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[FreeBSD/FreeBSD.git] / sys / netinet / ip_fw.h

/*-
 * Copyright (c) 2002 Luigi Rizzo, Universita` di Pisa
 *
 * 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.
 *
 * $FreeBSD$
 */

#ifndef _IPFW2_H
#define _IPFW2_H

/*
 * The kernel representation of ipfw rules is made of a list of
 * 'instructions' (for all practical purposes equivalent to BPF
 * instructions), which specify which fields of the packet
 * (or its metadata) should be analysed.
 *
 * Each instruction is stored in a structure which begins with
 * "ipfw_insn", and can contain extra fields depending on the
 * instruction type (listed below).
 * Note that the code is written so that individual instructions
 * have a size which is a multiple of 32 bits. This means that, if
 * such structures contain pointers or other 64-bit entities,
 * (there is just one instance now) they may end up unaligned on
 * 64-bit architectures, so the must be handled with care.
 *
 * "enum ipfw_opcodes" are the opcodes supported. We can have up
 * to 256 different opcodes. When adding new opcodes, they should
 * be appended to the end of the opcode list before O_LAST_OPCODE,
 * this will prevent the ABI from being broken, otherwise users
 * will have to recompile ipfw(8) when they update the kernel.
 */

enum ipfw_opcodes {             /* arguments (4 byte each)      */
        O_NOP,

        O_IP_SRC,               /* u32 = IP                     */
        O_IP_SRC_MASK,          /* ip = IP/mask                 */
        O_IP_SRC_ME,            /* none                         */
        O_IP_SRC_SET,           /* u32=base, arg1=len, bitmap   */

        O_IP_DST,               /* u32 = IP                     */
        O_IP_DST_MASK,          /* ip = IP/mask                 */
        O_IP_DST_ME,            /* none                         */
        O_IP_DST_SET,           /* u32=base, arg1=len, bitmap   */

        O_IP_SRCPORT,           /* (n)port list:mask 4 byte ea  */
        O_IP_DSTPORT,           /* (n)port list:mask 4 byte ea  */
        O_PROTO,                /* arg1=protocol                */

        O_MACADDR2,             /* 2 mac addr:mask              */
        O_MAC_TYPE,             /* same as srcport              */

        O_LAYER2,               /* none                         */
        O_IN,                   /* none                         */
        O_FRAG,                 /* none                         */

        O_RECV,                 /* none                         */
        O_XMIT,                 /* none                         */
        O_VIA,                  /* none                         */

        O_IPOPT,                /* arg1 = 2*u8 bitmap           */
        O_IPLEN,                /* arg1 = len                   */
        O_IPID,                 /* arg1 = id                    */

        O_IPTOS,                /* arg1 = id                    */
        O_IPPRECEDENCE,         /* arg1 = precedence << 5       */
        O_IPTTL,                /* arg1 = TTL                   */

        O_IPVER,                /* arg1 = version               */
        O_UID,                  /* u32 = id                     */
        O_GID,                  /* u32 = id                     */
        O_ESTAB,                /* none (tcp established)       */
        O_TCPFLAGS,             /* arg1 = 2*u8 bitmap           */
        O_TCPWIN,               /* arg1 = desired win           */
        O_TCPSEQ,               /* u32 = desired seq.           */
        O_TCPACK,               /* u32 = desired seq.           */
        O_ICMPTYPE,             /* u32 = icmp bitmap            */
        O_TCPOPTS,              /* arg1 = 2*u8 bitmap           */

        O_VERREVPATH,           /* none                         */
        O_VERSRCREACH,          /* none                         */

        O_PROBE_STATE,          /* none                         */
        O_KEEP_STATE,           /* none                         */
        O_LIMIT,                /* ipfw_insn_limit              */
        O_LIMIT_PARENT,         /* dyn_type, not an opcode.     */

        /*
         * These are really 'actions'.
         */

        O_LOG,                  /* ipfw_insn_log                */
        O_PROB,                 /* u32 = match probability      */

        O_CHECK_STATE,          /* none                         */
        O_ACCEPT,               /* none                         */
        O_DENY,                 /* none                         */
        O_REJECT,               /* arg1=icmp arg (same as deny) */
        O_COUNT,                /* none                         */
        O_SKIPTO,               /* arg1=next rule number        */
        O_PIPE,                 /* arg1=pipe number             */
        O_QUEUE,                /* arg1=queue number            */
        O_DIVERT,               /* arg1=port number             */
        O_TEE,                  /* arg1=port number             */
        O_FORWARD_IP,           /* fwd sockaddr                 */
        O_FORWARD_MAC,          /* fwd mac                      */
        O_NAT,                  /* nope                         */

        /*
         * More opcodes.
         */
        O_IPSEC,                /* has ipsec history            */
        O_IP_SRC_LOOKUP,        /* arg1=table number, u32=value */
        O_IP_DST_LOOKUP,        /* arg1=table number, u32=value */
        O_ANTISPOOF,            /* none                         */
        O_JAIL,                 /* u32 = id                     */
        O_ALTQ,                 /* u32 = altq classif. qid      */
        O_DIVERTED,             /* arg1=bitmap (1:loop, 2:out)  */
        O_TCPDATALEN,           /* arg1 = tcp data len          */
        O_IP6_SRC,              /* address without mask         */
        O_IP6_SRC_ME,           /* my addresses                 */
        O_IP6_SRC_MASK,         /* address with the mask        */
        O_IP6_DST,
        O_IP6_DST_ME,
        O_IP6_DST_MASK,
        O_FLOW6ID,              /* for flow id tag in the ipv6 pkt */
        O_ICMP6TYPE,            /* icmp6 packet type filtering  */
        O_EXT_HDR,              /* filtering for ipv6 extension header */
        O_IP6,

        /*
         * actions for ng_ipfw
         */
        O_NETGRAPH,             /* send to ng_ipfw              */
        O_NGTEE,                /* copy to ng_ipfw              */

        O_IP4,

        O_UNREACH6,             /* arg1=icmpv6 code arg (deny)  */

        O_TAG,                  /* arg1=tag number */
        O_TAGGED,               /* arg1=tag number */

        O_LAST_OPCODE           /* not an opcode!               */
};

/*
 * The extension header are filtered only for presence using a bit
 * vector with a flag for each header.
 */
#define EXT_FRAGMENT    0x1
#define EXT_HOPOPTS     0x2
#define EXT_ROUTING     0x4
#define EXT_AH          0x8
#define EXT_ESP         0x10
#define EXT_DSTOPTS     0x20
#define EXT_RTHDR0              0x40
#define EXT_RTHDR2              0x80

/*
 * Template for instructions.
 *
 * ipfw_insn is used for all instructions which require no operands,
 * a single 16-bit value (arg1), or a couple of 8-bit values.
 *
 * For other instructions which require different/larger arguments
 * we have derived structures, ipfw_insn_*.
 *
 * The size of the instruction (in 32-bit words) is in the low
 * 6 bits of "len". The 2 remaining bits are used to implement
 * NOT and OR on individual instructions. Given a type, you can
 * compute the length to be put in "len" using F_INSN_SIZE(t)
 *
 * F_NOT        negates the match result of the instruction.
 *
 * F_OR         is used to build or blocks. By default, instructions
 *              are evaluated as part of a logical AND. An "or" block
 *              { X or Y or Z } contains F_OR set in all but the last
 *              instruction of the block. A match will cause the code
 *              to skip past the last instruction of the block.
 *
 * NOTA BENE: in a couple of places we assume that
 *      sizeof(ipfw_insn) == sizeof(u_int32_t)
 * this needs to be fixed.
 *
 */
typedef struct  _ipfw_insn {    /* template for instructions */
        enum ipfw_opcodes       opcode:8;
        u_int8_t        len;    /* numer of 32-byte words */
#define F_NOT           0x80
#define F_OR            0x40
#define F_LEN_MASK      0x3f
#define F_LEN(cmd)      ((cmd)->len & F_LEN_MASK)

        u_int16_t       arg1;
} ipfw_insn;

/*
 * The F_INSN_SIZE(type) computes the size, in 4-byte words, of
 * a given type.
 */
#define F_INSN_SIZE(t)  ((sizeof (t))/sizeof(u_int32_t))

#define MTAG_IPFW       1148380143      /* IPFW-tagged cookie */

/*
 * This is used to store an array of 16-bit entries (ports etc.)
 */
typedef struct  _ipfw_insn_u16 {
        ipfw_insn o;
        u_int16_t ports[2];     /* there may be more */
} ipfw_insn_u16;

/*
 * This is used to store an array of 32-bit entries
 * (uid, single IPv4 addresses etc.)
 */
typedef struct  _ipfw_insn_u32 {
        ipfw_insn o;
        u_int32_t d[1]; /* one or more */
} ipfw_insn_u32;

/*
 * This is used to store IP addr-mask pairs.
 */
typedef struct  _ipfw_insn_ip {
        ipfw_insn o;
        struct in_addr  addr;
        struct in_addr  mask;
} ipfw_insn_ip;

/*
 * This is used to forward to a given address (ip).
 */
typedef struct  _ipfw_insn_sa {
        ipfw_insn o;
        struct sockaddr_in sa;
} ipfw_insn_sa;

/*
 * This is used for MAC addr-mask pairs.
 */
typedef struct  _ipfw_insn_mac {
        ipfw_insn o;
        u_char addr[12];        /* dst[6] + src[6] */
        u_char mask[12];        /* dst[6] + src[6] */
} ipfw_insn_mac;

/*
 * This is used for interface match rules (recv xx, xmit xx).
 */
typedef struct  _ipfw_insn_if {
        ipfw_insn o;
        union {
                struct in_addr ip;
                int glob;
        } p;
        char name[IFNAMSIZ];
} ipfw_insn_if;

/*
 * This is used for storing an altq queue id number.
 */
typedef struct _ipfw_insn_altq {
        ipfw_insn       o;
        u_int32_t       qid;
} ipfw_insn_altq;

/*
 * This is used for limit rules.
 */
typedef struct  _ipfw_insn_limit {
        ipfw_insn o;
        u_int8_t _pad;
        u_int8_t limit_mask;    /* combination of DYN_* below   */
#define DYN_SRC_ADDR    0x1
#define DYN_SRC_PORT    0x2
#define DYN_DST_ADDR    0x4
#define DYN_DST_PORT    0x8

        u_int16_t conn_limit;
} ipfw_insn_limit;

/*
 * This is used for log instructions.
 */
typedef struct  _ipfw_insn_log {
        ipfw_insn o;
        u_int32_t max_log;      /* how many do we log -- 0 = all */
        u_int32_t log_left;     /* how many left to log         */
} ipfw_insn_log;

/* Server pool support (LSNAT). */
struct cfg_spool {
        LIST_ENTRY(cfg_spool)   _next;          /* chain of spool instances */
        struct in_addr          addr;
        u_short                 port;
};

/* Redirect modes id. */
#define REDIR_ADDR      0x01
#define REDIR_PORT      0x02
#define REDIR_PROTO     0x04

/* Nat redirect configuration. */
struct cfg_redir {
        LIST_ENTRY(cfg_redir)   _next;          /* chain of redir instances */
        u_int16_t               mode;           /* type of redirect mode */
        struct in_addr          laddr;          /* local ip address */
        struct in_addr          paddr;          /* public ip address */
        struct in_addr          raddr;          /* remote ip address */
        u_short                 lport;          /* local port */
        u_short                 pport;          /* public port */
        u_short                 rport;          /* remote port  */
        u_short                 pport_cnt;      /* number of public ports */
        u_short                 rport_cnt;      /* number of remote ports */
        int                     proto;          /* protocol: tcp/udp */
        struct alias_link       **alink;        
        /* num of entry in spool chain */
        u_int16_t               spool_cnt;      
        /* chain of spool instances */
        LIST_HEAD(spool_chain, cfg_spool) spool_chain;
};

#define NAT_BUF_LEN     1024
/* Nat configuration data struct. */
struct cfg_nat {
        /* chain of nat instances */
        LIST_ENTRY(cfg_nat)     _next;
        int                     id;                     /* nat id */
        struct in_addr          ip;                     /* nat ip address */
        char                    if_name[IF_NAMESIZE];   /* interface name */
        int                     mode;                   /* aliasing mode */
        struct libalias         *lib;                   /* libalias instance */
        /* number of entry in spool chain */
        int                     redir_cnt;              
        /* chain of redir instances */
        LIST_HEAD(redir_chain, cfg_redir) redir_chain;  
};

#define SOF_NAT         sizeof(struct cfg_nat)
#define SOF_REDIR       sizeof(struct cfg_redir)
#define SOF_SPOOL       sizeof(struct cfg_spool)

/* Nat command. */
typedef struct  _ipfw_insn_nat {
        ipfw_insn       o;
        struct cfg_nat *nat;    
} ipfw_insn_nat;

/* Apply ipv6 mask on ipv6 addr */
#define APPLY_MASK(addr,mask)                          \
    (addr)->__u6_addr.__u6_addr32[0] &= (mask)->__u6_addr.__u6_addr32[0]; \
    (addr)->__u6_addr.__u6_addr32[1] &= (mask)->__u6_addr.__u6_addr32[1]; \
    (addr)->__u6_addr.__u6_addr32[2] &= (mask)->__u6_addr.__u6_addr32[2]; \
    (addr)->__u6_addr.__u6_addr32[3] &= (mask)->__u6_addr.__u6_addr32[3];

/* Structure for ipv6 */
typedef struct _ipfw_insn_ip6 {
       ipfw_insn o;
       struct in6_addr addr6;
       struct in6_addr mask6;
} ipfw_insn_ip6;

/* Used to support icmp6 types */
typedef struct _ipfw_insn_icmp6 {
       ipfw_insn o;
       uint32_t d[7]; /* XXX This number si related to the netinet/icmp6.h
                       *     define ICMP6_MAXTYPE
                       *     as follows: n = ICMP6_MAXTYPE/32 + 1
                        *     Actually is 203 
                       */
} ipfw_insn_icmp6;

/*
 * Here we have the structure representing an ipfw rule.
 *
 * It starts with a general area (with link fields and counters)
 * followed by an array of one or more instructions, which the code
 * accesses as an array of 32-bit values.
 *
 * Given a rule pointer  r:
 *
 *  r->cmd              is the start of the first instruction.
 *  ACTION_PTR(r)       is the start of the first action (things to do
 *                      once a rule matched).
 *
 * When assembling instruction, remember the following:
 *
 *  + if a rule has a "keep-state" (or "limit") option, then the
 *      first instruction (at r->cmd) MUST BE an O_PROBE_STATE
 *  + if a rule has a "log" option, then the first action
 *      (at ACTION_PTR(r)) MUST be O_LOG
 *  + if a rule has an "altq" option, it comes after "log"
 *  + if a rule has an O_TAG option, it comes after "log" and "altq"
 *
 * NOTE: we use a simple linked list of rules because we never need
 *      to delete a rule without scanning the list. We do not use
 *      queue(3) macros for portability and readability.
 */

struct ip_fw {
        struct ip_fw    *next;          /* linked list of rules         */
        struct ip_fw    *next_rule;     /* ptr to next [skipto] rule    */
        /* 'next_rule' is used to pass up 'set_disable' status          */

        u_int16_t       act_ofs;        /* offset of action in 32-bit units */
        u_int16_t       cmd_len;        /* # of 32-bit words in cmd     */
        u_int16_t       rulenum;        /* rule number                  */
        u_int8_t        set;            /* rule set (0..31)             */
#define RESVD_SET       31      /* set for default and persistent rules */
        u_int8_t        _pad;           /* padding                      */

        /* These fields are present in all rules.                       */
        u_int64_t       pcnt;           /* Packet counter               */
        u_int64_t       bcnt;           /* Byte counter                 */
        u_int32_t       timestamp;      /* tv_sec of last match         */

        ipfw_insn       cmd[1];         /* storage for commands         */
};

#define ACTION_PTR(rule)                                \
        (ipfw_insn *)( (u_int32_t *)((rule)->cmd) + ((rule)->act_ofs) )

#define RULESIZE(rule)  (sizeof(struct ip_fw) + \
        ((struct ip_fw *)(rule))->cmd_len * 4 - 4)

/*
 * This structure is used as a flow mask and a flow id for various
 * parts of the code.
 */
struct ipfw_flow_id {
        u_int32_t       dst_ip;
        u_int32_t       src_ip;
        u_int16_t       dst_port;
        u_int16_t       src_port;
        u_int8_t        proto;
        u_int8_t        flags;  /* protocol-specific flags */
        uint8_t         addr_type; /* 4 = ipv4, 6 = ipv6, 1=ether ? */
        struct in6_addr dst_ip6;        /* could also store MAC addr! */
        struct in6_addr src_ip6;
        u_int32_t       flow_id6;
        u_int32_t       frag_id6;
};

#define IS_IP6_FLOW_ID(id)      ((id)->addr_type == 6)

/*
 * Dynamic ipfw rule.
 */
typedef struct _ipfw_dyn_rule ipfw_dyn_rule;

struct _ipfw_dyn_rule {
        ipfw_dyn_rule   *next;          /* linked list of rules.        */
        struct ip_fw *rule;             /* pointer to rule              */
        /* 'rule' is used to pass up the rule number (from the parent)  */

        ipfw_dyn_rule *parent;          /* pointer to parent rule       */
        u_int64_t       pcnt;           /* packet match counter         */
        u_int64_t       bcnt;           /* byte match counter           */
        struct ipfw_flow_id id;         /* (masked) flow id             */
        u_int32_t       expire;         /* expire time                  */
        u_int32_t       bucket;         /* which bucket in hash table   */
        u_int32_t       state;          /* state of this rule (typically a
                                         * combination of TCP flags)
                                         */
        u_int32_t       ack_fwd;        /* most recent ACKs in forward  */
        u_int32_t       ack_rev;        /* and reverse directions (used */
                                        /* to generate keepalives)      */
        u_int16_t       dyn_type;       /* rule type                    */
        u_int16_t       count;          /* refcount                     */
};

/*
 * Definitions for IP option names.
 */
#define IP_FW_IPOPT_LSRR        0x01
#define IP_FW_IPOPT_SSRR        0x02
#define IP_FW_IPOPT_RR          0x04
#define IP_FW_IPOPT_TS          0x08

/*
 * Definitions for TCP option names.
 */
#define IP_FW_TCPOPT_MSS        0x01
#define IP_FW_TCPOPT_WINDOW     0x02
#define IP_FW_TCPOPT_SACK       0x04
#define IP_FW_TCPOPT_TS         0x08
#define IP_FW_TCPOPT_CC         0x10

#define ICMP_REJECT_RST         0x100   /* fake ICMP code (send a TCP RST) */
#define ICMP6_UNREACH_RST       0x100   /* fake ICMPv6 code (send a TCP RST) */

/*
 * These are used for lookup tables.
 */
typedef struct  _ipfw_table_entry {
        in_addr_t       addr;           /* network address              */
        u_int32_t       value;          /* value                        */
        u_int16_t       tbl;            /* table number                 */
        u_int8_t        masklen;        /* mask length                  */
} ipfw_table_entry;

typedef struct  _ipfw_table {
        u_int32_t       size;           /* size of entries in bytes     */
        u_int32_t       cnt;            /* # of entries                 */
        u_int16_t       tbl;            /* table number                 */
        ipfw_table_entry ent[0];        /* entries                      */
} ipfw_table;

#define IP_FW_TABLEARG  65535

/*
 * Main firewall chains definitions and global var's definitions.
 */
#ifdef _KERNEL

/* Return values from ipfw_chk() */
enum {
        IP_FW_PASS = 0,
        IP_FW_DENY,
        IP_FW_DIVERT,
        IP_FW_TEE,
        IP_FW_DUMMYNET,
        IP_FW_NETGRAPH,
        IP_FW_NGTEE,
        IP_FW_NAT,
};

/* flags for divert mtag */
#define IP_FW_DIVERT_LOOPBACK_FLAG      0x00080000
#define IP_FW_DIVERT_OUTPUT_FLAG        0x00100000

/*
 * Structure for collecting parameters to dummynet for ip6_output forwarding
 */
struct _ip6dn_args {
       struct ip6_pktopts *opt_or;
       struct route_in6 ro_or;
       int flags_or;
       struct ip6_moptions *im6o_or;
       struct ifnet *origifp_or;
       struct ifnet *ifp_or;
       struct sockaddr_in6 dst_or;
       u_long mtu_or;
       struct route_in6 ro_pmtu_or;
};

/*
 * Arguments for calling ipfw_chk() and dummynet_io(). We put them
 * all into a structure because this way it is easier and more
 * efficient to pass variables around and extend the interface.
 */
struct ip_fw_args {
        struct mbuf     *m;             /* the mbuf chain               */
        struct ifnet    *oif;           /* output interface             */
        struct sockaddr_in *next_hop;   /* forward address              */
        struct ip_fw    *rule;          /* matching rule                */
        struct ether_header *eh;        /* for bridged packets          */

        struct ipfw_flow_id f_id;       /* grabbed from IP header       */
        u_int32_t       cookie;         /* a cookie depending on rule action */
        struct inpcb    *inp;

        struct _ip6dn_args      dummypar; /* dummynet->ip6_output */
        struct sockaddr_in hopstore;    /* store here if cannot use a pointer */
};

/*
 * Function definitions.
 */

/* Firewall hooks */
struct sockopt;
struct dn_flow_set;

int ipfw_check_in(void *, struct mbuf **, struct ifnet *, int, struct inpcb *inp);
int ipfw_check_out(void *, struct mbuf **, struct ifnet *, int, struct inpcb *inp);

int ipfw_chk(struct ip_fw_args *);

int ipfw_init(void);
void ipfw_destroy(void);

typedef int ip_fw_ctl_t(struct sockopt *);
extern ip_fw_ctl_t *ip_fw_ctl_ptr;
extern int fw_one_pass;
extern int fw_enable;
#ifdef INET6
extern int fw6_enable;
#endif

/* For kernel ipfw_ether and ipfw_bridge. */
typedef int ip_fw_chk_t(struct ip_fw_args *args);
extern  ip_fw_chk_t     *ip_fw_chk_ptr;
#define IPFW_LOADED     (ip_fw_chk_ptr != NULL)

#endif /* _KERNEL */
#endif /* _IPFW2_H */