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freebsd-dev/sys/netpfil/ipfw/ip_fw_table_algo.c
Andrey V. Elsukov 20efcfc602 Switch RIB and RADIX_NODE_HEAD lock from rwlock(9) to rmlock(9). 
Using of rwlock with multiqueue NICs for IP forwarding on high pps
produces high lock contention and inefficient. Rmlock fits better for
such workloads.

Reviewed by:	melifaro, olivier
Obtained from:	Yandex LLC
Sponsored by:	Yandex LLC
Differential Revision:	https://reviews.freebsd.org/D15789
2018-06-16 08:26:23 +00:00

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/*-
* Copyright (c) 2014 Yandex LLC
* Copyright (c) 2014 Alexander V. Chernikov
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* Lookup table algorithms.
*
*/
#include "opt_ipfw.h"
#include "opt_inet.h"
#ifndef INET
#error IPFIREWALL requires INET.
#endif /* INET */
#include "opt_inet6.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/malloc.h>
#include <sys/kernel.h>
#include <sys/lock.h>
#include <sys/rwlock.h>
#include <sys/rmlock.h>
#include <sys/socket.h>
#include <sys/queue.h>
#include <net/if.h> /* ip_fw.h requires IFNAMSIZ */
#include <net/radix.h>
#include <net/route.h>
#include <net/route_var.h>
#include <netinet/in.h>
#include <netinet/in_fib.h>
#include <netinet/ip_var.h> /* struct ipfw_rule_ref */
#include <netinet/ip_fw.h>
#include <netinet6/in6_fib.h>
#include <netpfil/ipfw/ip_fw_private.h>
#include <netpfil/ipfw/ip_fw_table.h>
/*
* IPFW table lookup algorithms.
*
* What is needed to add another table algo?
*
* Algo init:
* * struct table_algo has to be filled with:
* name: "type:algoname" format, e.g. "addr:radix". Currently
* there are the following types: "addr", "iface", "number" and "flow".
* type: one of IPFW_TABLE_* types
* flags: one or more TA_FLAGS_*
* ta_buf_size: size of structure used to store add/del item state.
* Needs to be less than TA_BUF_SZ.
* callbacks: see below for description.
* * ipfw_add_table_algo / ipfw_del_table_algo has to be called
*
* Callbacks description:
*
* -init: request to initialize new table instance.
* typedef int (ta_init)(struct ip_fw_chain *ch, void **ta_state,
* struct table_info *ti, char *data, uint8_t tflags);
* MANDATORY, unlocked. (M_WAITOK). Returns 0 on success.
*
* Allocate all structures needed for normal operations.
* * Caller may want to parse @data for some algo-specific
* options provided by userland.
* * Caller may want to save configuration state pointer to @ta_state
* * Caller needs to save desired runtime structure pointer(s)
* inside @ti fields. Note that it is not correct to save
* @ti pointer at this moment. Use -change_ti hook for that.
* * Caller has to fill in ti->lookup to appropriate function
* pointer.
*
*
*
* -destroy: request to destroy table instance.
* typedef void (ta_destroy)(void *ta_state, struct table_info *ti);
* MANDATORY, unlocked. (M_WAITOK).
*
* Frees all table entries and all tables structures allocated by -init.
*
*
*
* -prepare_add: request to allocate state for adding new entry.
* typedef int (ta_prepare_add)(struct ip_fw_chain *ch, struct tentry_info *tei,
* void *ta_buf);
* MANDATORY, unlocked. (M_WAITOK). Returns 0 on success.
*
* Allocates state and fills it in with all necessary data (EXCEPT value)
* from @tei to minimize operations needed to be done under WLOCK.
* "value" field has to be copied to new entry in @add callback.
* Buffer ta_buf of size ta->ta_buf_sz may be used to store
* allocated state.
*
*
*
* -prepare_del: request to set state for deleting existing entry.
* typedef int (ta_prepare_del)(struct ip_fw_chain *ch, struct tentry_info *tei,
* void *ta_buf);
* MANDATORY, locked, UH. (M_NOWAIT). Returns 0 on success.
*
* Buffer ta_buf of size ta->ta_buf_sz may be used to store
* allocated state. Caller should use on-stack ta_buf allocation
* instead of doing malloc().
*
*
*
* -add: request to insert new entry into runtime/config structures.
* typedef int (ta_add)(void *ta_state, struct table_info *ti,
* struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
* MANDATORY, UH+WLOCK. (M_NOWAIT). Returns 0 on success.
*
* Insert new entry using previously-allocated state in @ta_buf.
* * @tei may have the following flags:
* TEI_FLAGS_UPDATE: request to add or update entry.
* TEI_FLAGS_DONTADD: request to update (but not add) entry.
* * Caller is required to do the following:
* copy real entry value from @tei
* entry added: return 0, set 1 to @pnum
* entry updated: return 0, store 0 to @pnum, store old value in @tei,
* add TEI_FLAGS_UPDATED flag to @tei.
* entry exists: return EEXIST
* entry not found: return ENOENT
* other error: return non-zero error code.
*
*
*
* -del: request to delete existing entry from runtime/config structures.
* typedef int (ta_del)(void *ta_state, struct table_info *ti,
* struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
* MANDATORY, UH+WLOCK. (M_NOWAIT). Returns 0 on success.
*
* Delete entry using previously set up in @ta_buf.
* * Caller is required to do the following:
* entry deleted: return 0, set 1 to @pnum, store old value in @tei.
* entry not found: return ENOENT
* other error: return non-zero error code.
*
*
*
* -flush_entry: flush entry state created by -prepare_add / -del / others
* typedef void (ta_flush_entry)(struct ip_fw_chain *ch,
* struct tentry_info *tei, void *ta_buf);
* MANDATORY, may be locked. (M_NOWAIT).
*
* Delete state allocated by:
* -prepare_add (-add returned EEXIST|UPDATED)
* -prepare_del (if any)
* -del
* * Caller is required to handle empty @ta_buf correctly.
*
*
* -find_tentry: finds entry specified by key @tei
* typedef int ta_find_tentry(void *ta_state, struct table_info *ti,
* ipfw_obj_tentry *tent);
* OPTIONAL, locked (UH). (M_NOWAIT). Returns 0 on success.
*
* Finds entry specified by given key.
* * Caller is required to do the following:
* entry found: returns 0, export entry to @tent
* entry not found: returns ENOENT
*
*
* -need_modify: checks if @ti has enough space to hold another @count items.
* typedef int (ta_need_modify)(void *ta_state, struct table_info *ti,
* uint32_t count, uint64_t *pflags);
* OPTIONAL, locked (UH). (M_NOWAIT). Returns 0 if has.
*
* Checks if given table has enough space to add @count items without
* resize. Caller may use @pflags to store desired modification data.
*
*
*
* -prepare_mod: allocate structures for table modification.
* typedef int (ta_prepare_mod)(void *ta_buf, uint64_t *pflags);
* OPTIONAL(need_modify), unlocked. (M_WAITOK). Returns 0 on success.
*
* Allocate all needed state for table modification. Caller
* should use `struct mod_item` to store new state in @ta_buf.
* Up to TA_BUF_SZ (128 bytes) can be stored in @ta_buf.
*
*
*
* -fill_mod: copy some data to new state/
* typedef int (ta_fill_mod)(void *ta_state, struct table_info *ti,
* void *ta_buf, uint64_t *pflags);
* OPTIONAL(need_modify), locked (UH). (M_NOWAIT). Returns 0 on success.
*
* Copy as much data as we can to minimize changes under WLOCK.
* For example, array can be merged inside this callback.
*
*
*
* -modify: perform final modification.
* typedef void (ta_modify)(void *ta_state, struct table_info *ti,
* void *ta_buf, uint64_t pflags);
* OPTIONAL(need_modify), locked (UH+WLOCK). (M_NOWAIT).
*
* Performs all changes necessary to switch to new structures.
* * Caller should save old pointers to @ta_buf storage.
*
*
*
* -flush_mod: flush table modification state.
* typedef void (ta_flush_mod)(void *ta_buf);
* OPTIONAL(need_modify), unlocked. (M_WAITOK).
*
* Performs flush for the following:
* - prepare_mod (modification was not necessary)
* - modify (for the old state)
*
*
*
* -change_gi: monitor table info pointer changes
* typedef void (ta_change_ti)(void *ta_state, struct table_info *ti);
* OPTIONAL, locked (UH). (M_NOWAIT).
*
* Called on @ti pointer changed. Called immediately after -init
* to set initial state.
*
*
*
* -foreach: calls @f for each table entry
* typedef void ta_foreach(void *ta_state, struct table_info *ti,
* ta_foreach_f *f, void *arg);
* MANDATORY, locked(UH). (M_NOWAIT).
*
* Runs callback with specified argument for each table entry,
* Typically used for dumping table entries.
*
*
*
* -dump_tentry: dump table entry in current @tentry format.
* typedef int ta_dump_tentry(void *ta_state, struct table_info *ti, void *e,
* ipfw_obj_tentry *tent);
* MANDATORY, locked(UH). (M_NOWAIT). Returns 0 on success.
*
* Dumps entry @e to @tent.
*
*
* -print_config: prints custom algorithm options into buffer.
* typedef void (ta_print_config)(void *ta_state, struct table_info *ti,
* char *buf, size_t bufsize);
* OPTIONAL. locked(UH). (M_NOWAIT).
*
* Prints custom algorithm options in the format suitable to pass
* back to -init callback.
*
*
*
* -dump_tinfo: dumps algo-specific info.
* typedef void ta_dump_tinfo(void *ta_state, struct table_info *ti,
* ipfw_ta_tinfo *tinfo);
* OPTIONAL. locked(UH). (M_NOWAIT).
*
* Dumps options like items size/hash size, etc.
*/
MALLOC_DEFINE(M_IPFW_TBL, "ipfw_tbl", "IpFw tables");
/*
* Utility structures/functions common to more than one algo
*/
struct mod_item {
void *main_ptr;
size_t size;
void *main_ptr6;
size_t size6;
};
static int badd(const void *key, void *item, void *base, size_t nmemb,
size_t size, int (*compar) (const void *, const void *));
static int bdel(const void *key, void *base, size_t nmemb, size_t size,
int (*compar) (const void *, const void *));
/*
* ADDR implementation using radix
*
*/
/*
* The radix code expects addr and mask to be array of bytes,
* with the first byte being the length of the array. rn_inithead
* is called with the offset in bits of the lookup key within the
* array. If we use a sockaddr_in as the underlying type,
* sin_len is conveniently located at offset 0, sin_addr is at
* offset 4 and normally aligned.
* But for portability, let's avoid assumption and make the code explicit
*/
#define KEY_LEN(v) *((uint8_t *)&(v))
/*
* Do not require radix to compare more than actual IPv4/IPv6 address
*/
#define KEY_LEN_INET (offsetof(struct sockaddr_in, sin_addr) + sizeof(in_addr_t))
#define KEY_LEN_INET6 (offsetof(struct sa_in6, sin6_addr) + sizeof(struct in6_addr))
#define OFF_LEN_INET (8 * offsetof(struct sockaddr_in, sin_addr))
#define OFF_LEN_INET6 (8 * offsetof(struct sa_in6, sin6_addr))
struct radix_addr_entry {
struct radix_node rn[2];
struct sockaddr_in addr;
uint32_t value;
uint8_t masklen;
};
struct sa_in6 {
uint8_t sin6_len;
uint8_t sin6_family;
uint8_t pad[2];
struct in6_addr sin6_addr;
};
struct radix_addr_xentry {
struct radix_node rn[2];
struct sa_in6 addr6;
uint32_t value;
uint8_t masklen;
};
struct radix_cfg {
struct radix_node_head *head4;
struct radix_node_head *head6;
size_t count4;
size_t count6;
};
struct ta_buf_radix
{
void *ent_ptr;
struct sockaddr *addr_ptr;
struct sockaddr *mask_ptr;
union {
struct {
struct sockaddr_in sa;
struct sockaddr_in ma;
} a4;
struct {
struct sa_in6 sa;
struct sa_in6 ma;
} a6;
} addr;
};
static int ta_lookup_radix(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val);
static int ta_init_radix(struct ip_fw_chain *ch, void **ta_state,
struct table_info *ti, char *data, uint8_t tflags);
static int flush_radix_entry(struct radix_node *rn, void *arg);
static void ta_destroy_radix(void *ta_state, struct table_info *ti);
static void ta_dump_radix_tinfo(void *ta_state, struct table_info *ti,
ipfw_ta_tinfo *tinfo);
static int ta_dump_radix_tentry(void *ta_state, struct table_info *ti,
void *e, ipfw_obj_tentry *tent);
static int ta_find_radix_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent);
static void ta_foreach_radix(void *ta_state, struct table_info *ti,
ta_foreach_f *f, void *arg);
static void tei_to_sockaddr_ent(struct tentry_info *tei, struct sockaddr *sa,
struct sockaddr *ma, int *set_mask);
static int ta_prepare_add_radix(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_add_radix(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static int ta_prepare_del_radix(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_del_radix(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static void ta_flush_radix_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_need_modify_radix(void *ta_state, struct table_info *ti,
uint32_t count, uint64_t *pflags);
static int
ta_lookup_radix(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct radix_node_head *rnh;
if (keylen == sizeof(in_addr_t)) {
struct radix_addr_entry *ent;
struct sockaddr_in sa;
KEY_LEN(sa) = KEY_LEN_INET;
sa.sin_addr.s_addr = *((in_addr_t *)key);
rnh = (struct radix_node_head *)ti->state;
ent = (struct radix_addr_entry *)(rnh->rnh_matchaddr(&sa, &rnh->rh));
if (ent != NULL) {
*val = ent->value;
return (1);
}
} else {
struct radix_addr_xentry *xent;
struct sa_in6 sa6;
KEY_LEN(sa6) = KEY_LEN_INET6;
memcpy(&sa6.sin6_addr, key, sizeof(struct in6_addr));
rnh = (struct radix_node_head *)ti->xstate;
xent = (struct radix_addr_xentry *)(rnh->rnh_matchaddr(&sa6, &rnh->rh));
if (xent != NULL) {
*val = xent->value;
return (1);
}
}
return (0);
}
/*
* New table
*/
static int
ta_init_radix(struct ip_fw_chain *ch, void **ta_state, struct table_info *ti,
char *data, uint8_t tflags)
{
struct radix_cfg *cfg;
if (!rn_inithead(&ti->state, OFF_LEN_INET))
return (ENOMEM);
if (!rn_inithead(&ti->xstate, OFF_LEN_INET6)) {
rn_detachhead(&ti->state);
return (ENOMEM);
}
cfg = malloc(sizeof(struct radix_cfg), M_IPFW, M_WAITOK | M_ZERO);
*ta_state = cfg;
ti->lookup = ta_lookup_radix;
return (0);
}
static int
flush_radix_entry(struct radix_node *rn, void *arg)
{
struct radix_node_head * const rnh = arg;
struct radix_addr_entry *ent;
ent = (struct radix_addr_entry *)
rnh->rnh_deladdr(rn->rn_key, rn->rn_mask, &rnh->rh);
if (ent != NULL)
free(ent, M_IPFW_TBL);
return (0);
}
static void
ta_destroy_radix(void *ta_state, struct table_info *ti)
{
struct radix_cfg *cfg;
struct radix_node_head *rnh;
cfg = (struct radix_cfg *)ta_state;
rnh = (struct radix_node_head *)(ti->state);
rnh->rnh_walktree(&rnh->rh, flush_radix_entry, rnh);
rn_detachhead(&ti->state);
rnh = (struct radix_node_head *)(ti->xstate);
rnh->rnh_walktree(&rnh->rh, flush_radix_entry, rnh);
rn_detachhead(&ti->xstate);
free(cfg, M_IPFW);
}
/*
* Provide algo-specific table info
*/
static void
ta_dump_radix_tinfo(void *ta_state, struct table_info *ti, ipfw_ta_tinfo *tinfo)
{
struct radix_cfg *cfg;
cfg = (struct radix_cfg *)ta_state;
tinfo->flags = IPFW_TATFLAGS_AFDATA | IPFW_TATFLAGS_AFITEM;
tinfo->taclass4 = IPFW_TACLASS_RADIX;
tinfo->count4 = cfg->count4;
tinfo->itemsize4 = sizeof(struct radix_addr_entry);
tinfo->taclass6 = IPFW_TACLASS_RADIX;
tinfo->count6 = cfg->count6;
tinfo->itemsize6 = sizeof(struct radix_addr_xentry);
}
static int
ta_dump_radix_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent)
{
struct radix_addr_entry *n;
#ifdef INET6
struct radix_addr_xentry *xn;
#endif
n = (struct radix_addr_entry *)e;
/* Guess IPv4/IPv6 radix by sockaddr family */
if (n->addr.sin_family == AF_INET) {
tent->k.addr.s_addr = n->addr.sin_addr.s_addr;
tent->masklen = n->masklen;
tent->subtype = AF_INET;
tent->v.kidx = n->value;
#ifdef INET6
} else {
xn = (struct radix_addr_xentry *)e;
memcpy(&tent->k.addr6, &xn->addr6.sin6_addr,
sizeof(struct in6_addr));
tent->masklen = xn->masklen;
tent->subtype = AF_INET6;
tent->v.kidx = xn->value;
#endif
}
return (0);
}
static int
ta_find_radix_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent)
{
struct radix_node_head *rnh;
void *e;
e = NULL;
if (tent->subtype == AF_INET) {
struct sockaddr_in sa;
KEY_LEN(sa) = KEY_LEN_INET;
sa.sin_addr.s_addr = tent->k.addr.s_addr;
rnh = (struct radix_node_head *)ti->state;
e = rnh->rnh_matchaddr(&sa, &rnh->rh);
} else {
struct sa_in6 sa6;
KEY_LEN(sa6) = KEY_LEN_INET6;
memcpy(&sa6.sin6_addr, &tent->k.addr6, sizeof(struct in6_addr));
rnh = (struct radix_node_head *)ti->xstate;
e = rnh->rnh_matchaddr(&sa6, &rnh->rh);
}
if (e != NULL) {
ta_dump_radix_tentry(ta_state, ti, e, tent);
return (0);
}
return (ENOENT);
}
static void
ta_foreach_radix(void *ta_state, struct table_info *ti, ta_foreach_f *f,
void *arg)
{
struct radix_node_head *rnh;
rnh = (struct radix_node_head *)(ti->state);
rnh->rnh_walktree(&rnh->rh, (walktree_f_t *)f, arg);
rnh = (struct radix_node_head *)(ti->xstate);
rnh->rnh_walktree(&rnh->rh, (walktree_f_t *)f, arg);
}
#ifdef INET6
static inline void ipv6_writemask(struct in6_addr *addr6, uint8_t mask);
static inline void
ipv6_writemask(struct in6_addr *addr6, uint8_t mask)
{
uint32_t *cp;
for (cp = (uint32_t *)addr6; mask >= 32; mask -= 32)
*cp++ = 0xFFFFFFFF;
if (mask > 0)
*cp = htonl(mask ? ~((1 << (32 - mask)) - 1) : 0);
}
#endif
static void
tei_to_sockaddr_ent(struct tentry_info *tei, struct sockaddr *sa,
struct sockaddr *ma, int *set_mask)
{
int mlen;
#ifdef INET
struct sockaddr_in *addr, *mask;
#endif
#ifdef INET6
struct sa_in6 *addr6, *mask6;
#endif
in_addr_t a4;
mlen = tei->masklen;
if (tei->subtype == AF_INET) {
#ifdef INET
addr = (struct sockaddr_in *)sa;
mask = (struct sockaddr_in *)ma;
/* Set 'total' structure length */
KEY_LEN(*addr) = KEY_LEN_INET;
KEY_LEN(*mask) = KEY_LEN_INET;
addr->sin_family = AF_INET;
mask->sin_addr.s_addr =
htonl(mlen ? ~((1 << (32 - mlen)) - 1) : 0);
a4 = *((in_addr_t *)tei->paddr);
addr->sin_addr.s_addr = a4 & mask->sin_addr.s_addr;
if (mlen != 32)
*set_mask = 1;
else
*set_mask = 0;
#endif
#ifdef INET6
} else if (tei->subtype == AF_INET6) {
/* IPv6 case */
addr6 = (struct sa_in6 *)sa;
mask6 = (struct sa_in6 *)ma;
/* Set 'total' structure length */
KEY_LEN(*addr6) = KEY_LEN_INET6;
KEY_LEN(*mask6) = KEY_LEN_INET6;
addr6->sin6_family = AF_INET6;
ipv6_writemask(&mask6->sin6_addr, mlen);
memcpy(&addr6->sin6_addr, tei->paddr, sizeof(struct in6_addr));
APPLY_MASK(&addr6->sin6_addr, &mask6->sin6_addr);
if (mlen != 128)
*set_mask = 1;
else
*set_mask = 0;
#endif
}
}
static int
ta_prepare_add_radix(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_radix *tb;
struct radix_addr_entry *ent;
#ifdef INET6
struct radix_addr_xentry *xent;
#endif
struct sockaddr *addr, *mask;
int mlen, set_mask;
tb = (struct ta_buf_radix *)ta_buf;
mlen = tei->masklen;
set_mask = 0;
if (tei->subtype == AF_INET) {
#ifdef INET
if (mlen > 32)
return (EINVAL);
ent = malloc(sizeof(*ent), M_IPFW_TBL, M_WAITOK | M_ZERO);
ent->masklen = mlen;
addr = (struct sockaddr *)&ent->addr;
mask = (struct sockaddr *)&tb->addr.a4.ma;
tb->ent_ptr = ent;
#endif
#ifdef INET6
} else if (tei->subtype == AF_INET6) {
/* IPv6 case */
if (mlen > 128)
return (EINVAL);
xent = malloc(sizeof(*xent), M_IPFW_TBL, M_WAITOK | M_ZERO);
xent->masklen = mlen;
addr = (struct sockaddr *)&xent->addr6;
mask = (struct sockaddr *)&tb->addr.a6.ma;
tb->ent_ptr = xent;
#endif
} else {
/* Unknown CIDR type */
return (EINVAL);
}
tei_to_sockaddr_ent(tei, addr, mask, &set_mask);
/* Set pointers */
tb->addr_ptr = addr;
if (set_mask != 0)
tb->mask_ptr = mask;
return (0);
}
static int
ta_add_radix(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct radix_cfg *cfg;
struct radix_node_head *rnh;
struct radix_node *rn;
struct ta_buf_radix *tb;
uint32_t *old_value, value;
cfg = (struct radix_cfg *)ta_state;
tb = (struct ta_buf_radix *)ta_buf;
/* Save current entry value from @tei */
if (tei->subtype == AF_INET) {
rnh = ti->state;
((struct radix_addr_entry *)tb->ent_ptr)->value = tei->value;
} else {
rnh = ti->xstate;
((struct radix_addr_xentry *)tb->ent_ptr)->value = tei->value;
}
/* Search for an entry first */
rn = rnh->rnh_lookup(tb->addr_ptr, tb->mask_ptr, &rnh->rh);
if (rn != NULL) {
if ((tei->flags & TEI_FLAGS_UPDATE) == 0)
return (EEXIST);
/* Record already exists. Update value if we're asked to */
if (tei->subtype == AF_INET)
old_value = &((struct radix_addr_entry *)rn)->value;
else
old_value = &((struct radix_addr_xentry *)rn)->value;
value = *old_value;
*old_value = tei->value;
tei->value = value;
/* Indicate that update has happened instead of addition */
tei->flags |= TEI_FLAGS_UPDATED;
*pnum = 0;
return (0);
}
if ((tei->flags & TEI_FLAGS_DONTADD) != 0)
return (EFBIG);
rn = rnh->rnh_addaddr(tb->addr_ptr, tb->mask_ptr, &rnh->rh,tb->ent_ptr);
if (rn == NULL) {
/* Unknown error */
return (EINVAL);
}
if (tei->subtype == AF_INET)
cfg->count4++;
else
cfg->count6++;
tb->ent_ptr = NULL;
*pnum = 1;
return (0);
}
static int
ta_prepare_del_radix(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_radix *tb;
struct sockaddr *addr, *mask;
int mlen, set_mask;
tb = (struct ta_buf_radix *)ta_buf;
mlen = tei->masklen;
set_mask = 0;
if (tei->subtype == AF_INET) {
if (mlen > 32)
return (EINVAL);
addr = (struct sockaddr *)&tb->addr.a4.sa;
mask = (struct sockaddr *)&tb->addr.a4.ma;
#ifdef INET6
} else if (tei->subtype == AF_INET6) {
if (mlen > 128)
return (EINVAL);
addr = (struct sockaddr *)&tb->addr.a6.sa;
mask = (struct sockaddr *)&tb->addr.a6.ma;
#endif
} else
return (EINVAL);
tei_to_sockaddr_ent(tei, addr, mask, &set_mask);
tb->addr_ptr = addr;
if (set_mask != 0)
tb->mask_ptr = mask;
return (0);
}
static int
ta_del_radix(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct radix_cfg *cfg;
struct radix_node_head *rnh;
struct radix_node *rn;
struct ta_buf_radix *tb;
cfg = (struct radix_cfg *)ta_state;
tb = (struct ta_buf_radix *)ta_buf;
if (tei->subtype == AF_INET)
rnh = ti->state;
else
rnh = ti->xstate;
rn = rnh->rnh_deladdr(tb->addr_ptr, tb->mask_ptr, &rnh->rh);
if (rn == NULL)
return (ENOENT);
/* Save entry value to @tei */
if (tei->subtype == AF_INET)
tei->value = ((struct radix_addr_entry *)rn)->value;
else
tei->value = ((struct radix_addr_xentry *)rn)->value;
tb->ent_ptr = rn;
if (tei->subtype == AF_INET)
cfg->count4--;
else
cfg->count6--;
*pnum = 1;
return (0);
}
static void
ta_flush_radix_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_radix *tb;
tb = (struct ta_buf_radix *)ta_buf;
if (tb->ent_ptr != NULL)
free(tb->ent_ptr, M_IPFW_TBL);
}
static int
ta_need_modify_radix(void *ta_state, struct table_info *ti, uint32_t count,
uint64_t *pflags)
{
/*
* radix does not require additional memory allocations
* other than nodes itself. Adding new masks to the tree do
* but we don't have any API to call (and we don't known which
* sizes do we need).
*/
return (0);
}
struct table_algo addr_radix = {
.name = "addr:radix",
.type = IPFW_TABLE_ADDR,
.flags = TA_FLAG_DEFAULT,
.ta_buf_size = sizeof(struct ta_buf_radix),
.init = ta_init_radix,
.destroy = ta_destroy_radix,
.prepare_add = ta_prepare_add_radix,
.prepare_del = ta_prepare_del_radix,
.add = ta_add_radix,
.del = ta_del_radix,
.flush_entry = ta_flush_radix_entry,
.foreach = ta_foreach_radix,
.dump_tentry = ta_dump_radix_tentry,
.find_tentry = ta_find_radix_tentry,
.dump_tinfo = ta_dump_radix_tinfo,
.need_modify = ta_need_modify_radix,
};
/*
* addr:hash cmds
*
*
* ti->data:
* [inv.mask4][inv.mask6][log2hsize4][log2hsize6]
* [ 8][ 8[ 8][ 8]
*
* inv.mask4: 32 - mask
* inv.mask6:
* 1) _slow lookup: mask
* 2) _aligned: (128 - mask) / 8
* 3) _64: 8
*
*
* pflags:
* [v4=1/v6=0][hsize]
* [ 32][ 32]
*/
struct chashentry;
SLIST_HEAD(chashbhead, chashentry);
struct chash_cfg {
struct chashbhead *head4;
struct chashbhead *head6;
size_t size4;
size_t size6;
size_t items4;
size_t items6;
uint8_t mask4;
uint8_t mask6;
};
struct chashentry {
SLIST_ENTRY(chashentry) next;
uint32_t value;
uint32_t type;
union {
uint32_t a4; /* Host format */
struct in6_addr a6; /* Network format */
} a;
};
struct ta_buf_chash
{
void *ent_ptr;
struct chashentry ent;
};
#ifdef INET
static __inline uint32_t hash_ip(uint32_t addr, int hsize);
#endif
#ifdef INET6
static __inline uint32_t hash_ip6(struct in6_addr *addr6, int hsize);
static __inline uint16_t hash_ip64(struct in6_addr *addr6, int hsize);
static __inline uint32_t hash_ip6_slow(struct in6_addr *addr6, void *key,
int mask, int hsize);
static __inline uint32_t hash_ip6_al(struct in6_addr *addr6, void *key, int mask,
int hsize);
#endif
static int ta_lookup_chash_slow(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val);
static int ta_lookup_chash_aligned(struct table_info *ti, void *key,
uint32_t keylen, uint32_t *val);
static int ta_lookup_chash_64(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val);
static int chash_parse_opts(struct chash_cfg *cfg, char *data);
static void ta_print_chash_config(void *ta_state, struct table_info *ti,
char *buf, size_t bufsize);
static int ta_log2(uint32_t v);
static int ta_init_chash(struct ip_fw_chain *ch, void **ta_state,
struct table_info *ti, char *data, uint8_t tflags);
static void ta_destroy_chash(void *ta_state, struct table_info *ti);
static void ta_dump_chash_tinfo(void *ta_state, struct table_info *ti,
ipfw_ta_tinfo *tinfo);
static int ta_dump_chash_tentry(void *ta_state, struct table_info *ti,
void *e, ipfw_obj_tentry *tent);
static uint32_t hash_ent(struct chashentry *ent, int af, int mlen,
uint32_t size);
static int tei_to_chash_ent(struct tentry_info *tei, struct chashentry *ent);
static int ta_find_chash_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent);
static void ta_foreach_chash(void *ta_state, struct table_info *ti,
ta_foreach_f *f, void *arg);
static int ta_prepare_add_chash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_add_chash(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static int ta_prepare_del_chash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_del_chash(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static void ta_flush_chash_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_need_modify_chash(void *ta_state, struct table_info *ti,
uint32_t count, uint64_t *pflags);
static int ta_prepare_mod_chash(void *ta_buf, uint64_t *pflags);
static int ta_fill_mod_chash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t *pflags);
static void ta_modify_chash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags);
static void ta_flush_mod_chash(void *ta_buf);
#ifdef INET
static __inline uint32_t
hash_ip(uint32_t addr, int hsize)
{
return (addr % (hsize - 1));
}
#endif
#ifdef INET6
static __inline uint32_t
hash_ip6(struct in6_addr *addr6, int hsize)
{
uint32_t i;
i = addr6->s6_addr32[0] ^ addr6->s6_addr32[1] ^
addr6->s6_addr32[2] ^ addr6->s6_addr32[3];
return (i % (hsize - 1));
}
static __inline uint16_t
hash_ip64(struct in6_addr *addr6, int hsize)
{
uint32_t i;
i = addr6->s6_addr32[0] ^ addr6->s6_addr32[1];
return (i % (hsize - 1));
}
static __inline uint32_t
hash_ip6_slow(struct in6_addr *addr6, void *key, int mask, int hsize)
{
struct in6_addr mask6;
ipv6_writemask(&mask6, mask);
memcpy(addr6, key, sizeof(struct in6_addr));
APPLY_MASK(addr6, &mask6);
return (hash_ip6(addr6, hsize));
}
static __inline uint32_t
hash_ip6_al(struct in6_addr *addr6, void *key, int mask, int hsize)
{
uint64_t *paddr;
paddr = (uint64_t *)addr6;
*paddr = 0;
*(paddr + 1) = 0;
memcpy(addr6, key, mask);
return (hash_ip6(addr6, hsize));
}
#endif
static int
ta_lookup_chash_slow(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct chashbhead *head;
struct chashentry *ent;
uint16_t hash, hsize;
uint8_t imask;
if (keylen == sizeof(in_addr_t)) {
#ifdef INET
head = (struct chashbhead *)ti->state;
imask = ti->data >> 24;
hsize = 1 << ((ti->data & 0xFFFF) >> 8);
uint32_t a;
a = ntohl(*((in_addr_t *)key));
a = a >> imask;
hash = hash_ip(a, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
if (ent->a.a4 == a) {
*val = ent->value;
return (1);
}
}
#endif
} else {
#ifdef INET6
/* IPv6: worst scenario: non-round mask */
struct in6_addr addr6;
head = (struct chashbhead *)ti->xstate;
imask = (ti->data & 0xFF0000) >> 16;
hsize = 1 << (ti->data & 0xFF);
hash = hash_ip6_slow(&addr6, key, imask, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
if (memcmp(&ent->a.a6, &addr6, 16) == 0) {
*val = ent->value;
return (1);
}
}
#endif
}
return (0);
}
static int
ta_lookup_chash_aligned(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct chashbhead *head;
struct chashentry *ent;
uint16_t hash, hsize;
uint8_t imask;
if (keylen == sizeof(in_addr_t)) {
#ifdef INET
head = (struct chashbhead *)ti->state;
imask = ti->data >> 24;
hsize = 1 << ((ti->data & 0xFFFF) >> 8);
uint32_t a;
a = ntohl(*((in_addr_t *)key));
a = a >> imask;
hash = hash_ip(a, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
if (ent->a.a4 == a) {
*val = ent->value;
return (1);
}
}
#endif
} else {
#ifdef INET6
/* IPv6: aligned to 8bit mask */
struct in6_addr addr6;
uint64_t *paddr, *ptmp;
head = (struct chashbhead *)ti->xstate;
imask = (ti->data & 0xFF0000) >> 16;
hsize = 1 << (ti->data & 0xFF);
hash = hash_ip6_al(&addr6, key, imask, hsize);
paddr = (uint64_t *)&addr6;
SLIST_FOREACH(ent, &head[hash], next) {
ptmp = (uint64_t *)&ent->a.a6;
if (paddr[0] == ptmp[0] && paddr[1] == ptmp[1]) {
*val = ent->value;
return (1);
}
}
#endif
}
return (0);
}
static int
ta_lookup_chash_64(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct chashbhead *head;
struct chashentry *ent;
uint16_t hash, hsize;
uint8_t imask;
if (keylen == sizeof(in_addr_t)) {
#ifdef INET
head = (struct chashbhead *)ti->state;
imask = ti->data >> 24;
hsize = 1 << ((ti->data & 0xFFFF) >> 8);
uint32_t a;
a = ntohl(*((in_addr_t *)key));
a = a >> imask;
hash = hash_ip(a, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
if (ent->a.a4 == a) {
*val = ent->value;
return (1);
}
}
#endif
} else {
#ifdef INET6
/* IPv6: /64 */
uint64_t a6, *paddr;
head = (struct chashbhead *)ti->xstate;
paddr = (uint64_t *)key;
hsize = 1 << (ti->data & 0xFF);
a6 = *paddr;
hash = hash_ip64((struct in6_addr *)key, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
paddr = (uint64_t *)&ent->a.a6;
if (a6 == *paddr) {
*val = ent->value;
return (1);
}
}
#endif
}
return (0);
}
static int
chash_parse_opts(struct chash_cfg *cfg, char *data)
{
char *pdel, *pend, *s;
int mask4, mask6;
mask4 = cfg->mask4;
mask6 = cfg->mask6;
if (data == NULL)
return (0);
if ((pdel = strchr(data, ' ')) == NULL)
return (0);
while (*pdel == ' ')
pdel++;
if (strncmp(pdel, "masks=", 6) != 0)
return (EINVAL);
if ((s = strchr(pdel, ' ')) != NULL)
*s++ = '\0';
pdel += 6;
/* Need /XX[,/YY] */
if (*pdel++ != '/')
return (EINVAL);
mask4 = strtol(pdel, &pend, 10);
if (*pend == ',') {
/* ,/YY */
pdel = pend + 1;
if (*pdel++ != '/')
return (EINVAL);
mask6 = strtol(pdel, &pend, 10);
if (*pend != '\0')
return (EINVAL);
} else if (*pend != '\0')
return (EINVAL);
if (mask4 < 0 || mask4 > 32 || mask6 < 0 || mask6 > 128)
return (EINVAL);
cfg->mask4 = mask4;
cfg->mask6 = mask6;
return (0);
}
static void
ta_print_chash_config(void *ta_state, struct table_info *ti, char *buf,
size_t bufsize)
{
struct chash_cfg *cfg;
cfg = (struct chash_cfg *)ta_state;
if (cfg->mask4 != 32 || cfg->mask6 != 128)
snprintf(buf, bufsize, "%s masks=/%d,/%d", "addr:hash",
cfg->mask4, cfg->mask6);
else
snprintf(buf, bufsize, "%s", "addr:hash");
}
static int
ta_log2(uint32_t v)
{
uint32_t r;
r = 0;
while (v >>= 1)
r++;
return (r);
}
/*
* New table.
* We assume 'data' to be either NULL or the following format:
* 'addr:hash [masks=/32[,/128]]'
*/
static int
ta_init_chash(struct ip_fw_chain *ch, void **ta_state, struct table_info *ti,
char *data, uint8_t tflags)
{
int error, i;
uint32_t hsize;
struct chash_cfg *cfg;
cfg = malloc(sizeof(struct chash_cfg), M_IPFW, M_WAITOK | M_ZERO);
cfg->mask4 = 32;
cfg->mask6 = 128;
if ((error = chash_parse_opts(cfg, data)) != 0) {
free(cfg, M_IPFW);
return (error);
}
cfg->size4 = 128;
cfg->size6 = 128;
cfg->head4 = malloc(sizeof(struct chashbhead) * cfg->size4, M_IPFW,
M_WAITOK | M_ZERO);
cfg->head6 = malloc(sizeof(struct chashbhead) * cfg->size6, M_IPFW,
M_WAITOK | M_ZERO);
for (i = 0; i < cfg->size4; i++)
SLIST_INIT(&cfg->head4[i]);
for (i = 0; i < cfg->size6; i++)
SLIST_INIT(&cfg->head6[i]);
*ta_state = cfg;
ti->state = cfg->head4;
ti->xstate = cfg->head6;
/* Store data depending on v6 mask length */
hsize = ta_log2(cfg->size4) << 8 | ta_log2(cfg->size6);
if (cfg->mask6 == 64) {
ti->data = (32 - cfg->mask4) << 24 | (128 - cfg->mask6) << 16|
hsize;
ti->lookup = ta_lookup_chash_64;
} else if ((cfg->mask6 % 8) == 0) {
ti->data = (32 - cfg->mask4) << 24 |
cfg->mask6 << 13 | hsize;
ti->lookup = ta_lookup_chash_aligned;
} else {
/* don't do that! */
ti->data = (32 - cfg->mask4) << 24 |
cfg->mask6 << 16 | hsize;
ti->lookup = ta_lookup_chash_slow;
}
return (0);
}
static void
ta_destroy_chash(void *ta_state, struct table_info *ti)
{
struct chash_cfg *cfg;
struct chashentry *ent, *ent_next;
int i;
cfg = (struct chash_cfg *)ta_state;
for (i = 0; i < cfg->size4; i++)
SLIST_FOREACH_SAFE(ent, &cfg->head4[i], next, ent_next)
free(ent, M_IPFW_TBL);
for (i = 0; i < cfg->size6; i++)
SLIST_FOREACH_SAFE(ent, &cfg->head6[i], next, ent_next)
free(ent, M_IPFW_TBL);
free(cfg->head4, M_IPFW);
free(cfg->head6, M_IPFW);
free(cfg, M_IPFW);
}
static void
ta_dump_chash_tinfo(void *ta_state, struct table_info *ti, ipfw_ta_tinfo *tinfo)
{
struct chash_cfg *cfg;
cfg = (struct chash_cfg *)ta_state;
tinfo->flags = IPFW_TATFLAGS_AFDATA | IPFW_TATFLAGS_AFITEM;
tinfo->taclass4 = IPFW_TACLASS_HASH;
tinfo->size4 = cfg->size4;
tinfo->count4 = cfg->items4;
tinfo->itemsize4 = sizeof(struct chashentry);
tinfo->taclass6 = IPFW_TACLASS_HASH;
tinfo->size6 = cfg->size6;
tinfo->count6 = cfg->items6;
tinfo->itemsize6 = sizeof(struct chashentry);
}
static int
ta_dump_chash_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent)
{
struct chash_cfg *cfg;
struct chashentry *ent;
cfg = (struct chash_cfg *)ta_state;
ent = (struct chashentry *)e;
if (ent->type == AF_INET) {
tent->k.addr.s_addr = htonl(ent->a.a4 << (32 - cfg->mask4));
tent->masklen = cfg->mask4;
tent->subtype = AF_INET;
tent->v.kidx = ent->value;
#ifdef INET6
} else {
memcpy(&tent->k.addr6, &ent->a.a6, sizeof(struct in6_addr));
tent->masklen = cfg->mask6;
tent->subtype = AF_INET6;
tent->v.kidx = ent->value;
#endif
}
return (0);
}
static uint32_t
hash_ent(struct chashentry *ent, int af, int mlen, uint32_t size)
{
uint32_t hash;
hash = 0;
if (af == AF_INET) {
#ifdef INET
hash = hash_ip(ent->a.a4, size);
#endif
} else {
#ifdef INET6
if (mlen == 64)
hash = hash_ip64(&ent->a.a6, size);
else
hash = hash_ip6(&ent->a.a6, size);
#endif
}
return (hash);
}
static int
tei_to_chash_ent(struct tentry_info *tei, struct chashentry *ent)
{
int mlen;
#ifdef INET6
struct in6_addr mask6;
#endif
mlen = tei->masklen;
if (tei->subtype == AF_INET) {
#ifdef INET
if (mlen > 32)
return (EINVAL);
ent->type = AF_INET;
/* Calculate masked address */
ent->a.a4 = ntohl(*((in_addr_t *)tei->paddr)) >> (32 - mlen);
#endif
#ifdef INET6
} else if (tei->subtype == AF_INET6) {
/* IPv6 case */
if (mlen > 128)
return (EINVAL);
ent->type = AF_INET6;
ipv6_writemask(&mask6, mlen);
memcpy(&ent->a.a6, tei->paddr, sizeof(struct in6_addr));
APPLY_MASK(&ent->a.a6, &mask6);
#endif
} else {
/* Unknown CIDR type */
return (EINVAL);
}
return (0);
}
static int
ta_find_chash_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent)
{
struct chash_cfg *cfg;
struct chashbhead *head;
struct chashentry ent, *tmp;
struct tentry_info tei;
int error;
uint32_t hash;
cfg = (struct chash_cfg *)ta_state;
memset(&ent, 0, sizeof(ent));
memset(&tei, 0, sizeof(tei));
if (tent->subtype == AF_INET) {
tei.paddr = &tent->k.addr;
tei.masklen = cfg->mask4;
tei.subtype = AF_INET;
if ((error = tei_to_chash_ent(&tei, &ent)) != 0)
return (error);
head = cfg->head4;
hash = hash_ent(&ent, AF_INET, cfg->mask4, cfg->size4);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (tmp->a.a4 != ent.a.a4)
continue;
ta_dump_chash_tentry(ta_state, ti, tmp, tent);
return (0);
}
} else {
tei.paddr = &tent->k.addr6;
tei.masklen = cfg->mask6;
tei.subtype = AF_INET6;
if ((error = tei_to_chash_ent(&tei, &ent)) != 0)
return (error);
head = cfg->head6;
hash = hash_ent(&ent, AF_INET6, cfg->mask6, cfg->size6);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (memcmp(&tmp->a.a6, &ent.a.a6, 16) != 0)
continue;
ta_dump_chash_tentry(ta_state, ti, tmp, tent);
return (0);
}
}
return (ENOENT);
}
static void
ta_foreach_chash(void *ta_state, struct table_info *ti, ta_foreach_f *f,
void *arg)
{
struct chash_cfg *cfg;
struct chashentry *ent, *ent_next;
int i;
cfg = (struct chash_cfg *)ta_state;
for (i = 0; i < cfg->size4; i++)
SLIST_FOREACH_SAFE(ent, &cfg->head4[i], next, ent_next)
f(ent, arg);
for (i = 0; i < cfg->size6; i++)
SLIST_FOREACH_SAFE(ent, &cfg->head6[i], next, ent_next)
f(ent, arg);
}
static int
ta_prepare_add_chash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_chash *tb;
struct chashentry *ent;
int error;
tb = (struct ta_buf_chash *)ta_buf;
ent = malloc(sizeof(*ent), M_IPFW_TBL, M_WAITOK | M_ZERO);
error = tei_to_chash_ent(tei, ent);
if (error != 0) {
free(ent, M_IPFW_TBL);
return (error);
}
tb->ent_ptr = ent;
return (0);
}
static int
ta_add_chash(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct chash_cfg *cfg;
struct chashbhead *head;
struct chashentry *ent, *tmp;
struct ta_buf_chash *tb;
int exists;
uint32_t hash, value;
cfg = (struct chash_cfg *)ta_state;
tb = (struct ta_buf_chash *)ta_buf;
ent = (struct chashentry *)tb->ent_ptr;
hash = 0;
exists = 0;
/* Read current value from @tei */
ent->value = tei->value;
/* Read cuurrent value */
if (tei->subtype == AF_INET) {
if (tei->masklen != cfg->mask4)
return (EINVAL);
head = cfg->head4;
hash = hash_ent(ent, AF_INET, cfg->mask4, cfg->size4);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (tmp->a.a4 == ent->a.a4) {
exists = 1;
break;
}
}
} else {
if (tei->masklen != cfg->mask6)
return (EINVAL);
head = cfg->head6;
hash = hash_ent(ent, AF_INET6, cfg->mask6, cfg->size6);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (memcmp(&tmp->a.a6, &ent->a.a6, 16) == 0) {
exists = 1;
break;
}
}
}
if (exists == 1) {
if ((tei->flags & TEI_FLAGS_UPDATE) == 0)
return (EEXIST);
/* Record already exists. Update value if we're asked to */
value = tmp->value;
tmp->value = tei->value;
tei->value = value;
/* Indicate that update has happened instead of addition */
tei->flags |= TEI_FLAGS_UPDATED;
*pnum = 0;
} else {
if ((tei->flags & TEI_FLAGS_DONTADD) != 0)
return (EFBIG);
SLIST_INSERT_HEAD(&head[hash], ent, next);
tb->ent_ptr = NULL;
*pnum = 1;
/* Update counters */
if (tei->subtype == AF_INET)
cfg->items4++;
else
cfg->items6++;
}
return (0);
}
static int
ta_prepare_del_chash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_chash *tb;
tb = (struct ta_buf_chash *)ta_buf;
return (tei_to_chash_ent(tei, &tb->ent));
}
static int
ta_del_chash(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct chash_cfg *cfg;
struct chashbhead *head;
struct chashentry *tmp, *tmp_next, *ent;
struct ta_buf_chash *tb;
uint32_t hash;
cfg = (struct chash_cfg *)ta_state;
tb = (struct ta_buf_chash *)ta_buf;
ent = &tb->ent;
if (tei->subtype == AF_INET) {
if (tei->masklen != cfg->mask4)
return (EINVAL);
head = cfg->head4;
hash = hash_ent(ent, AF_INET, cfg->mask4, cfg->size4);
SLIST_FOREACH_SAFE(tmp, &head[hash], next, tmp_next) {
if (tmp->a.a4 != ent->a.a4)
continue;
SLIST_REMOVE(&head[hash], tmp, chashentry, next);
cfg->items4--;
tb->ent_ptr = tmp;
tei->value = tmp->value;
*pnum = 1;
return (0);
}
} else {
if (tei->masklen != cfg->mask6)
return (EINVAL);
head = cfg->head6;
hash = hash_ent(ent, AF_INET6, cfg->mask6, cfg->size6);
SLIST_FOREACH_SAFE(tmp, &head[hash], next, tmp_next) {
if (memcmp(&tmp->a.a6, &ent->a.a6, 16) != 0)
continue;
SLIST_REMOVE(&head[hash], tmp, chashentry, next);
cfg->items6--;
tb->ent_ptr = tmp;
tei->value = tmp->value;
*pnum = 1;
return (0);
}
}
return (ENOENT);
}
static void
ta_flush_chash_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_chash *tb;
tb = (struct ta_buf_chash *)ta_buf;
if (tb->ent_ptr != NULL)
free(tb->ent_ptr, M_IPFW_TBL);
}
/*
* Hash growing callbacks.
*/
static int
ta_need_modify_chash(void *ta_state, struct table_info *ti, uint32_t count,
uint64_t *pflags)
{
struct chash_cfg *cfg;
uint64_t data;
/*
* Since we don't know exact number of IPv4/IPv6 records in @count,
* ignore non-zero @count value at all. Check current hash sizes
* and return appropriate data.
*/
cfg = (struct chash_cfg *)ta_state;
data = 0;
if (cfg->items4 > cfg->size4 && cfg->size4 < 65536)
data |= (cfg->size4 * 2) << 16;
if (cfg->items6 > cfg->size6 && cfg->size6 < 65536)
data |= cfg->size6 * 2;
if (data != 0) {
*pflags = data;
return (1);
}
return (0);
}
/*
* Allocate new, larger chash.
*/
static int
ta_prepare_mod_chash(void *ta_buf, uint64_t *pflags)
{
struct mod_item *mi;
struct chashbhead *head;
int i;
mi = (struct mod_item *)ta_buf;
memset(mi, 0, sizeof(struct mod_item));
mi->size = (*pflags >> 16) & 0xFFFF;
mi->size6 = *pflags & 0xFFFF;
if (mi->size > 0) {
head = malloc(sizeof(struct chashbhead) * mi->size,
M_IPFW, M_WAITOK | M_ZERO);
for (i = 0; i < mi->size; i++)
SLIST_INIT(&head[i]);
mi->main_ptr = head;
}
if (mi->size6 > 0) {
head = malloc(sizeof(struct chashbhead) * mi->size6,
M_IPFW, M_WAITOK | M_ZERO);
for (i = 0; i < mi->size6; i++)
SLIST_INIT(&head[i]);
mi->main_ptr6 = head;
}
return (0);
}
/*
* Copy data from old runtime array to new one.
*/
static int
ta_fill_mod_chash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t *pflags)
{
/* In is not possible to do rehash if we're not holidng WLOCK. */
return (0);
}
/*
* Switch old & new arrays.
*/
static void
ta_modify_chash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags)
{
struct mod_item *mi;
struct chash_cfg *cfg;
struct chashbhead *old_head, *new_head;
struct chashentry *ent, *ent_next;
int af, i, mlen;
uint32_t nhash;
size_t old_size, new_size;
mi = (struct mod_item *)ta_buf;
cfg = (struct chash_cfg *)ta_state;
/* Check which hash we need to grow and do we still need that */
if (mi->size > 0 && cfg->size4 < mi->size) {
new_head = (struct chashbhead *)mi->main_ptr;
new_size = mi->size;
old_size = cfg->size4;
old_head = ti->state;
mlen = cfg->mask4;
af = AF_INET;
for (i = 0; i < old_size; i++) {
SLIST_FOREACH_SAFE(ent, &old_head[i], next, ent_next) {
nhash = hash_ent(ent, af, mlen, new_size);
SLIST_INSERT_HEAD(&new_head[nhash], ent, next);
}
}
ti->state = new_head;
cfg->head4 = new_head;
cfg->size4 = mi->size;
mi->main_ptr = old_head;
}
if (mi->size6 > 0 && cfg->size6 < mi->size6) {
new_head = (struct chashbhead *)mi->main_ptr6;
new_size = mi->size6;
old_size = cfg->size6;
old_head = ti->xstate;
mlen = cfg->mask6;
af = AF_INET6;
for (i = 0; i < old_size; i++) {
SLIST_FOREACH_SAFE(ent, &old_head[i], next, ent_next) {
nhash = hash_ent(ent, af, mlen, new_size);
SLIST_INSERT_HEAD(&new_head[nhash], ent, next);
}
}
ti->xstate = new_head;
cfg->head6 = new_head;
cfg->size6 = mi->size6;
mi->main_ptr6 = old_head;
}
/* Update lower 32 bits with new values */
ti->data &= 0xFFFFFFFF00000000;
ti->data |= ta_log2(cfg->size4) << 8 | ta_log2(cfg->size6);
}
/*
* Free unneded array.
*/
static void
ta_flush_mod_chash(void *ta_buf)
{
struct mod_item *mi;
mi = (struct mod_item *)ta_buf;
if (mi->main_ptr != NULL)
free(mi->main_ptr, M_IPFW);
if (mi->main_ptr6 != NULL)
free(mi->main_ptr6, M_IPFW);
}
struct table_algo addr_hash = {
.name = "addr:hash",
.type = IPFW_TABLE_ADDR,
.ta_buf_size = sizeof(struct ta_buf_chash),
.init = ta_init_chash,
.destroy = ta_destroy_chash,
.prepare_add = ta_prepare_add_chash,
.prepare_del = ta_prepare_del_chash,
.add = ta_add_chash,
.del = ta_del_chash,
.flush_entry = ta_flush_chash_entry,
.foreach = ta_foreach_chash,
.dump_tentry = ta_dump_chash_tentry,
.find_tentry = ta_find_chash_tentry,
.print_config = ta_print_chash_config,
.dump_tinfo = ta_dump_chash_tinfo,
.need_modify = ta_need_modify_chash,
.prepare_mod = ta_prepare_mod_chash,
.fill_mod = ta_fill_mod_chash,
.modify = ta_modify_chash,
.flush_mod = ta_flush_mod_chash,
};
/*
* Iface table cmds.
*
* Implementation:
*
* Runtime part:
* - sorted array of "struct ifidx" pointed by ti->state.
* Array is allocated with rounding up to IFIDX_CHUNK. Only existing
* interfaces are stored in array, however its allocated size is
* sufficient to hold all table records if needed.
* - current array size is stored in ti->data
*
* Table data:
* - "struct iftable_cfg" is allocated to store table state (ta_state).
* - All table records are stored inside namedobj instance.
*
*/
struct ifidx {
uint16_t kidx;
uint16_t spare;
uint32_t value;
};
#define DEFAULT_IFIDX_SIZE 64
struct iftable_cfg;
struct ifentry {
struct named_object no;
struct ipfw_ifc ic;
struct iftable_cfg *icfg;
uint32_t value;
int linked;
};
struct iftable_cfg {
struct namedobj_instance *ii;
struct ip_fw_chain *ch;
struct table_info *ti;
void *main_ptr;
size_t size; /* Number of items allocated in array */
size_t count; /* Number of all items */
size_t used; /* Number of items _active_ now */
};
struct ta_buf_ifidx
{
struct ifentry *ife;
uint32_t value;
};
int compare_ifidx(const void *k, const void *v);
static struct ifidx * ifidx_find(struct table_info *ti, void *key);
static int ta_lookup_ifidx(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val);
static int ta_init_ifidx(struct ip_fw_chain *ch, void **ta_state,
struct table_info *ti, char *data, uint8_t tflags);
static void ta_change_ti_ifidx(void *ta_state, struct table_info *ti);
static int destroy_ifidx_locked(struct namedobj_instance *ii,
struct named_object *no, void *arg);
static void ta_destroy_ifidx(void *ta_state, struct table_info *ti);
static void ta_dump_ifidx_tinfo(void *ta_state, struct table_info *ti,
ipfw_ta_tinfo *tinfo);
static int ta_prepare_add_ifidx(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_add_ifidx(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static int ta_prepare_del_ifidx(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_del_ifidx(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static void ta_flush_ifidx_entry(struct ip_fw_chain *ch,
struct tentry_info *tei, void *ta_buf);
static void if_notifier(struct ip_fw_chain *ch, void *cbdata, uint16_t ifindex);
static int ta_need_modify_ifidx(void *ta_state, struct table_info *ti,
uint32_t count, uint64_t *pflags);
static int ta_prepare_mod_ifidx(void *ta_buf, uint64_t *pflags);
static int ta_fill_mod_ifidx(void *ta_state, struct table_info *ti,
void *ta_buf, uint64_t *pflags);
static void ta_modify_ifidx(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags);
static void ta_flush_mod_ifidx(void *ta_buf);
static int ta_dump_ifidx_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent);
static int ta_find_ifidx_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent);
static int foreach_ifidx(struct namedobj_instance *ii, struct named_object *no,
void *arg);
static void ta_foreach_ifidx(void *ta_state, struct table_info *ti,
ta_foreach_f *f, void *arg);
int
compare_ifidx(const void *k, const void *v)
{
const struct ifidx *ifidx;
uint16_t key;
key = *((const uint16_t *)k);
ifidx = (const struct ifidx *)v;
if (key < ifidx->kidx)
return (-1);
else if (key > ifidx->kidx)
return (1);
return (0);
}
/*
* Adds item @item with key @key into ascending-sorted array @base.
* Assumes @base has enough additional storage.
*
* Returns 1 on success, 0 on duplicate key.
*/
static int
badd(const void *key, void *item, void *base, size_t nmemb,
size_t size, int (*compar) (const void *, const void *))
{
int min, max, mid, shift, res;
caddr_t paddr;
if (nmemb == 0) {
memcpy(base, item, size);
return (1);
}
/* Binary search */
min = 0;
max = nmemb - 1;
mid = 0;
while (min <= max) {
mid = (min + max) / 2;
res = compar(key, (const void *)((caddr_t)base + mid * size));
if (res == 0)
return (0);
if (res > 0)
min = mid + 1;
else
max = mid - 1;
}
/* Item not found. */
res = compar(key, (const void *)((caddr_t)base + mid * size));
if (res > 0)
shift = mid + 1;
else
shift = mid;
paddr = (caddr_t)base + shift * size;
if (nmemb > shift)
memmove(paddr + size, paddr, (nmemb - shift) * size);
memcpy(paddr, item, size);
return (1);
}
/*
* Deletes item with key @key from ascending-sorted array @base.
*
* Returns 1 on success, 0 for non-existent key.
*/
static int
bdel(const void *key, void *base, size_t nmemb, size_t size,
int (*compar) (const void *, const void *))
{
caddr_t item;
size_t sz;
item = (caddr_t)bsearch(key, base, nmemb, size, compar);
if (item == NULL)
return (0);
sz = (caddr_t)base + nmemb * size - item;
if (sz > 0)
memmove(item, item + size, sz);
return (1);
}
static struct ifidx *
ifidx_find(struct table_info *ti, void *key)
{
struct ifidx *ifi;
ifi = bsearch(key, ti->state, ti->data, sizeof(struct ifidx),
compare_ifidx);
return (ifi);
}
static int
ta_lookup_ifidx(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct ifidx *ifi;
ifi = ifidx_find(ti, key);
if (ifi != NULL) {
*val = ifi->value;
return (1);
}
return (0);
}
static int
ta_init_ifidx(struct ip_fw_chain *ch, void **ta_state, struct table_info *ti,
char *data, uint8_t tflags)
{
struct iftable_cfg *icfg;
icfg = malloc(sizeof(struct iftable_cfg), M_IPFW, M_WAITOK | M_ZERO);
icfg->ii = ipfw_objhash_create(DEFAULT_IFIDX_SIZE);
icfg->size = DEFAULT_IFIDX_SIZE;
icfg->main_ptr = malloc(sizeof(struct ifidx) * icfg->size, M_IPFW,
M_WAITOK | M_ZERO);
icfg->ch = ch;
*ta_state = icfg;
ti->state = icfg->main_ptr;
ti->lookup = ta_lookup_ifidx;
return (0);
}
/*
* Handle tableinfo @ti pointer change (on table array resize).
*/
static void
ta_change_ti_ifidx(void *ta_state, struct table_info *ti)
{
struct iftable_cfg *icfg;
icfg = (struct iftable_cfg *)ta_state;
icfg->ti = ti;
}
static int
destroy_ifidx_locked(struct namedobj_instance *ii, struct named_object *no,
void *arg)
{
struct ifentry *ife;
struct ip_fw_chain *ch;
ch = (struct ip_fw_chain *)arg;
ife = (struct ifentry *)no;
ipfw_iface_del_notify(ch, &ife->ic);
ipfw_iface_unref(ch, &ife->ic);
free(ife, M_IPFW_TBL);
return (0);
}
/*
* Destroys table @ti
*/
static void
ta_destroy_ifidx(void *ta_state, struct table_info *ti)
{
struct iftable_cfg *icfg;
struct ip_fw_chain *ch;
icfg = (struct iftable_cfg *)ta_state;
ch = icfg->ch;
if (icfg->main_ptr != NULL)
free(icfg->main_ptr, M_IPFW);
IPFW_UH_WLOCK(ch);
ipfw_objhash_foreach(icfg->ii, destroy_ifidx_locked, ch);
IPFW_UH_WUNLOCK(ch);
ipfw_objhash_destroy(icfg->ii);
free(icfg, M_IPFW);
}
/*
* Provide algo-specific table info
*/
static void
ta_dump_ifidx_tinfo(void *ta_state, struct table_info *ti, ipfw_ta_tinfo *tinfo)
{
struct iftable_cfg *cfg;
cfg = (struct iftable_cfg *)ta_state;
tinfo->taclass4 = IPFW_TACLASS_ARRAY;
tinfo->size4 = cfg->size;
tinfo->count4 = cfg->used;
tinfo->itemsize4 = sizeof(struct ifidx);
}
/*
* Prepare state to add to the table:
* allocate ifentry and reference needed interface.
*/
static int
ta_prepare_add_ifidx(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_ifidx *tb;
char *ifname;
struct ifentry *ife;
tb = (struct ta_buf_ifidx *)ta_buf;
/* Check if string is terminated */
ifname = (char *)tei->paddr;
if (strnlen(ifname, IF_NAMESIZE) == IF_NAMESIZE)
return (EINVAL);
ife = malloc(sizeof(struct ifentry), M_IPFW_TBL, M_WAITOK | M_ZERO);
ife->ic.cb = if_notifier;
ife->ic.cbdata = ife;
if (ipfw_iface_ref(ch, ifname, &ife->ic) != 0) {
free(ife, M_IPFW_TBL);
return (EINVAL);
}
/* Use ipfw_iface 'ifname' field as stable storage */
ife->no.name = ife->ic.iface->ifname;
tb->ife = ife;
return (0);
}
static int
ta_add_ifidx(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct iftable_cfg *icfg;
struct ifentry *ife, *tmp;
struct ta_buf_ifidx *tb;
struct ipfw_iface *iif;
struct ifidx *ifi;
char *ifname;
uint32_t value;
tb = (struct ta_buf_ifidx *)ta_buf;
ifname = (char *)tei->paddr;
icfg = (struct iftable_cfg *)ta_state;
ife = tb->ife;
ife->icfg = icfg;
ife->value = tei->value;
tmp = (struct ifentry *)ipfw_objhash_lookup_name(icfg->ii, 0, ifname);
if (tmp != NULL) {
if ((tei->flags & TEI_FLAGS_UPDATE) == 0)
return (EEXIST);
/* Exchange values in @tmp and @tei */
value = tmp->value;
tmp->value = tei->value;
tei->value = value;
iif = tmp->ic.iface;
if (iif->resolved != 0) {
/* We have to update runtime value, too */
ifi = ifidx_find(ti, &iif->ifindex);
ifi->value = ife->value;
}
/* Indicate that update has happened instead of addition */
tei->flags |= TEI_FLAGS_UPDATED;
*pnum = 0;
return (0);
}
if ((tei->flags & TEI_FLAGS_DONTADD) != 0)
return (EFBIG);
/* Link to internal list */
ipfw_objhash_add(icfg->ii, &ife->no);
/* Link notifier (possible running its callback) */
ipfw_iface_add_notify(icfg->ch, &ife->ic);
icfg->count++;
tb->ife = NULL;
*pnum = 1;
return (0);
}
/*
* Prepare to delete key from table.
* Do basic interface name checks.
*/
static int
ta_prepare_del_ifidx(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_ifidx *tb;
char *ifname;
tb = (struct ta_buf_ifidx *)ta_buf;
/* Check if string is terminated */
ifname = (char *)tei->paddr;
if (strnlen(ifname, IF_NAMESIZE) == IF_NAMESIZE)
return (EINVAL);
return (0);
}
/*
* Remove key from both configuration list and
* runtime array. Removed interface notification.
*/
static int
ta_del_ifidx(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct iftable_cfg *icfg;
struct ifentry *ife;
struct ta_buf_ifidx *tb;
char *ifname;
uint16_t ifindex;
int res;
tb = (struct ta_buf_ifidx *)ta_buf;
ifname = (char *)tei->paddr;
icfg = (struct iftable_cfg *)ta_state;
ife = (struct ifentry *)ipfw_objhash_lookup_name(icfg->ii, 0, ifname);
if (ife == NULL)
return (ENOENT);
if (ife->linked != 0) {
/* We have to remove item from runtime */
ifindex = ife->ic.iface->ifindex;
res = bdel(&ifindex, icfg->main_ptr, icfg->used,
sizeof(struct ifidx), compare_ifidx);
KASSERT(res == 1, ("index %d does not exist", ifindex));
icfg->used--;
ti->data = icfg->used;
ife->linked = 0;
}
/* Unlink from local list */
ipfw_objhash_del(icfg->ii, &ife->no);
/* Unlink notifier and deref */
ipfw_iface_del_notify(icfg->ch, &ife->ic);
ipfw_iface_unref(icfg->ch, &ife->ic);
icfg->count--;
tei->value = ife->value;
tb->ife = ife;
*pnum = 1;
return (0);
}
/*
* Flush deleted entry.
* Drops interface reference and frees entry.
*/
static void
ta_flush_ifidx_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_ifidx *tb;
tb = (struct ta_buf_ifidx *)ta_buf;
if (tb->ife != NULL)
free(tb->ife, M_IPFW_TBL);
}
/*
* Handle interface announce/withdrawal for particular table.
* Every real runtime array modification happens here.
*/
static void
if_notifier(struct ip_fw_chain *ch, void *cbdata, uint16_t ifindex)
{
struct ifentry *ife;
struct ifidx ifi;
struct iftable_cfg *icfg;
struct table_info *ti;
int res;
ife = (struct ifentry *)cbdata;
icfg = ife->icfg;
ti = icfg->ti;
KASSERT(ti != NULL, ("ti=NULL, check change_ti handler"));
if (ife->linked == 0 && ifindex != 0) {
/* Interface announce */
ifi.kidx = ifindex;
ifi.spare = 0;
ifi.value = ife->value;
res = badd(&ifindex, &ifi, icfg->main_ptr, icfg->used,
sizeof(struct ifidx), compare_ifidx);
KASSERT(res == 1, ("index %d already exists", ifindex));
icfg->used++;
ti->data = icfg->used;
ife->linked = 1;
} else if (ife->linked != 0 && ifindex == 0) {
/* Interface withdrawal */
ifindex = ife->ic.iface->ifindex;
res = bdel(&ifindex, icfg->main_ptr, icfg->used,
sizeof(struct ifidx), compare_ifidx);
KASSERT(res == 1, ("index %d does not exist", ifindex));
icfg->used--;
ti->data = icfg->used;
ife->linked = 0;
}
}
/*
* Table growing callbacks.
*/
static int
ta_need_modify_ifidx(void *ta_state, struct table_info *ti, uint32_t count,
uint64_t *pflags)
{
struct iftable_cfg *cfg;
uint32_t size;
cfg = (struct iftable_cfg *)ta_state;
size = cfg->size;
while (size < cfg->count + count)
size *= 2;
if (size != cfg->size) {
*pflags = size;
return (1);
}
return (0);
}
/*
* Allocate ned, larger runtime ifidx array.
*/
static int
ta_prepare_mod_ifidx(void *ta_buf, uint64_t *pflags)
{
struct mod_item *mi;
mi = (struct mod_item *)ta_buf;
memset(mi, 0, sizeof(struct mod_item));
mi->size = *pflags;
mi->main_ptr = malloc(sizeof(struct ifidx) * mi->size, M_IPFW,
M_WAITOK | M_ZERO);
return (0);
}
/*
* Copy data from old runtime array to new one.
*/
static int
ta_fill_mod_ifidx(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t *pflags)
{
struct mod_item *mi;
struct iftable_cfg *icfg;
mi = (struct mod_item *)ta_buf;
icfg = (struct iftable_cfg *)ta_state;
/* Check if we still need to grow array */
if (icfg->size >= mi->size) {
*pflags = 0;
return (0);
}
memcpy(mi->main_ptr, icfg->main_ptr, icfg->used * sizeof(struct ifidx));
return (0);
}
/*
* Switch old & new arrays.
*/
static void
ta_modify_ifidx(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags)
{
struct mod_item *mi;
struct iftable_cfg *icfg;
void *old_ptr;
mi = (struct mod_item *)ta_buf;
icfg = (struct iftable_cfg *)ta_state;
old_ptr = icfg->main_ptr;
icfg->main_ptr = mi->main_ptr;
icfg->size = mi->size;
ti->state = icfg->main_ptr;
mi->main_ptr = old_ptr;
}
/*
* Free unneded array.
*/
static void
ta_flush_mod_ifidx(void *ta_buf)
{
struct mod_item *mi;
mi = (struct mod_item *)ta_buf;
if (mi->main_ptr != NULL)
free(mi->main_ptr, M_IPFW);
}
static int
ta_dump_ifidx_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent)
{
struct ifentry *ife;
ife = (struct ifentry *)e;
tent->masklen = 8 * IF_NAMESIZE;
memcpy(&tent->k, ife->no.name, IF_NAMESIZE);
tent->v.kidx = ife->value;
return (0);
}
static int
ta_find_ifidx_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent)
{
struct iftable_cfg *icfg;
struct ifentry *ife;
char *ifname;
icfg = (struct iftable_cfg *)ta_state;
ifname = tent->k.iface;
if (strnlen(ifname, IF_NAMESIZE) == IF_NAMESIZE)
return (EINVAL);
ife = (struct ifentry *)ipfw_objhash_lookup_name(icfg->ii, 0, ifname);
if (ife != NULL) {
ta_dump_ifidx_tentry(ta_state, ti, ife, tent);
return (0);
}
return (ENOENT);
}
struct wa_ifidx {
ta_foreach_f *f;
void *arg;
};
static int
foreach_ifidx(struct namedobj_instance *ii, struct named_object *no,
void *arg)
{
struct ifentry *ife;
struct wa_ifidx *wa;
ife = (struct ifentry *)no;
wa = (struct wa_ifidx *)arg;
wa->f(ife, wa->arg);
return (0);
}
static void
ta_foreach_ifidx(void *ta_state, struct table_info *ti, ta_foreach_f *f,
void *arg)
{
struct iftable_cfg *icfg;
struct wa_ifidx wa;
icfg = (struct iftable_cfg *)ta_state;
wa.f = f;
wa.arg = arg;
ipfw_objhash_foreach(icfg->ii, foreach_ifidx, &wa);
}
struct table_algo iface_idx = {
.name = "iface:array",
.type = IPFW_TABLE_INTERFACE,
.flags = TA_FLAG_DEFAULT,
.ta_buf_size = sizeof(struct ta_buf_ifidx),
.init = ta_init_ifidx,
.destroy = ta_destroy_ifidx,
.prepare_add = ta_prepare_add_ifidx,
.prepare_del = ta_prepare_del_ifidx,
.add = ta_add_ifidx,
.del = ta_del_ifidx,
.flush_entry = ta_flush_ifidx_entry,
.foreach = ta_foreach_ifidx,
.dump_tentry = ta_dump_ifidx_tentry,
.find_tentry = ta_find_ifidx_tentry,
.dump_tinfo = ta_dump_ifidx_tinfo,
.need_modify = ta_need_modify_ifidx,
.prepare_mod = ta_prepare_mod_ifidx,
.fill_mod = ta_fill_mod_ifidx,
.modify = ta_modify_ifidx,
.flush_mod = ta_flush_mod_ifidx,
.change_ti = ta_change_ti_ifidx,
};
/*
* Number array cmds.
*
* Implementation:
*
* Runtime part:
* - sorted array of "struct numarray" pointed by ti->state.
* Array is allocated with rounding up to NUMARRAY_CHUNK.
* - current array size is stored in ti->data
*
*/
struct numarray {
uint32_t number;
uint32_t value;
};
struct numarray_cfg {
void *main_ptr;
size_t size; /* Number of items allocated in array */
size_t used; /* Number of items _active_ now */
};
struct ta_buf_numarray
{
struct numarray na;
};
int compare_numarray(const void *k, const void *v);
static struct numarray *numarray_find(struct table_info *ti, void *key);
static int ta_lookup_numarray(struct table_info *ti, void *key,
uint32_t keylen, uint32_t *val);
static int ta_init_numarray(struct ip_fw_chain *ch, void **ta_state,
struct table_info *ti, char *data, uint8_t tflags);
static void ta_destroy_numarray(void *ta_state, struct table_info *ti);
static void ta_dump_numarray_tinfo(void *ta_state, struct table_info *ti,
ipfw_ta_tinfo *tinfo);
static int ta_prepare_add_numarray(struct ip_fw_chain *ch,
struct tentry_info *tei, void *ta_buf);
static int ta_add_numarray(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static int ta_del_numarray(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static void ta_flush_numarray_entry(struct ip_fw_chain *ch,
struct tentry_info *tei, void *ta_buf);
static int ta_need_modify_numarray(void *ta_state, struct table_info *ti,
uint32_t count, uint64_t *pflags);
static int ta_prepare_mod_numarray(void *ta_buf, uint64_t *pflags);
static int ta_fill_mod_numarray(void *ta_state, struct table_info *ti,
void *ta_buf, uint64_t *pflags);
static void ta_modify_numarray(void *ta_state, struct table_info *ti,
void *ta_buf, uint64_t pflags);
static void ta_flush_mod_numarray(void *ta_buf);
static int ta_dump_numarray_tentry(void *ta_state, struct table_info *ti,
void *e, ipfw_obj_tentry *tent);
static int ta_find_numarray_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent);
static void ta_foreach_numarray(void *ta_state, struct table_info *ti,
ta_foreach_f *f, void *arg);
int
compare_numarray(const void *k, const void *v)
{
const struct numarray *na;
uint32_t key;
key = *((const uint32_t *)k);
na = (const struct numarray *)v;
if (key < na->number)
return (-1);
else if (key > na->number)
return (1);
return (0);
}
static struct numarray *
numarray_find(struct table_info *ti, void *key)
{
struct numarray *ri;
ri = bsearch(key, ti->state, ti->data, sizeof(struct numarray),
compare_ifidx);
return (ri);
}
static int
ta_lookup_numarray(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct numarray *ri;
ri = numarray_find(ti, key);
if (ri != NULL) {
*val = ri->value;
return (1);
}
return (0);
}
static int
ta_init_numarray(struct ip_fw_chain *ch, void **ta_state, struct table_info *ti,
char *data, uint8_t tflags)
{
struct numarray_cfg *cfg;
cfg = malloc(sizeof(*cfg), M_IPFW, M_WAITOK | M_ZERO);
cfg->size = 16;
cfg->main_ptr = malloc(sizeof(struct numarray) * cfg->size, M_IPFW,
M_WAITOK | M_ZERO);
*ta_state = cfg;
ti->state = cfg->main_ptr;
ti->lookup = ta_lookup_numarray;
return (0);
}
/*
* Destroys table @ti
*/
static void
ta_destroy_numarray(void *ta_state, struct table_info *ti)
{
struct numarray_cfg *cfg;
cfg = (struct numarray_cfg *)ta_state;
if (cfg->main_ptr != NULL)
free(cfg->main_ptr, M_IPFW);
free(cfg, M_IPFW);
}
/*
* Provide algo-specific table info
*/
static void
ta_dump_numarray_tinfo(void *ta_state, struct table_info *ti, ipfw_ta_tinfo *tinfo)
{
struct numarray_cfg *cfg;
cfg = (struct numarray_cfg *)ta_state;
tinfo->taclass4 = IPFW_TACLASS_ARRAY;
tinfo->size4 = cfg->size;
tinfo->count4 = cfg->used;
tinfo->itemsize4 = sizeof(struct numarray);
}
/*
* Prepare for addition/deletion to an array.
*/
static int
ta_prepare_add_numarray(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_numarray *tb;
tb = (struct ta_buf_numarray *)ta_buf;
tb->na.number = *((uint32_t *)tei->paddr);
return (0);
}
static int
ta_add_numarray(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct numarray_cfg *cfg;
struct ta_buf_numarray *tb;
struct numarray *ri;
int res;
uint32_t value;
tb = (struct ta_buf_numarray *)ta_buf;
cfg = (struct numarray_cfg *)ta_state;
/* Read current value from @tei */
tb->na.value = tei->value;
ri = numarray_find(ti, &tb->na.number);
if (ri != NULL) {
if ((tei->flags & TEI_FLAGS_UPDATE) == 0)
return (EEXIST);
/* Exchange values between ri and @tei */
value = ri->value;
ri->value = tei->value;
tei->value = value;
/* Indicate that update has happened instead of addition */
tei->flags |= TEI_FLAGS_UPDATED;
*pnum = 0;
return (0);
}
if ((tei->flags & TEI_FLAGS_DONTADD) != 0)
return (EFBIG);
res = badd(&tb->na.number, &tb->na, cfg->main_ptr, cfg->used,
sizeof(struct numarray), compare_numarray);
KASSERT(res == 1, ("number %d already exists", tb->na.number));
cfg->used++;
ti->data = cfg->used;
*pnum = 1;
return (0);
}
/*
* Remove key from both configuration list and
* runtime array. Removed interface notification.
*/
static int
ta_del_numarray(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct numarray_cfg *cfg;
struct ta_buf_numarray *tb;
struct numarray *ri;
int res;
tb = (struct ta_buf_numarray *)ta_buf;
cfg = (struct numarray_cfg *)ta_state;
ri = numarray_find(ti, &tb->na.number);
if (ri == NULL)
return (ENOENT);
tei->value = ri->value;
res = bdel(&tb->na.number, cfg->main_ptr, cfg->used,
sizeof(struct numarray), compare_numarray);
KASSERT(res == 1, ("number %u does not exist", tb->na.number));
cfg->used--;
ti->data = cfg->used;
*pnum = 1;
return (0);
}
static void
ta_flush_numarray_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
/* We don't have any state, do nothing */
}
/*
* Table growing callbacks.
*/
static int
ta_need_modify_numarray(void *ta_state, struct table_info *ti, uint32_t count,
uint64_t *pflags)
{
struct numarray_cfg *cfg;
size_t size;
cfg = (struct numarray_cfg *)ta_state;
size = cfg->size;
while (size < cfg->used + count)
size *= 2;
if (size != cfg->size) {
*pflags = size;
return (1);
}
return (0);
}
/*
* Allocate new, larger runtime array.
*/
static int
ta_prepare_mod_numarray(void *ta_buf, uint64_t *pflags)
{
struct mod_item *mi;
mi = (struct mod_item *)ta_buf;
memset(mi, 0, sizeof(struct mod_item));
mi->size = *pflags;
mi->main_ptr = malloc(sizeof(struct numarray) * mi->size, M_IPFW,
M_WAITOK | M_ZERO);
return (0);
}
/*
* Copy data from old runtime array to new one.
*/
static int
ta_fill_mod_numarray(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t *pflags)
{
struct mod_item *mi;
struct numarray_cfg *cfg;
mi = (struct mod_item *)ta_buf;
cfg = (struct numarray_cfg *)ta_state;
/* Check if we still need to grow array */
if (cfg->size >= mi->size) {
*pflags = 0;
return (0);
}
memcpy(mi->main_ptr, cfg->main_ptr, cfg->used * sizeof(struct numarray));
return (0);
}
/*
* Switch old & new arrays.
*/
static void
ta_modify_numarray(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags)
{
struct mod_item *mi;
struct numarray_cfg *cfg;
void *old_ptr;
mi = (struct mod_item *)ta_buf;
cfg = (struct numarray_cfg *)ta_state;
old_ptr = cfg->main_ptr;
cfg->main_ptr = mi->main_ptr;
cfg->size = mi->size;
ti->state = cfg->main_ptr;
mi->main_ptr = old_ptr;
}
/*
* Free unneded array.
*/
static void
ta_flush_mod_numarray(void *ta_buf)
{
struct mod_item *mi;
mi = (struct mod_item *)ta_buf;
if (mi->main_ptr != NULL)
free(mi->main_ptr, M_IPFW);
}
static int
ta_dump_numarray_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent)
{
struct numarray *na;
na = (struct numarray *)e;
tent->k.key = na->number;
tent->v.kidx = na->value;
return (0);
}
static int
ta_find_numarray_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent)
{
struct numarray_cfg *cfg;
struct numarray *ri;
cfg = (struct numarray_cfg *)ta_state;
ri = numarray_find(ti, &tent->k.key);
if (ri != NULL) {
ta_dump_numarray_tentry(ta_state, ti, ri, tent);
return (0);
}
return (ENOENT);
}
static void
ta_foreach_numarray(void *ta_state, struct table_info *ti, ta_foreach_f *f,
void *arg)
{
struct numarray_cfg *cfg;
struct numarray *array;
int i;
cfg = (struct numarray_cfg *)ta_state;
array = cfg->main_ptr;
for (i = 0; i < cfg->used; i++)
f(&array[i], arg);
}
struct table_algo number_array = {
.name = "number:array",
.type = IPFW_TABLE_NUMBER,
.ta_buf_size = sizeof(struct ta_buf_numarray),
.init = ta_init_numarray,
.destroy = ta_destroy_numarray,
.prepare_add = ta_prepare_add_numarray,
.prepare_del = ta_prepare_add_numarray,
.add = ta_add_numarray,
.del = ta_del_numarray,
.flush_entry = ta_flush_numarray_entry,
.foreach = ta_foreach_numarray,
.dump_tentry = ta_dump_numarray_tentry,
.find_tentry = ta_find_numarray_tentry,
.dump_tinfo = ta_dump_numarray_tinfo,
.need_modify = ta_need_modify_numarray,
.prepare_mod = ta_prepare_mod_numarray,
.fill_mod = ta_fill_mod_numarray,
.modify = ta_modify_numarray,
.flush_mod = ta_flush_mod_numarray,
};
/*
* flow:hash cmds
*
*
* ti->data:
* [inv.mask4][inv.mask6][log2hsize4][log2hsize6]
* [ 8][ 8[ 8][ 8]
*
* inv.mask4: 32 - mask
* inv.mask6:
* 1) _slow lookup: mask
* 2) _aligned: (128 - mask) / 8
* 3) _64: 8
*
*
* pflags:
* [hsize4][hsize6]
* [ 16][ 16]
*/
struct fhashentry;
SLIST_HEAD(fhashbhead, fhashentry);
struct fhashentry {
SLIST_ENTRY(fhashentry) next;
uint8_t af;
uint8_t proto;
uint16_t spare0;
uint16_t dport;
uint16_t sport;
uint32_t value;
uint32_t spare1;
};
struct fhashentry4 {
struct fhashentry e;
struct in_addr dip;
struct in_addr sip;
};
struct fhashentry6 {
struct fhashentry e;
struct in6_addr dip6;
struct in6_addr sip6;
};
struct fhash_cfg {
struct fhashbhead *head;
size_t size;
size_t items;
struct fhashentry4 fe4;
struct fhashentry6 fe6;
};
struct ta_buf_fhash {
void *ent_ptr;
struct fhashentry6 fe6;
};
static __inline int cmp_flow_ent(struct fhashentry *a,
struct fhashentry *b, size_t sz);
static __inline uint32_t hash_flow4(struct fhashentry4 *f, int hsize);
static __inline uint32_t hash_flow6(struct fhashentry6 *f, int hsize);
static uint32_t hash_flow_ent(struct fhashentry *ent, uint32_t size);
static int ta_lookup_fhash(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val);
static int ta_init_fhash(struct ip_fw_chain *ch, void **ta_state,
struct table_info *ti, char *data, uint8_t tflags);
static void ta_destroy_fhash(void *ta_state, struct table_info *ti);
static void ta_dump_fhash_tinfo(void *ta_state, struct table_info *ti,
ipfw_ta_tinfo *tinfo);
static int ta_dump_fhash_tentry(void *ta_state, struct table_info *ti,
void *e, ipfw_obj_tentry *tent);
static int tei_to_fhash_ent(struct tentry_info *tei, struct fhashentry *ent);
static int ta_find_fhash_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent);
static void ta_foreach_fhash(void *ta_state, struct table_info *ti,
ta_foreach_f *f, void *arg);
static int ta_prepare_add_fhash(struct ip_fw_chain *ch,
struct tentry_info *tei, void *ta_buf);
static int ta_add_fhash(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static int ta_prepare_del_fhash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_del_fhash(void *ta_state, struct table_info *ti,
struct tentry_info *tei, void *ta_buf, uint32_t *pnum);
static void ta_flush_fhash_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf);
static int ta_need_modify_fhash(void *ta_state, struct table_info *ti,
uint32_t count, uint64_t *pflags);
static int ta_prepare_mod_fhash(void *ta_buf, uint64_t *pflags);
static int ta_fill_mod_fhash(void *ta_state, struct table_info *ti,
void *ta_buf, uint64_t *pflags);
static void ta_modify_fhash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags);
static void ta_flush_mod_fhash(void *ta_buf);
static __inline int
cmp_flow_ent(struct fhashentry *a, struct fhashentry *b, size_t sz)
{
uint64_t *ka, *kb;
ka = (uint64_t *)(&a->next + 1);
kb = (uint64_t *)(&b->next + 1);
if (*ka == *kb && (memcmp(a + 1, b + 1, sz) == 0))
return (1);
return (0);
}
static __inline uint32_t
hash_flow4(struct fhashentry4 *f, int hsize)
{
uint32_t i;
i = (f->dip.s_addr) ^ (f->sip.s_addr) ^ (f->e.dport) ^ (f->e.sport);
return (i % (hsize - 1));
}
static __inline uint32_t
hash_flow6(struct fhashentry6 *f, int hsize)
{
uint32_t i;
i = (f->dip6.__u6_addr.__u6_addr32[2]) ^
(f->dip6.__u6_addr.__u6_addr32[3]) ^
(f->sip6.__u6_addr.__u6_addr32[2]) ^
(f->sip6.__u6_addr.__u6_addr32[3]) ^
(f->e.dport) ^ (f->e.sport);
return (i % (hsize - 1));
}
static uint32_t
hash_flow_ent(struct fhashentry *ent, uint32_t size)
{
uint32_t hash;
if (ent->af == AF_INET) {
hash = hash_flow4((struct fhashentry4 *)ent, size);
} else {
hash = hash_flow6((struct fhashentry6 *)ent, size);
}
return (hash);
}
static int
ta_lookup_fhash(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
struct fhashbhead *head;
struct fhashentry *ent;
struct fhashentry4 *m4;
struct ipfw_flow_id *id;
uint16_t hash, hsize;
id = (struct ipfw_flow_id *)key;
head = (struct fhashbhead *)ti->state;
hsize = ti->data;
m4 = (struct fhashentry4 *)ti->xstate;
if (id->addr_type == 4) {
struct fhashentry4 f;
/* Copy hash mask */
f = *m4;
f.dip.s_addr &= id->dst_ip;
f.sip.s_addr &= id->src_ip;
f.e.dport &= id->dst_port;
f.e.sport &= id->src_port;
f.e.proto &= id->proto;
hash = hash_flow4(&f, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
if (cmp_flow_ent(ent, &f.e, 2 * 4) != 0) {
*val = ent->value;
return (1);
}
}
} else if (id->addr_type == 6) {
struct fhashentry6 f;
uint64_t *fp, *idp;
/* Copy hash mask */
f = *((struct fhashentry6 *)(m4 + 1));
/* Handle lack of __u6_addr.__u6_addr64 */
fp = (uint64_t *)&f.dip6;
idp = (uint64_t *)&id->dst_ip6;
/* src IPv6 is stored after dst IPv6 */
*fp++ &= *idp++;
*fp++ &= *idp++;
*fp++ &= *idp++;
*fp &= *idp;
f.e.dport &= id->dst_port;
f.e.sport &= id->src_port;
f.e.proto &= id->proto;
hash = hash_flow6(&f, hsize);
SLIST_FOREACH(ent, &head[hash], next) {
if (cmp_flow_ent(ent, &f.e, 2 * 16) != 0) {
*val = ent->value;
return (1);
}
}
}
return (0);
}
/*
* New table.
*/
static int
ta_init_fhash(struct ip_fw_chain *ch, void **ta_state, struct table_info *ti,
char *data, uint8_t tflags)
{
struct fhash_cfg *cfg;
struct fhashentry4 *fe4;
struct fhashentry6 *fe6;
u_int i;
cfg = malloc(sizeof(struct fhash_cfg), M_IPFW, M_WAITOK | M_ZERO);
cfg->size = 512;
cfg->head = malloc(sizeof(struct fhashbhead) * cfg->size, M_IPFW,
M_WAITOK | M_ZERO);
for (i = 0; i < cfg->size; i++)
SLIST_INIT(&cfg->head[i]);
/* Fill in fe masks based on @tflags */
fe4 = &cfg->fe4;
fe6 = &cfg->fe6;
if (tflags & IPFW_TFFLAG_SRCIP) {
memset(&fe4->sip, 0xFF, sizeof(fe4->sip));
memset(&fe6->sip6, 0xFF, sizeof(fe6->sip6));
}
if (tflags & IPFW_TFFLAG_DSTIP) {
memset(&fe4->dip, 0xFF, sizeof(fe4->dip));
memset(&fe6->dip6, 0xFF, sizeof(fe6->dip6));
}
if (tflags & IPFW_TFFLAG_SRCPORT) {
memset(&fe4->e.sport, 0xFF, sizeof(fe4->e.sport));
memset(&fe6->e.sport, 0xFF, sizeof(fe6->e.sport));
}
if (tflags & IPFW_TFFLAG_DSTPORT) {
memset(&fe4->e.dport, 0xFF, sizeof(fe4->e.dport));
memset(&fe6->e.dport, 0xFF, sizeof(fe6->e.dport));
}
if (tflags & IPFW_TFFLAG_PROTO) {
memset(&fe4->e.proto, 0xFF, sizeof(fe4->e.proto));
memset(&fe6->e.proto, 0xFF, sizeof(fe6->e.proto));
}
fe4->e.af = AF_INET;
fe6->e.af = AF_INET6;
*ta_state = cfg;
ti->state = cfg->head;
ti->xstate = &cfg->fe4;
ti->data = cfg->size;
ti->lookup = ta_lookup_fhash;
return (0);
}
static void
ta_destroy_fhash(void *ta_state, struct table_info *ti)
{
struct fhash_cfg *cfg;
struct fhashentry *ent, *ent_next;
int i;
cfg = (struct fhash_cfg *)ta_state;
for (i = 0; i < cfg->size; i++)
SLIST_FOREACH_SAFE(ent, &cfg->head[i], next, ent_next)
free(ent, M_IPFW_TBL);
free(cfg->head, M_IPFW);
free(cfg, M_IPFW);
}
/*
* Provide algo-specific table info
*/
static void
ta_dump_fhash_tinfo(void *ta_state, struct table_info *ti, ipfw_ta_tinfo *tinfo)
{
struct fhash_cfg *cfg;
cfg = (struct fhash_cfg *)ta_state;
tinfo->flags = IPFW_TATFLAGS_AFITEM;
tinfo->taclass4 = IPFW_TACLASS_HASH;
tinfo->size4 = cfg->size;
tinfo->count4 = cfg->items;
tinfo->itemsize4 = sizeof(struct fhashentry4);
tinfo->itemsize6 = sizeof(struct fhashentry6);
}
static int
ta_dump_fhash_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent)
{
struct fhash_cfg *cfg;
struct fhashentry *ent;
struct fhashentry4 *fe4;
#ifdef INET6
struct fhashentry6 *fe6;
#endif
struct tflow_entry *tfe;
cfg = (struct fhash_cfg *)ta_state;
ent = (struct fhashentry *)e;
tfe = &tent->k.flow;
tfe->af = ent->af;
tfe->proto = ent->proto;
tfe->dport = htons(ent->dport);
tfe->sport = htons(ent->sport);
tent->v.kidx = ent->value;
tent->subtype = ent->af;
if (ent->af == AF_INET) {
fe4 = (struct fhashentry4 *)ent;
tfe->a.a4.sip.s_addr = htonl(fe4->sip.s_addr);
tfe->a.a4.dip.s_addr = htonl(fe4->dip.s_addr);
tent->masklen = 32;
#ifdef INET6
} else {
fe6 = (struct fhashentry6 *)ent;
tfe->a.a6.sip6 = fe6->sip6;
tfe->a.a6.dip6 = fe6->dip6;
tent->masklen = 128;
#endif
}
return (0);
}
static int
tei_to_fhash_ent(struct tentry_info *tei, struct fhashentry *ent)
{
#ifdef INET
struct fhashentry4 *fe4;
#endif
#ifdef INET6
struct fhashentry6 *fe6;
#endif
struct tflow_entry *tfe;
tfe = (struct tflow_entry *)tei->paddr;
ent->af = tei->subtype;
ent->proto = tfe->proto;
ent->dport = ntohs(tfe->dport);
ent->sport = ntohs(tfe->sport);
if (tei->subtype == AF_INET) {
#ifdef INET
fe4 = (struct fhashentry4 *)ent;
fe4->sip.s_addr = ntohl(tfe->a.a4.sip.s_addr);
fe4->dip.s_addr = ntohl(tfe->a.a4.dip.s_addr);
#endif
#ifdef INET6
} else if (tei->subtype == AF_INET6) {
fe6 = (struct fhashentry6 *)ent;
fe6->sip6 = tfe->a.a6.sip6;
fe6->dip6 = tfe->a.a6.dip6;
#endif
} else {
/* Unknown CIDR type */
return (EINVAL);
}
return (0);
}
static int
ta_find_fhash_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent)
{
struct fhash_cfg *cfg;
struct fhashbhead *head;
struct fhashentry *ent, *tmp;
struct fhashentry6 fe6;
struct tentry_info tei;
int error;
uint32_t hash;
size_t sz;
cfg = (struct fhash_cfg *)ta_state;
ent = &fe6.e;
memset(&fe6, 0, sizeof(fe6));
memset(&tei, 0, sizeof(tei));
tei.paddr = &tent->k.flow;
tei.subtype = tent->subtype;
if ((error = tei_to_fhash_ent(&tei, ent)) != 0)
return (error);
head = cfg->head;
hash = hash_flow_ent(ent, cfg->size);
if (tei.subtype == AF_INET)
sz = 2 * sizeof(struct in_addr);
else
sz = 2 * sizeof(struct in6_addr);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (cmp_flow_ent(tmp, ent, sz) != 0) {
ta_dump_fhash_tentry(ta_state, ti, tmp, tent);
return (0);
}
}
return (ENOENT);
}
static void
ta_foreach_fhash(void *ta_state, struct table_info *ti, ta_foreach_f *f,
void *arg)
{
struct fhash_cfg *cfg;
struct fhashentry *ent, *ent_next;
int i;
cfg = (struct fhash_cfg *)ta_state;
for (i = 0; i < cfg->size; i++)
SLIST_FOREACH_SAFE(ent, &cfg->head[i], next, ent_next)
f(ent, arg);
}
static int
ta_prepare_add_fhash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_fhash *tb;
struct fhashentry *ent;
size_t sz;
int error;
tb = (struct ta_buf_fhash *)ta_buf;
if (tei->subtype == AF_INET)
sz = sizeof(struct fhashentry4);
else if (tei->subtype == AF_INET6)
sz = sizeof(struct fhashentry6);
else
return (EINVAL);
ent = malloc(sz, M_IPFW_TBL, M_WAITOK | M_ZERO);
error = tei_to_fhash_ent(tei, ent);
if (error != 0) {
free(ent, M_IPFW_TBL);
return (error);
}
tb->ent_ptr = ent;
return (0);
}
static int
ta_add_fhash(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct fhash_cfg *cfg;
struct fhashbhead *head;
struct fhashentry *ent, *tmp;
struct ta_buf_fhash *tb;
int exists;
uint32_t hash, value;
size_t sz;
cfg = (struct fhash_cfg *)ta_state;
tb = (struct ta_buf_fhash *)ta_buf;
ent = (struct fhashentry *)tb->ent_ptr;
exists = 0;
/* Read current value from @tei */
ent->value = tei->value;
head = cfg->head;
hash = hash_flow_ent(ent, cfg->size);
if (tei->subtype == AF_INET)
sz = 2 * sizeof(struct in_addr);
else
sz = 2 * sizeof(struct in6_addr);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (cmp_flow_ent(tmp, ent, sz) != 0) {
exists = 1;
break;
}
}
if (exists == 1) {
if ((tei->flags & TEI_FLAGS_UPDATE) == 0)
return (EEXIST);
/* Record already exists. Update value if we're asked to */
/* Exchange values between tmp and @tei */
value = tmp->value;
tmp->value = tei->value;
tei->value = value;
/* Indicate that update has happened instead of addition */
tei->flags |= TEI_FLAGS_UPDATED;
*pnum = 0;
} else {
if ((tei->flags & TEI_FLAGS_DONTADD) != 0)
return (EFBIG);
SLIST_INSERT_HEAD(&head[hash], ent, next);
tb->ent_ptr = NULL;
*pnum = 1;
/* Update counters and check if we need to grow hash */
cfg->items++;
}
return (0);
}
static int
ta_prepare_del_fhash(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_fhash *tb;
tb = (struct ta_buf_fhash *)ta_buf;
return (tei_to_fhash_ent(tei, &tb->fe6.e));
}
static int
ta_del_fhash(void *ta_state, struct table_info *ti, struct tentry_info *tei,
void *ta_buf, uint32_t *pnum)
{
struct fhash_cfg *cfg;
struct fhashbhead *head;
struct fhashentry *ent, *tmp;
struct ta_buf_fhash *tb;
uint32_t hash;
size_t sz;
cfg = (struct fhash_cfg *)ta_state;
tb = (struct ta_buf_fhash *)ta_buf;
ent = &tb->fe6.e;
head = cfg->head;
hash = hash_flow_ent(ent, cfg->size);
if (tei->subtype == AF_INET)
sz = 2 * sizeof(struct in_addr);
else
sz = 2 * sizeof(struct in6_addr);
/* Check for existence */
SLIST_FOREACH(tmp, &head[hash], next) {
if (cmp_flow_ent(tmp, ent, sz) == 0)
continue;
SLIST_REMOVE(&head[hash], tmp, fhashentry, next);
tei->value = tmp->value;
*pnum = 1;
cfg->items--;
tb->ent_ptr = tmp;
return (0);
}
return (ENOENT);
}
static void
ta_flush_fhash_entry(struct ip_fw_chain *ch, struct tentry_info *tei,
void *ta_buf)
{
struct ta_buf_fhash *tb;
tb = (struct ta_buf_fhash *)ta_buf;
if (tb->ent_ptr != NULL)
free(tb->ent_ptr, M_IPFW_TBL);
}
/*
* Hash growing callbacks.
*/
static int
ta_need_modify_fhash(void *ta_state, struct table_info *ti, uint32_t count,
uint64_t *pflags)
{
struct fhash_cfg *cfg;
cfg = (struct fhash_cfg *)ta_state;
if (cfg->items > cfg->size && cfg->size < 65536) {
*pflags = cfg->size * 2;
return (1);
}
return (0);
}
/*
* Allocate new, larger fhash.
*/
static int
ta_prepare_mod_fhash(void *ta_buf, uint64_t *pflags)
{
struct mod_item *mi;
struct fhashbhead *head;
u_int i;
mi = (struct mod_item *)ta_buf;
memset(mi, 0, sizeof(struct mod_item));
mi->size = *pflags;
head = malloc(sizeof(struct fhashbhead) * mi->size, M_IPFW,
M_WAITOK | M_ZERO);
for (i = 0; i < mi->size; i++)
SLIST_INIT(&head[i]);
mi->main_ptr = head;
return (0);
}
/*
* Copy data from old runtime array to new one.
*/
static int
ta_fill_mod_fhash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t *pflags)
{
/* In is not possible to do rehash if we're not holidng WLOCK. */
return (0);
}
/*
* Switch old & new arrays.
*/
static void
ta_modify_fhash(void *ta_state, struct table_info *ti, void *ta_buf,
uint64_t pflags)
{
struct mod_item *mi;
struct fhash_cfg *cfg;
struct fhashbhead *old_head, *new_head;
struct fhashentry *ent, *ent_next;
int i;
uint32_t nhash;
size_t old_size;
mi = (struct mod_item *)ta_buf;
cfg = (struct fhash_cfg *)ta_state;
old_size = cfg->size;
old_head = ti->state;
new_head = (struct fhashbhead *)mi->main_ptr;
for (i = 0; i < old_size; i++) {
SLIST_FOREACH_SAFE(ent, &old_head[i], next, ent_next) {
nhash = hash_flow_ent(ent, mi->size);
SLIST_INSERT_HEAD(&new_head[nhash], ent, next);
}
}
ti->state = new_head;
ti->data = mi->size;
cfg->head = new_head;
cfg->size = mi->size;
mi->main_ptr = old_head;
}
/*
* Free unneded array.
*/
static void
ta_flush_mod_fhash(void *ta_buf)
{
struct mod_item *mi;
mi = (struct mod_item *)ta_buf;
if (mi->main_ptr != NULL)
free(mi->main_ptr, M_IPFW);
}
struct table_algo flow_hash = {
.name = "flow:hash",
.type = IPFW_TABLE_FLOW,
.flags = TA_FLAG_DEFAULT,
.ta_buf_size = sizeof(struct ta_buf_fhash),
.init = ta_init_fhash,
.destroy = ta_destroy_fhash,
.prepare_add = ta_prepare_add_fhash,
.prepare_del = ta_prepare_del_fhash,
.add = ta_add_fhash,
.del = ta_del_fhash,
.flush_entry = ta_flush_fhash_entry,
.foreach = ta_foreach_fhash,
.dump_tentry = ta_dump_fhash_tentry,
.find_tentry = ta_find_fhash_tentry,
.dump_tinfo = ta_dump_fhash_tinfo,
.need_modify = ta_need_modify_fhash,
.prepare_mod = ta_prepare_mod_fhash,
.fill_mod = ta_fill_mod_fhash,
.modify = ta_modify_fhash,
.flush_mod = ta_flush_mod_fhash,
};
/*
* Kernel fibs bindings.
*
* Implementation:
*
* Runtime part:
* - fully relies on route API
* - fib number is stored in ti->data
*
*/
static int ta_lookup_kfib(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val);
static int kfib_parse_opts(int *pfib, char *data);
static void ta_print_kfib_config(void *ta_state, struct table_info *ti,
char *buf, size_t bufsize);
static int ta_init_kfib(struct ip_fw_chain *ch, void **ta_state,
struct table_info *ti, char *data, uint8_t tflags);
static void ta_destroy_kfib(void *ta_state, struct table_info *ti);
static void ta_dump_kfib_tinfo(void *ta_state, struct table_info *ti,
ipfw_ta_tinfo *tinfo);
static int contigmask(uint8_t *p, int len);
static int ta_dump_kfib_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent);
static int ta_dump_kfib_tentry_int(struct sockaddr *paddr,
struct sockaddr *pmask, ipfw_obj_tentry *tent);
static int ta_find_kfib_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent);
static void ta_foreach_kfib(void *ta_state, struct table_info *ti,
ta_foreach_f *f, void *arg);
static int
ta_lookup_kfib(struct table_info *ti, void *key, uint32_t keylen,
uint32_t *val)
{
#ifdef INET
struct nhop4_basic nh4;
struct in_addr in;
#endif
#ifdef INET6
struct nhop6_basic nh6;
#endif
int error;
error = ENOENT;
#ifdef INET
if (keylen == 4) {
in.s_addr = *(in_addr_t *)key;
error = fib4_lookup_nh_basic(ti->data,
in, 0, 0, &nh4);
}
#endif
#ifdef INET6
if (keylen == 6)
error = fib6_lookup_nh_basic(ti->data,
(struct in6_addr *)key, 0, 0, 0, &nh6);
#endif
if (error != 0)
return (0);
*val = 0;
return (1);
}
/* Parse 'fib=%d' */
static int
kfib_parse_opts(int *pfib, char *data)
{
char *pdel, *pend, *s;
int fibnum;
if (data == NULL)
return (0);
if ((pdel = strchr(data, ' ')) == NULL)
return (0);
while (*pdel == ' ')
pdel++;
if (strncmp(pdel, "fib=", 4) != 0)
return (EINVAL);
if ((s = strchr(pdel, ' ')) != NULL)
*s++ = '\0';
pdel += 4;
/* Need \d+ */
fibnum = strtol(pdel, &pend, 10);
if (*pend != '\0')
return (EINVAL);
*pfib = fibnum;
return (0);
}
static void
ta_print_kfib_config(void *ta_state, struct table_info *ti, char *buf,
size_t bufsize)
{
if (ti->data != 0)
snprintf(buf, bufsize, "%s fib=%lu", "addr:kfib", ti->data);
else
snprintf(buf, bufsize, "%s", "addr:kfib");
}
static int
ta_init_kfib(struct ip_fw_chain *ch, void **ta_state, struct table_info *ti,
char *data, uint8_t tflags)
{
int error, fibnum;
fibnum = 0;
if ((error = kfib_parse_opts(&fibnum, data)) != 0)
return (error);
if (fibnum >= rt_numfibs)
return (E2BIG);
ti->data = fibnum;
ti->lookup = ta_lookup_kfib;
return (0);
}
/*
* Destroys table @ti
*/
static void
ta_destroy_kfib(void *ta_state, struct table_info *ti)
{
}
/*
* Provide algo-specific table info
*/
static void
ta_dump_kfib_tinfo(void *ta_state, struct table_info *ti, ipfw_ta_tinfo *tinfo)
{
tinfo->flags = IPFW_TATFLAGS_AFDATA;
tinfo->taclass4 = IPFW_TACLASS_RADIX;
tinfo->count4 = 0;
tinfo->itemsize4 = sizeof(struct rtentry);
tinfo->taclass6 = IPFW_TACLASS_RADIX;
tinfo->count6 = 0;
tinfo->itemsize6 = sizeof(struct rtentry);
}
static int
contigmask(uint8_t *p, int len)
{
int i, n;
for (i = 0; i < len ; i++)
if ( (p[i/8] & (1 << (7 - (i%8)))) == 0) /* first bit unset */
break;
for (n= i + 1; n < len; n++)
if ( (p[n/8] & (1 << (7 - (n % 8)))) != 0)
return (-1); /* mask not contiguous */
return (i);
}
static int
ta_dump_kfib_tentry(void *ta_state, struct table_info *ti, void *e,
ipfw_obj_tentry *tent)
{
struct rtentry *rte;
rte = (struct rtentry *)e;
return ta_dump_kfib_tentry_int(rt_key(rte), rt_mask(rte), tent);
}
static int
ta_dump_kfib_tentry_int(struct sockaddr *paddr, struct sockaddr *pmask,
ipfw_obj_tentry *tent)
{
#ifdef INET
struct sockaddr_in *addr, *mask;
#endif
#ifdef INET6
struct sockaddr_in6 *addr6, *mask6;
#endif
int len;
len = 0;
/* Guess IPv4/IPv6 radix by sockaddr family */
#ifdef INET
if (paddr->sa_family == AF_INET) {
addr = (struct sockaddr_in *)paddr;
mask = (struct sockaddr_in *)pmask;
tent->k.addr.s_addr = addr->sin_addr.s_addr;
len = 32;
if (mask != NULL)
len = contigmask((uint8_t *)&mask->sin_addr, 32);
if (len == -1)
len = 0;
tent->masklen = len;
tent->subtype = AF_INET;
tent->v.kidx = 0; /* Do we need to put GW here? */
}
#endif
#ifdef INET6
if (paddr->sa_family == AF_INET6) {
addr6 = (struct sockaddr_in6 *)paddr;
mask6 = (struct sockaddr_in6 *)pmask;
memcpy(&tent->k.addr6, &addr6->sin6_addr,
sizeof(struct in6_addr));
len = 128;
if (mask6 != NULL)
len = contigmask((uint8_t *)&mask6->sin6_addr, 128);
if (len == -1)
len = 0;
tent->masklen = len;
tent->subtype = AF_INET6;
tent->v.kidx = 0;
}
#endif
return (0);
}
static int
ta_find_kfib_tentry(void *ta_state, struct table_info *ti,
ipfw_obj_tentry *tent)
{
struct rt_addrinfo info;
struct sockaddr_in6 key6, dst6, mask6;
struct sockaddr *dst, *key, *mask;
/* Prepare sockaddr for prefix/mask and info */
bzero(&dst6, sizeof(dst6));
dst6.sin6_len = sizeof(dst6);
dst = (struct sockaddr *)&dst6;
bzero(&mask6, sizeof(mask6));
mask6.sin6_len = sizeof(mask6);
mask = (struct sockaddr *)&mask6;
bzero(&info, sizeof(info));
info.rti_info[RTAX_DST] = dst;
info.rti_info[RTAX_NETMASK] = mask;
/* Prepare the lookup key */
bzero(&key6, sizeof(key6));
key6.sin6_family = tent->subtype;
key = (struct sockaddr *)&key6;
if (tent->subtype == AF_INET) {
((struct sockaddr_in *)&key6)->sin_addr = tent->k.addr;
key6.sin6_len = sizeof(struct sockaddr_in);
} else {
key6.sin6_addr = tent->k.addr6;
key6.sin6_len = sizeof(struct sockaddr_in6);
}
if (rib_lookup_info(ti->data, key, 0, 0, &info) != 0)
return (ENOENT);
if ((info.rti_addrs & RTA_NETMASK) == 0)
mask = NULL;
ta_dump_kfib_tentry_int(dst, mask, tent);
return (0);
}
static void
ta_foreach_kfib(void *ta_state, struct table_info *ti, ta_foreach_f *f,
void *arg)
{
RIB_RLOCK_TRACKER;
struct rib_head *rh;
int error;
rh = rt_tables_get_rnh(ti->data, AF_INET);
if (rh != NULL) {
RIB_RLOCK(rh);
error = rh->rnh_walktree(&rh->head, (walktree_f_t *)f, arg);
RIB_RUNLOCK(rh);
}
rh = rt_tables_get_rnh(ti->data, AF_INET6);
if (rh != NULL) {
RIB_RLOCK(rh);
error = rh->rnh_walktree(&rh->head, (walktree_f_t *)f, arg);
RIB_RUNLOCK(rh);
}
}
struct table_algo addr_kfib = {
.name = "addr:kfib",
.type = IPFW_TABLE_ADDR,
.flags = TA_FLAG_READONLY,
.ta_buf_size = 0,
.init = ta_init_kfib,
.destroy = ta_destroy_kfib,
.foreach = ta_foreach_kfib,
.dump_tentry = ta_dump_kfib_tentry,
.find_tentry = ta_find_kfib_tentry,
.dump_tinfo = ta_dump_kfib_tinfo,
.print_config = ta_print_kfib_config,
};
void
ipfw_table_algo_init(struct ip_fw_chain *ch)
{
size_t sz;
/*
* Register all algorithms presented here.
*/
sz = sizeof(struct table_algo);
ipfw_add_table_algo(ch, &addr_radix, sz, &addr_radix.idx);
ipfw_add_table_algo(ch, &addr_hash, sz, &addr_hash.idx);
ipfw_add_table_algo(ch, &iface_idx, sz, &iface_idx.idx);
ipfw_add_table_algo(ch, &number_array, sz, &number_array.idx);
ipfw_add_table_algo(ch, &flow_hash, sz, &flow_hash.idx);
ipfw_add_table_algo(ch, &addr_kfib, sz, &addr_kfib.idx);
}
void
ipfw_table_algo_destroy(struct ip_fw_chain *ch)
{
ipfw_del_table_algo(ch, addr_radix.idx);
ipfw_del_table_algo(ch, addr_hash.idx);
ipfw_del_table_algo(ch, iface_idx.idx);
ipfw_del_table_algo(ch, number_array.idx);
ipfw_del_table_algo(ch, flow_hash.idx);
ipfw_del_table_algo(ch, addr_kfib.idx);
}
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