freebsd-skq/contrib/ntp/ntpd/ntp_crypto.c
roberto 230e76b538 Merge 4.2.4p8 into contrib (r200452 & r200454).
Subversion is being difficult here so take a hammer and get it in.

MFC after:		2 weeks
Security:		CVE-2009-3563
2009-12-15 14:58:10 +00:00

4190 lines
115 KiB
C

/*
* ntp_crypto.c - NTP version 4 public key routines
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#ifdef OPENSSL
#include <stdio.h>
#include <sys/types.h>
#include <sys/param.h>
#include <unistd.h>
#include <fcntl.h>
#include "ntpd.h"
#include "ntp_stdlib.h"
#include "ntp_unixtime.h"
#include "ntp_string.h"
#include <ntp_random.h>
#include "openssl/asn1_mac.h"
#include "openssl/bn.h"
#include "openssl/err.h"
#include "openssl/evp.h"
#include "openssl/pem.h"
#include "openssl/rand.h"
#include "openssl/x509v3.h"
#ifdef KERNEL_PLL
#include "ntp_syscall.h"
#endif /* KERNEL_PLL */
/*
* Extension field message format
*
* These are always signed and saved before sending in network byte
* order. They must be converted to and from host byte order for
* processing.
*
* +-------+-------+
* | op | len | <- extension pointer
* +-------+-------+
* | assocID |
* +---------------+
* | timestamp | <- value pointer
* +---------------+
* | filestamp |
* +---------------+
* | value len |
* +---------------+
* | |
* = value =
* | |
* +---------------+
* | signature len |
* +---------------+
* | |
* = signature =
* | |
* +---------------+
*
* The CRYPTO_RESP bit is set to 0 for requests, 1 for responses.
* Requests carry the association ID of the receiver; responses carry
* the association ID of the sender. Some messages include only the
* operation/length and association ID words and so have length 8
* octets. Ohers include the value structure and associated value and
* signature fields. These messages include the timestamp, filestamp,
* value and signature words and so have length at least 24 octets. The
* signature and/or value fields can be empty, in which case the
* respective length words are zero. An empty value with nonempty
* signature is syntactically valid, but semantically questionable.
*
* The filestamp represents the time when a cryptographic data file such
* as a public/private key pair is created. It follows every reference
* depending on that file and serves as a means to obsolete earlier data
* of the same type. The timestamp represents the time when the
* cryptographic data of the message were last signed. Creation of a
* cryptographic data file or signing a message can occur only when the
* creator or signor is synchronized to an authoritative source and
* proventicated to a trusted authority.
*
* Note there are four conditions required for server trust. First, the
* public key on the certificate must be verified, which involves a
* number of format, content and consistency checks. Next, the server
* identity must be confirmed by one of four schemes: private
* certificate, IFF scheme, GQ scheme or certificate trail hike to a
* self signed trusted certificate. Finally, the server signature must
* be verified.
*/
/*
* Cryptodefines
*/
#define TAI_1972 10 /* initial TAI offset (s) */
#define MAX_LEAP 100 /* max UTC leapseconds (s) */
#define VALUE_LEN (6 * 4) /* min response field length */
#define YEAR (60 * 60 * 24 * 365) /* seconds in year */
/*
* Global cryptodata in host byte order
*/
u_int32 crypto_flags = 0x0; /* status word */
/*
* Global cryptodata in network byte order
*/
struct cert_info *cinfo = NULL; /* certificate info/value */
struct value hostval; /* host value */
struct value pubkey; /* public key */
struct value tai_leap; /* leapseconds table */
EVP_PKEY *iffpar_pkey = NULL; /* IFF parameters */
EVP_PKEY *gqpar_pkey = NULL; /* GQ parameters */
EVP_PKEY *mvpar_pkey = NULL; /* MV parameters */
char *iffpar_file = NULL; /* IFF parameters file */
char *gqpar_file = NULL; /* GQ parameters file */
char *mvpar_file = NULL; /* MV parameters file */
/*
* Private cryptodata in host byte order
*/
static char *passwd = NULL; /* private key password */
static EVP_PKEY *host_pkey = NULL; /* host key */
static EVP_PKEY *sign_pkey = NULL; /* sign key */
static const EVP_MD *sign_digest = NULL; /* sign digest */
static u_int sign_siglen; /* sign key length */
static char *rand_file = NULL; /* random seed file */
static char *host_file = NULL; /* host key file */
static char *sign_file = NULL; /* sign key file */
static char *cert_file = NULL; /* certificate file */
static char *leap_file = NULL; /* leapseconds file */
static tstamp_t if_fstamp = 0; /* IFF filestamp */
static tstamp_t gq_fstamp = 0; /* GQ file stamp */
static tstamp_t mv_fstamp = 0; /* MV filestamp */
static u_int ident_scheme = 0; /* server identity scheme */
/*
* Cryptotypes
*/
static int crypto_verify P((struct exten *, struct value *,
struct peer *));
static int crypto_encrypt P((struct exten *, struct value *,
keyid_t *));
static int crypto_alice P((struct peer *, struct value *));
static int crypto_alice2 P((struct peer *, struct value *));
static int crypto_alice3 P((struct peer *, struct value *));
static int crypto_bob P((struct exten *, struct value *));
static int crypto_bob2 P((struct exten *, struct value *));
static int crypto_bob3 P((struct exten *, struct value *));
static int crypto_iff P((struct exten *, struct peer *));
static int crypto_gq P((struct exten *, struct peer *));
static int crypto_mv P((struct exten *, struct peer *));
static u_int crypto_send P((struct exten *, struct value *));
static tstamp_t crypto_time P((void));
static u_long asn2ntp P((ASN1_TIME *));
static struct cert_info *cert_parse P((u_char *, u_int, tstamp_t));
static int cert_sign P((struct exten *, struct value *));
static int cert_valid P((struct cert_info *, EVP_PKEY *));
static int cert_install P((struct exten *, struct peer *));
static void cert_free P((struct cert_info *));
static EVP_PKEY *crypto_key P((char *, tstamp_t *));
static int bighash P((BIGNUM *, BIGNUM *));
static struct cert_info *crypto_cert P((char *));
static void crypto_tai P((char *));
#ifdef SYS_WINNT
int
readlink(char * link, char * file, int len) {
return (-1);
}
#endif
/*
* session_key - generate session key
*
* This routine generates a session key from the source address,
* destination address, key ID and private value. The value of the
* session key is the MD5 hash of these values, while the next key ID is
* the first four octets of the hash.
*
* Returns the next key ID
*/
keyid_t
session_key(
struct sockaddr_storage *srcadr, /* source address */
struct sockaddr_storage *dstadr, /* destination address */
keyid_t keyno, /* key ID */
keyid_t private, /* private value */
u_long lifetime /* key lifetime */
)
{
EVP_MD_CTX ctx; /* message digest context */
u_char dgst[EVP_MAX_MD_SIZE]; /* message digest */
keyid_t keyid; /* key identifer */
u_int32 header[10]; /* data in network byte order */
u_int hdlen, len;
if (!dstadr)
return 0;
/*
* Generate the session key and key ID. If the lifetime is
* greater than zero, install the key and call it trusted.
*/
hdlen = 0;
switch(srcadr->ss_family) {
case AF_INET:
header[0] = ((struct sockaddr_in *)srcadr)->sin_addr.s_addr;
header[1] = ((struct sockaddr_in *)dstadr)->sin_addr.s_addr;
header[2] = htonl(keyno);
header[3] = htonl(private);
hdlen = 4 * sizeof(u_int32);
break;
case AF_INET6:
memcpy(&header[0], &GET_INADDR6(*srcadr),
sizeof(struct in6_addr));
memcpy(&header[4], &GET_INADDR6(*dstadr),
sizeof(struct in6_addr));
header[8] = htonl(keyno);
header[9] = htonl(private);
hdlen = 10 * sizeof(u_int32);
break;
}
EVP_DigestInit(&ctx, EVP_md5());
EVP_DigestUpdate(&ctx, (u_char *)header, hdlen);
EVP_DigestFinal(&ctx, dgst, &len);
memcpy(&keyid, dgst, 4);
keyid = ntohl(keyid);
if (lifetime != 0) {
MD5auth_setkey(keyno, dgst, len);
authtrust(keyno, lifetime);
}
#ifdef DEBUG
if (debug > 1)
printf(
"session_key: %s > %s %08x %08x hash %08x life %lu\n",
stoa(srcadr), stoa(dstadr), keyno,
private, keyid, lifetime);
#endif
return (keyid);
}
/*
* make_keylist - generate key list
*
* Returns
* XEVNT_OK success
* XEVNT_PER host certificate expired
*
* This routine constructs a pseudo-random sequence by repeatedly
* hashing the session key starting from a given source address,
* destination address, private value and the next key ID of the
* preceeding session key. The last entry on the list is saved along
* with its sequence number and public signature.
*/
int
make_keylist(
struct peer *peer, /* peer structure pointer */
struct interface *dstadr /* interface */
)
{
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp; /* NTP timestamp */
struct autokey *ap; /* autokey pointer */
struct value *vp; /* value pointer */
keyid_t keyid = 0; /* next key ID */
keyid_t cookie; /* private value */
u_long lifetime;
u_int len, mpoll;
int i;
if (!dstadr)
return XEVNT_OK;
/*
* Allocate the key list if necessary.
*/
tstamp = crypto_time();
if (peer->keylist == NULL)
peer->keylist = emalloc(sizeof(keyid_t) *
NTP_MAXSESSION);
/*
* Generate an initial key ID which is unique and greater than
* NTP_MAXKEY.
*/
while (1) {
keyid = (ntp_random() + NTP_MAXKEY + 1) & ((1 <<
sizeof(keyid_t)) - 1);
if (authhavekey(keyid))
continue;
break;
}
/*
* Generate up to NTP_MAXSESSION session keys. Stop if the
* next one would not be unique or not a session key ID or if
* it would expire before the next poll. The private value
* included in the hash is zero if broadcast mode, the peer
* cookie if client mode or the host cookie if symmetric modes.
*/
mpoll = 1 << min(peer->ppoll, peer->hpoll);
lifetime = min(sys_automax, NTP_MAXSESSION * mpoll);
if (peer->hmode == MODE_BROADCAST)
cookie = 0;
else
cookie = peer->pcookie;
for (i = 0; i < NTP_MAXSESSION; i++) {
peer->keylist[i] = keyid;
peer->keynumber = i;
keyid = session_key(&dstadr->sin, &peer->srcadr, keyid,
cookie, lifetime);
lifetime -= mpoll;
if (auth_havekey(keyid) || keyid <= NTP_MAXKEY ||
lifetime <= mpoll)
break;
}
/*
* Save the last session key ID, sequence number and timestamp,
* then sign these values for later retrieval by the clients. Be
* careful not to use invalid key media. Use the public values
* timestamp as filestamp.
*/
vp = &peer->sndval;
if (vp->ptr == NULL)
vp->ptr = emalloc(sizeof(struct autokey));
ap = (struct autokey *)vp->ptr;
ap->seq = htonl(peer->keynumber);
ap->key = htonl(keyid);
vp->tstamp = htonl(tstamp);
vp->fstamp = hostval.tstamp;
vp->vallen = htonl(sizeof(struct autokey));
vp->siglen = 0;
if (tstamp != 0) {
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
if (vp->sig == NULL)
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)vp, 12);
EVP_SignUpdate(&ctx, vp->ptr, sizeof(struct autokey));
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
else
msyslog(LOG_ERR, "make_keys %s\n",
ERR_error_string(ERR_get_error(), NULL));
peer->flags |= FLAG_ASSOC;
}
#ifdef DEBUG
if (debug)
printf("make_keys: %d %08x %08x ts %u fs %u poll %d\n",
ntohl(ap->seq), ntohl(ap->key), cookie,
ntohl(vp->tstamp), ntohl(vp->fstamp), peer->hpoll);
#endif
return (XEVNT_OK);
}
/*
* crypto_recv - parse extension fields
*
* This routine is called when the packet has been matched to an
* association and passed sanity, format and MAC checks. We believe the
* extension field values only if the field has proper format and
* length, the timestamp and filestamp are valid and the signature has
* valid length and is verified. There are a few cases where some values
* are believed even if the signature fails, but only if the proventic
* bit is not set.
*/
int
crypto_recv(
struct peer *peer, /* peer structure pointer */
struct recvbuf *rbufp /* packet buffer pointer */
)
{
const EVP_MD *dp; /* message digest algorithm */
u_int32 *pkt; /* receive packet pointer */
struct autokey *ap, *bp; /* autokey pointer */
struct exten *ep, *fp; /* extension pointers */
int has_mac; /* length of MAC field */
int authlen; /* offset of MAC field */
associd_t associd; /* association ID */
tstamp_t tstamp = 0; /* timestamp */
tstamp_t fstamp = 0; /* filestamp */
u_int len; /* extension field length */
u_int code; /* extension field opcode */
u_int vallen = 0; /* value length */
X509 *cert; /* X509 certificate */
char statstr[NTP_MAXSTRLEN]; /* statistics for filegen */
keyid_t cookie; /* crumbles */
int hismode; /* packet mode */
int rval = XEVNT_OK;
u_char *ptr;
u_int32 temp32;
/*
* Initialize. Note that the packet has already been checked for
* valid format and extension field lengths. First extract the
* field length, command code and association ID in host byte
* order. These are used with all commands and modes. Then check
* the version number, which must be 2, and length, which must
* be at least 8 for requests and VALUE_LEN (24) for responses.
* Packets that fail either test sink without a trace. The
* association ID is saved only if nonzero.
*/
authlen = LEN_PKT_NOMAC;
hismode = (int)PKT_MODE((&rbufp->recv_pkt)->li_vn_mode);
while ((has_mac = rbufp->recv_length - authlen) > MAX_MAC_LEN) {
pkt = (u_int32 *)&rbufp->recv_pkt + authlen / 4;
ep = (struct exten *)pkt;
code = ntohl(ep->opcode) & 0xffff0000;
len = ntohl(ep->opcode) & 0x0000ffff;
associd = (associd_t) ntohl(pkt[1]);
rval = XEVNT_OK;
#ifdef DEBUG
if (debug)
printf(
"crypto_recv: flags 0x%x ext offset %d len %u code 0x%x assocID %d\n",
peer->crypto, authlen, len, code >> 16,
associd);
#endif
/*
* Check version number and field length. If bad,
* quietly ignore the packet.
*/
if (((code >> 24) & 0x3f) != CRYPTO_VN || len < 8) {
sys_unknownversion++;
code |= CRYPTO_ERROR;
}
/*
* Little vulnerability bandage here. If a perp tosses a
* fake association ID over the fence, we better toss it
* out. Only the first one counts.
*/
if (code & CRYPTO_RESP) {
if (peer->assoc == 0)
peer->assoc = associd;
else if (peer->assoc != associd)
code |= CRYPTO_ERROR;
}
if (len >= VALUE_LEN) {
tstamp = ntohl(ep->tstamp);
fstamp = ntohl(ep->fstamp);
vallen = ntohl(ep->vallen);
}
switch (code) {
/*
* Install status word, host name, signature scheme and
* association ID. In OpenSSL the signature algorithm is
* bound to the digest algorithm, so the NID completely
* defines the signature scheme. Note the request and
* response are identical, but neither is validated by
* signature. The request is processed here only in
* symmetric modes. The server name field might be
* useful to implement access controls in future.
*/
case CRYPTO_ASSOC:
/*
* If the machine is running when this message
* arrives, the other fellow has reset and so
* must we. Otherwise, pass the extension field
* to the transmit side.
*/
if (peer->crypto) {
rval = XEVNT_ERR;
break;
}
fp = emalloc(len);
memcpy(fp, ep, len);
temp32 = CRYPTO_RESP;
fp->opcode |= htonl(temp32);
peer->cmmd = fp;
/* fall through */
case CRYPTO_ASSOC | CRYPTO_RESP:
/*
* Discard the message if it has already been
* stored or the message has been amputated.
*/
if (peer->crypto)
break;
if (vallen == 0 || vallen > MAXHOSTNAME ||
len < VALUE_LEN + vallen) {
rval = XEVNT_LEN;
break;
}
/*
* Check the identity schemes are compatible. If
* the client has PC, the server must have PC,
* in which case the server public key and
* identity are presumed valid, so we skip the
* certificate and identity exchanges and move
* immediately to the cookie exchange which
* confirms the server signature.
*/
#ifdef DEBUG
if (debug)
printf(
"crypto_recv: ident host 0x%x server 0x%x\n",
crypto_flags, fstamp);
#endif
temp32 = (crypto_flags | ident_scheme) &
fstamp & CRYPTO_FLAG_MASK;
if (crypto_flags & CRYPTO_FLAG_PRIV) {
if (!(fstamp & CRYPTO_FLAG_PRIV)) {
rval = XEVNT_KEY;
break;
} else {
fstamp |= CRYPTO_FLAG_VALID |
CRYPTO_FLAG_VRFY |
CRYPTO_FLAG_SIGN;
}
/*
* In symmetric modes it is an error if either
* peer requests identity and the other peer
* does not support it.
*/
} else if ((hismode == MODE_ACTIVE || hismode ==
MODE_PASSIVE) && ((crypto_flags | fstamp) &
CRYPTO_FLAG_MASK) && !temp32) {
rval = XEVNT_KEY;
break;
/*
* It is an error if the client requests
* identity and the server does not support it.
*/
} else if (hismode == MODE_CLIENT && (fstamp &
CRYPTO_FLAG_MASK) && !temp32) {
rval = XEVNT_KEY;
break;
}
/*
* Otherwise, the identity scheme(s) are those
* that both client and server support.
*/
fstamp = temp32 | (fstamp & ~CRYPTO_FLAG_MASK);
/*
* Discard the message if the signature digest
* NID is not supported.
*/
temp32 = (fstamp >> 16) & 0xffff;
dp =
(const EVP_MD *)EVP_get_digestbynid(temp32);
if (dp == NULL) {
rval = XEVNT_MD;
break;
}
/*
* Save status word, host name and message
* digest/signature type.
*/
peer->crypto = fstamp;
peer->digest = dp;
peer->subject = emalloc(vallen + 1);
memcpy(peer->subject, ep->pkt, vallen);
peer->subject[vallen] = '\0';
peer->issuer = emalloc(vallen + 1);
strcpy(peer->issuer, peer->subject);
temp32 = (fstamp >> 16) & 0xffff;
snprintf(statstr, NTP_MAXSTRLEN,
"flags 0x%x host %s signature %s", fstamp,
peer->subject, OBJ_nid2ln(temp32));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Decode X509 certificate in ASN.1 format and extract
* the data containing, among other things, subject
* name and public key. In the default identification
* scheme, the certificate trail is followed to a self
* signed trusted certificate.
*/
case CRYPTO_CERT | CRYPTO_RESP:
/*
* Discard the message if invalid.
*/
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* Scan the certificate list to delete old
* versions and link the newest version first on
* the list.
*/
if ((rval = cert_install(ep, peer)) != XEVNT_OK)
break;
/*
* If we snatch the certificate before the
* server certificate has been signed by its
* server, it will be self signed. When it is,
* we chase the certificate issuer, which the
* server has, and keep going until a self
* signed trusted certificate is found. Be sure
* to update the issuer field, since it may
* change.
*/
if (peer->issuer != NULL)
free(peer->issuer);
peer->issuer = emalloc(strlen(cinfo->issuer) +
1);
strcpy(peer->issuer, cinfo->issuer);
/*
* We plug in the public key and lifetime from
* the first certificate received. However, note
* that this certificate might not be signed by
* the server, so we can't check the
* signature/digest NID.
*/
if (peer->pkey == NULL) {
ptr = (u_char *)cinfo->cert.ptr;
cert = d2i_X509(NULL, &ptr,
ntohl(cinfo->cert.vallen));
peer->pkey = X509_get_pubkey(cert);
X509_free(cert);
}
peer->flash &= ~TEST8;
temp32 = cinfo->nid;
snprintf(statstr, NTP_MAXSTRLEN,
"cert %s 0x%x %s (%u) fs %u",
cinfo->subject, cinfo->flags,
OBJ_nid2ln(temp32), temp32,
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Schnorr (IFF)identity scheme. This scheme is designed
* for use with shared secret group keys and where the
* certificate may be generated by a third party. The
* client sends a challenge to the server, which
* performs a calculation and returns the result. A
* positive result is possible only if both client and
* server contain the same secret group key.
*/
case CRYPTO_IFF | CRYPTO_RESP:
/*
* Discard the message if invalid or certificate
* trail not trusted.
*/
if (!(peer->crypto & CRYPTO_FLAG_VALID)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* If the the challenge matches the response,
* the certificate public key, as well as the
* server public key, signatyre and identity are
* all verified at the same time. The server is
* declared trusted, so we skip further
* certificate stages and move immediately to
* the cookie stage.
*/
if ((rval = crypto_iff(ep, peer)) != XEVNT_OK)
break;
peer->crypto |= CRYPTO_FLAG_VRFY |
CRYPTO_FLAG_PROV;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN, "iff fs %u",
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Guillou-Quisquater (GQ) identity scheme. This scheme
* is designed for use with public certificates carrying
* the GQ public key in an extension field. The client
* sends a challenge to the server, which performs a
* calculation and returns the result. A positive result
* is possible only if both client and server contain
* the same group key and the server has the matching GQ
* private key.
*/
case CRYPTO_GQ | CRYPTO_RESP:
/*
* Discard the message if invalid or certificate
* trail not trusted.
*/
if (!(peer->crypto & CRYPTO_FLAG_VALID)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* If the the challenge matches the response,
* the certificate public key, as well as the
* server public key, signatyre and identity are
* all verified at the same time. The server is
* declared trusted, so we skip further
* certificate stages and move immediately to
* the cookie stage.
*/
if ((rval = crypto_gq(ep, peer)) != XEVNT_OK)
break;
peer->crypto |= CRYPTO_FLAG_VRFY |
CRYPTO_FLAG_PROV;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN, "gq fs %u",
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* MV
*/
case CRYPTO_MV | CRYPTO_RESP:
/*
* Discard the message if invalid or certificate
* trail not trusted.
*/
if (!(peer->crypto & CRYPTO_FLAG_VALID)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* If the the challenge matches the response,
* the certificate public key, as well as the
* server public key, signatyre and identity are
* all verified at the same time. The server is
* declared trusted, so we skip further
* certificate stages and move immediately to
* the cookie stage.
*/
if ((rval = crypto_mv(ep, peer)) != XEVNT_OK)
break;
peer->crypto |= CRYPTO_FLAG_VRFY |
CRYPTO_FLAG_PROV;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN, "mv fs %u",
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Cookie request in symmetric modes. Roll a random
* cookie and install in symmetric mode. Encrypt for the
* response, which is transmitted later.
*/
case CRYPTO_COOK:
/*
* Discard the message if invalid or certificate
* trail not trusted.
*/
if (!(peer->crypto & CRYPTO_FLAG_VALID)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* Pass the extension field to the transmit
* side. If already agreed, walk away.
*/
fp = emalloc(len);
memcpy(fp, ep, len);
temp32 = CRYPTO_RESP;
fp->opcode |= htonl(temp32);
peer->cmmd = fp;
if (peer->crypto & CRYPTO_FLAG_AGREE) {
peer->flash &= ~TEST8;
break;
}
/*
* Install cookie values and light the cookie
* bit. The transmit side will pick up and
* encrypt it for the response.
*/
key_expire(peer);
peer->cookval.tstamp = ep->tstamp;
peer->cookval.fstamp = ep->fstamp;
RAND_bytes((u_char *)&peer->pcookie, 4);
peer->crypto &= ~CRYPTO_FLAG_AUTO;
peer->crypto |= CRYPTO_FLAG_AGREE;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN, "cook %x ts %u fs %u",
peer->pcookie, ntohl(ep->tstamp),
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Cookie response in client and symmetric modes. If the
* cookie bit is set, the working cookie is the EXOR of
* the current and new values.
*/
case CRYPTO_COOK | CRYPTO_RESP:
/*
* Discard the message if invalid or identity
* not confirmed or signature not verified with
* respect to the cookie values.
*/
if (!(peer->crypto & CRYPTO_FLAG_VRFY)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, &peer->cookval,
peer)) != XEVNT_OK)
break;
/*
* Decrypt the cookie, hunting all the time for
* errors.
*/
if (vallen == (u_int) EVP_PKEY_size(host_pkey)) {
RSA_private_decrypt(vallen,
(u_char *)ep->pkt,
(u_char *)&temp32,
host_pkey->pkey.rsa,
RSA_PKCS1_OAEP_PADDING);
cookie = ntohl(temp32);
} else {
rval = XEVNT_CKY;
break;
}
/*
* Install cookie values and light the cookie
* bit. If this is not broadcast client mode, we
* are done here.
*/
key_expire(peer);
peer->cookval.tstamp = ep->tstamp;
peer->cookval.fstamp = ep->fstamp;
if (peer->crypto & CRYPTO_FLAG_AGREE)
peer->pcookie ^= cookie;
else
peer->pcookie = cookie;
if (peer->hmode == MODE_CLIENT &&
!(peer->cast_flags & MDF_BCLNT))
peer->crypto |= CRYPTO_FLAG_AUTO;
else
peer->crypto &= ~CRYPTO_FLAG_AUTO;
peer->crypto |= CRYPTO_FLAG_AGREE;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN, "cook %x ts %u fs %u",
peer->pcookie, ntohl(ep->tstamp),
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Install autokey values in broadcast client and
* symmetric modes. We have to do this every time the
* sever/peer cookie changes or a new keylist is
* rolled. Ordinarily, this is automatic as this message
* is piggybacked on the first NTP packet sent upon
* either of these events. Note that a broadcast client
* or symmetric peer can receive this response without a
* matching request.
*/
case CRYPTO_AUTO | CRYPTO_RESP:
/*
* Discard the message if invalid or identity
* not confirmed or signature not verified with
* respect to the receive autokey values.
*/
if (!(peer->crypto & CRYPTO_FLAG_VRFY)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, &peer->recval,
peer)) != XEVNT_OK)
break;
/*
* Install autokey values and light the
* autokey bit. This is not hard.
*/
if (peer->recval.ptr == NULL)
peer->recval.ptr =
emalloc(sizeof(struct autokey));
bp = (struct autokey *)peer->recval.ptr;
peer->recval.tstamp = ep->tstamp;
peer->recval.fstamp = ep->fstamp;
ap = (struct autokey *)ep->pkt;
bp->seq = ntohl(ap->seq);
bp->key = ntohl(ap->key);
peer->pkeyid = bp->key;
peer->crypto |= CRYPTO_FLAG_AUTO;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN,
"auto seq %d key %x ts %u fs %u", bp->seq,
bp->key, ntohl(ep->tstamp),
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* X509 certificate sign response. Validate the
* certificate signed by the server and install. Later
* this can be provided to clients of this server in
* lieu of the self signed certificate in order to
* validate the public key.
*/
case CRYPTO_SIGN | CRYPTO_RESP:
/*
* Discard the message if invalid or not
* proventic.
*/
if (!(peer->crypto & CRYPTO_FLAG_PROV)) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* Scan the certificate list to delete old
* versions and link the newest version first on
* the list.
*/
if ((rval = cert_install(ep, peer)) != XEVNT_OK)
break;
peer->crypto |= CRYPTO_FLAG_SIGN;
peer->flash &= ~TEST8;
temp32 = cinfo->nid;
snprintf(statstr, NTP_MAXSTRLEN,
"sign %s 0x%x %s (%u) fs %u",
cinfo->issuer, cinfo->flags,
OBJ_nid2ln(temp32), temp32,
ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* Install leapseconds table in symmetric modes. This
* table is proventicated to the NIST primary servers,
* either by copying the file containing the table from
* a NIST server to a trusted server or directly using
* this protocol. While the entire table is installed at
* the server, presently only the current TAI offset is
* provided via the kernel to other applications.
*/
case CRYPTO_TAI:
/*
* Discard the message if invalid.
*/
if ((rval = crypto_verify(ep, NULL, peer)) !=
XEVNT_OK)
break;
/*
* Pass the extension field to the transmit
* side. Continue below if a leapseconds table
* accompanies the message.
*/
fp = emalloc(len);
memcpy(fp, ep, len);
temp32 = CRYPTO_RESP;
fp->opcode |= htonl(temp32);
peer->cmmd = fp;
if (len <= VALUE_LEN) {
peer->flash &= ~TEST8;
break;
}
/* fall through */
case CRYPTO_TAI | CRYPTO_RESP:
/*
* If this is a response, discard the message if
* signature not verified with respect to the
* leapsecond table values.
*/
if (peer->cmmd == NULL) {
if ((rval = crypto_verify(ep,
&peer->tai_leap, peer)) != XEVNT_OK)
break;
}
/*
* Initialize peer variables with latest update.
*/
peer->tai_leap.tstamp = ep->tstamp;
peer->tai_leap.fstamp = ep->fstamp;
peer->tai_leap.vallen = ep->vallen;
/*
* Install the new table if there is no stored
* table or the new table is more recent than
* the stored table. Since a filestamp may have
* changed, recompute the signatures.
*/
if (ntohl(peer->tai_leap.fstamp) >
ntohl(tai_leap.fstamp)) {
tai_leap.fstamp = ep->fstamp;
tai_leap.vallen = ep->vallen;
if (tai_leap.ptr != NULL)
free(tai_leap.ptr);
tai_leap.ptr = emalloc(vallen);
memcpy(tai_leap.ptr, ep->pkt, vallen);
crypto_update();
}
crypto_flags |= CRYPTO_FLAG_TAI;
peer->crypto |= CRYPTO_FLAG_LEAP;
peer->flash &= ~TEST8;
snprintf(statstr, NTP_MAXSTRLEN,
"leap %u ts %u fs %u", vallen,
ntohl(ep->tstamp), ntohl(ep->fstamp));
record_crypto_stats(&peer->srcadr, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
/*
* We come here in symmetric modes for miscellaneous
* commands that have value fields but are processed on
* the transmit side. All we need do here is check for
* valid field length. Remaining checks are below and on
* the transmit side.
*/
case CRYPTO_CERT:
case CRYPTO_IFF:
case CRYPTO_GQ:
case CRYPTO_MV:
case CRYPTO_SIGN:
if (len < VALUE_LEN) {
rval = XEVNT_LEN;
break;
}
/* fall through */
/*
* We come here for miscellaneous requests and unknown
* requests and responses. If an unknown response or
* error, forget it. If a request, save the extension
* field for later. Unknown requests will be caught on
* the transmit side.
*/
default:
if (code & (CRYPTO_RESP | CRYPTO_ERROR)) {
rval = XEVNT_ERR;
} else if ((rval = crypto_verify(ep, NULL,
peer)) == XEVNT_OK) {
fp = emalloc(len);
memcpy(fp, ep, len);
temp32 = CRYPTO_RESP;
fp->opcode |= htonl(temp32);
peer->cmmd = fp;
}
}
/*
* We don't log length/format/timestamp errors and
* duplicates, which are log clogging vulnerabilities.
* The first error found terminates the extension field
* scan and we return the laundry to the caller. A
* length/format/timestamp error on transmit is
* cheerfully ignored, as the message is not sent.
*/
if (rval > XEVNT_TSP) {
snprintf(statstr, NTP_MAXSTRLEN,
"error %x opcode %x ts %u fs %u", rval,
code, tstamp, fstamp);
record_crypto_stats(&peer->srcadr, statstr);
report_event(rval, peer);
#ifdef DEBUG
if (debug)
printf("crypto_recv: %s\n", statstr);
#endif
break;
} else if (rval > XEVNT_OK && (code & CRYPTO_RESP)) {
rval = XEVNT_OK;
}
authlen += len;
}
return (rval);
}
/*
* crypto_xmit - construct extension fields
*
* This routine is called both when an association is configured and
* when one is not. The only case where this matters is to retrieve the
* autokey information, in which case the caller has to provide the
* association ID to match the association.
*
* Returns length of extension field.
*/
int
crypto_xmit(
struct pkt *xpkt, /* transmit packet pointer */
struct sockaddr_storage *srcadr_sin, /* active runway */
int start, /* offset to extension field */
struct exten *ep, /* extension pointer */
keyid_t cookie /* session cookie */
)
{
u_int32 *pkt; /* packet pointer */
struct peer *peer; /* peer structure pointer */
u_int opcode; /* extension field opcode */
struct exten *fp; /* extension pointers */
struct cert_info *cp, *xp; /* certificate info/value pointer */
char certname[MAXHOSTNAME + 1]; /* subject name buffer */
char statstr[NTP_MAXSTRLEN]; /* statistics for filegen */
tstamp_t tstamp;
u_int vallen;
u_int len;
struct value vtemp;
associd_t associd;
int rval;
keyid_t tcookie;
/*
* Generate the requested extension field request code, length
* and association ID. If this is a response and the host is not
* synchronized, light the error bit and go home.
*/
pkt = (u_int32 *)xpkt + start / 4;
fp = (struct exten *)pkt;
opcode = ntohl(ep->opcode);
associd = (associd_t) ntohl(ep->associd);
fp->associd = htonl(associd);
len = 8;
rval = XEVNT_OK;
tstamp = crypto_time();
switch (opcode & 0xffff0000) {
/*
* Send association request and response with status word and
* host name. Note, this message is not signed and the filestamp
* contains only the status word.
*/
case CRYPTO_ASSOC | CRYPTO_RESP:
len += crypto_send(fp, &hostval);
fp->fstamp = htonl(crypto_flags);
break;
case CRYPTO_ASSOC:
len += crypto_send(fp, &hostval);
fp->fstamp = htonl(crypto_flags | ident_scheme);
break;
/*
* Send certificate request. Use the values from the extension
* field.
*/
case CRYPTO_CERT:
memset(&vtemp, 0, sizeof(vtemp));
vtemp.tstamp = ep->tstamp;
vtemp.fstamp = ep->fstamp;
vtemp.vallen = ep->vallen;
vtemp.ptr = (u_char *)ep->pkt;
len += crypto_send(fp, &vtemp);
break;
/*
* Send certificate response or sign request. Use the values
* from the certificate cache. If the request contains no
* subject name, assume the name of this host. This is for
* backwards compatibility. Private certificates are never sent.
*/
case CRYPTO_SIGN:
case CRYPTO_CERT | CRYPTO_RESP:
vallen = ntohl(ep->vallen);
if (vallen == 8) {
strcpy(certname, sys_hostname);
} else if (vallen == 0 || vallen > MAXHOSTNAME) {
rval = XEVNT_LEN;
break;
} else {
memcpy(certname, ep->pkt, vallen);
certname[vallen] = '\0';
}
/*
* Find all certificates with matching subject. If a
* self-signed, trusted certificate is found, use that.
* If not, use the first one with matching subject. A
* private certificate is never divulged or signed.
*/
xp = NULL;
for (cp = cinfo; cp != NULL; cp = cp->link) {
if (cp->flags & CERT_PRIV)
continue;
if (strcmp(certname, cp->subject) == 0) {
if (xp == NULL)
xp = cp;
if (strcmp(certname, cp->issuer) ==
0 && cp->flags & CERT_TRUST) {
xp = cp;
break;
}
}
}
/*
* Be careful who you trust. If not yet synchronized,
* give back an empty response. If certificate not found
* or beyond the lifetime, return an error. This is to
* avoid a bad dude trying to get an expired certificate
* re-signed. Otherwise, send it.
*
* Note the timestamp and filestamp are taken from the
* certificate value structure. For all certificates the
* timestamp is the latest signature update time. For
* host and imported certificates the filestamp is the
* creation epoch. For signed certificates the filestamp
* is the creation epoch of the trusted certificate at
* the base of the certificate trail. In principle, this
* allows strong checking for signature masquerade.
*/
if (tstamp == 0)
break;
if (xp == NULL)
rval = XEVNT_CRT;
else if (tstamp < xp->first || tstamp > xp->last)
rval = XEVNT_SRV;
else
len += crypto_send(fp, &xp->cert);
break;
/*
* Send challenge in Schnorr (IFF) identity scheme.
*/
case CRYPTO_IFF:
if ((peer = findpeerbyassoc(ep->pkt[0])) == NULL) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_alice(peer, &vtemp)) == XEVNT_OK) {
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
}
break;
/*
* Send response in Schnorr (IFF) identity scheme.
*/
case CRYPTO_IFF | CRYPTO_RESP:
if ((rval = crypto_bob(ep, &vtemp)) == XEVNT_OK) {
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
}
break;
/*
* Send challenge in Guillou-Quisquater (GQ) identity scheme.
*/
case CRYPTO_GQ:
if ((peer = findpeerbyassoc(ep->pkt[0])) == NULL) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_alice2(peer, &vtemp)) == XEVNT_OK) {
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
}
break;
/*
* Send response in Guillou-Quisquater (GQ) identity scheme.
*/
case CRYPTO_GQ | CRYPTO_RESP:
if ((rval = crypto_bob2(ep, &vtemp)) == XEVNT_OK) {
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
}
break;
/*
* Send challenge in MV identity scheme.
*/
case CRYPTO_MV:
if ((peer = findpeerbyassoc(ep->pkt[0])) == NULL) {
rval = XEVNT_ERR;
break;
}
if ((rval = crypto_alice3(peer, &vtemp)) == XEVNT_OK) {
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
}
break;
/*
* Send response in MV identity scheme.
*/
case CRYPTO_MV | CRYPTO_RESP:
if ((rval = crypto_bob3(ep, &vtemp)) == XEVNT_OK) {
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
}
break;
/*
* Send certificate sign response. The integrity of the request
* certificate has already been verified on the receive side.
* Sign the response using the local server key. Use the
* filestamp from the request and use the timestamp as the
* current time. Light the error bit if the certificate is
* invalid or contains an unverified signature.
*/
case CRYPTO_SIGN | CRYPTO_RESP:
if ((rval = cert_sign(ep, &vtemp)) == XEVNT_OK)
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
break;
/*
* Send public key and signature. Use the values from the public
* key.
*/
case CRYPTO_COOK:
len += crypto_send(fp, &pubkey);
break;
/*
* Encrypt and send cookie and signature. Light the error bit if
* anything goes wrong.
*/
case CRYPTO_COOK | CRYPTO_RESP:
if ((opcode & 0xffff) < VALUE_LEN) {
rval = XEVNT_LEN;
break;
}
if (PKT_MODE(xpkt->li_vn_mode) == MODE_SERVER) {
tcookie = cookie;
} else {
if ((peer = findpeerbyassoc(associd)) == NULL) {
rval = XEVNT_ERR;
break;
}
tcookie = peer->pcookie;
}
if ((rval = crypto_encrypt(ep, &vtemp, &tcookie)) ==
XEVNT_OK)
len += crypto_send(fp, &vtemp);
value_free(&vtemp);
break;
/*
* Find peer and send autokey data and signature in broadcast
* server and symmetric modes. Use the values in the autokey
* structure. If no association is found, either the server has
* restarted with new associations or some perp has replayed an
* old message, in which case light the error bit.
*/
case CRYPTO_AUTO | CRYPTO_RESP:
if ((peer = findpeerbyassoc(associd)) == NULL) {
rval = XEVNT_ERR;
break;
}
peer->flags &= ~FLAG_ASSOC;
len += crypto_send(fp, &peer->sndval);
break;
/*
* Send leapseconds table and signature. Use the values from the
* tai structure. If no table has been loaded, just send an
* empty request.
*/
case CRYPTO_TAI:
case CRYPTO_TAI | CRYPTO_RESP:
if (crypto_flags & CRYPTO_FLAG_TAI)
len += crypto_send(fp, &tai_leap);
break;
/*
* Default - Fall through for requests; for unknown responses,
* flag as error.
*/
default:
if (opcode & CRYPTO_RESP)
rval = XEVNT_ERR;
}
/*
* In case of error, flame the log. If a request, toss the
* puppy; if a response, return so the sender can flame, too.
*/
if (rval != XEVNT_OK) {
opcode |= CRYPTO_ERROR;
snprintf(statstr, NTP_MAXSTRLEN,
"error %x opcode %x", rval, opcode);
record_crypto_stats(srcadr_sin, statstr);
report_event(rval, NULL);
#ifdef DEBUG
if (debug)
printf("crypto_xmit: %s\n", statstr);
#endif
if (!(opcode & CRYPTO_RESP))
return (0);
}
/*
* Round up the field length to a multiple of 8 bytes and save
* the request code and length.
*/
len = ((len + 7) / 8) * 8;
fp->opcode = htonl((opcode & 0xffff0000) | len);
#ifdef DEBUG
if (debug)
printf(
"crypto_xmit: flags 0x%x ext offset %d len %u code 0x%x assocID %d\n",
crypto_flags, start, len, opcode >> 16, associd);
#endif
return (len);
}
/*
* crypto_verify - parse and verify the extension field and value
*
* Returns
* XEVNT_OK success
* XEVNT_LEN bad field format or length
* XEVNT_TSP bad timestamp
* XEVNT_FSP bad filestamp
* XEVNT_PUB bad or missing public key
* XEVNT_SGL bad signature length
* XEVNT_SIG signature not verified
* XEVNT_ERR protocol error
*/
static int
crypto_verify(
struct exten *ep, /* extension pointer */
struct value *vp, /* value pointer */
struct peer *peer /* peer structure pointer */
)
{
EVP_PKEY *pkey; /* server public key */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp, tstamp1 = 0; /* timestamp */
tstamp_t fstamp, fstamp1 = 0; /* filestamp */
u_int vallen; /* value length */
u_int siglen; /* signature length */
u_int opcode, len;
int i;
/*
* We require valid opcode and field lengths, timestamp,
* filestamp, public key, digest, signature length and
* signature, where relevant. Note that preliminary length
* checks are done in the main loop.
*/
len = ntohl(ep->opcode) & 0x0000ffff;
opcode = ntohl(ep->opcode) & 0xffff0000;
/*
* Check for valid operation code and protocol. The opcode must
* not have the error bit set. If a response, it must have a
* value header. If a request and does not contain a value
* header, no need for further checking.
*/
if (opcode & CRYPTO_ERROR)
return (XEVNT_ERR);
if (opcode & CRYPTO_RESP) {
if (len < VALUE_LEN)
return (XEVNT_LEN);
} else {
if (len < VALUE_LEN)
return (XEVNT_OK);
}
/*
* We have a value header. Check for valid field lengths. The
* field length must be long enough to contain the value header,
* value and signature. Note both the value and signature fields
* are rounded up to the next word.
*/
vallen = ntohl(ep->vallen);
i = (vallen + 3) / 4;
siglen = ntohl(ep->pkt[i++]);
if (len < VALUE_LEN + ((vallen + 3) / 4) * 4 + ((siglen + 3) /
4) * 4)
return (XEVNT_LEN);
/*
* Punt if this is a response with no data. Punt if this is a
* request and a previous response is pending.
*/
if (opcode & CRYPTO_RESP) {
if (vallen == 0)
return (XEVNT_LEN);
} else {
if (peer->cmmd != NULL)
return (XEVNT_LEN);
}
/*
* Check for valid timestamp and filestamp. If the timestamp is
* zero, the sender is not synchronized and signatures are
* disregarded. If not, the timestamp must not precede the
* filestamp. The timestamp and filestamp must not precede the
* corresponding values in the value structure, if present. Once
* the autokey values have been installed, the timestamp must
* always be later than the corresponding value in the value
* structure. Duplicate timestamps are illegal once the cookie
* has been validated.
*/
tstamp = ntohl(ep->tstamp);
fstamp = ntohl(ep->fstamp);
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < fstamp)
return (XEVNT_TSP);
if (vp != NULL) {
tstamp1 = ntohl(vp->tstamp);
fstamp1 = ntohl(vp->fstamp);
if ((tstamp < tstamp1 || (tstamp == tstamp1 &&
(peer->crypto & CRYPTO_FLAG_AUTO))))
return (XEVNT_TSP);
if ((tstamp < fstamp1 || fstamp < fstamp1))
return (XEVNT_FSP);
}
/*
* Check for valid signature length, public key and digest
* algorithm.
*/
if (crypto_flags & peer->crypto & CRYPTO_FLAG_PRIV)
pkey = sign_pkey;
else
pkey = peer->pkey;
if (siglen == 0 || pkey == NULL || peer->digest == NULL)
return (XEVNT_OK);
if (siglen != (u_int)EVP_PKEY_size(pkey))
return (XEVNT_SGL);
/*
* Darn, I thought we would never get here. Verify the
* signature. If the identity exchange is verified, light the
* proventic bit. If no client identity scheme is specified,
* avoid doing the sign exchange.
*/
EVP_VerifyInit(&ctx, peer->digest);
EVP_VerifyUpdate(&ctx, (u_char *)&ep->tstamp, vallen + 12);
if (EVP_VerifyFinal(&ctx, (u_char *)&ep->pkt[i], siglen, pkey) <= 0)
return (XEVNT_SIG);
if (peer->crypto & CRYPTO_FLAG_VRFY) {
peer->crypto |= CRYPTO_FLAG_PROV;
if (!(crypto_flags & CRYPTO_FLAG_MASK))
peer->crypto |= CRYPTO_FLAG_SIGN;
}
return (XEVNT_OK);
}
/*
* crypto_encrypt - construct encrypted cookie and signature from
* extension field and cookie
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_CKY bad or missing cookie
* XEVNT_PER host certificate expired
*/
static int
crypto_encrypt(
struct exten *ep, /* extension pointer */
struct value *vp, /* value pointer */
keyid_t *cookie /* server cookie */
)
{
EVP_PKEY *pkey; /* public key */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp; /* NTP timestamp */
u_int32 temp32;
u_int len;
u_char *ptr;
/*
* Extract the public key from the request.
*/
len = ntohl(ep->vallen);
ptr = (u_char *)ep->pkt;
pkey = d2i_PublicKey(EVP_PKEY_RSA, NULL, &ptr, len);
if (pkey == NULL) {
msyslog(LOG_ERR, "crypto_encrypt %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_PUB);
}
/*
* Encrypt the cookie, encode in ASN.1 and sign.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = hostval.tstamp;
len = EVP_PKEY_size(pkey);
vp->vallen = htonl(len);
vp->ptr = emalloc(len);
temp32 = htonl(*cookie);
if (!RSA_public_encrypt(4, (u_char *)&temp32, vp->ptr,
pkey->pkey.rsa, RSA_PKCS1_OAEP_PADDING)) {
msyslog(LOG_ERR, "crypto_encrypt %s\n",
ERR_error_string(ERR_get_error(), NULL));
EVP_PKEY_free(pkey);
return (XEVNT_CKY);
}
EVP_PKEY_free(pkey);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_ident - construct extension field for identity scheme
*
* This routine determines which identity scheme is in use and
* constructs an extension field for that scheme.
*/
u_int
crypto_ident(
struct peer *peer /* peer structure pointer */
)
{
char filename[MAXFILENAME + 1];
/*
* If the server identity has already been verified, no further
* action is necessary. Otherwise, try to load the identity file
* of the certificate issuer. If the issuer file is not found,
* try the host file. If nothing found, declare a cryptobust.
* Note we can't get here unless the trusted certificate has
* been found and the CRYPTO_FLAG_VALID bit is set, so the
* certificate issuer is valid.
*/
if (peer->ident_pkey != NULL)
EVP_PKEY_free(peer->ident_pkey);
if (peer->crypto & CRYPTO_FLAG_GQ) {
snprintf(filename, MAXFILENAME, "ntpkey_gq_%s",
peer->issuer);
peer->ident_pkey = crypto_key(filename, &peer->fstamp);
if (peer->ident_pkey != NULL)
return (CRYPTO_GQ);
snprintf(filename, MAXFILENAME, "ntpkey_gq_%s",
sys_hostname);
peer->ident_pkey = crypto_key(filename, &peer->fstamp);
if (peer->ident_pkey != NULL)
return (CRYPTO_GQ);
}
if (peer->crypto & CRYPTO_FLAG_IFF) {
snprintf(filename, MAXFILENAME, "ntpkey_iff_%s",
peer->issuer);
peer->ident_pkey = crypto_key(filename, &peer->fstamp);
if (peer->ident_pkey != NULL)
return (CRYPTO_IFF);
snprintf(filename, MAXFILENAME, "ntpkey_iff_%s",
sys_hostname);
peer->ident_pkey = crypto_key(filename, &peer->fstamp);
if (peer->ident_pkey != NULL)
return (CRYPTO_IFF);
}
if (peer->crypto & CRYPTO_FLAG_MV) {
snprintf(filename, MAXFILENAME, "ntpkey_mv_%s",
peer->issuer);
peer->ident_pkey = crypto_key(filename, &peer->fstamp);
if (peer->ident_pkey != NULL)
return (CRYPTO_MV);
snprintf(filename, MAXFILENAME, "ntpkey_mv_%s",
sys_hostname);
peer->ident_pkey = crypto_key(filename, &peer->fstamp);
if (peer->ident_pkey != NULL)
return (CRYPTO_MV);
}
/*
* No compatible identity scheme is available. Life is hard.
*/
msyslog(LOG_INFO,
"crypto_ident: no compatible identity scheme found");
return (0);
}
/*
* crypto_args - construct extension field from arguments
*
* This routine creates an extension field with current timestamps and
* specified opcode, association ID and optional string. Note that the
* extension field is created here, but freed after the crypto_xmit()
* call in the protocol module.
*
* Returns extension field pointer (no errors).
*/
struct exten *
crypto_args(
struct peer *peer, /* peer structure pointer */
u_int opcode, /* operation code */
char *str /* argument string */
)
{
tstamp_t tstamp; /* NTP timestamp */
struct exten *ep; /* extension field pointer */
u_int len; /* extension field length */
tstamp = crypto_time();
len = sizeof(struct exten);
if (str != NULL)
len += strlen(str);
ep = emalloc(len);
memset(ep, 0, len);
if (opcode == 0)
return (ep);
ep->opcode = htonl(opcode + len);
/*
* If a response, send our ID; if a request, send the
* responder's ID.
*/
if (opcode & CRYPTO_RESP)
ep->associd = htonl(peer->associd);
else
ep->associd = htonl(peer->assoc);
ep->tstamp = htonl(tstamp);
ep->fstamp = hostval.tstamp;
ep->vallen = 0;
if (str != NULL) {
ep->vallen = htonl(strlen(str));
memcpy((char *)ep->pkt, str, strlen(str));
} else {
ep->pkt[0] = peer->associd;
}
return (ep);
}
/*
* crypto_send - construct extension field from value components
*
* Returns extension field length. Note: it is not polite to send a
* nonempty signature with zero timestamp or a nonzero timestamp with
* empty signature, but these rules are not enforced here.
*/
u_int
crypto_send(
struct exten *ep, /* extension field pointer */
struct value *vp /* value pointer */
)
{
u_int len, temp32;
int i;
/*
* Copy data. If the data field is empty or zero length, encode
* an empty value with length zero.
*/
ep->tstamp = vp->tstamp;
ep->fstamp = vp->fstamp;
ep->vallen = vp->vallen;
len = 12;
temp32 = ntohl(vp->vallen);
if (temp32 > 0 && vp->ptr != NULL)
memcpy(ep->pkt, vp->ptr, temp32);
/*
* Copy signature. If the signature field is empty or zero
* length, encode an empty signature with length zero.
*/
i = (temp32 + 3) / 4;
len += i * 4 + 4;
ep->pkt[i++] = vp->siglen;
temp32 = ntohl(vp->siglen);
if (temp32 > 0 && vp->sig != NULL)
memcpy(&ep->pkt[i], vp->sig, temp32);
len += temp32;
return (len);
}
/*
* crypto_update - compute new public value and sign extension fields
*
* This routine runs periodically, like once a day, and when something
* changes. It updates the timestamps on three value structures and one
* value structure list, then signs all the structures:
*
* hostval host name (not signed)
* pubkey public key
* cinfo certificate info/value list
* tai_leap leapseconds file
*
* Filestamps are proventicated data, so this routine is run only when
* the host has been synchronized to a proventicated source. Thus, the
* timestamp is proventicated, too, and can be used to deflect
* clogging attacks and even cook breakfast.
*
* Returns void (no errors)
*/
void
crypto_update(void)
{
EVP_MD_CTX ctx; /* message digest context */
struct cert_info *cp, *cpn; /* certificate info/value */
char statstr[NTP_MAXSTRLEN]; /* statistics for filegen */
tstamp_t tstamp; /* NTP timestamp */
u_int len;
if ((tstamp = crypto_time()) == 0)
return;
hostval.tstamp = htonl(tstamp);
/*
* Sign public key and timestamps. The filestamp is derived from
* the host key file extension from wherever the file was
* generated.
*/
if (pubkey.vallen != 0) {
pubkey.tstamp = hostval.tstamp;
pubkey.siglen = 0;
if (pubkey.sig == NULL)
pubkey.sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&pubkey, 12);
EVP_SignUpdate(&ctx, pubkey.ptr, ntohl(pubkey.vallen));
if (EVP_SignFinal(&ctx, pubkey.sig, &len, sign_pkey))
pubkey.siglen = htonl(len);
}
/*
* Sign certificates and timestamps. The filestamp is derived
* from the certificate file extension from wherever the file
* was generated. Note we do not throw expired certificates
* away; they may have signed younger ones.
*/
for (cp = cinfo; cp != NULL; cp = cpn) {
cpn = cp->link;
cp->cert.tstamp = hostval.tstamp;
cp->cert.siglen = 0;
if (cp->cert.sig == NULL)
cp->cert.sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&cp->cert, 12);
EVP_SignUpdate(&ctx, cp->cert.ptr,
ntohl(cp->cert.vallen));
if (EVP_SignFinal(&ctx, cp->cert.sig, &len, sign_pkey))
cp->cert.siglen = htonl(len);
}
/*
* Sign leapseconds table and timestamps. The filestamp is
* derived from the leapsecond file extension from wherever the
* file was generated.
*/
if (tai_leap.vallen != 0) {
tai_leap.tstamp = hostval.tstamp;
tai_leap.siglen = 0;
if (tai_leap.sig == NULL)
tai_leap.sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&tai_leap, 12);
EVP_SignUpdate(&ctx, tai_leap.ptr,
ntohl(tai_leap.vallen));
if (EVP_SignFinal(&ctx, tai_leap.sig, &len, sign_pkey))
tai_leap.siglen = htonl(len);
}
snprintf(statstr, NTP_MAXSTRLEN,
"update ts %u", ntohl(hostval.tstamp));
record_crypto_stats(NULL, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_update: %s\n", statstr);
#endif
}
/*
* value_free - free value structure components.
*
* Returns void (no errors)
*/
void
value_free(
struct value *vp /* value structure */
)
{
if (vp->ptr != NULL)
free(vp->ptr);
if (vp->sig != NULL)
free(vp->sig);
memset(vp, 0, sizeof(struct value));
}
/*
* crypto_time - returns current NTP time in seconds.
*/
tstamp_t
crypto_time()
{
l_fp tstamp; /* NTP time */ L_CLR(&tstamp);
L_CLR(&tstamp);
if (sys_leap != LEAP_NOTINSYNC)
get_systime(&tstamp);
return (tstamp.l_ui);
}
/*
* asn2ntp - convert ASN1_TIME time structure to NTP time in seconds.
*/
u_long
asn2ntp (
ASN1_TIME *asn1time /* pointer to ASN1_TIME structure */
)
{
char *v; /* pointer to ASN1_TIME string */
struct tm tm; /* used to convert to NTP time */
/*
* Extract time string YYMMDDHHMMSSZ from ASN1 time structure.
* Note that the YY, MM, DD fields start with one, the HH, MM,
* SS fiels start with zero and the Z character should be 'Z'
* for UTC. Also note that years less than 50 map to years
* greater than 100. Dontcha love ASN.1? Better than MIL-188.
*/
if (asn1time->length > 13)
return ((u_long)(~0)); /* We can't use -1 here. It's invalid */
v = (char *)asn1time->data;
tm.tm_year = (v[0] - '0') * 10 + v[1] - '0';
if (tm.tm_year < 50)
tm.tm_year += 100;
tm.tm_mon = (v[2] - '0') * 10 + v[3] - '0' - 1;
tm.tm_mday = (v[4] - '0') * 10 + v[5] - '0';
tm.tm_hour = (v[6] - '0') * 10 + v[7] - '0';
tm.tm_min = (v[8] - '0') * 10 + v[9] - '0';
tm.tm_sec = (v[10] - '0') * 10 + v[11] - '0';
tm.tm_wday = 0;
tm.tm_yday = 0;
tm.tm_isdst = 0;
return (timegm(&tm) + JAN_1970);
}
/*
* bigdig() - compute a BIGNUM MD5 hash of a BIGNUM number.
*/
static int
bighash(
BIGNUM *bn, /* BIGNUM * from */
BIGNUM *bk /* BIGNUM * to */
)
{
EVP_MD_CTX ctx; /* message digest context */
u_char dgst[EVP_MAX_MD_SIZE]; /* message digest */
u_char *ptr; /* a BIGNUM as binary string */
u_int len;
len = BN_num_bytes(bn);
ptr = emalloc(len);
BN_bn2bin(bn, ptr);
EVP_DigestInit(&ctx, EVP_md5());
EVP_DigestUpdate(&ctx, ptr, len);
EVP_DigestFinal(&ctx, dgst, &len);
BN_bin2bn(dgst, len, bk);
/* XXX MEMLEAK? free ptr? */
return (1);
}
/*
***********************************************************************
* *
* The following routines implement the Schnorr (IFF) identity scheme *
* *
***********************************************************************
*
* The Schnorr (IFF) identity scheme is intended for use when
* the ntp-genkeys program does not generate the certificates used in
* the protocol and the group key cannot be conveyed in the certificate
* itself. For this purpose, new generations of IFF values must be
* securely transmitted to all members of the group before use. The
* scheme is self contained and independent of new generations of host
* keys, sign keys and certificates.
*
* The IFF identity scheme is based on DSA cryptography and algorithms
* described in Stinson p. 285. The IFF values hide in a DSA cuckoo
* structure, but only the primes and generator are used. The p is a
* 512-bit prime, q a 160-bit prime that divides p - 1 and is a qth root
* of 1 mod p; that is, g^q = 1 mod p. The TA rolls primvate random
* group key b disguised as a DSA structure member, then computes public
* key g^(q - b). These values are shared only among group members and
* never revealed in messages. Alice challenges Bob to confirm identity
* using the protocol described below.
*
* How it works
*
* The scheme goes like this. Both Alice and Bob have the public primes
* p, q and generator g. The TA gives private key b to Bob and public
* key v = g^(q - a) mod p to Alice.
*
* Alice rolls new random challenge r and sends to Bob in the IFF
* request message. Bob rolls new random k, then computes y = k + b r
* mod q and x = g^k mod p and sends (y, hash(x)) to Alice in the
* response message. Besides making the response shorter, the hash makes
* it effectivey impossible for an intruder to solve for b by observing
* a number of these messages.
*
* Alice receives the response and computes g^y v^r mod p. After a bit
* of algebra, this simplifies to g^k. If the hash of this result
* matches hash(x), Alice knows that Bob has the group key b. The signed
* response binds this knowledge to Bob's private key and the public key
* previously received in his certificate.
*
* crypto_alice - construct Alice's challenge in IFF scheme
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_ID bad or missing group key
*/
static int
crypto_alice(
struct peer *peer, /* peer pointer */
struct value *vp /* value pointer */
)
{
DSA *dsa; /* IFF parameters */
BN_CTX *bctx; /* BIGNUM context */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp;
u_int len;
/*
* The identity parameters must have correct format and content.
*/
if (peer->ident_pkey == NULL)
return (XEVNT_ID);
if ((dsa = peer->ident_pkey->pkey.dsa) == NULL) {
msyslog(LOG_INFO, "crypto_alice: defective key");
return (XEVNT_PUB);
}
/*
* Roll new random r (0 < r < q). The OpenSSL library has a bug
* omitting BN_rand_range, so we have to do it the hard way.
*/
bctx = BN_CTX_new();
len = BN_num_bytes(dsa->q);
if (peer->iffval != NULL)
BN_free(peer->iffval);
peer->iffval = BN_new();
BN_rand(peer->iffval, len * 8, -1, 1); /* r */
BN_mod(peer->iffval, peer->iffval, dsa->q, bctx);
BN_CTX_free(bctx);
/*
* Sign and send to Bob. The filestamp is from the local file.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = htonl(peer->fstamp);
vp->vallen = htonl(len);
vp->ptr = emalloc(len);
BN_bn2bin(peer->iffval, vp->ptr);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_bob - construct Bob's response to Alice's challenge
*
* Returns
* XEVNT_OK success
* XEVNT_ID bad or missing group key
* XEVNT_ERR protocol error
* XEVNT_PER host expired certificate
*/
static int
crypto_bob(
struct exten *ep, /* extension pointer */
struct value *vp /* value pointer */
)
{
DSA *dsa; /* IFF parameters */
DSA_SIG *sdsa; /* DSA signature context fake */
BN_CTX *bctx; /* BIGNUM context */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp; /* NTP timestamp */
BIGNUM *bn, *bk, *r;
u_char *ptr;
u_int len;
/*
* If the IFF parameters are not valid, something awful
* happened or we are being tormented.
*/
if (iffpar_pkey == NULL) {
msyslog(LOG_INFO, "crypto_bob: scheme unavailable");
return (XEVNT_ID);
}
dsa = iffpar_pkey->pkey.dsa;
/*
* Extract r from the challenge.
*/
len = ntohl(ep->vallen);
if ((r = BN_bin2bn((u_char *)ep->pkt, len, NULL)) == NULL) {
msyslog(LOG_ERR, "crypto_bob %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_ERR);
}
/*
* Bob rolls random k (0 < k < q), computes y = k + b r mod q
* and x = g^k mod p, then sends (y, hash(x)) to Alice.
*/
bctx = BN_CTX_new(); bk = BN_new(); bn = BN_new();
sdsa = DSA_SIG_new();
BN_rand(bk, len * 8, -1, 1); /* k */
BN_mod_mul(bn, dsa->priv_key, r, dsa->q, bctx); /* b r mod q */
BN_add(bn, bn, bk);
BN_mod(bn, bn, dsa->q, bctx); /* k + b r mod q */
sdsa->r = BN_dup(bn);
BN_mod_exp(bk, dsa->g, bk, dsa->p, bctx); /* g^k mod p */
bighash(bk, bk);
sdsa->s = BN_dup(bk);
BN_CTX_free(bctx);
BN_free(r); BN_free(bn); BN_free(bk);
/*
* Encode the values in ASN.1 and sign.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = htonl(if_fstamp);
len = i2d_DSA_SIG(sdsa, NULL);
if (len <= 0) {
msyslog(LOG_ERR, "crypto_bob %s\n",
ERR_error_string(ERR_get_error(), NULL));
DSA_SIG_free(sdsa);
return (XEVNT_ERR);
}
vp->vallen = htonl(len);
ptr = emalloc(len);
vp->ptr = ptr;
i2d_DSA_SIG(sdsa, &ptr);
DSA_SIG_free(sdsa);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_iff - verify Bob's response to Alice's challenge
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_ID bad or missing group key
* XEVNT_FSP bad filestamp
*/
int
crypto_iff(
struct exten *ep, /* extension pointer */
struct peer *peer /* peer structure pointer */
)
{
DSA *dsa; /* IFF parameters */
BN_CTX *bctx; /* BIGNUM context */
DSA_SIG *sdsa; /* DSA parameters */
BIGNUM *bn, *bk;
u_int len;
const u_char *ptr;
int temp;
/*
* If the IFF parameters are not valid or no challenge was sent,
* something awful happened or we are being tormented.
*/
if (peer->ident_pkey == NULL) {
msyslog(LOG_INFO, "crypto_iff: scheme unavailable");
return (XEVNT_ID);
}
if (ntohl(ep->fstamp) != peer->fstamp) {
msyslog(LOG_INFO, "crypto_iff: invalid filestamp %u",
ntohl(ep->fstamp));
return (XEVNT_FSP);
}
if ((dsa = peer->ident_pkey->pkey.dsa) == NULL) {
msyslog(LOG_INFO, "crypto_iff: defective key");
return (XEVNT_PUB);
}
if (peer->iffval == NULL) {
msyslog(LOG_INFO, "crypto_iff: missing challenge");
return (XEVNT_ID);
}
/*
* Extract the k + b r and g^k values from the response.
*/
bctx = BN_CTX_new(); bk = BN_new(); bn = BN_new();
len = ntohl(ep->vallen);
ptr = (const u_char *)ep->pkt;
if ((sdsa = d2i_DSA_SIG(NULL, &ptr, len)) == NULL) {
msyslog(LOG_ERR, "crypto_iff %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_ERR);
}
/*
* Compute g^(k + b r) g^(q - b)r mod p.
*/
BN_mod_exp(bn, dsa->pub_key, peer->iffval, dsa->p, bctx);
BN_mod_exp(bk, dsa->g, sdsa->r, dsa->p, bctx);
BN_mod_mul(bn, bn, bk, dsa->p, bctx);
/*
* Verify the hash of the result matches hash(x).
*/
bighash(bn, bn);
temp = BN_cmp(bn, sdsa->s);
BN_free(bn); BN_free(bk); BN_CTX_free(bctx);
BN_free(peer->iffval);
peer->iffval = NULL;
DSA_SIG_free(sdsa);
if (temp == 0)
return (XEVNT_OK);
else
return (XEVNT_ID);
}
/*
***********************************************************************
* *
* The following routines implement the Guillou-Quisquater (GQ) *
* identity scheme *
* *
***********************************************************************
*
* The Guillou-Quisquater (GQ) identity scheme is intended for use when
* the ntp-genkeys program generates the certificates used in the
* protocol and the group key can be conveyed in a certificate extension
* field. The scheme is self contained and independent of new
* generations of host keys, sign keys and certificates.
*
* The GQ identity scheme is based on RSA cryptography and algorithms
* described in Stinson p. 300 (with errors). The GQ values hide in a
* RSA cuckoo structure, but only the modulus is used. The 512-bit
* public modulus is n = p q, where p and q are secret large primes. The
* TA rolls random group key b disguised as a RSA structure member.
* Except for the public key, these values are shared only among group
* members and never revealed in messages.
*
* When rolling new certificates, Bob recomputes the private and
* public keys. The private key u is a random roll, while the public key
* is the inverse obscured by the group key v = (u^-1)^b. These values
* replace the private and public keys normally generated by the RSA
* scheme. Alice challenges Bob to confirm identity using the protocol
* described below.
*
* How it works
*
* The scheme goes like this. Both Alice and Bob have the same modulus n
* and some random b as the group key. These values are computed and
* distributed in advance via secret means, although only the group key
* b is truly secret. Each has a private random private key u and public
* key (u^-1)^b, although not necessarily the same ones. Bob and Alice
* can regenerate the key pair from time to time without affecting
* operations. The public key is conveyed on the certificate in an
* extension field; the private key is never revealed.
*
* Alice rolls new random challenge r and sends to Bob in the GQ
* request message. Bob rolls new random k, then computes y = k u^r mod
* n and x = k^b mod n and sends (y, hash(x)) to Alice in the response
* message. Besides making the response shorter, the hash makes it
* effectivey impossible for an intruder to solve for b by observing
* a number of these messages.
*
* Alice receives the response and computes y^b v^r mod n. After a bit
* of algebra, this simplifies to k^b. If the hash of this result
* matches hash(x), Alice knows that Bob has the group key b. The signed
* response binds this knowledge to Bob's private key and the public key
* previously received in his certificate.
*
* crypto_alice2 - construct Alice's challenge in GQ scheme
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_ID bad or missing group key
* XEVNT_PER host certificate expired
*/
static int
crypto_alice2(
struct peer *peer, /* peer pointer */
struct value *vp /* value pointer */
)
{
RSA *rsa; /* GQ parameters */
BN_CTX *bctx; /* BIGNUM context */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp;
u_int len;
/*
* The identity parameters must have correct format and content.
*/
if (peer->ident_pkey == NULL)
return (XEVNT_ID);
if ((rsa = peer->ident_pkey->pkey.rsa) == NULL) {
msyslog(LOG_INFO, "crypto_alice2: defective key");
return (XEVNT_PUB);
}
/*
* Roll new random r (0 < r < n). The OpenSSL library has a bug
* omitting BN_rand_range, so we have to do it the hard way.
*/
bctx = BN_CTX_new();
len = BN_num_bytes(rsa->n);
if (peer->iffval != NULL)
BN_free(peer->iffval);
peer->iffval = BN_new();
BN_rand(peer->iffval, len * 8, -1, 1); /* r mod n */
BN_mod(peer->iffval, peer->iffval, rsa->n, bctx);
BN_CTX_free(bctx);
/*
* Sign and send to Bob. The filestamp is from the local file.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = htonl(peer->fstamp);
vp->vallen = htonl(len);
vp->ptr = emalloc(len);
BN_bn2bin(peer->iffval, vp->ptr);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_bob2 - construct Bob's response to Alice's challenge
*
* Returns
* XEVNT_OK success
* XEVNT_ID bad or missing group key
* XEVNT_ERR protocol error
* XEVNT_PER host certificate expired
*/
static int
crypto_bob2(
struct exten *ep, /* extension pointer */
struct value *vp /* value pointer */
)
{
RSA *rsa; /* GQ parameters */
DSA_SIG *sdsa; /* DSA parameters */
BN_CTX *bctx; /* BIGNUM context */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp; /* NTP timestamp */
BIGNUM *r, *k, *g, *y;
u_char *ptr;
u_int len;
/*
* If the GQ parameters are not valid, something awful
* happened or we are being tormented.
*/
if (gqpar_pkey == NULL) {
msyslog(LOG_INFO, "crypto_bob2: scheme unavailable");
return (XEVNT_ID);
}
rsa = gqpar_pkey->pkey.rsa;
/*
* Extract r from the challenge.
*/
len = ntohl(ep->vallen);
if ((r = BN_bin2bn((u_char *)ep->pkt, len, NULL)) == NULL) {
msyslog(LOG_ERR, "crypto_bob2 %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_ERR);
}
/*
* Bob rolls random k (0 < k < n), computes y = k u^r mod n and
* x = k^b mod n, then sends (y, hash(x)) to Alice.
*/
bctx = BN_CTX_new(); k = BN_new(); g = BN_new(); y = BN_new();
sdsa = DSA_SIG_new();
BN_rand(k, len * 8, -1, 1); /* k */
BN_mod(k, k, rsa->n, bctx);
BN_mod_exp(y, rsa->p, r, rsa->n, bctx); /* u^r mod n */
BN_mod_mul(y, k, y, rsa->n, bctx); /* k u^r mod n */
sdsa->r = BN_dup(y);
BN_mod_exp(g, k, rsa->e, rsa->n, bctx); /* k^b mod n */
bighash(g, g);
sdsa->s = BN_dup(g);
BN_CTX_free(bctx);
BN_free(r); BN_free(k); BN_free(g); BN_free(y);
/*
* Encode the values in ASN.1 and sign.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = htonl(gq_fstamp);
len = i2d_DSA_SIG(sdsa, NULL);
if (len <= 0) {
msyslog(LOG_ERR, "crypto_bob2 %s\n",
ERR_error_string(ERR_get_error(), NULL));
DSA_SIG_free(sdsa);
return (XEVNT_ERR);
}
vp->vallen = htonl(len);
ptr = emalloc(len);
vp->ptr = ptr;
i2d_DSA_SIG(sdsa, &ptr);
DSA_SIG_free(sdsa);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_gq - verify Bob's response to Alice's challenge
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_ID bad or missing group keys
* XEVNT_ERR protocol error
* XEVNT_FSP bad filestamp
*/
int
crypto_gq(
struct exten *ep, /* extension pointer */
struct peer *peer /* peer structure pointer */
)
{
RSA *rsa; /* GQ parameters */
BN_CTX *bctx; /* BIGNUM context */
DSA_SIG *sdsa; /* RSA signature context fake */
BIGNUM *y, *v;
const u_char *ptr;
u_int len;
int temp;
/*
* If the GQ parameters are not valid or no challenge was sent,
* something awful happened or we are being tormented.
*/
if (peer->ident_pkey == NULL) {
msyslog(LOG_INFO, "crypto_gq: scheme unavailable");
return (XEVNT_ID);
}
if (ntohl(ep->fstamp) != peer->fstamp) {
msyslog(LOG_INFO, "crypto_gq: invalid filestamp %u",
ntohl(ep->fstamp));
return (XEVNT_FSP);
}
if ((rsa = peer->ident_pkey->pkey.rsa) == NULL) {
msyslog(LOG_INFO, "crypto_gq: defective key");
return (XEVNT_PUB);
}
if (peer->iffval == NULL) {
msyslog(LOG_INFO, "crypto_gq: missing challenge");
return (XEVNT_ID);
}
/*
* Extract the y = k u^r and hash(x = k^b) values from the
* response.
*/
bctx = BN_CTX_new(); y = BN_new(); v = BN_new();
len = ntohl(ep->vallen);
ptr = (const u_char *)ep->pkt;
if ((sdsa = d2i_DSA_SIG(NULL, &ptr, len)) == NULL) {
msyslog(LOG_ERR, "crypto_gq %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_ERR);
}
/*
* Compute v^r y^b mod n.
*/
BN_mod_exp(v, peer->grpkey, peer->iffval, rsa->n, bctx);
/* v^r mod n */
BN_mod_exp(y, sdsa->r, rsa->e, rsa->n, bctx); /* y^b mod n */
BN_mod_mul(y, v, y, rsa->n, bctx); /* v^r y^b mod n */
/*
* Verify the hash of the result matches hash(x).
*/
bighash(y, y);
temp = BN_cmp(y, sdsa->s);
BN_CTX_free(bctx); BN_free(y); BN_free(v);
BN_free(peer->iffval);
peer->iffval = NULL;
DSA_SIG_free(sdsa);
if (temp == 0)
return (XEVNT_OK);
else
return (XEVNT_ID);
}
/*
***********************************************************************
* *
* The following routines implement the Mu-Varadharajan (MV) identity *
* scheme *
* *
***********************************************************************
*/
/*
* The Mu-Varadharajan (MV) cryptosystem was originally intended when
* servers broadcast messages to clients, but clients never send
* messages to servers. There is one encryption key for the server and a
* separate decryption key for each client. It operated something like a
* pay-per-view satellite broadcasting system where the session key is
* encrypted by the broadcaster and the decryption keys are held in a
* tamperproof set-top box.
*
* The MV parameters and private encryption key hide in a DSA cuckoo
* structure which uses the same parameters, but generated in a
* different way. The values are used in an encryption scheme similar to
* El Gamal cryptography and a polynomial formed from the expansion of
* product terms (x - x[j]), as described in Mu, Y., and V.
* Varadharajan: Robust and Secure Broadcasting, Proc. Indocrypt 2001,
* 223-231. The paper has significant errors and serious omissions.
*
* Let q be the product of n distinct primes s'[j] (j = 1...n), where
* each s'[j] has m significant bits. Let p be a prime p = 2 * q + 1, so
* that q and each s'[j] divide p - 1 and p has M = n * m + 1
* significant bits. The elements x mod q of Zq with the elements 2 and
* the primes removed form a field Zq* valid for polynomial arithetic.
* Let g be a generator of Zp; that is, gcd(g, p - 1) = 1 and g^q = 1
* mod p. We expect M to be in the 500-bit range and n relatively small,
* like 25, so the likelihood of a randomly generated element of x mod q
* of Zq colliding with a factor of p - 1 is very small and can be
* avoided. Associated with each s'[j] is an element s[j] such that s[j]
* s'[j] = s'[j] mod q. We find s[j] as the quotient (q + s'[j]) /
* s'[j]. These are the parameters of the scheme and they are expensive
* to compute.
*
* We set up an instance of the scheme as follows. A set of random
* values x[j] mod q (j = 1...n), are generated as the zeros of a
* polynomial of order n. The product terms (x - x[j]) are expanded to
* form coefficients a[i] mod q (i = 0...n) in powers of x. These are
* used as exponents of the generator g mod p to generate the private
* encryption key A. The pair (gbar, ghat) of public server keys and the
* pairs (xbar[j], xhat[j]) (j = 1...n) of private client keys are used
* to construct the decryption keys. The devil is in the details.
*
* The distinguishing characteristic of this scheme is the capability to
* revoke keys. Included in the calculation of E, gbar and ghat is the
* product s = prod(s'[j]) (j = 1...n) above. If the factor s'[j] is
* subsequently removed from the product and E, gbar and ghat
* recomputed, the jth client will no longer be able to compute E^-1 and
* thus unable to decrypt the block.
*
* How it works
*
* The scheme goes like this. Bob has the server values (p, A, q, gbar,
* ghat) and Alice the client values (p, xbar, xhat).
*
* Alice rolls new random challenge r (0 < r < p) and sends to Bob in
* the MV request message. Bob rolls new random k (0 < k < q), encrypts
* y = A^k mod p (a permutation) and sends (hash(y), gbar^k, ghat^k) to
* Alice.
*
* Alice receives the response and computes the decryption key (the
* inverse permutation) from previously obtained (xbar, xhat) and
* (gbar^k, ghat^k) in the message. She computes the inverse, which is
* unique by reasons explained in the ntp-keygen.c program sources. If
* the hash of this result matches hash(y), Alice knows that Bob has the
* group key b. The signed response binds this knowledge to Bob's
* private key and the public key previously received in his
* certificate.
*
* crypto_alice3 - construct Alice's challenge in MV scheme
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_ID bad or missing group key
* XEVNT_PER host certificate expired
*/
static int
crypto_alice3(
struct peer *peer, /* peer pointer */
struct value *vp /* value pointer */
)
{
DSA *dsa; /* MV parameters */
BN_CTX *bctx; /* BIGNUM context */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp;
u_int len;
/*
* The identity parameters must have correct format and content.
*/
if (peer->ident_pkey == NULL)
return (XEVNT_ID);
if ((dsa = peer->ident_pkey->pkey.dsa) == NULL) {
msyslog(LOG_INFO, "crypto_alice3: defective key");
return (XEVNT_PUB);
}
/*
* Roll new random r (0 < r < q). The OpenSSL library has a bug
* omitting BN_rand_range, so we have to do it the hard way.
*/
bctx = BN_CTX_new();
len = BN_num_bytes(dsa->p);
if (peer->iffval != NULL)
BN_free(peer->iffval);
peer->iffval = BN_new();
BN_rand(peer->iffval, len * 8, -1, 1); /* r */
BN_mod(peer->iffval, peer->iffval, dsa->p, bctx);
BN_CTX_free(bctx);
/*
* Sign and send to Bob. The filestamp is from the local file.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = htonl(peer->fstamp);
vp->vallen = htonl(len);
vp->ptr = emalloc(len);
BN_bn2bin(peer->iffval, vp->ptr);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_bob3 - construct Bob's response to Alice's challenge
*
* Returns
* XEVNT_OK success
* XEVNT_ERR protocol error
* XEVNT_PER host certificate expired
*/
static int
crypto_bob3(
struct exten *ep, /* extension pointer */
struct value *vp /* value pointer */
)
{
DSA *dsa; /* MV parameters */
DSA *sdsa; /* DSA signature context fake */
BN_CTX *bctx; /* BIGNUM context */
EVP_MD_CTX ctx; /* signature context */
tstamp_t tstamp; /* NTP timestamp */
BIGNUM *r, *k, *u;
u_char *ptr;
u_int len;
/*
* If the MV parameters are not valid, something awful
* happened or we are being tormented.
*/
if (mvpar_pkey == NULL) {
msyslog(LOG_INFO, "crypto_bob3: scheme unavailable");
return (XEVNT_ID);
}
dsa = mvpar_pkey->pkey.dsa;
/*
* Extract r from the challenge.
*/
len = ntohl(ep->vallen);
if ((r = BN_bin2bn((u_char *)ep->pkt, len, NULL)) == NULL) {
msyslog(LOG_ERR, "crypto_bob3 %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_ERR);
}
/*
* Bob rolls random k (0 < k < q), making sure it is not a
* factor of q. He then computes y = A^k r and sends (hash(y),
* gbar^k, ghat^k) to Alice.
*/
bctx = BN_CTX_new(); k = BN_new(); u = BN_new();
sdsa = DSA_new();
sdsa->p = BN_new(); sdsa->q = BN_new(); sdsa->g = BN_new();
while (1) {
BN_rand(k, BN_num_bits(dsa->q), 0, 0);
BN_mod(k, k, dsa->q, bctx);
BN_gcd(u, k, dsa->q, bctx);
if (BN_is_one(u))
break;
}
BN_mod_exp(u, dsa->g, k, dsa->p, bctx); /* A r */
BN_mod_mul(u, u, r, dsa->p, bctx);
bighash(u, sdsa->p);
BN_mod_exp(sdsa->q, dsa->priv_key, k, dsa->p, bctx); /* gbar */
BN_mod_exp(sdsa->g, dsa->pub_key, k, dsa->p, bctx); /* ghat */
BN_CTX_free(bctx); BN_free(k); BN_free(r); BN_free(u);
/*
* Encode the values in ASN.1 and sign.
*/
tstamp = crypto_time();
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = htonl(mv_fstamp);
len = i2d_DSAparams(sdsa, NULL);
if (len <= 0) {
msyslog(LOG_ERR, "crypto_bob3 %s\n",
ERR_error_string(ERR_get_error(), NULL));
DSA_free(sdsa);
return (XEVNT_ERR);
}
vp->vallen = htonl(len);
ptr = emalloc(len);
vp->ptr = ptr;
i2d_DSAparams(sdsa, &ptr);
DSA_free(sdsa);
vp->siglen = 0;
if (tstamp == 0)
return (XEVNT_OK);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)&vp->tstamp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
return (XEVNT_OK);
}
/*
* crypto_mv - verify Bob's response to Alice's challenge
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_ID bad or missing group key
* XEVNT_ERR protocol error
* XEVNT_FSP bad filestamp
*/
int
crypto_mv(
struct exten *ep, /* extension pointer */
struct peer *peer /* peer structure pointer */
)
{
DSA *dsa; /* MV parameters */
DSA *sdsa; /* DSA parameters */
BN_CTX *bctx; /* BIGNUM context */
BIGNUM *k, *u, *v;
u_int len;
const u_char *ptr;
int temp;
/*
* If the MV parameters are not valid or no challenge was sent,
* something awful happened or we are being tormented.
*/
if (peer->ident_pkey == NULL) {
msyslog(LOG_INFO, "crypto_mv: scheme unavailable");
return (XEVNT_ID);
}
if (ntohl(ep->fstamp) != peer->fstamp) {
msyslog(LOG_INFO, "crypto_mv: invalid filestamp %u",
ntohl(ep->fstamp));
return (XEVNT_FSP);
}
if ((dsa = peer->ident_pkey->pkey.dsa) == NULL) {
msyslog(LOG_INFO, "crypto_mv: defective key");
return (XEVNT_PUB);
}
if (peer->iffval == NULL) {
msyslog(LOG_INFO, "crypto_mv: missing challenge");
return (XEVNT_ID);
}
/*
* Extract the (hash(y), gbar, ghat) values from the response.
*/
bctx = BN_CTX_new(); k = BN_new(); u = BN_new(); v = BN_new();
len = ntohl(ep->vallen);
ptr = (const u_char *)ep->pkt;
if ((sdsa = d2i_DSAparams(NULL, &ptr, len)) == NULL) {
msyslog(LOG_ERR, "crypto_mv %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_ERR);
}
/*
* Compute (gbar^xhat ghat^xbar)^-1 mod p.
*/
BN_mod_exp(u, sdsa->q, dsa->pub_key, dsa->p, bctx);
BN_mod_exp(v, sdsa->g, dsa->priv_key, dsa->p, bctx);
BN_mod_mul(u, u, v, dsa->p, bctx);
BN_mod_inverse(u, u, dsa->p, bctx);
BN_mod_mul(v, u, peer->iffval, dsa->p, bctx);
/*
* The result should match the hash of r mod p.
*/
bighash(v, v);
temp = BN_cmp(v, sdsa->p);
BN_CTX_free(bctx); BN_free(k); BN_free(u); BN_free(v);
BN_free(peer->iffval);
peer->iffval = NULL;
DSA_free(sdsa);
if (temp == 0)
return (XEVNT_OK);
else
return (XEVNT_ID);
}
/*
***********************************************************************
* *
* The following routines are used to manipulate certificates *
* *
***********************************************************************
*/
/*
* cert_parse - parse x509 certificate and create info/value structures.
*
* The server certificate includes the version number, issuer name,
* subject name, public key and valid date interval. If the issuer name
* is the same as the subject name, the certificate is self signed and
* valid only if the server is configured as trustable. If the names are
* different, another issuer has signed the server certificate and
* vouched for it. In this case the server certificate is valid if
* verified by the issuer public key.
*
* Returns certificate info/value pointer if valid, NULL if not.
*/
struct cert_info * /* certificate information structure */
cert_parse(
u_char *asn1cert, /* X509 certificate */
u_int len, /* certificate length */
tstamp_t fstamp /* filestamp */
)
{
X509 *cert; /* X509 certificate */
X509_EXTENSION *ext; /* X509v3 extension */
struct cert_info *ret; /* certificate info/value */
BIO *bp;
X509V3_EXT_METHOD *method;
char pathbuf[MAXFILENAME];
u_char *uptr;
char *ptr;
int temp, cnt, i;
/*
* Decode ASN.1 objects and construct certificate structure.
*/
uptr = asn1cert;
if ((cert = d2i_X509(NULL, &uptr, len)) == NULL) {
msyslog(LOG_ERR, "cert_parse %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (NULL);
}
/*
* Extract version, subject name and public key.
*/
ret = emalloc(sizeof(struct cert_info));
memset(ret, 0, sizeof(struct cert_info));
if ((ret->pkey = X509_get_pubkey(cert)) == NULL) {
msyslog(LOG_ERR, "cert_parse %s\n",
ERR_error_string(ERR_get_error(), NULL));
cert_free(ret);
X509_free(cert);
return (NULL);
}
ret->version = X509_get_version(cert);
X509_NAME_oneline(X509_get_subject_name(cert), pathbuf,
MAXFILENAME - 1);
ptr = strstr(pathbuf, "CN=");
if (ptr == NULL) {
msyslog(LOG_INFO, "cert_parse: invalid subject %s",
pathbuf);
cert_free(ret);
X509_free(cert);
return (NULL);
}
ret->subject = emalloc(strlen(ptr) + 1);
strcpy(ret->subject, ptr + 3);
/*
* Extract remaining objects. Note that the NTP serial number is
* the NTP seconds at the time of signing, but this might not be
* the case for other authority. We don't bother to check the
* objects at this time, since the real crunch can happen only
* when the time is valid but not yet certificated.
*/
ret->nid = OBJ_obj2nid(cert->cert_info->signature->algorithm);
ret->digest = (const EVP_MD *)EVP_get_digestbynid(ret->nid);
ret->serial =
(u_long)ASN1_INTEGER_get(X509_get_serialNumber(cert));
X509_NAME_oneline(X509_get_issuer_name(cert), pathbuf,
MAXFILENAME);
if ((ptr = strstr(pathbuf, "CN=")) == NULL) {
msyslog(LOG_INFO, "cert_parse: invalid issuer %s",
pathbuf);
cert_free(ret);
X509_free(cert);
return (NULL);
}
ret->issuer = emalloc(strlen(ptr) + 1);
strcpy(ret->issuer, ptr + 3);
ret->first = asn2ntp(X509_get_notBefore(cert));
ret->last = asn2ntp(X509_get_notAfter(cert));
/*
* Extract extension fields. These are ad hoc ripoffs of
* currently assigned functions and will certainly be changed
* before prime time.
*/
cnt = X509_get_ext_count(cert);
for (i = 0; i < cnt; i++) {
ext = X509_get_ext(cert, i);
method = X509V3_EXT_get(ext);
temp = OBJ_obj2nid(ext->object);
switch (temp) {
/*
* If a key_usage field is present, we decode whether
* this is a trusted or private certificate. This is
* dorky; all we want is to compare NIDs, but OpenSSL
* insists on BIO text strings.
*/
case NID_ext_key_usage:
bp = BIO_new(BIO_s_mem());
X509V3_EXT_print(bp, ext, 0, 0);
BIO_gets(bp, pathbuf, MAXFILENAME);
BIO_free(bp);
#if DEBUG
if (debug)
printf("cert_parse: %s: %s\n",
OBJ_nid2ln(temp), pathbuf);
#endif
if (strcmp(pathbuf, "Trust Root") == 0)
ret->flags |= CERT_TRUST;
else if (strcmp(pathbuf, "Private") == 0)
ret->flags |= CERT_PRIV;
break;
/*
* If a NID_subject_key_identifier field is present, it
* contains the GQ public key.
*/
case NID_subject_key_identifier:
ret->grplen = ext->value->length - 2;
ret->grpkey = emalloc(ret->grplen);
memcpy(ret->grpkey, &ext->value->data[2],
ret->grplen);
break;
}
}
/*
* If certificate is self signed, verify signature.
*/
if (strcmp(ret->subject, ret->issuer) == 0) {
if (!X509_verify(cert, ret->pkey)) {
msyslog(LOG_INFO,
"cert_parse: signature not verified %s",
pathbuf);
cert_free(ret);
X509_free(cert);
return (NULL);
}
}
/*
* Verify certificate valid times. Note that certificates cannot
* be retroactive.
*/
if (ret->first > ret->last || ret->first < fstamp) {
msyslog(LOG_INFO,
"cert_parse: invalid certificate %s first %u last %u fstamp %u",
ret->subject, ret->first, ret->last, fstamp);
cert_free(ret);
X509_free(cert);
return (NULL);
}
/*
* Build the value structure to sign and send later.
*/
ret->cert.fstamp = htonl(fstamp);
ret->cert.vallen = htonl(len);
ret->cert.ptr = emalloc(len);
memcpy(ret->cert.ptr, asn1cert, len);
#ifdef DEBUG
if (debug > 1)
X509_print_fp(stdout, cert);
#endif
X509_free(cert);
return (ret);
}
/*
* cert_sign - sign x509 certificate equest and update value structure.
*
* The certificate request includes a copy of the host certificate,
* which includes the version number, subject name and public key of the
* host. The resulting certificate includes these values plus the
* serial number, issuer name and valid interval of the server. The
* valid interval extends from the current time to the same time one
* year hence. This may extend the life of the signed certificate beyond
* that of the signer certificate.
*
* It is convenient to use the NTP seconds of the current time as the
* serial number. In the value structure the timestamp is the current
* time and the filestamp is taken from the extension field. Note this
* routine is called only when the client clock is synchronized to a
* proventic source, so timestamp comparisons are valid.
*
* The host certificate is valid from the time it was generated for a
* period of one year. A signed certificate is valid from the time of
* signature for a period of one year, but only the host certificate (or
* sign certificate if used) is actually used to encrypt and decrypt
* signatures. The signature trail is built from the client via the
* intermediate servers to the trusted server. Each signature on the
* trail must be valid at the time of signature, but it could happen
* that a signer certificate expire before the signed certificate, which
* remains valid until its expiration.
*
* Returns
* XEVNT_OK success
* XEVNT_PUB bad or missing public key
* XEVNT_CRT bad or missing certificate
* XEVNT_VFY certificate not verified
* XEVNT_PER host certificate expired
*/
static int
cert_sign(
struct exten *ep, /* extension field pointer */
struct value *vp /* value pointer */
)
{
X509 *req; /* X509 certificate request */
X509 *cert; /* X509 certificate */
X509_EXTENSION *ext; /* certificate extension */
ASN1_INTEGER *serial; /* serial number */
X509_NAME *subj; /* distinguished (common) name */
EVP_PKEY *pkey; /* public key */
EVP_MD_CTX ctx; /* message digest context */
tstamp_t tstamp; /* NTP timestamp */
u_int len;
u_char *ptr;
int i, temp;
/*
* Decode ASN.1 objects and construct certificate structure.
* Make sure the system clock is synchronized to a proventic
* source.
*/
tstamp = crypto_time();
if (tstamp == 0)
return (XEVNT_TSP);
if (tstamp < cinfo->first || tstamp > cinfo->last)
return (XEVNT_PER);
ptr = (u_char *)ep->pkt;
if ((req = d2i_X509(NULL, &ptr, ntohl(ep->vallen))) == NULL) {
msyslog(LOG_ERR, "cert_sign %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (XEVNT_CRT);
}
/*
* Extract public key and check for errors.
*/
if ((pkey = X509_get_pubkey(req)) == NULL) {
msyslog(LOG_ERR, "cert_sign %s\n",
ERR_error_string(ERR_get_error(), NULL));
X509_free(req);
return (XEVNT_PUB);
}
/*
* Generate X509 certificate signed by this server. For this
* purpose the issuer name is the server name. Also copy any
* extensions that might be present.
*/
cert = X509_new();
X509_set_version(cert, X509_get_version(req));
serial = ASN1_INTEGER_new();
ASN1_INTEGER_set(serial, tstamp);
X509_set_serialNumber(cert, serial);
X509_gmtime_adj(X509_get_notBefore(cert), 0L);
X509_gmtime_adj(X509_get_notAfter(cert), YEAR);
subj = X509_get_issuer_name(cert);
X509_NAME_add_entry_by_txt(subj, "commonName", MBSTRING_ASC,
(u_char *)sys_hostname, strlen(sys_hostname), -1, 0);
subj = X509_get_subject_name(req);
X509_set_subject_name(cert, subj);
X509_set_pubkey(cert, pkey);
ext = X509_get_ext(req, 0);
temp = X509_get_ext_count(req);
for (i = 0; i < temp; i++) {
ext = X509_get_ext(req, i);
X509_add_ext(cert, ext, -1);
}
X509_free(req);
/*
* Sign and verify the certificate.
*/
X509_sign(cert, sign_pkey, sign_digest);
if (!X509_verify(cert, sign_pkey)) {
printf("cert_sign\n%s\n",
ERR_error_string(ERR_get_error(), NULL));
X509_free(cert);
return (XEVNT_VFY);
}
len = i2d_X509(cert, NULL);
/*
* Build and sign the value structure. We have to sign it here,
* since the response has to be returned right away. This is a
* clogging hazard.
*/
memset(vp, 0, sizeof(struct value));
vp->tstamp = htonl(tstamp);
vp->fstamp = ep->fstamp;
vp->vallen = htonl(len);
vp->ptr = emalloc(len);
ptr = vp->ptr;
i2d_X509(cert, &ptr);
vp->siglen = 0;
vp->sig = emalloc(sign_siglen);
EVP_SignInit(&ctx, sign_digest);
EVP_SignUpdate(&ctx, (u_char *)vp, 12);
EVP_SignUpdate(&ctx, vp->ptr, len);
if (EVP_SignFinal(&ctx, vp->sig, &len, sign_pkey))
vp->siglen = htonl(len);
#ifdef DEBUG
if (debug > 1)
X509_print_fp(stdout, cert);
#endif
X509_free(cert);
return (XEVNT_OK);
}
/*
* cert_valid - verify certificate with given public key
*
* This is pretty ugly, as the certificate has to be verified in the
* OpenSSL X509 structure, not in the DER format in the info/value
* structure.
*
* Returns
* XEVNT_OK success
* XEVNT_VFY certificate not verified
*/
int
cert_valid(
struct cert_info *cinf, /* certificate information structure */
EVP_PKEY *pkey /* public key */
)
{
X509 *cert; /* X509 certificate */
u_char *ptr;
if (cinf->flags & CERT_SIGN)
return (XEVNT_OK);
ptr = (u_char *)cinf->cert.ptr;
cert = d2i_X509(NULL, &ptr, ntohl(cinf->cert.vallen));
if (cert == NULL || !X509_verify(cert, pkey))
return (XEVNT_VFY);
X509_free(cert);
return (XEVNT_OK);
}
/*
* cert - install certificate in certificate list
*
* This routine encodes an extension field into a certificate info/value
* structure. It searches the certificate list for duplicates and
* expunges whichever is older. It then searches the list for other
* certificates that might be verified by this latest one. Finally, it
* inserts this certificate first on the list.
*
* Returns
* XEVNT_OK success
* XEVNT_FSP bad or missing filestamp
* XEVNT_CRT bad or missing certificate
*/
int
cert_install(
struct exten *ep, /* cert info/value */
struct peer *peer /* peer structure */
)
{
struct cert_info *cp, *xp, *yp, **zp;
/*
* Parse and validate the signed certificate. If valid,
* construct the info/value structure; otherwise, scamper home.
*/
if ((cp = cert_parse((u_char *)ep->pkt, ntohl(ep->vallen),
ntohl(ep->fstamp))) == NULL)
return (XEVNT_CRT);
/*
* Scan certificate list looking for another certificate with
* the same subject and issuer. If another is found with the
* same or older filestamp, unlink it and return the goodies to
* the heap. If another is found with a later filestamp, discard
* the new one and leave the building.
*
* Make a note to study this issue again. An earlier certificate
* with a long lifetime might be overtaken by a later
* certificate with a short lifetime, thus invalidating the
* earlier signature. However, we gotta find a way to leak old
* stuff from the cache, so we do it anyway.
*/
yp = cp;
zp = &cinfo;
for (xp = cinfo; xp != NULL; xp = xp->link) {
if (strcmp(cp->subject, xp->subject) == 0 &&
strcmp(cp->issuer, xp->issuer) == 0) {
if (ntohl(cp->cert.fstamp) <=
ntohl(xp->cert.fstamp)) {
*zp = xp->link;;
cert_free(xp);
} else {
cert_free(cp);
return (XEVNT_FSP);
}
break;
}
zp = &xp->link;
}
yp->link = cinfo;
cinfo = yp;
/*
* Scan the certificate list to see if Y is signed by X. This is
* independent of order.
*/
for (yp = cinfo; yp != NULL; yp = yp->link) {
for (xp = cinfo; xp != NULL; xp = xp->link) {
/*
* If the issuer of certificate Y matches the
* subject of certificate X, verify the
* signature of Y using the public key of X. If
* so, X signs Y.
*/
if (strcmp(yp->issuer, xp->subject) != 0 ||
xp->flags & CERT_ERROR)
continue;
if (cert_valid(yp, xp->pkey) != XEVNT_OK) {
yp->flags |= CERT_ERROR;
continue;
}
/*
* The signature Y is valid only if it begins
* during the lifetime of X; however, it is not
* necessarily an error, since some other
* certificate might sign Y.
*/
if (yp->first < xp->first || yp->first >
xp->last)
continue;
yp->flags |= CERT_SIGN;
/*
* If X is trusted, then Y is trusted. Note that
* we might stumble over a self-signed
* certificate that is not trusted, at least
* temporarily. This can happen when a dude
* first comes up, but has not synchronized the
* clock and had its certificate signed by its
* server. In case of broken certificate trail,
* this might result in a loop that could
* persist until timeout.
*/
if (!(xp->flags & (CERT_TRUST | CERT_VALID)))
continue;
yp->flags |= CERT_VALID;
/*
* If subject Y matches the server subject name,
* then Y has completed the certificate trail.
* Save the group key and light the valid bit.
*/
if (strcmp(yp->subject, peer->subject) != 0)
continue;
if (yp->grpkey != NULL) {
if (peer->grpkey != NULL)
BN_free(peer->grpkey);
peer->grpkey = BN_bin2bn(yp->grpkey,
yp->grplen, NULL);
}
peer->crypto |= CRYPTO_FLAG_VALID;
/*
* If the server has an an identity scheme,
* fetch the identity credentials. If not, the
* identity is verified only by the trusted
* certificate. The next signature will set the
* server proventic.
*/
if (peer->crypto & (CRYPTO_FLAG_GQ |
CRYPTO_FLAG_IFF | CRYPTO_FLAG_MV))
continue;
peer->crypto |= CRYPTO_FLAG_VRFY;
}
}
/*
* That was awesome. Now update the timestamps and signatures.
*/
crypto_update();
return (XEVNT_OK);
}
/*
* cert_free - free certificate information structure
*/
void
cert_free(
struct cert_info *cinf /* certificate info/value structure */
)
{
if (cinf->pkey != NULL)
EVP_PKEY_free(cinf->pkey);
if (cinf->subject != NULL)
free(cinf->subject);
if (cinf->issuer != NULL)
free(cinf->issuer);
if (cinf->grpkey != NULL)
free(cinf->grpkey);
value_free(&cinf->cert);
free(cinf);
}
/*
***********************************************************************
* *
* The following routines are used only at initialization time *
* *
***********************************************************************
*/
/*
* crypto_key - load cryptographic parameters and keys from files
*
* This routine loads a PEM-encoded public/private key pair and extracts
* the filestamp from the file name.
*
* Returns public key pointer if valid, NULL if not. Side effect updates
* the filestamp if valid.
*/
static EVP_PKEY *
crypto_key(
char *cp, /* file name */
tstamp_t *fstamp /* filestamp */
)
{
FILE *str; /* file handle */
EVP_PKEY *pkey = NULL; /* public/private key */
char filename[MAXFILENAME]; /* name of key file */
char linkname[MAXFILENAME]; /* filestamp buffer) */
char statstr[NTP_MAXSTRLEN]; /* statistics for filegen */
char *ptr;
/*
* Open the key file. If the first character of the file name is
* not '/', prepend the keys directory string. If something goes
* wrong, abandon ship.
*/
if (*cp == '/')
strcpy(filename, cp);
else
snprintf(filename, MAXFILENAME, "%s/%s", keysdir, cp);
str = fopen(filename, "r");
if (str == NULL)
return (NULL);
/*
* Read the filestamp, which is contained in the first line.
*/
if ((ptr = fgets(linkname, MAXFILENAME, str)) == NULL) {
msyslog(LOG_ERR, "crypto_key: no data %s\n",
filename);
(void)fclose(str);
return (NULL);
}
if ((ptr = strrchr(ptr, '.')) == NULL) {
msyslog(LOG_ERR, "crypto_key: no filestamp %s\n",
filename);
(void)fclose(str);
return (NULL);
}
if (sscanf(++ptr, "%u", fstamp) != 1) {
msyslog(LOG_ERR, "crypto_key: invalid timestamp %s\n",
filename);
(void)fclose(str);
return (NULL);
}
/*
* Read and decrypt PEM-encoded private key.
*/
pkey = PEM_read_PrivateKey(str, NULL, NULL, passwd);
fclose(str);
if (pkey == NULL) {
msyslog(LOG_ERR, "crypto_key %s\n",
ERR_error_string(ERR_get_error(), NULL));
return (NULL);
}
/*
* Leave tracks in the cryptostats.
*/
if ((ptr = strrchr(linkname, '\n')) != NULL)
*ptr = '\0';
snprintf(statstr, NTP_MAXSTRLEN, "%s mod %d", &linkname[2],
EVP_PKEY_size(pkey) * 8);
record_crypto_stats(NULL, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_key: %s\n", statstr);
if (debug > 1) {
if (pkey->type == EVP_PKEY_DSA)
DSA_print_fp(stdout, pkey->pkey.dsa, 0);
else
RSA_print_fp(stdout, pkey->pkey.rsa, 0);
}
#endif
return (pkey);
}
/*
* crypto_cert - load certificate from file
*
* This routine loads a X.509 RSA or DSA certificate from a file and
* constructs a info/cert value structure for this machine. The
* structure includes a filestamp extracted from the file name. Later
* the certificate can be sent to another machine by request.
*
* Returns certificate info/value pointer if valid, NULL if not.
*/
static struct cert_info * /* certificate information */
crypto_cert(
char *cp /* file name */
)
{
struct cert_info *ret; /* certificate information */
FILE *str; /* file handle */
char filename[MAXFILENAME]; /* name of certificate file */
char linkname[MAXFILENAME]; /* filestamp buffer */
char statstr[NTP_MAXSTRLEN]; /* statistics for filegen */
tstamp_t fstamp; /* filestamp */
long len;
char *ptr;
char *name, *header;
u_char *data;
/*
* Open the certificate file. If the first character of the file
* name is not '/', prepend the keys directory string. If
* something goes wrong, abandon ship.
*/
if (*cp == '/')
strcpy(filename, cp);
else
snprintf(filename, MAXFILENAME, "%s/%s", keysdir, cp);
str = fopen(filename, "r");
if (str == NULL)
return (NULL);
/*
* Read the filestamp, which is contained in the first line.
*/
if ((ptr = fgets(linkname, MAXFILENAME, str)) == NULL) {
msyslog(LOG_ERR, "crypto_cert: no data %s\n",
filename);
(void)fclose(str);
return (NULL);
}
if ((ptr = strrchr(ptr, '.')) == NULL) {
msyslog(LOG_ERR, "crypto_cert: no filestamp %s\n",
filename);
(void)fclose(str);
return (NULL);
}
if (sscanf(++ptr, "%u", &fstamp) != 1) {
msyslog(LOG_ERR, "crypto_cert: invalid filestamp %s\n",
filename);
(void)fclose(str);
return (NULL);
}
/*
* Read PEM-encoded certificate and install.
*/
if (!PEM_read(str, &name, &header, &data, &len)) {
msyslog(LOG_ERR, "crypto_cert %s\n",
ERR_error_string(ERR_get_error(), NULL));
(void)fclose(str);
return (NULL);
}
free(header);
if (strcmp(name, "CERTIFICATE") !=0) {
msyslog(LOG_INFO, "crypto_cert: wrong PEM type %s",
name);
free(name);
free(data);
(void)fclose(str);
return (NULL);
}
free(name);
/*
* Parse certificate and generate info/value structure.
*/
ret = cert_parse(data, len, fstamp);
free(data);
(void)fclose(str);
if (ret == NULL)
return (NULL);
if ((ptr = strrchr(linkname, '\n')) != NULL)
*ptr = '\0';
snprintf(statstr, NTP_MAXSTRLEN,
"%s 0x%x len %lu", &linkname[2], ret->flags, len);
record_crypto_stats(NULL, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_cert: %s\n", statstr);
#endif
return (ret);
}
/*
* crypto_tai - load leapseconds table from file
*
* This routine loads the ERTS leapsecond file in NIST text format,
* converts to a value structure and extracts a filestamp from the file
* name. The data are used to establish the TAI offset from UTC, which
* is provided to the kernel if supported. Later the data can be sent to
* another machine on request.
*/
static void
crypto_tai(
char *cp /* file name */
)
{
FILE *str; /* file handle */
char buf[NTP_MAXSTRLEN]; /* file line buffer */
u_int32 leapsec[MAX_LEAP]; /* NTP time at leaps */
int offset; /* offset at leap (s) */
char filename[MAXFILENAME]; /* name of leapseconds file */
char linkname[MAXFILENAME]; /* file link (for filestamp) */
char statstr[NTP_MAXSTRLEN]; /* statistics for filegen */
tstamp_t fstamp; /* filestamp */
u_int len;
u_int32 *ptr;
char *dp;
int rval, i, j;
/*
* Open the file and discard comment lines. If the first
* character of the file name is not '/', prepend the keys
* directory string. If the file is not found, not to worry; it
* can be retrieved over the net. But, if it is found with
* errors, we crash and burn.
*/
if (*cp == '/')
strcpy(filename, cp);
else
snprintf(filename, MAXFILENAME, "%s/%s", keysdir, cp);
if ((str = fopen(filename, "r")) == NULL)
return;
/*
* Extract filestamp if present.
*/
rval = readlink(filename, linkname, MAXFILENAME - 1);
if (rval > 0) {
linkname[rval] = '\0';
dp = strrchr(linkname, '.');
} else {
dp = strrchr(filename, '.');
}
if (dp != NULL)
sscanf(++dp, "%u", &fstamp);
else
fstamp = 0;
tai_leap.fstamp = htonl(fstamp);
/*
* We are rather paranoid here, since an intruder might cause a
* coredump by infiltrating naughty values. Empty lines and
* comments are ignored. Other lines must begin with two
* integers followed by junk or comments. The first integer is
* the NTP seconds of leap insertion, the second is the offset
* of TAI relative to UTC after that insertion. The second word
* must equal the initial insertion of ten seconds on 1 January
* 1972 plus one second for each succeeding insertion.
*/
i = 0;
while (i < MAX_LEAP) {
dp = fgets(buf, NTP_MAXSTRLEN - 1, str);
if (dp == NULL)
break;
if (strlen(buf) < 1)
continue;
if (*buf == '#')
continue;
if (sscanf(buf, "%u %d", &leapsec[i], &offset) != 2)
continue;
if (i != offset - TAI_1972)
break;
i++;
}
fclose(str);
if (dp != NULL) {
msyslog(LOG_INFO,
"crypto_tai: leapseconds file %s error %d", cp,
rval);
exit (-1);
}
/*
* The extension field table entries consists of the NTP seconds
* of leap insertion in network byte order.
*/
len = i * sizeof(u_int32);
tai_leap.vallen = htonl(len);
ptr = emalloc(len);
tai_leap.ptr = (u_char *)ptr;
for (j = 0; j < i; j++)
*ptr++ = htonl(leapsec[j]);
crypto_flags |= CRYPTO_FLAG_TAI;
snprintf(statstr, NTP_MAXSTRLEN, "%s fs %u leap %u len %u", cp, fstamp,
leapsec[--j], len);
record_crypto_stats(NULL, statstr);
#ifdef DEBUG
if (debug)
printf("crypto_tai: %s\n", statstr);
#endif
}
/*
* crypto_setup - load keys, certificate and leapseconds table
*
* This routine loads the public/private host key and certificate. If
* available, it loads the public/private sign key, which defaults to
* the host key, and leapseconds table. The host key must be RSA, but
* the sign key can be either RSA or DSA. In either case, the public key
* on the certificate must agree with the sign key.
*/
void
crypto_setup(void)
{
EVP_PKEY *pkey; /* private/public key pair */
char filename[MAXFILENAME]; /* file name buffer */
l_fp seed; /* crypto PRNG seed as NTP timestamp */
tstamp_t fstamp; /* filestamp */
tstamp_t sstamp; /* sign filestamp */
u_int len, bytes;
u_char *ptr;
/*
* Initialize structures.
*/
if (!crypto_flags)
return;
gethostname(filename, MAXFILENAME);
bytes = strlen(filename) + 1;
sys_hostname = emalloc(bytes);
memcpy(sys_hostname, filename, bytes);
if (passwd == NULL)
passwd = sys_hostname;
memset(&hostval, 0, sizeof(hostval));
memset(&pubkey, 0, sizeof(pubkey));
memset(&tai_leap, 0, sizeof(tai_leap));
/*
* Load required random seed file and seed the random number
* generator. Be default, it is found in the user home
* directory. The root home directory may be / or /root,
* depending on the system. Wiggle the contents a bit and write
* it back so the sequence does not repeat when we next restart.
*/
ERR_load_crypto_strings();
if (rand_file == NULL) {
if ((RAND_file_name(filename, MAXFILENAME)) != NULL) {
rand_file = emalloc(strlen(filename) + 1);
strcpy(rand_file, filename);
}
} else if (*rand_file != '/') {
snprintf(filename, MAXFILENAME, "%s/%s", keysdir,
rand_file);
free(rand_file);
rand_file = emalloc(strlen(filename) + 1);
strcpy(rand_file, filename);
}
if (rand_file == NULL) {
msyslog(LOG_ERR,
"crypto_setup: random seed file not specified");
exit (-1);
}
if ((bytes = RAND_load_file(rand_file, -1)) == 0) {
msyslog(LOG_ERR,
"crypto_setup: random seed file %s not found\n",
rand_file);
exit (-1);
}
get_systime(&seed);
RAND_seed(&seed, sizeof(l_fp));
RAND_write_file(rand_file);
OpenSSL_add_all_algorithms();
#ifdef DEBUG
if (debug)
printf(
"crypto_setup: OpenSSL version %lx random seed file %s bytes read %d\n",
SSLeay(), rand_file, bytes);
#endif
/*
* Load required host key from file "ntpkey_host_<hostname>". It
* also becomes the default sign key.
*/
if (host_file == NULL) {
snprintf(filename, MAXFILENAME, "ntpkey_host_%s",
sys_hostname);
host_file = emalloc(strlen(filename) + 1);
strcpy(host_file, filename);
}
pkey = crypto_key(host_file, &fstamp);
if (pkey == NULL) {
msyslog(LOG_ERR,
"crypto_setup: host key file %s not found or corrupt",
host_file);
exit (-1);
}
host_pkey = pkey;
sign_pkey = pkey;
sstamp = fstamp;
hostval.fstamp = htonl(fstamp);
if (host_pkey->type != EVP_PKEY_RSA) {
msyslog(LOG_ERR,
"crypto_setup: host key is not RSA key type");
exit (-1);
}
hostval.vallen = htonl(strlen(sys_hostname));
hostval.ptr = (u_char *)sys_hostname;
/*
* Construct public key extension field for agreement scheme.
*/
len = i2d_PublicKey(host_pkey, NULL);
ptr = emalloc(len);
pubkey.ptr = ptr;
i2d_PublicKey(host_pkey, &ptr);
pubkey.vallen = htonl(len);
pubkey.fstamp = hostval.fstamp;
/*
* Load optional sign key from file "ntpkey_sign_<hostname>". If
* loaded, it becomes the sign key.
*/
if (sign_file == NULL) {
snprintf(filename, MAXFILENAME, "ntpkey_sign_%s",
sys_hostname);
sign_file = emalloc(strlen(filename) + 1);
strcpy(sign_file, filename);
}
pkey = crypto_key(sign_file, &fstamp);
if (pkey != NULL) {
sign_pkey = pkey;
sstamp = fstamp;
}
sign_siglen = EVP_PKEY_size(sign_pkey);
/*
* Load optional IFF parameters from file
* "ntpkey_iff_<hostname>".
*/
if (iffpar_file == NULL) {
snprintf(filename, MAXFILENAME, "ntpkey_iff_%s",
sys_hostname);
iffpar_file = emalloc(strlen(filename) + 1);
strcpy(iffpar_file, filename);
}
iffpar_pkey = crypto_key(iffpar_file, &if_fstamp);
if (iffpar_pkey != NULL)
crypto_flags |= CRYPTO_FLAG_IFF;
/*
* Load optional GQ parameters from file "ntpkey_gq_<hostname>".
*/
if (gqpar_file == NULL) {
snprintf(filename, MAXFILENAME, "ntpkey_gq_%s",
sys_hostname);
gqpar_file = emalloc(strlen(filename) + 1);
strcpy(gqpar_file, filename);
}
gqpar_pkey = crypto_key(gqpar_file, &gq_fstamp);
if (gqpar_pkey != NULL)
crypto_flags |= CRYPTO_FLAG_GQ;
/*
* Load optional MV parameters from file "ntpkey_mv_<hostname>".
*/
if (mvpar_file == NULL) {
snprintf(filename, MAXFILENAME, "ntpkey_mv_%s",
sys_hostname);
mvpar_file = emalloc(strlen(filename) + 1);
strcpy(mvpar_file, filename);
}
mvpar_pkey = crypto_key(mvpar_file, &mv_fstamp);
if (mvpar_pkey != NULL)
crypto_flags |= CRYPTO_FLAG_MV;
/*
* Load required certificate from file "ntpkey_cert_<hostname>".
*/
if (cert_file == NULL) {
snprintf(filename, MAXFILENAME, "ntpkey_cert_%s",
sys_hostname);
cert_file = emalloc(strlen(filename) + 1);
strcpy(cert_file, filename);
}
if ((cinfo = crypto_cert(cert_file)) == NULL) {
msyslog(LOG_ERR,
"certificate file %s not found or corrupt",
cert_file);
exit (-1);
}
/*
* The subject name must be the same as the host name, unless
* the certificate is private, in which case it may have come
* from another host.
*/
if (!(cinfo->flags & CERT_PRIV) && strcmp(cinfo->subject,
sys_hostname) != 0) {
msyslog(LOG_ERR,
"crypto_setup: certificate %s not for this host",
cert_file);
cert_free(cinfo);
exit (-1);
}
/*
* It the certificate is trusted, the subject must be the same
* as the issuer, in other words it must be self signed.
*/
if (cinfo->flags & CERT_TRUST && strcmp(cinfo->subject,
cinfo->issuer) != 0) {
if (cert_valid(cinfo, sign_pkey) != XEVNT_OK) {
msyslog(LOG_ERR,
"crypto_setup: certificate %s is trusted, but not self signed.",
cert_file);
cert_free(cinfo);
exit (-1);
}
}
sign_digest = cinfo->digest;
if (cinfo->flags & CERT_PRIV)
crypto_flags |= CRYPTO_FLAG_PRIV;
crypto_flags |= cinfo->nid << 16;
/*
* Load optional leapseconds table from file "ntpkey_leap". If
* the file is missing or defective, the values can later be
* retrieved from a server.
*/
if (leap_file == NULL)
leap_file = "ntpkey_leap";
crypto_tai(leap_file);
#ifdef DEBUG
if (debug)
printf(
"crypto_setup: flags 0x%x host %s signature %s\n",
crypto_flags, sys_hostname, OBJ_nid2ln(cinfo->nid));
#endif
}
/*
* crypto_config - configure data from crypto configuration command.
*/
void
crypto_config(
int item, /* configuration item */
char *cp /* file name */
)
{
switch (item) {
/*
* Set random seed file name.
*/
case CRYPTO_CONF_RAND:
rand_file = emalloc(strlen(cp) + 1);
strcpy(rand_file, cp);
break;
/*
* Set private key password.
*/
case CRYPTO_CONF_PW:
passwd = emalloc(strlen(cp) + 1);
strcpy(passwd, cp);
break;
/*
* Set host file name.
*/
case CRYPTO_CONF_PRIV:
host_file = emalloc(strlen(cp) + 1);
strcpy(host_file, cp);
break;
/*
* Set sign key file name.
*/
case CRYPTO_CONF_SIGN:
sign_file = emalloc(strlen(cp) + 1);
strcpy(sign_file, cp);
break;
/*
* Set iff parameters file name.
*/
case CRYPTO_CONF_IFFPAR:
iffpar_file = emalloc(strlen(cp) + 1);
strcpy(iffpar_file, cp);
break;
/*
* Set gq parameters file name.
*/
case CRYPTO_CONF_GQPAR:
gqpar_file = emalloc(strlen(cp) + 1);
strcpy(gqpar_file, cp);
break;
/*
* Set mv parameters file name.
*/
case CRYPTO_CONF_MVPAR:
mvpar_file = emalloc(strlen(cp) + 1);
strcpy(mvpar_file, cp);
break;
/*
* Set identity scheme.
*/
case CRYPTO_CONF_IDENT:
if (!strcasecmp(cp, "iff"))
ident_scheme |= CRYPTO_FLAG_IFF;
else if (!strcasecmp(cp, "gq"))
ident_scheme |= CRYPTO_FLAG_GQ;
else if (!strcasecmp(cp, "mv"))
ident_scheme |= CRYPTO_FLAG_MV;
break;
/*
* Set certificate file name.
*/
case CRYPTO_CONF_CERT:
cert_file = emalloc(strlen(cp) + 1);
strcpy(cert_file, cp);
break;
/*
* Set leapseconds file name.
*/
case CRYPTO_CONF_LEAP:
leap_file = emalloc(strlen(cp) + 1);
strcpy(leap_file, cp);
break;
}
crypto_flags |= CRYPTO_FLAG_ENAB;
}
# else
int ntp_crypto_bs_pubkey;
# endif /* OPENSSL */