bool
UsdGeomPrimvar::Get(
VtValue* value,
UsdTimeCode time) const
{
if (!_idTargetRelName.IsEmpty()) {
const SdfValueTypeName& typeName = _attr.GetTypeName();
if (typeName == SdfValueTypeNames->String) {
std::string s;
bool ret = Get(&s, time);
if (ret) {
*value = VtValue(s);
}
return ret;
}
else if (typeName == SdfValueTypeNames->StringArray) {
VtStringArray s;
bool ret = Get(&s, time);
if (ret) {
*value = VtValue(s);
}
return ret;
}
}
return _attr.Get(value, time);
}
bool
HdSt_TriangleIndexBuilderComputation::Resolve()
{
if (!_TryLock()) return false;
HD_TRACE_FUNCTION();
VtVec3iArray trianglesFaceVertexIndices;
VtIntArray primitiveParam;
HdMeshUtil meshUtil(_topology, _id);
meshUtil.ComputeTriangleIndices(
&trianglesFaceVertexIndices,
&primitiveParam);
_SetResult(HdBufferSourceSharedPtr(
new HdVtBufferSource(
HdTokens->indices,
VtValue(trianglesFaceVertexIndices))));
_primitiveParam.reset(new HdVtBufferSource(
HdTokens->primitiveParam,
VtValue(primitiveParam)));
_SetResolved();
return true;
}
inline VtValue
MakeShapedValueTemplate(vector<unsigned int> const &shape,
vector<Value> const &vars, size_t &index,
string *errStrPtr) {
if (shape.empty())
return VtValue(VtArray<T>());
// TF_AXIOM(shape.size() == 1);
unsigned int size = 1;
TF_FOR_ALL(i, shape)
size *= *i;
VtArray<T> array(size);
size_t shapeIndex = 0;
size_t origIndex = index;
try {
TF_FOR_ALL(i, array) {
MakeScalarValueImpl(&(*i), vars, index);
shapeIndex++;
}
} catch (const boost::bad_get &) {
*errStrPtr = TfStringPrintf("Failed to parse at element %zd "
"(at sub-part %zd if there are "
"multiple parts)", shapeIndex,
(index - origIndex) - 1);
return VtValue();
}
return VtValue(array);
}
/* static */
const VtDictionary& UsdMayaJobImportArgs::GetDefaultDictionary()
{
static VtDictionary d;
static std::once_flag once;
std::call_once(once, []() {
// Base defaults.
d[UsdMayaJobImportArgsTokens->assemblyRep] =
UsdMayaJobImportArgsTokens->Collapsed.GetString();
d[UsdMayaJobImportArgsTokens->apiSchema] = std::vector<VtValue>();
d[UsdMayaJobImportArgsTokens->excludePrimvar] = std::vector<VtValue>();
d[UsdMayaJobImportArgsTokens->metadata] =
std::vector<VtValue>({
VtValue(SdfFieldKeys->Hidden.GetString()),
VtValue(SdfFieldKeys->Instanceable.GetString()),
VtValue(SdfFieldKeys->Kind.GetString())
});
d[UsdMayaJobImportArgsTokens->shadingMode] =
UsdMayaShadingModeTokens->displayColor.GetString();
d[UsdMayaJobImportArgsTokens->useAsAnimationCache] = false;
// plugInfo.json site defaults.
// The defaults dict should be correctly-typed, so enable
// coerceToWeakerOpinionType.
const VtDictionary site =
UsdMaya_RegistryHelper::GetComposedInfoDictionary(
_usdImportInfoScope->allTokens);
VtDictionaryOver(site, &d, /*coerceToWeakerOpinionType*/ true);
});
return d;
}
void
My_TestGLDrawing::InitTest()
{
_renderIndex = HdRenderIndex::New(&_renderDelegate);
TF_VERIFY(_renderIndex != nullptr);
_delegate.reset(new Hdx_UnitTestDelegate(_renderIndex));
// prepare render task
SdfPath renderSetupTask("/renderSetupTask");
SdfPath renderTask("/renderTask");
SdfPath selectionTask("/selectionTask");
_delegate->AddRenderSetupTask(renderSetupTask);
_delegate->AddRenderTask(renderTask);
_delegate->AddSelectionTask(selectionTask);
// render task parameters.
VtValue vParam = _delegate->GetTaskParam(renderSetupTask, HdTokens->params);
HdxRenderTaskParams param = vParam.Get<HdxRenderTaskParams>();
param.enableLighting = true; // use default lighting
_delegate->SetTaskParam(renderSetupTask, HdTokens->params,
VtValue(param));
_delegate->SetTaskParam(renderTask, HdTokens->collection,
VtValue(HdRprimCollection(HdTokens->geometry,
HdReprSelector(HdReprTokens->hull))));
HdxSelectionTaskParams selParam;
selParam.enableSelection = true;
selParam.selectionColor = GfVec4f(1, 1, 0, 1);
selParam.locateColor = GfVec4f(1, 0, 1, 1);
_delegate->SetTaskParam(selectionTask, HdTokens->params,
VtValue(selParam));
// prepare scene
_InitScene();
SetCameraTranslate(GfVec3f(0, 0, -20));
// picking related init
_pickablesCol = HdRprimCollection(_tokens->pickables,
HdReprSelector(HdReprTokens->hull));
_marquee.InitGLResources();
_picker.InitIntersector(_renderIndex);
_SetPickParams();
// We have to unfortunately explictly add collections besides 'geometry'
// See HdRenderIndex constructor.
_delegate->GetRenderIndex().GetChangeTracker().AddCollection(_tokens->pickables);
// XXX: Setup a VAO, the current drawing engine will not yet do this.
glGenVertexArrays(1, &vao);
glBindVertexArray(vao);
glBindVertexArray(0);
}
void
UsdMayaGLBatchRenderer::TaskDelegate::_InsertRenderTask(SdfPath const &id)
{
GetRenderIndex().InsertTask<HdxRenderTask>(this, id);
_ValueCache &cache = _valueCacheMap[id];
HdxRenderTaskParams taskParams;
taskParams.camera = _cameraId;
// Initialize viewport to the latest value since render tasks can be lazily
// instantiated, potentially even after SetCameraState. All other
// parameters will be updated by _UpdateRenderParams.
taskParams.viewport = _viewport;
cache[HdTokens->params] = VtValue(taskParams);
cache[HdTokens->children] = VtValue(SdfPathVector());
cache[HdTokens->collection] = VtValue();
}
void
HdStreamTaskController::_CreateCamera()
{
// Create a default camera, driven by SetCameraMatrices.
_cameraId = GetControllerId().AppendChild(_tokens->camera);
GetRenderIndex()->InsertSprim(HdPrimTypeTokens->camera,
&_delegate, _cameraId);
_delegate.SetParameter(_cameraId, HdStCameraTokens->windowPolicy,
VtValue());
_delegate.SetParameter(_cameraId, HdStCameraTokens->matrices,
HdStCameraMatrices());
_delegate.SetParameter(_cameraId, HdStCameraTokens->clipPlanes,
VtValue(std::vector<GfVec4d>()));
}
bool
Hd_SmoothNormalsComputation::Resolve()
{
// dependency check first
if (_adjacencyBuilder) {
if (not _adjacencyBuilder->IsResolved()) return false;
}
if (_points) {
if (not _points->IsResolved()) return false;
}
if (not _TryLock()) return false;
HD_TRACE_FUNCTION();
HD_MALLOC_TAG_FUNCTION();
if (not TF_VERIFY(_adjacency)) return true;
int numPoints = _points->GetNumElements();
HdBufferSourceSharedPtr normals;
switch (_points->GetGLElementDataType()) {
case GL_FLOAT_VEC3:
normals = HdBufferSourceSharedPtr(
new HdVtBufferSource(
_dstName, VtValue(
_adjacency->ComputeSmoothNormals(
numPoints,
static_cast<const GfVec3f*>(_points->GetData())))));
break;
case GL_DOUBLE_VEC3:
normals = HdBufferSourceSharedPtr(
new HdVtBufferSource(
_dstName, VtValue(
_adjacency->ComputeSmoothNormals(
numPoints,
static_cast<const GfVec3d*>(_points->GetData())))));
break;
default:
TF_CODING_ERROR("Unsupported points type for computing smooth normals");
break;
}
_SetResult(normals);
// call base class to mark as resolved.
_SetResolved();
return true;
}
inline VtValue
MakeScalarValueTemplate(vector<unsigned int> const &,
vector<Value> const &vars, size_t &index,
string *errStrPtr) {
T t;
size_t origIndex = index;
try {
MakeScalarValueImpl(&t, vars, index);
} catch (const boost::bad_get &) {
*errStrPtr = TfStringPrintf("Failed to parse value (at sub-part %zd "
"if there are multiple parts)",
(index - origIndex) - 1);
return VtValue();
}
return VtValue(t);
}
static VtValue
_GetListOpForTokenVector(const TfTokenVector& vector)
{
SdfTokenListOp op;
op.SetPrependedItems(vector);
return VtValue(op);
}
bool
MayaPrimWriter::writePrimAttrs(const MDagPath &dagT, const UsdTimeCode &usdTime, UsdGeomImageable &primSchema)
{
MStatus status;
MFnDependencyNode depFn(getDagPath().node());
MFnDependencyNode depFn2(dagT.node()); // optionally also scan a shape's transform if merging transforms
if (getArgs().exportVisibility) {
bool isVisible = true; // if BOTH shape or xform is animated, then visible
bool isAnimated = false; // if either shape or xform is animated, then animated
PxrUsdMayaUtil::getPlugValue(depFn, "visibility", &isVisible, &isAnimated);
if ( dagT.isValid() ) {
bool isVis, isAnim;
if (PxrUsdMayaUtil::getPlugValue(depFn2, "visibility", &isVis, &isAnim)){
isVisible = isVisible and isVis;
isAnimated = isAnimated or isAnim;
}
}
TfToken const &visibilityTok = (isVisible ? UsdGeomTokens->inherited :
UsdGeomTokens->invisible);
if (usdTime.IsDefault() != isAnimated ) {
if (usdTime.IsDefault())
primSchema.CreateVisibilityAttr(VtValue(visibilityTok), true);
else
primSchema.CreateVisibilityAttr().Set(visibilityTok, usdTime);
}
}
UsdPrim usdPrim = primSchema.GetPrim();
// There is no Gprim abstraction in this module, so process the few
// gprim attrs here.
UsdGeomGprim gprim = UsdGeomGprim(usdPrim);
if (gprim and usdTime.IsDefault()){
PxrUsdMayaPrimWriterContext* unused = NULL;
PxrUsdMayaTranslatorGprim::Write(
getDagPath().node(),
gprim,
unused);
}
_writeUsdInfo(dagT, usdTime, usdPrim);
// Write user-tagged export attributes. Write attributes on the transform
// first, and then attributes on the shape node. This means that attribute
// name collisions will always be handled by taking the shape node's value
// if we're merging transforms and shapes.
if (dagT.isValid() and !(dagT == getDagPath())) {
PxrUsdMayaWriteUtil::WriteUserExportedAttributes(dagT, usdPrim, usdTime);
}
PxrUsdMayaWriteUtil::WriteUserExportedAttributes(getDagPath(), usdPrim, usdTime);
return true;
}
/*static*/
VtValue
UsdImagingConeAdapter::GetMeshTopology()
{
// topology is identical for all cones
static HdMeshTopology coneTopo = _GenerateConeMeshTopology();
return VtValue(coneTopo);
}
/*static*/
VtValue
UsdImagingCapsuleAdapter::GetMeshTopology()
{
// topology is identical for all capsules
static HdMeshTopology capsuleTopo = _GenerateCapsuleMeshTopology();
return VtValue(capsuleTopo);
}
static
void _SetMayaDictValue(const UsdAttribute& attr, const TfToken& flagName, const T& val)
{
VtValue data = attr.GetCustomDataByKey(_tokens->Maya);
VtDictionary newDict;
if (!data.IsEmpty()) {
if (data.IsHolding<VtDictionary>()) {
newDict = data.UncheckedGet<VtDictionary>();
}
else {
TF_WARN("Expected to get %s on <%s> to be a dictionary.",
_tokens->Maya.GetText(),
attr.GetPath().GetText());
return;
}
}
newDict[flagName] = VtValue(val);
attr.SetCustomDataByKey(_tokens->Maya, VtValue(newDict));
}
HdBufferSourceSharedPtr
HdSt_MeshTopology::GetPointsIndexBuilderComputation()
{
// this is simple enough to return the result right away.
int numPoints = GetNumPoints();
VtIntArray indices(numPoints);
for (int i = 0; i < numPoints; ++i) indices[i] = i;
return HdBufferSourceSharedPtr(
new HdVtBufferSource(HdTokens->indices, VtValue(indices)));
}
void
UsdImagingPointsAdapter::UpdateForTime(UsdPrim const& prim,
SdfPath const& cachePath,
UsdTimeCode time,
HdDirtyBits requestedBits,
HdDirtyBits* resultBits,
UsdImagingInstancerContext const*
instancerContext)
{
BaseAdapter::UpdateForTime(
prim, cachePath, time, requestedBits, resultBits, instancerContext);
UsdImagingValueCache* valueCache = _GetValueCache();
PrimvarInfoVector& primvars = valueCache->GetPrimvars(cachePath);
VtValue& pointsValues = valueCache->GetPoints(cachePath);
if (requestedBits & HdChangeTracker::DirtyPoints) {
_GetPoints(prim, &pointsValues, time);
UsdImagingValueCache::PrimvarInfo primvar;
primvar.name = HdTokens->points;
primvar.interpolation = UsdGeomTokens->vertex;
_MergePrimvar(primvar, &primvars);
}
if (requestedBits & HdChangeTracker::DirtyWidths) {
UsdImagingValueCache::PrimvarInfo primvar;
UsdGeomPoints points(prim);
VtFloatArray widths;
primvar.name = UsdGeomTokens->widths;
// XXX Add support for real constant interpolation
primvar.interpolation = UsdGeomTokens->vertex;
// Read the widths, if there is no widths create a buffer
// and fill it with default widths of 1.0f
if (!points.GetWidthsAttr().Get(&widths, time)) {
// Check if we have just updated the points because in that
// case we don't need to read the points again
if (!(requestedBits & HdChangeTracker::DirtyPoints)) {
_GetPoints(prim, &pointsValues, time);
}
for(size_t i = 0; i < pointsValues.Get<VtVec3fArray>().size() ; i ++) {
widths.push_back(1.0f);
}
}
_MergePrimvar(primvar, &primvars);
valueCache->GetWidths(cachePath) = VtValue(widths);
}
}
void
UsdMayaGLBatchRenderer::TaskDelegate::SetCameraState(
const GfMatrix4d& viewMatrix,
const GfMatrix4d& projectionMatrix,
const GfVec4d& viewport)
{
// cache the camera matrices
_ValueCache &cache = _valueCacheMap[_cameraId];
cache[HdStCameraTokens->worldToViewMatrix] = VtValue(viewMatrix);
cache[HdStCameraTokens->projectionMatrix] = VtValue(projectionMatrix);
cache[HdStCameraTokens->windowPolicy] = VtValue(); // no window policy.
// invalidate the camera to be synced
GetRenderIndex().GetChangeTracker().MarkSprimDirty(_cameraId,
HdStCamera::AllDirty);
if( _viewport != viewport )
{
// viewport is also read by HdxRenderTaskParam. invalidate it.
_viewport = viewport;
// update all render tasks
for( const auto &it : _renderTaskIdMap )
{
SdfPath const &taskId = it.second;
HdxRenderTaskParams taskParams
= _GetValue<HdxRenderTaskParams>(taskId, HdTokens->params);
// update viewport in HdxRenderTaskParams
taskParams.viewport = viewport;
_SetValue(taskId, HdTokens->params, taskParams);
// invalidate
GetRenderIndex().GetChangeTracker().MarkTaskDirty(
taskId, HdChangeTracker::DirtyParams);
}
}
}
UsdMayaGLBatchRenderer::TaskDelegate::TaskDelegate(
HdRenderIndex *renderIndex, SdfPath const& delegateID)
: HdSceneDelegate(renderIndex, delegateID)
{
_lightingContext = GlfSimpleLightingContext::New();
// populate tasks in renderindex
// create an unique namespace
_rootId = delegateID.AppendChild(
TfToken(TfStringPrintf("_UsdImaging_%p", this)));
_simpleLightTaskId = _rootId.AppendChild(_tokens->simpleLightTask);
_cameraId = _rootId.AppendChild(_tokens->camera);
// camera
{
// Since we're hardcoded to use HdStRenderDelegate, we expect to
// have camera Sprims.
TF_VERIFY(renderIndex->IsSprimTypeSupported(HdPrimTypeTokens->camera));
renderIndex->InsertSprim(HdPrimTypeTokens->camera, this, _cameraId);
_ValueCache &cache = _valueCacheMap[_cameraId];
cache[HdStCameraTokens->worldToViewMatrix] = VtValue(GfMatrix4d(1.0));
cache[HdStCameraTokens->projectionMatrix] = VtValue(GfMatrix4d(1.0));
cache[HdStCameraTokens->windowPolicy] = VtValue(); // no window policy.
}
// simple lighting task (for Hydra native)
{
renderIndex->InsertTask<HdxSimpleLightTask>(this, _simpleLightTaskId);
_ValueCache &cache = _valueCacheMap[_simpleLightTaskId];
HdxSimpleLightTaskParams taskParams;
taskParams.cameraPath = _cameraId;
cache[HdTokens->params] = VtValue(taskParams);
cache[HdTokens->children] = VtValue(SdfPathVector());
}
}
/*virtual*/
VtValue
UsdMayaGLBatchRenderer::TaskDelegate::Get(
SdfPath const& id,
TfToken const &key)
{
_ValueCache *vcache = TfMapLookupPtr(_valueCacheMap, id);
VtValue ret;
if( vcache && TfMapLookup(*vcache, key, &ret) )
return ret;
TF_CODING_ERROR("%s:%s doesn't exist in the value cache\n",
id.GetText(), key.GetText());
return VtValue();
}
UsdAttribute
UsdLuxLinkingAPI::_GetIncludeByDefaultAttr(bool create /* = false */) const
{
const TfToken &attrName =
_GetCollectionPropertyName(_tokens->includeByDefault);
if (create) {
return UsdSchemaBase::_CreateAttr(attrName,
SdfValueTypeNames->Bool,
/* custom = */ false,
SdfVariabilityUniform,
/* default = */ VtValue(),
/* writeSparsely */ false);
} else {
return GetPrim().GetAttribute(attrName);
}
}
/* static */
UsdUISceneGraphPrimAPI
UsdUISceneGraphPrimAPI::Apply(const UsdStagePtr &stage, const SdfPath &path)
{
// Ensure we have a valid stage, path and prim
if (!stage) {
TF_CODING_ERROR("Invalid stage");
return UsdUISceneGraphPrimAPI();
}
if (path == SdfPath::AbsoluteRootPath()) {
TF_CODING_ERROR("Cannot apply an api schema on the pseudoroot");
return UsdUISceneGraphPrimAPI();
}
auto prim = stage->GetPrimAtPath(path);
if (!prim) {
TF_CODING_ERROR("Prim at <%s> does not exist.", path.GetText());
return UsdUISceneGraphPrimAPI();
}
TfToken apiName("SceneGraphPrimAPI");
// Get the current listop at the edit target
UsdEditTarget editTarget = stage->GetEditTarget();
SdfPrimSpecHandle primSpec = editTarget.GetPrimSpecForScenePath(path);
SdfTokenListOp listOp = primSpec->GetInfo(UsdTokens->apiSchemas)
.UncheckedGet<SdfTokenListOp>();
// Append our name to the prepend list, if it doesnt exist locally
TfTokenVector prepends = listOp.GetPrependedItems();
if (std::find(prepends.begin(), prepends.end(), apiName) != prepends.end()) {
return UsdUISceneGraphPrimAPI();
}
SdfTokenListOp prependListOp;
prepends.push_back(apiName);
prependListOp.SetPrependedItems(prepends);
auto result = listOp.ApplyOperations(prependListOp);
if (!result) {
TF_CODING_ERROR("Failed to prepend api name to current listop.");
return UsdUISceneGraphPrimAPI();
}
// Set the listop at the current edit target and return the API prim
primSpec->SetInfo(UsdTokens->apiSchemas, VtValue(*result));
return UsdUISceneGraphPrimAPI(prim);
}
void
My_TestGLDrawing::
DrawScene(PickParam const * pickParam)
{
int width = GetWidth(), height = GetHeight();
GfMatrix4d viewMatrix = GetViewMatrix();
GfFrustum frustum = GetFrustum();
GfVec4d viewport(0, 0, width, height);
if (pickParam) {
frustum = frustum.ComputeNarrowedFrustum(
GfVec2d((2.0 * pickParam->location[0]) / width - 1.0,
(2.0 * (height-pickParam->location[1])) / height - 1.0),
GfVec2d(1.0 / width, 1.0 / height));
viewport = pickParam->viewport;
}
GfMatrix4d projMatrix = frustum.ComputeProjectionMatrix();
_delegate->SetCamera(viewMatrix, projMatrix);
glViewport(viewport[0], viewport[1], viewport[2], viewport[3]);
HdTaskSharedPtrVector tasks;
SdfPath renderSetupTask("/renderSetupTask");
SdfPath renderTask("/renderTask");
tasks.push_back(_delegate->GetRenderIndex().GetTask(renderSetupTask));
tasks.push_back(_delegate->GetRenderIndex().GetTask(renderTask));
HdxRenderTaskParams param
= _delegate->GetTaskParam(
renderSetupTask, HdTokens->params).Get<HdxRenderTaskParams>();
param.enableIdRender = (pickParam != NULL);
param.viewport = viewport;
_delegate->SetTaskParam(renderSetupTask, HdTokens->params, VtValue(param));
glEnable(GL_DEPTH_TEST);
glBindVertexArray(vao);
_engine.Execute(_delegate->GetRenderIndex(), tasks);
glBindVertexArray(0);
}
/*static*/
VtValue
UsdImagingCapsuleAdapter::GetMeshPoints(UsdPrim const& prim,
UsdTimeCode time)
{
UsdGeomCapsule capsule(prim);
double radius = 0.5;
double height = 1.0;
TfToken axis = UsdGeomTokens->z;
TF_VERIFY(capsule.GetRadiusAttr().Get(&radius, time));
TF_VERIFY(capsule.GetHeightAttr().Get(&height, time));
TF_VERIFY(capsule.GetAxisAttr().Get(&axis, time));
// We can't express varying radius and height via a non-uniform
// scaling transformation and maintain spherical end caps.
return VtValue(_GenerateCapsuleMeshPoints(float(radius),
float(height),
axis));
}
PXR_NAMESPACE_OPEN_SCOPE
// ---------------------------------------------------------------------------
// Delegate implementation.
/* virtual */
VtValue
HdStreamTaskController::_Delegate::Get(SdfPath const& id, TfToken const& key)
{
_ValueCache *vcache = TfMapLookupPtr(_valueCacheMap, id);
VtValue ret;
if (vcache && TfMapLookup(*vcache, key, &ret)) {
return ret;
}
TF_CODING_ERROR("%s:%s doesn't exist in the value cache\n",
id.GetText(), key.GetText());
return VtValue();
}
/*static*/
VtValue
UsdImagingCubeAdapter::GetMeshTopology()
{
static int numVerts[] = { 4, 4, 4, 4, 4, 4 };
static int verts[] = {
0, 1, 2, 3,
4, 5, 6, 7,
0, 6, 5, 1,
4, 7, 3, 2,
0, 3, 7, 6,
4, 2, 1, 5,
};
static HdMeshTopology cubeTopo(PxOsdOpenSubdivTokens->bilinear,
HdTokens->rightHanded,
_BuildVtArray(numVerts, sizeof(numVerts) / sizeof(numVerts[0])),
_BuildVtArray(verts, sizeof(verts) / sizeof(verts[0])));
return VtValue(cubeTopo);
}
/*static*/
VtValue
UsdImagingConeAdapter::GetMeshPoints(UsdPrim const& prim,
UsdTimeCode time)
{
UsdGeomCone cone(prim);
double radius = 1.0;
double height = 2.0;
TfToken axis = UsdGeomTokens->z;
TF_VERIFY(cone.GetRadiusAttr().Get(&radius, time));
TF_VERIFY(cone.GetHeightAttr().Get(&height, time));
TF_VERIFY(cone.GetAxisAttr().Get(&axis, time));
// We could express radius and height via a
// (potentially non-uniform) scaling transformation.
return VtValue(_GenerateConeMeshPoints(float(radius),
float(height),
axis));
}
/*static*/
VtValue
UsdImagingSphereAdapter::GetMeshPoints(UsdPrim const& prim,
UsdTimeCode time)
{
static GfVec3f points[] = {
GfVec3f( 0.2384, 0.1483, -0.9511) ,GfVec3f( 0.0839, 0.2606, -0.9511) ,GfVec3f(-0.1071, 0.2606, -0.9511),
GfVec3f(-0.2616, 0.1483, -0.9511) ,GfVec3f(-0.3206, -0.0333, -0.9511) ,GfVec3f(-0.2616, -0.2149, -0.9511),
GfVec3f(-0.1071, -0.3272, -0.9511) ,GfVec3f( 0.0839, -0.3272, -0.9511) ,GfVec3f( 0.2384, -0.2149, -0.9511),
GfVec3f( 0.2975, -0.0333, -0.9511) ,GfVec3f( 0.4640, 0.3122, -0.8090) ,GfVec3f( 0.1701, 0.5257, -0.8090),
GfVec3f(-0.1932, 0.5257, -0.8090) ,GfVec3f(-0.4871, 0.3122, -0.8090) ,GfVec3f(-0.5993, -0.0333, -0.8090),
GfVec3f(-0.4871, -0.3788, -0.8090) ,GfVec3f(-0.1932, -0.5923, -0.8090) ,GfVec3f( 0.1701, -0.5923, -0.8090),
GfVec3f( 0.4640, -0.3788, -0.8090) ,GfVec3f( 0.5762, -0.0333, -0.8090) ,GfVec3f( 0.6429, 0.4422, -0.5878),
GfVec3f( 0.2384, 0.7361, -0.5878) ,GfVec3f(-0.2616, 0.7361, -0.5878) ,GfVec3f(-0.6661, 0.4422, -0.5878),
GfVec3f(-0.8206, -0.0333, -0.5878) ,GfVec3f(-0.6661, -0.5088, -0.5878) ,GfVec3f(-0.2616, -0.8027, -0.5878),
GfVec3f( 0.2384, -0.8027, -0.5878) ,GfVec3f( 0.6429, -0.5088, -0.5878) ,GfVec3f( 0.7975, -0.0333, -0.5878),
GfVec3f( 0.7579, 0.5257, -0.3090) ,GfVec3f( 0.2823, 0.8712, -0.3090) ,GfVec3f(-0.3055, 0.8712, -0.3090),
GfVec3f(-0.7810, 0.5257, -0.3090) ,GfVec3f(-0.9626, -0.0333, -0.3090) ,GfVec3f(-0.7810, -0.5923, -0.3090),
GfVec3f(-0.3055, -0.9378, -0.3090) ,GfVec3f( 0.2823, -0.9378, -0.3090) ,GfVec3f( 0.7579, -0.5923, -0.3090),
GfVec3f( 0.9395, -0.0333, -0.3090) ,GfVec3f( 0.7975, 0.5545, -0.0000) ,GfVec3f( 0.2975, 0.9178, -0.0000),
GfVec3f(-0.3206, 0.9178, -0.0000) ,GfVec3f(-0.8206, 0.5545, -0.0000) ,GfVec3f(-1.0116, -0.0333, 0.0000),
GfVec3f(-0.8206, -0.6211, 0.0000) ,GfVec3f(-0.3206, -0.9844, 0.0000) ,GfVec3f( 0.2975, -0.9844, 0.0000),
GfVec3f( 0.7975, -0.6211, 0.0000) ,GfVec3f( 0.9884, -0.0333, 0.0000) ,GfVec3f( 0.7579, 0.5257, 0.3090),
GfVec3f( 0.2823, 0.8712, 0.3090) ,GfVec3f(-0.3055, 0.8712, 0.3090) ,GfVec3f(-0.7810, 0.5257, 0.3090),
GfVec3f(-0.9626, -0.0333, 0.3090) ,GfVec3f(-0.7810, -0.5923, 0.3090) ,GfVec3f(-0.3055, -0.9378, 0.3090),
GfVec3f( 0.2823, -0.9378, 0.3090) ,GfVec3f( 0.7579, -0.5923, 0.3090) ,GfVec3f( 0.9395, -0.0333, 0.3090),
GfVec3f( 0.6429, 0.4422, 0.5878) ,GfVec3f( 0.2384, 0.7361, 0.5878) ,GfVec3f(-0.2616, 0.7361, 0.5878),
GfVec3f(-0.6661, 0.4422, 0.5878) ,GfVec3f(-0.8206, -0.0333, 0.5878) ,GfVec3f(-0.6661, -0.5088, 0.5878),
GfVec3f(-0.2616, -0.8027, 0.5878) ,GfVec3f( 0.2384, -0.8027, 0.5878) ,GfVec3f( 0.6429, -0.5088, 0.5878),
GfVec3f( 0.7975, -0.0333, 0.5878) ,GfVec3f( 0.4640, 0.3122, 0.8090) ,GfVec3f( 0.1701, 0.5257, 0.8090),
GfVec3f(-0.1932, 0.5257, 0.8090) ,GfVec3f(-0.4871, 0.3122, 0.8090) ,GfVec3f(-0.5993, -0.0333, 0.8090),
GfVec3f(-0.4871, -0.3788, 0.8090) ,GfVec3f(-0.1932, -0.5923, 0.8090) ,GfVec3f( 0.1701, -0.5923, 0.8090),
GfVec3f( 0.4640, -0.3788, 0.8090) ,GfVec3f( 0.5762, -0.0333, 0.8090) ,GfVec3f( 0.2384, 0.1483, 0.9511),
GfVec3f( 0.0839, 0.2606, 0.9511) ,GfVec3f(-0.1071, 0.2606, 0.9511) ,GfVec3f(-0.2616, 0.1483, 0.9511),
GfVec3f(-0.3206, -0.0333, 0.9511) ,GfVec3f(-0.2616, -0.2149, 0.9511) ,GfVec3f(-0.1071, -0.3272, 0.9511),
GfVec3f( 0.0839, -0.3272, 0.9511) ,GfVec3f( 0.2384, -0.2149, 0.9511) ,GfVec3f( 0.2975, -0.0333, 0.9511),
GfVec3f(-0.0116, -0.0333, -1.0000) ,GfVec3f(-0.0116, -0.0333, 1.0000),
};
size_t numPoints = sizeof(points) / sizeof(points[0]);
VtArray<GfVec3f> output(numPoints);
std::copy(points, points + numPoints, output.begin());
return VtValue(output);
}
void
My_TestGLDrawing::DrawScene()
{
_Clear();
int width = GetWidth(), height = GetHeight();
GfMatrix4d viewMatrix = GetViewMatrix();
GfFrustum frustum = GetFrustum();
GfVec4d viewport(0, 0, width, height);
GfMatrix4d projMatrix = frustum.ComputeProjectionMatrix();
_delegate->SetCamera(viewMatrix, projMatrix);
glViewport(viewport[0], viewport[1], viewport[2], viewport[3]);
SdfPath renderSetupTask("/renderSetupTask");
SdfPath renderTask("/renderTask");
SdfPath selectionTask("/selectionTask");
// viewport
HdxRenderTaskParams param
= _delegate->GetTaskParam(
renderSetupTask, HdTokens->params).Get<HdxRenderTaskParams>();
param.viewport = viewport;
_delegate->SetTaskParam(renderSetupTask, HdTokens->params, VtValue(param));
HdTaskSharedPtrVector tasks;
tasks.push_back(_delegate->GetRenderIndex().GetTask(renderSetupTask));
tasks.push_back(_delegate->GetRenderIndex().GetTask(renderTask));
tasks.push_back(_delegate->GetRenderIndex().GetTask(selectionTask));
glEnable(GL_DEPTH_TEST);
glBindVertexArray(vao);
VtValue v(_picker.GetSelectionTracker());
_engine.SetTaskContextData(HdxTokens->selectionState, v);
_engine.Execute(_delegate->GetRenderIndex(), tasks);
glBindVertexArray(0);
}
/*static*/
VtValue
UsdImagingCubeAdapter::GetMeshPoints(UsdPrim const& prim,
UsdTimeCode time)
{
static GfVec3f points[] = {
GfVec3f( 0.5f, 0.5f, 0.5f ),
GfVec3f(-0.5f, 0.5f, 0.5f ),
GfVec3f(-0.5f,-0.5f, 0.5f ),
GfVec3f( 0.5f,-0.5f, 0.5f ),
GfVec3f(-0.5f,-0.5f,-0.5f ),
GfVec3f(-0.5f, 0.5f,-0.5f ),
GfVec3f( 0.5f, 0.5f,-0.5f ),
GfVec3f( 0.5f,-0.5f,-0.5f ),
};
size_t numPoints = sizeof(points) / sizeof(points[0]);
VtArray<GfVec3f> output(numPoints);
std::copy(points, points + numPoints, output.begin());
return VtValue(output);
}
/*static*/
VtValue
UsdImagingSphereAdapter::GetMeshTopology()
{
static int numVerts[] = {
4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4,
4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4,
4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4,
4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4 ,4,
3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3 ,3,
};
static int verts[] = {
0 ,1 ,11 ,10 ,1 ,2 ,12 ,11 ,2 ,3 ,13 ,12 ,3 ,4 ,14 ,13 ,4 ,5 ,15 ,14, 5
,6 ,16 ,15 ,6 ,7 ,17 ,16 ,7 ,8 ,18 ,17 ,8 ,9 ,19 ,18 ,9 ,0 ,10 ,19,
10 ,11 ,21 ,20 ,11 ,12 ,22 ,21 ,12 ,13 ,23 ,22 ,13 ,14 ,24 ,23 ,14 ,15
,25 ,24, 15 ,16 ,26 ,25 ,16 ,17 ,27 ,26 ,17 ,18 ,28 ,27 ,18 ,19 ,29
,28 ,19 ,10 ,20 ,29, 20 ,21 ,31 ,30 ,21 ,22 ,32 ,31 ,22 ,23 ,33 ,32
,23 ,24 ,34 ,33 ,24 ,25 ,35 ,34, 25 ,26 ,36 ,35 ,26 ,27 ,37 ,36 ,27
,28 ,38 ,37 ,28 ,29 ,39 ,38 ,29 ,20 ,30 ,39, 30 ,31 ,41 ,40 ,31 ,32
,42 ,41 ,32 ,33 ,43 ,42 ,33 ,34 ,44 ,43 ,34 ,35 ,45 ,44, 35 ,36 ,46
,45 ,36 ,37 ,47 ,46 ,37 ,38 ,48 ,47 ,38 ,39 ,49 ,48 ,39 ,30 ,40 ,49,
40 ,41 ,51 ,50 ,41 ,42 ,52 ,51 ,42 ,43 ,53 ,52 ,43 ,44 ,54 ,53 ,44 ,45
,55 ,54, 45 ,46 ,56 ,55 ,46 ,47 ,57 ,56 ,47 ,48 ,58 ,57 ,48 ,49 ,59
,58 ,49 ,40 ,50 ,59, 50 ,51 ,61 ,60 ,51 ,52 ,62 ,61 ,52 ,53 ,63 ,62
,53 ,54 ,64 ,63 ,54 ,55 ,65 ,64, 55 ,56 ,66 ,65 ,56 ,57 ,67 ,66 ,57
,58 ,68 ,67 ,58 ,59 ,69 ,68 ,59 ,50 ,60 ,69, 60 ,61 ,71 ,70 ,61 ,62
,72 ,71 ,62 ,63 ,73 ,72 ,63 ,64 ,74 ,73 ,64 ,65 ,75 ,74, 65 ,66 ,76
,75 ,66 ,67 ,77 ,76 ,67 ,68 ,78 ,77 ,68 ,69 ,79 ,78 ,69 ,60 ,70 ,79,
70 ,71 ,81 ,80 ,71 ,72 ,82 ,81 ,72 ,73 ,83 ,82 ,73 ,74 ,84 ,83 ,74 ,75
,85 ,84, 75 ,76 ,86 ,85 ,76 ,77 ,87 ,86 ,77 ,78 ,88 ,87 ,78 ,79 ,89
,88 ,79 ,70 ,80 ,89, 1 ,0 ,90 ,2 ,1 ,90 ,3 ,2 ,90 ,4 ,3 ,90 ,5 ,4
,90 ,6 ,5 ,90 ,7 ,6, 90 ,8 ,7 ,90 ,9 ,8 ,90 ,0 ,9 ,90 ,80 ,81 ,91
,81 ,82 ,91 ,82 ,83 ,91 ,83, 84 ,91 ,84 ,85 ,91 ,85 ,86 ,91 ,86 ,87
,91 ,87 ,88 ,91 ,88 ,89 ,91 ,89 ,80 ,91,
};
static HdMeshTopology sphereTopo(PxOsdOpenSubdivTokens->catmark,
HdTokens->rightHanded,
_BuildVtArray(numVerts, sizeof(numVerts) / sizeof(numVerts[0])),
_BuildVtArray(verts, sizeof(verts) / sizeof(verts[0])));
return VtValue(sphereTopo);
}
