#include <sys/types.h> #include <string.h> #include <unistd.h> #include <stdlib.h> #include <stdio.h> #ifdef CACKEY_TEST_AFL #include <sys/types.h> #include <fcntl.h> static unsigned char *inputData; static unsigned long inputDataLen; /* Include the CACKey source */ #include "cackey.c" #undef CACKEY_DEBUG_PRINTF #define CACKEY_DEBUG_PRINTF(x...) /**/ #undef malloc #undef realloc #undef strdup /* Fake a smartcard */ const SCARD_IO_REQUEST g_rgSCardT0Pci, g_rgSCardT1Pci; static int scard_inTransaction = 0; static LONG scard_protocol; PCSC_API LONG SCardEstablishContext(DWORD dwScope, LPCVOID pvReserved1, LPCVOID pvReserved2, LPSCARDCONTEXT phContext) { CACKEY_DEBUG_PRINTF("Called"); *phContext = 42; return(SCARD_S_SUCCESS); } PCSC_API LONG SCardIsValidContext(SCARDCONTEXT hContext) { CACKEY_DEBUG_PRINTF("Called"); if (hContext != 42) { return(SCARD_E_INVALID_HANDLE); } return(SCARD_S_SUCCESS); } PCSC_API LONG SCardListReaders(SCARDCONTEXT hContext, LPCSTR mszGroups, LPSTR mszReaders, LPDWORD pcchReaders) { static char *readers = "READER0"; CACKEY_DEBUG_PRINTF("Called"); if (hContext != 42) { return(SCARD_E_INVALID_HANDLE); } *pcchReaders = strlen(readers) + 1; if (mszReaders == NULL) { return(SCARD_S_SUCCESS); } memcpy(mszReaders, readers, *pcchReaders); return(SCARD_S_SUCCESS); } PCSC_API LONG SCardBeginTransaction(SCARDHANDLE hCard) { CACKEY_DEBUG_PRINTF("Called"); if (hCard != 99) { return(SCARD_E_INVALID_HANDLE); } if (scard_inTransaction) { return(SCARD_E_SHARING_VIOLATION); } scard_inTransaction = 1; return(SCARD_S_SUCCESS); } PCSC_API LONG SCardEndTransaction(SCARDHANDLE hCard, DWORD dwDisposition) { CACKEY_DEBUG_PRINTF("Called"); if (hCard != 99) { return(SCARD_E_INVALID_HANDLE); } scard_inTransaction = 0; return(SCARD_S_SUCCESS); } PCSC_API LONG SCardStatus(SCARDHANDLE hCard, LPSTR mszReaderName, LPDWORD pcchReaderLen, LPDWORD pdwState, LPDWORD pdwProtocol, LPBYTE pbAtr, LPDWORD pcbAtrLen) { LONG scardlistreaders_ret; CACKEY_DEBUG_PRINTF("Called"); if (hCard != 99) { return(SCARD_E_INVALID_HANDLE); } *pdwState = 0; scardlistreaders_ret = SCardListReaders(42, NULL, mszReaderName, pcchReaderLen); if (scardlistreaders_ret != SCARD_S_SUCCESS) { return(scardlistreaders_ret); } *pdwProtocol = scard_protocol; return(SCARD_S_SUCCESS); } PCSC_API LONG SCardConnect(SCARDCONTEXT hContext, LPCSTR szReader, DWORD dwShareMode, DWORD dwPreferredProtocols, LPSCARDHANDLE phCard, LPDWORD pdwActiveProtocol) { CACKEY_DEBUG_PRINTF("Called"); if (hContext != 42) { return(SCARD_E_INVALID_HANDLE); } if ((dwPreferredProtocols & SCARD_PROTOCOL_T0) == SCARD_PROTOCOL_T0) { *pdwActiveProtocol = SCARD_PROTOCOL_T0; } else { *pdwActiveProtocol = SCARD_PROTOCOL_T1; } scard_protocol = *pdwActiveProtocol; *phCard = 99; return(SCARD_S_SUCCESS); } PCSC_API LONG SCardDisconnect(SCARDHANDLE hCard, DWORD dwDisposition) { CACKEY_DEBUG_PRINTF("Called"); if (hCard != 99) { return(SCARD_E_INVALID_HANDLE); } return(SCARD_S_SUCCESS); } PCSC_API LONG SCardReconnect(SCARDHANDLE hCard, DWORD dwShareMode, DWORD dwPreferredProtocols, DWORD dwInitialization, LPDWORD pdwActiveProtocol) { CACKEY_DEBUG_PRINTF("Called"); if (hCard != 99) { return(SCARD_E_INVALID_HANDLE); } return(SCardConnect(42, NULL, dwShareMode, dwPreferredProtocols, NULL, pdwActiveProtocol)); } PCSC_API LONG SCardReleaseContext(SCARDCONTEXT hContext) { CACKEY_DEBUG_PRINTF("Called"); if (hContext != 42) { return(SCARD_E_INVALID_HANDLE); } return(SCARD_S_SUCCESS); } PCSC_API LONG SCardTransmit(SCARDHANDLE hCard, const SCARD_IO_REQUEST *pioSendPci, LPCBYTE pbSendBuffer, DWORD cbSendLength, SCARD_IO_REQUEST *pioRecvPci, LPBYTE pbRecvBuffer, LPDWORD pcbRecvLength) { CACKEY_DEBUG_PRINTF("Called"); unsigned int bytesToRead; if (hCard != 99) { return(SCARD_E_INVALID_HANDLE); } if (inputDataLen <= 1) { *pcbRecvLength = 0; return(SCARD_S_SUCCESS); } bytesToRead = (inputData[0] << 8) | inputData[1]; inputData += 2; inputDataLen -= 2; if (bytesToRead > inputDataLen) { bytesToRead = inputDataLen; } if (bytesToRead > *pcbRecvLength) { return(SCARD_E_INSUFFICIENT_BUFFER); } *pcbRecvLength = bytesToRead; memcpy(pbRecvBuffer, inputData, bytesToRead); inputData += bytesToRead; inputDataLen -= bytesToRead; return(SCARD_S_SUCCESS); } static void loadTestData(const char *fileName) { ssize_t read_ret; int fd; if (fileName == NULL) { goto cleanup; } fd = open(fileName, O_RDONLY); if (fd < 0) { goto cleanup; } inputDataLen = 16384; inputData = malloc(inputDataLen); read_ret = read(fd, inputData, inputDataLen); if (read_ret < 0) { goto cleanup; } inputDataLen = read_ret; inputData = realloc(inputData, inputDataLen); close(fd); cleanup: return; } #else #include "mypkcs11.h" static void loadTestData(const char *filename) { return; } #endif static char *pkcs11_attribute_to_name(CK_ATTRIBUTE_TYPE attrib) { static char retbuf[1024]; switch (attrib) { case 0x00000000: return "CKA_CLASS"; case 0x00000001: return "CKA_TOKEN"; case 0x00000002: return "CKA_PRIVATE"; case 0x00000003: return "CKA_LABEL"; case 0x00000010: return "CKA_APPLICATION"; case 0x00000011: return "CKA_VALUE"; case 0x00000012: return "CKA_OBJECT_ID"; case 0x00000080: return "CKA_CERTIFICATE_TYPE"; case 0x00000081: return "CKA_ISSUER"; case 0x00000082: return "CKA_SERIAL_NUMBER"; case 0x00000083: return "CKA_AC_ISSUER"; case 0x00000084: return "CKA_OWNER"; case 0x00000085: return "CKA_ATTR_TYPES"; case 0x00000086: return "CKA_TRUSTED"; case 0x00000100: return "CKA_KEY_TYPE"; case 0x00000101: return "CKA_SUBJECT"; case 0x00000102: return "CKA_ID"; case 0x00000103: return "CKA_SENSITIVE"; case 0x00000104: return "CKA_ENCRYPT"; case 0x00000105: return "CKA_DECRYPT"; case 0x00000106: return "CKA_WRAP"; case 0x00000107: return "CKA_UNWRAP"; case 0x00000108: return "CKA_SIGN"; case 0x00000109: return "CKA_SIGN_RECOVER"; case 0x0000010A: return "CKA_VERIFY"; case 0x0000010B: return "CKA_VERIFY_RECOVER"; case 0x0000010C: return "CKA_DERIVE"; case 0x00000110: return "CKA_START_DATE"; case 0x00000111: return "CKA_END_DATE"; case 0x00000120: return "CKA_MODULUS"; case 0x00000121: return "CKA_MODULUS_BITS"; case 0x00000122: return "CKA_PUBLIC_EXPONENT"; case 0x00000123: return "CKA_PRIVATE_EXPONENT"; case 0x00000124: return "CKA_PRIME_1"; case 0x00000125: return "CKA_PRIME_2"; case 0x00000126: return "CKA_EXPONENT_1"; case 0x00000127: return "CKA_EXPONENT_2"; case 0x00000128: return "CKA_COEFFICIENT"; case 0x00000130: return "CKA_PRIME"; case 0x00000131: return "CKA_SUBPRIME"; case 0x00000132: return "CKA_BASE"; case 0x00000133: return "CKA_PRIME_BITS"; case 0x00000134: return "CKA_SUB_PRIME_BITS"; case 0x00000160: return "CKA_VALUE_BITS"; case 0x00000161: return "CKA_VALUE_LEN"; case 0x00000162: return "CKA_EXTRACTABLE"; case 0x00000163: return "CKA_LOCAL"; case 0x00000164: return "CKA_NEVER_EXTRACTABLE"; case 0x00000165: return "CKA_ALWAYS_SENSITIVE"; case 0x00000166: return "CKA_KEY_GEN_MECHANISM"; case 0x00000170: return "CKA_MODIFIABLE"; case 0x00000180: return "CKA_EC_PARAMS"; case 0x00000181: return "CKA_EC_POINT"; case 0x00000200: return "CKA_SECONDARY_AUTH"; case 0x00000201: return "CKA_AUTH_PIN_FLAGS"; case 0x00000300: return "CKA_HW_FEATURE_TYPE"; case 0x00000301: return "CKA_RESET_ON_INIT"; case 0x00000302: return "CKA_HAS_RESET"; case 0xce5363b4: return "CKA_CERT_SHA1_HASH"; case 0xce5363b5: return "CKA_CERT_MD5_HASH"; } snprintf(retbuf, sizeof(retbuf), "0x%08lx", (unsigned long) attrib); retbuf[sizeof(retbuf) - 1] = '\0'; return(retbuf); } int main_pkcs11(void) { CK_FUNCTION_LIST_PTR pFunctionList; CK_RV (*C_CloseSession)(CK_SESSION_HANDLE hSession) = NULL; CK_RV (*C_Decrypt)(CK_SESSION_HANDLE hSession, CK_BYTE_PTR pEncryptedData, CK_ULONG ulEncryptedDataLen, CK_BYTE_PTR pData, CK_ULONG_PTR pulDataLen) = NULL; CK_RV (*C_DecryptInit)(CK_SESSION_HANDLE hSession, CK_MECHANISM_PTR pMechanism, CK_OBJECT_HANDLE hKey) = NULL; CK_RV (*C_Encrypt)(CK_SESSION_HANDLE hSession, CK_BYTE_PTR pData, CK_ULONG ulDataLen, CK_BYTE_PTR pEncryptedData, CK_ULONG_PTR pulEncryptedDataLen) = NULL; CK_RV (*C_EncryptInit)(CK_SESSION_HANDLE hSession, CK_MECHANISM_PTR pMechanism, CK_OBJECT_HANDLE hKey) = NULL; CK_RV (*C_Finalize)(CK_VOID_PTR pReserved) = NULL; CK_RV (*C_FindObjects)(CK_SESSION_HANDLE hSession, CK_OBJECT_HANDLE_PTR phObject, CK_ULONG ulMaxObjectCount, CK_ULONG_PTR pulObjectCount) = NULL; CK_RV (*C_FindObjectsFinal)(CK_SESSION_HANDLE hSession) = NULL; CK_RV (*C_FindObjectsInit)(CK_SESSION_HANDLE hSession, CK_ATTRIBUTE_PTR pTemplate, CK_ULONG ulCount) = NULL; CK_RV (*C_GetAttributeValue)(CK_SESSION_HANDLE hSession, CK_OBJECT_HANDLE hObject, CK_ATTRIBUTE_PTR pTemplate, CK_ULONG ulCount) = NULL; CK_RV (*C_GetInfo)(CK_INFO_PTR pInfo) = NULL; CK_RV (*C_GetSessionInfo)(CK_SESSION_HANDLE hSession, CK_SESSION_INFO_PTR pInfo) = NULL; CK_RV (*C_GetSlotInfo)(CK_SLOT_ID slotID, CK_SLOT_INFO_PTR pInfo) = NULL; CK_RV (*C_GetSlotList)(CK_BBOOL tokenPresent, CK_SLOT_ID_PTR pSlotList, CK_ULONG_PTR pulCount) = NULL; CK_RV (*C_GetTokenInfo)(CK_SLOT_ID slotID, CK_TOKEN_INFO_PTR pInfo) = NULL; CK_RV (*C_Initialize)(CK_VOID_PTR pInitArgs) = NULL; CK_RV (*C_Login)(CK_SESSION_HANDLE hSession, CK_USER_TYPE userType, CK_UTF8CHAR_PTR pPin, CK_ULONG ulPinLen) = NULL; CK_RV (*C_OpenSession)(CK_SLOT_ID slotID, CK_FLAGS flags, CK_VOID_PTR pApplication, CK_NOTIFY notify, CK_SESSION_HANDLE_PTR phSession) = NULL; CK_RV (*C_Sign)(CK_SESSION_HANDLE hSession, CK_BYTE_PTR pData, CK_ULONG ulDataLen, CK_BYTE_PTR pSignature, CK_ULONG_PTR pulSignatureLen) = NULL; CK_RV (*C_SignInit)(CK_SESSION_HANDLE hSession, CK_MECHANISM_PTR pMechanism, CK_OBJECT_HANDLE hKey) = NULL; CK_C_INITIALIZE_ARGS initargs; CK_INFO clientinfo; CK_ULONG numSlots, currSlot; CK_SLOT_ID_PTR slots; CK_SLOT_INFO slotInfo; CK_TOKEN_INFO tokenInfo; CK_SESSION_HANDLE hSession; CK_SESSION_INFO sessionInfo; CK_OBJECT_HANDLE hObject, *privateKeyObjects_root, *privateKeyObjects, *currPrivKey; CK_ULONG ulObjectCount; CK_ATTRIBUTE template[] = { {CKA_CLASS, NULL, 0}, {CKA_TOKEN, NULL, 0}, {CKA_LABEL, NULL, 0}, {CKA_PRIVATE, NULL, 0}, {CKA_ID, NULL, 0}, {CKA_SERIAL_NUMBER, NULL, 0}, {CKA_SUBJECT, NULL, 0}, {CKA_ISSUER, NULL, 0}, {CKA_CERTIFICATE_TYPE, NULL, 0}, {CKA_KEY_TYPE, NULL, 0}, {CKA_SIGN, NULL, 0}, {CKA_VALUE, NULL, 0}, {CKA_CERT_MD5_HASH, NULL, 0}, {CKA_CERT_SHA1_HASH, NULL, 0}, {CKA_TRUSTED, NULL, 0}, {CKA_TRUST_CLIENT_AUTH, NULL, 0}, {CKA_TRUST_CODE_SIGNING, NULL, 0}, {CKA_TRUST_CRL_SIGN, NULL, 0}, {CKA_TRUST_DATA_ENCIPHERMENT, NULL, 0}, {CKA_TRUST_DIGITAL_SIGNATURE, NULL, 0}, {CKA_TRUST_EMAIL_PROTECTION, NULL, 0}, {CKA_TRUST_KEY_AGREEMENT, NULL, 0}, {CKA_TRUST_KEY_CERT_SIGN, NULL, 0}, {CKA_TRUST_KEY_ENCIPHERMENT, NULL, 0}, {CKA_TRUST_NON_REPUDIATION, NULL, 0}, {CKA_TRUST_SERVER_AUTH, NULL, 0} }, *curr_attr; CK_ULONG curr_attr_idx; CK_ULONG byte_idx; CK_UTF8CHAR user_pin[1024], *pucValue; CK_OBJECT_CLASS objectClass; CK_BYTE signature[1024], encrypted_buf[16384], decrypted_buf[16384]; CK_ULONG signature_len, encrypted_buflen, decrypted_buflen; CK_MECHANISM mechanism = {CKM_RSA_PKCS, NULL, 0}; CK_RV chk_rv; char *fgets_ret; int i; chk_rv = C_GetFunctionList(&pFunctionList); if (chk_rv != CKR_OK) { printf("C_GetFunctionList() failed."); return(1); } C_CloseSession = pFunctionList->C_CloseSession; C_Decrypt = pFunctionList->C_Decrypt; C_DecryptInit = pFunctionList->C_DecryptInit; C_Encrypt = pFunctionList->C_Encrypt; C_EncryptInit = pFunctionList->C_EncryptInit; C_Finalize = pFunctionList->C_Finalize; C_FindObjects = pFunctionList->C_FindObjects; C_FindObjectsFinal = pFunctionList->C_FindObjectsFinal; C_FindObjectsInit = pFunctionList->C_FindObjectsInit; C_GetAttributeValue = pFunctionList->C_GetAttributeValue; C_GetInfo = pFunctionList->C_GetInfo; C_GetSessionInfo = pFunctionList->C_GetSessionInfo; C_GetSlotInfo = pFunctionList->C_GetSlotInfo; C_GetSlotList = pFunctionList->C_GetSlotList; C_GetTokenInfo = pFunctionList->C_GetTokenInfo; C_Initialize = pFunctionList->C_Initialize; C_Login = pFunctionList->C_Login; C_OpenSession = pFunctionList->C_OpenSession; C_Sign = pFunctionList->C_Sign; C_SignInit = pFunctionList->C_SignInit; privateKeyObjects = malloc(sizeof(*privateKeyObjects) * 1024); privateKeyObjects_root = privateKeyObjects; for (i = 0; i < 1024; i++) { privateKeyObjects[i] = CK_INVALID_HANDLE; } initargs.CreateMutex = NULL; initargs.DestroyMutex = NULL; initargs.LockMutex = NULL; initargs.UnlockMutex = NULL; initargs.flags = CKF_OS_LOCKING_OK; initargs.pReserved = NULL; chk_rv = C_Initialize(&initargs); if (chk_rv != CKR_OK) { initargs.CreateMutex = NULL; initargs.DestroyMutex = NULL; initargs.LockMutex = NULL; initargs.UnlockMutex = NULL; initargs.flags = 0; initargs.pReserved = NULL; chk_rv = C_Initialize(&initargs); if (chk_rv != CKR_OK) { printf("C_Initialize() failed."); return(1); } } chk_rv = C_GetInfo(&clientinfo); if (chk_rv != CKR_OK) { return(1); } printf("PKCS#11 Client Version: %i.%i, Library Version %i.%i\n", clientinfo.cryptokiVersion.major, clientinfo.cryptokiVersion.minor, clientinfo.libraryVersion.major, clientinfo.libraryVersion.minor); printf("PKCS#11 ManufID: %.*s, LibraryDesc: %.*s\n", 32, clientinfo.manufacturerID, 32, clientinfo.libraryDescription); chk_rv = C_GetSlotList(FALSE, NULL, &numSlots); if (chk_rv != CKR_OK) { return(1); } printf("Number of Slots: %lu\n", numSlots); slots = malloc(sizeof(*slots) * numSlots); chk_rv = C_GetSlotList(FALSE, slots, &numSlots); if (chk_rv != CKR_OK) { return(1); } for (currSlot = 0; currSlot < numSlots; currSlot++) { printf(" Slot %lu:\n", currSlot); chk_rv = C_GetSlotInfo(slots[currSlot], &slotInfo); if (chk_rv != CKR_OK) { return(1); } printf(" Id : %lu\n", (unsigned long) slots[currSlot]); printf(" Desc : %.*s\n", 32, slotInfo.slotDescription); printf(" ManufID: %.*s\n", 32, slotInfo.manufacturerID); printf(" HWVers : %i.%i\n", slotInfo.hardwareVersion.major, slotInfo.hardwareVersion.minor); printf(" FWVers : %i.%i\n", slotInfo.firmwareVersion.major, slotInfo.firmwareVersion.minor); printf(" Flags : "); if ((slotInfo.flags & CKF_TOKEN_PRESENT) == CKF_TOKEN_PRESENT) { printf("CKF_TOKEN_PRESENT "); } if ((slotInfo.flags & CKF_REMOVABLE_DEVICE) == CKF_REMOVABLE_DEVICE) { printf("CKF_REMOVABLE_DEVICE "); } if ((slotInfo.flags & CKF_HW_SLOT) == CKF_HW_SLOT) { printf("CKF_HW_SLOT "); } printf("\n"); if ((slotInfo.flags & CKF_TOKEN_PRESENT) == CKF_TOKEN_PRESENT) { printf(" Token:\n"); chk_rv = C_GetTokenInfo(slots[currSlot], &tokenInfo); if (chk_rv != CKR_OK) { return(1); } printf(" Label : %.*s\n", 32, tokenInfo.label); printf(" ManufID: %.*s\n", 32, tokenInfo.manufacturerID); printf(" Model : %.*s\n", 16, tokenInfo.model); printf(" SerNo : %.*s\n", 16, tokenInfo.serialNumber); printf(" HWVers : %i.%i\n", tokenInfo.hardwareVersion.major, tokenInfo.hardwareVersion.minor); printf(" FWVers : %i.%i\n", tokenInfo.firmwareVersion.major, tokenInfo.firmwareVersion.minor); printf(" Flags : "); if ((tokenInfo.flags & CKF_RNG) == CKF_RNG) { printf("CKF_RNG "); } if ((tokenInfo.flags & CKF_WRITE_PROTECTED) == CKF_WRITE_PROTECTED) { printf("CKF_WRITE_PROTECTED "); } if ((tokenInfo.flags & CKF_LOGIN_REQUIRED) == CKF_LOGIN_REQUIRED) { printf("CKF_LOGIN_REQUIRED "); } if ((tokenInfo.flags & CKF_USER_PIN_INITIALIZED) == CKF_USER_PIN_INITIALIZED) { printf("CKF_USER_PIN_INITIALIZED "); } if ((tokenInfo.flags & CKF_RESTORE_KEY_NOT_NEEDED) == CKF_RESTORE_KEY_NOT_NEEDED) { printf("CKF_RESTORE_KEY_NOT_NEEDED "); } if ((tokenInfo.flags & CKF_CLOCK_ON_TOKEN) == CKF_CLOCK_ON_TOKEN) { printf("CKF_CLOCK_ON_TOKEN "); } if ((tokenInfo.flags & CKF_PROTECTED_AUTHENTICATION_PATH) == CKF_PROTECTED_AUTHENTICATION_PATH) { printf("CKF_PROTECTED_AUTHENTICATION_PATH "); } if ((tokenInfo.flags & CKF_DUAL_CRYPTO_OPERATIONS) == CKF_DUAL_CRYPTO_OPERATIONS) { printf("CKF_DUAL_CRYPTO_OPERATIONS "); } if ((tokenInfo.flags & CKF_TOKEN_INITIALIZED) == CKF_TOKEN_INITIALIZED) { printf("CKF_TOKEN_INITIALIZED "); } if ((tokenInfo.flags & CKF_SECONDARY_AUTHENTICATION) == CKF_SECONDARY_AUTHENTICATION) { printf("CKF_SECONDARY_AUTHENTICATION "); } if ((tokenInfo.flags & CKF_USER_PIN_COUNT_LOW) == CKF_USER_PIN_COUNT_LOW) { printf("CKF_USER_PIN_COUNT_LOW "); } if ((tokenInfo.flags & CKF_USER_PIN_FINAL_TRY) == CKF_USER_PIN_FINAL_TRY) { printf("CKF_USER_PIN_FINAL_TRY "); } if ((tokenInfo.flags & CKF_USER_PIN_LOCKED) == CKF_USER_PIN_LOCKED) { printf("CKF_USER_PIN_LOCKED "); } if ((tokenInfo.flags & CKF_USER_PIN_TO_BE_CHANGED) == CKF_USER_PIN_TO_BE_CHANGED) { printf("CKF_USER_PIN_TO_BE_CHANGED "); } if ((tokenInfo.flags & CKF_SO_PIN_COUNT_LOW) == CKF_SO_PIN_COUNT_LOW) { printf("CKF_SO_PIN_COUNT_LOW "); } if ((tokenInfo.flags & CKF_SO_PIN_FINAL_TRY) == CKF_SO_PIN_FINAL_TRY) { printf("CKF_SO_PIN_FINAL_TRY "); } if ((tokenInfo.flags & CKF_SO_PIN_LOCKED) == CKF_SO_PIN_LOCKED) { printf("CKF_SO_PIN_LOCKED "); } if ((tokenInfo.flags & CKF_SO_PIN_TO_BE_CHANGED) == CKF_SO_PIN_TO_BE_CHANGED) { printf("CKF_SO_PIN_TO_BE_CHANGED "); } printf("\n"); } } chk_rv = C_OpenSession(slots[0], CKF_SERIAL_SESSION, NULL, NULL, &hSession); if (chk_rv == CKR_OK) { chk_rv = C_GetTokenInfo(slots[0], &tokenInfo); if (chk_rv != CKR_OK) { return(1); } if ((tokenInfo.flags & CKF_LOGIN_REQUIRED) == CKF_LOGIN_REQUIRED && (tokenInfo.flags & CKF_PROTECTED_AUTHENTICATION_PATH) == 0) { fgets_ret = NULL; while (fgets_ret == NULL) { printf("** ENTER PIN: "); fflush(stdout); #ifdef CACKEY_TEST_AFL memcpy(user_pin, "0000000", 8); fgets_ret = (char *) user_pin; #else fgets_ret = fgets((char *) user_pin, sizeof(user_pin), stdin); #endif } if (strlen((char *) user_pin) >= 1) { while (user_pin[strlen((char *) user_pin) - 1] < ' ') { user_pin[strlen((char *) user_pin) - 1] = '\0'; } } chk_rv = C_Login(hSession, CKU_USER, user_pin, strlen((char *) user_pin)); } else { chk_rv = C_Login(hSession, CKU_USER, NULL, 0); } if (chk_rv == CKR_OK) { printf("Login to device succeed.\n"); } else { printf("Login to device failed.\n"); } chk_rv = C_GetSessionInfo(hSession, &sessionInfo); if (chk_rv == CKR_OK) { printf("Session Info:\n"); printf(" Slot ID: %lu\n", (unsigned long) sessionInfo.slotID); printf(" Dev Err: %lu\n", (unsigned long) sessionInfo.ulDeviceError); printf(" State : "); if (sessionInfo.state == CKS_RO_PUBLIC_SESSION) { printf("CKS_RO_PUBLIC_SESSION\n"); } else if (sessionInfo.state == CKS_RO_USER_FUNCTIONS) { printf("CKS_RO_USER_FUNCTIONS\n"); } else if (sessionInfo.state == CKS_RW_PUBLIC_SESSION) { printf("CKS_RW_PUBLIC_SESSION\n"); } else if (sessionInfo.state == CKS_RW_USER_FUNCTIONS) { printf("CKS_RW_USER_FUNCTIONS\n"); } else if (sessionInfo.state == CKS_RO_PUBLIC_SESSION) { printf("CKS_RW_SO_FUNCTIONS\n"); } else { printf("Unknown (%lu)", (unsigned long) sessionInfo.state); } printf(" Flags : "); if ((sessionInfo.flags & CKF_RW_SESSION) == CKF_RW_SESSION) { printf("CKF_RW_SESSION "); } if ((sessionInfo.flags & CKF_SERIAL_SESSION) == CKF_SERIAL_SESSION) { printf("CKF_SERIAL_SESSION "); } printf("\n"); } else { printf("GetSessionInfo() failed.\n"); } chk_rv = C_FindObjectsInit(hSession, NULL, 0); if (chk_rv == CKR_OK) { while (1) { chk_rv = C_FindObjects(hSession, &hObject, 1, &ulObjectCount); if (chk_rv != CKR_OK) { printf("FindObjects() failed.\n"); break; } if (ulObjectCount == 0) { break; } if (ulObjectCount != 1) { printf("FindObjects() returned a weird number of objects. Asked for 1, got %lu.\n", ulObjectCount); break; } printf(" Object Info (object %lu):\n", (unsigned long) hObject); for (curr_attr_idx = 0; curr_attr_idx < (sizeof(template) / sizeof(template[0])); curr_attr_idx++) { curr_attr = &template[curr_attr_idx]; if (curr_attr->pValue) { free(curr_attr->pValue); } curr_attr->pValue = NULL; } chk_rv = C_GetAttributeValue(hSession, hObject, &template[0], sizeof(template) / sizeof(template[0])); if (chk_rv == CKR_ATTRIBUTE_TYPE_INVALID || chk_rv == CKR_ATTRIBUTE_SENSITIVE || chk_rv == CKR_BUFFER_TOO_SMALL) { chk_rv = CKR_OK; } if (chk_rv == CKR_OK) { for (curr_attr_idx = 0; curr_attr_idx < (sizeof(template) / sizeof(template[0])); curr_attr_idx++) { curr_attr = &template[curr_attr_idx]; if (((CK_LONG) curr_attr->ulValueLen) != ((CK_LONG) -1)) { curr_attr->pValue = malloc(curr_attr->ulValueLen); } } chk_rv = C_GetAttributeValue(hSession, hObject, &template[0], sizeof(template) / sizeof(template[0])); if (chk_rv == CKR_OK || chk_rv == CKR_ATTRIBUTE_SENSITIVE || chk_rv == CKR_ATTRIBUTE_TYPE_INVALID || chk_rv == CKR_BUFFER_TOO_SMALL) { for (curr_attr_idx = 0; curr_attr_idx < (sizeof(template) / sizeof(template[0])); curr_attr_idx++) { curr_attr = &template[curr_attr_idx]; if (curr_attr->pValue) { switch (curr_attr->type) { case CKA_LABEL: printf(" [%lu] %20s: %.*s\n", hObject, pkcs11_attribute_to_name(curr_attr->type), (int) curr_attr->ulValueLen, (char *) curr_attr->pValue); break; case CKA_CLASS: objectClass = *((CK_OBJECT_CLASS *) curr_attr->pValue); if (objectClass == CKO_PRIVATE_KEY) { *privateKeyObjects = hObject; privateKeyObjects++; } case CKA_TOKEN: case CKA_ID: case CKA_SERIAL_NUMBER: case CKA_PRIVATE: case CKA_CERTIFICATE_TYPE: case CKA_KEY_TYPE: case CKA_SIGN: case CKA_DECRYPT: case CKA_TRUSTED: case CKA_CERT_MD5_HASH: case CKA_CERT_SHA1_HASH: pucValue = curr_attr->pValue; printf(" [%lu] %20s: ", hObject, pkcs11_attribute_to_name(curr_attr->type)); for (byte_idx = 0; byte_idx < curr_attr->ulValueLen; byte_idx++) { printf("%02x ", (unsigned int) pucValue[byte_idx]); } printf(";; %p/%lu\n", curr_attr->pValue, curr_attr->ulValueLen); break; case CKA_SUBJECT: case CKA_ISSUER: pucValue = curr_attr->pValue; printf(" [%lu] %20s: ", hObject, pkcs11_attribute_to_name(curr_attr->type)); for (byte_idx = 0; byte_idx < curr_attr->ulValueLen; byte_idx++) { printf("\\x%02x", (unsigned int) pucValue[byte_idx]); } printf(" ;; %p/%lu\n", curr_attr->pValue, curr_attr->ulValueLen); break; case CKA_TRUST_CLIENT_AUTH: case CKA_TRUST_CODE_SIGNING: case CKA_TRUST_CRL_SIGN: case CKA_TRUST_DATA_ENCIPHERMENT: case CKA_TRUST_DIGITAL_SIGNATURE: case CKA_TRUST_EMAIL_PROTECTION: case CKA_TRUST_KEY_AGREEMENT: case CKA_TRUST_KEY_CERT_SIGN: case CKA_TRUST_KEY_ENCIPHERMENT: case CKA_TRUST_NON_REPUDIATION: case CKA_TRUST_SERVER_AUTH: break; default: printf(" [%lu] %20s: %p/%lu\n", hObject, pkcs11_attribute_to_name(curr_attr->type), curr_attr->pValue, curr_attr->ulValueLen); break; } } else { printf(" [%lu] %20s: (not found)\n", hObject, pkcs11_attribute_to_name(curr_attr->type)); } free(curr_attr->pValue); curr_attr->pValue = NULL; } } else { printf("GetAttributeValue()/2 failed.\n"); } } else { printf("GetAttributeValue(hObject=%lu)/1 failed (rv = %lu).\n", (unsigned long) hObject, (unsigned long) chk_rv); } } chk_rv = C_FindObjectsFinal(hSession); if (chk_rv != CKR_OK) { printf("FindObjectsFinal() failed.\n"); } } else { printf("FindObjectsInit() failed.\n"); } printf("--- Operations ---\n"); for (currPrivKey = privateKeyObjects_root; *currPrivKey != CK_INVALID_HANDLE; currPrivKey++) { chk_rv = C_SignInit(hSession, &mechanism, *currPrivKey); if (chk_rv == CKR_OK) { signature_len = sizeof(signature); chk_rv = C_Sign(hSession, (CK_BYTE_PTR) "Test", strlen("Test"), (CK_BYTE_PTR) &signature, &signature_len); if (chk_rv == CKR_OK) { printf("[%04lu/%02lx] Signature: ", (unsigned long) *currPrivKey, (unsigned long) mechanism.mechanism); for (byte_idx = 0; byte_idx < signature_len; byte_idx++) { printf("%02x ", (unsigned int) signature[byte_idx]); } printf("\n"); } else { printf("Sign() failed.\n"); } } else { printf("SignInit() failed.\n"); } } for (currPrivKey = privateKeyObjects_root; *currPrivKey != CK_INVALID_HANDLE; currPrivKey++) { chk_rv = C_EncryptInit(hSession, &mechanism, *currPrivKey); if (chk_rv == CKR_OK) { encrypted_buflen = sizeof(encrypted_buf); chk_rv = C_Encrypt(hSession, (CK_BYTE_PTR) "Test", strlen("Test"), encrypted_buf, &encrypted_buflen); if (chk_rv == CKR_OK) { printf("[%04lu/%02lx] Encrypted(Test): ", (unsigned long) *currPrivKey, (unsigned long) mechanism.mechanism); for (byte_idx = 0; byte_idx < encrypted_buflen; byte_idx++) { printf("%02x ", (unsigned int) encrypted_buf[byte_idx]); } printf("\n"); } else { printf("Encrypt() failed.\n"); } } else { printf("EncryptInit() failed.\n"); } } for (currPrivKey = privateKeyObjects_root; *currPrivKey != CK_INVALID_HANDLE; currPrivKey++) { chk_rv = C_DecryptInit(hSession, &mechanism, *currPrivKey); if (chk_rv == CKR_OK) { decrypted_buflen = sizeof(decrypted_buf); chk_rv = C_Decrypt(hSession, (CK_BYTE_PTR) "\x4c\x36\x0f\x86\x2d\xb7\xb2\x46\x92\x11\x7e\x5f\xd1\xeb\x2c\xb0\xdb\x34\x60\xb8\x0c\xf8\x27\xb5\xfb\xce\xd1\xf4\x58\xa3\x20\x52\x9d\x97\x08\xd8\x2b\x5e\xb2\x37\x46\x72\x45\x7c\x66\x23\x53\xb5\xa5\x16\x61\x96\xbc\x5c\x8d\x85\x18\x24\xcf\x74\x7f\xc2\x23\x15\xd6\x42\x72\xa5\x2b\x29\x29\x1d\xa6\xea\x2b\xcb\x57\x59\xb3\x5f\xe2\xf8\x30\x12\x2f\x1b\xfa\xbd\xa9\x19\xef\x5c\xbb\x48\xdc\x28\x42\xdd\x90\xbe\x63\xeb\x59\x0c\xaf\x59\xcb\xe4\x6a\xf2\x56\x24\x41\xc2\x77\x7b\xc9\xf8\x02\x0f\x67\x3d\x2a\x98\x91\x14\xa2\x57", 128, decrypted_buf, &decrypted_buflen); if (chk_rv == CKR_OK) { printf("[%04lu/%02lx] Decrypted(It works!): ", (unsigned long) *currPrivKey, (unsigned long) mechanism.mechanism); for (byte_idx = 0; byte_idx < decrypted_buflen; byte_idx++) { printf("%02x ", (unsigned int) decrypted_buf[byte_idx]); } printf("\n"); } else { printf("Decrypt() failed.\n"); } } else { printf("DecryptInit() failed.\n"); } } chk_rv = C_CloseSession(hSession); if (chk_rv != CKR_OK) { printf("CloseSession failed.\n"); } } else { printf("OpenSession failed.\n"); } C_Finalize(NULL); if (slots) { free(slots); } if (privateKeyObjects_root) { free(privateKeyObjects_root); } return(0); } int main(int argc, char **argv) { int retval = 0, ck_retval; printf("Testing libcackey...\n"); if (argc > 1) { loadTestData(argv[1]); } ck_retval = main_pkcs11(); if (ck_retval != 0) { retval = ck_retval; } printf("Testing libcackey... DONE. Status = %i\n", ck_retval); return(retval); }