void ZoomNavigator::OnPreviewClicked(wxMouseEvent& e)
{
IEditor* curEditor = m_mgr->GetActiveEditor();
// user clicked on the preview
CHECK_CONDITION(m_startupCompleted);
CHECK_CONDITION(curEditor);
CHECK_CONDITION(m_enabled);
// the first line is taken from the preview
int pos = m_text->PositionFromPoint(e.GetPosition());
if(pos == wxSTC_INVALID_POSITION) {
return;
}
int first = m_text->LineFromPosition(pos);
int nLinesOnScreen = curEditor->GetCtrl()->LinesOnScreen();
first -= (nLinesOnScreen / 2);
if(first < 0) first = 0;
// however, the last line is set according to the actual editor
int last = nLinesOnScreen + first;
PatchUpHighlights(first, last);
curEditor->GetCtrl()->SetFirstVisibleLine(first);
curEditor->SetCaretAt(curEditor->PosFromLine(first + (nLinesOnScreen / 2)));
// reset the from/last members to avoid unwanted movements in the 'OnTimer' function
m_markerFirstLine = curEditor->GetCtrl()->GetFirstVisibleLine();
m_markerLastLine = m_markerFirstLine + curEditor->GetCtrl()->LinesOnScreen();
}
void ZoomNavigator::DoUpdate()
{
// sanity tests
CHECK_CONDITION(m_enabled);
CHECK_CONDITION(!m_mgr->IsShutdownInProgress());
IEditor* curEditor = m_mgr->GetActiveEditor();
if(!curEditor && !m_text->IsEmpty()) {
DoCleanup();
}
CHECK_CONDITION(curEditor);
wxStyledTextCtrl* stc = curEditor->GetCtrl();
CHECK_CONDITION(stc);
if(curEditor->GetFileName().GetFullPath() != m_curfile) {
SetEditorText(curEditor);
}
int first = stc->GetFirstVisibleLine();
int last = stc->LinesOnScreen() + first;
if(m_markerFirstLine != first || m_markerLastLine != last) {
PatchUpHighlights(first, last);
SetZoomTextScrollPosToMiddle(stc);
}
}
const config_file::value& config_file::value::operator[](const char* rec_name) const
{
CHECK_CONDITION(this->type_ == RECORD, "Not a record type");
mapci it = record_.find(rec_name);
CHECK_CONDITION(it != this->record_.end(), "Record not found");
return it->second;
}
bool AES_KW_Encrypt(COSE_RecipientInfo * pcose, const byte * pbKeyIn, int cbitKey, const byte * pbContent, int cbContent, cose_errback * perr)
{
byte *pbOut = NULL;
AES_KEY key;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_encrypt.m_message.m_allocContext;
#endif
cn_cbor * cnTmp = NULL;
pbOut = COSE_CALLOC(cbContent + 8, 1, context);
CHECK_CONDITION(AES_set_encrypt_key(pbKeyIn, cbitKey, &key) == 0, COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(AES_wrap_key(&key, NULL, pbOut, pbContent, cbContent), COSE_ERR_CRYPTO_FAIL);
cnTmp = cn_cbor_data_create(pbOut, (int)cbContent + 8, CBOR_CONTEXT_PARAM_COMMA NULL);
CHECK_CONDITION(cnTmp != NULL, COSE_ERR_CBOR);
pbOut = NULL;
CHECK_CONDITION(_COSE_array_replace(&pcose->m_encrypt.m_message, cnTmp, INDEX_BODY, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
cnTmp = NULL;
return true;
errorReturn:
COSE_FREE(cnTmp, context);
if (pbOut != NULL) COSE_FREE(pbOut, context);
return false;
}
const config_file::value& config_file::value::operator[](size_t index) const
{
CHECK_CONDITION(this->type_ == ARRAY, "Not an array type");
CHECK_CONDITION(index < this->array_.size() && index>=0, "Array out of range");
return this->array_[index];
}
// Function Specification
//
// Name: errlTestTime
//
// Description: errlTestTime
//
// End Function Specification
uint32_t errlTestTime()
{
uint32_t l_rc = 0;
do
{
ERRL_DBG("START");
errlHndl_t l_handle = NULL;
uint64_t l_start = 0;
uint64_t l_end = 0;
/****************************************************/
// Check timeStamp
// Create one log
l_start = ssx_timebase_get();
l_handle = createErrl( 0x1716, 0x08, OCC_NO_EXTENDED_RC, ERRL_SEV_CALLHOME_DATA, g_trac_inf, 128, 0x1, 0x2);
CHECK_CONDITION( l_handle != INVALID_ERR_HNDL, l_rc);
// check time stamp
errlHndl_t l_handle2 = l_handle;
commitErrl( &l_handle );
l_end = ssx_timebase_get();
CHECK_CONDITION( (l_handle2->iv_userDetails.iv_timeStamp >= l_start) &&
(l_handle2->iv_userDetails.iv_timeStamp <= l_end ), l_rc);
deleteErrl(&l_handle2);
ERRL_DBG("END \n");
}while(0);
return l_rc;
}
bool ECDSA_Sign(COSE * pSigner, int index, const cn_cbor * pKey, int cbitDigest, const byte * rgbToSign, size_t cbToSign, cose_errback * perr)
{
EC_KEY * eckey = NULL;
byte rgbDigest[EVP_MAX_MD_SIZE];
unsigned int cbDigest = sizeof(rgbDigest);
byte * pbSig = NULL;
const EVP_MD * digest;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pSigner->m_allocContext;
#endif
cn_cbor * p = NULL;
ECDSA_SIG * psig = NULL;
cn_cbor_errback cbor_error;
int cbR;
byte rgbSig[66];
int cb;
eckey = ECKey_From(pKey, &cbR, perr);
if (eckey == NULL) {
errorReturn:
if (p != NULL) CN_CBOR_FREE(p, context);
if (eckey != NULL) EC_KEY_free(eckey);
return false;
}
switch (cbitDigest) {
case 256: digest = EVP_sha256(); break;
case 512: digest = EVP_sha512(); break;
case 384: digest = EVP_sha384(); break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
EVP_Digest(rgbToSign, cbToSign, rgbDigest, &cbDigest, digest, NULL);
psig = ECDSA_do_sign(rgbDigest, cbDigest, eckey);
CHECK_CONDITION(psig != NULL, COSE_ERR_CRYPTO_FAIL);
pbSig = COSE_CALLOC(cbR, 2, context);
CHECK_CONDITION(pbSig != NULL, COSE_ERR_OUT_OF_MEMORY);
cb = BN_bn2bin(psig->r, rgbSig);
CHECK_CONDITION(cb <= cbR, COSE_ERR_INVALID_PARAMETER);
memcpy(pbSig + cbR - cb, rgbSig, cb);
cb = BN_bn2bin(psig->s, rgbSig);
CHECK_CONDITION(cb <= cbR, COSE_ERR_INVALID_PARAMETER);
memcpy(pbSig + 2*cbR - cb, rgbSig, cb);
p = cn_cbor_data_create(pbSig, cbR*2, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(p != NULL, cbor_error);
CHECK_CONDITION(_COSE_array_replace(pSigner, p, index, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
return true;
}
bool COSE_Enveloped_SetContent(HCOSE_ENVELOPED h, const byte * rgb, size_t cb, cose_errback * perr)
{
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(rgb != NULL, COSE_ERR_INVALID_PARAMETER);
return _COSE_Enveloped_SetContent((COSE_Enveloped *)h, rgb, cb, perr);
errorReturn:
return false;
}
bool COSE_Enveloped_SetExternal(HCOSE_ENVELOPED hcose, const byte * pbExternalData, size_t cbExternalData, cose_errback * perr)
{
CHECK_CONDITION(IsValidEnvelopedHandle(hcose), COSE_ERR_INVALID_HANDLE)
CHECK_CONDITION((pbExternalData != NULL) || (cbExternalData == 0), COSE_ERR_INVALID_PARAMETER);
return _COSE_SetExternal(&((COSE_Enveloped *)hcose)->m_message, pbExternalData, cbExternalData, perr);
errorReturn:
return false;
}
bool COSE_Enveloped_map_put_int(HCOSE_ENVELOPED h, int key, cn_cbor * value, int flags, cose_errback * perr)
{
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(value != NULL, COSE_ERR_INVALID_PARAMETER);
return _COSE_map_put(&((COSE_Enveloped *)h)->m_message, key, value, flags, perr);
errorReturn:
return false;
}
bool COSE_Encrypt_encrypt(HCOSE_ENCRYPT h, const byte * pbKey, size_t cbKey, cose_errback * perr)
{
CHECK_CONDITION(IsValidEncryptHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(pbKey != NULL, COSE_ERR_INVALID_PARAMETER);
return _COSE_Enveloped_encrypt((COSE_Encrypt *)h, pbKey, cbKey, "Encrypt0", perr);
errorReturn:
return false;
}
bool _COSE_Encrypt_Build_AAD(COSE * pMessage, byte ** ppbAAD, size_t * pcbAAD, const char * szContext, cose_errback * perr)
{
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pMessage->m_allocContext;
#endif
cn_cbor_errback cbor_error;
byte * pbAuthData;
size_t cbAuthData;
cn_cbor * pAuthData;
cn_cbor * pItem;
cn_cbor * ptmp = NULL;
// Build authenticated data
pbAuthData = NULL;
pAuthData = cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(pAuthData != NULL, cbor_error);
ptmp = cn_cbor_string_create(szContext, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(cn_cbor_array_append(pAuthData, ptmp, &cbor_error), cbor_error);
ptmp = NULL;
pItem = _COSE_arrayget_int(pMessage, INDEX_PROTECTED);
CHECK_CONDITION(pItem != NULL, COSE_ERR_INVALID_PARAMETER);
if ((pItem->length == 1) && (pItem->v.bytes[0] == 0xa0)) {
ptmp = cn_cbor_data_create(NULL, 0, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
}
else {
ptmp = cn_cbor_data_create(pItem->v.bytes, (int)pItem->length, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
}
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(cn_cbor_array_append(pAuthData, ptmp, &cbor_error), cbor_error);
ptmp = NULL;
ptmp = cn_cbor_data_create(pMessage->m_pbExternal, (int) pMessage->m_cbExternal, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(cn_cbor_array_append(pAuthData, ptmp, &cbor_error), cbor_error);
ptmp = NULL;
cbAuthData = cn_cbor_encoder_write(RgbDontUse, 0, sizeof(RgbDontUse), pAuthData);
pbAuthData = (byte *)COSE_CALLOC(cbAuthData, 1, context);
CHECK_CONDITION(pbAuthData != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION((size_t)cn_cbor_encoder_write(pbAuthData, 0, cbAuthData, pAuthData) == cbAuthData, COSE_ERR_CBOR);
*ppbAAD = pbAuthData;
*pcbAAD = cbAuthData;
return true;
errorReturn:
if (pbAuthData != NULL) COSE_FREE(pbAuthData, context);
if (ptmp != NULL) CN_CBOR_FREE(ptmp, NULL);
if (pAuthData != NULL) CN_CBOR_FREE(pAuthData, context);
return false;
}
bool COSE_Enveloped_encrypt(HCOSE_ENVELOPED h, cose_errback * perr)
{
COSE_Enveloped * pcose = (COSE_Enveloped *)h;
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(pcose->m_recipientFirst != NULL, COSE_ERR_INVALID_HANDLE);
return _COSE_Enveloped_encrypt(pcose, NULL, 0, "Encrypt", perr);
errorReturn:
return false;
}
TEST(ModelBase, SimpleModelCreation)
{
Model model;
CHECK_CONDITION( model.root() == nullptr );
TestNodes::BinaryNode* root = dynamic_cast<TestNodes::BinaryNode*> (model.createRoot("BinaryNode"));
CHECK_CONDITION( model.root() == root );
CHECK_CONDITION( root->model() == &model );
CHECK_CONDITION( root->name()->model() == &model );
}
TEST(OOModel, SimpleClassTest)
{
Model::Model model;
Class* root = dynamic_cast<Class*> (model.createRoot("Class"));
CHECK_CONDITION(root != nullptr);
CHECK_CONDITION(root->name().isEmpty());
model.beginModification(root, "setName");
root->setName("Test");
model.endModification();
CHECK_STR_EQUAL("Test", root->name());
}
TEST(OOModel, SimpleProjectTest)
{
Model::Model model;
Project* root = dynamic_cast<Project*> (model.createRoot("Project"));
CHECK_CONDITION(root != nullptr);
CHECK_CONDITION(root->name().isEmpty());
model.beginModification(root, "setName");
root->setName("prj");
model.endModification();
CHECK_STR_EQUAL("prj", root->name());
}
pipeline_data_queue::~pipeline_data_queue()
{
while(!free_list_.empty()){
delete free_list_.front();
free_list_.pop_front();
}
while(!active_queue_.empty()){
delete active_queue_.front();
active_queue_.pop_front();
}
CHECK_CONDITION(active_queue_.empty(), "active_queue_ not properly destroyed");
CHECK_CONDITION(free_list_.empty(), "free_list_ not properly destroyed");
}
bool AES_CBC_MAC_Validate(COSE_MacMessage * pcose, int TSize, const byte * pbKey, size_t cbKey, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
const EVP_CIPHER * pcipher = NULL;
EVP_CIPHER_CTX ctx;
int cbOut;
byte rgbIV[16] = { 0 };
byte rgbTag[16] = { 0 };
bool f = false;
unsigned int i;
switch (cbKey*8) {
case 128:
pcipher = EVP_aes_128_cbc();
break;
case 256:
pcipher = EVP_aes_256_cbc();
break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
// Setup and run the OpenSSL code
EVP_CIPHER_CTX_init(&ctx);
CHECK_CONDITION(EVP_EncryptInit_ex(&ctx, pcipher, NULL, pbKey, rgbIV), COSE_ERR_CRYPTO_FAIL);
TSize /= 8;
for (i = 0; i < (unsigned int) cbAuthData / 16; i++) {
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbTag, &cbOut, pbAuthData+(i*16), 16), COSE_ERR_CRYPTO_FAIL);
}
if (cbAuthData % 16 != 0) {
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbTag, &cbOut, pbAuthData + (i * 16), cbAuthData % 16), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbTag, &cbOut, rgbIV, 16 - (cbAuthData % 16)), COSE_ERR_CRYPTO_FAIL);
}
cn_cbor * cn = _COSE_arrayget_int(&pcose->m_message, INDEX_MAC_TAG);
CHECK_CONDITION(cn != NULL, COSE_ERR_CBOR);
for (i = 0; i < (unsigned int)TSize; i++) f |= (cn->v.bytes[i] != rgbTag[i]);
EVP_CIPHER_CTX_cleanup(&ctx);
return !f;
errorReturn:
EVP_CIPHER_CTX_cleanup(&ctx);
return false;
}
bool ECDSA_Verify(COSE * pSigner, int index, const cn_cbor * pKey, int cbitDigest, const byte * rgbToSign, size_t cbToSign, cose_errback * perr)
{
EC_KEY * eckey = NULL;
byte rgbDigest[EVP_MAX_MD_SIZE];
unsigned int cbDigest = sizeof(rgbDigest);
const EVP_MD * digest;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pSigner->m_allocContext;
#endif
cn_cbor * p = NULL;
ECDSA_SIG sig = { NULL, NULL };
int cbR;
cn_cbor * pSig;
size_t cbSignature;
eckey = ECKey_From(pKey, &cbR, perr);
if (eckey == NULL) {
errorReturn:
if (sig.r != NULL) BN_free(sig.r);
if (sig.s != NULL) BN_free(sig.s);
if (p != NULL) CN_CBOR_FREE(p, context);
if (eckey != NULL) EC_KEY_free(eckey);
return false;
}
switch (cbitDigest) {
case 256: digest = EVP_sha256(); break;
case 512: digest = EVP_sha512(); break;
case 384: digest = EVP_sha384(); break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
EVP_Digest(rgbToSign, cbToSign, rgbDigest, &cbDigest, digest, NULL);
pSig = _COSE_arrayget_int(pSigner, index);
CHECK_CONDITION(pSig != NULL, CN_CBOR_ERR_INVALID_PARAMETER);
cbSignature = pSig->length;
CHECK_CONDITION(cbSignature / 2 == cbR, COSE_ERR_INVALID_PARAMETER);
sig.r = BN_bin2bn(pSig->v.bytes,(int) cbSignature/2, NULL);
sig.s = BN_bin2bn(pSig->v.bytes+cbSignature/2, (int) cbSignature/2, NULL);
CHECK_CONDITION(ECDSA_do_verify(rgbDigest, cbDigest, &sig, eckey) == 1, COSE_ERR_CRYPTO_FAIL);
BN_free(sig.r);
BN_free(sig.s);
if (eckey != NULL) EC_KEY_free(eckey);
return true;
}
///////////////////////////////////////////////////////////////////////////////
//
// ConstructWriterDefinition
//
///////////////////////////////////////////////////////////////////////////////
bool ConstructWriterDefinition(
__in IVssCreateExpressWriterMetadata *pMetadata
)
{
HRESULT hr = S_OK;
bool bResult = false;
PCWSTR wszComponent = L"SampleComponent";
wprintf(L"INFO: ConstructWriterDefinition called\n");
//
// Select restore method
//
wprintf(L"INFO: Selecting restore method...\n");
CHECK_CONDITION(
SetRestoreMethod(
pMetadata,
VSS_RME_RESTORE_IF_CAN_REPLACE, // VSS_RESTOREMETHOD_ENUM
NULL, // Service name, if method is VSS_RME_STOP_RESTORE_RESTART
false), // Reboot required
L"SetRestoreMethod failed");
//
// Add components and files
//
wprintf(L"INFO: Adding basic component...\n");
CHECK_CONDITION(
AddComponent(
pMetadata,
VSS_CT_FILEGROUP, // VSS_COMPONENT_TYPE
wszComponent), // Component name
L"AddComponent failed");
CHECK_CONDITION(
AddFilesToFileGroup(
pMetadata,
wszComponent, // Component name
L"c:\\xwdata", // Directory covered
L"*.*", // Files covered
true, // Recursive
VSS_FSBT_ALL_SNAPSHOT_REQUIRED |
VSS_FSBT_FULL_BACKUP_REQUIRED), // Backup type mask
L"AddFilesToFileGroup failed");
bResult = true;
_exit:
return bResult;
}
TEST(FilePersistence, LoadMultipleUnits)
{
QString testDir = ":/FilePersistence/test/persisted";
Model::Model model;
FileStore store;
store.setBaseFolder(testDir);
model.load(&store, "units");
TestNodes::BinaryNode* root = dynamic_cast<TestNodes::BinaryNode*> (model.root());
CHECK_STR_EQUAL("BinaryNode", root->typeName() );
CHECK_STR_EQUAL("Root", root->name()->get() );
CHECK_CONDITION(root->left() != nullptr);
CHECK_CONDITION(root->right() != nullptr);
CHECK_STR_EQUAL("BinaryNodePersistenceUnit", root->left()->typeName() );
CHECK_STR_EQUAL("Left child", root->left()->name()->get() );
CHECK_CONDITION(root->left()->left() != nullptr);
CHECK_CONDITION(root->left()->right() == nullptr);
CHECK_STR_EQUAL("BinaryNode", root->left()->left()->typeName() );
CHECK_STR_EQUAL("in a new unit", root->left()->left()->name()->get() );
CHECK_CONDITION(root->left()->left()->left() == nullptr);
CHECK_CONDITION(root->left()->left()->right() == nullptr);
CHECK_STR_EQUAL("BinaryNode", root->right()->typeName() );
CHECK_STR_EQUAL("Right child", root->right()->name()->get() );
CHECK_CONDITION(root->right()->left() == nullptr);
CHECK_CONDITION(root->right()->right() == nullptr);
}
///////////////////////////////////////////////////////////////////////////////
//
// CreateAndSaveToFile
//
///////////////////////////////////////////////////////////////////////////////
bool CreateAndSaveToFile()
{
HRESULT hr = S_OK;
bool bResult = false;
CComPtr<IVssExpressWriter> spExpressWriter;
CComPtr<IVssCreateExpressWriterMetadata> spMetadata;
wprintf(L"INFO: CreateAndSaveToFile called\n");
//
// Create Express Writer
//
wprintf(L"INFO: Creating Express Writer...\n");
CHECK_HR(
CreateVssExpressWriter(&spExpressWriter),
L"CreateVssExpressWriter failed");
//
// Create metadata
//
wprintf(L"INFO: Creating metadata...\n");
CHECK_HR(
spExpressWriter->CreateMetadata(
EXPRESS_WRITER_SAMPLE_GUID, // Express Writer GUID
L"Sample Express Writer", // Express Writer friendly name
VSS_UT_BOOTABLESYSTEMSTATE, // VSS_USAGE_TYPE
1, // Major version
0, // Minor version
0, // Reserved (must be 0)
&spMetadata),
L"CreateVssExpressWriter failed");
CHECK_CONDITION(
ConstructWriterDefinition(spMetadata),
L"ConstructWriterDefinition failed");
bResult = true;
//
// Save results
//
CHECK_CONDITION(SaveToFile(spMetadata, g_wszFileName), L"SaveToFile failed");
bResult = true;
_exit:
return bResult;
}
// Function Specification
//
// Name: errlTestWordAlign
//
// Description: errlTestWordAlign
//
// End Function Specification
uint32_t errlTestWordAlign()
{
uint32_t l_rc = 0;
uint16_t l_entrySizeBefore = 0;
uint16_t l_entrySizeAfter = 0;
ERRL_DBG("START");
do
{
/****************************************************/
// Test word align for addUsrDtlsToErrl
// Create log
errlHndl_t l_handle = createErrl( TEST_MODULE_ID, 0x08, OCC_NO_EXTENDED_RC, ERRL_SEV_PREDICTIVE, NULL, 0, 0x1, 0x2);
CHECK_CONDITION( l_handle != INVALID_ERR_HNDL, l_rc);
// l_handle will set to NULL after calling the commitErrl, so we need to store it
errlHndl_t l_handleX = l_handle;
ppdumpslot();
// add 13 bytes of "user details"
l_entrySizeBefore = l_handle->iv_userDetails.iv_entrySize;
memset( G_data, 0xAA, sizeof( G_data ) );
addUsrDtlsToErrl( l_handle, G_data, 13, ERRL_USR_DTL_STRUCT_VERSION_1, ERRL_USR_DTL_TRACE_DATA );
l_entrySizeAfter = l_handle->iv_userDetails.iv_entrySize;
ERRL_DBG("Slots after create + 13 bytes" );
ppdumpslot();
// (header + WORDALIGN(13)) is the size that add to entry
CHECK_CONDITION( l_entrySizeAfter == (l_entrySizeBefore+sizeof(ErrlUserDetailsEntry_t)+16), l_rc);
/****************************************************/
// Test word align for addTraceToErrl
// add 21 bytes of trace
l_entrySizeBefore = l_handle->iv_userDetails.iv_entrySize;
addTraceToErrl(g_trac_inf, 21, l_handle); // @at012c
l_entrySizeAfter = l_handle->iv_userDetails.iv_entrySize;
ERRL_DBG("Slots after create + 21 bytes" );
ppdumpslot();
// (header + WORDALIGN(21)) is the size that add to entry
CHECK_CONDITION( l_entrySizeAfter <= (l_entrySizeBefore+sizeof(ErrlUserDetailsEntry_t)+24), l_rc);
commitErrl( &l_handle );
deleteErrl(&l_handleX);
ERRL_DBG("Slots should now be empty");
ppdumpslot();
ERRL_DBG("END \n");
}while(0);
return l_rc;
}
bool COSE_Enveloped_decrypt(HCOSE_ENVELOPED h, HCOSE_RECIPIENT hRecip, cose_errback * perr)
{
COSE_Enveloped * pcose = (COSE_Enveloped *)h;
COSE_RecipientInfo * pRecip = (COSE_RecipientInfo *)hRecip;
bool f = false;
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(IsValidRecipientHandle(hRecip), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(pcose->m_recipientFirst != NULL, COSE_ERR_INVALID_PARAMETER);
f = _COSE_Enveloped_decrypt(pcose, pRecip, NULL, 0, "Encrypt", perr);
errorReturn:
return f;
}
bool AES_CCM_Decrypt(COSE_Enveloped * pcose, int TSize, int LSize, const byte * pbKey, size_t cbKey, const byte * pbCrypto, size_t cbCrypto, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
mbedtls_ccm_context ctx;
int cbOut;
byte * rgbOut = NULL;
int NSize = 15 - (LSize/8);
byte rgbIV[15] = { 0 };
const cn_cbor * pIV = NULL;
mbedtls_cipher_id_t cipher;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_message.m_allocContext;
#endif
mbedtls_ccm_init(&ctx);
// Setup the IV/Nonce and put it into the message
pIV = _COSE_map_get_int(&pcose->m_message, COSE_Header_IV, COSE_BOTH, NULL);
if ((pIV == NULL) || (pIV->type!= CN_CBOR_BYTES)) {
if (perr != NULL) perr->err = COSE_ERR_INVALID_PARAMETER;
errorReturn:
if (rgbOut != NULL) COSE_FREE(rgbOut, context);
mbedtls_ccm_free(&ctx);
return false;
}
CHECK_CONDITION(pIV->length == NSize, COSE_ERR_INVALID_PARAMETER);
memcpy(rgbIV, pIV->v.str, pIV->length);
// Setup and run the mbedTLS code
cipher = MBEDTLS_CIPHER_ID_AES;
CHECK_CONDITION(!mbedtls_ccm_setkey(&ctx, cipher, pbKey, cbKey*8), COSE_ERR_CRYPTO_FAIL);
TSize /= 8; // Comes in in bits not bytes.
cbOut = (int) cbCrypto - TSize;
rgbOut = (byte *)COSE_CALLOC(cbOut, 1, context);
CHECK_CONDITION(rgbOut != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(!mbedtls_ccm_auth_decrypt(&ctx, cbOut, rgbIV, NSize, pbAuthData, cbAuthData, pbCrypto, rgbOut, &pbCrypto[cbOut], TSize), COSE_ERR_CRYPTO_FAIL);
mbedtls_ccm_free(&ctx);
pcose->pbContent = rgbOut;
pcose->cbContent = cbOut;
return true;
}
size_t FileImpl::Write(const t_byte *buf, size_t len)
{
if(!IsOpen()) return 0;
t_ulong nwritten = 0;
CHECK_CONDITION
(
::WriteFile(m_fhdl, buf, (DWORD)len, &nwritten, NULL),
"FileImpl::Write "
);
CHECK_CONDITION((nwritten == len), "FileImpl::Write ");
return len;
}
double loadGraphFile(void *graph, const char *filename, BOOL (*lineHandleFun)(void*,int,int,int)){
int fromId, toId, lineCounter = 0, count;
clock_t begin, end;
FILE *fp;
begin = clock();
fp = fopen(filename, "r");
CHECK_CONDITION(fp != NULL, "Cannot Open Graph File!");
while(!feof(fp)){
count = fscanf(fp, "%d\t%d", &fromId, &toId);
if(count != 2){ // check reading count of ids
continue;
}
if(!lineHandleFun(graph, lineCounter, fromId, toId)){
break;
}
if(lineCounter % 1000000 == 0 && lineCounter != 0){
logMsg("read %d lines\n", lineCounter);
}
lineCounter += 1;
}
fclose(fp);
end = clock();
return (double)(end - begin) / CLOCKS_PER_SEC;
}
HCOSE_MAC0 _COSE_Mac0_Init_From_Object(cn_cbor * cbor, COSE_Mac0Message * pIn, CBOR_CONTEXT_COMMA cose_errback * perr)
{
COSE_Mac0Message * pobj = pIn;
cn_cbor * pRecipients = NULL;
// cn_cbor * tmp;
cose_errback error = { COSE_ERR_NONE };
if (perr == NULL) perr = &error;
if (pobj == NULL) pobj = (COSE_Mac0Message *)COSE_CALLOC(1, sizeof(COSE_Mac0Message), context);
if (pobj == NULL) {
perr->err = COSE_ERR_OUT_OF_MEMORY;
errorReturn:
if ((pIn == NULL) && (pobj != NULL)) COSE_FREE(pobj, context);
return NULL;
}
if (!_COSE_Init_From_Object(&pobj->m_message, cbor, CBOR_CONTEXT_PARAM_COMMA perr)) {
goto errorReturn;
}
pRecipients = _COSE_arrayget_int(&pobj->m_message, INDEX_MAC_RECIPIENTS);
CHECK_CONDITION(pRecipients == NULL, COSE_ERR_INVALID_PARAMETER);
return(HCOSE_MAC0)pobj;
}
HCOSE_ENCRYPT _COSE_Encrypt_Init_From_Object(cn_cbor * cbor, COSE_Encrypt * pIn, CBOR_CONTEXT_COMMA cose_errback * perr)
{
COSE_Encrypt * pobj = pIn;
cn_cbor * pRecipients = NULL;
cose_errback error = { 0 };
if (perr == NULL) perr = &error;
if (pobj == NULL) pobj = (COSE_Encrypt *)COSE_CALLOC(1, sizeof(COSE_Encrypt), context);
if (pobj == NULL) {
perr->err = COSE_ERR_OUT_OF_MEMORY;
errorReturn:
if ((pIn == NULL) && (pobj != NULL)) COSE_FREE(pobj, context);
return NULL;
}
if (!_COSE_Init_From_Object(&pobj->m_message, cbor, CBOR_CONTEXT_PARAM_COMMA perr)) {
goto errorReturn;
}
pRecipients = _COSE_arrayget_int(&pobj->m_message, INDEX_RECIPIENTS);
CHECK_CONDITION(pRecipients == NULL, COSE_ERR_INVALID_PARAMETER);
_COSE_InsertInList(&EncryptRoot, &pobj->m_message);
return(HCOSE_ENCRYPT) pobj;
}
TEST(FilePersistence, LoadRootOnly)
{
QString testDir = ":/FilePersistence/test/persisted";
Model::Model model;
FileStore store;
store.setBaseFolder(testDir);
model.load(&store, "rootOnly");
TestNodes::BinaryNode* root = dynamic_cast<TestNodes::BinaryNode*> (model.root());
CHECK_CONDITION(root);
CHECK_STR_EQUAL("BinaryNode", root->typeName() );
CHECK_STR_EQUAL("Title", root->name()->get() );
CHECK_CONDITION(root->left() == nullptr);
CHECK_CONDITION(root->right() == nullptr);
}