SECStatus
handle_connection(PRFileDesc *sslSocket, int connection)
{
int countRead = 0;
PRInt32 numBytes;
char *readBuffer;
readBuffer = PORT_Alloc(RD_BUF_SIZE);
if (!readBuffer) {
exitErr("PORT_Alloc");
}
/* compose the http request here. */
numBytes = PR_Write(sslSocket, requestString, strlen(requestString));
if (numBytes <= 0) {
errWarn("PR_Write");
PR_Free(readBuffer);
readBuffer = NULL;
return SECFailure;
}
/* read until EOF */
while (PR_TRUE) {
numBytes = PR_Read(sslSocket, readBuffer, RD_BUF_SIZE);
if (numBytes == 0) {
break; /* EOF */
}
if (numBytes < 0) {
errWarn("PR_Read");
break;
}
countRead += numBytes;
}
printSecurityInfo(stderr, sslSocket);
PR_Free(readBuffer);
readBuffer = NULL;
/* Caller closes the socket. */
fprintf(stderr,
"***** Connection %d read %d bytes total.\n",
connection, countRead);
return SECSuccess; /* success */
}
void
dumpCertChain(CERTCertificate *cert, SECCertUsage usage)
{
CERTCertificateList *certList;
unsigned int count = 0;
certList = CERT_CertChainFromCert(cert, usage, PR_TRUE);
if (certList == NULL) {
errWarn("CERT_CertChainFromCert");
return;
}
for(count = 0; count < (unsigned int)certList->len; count++) {
char certFileName[16];
PRFileDesc *cfd;
PR_snprintf(certFileName, sizeof certFileName, "cert.%03d",
count);
cfd = PR_Open(certFileName, PR_WRONLY|PR_CREATE_FILE|PR_TRUNCATE,
0664);
if (!cfd) {
PR_fprintf(PR_STDOUT,
"Error: couldn't save cert der in file '%s'\n",
certFileName);
} else {
PR_Write(cfd, certList->certs[count].data, certList->certs[count].len);
PR_Close(cfd);
PR_fprintf(PR_STDOUT, "Cert file %s was created.\n", certFileName);
}
}
CERT_DestroyCertificateList(certList);
}
void
exitErr(char *function)
{
errWarn(function);
/* Exit gracefully. */
/* ignoring return value of NSS_Shutdown as code exits with 1 anyway*/
(void) NSS_Shutdown();
PR_Cleanup();
exit(1);
}
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
client_main(unsigned short port,
int connections,
const char * hostName)
{
int i;
SECStatus secStatus;
PRStatus prStatus;
PRInt32 rv;
PRNetAddr addr;
PRHostEnt hostEntry;
char buffer[PR_NETDB_BUF_SIZE];
/* Setup network connection. */
prStatus = PR_GetHostByName(hostName, buffer, sizeof(buffer), &hostEntry);
if (prStatus != PR_SUCCESS) {
exitErr("PR_GetHostByName");
}
rv = PR_EnumerateHostEnt(0, &hostEntry, port, &addr);
if (rv < 0) {
exitErr("PR_EnumerateHostEnt");
}
secStatus = launch_thread(&threadMGR, do_connects, &addr, 1);
if (secStatus != SECSuccess) {
exitErr("launch_thread");
}
if (connections > 1) {
/* wait for the first connection to terminate, then launch the rest. */
reap_threads(&threadMGR);
/* Start up the connections */
for (i = 2; i <= connections; ++i) {
secStatus = launch_thread(&threadMGR, do_connects, &addr, i);
if (secStatus != SECSuccess) {
errWarn("launch_thread");
}
}
}
reap_threads(&threadMGR);
destroy_thread_data(&threadMGR);
}
void
disableAllSSLCiphers(void)
{
const PRUint16 *cipherSuites = SSL_GetImplementedCiphers();
int i = SSL_GetNumImplementedCiphers();
SECStatus rv;
/* disable all the SSL3 cipher suites */
while (--i >= 0) {
PRUint16 suite = cipherSuites[i];
rv = SSL_CipherPrefSetDefault(suite, PR_FALSE);
if (rv != SECSuccess) {
printf("SSL_CipherPrefSetDefault didn't like value 0x%04x (i = %d)\n",
suite, i);
errWarn("SSL_CipherPrefSetDefault");
exit(2);
}
}
}
static void
errExit(char * funcString)
{
errWarn(funcString);
exit(1);
}
PRFileDesc *
setupSSLSocket(PRNetAddr *addr)
{
PRFileDesc *tcpSocket;
PRFileDesc *sslSocket;
PRSocketOptionData socketOption;
PRStatus prStatus;
SECStatus secStatus;
tcpSocket = PR_NewTCPSocket();
if (tcpSocket == NULL) {
errWarn("PR_NewTCPSocket");
}
/* Make the socket blocking. */
socketOption.option = PR_SockOpt_Nonblocking;
socketOption.value.non_blocking = PR_FALSE;
prStatus = PR_SetSocketOption(tcpSocket, &socketOption);
if (prStatus != PR_SUCCESS) {
errWarn("PR_SetSocketOption");
goto loser;
}
/* Import the socket into the SSL layer. */
sslSocket = SSL_ImportFD(NULL, tcpSocket);
if (!sslSocket) {
errWarn("SSL_ImportFD");
goto loser;
}
/* Set configuration options. */
secStatus = SSL_OptionSet(sslSocket, SSL_SECURITY, PR_TRUE);
if (secStatus != SECSuccess) {
errWarn("SSL_OptionSet:SSL_SECURITY");
goto loser;
}
secStatus = SSL_OptionSet(sslSocket, SSL_HANDSHAKE_AS_CLIENT, PR_TRUE);
if (secStatus != SECSuccess) {
errWarn("SSL_OptionSet:SSL_HANDSHAKE_AS_CLIENT");
goto loser;
}
/* Set SSL callback routines. */
secStatus = SSL_GetClientAuthDataHook(sslSocket,
(SSLGetClientAuthData)myGetClientAuthData,
(void *)certNickname);
if (secStatus != SECSuccess) {
errWarn("SSL_GetClientAuthDataHook");
goto loser;
}
secStatus = SSL_AuthCertificateHook(sslSocket,
(SSLAuthCertificate)myAuthCertificate,
(void *)CERT_GetDefaultCertDB());
if (secStatus != SECSuccess) {
errWarn("SSL_AuthCertificateHook");
goto loser;
}
secStatus = SSL_BadCertHook(sslSocket,
(SSLBadCertHandler)myBadCertHandler, NULL);
if (secStatus != SECSuccess) {
errWarn("SSL_BadCertHook");
goto loser;
}
secStatus = SSL_HandshakeCallback(sslSocket,
myHandshakeCallback,
NULL);
if (secStatus != SECSuccess) {
errWarn("SSL_HandshakeCallback");
goto loser;
}
return sslSocket;
loser:
PR_Close(tcpSocket);
return NULL;
}
/* one copy of this function is launched in a separate thread for each
** connection to be made.
*/
SECStatus
do_connects(void *a, int connection)
{
PRNetAddr *addr = (PRNetAddr *)a;
PRFileDesc *sslSocket;
PRHostEnt hostEntry;
char buffer[PR_NETDB_BUF_SIZE];
PRStatus prStatus;
PRIntn hostenum;
PRInt32 ip;
SECStatus secStatus;
/* Set up SSL secure socket. */
sslSocket = setupSSLSocket(addr);
if (sslSocket == NULL) {
errWarn("setupSSLSocket");
return SECFailure;
}
secStatus = SSL_SetPKCS11PinArg(sslSocket, &pwdata);
if (secStatus != SECSuccess) {
errWarn("SSL_SetPKCS11PinArg");
return secStatus;
}
secStatus = SSL_SetURL(sslSocket, hostName);
if (secStatus != SECSuccess) {
errWarn("SSL_SetURL");
return secStatus;
}
/* Prepare and setup network connection. */
prStatus = PR_GetHostByName(hostName, buffer, sizeof(buffer), &hostEntry);
if (prStatus != PR_SUCCESS) {
errWarn("PR_GetHostByName");
return SECFailure;
}
hostenum = PR_EnumerateHostEnt(0, &hostEntry, port, addr);
if (hostenum == -1) {
errWarn("PR_EnumerateHostEnt");
return SECFailure;
}
ip = PR_ntohl(addr->inet.ip);
fprintf(stderr,
"Connecting to host %s (addr %d.%d.%d.%d) on port %d\n",
hostName, BYTE(3,ip), BYTE(2,ip), BYTE(1,ip),
BYTE(0,ip), PR_ntohs(addr->inet.port));
prStatus = PR_Connect(sslSocket, addr, PR_INTERVAL_NO_TIMEOUT);
if (prStatus != PR_SUCCESS) {
errWarn("PR_Connect");
return SECFailure;
}
/* Established SSL connection, ready to send data. */
#if 0
secStatus = SSL_ForceHandshake(sslSocket);
if (secStatus != SECSuccess) {
errWarn("SSL_ForceHandshake");
return secStatus;
}
#endif
secStatus = SSL_ResetHandshake(sslSocket, /* asServer */ PR_FALSE);
if (secStatus != SECSuccess) {
errWarn("SSL_ResetHandshake");
prStatus = PR_Close(sslSocket);
if (prStatus != PR_SUCCESS) {
errWarn("PR_Close");
}
return secStatus;
}
secStatus = handle_connection(sslSocket, connection);
if (secStatus != SECSuccess) {
/* error already printed out in handle_connection */
/* errWarn("handle_connection"); */
prStatus = PR_Close(sslSocket);
if (prStatus != PR_SUCCESS) {
errWarn("PR_Close");
}
return secStatus;
}
PR_Close(sslSocket);
return SECSuccess;
}
int
handle_connection(
PRFileDesc *tcp_sock,
PRFileDesc *model_sock,
int requestCert)
{
PRFileDesc *ssl_sock = NULL;
PRFileDesc *local_file_fd = NULL;
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 *getData = NULL; /* inplace conversion */
SECItem postData;
PRBool isOcspRequest = PR_FALSE;
PRBool isPost;
postData.data = NULL;
postData.len = 0;
pBuf = buf;
bufRem = sizeof buf;
VLOG(("httpserv: handle_connection: starting"));
opt.option = PR_SockOpt_Nonblocking;
opt.value.non_blocking = PR_FALSE;
PR_SetSocketOption(tcp_sock, &opt);
VLOG(("httpserv: handle_connection: starting\n"));
ssl_sock = tcp_sock;
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) {
const char *post;
const char *foundStr = NULL;
const char *tmp = NULL;
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;
}
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;
postData.data = (void *)(buf + reqLen);
tmp = "content-length: ";
foundStr = PL_strcasestr(buf, tmp);
if (foundStr) {
int expectedPostLen;
int havePostLen;
expectedPostLen = atoi(foundStr + strlen(tmp));
havePostLen = bufDat - reqLen;
if (havePostLen >= expectedPostLen) {
postData.len = expectedPostLen;
break;
}
} else {
/* use legacy hack */
/* It's a post, so look for the next and final CR/LF. */
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) {
PRBool isGetOrPost = PR_FALSE;
unsigned skipChars = 0;
isPost = PR_FALSE;
if (!strncmp(buf, getCmd, sizeof getCmd - 1)) {
isGetOrPost = PR_TRUE;
skipChars = 4;
} else if (!strncmp(buf, "POST ", 5)) {
isGetOrPost = PR_TRUE;
isPost = PR_TRUE;
skipChars = 5;
}
if (isGetOrPost) {
char *fnBegin = buf;
char *fnEnd;
char *fnstart = NULL;
PRFileInfo info;
fnBegin += skipChars;
fnEnd = strpbrk(fnBegin, " \r\n");
if (fnEnd) {
int fnLen = fnEnd - fnBegin;
if (fnLen < sizeof fileName) {
strncpy(fileName, fnBegin, fnLen);
fileName[fnLen] = 0; /* null terminate */
fnstart = fileName;
/* strip initial / because our root is the current directory*/
while (*fnstart && *fnstart == '/')
++fnstart;
}
}
if (fnstart) {
if (!strncmp(fnstart, "ocsp", 4)) {
if (isPost) {
if (postData.data) {
isOcspRequest = PR_TRUE;
}
} else {
if (!strncmp(fnstart, "ocsp/", 5)) {
isOcspRequest = PR_TRUE;
getData = fnstart + 5;
}
}
} else {
/* try to open the file named.
* If successful, then write it to the client.
*/
status = PR_GetFileInfo(fnstart, &info);
if (status == PR_SUCCESS &&
info.type == PR_FILE_FILE &&
info.size >= 0) {
local_file_fd = PR_Open(fnstart, PR_RDONLY, 0);
}
}
}
}
}
numIOVs = 0;
iovs[numIOVs].iov_base = (char *)outHeader;
iovs[numIOVs].iov_len = (sizeof(outHeader)) - 1;
numIOVs++;
if (isOcspRequest && caRevoInfos) {
CERTOCSPRequest *request = NULL;
PRBool failThisRequest = PR_FALSE;
PLArenaPool *arena = NULL;
if (ocspMethodsAllowed == ocspGetOnly && postData.len) {
failThisRequest = PR_TRUE;
} else if (ocspMethodsAllowed == ocspPostOnly && getData) {
failThisRequest = PR_TRUE;
} else if (ocspMethodsAllowed == ocspRandomGetFailure && getData) {
if (!(rand() % 2)) {
failThisRequest = PR_TRUE;
}
}
if (failThisRequest) {
PR_Write(ssl_sock, outBadRequestHeader, strlen(outBadRequestHeader));
break;
}
/* get is base64, post is binary.
* If we have base64, convert into the (empty) postData array.
*/
if (getData) {
if (urldecode_base64chars_inplace(getData) == SECSuccess) {
/* The code below can handle a NULL arena */
arena = PORT_NewArena(DER_DEFAULT_CHUNKSIZE);
NSSBase64_DecodeBuffer(arena, &postData, getData, strlen(getData));
}
}
if (postData.len) {
request = CERT_DecodeOCSPRequest(&postData);
}
if (arena) {
PORT_FreeArena(arena, PR_FALSE);
}
if (!request || !request->tbsRequest ||
!request->tbsRequest->requestList ||
!request->tbsRequest->requestList[0]) {
PORT_Sprintf(msgBuf, "Cannot decode OCSP request.\r\n");
iovs[numIOVs].iov_base = msgBuf;
iovs[numIOVs].iov_len = PORT_Strlen(msgBuf);
numIOVs++;
} else {
/* TODO: support more than one request entry */
CERTOCSPCertID *reqid = request->tbsRequest->requestList[0]->reqCert;
const caRevoInfo *revoInfo = NULL;
PRBool unknown = PR_FALSE;
PRBool revoked = PR_FALSE;
PRTime nextUpdate = 0;
PRTime revoDate = 0;
PRCList *caRevoIter;
caRevoIter = &caRevoInfos->link;
do {
CERTOCSPCertID *caid;
revoInfo = (caRevoInfo *)caRevoIter;
caid = revoInfo->id;
if (SECOID_CompareAlgorithmID(&reqid->hashAlgorithm,
&caid->hashAlgorithm) == SECEqual &&
SECITEM_CompareItem(&reqid->issuerNameHash,
&caid->issuerNameHash) == SECEqual &&
SECITEM_CompareItem(&reqid->issuerKeyHash,
&caid->issuerKeyHash) == SECEqual) {
break;
}
revoInfo = NULL;
caRevoIter = PR_NEXT_LINK(caRevoIter);
} while (caRevoIter != &caRevoInfos->link);
if (!revoInfo) {
unknown = PR_TRUE;
revoInfo = caRevoInfos;
} else {
CERTCrl *crl = &revoInfo->crl->crl;
CERTCrlEntry *entry = NULL;
DER_DecodeTimeChoice(&nextUpdate, &crl->nextUpdate);
if (crl->entries) {
int iv = 0;
/* assign, not compare */
while ((entry = crl->entries[iv++])) {
if (SECITEM_CompareItem(&reqid->serialNumber,
&entry->serialNumber) == SECEqual) {
break;
}
}
}
if (entry) {
/* revoked status response */
revoked = PR_TRUE;
DER_DecodeTimeChoice(&revoDate, &entry->revocationDate);
} else {
/* else good status response */
if (!isPost && ocspMethodsAllowed == ocspGetUnknown) {
unknown = PR_TRUE;
nextUpdate = PR_Now() + (PRTime)60 * 60 * 24 * PR_USEC_PER_SEC; /*tomorrow*/
revoDate = PR_Now() - (PRTime)60 * 60 * 24 * PR_USEC_PER_SEC; /*yesterday*/
}
}
}
{
PRTime now = PR_Now();
PLArenaPool *arena = NULL;
CERTOCSPSingleResponse *sr;
CERTOCSPSingleResponse **singleResponses;
SECItem *ocspResponse;
arena = PORT_NewArena(DER_DEFAULT_CHUNKSIZE);
if (unknown) {
sr = CERT_CreateOCSPSingleResponseUnknown(arena, reqid, now,
&nextUpdate);
} else if (revoked) {
sr = CERT_CreateOCSPSingleResponseRevoked(arena, reqid, now,
&nextUpdate, revoDate, NULL);
} else {
sr = CERT_CreateOCSPSingleResponseGood(arena, reqid, now,
&nextUpdate);
}
/* meaning of value 2: one entry + one end marker */
singleResponses = PORT_ArenaNewArray(arena, CERTOCSPSingleResponse *, 2);
singleResponses[0] = sr;
singleResponses[1] = NULL;
ocspResponse = CERT_CreateEncodedOCSPSuccessResponse(arena,
revoInfo->cert, ocspResponderID_byName, now,
singleResponses, &pwdata);
if (!ocspResponse) {
PORT_Sprintf(msgBuf, "Failed to encode response\r\n");
iovs[numIOVs].iov_base = msgBuf;
iovs[numIOVs].iov_len = PORT_Strlen(msgBuf);
numIOVs++;
} else {
PR_Write(ssl_sock, outOcspHeader, strlen(outOcspHeader));
PR_Write(ssl_sock, ocspResponse->data, ocspResponse->len);
PORT_FreeArena(arena, PR_FALSE);
}
}
CERT_DestroyOCSPRequest(request);
break;
}
} else if (local_file_fd) {
PRInt32 bytes;
int errLen;
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,
"httpserv: 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++;
} 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++;
}
rv = PR_Writev(ssl_sock, iovs, numIOVs, PR_INTERVAL_NO_TIMEOUT);
if (rv < 0) {
errWarn("PR_Writev");
break;
}
} while (0);
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"));
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 reacquire 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;
}
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];
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"));
ssl_sock = tcp_sock;
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;
}
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 *fnstart;
strncpy(fileName, fnBegin, fnLen);
fileName[fnLen] = 0; /* null terminate */
fnstart = fileName;
/* strip initial / because our root is the current directory*/
while (*fnstart && *fnstart=='/')
++fnstart;
status = PR_GetFileInfo(fnstart, &info);
if (status == PR_SUCCESS &&
info.type == PR_FILE_FILE &&
info.size >= 0 ) {
local_file_fd = PR_Open(fnstart, PR_RDONLY, 0);
}
}
}
}
numIOVs = 0;
iovs[numIOVs].iov_base = (char *)outHeader;
iovs[numIOVs].iov_len = (sizeof(outHeader)) - 1;
numIOVs++;
if (local_file_fd) {
PRInt32 bytes;
int errLen;
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++;
} 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;
}
} 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 */
}
int configure_loopback_interface() {
struct nl_sock *sock = NULL;
struct rtnl_addr *addr = NULL;
struct nl_addr* lo_addr = NULL;
struct nl_cache *cache = NULL;
struct rtnl_link *link = NULL, *link2 = NULL;
int err, nlflags = NLM_F_CREATE, ret = 0;
if(!want_cap(CAP_NET_ADMIN)) {
errWarn("Cannot set the CAP_NET_ADMIN effective capability");
return -1;
}
sock = nl_socket_alloc();
if(sock == NULL) {
errWarn("nl_socket_alloc");
return -1;
}
if((err = nl_connect(sock, NETLINK_ROUTE)) < 0) {
fprintf(stderr, "Unable to connect to netlink: %s\n", nl_geterror(err));
ret = -1;
goto out2;
}
if(rtnl_link_alloc_cache(sock, AF_UNSPEC, &cache) < 0) {
ret = -1;
goto out;
}
link = rtnl_link_get_by_name(cache, "lo");
if (link == NULL) {
ret = -1;
goto out;
}
addr = rtnl_addr_alloc();
if(addr == NULL) {
ret = -1;
goto out;
}
rtnl_addr_set_link(addr, link);
rtnl_addr_set_family(addr, AF_INET);
if((err = nl_addr_parse("127.0.0.1/8", AF_INET, &lo_addr)) < 0) {
fprintf(stderr, "Unable to parse address: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
if((err = rtnl_addr_set_local(addr, lo_addr)) < 0) {
fprintf(stderr, "Unable to set address: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
nl_addr_put(lo_addr);
lo_addr = NULL;
if ((err = rtnl_addr_add(sock, addr, nlflags)) < 0) {
fprintf(stderr, "Unable to add address: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
rtnl_addr_set_family(addr, AF_INET6);
if((err = nl_addr_parse("::1/128", AF_INET6, &lo_addr)) < 0) {
fprintf(stderr, "Unable to parse address: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
if((err = rtnl_addr_set_local(addr, lo_addr)) < 0) {
fprintf(stderr, "Unable to set address: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
nl_addr_put(lo_addr);
lo_addr = NULL;
if ((err = rtnl_addr_add(sock, addr, nlflags)) < 0) {
fprintf(stderr, "Unable to add address: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
link2 = rtnl_link_alloc();
if(link2 == NULL) {
ret = -1;
goto out;
}
rtnl_link_set_flags(link2, IFF_UP);
if((err = rtnl_link_change(sock, link, link2, 0)) < 0) {
fprintf(stderr, "Unable to change link: %s\n", nl_geterror(err));
ret = -1;
goto out;
}
out:
if(lo_addr!=NULL)
nl_addr_put(lo_addr);
if(link2!=NULL)
rtnl_link_put(link2);
if(link!=NULL)
rtnl_link_put(link);
if(cache!=NULL)
nl_cache_put(cache);
if(addr!=NULL)
rtnl_addr_put(addr);
nl_close(sock);
out2:
nl_socket_free(sock);
drop_caps();
return ret;
}
/* Function: SECStatus myAuthCertificate()
*
* Purpose: This function is our custom certificate authentication handler.
*
* Note: This implementation is essentially the same as the default
* SSL_AuthCertificate().
*/
SECStatus
myAuthCertificate(void *arg, PRFileDesc *socket,
PRBool checksig, PRBool isServer)
{
SECCertificateUsage certUsage;
CERTCertificate * cert;
void * pinArg;
char * hostName;
SECStatus secStatus;
if (!arg || !socket) {
errWarn("myAuthCertificate");
return SECFailure;
}
/* Define how the cert is being used based upon the isServer flag. */
certUsage = isServer ? certificateUsageSSLClient : certificateUsageSSLServer;
cert = SSL_PeerCertificate(socket);
pinArg = SSL_RevealPinArg(socket);
if (dumpChain == PR_TRUE) {
dumpCertChain(cert, certUsage);
}
secStatus = CERT_VerifyCertificateNow((CERTCertDBHandle *)arg,
cert,
checksig,
certUsage,
pinArg,
NULL);
/* If this is a server, we're finished. */
if (isServer || secStatus != SECSuccess) {
SECU_printCertProblems(stderr, (CERTCertDBHandle *)arg, cert,
checksig, certUsage, pinArg, PR_FALSE);
CERT_DestroyCertificate(cert);
return secStatus;
}
/* Certificate is OK. Since this is the client side of an SSL
* connection, we need to verify that the name field in the cert
* matches the desired hostname. This is our defense against
* man-in-the-middle attacks.
*/
/* SSL_RevealURL returns a hostName, not an URL. */
hostName = SSL_RevealURL(socket);
if (hostName && hostName[0]) {
secStatus = CERT_VerifyCertName(cert, hostName);
} else {
PR_SetError(SSL_ERROR_BAD_CERT_DOMAIN, 0);
secStatus = SECFailure;
}
if (hostName)
PR_Free(hostName);
CERT_DestroyCertificate(cert);
return secStatus;
}
