net/netfilter/xt_limit.c - linux - Git at Google

 /* (C) 1999 Jérôme de Vivie <devivie@info.enserb.u-bordeaux.fr>
  * (C) 1999 Hervé Eychenne <eychenne@info.enserb.u-bordeaux.fr>
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 as
  * published by the Free Software Foundation.
  */

 #include <linux/module.h>
 #include <linux/skbuff.h>
 #include <linux/spinlock.h>
 #include <linux/interrupt.h>

 #include <linux/netfilter/x_tables.h>
 #include <linux/netfilter/xt_limit.h>

 MODULE_LICENSE("GPL");
 MODULE_AUTHOR("Herve Eychenne <rv@wallfire.org>");
 MODULE_DESCRIPTION("Xtables: rate-limit match");
 MODULE_ALIAS("ipt_limit");
 MODULE_ALIAS("ip6t_limit");

 /* The algorithm used is the Simple Token Bucket Filter (TBF)
  * see net/sched/sch_tbf.c in the linux source tree
  */

 static DEFINE_SPINLOCK(limit_lock);

 /* Rusty: This is my (non-mathematically-inclined) understanding of
    this algorithm.  The `average rate' in jiffies becomes your initial
    amount of credit `credit' and the most credit you can ever have
    `credit_cap'.  The `peak rate' becomes the cost of passing the
    test, `cost'.

    `prev' tracks the last packet hit: you gain one credit per jiffy.
    If you get credit balance more than this, the extra credit is
    discarded.  Every time the match passes, you lose `cost' credits;
    if you don't have that many, the test fails.

    See Alexey's formal explanation in net/sched/sch_tbf.c.

    To get the maxmum range, we multiply by this factor (ie. you get N
    credits per jiffy).  We want to allow a rate as low as 1 per day
    (slowest userspace tool allows), which means
    CREDITS_PER_JIFFY*HZ*60*60*24 < 2^32. ie. */
 #define MAX_CPJ (0xFFFFFFFF / (HZ*60*60*24))

 /* Repeated shift and or gives us all 1s, final shift and add 1 gives
  * us the power of 2 below the theoretical max, so GCC simply does a
  * shift. */
 #define _POW2_BELOW2(x) ((x)|((x)>>1))
 #define _POW2_BELOW4(x) (_POW2_BELOW2(x)|_POW2_BELOW2((x)>>2))
 #define _POW2_BELOW8(x) (_POW2_BELOW4(x)|_POW2_BELOW4((x)>>4))
 #define _POW2_BELOW16(x) (_POW2_BELOW8(x)|_POW2_BELOW8((x)>>8))
 #define _POW2_BELOW32(x) (_POW2_BELOW16(x)|_POW2_BELOW16((x)>>16))
 #define POW2_BELOW32(x) ((_POW2_BELOW32(x)>>1) + 1)

 #define CREDITS_PER_JIFFY POW2_BELOW32(MAX_CPJ)

 static bool
 limit_mt(const struct sk_buff *skb, const struct net_device *in,
          const struct net_device *out, const struct xt_match *match,
          const void *matchinfo, int offset, unsigned int protoff,
          bool *hotdrop)
 {
 	struct xt_rateinfo *r =
 		((const struct xt_rateinfo *)matchinfo)->master;
 	unsigned long now = jiffies;

 	spin_lock_bh(&limit_lock);
 	r->credit += (now - xchg(&r->prev, now)) * CREDITS_PER_JIFFY;
 	if (r->credit > r->credit_cap)
 		r->credit = r->credit_cap;

 	if (r->credit >= r->cost) {
 		/* We're not limited. */
 		r->credit -= r->cost;
 		spin_unlock_bh(&limit_lock);
 		return true;
 	}

 	spin_unlock_bh(&limit_lock);
 	return false;
 }

 /* Precision saver. */
 static u_int32_t
 user2credits(u_int32_t user)
 {
 	/* If multiplying would overflow... */
 	if (user > 0xFFFFFFFF / (HZ*CREDITS_PER_JIFFY))
 		/* Divide first. */
 		return (user / XT_LIMIT_SCALE) * HZ * CREDITS_PER_JIFFY;

 	return (user * HZ * CREDITS_PER_JIFFY) / XT_LIMIT_SCALE;
 }

 static bool
 limit_mt_check(const char *tablename, const void *inf,
                const struct xt_match *match, void *matchinfo,
                unsigned int hook_mask)
 {
 	struct xt_rateinfo *r = matchinfo;

 	/* Check for overflow. */
 	if (r->burst == 0
 	    || user2credits(r->avg * r->burst) < user2credits(r->avg)) {
 		printk("Overflow in xt_limit, try lower: %u/%u\n",
 		       r->avg, r->burst);
 		return false;
 	}

 	/* For SMP, we only want to use one set of counters. */
 	r->master = r;
 	if (r->cost == 0) {
 		/* User avg in seconds * XT_LIMIT_SCALE: convert to jiffies *
 		   128. */
 		r->prev = jiffies;
 		r->credit = user2credits(r->avg * r->burst);	 /* Credits full. */
 		r->credit_cap = user2credits(r->avg * r->burst); /* Credits full. */
 		r->cost = user2credits(r->avg);
 	}
 	return true;
 }

 #ifdef CONFIG_COMPAT
 struct compat_xt_rateinfo {
 	u_int32_t avg;
 	u_int32_t burst;

 	compat_ulong_t prev;
 	u_int32_t credit;
 	u_int32_t credit_cap, cost;

 	u_int32_t master;
 };

 /* To keep the full "prev" timestamp, the upper 32 bits are stored in the
  * master pointer, which does not need to be preserved. */
 static void limit_mt_compat_from_user(void *dst, void *src)
 {
 	const struct compat_xt_rateinfo *cm = src;
 	struct xt_rateinfo m = {
 		.avg		= cm->avg,
 		.burst		= cm->burst,
 		.prev		= cm->prev | (unsigned long)cm->master << 32,
 		.credit		= cm->credit,
 		.credit_cap	= cm->credit_cap,
 		.cost		= cm->cost,
 	};
 	memcpy(dst, &m, sizeof(m));
 }

 static int limit_mt_compat_to_user(void __user *dst, void *src)
 {
 	const struct xt_rateinfo *m = src;
 	struct compat_xt_rateinfo cm = {
 		.avg		= m->avg,
 		.burst		= m->burst,
 		.prev		= m->prev,
 		.credit		= m->credit,
 		.credit_cap	= m->credit_cap,
 		.cost		= m->cost,
 		.master		= m->prev >> 32,
 	};
 	return copy_to_user(dst, &cm, sizeof(cm)) ? -EFAULT : 0;
 }
 #endif /* CONFIG_COMPAT */

 static struct xt_match limit_mt_reg[] __read_mostly = {
 	{
 		.name		= "limit",
 		.family		= AF_INET,
 		.checkentry	= limit_mt_check,
 		.match		= limit_mt,
 		.matchsize	= sizeof(struct xt_rateinfo),
 #ifdef CONFIG_COMPAT
 		.compatsize	= sizeof(struct compat_xt_rateinfo),
 		.compat_from_user = limit_mt_compat_from_user,
 		.compat_to_user	= limit_mt_compat_to_user,
 #endif
 		.me		= THIS_MODULE,
 	},
 	{
 		.name		= "limit",
 		.family		= AF_INET6,
 		.checkentry	= limit_mt_check,
 		.match		= limit_mt,
 		.matchsize	= sizeof(struct xt_rateinfo),
 #ifdef CONFIG_COMPAT
 		.compatsize	= sizeof(struct compat_xt_rateinfo),
 		.compat_from_user = limit_mt_compat_from_user,
 		.compat_to_user	= limit_mt_compat_to_user,
 #endif
 		.me		= THIS_MODULE,
 	},
 };

 static int __init limit_mt_init(void)
 {
 	return xt_register_matches(limit_mt_reg, ARRAY_SIZE(limit_mt_reg));
 }

 static void __exit limit_mt_exit(void)
 {
 	xt_unregister_matches(limit_mt_reg, ARRAY_SIZE(limit_mt_reg));
 }

 module_init(limit_mt_init);
 module_exit(limit_mt_exit);
	/* (C) 1999 Jérôme de Vivie <devivie@info.enserb.u-bordeaux.fr>
	* (C) 1999 Hervé Eychenne <eychenne@info.enserb.u-bordeaux.fr>
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 as
	* published by the Free Software Foundation.
	*/

	#include <linux/module.h>
	#include <linux/skbuff.h>
	#include <linux/spinlock.h>
	#include <linux/interrupt.h>

	#include <linux/netfilter/x_tables.h>
	#include <linux/netfilter/xt_limit.h>

	MODULE_LICENSE("GPL");
	MODULE_AUTHOR("Herve Eychenne <rv@wallfire.org>");
	MODULE_DESCRIPTION("Xtables: rate-limit match");
	MODULE_ALIAS("ipt_limit");
	MODULE_ALIAS("ip6t_limit");

	/* The algorithm used is the Simple Token Bucket Filter (TBF)
	* see net/sched/sch_tbf.c in the linux source tree
	*/

	static DEFINE_SPINLOCK(limit_lock);

	/* Rusty: This is my (non-mathematically-inclined) understanding of
	this algorithm. The `average rate' in jiffies becomes your initial
	amount of credit `credit' and the most credit you can ever have
	`credit_cap'. The `peak rate' becomes the cost of passing the
	test, `cost'.

	`prev' tracks the last packet hit: you gain one credit per jiffy.
	If you get credit balance more than this, the extra credit is
	discarded. Every time the match passes, you lose `cost' credits;
	if you don't have that many, the test fails.

	See Alexey's formal explanation in net/sched/sch_tbf.c.

	To get the maxmum range, we multiply by this factor (ie. you get N
	credits per jiffy). We want to allow a rate as low as 1 per day
	(slowest userspace tool allows), which means
	CREDITS_PER_JIFFYHZ606024 < 2^32. ie. */
	#define MAX_CPJ (0xFFFFFFFF / (HZ6060*24))

	/* Repeated shift and or gives us all 1s, final shift and add 1 gives
	* us the power of 2 below the theoretical max, so GCC simply does a
	* shift. */
	#define _POW2_BELOW2(x) ((x)\|((x)>>1))
	#define _POW2_BELOW4(x) (_POW2_BELOW2(x)\|_POW2_BELOW2((x)>>2))
	#define _POW2_BELOW8(x) (_POW2_BELOW4(x)\|_POW2_BELOW4((x)>>4))
	#define _POW2_BELOW16(x) (_POW2_BELOW8(x)\|_POW2_BELOW8((x)>>8))
	#define _POW2_BELOW32(x) (_POW2_BELOW16(x)\|_POW2_BELOW16((x)>>16))
	#define POW2_BELOW32(x) ((_POW2_BELOW32(x)>>1) + 1)

	#define CREDITS_PER_JIFFY POW2_BELOW32(MAX_CPJ)

	static bool
	limit_mt(const struct sk_buff skb, const struct net_device in,
	const struct net_device out, const struct xt_match match,
	const void *matchinfo, int offset, unsigned int protoff,
	bool *hotdrop)
	{
	struct xt_rateinfo *r =
	((const struct xt_rateinfo *)matchinfo)->master;
	unsigned long now = jiffies;

	spin_lock_bh(&limit_lock);
	r->credit += (now - xchg(&r->prev, now)) * CREDITS_PER_JIFFY;
	if (r->credit > r->credit_cap)
	r->credit = r->credit_cap;

	if (r->credit >= r->cost) {
	/* We're not limited. */
	r->credit -= r->cost;
	spin_unlock_bh(&limit_lock);
	return true;
	}

	spin_unlock_bh(&limit_lock);
	return false;
	}

	/* Precision saver. */
	static u_int32_t
	user2credits(u_int32_t user)
	{
	/* If multiplying would overflow... */
	if (user > 0xFFFFFFFF / (HZ*CREDITS_PER_JIFFY))
	/* Divide first. */
	return (user / XT_LIMIT_SCALE) * HZ * CREDITS_PER_JIFFY;

	return (user * HZ * CREDITS_PER_JIFFY) / XT_LIMIT_SCALE;
	}

	static bool
	limit_mt_check(const char tablename, const void inf,
	const struct xt_match match, void matchinfo,
	unsigned int hook_mask)
	{
	struct xt_rateinfo *r = matchinfo;

	/* Check for overflow. */
	if (r->burst == 0
	\|\| user2credits(r->avg * r->burst) < user2credits(r->avg)) {
	printk("Overflow in xt_limit, try lower: %u/%u\n",
	r->avg, r->burst);
	return false;
	}

	/* For SMP, we only want to use one set of counters. */
	r->master = r;
	if (r->cost == 0) {
	/* User avg in seconds * XT_LIMIT_SCALE: convert to jiffies *
	128. */
	r->prev = jiffies;
	r->credit = user2credits(r->avg * r->burst); /* Credits full. */
	r->credit_cap = user2credits(r->avg * r->burst); /* Credits full. */
	r->cost = user2credits(r->avg);
	}
	return true;
	}

	#ifdef CONFIG_COMPAT
	struct compat_xt_rateinfo {
	u_int32_t avg;
	u_int32_t burst;

	compat_ulong_t prev;
	u_int32_t credit;
	u_int32_t credit_cap, cost;

	u_int32_t master;
	};

	/* To keep the full "prev" timestamp, the upper 32 bits are stored in the
	* master pointer, which does not need to be preserved. */
	static void limit_mt_compat_from_user(void dst, void src)
	{
	const struct compat_xt_rateinfo *cm = src;
	struct xt_rateinfo m = {
	.avg = cm->avg,
	.burst = cm->burst,
	.prev = cm->prev \| (unsigned long)cm->master << 32,
	.credit = cm->credit,
	.credit_cap = cm->credit_cap,
	.cost = cm->cost,
	};
	memcpy(dst, &m, sizeof(m));
	}

	static int limit_mt_compat_to_user(void __user dst, void src)
	{
	const struct xt_rateinfo *m = src;
	struct compat_xt_rateinfo cm = {
	.avg = m->avg,
	.burst = m->burst,
	.prev = m->prev,
	.credit = m->credit,
	.credit_cap = m->credit_cap,
	.cost = m->cost,
	.master = m->prev >> 32,
	};
	return copy_to_user(dst, &cm, sizeof(cm)) ? -EFAULT : 0;
	}
	#endif /* CONFIG_COMPAT */

	static struct xt_match limit_mt_reg[] __read_mostly = {
	{
	.name = "limit",
	.family = AF_INET,
	.checkentry = limit_mt_check,
	.match = limit_mt,
	.matchsize = sizeof(struct xt_rateinfo),
	#ifdef CONFIG_COMPAT
	.compatsize = sizeof(struct compat_xt_rateinfo),
	.compat_from_user = limit_mt_compat_from_user,
	.compat_to_user = limit_mt_compat_to_user,
	#endif
	.me = THIS_MODULE,
	},
	{
	.name = "limit",
	.family = AF_INET6,
	.checkentry = limit_mt_check,
	.match = limit_mt,
	.matchsize = sizeof(struct xt_rateinfo),
	#ifdef CONFIG_COMPAT
	.compatsize = sizeof(struct compat_xt_rateinfo),
	.compat_from_user = limit_mt_compat_from_user,
	.compat_to_user = limit_mt_compat_to_user,
	#endif
	.me = THIS_MODULE,
	},
	};

	static int __init limit_mt_init(void)
	{
	return xt_register_matches(limit_mt_reg, ARRAY_SIZE(limit_mt_reg));
	}

	static void __exit limit_mt_exit(void)
	{
	xt_unregister_matches(limit_mt_reg, ARRAY_SIZE(limit_mt_reg));
	}

	module_init(limit_mt_init);
	module_exit(limit_mt_exit);