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tdelibs/tdecore/tdehw/tdecryptographiccarddevice.cpp

955 lines
27 KiB

/* This file is part of the TDE libraries
Copyright (C) 2015 Timothy Pearson <kb9vqf@pearsoncomputing.net>
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public
License version 2 as published by the Free Software Foundation.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Library General Public License for more details.
You should have received a copy of the GNU Library General Public License
along with this library; see the file COPYING.LIB. If not, write to
the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301, USA.
*/
#ifdef WITH_PKCS
#define _TDECRYPTOGRAPHICCARDDEVICE_INTERNAL 1
#endif
#include "tdecryptographiccarddevice_private.h"
#include "tdecryptographiccarddevice.h"
#include <tqpixmap.h>
#include <tqtimer.h>
#include <ntqthread.h>
#include <ntqeventloop.h>
#include <ntqapplication.h>
#include "tdeglobal.h"
#include "tdelocale.h"
#include "tdeapplication.h"
#include "tdehardwaredevices.h"
#include "config.h"
// 1 second
#define PCSC_POLL_TIMEOUT_S 1000
#define CARD_MAX_LOGIN_RETRY_COUNT 3
/* FIXME
* This is incomplete
*/
#ifdef WITH_PCSC
static TQString pcsc_error_code_to_string(long errcode) {
if (errcode == SCARD_W_UNPOWERED_CARD) {
return i18n("card not powered on");
}
else if (errcode == SCARD_E_PROTO_MISMATCH) {
return i18n("protocol mismatch");
}
else {
return TQString::null;
}
}
#endif
CryptoCardDeviceWatcher::CryptoCardDeviceWatcher() {
#ifdef WITH_PCSC
m_readerStates = NULL;
#endif
m_cardPINPromptDone = true;
m_pinCallbacksEnabled = false;
m_cardReusePIN = false;
}
CryptoCardDeviceWatcher::~CryptoCardDeviceWatcher() {
#ifdef WITH_PCSC
free(m_readerStates);
#endif
}
void CryptoCardDeviceWatcher::run() {
#ifdef WITH_PCSC
bool first_loop;
unsigned int i;
long ret;
DWORD dword_readers;
LPSTR lpstring_readers = NULL;
TQStringList readers;
first_loop = true;
m_terminationRequested = false;
TQEventLoop* eventLoop = TQApplication::eventLoop();
if (!eventLoop) return;
ret = SCardEstablishContext(SCARD_SCOPE_SYSTEM, NULL, NULL, &m_cardContext);
if (ret != SCARD_S_SUCCESS) {
printf("TDECryptographicCardDevice: PCSC SCardEstablishContext cannot connect to resource manager (%lX)", ret);
eventLoop->exit(0);
return;
}
ret = SCardListReaders(m_cardContext, NULL, NULL, &dword_readers);
if (ret == SCARD_S_SUCCESS) {
lpstring_readers = (LPSTR)malloc(sizeof(char)*dword_readers);
if (lpstring_readers == NULL) {
printf("TDECryptographicCardDevice: insufficient memory, aborting");
eventLoop->exit(0);
return;
}
ret = SCardListReaders(m_cardContext, NULL, lpstring_readers, &dword_readers);
if (ret == SCARD_S_SUCCESS) {
/* Extract reader names from the null separated string */
char *ptr = lpstring_readers;
while (*ptr != '\0') {
readers.append(ptr);
ptr += strlen(ptr)+1;
}
free(lpstring_readers);
m_readerStates = (SCARD_READERSTATE*)calloc(readers.count(), sizeof(*m_readerStates));
if (m_readerStates == NULL) {
printf("TDECryptographicCardDevice: insufficient memory, aborting");
free(lpstring_readers);
eventLoop->exit(0);
return;
}
for (i=0; i<readers.count(); i++) {
m_readerStates[i].szReader = strdup(readers[i].ascii());
m_readerStates[i].dwCurrentState = SCARD_STATE_UNAWARE;
}
ret = SCardGetStatusChange(m_cardContext, PCSC_POLL_TIMEOUT_S, m_readerStates, readers.count());
while ((ret == SCARD_S_SUCCESS) || (ret == SCARD_E_TIMEOUT)) {
if (m_terminationRequested) {
for (i=0; i<readers.count(); i++) {
free((char*)m_readerStates[i].szReader);
m_readerStates[i].szReader = NULL;
}
eventLoop->exit(0);
return;
}
for (i=0; i<readers.count(); i++) {
/* FIXME
* Find a better / more reliable way to match the card low level device to the PCSC name
*/
SCARDHANDLE hCard = 0;
DWORD dwActiveProtocol = 0;
DWORD cByte = 0;
TQString reader_vendor_name;
TQString reader_interface_type;
ret = SCardConnect(m_cardContext, readers[i].ascii(), SCARD_SHARE_DIRECT, SCARD_PROTOCOL_T0 | SCARD_PROTOCOL_T1, &hCard, &dwActiveProtocol);
if (ret == SCARD_S_SUCCESS) {
ret = SCardGetAttrib(hCard, SCARD_ATTR_VENDOR_NAME, NULL, &cByte);
if (ret == SCARD_S_SUCCESS) {
char* data = new char[cByte];
ret = SCardGetAttrib(hCard, SCARD_ATTR_VENDOR_NAME, (LPBYTE)data, &cByte);
reader_vendor_name = data;
delete [] data;
}
ret = SCardGetAttrib(hCard, SCARD_ATTR_VENDOR_IFD_TYPE, NULL, &cByte);
if (ret == SCARD_S_SUCCESS) {
char* data = new char[cByte];
ret = SCardGetAttrib(hCard, SCARD_ATTR_VENDOR_IFD_TYPE, (LPBYTE)data, &cByte);
reader_interface_type = data;
delete [] data;
}
SCardDisconnect(hCard, SCARD_LEAVE_CARD);
}
/* FIXME
* If only one reader was detected by PCSC, assume it corresponds to the current device node.
* This is fragile, but avoids corner cases with common systems failing to work due to
* mismatched udev / PCSC card reader vendor names...
*/
if (readers.count() > 1) {
if (!readers[i].contains(cardDevice->friendlyName())) {
if (!cardDevice->friendlyName().contains(reader_vendor_name) ||
((reader_interface_type != "") && !cardDevice->friendlyName().contains(reader_vendor_name))) {
continue;
}
}
}
if (first_loop) {
if (m_readerStates[i].dwEventState & SCARD_STATE_PRESENT) {
// sleep(1); // Allow the card to settle
TQString atr = getCardATR(readers[i]);
retrieveCardCertificates(readers[i]);
statusChanged("PRESENT", atr);
}
else {
deleteAllCertificatesFromCache();
}
first_loop = false;
}
if (m_readerStates[i].dwEventState & SCARD_STATE_CHANGED) {
if ((m_readerStates[i].dwCurrentState & SCARD_STATE_PRESENT)
&& (m_readerStates[i].dwEventState & SCARD_STATE_EMPTY)) {
deleteAllCertificatesFromCache();
statusChanged("REMOVED", TQString::null);
}
else if ((m_readerStates[i].dwCurrentState & SCARD_STATE_EMPTY)
&& (m_readerStates[i].dwEventState & SCARD_STATE_PRESENT)) {
// sleep(1); // Allow the card to settle
TQString atr = getCardATR(readers[i]);
retrieveCardCertificates(readers[i]);
statusChanged("INSERTED", atr);
}
m_readerStates[i].dwCurrentState = m_readerStates[i].dwEventState;
}
else {
continue;
}
}
ret = SCardGetStatusChange(m_cardContext, PCSC_POLL_TIMEOUT_S, m_readerStates, readers.count());
}
}
}
eventLoop->exit(0);
#endif
}
void CryptoCardDeviceWatcher::requestTermination() {
m_terminationRequested = true;
}
void CryptoCardDeviceWatcher::setProvidedPin(TQString pin) {
m_cardPIN = pin;
m_cardPINPromptDone = true;
}
void CryptoCardDeviceWatcher::retrySamePin(bool enable) {
m_cardReusePIN = enable;
if (!enable) {
m_cardPIN = "SHREDDINGTHEPINISMOSTSECURE";
m_cardPIN = TQString::null;
}
}
TQString CryptoCardDeviceWatcher::getCardATR(TQString readerName) {
#ifdef WITH_PCSC
unsigned int i;
long ret;
TQString atr_formatted;
SCARDHANDLE hCard = 0;
DWORD dwActiveProtocol = 0;
DWORD cByte = 0;
ret = SCardConnect(m_cardContext, readerName.ascii(), SCARD_SHARE_SHARED, SCARD_PROTOCOL_T0 | SCARD_PROTOCOL_T1, &hCard, &dwActiveProtocol);
if (ret == SCARD_S_SUCCESS) {
ret = SCardGetAttrib(hCard, SCARD_ATTR_ATR_STRING, NULL, &cByte);
if (ret == SCARD_S_SUCCESS) {
char* data = new char[cByte];
ret = SCardGetAttrib(hCard, SCARD_ATTR_ATR_STRING, (LPBYTE)data, &cByte);
atr_formatted = TQString::null;
for (i=0; i<cByte; i++) {
TQString formatted;
formatted.sprintf("%02x ", ((uint8_t)(*(data+i))));
atr_formatted.append(formatted.upper());
}
atr_formatted = atr_formatted.stripWhiteSpace();
delete [] data;
SCardDisconnect(hCard, SCARD_LEAVE_CARD);
}
}
else {
TQString errstring = pcsc_error_code_to_string(ret);
if (errstring != "") {
atr_formatted = i18n("Unknown (%1)").arg(errstring);
}
else {
atr_formatted = TQString("CARD_CONNECT_FAIL (%1)").arg(ret, 0, 16);
}
}
return atr_formatted;
#else
return TQString::null;
#endif
}
void CryptoCardDeviceWatcher::enablePINEntryCallbacks(bool enable) {
m_pinCallbacksEnabled = enable;
}
TQString CryptoCardDeviceWatcher::doPinRequest(TQString prompt) {
if (!m_pinCallbacksEnabled) {
return TQString::null;
}
if (m_cardReusePIN) {
return m_cardPIN;
}
m_cardPINPromptDone = false;
emit(pinRequested(prompt));
while (!m_cardPINPromptDone) {
usleep(100);
}
if (m_cardPIN.length() > 0) {
return m_cardPIN;
}
else {
return TQString::null;
}
}
#ifdef WITH_PKCS
static void pkcs_log_hook(IN void * const global_data, IN unsigned flags, IN const char * const format, IN va_list args) {
vprintf(format, args);
printf("\n");
}
static PKCS11H_BOOL pkcs_pin_hook(IN void * const global_data, IN void * const user_data, IN const pkcs11h_token_id_t token, IN const unsigned retry, OUT char * const pin, IN const size_t pin_max) {
CryptoCardDeviceWatcher* watcher = (CryptoCardDeviceWatcher*)global_data;
TQString providedPin = watcher->doPinRequest(i18n("Please enter the PIN for '%1'").arg(token->display));
if (providedPin.length() > 0) {
snprintf(pin, pin_max, "%s", providedPin.ascii());
// Success
return 1;
}
else {
// Abort
return 0;
}
}
#endif
int CryptoCardDeviceWatcher::initializePkcs() {
#if defined(WITH_PKCS)
CK_RV rv;
printf("Initializing pkcs11-helper\n");
if ((rv = pkcs11h_initialize()) != CKR_OK) {
printf("pkcs11h_initialize failed: %s\n", pkcs11h_getMessage(rv));
return -1;
}
printf("Registering pkcs11-helper hooks\n");
if ((rv = pkcs11h_setLogHook(pkcs_log_hook, this)) != CKR_OK) {
printf("pkcs11h_setLogHook failed: %s\n", pkcs11h_getMessage(rv));
return -1;
}
pkcs11h_setLogLevel(PKCS11H_LOG_WARN);
// pkcs11h_setLogLevel(PKCS11H_LOG_DEBUG2);
#if 0
if ((rv = pkcs11h_setTokenPromptHook(_pkcs11h_hooks_token_prompt, NULL)) != CKR_OK) {
printf("pkcs11h_setTokenPromptHook failed: %s\n", pkcs11h_getMessage(rv));
return -1;
}
#endif
if ((rv = pkcs11h_setMaxLoginRetries(CARD_MAX_LOGIN_RETRY_COUNT)) != CKR_OK) {
printf("pkcs11h_setMaxLoginRetries failed: %s\n", pkcs11h_getMessage(rv));
return -1;
}
if ((rv = pkcs11h_setPINPromptHook(pkcs_pin_hook, this)) != CKR_OK) {
printf("pkcs11h_setPINPromptHook failed: %s\n", pkcs11h_getMessage(rv));
return -1;
}
printf("Adding provider '%s'\n", OPENSC_PKCS11_PROVIDER_LIBRARY);
if ((rv = pkcs11h_addProvider(OPENSC_PKCS11_PROVIDER_LIBRARY, OPENSC_PKCS11_PROVIDER_LIBRARY, false, PKCS11H_PRIVATEMODE_MASK_AUTO, PKCS11H_SLOTEVENT_METHOD_AUTO, 0, false)) != CKR_OK) {
printf("pkcs11h_addProvider failed: %s\n", pkcs11h_getMessage(rv));
return -1;
}
return 0;
#else
return -1;
#endif
}
int CryptoCardDeviceWatcher::retrieveCardCertificates(TQString readerName) {
#if defined(WITH_PKCS)
int ret = -1;
CK_RV rv;
pkcs11h_certificate_id_list_t issuers;
pkcs11h_certificate_id_list_t certs;
if (initializePkcs() < 0) {
printf("Unable to initialize PKCS\n");
return -1;
}
rv = pkcs11h_certificate_enumCertificateIds(PKCS11H_ENUM_METHOD_CACHE, NULL, PKCS11H_PROMPT_MASK_ALLOW_PIN_PROMPT, &issuers, &certs);
if ((rv != CKR_OK) || (certs == NULL)) {
printf("Cannot enumerate certificates: %s\n", pkcs11h_getMessage(rv));
return -1;
}
printf("Successfully enumerated certificates\n");
int i = 0;
for (pkcs11h_certificate_id_list_t cert = certs; cert != NULL; cert = cert->next) {
TQString label = cert->certificate_id->displayName;
printf("Certificate %d name: '%s'\n", i, label.ascii());
pkcs11h_certificate_t certificate;
rv = pkcs11h_certificate_create(certs->certificate_id, NULL, PKCS11H_PROMPT_MASK_ALLOW_PIN_PROMPT, PKCS11H_PIN_CACHE_INFINITE, &certificate);
if (rv != CKR_OK) {
printf("Cannot read certificate: %s\n", pkcs11h_getMessage(rv));
pkcs11h_certificate_freeCertificateId(certs->certificate_id);
ret = -1;
break;
}
pkcs11h_certificate_freeCertificateId(certs->certificate_id);
pkcs11h_openssl_session_t openssl_session = NULL;
if ((openssl_session = pkcs11h_openssl_createSession(certificate)) == NULL) {
printf("Cannot initialize openssl session to retrieve cryptographic objects\n");
pkcs11h_certificate_freeCertificate(certificate);
ret = -1;
break;
}
certificate = NULL; // the certificate object is managed by openssl_session
X509* x509_local;
x509_local = pkcs11h_openssl_session_getX509(openssl_session);
if (x509_local) {
printf("Successfully retrieved X509 certificate\n");
}
else {
printf("Cannot get X509 object\n");
ret = -1;
}
#if 0
RSA* rsa_local;
rsa_local = pkcs11h_openssl_session_getRSA(openssl_session);
if (rsa_local) {
printf("Successfully retrieved RSA public key\n");
}
else {
printf("Cannot get RSA object\n");
ret = -1;
}
#endif
X509* x509_copy = X509_dup(x509_local);
if (x509_copy) {
cardDevice->m_cardCertificates.append(x509_copy);
}
else {
printf("Unable to copy X509 certificate\n");
}
pkcs11h_openssl_freeSession(openssl_session);
i++;
}
pkcs11h_certificate_freeCertificateIdList(issuers);
return ret;
#else
return -1;
#endif
}
void CryptoCardDeviceWatcher::deleteAllCertificatesFromCache() {
#ifdef WITH_PKCS
X509 *x509_cert;
X509CertificatePtrListIterator it;
for (it = cardDevice->m_cardCertificates.begin(); it != cardDevice->m_cardCertificates.end(); ++it) {
x509_cert = *it;
X509_free(x509_cert);
}
cardDevice->m_cardCertificates.clear();
#endif
}
TDECryptographicCardDevice::TDECryptographicCardDevice(TDEGenericDeviceType::TDEGenericDeviceType dt, TQString dn) : TDEGenericDevice(dt, dn),
m_watcherThread(NULL),
m_watcherObject(NULL),
m_cardPresent(false) {
}
TDECryptographicCardDevice::~TDECryptographicCardDevice() {
enableCardMonitoring(false);
}
void TDECryptographicCardDevice::enableCardMonitoring(bool enable) {
#ifdef WITH_PCSC
if (enable) {
if (m_watcherObject && m_watcherThread) {
// Monitoring thread already active
if ((cardPresent() == 1) && (cardX509Certificates().count() > 0)) {
// Card was already inserted and initialized
emit(certificateListAvailable(this));
}
// Abort!
return;
}
m_watcherThread = new TQEventLoopThread();
m_watcherObject = new CryptoCardDeviceWatcher();
m_watcherObject->cardDevice = this;
m_watcherObject->moveToThread(m_watcherThread);
TQObject::connect(m_watcherObject, SIGNAL(statusChanged(TQString,TQString)), this, SLOT(cardStatusChanged(TQString,TQString)));
TQObject::connect(m_watcherObject, SIGNAL(pinRequested(TQString)), this, SLOT(workerRequestedPin(TQString)));
TQTimer::singleShot(0, m_watcherObject, SLOT(run()));
m_watcherThread->start();
}
else {
if (m_watcherObject) {
m_watcherObject->requestTermination();
}
if (m_watcherThread) {
m_watcherThread->wait();
delete m_watcherThread;
m_watcherThread = NULL;
}
if (m_watcherObject) {
delete m_watcherObject;
m_watcherObject = NULL;
}
}
#endif
}
void TDECryptographicCardDevice::enablePINEntryCallbacks(bool enable) {
if (m_watcherObject) {
m_watcherObject->enablePINEntryCallbacks(enable);
}
}
int TDECryptographicCardDevice::cardPresent() {
if (m_watcherObject && m_watcherThread) {
if (m_cardPresent)
return 1;
else
return 0;
}
else {
return -1;
}
}
TQString TDECryptographicCardDevice::cardATR() {
if (m_watcherObject && m_watcherThread) {
if (m_cardPresent)
return m_cardATR;
else
return TQString::null;
}
else {
return TQString::null;
}
}
X509CertificatePtrList TDECryptographicCardDevice::cardX509Certificates() {
if (m_watcherObject && m_watcherThread) {
if (m_cardPresent) {
return m_cardCertificates;
}
else {
return X509CertificatePtrList();
}
}
else {
return X509CertificatePtrList();
}
}
void TDECryptographicCardDevice::cardStatusChanged(TQString status, TQString atr) {
if (status == "INSERTED") {
m_cardPresent = true;
m_cardATR = atr;
emit(cardInserted(this));
if (m_cardCertificates.count() > 0) {
emit(certificateListAvailable(this));
}
}
else if (status == "REMOVED") {
m_cardPresent = false;
m_cardATR = atr;
emit(cardRemoved(this));
}
else if (status == "PRESENT") {
m_cardATR = atr;
m_cardPresent = true;
if (m_cardCertificates.count() > 0) {
emit(certificateListAvailable(this));
}
}
}
void TDECryptographicCardDevice::setProvidedPin(TQString pin) {
if (m_watcherObject) {
m_watcherObject->setProvidedPin(pin);
}
}
TQString TDECryptographicCardDevice::autoPIN() {
#if defined(WITH_PKCS)
TQString retString = TQString::null;
// Use subjAltName field in card certificate to provide the card's PIN,
// in order to support optional pin-less operation.
// Parse the TDE autologin extension
// Structure:
// OID 1.3.6.1.4.1.40364.1.2.1
// SEQUENCE
// ASN1_CONSTRUCTED [index: 0] (field name: pin)
// GeneralString
// Register custom OID type for TDE autopin data
ASN1_OBJECT* tde_autopin_data_object = OBJ_txt2obj("1.3.6.1.4.1.40364.1.2.1", 0);
int i;
X509CertificatePtrListIterator it;
for (it = m_cardCertificates.begin(); it != m_cardCertificates.end(); ++it) {
X509* x509_cert = *it;
GENERAL_NAMES* subjectAltNames = (GENERAL_NAMES*)X509_get_ext_d2i(x509_cert, NID_subject_alt_name, NULL, NULL);
int altNameCount = sk_GENERAL_NAME_num(subjectAltNames);
for (i=0; i < altNameCount; i++) {
GENERAL_NAME* generalName = sk_GENERAL_NAME_value(subjectAltNames, i);
if (generalName->type == GEN_OTHERNAME) {
OTHERNAME* otherName = generalName->d.otherName;
if (!OBJ_cmp(otherName->type_id, tde_autopin_data_object)) {
ASN1_TYPE* asnValue = otherName->value;
if (asnValue) {
// Found autopin structure
ASN1_TYPE* asnSeqValue = NULL;
ASN1_GENERALSTRING* asnGeneralString = NULL;
STACK_OF(ASN1_TYPE) *asnSeqValueStack = NULL;
long asn1SeqValueObjectLength;
int asn1SeqValueObjectTag;
int asn1SeqValueObjectClass;
int returnCode;
int index = 0; // Search for the PIN field
#if OPENSSL_VERSION_NUMBER >= 0x10100000L && !defined(LIBRESSL_VERSION_NUMBER)
const uint8_t* asnSeqValueString = ASN1_STRING_get0_data(asnValue->value.sequence);
asnSeqValueStack = d2i_ASN1_SEQUENCE_ANY(NULL, &asnSeqValueString, ASN1_STRING_length(asnValue->value.sequence));
#else
uint8_t* asnSeqValueString = ASN1_STRING_data(asnValue->value.sequence);
asnSeqValueStack = ASN1_seq_unpack_ASN1_TYPE(asnSeqValueString, ASN1_STRING_length(asnValue->value.sequence), d2i_ASN1_TYPE, ASN1_TYPE_free);
#endif
asnSeqValue = sk_ASN1_TYPE_value(asnSeqValueStack, index);
if (asnSeqValue) {
if (asnSeqValue->value.octet_string->data[0] == ((V_ASN1_CONSTRUCTED | V_ASN1_CONTEXT_SPECIFIC) + index)) {
const unsigned char* asn1SeqValueObjectData = asnSeqValue->value.sequence->data;
returnCode = ASN1_get_object(&asn1SeqValueObjectData, &asn1SeqValueObjectLength, &asn1SeqValueObjectTag, &asn1SeqValueObjectClass, asnSeqValue->value.sequence->length);
if (!(returnCode & 0x80)) {
if (returnCode == (V_ASN1_CONSTRUCTED + index)) {
if (d2i_ASN1_GENERALSTRING(&asnGeneralString, &asn1SeqValueObjectData, asn1SeqValueObjectLength) != NULL) {
#if OPENSSL_VERSION_NUMBER >= 0x10100000L && !defined(LIBRESSL_VERSION_NUMBER)
retString = TQString((const char *)ASN1_STRING_get0_data(asnGeneralString));
#else
retString = TQString((const char *)ASN1_STRING_data(asnGeneralString));
#endif
}
}
}
}
}
#if OPENSSL_VERSION_NUMBER >= 0x10100000L && !defined(LIBRESSL_VERSION_NUMBER)
sk_ASN1_TYPE_pop_free(asnSeqValueStack, ASN1_TYPE_free);
#endif
}
}
}
}
}
// Clean up
OBJ_cleanup();
return retString;
#else
return TQString::null;
#endif
}
void TDECryptographicCardDevice::workerRequestedPin(TQString prompt) {
emit(pinRequested(prompt, this));
}
int TDECryptographicCardDevice::decryptDataEncryptedWithCertPublicKey(TQByteArray &ciphertext, TQByteArray &plaintext, TQString *errstr) {
TQValueList<TQByteArray> cipherTextList;
TQValueList<TQByteArray> plainTextList;
TQValueList<int> retCodeList;
cipherTextList.append(ciphertext);
this->decryptDataEncryptedWithCertPublicKey(cipherTextList, plainTextList, retCodeList, errstr);
plaintext = plainTextList[0];
return retCodeList[0];
}
int TDECryptographicCardDevice::decryptDataEncryptedWithCertPublicKey(TQValueList<TQByteArray> &cipherTextList, TQValueList<TQByteArray> &plainTextList, TQValueList<int> &retcodes, TQString *errstr) {
#if defined(WITH_PKCS)
int ret = -1;
if (!m_watcherObject) {
if (errstr) *errstr = i18n("Card watcher object not available");
return -1;
}
CK_RV rv;
pkcs11h_certificate_id_list_t issuers;
pkcs11h_certificate_id_list_t certs;
if (m_watcherObject->initializePkcs() < 0) {
if (errstr) *errstr = i18n("Unable to initialize PKCS");
return -1;
}
rv = pkcs11h_certificate_enumCertificateIds(PKCS11H_ENUM_METHOD_CACHE, NULL, PKCS11H_PROMPT_MASK_ALLOW_PIN_PROMPT, &issuers, &certs);
if ((rv != CKR_OK) || (certs == NULL)) {
if (errstr) *errstr = i18n("Cannot enumerate certificates: %1").arg(pkcs11h_getMessage(rv));
return -1;
}
int i = 0;
for (pkcs11h_certificate_id_list_t cert = certs; cert != NULL; cert = cert->next) {
TQString label = cert->certificate_id->displayName;
pkcs11h_certificate_t certificate;
rv = pkcs11h_certificate_create(certs->certificate_id, NULL, PKCS11H_PROMPT_MASK_ALLOW_PIN_PROMPT, PKCS11H_PIN_CACHE_INFINITE, &certificate);
if (rv != CKR_OK) {
if (errstr) *errstr = i18n("Cannot read certificate: %1").arg(pkcs11h_getMessage(rv));
pkcs11h_certificate_freeCertificateId(certs->certificate_id);
ret = -1;
break;
}
pkcs11h_certificate_freeCertificateId(certs->certificate_id);
pkcs11h_openssl_session_t openssl_session = NULL;
if ((openssl_session = pkcs11h_openssl_createSession(certificate)) == NULL) {
if (errstr) *errstr = i18n("Cannot initialize openssl session to retrieve cryptographic objects");
pkcs11h_certificate_freeCertificate(certificate);
ret = -1;
break;
}
// Get certificate data
X509* x509_local;
x509_local = pkcs11h_openssl_session_getX509(openssl_session);
if (!x509_local) {
if (errstr) *errstr = i18n("Cannot get X509 object");
ret = -1;
}
// Extract public key from X509 certificate
EVP_PKEY* x509_pubkey = NULL;
RSA* rsa_pubkey = NULL;
x509_pubkey = X509_get_pubkey(x509_local);
if (x509_pubkey) {
rsa_pubkey = EVP_PKEY_get1_RSA(x509_pubkey);
}
// Check PIN
rv = pkcs11h_certificate_ensureKeyAccess(certificate);
if (rv != CKR_OK) {
if (rv == CKR_CANCEL) {
ret = -3;
break;
}
else if ((rv == CKR_PIN_INCORRECT) || (rv == CKR_USER_NOT_LOGGED_IN)) {
ret = -2;
break;
}
else {
ret = -2;
break;
}
}
// We know the cached PIN is correct; disable any further login prompts
m_watcherObject->retrySamePin(true);
TQValueList<TQByteArray>::iterator it;
TQValueList<TQByteArray>::iterator it2;
TQValueList<int>::iterator it3;
plainTextList.clear();
retcodes.clear();
for (it = cipherTextList.begin(); it != cipherTextList.end(); ++it) {
plainTextList.append(TQByteArray());
retcodes.append(-1);
}
for (it = cipherTextList.begin(), it2 = plainTextList.begin(), it3 = retcodes.begin(); it != cipherTextList.end(); ++it, ++it2, ++it3) {
TQByteArray& ciphertext = *it;
TQByteArray& plaintext = *it2;
int& retcode = *it3;
// Verify minimum size
if (ciphertext.size() < 16) {
if (errstr) *errstr = i18n("Cannot decrypt: %1").arg(i18n("Ciphertext too small"));
ret = -2;
retcode = -2;
continue;
}
// Try to get RSA parameters and verify maximum size
if (rsa_pubkey) {
unsigned int rsa_length = RSA_size(rsa_pubkey);
if (ciphertext.size() > rsa_length) {
if (errstr) *errstr = i18n("Cannot decrypt: %1").arg(i18n("Ciphertext too large"));
ret = -2;
retcode = -2;
continue;
}
}
size_t size = 0;
// Determine output buffer size
rv = pkcs11h_certificate_decryptAny(certificate, CKM_RSA_PKCS, (unsigned char*)ciphertext.data(), ciphertext.size(), NULL, &size);
if (rv != CKR_OK) {
if (errstr) *errstr = i18n("Cannot determine decrypted message length: %1 (%2)").arg(pkcs11h_getMessage(rv)).arg(rv);
if (rv == CKR_CANCEL) {
ret = -3;
retcode = -3;
break;
}
else if ((rv == CKR_PIN_INCORRECT) || (rv == CKR_USER_NOT_LOGGED_IN)) {
ret = -2;
retcode = -2;
break;
}
else {
ret = -2;
retcode = -2;
}
}
else {
// Decrypt data
plaintext.resize(size);
rv = pkcs11h_certificate_decryptAny(certificate, CKM_RSA_PKCS, (unsigned char*)ciphertext.data(), ciphertext.size(), (unsigned char*)plaintext.data(), &size);
if (rv != CKR_OK) {
if (errstr) *errstr = i18n("Cannot decrypt: %1 (%2)").arg(pkcs11h_getMessage(rv)).arg(rv);
if (rv == CKR_CANCEL) {
ret = -3;
retcode = -3;
break;
}
else if ((rv == CKR_PIN_INCORRECT) || (rv == CKR_USER_NOT_LOGGED_IN)) {
ret = -2;
retcode = -2;
break;
}
else {
ret = -2;
retcode = -2;
}
}
else {
if (errstr) *errstr = TQString::null;
ret = 0;
retcode = 0;
}
}
}
pkcs11h_openssl_freeSession(openssl_session);
// Only interested in first certificate for now
// FIXME
// If cards with multiple certificates are used this should be modified to try decryption
// using each certificate in turn...
break;
i++;
}
pkcs11h_certificate_freeCertificateIdList(issuers);
// Restore normal login attempt method
m_watcherObject->retrySamePin(false);
return ret;
#else
return -1;
#endif
}
int TDECryptographicCardDevice::createNewSecretRSAKeyFromCertificate(TQByteArray &plaintext, TQByteArray &ciphertext, X509* certificate) {
#if defined(WITH_PKCS)
unsigned int i;
int retcode = -1;
// Extract public key from X509 certificate
EVP_PKEY* x509_pubkey = NULL;
RSA* rsa_pubkey = NULL;
x509_pubkey = X509_get_pubkey(certificate);
if (x509_pubkey) {
rsa_pubkey = EVP_PKEY_get1_RSA(x509_pubkey);
}
if (rsa_pubkey) {
// Determine encryption parameters
// NOTE
// RSA_PKCS1_OAEP_PADDING is preferred but cannot be decoded from
// the command line via openssl at this time of this writing.
int rsa_padding_style = RSA_PKCS1_PADDING;
unsigned int rsa_length = RSA_size(rsa_pubkey);
unsigned int max_key_length = rsa_length - 41;
// Create a new random key as the plaintext
plaintext.resize(max_key_length);
for (i=0; i < max_key_length; i++) {
plaintext[i] = TDEApplication::random();
}
// Encrypt data
ciphertext.resize(rsa_length);
if (RSA_public_encrypt(plaintext.size(), (unsigned char *)plaintext.data(), (unsigned char *)ciphertext.data(), rsa_pubkey, rsa_padding_style) < 0) {
retcode = -2;
}
// Success!
retcode = 0;
}
// Clean up
if (rsa_pubkey) {
RSA_free(rsa_pubkey);
}
if (x509_pubkey) {
EVP_PKEY_free(x509_pubkey);
}
return retcode;
#else
return -1;
#endif
}
TQString TDECryptographicCardDevice::pkcsProviderLibrary() {
#if defined(WITH_PKCS)
return OPENSC_PKCS11_PROVIDER_LIBRARY;
#else
return TQString::null;
#endif
}
#include "tdecryptographiccarddevice.moc"
#include "tdecryptographiccarddevice_private.moc"