blob: cabd082a7da785a78527bbe343a7561ef5cdf8f8 [file] [log] [blame]
/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil -*- */
/**
* Copyright (C) 2013 Regents of the University of California.
* @author: Yingdi Yu <yingdi@cs.ucla.edu>
* @author: Jeff Thompson <jefft0@remap.ucla.edu>
* See COPYING for copyright and distribution information.
*/
#include "common.hpp"
#include "validator.hpp"
#include "../util/logging.hpp"
#include <cryptopp/rsa.h>
using namespace std;
INIT_LOGGER("ndn::Validator");
namespace ndn {
const shared_ptr<Face> Validator::DefaultFace = shared_ptr<Face>();
Validator::Validator(shared_ptr<Face> face /* = DefaultFace */)
: m_face(face)
{}
void
Validator::validate(const Interest& interest,
const OnInterestValidated &onValidated,
const OnInterestValidationFailed &onValidationFailed,
int stepCount)
{
vector<shared_ptr<ValidationRequest> > nextSteps;
checkPolicy(interest, stepCount, onValidated, onValidationFailed, nextSteps);
if (!nextSteps.empty())
{
if(!static_cast<bool>(m_face))
throw Error("Face should be set prior to verify method to call");
vector<shared_ptr<ValidationRequest> >::const_iterator it = nextSteps.begin();
OnFailure onFailure = bind(onValidationFailed, interest.shared_from_this(), _1);
for(; it != nextSteps.end(); it++)
m_face->expressInterest((*it)->m_interest,
bind(&Validator::onData, this, _1, _2, *it),
bind(&Validator::onTimeout,
this, _1, (*it)->m_retry,
onFailure,
*it));
}
else
{
//If there is no nextStep, that means InterestPolicy has already been able to verify the Interest.
//No more further processes.
}
}
void
Validator::validate(const Data& data,
const OnDataValidated &onValidated,
const OnDataValidationFailed &onValidationFailed,
int stepCount)
{
vector<shared_ptr<ValidationRequest> > nextSteps;
checkPolicy(data, stepCount, onValidated, onValidationFailed, nextSteps);
if (!nextSteps.empty())
{
if(!static_cast<bool>(m_face))
throw Error("Face should be set prior to verify method to call");
vector<shared_ptr<ValidationRequest> >::const_iterator it = nextSteps.begin();
OnFailure onFailure = bind(onValidationFailed, data.shared_from_this(), _1);
for(; it != nextSteps.end(); it++)
m_face->expressInterest((*it)->m_interest,
bind(&Validator::onData, this, _1, _2, *it),
bind(&Validator::onTimeout,
this, _1, (*it)->m_retry,
onFailure,
*it));
}
else
{
//If there is no nextStep, that means InterestPolicy has already been able to verify the Interest.
//No more further processes.
}
}
void
Validator::onData(const Interest& interest,
Data& data,
const shared_ptr<ValidationRequest>& nextStep)
{
validate(data, nextStep->m_onValidated, nextStep->m_onDataValidated, nextStep->m_stepCount);
}
void
Validator::onTimeout(const Interest& interest,
int retry,
const OnFailure &onFailure,
const shared_ptr<ValidationRequest>& nextStep)
{
if (retry > 0)
// Issue the same expressInterest except decrement retry.
m_face->expressInterest(interest,
bind(&Validator::onData, this, _1, _2, nextStep),
bind(&Validator::onTimeout, this, _1, retry - 1, onFailure, nextStep));
else
onFailure("Cannot fetch cert: " + interest.getName().toUri());
}
bool
Validator::verifySignature(const Data& data, const PublicKey& key)
{
try
{
switch(data.getSignature().getType()){
case Signature::Sha256WithRsa:
{
SignatureSha256WithRsa sigSha256Rsa(data.getSignature());
return verifySignature(data, sigSha256Rsa, key);
}
default:
{
_LOG_DEBUG("verifySignature: Unknown signature type: " << data.getSignature().getType());
return false;
}
}
}
catch(Signature::Error &e)
{
_LOG_DEBUG("verifySignature: " << e.what());
return false;
}
return false;
}
bool
Validator::verifySignature(const Interest &interest, const PublicKey &key)
{
const Name &interestName = interest.getName();
if(interestName.size() < 2)
return false;
try
{
const Block& nameBlock = interestName.wireEncode();
Signature sig(interestName[-2].blockFromValue(),
interestName[-1].blockFromValue());
switch(sig.getType()){
case Signature::Sha256WithRsa:
{
SignatureSha256WithRsa sigSha256Rsa(sig);
return verifySignature(nameBlock.value(),
nameBlock.value_size() - interestName[-1].size(),
sigSha256Rsa, key);
}
default:
{
_LOG_DEBUG("verifySignature: Unknown signature type: " << sig.getType());
return false;
}
}
}
catch(Signature::Error &e)
{
_LOG_DEBUG("verifySignature: " << e.what());
return false;
}
catch(Block::Error &e)
{
_LOG_DEBUG("verifySignature: " << e.what());
return false;
}
return false;
}
bool
Validator::verifySignature(const Buffer &data, const Signature &sig, const PublicKey &key)
{
try
{
switch(sig.getType()){
case Signature::Sha256WithRsa:
{
SignatureSha256WithRsa sigSha256Rsa(sig);
return verifySignature(data, sigSha256Rsa, key);
}
default:
{
_LOG_DEBUG("verifySignature: Unknown signature type: " << sig.getType());
return false;
}
}
}
catch(Signature::Error &e)
{
_LOG_DEBUG("verifySignature: " << e.what());
return false;
}
return false;
}
bool
Validator::verifySignature(const uint8_t* buf, const size_t size, const SignatureSha256WithRsa &sig, const PublicKey &key)
{
try
{
using namespace CryptoPP;
RSA::PublicKey publicKey;
ByteQueue queue;
queue.Put(reinterpret_cast<const byte*>(key.get().buf()), key.get().size());
publicKey.Load(queue);
RSASS<PKCS1v15, SHA256>::Verifier verifier (publicKey);
return verifier.VerifyMessage(buf, size, sig.getValue().value(), sig.getValue().value_size());
}
catch(CryptoPP::Exception& e)
{
_LOG_DEBUG("verifySignature: " << e.what());
return false;
}
}
} // namespace ndn