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gecko-dev/security/nss/lib/ssl/sslsnce.c

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C
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/* This file implements the SERVER Session ID cache.
* NOTE: The contents of this file are NOT used by the client.
*
* The contents of this file are subject to the Mozilla Public
* License Version 1.1 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS
* IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
* implied. See the License for the specific language governing
* rights and limitations under the License.
*
* The Original Code is the Netscape security libraries.
*
* The Initial Developer of the Original Code is Netscape
* Communications Corporation. Portions created by Netscape are
* Copyright (C) 1994-2000 Netscape Communications Corporation. All
* Rights Reserved.
*
* Contributor(s):
*
* Alternatively, the contents of this file may be used under the
* terms of the GNU General Public License Version 2 or later (the
* "GPL"), in which case the provisions of the GPL are applicable
* instead of those above. If you wish to allow use of your
* version of this file only under the terms of the GPL and not to
* allow others to use your version of this file under the MPL,
* indicate your decision by deleting the provisions above and
* replace them with the notice and other provisions required by
* the GPL. If you do not delete the provisions above, a recipient
* may use your version of this file under either the MPL or the
* GPL.
*
* $Id: sslsnce.c,v 1.18 2002/01/09 23:22:19 javi%netscape.com Exp $
*/
/* Note: ssl_FreeSID() in sslnonce.c gets used for both client and server
* cache sids!
*
* About record locking among different server processes:
*
* All processes that are part of the same conceptual server (serving on
* the same address and port) MUST share a common SSL session cache.
* This code makes the content of the shared cache accessible to all
* processes on the same "server". This code works on Unix and Win32 only.
*
* We use NSPR anonymous shared memory and move data to & from shared memory.
* We must do explicit locking of the records for all reads and writes.
* The set of Cache entries are divided up into "sets" of 128 entries.
* Each set is protected by a lock. There may be one or more sets protected
* by each lock. That is, locks to sets are 1:N.
* There is one lock for the entire cert cache.
* There is one lock for the set of wrapped sym wrap keys.
*
* The anonymous shared memory is laid out as if it were declared like this:
*
* struct {
* cacheDescriptor desc;
* sidCacheLock sidCacheLocks[ numSIDCacheLocks];
* sidCacheLock keyCacheLock;
* sidCacheLock certCacheLock;
* sidCacheSet sidCacheSets[ numSIDCacheSets ];
* sidCacheEntry sidCacheData[ numSIDCacheEntries];
* certCacheEntry certCacheData[numCertCacheEntries];
* SSLWrappedSymWrappingKey keyCacheData[kt_kea_size][SSL_NUM_WRAP_MECHS];
* } sharedMemCacheData;
*/
#include "nssrenam.h"
#include "seccomon.h"
#if defined(XP_UNIX) || defined(XP_WIN32) || defined (XP_OS2)
#include "cert.h"
#include "ssl.h"
#include "sslimpl.h"
#include "sslproto.h"
#include "pk11func.h"
#include "base64.h"
#include <stdio.h>
#ifdef XP_UNIX
#include <syslog.h>
#include <fcntl.h>
#include <unistd.h>
#include <errno.h>
#include <signal.h>
#include "unix_err.h"
#else
#ifdef XP_WIN32
#include <wtypes.h>
#include "win32err.h"
#endif
#endif
#include <sys/types.h>
#define SET_ERROR_CODE /* reminder */
#include "nspr.h"
#include "nsslocks.h"
#include "sslmutex.h"
#ifdef XP_OS2_VACPP
#pragma pack(1)
#endif
/*
** Format of a cache entry in the shared memory.
*/
struct sidCacheEntryStr {
/* 16 */ PRIPv6Addr addr; /* client's IP address */
/* 4 */ PRUint32 creationTime;
/* 4 */ PRUint32 lastAccessTime;
/* 4 */ PRUint32 expirationTime;
/* 2 */ PRUint16 version;
/* 1 */ PRUint8 valid;
/* 1 */ PRUint8 sessionIDLength;
/* 32 */ PRUint8 sessionID[SSL3_SESSIONID_BYTES];
/* 2 */ PRUint16 authAlgorithm;
/* 2 */ PRUint16 authKeyBits;
/* 2 */ PRUint16 keaType;
/* 2 */ PRUint16 keaKeyBits;
/* 72 - common header total */
union {
struct {
/* 64 */ PRUint8 masterKey[SSL_MAX_MASTER_KEY_BYTES];
/* 32 */ PRUint8 cipherArg[SSL_MAX_CYPHER_ARG_BYTES];
/* 1 */ PRUint8 cipherType;
/* 1 */ PRUint8 masterKeyLen;
/* 1 */ PRUint8 keyBits;
/* 1 */ PRUint8 secretKeyBits;
/* 1 */ PRUint8 cipherArgLen;
/*101 */} ssl2;
struct {
/* 2 */ ssl3CipherSuite cipherSuite;
/* 2 */ PRUint16 compression; /* SSL3CompressionMethod */
/*122 */ ssl3SidKeys keys; /* keys and ivs, wrapped as needed. */
/* 1 */ PRUint8 hasFortezza;
/* 1 */ PRUint8 resumable;
/* 4 */ PRUint32 masterWrapMech;
/* 4 */ SSL3KEAType exchKeyType;
/* 4 */ PRInt32 certIndex;
/*140 */} ssl3;
#if defined(LINUX)
struct {
PRUint8 filler[144];
} forceSize;
#endif
} u;
};
typedef struct sidCacheEntryStr sidCacheEntry;
/* The length of this struct is supposed to be a power of 2, e.g. 4KB */
struct certCacheEntryStr {
PRUint16 certLength; /* 2 */
PRUint16 sessionIDLength; /* 2 */
PRUint8 sessionID[SSL3_SESSIONID_BYTES]; /* 32 */
PRUint8 cert[SSL_MAX_CACHED_CERT_LEN]; /* 4060 */
}; /* total 4096 */
typedef struct certCacheEntryStr certCacheEntry;
struct sidCacheLockStr {
PRUint32 timeStamp;
sslMutex mutex;
sslPID pid;
};
typedef struct sidCacheLockStr sidCacheLock;
struct sidCacheSetStr {
PRIntn next;
};
typedef struct sidCacheSetStr sidCacheSet;
struct cacheDescStr {
PRUint32 sharedMemSize;
PRUint32 numSIDCacheLocks;
PRUint32 numSIDCacheSets;
PRUint32 numSIDCacheSetsPerLock;
PRUint32 numSIDCacheEntries;
PRUint32 sidCacheSize;
PRUint32 numCertCacheEntries;
PRUint32 certCacheSize;
PRUint32 numKeyCacheEntries;
PRUint32 keyCacheSize;
PRUint32 ssl2Timeout;
PRUint32 ssl3Timeout;
/* These values are volatile, and are accessed through sharedCache-> */
PRUint32 nextCertCacheEntry; /* certCacheLock protects */
PRBool stopPolling;
/* The private copies of these values are pointers into shared mem */
/* The copies of these values in shared memory are merely offsets */
sidCacheLock * sidCacheLocks;
sidCacheLock * keyCacheLock;
sidCacheLock * certCacheLock;
sidCacheSet * sidCacheSets;
sidCacheEntry * sidCacheData;
certCacheEntry * certCacheData;
SSLWrappedSymWrappingKey * keyCacheData;
/* Only the private copies of these pointers are valid */
char * sharedMem;
struct cacheDescStr * sharedCache; /* shared copy of this struct */
PRFileMap * cacheMemMap;
PRThread * poller;
};
typedef struct cacheDescStr cacheDesc;
static cacheDesc globalCache;
static const char envVarName[] = { SSL_ENV_VAR_NAME };
static PRBool isMultiProcess = PR_FALSE;
#define DEF_SID_CACHE_ENTRIES 10000
#define DEF_CERT_CACHE_ENTRIES 250
#define MIN_CERT_CACHE_ENTRIES 125 /* the effective size in old releases. */
#define DEF_KEY_CACHE_ENTRIES 250
#define SID_CACHE_ENTRIES_PER_SET 128
#define SID_ALIGNMENT 16
#define DEF_SSL2_TIMEOUT 100 /* seconds */
#define MAX_SSL2_TIMEOUT 100 /* seconds */
#define MIN_SSL2_TIMEOUT 5 /* seconds */
#define DEF_SSL3_TIMEOUT 86400L /* 24 hours */
#define MAX_SSL3_TIMEOUT 86400L /* 24 hours */
#define MIN_SSL3_TIMEOUT 5 /* seconds */
#if defined(AIX) || defined(LINUX)
#define MAX_SID_CACHE_LOCKS 8 /* two FDs per lock */
#elif defined(OSF1)
#define MAX_SID_CACHE_LOCKS 16 /* one FD per lock */
#else
#define MAX_SID_CACHE_LOCKS 256
#endif
#define SID_HOWMANY(val, size) (((val) + ((size) - 1)) / (size))
#define SID_ROUNDUP(val, size) ((size) * SID_HOWMANY((val), (size)))
static sslPID myPid;
static PRUint32 ssl_max_sid_cache_locks = MAX_SID_CACHE_LOCKS;
/* forward static function declarations */
static void IOError(int rv, char *type);
static PRUint32 SIDindex(cacheDesc *cache, const PRIPv6Addr *addr, PRUint8 *s, unsigned nl);
static SECStatus LaunchLockPoller(cacheDesc *cache);
struct inheritanceStr {
PRUint32 sharedMemSize;
PRUint16 fmStrLen;
};
typedef struct inheritanceStr inheritance;
#if defined(_WIN32) || defined(XP_OS2)
#define DEFAULT_CACHE_DIRECTORY "\\temp"
#endif /* _win32 */
#ifdef XP_UNIX
#define DEFAULT_CACHE_DIRECTORY "/tmp"
#endif /* XP_UNIX */
/************************************************************************/
static void
IOError(int rv, char *type)
{
#ifdef XP_UNIX
syslog(LOG_ALERT,
"SSL: %s error with session-id cache, pid=%d, rv=%d, error='%m'",
type, myPid, rv);
#else /* XP_WIN32 */
/* wish win32 had something like syslog() */
#endif /* XP_UNIX */
}
static PRUint32
LockSidCacheLock(sidCacheLock *lock, PRUint32 now)
{
SECStatus rv = sslMutex_Lock(&lock->mutex);
if (rv != SECSuccess)
return 0;
if (!now)
now = ssl_Time();
lock->timeStamp = now;
lock->pid = myPid;
return now;
}
static SECStatus
UnlockSidCacheLock(sidCacheLock *lock)
{
SECStatus rv;
lock->pid = 0;
rv = sslMutex_Unlock(&lock->mutex);
return rv;
}
/* returns the value of ssl_Time on success, zero on failure. */
static PRUint32
LockSet(cacheDesc *cache, PRUint32 set, PRUint32 now)
{
PRUint32 lockNum = set % cache->numSIDCacheLocks;
sidCacheLock * lock = cache->sidCacheLocks + lockNum;
return LockSidCacheLock(lock, now);
}
static SECStatus
UnlockSet(cacheDesc *cache, PRUint32 set)
{
PRUint32 lockNum = set % cache->numSIDCacheLocks;
sidCacheLock * lock = cache->sidCacheLocks + lockNum;
return UnlockSidCacheLock(lock);
}
/************************************************************************/
/* Put a certificate in the cache. Update the cert index in the sce.
*/
static PRUint32
CacheCert(cacheDesc * cache, CERTCertificate *cert, sidCacheEntry *sce)
{
PRUint32 now;
certCacheEntry cce;
if ((cert->derCert.len > SSL_MAX_CACHED_CERT_LEN) ||
(cert->derCert.len <= 0) ||
(cert->derCert.data == NULL)) {
PORT_SetError(SEC_ERROR_INVALID_ARGS);
return 0;
}
cce.sessionIDLength = sce->sessionIDLength;
PORT_Memcpy(cce.sessionID, sce->sessionID, cce.sessionIDLength);
cce.certLength = cert->derCert.len;
PORT_Memcpy(cce.cert, cert->derCert.data, cce.certLength);
/* get lock on cert cache */
now = LockSidCacheLock(cache->certCacheLock, 0);
if (now) {
/* Find where to place the next cert cache entry. */
cacheDesc * sharedCache = cache->sharedCache;
PRUint32 ndx = sharedCache->nextCertCacheEntry;
/* write the entry */
cache->certCacheData[ndx] = cce;
/* remember where we put it. */
sce->u.ssl3.certIndex = ndx;
/* update the "next" cache entry index */
sharedCache->nextCertCacheEntry =
(ndx + 1) % cache->numCertCacheEntries;
UnlockSidCacheLock(cache->certCacheLock);
}
return now;
}
/*
** Convert local SID to shared memory one
*/
static void
ConvertFromSID(sidCacheEntry *to, sslSessionID *from)
{
to->valid = 1;
to->version = from->version;
to->addr = from->addr;
to->creationTime = from->creationTime;
to->lastAccessTime = from->lastAccessTime;
to->expirationTime = from->expirationTime;
to->authAlgorithm = from->authAlgorithm;
to->authKeyBits = from->authKeyBits;
to->keaType = from->keaType;
to->keaKeyBits = from->keaKeyBits;
if (from->version < SSL_LIBRARY_VERSION_3_0) {
if ((from->u.ssl2.masterKey.len > SSL_MAX_MASTER_KEY_BYTES) ||
(from->u.ssl2.cipherArg.len > SSL_MAX_CYPHER_ARG_BYTES)) {
SSL_DBG(("%d: SSL: masterKeyLen=%d cipherArgLen=%d",
myPid, from->u.ssl2.masterKey.len,
from->u.ssl2.cipherArg.len));
to->valid = 0;
return;
}
to->u.ssl2.cipherType = from->u.ssl2.cipherType;
to->u.ssl2.masterKeyLen = from->u.ssl2.masterKey.len;
to->u.ssl2.cipherArgLen = from->u.ssl2.cipherArg.len;
to->u.ssl2.keyBits = from->u.ssl2.keyBits;
to->u.ssl2.secretKeyBits = from->u.ssl2.secretKeyBits;
to->sessionIDLength = SSL2_SESSIONID_BYTES;
PORT_Memcpy(to->sessionID, from->u.ssl2.sessionID, SSL2_SESSIONID_BYTES);
PORT_Memcpy(to->u.ssl2.masterKey, from->u.ssl2.masterKey.data,
from->u.ssl2.masterKey.len);
PORT_Memcpy(to->u.ssl2.cipherArg, from->u.ssl2.cipherArg.data,
from->u.ssl2.cipherArg.len);
#ifdef DEBUG
PORT_Memset(to->u.ssl2.masterKey+from->u.ssl2.masterKey.len, 0,
sizeof(to->u.ssl2.masterKey) - from->u.ssl2.masterKey.len);
PORT_Memset(to->u.ssl2.cipherArg+from->u.ssl2.cipherArg.len, 0,
sizeof(to->u.ssl2.cipherArg) - from->u.ssl2.cipherArg.len);
#endif
SSL_TRC(8, ("%d: SSL: ConvertSID: masterKeyLen=%d cipherArgLen=%d "
"time=%d addr=0x%08x%08x%08x%08x cipherType=%d", myPid,
to->u.ssl2.masterKeyLen, to->u.ssl2.cipherArgLen,
to->creationTime, to->addr.pr_s6_addr32[0],
to->addr.pr_s6_addr32[1], to->addr.pr_s6_addr32[2],
to->addr.pr_s6_addr32[3], to->u.ssl2.cipherType));
} else {
/* This is an SSL v3 session */
to->u.ssl3.cipherSuite = from->u.ssl3.cipherSuite;
to->u.ssl3.compression = (uint16)from->u.ssl3.compression;
to->u.ssl3.resumable = from->u.ssl3.resumable;
to->u.ssl3.hasFortezza = from->u.ssl3.hasFortezza;
to->u.ssl3.keys = from->u.ssl3.keys;
to->u.ssl3.masterWrapMech = from->u.ssl3.masterWrapMech;
to->u.ssl3.exchKeyType = from->u.ssl3.exchKeyType;
to->sessionIDLength = from->u.ssl3.sessionIDLength;
to->u.ssl3.certIndex = -1;
PORT_Memcpy(to->sessionID, from->u.ssl3.sessionID,
to->sessionIDLength);
SSL_TRC(8, ("%d: SSL3: ConvertSID: time=%d addr=0x%08x%08x%08x%08x "
"cipherSuite=%d",
myPid, to->creationTime, to->addr.pr_s6_addr32[0],
to->addr.pr_s6_addr32[1], to->addr.pr_s6_addr32[2],
to->addr.pr_s6_addr32[3], to->u.ssl3.cipherSuite));
}
}
/*
** Convert shared memory cache-entry to local memory based one
** This is only called from ServerSessionIDLookup().
** Caller must hold cache lock when calling this.
*/
static sslSessionID *
ConvertToSID(sidCacheEntry *from, certCacheEntry *pcce,
CERTCertDBHandle * dbHandle)
{
sslSessionID *to;
uint16 version = from->version;
to = (sslSessionID*) PORT_ZAlloc(sizeof(sslSessionID));
if (!to) {
return 0;
}
if (version < SSL_LIBRARY_VERSION_3_0) {
/* This is an SSL v2 session */
to->u.ssl2.masterKey.data =
(unsigned char*) PORT_Alloc(from->u.ssl2.masterKeyLen);
if (!to->u.ssl2.masterKey.data) {
goto loser;
}
if (from->u.ssl2.cipherArgLen) {
to->u.ssl2.cipherArg.data =
(unsigned char*)PORT_Alloc(from->u.ssl2.cipherArgLen);
if (!to->u.ssl2.cipherArg.data) {
goto loser;
}
PORT_Memcpy(to->u.ssl2.cipherArg.data, from->u.ssl2.cipherArg,
from->u.ssl2.cipherArgLen);
}
to->u.ssl2.cipherType = from->u.ssl2.cipherType;
to->u.ssl2.masterKey.len = from->u.ssl2.masterKeyLen;
to->u.ssl2.cipherArg.len = from->u.ssl2.cipherArgLen;
to->u.ssl2.keyBits = from->u.ssl2.keyBits;
to->u.ssl2.secretKeyBits = from->u.ssl2.secretKeyBits;
/* to->sessionIDLength = SSL2_SESSIONID_BYTES; */
PORT_Memcpy(to->u.ssl2.sessionID, from->sessionID, SSL2_SESSIONID_BYTES);
PORT_Memcpy(to->u.ssl2.masterKey.data, from->u.ssl2.masterKey,
from->u.ssl2.masterKeyLen);
SSL_TRC(8, ("%d: SSL: ConvertToSID: masterKeyLen=%d cipherArgLen=%d "
"time=%d addr=0x%08x%08x%08x%08x cipherType=%d",
myPid, to->u.ssl2.masterKey.len,
to->u.ssl2.cipherArg.len, to->creationTime,
to->addr.pr_s6_addr32[0], to->addr.pr_s6_addr32[1],
to->addr.pr_s6_addr32[2], to->addr.pr_s6_addr32[3],
to->u.ssl2.cipherType));
} else {
/* This is an SSL v3 session */
to->u.ssl3.sessionIDLength = from->sessionIDLength;
to->u.ssl3.cipherSuite = from->u.ssl3.cipherSuite;
to->u.ssl3.compression = (SSL3CompressionMethod)from->u.ssl3.compression;
to->u.ssl3.resumable = from->u.ssl3.resumable;
to->u.ssl3.hasFortezza = from->u.ssl3.hasFortezza;
to->u.ssl3.keys = from->u.ssl3.keys;
to->u.ssl3.masterWrapMech = from->u.ssl3.masterWrapMech;
to->u.ssl3.exchKeyType = from->u.ssl3.exchKeyType;
PORT_Memcpy(to->u.ssl3.sessionID, from->sessionID, from->sessionIDLength);
/* the portions of the SID that are only restored on the client
* are set to invalid values on the server.
*/
to->u.ssl3.clientWriteKey = NULL;
to->u.ssl3.serverWriteKey = NULL;
to->u.ssl3.tek = NULL;
to->urlSvrName = NULL;
to->u.ssl3.masterModuleID = (SECMODModuleID)-1; /* invalid value */
to->u.ssl3.masterSlotID = (CK_SLOT_ID)-1; /* invalid value */
to->u.ssl3.masterWrapIndex = 0;
to->u.ssl3.masterWrapSeries = 0;
to->u.ssl3.masterValid = PR_FALSE;
to->u.ssl3.clAuthModuleID = (SECMODModuleID)-1; /* invalid value */
to->u.ssl3.clAuthSlotID = (CK_SLOT_ID)-1; /* invalid value */
to->u.ssl3.clAuthSeries = 0;
to->u.ssl3.clAuthValid = PR_FALSE;
to->u.ssl3.clientWriteSaveLen = 0;
if (from->u.ssl3.certIndex != -1 && pcce) {
SECItem derCert;
derCert.len = pcce->certLength;
derCert.data = pcce->cert;
to->peerCert = CERT_NewTempCertificate(dbHandle, &derCert, NULL,
PR_FALSE, PR_TRUE);
if (to->peerCert == NULL)
goto loser;
}
}
to->version = from->version;
to->creationTime = from->creationTime;
to->lastAccessTime = from->lastAccessTime;
to->expirationTime = from->expirationTime;
to->cached = in_server_cache;
to->addr = from->addr;
to->references = 1;
to->authAlgorithm = from->authAlgorithm;
to->authKeyBits = from->authKeyBits;
to->keaType = from->keaType;
to->keaKeyBits = from->keaKeyBits;
return to;
loser:
if (to) {
if (version < SSL_LIBRARY_VERSION_3_0) {
if (to->u.ssl2.masterKey.data)
PORT_Free(to->u.ssl2.masterKey.data);
if (to->u.ssl2.cipherArg.data)
PORT_Free(to->u.ssl2.cipherArg.data);
}
PORT_Free(to);
}
return NULL;
}
/*
** Perform some mumbo jumbo on the ip-address and the session-id value to
** compute a hash value.
*/
static PRUint32
SIDindex(cacheDesc *cache, const PRIPv6Addr *addr, PRUint8 *s, unsigned nl)
{
PRUint32 rv;
PRUint32 x[8];
memset(x, 0, sizeof x);
if (nl > sizeof x)
nl = sizeof x;
memcpy(x, s, nl);
rv = (addr->pr_s6_addr32[0] ^ addr->pr_s6_addr32[1] ^
addr->pr_s6_addr32[2] ^ addr->pr_s6_addr32[3] ^
x[0] ^ x[1] ^ x[2] ^ x[3] ^ x[4] ^ x[5] ^ x[6] ^ x[7])
% cache->numSIDCacheSets;
return rv;
}
/*
** Look something up in the cache. This will invalidate old entries
** in the process. Caller has locked the cache set!
** Returns PR_TRUE if found a valid match. PR_FALSE otherwise.
*/
static sidCacheEntry *
FindSID(cacheDesc *cache, PRUint32 setNum, PRUint32 now,
const PRIPv6Addr *addr, unsigned char *sessionID,
unsigned sessionIDLength)
{
PRUint32 ndx = cache->sidCacheSets[setNum].next;
int i;
sidCacheEntry * set = cache->sidCacheData +
(setNum * SID_CACHE_ENTRIES_PER_SET);
for (i = SID_CACHE_ENTRIES_PER_SET; i > 0; --i) {
sidCacheEntry * sce;
ndx = (ndx - 1) % SID_CACHE_ENTRIES_PER_SET;
sce = set + ndx;
if (!sce->valid)
continue;
if (now > sce->expirationTime) {
/* SessionID has timed out. Invalidate the entry. */
SSL_TRC(7, ("%d: timed out sid entry addr=%08x%08x%08x%08x now=%x "
"time+=%x",
myPid, sce->addr.pr_s6_addr32[0],
sce->addr.pr_s6_addr32[1], sce->addr.pr_s6_addr32[2],
sce->addr.pr_s6_addr32[3], now,
sce->expirationTime ));
sce->valid = 0;
continue;
}
/*
** Next, examine specific session-id/addr data to see if the cache
** entry matches our addr+session-id value
*/
if (sessionIDLength == sce->sessionIDLength &&
!memcmp(&sce->addr, addr, sizeof(PRIPv6Addr)) &&
!memcmp(sce->sessionID, sessionID, sessionIDLength)) {
/* Found it */
return sce;
}
}
PORT_SetError(SSL_ERROR_SESSION_NOT_FOUND);
return NULL;
}
/************************************************************************/
/* This is the primary function for finding entries in the server's sid cache.
* Although it is static, this function is called via the global function
* pointer ssl_sid_lookup.
*/
static sslSessionID *
ServerSessionIDLookup(const PRIPv6Addr *addr,
unsigned char *sessionID,
unsigned int sessionIDLength,
CERTCertDBHandle * dbHandle)
{
sslSessionID * sid = 0;
sidCacheEntry * psce;
certCacheEntry *pcce = 0;
cacheDesc * cache = &globalCache;
PRUint32 now;
PRUint32 set;
PRInt32 cndx;
sidCacheEntry sce;
certCacheEntry cce;
set = SIDindex(cache, addr, sessionID, sessionIDLength);
now = LockSet(cache, set, 0);
if (!now)
return NULL;
psce = FindSID(cache, set, now, addr, sessionID, sessionIDLength);
if (psce) {
if (psce->version >= SSL_LIBRARY_VERSION_3_0 &&
(cndx = psce->u.ssl3.certIndex) != -1) {
PRUint32 gotLock = LockSidCacheLock(cache->certCacheLock, now);
if (gotLock) {
pcce = &cache->certCacheData[cndx];
/* See if the cert's session ID matches the sce cache. */
if ((pcce->sessionIDLength == psce->sessionIDLength) &&
!PORT_Memcmp(pcce->sessionID, psce->sessionID,
pcce->sessionIDLength)) {
cce = *pcce;
} else {
/* The cert doesen't match the SID cache entry,
** so invalidate the SID cache entry.
*/
psce->valid = 0;
psce = 0;
pcce = 0;
}
UnlockSidCacheLock(cache->certCacheLock);
} else {
/* what the ??. Didn't get the cert cache lock.
** Don't invalidate the SID cache entry, but don't find it.
*/
PORT_Assert(!("Didn't get cert Cache Lock!"));
psce = 0;
pcce = 0;
}
}
if (psce) {
psce->lastAccessTime = now;
sce = *psce; /* grab a copy while holding the lock */
}
}
UnlockSet(cache, set);
if (psce) {
/* sce conains a copy of the cache entry.
** Convert shared memory format to local format
*/
sid = ConvertToSID(&sce, pcce ? &cce : 0, dbHandle);
}
return sid;
}
/*
** Place a sid into the cache, if it isn't already there.
*/
static void
ServerSessionIDCache(sslSessionID *sid)
{
sidCacheEntry sce;
PRUint32 now = 0;
uint16 version = sid->version;
cacheDesc * cache = &globalCache;
if ((version >= SSL_LIBRARY_VERSION_3_0) &&
(sid->u.ssl3.sessionIDLength == 0)) {
return;
}
if (sid->cached == never_cached || sid->cached == invalid_cache) {
PRUint32 set;
PORT_Assert(sid->creationTime != 0 && sid->expirationTime != 0);
if (!sid->creationTime)
sid->lastAccessTime = sid->creationTime = ssl_Time();
if (version < SSL_LIBRARY_VERSION_3_0) {
if (!sid->expirationTime)
sid->expirationTime = sid->creationTime + ssl_sid_timeout;
SSL_TRC(8, ("%d: SSL: CacheMT: cached=%d addr=0x%08x%08x%08x%08x time=%x "
"cipher=%d", myPid, sid->cached,
sid->addr.pr_s6_addr32[0], sid->addr.pr_s6_addr32[1],
sid->addr.pr_s6_addr32[2], sid->addr.pr_s6_addr32[3],
sid->creationTime, sid->u.ssl2.cipherType));
PRINT_BUF(8, (0, "sessionID:", sid->u.ssl2.sessionID,
SSL2_SESSIONID_BYTES));
PRINT_BUF(8, (0, "masterKey:", sid->u.ssl2.masterKey.data,
sid->u.ssl2.masterKey.len));
PRINT_BUF(8, (0, "cipherArg:", sid->u.ssl2.cipherArg.data,
sid->u.ssl2.cipherArg.len));
} else {
if (!sid->expirationTime)
sid->expirationTime = sid->creationTime + ssl3_sid_timeout;
SSL_TRC(8, ("%d: SSL: CacheMT: cached=%d addr=0x%08x%08x%08x%08x time=%x "
"cipherSuite=%d", myPid, sid->cached,
sid->addr.pr_s6_addr32[0], sid->addr.pr_s6_addr32[1],
sid->addr.pr_s6_addr32[2], sid->addr.pr_s6_addr32[3],
sid->creationTime, sid->u.ssl3.cipherSuite));
PRINT_BUF(8, (0, "sessionID:", sid->u.ssl3.sessionID,
sid->u.ssl3.sessionIDLength));
}
ConvertFromSID(&sce, sid);
if ((version >= SSL_LIBRARY_VERSION_3_0) &&
(sid->peerCert != NULL)) {
now = CacheCert(cache, sid->peerCert, &sce);
}
set = SIDindex(cache, &sce.addr, sce.sessionID, sce.sessionIDLength);
now = LockSet(cache, set, now);
if (now) {
PRUint32 next = cache->sidCacheSets[set].next;
PRUint32 ndx = set * SID_CACHE_ENTRIES_PER_SET + next;
/* Write out new cache entry */
cache->sidCacheData[ndx] = sce;
cache->sidCacheSets[set].next =
(next + 1) % SID_CACHE_ENTRIES_PER_SET;
UnlockSet(cache, set);
sid->cached = in_server_cache;
}
}
}
/*
** Although this is static, it is called from ssl via global function pointer
** ssl_sid_uncache. This invalidates the referenced cache entry.
*/
static void
ServerSessionIDUncache(sslSessionID *sid)
{
cacheDesc * cache = &globalCache;
PRUint8 * sessionID;
unsigned int sessionIDLength;
PRErrorCode err;
PRUint32 set;
PRUint32 now;
sidCacheEntry *psce;
if (sid == NULL)
return;
/* Uncaching a SID should never change the error code.
** So save it here and restore it before exiting.
*/
err = PR_GetError();
if (sid->version < SSL_LIBRARY_VERSION_3_0) {
sessionID = sid->u.ssl2.sessionID;
sessionIDLength = SSL2_SESSIONID_BYTES;
SSL_TRC(8, ("%d: SSL: UncacheMT: valid=%d addr=0x%08x%08x%08x%08x time=%x "
"cipher=%d", myPid, sid->cached,
sid->addr.pr_s6_addr32[0], sid->addr.pr_s6_addr32[1],
sid->addr.pr_s6_addr32[2], sid->addr.pr_s6_addr32[3],
sid->creationTime, sid->u.ssl2.cipherType));
PRINT_BUF(8, (0, "sessionID:", sessionID, sessionIDLength));
PRINT_BUF(8, (0, "masterKey:", sid->u.ssl2.masterKey.data,
sid->u.ssl2.masterKey.len));
PRINT_BUF(8, (0, "cipherArg:", sid->u.ssl2.cipherArg.data,
sid->u.ssl2.cipherArg.len));
} else {
sessionID = sid->u.ssl3.sessionID;
sessionIDLength = sid->u.ssl3.sessionIDLength;
SSL_TRC(8, ("%d: SSL3: UncacheMT: valid=%d addr=0x%08x%08x%08x%08x time=%x "
"cipherSuite=%d", myPid, sid->cached,
sid->addr.pr_s6_addr32[0], sid->addr.pr_s6_addr32[1],
sid->addr.pr_s6_addr32[2], sid->addr.pr_s6_addr32[3],
sid->creationTime, sid->u.ssl3.cipherSuite));
PRINT_BUF(8, (0, "sessionID:", sessionID, sessionIDLength));
}
set = SIDindex(cache, &sid->addr, sessionID, sessionIDLength);
now = LockSet(cache, set, 0);
if (now) {
psce = FindSID(cache, set, now, &sid->addr, sessionID, sessionIDLength);
if (psce) {
psce->valid = 0;
}
UnlockSet(cache, set);
}
sid->cached = invalid_cache;
PORT_SetError(err);
}
#ifdef XP_OS2
#define INCL_DOSPROCESS
#include <os2.h>
long gettid(void)
{
PTIB ptib;
PPIB ppib;
DosGetInfoBlocks(&ptib, &ppib);
return ((long)ptib->tib_ordinal); /* thread id */
}
#endif
static SECStatus
InitCache(cacheDesc *cache, int maxCacheEntries, PRUint32 ssl2_timeout,
PRUint32 ssl3_timeout, const char *directory)
{
ptrdiff_t ptr;
sidCacheLock *pLock;
char * sharedMem;
PRFileMap * cacheMemMap;
char * cfn = NULL; /* cache file name */
int locks_initialized = 0;
int locks_to_initialize = 0;
PRUint32 init_time;
if (cache->sharedMem) {
/* Already done */
return SECSuccess;
}
cache->numSIDCacheEntries = maxCacheEntries ? maxCacheEntries
: DEF_SID_CACHE_ENTRIES;
cache->numSIDCacheSets =
SID_HOWMANY(cache->numSIDCacheEntries, SID_CACHE_ENTRIES_PER_SET);
cache->numSIDCacheEntries =
cache->numSIDCacheSets * SID_CACHE_ENTRIES_PER_SET;
cache->numSIDCacheLocks =
PR_MIN(cache->numSIDCacheSets, ssl_max_sid_cache_locks);
cache->numSIDCacheSetsPerLock =
SID_HOWMANY(cache->numSIDCacheSets, cache->numSIDCacheLocks);
/* compute size of shared memory, and offsets of all pointers */
ptr = 0;
cache->sharedMem = (char *)ptr;
ptr += SID_ROUNDUP(sizeof(cacheDesc), SID_ALIGNMENT);
cache->sidCacheLocks = (sidCacheLock *)ptr;
cache->keyCacheLock = cache->sidCacheLocks + cache->numSIDCacheLocks;
cache->certCacheLock = cache->keyCacheLock + 1;
ptr = (ptrdiff_t)(cache->certCacheLock + 1);
ptr = SID_ROUNDUP(ptr, SID_ALIGNMENT);
cache->sidCacheSets = (sidCacheSet *)ptr;
ptr = (ptrdiff_t)(cache->sidCacheSets + cache->numSIDCacheSets);
ptr = SID_ROUNDUP(ptr, SID_ALIGNMENT);
cache->sidCacheData = (sidCacheEntry *)ptr;
ptr = (ptrdiff_t)(cache->sidCacheData + cache->numSIDCacheEntries);
ptr = SID_ROUNDUP(ptr, SID_ALIGNMENT);
cache->certCacheData = (certCacheEntry *)ptr;
cache->sidCacheSize =
(char *)cache->certCacheData - (char *)cache->sidCacheData;
/* This is really a poor way to computer this! */
cache->numCertCacheEntries = cache->sidCacheSize / sizeof(certCacheEntry);
if (cache->numCertCacheEntries < MIN_CERT_CACHE_ENTRIES)
cache->numCertCacheEntries = MIN_CERT_CACHE_ENTRIES;
ptr = (ptrdiff_t)(cache->certCacheData + cache->numCertCacheEntries);
ptr = SID_ROUNDUP(ptr, SID_ALIGNMENT);
cache->keyCacheData = (SSLWrappedSymWrappingKey *)ptr;
cache->certCacheSize =
(char *)cache->keyCacheData - (char *)cache->certCacheData;
cache->numKeyCacheEntries = kt_kea_size * SSL_NUM_WRAP_MECHS;
ptr = (ptrdiff_t)(cache->keyCacheData + cache->numKeyCacheEntries);
ptr = SID_ROUNDUP(ptr, SID_ALIGNMENT);
cache->sharedMemSize = ptr;
cache->keyCacheSize = (char *)ptr - (char *)cache->keyCacheData;
if (ssl2_timeout) {
if (ssl2_timeout > MAX_SSL2_TIMEOUT) {
ssl2_timeout = MAX_SSL2_TIMEOUT;
}
if (ssl2_timeout < MIN_SSL2_TIMEOUT) {
ssl2_timeout = MIN_SSL2_TIMEOUT;
}
cache->ssl2Timeout = ssl2_timeout;
} else {
cache->ssl2Timeout = DEF_SSL2_TIMEOUT;
}
if (ssl3_timeout) {
if (ssl3_timeout > MAX_SSL3_TIMEOUT) {
ssl3_timeout = MAX_SSL3_TIMEOUT;
}
if (ssl3_timeout < MIN_SSL3_TIMEOUT) {
ssl3_timeout = MIN_SSL3_TIMEOUT;
}
cache->ssl3Timeout = ssl3_timeout;
} else {
cache->ssl3Timeout = DEF_SSL3_TIMEOUT;
}
/* Create file names */
#ifdef XP_UNIX
/* there's some confusion here about whether PR_OpenAnonFileMap wants
** a directory name or a file name for its first argument.
cfn = PR_smprintf("%s/.sslsvrcache.%d", directory, myPid);
*/
cfn = PR_smprintf("%s", directory);
#endif
#ifdef XP_WIN32
cfn = PR_smprintf("%s/svrcache_%d_%x.ssl", directory, myPid,
GetCurrentThreadId());
#endif
#ifdef XP_OS2
cfn = PR_smprintf("%s/svrcache_%d_%x.ssl", directory, myPid,
gettid());
#endif
if (!cfn) {
goto loser;
}
/* Create cache */
cacheMemMap = PR_OpenAnonFileMap(cfn, cache->sharedMemSize,
PR_PROT_READWRITE);
PR_smprintf_free(cfn);
if(! cacheMemMap) {
goto loser;
}
sharedMem = PR_MemMap(cacheMemMap, 0, cache->sharedMemSize);
if (! sharedMem) {
goto loser;
}
/* Initialize shared memory. This may not be necessary on all platforms */
memset(sharedMem, 0, cache->sharedMemSize);
/* Copy cache descriptor header into shared memory */
memcpy(sharedMem, cache, sizeof *cache);
/* save private copies of these values */
cache->cacheMemMap = cacheMemMap;
cache->sharedMem = sharedMem;
cache->sharedCache = (cacheDesc *)sharedMem;
/* Fix pointers in our private copy of cache descriptor to point to
** spaces in shared memory
*/
ptr = (ptrdiff_t)cache->sharedMem;
*(ptrdiff_t *)(&cache->sidCacheLocks) += ptr;
*(ptrdiff_t *)(&cache->keyCacheLock ) += ptr;
*(ptrdiff_t *)(&cache->certCacheLock) += ptr;
*(ptrdiff_t *)(&cache->sidCacheSets ) += ptr;
*(ptrdiff_t *)(&cache->sidCacheData ) += ptr;
*(ptrdiff_t *)(&cache->certCacheData) += ptr;
*(ptrdiff_t *)(&cache->keyCacheData ) += ptr;
/* initialize the locks */
init_time = ssl_Time();
pLock = cache->sidCacheLocks;
for (locks_to_initialize = cache->numSIDCacheLocks + 2;
locks_initialized < locks_to_initialize;
++locks_initialized, ++pLock ) {
SECStatus err = sslMutex_Init(&pLock->mutex, isMultiProcess);
if (err)
goto loser;
pLock->timeStamp = init_time;
pLock->pid = 0;
}
return SECSuccess;
loser:
if (cache->cacheMemMap) {
if (cache->sharedMem) {
if (locks_initialized > 0) {
pLock = cache->sidCacheLocks;
for (; locks_initialized > 0; --locks_initialized, ++pLock ) {
sslMutex_Destroy(&pLock->mutex);
}
}
PR_MemUnmap(cache->sharedMem, cache->sharedMemSize);
cache->sharedMem = NULL;
}
PR_CloseFileMap(cache->cacheMemMap);
cache->cacheMemMap = NULL;
}
return SECFailure;
}
PRUint32
SSL_GetMaxServerCacheLocks(void)
{
return ssl_max_sid_cache_locks + 2;
/* The extra two are the cert cache lock and the key cache lock. */
}
SECStatus
SSL_SetMaxServerCacheLocks(PRUint32 maxLocks)
{
/* Minimum is 1 sid cache lock, 1 cert cache lock and 1 key cache lock.
** We'd like to test for a maximum value, but not all platforms' header
** files provide a symbol or function or other means of determining
** the maximum, other than trial and error.
*/
if (maxLocks < 3) {
PORT_SetError(SEC_ERROR_INVALID_ARGS);
return SECFailure;
}
ssl_max_sid_cache_locks = maxLocks - 2;
/* The extra two are the cert cache lock and the key cache lock. */
return SECSuccess;
}
SECStatus
SSL_ConfigServerSessionIDCacheInstance( cacheDesc *cache,
int maxCacheEntries,
PRUint32 ssl2_timeout,
PRUint32 ssl3_timeout,
const char * directory)
{
SECStatus rv;
#if defined(DEBUG_nelsonb)
printf("sizeof(sidCacheEntry) == %u\n", sizeof(sidCacheEntry));
#endif
#if !(defined(SOLARIS) && defined(i386))
#ifndef XP_OS2
PORT_Assert(sizeof(sidCacheEntry) % 8 == 0);
#endif
#endif
PORT_Assert(sizeof(certCacheEntry) == 4096);
myPid = SSL_GETPID();
if (!directory) {
directory = DEFAULT_CACHE_DIRECTORY;
}
rv = InitCache(cache, maxCacheEntries, ssl2_timeout, ssl3_timeout,
directory);
if (rv) {
SET_ERROR_CODE
return SECFailure;
}
ssl_sid_lookup = ServerSessionIDLookup;
ssl_sid_cache = ServerSessionIDCache;
ssl_sid_uncache = ServerSessionIDUncache;
return SECSuccess;
}
SECStatus
SSL_ConfigServerSessionIDCache( int maxCacheEntries,
PRUint32 ssl2_timeout,
PRUint32 ssl3_timeout,
const char * directory)
{
return SSL_ConfigServerSessionIDCacheInstance(&globalCache,
maxCacheEntries, ssl2_timeout, ssl3_timeout, directory);
}
/* Use this function, instead of SSL_ConfigServerSessionIDCache,
* if the cache will be shared by multiple processes.
*/
SECStatus
SSL_ConfigMPServerSIDCache( int maxCacheEntries,
PRUint32 ssl2_timeout,
PRUint32 ssl3_timeout,
const char * directory)
{
char * envValue;
char * inhValue;
cacheDesc * cache = &globalCache;
PRUint32 fmStrLen;
SECStatus result;
PRStatus prStatus;
SECStatus putEnvFailed;
inheritance inherit;
char fmString[PR_FILEMAP_STRING_BUFSIZE];
isMultiProcess = PR_TRUE;
result = SSL_ConfigServerSessionIDCacheInstance(cache, maxCacheEntries,
ssl2_timeout, ssl3_timeout, directory);
if (result != SECSuccess)
return result;
prStatus = PR_ExportFileMapAsString(cache->cacheMemMap,
sizeof fmString, fmString);
if ((prStatus != PR_SUCCESS) || !(fmStrLen = strlen(fmString))) {
SET_ERROR_CODE
return SECFailure;
}
inherit.sharedMemSize = cache->sharedMemSize;
inherit.fmStrLen = fmStrLen;
inhValue = BTOA_DataToAscii((unsigned char *)&inherit, sizeof inherit);
if (!inhValue || !strlen(inhValue)) {
SET_ERROR_CODE
return SECFailure;
}
envValue = PR_smprintf("%s,%s", inhValue, fmString);
if (!envValue || !strlen(envValue)) {
SET_ERROR_CODE
return SECFailure;
}
PORT_Free(inhValue);
putEnvFailed = (SECStatus)NSS_PutEnv(envVarName, envValue);
PR_smprintf_free(envValue);
if (putEnvFailed) {
SET_ERROR_CODE
result = SECFailure;
}
#if defined(XP_UNIX)
/* Launch thread to poll cache for expired locks on Unix */
LaunchLockPoller(cache);
#endif
return result;
}
SECStatus
SSL_InheritMPServerSIDCacheInstance(cacheDesc *cache, const char * envString)
{
unsigned char * decoString = NULL;
char * fmString = NULL;
unsigned int decoLen;
ptrdiff_t ptr;
inheritance inherit;
cacheDesc my;
#ifdef WINNT
sidCacheLock* newLocks;
int locks_initialized = 0;
int locks_to_initialize = 0;
#endif
myPid = SSL_GETPID();
/* If this child was created by fork(), and not by exec() on unix,
** then isMultiProcess will already be set.
** If not, we'll set it below.
*/
if (isMultiProcess)
return SECSuccess; /* already done. */
ssl_sid_lookup = ServerSessionIDLookup;
ssl_sid_cache = ServerSessionIDCache;
ssl_sid_uncache = ServerSessionIDUncache;
if (!envString) {
envString = getenv(envVarName);
if (!envString) {
SET_ERROR_CODE
return SECFailure;
}
}
envString = PORT_Strdup(envString);
if (!envString)
return SECFailure;
fmString = strchr(envString, ',');
if (!fmString)
goto loser;
*fmString++ = 0;
decoString = ATOB_AsciiToData(envString, &decoLen);
if (!decoString) {
SET_ERROR_CODE
goto loser;
}
if (decoLen != sizeof inherit) {
SET_ERROR_CODE
goto loser;
}
PORT_Memcpy(&inherit, decoString, sizeof inherit);
if (strlen(fmString) != inherit.fmStrLen ) {
goto loser;
}
memset(&my, 0, sizeof my);
my.sharedMemSize = inherit.sharedMemSize;
/* Create cache */
my.cacheMemMap = PR_ImportFileMapFromString(fmString);
if(! my.cacheMemMap) {
goto loser;
}
my.sharedMem = PR_MemMap(my.cacheMemMap, 0, my.sharedMemSize);
if (! my.sharedMem) {
goto loser;
}
my.sharedCache = (cacheDesc *)my.sharedMem;
if (my.sharedCache->sharedMemSize != my.sharedMemSize) {
SET_ERROR_CODE
goto loser;
}
memcpy(cache, my.sharedCache, sizeof *cache);
cache->cacheMemMap = my.cacheMemMap;
cache->sharedMem = my.sharedMem;
cache->sharedCache = my.sharedCache;
/* Fix pointers in our private copy of cache descriptor to point to
** spaces in shared memory
*/
ptr = (ptrdiff_t)cache->sharedMem;
*(ptrdiff_t *)(&cache->sidCacheLocks) += ptr;
*(ptrdiff_t *)(&cache->keyCacheLock ) += ptr;
*(ptrdiff_t *)(&cache->certCacheLock) += ptr;
*(ptrdiff_t *)(&cache->sidCacheSets ) += ptr;
*(ptrdiff_t *)(&cache->sidCacheData ) += ptr;
*(ptrdiff_t *)(&cache->certCacheData) += ptr;
*(ptrdiff_t *)(&cache->keyCacheData ) += ptr;
#ifdef WINNT
/* On Windows NT we need to "fix" the sidCacheLocks here to support fibers
When NT fibers are used in a multi-process server, a second level of
locking is needed to prevent a deadlock, in case a fiber acquires the
cross-process mutex, yields, and another fiber is later scheduled on
the same native thread and tries to acquire the cross-process mutex.
We do this by using a PRLock in the sslMutex. However, it is stored in
shared memory as part of sidCacheLocks, and we don't want to overwrite
the PRLock of the parent process. So we need to make new, private
copies of sidCacheLocks before modifying the sslMutex with our own
PRLock
*/
newLocks = (sidCacheLock*)PORT_Alloc(sizeof(sidCacheLock)*(cache->numSIDCacheLocks + 2));
/* note from jpierre : this should be free'd in child processes when
a function is added to delete the SSL session cache in the future */
/* fix the locks */
for (locks_to_initialize = cache->numSIDCacheLocks + 2;
locks_initialized < locks_to_initialize;
++locks_initialized) {
/* copy the old lock */
memcpy(&newLocks[locks_initialized], &cache->sidCacheLocks[locks_initialized], sizeof(sidCacheLock));
/* now, make a local PRLock in this sslMutex for this child process */
sslMutex_2LevelInit(&newLocks[locks_initialized].mutex);
}
/* then, make our cache object point to our new private sidCacheLocks */
/* first the session cache */
cache->sidCacheLocks = newLocks;
/* also fix the key and cert cache which use the last 2 lock entries */
cache->keyCacheLock = cache->sidCacheLocks + cache->numSIDCacheLocks;
cache->certCacheLock = cache->keyCacheLock + 1;
#endif
PORT_Free(decoString);
isMultiProcess = PR_TRUE;
return SECSuccess;
loser:
if (decoString)
PORT_Free(decoString);
return SECFailure;
}
SECStatus
SSL_InheritMPServerSIDCache(const char * envString)
{
return SSL_InheritMPServerSIDCacheInstance(&globalCache, envString);
}
#if defined(XP_UNIX)
#define SID_LOCK_EXPIRATION_TIMEOUT 30 /* seconds */
static void
LockPoller(void * arg)
{
cacheDesc * cache = (cacheDesc *)arg;
cacheDesc * sharedCache = cache->sharedCache;
sidCacheLock * pLock;
const char * timeoutString;
PRIntervalTime timeout;
PRUint32 now;
PRUint32 then;
int locks_polled = 0;
int locks_to_poll = cache->numSIDCacheLocks + 2;
PRUint32 expiration = SID_LOCK_EXPIRATION_TIMEOUT;
timeoutString = getenv("NSS_SSL_SERVER_CACHE_MUTEX_TIMEOUT");
if (timeoutString) {
long newTime = strtol(timeoutString, 0, 0);
if (newTime == 0)
return; /* application doesn't want this function */
if (newTime > 0)
expiration = (PRUint32)newTime;
/* if error (newTime < 0) ignore it and use default */
}
timeout = PR_SecondsToInterval(expiration);
while(!sharedCache->stopPolling) {
PR_Sleep(timeout);
if (sharedCache->stopPolling)
break;
now = ssl_Time();
then = now - expiration;
for (pLock = cache->sidCacheLocks, locks_polled = 0;
locks_to_poll > locks_polled && !sharedCache->stopPolling;
++locks_polled, ++pLock ) {
pid_t pid;
if (pLock->timeStamp < then &&
pLock->timeStamp != 0 &&
(pid = pLock->pid) != 0) {
/* maybe we should try the lock? */
int result = kill(pid, 0);
if (result < 0 && errno == ESRCH) {
SECStatus rv;
/* No process exists by that pid any more.
** Treat this mutex as abandoned.
*/
pLock->timeStamp = now;
pLock->pid = 0;
rv = sslMutex_Unlock(&pLock->mutex);
if (rv != SECSuccess) {
/* Now what? */
}
}
}
} /* end of loop over locks */
} /* end of entire polling loop */
}
/* Launch thread to poll cache for expired locks */
static SECStatus
LaunchLockPoller(cacheDesc *cache)
{
PRThread * pollerThread;
pollerThread =
PR_CreateThread(PR_USER_THREAD, LockPoller, cache, PR_PRIORITY_NORMAL,
PR_GLOBAL_THREAD, PR_UNJOINABLE_THREAD, 0);
if (!pollerThread) {
return SECFailure;
}
cache->poller = pollerThread;
return SECSuccess;
}
#endif
/************************************************************************
* Code dealing with shared wrapped symmetric wrapping keys below *
************************************************************************/
/* If now is zero, it implies that the lock is not held, and must be
** aquired here.
*/
static PRBool
getSvrWrappingKey(PRInt32 symWrapMechIndex,
SSL3KEAType exchKeyType,
SSLWrappedSymWrappingKey *wswk,
cacheDesc * cache,
PRUint32 lockTime)
{
PRUint32 ndx = (exchKeyType * SSL_NUM_WRAP_MECHS) + symWrapMechIndex;
SSLWrappedSymWrappingKey * pwswk = cache->keyCacheData + ndx;
PRUint32 now = 0;
PRBool rv = PR_FALSE;
if (!lockTime) {
lockTime = now = LockSidCacheLock(cache->keyCacheLock, now);
if (!lockTime) {
return rv;
}
}
if (pwswk->exchKeyType == exchKeyType &&
pwswk->symWrapMechIndex == symWrapMechIndex &&
pwswk->wrappedSymKeyLen != 0) {
*wswk = *pwswk;
rv = PR_TRUE;
}
if (now) {
UnlockSidCacheLock(cache->keyCacheLock);
}
return rv;
}
PRBool
ssl_GetWrappingKey( PRInt32 symWrapMechIndex,
SSL3KEAType exchKeyType,
SSLWrappedSymWrappingKey *wswk)
{
PRBool rv;
PORT_Assert( (unsigned)exchKeyType < kt_kea_size);
PORT_Assert( (unsigned)symWrapMechIndex < SSL_NUM_WRAP_MECHS);
if ((unsigned)exchKeyType < kt_kea_size &&
(unsigned)symWrapMechIndex < SSL_NUM_WRAP_MECHS) {
rv = getSvrWrappingKey(symWrapMechIndex, exchKeyType, wswk,
&globalCache, 0);
} else {
rv = PR_FALSE;
}
return rv;
}
/* The caller passes in the new value it wants
* to set. This code tests the wrapped sym key entry in the shared memory.
* If it is uninitialized, this function writes the caller's value into
* the disk entry, and returns false.
* Otherwise, it overwrites the caller's wswk with the value obtained from
* the disk, and returns PR_TRUE.
* This is all done while holding the locks/mutexes necessary to make
* the operation atomic.
*/
PRBool
ssl_SetWrappingKey(SSLWrappedSymWrappingKey *wswk)
{
cacheDesc * cache = &globalCache;
PRBool rv = PR_FALSE;
SSL3KEAType exchKeyType = wswk->exchKeyType;
/* type of keys used to wrap SymWrapKey*/
PRInt32 symWrapMechIndex = wswk->symWrapMechIndex;
PRUint32 ndx;
PRUint32 now = 0;
SSLWrappedSymWrappingKey myWswk;
PORT_Assert( (unsigned)exchKeyType < kt_kea_size);
if ((unsigned)exchKeyType >= kt_kea_size)
return 0;
PORT_Assert( (unsigned)symWrapMechIndex < SSL_NUM_WRAP_MECHS);
if ((unsigned)symWrapMechIndex >= SSL_NUM_WRAP_MECHS)
return 0;
ndx = (exchKeyType * SSL_NUM_WRAP_MECHS) + symWrapMechIndex;
PORT_Memset(&myWswk, 0, sizeof myWswk); /* eliminate UMRs. */
now = LockSidCacheLock(cache->keyCacheLock, now);
if (now) {
rv = getSvrWrappingKey(wswk->symWrapMechIndex, wswk->exchKeyType,
&myWswk, cache, now);
if (rv) {
/* we found it on disk, copy it out to the caller. */
PORT_Memcpy(wswk, &myWswk, sizeof *wswk);
} else {
/* Wasn't on disk, and we're still holding the lock, so write it. */
cache->keyCacheData[ndx] = *wswk;
}
UnlockSidCacheLock(cache->keyCacheLock);
}
return rv;
}
#else /* MAC version or other platform */
#include "seccomon.h"
#include "cert.h"
#include "ssl.h"
#include "sslimpl.h"
SECStatus
SSL_ConfigServerSessionIDCache( int maxCacheEntries,
PRUint32 ssl2_timeout,
PRUint32 ssl3_timeout,
const char * directory)
{
PR_ASSERT(!"SSL servers are not supported on this platform. (SSL_ConfigServerSessionIDCache)");
return SECFailure;
}
SECStatus
SSL_ConfigMPServerSIDCache( int maxCacheEntries,
PRUint32 ssl2_timeout,
PRUint32 ssl3_timeout,
const char * directory)
{
PR_ASSERT(!"SSL servers are not supported on this platform. (SSL_ConfigMPServerSIDCache)");
return SECFailure;
}
SECStatus
SSL_InheritMPServerSIDCache(const char * envString)
{
PR_ASSERT(!"SSL servers are not supported on this platform. (SSL_InheritMPServerSIDCache)");
return SECFailure;
}
PRBool
ssl_GetWrappingKey( PRInt32 symWrapMechIndex,
SSL3KEAType exchKeyType,
SSLWrappedSymWrappingKey *wswk)
{
PRBool rv = PR_FALSE;
PR_ASSERT(!"SSL servers are not supported on this platform. (ssl_GetWrappingKey)");
return rv;
}
/* This is a kind of test-and-set. The caller passes in the new value it wants
* to set. This code tests the wrapped sym key entry in the shared memory.
* If it is uninitialized, this function writes the caller's value into
* the disk entry, and returns false.
* Otherwise, it overwrites the caller's wswk with the value obtained from
* the disk, and returns PR_TRUE.
* This is all done while holding the locks/mutexes necessary to make
* the operation atomic.
*/
PRBool
ssl_SetWrappingKey(SSLWrappedSymWrappingKey *wswk)
{
PRBool rv = PR_FALSE;
PR_ASSERT(!"SSL servers are not supported on this platform. (ssl_SetWrappingKey)");
return rv;
}
PRUint32
SSL_GetMaxServerCacheLocks(void)
{
PR_ASSERT(!"SSL servers are not supported on this platform. (SSL_GetMaxServerCacheLocks)");
return -1;
}
SECStatus
SSL_SetMaxServerCacheLocks(PRUint32 maxLocks)
{
PR_ASSERT(!"SSL servers are not supported on this platform. (SSL_SetMaxServerCacheLocks)");
return SECFailure;
}
#endif /* XP_UNIX || XP_WIN32 */
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