void AxisPlot::DrawAxesArray(wxDC &dc, wxRect rc, AxisArray *axes, bool vertical)
{
wxRect rcAxis(rc);
for (size_t nAxis = 0; nAxis < axes->Count(); nAxis++) {
Axis *axis = (*axes)[nAxis];
wxCoord ext = axis->GetExtent(dc);
if (vertical) {
rcAxis.width = ext;
}
else {
rcAxis.height = ext;
}
axis->Draw(dc, rcAxis);
if (vertical) {
rcAxis.x += ext;
}
else {
rcAxis.y += ext;
}
}
}
/** Set up the output workspace in a Workspace2D
* @param numentries :: number of log entries to output
* @param times :: vector of Kernel::DateAndTime
* @param values :: vector of log value in double
*/
void ExportTimeSeriesLog::setupWorkspace2D(int numentries,
vector<DateAndTime> ×,
vector<double> values) {
Kernel::DateAndTime runstart(
m_dataWS->run().getProperty("run_start")->value());
size_t size = static_cast<size_t>(numentries);
m_outWS = boost::dynamic_pointer_cast<MatrixWorkspace>(
WorkspaceFactory::Instance().create("Workspace2D", 1, size, size));
if (!m_outWS)
throw runtime_error(
"Unable to create a Workspace2D casted to MatrixWorkspace.");
MantidVec &vecX = m_outWS->dataX(0);
MantidVec &vecY = m_outWS->dataY(0);
MantidVec &vecE = m_outWS->dataE(0);
for (size_t i = 0; i < size; ++i) {
int64_t dtns = times[i].totalNanoseconds() - runstart.totalNanoseconds();
vecX[i] = static_cast<double>(dtns) * 1.0E-9;
vecY[i] = values[i];
vecE[i] = 0.0;
}
Axis *xaxis = m_outWS->getAxis(0);
xaxis->setUnit("Time");
return;
}
TH2* RootWriter::CreateTH2(Histogram2D* h)
{
const Axis& xax = h->GetAxisX(), yax = h->GetAxisY();
const int xchannels = xax.GetBinCount();
const int ychannels = yax.GetBinCount();
TH2* mat = new TH2F( h->GetName().c_str(), h->GetTitle().c_str(),
xchannels, xax.GetLeft(), xax.GetRight(),
ychannels, yax.GetLeft(), yax.GetRight() );
mat->SetOption( "colz" );
mat->SetContour( 64 );
TAxis* rxax = mat->GetXaxis();
rxax->SetTitle(xax.GetTitle().c_str());
rxax->SetTitleSize(0.03);
rxax->SetLabelSize(0.03);
TAxis* ryax = mat->GetYaxis();
ryax->SetTitle(yax.GetTitle().c_str());
ryax->SetTitleSize(0.03);
ryax->SetLabelSize(0.03);
ryax->SetTitleOffset(1.3);
TAxis* zax = mat->GetZaxis();
zax->SetLabelSize(0.025);
for(int iy=0; iy<ychannels+2; ++iy)
for(int ix=0; ix<xchannels+2; ++ix)
mat->SetBinContent(ix, iy, h->GetBinContent(ix, iy));
mat->SetEntries( h->GetEntries() );
return mat;
}
void Pulsar::ComponentModel::evaluate (float *vals,
unsigned nvals, int icomp_selected)
{
//Construct the summed model
SumRule< Univariate<Scalar> > m;
if (icomp_selected >= 0)
{
check ("evaluate", icomp_selected);
m += components[icomp_selected];
}
else
{
for (unsigned icomp=0; icomp < components.size(); icomp++)
m += components[icomp];
}
// evaluate
Axis<double> argument;
m.set_argument (0, &argument);
for (unsigned i=0; i < nvals; i++)
{
argument.set_value( (i+0.5)/nvals * 2*M_PI );
vals[i] = m.evaluate();
}
}
void update(float delta)
{
x_axis->update(delta);
y_axis->update(delta);
if (speed_button) speed_button->update(delta);
Vector2f new_pos = pos;
float c_speed = speed;
if (speed_button && speed_button->get_state() == BUTTON_PRESSED)
{
c_speed *= 5.0f;
}
new_pos.x += x_axis->get_pos() * c_speed * delta;
new_pos.y += y_axis->get_pos() * c_speed * delta;
// FIXME: shouldn't depend on Display
new_pos.x = Math::clamp(0.0f, new_pos.x, static_cast<float>(Display::get_width()));
new_pos.y = Math::clamp(0.0f, new_pos.y, static_cast<float>(Display::get_height()));
if (new_pos != pos)
{
pos = new_pos;
notify_parent();
}
}
int Graph::createAxis(int objc, Tcl_Obj* const objv[])
{
char *string = Tcl_GetString(objv[3]);
if (string[0] == '-') {
Tcl_AppendResult(interp_, "name of axis \"", string,
"\" can't start with a '-'", NULL);
return TCL_ERROR;
}
int isNew;
Tcl_HashEntry* hPtr = Tcl_CreateHashEntry(&axes_.table, string, &isNew);
if (!isNew) {
Tcl_AppendResult(interp_, "axis \"", string, "\" already exists in \"",
Tcl_GetString(objv[0]), "\"", NULL);
return TCL_ERROR;
}
Axis* axisPtr = new Axis(this, Tcl_GetString(objv[3]), MARGIN_NONE, hPtr);
if (!axisPtr)
return TCL_ERROR;
Tcl_SetHashValue(hPtr, axisPtr);
if ((Tk_InitOptions(interp_, (char*)axisPtr->ops(), axisPtr->optionTable(), tkwin_) != TCL_OK) || (AxisObjConfigure(axisPtr, interp_, objc-4, objv+4) != TCL_OK)) {
delete axisPtr;
return TCL_ERROR;
}
return TCL_OK;
}
void Pulsar::ComponentModel::evaluate (float *vals,
unsigned nvals, int icomp_selected)
{
double phase_offset = 0;
if (report_absolute_phases)
phase_offset = phase->get_value().val;
if (verbose)
cerr << "Pulsar::ComponentModel::evaluate"
" phase_offset=" << phase_offset/(2*M_PI) << " turns" << endl;
//Construct the summed model
SumRule< Univariate<Scalar> > m;
if (icomp_selected >= 0)
{
check ("evaluate", icomp_selected);
m += components[icomp_selected];
}
else
{
for (unsigned icomp=0; icomp < components.size(); icomp++)
m += components[icomp];
}
// evaluate
Axis<double> argument;
m.set_argument (0, &argument);
for (unsigned i=0; i < nvals; i++)
{
argument.set_value( (i+0.5)/nvals * 2*M_PI + phase_offset );
vals[i] = m.evaluate();
}
}
void wxChartPanel::OnScrollWin(wxScrollWinEvent &ev)
{
if (m_chart == NULL) {
return ;
}
Axis *axis = NULL;
switch (ev.GetOrientation()) {
case wxHORIZONTAL:
axis = m_chart->GetHorizScrolledAxis();
break;
case wxVERTICAL:
axis = m_chart->GetVertScrolledAxis();
break;
default: // BUG
return ;
}
if (axis != NULL) {
double winPos = (double) ev.GetPosition() / (double) stepMult;
double minValue, maxValue;
axis->GetDataBounds(minValue, maxValue);
winPos += minValue;
axis->SetWindowPosition(winPos);
}
ev.Skip();
}
Axis* Graph::nearestAxis(int x, int y)
{
Tcl_HashSearch cursor;
for (Tcl_HashEntry* hPtr=Tcl_FirstHashEntry(&axes_.table, &cursor);
hPtr; hPtr = Tcl_NextHashEntry(&cursor)) {
Axis *axisPtr = (Axis*)Tcl_GetHashValue(hPtr);
AxisOptions* ops = (AxisOptions*)axisPtr->ops();
if (ops->hide || !axisPtr->use_)
continue;
if (ops->showTicks) {
for (ChainLink* link = Chain_FirstLink(axisPtr->tickLabels_); link;
link = Chain_NextLink(link)) {
TickLabel *labelPtr = (TickLabel*)Chain_GetValue(link);
double rw, rh;
Point2d bbox[5];
getBoundingBox(labelPtr->width, labelPtr->height, ops->tickAngle,
&rw, &rh, bbox);
Point2d t;
t = anchorPoint(labelPtr->anchorPos.x, labelPtr->anchorPos.y,
rw, rh, axisPtr->tickAnchor_);
t.x = x - t.x - (rw * 0.5);
t.y = y - t.y - (rh * 0.5);
bbox[4] = bbox[0];
if (pointInPolygon(&t, bbox, 5)) {
return axisPtr;
}
}
}
if (ops->title) {
int w, h;
double rw, rh;
Point2d bbox[5];
getTextExtents(ops->titleFont, ops->title, -1, &w, &h);
getBoundingBox(w, h, axisPtr->titleAngle_, &rw, &rh, bbox);
Point2d t = anchorPoint(axisPtr->titlePos_.x, axisPtr->titlePos_.y,
rw, rh, axisPtr->titleAnchor_);
// Translate the point so that the 0,0 is the upper left
// corner of the bounding box
t.x = x - t.x - (rw * 0.5);
t.y = y - t.y - (rh * 0.5);
bbox[4] = bbox[0];
if (pointInPolygon(&t, bbox, 5)) {
return axisPtr;
}
}
if (ops->lineWidth > 0) {
if ((x <= axisPtr->right_) && (x >= axisPtr->left_) &&
(y <= axisPtr->bottom_) && (y >= axisPtr->top_)) {
return axisPtr;
}
}
}
return NULL;
}
ClientData Graph::pickEntry(int xx, int yy, ClassId* classIdPtr)
{
if (flags & (LAYOUT | MAP_MARKERS)) {
*classIdPtr = CID_NONE;
return NULL;
}
// Sample coordinate is in one of the graph margins. Can only pick an axis.
Region2d exts;
extents(&exts);
if (xx>=exts.right || xx<exts.left || yy>=exts.bottom || yy<exts.top) {
Axis* axisPtr = nearestAxis(xx, yy);
if (axisPtr) {
*classIdPtr = axisPtr->classId();
return axisPtr;
}
}
// From top-to-bottom check:
// 1. markers drawn on top (-under false).
// 2. elements using its display list back to front.
// 3. markers drawn under element (-under true).
Marker* markerPtr = nearestMarker(xx, yy, 0);
if (markerPtr) {
*classIdPtr = markerPtr->classId();
return markerPtr;
}
GraphOptions* ops = (GraphOptions*)ops_;
ClosestSearch* searchPtr = &ops->search;
searchPtr->index = -1;
searchPtr->x = xx;
searchPtr->y = yy;
searchPtr->dist = (double)(searchPtr->halo + 1);
for (ChainLink* link = Chain_LastLink(elements_.displayList); link;
link = Chain_PrevLink(link)) {
Element* elemPtr = (Element*)Chain_GetValue(link);
ElementOptions* eops = (ElementOptions*)elemPtr->ops();
if (eops->hide)
continue;
elemPtr->closest();
}
// Found an element within the minimum halo distance.
if (searchPtr->dist <= (double)searchPtr->halo) {
*classIdPtr = searchPtr->elemPtr->classId();
return searchPtr->elemPtr;
}
markerPtr = nearestMarker(xx, yy, 1);
if (markerPtr) {
*classIdPtr = markerPtr->classId();
return markerPtr;
}
*classIdPtr = CID_NONE;
return NULL;
}
void Graph::configureAxes()
{
Tcl_HashSearch cursor;
for (Tcl_HashEntry *hPtr=Tcl_FirstHashEntry(&axes_.table, &cursor);
hPtr; hPtr = Tcl_NextHashEntry(&cursor)) {
Axis *axisPtr = (Axis*)Tcl_GetHashValue(hPtr);
axisPtr->configure();
}
}
void Graph::printAxesLimits(PSOutput* psPtr)
{
Tcl_HashSearch cursor;
for (Tcl_HashEntry* hPtr=Tcl_FirstHashEntry(&axes_.table, &cursor);
hPtr; hPtr = Tcl_NextHashEntry(&cursor)) {
Axis *axisPtr = (Axis*)Tcl_GetHashValue(hPtr);
axisPtr->printLimits(psPtr);
}
}
/** Creates the output workspace, setting the X vector to the bins boundaries in
* Qx.
* @return A pointer to the newly-created workspace
*/
API::MatrixWorkspace_sptr
Qxy::setUpOutputWorkspace(API::MatrixWorkspace_const_sptr inputWorkspace) {
const double max = getProperty("MaxQxy");
const double delta = getProperty("DeltaQ");
int bins = static_cast<int>(max / delta);
if (bins * delta != max)
++bins; // Stop at first boundary past MaxQxy if max is not a multiple of
// delta
const double startVal = -1.0 * delta * bins;
bins *= 2; // go from -max to +max
bins += 1; // Add 1 - this is a histogram
// Create an output workspace with the same meta-data as the input
MatrixWorkspace_sptr outputWorkspace = WorkspaceFactory::Instance().create(
inputWorkspace, bins - 1, bins, bins - 1);
// ... but clear the masking from the parameter map as we don't want to carry
// that over since this is essentially
// a 2D rebin
ParameterMap &pmap = outputWorkspace->instrumentParameters();
pmap.clearParametersByName("masked");
// Create a numeric axis to replace the vertical one
Axis *verticalAxis = new BinEdgeAxis(bins);
outputWorkspace->replaceAxis(1, verticalAxis);
// Build up the X values
Kernel::cow_ptr<MantidVec> axis;
MantidVec &horizontalAxisRef = axis.access();
horizontalAxisRef.resize(bins);
for (int i = 0; i < bins; ++i) {
const double currentVal = startVal + i * delta;
// Set the X value
horizontalAxisRef[i] = currentVal;
// Set the Y value on the axis
verticalAxis->setValue(i, currentVal);
}
// Fill the X vectors in the output workspace
for (int i = 0; i < bins - 1; ++i) {
outputWorkspace->setX(i, axis);
for (int j = 0; j < bins - j; ++j) {
outputWorkspace->dataY(i)[j] = std::numeric_limits<double>::quiet_NaN();
outputWorkspace->dataE(i)[j] = std::numeric_limits<double>::quiet_NaN();
}
}
// Set the axis units
outputWorkspace->getAxis(1)->unit() = outputWorkspace->getAxis(0)->unit() =
UnitFactory::Instance().create("MomentumTransfer");
// Set the 'Y' unit (gets confusing here...this is probably a Z axis in this
// case)
outputWorkspace->setYUnitLabel("Cross Section (1/cm)");
setProperty("OutputWorkspace", outputWorkspace);
return outputWorkspace;
}
void Graph::drawAxesLimits(Drawable drawable)
{
Tcl_HashSearch cursor;
for (Tcl_HashEntry* hPtr=Tcl_FirstHashEntry(&axes_.table, &cursor);
hPtr; hPtr = Tcl_NextHashEntry(&cursor)) {
Axis *axisPtr = (Axis*)Tcl_GetHashValue(hPtr);
axisPtr->drawLimits(drawable);
}
}
void RegionLoad::UpdateRegions()
{
//Define all regions actors
//Reset axis (Solve the bug "Game behavior differ based on editor grid position when uses regions", ALPHA_1_1_4.ged)
int xAxisAnt, yAxisAnt;
double scaleAnt;
Axis *pAxis = GameControl::Get()->GetAxis();
scaleAnt = pAxis->getScale();
xAxisAnt = pAxis->getImage()->X();
yAxisAnt = pAxis->getImage()->Y();
pAxis->SetScale(1.0);
pAxis->SetPos(0, 0);
pAxis->getImage()->Invalidate();
//Define actors
MapRegionsIterator it(regions);
RegionLoad *pRegion;
for( it.Begin(); !it.Done(); it.Next() )
{
pRegion = *it.Key();
pRegion->DefineActors();
}
SetDefaultRegionView();
//Restore axis (Solve the bug "Game behavior differ based on editor grid position when uses regions", ALPHA_1_1_4.ged)
pAxis->SetScale(scaleAnt);
pAxis->SetPos(xAxisAnt, yAxisAnt);
pAxis->getImage()->Invalidate();
}
// ************************************************ Window::recompute_axis_y
void recompute_axis_y( int key )
{
// Re-compute Y-Axis
_axis_y = Axis{ "Y", {0.0, 1.0, 5, 2} };
for( auto& pt: _c_sim_convol.get_samples()) {
_axis_y.get_range().update( pt.y );
}
std::cout << "New AxisY: " << _axis_y.get_range()._min << ", " << _axis_y.get_range()._max << std::endl;
}
void Graph::printAxes(PSOutput* psPtr)
{
GraphOptions* ops = (GraphOptions*)ops_;
for (Margin *mp = ops->margins, *mend = mp + 4; mp < mend; mp++) {
for (ChainLink* link = Chain_FirstLink(mp->axes); link;
link = Chain_NextLink(link)) {
Axis *axisPtr = (Axis*)Chain_GetValue(link);
axisPtr->print(psPtr);
}
}
}
void Graph::drawAxes(Drawable drawable)
{
GraphOptions* ops = (GraphOptions*)ops_;
for (int ii=0; ii<4; ii++) {
for (ChainLink* link = Chain_LastLink(ops->margins[ii].axes); link;
link = Chain_PrevLink(link)) {
Axis *axisPtr = (Axis*)Chain_GetValue(link);
axisPtr->draw(drawable);
}
}
}
void Graph::printAxesGrids(PSOutput* psPtr)
{
GraphOptions* ops = (GraphOptions*)ops_;
for (int ii=0; ii<4; ii++) {
for (ChainLink* link = Chain_FirstLink(ops->margins[ii].axes); link;
link = Chain_NextLink(link)) {
Axis *axisPtr = (Axis*)Chain_GetValue(link);
axisPtr->printGrids(psPtr);
}
}
}
/** Set up the output workspace in a Workspace2D
* @brief ExportTimeSeriesLog::setupWorkspace2D
* @param start_index :: array index for the first log entry
* @param stop_index :: array index for the last log entry
* @param numentries :: number of log entries to output
* @param times :: vector of Kernel::DateAndTime
* @param values :: vector of log value in double
* @param epochtime :: flag to output time in epoch time/absolute time
* @param timeunitfactor :: conversion factor for various unit of time for
* output
*/
void ExportTimeSeriesLog::setupWorkspace2D(
const size_t &start_index, const size_t &stop_index, int numentries,
vector<DateAndTime> ×, vector<double> values, const bool &epochtime,
const double &timeunitfactor) {
// Determine time shift
int64_t timeshift(0);
if (!epochtime) {
// relative time
Kernel::DateAndTime runstart(
m_inputWS->run().getProperty("run_start")->value());
timeshift = runstart.totalNanoseconds();
}
// Determine the size
size_t outsize = stop_index - start_index + 1;
if (outsize > static_cast<size_t>(numentries))
outsize = static_cast<size_t>(numentries);
// Create 2D workspace
m_outWS = boost::dynamic_pointer_cast<MatrixWorkspace>(
WorkspaceFactory::Instance().create("Workspace2D", 1, outsize, outsize));
if (!m_outWS)
throw runtime_error(
"Unable to create a Workspace2D casted to MatrixWorkspace.");
MantidVec &vecX = m_outWS->dataX(0);
MantidVec &vecY = m_outWS->dataY(0);
MantidVec &vecE = m_outWS->dataE(0);
for (size_t index = 0; index < outsize; ++index) {
size_t i_time = index + start_index;
// safety check
if (i_time >= times.size()) {
std::stringstream errss;
errss << "It shouldn't happen that the index is out of boundary."
<< "start index = " << start_index << ", output size = " << outsize
<< ", index = " << index << "\n";
throw std::runtime_error(errss.str());
}
int64_t dtns = times[i_time].totalNanoseconds() - timeshift;
vecX[index] = static_cast<double>(dtns) * timeunitfactor;
vecY[index] = values[i_time];
vecE[index] = 0.0;
}
Axis *xaxis = m_outWS->getAxis(0);
xaxis->setUnit("Time");
return;
}
void SpaceND::ProceedPanAt(double rx, double ry)
{
DPRINTF("SpaceND::ProceedPanAt\n");
Axis *xaxis;
Axis *yaxis;
xaxis = m_axes[AXIS_X];//let x be 1st dimension
yaxis = m_axes[AXIS_Y];//let y be 2nd dimension
//TO DO: need to review this code
if (xaxis != NULL)
{
xaxis->SetOffset(m_pan_start_at_vx - xaxis->GetRange() * (rx - m_pan_start_at_rx));
xaxis->PropagateToCommonScale();
}
if (yaxis != NULL)
{
yaxis->SetOffset(m_pan_start_at_vy - yaxis->GetRange() * (ry - m_pan_start_at_ry));
yaxis->PropagateToCommonScale();
}
}
/**
* Checks that X axis is in the right direction.
*
* @param value The workspace to check
* @return "" if is valid, otherwise a user level description of a problem
*/
std::string IncreasingAxisValidator::checkValidity(
const MatrixWorkspace_sptr &value) const {
// 0 for X axis
Axis *xAxis = value->getAxis(0);
// Left-most axis value should be less than the right-most, if ws has
// more than one X axis value
if (xAxis->length() > 1 &&
xAxis->getValue(0) >= xAxis->getValue(xAxis->length() - 1))
return "X axis of the workspace should be increasing from left to "
"right";
else
return "";
}
void Graph::resetAxes()
{
// Step 1: Reset all axes. Initialize the data limits of the axis to
// impossible values.
Tcl_HashSearch cursor;
for (Tcl_HashEntry* hPtr = Tcl_FirstHashEntry(&axes_.table, &cursor);
hPtr; hPtr = Tcl_NextHashEntry(&cursor)) {
Axis *axisPtr = (Axis*)Tcl_GetHashValue(hPtr);
axisPtr->min_ = axisPtr->valueRange_.min = DBL_MAX;
axisPtr->max_ = axisPtr->valueRange_.max = -DBL_MAX;
}
// Step 2: For each element that's to be displayed, get the smallest
// and largest data values mapped to each X and Y-axis. This
// will be the axis limits if the user doesn't override them
// with -min and -max options.
for (ChainLink* link = Chain_FirstLink(elements_.displayList); link;
link = Chain_NextLink(link)) {
Region2d exts;
Element* elemPtr = (Element*)Chain_GetValue(link);
ElementOptions* elemops = (ElementOptions*)elemPtr->ops();
elemPtr->extents(&exts);
elemops->xAxis->getDataLimits(exts.left, exts.right);
elemops->yAxis->getDataLimits(exts.top, exts.bottom);
}
// Step 3: Now that we know the range of data values for each axis,
// set axis limits and compute a sweep to generate tick values.
for (Tcl_HashEntry* hPtr = Tcl_FirstHashEntry(&axes_.table, &cursor);
hPtr; hPtr = Tcl_NextHashEntry(&cursor)) {
Axis *axisPtr = (Axis*)Tcl_GetHashValue(hPtr);
AxisOptions* ops = (AxisOptions*)axisPtr->ops();
axisPtr->fixRange();
double min = axisPtr->min_;
double max = axisPtr->max_;
if ((!isnan(axisPtr->scrollMin_)) && (min < axisPtr->scrollMin_))
min = axisPtr->scrollMin_;
if ((!isnan(axisPtr->scrollMax_)) && (max > axisPtr->scrollMax_))
max = axisPtr->scrollMax_;
if (ops->logScale)
axisPtr->logScale(min, max);
else
axisPtr->linearScale(min, max);
}
}
void UpdateAxisActionJob::updateAxis(LogicalDevice *device)
{
const auto axisIds = device->axes();
for (const Qt3DCore::QNodeId axisId : axisIds) {
Axis *axis = m_handler->axisManager()->lookupResource(axisId);
float axisValue = 0.0f;
const auto axisInputIds = axis->inputs();
for (const Qt3DCore::QNodeId axisInputId : axisInputIds)
axisValue += processAxisInput(axisInputId);
// Clamp the axisValue -1/1
axisValue = qMin(1.0f, qMax(axisValue, -1.0f));
axis->setAxisValue(axisValue);
}
}
bool
AndroidFlingAnimation::CheckBounds(Axis& aAxis, float aValue, float aDirection, float* aClamped)
{
if ((aDirection < 0.0f) && (aValue <= aAxis.GetPageStart().value)) {
if (aClamped) {
*aClamped = aAxis.GetPageStart().value;
}
return true;
} else if ((aDirection > 0.0f) && (aValue >= aAxis.GetScrollRangeEnd().value)) {
if (aClamped) {
*aClamped = aAxis.GetScrollRangeEnd().value;
}
return true;
}
return false;
}
void GraphPane::PickScale(QPainter *g, float scaleFactor)
{
int maxTics = 0;
_xAxis->scale()->PickScale( this, g, scaleFactor );
_x2Axis->scale()->PickScale( this, g, scaleFactor );
for(unsigned int i = 0; i < _yAxisList->length(); i++)
{
Axis* axis = _yAxisList->at(i);
axis->scale()->PickScale(this,g,scaleFactor);
}
// foreach ( Axis axis in _yAxisList )
// {
// axis._scale.PickScale( this, g, scaleFactor );
// if ( axis._scale.MaxAuto )
// {
// int nTics = axis._scale.CalcNumTics();
// maxTics = nTics > maxTics ? nTics : maxTics;
// }
// }
// foreach ( Axis axis in _y2AxisList )
// {
// axis._scale.PickScale( this, g, scaleFactor );
// if ( axis._scale.MaxAuto )
// {
// int nTics = axis._scale.CalcNumTics();
// maxTics = nTics > maxTics ? nTics : maxTics;
// }
// }
// if ( _isAlignGrids )
// {
// foreach ( Axis axis in _yAxisList )
// ForceNumTics( axis, maxTics );
// foreach ( Axis axis in _y2AxisList )
// ForceNumTics( axis, maxTics );
// }
}
/** Check if two axis defined as spectra or numeric axis are equivalent
* @param axis2 :: Reference to the axis to compare to
* @return true is self and second axis are equal
*/
bool RefAxis::operator==(const Axis &axis2) const {
if (length() != axis2.length()) {
return false;
}
const RefAxis *ra2 = dynamic_cast<const RefAxis *>(&axis2);
if (!ra2) {
return false;
}
return true;
}
/**
* @brief
* Test: Controller
*/
void Application30::TestController()
{
// Start
System::GetInstance()->GetConsole().Print("Controller 'GameBoy'\n");
System::GetInstance()->GetConsole().Print('\n');
// Create test controller
GameBoyController cController;
// List all controls
System::GetInstance()->GetConsole().Print("Controls:\n");
const List<Control*> &lstControls = cController.GetControls();
for (uint32 i=0; i<lstControls.GetNumOfElements(); i++) {
// Get control
Control *pControl = lstControls[i];
if (pControl->GetType() == ControlButton)
System::GetInstance()->GetConsole().Print("- Button '" + pControl->GetName() + "' [" + pControl->GetDescription() + "]\n");
else if (pControl->GetType() == ControlAxis)
System::GetInstance()->GetConsole().Print("- Axis '" + pControl->GetName() + "' [" + pControl->GetDescription() + "]\n");
}
System::GetInstance()->GetConsole().Print('\n');
// List buttons
System::GetInstance()->GetConsole().Print("Buttons:\n");
const List<Button*> &lstButtons = cController.GetButtons();
for (uint32 i=0; i<lstButtons.GetNumOfElements(); i++) {
Button *pButton = lstButtons[i];
System::GetInstance()->GetConsole().Print("- Button '" + pButton->GetName() + "' [" + pButton->GetDescription() + "]\n");
}
System::GetInstance()->GetConsole().Print('\n');
// List axes
System::GetInstance()->GetConsole().Print("Axes:\n");
const List<Axis*> &lstAxes = cController.GetAxes();
for (uint32 i=0; i<lstAxes.GetNumOfElements(); i++) {
Axis *pAxis = lstAxes[i];
System::GetInstance()->GetConsole().Print("- Axis '" + pAxis->GetName() + "' [" + pAxis->GetDescription() + "]\n");
}
System::GetInstance()->GetConsole().Print('\n');
// Done
System::GetInstance()->GetConsole().Print('\n');
}
void PlotArea::Private::initAxes()
{
// The category data region is anchored to an axis and will be set on addAxis if the
// axis defines the Axis::categoryDataRegion(). So, clear it now.
q->proxyModel()->setCategoryDataRegion(CellRegion());
// Remove all old axes
while(!axes.isEmpty()) {
Axis *axis = axes.takeLast();
Q_ASSERT(axis);
if (axis->title())
automaticallyHiddenAxisTitles.removeAll(axis->title());
delete axis;
}
// There need to be at least these two axes. Their constructor will
// automatically add them to the plot area as child shape.
new Axis(q, XAxisDimension);
Axis *yAxis = new Axis(q, YAxisDimension);
yAxis->setShowMajorGrid(true);
}
void update(float delta_)
{
x_axis->update(delta_);
y_axis->update(delta_);
if (speed_button) speed_button->update(delta_);
float c_speed = speed;
if (speed_button && speed_button->get_state() == BUTTON_PRESSED)
{
c_speed *= 5.0f;
}
this->delta.x = -x_axis->get_pos() * c_speed * delta_;
this->delta.y = y_axis->get_pos() * c_speed * delta_;
notify_parent();
}
