[tripe] / server / tripe.h

/* -*-c-*-
 *
 * Main header file for TrIPE
 *
 * (c) 2001 Straylight/Edgeware
 */

/*----- Licensing notice --------------------------------------------------*
 *
 * This file is part of Trivial IP Encryption (TrIPE).
 *
 * TrIPE is free software: you can redistribute it and/or modify it under
 * the terms of the GNU General Public License as published by the Free
 * Software Foundation; either version 3 of the License, or (at your
 * option) any later version.
 *
 * TrIPE is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with TrIPE.  If not, see <https://www.gnu.org/licenses/>.
 */

#ifndef TRIPE_H
#define TRIPE_H

#ifdef __cplusplus
  extern "C" {
#endif

/*----- Header files ------------------------------------------------------*/

#include "config.h"

#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <limits.h>
#include <signal.h>
#include <stdarg.h>
#include <stddef.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>

#include <sys/types.h>
#include <sys/time.h>
#include <unistd.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <sys/wait.h>

#include <sys/socket.h>
#include <sys/un.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <netdb.h>

#include <pwd.h>
#include <grp.h>

#include <mLib/alloc.h>
#include <mLib/arena.h>
#include <mLib/base64.h>
#include <mLib/bres.h>
#include <mLib/codec.h>
#include <mLib/daemonize.h>
#include <mLib/dstr.h>
#include <mLib/env.h>
#include <mLib/fdflags.h>
#include <mLib/fdpass.h>
#include <mLib/fwatch.h>
#include <mLib/hash.h>
#include <mLib/macros.h>
#include <mLib/mdup.h>
#include <mLib/mdwopt.h>
#include <mLib/quis.h>
#include <mLib/report.h>
#include <mLib/sel.h>
#include <mLib/selbuf.h>
#include <mLib/sig.h>
#include <mLib/str.h>
#include <mLib/sub.h>
#include <mLib/trace.h>
#include <mLib/tv.h>
#include <mLib/versioncmp.h>

#include <catacomb/buf.h>
#include <catacomb/ct.h>

#include <catacomb/chacha.h>
#include <catacomb/gcipher.h>
#include <catacomb/gmac.h>
#include <catacomb/grand.h>
#include <catacomb/key.h>
#include <catacomb/paranoia.h>
#include <catacomb/poly1305.h>
#include <catacomb/salsa20.h>

#include <catacomb/noise.h>
#include <catacomb/rand.h>

#include <catacomb/mp.h>
#include <catacomb/mpmont.h>
#include <catacomb/mprand.h>
#include <catacomb/dh.h>
#include <catacomb/ec.h>
#include <catacomb/ec-raw.h>
#include <catacomb/ec-keys.h>
#include <catacomb/x25519.h>
#include <catacomb/x448.h>

#include "priv.h"
#include "protocol.h"
#include "slip.h"
#include "util.h"

#undef sun

/*----- Magic numbers -----------------------------------------------------*/

/* --- Trace flags --- */

#define T_TUNNEL 1u
#define T_PEER 2u
#define T_PACKET 4u
#define T_ADMIN 8u
#define T_CRYPTO 16u
#define T_KEYSET 32u
#define T_KEYEXCH 64u
#define T_KEYMGMT 128u
#define T_CHAL 256u
/* T_PRIVSEP  in priv.h */

#define T_ALL 1023u

/* --- Units --- */

#define SEC(n) (n##u)
#define MIN(n) (n##u * 60u)
#define F_2P32 (65536.0*65536.0)
#define MEG(n) (n##ul * 1024ul * 1024ul)

/* --- Timing parameters --- */

#define T_EXP MIN(60)			/* Expiry time for a key */
#define T_REGEN MIN(40)			/* Regeneration time for a key */

#define T_VALID SEC(20)			/* Challenge validity period */
#define T_RETRYMIN SEC(2)		/* Minimum retry interval */
#define T_RETRYMAX MIN(5)		/* Maximum retry interval */
#define T_RETRYGROW (5.0/4.0)		/* Retry interval growth factor */

#define T_WOBBLE (1.0/3.0)		/* Relative timer randomness */

/* --- Other things --- */

#define PKBUFSZ 65536

/*----- Cipher selections -------------------------------------------------*/

typedef struct keyset keyset;
typedef struct algswitch algswitch;
typedef struct kdata kdata;
typedef struct admin admin;

typedef struct dhgrp {
  const struct dhops *ops;
  size_t scsz;
} dhgrp;

typedef struct dhsc dhsc;
typedef struct dhge dhge;

enum {
  DHFMT_STD,		    /* Fixed-width format, suitable for encryption */
  DHFMT_HASH,		     /* Deterministic format, suitable for hashing */
  DHFMT_VAR		       /* Variable-width-format, mostly a bad idea */
};

typedef struct deriveargs {
  const char *what;			/* Operation name (hashed) */
  unsigned f;				/* Flags */
#define DF_IN 1u			/*   Make incoming key */
#define DF_OUT 2u			/*   Make outgoing key */
  const gchash *hc;			/* Hash class */
  const octet *k;			/* Pointer to contributions */
  size_t x, y, z;			/* Markers in contributions */
} deriveargs;

typedef struct bulkalgs {
  const struct bulkops *ops;
} bulkalgs;

typedef struct bulkctx {
  const struct bulkops *ops;
} bulkctx;

typedef struct bulkchal {
  const struct bulkops *ops;
  size_t tagsz;
} bulkchal;

typedef struct dhops {
  const char *name;

  int (*ldpriv)(key_file */*kf*/, key */*k*/, key_data */*d*/,
		kdata */*kd*/, dstr */*t*/, dstr */*e*/);
	/* Load a private key from @d@, storing the data in @kd@.  The key's
	 * file and key object are in @kf@ and @k@, mostly in case its
	 * attributes are interesting; the key tag is in @t@; errors are
	 * reported by writing tokens to @e@ and returning nonzero.
	 */

  int (*ldpub)(key_file */*kf*/, key */*k*/, key_data */*d*/,
	       kdata */*kd*/, dstr */*t*/, dstr */*e*/);
	/* Load a public key from @d@, storing the data in @kd@.  The key's
	 * file and key object are in @kf@ and @k@, mostly in case its
	 * attributes are interesting; the key tag is in @t@; errors are
	 * reported by writing tokens to @e@ and returning nonzero.
	 */

  const char *(*checkgrp)(const dhgrp */*g*/);
	/* Check that the group is valid; return null on success, or an error
	 * string.
	 */

  void (*grpinfo)(const dhgrp */*g*/, admin */*a*/);
	/* Report on the group to an admin client. */

  T( void (*tracegrp)(const dhgrp */*g*/); )
	/* Trace a description of the group. */

  int (*samegrpp)(const dhgrp */*g*/, const dhgrp */*gg*/);
	/* Return nonzero if the two group objects represent the same
	 * group.
	 */

  void (*freegrp)(dhgrp */*g*/);
	/* Free a group and the resources it holds. */

  dhsc *(*ldsc)(const dhgrp */*g*/, const void */*p*/, size_t /*sz*/);
	/* Load a scalar from @p@, @sz@ and return it.  Return null on
	 * error.
	 */

  int (*stsc)(const dhgrp */*g*/,
	       void */*p*/, size_t /*sz*/, const dhsc */*x*/);
	/* Store a scalar at @p@, @sz@.  Return nonzero on error. */

  dhsc *(*randsc)(const dhgrp */*g*/);
	/* Return a random scalar. */

  T( const char *(*scstr)(const dhgrp */*g*/, const dhsc */*x*/); )
	/* Return a human-readable representation of @x@; @buf_t@ may be used
	 * to hold it.
	 */

  void (*freesc)(const dhgrp */*g*/, dhsc */*x*/);
	/* Free a scalar and the resources it holds. */

  dhge *(*ldge)(const dhgrp */*g*/, buf */*b*/, int /*fmt*/);
	/* Load a group element from @b@, encoded using format @fmt@.  Return
	 * null on error.
	 */

  int (*stge)(const dhgrp */*g*/, buf */*b*/,
	      const dhge */*Y*/, int /*fmt*/);
	/* Store a group element in @b@, encoded using format @fmt@.  Return
	 * nonzero on error.
	 */

  int (*checkge)(const dhgrp */*h*/, const dhge */*Y*/);
	/* Check a group element for validity.  Return zero if everything
	 * checks out; nonzero on failure.
	 */

  int (*eq)(const dhgrp */*g*/, const dhge */*Y*/, const dhge */*Z*/);
	/* Return nonzero if @Y@ and @Z@ are equal. */

  dhge *(*mul)(const dhgrp */*g*/, const dhsc */*x*/, const dhge */*Y*/);
	/* Multiply a group element by a scalar, resulting in a shared-secret
	 * group element.  If @y@ is null, then multiply the well-known
	 * generator.
	 */

  T( const char *(*gestr)(const dhgrp */*g*/, const dhge */*Y*/); )
	/* Return a human-readable representation of @Y@; @buf_t@ may be used
	 * to hold it.
	 */

  void (*freege)(const dhgrp */*g*/, dhge */*Y*/);
	/* Free a group element and the resources it holds. */

} dhops;

typedef struct bulkops {
  const char *name;

  bulkalgs *(*getalgs)(const algswitch */*asw*/, dstr */*e*/,
		       key_file */*kf*/, key */*k*/);
	/* Determine algorithms to use and return a @bulkalgs@ object
	 * representing the decision.  On error, write tokens to @e@ and
	 * return null.
	 */

  T( void (*tracealgs)(const bulkalgs */*a*/); )
	/* Write trace information about the algorithm selection. */

  int (*checkalgs)(bulkalgs */*a*/, const algswitch */*asw*/, dstr */*e*/);
	/* Check that the algorithms in @a@ and @asw@ are acceptable.  On
	 * error, write tokens to @e@ and return @-1@; otherwise return zero.
	 */

  int (*samealgsp)(const bulkalgs */*a*/, const bulkalgs */*aa*/);
	/* If @a@ and @aa@ represent the same algorithm selection, return
	 * nonzero; if not, return zero.
	 */

  void (*alginfo)(const bulkalgs */*a*/, admin */*adm*/);
	/* Report on the algorithm selection to an admin client: call
	 * @a_info@ with appropriate key-value pairs.
	 */

  size_t (*overhead)(const bulkalgs */*a*/);
	/* Return the per-packet overhead of the bulk transform, in bytes. */

  size_t (*expsz)(const bulkalgs */*a*/);
	/* Return the total size limit for the bulk transform, in bytes,
	 * after which the keys must no longer be used.
	 */

  bulkctx *(*genkeys)(const bulkalgs */*a*/, const deriveargs */*a*/);
	/* Generate session keys and construct and return an appropriate
	 * context for using them.  The offsets @a->x@, @a->y@ and @a->z@
	 * separate the key material into three parts.  Between @a->k@ and
	 * @a->k + a->x@ is `my' contribution to the key material; between
	 * @a->k + a->x@ and @a->k + a->y@ is `your' contribution; and
	 * between @a->k + a->y@ and @a->k + a->z@ is a shared value we made
	 * together.  These are used to construct (up to) two collections of
	 * symmetric keys: one for outgoing messages, the other for incoming
	 * messages.  If @a->x == 0@ (or @a->y == a->x@) then my (or your)
	 * contribution is omitted.
	 */

  bulkchal *(*genchal)(const bulkalgs */*a*/);
	/* Construct and return a challenge issuing and verification
	 * context with a fresh random key.
	 */

  void (*freealgs)(bulkalgs */*a*/);
	/* Release an algorithm selection object.  (Associated bulk
	 * encryption contexts and challenge contexts may still exist and
	 * must remain valid.)
	 */

  int (*encrypt)(bulkctx */*bc*/, unsigned /*ty*/,
		 buf */*b*/, buf */*bb*/, uint32 /*seq*/);
	/* Encrypt the packet in @b@, with type @ty@ (which doesn't need
	 * encoding separately) and sequence number @seq@ (which must be
	 * recoverable by @decrypt@), and write the result to @bb@.  On
	 * error, return a @KSERR_...@ code and/or break the output buffer.
	 */

  int (*decrypt)(bulkctx */*bc*/, unsigned /*ty*/,
		 buf */*b*/, buf */*bb*/, uint32 */*seq*/);
	/* Decrypt the packet in @b@, with type @ty@, writing the result to
	 * @bb@ and storing the incoming (claimed) sequence number in @seq@.
	 * On error, return a @KSERR_...@ code.
	 */

  void (*freectx)(bulkctx */*a*/);
	/* Release a bulk encryption context and the resources it holds. */

  int (*chaltag)(bulkchal */*bc*/, const void */*m*/, size_t /*msz*/,
		 uint32 /*seq*/, void */*t*/);
	/* Calculate a tag for the challenge in @m@, @msz@, with the sequence
	 * number @seq@, and write it to @t@.  Return @-1@ on error, zero on
	 * success.
	 */

  int (*chalvrf)(bulkchal */*bc*/, const void */*m*/, size_t /*msz*/,
		 uint32 /*seq*/, const void */*t*/);
	/* Check the tag @t@ on @m@, @msz@ and @seq@: return zero if the tag
	 * is OK, nonzero if it's bad.
	 */

  void (*freechal)(bulkchal */*bc*/);
	/* Release a challenge context and the resources it holds. */

} bulkops;

struct algswitch {
  const gchash *h; size_t hashsz;	/* Hash function */
  const gccipher *mgf;			/* Mask-generation function */
  bulkalgs *bulk;			/* Bulk crypto algorithms */
};

struct kdata {
  unsigned ref;				/* Reference counter */
  struct knode *kn;			/* Pointer to cache entry */
  uint32 id;				/* The underlying key's id */
  char *tag;				/* Full tag name of the key */
  dhgrp *grp;				/* The group we work in */
  dhsc *k;				/* The private key (or null) */
  dhge *K;				/* The public key */
  time_t t_exp;				/* Expiry time of the key */
  algswitch algs;			/* Collection of algorithms */
};

typedef struct knode {
  sym_base _b;				/* Symbol table intrusion */
  unsigned f;				/* Various flags */
#define KNF_BROKEN 1u			/*   Don't use this key any more */
  struct keyhalf *kh;			/* Pointer to the home keyhalf */
  kdata *kd;				/* Pointer to the key data */
} knode;

#define MAXHASHSZ 64			/* Largest possible hash size */

#define HASH_STRING(h, s) GH_HASH((h), (s), sizeof(s))

extern const dhops dhtab[];
extern const bulkops bulktab[];

/*----- Data structures ---------------------------------------------------*/

/* --- Socket addresses --- *
 *
 * A magic union of supported socket addresses.
 */

typedef union addr {
  struct sockaddr sa;
  struct sockaddr_in sin;
} addr;

/* --- Mapping keyed on addresses --- */

typedef struct addrmap {
  hash_table t;
  size_t load;
} addrmap;

typedef struct addrmap_base {
  hash_base b;
  addr a;
} addrmap_base;

/* --- Sequence number checking --- */

typedef struct seqwin {
  uint32 seq;				/* First acceptable input sequence */
  uint32 win;				/* Window of acceptable numbers */
} seqwin;

#define SEQ_WINSZ 32			/* Bits in sequence number window */

/* --- A symmetric keyset --- *
 *
 * A keyset contains a set of symmetric keys for encrypting and decrypting
 * packets.  Keysets are stored in a list, sorted in reverse order of
 * creation, so that the most recent keyset (the one most likely to be used)
 * is first.
 *
 * Each keyset has a time limit and a data limit.  The keyset is destroyed
 * when either it has existed for too long, or it has been used to encrypt
 * too much data.  New key exchanges are triggered when keys are close to
 * expiry.
 */

enum { DIR_IN, DIR_OUT, NDIR };

struct keyset {
  struct keyset *next;			/* Next active keyset in the list */
  unsigned ref;				/* Reference count for keyset */
  struct peer *p;			/* Pointer to peer structure */
  time_t t_exp;				/* Expiry time for this keyset */
  unsigned long sz_exp, sz_regen;	/* Data limits for the keyset */
  T( unsigned seq; )			/* Sequence number for tracing */
  unsigned f;				/* Various useful flags */
  bulkctx *bulk;			/* Bulk crypto transform */
  uint32 oseq;				/* Outbound sequence number */
  seqwin iseq;				/* Inbound sequence number */
};

#define KSF_LISTEN 1u			/* Don't encrypt packets yet */
#define KSF_LINK 2u			/* Key is in a linked list */

#define KSERR_REGEN -1			/* Regenerate keys */
#define KSERR_NOKEYS -2			/* No keys left */
#define KSERR_DECRYPT -3		/* Unable to decrypt message */
#define KSERR_SEQ -4			/* Incorrect sequence number */
#define KSERR_MALFORMED -5		/* Input ciphertext is broken */

/* --- Key exchange --- *
 *
 * TrIPE uses the Wrestlers Protocol for its key exchange.  The Wrestlers
 * Protocol has a number of desirable features (e.g., perfect forward
 * secrecy, and zero-knowledge authentication) which make it attractive for
 * use in TrIPE.  The Wrestlers Protocol was designed by Mark Wooding and
 * Clive Jones.
 */

typedef struct retry {
  double t;				/* Current retry time */
} retry;

#define KX_NCHAL 16u

typedef struct kxchal {
  struct keyexch *kx;			/* Pointer back to key exchange */
  dhge *C;				/* Responder's challenge */
  dhge *R;				/* My reply to the challenge */
  keyset *ks;				/* Pointer to temporary keyset */
  unsigned f;				/* Various useful flags */
  sel_timer t;				/* Response timer for challenge */
  retry rs;				/* Retry state */
  octet hc[MAXHASHSZ];			/* Hash of his challenge */
  octet ck[MAXHASHSZ];			/* His magical check value */
  octet hswrq_in[MAXHASHSZ];		/* Inbound switch request message */
  octet hswok_in[MAXHASHSZ];		/* Inbound switch confirmation */
  octet hswrq_out[MAXHASHSZ];		/* Outbound switch request message */
  octet hswok_out[MAXHASHSZ];		/* Outbound switch confirmation */
} kxchal;

typedef struct keyexch {
  struct peer *p;			/* Pointer back to the peer */
  kdata *kpriv;				/* Private key and related info */
  kdata *kpub;				/* Peer's public key */
  keyset **ks;				/* Peer's list of keysets */
  unsigned f;				/* Various useful flags */
  unsigned s;				/* Current state in exchange */
  sel_timer t;				/* Timer for next exchange */
  retry rs;				/* Retry state */
  dhsc *a;				/* My temporary secret */
  dhge *C;				/* My challenge */
  dhge *RX;				/* The expected response */
  unsigned nr;				/* Number of extant responses */
  time_t t_valid;			/* When this exchange goes bad */
  octet hc[MAXHASHSZ];			/* Hash of my challenge */
  kxchal *r[KX_NCHAL];			/* Array of challenges */
} keyexch;

#define KXF_TIMER 1u			/* Waiting for a timer to go off */
#define KXF_DEAD 2u			/* The key-exchanger isn't up */
#define KXF_PUBKEY 4u			/* Key exchanger has a public key */
#define KXF_CORK 8u			/* Don't send anything yet */

enum {
  KXS_DEAD,				/* Uninitialized state (magical) */
  KXS_CHAL,				/* Main answer-challenges state */
  KXS_COMMIT,				/* Committed: send switch request */
  KXS_SWITCH				/* Switched: send confirmation */
};

/* --- Tunnel structure --- *
 *
 * Used to maintain system-specific information about the tunnel interface.
 */

typedef struct tunnel tunnel;
struct peer;

typedef struct tunnel_ops {
  const char *name;			/* Name of this tunnel driver */
  unsigned flags;			/* Various interesting flags */
#define TUNF_PRIVOPEN 1u		/*   Need helper to open file */
  void (*init)(void);			/* Initializes the system */
  tunnel *(*create)(struct peer */*p*/, int /*fd*/, char **/*ifn*/);
					/* Initializes a new tunnel */
  void (*setifname)(tunnel */*t*/, const char */*ifn*/);
					/*  Notifies ifname change */
  void (*inject)(tunnel */*t*/, buf */*b*/); /* Sends packet through if */
  void (*destroy)(tunnel */*t*/);	/* Destroys a tunnel */
} tunnel_ops;

#ifndef TUN_INTERNALS
struct tunnel { const tunnel_ops *ops; };
#endif

/* --- Peer statistics --- *
 *
 * Contains various interesting and not-so-interesting statistics about a
 * peer.  This is updated by various parts of the code.  The format of the
 * structure isn't considered private, and @p_stats@ returns a pointer to the
 * statistics block for a given peer.
 */

typedef struct stats {
  unsigned long sz_in, sz_out;		/* Size of all data in and out */
  unsigned long sz_kxin, sz_kxout;	/* Size of key exchange messages */
  unsigned long sz_ipin, sz_ipout;	/* Size of encapsulated IP packets */
  time_t t_start, t_last, t_kx;		/* Time peer created, last pk, kx */
  unsigned long n_reject;		/* Number of rejected packets */
  unsigned long n_in, n_out;		/* Number of packets in and out */
  unsigned long n_kxin, n_kxout;	/* Number of key exchange packets */
  unsigned long n_ipin, n_ipout;	/* Number of encrypted packets */
} stats;

/* --- Peer structure --- *
 *
 * The main structure which glues everything else together.
 */

typedef struct peerspec {
  char *name;				/* Peer's name */
  char *privtag;			/* Private key tag */
  char *tag;				/* Public key tag */
  const tunnel_ops *tops;		/* Tunnel operations */
  unsigned long t_ka;			/* Keep alive interval */
  addr sa;				/* Socket address to speak to */
  unsigned f;				/* Flags for the peer */
#define PSF_KXMASK 255u			/*   Key-exchange flags to set */
#define PSF_MOBILE 256u			/*   Address may change rapidly */
} peerspec;

typedef struct peer_byname {
  sym_base _b;
  struct peer *p;
} peer_byname;

typedef struct peer_byaddr {
  addrmap_base _b;
  struct peer *p;
} peer_byaddr;

typedef struct peer {
  peer_byname *byname;			/* Lookup-by-name block */
  peer_byaddr *byaddr;			/* Lookup-by-address block */
  struct ping *pings;			/* Pings we're waiting for */
  peerspec spec;			/* Specifications for this peer */
  tunnel *t;				/* Tunnel for local packets */
  char *ifname;				/* Interface name for tunnel */
  keyset *ks;				/* List head for keysets */
  buf b;				/* Buffer for sending packets */
  stats st;				/* Statistics */
  keyexch kx;				/* Key exchange protocol block */
  sel_timer tka;			/* Timer for keepalives */
} peer;

typedef struct peer_iter { sym_iter i; } peer_iter;

typedef struct ping {
  struct ping *next, *prev;		/* Links to next and previous */
  peer *p;				/* Peer so we can free it */
  unsigned msg;				/* Kind of response expected */
  uint32 id;				/* Id so we can recognize response */
  octet magic[32];			/* Some random data */
  sel_timer t;				/* Timeout for ping */
  void (*func)(int /*rc*/, void */*arg*/); /* Function to call when done */
  void *arg;				/* Argument for callback */
} ping;

enum {
  PING_NONOTIFY = -1,
  PING_OK = 0,
  PING_TIMEOUT,
  PING_PEERDIED,
  PING_MAX
};

/* --- Admin structure --- */

#define OBUFSZ 16384u

typedef struct obuf {
  struct obuf *next;			/* Next buffer in list */
  char *p_in, *p_out;			/* Pointers into the buffer */
  char buf[OBUFSZ];			/* The actual buffer */
} obuf;

typedef struct oqueue {
  obuf *hd, *tl;			/* Head and tail pointers */
} oqueue;

struct admin;

typedef struct admin_bgop {
  struct admin_bgop *next, *prev;	/* Links to next and previous */
  struct admin *a;			/* Owner job */
  char *tag;				/* Tag string for messages */
  void (*cancel)(struct admin_bgop *);	/* Destructor function */
} admin_bgop;

typedef struct admin_resop {
  admin_bgop bg;			/* Background operation header */
  char *addr;				/* Hostname to be resolved */
  bres_client r;			/* Background resolver task */
  sel_timer t;				/* Timer for resolver */
  addr sa;				/* Socket address */
  size_t sasz;				/* Socket address size */
  void (*func)(struct admin_resop *, int); /* Handler */
} admin_resop;

enum { ARES_OK, ARES_FAIL };

typedef struct admin_addop {
  admin_resop r;			/* Name resolution header */
  peerspec peer;			/* Peer pending creation */
} admin_addop;

typedef struct admin_pingop {
  admin_bgop bg;			/* Background operation header */
  ping ping;				/* Ping pending response */
  struct timeval pingtime;		/* Time last ping was sent */
} admin_pingop;

typedef struct admin_service {
  sym_base _b;				/* Hash table base structure */
  char *version;			/* The provided version */
  struct admin *prov;			/* Which client provides me */
  struct admin_service *next, *prev;	/* Client's list of services */
} admin_service;

typedef struct admin_svcop {
  admin_bgop bg;			/* Background operation header */
  struct admin *prov;			/* Client servicing this job */
  unsigned index;			/* This job's index */
  struct admin_svcop *next, *prev;	/* Links for provider's jobs */
} admin_svcop;

typedef struct admin_jobentry {
  unsigned short seq;			/* Zero if unused */
  union {
    admin_svcop *op;			/* Operation, if slot in use, ... */
    uint32 next;			/* ... or index of next free slot */
  } u;
} admin_jobentry;

typedef struct admin_jobtable {
  uint32 n, sz;				/* Used slots and table size */
  admin_svcop *active;			/* List of active jobs */
  uint32 free;				/* Index of first free slot */
  admin_jobentry *v;			/* And the big array of entries */
} admin_jobtable;

struct admin {
  struct admin *next, *prev;		/* Links to next and previous */
  unsigned f;				/* Various useful flags */
  unsigned ref;				/* Reference counter */
#ifndef NTRACE
  unsigned seq;				/* Sequence number for tracing */
#endif
  oqueue out;				/* Output buffer list */
  oqueue delay;				/* Delayed output buffer list */
  admin_bgop *bg;			/* Backgrounded operations */
  admin_service *svcs;			/* Which services I provide */
  admin_jobtable j;			/* Table of outstanding jobs */
  selbuf b;				/* Line buffer for commands */
  sel_file w;				/* Selector for write buffering */
};

#define AF_DEAD 1u			/* Destroy this admin block */
#define AF_CLOSE 2u			/* Client closed connection */
#define AF_NOTE 4u			/* Catch notifications */
#define AF_WARN 8u			/* Catch warning messages */
#ifndef NTRACE
#  define AF_TRACE 16u			/* Catch tracing */
#endif
#define AF_FOREGROUND 32u		/* Quit server when client closes */

#ifndef NTRACE
#  define AF_ALLMSGS (AF_NOTE | AF_TRACE | AF_WARN)
#else
#  define AF_ALLMSGS (AF_NOTE | AF_WARN)
#endif

/*----- Global variables --------------------------------------------------*/

extern sel_state sel;			/* Global I/O event state */
extern octet buf_i[PKBUFSZ], buf_o[PKBUFSZ], buf_t[PKBUFSZ], buf_u[PKBUFSZ];
extern const tunnel_ops *tunnels[];	/* Table of tunnels (0-term) */
extern const tunnel_ops *tun_default;	/* Default tunnel to use */
extern kdata *master;			/* Default private key */
extern const char *tag_priv;		/* Default private key tag */

#ifndef NTRACE
extern const trace_opt tr_opts[];	/* Trace options array */
extern unsigned tr_flags;		/* Trace options flags */
#endif

/*----- Other macros ------------------------------------------------------*/

#define QUICKRAND							\
  do { rand_quick(RAND_GLOBAL); noise_timer(RAND_GLOBAL); } while (0)

/*----- Key management ----------------------------------------------------*/

/* --- @km_init@ --- *
 *
 * Arguments:	@const char *privkr@ = private keyring file
 *		@const char *pubkr@ = public keyring file
 *		@const char *ptag@ = default private-key tag
 *
 * Returns:	---
 *
 * Use:		Initializes the key-management machinery, loading the
 *		keyrings and so on.
 */

extern void km_init(const char */*privkr*/, const char */*pubkr*/,
		    const char */*ptag*/);

/* --- @km_reload@ --- *
 *
 * Arguments:	---
 *
 * Returns:	Zero if OK, nonzero to force reloading of keys.
 *
 * Use:		Checks the keyrings to see if they need reloading.
 */

extern int km_reload(void);

/* --- @km_findpub@, @km_findpriv@ --- *
 *
 * Arguments:	@const char *tag@ = key tag to load
 *
 * Returns:	Pointer to the kdata object if successful, or null on error.
 *
 * Use:		Fetches a public or private key from the keyring.
 */

extern kdata *km_findpub(const char */*tag*/);
extern kdata *km_findpriv(const char */*tag*/);

/* --- @km_findpubbyid@, @km_findprivbyid@ --- *
 *
 * Arguments:	@uint32 id@ = key id to load
 *
 * Returns:	Pointer to the kdata object if successful, or null on error.
 *
 * Use:		Fetches a public or private key from the keyring given its
 *		numeric id.
 */

extern kdata *km_findpubbyid(uint32 /*id*/);
extern kdata *km_findprivbyid(uint32 /*id*/);

/* --- @km_samealgsp@ --- *
 *
 * Arguments:	@const kdata *kdx, *kdy@ = two key data objects
 *
 * Returns:	Nonzero if their two algorithm selections are the same.
 *
 * Use:		Checks sameness of algorithm selections: used to ensure that
 *		peers are using sensible algorithms.
 */

extern int km_samealgsp(const kdata */*kdx*/, const kdata */*kdy*/);

/* --- @km_ref@ --- *
 *
 * Arguments:	@kdata *kd@ = pointer to the kdata object
 *
 * Returns:	---
 *
 * Use:		Claim a new reference to a kdata object.
 */

extern void km_ref(kdata */*kd*/);

/* --- @km_unref@ --- *
 *
 * Arguments:	@kdata *kd@ = pointer to the kdata object
 *
 * Returns:	---
 *
 * Use:		Releases a reference to a kdata object.
 */

extern void km_unref(kdata */*kd*/);

/* --- @km_tag@ --- *
 *
 * Arguments:	@kdata *kd@ - pointer to the kdata object
 *
 * Returns:	A pointer to the short tag by which the kdata was loaded.
 */

extern const char *km_tag(kdata */*kd*/);

/*----- Key exchange ------------------------------------------------------*/

/* --- @kx_start@ --- *
 *
 * Arguments:	@keyexch *kx@ = pointer to key exchange context
 *		@int forcep@ = nonzero to ignore the quiet timer
 *
 * Returns:	---
 *
 * Use:		Stimulates a key exchange.  If a key exchage is in progress,
 *		a new challenge is sent (unless the quiet timer forbids
 *		this); if no exchange is in progress, one is commenced.
 */

extern void kx_start(keyexch */*kx*/, int /*forcep*/);

/* --- @kx_message@ --- *
 *
 * Arguments:	@keyexch *kx@ = pointer to key exchange context
 *		@const addr *a@ = sender's IP address and port
 *		@unsigned msg@ = the message code
 *		@buf *b@ = pointer to buffer containing the packet
 *
 * Returns:	Nonzero if the sender's address was unknown.
 *
 * Use:		Reads a packet containing key exchange messages and handles
 *		it.
 */

extern int kx_message(keyexch */*kx*/, const addr */*a*/,
		      unsigned /*msg*/, buf */*b*/);

/* --- @kx_free@ --- *
 *
 * Arguments:	@keyexch *kx@ = pointer to key exchange context
 *
 * Returns:	---
 *
 * Use:		Frees everything in a key exchange context.
 */

extern void kx_free(keyexch */*kx*/);

/* --- @kx_newkeys@ --- *
 *
 * Arguments:	@keyexch *kx@ = pointer to key exchange context
 *
 * Returns:	---
 *
 * Use:		Informs the key exchange module that its keys may have
 *		changed.  If fetching the new keys fails, the peer will be
 *		destroyed, we log messages and struggle along with the old
 *		keys.
 */

extern void kx_newkeys(keyexch */*kx*/);

/* --- @kx_setup@ --- *
 *
 * Arguments:	@keyexch *kx@ = pointer to key exchange context
 *		@peer *p@ = pointer to peer context
 *		@keyset **ks@ = pointer to keyset list
 *		@unsigned f@ = various useful flags
 *
 * Returns:	Zero if OK, nonzero if it failed.
 *
 * Use:		Initializes a key exchange module.  The module currently
 *		contains no keys, and will attempt to initiate a key
 *		exchange.
 */

extern int kx_setup(keyexch */*kx*/, peer */*p*/,
		    keyset **/*ks*/, unsigned /*f*/);

/*----- Keysets and symmetric cryptography --------------------------------*/

/* --- @ks_drop@ --- *
 *
 * Arguments:	@keyset *ks@ = pointer to a keyset
 *
 * Returns:	---
 *
 * Use:		Decrements a keyset's reference counter.  If the counter hits
 *		zero, the keyset is freed.
 */

extern void ks_drop(keyset */*ks*/);

/* --- @ks_gen@ --- *
 *
 * Arguments:	@deriveargs *a@ = key derivation parameters (modified)
 *		@peer *p@ = pointer to peer information
 *
 * Returns:	A pointer to the new keyset.
 *
 * Use:		Derives a new keyset from the given key material.  This will
 *		set the @what@, @f@, and @hc@ members in @*a@; other members
 *		must be filled in by the caller.
 *
 *		The new key is marked so that it won't be selected for output
 *		by @ksl_encrypt@.  You can still encrypt data with it by
 *		calling @ks_encrypt@ directly.
 */

extern keyset *ks_gen(deriveargs */*a*/, peer */*p*/);

/* --- @ks_activate@ --- *
 *
 * Arguments:	@keyset *ks@ = pointer to a keyset
 *
 * Returns:	---
 *
 * Use:		Activates a keyset, so that it can be used for encrypting
 *		outgoing messages.
 */

extern void ks_activate(keyset */*ks*/);

/* --- @ks_encrypt@ --- *
 *
 * Arguments:	@keyset *ks@ = pointer to a keyset
 *		@unsigned ty@ = message type
 *		@buf *b@ = pointer to input buffer
 *		@buf *bb@ = pointer to output buffer
 *
 * Returns:	Zero if successful; @KSERR_REGEN@ if we should negotiate a
 *		new key; @KSERR_NOKEYS@ if the key is not usable.  Also
 *		returns zero if there was insufficient buffer (but the output
 *		buffer is broken in this case).
 *
 * Use:		Encrypts a block of data using the key.  Note that the `key
 *		ought to be replaced' notification is only ever given once
 *		for each key.  Also note that this call forces a keyset to be
 *		used even if it's marked as not for data output.
 *
 *		The encryption transform is permitted to corrupt @buf_u@ for
 *		its own purposes.  Neither the source nor destination should
 *		be within @buf_u@; and callers mustn't expect anything stored
 *		in @buf_u@ to still
 */

extern int ks_encrypt(keyset */*ks*/, unsigned /*ty*/,
		      buf */*b*/, buf */*bb*/);

/* --- @ks_decrypt@ --- *
 *
 * Arguments:	@keyset *ks@ = pointer to a keyset
 *		@unsigned ty@ = expected type code
 *		@buf *b@ = pointer to an input buffer
 *		@buf *bb@ = pointer to an output buffer
 *
 * Returns:	Zero on success; @KSERR_DECRYPT@ on failure.  Also returns
 *		zero if there was insufficient buffer (but the output buffer
 *		is broken in this case).
 *
 * Use:		Attempts to decrypt a message using a given key.  Note that
 *		requesting decryption with a key directly won't clear a
 *		marking that it's not for encryption.
 *
 *		The decryption transform is permitted to corrupt @buf_u@ for
 *		its own purposes.  Neither the source nor destination should
 *		be within @buf_u@; and callers mustn't expect anything stored
 *		in @buf_u@ to still
 */

extern int ks_decrypt(keyset */*ks*/, unsigned /*ty*/,
		      buf */*b*/, buf */*bb*/);

/* --- @ksl_free@ --- *
 *
 * Arguments:	@keyset **ksroot@ = pointer to keyset list head
 *
 * Returns:	---
 *
 * Use:		Frees (releases references to) all of the keys in a keyset.
 */

extern void ksl_free(keyset **/*ksroot*/);

/* --- @ksl_link@ --- *
 *
 * Arguments:	@keyset **ksroot@ = pointer to keyset list head
 *		@keyset *ks@ = pointer to a keyset
 *
 * Returns:	---
 *
 * Use:		Links a keyset into a list.  A keyset can only be on one list
 *		at a time.  Bad things happen otherwise.
 */

extern void ksl_link(keyset **/*ksroot*/, keyset */*ks*/);

/* --- @ksl_prune@ --- *
 *
 * Arguments:	@keyset **ksroot@ = pointer to keyset list head
 *
 * Returns:	---
 *
 * Use:		Prunes the keyset list by removing keys which mustn't be used
 *		any more.
 */

extern void ksl_prune(keyset **/*ksroot*/);

/* --- @ksl_encrypt@ --- *
 *
 * Arguments:	@keyset **ksroot@ = pointer to keyset list head
 *		@unsigned ty@ = message type
 *		@buf *b@ = pointer to input buffer
 *		@buf *bb@ = pointer to output buffer
 *
 * Returns:	Zero if successful; @KSERR_REGEN@ if it's time to negotiate a
 *		new key; @KSERR_NOKEYS@ if there are no suitable keys
 *		available.  Also returns zero if there was insufficient
 *		buffer space (but the output buffer is broken in this case).
 *
 * Use:		Encrypts a packet.
 */

extern int ksl_encrypt(keyset **/*ksroot*/, unsigned /*ty*/,
		       buf */*b*/, buf */*bb*/);

/* --- @ksl_decrypt@ --- *
 *
 * Arguments:	@keyset **ksroot@ = pointer to keyset list head
 *		@unsigned ty@ = expected type code
 *		@buf *b@ = pointer to input buffer
 *		@buf *bb@ = pointer to output buffer
 *
 * Returns:	Zero on success; @KSERR_DECRYPT@ on failure.  Also returns
 *		zero if there was insufficient buffer (but the output buffer
 *		is broken in this case).
 *
 * Use:		Decrypts a packet.
 */

extern int ksl_decrypt(keyset **/*ksroot*/, unsigned /*ty*/,
		       buf */*b*/, buf */*bb*/);

/*----- Challenges --------------------------------------------------------*/

/* --- @c_new@ --- *
 *
 * Arguments:	@const void *m@ = pointer to associated message, or null
 *		@size_t msz@ = length of associated message
 *		@buf *b@ = where to put the challenge
 *
 * Returns:	Zero if OK, nonzero on error.
 *
 * Use:		Issues a new challenge.
 */

extern int c_new(const void */*m*/, size_t /*msz*/, buf */*b*/);

/* --- @c_check@ --- *
 *
 * Arguments:	@const void *m@ = pointer to associated message, or null
 *		@size_t msz@ = length of associated message
 *		@buf *b@ = where to find the challenge
 *
 * Returns:	Zero if OK, nonzero if it didn't work.
 *
 * Use:		Checks a challenge.  On failure, the buffer is broken.
 */

extern int c_check(const void */*m*/, size_t /*msz*/, buf */*b*/);

/*----- Administration interface ------------------------------------------*/

#define A_END ((char *)0)

/* --- @a_vformat@ --- *
 *
 * Arguments:	@dstr *d@ = where to leave the formatted message
 *		@const char *fmt@ = pointer to format string
 *		@va_list *ap@ = arguments in list
 *
 * Returns:	---
 *
 * Use:		Main message token formatting driver.  The arguments are
 *		interleaved formatting tokens and their parameters, finally
 *		terminated by an entry @A_END@.
 *
 *		Tokens recognized:
 *
 *		  * "*..." ... -- pretokenized @dstr_putf@-like string
 *
 *		  * "?ADDR" SOCKADDR -- a socket address, to be converted
 *
 *		  * "?B64" BUFFER SIZE -- binary data to be base64-encoded
 *
 *		  * "?TOKENS" VECTOR -- null-terminated vector of tokens
 *
 *		  * "?PEER" PEER -- peer's name
 *
 *		  * "?ERRNO" ERRNO -- system error code
 *
 *		  * "[!]..." ... -- @dstr_putf@-like string as single token
 */

extern void a_vformat(dstr */*d*/, const char */*fmt*/, va_list */*ap*/);

/* --- @a_format@ --- *
 *
 * Arguments:	@dstr *d@ = where to leave the formatted message
 *		@const char *fmt@ = pointer to format string
 *
 * Returns:	---
 *
 * Use:		Writes a tokenized message into a string, for later
 *		presentation.
 */

extern void EXECL_LIKE(0) a_format(dstr */*d*/, const char */*fmt*/, ...);

/* --- @a_info@ --- *
 *
 * Arguments:	@admin *a@ = connection
 *		@const char *fmt@ = format string
 *		@...@ = other arguments
 *
 * Returns:	---
 *
 * Use:		Report information to an admin client.
 */

extern void EXECL_LIKE(0) a_info(admin */*a*/, const char */*fmt*/, ...);

/* --- @a_warn@ --- *
 *
 * Arguments:	@const char *fmt@ = pointer to format string
 *		@...@ = other arguments
 *
 * Returns:	---
 *
 * Use:		Informs all admin connections of a warning.
 */

extern void EXECL_LIKE(0) a_warn(const char */*fmt*/, ...);

/* --- @a_notify@ --- *
 *
 * Arguments:	@const char *fmt@ = pointer to format string
 *		@...@ = other arguments
 *
 * Returns:	---
 *
 * Use:		Sends a notification to interested admin connections.
 */

extern void EXECL_LIKE(0) a_notify(const char */*fmt*/, ...);

/* --- @a_create@ --- *
 *
 * Arguments:	@int fd_in, fd_out@ = file descriptors to use
 *		@unsigned f@ = initial flags to set
 *
 * Returns:	---
 *
 * Use:		Creates a new admin connection.
 */

extern void a_create(int /*fd_in*/, int /*fd_out*/, unsigned /*f*/);

/* --- @a_quit@ --- *
 *
 * Arguments:	---
 *
 * Returns:	---
 *
 * Use:		Shuts things down nicely.
 */

extern void a_quit(void);

/* --- @a_preselect@ --- *
 *
 * Arguments:	---
 *
 * Returns:	---
 *
 * Use:		Informs the admin module that we're about to select again,
 *		and that it should do cleanup things it has delayed until a
 *		`safe' time.
 */

extern void a_preselect(void);

/* --- @a_daemon@ --- *
 *
 * Arguments:	---
 *
 * Returns:	---
 *
 * Use:		Informs the admin module that it's a daemon.
 */

extern void a_daemon(void);

/* --- @a_init@ --- *
 *
 * Arguments:	@const char *sock@ = socket name to create
 *		@uid_t u@ = user to own the socket
 *		@gid_t g@ = group to own the socket
 *		@mode_t m@ = permissions to set on the socket
 *
 * Returns:	---
 *
 * Use:		Creates the admin listening socket.
 */

extern void a_init(const char */*sock*/,
		   uid_t /*u*/, gid_t /*g*/, mode_t /*m*/);

/*----- Mapping with addresses as keys ------------------------------------*/

/* --- @am_create@ --- *
 *
 * Arguments:	@addrmap *m@ = pointer to map
 *
 * Returns:	---
 *
 * Use:		Create an address map, properly set up.
 */

extern void am_create(addrmap */*m*/);

/* --- @am_destroy@ --- *
 *
 * Arguments:	@addrmap *m@ = pointer to map
 *
 * Returns:	---
 *
 * Use:		Destroy an address map, throwing away all the entries.
 */

extern void am_destroy(addrmap */*m*/);

/* --- @am_find@ --- *
 *
 * Arguments:	@addrmap *m@ = pointer to map
 *		@const addr *a@ = address to look up
 *		@size_t sz@ = size of block to allocate
 *		@unsigned *f@ = where to store flags
 *
 * Returns:	Pointer to found item, or null.
 *
 * Use:		Finds a record with the given IP address, set @*f@ nonzero
 *		and returns it.  If @sz@ is zero, and no match was found,
 *		return null; otherwise allocate a new block of @sz@ bytes,
 *		clear @*f@ to zero and return the block pointer.
 */

extern void *am_find(addrmap */*m*/, const addr */*a*/,
		     size_t /*sz*/, unsigned */*f*/);

/* --- @am_remove@ --- *
 *
 * Arguments:	@addrmap *m@ = pointer to map
 *		@void *i@ = pointer to the item
 *
 * Returns:	---
 *
 * Use:		Removes an item from the map.
 */

extern void am_remove(addrmap */*m*/, void */*i*/);

/*----- Privilege separation ----------------------------------------------*/

/* --- @ps_trace@ --- *
 *
 * Arguments:	@unsigned mask@ = trace mask to check
 *		@const char *fmt@ = message format
 *		@...@ = values for placeholders
 *
 * Returns:	---
 *
 * Use:		Writes a trace message.
 */

T( extern void PRINTF_LIKE(2, 3)
     ps_trace(unsigned /*mask*/, const char */*fmt*/, ...); )

/* --- @ps_warn@ --- *
 *
 * Arguments:	@const char *fmt@ = message format
 *		@...@ = values for placeholders
 *
 * Returns:	---
 *
 * Use:		Writes a warning message.
 */

extern void PRINTF_LIKE(1, 2) ps_warn(const char */*fmt*/, ...);

/* --- @ps_tunfd@ --- *
 *
 * Arguments:	@const tunnel_ops *tops@ = pointer to tunnel operations
 *		@char **ifn@ = where to put the interface name
 *
 * Returns:	The file descriptor, or @-1@ on error.
 *
 * Use:		Fetches a file descriptor for a tunnel driver.
 */

extern int ps_tunfd(const tunnel_ops */*tops*/, char **/*ifn*/);

/* --- @ps_split@ --- *
 *
 * Arguments:	@int detachp@ = whether to detach the child from its terminal
 *
 * Returns:	---
 *
 * Use:		Separates off the privileged tunnel-opening service from the
 *		rest of the server.
 */

extern void ps_split(int /*detachp*/);

/* --- @ps_quit@ --- *
 *
 * Arguments:	---
 *
 * Returns:	---
 *
 * Use:		Detaches from the helper process.
 */

extern void ps_quit(void);

/*----- Peer management ---------------------------------------------------*/

/* --- @p_updateaddr@ --- *
 *
 * Arguments:	@peer *p@ = pointer to peer block
 *		@const addr *a@ = address to associate with this peer
 *
 * Returns:	Zero if the address was changed; @+1@ if it was already
 *		right.
 *
 * Use:		Updates our idea of @p@'s address.
 */

extern int p_updateaddr(peer */*p*/, const addr */*a*/);

/* --- @p_txstart@ --- *
 *
 * Arguments:	@peer *p@ = pointer to peer block
 *		@unsigned msg@ = message type code
 *
 * Returns:	A pointer to a buffer to write to.
 *
 * Use:		Starts sending to a peer.  Only one send can happen at a
 *		time.
 */

extern buf *p_txstart(peer */*p*/, unsigned /*msg*/);

/* --- @p_txend@ --- *
 *
 * Arguments:	@peer *p@ = pointer to peer block
 *
 * Returns:	---
 *
 * Use:		Sends a packet to the peer.
 */

extern void p_txend(peer */*p*/);

/* --- @p_pingsend@ --- *
 *
 * Arguments:	@peer *p@ = destination peer
 *		@ping *pg@ = structure to fill in
 *		@unsigned type@ = message type
 *		@unsigned long timeout@ = how long to wait before giving up
 *		@void (*func)(int, void *)@ = callback function
 *		@void *arg@ = argument for callback
 *
 * Returns:	Zero if successful, nonzero if it failed.
 *
 * Use:		Sends a ping to a peer.  Call @func@ with a nonzero argument
 *		if we get an answer within the timeout, or zero if no answer.
 */

extern int p_pingsend(peer */*p*/, ping */*pg*/, unsigned /*type*/,
		      unsigned long /*timeout*/,
		      void (*/*func*/)(int, void *), void */*arg*/);

/* --- @p_pingdone@ --- *
 *
 * Arguments:	@ping *p@ = ping structure
 *		@int rc@ = return code to pass on
 *
 * Returns:	---
 *
 * Use:		Disposes of a ping structure, maybe sending a notification.
 */

extern void p_pingdone(ping */*p*/, int /*rc*/);

/* --- @p_greet@ --- *
 *
 * Arguments:	@peer *p@ = peer to send to
 *		@const void *c@ = pointer to challenge
 *		@size_t sz@ = size of challenge
 *
 * Returns:	---
 *
 * Use:		Sends a greeting packet.
 */

extern void p_greet(peer */*p*/, const void */*c*/, size_t /*sz*/);

/* --- @p_tun@ --- *
 *
 * Arguments:	@peer *p@ = pointer to peer block
 *		@buf *b@ = buffer containing incoming packet
 *
 * Returns:	---
 *
 * Use:		Handles a packet which needs to be sent to a peer.
 */

extern void p_tun(peer */*p*/, buf */*b*/);

/* --- @p_keyreload@ --- *
 *
 * Arguments:	---
 *
 * Returns:	---
 *
 * Use:		Forces a check of the daemon's keyring files.
 */

extern void p_keyreload(void);

/* --- @p_interval@ --- *
 *
 * Arguments:	---
 *
 * Returns:	---
 *
 * Use:		Called periodically to do tidying.
 */

extern void p_interval(void);

/* --- @p_stats@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	A pointer to the peer's statistics.
 */

extern stats *p_stats(peer */*p*/);

/* --- @p_ifname@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	A pointer to the peer's interface name.
 */

extern const char *p_ifname(peer */*p*/);

/* --- @p_setifname@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *		@const char *name@ = pointer to the new name
 *
 * Returns:	---
 *
 * Use:		Changes the name held for a peer's interface.
 */

extern void p_setifname(peer */*p*/, const char */*name*/);

/* --- @p_addr@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	A pointer to the peer's address.
 */

extern const addr *p_addr(peer */*p*/);

/* --- @p_init@ --- *
 *
 * Arguments:	@struct in_addr addr@ = address to bind to
 *		@unsigned port@ = port number to listen to
 *
 * Returns:	---
 *
 * Use:		Initializes the peer system; creates the socket.
 */

extern void p_init(struct in_addr /*addr*/, unsigned /*port*/);

/* --- @p_port@ --- *
 *
 * Arguments:	---
 *
 * Returns:	Port number used for socket.
 */

unsigned p_port(void);

/* --- @p_create@ --- *
 *
 * Arguments:	@peerspec *spec@ = information about this peer
 *
 * Returns:	Pointer to the peer block, or null if it failed.
 *
 * Use:		Creates a new named peer block.  No peer is actually attached
 *		by this point.
 */

extern peer *p_create(peerspec */*spec*/);

/* --- @p_name@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	A pointer to the peer's name.
 *
 * Use:		Equivalent to @p_spec(p)->name@.
 */

extern const char *p_name(peer */*p*/);

/* --- @p_tag@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	A pointer to the peer's public key tag.
 */

extern const char *p_tag(peer */*p*/);

/* --- @p_privtag@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	A pointer to the peer's private key tag.
 */

extern const char *p_privtag(peer */*p*/);

/* --- @p_spec@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer block
 *
 * Returns:	Pointer to the peer's specification
 */

extern const peerspec *p_spec(peer */*p*/);

/* --- @p_findbyaddr@ --- *
 *
 * Arguments:	@const addr *a@ = address to look up
 *
 * Returns:	Pointer to the peer block, or null if not found.
 *
 * Use:		Finds a peer by address.
 */

extern peer *p_findbyaddr(const addr */*a*/);

/* --- @p_find@ --- *
 *
 * Arguments:	@const char *name@ = name to look up
 *
 * Returns:	Pointer to the peer block, or null if not found.
 *
 * Use:		Finds a peer by name.
 */

extern peer *p_find(const char */*name*/);

/* --- @p_destroy@ --- *
 *
 * Arguments:	@peer *p@ = pointer to a peer
 *
 * Returns:	---
 *
 * Use:		Destroys a peer.
 */

extern void p_destroy(peer */*p*/);

/* --- @FOREACH_PEER@ --- *
 *
 * Arguments:	@p@ = name to bind to each peer
 *		@stuff@ = thing to do for each item
 *
 * Use:		Does something for each current peer.
 */

#define FOREACH_PEER(p, stuff) do {					\
  peer_iter i_;								\
  peer *p;								\
  for (p_mkiter(&i_); (p = p_next(&i_)) != 0; ) stuff			\
} while (0)

/* --- @p_mkiter@ --- *
 *
 * Arguments:	@peer_iter *i@ = pointer to an iterator
 *
 * Returns:	---
 *
 * Use:		Initializes the iterator.
 */

extern void p_mkiter(peer_iter */*i*/);

/* --- @p_next@ --- *
 *
 * Arguments:	@peer_iter *i@ = pointer to an iterator
 *
 * Returns:	Next peer, or null if at the end.
 *
 * Use:		Returns the next peer.
 */

extern peer *p_next(peer_iter */*i*/);

/*----- Tunnel drivers ----------------------------------------------------*/

#ifdef TUN_LINUX
  extern const tunnel_ops tun_linux;
#endif

#ifdef TUN_UNET
  extern const tunnel_ops tun_unet;
#endif

#ifdef TUN_BSD
  extern const tunnel_ops tun_bsd;
#endif

extern const tunnel_ops tun_slip;

/*----- Other handy utilities ---------------------------------------------*/

/* --- @timestr@ --- *
 *
 * Arguments:	@time_t t@ = a time to convert
 *
 * Returns:	A pointer to a textual representation of the time.
 *
 * Use:		Converts a time to a textual representation.  Corrupts
 *		@buf_u@.
 */

extern const char *timestr(time_t /*t*/);

/* --- @mystrieq@ --- *
 *
 * Arguments:	@const char *x, *y@ = two strings
 *
 * Returns:	True if @x@ and @y are equal, up to case.
 */

extern int mystrieq(const char */*x*/, const char */*y*/);

/* --- @addrsz@ --- *
 *
 * Arguments:	@const addr *a@ = a network address
 *
 * Returns:	The size of the address, for passing into the sockets API.
 */

extern socklen_t addrsz(const addr */*a*/);

/* --- @seq_reset@ --- *
 *
 * Arguments:	@seqwin *s@ = sequence-checking window
 *
 * Returns:	---
 *
 * Use:		Resets a sequence number window.
 */

extern void seq_reset(seqwin */*s*/);

/* --- @seq_check@ --- *
 *
 * Arguments:	@seqwin *s@ = sequence-checking window
 *		@uint32 q@ = sequence number to check
 *		@const char *service@ = service to report message from
 *
 * Returns:	A @SEQ_@ code.
 *
 * Use:		Checks a sequence number against the window, updating things
 *		as necessary.
 */

extern int seq_check(seqwin */*s*/, uint32 /*q*/, const char */*service*/);

typedef struct ratelim {
  unsigned n, max, persec;
  struct timeval when;
} ratelim;

/* --- @ratelim_init@ --- *
 *
 * Arguments:	@ratelim *r@ = rate-limiting state to fill in
 *		@unsigned persec@ = credit to accumulate per second
 *		@unsigned max@ = maximum credit to retain
 *
 * Returns:	---
 *
 * Use:		Initialize a rate-limiting state.
 */

extern void ratelim_init(ratelim */*r*/,
			 unsigned /*persec*/, unsigned /*max*/);

/* --- @ratelim_withdraw@ --- *
 *
 * Arguments:	@ratelim *r@ = rate-limiting state
 *		@unsigned n@ = credit to withdraw
 *
 * Returns:	Zero if successful; @-1@ if there is unsufficient credit
 *
 * Use:		Updates the state with any accumulated credit.  Then, if
 *		there there are more than @n@ credits available, withdraw @n@
 *		and return successfully; otherwise, report failure.
 */

extern int ratelim_withdraw(ratelim */*r*/, unsigned /*n*/);

/* --- @ies_encrypt@ --- *
 *
 * Arguments:	@kdata *kpub@ = recipient's public key
 *		@unsigned ty@ = message type octet
 *		@buf *b@ = input message buffer
 *		@buf *bb@ = output buffer for the ciphertext
 *
 * Returns:	On error, returns a @KSERR_...@ code or breaks the buffer;
 *		on success, returns zero and the buffer is good.
 *
 * Use:		Encrypts a message for a recipient, given their public key.
 *		This does not (by itself) provide forward secrecy or sender
 *		authenticity.  The ciphertext is self-delimiting (unlike
 *		@ks_encrypt@).
 */

extern int ies_encrypt(kdata */*kpub*/, unsigned /*ty*/,
		       buf */*b*/, buf */*bb*/);

/* --- @ies_decrypt@ --- *
 *
 * Arguments:	@kdata *kpub@ = private key key
 *		@unsigned ty@ = message type octet
 *		@buf *b@ = input ciphertext buffer
 *		@buf *bb@ = output buffer for the message
 *
 * Returns:	On error, returns a @KSERR_...@ code; on success, returns
 *		zero and the buffer is good.
 *
 * Use:		Decrypts a message encrypted using @ies_encrypt@, given our
 *		private key.
 */

extern int ies_decrypt(kdata */*kpriv*/, unsigned /*ty*/,
		       buf */*b*/, buf */*bb*/);

/*----- That's all, folks -------------------------------------------------*/

#ifdef __cplusplus
  }
#endif

#endif