void Picker::Pick(GfVec2i const& startPos, GfVec2i const& endPos) { if (!_intersector) return; // for readability GfVec2i const& pickRadius = _pParams.pickRadius; float const& width = _pParams.screenWidth; float const& height = _pParams.screenHeight; GfFrustum const& frustum = _pParams.viewFrustum; GfMatrix4d const& viewMatrix = _pParams.viewMatrix; int fwidth = std::max(pickRadius[0], std::abs(startPos[0] - endPos[0])); int fheight = std::max(pickRadius[1], std::abs(startPos[1] - endPos[1])); _intersector->SetResolution(GfVec2i(fwidth, fheight)); GfVec2d min(2*startPos[0]/width-1, 1-2*startPos[1]/height); GfVec2d max(2*(endPos[0]+1)/width-1, 1-2*(endPos[1]+1)/height); // scale window GfVec2d origin = frustum.GetWindow().GetMin(); GfVec2d scale = frustum.GetWindow().GetMax() - frustum.GetWindow().GetMin(); min = origin + GfCompMult(scale, 0.5 * (GfVec2d(1.0, 1.0) + min)); max = origin + GfCompMult(scale, 0.5 * (GfVec2d(1.0, 1.0) + max)); GfFrustum pickFrustum(frustum); pickFrustum.SetWindow(GfRange2d(min, max)); HdxIntersector::Params iParams; iParams.pickTarget = _pParams.pickTarget; iParams.doUnpickablesOcclude = _pParams.doUnpickablesOcclude; iParams.hitMode = HdxIntersector::HitFirst; iParams.projectionMatrix = pickFrustum.ComputeProjectionMatrix(); iParams.viewMatrix = viewMatrix; std::cout << "Pick " << startPos << " - " << endPos << "\n"; HdxIntersector::Result result; _intersector->Query(iParams, *_pParams.pickablesCol, _pParams.engine, &result); HdxIntersector::HitSet hits; HdSelectionSharedPtr selection(new HdSelection); if (result.ResolveUnique(&hits)) { AggregatedHits aggrHits = _AggregateHits(hits); for(const auto& pair : aggrHits) { _ProcessHit(pair.second, _pParams.pickTarget, _pParams.highlightMode, selection); } } _selectionTracker->SetSelection(selection); }
GfRange2d GfRange2d::GetQuadrant(size_t i) const { if (i > 3) { TF_CODING_ERROR("Invalid quadrant %zu > 3.", i); return GfRange2d(); } GfVec2d a = GetCorner(i); GfVec2d b = .5 * (_min + _max); return GfRange2d( GfVec2d(GfMin(a[0], b[0]), GfMin(a[1], b[1])), GfVec2d(GfMax(a[0], b[0]), GfMax(a[1], b[1]))); }
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); }
GfVec2d GfRange2d::GetCorner(size_t i) const { if (i > 3) { TF_CODING_ERROR("Invalid corner %zu > 3.", i); return _min; } return GfVec2d((i & 1 ? _max : _min)[0], (i & 2 ? _max : _min)[1]); }
} GfVec2d GfRange2d::GetCorner(size_t i) const { if (i > 3) { TF_CODING_ERROR("Invalid corner %zu > 3.", i); return _min; } return GfVec2d((i & 1 ? _max : _min)[0], (i & 2 ? _max : _min)[1]); } GfRange2d GfRange2d::GetQuadrant(size_t i) const { if (i > 3) { TF_CODING_ERROR("Invalid quadrant %zu > 3.", i); return GfRange2d(); } GfVec2d a = GetCorner(i); GfVec2d b = .5 * (_min + _max); return GfRange2d( GfVec2d(GfMin(a[0], b[0]), GfMin(a[1], b[1])), GfVec2d(GfMax(a[0], b[0]), GfMax(a[1], b[1]))); } const GfRange2d GfRange2d::UnitSquare(GfVec2d(0,0), GfVec2d(1,1));
bool PxrUsdMayaWriteUtil::SetUsdAttr( const MPlug& attrPlug, const UsdAttribute& usdAttr, const UsdTimeCode& usdTime, const bool translateMayaDoubleToUsdSinglePrecision) { if (!usdAttr || attrPlug.isNull()) { return false; } bool isAnimated = attrPlug.isDestination(); if (usdTime.IsDefault() == isAnimated) { return true; } // We perform a similar set of type-infererence acrobatics here as we do up // above in GetUsdTypeName(). See the comments there for more detail on a // few type-related oddities. MObject attrObj(attrPlug.attribute()); if (attrObj.hasFn(MFn::kEnumAttribute)) { MFnEnumAttribute enumAttrFn(attrObj); const short enumIndex = attrPlug.asShort(); const TfToken enumToken(enumAttrFn.fieldName(enumIndex).asChar()); return usdAttr.Set(enumToken, usdTime); } MFnNumericData::Type numericDataType; MFnData::Type typedDataType; MFnUnitAttribute::Type unitDataType; _GetMayaAttributeNumericTypedAndUnitDataTypes(attrPlug, numericDataType, typedDataType, unitDataType); if (attrObj.hasFn(MFn::kMatrixAttribute)) { typedDataType = MFnData::kMatrix; } switch (typedDataType) { case MFnData::kString: { MFnStringData stringDataFn(attrPlug.asMObject()); const std::string usdVal(stringDataFn.string().asChar()); return usdAttr.Set(usdVal, usdTime); break; } case MFnData::kMatrix: { MFnMatrixData matrixDataFn(attrPlug.asMObject()); const GfMatrix4d usdVal(matrixDataFn.matrix().matrix); return usdAttr.Set(usdVal, usdTime); break; } case MFnData::kStringArray: { MFnStringArrayData stringArrayDataFn(attrPlug.asMObject()); VtStringArray usdVal(stringArrayDataFn.length()); for (unsigned int i = 0; i < stringArrayDataFn.length(); ++i) { usdVal[i] = std::string(stringArrayDataFn[i].asChar()); } return usdAttr.Set(usdVal, usdTime); break; } case MFnData::kDoubleArray: { MFnDoubleArrayData doubleArrayDataFn(attrPlug.asMObject()); if (translateMayaDoubleToUsdSinglePrecision) { VtFloatArray usdVal(doubleArrayDataFn.length()); for (unsigned int i = 0; i < doubleArrayDataFn.length(); ++i) { usdVal[i] = (float)doubleArrayDataFn[i]; } return usdAttr.Set(usdVal, usdTime); } else { VtDoubleArray usdVal(doubleArrayDataFn.length()); for (unsigned int i = 0; i < doubleArrayDataFn.length(); ++i) { usdVal[i] = doubleArrayDataFn[i]; } return usdAttr.Set(usdVal, usdTime); } break; } case MFnData::kFloatArray: { MFnFloatArrayData floatArrayDataFn(attrPlug.asMObject()); VtFloatArray usdVal(floatArrayDataFn.length()); for (unsigned int i = 0; i < floatArrayDataFn.length(); ++i) { usdVal[i] = floatArrayDataFn[i]; } return usdAttr.Set(usdVal, usdTime); break; } case MFnData::kIntArray: { MFnIntArrayData intArrayDataFn(attrPlug.asMObject()); VtIntArray usdVal(intArrayDataFn.length()); for (unsigned int i = 0; i < intArrayDataFn.length(); ++i) { usdVal[i] = intArrayDataFn[i]; } return usdAttr.Set(usdVal, usdTime); break; } case MFnData::kPointArray: { MFnPointArrayData pointArrayDataFn(attrPlug.asMObject()); if (translateMayaDoubleToUsdSinglePrecision) { VtVec3fArray usdVal(pointArrayDataFn.length()); for (unsigned int i = 0; i < pointArrayDataFn.length(); ++i) { MPoint tmpMayaVal = pointArrayDataFn[i]; if (tmpMayaVal.w != 0) { tmpMayaVal.cartesianize(); } usdVal[i] = GfVec3f((float)tmpMayaVal[0], (float)tmpMayaVal[1], (float)tmpMayaVal[2]); } return usdAttr.Set(usdVal, usdTime); } else { VtVec3dArray usdVal(pointArrayDataFn.length()); for (unsigned int i = 0; i < pointArrayDataFn.length(); ++i) { MPoint tmpMayaVal = pointArrayDataFn[i]; if (tmpMayaVal.w != 0) { tmpMayaVal.cartesianize(); } usdVal[i] = GfVec3d(tmpMayaVal[0], tmpMayaVal[1], tmpMayaVal[2]); } return usdAttr.Set(usdVal, usdTime); } break; } case MFnData::kVectorArray: { MFnVectorArrayData vectorArrayDataFn(attrPlug.asMObject()); if (translateMayaDoubleToUsdSinglePrecision) { VtVec3fArray usdVal(vectorArrayDataFn.length()); for (unsigned int i = 0; i < vectorArrayDataFn.length(); ++i) { MVector tmpMayaVal = vectorArrayDataFn[i]; usdVal[i] = GfVec3f((float)tmpMayaVal[0], (float)tmpMayaVal[1], (float)tmpMayaVal[2]); } return usdAttr.Set(usdVal, usdTime); } else { VtVec3dArray usdVal(vectorArrayDataFn.length()); for (unsigned int i = 0; i < vectorArrayDataFn.length(); ++i) { MVector tmpMayaVal = vectorArrayDataFn[i]; usdVal[i] = GfVec3d(tmpMayaVal[0], tmpMayaVal[1], tmpMayaVal[2]); } return usdAttr.Set(usdVal, usdTime); } break; } default: break; } switch (numericDataType) { case MFnNumericData::kBoolean: { const bool usdVal(attrPlug.asBool()); return usdAttr.Set(usdVal, usdTime); break; } case MFnNumericData::kByte: case MFnNumericData::kChar: { const int usdVal(attrPlug.asChar()); return usdAttr.Set(usdVal, usdTime); break; } case MFnNumericData::kShort: { const int usdVal(attrPlug.asShort()); return usdAttr.Set(usdVal, usdTime); break; } case MFnNumericData::kInt: { const int usdVal(attrPlug.asInt()); return usdAttr.Set(usdVal, usdTime); break; } case MFnNumericData::k2Short: { short tmp1, tmp2; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2); return usdAttr.Set(GfVec2i(tmp1, tmp2), usdTime); break; } case MFnNumericData::k2Int: { int tmp1, tmp2; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2); return usdAttr.Set(GfVec2i(tmp1, tmp2), usdTime); break; } case MFnNumericData::k3Short: { short tmp1, tmp2, tmp3; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2, tmp3); return usdAttr.Set(GfVec3i(tmp1, tmp2, tmp3), usdTime); break; } case MFnNumericData::k3Int: { int tmp1, tmp2, tmp3; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2, tmp3); return usdAttr.Set(GfVec3i(tmp1, tmp2, tmp3), usdTime); break; } case MFnNumericData::kFloat: { const float usdVal(attrPlug.asFloat()); return usdAttr.Set(usdVal, usdTime); break; } case MFnNumericData::k2Float: { float tmp1, tmp2; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2); return usdAttr.Set(GfVec2f(tmp1, tmp2), usdTime); break; } case MFnNumericData::k3Float: { float tmp1, tmp2, tmp3; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2, tmp3); return _SetVec(usdAttr, GfVec3f(tmp1, tmp2, tmp3), usdTime); break; } case MFnNumericData::kDouble: { const double usdVal(attrPlug.asDouble()); if (translateMayaDoubleToUsdSinglePrecision) { return usdAttr.Set((float)usdVal, usdTime); } else { return usdAttr.Set(usdVal, usdTime); } break; } case MFnNumericData::k2Double: { double tmp1, tmp2; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2); if (translateMayaDoubleToUsdSinglePrecision) { return usdAttr.Set(GfVec2f((float)tmp1, (float)tmp2), usdTime); } else { return usdAttr.Set(GfVec2d(tmp1, tmp2), usdTime); } break; } case MFnNumericData::k3Double: { double tmp1, tmp2, tmp3; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2, tmp3); if (translateMayaDoubleToUsdSinglePrecision) { return _SetVec(usdAttr, GfVec3f((float)tmp1, (float)tmp2, (float)tmp3), usdTime); } else { return _SetVec(usdAttr, GfVec3d(tmp1, tmp2, tmp3), usdTime); } break; } case MFnNumericData::k4Double: { double tmp1, tmp2, tmp3, tmp4; MFnNumericData numericDataFn(attrPlug.asMObject()); numericDataFn.getData(tmp1, tmp2, tmp3, tmp4); if (translateMayaDoubleToUsdSinglePrecision) { return _SetVec(usdAttr, GfVec4f((float)tmp1, (float)tmp2, (float)tmp3, (float)tmp4), usdTime); } else { return _SetVec(usdAttr, GfVec4d(tmp1, tmp2, tmp3, tmp4), usdTime); } break; } default: break; } switch (unitDataType) { case MFnUnitAttribute::kAngle: case MFnUnitAttribute::kDistance: if (translateMayaDoubleToUsdSinglePrecision) { const float usdVal(attrPlug.asFloat()); return usdAttr.Set(usdVal, usdTime); } else { const double usdVal(attrPlug.asDouble()); return usdAttr.Set(usdVal, usdTime); } break; default: break; } return false; }
SdfPath My_TestGLDrawing::PickScene(int pickX, int pickY, int * outInstanceIndex, int * outElementIndex) { int width = 128; int height = 128; GlfDrawTargetRefPtr drawTarget = GlfDrawTarget::New(GfVec2i(width, height)); drawTarget->Bind(); drawTarget->AddAttachment( "primId", GL_RGBA, GL_UNSIGNED_BYTE, GL_RGBA8); drawTarget->AddAttachment( "instanceId", GL_RGBA, GL_UNSIGNED_BYTE, GL_RGBA8); drawTarget->AddAttachment( "elementId", GL_RGBA, GL_UNSIGNED_BYTE, GL_RGBA8); drawTarget->AddAttachment( "depth", GL_DEPTH_COMPONENT, GL_FLOAT, GL_DEPTH_COMPONENT32F); drawTarget->Unbind(); drawTarget->Bind(); GLenum drawBuffers[] = { GL_COLOR_ATTACHMENT0, GL_COLOR_ATTACHMENT1, GL_COLOR_ATTACHMENT2 }; glDrawBuffers(3, drawBuffers); glEnable(GL_DEPTH_TEST); GLfloat clearColor[4] = { 0.0f, 0.0f, 0.0f, 0.0f }; glClearBufferfv(GL_COLOR, 0, clearColor); glClearBufferfv(GL_COLOR, 1, clearColor); GLfloat clearDepth[1] = { 1.0f }; glClearBufferfv(GL_DEPTH, 0, clearDepth); PickParam pickParam; pickParam.location = GfVec2d(pickX, pickY); pickParam.viewport = GfVec4d(0, 0, width, height); DrawScene(&pickParam); drawTarget->Unbind(); GLubyte primId[width*height*4]; glBindTexture(GL_TEXTURE_2D, drawTarget->GetAttachments().at("primId")->GetGlTextureName()); glGetTexImage(GL_TEXTURE_2D, 0, GL_RGBA, GL_UNSIGNED_BYTE, primId); GLubyte instanceId[width*height*4]; glBindTexture(GL_TEXTURE_2D, drawTarget->GetAttachments().at("instanceId")->GetGlTextureName()); glGetTexImage(GL_TEXTURE_2D, 0, GL_RGBA, GL_UNSIGNED_BYTE, instanceId); GLubyte elementId[width*height*4]; glBindTexture(GL_TEXTURE_2D, drawTarget->GetAttachments().at("elementId")->GetGlTextureName()); glGetTexImage(GL_TEXTURE_2D, 0, GL_RGBA, GL_UNSIGNED_BYTE, elementId); GLfloat depths[width*height]; glBindTexture(GL_TEXTURE_2D, drawTarget->GetAttachments().at("depth")->GetGlTextureName()); glGetTexImage(GL_TEXTURE_2D, 0, GL_DEPTH_COMPONENT, GL_FLOAT, depths); double zMin = 1.0; int zMinIndex = -1; for (int y=0, i=0; y<height; y++) { for (int x=0; x<width; x++, i++) { if (depths[i] < zMin) { zMin = depths[i]; zMinIndex = i; } } } bool didHit = (zMin < 1.0); SdfPath result; if (didHit) { int idIndex = zMinIndex*4; result = _delegate->GetRenderIndex().GetRprimPathFromPrimId( HdxRenderSetupTask::DecodeIDRenderColor(&primId[idIndex])); if (outInstanceIndex) { *outInstanceIndex = HdxRenderSetupTask::DecodeIDRenderColor( &instanceId[idIndex]); } if (outElementIndex) { *outElementIndex = HdxRenderSetupTask::DecodeIDRenderColor( &elementId[idIndex]); } } return result; }
bool PxrUsdMayaWriteUtil::SetUsdAttr( const MPlug &plg, const UsdAttribute& usdAttr, const UsdTimeCode &usdTime) { MStatus status; if (!usdAttr || plg.isNull() ) { return false; } bool isAnimated = plg.isDestination(); if (usdTime.IsDefault() == isAnimated ) { return true; } // Set UsdAttr MObject attrObj = plg.attribute(); if (attrObj.hasFn(MFn::kNumericAttribute)) { MFnNumericAttribute attrNumericFn(attrObj); switch (attrNumericFn.unitType()) { case MFnNumericData::kBoolean: usdAttr.Set(plg.asBool(), usdTime); break; case MFnNumericData::kByte: case MFnNumericData::kChar: usdAttr.Set((int)plg.asChar(), usdTime); break; case MFnNumericData::kShort: usdAttr.Set(int(plg.asShort()), usdTime); break; case MFnNumericData::kInt: usdAttr.Set(int(plg.asInt()), usdTime); break; //case MFnNumericData::kLong: //case MFnNumericData::kAddr: // usdAttr.Set(plg.asInt(), usdTime); // break; case MFnNumericData::kFloat: usdAttr.Set(plg.asFloat(), usdTime); break; case MFnNumericData::kDouble: usdAttr.Set(plg.asDouble(), usdTime); break; case MFnNumericData::k2Short: { short tmp1, tmp2; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2); usdAttr.Set(GfVec2i(tmp1, tmp2), usdTime); break; } case MFnNumericData::k2Int: { int tmp1, tmp2; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2); usdAttr.Set(GfVec2i(tmp1, tmp2), usdTime); break; } //case MFnNumericData::k2Long: case MFnNumericData::k3Short: { short tmp1, tmp2, tmp3; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2, tmp3); usdAttr.Set(GfVec3i(tmp1, tmp2, tmp3), usdTime); break; } case MFnNumericData::k3Int: { int tmp1, tmp2, tmp3; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2, tmp3); usdAttr.Set(GfVec3i(tmp1, tmp2, tmp3), usdTime); break; } //case MFnNumericData::k3Long: case MFnNumericData::k2Float: { float tmp1, tmp2; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2); usdAttr.Set(GfVec2f(tmp1, tmp2), usdTime); break; } case MFnNumericData::k3Float: { float tmp1, tmp2, tmp3; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2, tmp3); _SetVec(usdAttr, GfVec3f(tmp1, tmp2, tmp3), usdTime); break; } case MFnNumericData::k2Double: { double tmp1, tmp2; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2); usdAttr.Set(GfVec2d(tmp1, tmp2), usdTime); break; } case MFnNumericData::k3Double: { double tmp1, tmp2, tmp3; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2, tmp3); _SetVec(usdAttr, GfVec3d(tmp1, tmp2, tmp3), usdTime); break; } case MFnNumericData::k4Double: { double tmp1, tmp2, tmp3, tmp4; MFnNumericData attrNumericDataFn(plg.asMObject()); attrNumericDataFn.getData(tmp1, tmp2, tmp3, tmp4); _SetVec(usdAttr, GfVec4d(tmp1, tmp2, tmp3, tmp4), usdTime); break; } default: return false; } } else if (attrObj.hasFn(MFn::kTypedAttribute)) { MFnTypedAttribute attrTypedFn(attrObj); switch (attrTypedFn.attrType()) { case MFnData::kString: usdAttr.Set(std::string(plg.asString().asChar()), usdTime); break; case MFnData::kMatrix: { MFnMatrixData attrMatrixDataFn(plg.asMObject()); MMatrix mat1 = attrMatrixDataFn.matrix(); usdAttr.Set(GfMatrix4d(mat1.matrix), usdTime); break; } case MFnData::kStringArray: { MFnStringArrayData attrDataFn(plg.asMObject()); VtArray<std::string> usdVal(attrDataFn.length()); for (unsigned int i=0; i < attrDataFn.length(); i++) { usdVal[i] = std::string(attrDataFn[i].asChar()); } usdAttr.Set(usdVal, usdTime); break; } case MFnData::kIntArray: { MFnIntArrayData attrDataFn(plg.asMObject()); VtArray<int> usdVal(attrDataFn.length()); for (unsigned int i=0; i < attrDataFn.length(); i++) { usdVal[i] = attrDataFn[i]; } usdAttr.Set(usdVal, usdTime); break; } case MFnData::kFloatArray: { MFnFloatArrayData attrDataFn(plg.asMObject()); VtArray<float> usdVal(attrDataFn.length()); for (unsigned int i=0; i < attrDataFn.length(); i++) { usdVal[i] = attrDataFn[i]; } usdAttr.Set(usdVal, usdTime); break; } case MFnData::kDoubleArray: { MFnDoubleArrayData attrDataFn(plg.asMObject()); VtArray<double> usdVal(attrDataFn.length()); for (unsigned int i=0; i < attrDataFn.length(); i++) { usdVal[i] = attrDataFn[i]; } usdAttr.Set(usdVal, usdTime); break; } case MFnData::kVectorArray: { MFnVectorArrayData attrDataFn(plg.asMObject()); VtArray<GfVec3d> usdVal(attrDataFn.length()); for (unsigned int i=0; i < attrDataFn.length(); i++) { MVector tmpMayaVal = attrDataFn[i]; usdVal[i] = GfVec3d(tmpMayaVal[0], tmpMayaVal[1], tmpMayaVal[2]); } usdAttr.Set(usdVal, usdTime); break; } case MFnData::kPointArray: { MFnPointArrayData attrDataFn(plg.asMObject()); VtArray<GfVec4d> usdVal(attrDataFn.length()); for (unsigned int i=0; i < attrDataFn.length(); i++) { MPoint tmpMayaVal = attrDataFn[i]; usdVal[i] = GfVec4d(tmpMayaVal[0], tmpMayaVal[1], tmpMayaVal[2], tmpMayaVal[3]); } usdAttr.Set(usdVal, usdTime); break; } default: return false; } } else if (attrObj.hasFn(MFn::kUnitAttribute)) { //MFnUnitAttribute attrUnitFn(attrObj); return false; } else if (attrObj.hasFn(MFn::kEnumAttribute)) { MFnEnumAttribute attrEnumFn(attrObj); short enumIndex = plg.asShort(); TfToken enumToken( std::string(attrEnumFn.fieldName(enumIndex, &status).asChar()) ); usdAttr.Set(enumToken, usdTime); return false; } return true; }