/* * Copyright (c) 2012 Isode Limited, London, England. * Licensed under the simplified BSD license. * See Documentation/Licenses/BSD-simplified.txt for more information. */ #pragma once #include #include #include #include #include #include // Size of the SHA1 hash #define SHA1_HASH_LEN 20 namespace Swift { CAPICertificate::CAPICertificate(const std::string& capiUri, TimerFactory* timerFactory) : valid_(false), uri_(capiUri), certStoreHandle_(0), scardContext_(0), cardHandle_(0), certStore_(), certName_(), smartCardReaderName_(), timerFactory_(timerFactory), lastPollingResult_(true) { assert(timerFactory_); setUri(capiUri); } CAPICertificate::~CAPICertificate() { if (smartCardTimer_) { smartCardTimer_->stop(); smartCardTimer_->onTick.disconnect(boost::bind(&CAPICertificate::handleSmartCardTimerTick, this)); smartCardTimer_.reset(); } if (certStoreHandle_) { CertCloseStore(certStoreHandle_, 0); } if (cardHandle_) { (void) SCardDisconnect(cardHandle_, SCARD_LEAVE_CARD); } if (scardContext_) { SCardReleaseContext(scardContext_); } } bool CAPICertificate::isNull() const { return uri_.empty() || !valid_; } const std::string& CAPICertificate::getCertStoreName() const { return certStore_; } const std::string& CAPICertificate::getCertName() const { return certName_; } const std::string& CAPICertificate::getSmartCardReaderName() const { return smartCardReaderName_; } PCCERT_CONTEXT findCertificateInStore (HCERTSTORE certStoreHandle, const std::string &certName) { if (!boost::iequals(certName.substr(0, 5), "sha1:")) { // Find client certificate. Note that this sample just searches for a // certificate that contains the user name somewhere in the subject name. return CertFindCertificateInStore(certStoreHandle, X509_ASN_ENCODING, /*dwFindFlags*/ 0, CERT_FIND_SUBJECT_STR_A, /* *pvFindPara*/certName.c_str(), /*pPrevCertContext*/ NULL); } std::string hexstring = certName.substr(5); ByteArray byteArray = Hexify::unhexify(hexstring); CRYPT_HASH_BLOB HashBlob; if (byteArray.size() != SHA1_HASH_LEN) { return NULL; } HashBlob.cbData = SHA1_HASH_LEN; HashBlob.pbData = static_cast(vecptr(byteArray)); // Find client certificate. Note that this sample just searches for a // certificate that contains the user name somewhere in the subject name. return CertFindCertificateInStore(certStoreHandle, X509_ASN_ENCODING, /* dwFindFlags */ 0, CERT_FIND_HASH, &HashBlob, /* pPrevCertContext */ NULL); } void CAPICertificate::setUri (const std::string& capiUri) { valid_ = false; /* Syntax: "certstore:" ":" ":" */ if (!boost::iequals(capiUri.substr(0, 10), "certstore:")) { return; } /* Substring of subject: uses "storename" */ std::string capiIdentity = capiUri.substr(10); std::string newCertStoreName; size_t pos = capiIdentity.find_first_of (':'); if (pos == std::string::npos) { /* Using the default certificate store */ newCertStoreName = "MY"; certName_ = capiIdentity; } else { newCertStoreName = capiIdentity.substr(0, pos); certName_ = capiIdentity.substr(pos + 1); } if (certStoreHandle_ != NULL) { if (newCertStoreName != certStore_) { CertCloseStore(certStoreHandle_, 0); certStoreHandle_ = NULL; } } if (certStoreHandle_ == NULL) { certStoreHandle_ = CertOpenSystemStore(0, newCertStoreName.c_str()); if (!certStoreHandle_) { return; } } certStore_ = newCertStoreName; PCCERT_CONTEXT certContext = findCertificateInStore (certStoreHandle_, certName_); if (!certContext) { return; } /* Now verify that we can have access to the corresponding private key */ DWORD len; CRYPT_KEY_PROV_INFO *pinfo; HCRYPTPROV hprov; HCRYPTKEY key; if (!CertGetCertificateContextProperty(certContext, CERT_KEY_PROV_INFO_PROP_ID, NULL, &len)) { CertFreeCertificateContext(certContext); return; } pinfo = static_cast(malloc(len)); if (!pinfo) { CertFreeCertificateContext(certContext); return; } if (!CertGetCertificateContextProperty(certContext, CERT_KEY_PROV_INFO_PROP_ID, pinfo, &len)) { CertFreeCertificateContext(certContext); free(pinfo); return; } CertFreeCertificateContext(certContext); // Now verify if we have access to the private key if (!CryptAcquireContextW(&hprov, pinfo->pwszContainerName, pinfo->pwszProvName, pinfo->dwProvType, 0)) { free(pinfo); return; } char smartCardReader[1024]; DWORD bufferLength = sizeof(smartCardReader); if (!CryptGetProvParam(hprov, PP_SMARTCARD_READER, (BYTE *)&smartCardReader, &bufferLength, 0)) { DWORD error = GetLastError(); smartCardReaderName_ = ""; } else { smartCardReaderName_ = smartCardReader; LONG result = SCardEstablishContext(SCARD_SCOPE_USER, NULL, NULL, &scardContext_); if (SCARD_S_SUCCESS == result) { // Initiate monitoring for smartcard ejection smartCardTimer_ = timerFactory_->createTimer(SMARTCARD_EJECTION_CHECK_FREQUENCY_MILLISECONDS); } else { ///Need to handle an error here } } if (!CryptGetUserKey(hprov, pinfo->dwKeySpec, &key)) { CryptReleaseContext(hprov, 0); free(pinfo); return; } CryptDestroyKey(key); CryptReleaseContext(hprov, 0); free(pinfo); if (smartCardTimer_) { smartCardTimer_->onTick.connect(boost::bind(&CAPICertificate::handleSmartCardTimerTick, this)); smartCardTimer_->start(); } valid_ = true; } static void smartcard_check_status (SCARDCONTEXT hContext, const char* pReader, SCARDHANDLE hCardHandle, /* Can be 0 on the first call */ SCARDHANDLE* newCardHandle, /* The handle returned */ DWORD* pdwState) { if (hCardHandle == 0) { DWORD dwAP; LONG result = SCardConnect(hContext, pReader, SCARD_SHARE_SHARED, SCARD_PROTOCOL_T0 | SCARD_PROTOCOL_T1, &hCardHandle, &dwAP); if (SCARD_S_SUCCESS != result) { hCardHandle = 0; if (SCARD_E_NO_SMARTCARD == result || SCARD_W_REMOVED_CARD == result) { *pdwState = SCARD_ABSENT; } else { *pdwState = SCARD_UNKNOWN; } if (newCardHandle == NULL) { (void) SCardDisconnect(hCardHandle, SCARD_LEAVE_CARD); hCardHandle = 0; } else { *newCardHandle = hCardHandle; } } } char szReader[200]; DWORD cch = sizeof(szReader); BYTE bAttr[32]; DWORD cByte = 32; LONG result = SCardStatus(hCardHandle, /* Unfortunately we can't use NULL here */ szReader, &cch, pdwState, NULL, (LPBYTE)&bAttr, &cByte); if (SCARD_S_SUCCESS != result) { if (SCARD_E_NO_SMARTCARD == result || SCARD_W_REMOVED_CARD == result) { *pdwState = SCARD_ABSENT; } else { *pdwState = SCARD_UNKNOWN; } } if (newCardHandle == NULL) { (void) SCardDisconnect(hCardHandle, SCARD_LEAVE_CARD); hCardHandle = 0; } else { *newCardHandle = hCardHandle; } } bool CAPICertificate::checkIfSmartCardPresent () { if (!smartCardReaderName_.empty()) { DWORD dwState; smartcard_check_status(scardContext_, smartCardReaderName_.c_str(), cardHandle_, &cardHandle_, &dwState); switch (dwState) { case SCARD_ABSENT: SWIFT_LOG(debug) << "Card absent." << std::endl; break; case SCARD_PRESENT: SWIFT_LOG(debug) << "Card present." << std::endl; break; case SCARD_SWALLOWED: SWIFT_LOG(debug) << "Card swallowed." << std::endl; break; case SCARD_POWERED: SWIFT_LOG(debug) << "Card has power." << std::endl; break; case SCARD_NEGOTIABLE: SWIFT_LOG(debug) << "Card reset and waiting PTS negotiation." << std::endl; break; case SCARD_SPECIFIC: SWIFT_LOG(debug) << "Card has specific communication protocols set." << std::endl; break; default: SWIFT_LOG(debug) << "Unknown or unexpected card state." << std::endl; break; } switch (dwState) { case SCARD_ABSENT: return false; case SCARD_PRESENT: case SCARD_SWALLOWED: case SCARD_POWERED: case SCARD_NEGOTIABLE: case SCARD_SPECIFIC: return true; default: return false; } } else { return false; } } void CAPICertificate::handleSmartCardTimerTick() { bool poll = checkIfSmartCardPresent(); if (lastPollingResult_ && !poll) { onCertificateCardRemoved(); } lastPollingResult_ = poll; smartCardTimer_->start(); } }