline int meta_type(struct meta_value *v)
 {
 	return TCF_META_TYPE(v->hdr.kind);
 }

 #define META_COLLECTOR(FUNC) static void meta_##FUNC(struct sk_buff *skb, \
 	struct tcf_pkt_info *info, struct meta_value *v, \
 	struct meta_obj *dst, int *err)

 /**************************************************************************
  * System status & misc
  **************************************************************************/

 META_COLLECTOR(int_random)
 {
 	get_random_bytes(&dst->value, sizeof(dst->value));
 }

 static inline unsigned long fixed_loadavg(int load)
 {
 	int rnd_load = load + (FIXED_1/200);
 	int rnd_frac = ((rnd_load & (FIXED_1-1)) * 100) >> FSHIFT;

 	return ((rnd_load >> FSHIFT) * 100) + rnd_frac;
 }

 META_COLLECTOR(int_loadavg_0)
 {
 	dst->value = fixed_loadavg(avenrun[0]);
 }

 META_COLLECTOR(int_loadavg_1)
 {
 	dst->value = fixed_loadavg(avenrun[1]);
 }

 META_COLLECTOR(int_loadavg_2)
 {
 	dst->value = fixed_loadavg(avenrun[2]);
 }

 /**************************************************************************
  * Device names & indices
  **************************************************************************/

 static inline int int_dev(struct net_device *dev, struct meta_obj *dst)
 {
 	if (unlikely(dev == NULL))
 		return -1;

 	dst->value = dev->ifindex;
 	return 0;
 }

 static inline int var_dev(struct net_device *dev, struct meta_obj *dst)
 {
 	if (unlikely(dev == NULL))
 		return -1;

 	dst->value = (unsigned long) dev->name;
 	dst->len = strlen(dev->name);
 	return 0;
 }

 META_COLLECTOR(int_dev)
 {
 	*err = int_dev(skb->dev, dst);
 }

 META_COLLECTOR(var_dev)
 {
 	*err = var_dev(skb->dev, dst);
 }

 /**************************************************************************
  * skb attributes
  **************************************************************************/

 META_COLLECTOR(int_priority)
 {
 	dst->value = skb->priority;
 }

 META_COLLECTOR(int_protocol)
 {
 	/* Let userspace take care of the byte ordering */
 	dst->value = skb->protocol;
 }

 META_COLLECTOR(int_pkttype)
 {
 	dst->value = skb->pkt_type;
 }

 META_COLLECTOR(int_pktlen)
 {
 	dst->value = skb->len;
 }

 META_COLLECTOR(int_datalen)
 {
 	dst->value = skb->data_len;
 }

 META_COLLECTOR(int_maclen)
 {
 	dst->value = skb->mac_len;
 }

 /**************************************************************************
  * Netfilter
  **************************************************************************/

 META_COLLECTOR(int_nfmark)
 {
 #ifdef CONFIG_NETFILTER
 	dst->value = skb->nfmark;
 #else
 	dst->value = 0;
 #endif
 }

 /**************************************************************************
  * Traffic Control
  **************************************************************************/

 META_COLLECTOR(int_tcindex)
 {
 	dst->value = skb->tc_index;
 }

 /**************************************************************************
  * Routing
  **************************************************************************/

 META_COLLECTOR(int_rtclassid)
 {
 	if (unlikely(skb->dst == NULL))
 		*err = -1;
 	else
 #ifdef CONFIG_NET_CLS_ROUTE
 		dst->value = skb->dst->tclassid;
 #else
 		dst->value = 0;
 #endif
 }

 META_COLLECTOR(int_rtiif)
 {
 	if (unlikely(skb->dst == NULL))
 		*err = -1;
 	else
 		dst->value = ((struct rtable*) skb->dst)->fl.iif;
 }

 /**************************************************************************
  * Socket Attributes
  **************************************************************************/

 #define SKIP_NONLOCAL(skb)			\
 	if (unlikely(skb->sk == NULL)) {	\
 		*err = -1;			\
 		return;				\
 	}

 META_COLLECTOR(int_sk_family)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_family;
 }

 META_COLLECTOR(int_sk_state)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_state;
 }

 META_COLLECTOR(int_sk_reuse)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_reuse;
 }

 META_COLLECTOR(int_sk_bound_if)
 {
 	SKIP_NONLOCAL(skb);
 	/* No error if bound_dev_if is 0, legal userspace check */
 	dst->value = skb->sk->sk_bound_dev_if;
 }

 META_COLLECTOR(var_sk_bound_if)
 {
 	SKIP_NONLOCAL(skb);

 	 if (skb->sk->sk_bound_dev_if == 0) {
 		dst->value = (unsigned long) "any";
 		dst->len = 3;
 	 } else  {
 		struct net_device *dev;

 		dev = dev_get_by_index(skb->sk->sk_bound_dev_if);
 		*err = var_dev(dev, dst);
 		if (dev)
 			dev_put(dev);
 	 }
 }

 META_COLLECTOR(int_sk_refcnt)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = atomic_read(&skb->sk->sk_refcnt);
 }

 META_COLLECTOR(int_sk_rcvbuf)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_rcvbuf;
 }

 META_COLLECTOR(int_sk_shutdown)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_shutdown;
 }

 META_COLLECTOR(int_sk_proto)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_protocol;
 }

 META_COLLECTOR(int_sk_type)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_type;
 }

 META_COLLECTOR(int_sk_rmem_alloc)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = atomic_read(&skb->sk->sk_rmem_alloc);
 }

 META_COLLECTOR(int_sk_wmem_alloc)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = atomic_read(&skb->sk->sk_wmem_alloc);
 }

 META_COLLECTOR(int_sk_omem_alloc)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = atomic_read(&skb->sk->sk_omem_alloc);
 }

 META_COLLECTOR(int_sk_rcv_qlen)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_receive_queue.qlen;
 }

 META_COLLECTOR(int_sk_snd_qlen)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_write_queue.qlen;
 }

 META_COLLECTOR(int_sk_wmem_queued)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_wmem_queued;
 }

 META_COLLECTOR(int_sk_fwd_alloc)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_forward_alloc;
 }

 META_COLLECTOR(int_sk_sndbuf)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_sndbuf;
 }

 META_COLLECTOR(int_sk_alloc)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_allocation;
 }

 META_COLLECTOR(int_sk_route_caps)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_route_caps;
 }

 META_COLLECTOR(int_sk_hash)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_hash;
 }

 META_COLLECTOR(int_sk_lingertime)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_lingertime / HZ;
 }

 META_COLLECTOR(int_sk_err_qlen)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_error_queue.qlen;
 }

 META_COLLECTOR(int_sk_ack_bl)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_ack_backlog;
 }

 META_COLLECTOR(int_sk_max_ack_bl)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_max_ack_backlog;
 }

 META_COLLECTOR(int_sk_prio)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_priority;
 }

 META_COLLECTOR(int_sk_rcvlowat)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_rcvlowat;
 }

 META_COLLECTOR(int_sk_rcvtimeo)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_rcvtimeo / HZ;
 }

 META_COLLECTOR(int_sk_sndtimeo)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_sndtimeo / HZ;
 }

 META_COLLECTOR(int_sk_sendmsg_off)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_sndmsg_off;
 }

 META_COLLECTOR(int_sk_write_pend)
 {
 	SKIP_NONLOCAL(skb);
 	dst->value = skb->sk->sk_write_pending;
 }

 /**************************************************************************
  * Meta value collectors assignment table
  **************************************************************************/

 struct meta_ops
 {
 	void		(*get)(struct sk_buff *, struct tcf_pkt_info *,
 			       struct meta_value *, struct meta_obj *, int *);
 };

 #define META_ID(name) TCF_META_ID_##name
 #define META_FUNC(name) { .get = meta_##name }

 /* Meta value operations table listing all meta value collectors and
  * assigns them to a type and meta id. */
 static struct meta_ops __meta_ops[TCF_META_TYPE_MAX+1][TCF_META_ID_MAX+1] = {
 	[TCF_META_TYPE_VAR] = {
 		[META_ID(DEV)]			= META_FUNC(var_dev),
 		[META_ID(SK_BOUND_IF)] 		= META_FUNC(var_sk_bound_if),
 	},
 	[TCF_META_TYPE_INT] = {
 		[META_ID(RANDOM)]		= META_FUNC(int_random),
 		[META_ID(LOADAVG_0)]		= META_FUNC(int_loadavg_0),
 		[META_ID(LOADAVG_1)]		= META_FUNC(int_loadavg_1),
 		[META_ID(LOADAVG_2)]		= META_FUNC(int_loadavg_2),
 		[META_ID(DEV)]			= META_FUNC(int_dev),
 		[META_ID(PRIORITY)]		= META_FUNC(int_priority),
 		[META_ID(PROTOCOL)]		= META_FUNC(int_protocol),
 		[META_ID(PKTTYPE)]		= META_FUNC(int_pkttype),
 		[META_ID(PKTLEN)]		= META_FUNC(int_pktlen),
 		[META_ID(DATALEN)]		= META_FUNC(int_datalen),
 		[META_ID(MACLEN)]		= META_FUNC(int_maclen),
 		[META_ID(NFMARK)]		= META_FUNC(int_nfmark),
 		[META_ID(TCINDEX)]		= META_FUNC(int_tcindex),
 		[META_ID(RTCLASSID)]		= META_FUNC(int_rtclassid),
 		[META_ID(RTIIF)]		= META_FUNC(int_rtiif),
 		[META_ID(SK_FAMILY)]		= META_FUNC(int_sk_family),
 		[META_ID(SK_STATE)]		= META_FUNC(int_sk_state),
 		[META_ID(SK_REUSE)]		= META_FUNC(int_sk_reuse),
 		[META_ID(SK_BOUND_IF)]		= META_FUNC(int_sk_bound_if),
 		[META_ID(SK_REFCNT)]		= META_FUNC(int_sk_refcnt),
 		[META_ID(SK_RCVBUF)]		= META_FUNC(int_sk_rcvbuf),
 		[META_ID(SK_SNDBUF)]		= META_FUNC(int_sk_sndbuf),
 		[META_ID(SK_SHUTDOWN)]		= META_FUNC(int_sk_shutdown),
 		[META_ID(SK_PROTO)]		= META_FUNC(int_sk_proto),
 		[META_ID(SK_TYPE)]		= META_FUNC(int_sk_type),
 		[META_ID(SK_RMEM_ALLOC)]	= META_FUNC(int_sk_rmem_alloc),
 		[META_ID(SK_WMEM_ALLOC)]	= META_FUNC(int_sk_wmem_alloc),
 		[META_ID(SK_OMEM_ALLOC)]	= META_FUNC(int_sk_omem_alloc),
 		[META_ID(SK_WMEM_QUEUED)]	= META_FUNC(int_sk_wmem_queued),
 		[META_ID(SK_RCV_QLEN)]		= META_FUNC(int_sk_rcv_qlen),
 		[META_ID(SK_SND_QLEN)]		= META_FUNC(int_sk_snd_qlen),
 		[META_ID(SK_ERR_QLEN)]		= META_FUNC(int_sk_err_qlen),
 		[META_ID(SK_FORWARD_ALLOCS)]	= META_FUNC(int_sk_fwd_alloc),
 		[META_ID(SK_ALLOCS)]		= META_FUNC(int_sk_alloc),
 		[META_ID(SK_ROUTE_CAPS)]	= META_FUNC(int_sk_route_caps),
 		[META_ID(SK_HASH)]		= META_FUNC(int_sk_hash),
 		[META_ID(SK_LINGERTIME)]	= META_FUNC(int_sk_lingertime),
 		[META_ID(SK_ACK_BACKLOG)]	= META_FUNC(int_sk_ack_bl),
 		[META_ID(SK_MAX_ACK_BACKLOG)]	= META_FUNC(int_sk_max_ack_bl),
 		[META_ID(SK_PRIO)]		= META_FUNC(int_sk_prio),
 		[META_ID(SK_RCVLOWAT)]		= META_FUNC(int_sk_rcvlowat),
 		[META_ID(SK_RCVTIMEO)]		= META_FUNC(int_sk_rcvtimeo),
 		[META_ID(SK_SNDTIMEO)]		= META_FUNC(int_sk_sndtimeo),
 		[META_ID(SK_SENDMSG_OFF)]	= META_FUNC(int_sk_sendmsg_off),
 		[META_ID(SK_WRITE_PENDING)]	= META_FUNC(int_sk_write_pend),
 	}
 };

 static inline struct meta_ops * meta_ops(struct meta_value *val)
 {
 	return &__meta_ops[meta_type(val)][meta_id(val)];
 }

 /**************************************************************************
  * Type specific operations for TCF_META_TYPE_VAR
  **************************************************************************/

 static int meta_var_compare(struct meta_obj *a, struct meta_obj *b)
 {
 	int r = a->len - b->len;

 	if (r == 0)
 		r = memcmp((void *) a->value, (void *) b->value, a->len);

 	return r;
 }

 static int meta_var_change(struct meta_value *dst, struct rtattr *rta)
 {
 	int len = RTA_PAYLOAD(rta);

 	dst->val = (unsigned long) kmalloc(len, GFP_KERNEL);
 	if (dst->val == 0UL)
 		return -ENOMEM;
 	memcpy((void *) dst->val, RTA_DATA(rta), len);
 	dst->len = len;
 	return 0;
 }

 static void meta_var_destroy(struct meta_value *v)
 {
 	kfree((void *) v->val);
 }

 static void meta_var_apply_extras(struct meta_value *v,
 				  struct meta_obj *dst)
 {
 	int shift = v->hdr.shift;

 	if (shift && shift < dst->len)
 		dst->len -= shift;
 }

 static int meta_var_dump(struct sk_buff *skb, struct meta_value *v, int tlv)
 {
 	if (v->val && v->len)
 		RTA_PUT(skb, tlv, v->len, (void *) v->val);
 	return 0;

 rtattr_failure:
 	return -1;
 }

 /**************************************************************************
  * Type specific operations for TCF_META_TYPE_INT
  **************************************************************************/

 static int meta_int_compare(struct meta_obj *a, struct meta_obj *b)
 {
 	/* Let gcc optimize it, the unlikely is not really based on
 	 * some numbers but jump free code for mismatches seems
 	 * more logical. */
 	if (unlikely(a->value == b->value))
 		return 0;
 	else if (a->value < b->value)
 		return -1;
 	else
 		return 1;
 }

 static int meta_int_change(struct meta_value *dst, struct rtattr *rta)
 {
 	if (RTA_PAYLOAD(rta) >= sizeof(unsigned long)) {
 		dst->val = *(unsigned long *) RTA_DATA(rta);
 		dst->len = sizeof(unsigned long);
 	} else if (RTA_PAYLOAD(rta) == sizeof(u32)) {
 		dst->val = *(u32 *) RTA_DATA(rta);
 		dst->len = sizeof(u32);
 	} else
 		return -EINVAL;

 	return 0;
 }

 static void meta_int_apply_extras(struct meta_value *v,
 				  struct meta_obj *dst)
 {
 	if (v->hdr.shift)
 		dst->value >>= v->hdr.shift;

 	if (v->val)
 		dst->value &= v->val;
 }

 static int meta_int_dump(struct sk_buff *skb, struct meta_value *v, int tlv)
 {
 	if (v->len == sizeof(unsigned long))
 		RTA_PUT(skb, tlv, sizeof(unsigned long), &v->val);
 	else if (v->len == sizeof(u32)) {
 		u32 d = v->val;
 		RTA_PUT(skb, tlv, sizeof(d), &d);
 	}

 	return 0;

 rtattr_failure:
 	return -1;
 }

 /**************************************************************************
  * Type specific operations table
  **************************************************************************/

 struct meta_type_ops
 {
 	void	(*destroy)(struct meta_value *);
 	int	(*compare)(struct meta_obj *, struct meta_obj *);
 	int	(*change)(struct meta_value *, struct rtattr *);
 	void	(*apply_extras)(struct meta_value *, struct meta_obj *);
 	int	(*dump)(struct sk_buff *, struct meta_value *, int);
 };

 static struct meta_type_ops __meta_type_ops[TCF_META_TYPE_MAX+1] = {
 	[TCF_META_TYPE_VAR] = {
 		.destroy = meta_var_destroy,
 		.compare = meta_var_compare,
 		.change = meta_var_change,
 		.apply_extras = meta_var_apply_extras,
 		.dump = meta_var_dump
 	},
 	[TCF_META_TYPE_INT] = {
 		.compare = meta_int_compare,
 		.change = meta_int_change,
 		.apply_extras = meta_int_apply_extras,
 		.dump = meta_int_dump
 	}
 };

 static inline struct meta_type_ops * meta_type_ops(struct meta_value *v)
 {
 	return &__meta_type_ops[meta_type(v)];
 }

 /**************************************************************************
  * Core
  **************************************************************************/

 static inline int meta_get(struct sk_buff *skb, struct tcf_pkt_info *info,
 			   struct meta_value *v, struct meta_obj *dst)
 {
 	int err = 0;

 	if (meta_id(v) == TCF_META_ID_VALUE) {
 		dst->value = v->val;
 		dst->len = v->len;
 		return 0;
 	}

 	meta_ops(v)->get(skb, info, v, dst, &err);
 	if (err < 0)
 		return err;

 	if (meta_type_ops(v)->apply_extras)
 	    meta_type_ops(v)->apply_extras(v, dst);

 	return 0;
 }

 static int em_meta_match(struct sk_buff *skb, struct tcf_ematch *m,
 			 struct tcf_pkt_info *info)
 {
 	int r;
 	struct meta_match *meta = (struct meta_match *) m->data;
 	struct meta_obj l_value, r_value;

 	if (meta_get(skb, info, &meta->lvalue, &l_value) < 0 ||
 	    meta_get(skb, info, &meta->rvalue, &r_value) < 0)
 		return 0;

 	r = meta_type_ops(&meta->lvalue)->compare(&l_value, &r_value);

 	switch (meta->lvalue.hdr.op) {
 		case TCF_EM_OPND_EQ:
 			return !r;
 		case TCF_EM_OPND_LT:
 			return r < 0;
 		case TCF_EM_OPND_GT:
 			return r > 0;
 	}

 	return 0;
 }

 static inline void meta_delete(struct meta_match *meta)
 {
 	struct meta_type_ops *ops = meta_type_ops(&meta->lvalue);

 	if (ops && ops->destroy) {
 		ops->destroy(&meta->lvalue);
 		ops->destroy(&meta->rvalue);
 	}

 	kfree(meta);
 }

 static inline int meta_change_data(struct meta_value *dst, struct rtattr *rta)
 {
 	if (rta) {
 		if (RTA_PAYLOAD(rta) == 0)
 			return -EINVAL;

 		return meta_type_ops(dst)->change(dst, rta);
 	}

 	return 0;
 }

 static inline int meta_is_supported(struct meta_value *val)
 {
 	return (!meta_id(val) || meta_ops(val)->get);
 }

 static int em_meta_change(struct tcf_proto *tp, void *data, int len,
 			  struct tcf_ematch *m)
 {
 	int err = -EINVAL;
 	struct rtattr *tb[TCA_EM_META_MAX];
 	struct tcf_meta_hdr *hdr;
 	struct meta_match *meta = NULL;

 	if (rtattr_parse(tb, TCA_EM_META_MAX, data, len) < 0)
 		goto errout;

 	if (tb[TCA_EM_META_HDR-1] == NULL ||
 	    RTA_PAYLOAD(tb[TCA_EM_META_HDR-1]) < sizeof(*hdr))
 		goto errout;
 	hdr = RTA_DATA(tb[TCA_EM_META_HDR-1]);

 	if (TCF_META_TYPE(hdr->left.kind) != TCF_META_TYPE(hdr->right.kind) ||
 	    TCF_META_TYPE(hdr->left.kind) > TCF_META_TYPE_MAX ||
 	    TCF_META_ID(hdr->left.kind) > TCF_META_ID_MAX ||
 	    TCF_META_ID(hdr->right.kind) > TCF_META_ID_MAX)
 		goto errout;

 	meta = kzalloc(sizeof(*meta), GFP_KERNEL);
 	if (meta == NULL)
 		goto errout;

 	memcpy(&meta->lvalue.hdr, &hdr->left, sizeof(hdr->left));
 	memcpy(&meta->rvalue.hdr, &hdr->right, sizeof(hdr->right));

 	if (!meta_is_supported(&meta->lvalue) ||
 	    !meta_is_supported(&meta->rvalue)) {
 		err = -EOPNOTSUPP;
 		goto errout;
 	}

 	if (meta_change_data(&meta->lvalue, tb[TCA_EM_META_LVALUE-1]) < 0 ||
 	    meta_change_data(&meta->rvalue, tb[TCA_EM_META_RVALUE-1]) < 0)
 		goto errout;

 	m->datalen = sizeof(*meta);
 	m->data = (unsigned long) meta;

 	err = 0;
 errout:
 	if (err && meta)
 		meta_delete(meta);
 	return err;
 }

 static void em_meta_destroy(struct tcf_proto *tp, struct tcf_ematch *m)
 {
 	if (m)
 		meta_delete((struct meta_match *) m->data);
 }

 static int em_meta_dump(struct sk_buff *skb, struct tcf_ematch *em)
 {
 	struct meta_match *meta = (struct meta_match *) em->data;
 	struct tcf_meta_hdr hdr;
 	struct meta_type_ops *ops;

 	memset(&hdr, 0, sizeof(hdr));
 	memcpy(&hdr.left, &meta->lvalue.hdr, sizeof(hdr.left));
 	memcpy(&hdr.right, &meta->rvalue.hdr, sizeof(hdr.right));

 	RTA_PUT(skb, TCA_EM_META_HDR, sizeof(hdr), &hdr);

 	ops = meta_type_ops(&meta->lvalue);
 	if (ops->dump(skb, &meta->lvalue, TCA_EM_META_LVALUE) < 0 ||
 	    ops->dump(skb, &meta->rvalue, TCA_EM_META_RVALUE) < 0)
 		goto rtattr_failure;

 	return 0;

 rtattr_failure:
 	return -1;
 }

 static struct tcf_ematch_ops em_meta_ops = {
 	.kind	  = TCF_EM_META,
 	.change	  = em_meta_change,
 	.match	  = em_meta_match,
 	.destroy  = em_meta_destroy,
 	.dump	  = em_meta_dump,
 	.owner	  = THIS_MODULE,
 	.link	  = LIST_HEAD_INIT(em_meta_ops.link)
 };

 static int __init init_em_meta(void)
 {
 	return tcf_em_register(&em_meta_ops);
 }

 static void __exit exit_em_meta(void)
 {
 	tcf_em_unregister(&em_meta_ops);
 }

 MODULE_LICENSE("GPL");

 module_init(init_em_meta);
 module_exit(exit_em_meta);
	/*
	* net/sched/em_meta.c Metadata ematch
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License
	* as published by the Free Software Foundation; either version
	* 2 of the License, or (at your option) any later version.
	*
	* Authors: Thomas Graf <tgraf@suug.ch>
	*
	* ==========================================================================
	*
	* The metadata ematch compares two meta objects where each object
	* represents either a meta value stored in the kernel or a static
	* value provided by userspace. The objects are not provided by
	* userspace itself but rather a definition providing the information
	* to build them. Every object is of a certain type which must be
	* equal to the object it is being compared to.
	*
	* The definition of a objects conists of the type (meta type), a
	* identifier (meta id) and additional type specific information.
	* The meta id is either TCF_META_TYPE_VALUE for values provided by
	* userspace or a index to the meta operations table consisting of
	* function pointers to type specific meta data collectors returning
	* the value of the requested meta value.
	*
	* lvalue rvalue
	* +-----------+ +-----------+
	* \| type: INT \| \| type: INT \|
	* def \| id: DEV \| \| id: VALUE \|
	* \| data: \| \| data: 3 \|
	* +-----------+ +-----------+
	* \| \|
	* ---> meta_ops[INT][DEV](...) \|
	* \| \|
	* ----------- \|
	* V V
	* +-----------+ +-----------+
	* \| type: INT \| \| type: INT \|
	* obj \| id: DEV \| \| id: VALUE \|
	* \| data: 2 \|<--data got filled out \| data: 3 \|
	* +-----------+ +-----------+
	* \| \|
	* --------------> 2 equals 3 <--------------
	*
	* This is a simplified schema, the complexity varies depending
	* on the meta type. Obviously, the length of the data must also
	* be provided for non-numeric types.
	*
	* Additionaly, type dependant modifiers such as shift operators
	* or mask may be applied to extend the functionaliy. As of now,
	* the variable length type supports shifting the byte string to
	* the right, eating up any number of octets and thus supporting
	* wildcard interface name comparisons such as "ppp%" matching
	* ppp0..9.
	*
	* NOTE: Certain meta values depend on other subsystems and are
	* only available if that subsytem is enabled in the kernel.
	*/

	#include <linux/module.h>
	#include <linux/types.h>
	#include <linux/kernel.h>
	#include <linux/sched.h>
	#include <linux/string.h>
	#include <linux/skbuff.h>
	#include <linux/random.h>
	#include <linux/tc_ematch/tc_em_meta.h>
	#include <net/dst.h>
	#include <net/route.h>
	#include <net/pkt_cls.h>
	#include <net/sock.h>

	struct meta_obj
	{
	unsigned long value;
	unsigned int len;
	};

	struct meta_value
	{
	struct tcf_meta_val hdr;
	unsigned long val;
	unsigned int len;
	};

	struct meta_match
	{
	struct meta_value lvalue;
	struct meta_value rvalue;
	};

	static inline int meta_id(struct meta_value *v)
	{
	return TCF_META_ID(v->hdr.kind);
	}

	static inline int meta_type(struct meta_value *v)
	{
	return TCF_META_TYPE(v->hdr.kind);
	}

	#define META_COLLECTOR(FUNC) static void meta_##FUNC(struct sk_buff *skb, \
	struct tcf_pkt_info info, struct meta_value v, \
	struct meta_obj dst, int err)

	/**************************************************************************
	* System status & misc
	**************************************************************************/

	META_COLLECTOR(int_random)
	{
	get_random_bytes(&dst->value, sizeof(dst->value));
	}

	static inline unsigned long fixed_loadavg(int load)
	{
	int rnd_load = load + (FIXED_1/200);
	int rnd_frac = ((rnd_load & (FIXED_1-1)) * 100) >> FSHIFT;

	return ((rnd_load >> FSHIFT) * 100) + rnd_frac;
	}

	META_COLLECTOR(int_loadavg_0)
	{
	dst->value = fixed_loadavg(avenrun[0]);
	}

	META_COLLECTOR(int_loadavg_1)
	{
	dst->value = fixed_loadavg(avenrun[1]);
	}

	META_COLLECTOR(int_loadavg_2)
	{
	dst->value = fixed_loadavg(avenrun[2]);
	}

	/**************************************************************************
	* Device names & indices
	**************************************************************************/

	static inline int int_dev(struct net_device dev, struct meta_obj dst)
	{
	if (unlikely(dev == NULL))
	return -1;

	dst->value = dev->ifindex;
	return 0;
	}

	static inline int var_dev(struct net_device dev, struct meta_obj dst)
	{
	if (unlikely(dev == NULL))
	return -1;

	dst->value = (unsigned long) dev->name;
	dst->len = strlen(dev->name);
	return 0;
	}

	META_COLLECTOR(int_dev)
	{
	*err = int_dev(skb->dev, dst);
	}

	META_COLLECTOR(var_dev)
	{
	*err = var_dev(skb->dev, dst);
	}

	/**************************************************************************
	* skb attributes
	**************************************************************************/

	META_COLLECTOR(int_priority)
	{
	dst->value = skb->priority;
	}

	META_COLLECTOR(int_protocol)
	{
	/* Let userspace take care of the byte ordering */
	dst->value = skb->protocol;
	}

	META_COLLECTOR(int_pkttype)
	{
	dst->value = skb->pkt_type;
	}

	META_COLLECTOR(int_pktlen)
	{
	dst->value = skb->len;
	}

	META_COLLECTOR(int_datalen)
	{
	dst->value = skb->data_len;
	}

	META_COLLECTOR(int_maclen)
	{
	dst->value = skb->mac_len;
	}

	/**************************************************************************
	* Netfilter
	**************************************************************************/

	META_COLLECTOR(int_nfmark)
	{
	#ifdef CONFIG_NETFILTER
	dst->value = skb->nfmark;
	#else
	dst->value = 0;
	#endif
	}

	/**************************************************************************
	* Traffic Control
	**************************************************************************/

	META_COLLECTOR(int_tcindex)
	{
	dst->value = skb->tc_index;
	}

	/**************************************************************************
	* Routing
	**************************************************************************/

	META_COLLECTOR(int_rtclassid)
	{
	if (unlikely(skb->dst == NULL))
	*err = -1;
	else
	#ifdef CONFIG_NET_CLS_ROUTE
	dst->value = skb->dst->tclassid;
	#else
	dst->value = 0;
	#endif
	}

	META_COLLECTOR(int_rtiif)
	{
	if (unlikely(skb->dst == NULL))
	*err = -1;
	else
	dst->value = ((struct rtable*) skb->dst)->fl.iif;
	}

	/**************************************************************************
	* Socket Attributes
	**************************************************************************/

	#define SKIP_NONLOCAL(skb) \
	if (unlikely(skb->sk == NULL)) { \
	*err = -1; \
	return; \
	}

	META_COLLECTOR(int_sk_family)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_family;
	}

	META_COLLECTOR(int_sk_state)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_state;
	}

	META_COLLECTOR(int_sk_reuse)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_reuse;
	}

	META_COLLECTOR(int_sk_bound_if)
	{
	SKIP_NONLOCAL(skb);
	/* No error if bound_dev_if is 0, legal userspace check */
	dst->value = skb->sk->sk_bound_dev_if;
	}

	META_COLLECTOR(var_sk_bound_if)
	{
	SKIP_NONLOCAL(skb);

	if (skb->sk->sk_bound_dev_if == 0) {
	dst->value = (unsigned long) "any";
	dst->len = 3;
	} else {
	struct net_device *dev;

	dev = dev_get_by_index(skb->sk->sk_bound_dev_if);
	*err = var_dev(dev, dst);
	if (dev)
	dev_put(dev);
	}
	}

	META_COLLECTOR(int_sk_refcnt)
	{
	SKIP_NONLOCAL(skb);
	dst->value = atomic_read(&skb->sk->sk_refcnt);
	}

	META_COLLECTOR(int_sk_rcvbuf)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_rcvbuf;
	}

	META_COLLECTOR(int_sk_shutdown)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_shutdown;
	}

	META_COLLECTOR(int_sk_proto)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_protocol;
	}

	META_COLLECTOR(int_sk_type)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_type;
	}

	META_COLLECTOR(int_sk_rmem_alloc)
	{
	SKIP_NONLOCAL(skb);
	dst->value = atomic_read(&skb->sk->sk_rmem_alloc);
	}

	META_COLLECTOR(int_sk_wmem_alloc)
	{
	SKIP_NONLOCAL(skb);
	dst->value = atomic_read(&skb->sk->sk_wmem_alloc);
	}

	META_COLLECTOR(int_sk_omem_alloc)
	{
	SKIP_NONLOCAL(skb);
	dst->value = atomic_read(&skb->sk->sk_omem_alloc);
	}

	META_COLLECTOR(int_sk_rcv_qlen)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_receive_queue.qlen;
	}

	META_COLLECTOR(int_sk_snd_qlen)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_write_queue.qlen;
	}

	META_COLLECTOR(int_sk_wmem_queued)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_wmem_queued;
	}

	META_COLLECTOR(int_sk_fwd_alloc)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_forward_alloc;
	}

	META_COLLECTOR(int_sk_sndbuf)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_sndbuf;
	}

	META_COLLECTOR(int_sk_alloc)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_allocation;
	}

	META_COLLECTOR(int_sk_route_caps)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_route_caps;
	}

	META_COLLECTOR(int_sk_hash)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_hash;
	}

	META_COLLECTOR(int_sk_lingertime)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_lingertime / HZ;
	}

	META_COLLECTOR(int_sk_err_qlen)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_error_queue.qlen;
	}

	META_COLLECTOR(int_sk_ack_bl)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_ack_backlog;
	}

	META_COLLECTOR(int_sk_max_ack_bl)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_max_ack_backlog;
	}

	META_COLLECTOR(int_sk_prio)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_priority;
	}

	META_COLLECTOR(int_sk_rcvlowat)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_rcvlowat;
	}

	META_COLLECTOR(int_sk_rcvtimeo)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_rcvtimeo / HZ;
	}

	META_COLLECTOR(int_sk_sndtimeo)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_sndtimeo / HZ;
	}

	META_COLLECTOR(int_sk_sendmsg_off)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_sndmsg_off;
	}

	META_COLLECTOR(int_sk_write_pend)
	{
	SKIP_NONLOCAL(skb);
	dst->value = skb->sk->sk_write_pending;
	}

	/**************************************************************************
	* Meta value collectors assignment table
	**************************************************************************/

	struct meta_ops
	{
	void (get)(struct sk_buff , struct tcf_pkt_info *,
	struct meta_value , struct meta_obj , int *);
	};

	#define META_ID(name) TCF_META_ID_##name
	#define META_FUNC(name) { .get = meta_##name }

	/* Meta value operations table listing all meta value collectors and
	* assigns them to a type and meta id. */
	static struct meta_ops __meta_ops[TCF_META_TYPE_MAX+1][TCF_META_ID_MAX+1] = {
	[TCF_META_TYPE_VAR] = {
	[META_ID(DEV)] = META_FUNC(var_dev),
	[META_ID(SK_BOUND_IF)] = META_FUNC(var_sk_bound_if),
	},
	[TCF_META_TYPE_INT] = {
	[META_ID(RANDOM)] = META_FUNC(int_random),
	[META_ID(LOADAVG_0)] = META_FUNC(int_loadavg_0),
	[META_ID(LOADAVG_1)] = META_FUNC(int_loadavg_1),
	[META_ID(LOADAVG_2)] = META_FUNC(int_loadavg_2),
	[META_ID(DEV)] = META_FUNC(int_dev),
	[META_ID(PRIORITY)] = META_FUNC(int_priority),
	[META_ID(PROTOCOL)] = META_FUNC(int_protocol),
	[META_ID(PKTTYPE)] = META_FUNC(int_pkttype),
	[META_ID(PKTLEN)] = META_FUNC(int_pktlen),
	[META_ID(DATALEN)] = META_FUNC(int_datalen),
	[META_ID(MACLEN)] = META_FUNC(int_maclen),
	[META_ID(NFMARK)] = META_FUNC(int_nfmark),
	[META_ID(TCINDEX)] = META_FUNC(int_tcindex),
	[META_ID(RTCLASSID)] = META_FUNC(int_rtclassid),
	[META_ID(RTIIF)] = META_FUNC(int_rtiif),
	[META_ID(SK_FAMILY)] = META_FUNC(int_sk_family),
	[META_ID(SK_STATE)] = META_FUNC(int_sk_state),
	[META_ID(SK_REUSE)] = META_FUNC(int_sk_reuse),
	[META_ID(SK_BOUND_IF)] = META_FUNC(int_sk_bound_if),
	[META_ID(SK_REFCNT)] = META_FUNC(int_sk_refcnt),
	[META_ID(SK_RCVBUF)] = META_FUNC(int_sk_rcvbuf),
	[META_ID(SK_SNDBUF)] = META_FUNC(int_sk_sndbuf),
	[META_ID(SK_SHUTDOWN)] = META_FUNC(int_sk_shutdown),
	[META_ID(SK_PROTO)] = META_FUNC(int_sk_proto),
	[META_ID(SK_TYPE)] = META_FUNC(int_sk_type),
	[META_ID(SK_RMEM_ALLOC)] = META_FUNC(int_sk_rmem_alloc),
	[META_ID(SK_WMEM_ALLOC)] = META_FUNC(int_sk_wmem_alloc),
	[META_ID(SK_OMEM_ALLOC)] = META_FUNC(int_sk_omem_alloc),
	[META_ID(SK_WMEM_QUEUED)] = META_FUNC(int_sk_wmem_queued),
	[META_ID(SK_RCV_QLEN)] = META_FUNC(int_sk_rcv_qlen),
	[META_ID(SK_SND_QLEN)] = META_FUNC(int_sk_snd_qlen),
	[META_ID(SK_ERR_QLEN)] = META_FUNC(int_sk_err_qlen),
	[META_ID(SK_FORWARD_ALLOCS)] = META_FUNC(int_sk_fwd_alloc),
	[META_ID(SK_ALLOCS)] = META_FUNC(int_sk_alloc),
	[META_ID(SK_ROUTE_CAPS)] = META_FUNC(int_sk_route_caps),
	[META_ID(SK_HASH)] = META_FUNC(int_sk_hash),
	[META_ID(SK_LINGERTIME)] = META_FUNC(int_sk_lingertime),
	[META_ID(SK_ACK_BACKLOG)] = META_FUNC(int_sk_ack_bl),
	[META_ID(SK_MAX_ACK_BACKLOG)] = META_FUNC(int_sk_max_ack_bl),
	[META_ID(SK_PRIO)] = META_FUNC(int_sk_prio),
	[META_ID(SK_RCVLOWAT)] = META_FUNC(int_sk_rcvlowat),
	[META_ID(SK_RCVTIMEO)] = META_FUNC(int_sk_rcvtimeo),
	[META_ID(SK_SNDTIMEO)] = META_FUNC(int_sk_sndtimeo),
	[META_ID(SK_SENDMSG_OFF)] = META_FUNC(int_sk_sendmsg_off),
	[META_ID(SK_WRITE_PENDING)] = META_FUNC(int_sk_write_pend),
	}
	};

	static inline struct meta_ops * meta_ops(struct meta_value *val)
	{
	return &__meta_ops[meta_type(val)][meta_id(val)];
	}

	/**************************************************************************
	* Type specific operations for TCF_META_TYPE_VAR
	**************************************************************************/

	static int meta_var_compare(struct meta_obj a, struct meta_obj b)
	{
	int r = a->len - b->len;

	if (r == 0)
	r = memcmp((void ) a->value, (void ) b->value, a->len);

	return r;
	}

	static int meta_var_change(struct meta_value dst, struct rtattr rta)
	{
	int len = RTA_PAYLOAD(rta);

	dst->val = (unsigned long) kmalloc(len, GFP_KERNEL);
	if (dst->val == 0UL)
	return -ENOMEM;
	memcpy((void *) dst->val, RTA_DATA(rta), len);
	dst->len = len;
	return 0;
	}

	static void meta_var_destroy(struct meta_value *v)
	{
	kfree((void *) v->val);
	}

	static void meta_var_apply_extras(struct meta_value *v,
	struct meta_obj *dst)
	{
	int shift = v->hdr.shift;

	if (shift && shift < dst->len)
	dst->len -= shift;
	}

	static int meta_var_dump(struct sk_buff skb, struct meta_value v, int tlv)
	{
	if (v->val && v->len)
	RTA_PUT(skb, tlv, v->len, (void *) v->val);
	return 0;

	rtattr_failure:
	return -1;
	}

	/**************************************************************************
	* Type specific operations for TCF_META_TYPE_INT
	**************************************************************************/

	static int meta_int_compare(struct meta_obj a, struct meta_obj b)
	{
	/* Let gcc optimize it, the unlikely is not really based on
	* some numbers but jump free code for mismatches seems
	* more logical. */
	if (unlikely(a->value == b->value))
	return 0;
	else if (a->value < b->value)
	return -1;
	else
	return 1;
	}

	static int meta_int_change(struct meta_value dst, struct rtattr rta)
	{
	if (RTA_PAYLOAD(rta) >= sizeof(unsigned long)) {
	dst->val = (unsigned long ) RTA_DATA(rta);
	dst->len = sizeof(unsigned long);
	} else if (RTA_PAYLOAD(rta) == sizeof(u32)) {
	dst->val = (u32 ) RTA_DATA(rta);
	dst->len = sizeof(u32);
	} else
	return -EINVAL;

	return 0;
	}

	static void meta_int_apply_extras(struct meta_value *v,
	struct meta_obj *dst)
	{
	if (v->hdr.shift)
	dst->value >>= v->hdr.shift;

	if (v->val)
	dst->value &= v->val;
	}

	static int meta_int_dump(struct sk_buff skb, struct meta_value v, int tlv)
	{
	if (v->len == sizeof(unsigned long))
	RTA_PUT(skb, tlv, sizeof(unsigned long), &v->val);
	else if (v->len == sizeof(u32)) {
	u32 d = v->val;
	RTA_PUT(skb, tlv, sizeof(d), &d);
	}

	return 0;

	rtattr_failure:
	return -1;
	}

	/**************************************************************************
	* Type specific operations table
	**************************************************************************/

	struct meta_type_ops
	{
	void (destroy)(struct meta_value );
	int (compare)(struct meta_obj , struct meta_obj *);
	int (change)(struct meta_value , struct rtattr *);
	void (apply_extras)(struct meta_value , struct meta_obj *);
	int (dump)(struct sk_buff , struct meta_value *, int);
	};

	static struct meta_type_ops __meta_type_ops[TCF_META_TYPE_MAX+1] = {
	[TCF_META_TYPE_VAR] = {
	.destroy = meta_var_destroy,
	.compare = meta_var_compare,
	.change = meta_var_change,
	.apply_extras = meta_var_apply_extras,
	.dump = meta_var_dump
	},
	[TCF_META_TYPE_INT] = {
	.compare = meta_int_compare,
	.change = meta_int_change,
	.apply_extras = meta_int_apply_extras,
	.dump = meta_int_dump
	}
	};

	static inline struct meta_type_ops * meta_type_ops(struct meta_value *v)
	{
	return &__meta_type_ops[meta_type(v)];
	}

	/**************************************************************************
	* Core
	**************************************************************************/

	static inline int meta_get(struct sk_buff skb, struct tcf_pkt_info info,
	struct meta_value v, struct meta_obj dst)
	{
	int err = 0;

	if (meta_id(v) == TCF_META_ID_VALUE) {
	dst->value = v->val;
	dst->len = v->len;
	return 0;
	}

	meta_ops(v)->get(skb, info, v, dst, &err);
	if (err < 0)
	return err;

	if (meta_type_ops(v)->apply_extras)
	meta_type_ops(v)->apply_extras(v, dst);

	return 0;
	}

	static int em_meta_match(struct sk_buff skb, struct tcf_ematch m,
	struct tcf_pkt_info *info)
	{
	int r;
	struct meta_match meta = (struct meta_match ) m->data;
	struct meta_obj l_value, r_value;

	if (meta_get(skb, info, &meta->lvalue, &l_value) < 0 \|\|
	meta_get(skb, info, &meta->rvalue, &r_value) < 0)
	return 0;

	r = meta_type_ops(&meta->lvalue)->compare(&l_value, &r_value);

	switch (meta->lvalue.hdr.op) {
	case TCF_EM_OPND_EQ:
	return !r;
	case TCF_EM_OPND_LT:
	return r < 0;
	case TCF_EM_OPND_GT:
	return r > 0;
	}

	return 0;
	}

	static inline void meta_delete(struct meta_match *meta)
	{
	struct meta_type_ops *ops = meta_type_ops(&meta->lvalue);

	if (ops && ops->destroy) {
	ops->destroy(&meta->lvalue);
	ops->destroy(&meta->rvalue);
	}

	kfree(meta);
	}

	static inline int meta_change_data(struct meta_value dst, struct rtattr rta)
	{
	if (rta) {
	if (RTA_PAYLOAD(rta) == 0)
	return -EINVAL;

	return meta_type_ops(dst)->change(dst, rta);
	}

	return 0;
	}

	static inline int meta_is_supported(struct meta_value *val)
	{
	return (!meta_id(val) \|\| meta_ops(val)->get);
	}

	static int em_meta_change(struct tcf_proto tp, void data, int len,
	struct tcf_ematch *m)
	{
	int err = -EINVAL;
	struct rtattr *tb[TCA_EM_META_MAX];
	struct tcf_meta_hdr *hdr;
	struct meta_match *meta = NULL;

	if (rtattr_parse(tb, TCA_EM_META_MAX, data, len) < 0)
	goto errout;

	if (tb[TCA_EM_META_HDR-1] == NULL \|\|
	RTA_PAYLOAD(tb[TCA_EM_META_HDR-1]) < sizeof(*hdr))
	goto errout;
	hdr = RTA_DATA(tb[TCA_EM_META_HDR-1]);

	if (TCF_META_TYPE(hdr->left.kind) != TCF_META_TYPE(hdr->right.kind) \|\|
	TCF_META_TYPE(hdr->left.kind) > TCF_META_TYPE_MAX \|\|
	TCF_META_ID(hdr->left.kind) > TCF_META_ID_MAX \|\|
	TCF_META_ID(hdr->right.kind) > TCF_META_ID_MAX)
	goto errout;

	meta = kzalloc(sizeof(*meta), GFP_KERNEL);
	if (meta == NULL)
	goto errout;

	memcpy(&meta->lvalue.hdr, &hdr->left, sizeof(hdr->left));
	memcpy(&meta->rvalue.hdr, &hdr->right, sizeof(hdr->right));

	if (!meta_is_supported(&meta->lvalue) \|\|
	!meta_is_supported(&meta->rvalue)) {
	err = -EOPNOTSUPP;
	goto errout;
	}

	if (meta_change_data(&meta->lvalue, tb[TCA_EM_META_LVALUE-1]) < 0 \|\|
	meta_change_data(&meta->rvalue, tb[TCA_EM_META_RVALUE-1]) < 0)
	goto errout;

	m->datalen = sizeof(*meta);
	m->data = (unsigned long) meta;

	err = 0;
	errout:
	if (err && meta)
	meta_delete(meta);
	return err;
	}

	static void em_meta_destroy(struct tcf_proto tp, struct tcf_ematch m)
	{
	if (m)
	meta_delete((struct meta_match *) m->data);
	}

	static int em_meta_dump(struct sk_buff skb, struct tcf_ematch em)
	{
	struct meta_match meta = (struct meta_match ) em->data;
	struct tcf_meta_hdr hdr;
	struct meta_type_ops *ops;

	memset(&hdr, 0, sizeof(hdr));
	memcpy(&hdr.left, &meta->lvalue.hdr, sizeof(hdr.left));
	memcpy(&hdr.right, &meta->rvalue.hdr, sizeof(hdr.right));

	RTA_PUT(skb, TCA_EM_META_HDR, sizeof(hdr), &hdr);

	ops = meta_type_ops(&meta->lvalue);
	if (ops->dump(skb, &meta->lvalue, TCA_EM_META_LVALUE) < 0 \|\|
	ops->dump(skb, &meta->rvalue, TCA_EM_META_RVALUE) < 0)
	goto rtattr_failure;

	return 0;

	rtattr_failure:
	return -1;
	}

	static struct tcf_ematch_ops em_meta_ops = {
	.kind = TCF_EM_META,
	.change = em_meta_change,
	.match = em_meta_match,
	.destroy = em_meta_destroy,
	.dump = em_meta_dump,
	.owner = THIS_MODULE,
	.link = LIST_HEAD_INIT(em_meta_ops.link)
	};

	static int __init init_em_meta(void)
	{
	return tcf_em_register(&em_meta_ops);
	}

	static void __exit exit_em_meta(void)
	{
	tcf_em_unregister(&em_meta_ops);
	}

	MODULE_LICENSE("GPL");

	module_init(init_em_meta);
	module_exit(exit_em_meta);