bool XMLSceneryReader::openFile(const char* fileName) {
bool result = false;
XercesDOMParser* parser = new XercesDOMParser;
parser->setValidationScheme(XercesDOMParser::Val_Never);
parser->setDoSchema(false);
parser->setLoadExternalDTD(false);
parser->setErrorHandler(new XMLSceneryErrorHandler);
parser->parse(LocalFileInputSource(XMLString::transcode(fileName)));
if(!parser->getErrorCount()) {
m_root = parser->getDocument()->getFirstChild();
m_node = m_root;
result = true;
}
return result;
}
int evaluate(int argc, char ** argv) {
char * filename = NULL;
char * outfile = NULL;
unsigned char * keyStr = NULL;
bool doDecrypt = true;
bool errorsOccured = false;
bool doDecryptElement = false;
bool useInteropResolver = false;
bool encryptFileAsData = false;
bool parseXMLInput = true;
bool doXMLOutput = false;
bool isXKMSKey = false;
XSECCryptoKey * kek = NULL;
XSECCryptoKey * key = NULL;
int keyLen = 0;
encryptionMethod kekAlg = ENCRYPT_NONE;
encryptionMethod keyAlg = ENCRYPT_NONE;
DOMDocument *doc;
unsigned char keyBuf[24];
XMLFormatTarget *formatTarget ;
#if defined(_WIN32) && defined (XSEC_HAVE_WINCAPI)
HCRYPTPROV win32DSSCSP = 0; // Crypto Providers
HCRYPTPROV win32RSACSP = 0;
CryptAcquireContext(&win32DSSCSP, NULL, NULL, PROV_DSS, CRYPT_VERIFYCONTEXT);
CryptAcquireContext(&win32RSACSP, NULL, NULL, PROV_RSA_FULL, CRYPT_VERIFYCONTEXT);
#endif
if (argc < 2) {
printUsage();
return 2;
}
// Run through parameters
int paramCount = 1;
while (paramCount < argc - 1) {
if (_stricmp(argv[paramCount], "--decrypt-element") == 0 || _stricmp(argv[paramCount], "-de") == 0) {
paramCount++;
doDecrypt = true;
doDecryptElement = true;
doXMLOutput = true;
parseXMLInput = true;
}
else if (_stricmp(argv[paramCount], "--interop") == 0 || _stricmp(argv[paramCount], "-i") == 0) {
// Use the interop key resolver
useInteropResolver = true;
paramCount++;
}
else if (_stricmp(argv[paramCount], "--encrypt-file") == 0 || _stricmp(argv[paramCount], "-ef") == 0) {
// Use this file as the input
doDecrypt = false;
encryptFileAsData = true;
doXMLOutput = true;
parseXMLInput = false;
paramCount++;
}
else if (_stricmp(argv[paramCount], "--encrypt-xml") == 0 || _stricmp(argv[paramCount], "-ex") == 0) {
// Us this file as an XML input file
doDecrypt = false;
encryptFileAsData = false;
doXMLOutput = true;
parseXMLInput = true;
paramCount++;
}
else if (_stricmp(argv[paramCount], "--out-file") == 0 || _stricmp(argv[paramCount], "-o") == 0) {
if (paramCount +2 >= argc) {
printUsage();
return 1;
}
paramCount++;
outfile = argv[paramCount];
paramCount++;
}
else if (_stricmp(argv[paramCount], "--xkms") == 0 || _stricmp(argv[paramCount], "-x") == 0) {
paramCount++;
isXKMSKey = true;
}
#if defined (XSEC_HAVE_WINCAPI)
else if (_stricmp(argv[paramCount], "--wincapi") == 0 || _stricmp(argv[paramCount], "-w") == 0) {
// Use the interop key resolver
WinCAPICryptoProvider * cp = new WinCAPICryptoProvider();
XSECPlatformUtils::SetCryptoProvider(cp);
paramCount++;
}
#endif
#if defined (XSEC_HAVE_NSS)
else if (_stricmp(argv[paramCount], "--nss") == 0 || _stricmp(argv[paramCount], "-n") == 0) {
// NSS Crypto Provider
NSSCryptoProvider * cp = new NSSCryptoProvider();
XSECPlatformUtils::SetCryptoProvider(cp);
paramCount++;
}
#endif
else if (_stricmp(argv[paramCount], "--key") == 0 || _stricmp(argv[paramCount], "-k") == 0) {
// Have a key!
paramCount++;
bool isKEK = false;
XSECCryptoSymmetricKey::SymmetricKeyType loadKeyAs =
XSECCryptoSymmetricKey::KEY_NONE;
if (_stricmp(argv[paramCount], "kek") == 0) {
isKEK = true;
paramCount++;
if (paramCount >= argc) {
printUsage();
return 2;
}
}
if (_stricmp(argv[paramCount], "3DES") == 0 ||
_stricmp(argv[paramCount], "AES128") == 0 ||
_stricmp(argv[paramCount], "AES192") == 0 ||
_stricmp(argv[paramCount], "AES256") == 0 ||
_stricmp(argv[paramCount], "AES128-GCM") == 0 ||
_stricmp(argv[paramCount], "AES192-GCM") == 0 ||
_stricmp(argv[paramCount], "AES256-GCM") == 0) {
if (paramCount +2 >= argc) {
printUsage();
return 2;
}
switch(argv[paramCount][4]) {
case '\0' :
keyLen = 24;
loadKeyAs = XSECCryptoSymmetricKey::KEY_3DES_192;
keyAlg = ENCRYPT_3DES_CBC;
break;
case '2' :
keyLen = 16;
loadKeyAs = XSECCryptoSymmetricKey::KEY_AES_128;
if (isKEK) {
kekAlg = ENCRYPT_KW_AES128;
}
else if (strlen(argv[paramCount]) == 6) {
keyAlg = ENCRYPT_AES128_CBC;
}
else {
keyAlg = ENCRYPT_AES128_GCM;
}
break;
case '9' :
keyLen = 24;
loadKeyAs = XSECCryptoSymmetricKey::KEY_AES_192;
if (isKEK) {
kekAlg = ENCRYPT_KW_AES192;
}
else if (strlen(argv[paramCount]) == 6) {
keyAlg = ENCRYPT_AES192_CBC;
}
else {
keyAlg = ENCRYPT_AES192_GCM;
}
break;
case '5' :
keyLen = 32;
loadKeyAs = XSECCryptoSymmetricKey::KEY_AES_256;
if (isKEK) {
kekAlg = ENCRYPT_KW_AES256;
}
else if (strlen(argv[paramCount]) == 6) {
keyAlg = ENCRYPT_AES256_CBC;
}
else {
keyAlg = ENCRYPT_AES256_GCM;
}
break;
}
paramCount++;
unsigned char keyStr[64];
if (strlen(argv[paramCount]) > 64) {
cerr << "Key string too long\n";
return 2;
}
XSECCryptoSymmetricKey * sk =
XSECPlatformUtils::g_cryptoProvider->keySymmetric(loadKeyAs);
if (isXKMSKey) {
unsigned char kbuf[XSEC_MAX_HASH_SIZE];
CalculateXKMSKEK((unsigned char *) argv[paramCount], (int) strlen(argv[paramCount]), kbuf, XSEC_MAX_HASH_SIZE);
sk->setKey(kbuf, keyLen);
}
else {
memset(keyStr, 0, 64);
strcpy((char *) keyStr, argv[paramCount]);
sk->setKey(keyStr, keyLen);
}
paramCount++;
if (isKEK)
kek = sk;
else
key = sk;
}
#if defined (XSEC_HAVE_OPENSSL)
else if (_stricmp(argv[paramCount], "RSA") == 0) {
// RSA private key file
if (paramCount + 3 >= argc) {
printUsage();
return 2;
}
if (!isKEK) {
cerr << "RSA private keys may only be KEKs\n";
return 2;
}
BIO * bioKey;
if ((bioKey = BIO_new(BIO_s_file())) == NULL) {
cerr << "Error opening private key file\n\n";
return 1;
}
if (BIO_read_filename(bioKey, argv[paramCount + 1]) <= 0) {
cerr << "Error opening private key file\n\n";
return 1;
}
EVP_PKEY * pkey;
pkey = PEM_read_bio_PrivateKey(bioKey,NULL,NULL,argv[paramCount + 2]);
if (pkey == NULL) {
cerr << "Error loading private key\n\n";
return 1;
}
kek = new OpenSSLCryptoKeyRSA(pkey);
kekAlg = ENCRYPT_RSA_15;
EVP_PKEY_free(pkey);
BIO_free(bioKey);
paramCount += 3;
}
else if (_stricmp(argv[paramCount], "X509") == 0) {
// X509 cert used to load an encrypting key
if (paramCount + 2 >= argc) {
printUsage();
exit (1);
}
if (!isKEK) {
cerr << "X509 private keys may only be KEKs\n";
return 2;
}
// Load the encrypting key
// For now just read a particular file
BIO * bioX509;
if ((bioX509 = BIO_new(BIO_s_file())) == NULL) {
cerr << "Error opening file\n\n";
exit (1);
}
if (BIO_read_filename(bioX509, argv[paramCount + 1]) <= 0) {
cerr << "Error opening X509 Certificate " << argv[paramCount + 1] << "\n\n";
exit (1);
}
X509 * x
;
x = PEM_read_bio_X509_AUX(bioX509,NULL,NULL,NULL);
if (x == NULL) {
BIO * bio_err;
if ((bio_err=BIO_new(BIO_s_file())) != NULL)
BIO_set_fp(bio_err,stderr,BIO_NOCLOSE|BIO_FP_TEXT);
cerr << "Error loading certificate key\n\n";
ERR_print_errors(bio_err);
BIO_free(bio_err);
exit (1);
}
// Now load the key
EVP_PKEY *pkey;
pkey = X509_get_pubkey(x);
if (pkey == NULL || pkey->type != EVP_PKEY_RSA) {
cerr << "Error extracting RSA key from certificate" << endl;
}
kek = new OpenSSLCryptoKeyRSA(pkey);
kekAlg = ENCRYPT_RSA_15;
// Clean up
EVP_PKEY_free (pkey);
X509_free(x);
BIO_free(bioX509);
paramCount += 2;
} /* argv[1] = "--x509cert" */
#endif /* XSEC_HAVE_OPENSSL */
else {
printUsage();
return 2;
}
}
else {
cerr << "Unknown option: " << argv[paramCount] << endl;
printUsage();
return 2;
}
}
if (paramCount >= argc) {
printUsage();
return 2;
}
if (outfile != NULL) {
formatTarget = new LocalFileFormatTarget(outfile);
}
else {
formatTarget = new StdOutFormatTarget();
}
filename = argv[paramCount];
if (parseXMLInput) {
XercesDOMParser * parser = new XercesDOMParser;
Janitor<XercesDOMParser> j_parser(parser);
parser->setDoNamespaces(true);
parser->setCreateEntityReferenceNodes(true);
// Now parse out file
xsecsize_t errorCount = 0;
try
{
parser->parse(filename);
errorCount = parser->getErrorCount();
if (errorCount > 0)
errorsOccured = true;
}
catch (const XMLException& e)
{
cerr << "An error occured during parsing\n Message: "
<< e.getMessage() << endl;
errorsOccured = true;
}
catch (const DOMException& e)
{
cerr << "A DOM error occured during parsing\n DOMException code: "
<< e.code << endl;
errorsOccured = true;
}
if (errorsOccured) {
cout << "Errors during parse" << endl;
return (2);
}
/*
Now that we have the parsed file, get the DOM document and start looking at it
*/
doc = parser->adoptDocument();
}
else {
// Create an empty document
XMLCh tempStr[100];
XMLString::transcode("Core", tempStr, 99);
DOMImplementation *impl = DOMImplementationRegistry::getDOMImplementation(tempStr);
doc = impl->createDocument(
0, // root element namespace URI.
MAKE_UNICODE_STRING("ADoc"), // root element name
NULL);// DOMDocumentType()); // document type object (DTD).
}
XSECProvider prov;
XENCCipher * cipher = prov.newCipher(doc);
if (kek != NULL)
cipher->setKEK(kek);
if (key != NULL)
cipher->setKey(key);
try {
if (doDecrypt) {
if (useInteropResolver == true) {
// Map out base path of the file
char path[_MAX_PATH];
char baseURI[(_MAX_PATH * 2) + 10];
getcwd(path, _MAX_PATH);
strcpy(baseURI, "file:///");
// Ugly and nasty but quick
if (filename[0] != '\\' && filename[0] != '/' && filename[1] != ':') {
strcat(baseURI, path);
strcat(baseURI, "/");
} else if (path[1] == ':') {
path[2] = '\0';
strcat(baseURI, path);
}
strcat(baseURI, filename);
// Find any ':' and "\" characters
int lastSlash = 0;
for (unsigned int i = 8; i < strlen(baseURI); ++i) {
if (baseURI[i] == '\\') {
lastSlash = i;
baseURI[i] = '/';
}
else if (baseURI[i] == '/')
lastSlash = i;
}
// The last "\\" must prefix the filename
baseURI[lastSlash + 1] = '\0';
XMLCh * uriT = XMLString::transcode(baseURI);
XencInteropResolver ires(doc, &(uriT[8]));
XSEC_RELEASE_XMLCH(uriT);
cipher->setKeyInfoResolver(&ires);
}
// Find the EncryptedData node
DOMNode * n = findXENCNode(doc, "EncryptedData");
if (doDecryptElement) {
while (n != NULL) {
// decrypt
cipher->decryptElement(static_cast<DOMElement *>(n));
// Find the next EncryptedData node
n = findXENCNode(doc, "EncryptedData");
}
}
else {
XSECBinTXFMInputStream * bis = cipher->decryptToBinInputStream(static_cast<DOMElement *>(n));
Janitor<XSECBinTXFMInputStream> j_bis(bis);
XMLByte buf[1024];
xsecsize_t read = bis->readBytes(buf, 1023);
while (read > 0) {
formatTarget->writeChars(buf, read, NULL);
read = bis->readBytes(buf, 1023);
}
}
}
else {
XENCEncryptedData *xenc = NULL;
// Encrypting
if (kek != NULL && key == NULL) {
XSECPlatformUtils::g_cryptoProvider->getRandom(keyBuf, 24);
XSECCryptoSymmetricKey * k =
XSECPlatformUtils::g_cryptoProvider->keySymmetric(XSECCryptoSymmetricKey::KEY_3DES_192);
k->setKey(keyBuf, 24);
cipher->setKey(k);
keyAlg = ENCRYPT_3DES_CBC;
keyStr = keyBuf;
keyLen = 24;
}
if (encryptFileAsData) {
// Create a BinInputStream
#if defined(XSEC_XERCES_REQUIRES_MEMMGR)
BinFileInputStream * is = new BinFileInputStream(filename, XMLPlatformUtils::fgMemoryManager);
#else
BinFileInputStream * is = new BinFileInputStream(filename);
#endif
xenc = cipher->encryptBinInputStream(is, keyAlg);
// Replace the document element
DOMElement * elt = doc->getDocumentElement();
doc->replaceChild(xenc->getElement(), elt);
elt->release();
}
else {
// Document encryption
cipher->encryptElement(doc->getDocumentElement(), keyAlg);
}
// Do we encrypt a created key?
if (kek != NULL && xenc != NULL) {
XENCEncryptedKey *xkey = cipher->encryptKey(keyStr, keyLen, kekAlg);
// Add to the EncryptedData
xenc->appendEncryptedKey(xkey);
}
}
if (doXMLOutput) {
// Output the result
XMLCh core[] = {
XERCES_CPP_NAMESPACE_QUALIFIER chLatin_C,
XERCES_CPP_NAMESPACE_QUALIFIER chLatin_o,
XERCES_CPP_NAMESPACE_QUALIFIER chLatin_r,
XERCES_CPP_NAMESPACE_QUALIFIER chLatin_e,
XERCES_CPP_NAMESPACE_QUALIFIER chNull
};
DOMImplementation *impl = DOMImplementationRegistry::getDOMImplementation(core);
#if defined (XSEC_XERCES_DOMLSSERIALIZER)
// DOM L3 version as per Xerces 3.0 API
DOMLSSerializer *theSerializer = ((DOMImplementationLS*)impl)->createLSSerializer();
Janitor<DOMLSSerializer> j_theSerializer(theSerializer);
// Get the config so we can set up pretty printing
DOMConfiguration *dc = theSerializer->getDomConfig();
dc->setParameter(XMLUni::fgDOMWRTFormatPrettyPrint, false);
// Now create an output object to format to UTF-8
DOMLSOutput *theOutput = ((DOMImplementationLS*)impl)->createLSOutput();
Janitor<DOMLSOutput> j_theOutput(theOutput);
theOutput->setEncoding(MAKE_UNICODE_STRING("UTF-8"));
theOutput->setByteStream(formatTarget);
theSerializer->write(doc, theOutput);
#else
DOMWriter *theSerializer = ((DOMImplementationLS*)impl)->createDOMWriter();
Janitor<DOMWriter> j_theSerializer(theSerializer);
theSerializer->setEncoding(MAKE_UNICODE_STRING("UTF-8"));
if (theSerializer->canSetFeature(XMLUni::fgDOMWRTFormatPrettyPrint, false))
theSerializer->setFeature(XMLUni::fgDOMWRTFormatPrettyPrint, false);
theSerializer->writeNode(formatTarget, *doc);
#endif
cout << endl;
}
}
catch (XSECException &e) {
char * msg = XMLString::transcode(e.getMsg());
cerr << "An error occured during encryption/decryption operation\n Message: "
<< msg << endl;
XSEC_RELEASE_XMLCH(msg);
errorsOccured = true;
if (formatTarget != NULL)
delete formatTarget;
doc->release();
return 2;
}
catch (XSECCryptoException &e) {
cerr << "An error occured during encryption/decryption operation\n Message: "
<< e.getMsg() << endl;
errorsOccured = true;
if (formatTarget != NULL)
delete formatTarget;
doc->release();
#if defined (XSEC_HAVE_OPENSSL)
ERR_load_crypto_strings();
BIO * bio_err;
if ((bio_err=BIO_new(BIO_s_file())) != NULL)
BIO_set_fp(bio_err,stderr,BIO_NOCLOSE|BIO_FP_TEXT);
ERR_print_errors(bio_err);
#endif
return 2;
}
if (formatTarget != NULL)
delete formatTarget;
doc->release();
return 0;
}
int main(int argc, char **argv) {
XSECCryptoKey * key = NULL;
DSIGKeyInfoX509 * keyInfoX509 = NULL;
OpenSSLCryptoX509 * certs[128];
int certCount = 0;
int paramCount;
bool clearKeyInfo = false;
// Initialise the XML system
try {
XMLPlatformUtils::Initialize();
#ifndef XSEC_NO_XALAN
XPathEvaluator::initialize();
XalanTransformer::initialize();
#endif
XSECPlatformUtils::Initialise();
}
catch (const XMLException &e) {
cerr << "Error during initialisation of Xerces" << endl;
cerr << "Error Message = : "
<< e.getMessage() << endl;
}
// Initialise OpenSSL
ERR_load_crypto_strings();
BIO * bio_err;
if ((bio_err=BIO_new(BIO_s_file())) != NULL)
BIO_set_fp(bio_err,stderr,BIO_NOCLOSE|BIO_FP_TEXT);
if (argc < 2) {
printUsage();
exit (1);
}
paramCount = 1;
while (paramCount < argc - 1) {
// Run through all parameters
if (stricmp(argv[paramCount], "--dsakey") == 0 || stricmp(argv[paramCount], "-d") == 0 ||
stricmp(argv[paramCount], "--rsakey") == 0 || stricmp(argv[paramCount], "-r") == 0) {
// DSA or RSA Key
if (paramCount + 3 >= argc) {
printUsage();
exit (1);
}
if (key != 0) {
cerr << "\nError loading RSA or DSA key - another key already loaded\n\n";
printUsage();
exit(1);
}
// Load the signing key
// For now just read a particular file
BIO * bioKey;
if ((bioKey = BIO_new(BIO_s_file())) == NULL) {
cerr << "Error opening private key file\n\n";
exit (1);
}
if (BIO_read_filename(bioKey, argv[paramCount + 1]) <= 0) {
cerr << "Error opening private key file\n\n";
exit (1);
}
EVP_PKEY * pkey;
pkey = PEM_read_bio_PrivateKey(bioKey,NULL,NULL,argv[paramCount + 2]);
if (pkey == NULL) {
cerr << "Error loading private key\n\n";
ERR_print_errors(bio_err);
exit (1);
}
if (stricmp(argv[paramCount], "--dsakey") == 0 || stricmp(argv[paramCount], "-d") == 0) {
// Check type is correct
if (pkey->type != EVP_PKEY_DSA) {
cerr << "DSA Key requested, but OpenSSL loaded something else\n";
exit (1);
}
// Create the XSEC OpenSSL interface
key = new OpenSSLCryptoKeyDSA(pkey);
}
else {
if (pkey->type != EVP_PKEY_RSA) {
cerr << "RSA Key requested, but OpenSSL loaded something else\n";
exit (1);
}
key = new OpenSSLCryptoKeyRSA(pkey);
}
EVP_PKEY_free(pkey);
BIO_free(bioKey);
paramCount += 3;
} /* argv[1] = "dsa/rsa" */
else if (stricmp(argv[paramCount], "--x509cert") == 0 || stricmp(argv[paramCount], "-x") == 0) {
// X509Data keyInfo
if (paramCount + 2 >= argc) {
printUsage();
exit (1);
}
// Load the signing key
// For now just read a particular file
BIO * bioX509;
if ((bioX509 = BIO_new(BIO_s_file())) == NULL) {
cerr << "Error opening file\n\n";
exit (1);
}
if (BIO_read_filename(bioX509, argv[paramCount + 1]) <= 0) {
cerr << "Error opening X509 Certificate " << argv[paramCount + 1] << "\n\n";
exit (1);
}
X509 * x
;
x = PEM_read_bio_X509_AUX(bioX509,NULL,NULL,NULL);
if (x == NULL) {
cerr << "Error loading certificate key\n\n";
ERR_print_errors(bio_err);
exit (1);
}
// Create the XSEC OpenSSL interface - used only to translate to Base64
certs[certCount++] = new OpenSSLCryptoX509(x);
X509_free(x);
BIO_free(bioX509);
paramCount += 2;
} /* argv[1] = "--x509cert" */
else if (stricmp(argv[paramCount], "--hmackey") == 0 || stricmp(argv[paramCount], "-h") == 0) {
OpenSSLCryptoKeyHMAC * hmacKey = new OpenSSLCryptoKeyHMAC();
hmacKey->setKey((unsigned char *) argv[paramCount + 1], strlen(argv[paramCount + 1]));
key = hmacKey;
paramCount += 2;
}
else if (stricmp(argv[paramCount], "--clearkeys") == 0 || stricmp(argv[paramCount], "-c") == 0) {
clearKeyInfo = true;
paramCount += 1;
}
else {
printUsage();
exit(1);
}
}
// Create and set up the parser
XercesDOMParser * parser = new XercesDOMParser;
parser->setDoNamespaces(true);
parser->setCreateEntityReferenceNodes(true);
// Now parse out file
bool errorsOccured = false;
int errorCount = 0;
try
{
parser->parse(argv[argc - 1]);
errorCount = parser->getErrorCount();
if (errorCount > 0)
errorsOccured = true;
}
catch (const XMLException& e)
{
cerr << "An error occured during parsing\n Message: "
<< e.getMessage() << endl;
errorsOccured = true;
}
catch (const DOMException& e)
{
cerr << "A DOM error occured during parsing\n DOMException code: "
<< e.code << endl;
errorsOccured = true;
}
if (errorsOccured) {
cout << "Errors during parse" << endl;
exit (1);
}
/*
Now that we have the parsed file, get the DOM document and start looking at it
*/
DOMNode *doc; // The document that we parsed
doc = parser->getDocument();
DOMDocument *theDOM = parser->getDocument();
// Find the signature node
DOMNode *sigNode = findDSIGNode(doc, "Signature");
// Create the signature checker
if (sigNode == 0) {
cerr << "Could not find <Signature> node in " << argv[argc-1] << endl;
exit(1);
}
XSECProvider prov;
DSIGSignature * sig = prov.newSignatureFromDOM(theDOM, sigNode);
int i;
try {
sig->load();
if (clearKeyInfo == true)
sig->clearKeyInfo();
if (key != NULL)
sig->setSigningKey(key);
sig->sign();
// Add any KeyInfo elements
if (certCount > 0) {
// Have some certificates - see if there is already an X509 list
DSIGKeyInfoList * kiList = sig->getKeyInfoList();
int kiSize = kiList->getSize();
for (i = 0; i < kiSize; ++i) {
if (kiList->item(i)->getKeyInfoType() == DSIGKeyInfo::KEYINFO_X509) {
keyInfoX509 = (DSIGKeyInfoX509 *) kiList->item(i);
break;
}
}
if (keyInfoX509 == 0) {
// Not found - need to create
keyInfoX509 = sig->appendX509Data();
}
for (i = 0; i < certCount; ++i) {
keyInfoX509->appendX509Certificate(certs[i]->getDEREncodingSB().rawCharBuffer());
}
} /* certCount > 0 */
}
catch (XSECException &e) {
cerr << "An error occured during signature verification\n Message: "
<< e.getMsg() << endl;
errorsOccured = true;
exit (1);
}
// Print out the result
DOMPrintFormatTarget* formatTarget = new DOMPrintFormatTarget();
const XMLCh* encNameStr = XMLString::transcode("UTF-8");
DOMNode *aNode = doc->getFirstChild();
if (aNode->getNodeType() == DOMNode::ENTITY_NODE)
{
const XMLCh* aStr = ((DOMEntity *)aNode)->getEncoding();
if (!strEquals(aStr, ""))
{
encNameStr = aStr;
}
}
unsigned int lent = XMLString::stringLen(encNameStr);
gEncodingName = new XMLCh[lent + 1];
XMLString::copyNString(gEncodingName, encNameStr, lent);
gEncodingName[lent] = 0;
gFormatter = new XMLFormatter("UTF-8", formatTarget,
XMLFormatter::NoEscapes, gUnRepFlags);
cout << doc;
prov.releaseSignature(sig);
return 0;
}
void ClsSettingsReader::parseBuffer(string strFileName) {
#ifdef DEBUG_CLSSETTINGSREADER
cout << "ClsSettingsReader::parseBuffer()" << endl;
#endif
cout << "reading settings from: " << strFileName << endl;
static bool gDoNamespaces = false;
if(!bXMLPlatformInitialized){
try {
XMLPlatformUtils::Initialize();
}
catch(const XMLException& toCatch) {
cerr << "Error during Xerces-c Initialization.\n"
<< " Exception message:"
<< toCatch.getMessage() << endl;
bXMLPlatformInitialized = false;
return;
}
bXMLPlatformInitialized = true;
}
//--------------------
XercesDOMParser* parser = new XercesDOMParser();
parser->setValidationScheme(XercesDOMParser::Val_Never);
/*
XercesDOMParser::Val_Never;
XercesDOMParser::Val_Auto;
XercesDOMParser::Val_Always;
*/
// cout << __FILE__ << ":" << __LINE__ << endl;
parser->setDoNamespaces(gDoNamespaces);
ErrorHandler* errHandler = (ErrorHandler*) new HandlerBase();
parser->setErrorHandler(errHandler);
// cout << __FILE__ << ":" << __LINE__ << endl;
bool errorsOccured = false;
try {
parser->parse(strFileName.c_str());
int errorCount = parser->getErrorCount();
if (errorCount > 0){
errorsOccured = true;
}
} catch (const XMLException& e) {
cerr << "An error occured during parsing (XMLException)\n NMessage: " << XMLString::transcode(e.getMessage()) << endl;
ClsSettingsReaderException clsSettingsReaderException(XMLString::transcode(e.getMessage()));
errorsOccured = true;
throw clsSettingsReaderException;
} catch (const DOMException& e) {
cerr << "An error occured during parsing (DOMException)\n DMessage: " << XMLString::transcode(e.msg) << endl;
ClsSettingsReaderException clsSettingsReaderException(XMLString::transcode(e.msg));
errorsOccured = true;
throw clsSettingsReaderException;
} catch (const SAXException& e) {
cerr << "An error occured during parsing (SAXException)\n DMessage: " << XMLString::transcode(e.getMessage()) << endl;
ClsSettingsReaderException clsSettingsReaderException(XMLString::transcode(e.getMessage()));
errorsOccured = true;
throw clsSettingsReaderException;
} catch (...) {
cerr << "An error occured during parsing\n " << endl;
errorsOccured = true;
ClsSettingsReaderException clsSettingsReaderException(ClsSettingsReaderException::PARSE_ERROR);
throw clsSettingsReaderException;
}
if (errorsOccured){
cerr << "An error occured during parsing\n " << endl;
ClsSettingsReaderException clsSettingsReaderException(ClsSettingsReaderException::PARSE_ERROR);
throw clsSettingsReaderException;
}
if (!errorsOccured) {
DOMNode* dnIqrSetting;
DOMNodeList* dnlstTemp;
ddocIqrSetting = parser->getDocument();
// first we have to find the top System node
dnlstTemp = ddocIqrSetting->getElementsByTagName(XMLString::transcode((const char*)"iqrSetting"));
dnlstTemp = ddocIqrSetting->getElementsByTagName(XMLString::transcode(ClsTagLibrary::iqrSettings()));
if ( dnlstTemp->getLength() == 1){
dnIqrSetting = dnlstTemp->item(0);
} else if ( dnlstTemp->getLength() < 1) {
ClsSettingsReaderException clsSettingsReaderException(ClsSettingsReaderException::NO_IQRSETTING_NODE);
throw clsSettingsReaderException;
}
iSysSettingReaderState = PARSER_BUFFER_PARSED;
}
delete errHandler;
// delete parser;
};
list<ClsDataClientConfig> ClsDataClientConfigReader::getDataClientConfig(string strFileName) {
#ifdef DEBUG_CLSDATACLIENTCONFIGREADER
cout << "ClsDataClientConfigReader::getDataClientConfig()" << endl;
#endif
list<ClsDataClientConfig> lstConfigs;
#ifdef DEBUG_CLSDATACLIENTCONFIGREADER
cout << "reading settings from: " << strFileName << endl;
#endif
bool errorsOccured = false;
static bool gDoNamespaces = false;
if(!bXMLPlatformInitialized){
try {
XMLPlatformUtils::Initialize();
}
catch(const XMLException& toCatch) {
cerr << "Error during Xerces-c Initialization.\n"
<< " Exception message:"
<< toCatch.getMessage() << endl;
bXMLPlatformInitialized = false;
errorsOccured = true;
// return;
}
bXMLPlatformInitialized = true;
errorsOccured = false;
}
//--------------------
if (!errorsOccured) {
XercesDOMParser* parser = new XercesDOMParser();
parser->setValidationScheme(XercesDOMParser::Val_Never);
/*
XercesDOMParser::Val_Never;
XercesDOMParser::Val_Auto;
XercesDOMParser::Val_Always;
*/
parser->setDoNamespaces(gDoNamespaces);
ErrorHandler* errHandler = (ErrorHandler*) new HandlerBase();
parser->setErrorHandler(errHandler);
try {
parser->parse(strFileName.c_str());
int errorCount = parser->getErrorCount();
if (errorCount > 0){
errorsOccured = true;
}
} catch (const XMLException& e) {
cerr << "An error occured during parsing (XMLException)\n NMessage: " << XMLString::transcode(e.getMessage()) << endl;
ClsDataClientConfigReaderException clsDataClientConfigReaderException(XMLString::transcode(e.getMessage()));
errorsOccured = true;
throw clsDataClientConfigReaderException;
} catch (const DOMException& e) {
cerr << "An error occured during parsing (DOMException)\n DMessage: " << XMLString::transcode(e.msg) << endl;
ClsDataClientConfigReaderException clsDataClientConfigReaderException(XMLString::transcode(e.msg));
errorsOccured = true;
throw clsDataClientConfigReaderException;
} catch (const SAXException& e) {
cerr << "An error occured during parsing (SAXException)\n DMessage: " << XMLString::transcode(e.getMessage()) << endl;
ClsDataClientConfigReaderException clsDataClientConfigReaderException(XMLString::transcode(e.getMessage()));
errorsOccured = true;
throw clsDataClientConfigReaderException;
} catch (...) {
cerr << "An error occured during parsing\n " << endl;
errorsOccured = true;
ClsDataClientConfigReaderException clsDataClientConfigReaderException(ClsDataClientConfigReaderException::PARSE_ERROR);
throw clsDataClientConfigReaderException;
}
/* DOMNode* dnIqrConfig; */
DOMDocument *ddocConfig = parser->getDocument();
DOMNodeList* dnlstClients = ddocConfig->getElementsByTagName(XMLString::transcode(ConfigTagLibrary::DataClientTag()));
try{
if(dnlstClients->getLength()>0){
DOMNode* dnValue = NULL;
unsigned int ii = 0;
while( ii< dnlstClients->getLength()){
DOMNode* dnClient = dnlstClients->item(ii);
ii++;
string strType = getAttributeValue(dnClient, ConfigTagLibrary::TypeTag(), true);
string strID = getAttributeValue(dnClient, ConfigTagLibrary::IDTag(), false);
ClsDataClientConfig clsDataClientConfig(strID, strType);
DOMNodeList* dnlstClientChildren = dnClient->getChildNodes();
unsigned int i2 = 0;
while( i2< dnlstClientChildren->getLength()){
DOMNode* dnClientChild = dnlstClientChildren->item(i2);
if(dnClientChild->getNodeType() == 1){
string strName = XMLString::transcode(dnClientChild->getNodeName());
if(!strName.compare(ConfigTagLibrary::PositionTag())){
int iX = 0;
int iY = 0;
iX = iqrUtils::string2int(getAttributeValue(dnClientChild, ConfigTagLibrary::PositionXTag(), true));
iY = iqrUtils::string2int(getAttributeValue(dnClientChild, ConfigTagLibrary::PositionYTag(), true));
clsDataClientConfig.setPosition(iX, iY);
} else if(!strName.compare(ConfigTagLibrary::Geometry())){
int iWidth = 0;
int iHeight = 0;
iWidth = iqrUtils::string2int(getAttributeValue(dnClientChild, ConfigTagLibrary::GeometryWidthTag(), true));
iHeight = iqrUtils::string2int(getAttributeValue(dnClientChild, ConfigTagLibrary::GeometryHeightTag(), true));
clsDataClientConfig.setGeometry(iWidth, iHeight);
} else if(!strName.compare(ConfigTagLibrary::StateVariableDisplayTag())){
DOMNodeList* dnlstSVD = dnClientChild->getChildNodes();
unsigned int i3 = 0;
while( i3< dnlstSVD->getLength()){
DOMNode* dnSVD = dnlstSVD->item(i3);
if(dnSVD->getNodeType() == 1){
string strSVDID = getAttributeValue(dnSVD, ConfigTagLibrary::IDTag(), true);
//-- string strItemType = getAttributeValue(dnSVD, ConfigTagLibrary::TypeTag(), true);
string strItemID = getAttributeValue(dnSVD, ConfigTagLibrary::ItemIDTag(), true);
string strSelectedIndices = getAttributeValue(dnSVD, ConfigTagLibrary::SelectedIndicesTag(), true);
ClsStateVariableDisplayConfig clsStateVariableDisplayConfig(/*strItemType,*/ strSVDID, strItemID, strSelectedIndices);
DOMNodeList* dnlstSVDParams = dnSVD->getChildNodes();
unsigned int i4 = 0;
while( i4< dnlstSVDParams->getLength()){
DOMNode* dnSVDParam = dnlstSVDParams->item(i4);
if(dnSVDParam->getNodeType() == 1){
string strParamName = XMLString::transcode(dnSVDParam->getNodeName());
dnValue = dnSVDParam->getFirstChild();
string strParamValue = "";
if(dnValue!=NULL){
strParamValue = XMLString::transcode(dnValue->getNodeValue());
}
pair<string, string> pParam(strParamName, strParamValue);
clsStateVariableDisplayConfig.addParameter(pParam);
}
i4++;
}
clsDataClientConfig.addStateVariableDisplayConfig(clsStateVariableDisplayConfig);
}
i3++;
}
} else {
string strValue = "";
dnValue = dnClientChild->getFirstChild();
if(dnValue!=NULL){
strValue = XMLString::transcode(dnValue->getNodeValue());
}
pair<string, string> pParam(strName, strValue);
clsDataClientConfig.addParameter(pParam);
}
}
i2++;
}
lstConfigs.push_back(clsDataClientConfig);
}
}
} catch (...) {
ClsDataClientConfigReaderException clsDataClientConfigReaderException(ClsDataClientConfigReaderException::PARSE_ERROR);
throw clsDataClientConfigReaderException;
}
delete errHandler;
}
return lstConfigs;
};
XERCES_CPP_NAMESPACE_USE
int main( int argc, char *argv[] )
{
std::cout << "****************************" << std::endl;
std::cout << "XML DOM PARSER PLAY" << std::endl;
std::cout << "****************************" << std::endl;
try
{
XMLPlatformUtils::Initialize();
}
catch( const XMLException& ex )
{
std::cerr << "error with xml initialisation:" << ex.getMessage() << std::endl;
return 1;
}
std::cout << "Building parser ..." << std::endl;
XercesDOMParser* parser = new XercesDOMParser();
if( !parser )
{
std::cerr << "no parser" << std::endl;
return 1;
}
parser->setValidationScheme(XercesDOMParser::Val_Always);
parser->setDoNamespaces(false);
parser->setDoSchema(false);
parser->setCreateEntityReferenceNodes(false);
std::cout << "Building error handler" << std::endl;
ErrorHandler* errHandler = dynamic_cast<ErrorHandler*>(new HandlerBase());
if( errHandler == 0 )
{
std::cerr << "ibad cast" << std::endl;
return 1;
}
if( errHandler == 0 )
{
std::cerr << "error with errorhandler caszting:" << std::endl;
return 1;
}
parser->setErrorHandler(errHandler);
char* xmlFile = "/home/suggitpe/test/RPMS/config/rpms_config.xml";
try
{
parser->parse(xmlFile);
if( parser->getErrorCount() == 0 )
{
std::cerr << "errors in parsing" << std::endl;
return 1;
}
DOMDocument * doc = parser->getDocument();
if( doc->hasChildNodes() )
{
std::cout << "Num nodes: " << doc->getChildNodes()->getLength() << std::endl;
for( int i = 0; i < doc->getChildNodes()->getLength();++i )
{
cout << "\t" << i << " type: " << doc->getChildNodes()->item(i)->getNodeType() << endl;
if( doc->getChildNodes()->item(i)->getNodeType() == 1 )
{
DOMElement *e = dynamic_cast<DOMElement*>(doc->getChildNodes()->item(i));
if( !e ) { cerr << "bad cast" << endl; }
if( e->hasChildNodes() )
{
cout << "\t\telement found with " << e->getChildNodes()->getLength() << " nodes"<< endl;
}
else
{
cout << "No child nodes" << endl;
}
}
}
cout << "now for the other way" << endl;
XMLCh * name = XMLString::transcode("system_components");
DOMNodeList *list = doc->getDocumentElement()->getElementsByTagName( name );
XMLString::release(&name);
std::cout << "Got list [" << list->getLength() << "]" << std::endl;
for( XMLSize_t i =0; i < list->getLength(); ++i )
{
std::cout << "." << std::endl;
}
}
else
{
std::cout << "no child nodes" << std::endl;
}
}
catch( const XMLException& ex )
{
std::cerr << "error with xml parser:" << ex.getMessage() << std::endl;
return 1;
}
catch( const DOMException& dex )
{
std::cerr << "error with xml parser:" << dex.msg << std::endl;
return 1;
}
catch(...)
{
std::cerr << "unknown problems" << std::endl;
return 1;
}
delete parser;
delete errHandler;
std::cout << "****************************" << std::endl;
std::cout << "" << std::endl;
return 0;
}
