void ConnectorTypeWidget::cancel() {
setType(m_typeBackUp);
}
gqbTable::gqbTable(gqbObject *parent, wxString name, pgConn *connection, type_gqbObject type, OID oid)
: gqbObjectCollection(name, parent, connection, oid)
{
setType(type);
}
JNIEXPORT jobject JNICALL
Java_org_ocera_orte_Publication_jORTEPublicationPropertiesGet
(JNIEnv *env, jobject obj, jlong j_appDomain_handle)
{
// jni types
jclass cls_pp = NULL; // PublProp class
jclass cls_ntpT = NULL; // NtpTime class
jobject obj_pp = NULL; // instance of PublProp
jobject obj_ntpT = NULL; // instance of NtpTime
jfieldID fid = NULL;
jmethodID mid;
jboolean jbool = 0;
//
int b = 0;
int flag_ok = 0;
ORTEPublProp pp;
ORTEPublProp *publ_prop = &pp;
// calling original orte function
#ifdef TEST_STAGE
printf(":c: ORTEPublicationPropertiesGet() called.. \n");
#endif
// create new PublProps instance and set its fields
do {
// call ORTE function
b = ORTEPublicationPropertiesGet((ORTEPublication *)j_appDomain_handle,
publ_prop);
if (b == ORTE_BAD_HANDLE) {
printf(":!c: PublicationPropertiesGet() failed! [bad pub handle] \n");
break;
}
// find class
cls_pp = findClass(env, "org.ocera.orte.types.PublProp");
if (cls_pp == 0) {
#ifdef TEST_STAGE
printf(":!c: cls_pp = NULL \n");
#endif
break;
}
// call object constructor
mid = (*env)->GetMethodID(env, cls_pp, "<init>", "()V");
if (mid == 0) {
#ifdef TEST_STAGE
printf(":!c: mid = NULL \n");
#endif
break;
}
// new object
obj_pp = (*env)->NewObject(env, cls_pp, mid);
if (obj_pp == 0) {
#ifdef TEST_STAGE
printf(":!c: obj_pp = NULL \n");
#endif
break;
}
#ifdef TEST_STAGE
printf(":c: instance of 'org.ocera.orte.types.PublProp' created..\n");
#endif
// ///////////////////////////////////////////////
// setting object's fields
/////////////////////////////////////////////////
// set topic
if (!setTopic(env, cls_pp, obj_pp, (const char *)publ_prop->topic)) {
#ifdef TEST_STAGE
printf(":!c: setTopic() failed! \n");
#endif
break;
}
/////////////////////////////////////////////////
// set type
if (!setType(env, cls_pp, obj_pp, (const char *)publ_prop->typeName)) {
#ifdef TEST_STAGE
printf(":!c: setType() failed! \n");
#endif
break;
}
/////////////////////////////////////////////////
// fieldID - typeChecksum
fid = (*env)->GetFieldID(env,
cls_pp,
"typeChecksum",
"I");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetIntField(env,
obj_pp,
fid,
(jint)publ_prop->typeChecksum);
/////////////////////////////////////////////////
// fieldID - expectsAck
fid = (*env)->GetFieldID(env,
cls_pp,
"expectsAck",
"Z");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
if (publ_prop->expectsAck == ORTE_FALSE)
jbool = 0;
else
jbool = 1;
(*env)->SetBooleanField(env,
obj_pp,
fid,
jbool);
/////////////////////////////////////////////////
// fieldID - persistence
cls_ntpT = findClass(env, "org.ocera.orte.types.NtpTime");
if (cls_ntpT == 0) {
#ifdef TEST_STAGE
printf(":!c: cls_ntpT = NULL \n");
#endif
break;
}
// call object constructor
mid = (*env)->GetMethodID(env, cls_ntpT, "<init>", "(IJ)V");
if (mid == 0) {
#ifdef TEST_STAGE
printf(":!c: mid = NULL \n");
#endif
break;
}
// new object
obj_ntpT = (*env)->NewObject(env,
cls_ntpT,
mid,
(jint)publ_prop->persistence.seconds,
(jlong)publ_prop->persistence.fraction);
if (obj_ntpT == 0) {
#ifdef TEST_STAGE
printf(":!c: obj_ntpT = NULL \n");
#endif
break;
}
#ifdef TEST_STAGE
printf(":c: instance of 'org.ocera.orte.types.NtpTime' created..\n");
#endif
// set 'PublProp' NtpTime's field
fid = (*env)->GetFieldID(env,
cls_pp,
"persistence",
"Lorg/ocera/orte/types/NtpTime;");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetObjectField(env,
obj_pp,
fid,
obj_ntpT);
/////////////////////////////////////////////////
// fieldID - HBNornalRate
// cls_ntpT and obj_ntpT already readed!!
// new object
obj_ntpT = (*env)->NewObject(env,
cls_ntpT,
mid,
(jint)publ_prop->HBNornalRate.seconds,
(jlong)publ_prop->HBNornalRate.fraction);
if (obj_ntpT == 0) {
#ifdef TEST_STAGE
printf(":!c: obj_ntpT = NULL \n");
#endif
break;
}
#ifdef TEST_STAGE
printf(":c: instance of 'org.ocera.orte.types.NtpTime' created..\n");
#endif
// set 'PublProp' NtpTime's field
fid = (*env)->GetFieldID(env,
cls_pp,
"HBNornalRate",
"Lorg/ocera/orte/types/NtpTime;");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetObjectField(env,
obj_pp,
fid,
obj_ntpT);
/////////////////////////////////////////////////
// fieldID - HBCQLRate
// cls_ntpT and obj_ntpT already readed!!
// new object
obj_ntpT = (*env)->NewObject(env,
cls_ntpT,
mid,
(jint)publ_prop->HBCQLRate.seconds,
(jlong)publ_prop->HBCQLRate.fraction);
if (obj_ntpT == 0) {
#ifdef TEST_STAGE
printf(":!c: obj_ntpT = NULL \n");
#endif
break;
}
#ifdef TEST_STAGE
printf(":c: instance of 'org.ocera.orte.types.NtpTime' created..\n");
#endif
// set 'PublProp' NtpTime's field
fid = (*env)->GetFieldID(env,
cls_pp,
"HBCQLRate",
"Lorg/ocera/orte/types/NtpTime;");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetObjectField(env,
obj_pp,
fid,
obj_ntpT);
/////////////////////////////////////////////////
// fieldID - HBCQLRate
// cls_ntpT and obj_ntpT already readed!!
// new object
obj_ntpT = (*env)->NewObject(env,
cls_ntpT,
mid,
(jint)publ_prop->maxBlockTime.seconds,
(jlong)publ_prop->maxBlockTime.fraction);
if (obj_ntpT == 0) {
#ifdef TEST_STAGE
printf(":!c: obj_ntpT = NULL \n");
#endif
break;
}
#ifdef TEST_STAGE
printf(":c: instance of 'org.ocera.orte.types.NtpTime' created..\n");
#endif
// set 'PublProp' NtpTime's field
fid = (*env)->GetFieldID(env,
cls_pp,
"maxBlockTime",
"Lorg/ocera/orte/types/NtpTime;");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetObjectField(env,
obj_pp,
fid,
obj_ntpT);
/////////////////////////////////////////////////
// fieldID - reliabilityOffered
fid = (*env)->GetFieldID(env,
cls_pp,
"reliabilityOffered",
"J");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetLongField(env,
obj_pp,
fid,
(jlong)publ_prop->reliabilityOffered);
/////////////////////////////////////////////////
// fieldID - sendQueueSize
fid = (*env)->GetFieldID(env,
cls_pp,
"sendQueueSize",
"J");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetLongField(env,
obj_pp,
fid,
(jlong)publ_prop->sendQueueSize);
/////////////////////////////////////////////////
// fieldID - strength
fid = (*env)->GetFieldID(env,
cls_pp,
"strength",
"I");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetIntField(env,
obj_pp,
fid,
(jint)publ_prop->strength);
/////////////////////////////////////////////////
// fieldID - criticalQueueLevel
fid = (*env)->GetFieldID(env,
cls_pp,
"criticalQueueLevel",
"J");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetLongField(env,
obj_pp,
fid,
(jlong)publ_prop->criticalQueueLevel);
/////////////////////////////////////////////////
// fieldID - HBMaxRetries
fid = (*env)->GetFieldID(env,
cls_pp,
"HBMaxRetries",
"J");
if (fid == 0) {
#ifdef TEST_STAGE
printf(":!c: fid = NULL \n");
#endif
break;
}
(*env)->SetLongField(env,
obj_pp,
fid,
(jlong)publ_prop->HBMaxRetries);
// set flag
flag_ok = 1;
} while (0);
if (flag_ok == 0) {
return NULL;
}
return obj_pp;
}
static oop _newOops(int type, size_t size) { oop obj= GC_malloc(size); setType(obj, type); return obj; }
//
// Establishes the type of the resultant operation, as well as
// makes the operator the correct one for the operands.
//
// Returns false if operator can't work on operands.
//
bool TIntermBinary::promote(TInfoSink& infoSink)
{
// This function only handles scalars, vectors, and matrices.
if (left->isArray() || right->isArray()) {
infoSink.info.message(EPrefixInternalError, getLine(), "Invalid operation for arrays");
return false;
}
// GLSL ES 2.0 does not support implicit type casting.
// So the basic type should always match.
if (left->getBasicType() != right->getBasicType())
return false;
//
// Base assumption: just make the type the same as the left
// operand. Then only deviations from this need be coded.
//
setType(left->getType());
// The result gets promoted to the highest precision.
TPrecision higherPrecision = GetHigherPrecision(left->getPrecision(), right->getPrecision());
getTypePointer()->setPrecision(higherPrecision);
// Binary operations results in temporary variables unless both
// operands are const.
if (left->getQualifier() != EvqConst || right->getQualifier() != EvqConst) {
getTypePointer()->setQualifier(EvqTemporary);
}
int size = std::max(left->getNominalSize(), right->getNominalSize());
//
// All scalars. Code after this test assumes this case is removed!
//
if (size == 1) {
switch (op) {
//
// Promote to conditional
//
case EOpEqual:
case EOpNotEqual:
case EOpLessThan:
case EOpGreaterThan:
case EOpLessThanEqual:
case EOpGreaterThanEqual:
setType(TType(EbtBool, EbpUndefined));
break;
//
// And and Or operate on conditionals
//
case EOpLogicalAnd:
case EOpLogicalOr:
// Both operands must be of type bool.
if (left->getBasicType() != EbtBool || right->getBasicType() != EbtBool)
return false;
setType(TType(EbtBool, EbpUndefined));
break;
default:
break;
}
return true;
}
// If we reach here, at least one of the operands is vector or matrix.
// The other operand could be a scalar, vector, or matrix.
// Are the sizes compatible?
//
if (left->getNominalSize() != right->getNominalSize()) {
// If the nominal size of operands do not match:
// One of them must be scalar.
if (left->getNominalSize() != 1 && right->getNominalSize() != 1)
return false;
// Operator cannot be of type pure assignment.
if (op == EOpAssign || op == EOpInitialize)
return false;
}
//
// Can these two operands be combined?
//
TBasicType basicType = left->getBasicType();
switch (op) {
case EOpMul:
if (!left->isMatrix() && right->isMatrix()) {
if (left->isVector())
op = EOpVectorTimesMatrix;
else {
op = EOpMatrixTimesScalar;
setType(TType(basicType, higherPrecision, EvqTemporary, size, true));
}
} else if (left->isMatrix() && !right->isMatrix()) {
if (right->isVector()) {
op = EOpMatrixTimesVector;
setType(TType(basicType, higherPrecision, EvqTemporary, size, false));
} else {
op = EOpMatrixTimesScalar;
}
} else if (left->isMatrix() && right->isMatrix()) {
op = EOpMatrixTimesMatrix;
} else if (!left->isMatrix() && !right->isMatrix()) {
if (left->isVector() && right->isVector()) {
// leave as component product
} else if (left->isVector() || right->isVector()) {
op = EOpVectorTimesScalar;
setType(TType(basicType, higherPrecision, EvqTemporary, size, false));
}
} else {
infoSink.info.message(EPrefixInternalError, getLine(), "Missing elses");
return false;
}
break;
case EOpMulAssign:
if (!left->isMatrix() && right->isMatrix()) {
if (left->isVector())
op = EOpVectorTimesMatrixAssign;
else {
return false;
}
} else if (left->isMatrix() && !right->isMatrix()) {
if (right->isVector()) {
return false;
} else {
op = EOpMatrixTimesScalarAssign;
}
} else if (left->isMatrix() && right->isMatrix()) {
op = EOpMatrixTimesMatrixAssign;
} else if (!left->isMatrix() && !right->isMatrix()) {
if (left->isVector() && right->isVector()) {
// leave as component product
} else if (left->isVector() || right->isVector()) {
if (! left->isVector())
return false;
op = EOpVectorTimesScalarAssign;
setType(TType(basicType, higherPrecision, EvqTemporary, size, false));
}
} else {
infoSink.info.message(EPrefixInternalError, getLine(), "Missing elses");
return false;
}
break;
case EOpAssign:
case EOpInitialize:
case EOpAdd:
case EOpSub:
case EOpDiv:
case EOpAddAssign:
case EOpSubAssign:
case EOpDivAssign:
if ((left->isMatrix() && right->isVector()) ||
(left->isVector() && right->isMatrix()))
return false;
setType(TType(basicType, higherPrecision, EvqTemporary, size, left->isMatrix() || right->isMatrix()));
break;
case EOpEqual:
case EOpNotEqual:
case EOpLessThan:
case EOpGreaterThan:
case EOpLessThanEqual:
case EOpGreaterThanEqual:
if ((left->isMatrix() && right->isVector()) ||
(left->isVector() && right->isMatrix()))
return false;
setType(TType(EbtBool, EbpUndefined));
break;
default:
return false;
}
return true;
}
ChessBoardPiece::ChessBoardPiece(CBW::WidgetType type, CBW::WidgetColor color, int file, int rank)
{
setPostition(file, rank);
setType(type);
setColor(color);
}
// Internal set type method
SubsystemType
SubsystemInfo::setType( SubsystemType _type, const char *_type_name )
{
return setType( m_InfoTable->lookup(_type), _type_name );
}
MidiChannelMessage::MidiChannelMessage(MidiMessageType type){
setType(type);
};
void Font::init()
{
setType(GameObjectMetaType::Font);
mFontAsset = 0;
}
Weapon::Weapon(std::string str)
{
setType(str);
std::cout << "Weapon created" << std::endl;
return ;
}
MappedEvent::MappedEvent(InstrumentId id,
const Event &e,
const RealTime &eventTime,
const RealTime &duration):
m_trackId((int)NO_TRACK),
m_instrument(id),
m_type(MidiNote),
m_data1(0),
m_data2(0),
m_eventTime(eventTime),
m_duration(duration),
m_audioStartMarker(0, 0),
m_dataBlockId(0),
m_runtimeSegmentId( -1),
m_autoFade(false),
m_fadeInTime(RealTime::zeroTime),
m_fadeOutTime(RealTime::zeroTime),
m_recordedChannel(0),
m_recordedDevice(0)
{
try {
// For each event type, we set the properties in a particular
// order: first the type, then whichever of data1 and data2 fits
// less well with its default value. This way if one throws an
// exception for no data, we still have a good event with the
// defaults set.
if (e.isa(Note::EventType)) {
m_type = MidiNoteOneShot;
long v = MidiMaxValue;
e.get<Int>(BaseProperties::VELOCITY, v);
m_data2 = v;
m_data1 = e.get<Int>(BaseProperties::PITCH);
} else if (e.isa(PitchBend::EventType)) {
m_type = MidiPitchBend;
PitchBend pb(e);
m_data1 = pb.getMSB();
m_data2 = pb.getLSB();
} else if (e.isa(Controller::EventType)) {
m_type = MidiController;
Controller c(e);
m_data1 = c.getNumber();
m_data2 = c.getValue();
} else if (e.isa(ProgramChange::EventType)) {
m_type = MidiProgramChange;
ProgramChange pc(e);
m_data1 = pc.getProgram();
} else if (e.isa(KeyPressure::EventType)) {
m_type = MidiKeyPressure;
KeyPressure kp(e);
m_data1 = kp.getPitch();
m_data2 = kp.getPressure();
} else if (e.isa(ChannelPressure::EventType)) {
m_type = MidiChannelPressure;
ChannelPressure cp(e);
m_data1 = cp.getPressure();
} else if (e.isa(SystemExclusive::EventType)) {
m_type = MidiSystemMessage;
m_data1 = MIDI_SYSTEM_EXCLUSIVE;
SystemExclusive s(e);
std::string dataBlock = s.getRawData();
DataBlockRepository::getInstance()->registerDataBlockForEvent(dataBlock, this);
} else if (e.isa(Text::EventType)) {
const Rosegarden::Text text(e);
// Somewhat hacky: We know that annotations and LilyPond directives
// aren't to be output, so we make their MappedEvents invalid.
// InternalSegmentMapper will then discard those.
if (text.getTextType() == Text::Annotation || text.getTextType() == Text::LilyPondDirective) {
setType(InvalidMappedEvent);
} else {
setType(MappedEvent::Text);
MidiByte midiTextType =
(text.getTextType() == Text::Lyric) ?
MIDI_LYRIC :
MIDI_TEXT_EVENT;
setData1(midiTextType);
std::string metaMessage = text.getText();
addDataString(metaMessage);
}
} else {
m_type = InvalidMappedEvent;
}
} catch (MIDIValueOutOfRange r) {
#ifdef DEBUG_MAPPEDEVENT
std::cerr << "MIDI value out of range in MappedEvent ctor"
<< std::endl;
#else
;
#endif
} catch (Event::NoData d) {
#ifdef DEBUG_MAPPEDEVENT
std::cerr << "Caught Event::NoData in MappedEvent ctor, message is:"
<< std::endl << d.getMessage() << std::endl;
#else
;
#endif
} catch (Event::BadType b) {
#ifdef DEBUG_MAPPEDEVENT
std::cerr << "Caught Event::BadType in MappedEvent ctor, message is:"
<< std::endl << b.getMessage() << std::endl;
#else
;
#endif
} catch (SystemExclusive::BadEncoding e) {
#ifdef DEBUG_MAPPEDEVENT
std::cerr << "Caught bad SysEx encoding in MappedEvent ctor"
<< std::endl;
#else
;
#endif
}
}
Customer::Customer()
{
setType(Location::CUSTOMER);
}
QgsRasterFormatSaveOptionsWidget::QgsRasterFormatSaveOptionsWidget( QWidget* parent, const QString& format,
QgsRasterFormatSaveOptionsWidget::Type type, const QString& provider )
: QWidget( parent )
, mFormat( format )
, mProvider( provider )
, mRasterLayer( nullptr )
, mRasterFileName( QString() )
, mPyramids( false )
, mPyramidsFormat( QgsRaster::PyramidsGTiff )
{
setupUi( this );
setType( type );
if ( mBuiltinProfiles.isEmpty() )
{
// key=profileKey values=format,profileName,options
mBuiltinProfiles[ QStringLiteral( "z_adefault" )] = ( QStringList() << QLatin1String( "" ) << tr( "Default" ) << QLatin1String( "" ) );
// these GTiff profiles are based on Tim's benchmarks at
// http://linfiniti.com/2011/05/gdal-efficiency-of-various-compression-algorithms/
// big: no compression | medium: reasonable size/speed tradeoff | small: smallest size
mBuiltinProfiles[ QStringLiteral( "z_gtiff_1big" )] =
( QStringList() << QStringLiteral( "GTiff" ) << tr( "No compression" )
<< QStringLiteral( "COMPRESS=NONE BIGTIFF=IF_NEEDED" ) );
mBuiltinProfiles[ QStringLiteral( "z_gtiff_2medium" )] =
( QStringList() << QStringLiteral( "GTiff" ) << tr( "Low compression" )
<< QStringLiteral( "COMPRESS=PACKBITS" ) );
mBuiltinProfiles[ QStringLiteral( "z_gtiff_3small" )] =
( QStringList() << QStringLiteral( "GTiff" ) << tr( "High compression" )
<< QStringLiteral( "COMPRESS=DEFLATE PREDICTOR=2 ZLEVEL=9" ) );
mBuiltinProfiles[ QStringLiteral( "z_gtiff_4jpeg" )] =
( QStringList() << QStringLiteral( "GTiff" ) << tr( "JPEG compression" )
<< QStringLiteral( "COMPRESS=JPEG JPEG_QUALITY=75" ) );
// overview compression schemes for GTiff format, see
// http://www.gdal.org/gdaladdo.html and http://www.gdal.org/frmt_gtiff.html
// TODO - should we offer GDAL_TIFF_OVR_BLOCKSIZE option here or in QgsRasterPyramidsOptionsWidget ?
mBuiltinProfiles[ QStringLiteral( "z__pyramids_gtiff_1big" )] =
( QStringList() << QStringLiteral( "_pyramids" ) << tr( "No compression" )
<< QStringLiteral( "COMPRESS_OVERVIEW=NONE BIGTIFF_OVERVIEW=IF_NEEDED" ) );
mBuiltinProfiles[ QStringLiteral( "z__pyramids_gtiff_2medium" )] =
( QStringList() << QStringLiteral( "_pyramids" ) << tr( "Low compression" )
<< QStringLiteral( "COMPRESS_OVERVIEW=PACKBITS" ) );
mBuiltinProfiles[ QStringLiteral( "z__pyramids_gtiff_3small" )] =
( QStringList() << QStringLiteral( "_pyramids" ) << tr( "High compression" )
<< QStringLiteral( "COMPRESS_OVERVIEW=DEFLATE PREDICTOR_OVERVIEW=2 ZLEVEL=9" ) ); // how to set zlevel?
mBuiltinProfiles[ QStringLiteral( "z__pyramids_gtiff_4jpeg" )] =
( QStringList() << QStringLiteral( "_pyramids" ) << tr( "JPEG compression" )
<< PYRAMID_JPEG_YCBCR_COMPRESSION );
}
connect( mProfileComboBox, SIGNAL( currentIndexChanged( const QString & ) ),
this, SLOT( updateOptions() ) );
connect( mOptionsTable, SIGNAL( cellChanged( int, int ) ), this, SLOT( optionsTableChanged() ) );
connect( mOptionsHelpButton, SIGNAL( clicked() ), this, SLOT( helpOptions() ) );
connect( mOptionsValidateButton, SIGNAL( clicked() ), this, SLOT( validateOptions() ) );
// create eventFilter to map right click to swapOptionsUI()
// mOptionsLabel->installEventFilter( this );
mOptionsLineEdit->installEventFilter( this );
mOptionsStackedWidget->installEventFilter( this );
updateControls();
updateProfiles();
QgsDebugMsg( "done" );
}
bool CSensorUSBMotionNodeAccel::detect()
{
setType();
setPort();
if (qcn_main::g_iStop) return false;
// always check dll existence & try to load!
std::string sstrDLL;
// setup DLL path, if returns false then DLL doesn't exist at the path where it should
if (!qcn_util::setDLLPath(sstrDLL, m_cstrDLL)) {
closePort();
return false;
}
#ifdef __USE_DLOPEN__
if (qcn_main::g_iStop) return false;
m_WinDLLHandle = dlopen(sstrDLL.c_str(), RTLD_LAZY | RTLD_GLOBAL); // default
if (!m_WinDLLHandle) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: dynamic library %s dlopen error %s\n", sstrDLL.c_str(), dlerror());
return false;
}
if (qcn_main::g_iStop) return false;
m_SymHandle = (PtrMotionNodeAccelFactory) dlsym(m_WinDLLHandle, "MotionNodeAccel_Factory");
if (!m_SymHandle) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: Could not get dlsym MotionNode Accel dylib file %s - error %s\n", sstrDLL.c_str(), dlerror());
return false;
}
m_node = (*m_SymHandle)(MOTIONNODE_ACCEL_API_VERSION);
#else // for Windows or not using dlopen just use the direct motionnode factory
if ( ! ( m_WinDLLHandle = ::LoadLibrary(sstrDLL.c_str()) ) ) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: Cannot load DLL %s\n", sstrDLL.c_str());
return false;
}
m_node = MotionNodeAccel::Factory();
#endif
if (!m_node) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: Could not make MotionNode Factory\n");
return false; // not found
}
if (qcn_main::g_iStop) return false;
// Detect the number of available devices.
unsigned int count = 0;
m_node->get_num_device(count);
if (!count) {
// fprintf(stderr, "CSensorUSBMotionNodeAccel: no MN detected via DLL %s\n", sstrDLL.c_str());
closePort();
return false;
}
if (qcn_main::g_iStop) return false;
// Set the G range. Default is 2.
if (!m_node->set_gselect(2.0)) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: Could not set range on MotionNode Accel\n");
closePort();
return false;
}
// set the sample rate to 100Hz to get at least 1 & possibly 2 samples at 50Hz
/* from Luke Tokheim:
Use the "set_delay" method before you connect, just like choosing the G
range. The delay ranges from 0 to 1. The available sample rates are from
50 to 100 Hz by 10 Hz increments. Compute the delay value with the
following formula:
delay = 1 - (target_rate - minimum_rate) * 0.0125;
So, to sample at 100 Hz set the delay to:
1 - (100 - 50) * 0.0125 = 0.375
To sample at 50 Hz, set the delay to:
1 - (50 - 50) * 0.0125 = 1
*/
if (!m_node->set_delay(0.0f)) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: Could not set delay time on MotionNode Accel\n");
closePort();
return false;
}
if (qcn_main::g_iStop) return false;
if (!m_node->connect()) { // connect to the sensor
fprintf(stderr, "CSensorUSBMotionNodeAccel: Could not connect to MotionNode Accel\n");
closePort();
return false;
}
if (qcn_main::g_iStop) return false;
if (!m_node->start()) {
fprintf(stderr, "CSensorUSBMotionNodeAccel: Could not start MotionNode Accel\n");
closePort();
return false;
}
// OK, at this point we should be connected, so from here on out can just read_xyz until closePort()
// set as a single sample per point
setSingleSampleDT(true); // mn samples itself
// NB: closePort resets the type & port, so have to set again
setType(SENSOR_USB_MOTIONNODEACCEL);
setPort(getTypeEnum());
return true;
}
NumToken::NumToken(ANTLRTokenType tokenTypeNew) {
init();
setType(tokenTypeNew);
setLine(0);
}
RectMulticastStrategy::RectMulticastStrategy(CkArrayID aid)
: Strategy(), CharmStrategy() {
ainfo.setDestinationArray(aid);
setType(ARRAY_STRATEGY);
}
//
// Establishes the type of the resultant operation, as well as
// makes the operator the correct one for the operands.
//
// For lots of operations it should already be established that the operand
// combination is valid, but returns false if operator can't work on operands.
//
bool TIntermBinary::promote(TInfoSink &infoSink)
{
ASSERT(mLeft->isArray() == mRight->isArray());
//
// Base assumption: just make the type the same as the left
// operand. Then only deviations from this need be coded.
//
setType(mLeft->getType());
// The result gets promoted to the highest precision.
TPrecision higherPrecision = GetHigherPrecision(
mLeft->getPrecision(), mRight->getPrecision());
getTypePointer()->setPrecision(higherPrecision);
// Binary operations results in temporary variables unless both
// operands are const.
if (mLeft->getQualifier() != EvqConst || mRight->getQualifier() != EvqConst)
{
getTypePointer()->setQualifier(EvqTemporary);
}
const int nominalSize =
std::max(mLeft->getNominalSize(), mRight->getNominalSize());
//
// All scalars or structs. Code after this test assumes this case is removed!
//
if (nominalSize == 1)
{
switch (mOp)
{
//
// Promote to conditional
//
case EOpEqual:
case EOpNotEqual:
case EOpLessThan:
case EOpGreaterThan:
case EOpLessThanEqual:
case EOpGreaterThanEqual:
setType(TType(EbtBool, EbpUndefined));
break;
//
// And and Or operate on conditionals
//
case EOpLogicalAnd:
case EOpLogicalXor:
case EOpLogicalOr:
ASSERT(mLeft->getBasicType() == EbtBool && mRight->getBasicType() == EbtBool);
setType(TType(EbtBool, EbpUndefined));
break;
default:
break;
}
return true;
}
// If we reach here, at least one of the operands is vector or matrix.
// The other operand could be a scalar, vector, or matrix.
// Can these two operands be combined?
//
TBasicType basicType = mLeft->getBasicType();
switch (mOp)
{
case EOpMul:
if (!mLeft->isMatrix() && mRight->isMatrix())
{
if (mLeft->isVector())
{
mOp = EOpVectorTimesMatrix;
setType(TType(basicType, higherPrecision, EvqTemporary,
mRight->getCols(), 1));
}
else
{
mOp = EOpMatrixTimesScalar;
setType(TType(basicType, higherPrecision, EvqTemporary,
mRight->getCols(), mRight->getRows()));
}
}
else if (mLeft->isMatrix() && !mRight->isMatrix())
{
if (mRight->isVector())
{
mOp = EOpMatrixTimesVector;
setType(TType(basicType, higherPrecision, EvqTemporary,
mLeft->getRows(), 1));
}
else
{
mOp = EOpMatrixTimesScalar;
}
}
else if (mLeft->isMatrix() && mRight->isMatrix())
{
mOp = EOpMatrixTimesMatrix;
setType(TType(basicType, higherPrecision, EvqTemporary,
mRight->getCols(), mLeft->getRows()));
}
else if (!mLeft->isMatrix() && !mRight->isMatrix())
{
if (mLeft->isVector() && mRight->isVector())
{
// leave as component product
}
else if (mLeft->isVector() || mRight->isVector())
{
mOp = EOpVectorTimesScalar;
setType(TType(basicType, higherPrecision, EvqTemporary,
nominalSize, 1));
}
}
else
{
infoSink.info.message(EPrefixInternalError, getLine(),
"Missing elses");
return false;
}
if (!ValidateMultiplication(mOp, mLeft->getType(), mRight->getType()))
{
return false;
}
break;
case EOpMulAssign:
if (!mLeft->isMatrix() && mRight->isMatrix())
{
if (mLeft->isVector())
{
mOp = EOpVectorTimesMatrixAssign;
}
else
{
return false;
}
}
else if (mLeft->isMatrix() && !mRight->isMatrix())
{
if (mRight->isVector())
{
return false;
}
else
{
mOp = EOpMatrixTimesScalarAssign;
}
}
else if (mLeft->isMatrix() && mRight->isMatrix())
{
mOp = EOpMatrixTimesMatrixAssign;
setType(TType(basicType, higherPrecision, EvqTemporary,
mRight->getCols(), mLeft->getRows()));
}
else if (!mLeft->isMatrix() && !mRight->isMatrix())
{
if (mLeft->isVector() && mRight->isVector())
{
// leave as component product
}
else if (mLeft->isVector() || mRight->isVector())
{
if (!mLeft->isVector())
return false;
mOp = EOpVectorTimesScalarAssign;
setType(TType(basicType, higherPrecision, EvqTemporary,
mLeft->getNominalSize(), 1));
}
}
else
{
infoSink.info.message(EPrefixInternalError, getLine(),
"Missing elses");
return false;
}
if (!ValidateMultiplication(mOp, mLeft->getType(), mRight->getType()))
{
return false;
}
break;
case EOpAssign:
case EOpInitialize:
// No more additional checks are needed.
ASSERT((mLeft->getNominalSize() == mRight->getNominalSize()) &&
(mLeft->getSecondarySize() == mRight->getSecondarySize()));
break;
case EOpAdd:
case EOpSub:
case EOpDiv:
case EOpIMod:
case EOpBitShiftLeft:
case EOpBitShiftRight:
case EOpBitwiseAnd:
case EOpBitwiseXor:
case EOpBitwiseOr:
case EOpAddAssign:
case EOpSubAssign:
case EOpDivAssign:
case EOpIModAssign:
case EOpBitShiftLeftAssign:
case EOpBitShiftRightAssign:
case EOpBitwiseAndAssign:
case EOpBitwiseXorAssign:
case EOpBitwiseOrAssign:
if ((mLeft->isMatrix() && mRight->isVector()) ||
(mLeft->isVector() && mRight->isMatrix()))
{
return false;
}
// Are the sizes compatible?
if (mLeft->getNominalSize() != mRight->getNominalSize() ||
mLeft->getSecondarySize() != mRight->getSecondarySize())
{
// If the nominal sizes of operands do not match:
// One of them must be a scalar.
if (!mLeft->isScalar() && !mRight->isScalar())
return false;
// In the case of compound assignment other than multiply-assign,
// the right side needs to be a scalar. Otherwise a vector/matrix
// would be assigned to a scalar. A scalar can't be shifted by a
// vector either.
if (!mRight->isScalar() &&
(isAssignment() ||
mOp == EOpBitShiftLeft ||
mOp == EOpBitShiftRight))
return false;
}
{
const int secondarySize = std::max(
mLeft->getSecondarySize(), mRight->getSecondarySize());
setType(TType(basicType, higherPrecision, EvqTemporary,
nominalSize, secondarySize));
if (mLeft->isArray())
{
ASSERT(mLeft->getArraySize() == mRight->getArraySize());
mType.setArraySize(mLeft->getArraySize());
}
}
break;
case EOpEqual:
case EOpNotEqual:
case EOpLessThan:
case EOpGreaterThan:
case EOpLessThanEqual:
case EOpGreaterThanEqual:
ASSERT((mLeft->getNominalSize() == mRight->getNominalSize()) &&
(mLeft->getSecondarySize() == mRight->getSecondarySize()));
setType(TType(EbtBool, EbpUndefined));
break;
default:
return false;
}
return true;
}
/**
* Sets message type to @a type.
*
* @overload
* @sa Type
*/
void Message::setType(Type type)
{
setType( typeToString(type) );
}
// Public set type method
SubsystemType
SubsystemInfo::setType( SubsystemType _type )
{
return setType( _type, NULL );
}
PC::PC() {
setType(0);
}
static oop _newBits(int type, size_t size) { oop obj= GC_malloc_atomic(size); setType(obj, type); return obj; }
Mouse::Mouse()
{
// Hide cursor
SDL_ShowCursor(0);
setType(BIG_ARROW);
}
CntDetailModelItem::CntDetailModelItem( QContactDetail aDetail ) :
HbDataFormModelItem(),
mDetail( aDetail )
{
setType( CustomItemBase );
}
Company::Company(const char* username, const char* password) : Customer(username, password) {
setType(2);
}
//Default constructor
Fruit::Fruit() : Food()
{
setType(FRUIT);
}
void LDZGameLayer::initLevel(int level){
Size vs = Director::getInstance()->getVisibleSize();
Vec2 vo = Director::getInstance()->getVisibleOrigin();
_mode = MODE_BEGAIN;
TMXTiledMap *map = TMXTiledMap::create("back.tmx");
_map = map;
_mapSize = Size(map->getMapSize().width * map->getTileSize().width , map->getMapSize().height * map->getTileSize().height);
map->setPosition(Vec2(0, 0));
this->addChild(map);
//main char
_mainC = Sprite::createWithSpriteFrameName("1.png");
_mainC->setPosition(_mapSize.width/2, _mainC->getContentSize().height/2 + 10);
this->addChild(_mainC,1);
//progress
auto progress = ProgressTimer::create(Sprite::createWithSpriteFrameName("tempb.png"));
float progx = _mapSize.width/2 - _mainC->getContentSize().width/2 - progress->getContentSize().width/2 - 5;
float progy = _mainC->getContentSize().height/2 + 10;
progress->setPosition( progx, progy);
progress->setType(cocos2d::ProgressTimer::Type::BAR);
progress->setBarChangeRate(Vec2(0, 1));
progress->setMidpoint(Vec2(0, 0));
auto progback = Sprite::createWithSpriteFrameName("temp.png");
progback->setPosition(progx, progy);
this->addChild(progback);
this->addChild(progress,1);
progress->setVisible(false);
progback->setVisible(false);
_powerProg = progress;
_powerProgBack = progback;
//limit
float height = 50 + arc4random()%100;
float uy = _mapSize.height/3 + _mapSize.height/3*2*CCRANDOM_0_1() - 5;
float dy = uy - height;
_upLimit = Sprite::createWithSpriteFrameName("limit.png");
_upLimit->setPosition(_mapSize.width/2, uy);
this->addChild(_upLimit);
_downLimit = Sprite::createWithSpriteFrameName("limit.png");
_downLimit->setPosition(_mapSize.width/2, dy);
this->addChild(_downLimit);
//guide
auto gt = ui::Text::create(LHLocalizedCString("guidetext"), Common_Font, 25);
gt->setColor(Color3B::RED);
gt->setPosition(Vec2(_mainC->getPosition().x , _mainC->getBoundingBox().getMaxY() + gt->getContentSize().height/2));
this->addChild(gt);
auto bl = Blink::create(1, 1);
auto rp = RepeatForever::create(bl);
gt->runAction(rp);
auto da = Sprite::create("da.png");
da->setScaleY(height/da->getContentSize().height);
da->setPosition(Vec2(_mainC->getPosition().x,_downLimit->getPositionY()+height/2));
this->addChild(da);
auto lis = EventListenerTouchOneByOne::create();
lis->onTouchBegan = [this,gt,progress,progback,da](Touch* tmpTouch, Event*){
if (_mode == MODE_VIEW) {
Vec2 loca = tmpTouch->getLocation();
loca = this->convertToNodeSpace(loca);
if (_mainC->getBoundingBox().containsPoint(loca)) {
CallFunc *call = CallFunc::create([this](){
_mode = MODE_POWER;
this->scheduleUpdate();
CocosDenshion::SimpleAudioEngine::getInstance()->playEffect("wiso.wav");
});
float focusMargin = 20;
this->focusOn(_mainC->getPosition(), _mainC->getContentSize().height + focusMargin, true , call);
_mode = MODE_BEGAIN;
gt->removeFromParent();
da->removeFromParent();
progress->setVisible(true);
progback->setVisible(true);
progress->setPercentage(0);
}
}else if (_mode == MODE_POWER_END){
_mode = MODE_POWER;
}
return true;
};
lis->onTouchMoved = [this](Touch* tmpTouch, Event*){
Vec2 cu = tmpTouch->getLocation();
Vec2 last = tmpTouch->getPreviousLocation();
if (_mode == MODE_VIEW) {
float toy = _focusCenter.y + (last.y - cu.y);
if (toy+_focusLen/2 > _upLimit->getPositionY() + 20) {
toy = _upLimit->getPositionY()+20 - _focusLen/2;
}
this->focusOn(Vec2(_focusCenter.x , toy),_focusLen, false);
}else if (_mode == MODE_POWER){
float dy = fabsf(cu.y - last.y);
_powerProg->setPercentage(_powerProg->getPercentage()+dy/(_powerProg->getPercentage()+1)/MOVE_FACTOR);
}
};
lis->onTouchEnded = [this](Touch*, Event*){
if (_mode == MODE_POWER) {
_mode = MODE_POWER_END;
_powerCount = 0.1f;
}
};
this->getEventDispatcher()->addEventListenerWithSceneGraphPriority(lis, this);
focusOn(Vec2(_mapSize.width/2,(uy - height/2)), vs.width, false);
auto dl2 = DelayTime::create(1);
CallFunc *call = CallFunc::create([this](){
auto tmpcall = CallFunc::create([this](){
_mode = MODE_VIEW;
});
this->focusOn(_mainC->getPosition(), _focusLen, true , tmpcall);
});
auto sq = Sequence::create(dl2,call, NULL);
this->runAction(sq);
}
XHtmlElements::Img::Img() :
XHtmlElement()
{
setType( "IMG" );
}
ConstantExpression::ConstantExpression(Constant constant) :
constant { constant }
{
auto type = constant.getType();
setType(*type);
}
/*!
Constructs an easing curve of the given \a type.
*/
QEasingCurve::QEasingCurve(Type type)
: d_ptr(new QEasingCurvePrivate)
{
setType(type);
}
void WatchItem::parseHelper(const GdbMi &input)
{
setChildrenUnneeded();
GdbMi mi = input["type"];
if (mi.isValid())
setType(mi.data());
editvalue = input["editvalue"].data();
editformat = DebuggerDisplay(input["editformat"].toInt());
editencoding = DebuggerEncoding(input["editencoding"].data());
mi = input["valueelided"];
if (mi.isValid())
elided = mi.toInt();
mi = input["bitpos"];
if (mi.isValid())
bitpos = mi.toInt();
mi = input["bitsize"];
if (mi.isValid())
bitsize = mi.toInt();
mi = input["origaddr"];
if (mi.isValid())
origaddr = mi.toAddress();
mi = input["address"];
if (mi.isValid()) {
address = mi.toAddress();
if (exp.isEmpty()) {
if (iname.startsWith("local.") && iname.count('.') == 1)
// Solve one common case of adding 'class' in
// *(class X*)0xdeadbeef for gdb.
exp = name.toLatin1();
else
exp = "*(" + gdbQuoteTypes(type) + "*)" + hexAddress();
}
}
mi = input["value"];
QByteArray enc = input["valueencoded"].data();
if (mi.isValid() || !enc.isEmpty()) {
setValue(decodeData(mi.data(), enc));
} else {
setValueNeeded();
}
mi = input["size"];
if (mi.isValid())
size = mi.toInt();
mi = input["exp"];
if (mi.isValid())
exp = mi.data();
mi = input["valueenabled"];
if (mi.data() == "true")
valueEnabled = true;
else if (mi.data() == "false")
valueEnabled = false;
mi = input["valueeditable"];
if (mi.data() == "true")
valueEditable = true;
else if (mi.data() == "false")
valueEditable = false;
mi = input["numchild"]; // GDB/MI
if (mi.isValid())
setHasChildren(mi.toInt() > 0);
mi = input["haschild"]; // native-mixed
if (mi.isValid())
setHasChildren(mi.toInt() > 0);
mi = input["arraydata"];
if (mi.isValid()) {
DebuggerEncoding encoding(input["arrayencoding"].data());
QByteArray childType = input["childtype"].data();
decodeArrayData(this, mi.data(), encoding, childType);
} else {
const GdbMi children = input["children"];
if (children.isValid()) {
bool ok = false;
// Try not to repeat data too often.
const GdbMi childType = input["childtype"];
const GdbMi childNumChild = input["childnumchild"];
qulonglong addressBase = input["addrbase"].data().toULongLong(&ok, 0);
qulonglong addressStep = input["addrstep"].data().toULongLong(&ok, 0);
for (int i = 0, n = int(children.children().size()); i != n; ++i) {
const GdbMi &subinput = children.children().at(i);
WatchItem *child = new WatchItem;
if (childType.isValid())
child->setType(childType.data());
if (childNumChild.isValid())
child->setHasChildren(childNumChild.toInt() > 0);
GdbMi name = subinput["name"];
QByteArray nn;
if (name.isValid()) {
nn = name.data();
child->name = QString::fromLatin1(nn);
} else {
nn.setNum(i);
child->name = QString::fromLatin1("[%1]").arg(i);
}
GdbMi iname = subinput["iname"];
if (iname.isValid())
child->iname = iname.data();
else
child->iname = this->iname + '.' + nn;
if (addressStep) {
child->address = addressBase + i * addressStep;
child->exp = "*(" + gdbQuoteTypes(child->type) + "*)" + child->hexAddress();
}
QByteArray key = subinput["key"].data();
if (!key.isEmpty())
child->name = decodeData(key, subinput["keyencoded"].data());
child->parseHelper(subinput);
appendChild(child);
}
}
}
}
