// ****************************************************************************
// Method: StopTimer
//
// Purpose: Time the IceT rendering process.
// IceT includes its own timing code that we might consider using at
// some point ...
//
// Programmer: Tom Fogal
// Creation: July 14, 2008
//
// Modifications:
//
// Hank Childs, Thu Jan 15 11:07:53 CST 2009
// Changed GetSize call to GetCaptureRegion, since that works for 2D.
//
// Tom Fogal, Fri May 29 20:37:59 MDT 2009
// Remove an unused variable.
//
// Burlen Loring, Tue Sep 1 14:26:30 PDT 2015
// sync up with network manager(base class) order compositing refactor
//
// ****************************************************************************
void
IceTNetworkManager::StopTimer()
{
char msg[1024];
VisWindow *viswin = renderState.window;
int rows,cols, width_start, height_start;
// This basically gets the width and the height.
// The distinction is for 2D rendering, where we only want the
// width and the height of the viewport.
viswin->GetCaptureRegion(width_start, height_start, rows,cols,
renderState.viewportedMode);
SNPRINTF(msg, 1023, "IceTNM::Render %lld cells %d pixels",
renderState.cellCountTotal, rows*cols);
visitTimer->StopTimer(renderState.timer, msg);
renderState.timer = -1;
}
// ****************************************************************************
// Method: StopTimer
//
// Purpose: Time the IceT rendering process.
// IceT includes its own timing code that we might consider using at
// some point ...
//
// Programmer: Tom Fogal
// Creation: July 14, 2008
//
// Modifications:
//
// Hank Childs, Thu Jan 15 11:07:53 CST 2009
// Changed GetSize call to GetCaptureRegion, since that works for 2D.
//
// Tom Fogal, Fri May 29 20:37:59 MDT 2009
// Remove an unused variable.
//
// ****************************************************************************
void
IceTNetworkManager::StopTimer(int windowID)
{
char msg[1024];
VisWindow *viswin = this->viswinMap.find(windowID)->second.viswin;
int rows,cols, width_start, height_start;
// This basically gets the width and the height.
// The distinction is for 2D rendering, where we only want the
// width and the height of the viewport.
viswin->GetCaptureRegion(width_start, height_start, rows,cols,
this->r_mgmt.viewportedMode);
SNPRINTF(msg, 1023, "IceTNM::Render %ld cells %d pixels",
GetTotalGlobalCellCounts(windowID), rows*cols);
visitTimer->StopTimer(this->r_mgmt.timer, msg);
this->r_mgmt.timer = -1;
}
avtDataObject_p
IceTNetworkManager::Render(
bool checkThreshold, intVector networkIds,
bool getZBuffer, int annotMode, int windowID,
bool leftEye)
{
int t0 = visitTimer->StartTimer();
DataNetwork *origWorkingNet = workingNet;
avtDataObject_p retval;
EngineVisWinInfo &viswinInfo = viswinMap[windowID];
viswinInfo.markedForDeletion = false;
VisWindow *viswin = viswinInfo.viswin;
std::vector<avtPlot_p>& imageBasedPlots = viswinInfo.imageBasedPlots;
renderings = 0;
TRY
{
this->StartTimer();
RenderSetup(windowID, networkIds, getZBuffer,
annotMode, leftEye, checkThreshold);
bool plotDoingTransparencyOutsideTransparencyActor = false;
for(size_t i = 0 ; i < networkIds.size() ; i++)
{
workingNet = NULL;
UseNetwork(networkIds[i]);
if(this->workingNet->GetPlot()->ManagesOwnTransparency())
{
plotDoingTransparencyOutsideTransparencyActor = true;
}
}
workingNet = NULL;
// We can't easily figure out a compositing order, which IceT requires
// in order to properly composite transparent geometry. Thus if there
// is some transparency, fallback to our parent implementation.
avtTransparencyActor* trans = viswin->GetTransparencyActor();
bool transparenciesExist = trans->TransparenciesExist()
|| plotDoingTransparencyOutsideTransparencyActor;
if (transparenciesExist)
{
debug2 << "Encountered transparency: falling back to old "
"SR / compositing routines." << std::endl;
retval = NetworkManager::RenderInternal();
}
else
{
bool needZB = !imageBasedPlots.empty() ||
renderState.shadowMap ||
renderState.depthCues;
// Confusingly, we need to set the input to be *opposite* of what VisIt
// wants. This is due to (IMHO) poor naming in the IceT case; on the
// input side:
// ICET_DEPTH_BUFFER_BIT set: do Z-testing
// ICET_DEPTH_BUFFER_BIT not set: do Z-based compositing.
// On the output side:
// ICET_DEPTH_BUFFER_BIT set: readback of Z buffer is allowed
// ICET_DEPTH_BUFFER_BIT not set: readback of Z does not work.
// In VisIt's case, we calculated a `need Z buffer' predicate based
// around the idea that we need the Z buffer to do Z-compositing.
// However, IceT \emph{always} needs the Z buffer internally -- the
// flag only differentiates between `compositing' methodologies
// (painter-style or `over' operator) on input.
GLenum inputs = ICET_COLOR_BUFFER_BIT;
GLenum outputs = ICET_COLOR_BUFFER_BIT;
// Scratch all that, I guess. That might be the correct way to go
// about things in the long run, but IceT only gives us back half an
// image if we don't set the depth buffer bit. The compositing is a
// bit wrong, but there's not much else we can do..
// Consider removing the `hack' if a workaround is found.
if (/*hack*/true/*hack*/) // || !this->MemoMultipass(viswin))
{
inputs |= ICET_DEPTH_BUFFER_BIT;
}
if(needZB)
{
outputs |= ICET_DEPTH_BUFFER_BIT;
}
ICET(icetInputOutputBuffers(inputs, outputs));
// If there is a backdrop image, we need to tell IceT so that it can
// composite correctly.
if(viswin->GetBackgroundMode() != AnnotationAttributes::Solid)
{
ICET(icetEnable(ICET_CORRECT_COLORED_BACKGROUND));
}
else
{
ICET(icetDisable(ICET_CORRECT_COLORED_BACKGROUND));
}
if (renderState.renderOnViewer)
{
RenderCleanup();
avtDataObject_p dobj = NULL;
CATCH_RETURN2(1, dobj);
}
debug5 << "Rendering " << viswin->GetNumPrimitives()
<< " primitives." << endl;
int width, height, width_start, height_start;
// This basically gets the width and the height.
// The distinction is for 2D rendering, where we only want the
// width and the height of the viewport.
viswin->GetCaptureRegion(width_start, height_start, width, height,
renderState.viewportedMode);
this->TileLayout(width, height);
CallInitializeProgressCallback(this->RenderingStages());
// IceT mode is different from the standard network manager; we don't
// need to create any compositor or anything: it's all done under the
// hood.
// Whether or not to do multipass rendering (opaque first, translucent
// second) is all handled in the callback; from our perspective, we
// just say draw, read back the image, and post-process it.
// IceT sometimes omits large parts of Curve plots when using the
// REDUCE strategy. Use a different compositing strategy for Curve
// plots to avoid the problem.
if(viswin->GetWindowMode() == WINMODE_CURVE)
ICET(icetStrategy(ICET_STRATEGY_VTREE));
else
ICET(icetStrategy(ICET_STRATEGY_REDUCE));
ICET(icetDrawFunc(render));
ICET(icetDrawFrame());
// Now that we're done rendering, we need to post process the image.
debug3 << "IceTNM: Starting readback." << std::endl;
avtImage_p img = this->Readback(viswin, needZB);
// Now its essentially back to the same behavior as our parent:
// shadows
// depth cueing
// post processing
if (renderState.shadowMap)
this->RenderShadows(img);
if (renderState.depthCues)
this->RenderDepthCues(img);
// If the engine is doing more than just 3D annotations,
// post-process the composited image.
RenderPostProcess(img);
CopyTo(retval, img);
}
RenderCleanup();
}
CATCHALL
{
RenderCleanup();
RETHROW;
}
ENDTRY
workingNet = origWorkingNet;
visitTimer->StopTimer(t0, "Ice-T Render");
return retval;
}