gecko/security/nss/cmd/selfserv/selfserv.c

/* ***** BEGIN LICENSE BLOCK *****
 * Version: MPL 1.1/GPL 2.0/LGPL 2.1
 *
 * 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 the Initial Developer are Copyright (C) 1994-2000
 * the Initial Developer. All Rights Reserved.
 *
 * Contributor(s):
 *   Dr Vipul Gupta <vipul.gupta@sun.com>, Sun Microsystems Laboratories
 *
 * Alternatively, the contents of this file may be used under the terms of
 * either the GNU General Public License Version 2 or later (the "GPL"), or
 * the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
 * in which case the provisions of the GPL or the LGPL are applicable instead
 * of those above. If you wish to allow use of your version of this file only
 * under the terms of either the GPL or the LGPL, and not to allow others to
 * use your version of this file under the terms of the MPL, indicate your
 * decision by deleting the provisions above and replace them with the notice
 * and other provisions required by the GPL or the LGPL. If you do not delete
 * the provisions above, a recipient may use your version of this file under
 * the terms of any one of the MPL, the GPL or the LGPL.
 *
 * ***** END LICENSE BLOCK ***** */

/* -r flag is interepreted as follows:
 *	1 -r  means request, not require, on initial handshake.
 *	2 -r's mean request  and require, on initial handshake.
 *	3 -r's mean request, not require, on second handshake.
 *	4 -r's mean request  and require, on second handshake.
 */
#include <stdio.h>
#include <string.h>

#include "secutil.h"

#if defined(XP_UNIX)
#include <unistd.h>
#endif

#if defined(_WINDOWS)
#include <process.h>	/* for getpid() */
#endif

#include <signal.h>
#include <stdlib.h>
#include <errno.h>
#include <fcntl.h>
#include <stdarg.h>

#include "nspr.h"
#include "prio.h"
#include "prerror.h"
#include "prnetdb.h"
#include "prclist.h"
#include "plgetopt.h"
#include "pk11func.h"
#include "secitem.h"
#include "nss.h"
#include "ssl.h"
#include "sslproto.h"
#include "cert.h"
#include "certt.h"

#ifndef PORT_Sprintf
#define PORT_Sprintf sprintf
#endif

#ifndef PORT_Strstr
#define PORT_Strstr strstr
#endif

#ifndef PORT_Malloc
#define PORT_Malloc PR_Malloc
#endif

int NumSidCacheEntries = 1024;

static int handle_connection( PRFileDesc *, PRFileDesc *, int );

static const char envVarName[] = { SSL_ENV_VAR_NAME };
static const char inheritableSockName[] = { "SELFSERV_LISTEN_SOCKET" };

#define DEFAULT_BULK_TEST 16384
#define MAX_BULK_TEST     1048576 /* 1 MB */
static PRBool testBulk;
static PRUint32 testBulkSize       = DEFAULT_BULK_TEST;
static PRUint32 testBulkTotal;
static char* testBulkBuf;
static PRDescIdentity log_layer_id = PR_INVALID_IO_LAYER;
static PRFileDesc *loggingFD;
static PRIOMethods loggingMethods;

static PRBool logStats;
static PRBool loggingLayer;
static int logPeriod = 30;
static PRUint32 loggerOps;
static PRUint32 loggerBytes;
static PRUint32 loggerBytesTCP;
static PRUint32 bulkSentChunks;

const int ssl2CipherSuites[] = {
    SSL_EN_RC4_128_WITH_MD5,			/* A */
    SSL_EN_RC4_128_EXPORT40_WITH_MD5,		/* B */
    SSL_EN_RC2_128_CBC_WITH_MD5,		/* C */
    SSL_EN_RC2_128_CBC_EXPORT40_WITH_MD5,	/* D */
    SSL_EN_DES_64_CBC_WITH_MD5,			/* E */
    SSL_EN_DES_192_EDE3_CBC_WITH_MD5,		/* F */
    0
};

const int ssl3CipherSuites[] = {
    -1, /* SSL_FORTEZZA_DMS_WITH_FORTEZZA_CBC_SHA* a */
    -1, /* SSL_FORTEZZA_DMS_WITH_RC4_128_SHA	 * b */
    SSL_RSA_WITH_RC4_128_MD5,			/* c */
    SSL_RSA_WITH_3DES_EDE_CBC_SHA,		/* d */
    SSL_RSA_WITH_DES_CBC_SHA,			/* e */
    SSL_RSA_EXPORT_WITH_RC4_40_MD5,		/* f */
    SSL_RSA_EXPORT_WITH_RC2_CBC_40_MD5,		/* g */
    -1, /* SSL_FORTEZZA_DMS_WITH_NULL_SHA,	 * h */
    SSL_RSA_WITH_NULL_MD5,			/* i */
    SSL_RSA_FIPS_WITH_3DES_EDE_CBC_SHA,		/* j */
    SSL_RSA_FIPS_WITH_DES_CBC_SHA,		/* k */
    TLS_RSA_EXPORT1024_WITH_DES_CBC_SHA,	/* l */
    TLS_RSA_EXPORT1024_WITH_RC4_56_SHA,	        /* m */
    SSL_RSA_WITH_RC4_128_SHA,			/* n */
    -1, /* TLS_DHE_DSS_WITH_RC4_128_SHA, 	 * o */
    -1, /* SSL_DHE_RSA_WITH_3DES_EDE_CBC_SHA,	 * p */
    -1, /* SSL_DHE_DSS_WITH_3DES_EDE_CBC_SHA,	 * q */
    -1, /* SSL_DHE_RSA_WITH_DES_CBC_SHA,	 * r */
    -1, /* SSL_DHE_DSS_WITH_DES_CBC_SHA,	 * s */
    -1, /* TLS_DHE_DSS_WITH_AES_128_CBC_SHA,	 * t */
    -1, /* TLS_DHE_RSA_WITH_AES_128_CBC_SHA,	 * u */
    TLS_RSA_WITH_AES_128_CBC_SHA,     	    	/* v */
    -1, /* TLS_DHE_DSS_WITH_AES_256_CBC_SHA,	 * w */
    -1, /* TLS_DHE_RSA_WITH_AES_256_CBC_SHA,	 * x */
    TLS_RSA_WITH_AES_256_CBC_SHA,     	    	/* y */
    SSL_RSA_WITH_NULL_SHA,			/* z */
    0
};

/* data and structures for shutdown */
static int	stopping;

static PRBool  noDelay;
static int     requestCert;
static int	verbose;
static SECItem	bigBuf;

static PRThread * acceptorThread;

static PRLogModuleInfo *lm;

#define PRINTF  if (verbose)  printf
#define FPRINTF if (verbose) fprintf
#define FLUSH	if (verbose) { fflush(stdout); fflush(stderr); }
#define VLOG(arg) PR_LOG(lm,PR_LOG_DEBUG,arg)

static void
Usage(const char *progName)
{
    fprintf(stderr, 

"Usage: %s -n rsa_nickname -p port [-3BDENRSTbjlmrsuvx] [-w password]\n"
"         [-t threads] [-i pid_file] [-c ciphers] [-d dbdir] [-g numblocks]\n"
"         [-f password_file] [-L [seconds]] [-M maxProcs] [-P dbprefix]\n"
"         [-a sni_name]\n"
#ifdef NSS_ENABLE_ECC
"         [-C SSLCacheEntries] [-e ec_nickname]\n"
#else
"         [-C SSLCacheEntries]\n"
#endif /* NSS_ENABLE_ECC */
"-S means disable SSL v2\n"
"-3 means disable SSL v3\n"
"-T means disable TLS\n"
"-B bypasses the PKCS11 layer for SSL encryption and MACing\n"
"-q checks for bypassability\n"
"-D means disable Nagle delays in TCP\n"
"-E means disable export ciphersuites and SSL step down key gen\n"
"-R means disable detection of rollback from TLS to SSL3\n"
"-a configure server for SNI.\n"
"-k expected name negotiated on server sockets"
"-b means try binding to the port and exit\n"
"-m means test the model-socket feature of SSL_ImportFD.\n"
"-r flag is interepreted as follows:\n"
"    1 -r  means request, not require, cert on initial handshake.\n"
"    2 -r's mean request  and require, cert on initial handshake.\n"
"    3 -r's mean request, not require, cert on second handshake.\n"
"    4 -r's mean request  and require, cert on second handshake.\n"
"-s means disable SSL socket locking for performance\n"
"-u means enable Session Ticket extension for TLS.\n"
"-v means verbose output\n"
"-x means use export policy.\n"
"-z means enable compression.\n"
"-L seconds means log statistics every 'seconds' seconds (default=30).\n"
"-M maxProcs tells how many processes to run in a multi-process server\n"
"-N means do NOT use the server session cache.  Incompatible with -M.\n"
"-t threads -- specify the number of threads to use for connections.\n"
"-i pid_file file to write the process id of selfserve\n"
"-l means use local threads instead of global threads\n"
"-g numblocks means test throughput by sending total numblocks chunks\n"
"    of size 16kb to the client, 0 means unlimited (default=0)\n"
"-j means measure TCP throughput (for use with -g option)\n"
"-C SSLCacheEntries sets the maximum number of entries in the SSL\n" 
"    session cache\n"
"-c ciphers   Letter(s) chosen from the following list\n"
"A    SSL2 RC4 128 WITH MD5\n"
"B    SSL2 RC4 128 EXPORT40 WITH MD5\n"
"C    SSL2 RC2 128 CBC WITH MD5\n"
"D    SSL2 RC2 128 CBC EXPORT40 WITH MD5\n"
"E    SSL2 DES 64 CBC WITH MD5\n"
"F    SSL2 DES 192 EDE3 CBC WITH MD5\n"
"\n"
"c    SSL3 RSA WITH RC4 128 MD5\n"
"d    SSL3 RSA WITH 3DES EDE CBC SHA\n"
"e    SSL3 RSA WITH DES CBC SHA\n"
"f    SSL3 RSA EXPORT WITH RC4 40 MD5\n"
"g    SSL3 RSA EXPORT WITH RC2 CBC 40 MD5\n"
"i    SSL3 RSA WITH NULL MD5\n"
"j    SSL3 RSA FIPS WITH 3DES EDE CBC SHA\n"
"k    SSL3 RSA FIPS WITH DES CBC SHA\n"
"l    SSL3 RSA EXPORT WITH DES CBC SHA\t(new)\n"
"m    SSL3 RSA EXPORT WITH RC4 56 SHA\t(new)\n"
"n    SSL3 RSA WITH RC4 128 SHA\n"
"v    SSL3 RSA WITH AES 128 CBC SHA\n"
"y    SSL3 RSA WITH AES 256 CBC SHA\n"
"z    SSL3 RSA WITH NULL SHA\n"
"\n"
":WXYZ  Use cipher with hex code { 0xWX , 0xYZ } in TLS\n"
	,progName);
}

static const char *
errWarn(char * funcString)
{
    PRErrorCode  perr      = PR_GetError();
    const char * errString = SECU_Strerror(perr);

    fprintf(stderr, "selfserv: %s returned error %d:\n%s\n",
            funcString, perr, errString);
    return errString;
}

static void
errExit(char * funcString)
{
    errWarn(funcString);
    exit(3);
}


/**************************************************************************
** 
** Routines for disabling SSL ciphers.
**
**************************************************************************/

/* disable all the SSL cipher suites */
void
disableAllSSLCiphers(void)
{
    const PRUint16 *cipherSuites = SSL_ImplementedCiphers;
    int             i            = SSL_NumImplementedCiphers;
    SECStatus       rv;

    while (--i >= 0) {
	PRUint16 suite = cipherSuites[i];
        rv = SSL_CipherPrefSetDefault(suite, PR_FALSE);
	if (rv != SECSuccess) {
	    printf("SSL_CipherPrefSetDefault rejected suite 0x%04x (i = %d)\n",
	    	   suite, i);
	    errWarn("SSL_CipherPrefSetDefault");
	}
    }
}

/* disable all the export SSL cipher suites */
SECStatus
disableExportSSLCiphers(void)
{
    const PRUint16 *cipherSuites = SSL_ImplementedCiphers;
    int             i            = SSL_NumImplementedCiphers;
    SECStatus       rv           = SECSuccess;
    SSLCipherSuiteInfo info;

    while (--i >= 0) {
	PRUint16 suite = cipherSuites[i];
	SECStatus status;
	status = SSL_GetCipherSuiteInfo(suite, &info, sizeof info);
	if (status != SECSuccess) {
	    printf("SSL_GetCipherSuiteInfo rejected suite 0x%04x (i = %d)\n",
		   suite, i);
	    errWarn("SSL_GetCipherSuiteInfo");
	    rv = SECFailure;
	    continue;
	}
	if (info.cipherSuite != suite) {
	    printf(
"SSL_GetCipherSuiteInfo returned wrong suite! Wanted 0x%04x, Got 0x%04x\n",
		   suite, i);
	    PORT_SetError(SEC_ERROR_LIBRARY_FAILURE);
	    rv = SECFailure;
	    continue;
	}
	/* should check here that info.length >= offsetof isExportable */
	if (info.isExportable) {
	    status = SSL_CipherPolicySet(suite, SSL_NOT_ALLOWED);
	    if (status != SECSuccess) {
		printf("SSL_CipherPolicySet rejected suite 0x%04x (i = %d)\n",
		       suite, i);
		errWarn("SSL_CipherPolicySet");
		rv = SECFailure;
	    }
	}
    }
    return rv;
}

static SECStatus
mySSLAuthCertificate(void *arg, PRFileDesc *fd, PRBool checkSig,
		     PRBool isServer)
{
    SECStatus rv;
    CERTCertificate *    peerCert;

    peerCert = SSL_PeerCertificate(fd);

    PRINTF("selfserv: Subject: %s\nselfserv: Issuer : %s\n",
           peerCert->subjectName, peerCert->issuerName);

    rv = SSL_AuthCertificate(arg, fd, checkSig, isServer);

    if (rv == SECSuccess) {
	PRINTF("selfserv: -- SSL3: Certificate Validated.\n");
    } else {
    	int err = PR_GetError();
	FPRINTF(stderr, "selfserv: -- SSL3: Certificate Invalid, err %d.\n%s\n", 
                err, SECU_Strerror(err));
    }
    CERT_DestroyCertificate(peerCert);
    FLUSH;
    return rv;  
}

void
printSSLStatistics()
{
    SSL3Statistics *  ssl3stats = SSL_GetStatistics();

    printf(
	"selfserv: %ld cache hits; %ld cache misses, %ld cache not reusable\n"
	"          %ld stateless resumes, %ld ticket parse failures\n",
	ssl3stats->hch_sid_cache_hits, ssl3stats->hch_sid_cache_misses,
	ssl3stats->hch_sid_cache_not_ok, ssl3stats->hch_sid_stateless_resumes,
	ssl3stats->hch_sid_ticket_parse_failures);
}

void 
printSecurityInfo(PRFileDesc *fd)
{
    CERTCertificate * cert      = NULL;
    SECStatus         result;
    SSLChannelInfo    channel;
    SSLCipherSuiteInfo suite;

    if (verbose)
	printSSLStatistics();

    result = SSL_GetChannelInfo(fd, &channel, sizeof channel);
    if (result == SECSuccess && 
        channel.length == sizeof channel && 
	channel.cipherSuite) {
	result = SSL_GetCipherSuiteInfo(channel.cipherSuite, 
					&suite, sizeof suite);
	if (result == SECSuccess) {
	    FPRINTF(stderr, 
	    "selfserv: SSL version %d.%d using %d-bit %s with %d-bit %s MAC\n",
	       channel.protocolVersion >> 8, channel.protocolVersion & 0xff,
	       suite.effectiveKeyBits, suite.symCipherName, 
	       suite.macBits, suite.macAlgorithmName);
	    FPRINTF(stderr, 
	    "selfserv: Server Auth: %d-bit %s, Key Exchange: %d-bit %s\n"
	    "          Compression: %s\n",
	       channel.authKeyBits, suite.authAlgorithmName,
	       channel.keaKeyBits,  suite.keaTypeName,
	       channel.compressionMethodName);
    	}
    }
    if (verbose) {
        SECItem *hostInfo  = SSL_GetNegotiatedHostInfo(fd);
        if (hostInfo) {
            char namePref[] = "selfserv: Negotiated server name: ";

            fprintf(stderr, "%s", namePref);
            fwrite(hostInfo->data, hostInfo->len, 1, stderr);
            SECITEM_FreeItem(hostInfo, PR_TRUE);
            hostInfo = NULL;
            fprintf(stderr, "\n");
        }
    }
    if (requestCert)
	cert = SSL_PeerCertificate(fd);
    else
	cert = SSL_LocalCertificate(fd);
    if (cert) {
	char * ip = CERT_NameToAscii(&cert->issuer);
	char * sp = CERT_NameToAscii(&cert->subject);
        if (sp) {
	    FPRINTF(stderr, "selfserv: subject DN: %s\n", sp);
	    PORT_Free(sp);
	}
        if (ip) {
	    FPRINTF(stderr, "selfserv: issuer  DN: %s\n", ip);
	    PORT_Free(ip);
	}
	CERT_DestroyCertificate(cert);
	cert = NULL;
    }
    FLUSH;
}

static int MakeCertOK;

static SECStatus
myBadCertHandler( void *arg, PRFileDesc *fd)
{
    int err = PR_GetError();
    if (!MakeCertOK)
	fprintf(stderr, 
	    "selfserv: -- SSL: Client Certificate Invalid, err %d.\n%s\n", 
            err, SECU_Strerror(err));
    return (MakeCertOK ? SECSuccess : SECFailure);
}

#define MAX_VIRT_SERVER_NAME_ARRAY_INDEX  10

/* Simple SNI socket config function that does not use SSL_ReconfigFD.
 * Only uses one server name but verifies that the names match. */
PRInt32 
mySSLSNISocketConfig(PRFileDesc *fd, const SECItem *sniNameArr,
                     PRUint32 sniNameArrSize, void *arg)
{
    PRInt32        i = 0;
    const SECItem *current = sniNameArr;
    const char    **nameArr = (const char**)arg;
    const secuPWData *pwdata;
    CERTCertificate *    cert = NULL;
    SECKEYPrivateKey *   privKey = NULL;

    PORT_Assert(fd && sniNameArr);
    if (!fd || !sniNameArr) {
	return SSL_SNI_SEND_ALERT;
    }

    pwdata = SSL_RevealPinArg(fd);

    for (;current && i < sniNameArrSize;i++) {
        int j = 0;
        for (;j < MAX_VIRT_SERVER_NAME_ARRAY_INDEX && nameArr[j];j++) {
            if (!PORT_Strncmp(nameArr[j],
                              (const char *)current[i].data,
                              current[i].len) &&
                PORT_Strlen(nameArr[j]) == current[i].len) {
                const char *nickName = nameArr[j];
                if (j == 0) {
                    /* default cert */
                    return 0;
                }
                /* if pwdata is NULL, then we would not get the key and
                 * return an error status. */
                cert = PK11_FindCertFromNickname(nickName, &pwdata);
                if (cert == NULL) {
                    goto loser; /* Send alert */
                }
                privKey = PK11_FindKeyByAnyCert(cert, &pwdata);
                if (privKey == NULL) {
                    goto loser; /* Send alert */
                }
                if (SSL_ConfigSecureServer(fd, cert, privKey,
                                           kt_rsa) != SECSuccess) {
                    goto loser; /* Send alert */
                }
                SECKEY_DestroyPrivateKey(privKey);
                CERT_DestroyCertificate(cert);
                return i;
            }
        }
    }
loser:
    if (privKey) {
        SECKEY_DestroyPrivateKey(privKey);
    }
    if (cert) {
        CERT_DestroyCertificate(cert);
    }
    return SSL_SNI_SEND_ALERT;
}


/**************************************************************************
** Begin thread management routines and data.
**************************************************************************/
#define MIN_THREADS 3
#define DEFAULT_THREADS 8
#define MAX_THREADS 4096
#define MAX_PROCS 25
static int  maxThreads = DEFAULT_THREADS;


typedef struct jobStr {
    PRCList     link;
    PRFileDesc *tcp_sock;
    PRFileDesc *model_sock;
    int         requestCert;
} JOB;

static PZLock    * qLock; /* this lock protects all data immediately below */
static PRLock    * lastLoadedCrlLock; /* this lock protects lastLoadedCrl variable */
static PZCondVar * jobQNotEmptyCv;
static PZCondVar * freeListNotEmptyCv;
static PZCondVar * threadCountChangeCv;
static int  threadCount;
static PRCList  jobQ;
static PRCList  freeJobs;
static JOB *jobTable;

SECStatus
setupJobs(int maxJobs)
{
    int i;

    jobTable = (JOB *)PR_Calloc(maxJobs, sizeof(JOB));
    if (!jobTable)
    	return SECFailure;

    PR_INIT_CLIST(&jobQ);
    PR_INIT_CLIST(&freeJobs);

    for (i = 0; i < maxJobs; ++i) {
	JOB * pJob = jobTable + i;
	PR_APPEND_LINK(&pJob->link, &freeJobs);
    }
    return SECSuccess;
}

typedef int startFn(PRFileDesc *a, PRFileDesc *b, int c);

typedef enum { rs_idle = 0, rs_running = 1, rs_zombie = 2 } runState;

typedef struct perThreadStr {
    PRFileDesc *a;
    PRFileDesc *b;
    int         c;
    int         rv;
    startFn  *  startFunc;
    PRThread *  prThread;
    runState	state;
} perThread;

static perThread *threads;

void
thread_wrapper(void * arg)
{
    perThread * slot = (perThread *)arg;

    slot->rv = (* slot->startFunc)(slot->a, slot->b, slot->c);

    /* notify the thread exit handler. */
    PZ_Lock(qLock);
    slot->state = rs_zombie;
    --threadCount;
    PZ_NotifyAllCondVar(threadCountChangeCv);
    PZ_Unlock(qLock);
}

int 
jobLoop(PRFileDesc *a, PRFileDesc *b, int c)
{
    PRCList * myLink = 0;
    JOB     * myJob;

    PZ_Lock(qLock);
    do {
	myLink = 0;
	while (PR_CLIST_IS_EMPTY(&jobQ) && !stopping) {
            PZ_WaitCondVar(jobQNotEmptyCv, PR_INTERVAL_NO_TIMEOUT);
	}
	if (!PR_CLIST_IS_EMPTY(&jobQ)) {
	    myLink = PR_LIST_HEAD(&jobQ);
	    PR_REMOVE_AND_INIT_LINK(myLink);
	}
	PZ_Unlock(qLock);
	myJob = (JOB *)myLink;
	/* myJob will be null when stopping is true and jobQ is empty */
	if (!myJob) 
	    break;
	handle_connection( myJob->tcp_sock, myJob->model_sock, 
			   myJob->requestCert);
	PZ_Lock(qLock);
	PR_APPEND_LINK(myLink, &freeJobs);
	PZ_NotifyCondVar(freeListNotEmptyCv);
    } while (PR_TRUE);
    return 0;
}


SECStatus
launch_threads(
    startFn    *startFunc,
    PRFileDesc *a,
    PRFileDesc *b,
    int         c,
    PRBool      local)
{
    int i;
    SECStatus rv = SECSuccess;

    /* create the thread management serialization structs */
    qLock               = PZ_NewLock(nssILockSelfServ);
    jobQNotEmptyCv      = PZ_NewCondVar(qLock);
    freeListNotEmptyCv  = PZ_NewCondVar(qLock);
    threadCountChangeCv = PZ_NewCondVar(qLock);

    /* create monitor for crl reload procedure */
    lastLoadedCrlLock   = PR_NewLock();

    /* allocate the array of thread slots */
    threads = PR_Calloc(maxThreads, sizeof(perThread));
    if ( NULL == threads )  {
        fprintf(stderr, "Oh Drat! Can't allocate the perThread array\n");
        return SECFailure;
    }
    /* 5 is a little extra, intended to keep the jobQ from underflowing. 
    ** That is, from going empty while not stopping and clients are still
    ** trying to contact us.
    */
    rv = setupJobs(maxThreads + 5);
    if (rv != SECSuccess)
    	return rv;

    PZ_Lock(qLock);
    for (i = 0; i < maxThreads; ++i) {
    	perThread * slot = threads + i;

	slot->state = rs_running;
	slot->a = a;
	slot->b = b;
	slot->c = c;
	slot->startFunc = startFunc;
	slot->prThread = PR_CreateThread(PR_USER_THREAD, 
			thread_wrapper, slot, PR_PRIORITY_NORMAL, 
                        (PR_TRUE==local)?PR_LOCAL_THREAD:PR_GLOBAL_THREAD,
                        PR_UNJOINABLE_THREAD, 0);
	if (slot->prThread == NULL) {
	    printf("selfserv: Failed to launch thread!\n");
	    slot->state = rs_idle;
	    rv = SECFailure;
	    break;
	} 

	++threadCount;
    }
    PZ_Unlock(qLock); 

    return rv;
}

#define DESTROY_CONDVAR(name) if (name) { \
        PZ_DestroyCondVar(name); name = NULL; }
#define DESTROY_LOCK(name) if (name) { \
        PZ_DestroyLock(name); name = NULL; }
	

void
terminateWorkerThreads(void)
{
    VLOG(("selfserv: server_thead: waiting on stopping"));
    PZ_Lock(qLock);
    PZ_NotifyAllCondVar(jobQNotEmptyCv);
    while (threadCount > 0) {
	PZ_WaitCondVar(threadCountChangeCv, PR_INTERVAL_NO_TIMEOUT);
    }
    /* The worker threads empty the jobQ before they terminate. */
    PORT_Assert(PR_CLIST_IS_EMPTY(&jobQ));
    PZ_Unlock(qLock); 

    DESTROY_CONDVAR(jobQNotEmptyCv);
    DESTROY_CONDVAR(freeListNotEmptyCv);
    DESTROY_CONDVAR(threadCountChangeCv);

    PR_DestroyLock(lastLoadedCrlLock);
    DESTROY_LOCK(qLock);
    PR_Free(jobTable);
    PR_Free(threads);
}

static void 
logger(void *arg)
{
    PRFloat64 seconds;
    PRFloat64 opsPerSec;
    PRIntervalTime period;
    PRIntervalTime previousTime;
    PRIntervalTime latestTime;
    PRUint32 previousOps;
    PRUint32 ops;
    PRIntervalTime logPeriodTicks = PR_TicksPerSecond();
    PRFloat64 secondsPerTick = 1.0 / (PRFloat64)logPeriodTicks;
    int iterations = 0;
    int secondsElapsed = 0;
    static PRInt64 totalPeriodBytes = 0;
    static PRInt64 totalPeriodBytesTCP = 0;

    previousOps = loggerOps;
    previousTime = PR_IntervalNow();
 
    for (;;) {
        /* OK, implementing a new sleep algorithm here... always sleep 
         * for 1 second but print out info at the user-specified interval.
         * This way, we don't overflow all of our PR_Atomic* functions and 
         * we don't have to use locks. 
         */
        PR_Sleep(logPeriodTicks);
        secondsElapsed++;
        totalPeriodBytes +=  PR_AtomicSet(&loggerBytes, 0);
        totalPeriodBytesTCP += PR_AtomicSet(&loggerBytesTCP, 0);
        if (secondsElapsed != logPeriod) {
            continue;
        }
        /* when we reach the user-specified logging interval, print out all
         * data 
         */
        secondsElapsed = 0;
        latestTime = PR_IntervalNow();
        ops = loggerOps;
        period = latestTime - previousTime;
        seconds = (PRFloat64) period*secondsPerTick;
        opsPerSec = (ops - previousOps) / seconds;

        if (testBulk) {
            if (iterations == 0) {
                if (loggingLayer == PR_TRUE) {
                    printf("Conn.--------App Data--------TCP Data\n");
                } else {
                    printf("Conn.--------App Data\n");
                }
            }
            if (loggingLayer == PR_TRUE) {
                printf("%4.d       %5.3f MB/s      %5.3f MB/s\n", ops, 
                    totalPeriodBytes / (seconds * 1048576.0), 
                    totalPeriodBytesTCP / (seconds * 1048576.0));
            } else {
                printf("%4.d       %5.3f MB/s\n", ops, 
                    totalPeriodBytes / (seconds * 1048576.0));
            }
            totalPeriodBytes = 0;
            totalPeriodBytesTCP = 0;
            /* Print the "legend" every 20 iterations */
            iterations = (iterations + 1) % 20; 
        } else {
            printf("%.2f ops/second, %d threads\n", opsPerSec, threadCount);
        }

        fflush(stdout);
        previousOps = ops;
        previousTime = latestTime;
        if (stopping) {
            break;
        }
    }
}


/**************************************************************************
** End   thread management routines.
**************************************************************************/

PRBool useModelSocket  = PR_FALSE;
PRBool disableSSL2     = PR_FALSE;
PRBool disableSSL3     = PR_FALSE;
PRBool disableTLS      = PR_FALSE;
PRBool disableRollBack = PR_FALSE;
PRBool NoReuse         = PR_FALSE;
PRBool hasSidCache     = PR_FALSE;
PRBool disableStepDown = PR_FALSE;
PRBool bypassPKCS11    = PR_FALSE;
PRBool disableLocking  = PR_FALSE;
PRBool testbypass      = PR_FALSE;
PRBool enableSessionTickets = PR_FALSE;
PRBool enableCompression    = PR_FALSE;
PRBool failedToNegotiateName  = PR_FALSE;
static char  *virtServerNameArray[MAX_VIRT_SERVER_NAME_ARRAY_INDEX];

static const char stopCmd[] = { "GET /stop " };
static const char getCmd[]  = { "GET " };
static const char EOFmsg[]  = { "EOF\r\n\r\n\r\n" };
static const char outHeader[] = {
    "HTTP/1.0 200 OK\r\n"
    "Server: Generic Web Server\r\n"
    "Date: Tue, 26 Aug 1997 22:10:05 GMT\r\n"
    "Content-type: text/plain\r\n"
    "\r\n"
};
static const char crlCacheErr[]  = { "CRL ReCache Error: " };

PRUint16 cipherlist[100];
int nciphers;

void
savecipher(int c)
{
    if (nciphers < sizeof cipherlist / sizeof (cipherlist[0]))
	cipherlist[nciphers++] = (PRUint16)c;
}


#ifdef FULL_DUPLEX_CAPABLE

struct lockedVarsStr {
    PZLock *	lock;
    int		count;
    int		waiters;
    PZCondVar *	condVar;
};

typedef struct lockedVarsStr lockedVars;

void 
lockedVars_Init( lockedVars * lv)
{
    lv->count   = 0;
    lv->waiters = 0;
    lv->lock    = PZ_NewLock(nssILockSelfServ);
    lv->condVar = PZ_NewCondVar(lv->lock);
}

void
lockedVars_Destroy( lockedVars * lv)
{
    PZ_DestroyCondVar(lv->condVar);
    lv->condVar = NULL;

    PZ_DestroyLock(lv->lock);
    lv->lock = NULL;
}

void
lockedVars_WaitForDone(lockedVars * lv)
{
    PZ_Lock(lv->lock);
    while (lv->count > 0) {
    	PZ_WaitCondVar(lv->condVar, PR_INTERVAL_NO_TIMEOUT);
    }
    PZ_Unlock(lv->lock);
}

int	/* returns count */
lockedVars_AddToCount(lockedVars * lv, int addend)
{
    int rv;

    PZ_Lock(lv->lock);
    rv = lv->count += addend;
    if (rv <= 0) {
	PZ_NotifyCondVar(lv->condVar);
    }
    PZ_Unlock(lv->lock);
    return rv;
}

int
do_writes(
    PRFileDesc *	ssl_sock,
    PRFileDesc *	model_sock,
    int         	requestCert
    )
{
    int			sent  = 0;
    int 		count = 0;
    lockedVars *	lv = (lockedVars *)model_sock;

    VLOG(("selfserv: do_writes: starting"));
    while (sent < bigBuf.len) {

	count = PR_Write(ssl_sock, bigBuf.data + sent, bigBuf.len - sent);
	if (count < 0) {
	    errWarn("PR_Write bigBuf");
	    break;
	}
	FPRINTF(stderr, "selfserv: PR_Write wrote %d bytes from bigBuf\n", count );
	sent += count;
    }
    if (count >= 0) {	/* last write didn't fail. */
    	PR_Shutdown(ssl_sock, PR_SHUTDOWN_SEND);
    }

    /* notify the reader that we're done. */
    lockedVars_AddToCount(lv, -1);
    FLUSH;
    VLOG(("selfserv: do_writes: exiting"));
    return (sent < bigBuf.len) ? SECFailure : SECSuccess;
}

static int 
handle_fdx_connection(
    PRFileDesc *       tcp_sock,
    PRFileDesc *       model_sock,
    int                requestCert
    )
{
    PRFileDesc *       ssl_sock	= NULL;
    SECStatus          result;
    int                firstTime = 1;
    lockedVars         lv;
    PRSocketOptionData opt;
    char               buf[10240];


    VLOG(("selfserv: handle_fdx_connection: starting"));
    opt.option             = PR_SockOpt_Nonblocking;
    opt.value.non_blocking = PR_FALSE;
    PR_SetSocketOption(tcp_sock, &opt);

    if (useModelSocket && model_sock) {
	SECStatus rv;
	ssl_sock = SSL_ImportFD(model_sock, tcp_sock);
	if (!ssl_sock) {
	    errWarn("SSL_ImportFD with model");
	    goto cleanup;
	}
	rv = SSL_ResetHandshake(ssl_sock, /* asServer */ 1);
	if (rv != SECSuccess) {
	    errWarn("SSL_ResetHandshake");
	    goto cleanup;
	}
    } else {
	ssl_sock = tcp_sock;
    }

    lockedVars_Init(&lv);
    lockedVars_AddToCount(&lv, 1);

    /* Attempt to launch the writer thread. */
    result = launch_thread(do_writes, ssl_sock, (PRFileDesc *)&lv, 
                           requestCert);

    if (result == SECSuccess) 
      do {
	/* do reads here. */
	int count;
	count = PR_Read(ssl_sock, buf, sizeof buf);
	if (count < 0) {
	    errWarn("FDX PR_Read");
	    break;
	}
	FPRINTF(stderr, "selfserv: FDX PR_Read read %d bytes.\n", count );
	if (firstTime) {
	    firstTime = 0;
	    printSecurityInfo(ssl_sock);
	}
    } while (lockedVars_AddToCount(&lv, 0) > 0);

    /* Wait for writer to finish */
    lockedVars_WaitForDone(&lv);
    lockedVars_Destroy(&lv);
    FLUSH;

cleanup:
    if (ssl_sock) {
	PR_Close(ssl_sock);
    } else if (tcp_sock) {
	PR_Close(tcp_sock);
    }

    VLOG(("selfserv: handle_fdx_connection: exiting"));
    return SECSuccess;
}

#endif

static SECItem *lastLoadedCrl = NULL;

static SECStatus
reload_crl(PRFileDesc *crlFile)
{
    SECItem *crlDer;
    CERTCertDBHandle *certHandle = CERT_GetDefaultCertDB();
    SECStatus rv;

    /* Read in the entire file specified with the -f argument */
    crlDer = PORT_Malloc(sizeof(SECItem));
    if (!crlDer) {
        errWarn("Can not allocate memory.");
        return SECFailure;
    }

    rv = SECU_ReadDERFromFile(crlDer, crlFile, PR_FALSE);
    if (rv != SECSuccess) {
        errWarn("Unable to read input file.");
        PORT_Free(crlDer);
        return SECFailure;
    }

    PR_Lock(lastLoadedCrlLock);
    rv = CERT_CacheCRL(certHandle, crlDer);
    if (rv == SECSuccess) {
        SECItem *tempItem = crlDer;
        if (lastLoadedCrl != NULL) {
            rv = CERT_UncacheCRL(certHandle, lastLoadedCrl);
            if (rv != SECSuccess) {
                errWarn("Unable to uncache crl.");
                goto loser;
            }
            crlDer = lastLoadedCrl;
        } else {
            crlDer = NULL;
        }
        lastLoadedCrl = tempItem;
    }

  loser:
    PR_Unlock(lastLoadedCrlLock);
    SECITEM_FreeItem(crlDer, PR_TRUE);
    return rv;
}

void stop_server()
{
    stopping = 1;
    PR_Interrupt(acceptorThread);
    PZ_TraceFlush();
}

int
handle_connection( 
    PRFileDesc *tcp_sock,
    PRFileDesc *model_sock,
    int         requestCert
    )
{
    PRFileDesc *       ssl_sock = NULL;
    PRFileDesc *       local_file_fd = NULL;
    char  *            post;
    char  *            pBuf;			/* unused space at end of buf */
    const char *       errString;
    PRStatus           status;
    int                bufRem;			/* unused bytes at end of buf */
    int                bufDat;			/* characters received in buf */
    int                newln    = 0;		/* # of consecutive newlns */
    int                firstTime = 1;
    int                reqLen;
    int                rv;
    int                numIOVs;
    PRSocketOptionData opt;
    PRIOVec            iovs[16];
    char               msgBuf[160];
    char               buf[10240];
    char               fileName[513];
    char               proto[128];
    PRDescIdentity     aboveLayer = PR_INVALID_IO_LAYER;

    pBuf   = buf;
    bufRem = sizeof buf;

    VLOG(("selfserv: handle_connection: starting"));
    opt.option             = PR_SockOpt_Nonblocking;
    opt.value.non_blocking = PR_FALSE;
    PR_SetSocketOption(tcp_sock, &opt);

    VLOG(("selfserv: handle_connection: starting\n"));
    if (useModelSocket && model_sock) {
	SECStatus rv;
	ssl_sock = SSL_ImportFD(model_sock, tcp_sock);
	if (!ssl_sock) {
	    errWarn("SSL_ImportFD with model");
	    goto cleanup;
	}
	rv = SSL_ResetHandshake(ssl_sock, /* asServer */ 1);
	if (rv != SECSuccess) {
	    errWarn("SSL_ResetHandshake");
	    goto cleanup;
	}
    } else {
	ssl_sock = tcp_sock;
    }

    if (loggingLayer) {
        /* find the layer where our new layer is to be pushed */
        aboveLayer = PR_GetLayersIdentity(ssl_sock->lower);
        if (aboveLayer == PR_INVALID_IO_LAYER) {
            errExit("PRGetUniqueIdentity");
        }
        /* create the new layer - this is a very cheap operation */
        loggingFD = PR_CreateIOLayerStub(log_layer_id, &loggingMethods);
        if (!loggingFD)
            errExit("PR_CreateIOLayerStub");
        /* push the layer below ssl but above TCP */
        rv = PR_PushIOLayer(ssl_sock, aboveLayer, loggingFD);
        if (rv != PR_SUCCESS) {
            errExit("PR_PushIOLayer");
        }
    }

    if (noDelay) {
	opt.option         = PR_SockOpt_NoDelay;
	opt.value.no_delay = PR_TRUE;
	status = PR_SetSocketOption(ssl_sock, &opt);
	if (status != PR_SUCCESS) {
	    errWarn("PR_SetSocketOption(PR_SockOpt_NoDelay, PR_TRUE)");
            if (ssl_sock) {
	        PR_Close(ssl_sock);
            }
	    return SECFailure;
	}
    }

    while (1) {
	newln = 0;
	reqLen     = 0;
	rv = PR_Read(ssl_sock, pBuf, bufRem - 1);
	if (rv == 0 || 
	    (rv < 0 && PR_END_OF_FILE_ERROR == PR_GetError())) {
	    if (verbose)
		errWarn("HDX PR_Read hit EOF");
	    break;
	}
	if (rv < 0) {
	    errWarn("HDX PR_Read");
	    goto cleanup;
	}
	/* NULL termination */
	pBuf[rv] = 0;
	if (firstTime) {
	    firstTime = 0;
	    printSecurityInfo(ssl_sock);
	}

	pBuf   += rv;
	bufRem -= rv;
	bufDat = pBuf - buf;
	/* Parse the input, starting at the beginning of the buffer.
	 * Stop when we detect two consecutive \n's (or \r\n's) 
	 * as this signifies the end of the GET or POST portion.
	 * The posted data follows.
	 */
	while (reqLen < bufDat && newln < 2) {
	    int octet = buf[reqLen++];
	    if (octet == '\n') {
		newln++;
	    } else if (octet != '\r') {
		newln = 0;
	    }
	}

	/* came to the end of the buffer, or second newln
	 * If we didn't get an empty line (CRLFCRLF) then keep on reading.
	 */
	if (newln < 2) 
	    continue;

	/* we're at the end of the HTTP request.
	 * If the request is a POST, then there will be one more
	 * line of data.
	 * This parsing is a hack, but ok for SSL test purposes.
	 */
	post = PORT_Strstr(buf, "POST ");
	if (!post || *post != 'P') 
	    break;

	/* It's a post, so look for the next and final CR/LF. */
	/* We should parse content length here, but ... */
	while (reqLen < bufDat && newln < 3) {
	    int octet = buf[reqLen++];
	    if (octet == '\n') {
		newln++;
	    }
	}
	if (newln == 3)
	    break;
    } /* read loop */

    bufDat = pBuf - buf;
    if (bufDat) do {	/* just close if no data */
	/* Have either (a) a complete get, (b) a complete post, (c) EOF */
	if (reqLen > 0 && !strncmp(buf, getCmd, sizeof getCmd - 1)) {
	    char *      fnBegin = buf + 4;
	    char *      fnEnd;
	    PRFileInfo  info;
	    /* try to open the file named.  
	     * If successful, then write it to the client.
	     */
	    fnEnd = strpbrk(fnBegin, " \r\n");
	    if (fnEnd) {
		int fnLen = fnEnd - fnBegin;
		if (fnLen < sizeof fileName) {
                    char *real_fileName = fileName;
                    char *protoEnd = NULL;
                    strncpy(fileName, fnBegin, fnLen);
                    fileName[fnLen] = 0;	/* null terminate */
                    if ((protoEnd = strstr(fileName, "://")) != NULL) {
                        int protoLen = PR_MIN(protoEnd - fileName, sizeof(proto) - 1);
                        PL_strncpy(proto, fileName, protoLen);
                        proto[protoLen] = 0;
                        real_fileName= protoEnd + 3;
                    } else {
                        proto[0] = 0;
                    }
		    status = PR_GetFileInfo(real_fileName, &info);
		    if (status == PR_SUCCESS &&
			info.type == PR_FILE_FILE &&
			info.size >= 0 ) {
			local_file_fd = PR_Open(real_fileName, PR_RDONLY, 0);
		    }
		}
	    }
	}
	/* if user has requested client auth in a subsequent handshake,
	 * do it here.
	 */
	if (requestCert > 2) { /* request cert was 3 or 4 */
	    CERTCertificate *  cert =  SSL_PeerCertificate(ssl_sock);
	    if (cert) {
		CERT_DestroyCertificate(cert);
	    } else {
		rv = SSL_OptionSet(ssl_sock, SSL_REQUEST_CERTIFICATE, 1);
		if (rv < 0) {
		    errWarn("second SSL_OptionSet SSL_REQUEST_CERTIFICATE");
		    break;
		}
		rv = SSL_OptionSet(ssl_sock, SSL_REQUIRE_CERTIFICATE, 
				(requestCert == 4));
		if (rv < 0) {
		    errWarn("second SSL_OptionSet SSL_REQUIRE_CERTIFICATE");
		    break;
		}
		rv = SSL_ReHandshake(ssl_sock, PR_TRUE);
		if (rv != 0) {
		    errWarn("SSL_ReHandshake");
		    break;
		}
		rv = SSL_ForceHandshake(ssl_sock);
		if (rv < 0) {
		    errWarn("SSL_ForceHandshake");
		    break;
		}
	    }
	}

	numIOVs = 0;

	iovs[numIOVs].iov_base = (char *)outHeader;
	iovs[numIOVs].iov_len  = (sizeof(outHeader)) - 1;
	numIOVs++;

	if (local_file_fd) {
	    PRInt32     bytes;
	    int         errLen;
	    if (!PL_strlen(proto) || !PL_strcmp(proto, "file")) {
                bytes = PR_TransmitFile(ssl_sock, local_file_fd, outHeader,
                                        sizeof outHeader - 1,
                                        PR_TRANSMITFILE_KEEP_OPEN,
                                        PR_INTERVAL_NO_TIMEOUT);
                if (bytes >= 0) {
                    bytes -= sizeof outHeader - 1;
                    FPRINTF(stderr, 
                            "selfserv: PR_TransmitFile wrote %d bytes from %s\n",
                            bytes, fileName);
                    break;
                }
                errString = errWarn("PR_TransmitFile");
                errLen = PORT_Strlen(errString);
                errLen = PR_MIN(errLen, sizeof msgBuf - 1);
                PORT_Memcpy(msgBuf, errString, errLen);
                msgBuf[errLen] = 0;
                
                iovs[numIOVs].iov_base = msgBuf;
                iovs[numIOVs].iov_len  = PORT_Strlen(msgBuf);
                numIOVs++;
            }
            if (!PL_strcmp(proto, "crl")) {
                if (reload_crl(local_file_fd) == SECFailure) {
                    errString = errWarn("CERT_CacheCRL");
                    if (!errString)
                        errString = "Unknow error";
                    PR_snprintf(msgBuf, sizeof(msgBuf), "%s%s ",
                                crlCacheErr, errString);
                    
                    iovs[numIOVs].iov_base = msgBuf;
                    iovs[numIOVs].iov_len  = PORT_Strlen(msgBuf);
                    numIOVs++;
                } else {
                    FPRINTF(stderr, 
                            "selfserv: CRL %s reloaded.\n",
                            fileName);
                    break;
                }
            }
	} else if (reqLen <= 0) {	/* hit eof */
	    PORT_Sprintf(msgBuf, "Get or Post incomplete after %d bytes.\r\n",
			 bufDat);

	    iovs[numIOVs].iov_base = msgBuf;
	    iovs[numIOVs].iov_len  = PORT_Strlen(msgBuf);
	    numIOVs++;
	} else if (reqLen < bufDat) {
	    PORT_Sprintf(msgBuf, "Discarded %d characters.\r\n", 
	                 bufDat - reqLen);

	    iovs[numIOVs].iov_base = msgBuf;
	    iovs[numIOVs].iov_len  = PORT_Strlen(msgBuf);
	    numIOVs++;
	}

	if (reqLen > 0) {
	    if (verbose > 1) 
	    	fwrite(buf, 1, reqLen, stdout);	/* display it */

	    iovs[numIOVs].iov_base = buf;
	    iovs[numIOVs].iov_len  = reqLen;
	    numIOVs++;
	}

        /* Don't add the EOF if we want to test bulk encryption */
        if (!testBulk) {
            iovs[numIOVs].iov_base = (char *)EOFmsg;
            iovs[numIOVs].iov_len  = sizeof EOFmsg - 1;
            numIOVs++;
        }

	rv = PR_Writev(ssl_sock, iovs, numIOVs, PR_INTERVAL_NO_TIMEOUT);
	if (rv < 0) {
	    errWarn("PR_Writev");
	    break;
	}

        /* Send testBulkTotal chunks to the client. Unlimited if 0. */
        if (testBulk) {
            while (0 < (rv = PR_Write(ssl_sock, testBulkBuf, testBulkSize))) {
                PR_AtomicAdd(&loggerBytes, rv);
                PR_AtomicIncrement(&bulkSentChunks);
                if ((bulkSentChunks > testBulkTotal) && (testBulkTotal != 0))
                    break;
            }

            /* There was a write error, so close this connection. */
            if (bulkSentChunks <= testBulkTotal) {
                errWarn("PR_Write");
            }
            PR_AtomicDecrement(&loggerOps);
            break;
        }
    } while (0);

cleanup:
    if (ssl_sock) {
        PR_Close(ssl_sock);
    } else if (tcp_sock) {
        PR_Close(tcp_sock);
    }
    if (local_file_fd)
	PR_Close(local_file_fd);
    VLOG(("selfserv: handle_connection: exiting\n"));

    /* do a nice shutdown if asked. */
    if (!strncmp(buf, stopCmd, sizeof stopCmd - 1)) {
        VLOG(("selfserv: handle_connection: stop command"));
        stop_server();
    }
    VLOG(("selfserv: handle_connection: exiting"));
    return SECSuccess;	/* success */
}

#ifdef XP_UNIX

void sigusr1_handler(int sig)
{
    VLOG(("selfserv: sigusr1_handler: stop server"));
    stop_server();
}

#endif

SECStatus
do_accepts(
    PRFileDesc *listen_sock,
    PRFileDesc *model_sock,
    int         requestCert
    )
{
    PRNetAddr   addr;
    PRErrorCode  perr;
#ifdef XP_UNIX
    struct sigaction act;
#endif

    VLOG(("selfserv: do_accepts: starting"));
    PR_SetThreadPriority( PR_GetCurrentThread(), PR_PRIORITY_HIGH);

    acceptorThread = PR_GetCurrentThread();
#ifdef XP_UNIX
    /* set up the signal handler */
    act.sa_handler = sigusr1_handler;
    sigemptyset(&act.sa_mask);
    act.sa_flags = 0;
    if (sigaction(SIGUSR1, &act, NULL)) {
        fprintf(stderr, "Error installing signal handler.\n");
        exit(1);
    }
#endif
    while (!stopping) {
	PRFileDesc *tcp_sock;
	PRCList    *myLink;

	FPRINTF(stderr, "\n\n\nselfserv: About to call accept.\n");
	tcp_sock = PR_Accept(listen_sock, &addr, PR_INTERVAL_NO_TIMEOUT);
	if (tcp_sock == NULL) {
    	    perr      = PR_GetError();
	    if ((perr != PR_CONNECT_RESET_ERROR &&
	         perr != PR_PENDING_INTERRUPT_ERROR) || verbose) {
		errWarn("PR_Accept");
	    } 
	    if (perr == PR_CONNECT_RESET_ERROR) {
		FPRINTF(stderr, 
		        "Ignoring PR_CONNECT_RESET_ERROR error - continue\n");
		continue;
	    }
	    stopping = 1;
	    break;
	}

        VLOG(("selfserv: do_accept: Got connection\n"));

        if (logStats) {
            PR_AtomicIncrement(&loggerOps);
        }

	PZ_Lock(qLock);
	while (PR_CLIST_IS_EMPTY(&freeJobs) && !stopping) {
            PZ_WaitCondVar(freeListNotEmptyCv, PR_INTERVAL_NO_TIMEOUT);
	}
	if (stopping) {
	    PZ_Unlock(qLock);
            if (tcp_sock) {
	        PR_Close(tcp_sock);
            }
	    break;
	}
	myLink = PR_LIST_HEAD(&freeJobs);
	PR_REMOVE_AND_INIT_LINK(myLink);
	/* could release qLock here and reaquire it 7 lines below, but 
	** why bother for 4 assignment statements? 
	*/
	{
	    JOB * myJob = (JOB *)myLink;
	    myJob->tcp_sock    = tcp_sock;
	    myJob->model_sock  = model_sock;
	    myJob->requestCert = requestCert;
	}

	PR_APPEND_LINK(myLink, &jobQ);
	PZ_NotifyCondVar(jobQNotEmptyCv);
	PZ_Unlock(qLock);
    }

    FPRINTF(stderr, "selfserv: Closing listen socket.\n");
    VLOG(("selfserv: do_accepts: exiting"));
    if (listen_sock) {
        PR_Close(listen_sock);
    }
    return SECSuccess;
}

PRFileDesc *
getBoundListenSocket(unsigned short port)
{
    PRFileDesc *       listen_sock;
    int                listenQueueDepth = 5 + (2 * maxThreads);
    PRStatus	       prStatus;
    PRNetAddr          addr;
    PRSocketOptionData opt;

    addr.inet.family = PR_AF_INET;
    addr.inet.ip     = PR_INADDR_ANY;
    addr.inet.port   = PR_htons(port);

    listen_sock = PR_NewTCPSocket();
    if (listen_sock == NULL) {
	errExit("PR_NewTCPSocket");
    }

    opt.option = PR_SockOpt_Nonblocking;
    opt.value.non_blocking = PR_FALSE;
    prStatus = PR_SetSocketOption(listen_sock, &opt);
    if (prStatus < 0) {
        PR_Close(listen_sock);
	errExit("PR_SetSocketOption(PR_SockOpt_Nonblocking)");
    }

    opt.option=PR_SockOpt_Reuseaddr;
    opt.value.reuse_addr = PR_TRUE;
    prStatus = PR_SetSocketOption(listen_sock, &opt);
    if (prStatus < 0) {
        PR_Close(listen_sock);
	errExit("PR_SetSocketOption(PR_SockOpt_Reuseaddr)");
    }

#ifndef WIN95
    /* Set PR_SockOpt_Linger because it helps prevent a server bind issue
     * after clean shutdown . See bug 331413 .
     * Don't do it in the WIN95 build configuration because clean shutdown is
     * not implemented, and PR_SockOpt_Linger causes a hang in ssl.sh .
     * See bug 332348 */
    opt.option=PR_SockOpt_Linger;
    opt.value.linger.polarity = PR_TRUE;
    opt.value.linger.linger = PR_SecondsToInterval(1);
    prStatus = PR_SetSocketOption(listen_sock, &opt);
    if (prStatus < 0) {
        PR_Close(listen_sock);
        errExit("PR_SetSocketOption(PR_SockOpt_Linger)");
    }
#endif

    prStatus = PR_Bind(listen_sock, &addr);
    if (prStatus < 0) {
        PR_Close(listen_sock);
	errExit("PR_Bind");
    }

    prStatus = PR_Listen(listen_sock, listenQueueDepth);
    if (prStatus < 0) {
        PR_Close(listen_sock);
	errExit("PR_Listen");
    }
    return listen_sock;
}

PRInt32 PR_CALLBACK 
logWritev (
    PRFileDesc     *fd,
    const PRIOVec  *iov,
    PRInt32         size, 
    PRIntervalTime  timeout )
{
    PRInt32 rv = (fd->lower->methods->writev)(fd->lower, iov, size, 
        timeout);
    /* Add the amount written, but not if there's an error */
    if (rv > 0) 
        PR_AtomicAdd(&loggerBytesTCP, rv);
    return rv;
}
    
PRInt32 PR_CALLBACK 
logWrite (
    PRFileDesc  *fd, 
    const void  *buf, 
    PRInt32      amount)
{   
    PRInt32 rv = (fd->lower->methods->write)(fd->lower, buf, amount);
    /* Add the amount written, but not if there's an error */
    if (rv > 0) 
        PR_AtomicAdd(&loggerBytesTCP, rv);
    
    return rv;
}

PRInt32 PR_CALLBACK 
logSend (
    PRFileDesc     *fd, 
    const void     *buf, 
    PRInt32         amount, 
    PRIntn          flags, 
    PRIntervalTime  timeout)
{
    PRInt32 rv = (fd->lower->methods->send)(fd->lower, buf, amount, 
        flags, timeout);
    /* Add the amount written, but not if there's an error */
    if (rv > 0) 
        PR_AtomicAdd(&loggerBytesTCP, rv);
    return rv;
}
 
void initLoggingLayer(void)
{   
    /* get a new layer ID */
    log_layer_id = PR_GetUniqueIdentity("Selfserv Logging");
    if (log_layer_id == PR_INVALID_IO_LAYER)
        errExit("PR_GetUniqueIdentity");
    
    /* setup the default IO methods with my custom write methods */
    memcpy(&loggingMethods, PR_GetDefaultIOMethods(), sizeof(PRIOMethods));
    loggingMethods.writev = logWritev;
    loggingMethods.write  = logWrite;
    loggingMethods.send   = logSend;
}

void
handshakeCallback(PRFileDesc *fd, void *client_data)
{
    const char *handshakeName = (const char *)client_data;
    if (handshakeName && !failedToNegotiateName) {
        SECItem *hostInfo  = SSL_GetNegotiatedHostInfo(fd);
        if (!hostInfo || PORT_Strncmp(handshakeName, (char*)hostInfo->data,
                                      hostInfo->len)) {
            failedToNegotiateName = PR_TRUE;
        }
    }
}

void
server_main(
    PRFileDesc *        listen_sock,
    int                 requestCert, 
    SECKEYPrivateKey ** privKey,
    CERTCertificate **  cert,
    const char *expectedHostNameVal)
{
    PRFileDesc *model_sock	= NULL;
    int         rv;
    SSLKEAType  kea;
    SECStatus	secStatus;

    if (useModelSocket) {
    	model_sock = PR_NewTCPSocket();
	if (model_sock == NULL) {
	    errExit("PR_NewTCPSocket on model socket");
	}
	model_sock = SSL_ImportFD(NULL, model_sock);
	if (model_sock == NULL) {
	    errExit("SSL_ImportFD");
	}
    } else {
	model_sock = listen_sock = SSL_ImportFD(NULL, listen_sock);
	if (listen_sock == NULL) {
	    errExit("SSL_ImportFD");
	}
    }

    /* do SSL configuration. */
    rv = SSL_OptionSet(model_sock, SSL_SECURITY,
        !(disableSSL2 && disableSSL3 && disableTLS));
    if (rv < 0) {
	errExit("SSL_OptionSet SSL_SECURITY");
    }

    rv = SSL_OptionSet(model_sock, SSL_ENABLE_SSL3, !disableSSL3);
    if (rv != SECSuccess) {
	errExit("error enabling SSLv3 ");
    }

    rv = SSL_OptionSet(model_sock, SSL_ENABLE_TLS, !disableTLS);
    if (rv != SECSuccess) {
	errExit("error enabling TLS ");
    }

    rv = SSL_OptionSet(model_sock, SSL_ENABLE_SSL2, !disableSSL2);
    if (rv != SECSuccess) {
	errExit("error enabling SSLv2 ");
    }
    
    rv = SSL_OptionSet(model_sock, SSL_ROLLBACK_DETECTION, !disableRollBack);
    if (rv != SECSuccess) {
	errExit("error enabling RollBack detection ");
    }
    if (disableStepDown) {
	rv = SSL_OptionSet(model_sock, SSL_NO_STEP_DOWN, PR_TRUE);
	if (rv != SECSuccess) {
	    errExit("error disabling SSL StepDown ");
	}
    }
    if (bypassPKCS11) {
       rv = SSL_OptionSet(model_sock, SSL_BYPASS_PKCS11, PR_TRUE);
	if (rv != SECSuccess) {
	    errExit("error enabling PKCS11 bypass ");
	}
    }
    if (disableLocking) {
       rv = SSL_OptionSet(model_sock, SSL_NO_LOCKS, PR_TRUE);
	if (rv != SECSuccess) {
	    errExit("error disabling SSL socket locking ");
	}
    } 
    if (enableSessionTickets) {
	rv = SSL_OptionSet(model_sock, SSL_ENABLE_SESSION_TICKETS, PR_TRUE);
	if (rv != SECSuccess) {
	    errExit("error enabling Session Ticket extension ");
	}
    }

    if (enableCompression) {
	rv = SSL_OptionSet(model_sock, SSL_ENABLE_DEFLATE, PR_TRUE);
	if (rv != SECSuccess) {
	    errExit("error enabling compression ");
	}
    }

    rv = SSL_SNISocketConfigHook(model_sock, mySSLSNISocketConfig,
                                 (void*)&virtServerNameArray);
    if (rv != SECSuccess) {
        errExit("error enabling SNI extension ");
    }

    for (kea = kt_rsa; kea < kt_kea_size; kea++) {
	if (cert[kea] != NULL) {
	    secStatus = SSL_ConfigSecureServer(model_sock, 
	    		cert[kea], privKey[kea], kea);
	    if (secStatus != SECSuccess)
		errExit("SSL_ConfigSecureServer");
	}
    }

    if (bigBuf.data) { /* doing FDX */
	rv = SSL_OptionSet(model_sock, SSL_ENABLE_FDX, 1);
	if (rv < 0) {
	    errExit("SSL_OptionSet SSL_ENABLE_FDX");
	}
    }

    if (NoReuse) {
        rv = SSL_OptionSet(model_sock, SSL_NO_CACHE, 1);
        if (rv < 0) {
            errExit("SSL_OptionSet SSL_NO_CACHE");
        }
    }

    /* This cipher is not on by default. The Acceptance test
     * would like it to be. Turn this cipher on.
     */

    secStatus = SSL_CipherPrefSetDefault( SSL_RSA_WITH_NULL_MD5, PR_TRUE);
    if ( secStatus != SECSuccess ) {
	errExit("SSL_CipherPrefSetDefault:SSL_RSA_WITH_NULL_MD5");
    }

    if (expectedHostNameVal) {
        SSL_HandshakeCallback(model_sock, handshakeCallback,
                              (void*)expectedHostNameVal);
    }

    if (requestCert) {
	SSL_AuthCertificateHook(model_sock, mySSLAuthCertificate, 
	                        (void *)CERT_GetDefaultCertDB());
	if (requestCert <= 2) { 
	    rv = SSL_OptionSet(model_sock, SSL_REQUEST_CERTIFICATE, 1);
	    if (rv < 0) {
		errExit("first SSL_OptionSet SSL_REQUEST_CERTIFICATE");
	    }
	    rv = SSL_OptionSet(model_sock, SSL_REQUIRE_CERTIFICATE, 
	                    (requestCert == 2));
	    if (rv < 0) {
		errExit("first SSL_OptionSet SSL_REQUIRE_CERTIFICATE");
	    }
	}
    }

    if (MakeCertOK)
	SSL_BadCertHook(model_sock, myBadCertHandler, NULL);

    /* end of ssl configuration. */


    /* Now, do the accepting, here in the main thread. */
    rv = do_accepts(listen_sock, model_sock, requestCert);

    terminateWorkerThreads();

    if (useModelSocket && model_sock) {
        if (model_sock) {
            PR_Close(model_sock);
        }
    }

}

SECStatus
readBigFile(const char * fileName)
{
    PRFileInfo  info;
    PRStatus	status;
    SECStatus	rv	= SECFailure;
    int		count;
    int		hdrLen;
    PRFileDesc *local_file_fd = NULL;

    status = PR_GetFileInfo(fileName, &info);

    if (status == PR_SUCCESS &&
	info.type == PR_FILE_FILE &&
	info.size > 0 &&
	NULL != (local_file_fd = PR_Open(fileName, PR_RDONLY, 0))) {

	hdrLen      = PORT_Strlen(outHeader);
	bigBuf.len  = hdrLen + info.size;
	bigBuf.data = PORT_Malloc(bigBuf.len + 4095);
	if (!bigBuf.data) {
	    errWarn("PORT_Malloc");
	    goto done;
	}

	PORT_Memcpy(bigBuf.data, outHeader, hdrLen);

	count = PR_Read(local_file_fd, bigBuf.data + hdrLen, info.size);
	if (count != info.size) {
	    errWarn("PR_Read local file");
	    goto done;
	}
	rv = SECSuccess;
done:
        if (local_file_fd) {
            PR_Close(local_file_fd);
        }
    }
    return rv;
}

int          numChildren;
PRProcess *  child[MAX_PROCS];

PRProcess *
haveAChild(int argc, char **argv, PRProcessAttr * attr)
{
    PRProcess *  newProcess;

    newProcess = PR_CreateProcess(argv[0], argv, NULL, attr);
    if (!newProcess) {
	errWarn("Can't create new process.");
    } else {
	child[numChildren++] = newProcess;
    }
    return newProcess;
}

void
beAGoodParent(int argc, char **argv, int maxProcs, PRFileDesc * listen_sock)
{
    PRProcess *     newProcess;
    PRProcessAttr * attr;
    int             i;
    PRInt32         exitCode;
    PRStatus        rv;

    rv = PR_SetFDInheritable(listen_sock, PR_TRUE);
    if (rv != PR_SUCCESS)
	errExit("PR_SetFDInheritable");

    attr = PR_NewProcessAttr();
    if (!attr)
	errExit("PR_NewProcessAttr");

    rv = PR_ProcessAttrSetInheritableFD(attr, listen_sock, inheritableSockName);
    if (rv != PR_SUCCESS)
	errExit("PR_ProcessAttrSetInheritableFD");

    for (i = 0; i < maxProcs; ++i) {
	newProcess = haveAChild(argc, argv, attr);
	if (!newProcess) 
	    break;
    }

    rv = PR_SetFDInheritable(listen_sock, PR_FALSE);
    if (rv != PR_SUCCESS)
	errExit("PR_SetFDInheritable");

    while (numChildren > 0) {
	newProcess = child[numChildren - 1];
	PR_WaitProcess(newProcess, &exitCode);
	fprintf(stderr, "Child %d exited with exit code %x\n", 
		numChildren, exitCode);
	numChildren--;
    }
    exit(0);
}

#define HEXCHAR_TO_INT(c, i) \
    if (((c) >= '0') && ((c) <= '9')) { \
	i = (c) - '0'; \
    } else if (((c) >= 'a') && ((c) <= 'f')) { \
	i = (c) - 'a' + 10; \
    } else if (((c) >= 'A') && ((c) <= 'F')) { \
	i = (c) - 'A' + 10; \
    } else if ((c) == '\0') { \
	fprintf(stderr, "Invalid length of cipher string (-c :WXYZ).\n"); \
	exit(9); \
    } else { \
	fprintf(stderr, "Non-hex char in cipher string (-c :WXYZ).\n"); \
	exit(9); \
    } 

int
main(int argc, char **argv)
{
    char *               progName    = NULL;
    char *               nickName    = NULL;
#ifdef NSS_ENABLE_ECC
    char *               ecNickName   = NULL;
#endif
    const char *         fileName    = NULL;
    char *               cipherString= NULL;
    const char *         dir         = ".";
    char *               passwd      = NULL;
    char *               pwfile      = NULL;
    const char *         pidFile     = NULL;
    char *               tmp;
    char *               envString;
    PRFileDesc *         listen_sock;
    CERTCertificate *    cert   [kt_kea_size] = { NULL };
    SECKEYPrivateKey *   privKey[kt_kea_size] = { NULL };
    int                  optionsFound = 0;
    int                  maxProcs     = 1;
    unsigned short       port        = 0;
    SECStatus            rv;
    PRStatus             prStatus;
    PRBool               bindOnly = PR_FALSE;
    PRBool               useExportPolicy = PR_FALSE;
    PRBool               useLocalThreads = PR_FALSE;
    PLOptState		*optstate;
    PLOptStatus          status;
    PRThread             *loggerThread = NULL;
    PRBool               debugCache = PR_FALSE; /* bug 90518 */
    char                 emptyString[] = { "" };
    char*                certPrefix = emptyString;
    PRUint32             protos = 0;
    SSL3Statistics      *ssl3stats;
    PRUint32             i;
    secuPWData  pwdata = { PW_NONE, 0 };
    int                  virtServerNameIndex = 1;
    char                *expectedHostNameVal = NULL;

    tmp = strrchr(argv[0], '/');
    tmp = tmp ? tmp + 1 : argv[0];
    progName = strrchr(tmp, '\\');
    progName = progName ? progName + 1 : tmp;

    PR_Init( PR_SYSTEM_THREAD, PR_PRIORITY_NORMAL, 1);

    /* please keep this list of options in ASCII collating sequence.
    ** numbers, then capital letters, then lower case, alphabetical. 
    */
    optstate = PL_CreateOptState(argc, argv, 
        "2:3BC:DEL:M:NP:RSTa:bc:d:e:f:g:hi:jk:lmn:op:qrst:uvw:xyz");
    while ((status = PL_GetNextOpt(optstate)) == PL_OPT_OK) {
	++optionsFound;
	switch(optstate->option) {
	case '2': fileName = optstate->value; break;

	case '3': disableSSL3 = PR_TRUE; break;

	case 'B': bypassPKCS11 = PR_TRUE; break;

        case 'C': if (optstate->value) NumSidCacheEntries = PORT_Atoi(optstate->value); break;

	case 'D': noDelay = PR_TRUE; break;
	case 'E': disableStepDown = PR_TRUE; break;

        case 'L':
            logStats = PR_TRUE;
	    if (optstate->value == NULL) {
	    	logPeriod = 30;
	    } else {
                logPeriod  = PORT_Atoi(optstate->value);
                if (logPeriod <= 0) logPeriod = 30;
	    }
            break;

	case 'M': 
	    maxProcs = PORT_Atoi(optstate->value); 
	    if (maxProcs < 1)         maxProcs = 1;
	    if (maxProcs > MAX_PROCS) maxProcs = MAX_PROCS;
	    break;

	case 'N': NoReuse = PR_TRUE; break;

	case 'R': disableRollBack = PR_TRUE; break;
        
        case 'S': disableSSL2 = PR_TRUE; break;

	case 'T': disableTLS = PR_TRUE; break;

	case 'a': if (virtServerNameIndex >= MAX_VIRT_SERVER_NAME_ARRAY_INDEX) {
                      Usage(progName);
                  }
                  virtServerNameArray[virtServerNameIndex++] =
                      PORT_Strdup(optstate->value); break;

	case 'b': bindOnly = PR_TRUE; break;

	case 'c': cipherString = PORT_Strdup(optstate->value); break;

	case 'd': dir = optstate->value; break;

#ifdef NSS_ENABLE_ECC
	case 'e': ecNickName = PORT_Strdup(optstate->value); break;
#endif /* NSS_ENABLE_ECC */

	case 'f':
            pwdata.source = PW_FROMFILE;
            pwdata.data = pwfile = PORT_Strdup(optstate->value);
            break;

        case 'g': 
            testBulk = PR_TRUE;
            testBulkTotal = PORT_Atoi(optstate->value);
            break;

	case 'h': Usage(progName); exit(0); break;

	case 'i': pidFile = optstate->value; break;

        case 'j': 
            initLoggingLayer(); 
            loggingLayer = PR_TRUE;
            break;

        case 'k': expectedHostNameVal = PORT_Strdup(optstate->value);
                  break;

        case 'l': useLocalThreads = PR_TRUE; break;

	case 'm': useModelSocket = PR_TRUE; break;

	case 'n': nickName = PORT_Strdup(optstate->value);
                  virtServerNameArray[0] = PORT_Strdup(optstate->value);
                  break;

	case 'P': certPrefix = PORT_Strdup(optstate->value); break;

	case 'o': MakeCertOK = 1; break;

	case 'p': port = PORT_Atoi(optstate->value); break;

	case 'q': testbypass = PR_TRUE; break;

	case 'r': ++requestCert; break;

	case 's': disableLocking = PR_TRUE; break;

	case 't':
	    maxThreads = PORT_Atoi(optstate->value);
	    if ( maxThreads > MAX_THREADS ) maxThreads = MAX_THREADS;
	    if ( maxThreads < MIN_THREADS ) maxThreads = MIN_THREADS;
	    break;

	case 'u': enableSessionTickets = PR_TRUE; break;

	case 'v': verbose++; break;

	case 'w':
            pwdata.source = PW_PLAINTEXT;
            pwdata.data = passwd = PORT_Strdup(optstate->value);
            break;

	case 'x': useExportPolicy = PR_TRUE; break;

	case 'y': debugCache = PR_TRUE; break;

	case 'z': enableCompression = PR_TRUE; break;

	default:
	case '?':
	    fprintf(stderr, "Unrecognized or bad option specified.\n");
	    fprintf(stderr, "Run '%s -h' for usage information.\n", progName);
	    exit(4);
	    break;
	}
    }
    PL_DestroyOptState(optstate);
    if (status == PL_OPT_BAD) {
	fprintf(stderr, "Unrecognized or bad option specified.\n");
	fprintf(stderr, "Run '%s -h' for usage information.\n", progName);
	exit(5);
    }
    if (!optionsFound) {
	Usage(progName);
	exit(51);
    } 

    /* The -b (bindOnly) option is only used by the ssl.sh test
     * script on Linux to determine whether a previous selfserv
     * process has fully died and freed the port.  (Bug 129701)
     */
    if (bindOnly) {
	listen_sock = getBoundListenSocket(port);
	if (!listen_sock) {
	    exit(1);
	}
        if (listen_sock) {
            PR_Close(listen_sock);
        }
	exit(0);
    }

    if ((nickName == NULL)
 #ifdef NSS_ENABLE_ECC
						&& (ecNickName == NULL)
 #endif
    ) {

	fprintf(stderr, "Required arg '-n' (rsa nickname) not supplied.\n");
	fprintf(stderr, "Run '%s -h' for usage information.\n", progName);
        exit(6);
    }

    if (port == 0) {
	fprintf(stderr, "Required argument 'port' must be non-zero value\n");
	exit(7);
    }

    if (NoReuse && maxProcs > 1) {
	fprintf(stderr, "-M and -N options are mutually exclusive.\n");
	exit(14);
    }

    if (pidFile) {
	FILE *tmpfile=fopen(pidFile,"w+");

	if (tmpfile) {
	    fprintf(tmpfile,"%d",getpid());
	    fclose(tmpfile);
	}
    }

    /* allocate and initialize app data for bulk encryption testing */
    if (testBulk) {
        testBulkBuf = PORT_Malloc(testBulkSize);
        if (testBulkBuf == NULL)
            errExit("Out of memory: testBulkBuf");
        for (i = 0; i < testBulkSize; i++)
            testBulkBuf[i] = i;
    }

    envString = getenv(envVarName);
    tmp = getenv("TMP");
    if (!tmp)
	tmp = getenv("TMPDIR");
    if (!tmp)
	tmp = getenv("TEMP");
    if (envString) {
	/* we're one of the children in a multi-process server. */
	listen_sock = PR_GetInheritedFD(inheritableSockName);
	if (!listen_sock)
	    errExit("PR_GetInheritedFD");
#ifndef WINNT
	/* we can't do this on NT because it breaks NSPR and
	PR_Accept will fail on the socket in the child process if
	the socket state is change to non inheritable
	It is however a security issue to leave it accessible,
	but it is OK for a test server such as selfserv.
	NSPR should fix it eventually . see bugzilla 101617
	and 102077
	*/
	prStatus = PR_SetFDInheritable(listen_sock, PR_FALSE);
	if (prStatus != PR_SUCCESS)
	    errExit("PR_SetFDInheritable");
#endif
	rv = SSL_InheritMPServerSIDCache(envString);
	if (rv != SECSuccess)
	    errExit("SSL_InheritMPServerSIDCache");
    	hasSidCache = PR_TRUE;
    } else if (maxProcs > 1) {
	/* we're going to be the parent in a multi-process server.  */
	listen_sock = getBoundListenSocket(port);
	rv = SSL_ConfigMPServerSIDCache(NumSidCacheEntries, 0, 0, tmp);
	if (rv != SECSuccess)
	    errExit("SSL_ConfigMPServerSIDCache");
    	hasSidCache = PR_TRUE;
	beAGoodParent(argc, argv, maxProcs, listen_sock);
	exit(99); /* should never get here */
    } else {
	/* we're an ordinary single process server. */
	listen_sock = getBoundListenSocket(port);
	prStatus = PR_SetFDInheritable(listen_sock, PR_FALSE);
	if (prStatus != PR_SUCCESS)
	    errExit("PR_SetFDInheritable");
	if (!NoReuse) {
	    rv = SSL_ConfigServerSessionIDCache(NumSidCacheEntries, 
	                                        0, 0, tmp);
	    if (rv != SECSuccess)
		errExit("SSL_ConfigServerSessionIDCache");
	    hasSidCache = PR_TRUE;
	}
    }

    lm = PR_NewLogModule("TestCase");

    if (fileName)
    	readBigFile(fileName);

    /* set our password function */
    PK11_SetPasswordFunc(SECU_GetModulePassword);

    /* Call the NSS initialization routines */
    rv = NSS_Initialize(dir, certPrefix, certPrefix, SECMOD_DB, NSS_INIT_READONLY);
    if (rv != SECSuccess) {
    	fputs("NSS_Init failed.\n", stderr);
		exit(8);
    }

    /* set the policy bits true for all the cipher suites. */
    if (useExportPolicy) {
	NSS_SetExportPolicy();
	if (disableStepDown) {
	    fputs("selfserv: -x and -E options may not be used together\n", 
	          stderr);
	    exit(98);
	}
    } else {
	NSS_SetDomesticPolicy();
	if (disableStepDown) {
	    rv = disableExportSSLCiphers();
	    if (rv != SECSuccess) {
		errExit("error disabling export ciphersuites ");
	    }
    	}
    }

    /* all the SSL2 and SSL3 cipher suites are enabled by default. */
    if (cipherString) {
    	char *cstringSaved = cipherString;
    	int ndx;

	/* disable all the ciphers, then enable the ones we want. */
	disableAllSSLCiphers();

	while (0 != (ndx = *cipherString++)) {
	    int  cipher;

	    if (ndx == ':') {
		int ctmp;

		cipher = 0;
		HEXCHAR_TO_INT(*cipherString, ctmp)
		cipher |= (ctmp << 12);
		cipherString++;
		HEXCHAR_TO_INT(*cipherString, ctmp)
		cipher |= (ctmp << 8);
		cipherString++;
		HEXCHAR_TO_INT(*cipherString, ctmp)
		cipher |= (ctmp << 4);
		cipherString++;
		HEXCHAR_TO_INT(*cipherString, ctmp)
		cipher |= ctmp;
		cipherString++;
	    } else {
		const int *cptr;

		if (! isalpha(ndx)) {
		    fprintf(stderr, 
			    "Non-alphabetic char in cipher string (-c arg).\n");
		    exit(9);
		}
		cptr = islower(ndx) ? ssl3CipherSuites : ssl2CipherSuites;
		for (ndx &= 0x1f; (cipher = *cptr++) != 0 && --ndx > 0; ) 
		    /* do nothing */;
	    }
	    if (cipher > 0) {
		SECStatus status;
		status = SSL_CipherPrefSetDefault(cipher, SSL_ALLOWED);
		if (status != SECSuccess) 
		    SECU_PrintError(progName, "SSL_CipherPrefSet()");
	    } else {
		fprintf(stderr, 
			"Invalid cipher specification (-c arg).\n");
		exit(9);
	    }
	}
	PORT_Free(cstringSaved);
    }

    if (testbypass) {
	const PRUint16 *cipherSuites = SSL_ImplementedCiphers;
	int             i            = SSL_NumImplementedCiphers;
	PRBool		enabled;

	for (i=0; i < SSL_NumImplementedCiphers; i++, cipherSuites++) {
	    if (SSL_CipherPrefGetDefault(*cipherSuites, &enabled) == SECSuccess
				    && enabled)
		savecipher(*cipherSuites);		    
	}
	protos = (disableTLS ? 0 : SSL_CBP_TLS1_0) +
		 (disableSSL3 ? 0 : SSL_CBP_SSL3);
    }

    if (nickName) {
	cert[kt_rsa] = PK11_FindCertFromNickname(nickName, &pwdata);
	if (cert[kt_rsa] == NULL) {
	    fprintf(stderr, "selfserv: Can't find certificate %s\n", nickName);
	    exit(10);
	}
	privKey[kt_rsa] = PK11_FindKeyByAnyCert(cert[kt_rsa], &pwdata);
	if (privKey[kt_rsa] == NULL) {
	    fprintf(stderr, "selfserv: Can't find Private Key for cert %s\n", 
	            nickName);
	    exit(11);
	}
	if (testbypass) {
	    PRBool bypassOK;
	    if (SSL_CanBypass(cert[kt_rsa], privKey[kt_rsa], protos, cipherlist, 
	                      nciphers, &bypassOK, &pwdata) != SECSuccess) {
		SECU_PrintError(progName, "Bypass test failed %s\n", nickName);
		exit(14);
	    }
	    fprintf(stderr, "selfserv: %s can%s bypass\n", nickName,
		    bypassOK ? "" : "not");
	}
    }
#ifdef NSS_ENABLE_ECC
    if (ecNickName) {
	cert[kt_ecdh] = PK11_FindCertFromNickname(ecNickName, &pwdata);
	if (cert[kt_ecdh] == NULL) {
	    fprintf(stderr, "selfserv: Can't find certificate %s\n",
		    ecNickName);
	    exit(13);
	}
	privKey[kt_ecdh] = PK11_FindKeyByAnyCert(cert[kt_ecdh], &pwdata);
	if (privKey[kt_ecdh] == NULL) {
	    fprintf(stderr, "selfserv: Can't find Private Key for cert %s\n", 
	            ecNickName);
	    exit(11);
	}	    
	if (testbypass) {
	    PRBool bypassOK;
	    if (SSL_CanBypass(cert[kt_ecdh], privKey[kt_ecdh], protos, cipherlist,
			      nciphers, &bypassOK, &pwdata) != SECSuccess) {
		SECU_PrintError(progName, "Bypass test failed %s\n", ecNickName);
		exit(15);
	    }
	    fprintf(stderr, "selfserv: %s can%s bypass\n", ecNickName,
		    bypassOK ? "" : "not");
       }
    }
#endif /* NSS_ENABLE_ECC */

    if (testbypass)
	goto cleanup;

/* allocate the array of thread slots, and launch the worker threads. */
    rv = launch_threads(&jobLoop, 0, 0, requestCert, useLocalThreads);

    if (rv == SECSuccess && logStats) {
	loggerThread = PR_CreateThread(PR_SYSTEM_THREAD, 
			logger, NULL, PR_PRIORITY_NORMAL, 
                        useLocalThreads ? PR_LOCAL_THREAD:PR_GLOBAL_THREAD,
                        PR_JOINABLE_THREAD, 0);
	if (loggerThread == NULL) {
	    fprintf(stderr, "selfserv: Failed to launch logger thread!\n");
	    rv = SECFailure;
	} 
    }

    if (rv == SECSuccess) {
	server_main(listen_sock, requestCert, privKey, cert,
                    expectedHostNameVal);
    }

    VLOG(("selfserv: server_thread: exiting"));

cleanup:
    printSSLStatistics();
    ssl3stats = SSL_GetStatistics();
    if (ssl3stats->hch_sid_ticket_parse_failures != 0) {
	fprintf(stderr, "selfserv: Experienced ticket parse failure(s)\n");
	exit(1);
    }
    if (failedToNegotiateName) {
        fprintf(stderr, "selfserv: Failed properly negotiate server name\n");
        exit(1);
    }

    {
	int i;
	for (i=0; i<kt_kea_size; i++) {
	    if (cert[i]) {
		CERT_DestroyCertificate(cert[i]);
	    }
	    if (privKey[i]) {
		SECKEY_DestroyPrivateKey(privKey[i]);
	    }
	}
        for (i = 0;virtServerNameArray[i];i++) {
            PORT_Free(virtServerNameArray[i]);
        }
    }

    if (debugCache) {
	nss_DumpCertificateCacheInfo();
    }
    if (nickName) {
        PORT_Free(nickName);
    }
    if (expectedHostNameVal) {
        PORT_Free(expectedHostNameVal);
    }
    if (passwd) {
        PORT_Free(passwd);
    }
    if (pwfile) {
        PORT_Free(pwfile);
    }
    if (certPrefix && certPrefix != emptyString) {                            
        PORT_Free(certPrefix);
    }
 #ifdef NSS_ENABLE_ECC
    if (ecNickName) {
        PORT_Free(ecNickName);
    }
 #endif

    if (hasSidCache) {
	SSL_ShutdownServerSessionIDCache();
    }
    if (NSS_Shutdown() != SECSuccess) {
	SECU_PrintError(progName, "NSS_Shutdown");
        if (loggerThread) {
            PR_JoinThread(loggerThread);
        }
	PR_Cleanup();
	exit(1);
    }
    PR_Cleanup();
    printf("selfserv: normal termination\n");
    return 0;
}