*/
#include "internal.h"
+#include "security/Credential.h"
+#include "security/CredentialCriteria.h"
+#include "security/CredentialResolver.h"
#include "security/OpenSSLTrustEngine.h"
#include "signature/SignatureValidator.h"
#include "util/NDC.h"
virtual bool validate(
Signature& sig,
- const KeyInfoSource& keyInfoSource,
- const KeyResolver* keyResolver=NULL
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria=NULL
) const;
virtual bool validate(
const XMLCh* sigAlgorithm,
KeyInfo* keyInfo,
const char* in,
unsigned int in_len,
- const KeyInfoSource& keyInfoSource,
- const KeyResolver* keyResolver=NULL
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria=NULL
) const;
virtual bool validate(
XSECCryptoX509* certEE,
const vector<XSECCryptoX509*>& certChain,
- const KeyInfoSource& keyInfoSource,
- bool checkName=true,
- const KeyResolver* keyResolver=NULL
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria=NULL
) const;
virtual bool validate(
X509* certEE,
STACK_OF(X509)* certChain,
- const KeyInfoSource& keyInfoSource,
- bool checkName=true,
- const KeyResolver* keyResolver=NULL
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria=NULL
) const;
};
bool ExplicitKeyTrustEngine::validate(
Signature& sig,
- const KeyInfoSource& keyInfoSource,
- const KeyResolver* keyResolver
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria
) const
{
#ifdef _DEBUG
NDC ndc("validate");
#endif
Category& log=Category::getInstance(XMLTOOLING_LOGCAT".TrustEngine");
-
- auto_ptr<KeyInfoIterator> keyInfoIter(keyInfoSource.getKeyInfoIterator());
- if (!keyInfoIter->hasNext()) {
- log.warn("unable to validate signature, no key information available for peer");
+
+ vector<const Credential*> credentials;
+ if (criteria) {
+ criteria->setUsage(CredentialCriteria::SIGNING_CREDENTIAL);
+ criteria->setSignature(sig);
+ credResolver.resolve(credentials,criteria);
+ }
+ else {
+ CredentialCriteria cc;
+ cc.setUsage(CredentialCriteria::SIGNING_CREDENTIAL);
+ cc.setSignature(sig);
+ credResolver.resolve(credentials,&cc);
+ }
+ if (credentials.empty()) {
+ log.warn("unable to validate signature, no credentials available from peer");
return false;
}
- log.debug("attempting to validate signature with the key information for peer");
+ log.debug("attempting to validate signature with the peer's credentials");
SignatureValidator sigValidator;
- while (keyInfoIter->hasNext()) {
- XSECCryptoKey* key = (keyResolver ? keyResolver : m_keyResolver)->resolveKey(keyInfoIter->next());
- if (key) {
- log.debug("attempting to validate signature with public key...");
- try {
- sigValidator.setKey(key); // key now owned by validator
- sigValidator.validate(&sig);
- log.debug("signature validated with public key");
- return true;
- }
- catch (ValidationException& e) {
- log.debug("public key did not validate signature: %s", e.what());
- }
+ for (vector<const Credential*>::const_iterator c=credentials.begin(); c!=credentials.end(); ++c) {
+ sigValidator.setCredential(*c);
+ try {
+ sigValidator.validate(&sig);
+ log.debug("signature validated with credential");
+ return true;
}
- else {
- log.debug("key information does not resolve to a public key, skipping it");
+ catch (ValidationException& e) {
+ log.debug("public key did not validate signature: %s", e.what());
}
}
- log.error("no peer key information validated the signature");
+ log.error("no peer credentials validated the signature");
return false;
}
KeyInfo* keyInfo,
const char* in,
unsigned int in_len,
- const KeyInfoSource& keyInfoSource,
- const KeyResolver* keyResolver
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria
) const
{
#ifdef _DEBUG
#endif
Category& log=Category::getInstance(XMLTOOLING_LOGCAT".TrustEngine");
- auto_ptr<KeyInfoIterator> keyInfoIter(keyInfoSource.getKeyInfoIterator());
- if (!keyInfoIter->hasNext()) {
- log.warn("unable to validate signature, no key information available for peer");
+ vector<const Credential*> credentials;
+ if (criteria) {
+ criteria->setUsage(CredentialCriteria::SIGNING_CREDENTIAL);
+ criteria->setKeyInfo(keyInfo);
+ credResolver.resolve(credentials,criteria);
+ }
+ else {
+ CredentialCriteria cc;
+ cc.setUsage(CredentialCriteria::SIGNING_CREDENTIAL);
+ cc.setKeyInfo(keyInfo);
+ credResolver.resolve(credentials,&cc);
+ }
+ if (credentials.empty()) {
+ log.warn("unable to validate signature, no credentials available from peer");
return false;
}
- log.debug("attempting to validate signature with the key information for peer");
- while (keyInfoIter->hasNext()) {
- auto_ptr<XSECCryptoKey> key((keyResolver ? keyResolver : m_keyResolver)->resolveKey(keyInfoIter->next()));
- if (key.get()) {
- log.debug("attempting to validate signature with public key...");
+ log.debug("attempting to validate signature with the peer's credentials");
+ for (vector<const Credential*>::const_iterator c=credentials.begin(); c!=credentials.end(); ++c) {
+ if ((*c)->getPublicKey()) {
try {
- if (Signature::verifyRawSignature(key.get(), sigAlgorithm, sig, in, in_len)) {
+ if (Signature::verifyRawSignature((*c)->getPublicKey(), sigAlgorithm, sig, in, in_len)) {
log.debug("signature validated with public key");
return true;
}
}
}
}
- else {
- log.debug("key information does not resolve to a public key, skipping it");
- }
}
- log.error("no peer key information validated the signature");
+ log.error("no peer credentials validated the signature");
return false;
}
bool ExplicitKeyTrustEngine::validate(
XSECCryptoX509* certEE,
const vector<XSECCryptoX509*>& certChain,
- const KeyInfoSource& keyInfoSource,
- bool checkName,
- const KeyResolver* keyResolver
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria
) const
{
#ifdef _DEBUG
return false;
}
- return validate(static_cast<OpenSSLCryptoX509*>(certEE)->getOpenSSLX509(), NULL, keyInfoSource, checkName, keyResolver);
+ return validate(static_cast<OpenSSLCryptoX509*>(certEE)->getOpenSSLX509(), NULL, credResolver, criteria);
}
bool ExplicitKeyTrustEngine::validate(
X509* certEE,
STACK_OF(X509)* certChain,
- const KeyInfoSource& keyInfoSource,
- bool checkName,
- const KeyResolver* keyResolver
+ const CredentialResolver& credResolver,
+ CredentialCriteria* criteria
) const
{
#ifdef _DEBUG
return false;
}
- auto_ptr<KeyInfoIterator> keyInfoIter(keyInfoSource.getKeyInfoIterator());
- if (!keyInfoIter->hasNext()) {
- log.warn("unable to validate, no key information available for peer");
+ vector<const Credential*> credentials;
+ if (criteria) {
+ if (criteria->getUsage()==CredentialCriteria::UNSPECIFIED_CREDENTIAL)
+ criteria->setUsage(CredentialCriteria::SIGNING_CREDENTIAL);
+ credResolver.resolve(credentials,criteria);
+ }
+ else {
+ CredentialCriteria cc;
+ cc.setUsage(CredentialCriteria::SIGNING_CREDENTIAL);
+ credResolver.resolve(credentials,&cc);
+ }
+ if (credentials.empty()) {
+ log.warn("unable to validate certificate, no credentials available from peer");
return false;
}
// The "explicit" trust implementation relies solely on keys living within the
- // peer interface to verify the EE certificate.
+ // peer resolver to verify the EE certificate.
- log.debug("attempting to match key information from peer with end-entity certificate");
- while (keyInfoIter->hasNext()) {
- auto_ptr<XSECCryptoKey> key((keyResolver ? keyResolver : m_keyResolver)->resolveKey(keyInfoIter->next()));
- if (key.get()) {
+ log.debug("attempting to match credentials from peer with end-entity certificate");
+ for (vector<const Credential*>::const_iterator c=credentials.begin(); c!=credentials.end(); ++c) {
+ XSECCryptoKey* key = (*c)->getPublicKey();
+ if (key) {
log.debug("checking if peer key matches end-entity certificate");
if (key->getProviderName()!=DSIGConstants::s_unicodeStrPROVOpenSSL) {
log.error("only the OpenSSL XSEC provider is supported");
switch (key->getKeyType()) {
case XSECCryptoKey::KEY_RSA_PUBLIC:
{
- RSA* rsa = static_cast<OpenSSLCryptoKeyRSA*>(key.get())->getOpenSSLRSA();
+ RSA* rsa = static_cast<OpenSSLCryptoKeyRSA*>(key)->getOpenSSLRSA();
EVP_PKEY* evp = X509_PUBKEY_get(X509_get_X509_PUBKEY(certEE));
if (rsa && evp && evp->type == EVP_PKEY_RSA &&
BN_cmp(rsa->n,evp->pkey.rsa->n) == 0 && BN_cmp(rsa->e,evp->pkey.rsa->e) == 0) {
- log.debug("end-entity certificate matches peer RSA key information");
if (evp)
EVP_PKEY_free(evp);
+ log.debug("end-entity certificate matches peer RSA key information");
return true;
}
if (evp)
case XSECCryptoKey::KEY_DSA_PUBLIC:
{
- DSA* dsa = static_cast<OpenSSLCryptoKeyDSA*>(key.get())->getOpenSSLDSA();
+ DSA* dsa = static_cast<OpenSSLCryptoKeyDSA*>(key)->getOpenSSLDSA();
EVP_PKEY* evp = X509_PUBKEY_get(X509_get_X509_PUBKEY(certEE));
if (dsa && evp && evp->type == EVP_PKEY_DSA && BN_cmp(dsa->pub_key,evp->pkey.dsa->pub_key) == 0) {
- log.debug("end-entity certificate matches peer DSA key information");
if (evp)
EVP_PKEY_free(evp);
+ log.debug("end-entity certificate matches peer DSA key information");
return true;
}
if (evp)
log.warn("unknown peer key type, skipping...");
}
}
- else {
- log.debug("key information does not resolve to a public key, skipping it");
- }
}
log.debug("no keys within this peer's key information matched the given end-entity certificate");