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@thewtex/vtk.js-esm

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Visualization Toolkit for the Web

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import _defineProperty from '@babel/runtime/helpers/defineProperty'; import { obj, setGet, newInstance as newInstance$1, vtkWarningMacro as vtkWarningMacro$1, vtkErrorMacro as vtkErrorMacro$1 } from '../../macro.js'; import vtkDataArray from '../../Common/Core/DataArray.js'; import { VtkDataTypes } from '../../Common/Core/DataArray/Constants.js'; import vtkHelper from './Helper.js'; import { u as uninitializeBounds } from '../../Common/Core/Math/index.js'; import vtkOpenGLFramebuffer from './Framebuffer.js'; import vtkOpenGLTexture from './Texture.js'; import vtkShaderProgram from './ShaderProgram.js'; import vtkVertexArrayObject from './VertexArrayObject.js'; import vtkViewNode from '../SceneGraph/ViewNode.js'; import { Representation } from '../Core/Property/Constants.js'; import { Wrap, Filter } from './Texture/Constants.js'; import { InterpolationType, OpacityMode } from '../Core/VolumeProperty/Constants.js'; import { BlendMode } from '../Core/VolumeMapper/Constants.js'; import { v as vtkVolumeVS } from './glsl/vtkVolumeVS.glsl.js'; import { v as vtkVolumeFS } from './glsl/vtkVolumeFS.glsl.js'; import { registerOverride } from './ViewNodeFactory.js'; import { i as identity, m as multiply, g as invert } from '../../vendor/gl-matrix/esm/mat4.js'; import { i as identity$1, m as multiply$1 } from '../../vendor/gl-matrix/esm/mat3.js'; import { s as set, l as length, t as transformMat4, n as normalize, b as scale, o as divide, p as transformMat3, d as dot } from '../../vendor/gl-matrix/esm/vec3.js'; function ownKeys(object, enumerableOnly) { var keys = Object.keys(object); if (Object.getOwnPropertySymbols) { var symbols = Object.getOwnPropertySymbols(object); if (enumerableOnly) symbols = symbols.filter(function (sym) { return Object.getOwnPropertyDescriptor(object, sym).enumerable; }); keys.push.apply(keys, symbols); } return keys; } function _objectSpread(target) { for (var i = 1; i < arguments.length; i++) { var source = arguments[i] != null ? arguments[i] : {}; if (i % 2) { ownKeys(Object(source), true).forEach(function (key) { _defineProperty(target, key, source[key]); }); } else if (Object.getOwnPropertyDescriptors) { Object.defineProperties(target, Object.getOwnPropertyDescriptors(source)); } else { ownKeys(Object(source)).forEach(function (key) { Object.defineProperty(target, key, Object.getOwnPropertyDescriptor(source, key)); }); } } return target; } var vtkWarningMacro = vtkWarningMacro$1, vtkErrorMacro = vtkErrorMacro$1; // TODO: Do we want this in some shared utility? Shouldwe just use lodash.isEqual function arrayEquals(a, b) { if (a.length !== b.length) { return false; } for (var i = 0; i < a.length; ++i) { if (a[i] !== b[i]) { return false; } } return true; } // ---------------------------------------------------------------------------- // vtkOpenGLVolumeMapper methods // ---------------------------------------------------------------------------- function vtkOpenGLVolumeMapper(publicAPI, model) { // Set our className model.classHierarchy.push('vtkOpenGLVolumeMapper'); publicAPI.buildPass = function () { model.zBufferTexture = null; }; // ohh someone is doing a zbuffer pass, use that for // intermixed volume rendering publicAPI.opaqueZBufferPass = function (prepass, renderPass) { if (prepass) { var zbt = renderPass.getZBufferTexture(); if (zbt !== model.zBufferTexture) { model.zBufferTexture = zbt; } } }; // Renders myself publicAPI.volumePass = function (prepass, renderPass) { if (prepass) { model.openGLRenderWindow = publicAPI.getFirstAncestorOfType('vtkOpenGLRenderWindow'); model.context = model.openGLRenderWindow.getContext(); model.tris.setOpenGLRenderWindow(model.openGLRenderWindow); model.jitterTexture.setOpenGLRenderWindow(model.openGLRenderWindow); model.framebuffer.setOpenGLRenderWindow(model.openGLRenderWindow); // Per Component? model.scalarTexture.setOpenGLRenderWindow(model.openGLRenderWindow); model.colorTexture.setOpenGLRenderWindow(model.openGLRenderWindow); model.opacityTexture.setOpenGLRenderWindow(model.openGLRenderWindow); model.openGLVolume = publicAPI.getFirstAncestorOfType('vtkOpenGLVolume'); var actor = model.openGLVolume.getRenderable(); model.openGLRenderer = publicAPI.getFirstAncestorOfType('vtkOpenGLRenderer'); var ren = model.openGLRenderer.getRenderable(); model.openGLCamera = model.openGLRenderer.getViewNodeFor(ren.getActiveCamera()); publicAPI.renderPiece(ren, actor); } }; publicAPI.buildShaders = function (shaders, ren, actor) { publicAPI.getShaderTemplate(shaders, ren, actor); publicAPI.replaceShaderValues(shaders, ren, actor); }; publicAPI.getShaderTemplate = function (shaders, ren, actor) { shaders.Vertex = vtkVolumeVS; shaders.Fragment = vtkVolumeFS; shaders.Geometry = ''; }; publicAPI.replaceShaderValues = function (shaders, ren, actor) { var FSSource = shaders.Fragment; // define some values in the shader var iType = actor.getProperty().getInterpolationType(); if (iType === InterpolationType.LINEAR) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::TrilinearOn', '#define vtkTrilinearOn').result; } var vtkImageLabelOutline = actor.getProperty().getUseLabelOutline(); if (vtkImageLabelOutline === true) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::ImageLabelOutlineOn', '#define vtkImageLabelOutlineOn').result; } var numComp = model.scalarTexture.getComponents(); FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::NumComponents', "#define vtkNumComponents ".concat(numComp)).result; var iComps = actor.getProperty().getIndependentComponents(); if (iComps) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::IndependentComponentsOn', '#define vtkIndependentComponentsOn').result; // Define any proportional components var proportionalComponents = []; for (var nc = 0; nc < numComp; nc++) { if (actor.getProperty().getOpacityMode(nc) === OpacityMode.PROPORTIONAL) { proportionalComponents.push("#define vtkComponent".concat(nc, "Proportional")); } } if (proportionalComponents.length > 0) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::vtkProportionalComponents', proportionalComponents.join('\n')).result; } } // WebGL only supports loops over constants // and does not support while loops so we // have to hard code how many steps/samples to take // We do a break so most systems will gracefully // early terminate, but it is always possible // a system will execute every step regardless var ext = model.currentInput.getExtent(); var spc = model.currentInput.getSpacing(); var vsize = new Float64Array(3); set(vsize, (ext[1] - ext[0]) * spc[0], (ext[3] - ext[2]) * spc[1], (ext[5] - ext[4]) * spc[2]); var maxSamples = length(vsize) / model.renderable.getSampleDistance(); FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::MaximumSamplesValue', "".concat(Math.ceil(maxSamples))).result; // set light complexity FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::LightComplexity', "#define vtkLightComplexity ".concat(model.lastLightComplexity)).result; // if using gradient opacity define that model.gopacity = actor.getProperty().getUseGradientOpacity(0); for (var _nc = 1; iComps && !model.gopacity && _nc < numComp; ++_nc) { if (actor.getProperty().getUseGradientOpacity(_nc)) { model.gopacity = true; } } if (model.gopacity) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::GradientOpacityOn', '#define vtkGradientOpacityOn').result; } // if we have a ztexture then declare it and use it if (model.zBufferTexture !== null) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::ZBuffer::Dec', ['uniform sampler2D zBufferTexture;', 'uniform float vpWidth;', 'uniform float vpHeight;']).result; FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::ZBuffer::Impl', ['vec4 depthVec = texture2D(zBufferTexture, vec2(gl_FragCoord.x / vpWidth, gl_FragCoord.y/vpHeight));', 'float zdepth = (depthVec.r*256.0 + depthVec.g)/257.0;', 'zdepth = zdepth * 2.0 - 1.0;', 'zdepth = -2.0 * camFar * camNear / (zdepth*(camFar-camNear)-(camFar+camNear)) - camNear;', 'zdepth = -zdepth/rayDir.z;', 'dists.y = min(zdepth,dists.y);']).result; } // Set the BlendMode approach FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::BlendMode', "".concat(model.renderable.getBlendMode())).result; var ipScalarRange = model.renderable.getIpScalarRange(); var min = ipScalarRange[0]; var max = ipScalarRange[1]; // If min or max is not already a float. // make them into floats for glsl min = Number.isInteger(min) ? min.toFixed(1).toString() : min.toString(); max = Number.isInteger(max) ? max.toFixed(1).toString() : max.toString(); FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::IPScalarRangeMin', min).result; FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::IPScalarRangeMax', max).result; shaders.Fragment = FSSource; publicAPI.replaceShaderLight(shaders, ren, actor); publicAPI.replaceShaderClippingPlane(shaders, ren, actor); }; publicAPI.replaceShaderLight = function (shaders, ren, actor) { var FSSource = shaders.Fragment; // check for shadow maps var shadowFactor = ''; switch (model.lastLightComplexity) { default: case 0: // no lighting, tcolor is fine as is break; case 1: // headlight case 2: // light kit case 3: { // positional not implemented fallback to directional var lightNum = 0; ren.getLights().forEach(function (light) { var status = light.getSwitch(); if (status > 0) { FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::Light::Dec', [// intensity weighted color "uniform vec3 lightColor".concat(lightNum, ";"), "uniform vec3 lightDirectionVC".concat(lightNum, "; // normalized"), "uniform vec3 lightHalfAngleVC".concat(lightNum, "; // normalized"), '//VTK::Light::Dec'], false).result; FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::Light::Impl', [// ` float df = max(0.0, dot(normal.rgb, -lightDirectionVC${lightNum}));`, " float df = abs(dot(normal.rgb, -lightDirectionVC".concat(lightNum, "));"), " diffuse += ((df".concat(shadowFactor, ") * lightColor").concat(lightNum, ");"), // ' if (df > 0.0)', // ' {', // ` float sf = pow( max(0.0, dot(lightHalfAngleWC${lightNum},normal.rgb)), specularPower);`, " float sf = pow( abs(dot(lightHalfAngleVC".concat(lightNum, ",normal.rgb)), vSpecularPower);"), " specular += ((sf".concat(shadowFactor, ") * lightColor").concat(lightNum, ");"), // ' }', ' //VTK::Light::Impl'], false).result; lightNum++; } }); } } shaders.Fragment = FSSource; }; publicAPI.replaceShaderClippingPlane = function (shaders, ren, actor) { var FSSource = shaders.Fragment; if (model.renderable.getClippingPlanes().length > 0) { var clipPlaneSize = model.renderable.getClippingPlanes().length; FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::ClipPlane::Dec', ["uniform vec3 vClipPlaneNormals[6];", "uniform float vClipPlaneDistances[6];", '//VTK::ClipPlane::Dec'], false).result; FSSource = vtkShaderProgram.substitute(FSSource, '//VTK::ClipPlane::Impl', ["for(int i = 0; i < ".concat(clipPlaneSize, "; i++) {"), ' float rayDirRatio = dot(rayDir, vClipPlaneNormals[i]);', ' float equationResult = dot(vertexVCVSOutput, vClipPlaneNormals[i]) + vClipPlaneDistances[i];', ' if (rayDirRatio == 0.0)', ' {', ' if (equationResult < 0.0) dists.x = dists.y;', ' continue;', ' }', ' float result = -1.0 * equationResult / rayDirRatio;', ' if (rayDirRatio < 0.0) dists.y = min(dists.y, result);', ' else dists.x = max(dists.x, result);', '}', '//VTK::ClipPlane::Impl'], false).result; } shaders.Fragment = FSSource; }; publicAPI.getNeedToRebuildShaders = function (cellBO, ren, actor) { // do we need lighting? var lightComplexity = 0; if (actor.getProperty().getShade() && model.renderable.getBlendMode() === BlendMode.COMPOSITE_BLEND) { // consider the lighting complexity to determine which case applies // simple headlight, Light Kit, the whole feature set of VTK lightComplexity = 0; model.numberOfLights = 0; ren.getLights().forEach(function (light) { var status = light.getSwitch(); if (status > 0) { model.numberOfLights++; if (lightComplexity === 0) { lightComplexity = 1; } } if (lightComplexity === 1 && (model.numberOfLights > 1 || light.getIntensity() !== 1.0 || !light.lightTypeIsHeadLight())) { lightComplexity = 2; } if (lightComplexity < 3 && light.getPositional()) { lightComplexity = 3; } }); } var needRebuild = false; if (model.lastLightComplexity !== lightComplexity) { model.lastLightComplexity = lightComplexity; needRebuild = true; } var numComp = model.scalarTexture.getComponents(); var iComps = actor.getProperty().getIndependentComponents(); var usesProportionalComponents = false; var proportionalComponents = []; if (iComps) { // Define any proportional components for (var nc = 0; nc < numComp; nc++) { proportionalComponents.push(actor.getProperty().getOpacityMode(nc)); } if (proportionalComponents.length > 0) { usesProportionalComponents = true; } } var ext = model.currentInput.getExtent(); var spc = model.currentInput.getSpacing(); var vsize = new Float64Array(3); set(vsize, (ext[1] - ext[0]) * spc[0], (ext[3] - ext[2]) * spc[1], (ext[5] - ext[4]) * spc[2]); var maxSamples = length(vsize) / model.renderable.getSampleDistance(); var state = { interpolationType: actor.getProperty().getInterpolationType(), useLabelOutline: actor.getProperty().getUseLabelOutline(), numComp: numComp, usesProportionalComponents: usesProportionalComponents, iComps: iComps, maxSamples: maxSamples, useGradientOpacity: actor.getProperty().getUseGradientOpacity(0), blendMode: model.renderable.getBlendMode(), ipScalarMode: model.renderable.getIpScalarRange(), proportionalComponents: proportionalComponents }; // We only need to rebuild the shader if one of these variables has changed, // since they are used in the shader template replacement step. if (!model.previousState || model.previousState.interpolationType !== state.interpolationType || model.previousState.useLabelOutline !== state.useLabelOutline || model.previousState.numComp !== state.numComp || model.previousState.usesProportionalComponents !== state.usesProportionalComponents || model.previousState.iComps !== state.iComps || model.previousState.maxSamples !== state.maxSamples || model.previousState.useGradientOpacity !== state.useGradientOpacity || model.previousState.blendMode !== state.blendMode || !arrayEquals(model.previousState.ipScalarMode, state.ipScalarMode) || !arrayEquals(model.previousState.proportionalComponents, state.proportionalComponents)) { model.previousState = _objectSpread({}, state); return true; } // has something changed that would require us to recreate the shader? if (cellBO.getProgram() === 0 || needRebuild || model.lastHaveSeenDepthRequest !== model.haveSeenDepthRequest || !!model.lastZBufferTexture !== !!model.zBufferTexture || cellBO.getShaderSourceTime().getMTime() < publicAPI.getMTime() || cellBO.getShaderSourceTime().getMTime() < model.renderable.getMTime()) { model.lastZBufferTexture = model.zBufferTexture; return true; } return false; }; publicAPI.updateShaders = function (cellBO, ren, actor) { model.lastBoundBO = cellBO; // has something changed that would require us to recreate the shader? if (publicAPI.getNeedToRebuildShaders(cellBO, ren, actor)) { var shaders = { Vertex: null, Fragment: null, Geometry: null }; publicAPI.buildShaders(shaders, ren, actor); // compile and bind the program if needed var newShader = model.openGLRenderWindow.getShaderCache().readyShaderProgramArray(shaders.Vertex, shaders.Fragment, shaders.Geometry); // if the shader changed reinitialize the VAO if (newShader !== cellBO.getProgram()) { cellBO.setProgram(newShader); // reset the VAO as the shader has changed cellBO.getVAO().releaseGraphicsResources(); } cellBO.getShaderSourceTime().modified(); } else { model.openGLRenderWindow.getShaderCache().readyShaderProgram(cellBO.getProgram()); } cellBO.getVAO().bind(); publicAPI.setMapperShaderParameters(cellBO, ren, actor); publicAPI.setCameraShaderParameters(cellBO, ren, actor); publicAPI.setPropertyShaderParameters(cellBO, ren, actor); publicAPI.getClippingPlaneShaderParameters(cellBO, ren, actor); }; publicAPI.setMapperShaderParameters = function (cellBO, ren, actor) { // Now to update the VAO too, if necessary. var program = cellBO.getProgram(); if (cellBO.getCABO().getElementCount() && (model.VBOBuildTime.getMTime() > cellBO.getAttributeUpdateTime().getMTime() || cellBO.getShaderSourceTime().getMTime() > cellBO.getAttributeUpdateTime().getMTime())) { if (program.isAttributeUsed('vertexDC')) { if (!cellBO.getVAO().addAttributeArray(program, cellBO.getCABO(), 'vertexDC', cellBO.getCABO().getVertexOffset(), cellBO.getCABO().getStride(), model.context.FLOAT, 3, model.context.FALSE)) { vtkErrorMacro('Error setting vertexDC in shader VAO.'); } } cellBO.getAttributeUpdateTime().modified(); } program.setUniformi('texture1', model.scalarTexture.getTextureUnit()); program.setUniformf('sampleDistance', model.renderable.getSampleDistance()); // if we have a zbuffer texture then set it if (model.zBufferTexture !== null) { program.setUniformi('zBufferTexture', model.zBufferTexture.getTextureUnit()); var size = publicAPI.getRenderTargetSize(); program.setUniformf('vpWidth', size[0]); program.setUniformf('vpHeight', size[1]); } }; publicAPI.setCameraShaderParameters = function (cellBO, ren, actor) { // // [WMVP]C == {world, model, view, projection} coordinates // // E.g., WCPC == world to projection coordinate transformation var keyMats = model.openGLCamera.getKeyMatrices(ren); var actMats = model.openGLVolume.getKeyMatrices(); multiply(model.modelToView, keyMats.wcvc, actMats.mcwc); var program = cellBO.getProgram(); var cam = model.openGLCamera.getRenderable(); var crange = cam.getClippingRange(); program.setUniformf('camThick', crange[1] - crange[0]); program.setUniformf('camNear', crange[0]); program.setUniformf('camFar', crange[1]); var bounds = model.currentInput.getBounds(); var dims = model.currentInput.getDimensions(); // compute the viewport bounds of the volume // we will only render those fragments. var pos = new Float64Array(3); var dir = new Float64Array(3); var dcxmin = 1.0; var dcxmax = -1.0; var dcymin = 1.0; var dcymax = -1.0; for (var i = 0; i < 8; ++i) { set(pos, bounds[i % 2], bounds[2 + Math.floor(i / 2) % 2], bounds[4 + Math.floor(i / 4)]); transformMat4(pos, pos, model.modelToView); if (!cam.getParallelProjection()) { normalize(dir, pos); // now find the projection of this point onto a // nearZ distance plane. Since the camera is at 0,0,0 // in VC the ray is just t*pos and // t is -nearZ/dir.z // intersection becomes pos.x/pos.z var t = -crange[0] / pos[2]; scale(pos, dir, t); } // now convert to DC transformMat4(pos, pos, keyMats.vcpc); dcxmin = Math.min(pos[0], dcxmin); dcxmax = Math.max(pos[0], dcxmax); dcymin = Math.min(pos[1], dcymin); dcymax = Math.max(pos[1], dcymax); } program.setUniformf('dcxmin', dcxmin); program.setUniformf('dcxmax', dcxmax); program.setUniformf('dcymin', dcymin); program.setUniformf('dcymax', dcymax); if (program.isUniformUsed('cameraParallel')) { program.setUniformi('cameraParallel', cam.getParallelProjection()); } var ext = model.currentInput.getExtent(); var spc = model.currentInput.getSpacing(); var vsize = new Float64Array(3); set(vsize, (ext[1] - ext[0] + 1) * spc[0], (ext[3] - ext[2] + 1) * spc[1], (ext[5] - ext[4] + 1) * spc[2]); program.setUniform3f('vSpacing', spc[0], spc[1], spc[2]); set(pos, ext[0], ext[2], ext[4]); model.currentInput.indexToWorldVec3(pos, pos); transformMat4(pos, pos, model.modelToView); program.setUniform3f('vOriginVC', pos[0], pos[1], pos[2]); // apply the image directions var i2wmat4 = model.currentInput.getIndexToWorld(); multiply(model.idxToView, model.modelToView, i2wmat4); multiply$1(model.idxNormalMatrix, keyMats.normalMatrix, actMats.normalMatrix); multiply$1(model.idxNormalMatrix, model.idxNormalMatrix, model.currentInput.getDirection()); var maxSamples = length(vsize) / model.renderable.getSampleDistance(); if (maxSamples > model.renderable.getMaximumSamplesPerRay()) { vtkWarningMacro("The number of steps required ".concat(Math.ceil(maxSamples), " is larger than the\n specified maximum number of steps ").concat(model.renderable.getMaximumSamplesPerRay(), ".\n Please either change the\n volumeMapper sampleDistance or its maximum number of samples.")); } var vctoijk = new Float64Array(3); set(vctoijk, 1.0, 1.0, 1.0); divide(vctoijk, vctoijk, vsize); program.setUniform3f('vVCToIJK', vctoijk[0], vctoijk[1], vctoijk[2]); program.setUniform3i('volumeDimensions', dims[0], dims[1], dims[2]); if (!model.openGLRenderWindow.getWebgl2()) { var volInfo = model.scalarTexture.getVolumeInfo(); program.setUniformf('texWidth', model.scalarTexture.getWidth()); program.setUniformf('texHeight', model.scalarTexture.getHeight()); program.setUniformi('xreps', volInfo.xreps); program.setUniformi('xstride', volInfo.xstride); program.setUniformi('ystride', volInfo.ystride); } // map normals through normal matrix // then use a point on the plane to compute the distance var normal = new Float64Array(3); var pos2 = new Float64Array(3); for (var _i = 0; _i < 6; ++_i) { switch (_i) { default: case 0: set(normal, 1.0, 0.0, 0.0); set(pos2, ext[1], ext[3], ext[5]); break; case 1: set(normal, -1.0, 0.0, 0.0); set(pos2, ext[0], ext[2], ext[4]); break; case 2: set(normal, 0.0, 1.0, 0.0); set(pos2, ext[1], ext[3], ext[5]); break; case 3: set(normal, 0.0, -1.0, 0.0); set(pos2, ext[0], ext[2], ext[4]); break; case 4: set(normal, 0.0, 0.0, 1.0); set(pos2, ext[1], ext[3], ext[5]); break; case 5: set(normal, 0.0, 0.0, -1.0); set(pos2, ext[0], ext[2], ext[4]); break; } transformMat3(normal, normal, model.idxNormalMatrix); transformMat4(pos2, pos2, model.idxToView); var dist = -1.0 * dot(pos2, normal); // we have the plane in view coordinates // specify the planes in view coordinates program.setUniform3f("vPlaneNormal".concat(_i), normal[0], normal[1], normal[2]); program.setUniformf("vPlaneDistance".concat(_i), dist); if (actor.getProperty().getUseLabelOutline()) { var image = model.currentInput; var worldToIndex = image.getWorldToIndex(); program.setUniformMatrix('vWCtoIDX', worldToIndex); // Get the projection coordinate to world coordinate transformation matrix. invert(model.projectionToWorld, keyMats.wcpc); program.setUniformMatrix('PCWCMatrix', model.projectionToWorld); var size = publicAPI.getRenderTargetSize(); program.setUniformf('vpWidth', size[0]); program.setUniformf('vpHeight', size[1]); } } invert(model.projectionToView, keyMats.vcpc); program.setUniformMatrix('PCVCMatrix', model.projectionToView); // handle lighting values switch (model.lastLightComplexity) { default: case 0: // no lighting, tcolor is fine as is break; case 1: // headlight case 2: // light kit case 3: { // positional not implemented fallback to directional // mat3.transpose(keyMats.normalMatrix, keyMats.normalMatrix); var lightNum = 0; var lightColor = []; ren.getLights().forEach(function (light) { var status = light.getSwitch(); if (status > 0) { var dColor = light.getColor(); var intensity = light.getIntensity(); lightColor[0] = dColor[0] * intensity; lightColor[1] = dColor[1] * intensity; lightColor[2] = dColor[2] * intensity; program.setUniform3fArray("lightColor".concat(lightNum), lightColor); var ldir = light.getDirection(); set(normal, ldir[0], ldir[1], ldir[2]); transformMat3(normal, normal, keyMats.normalMatrix); program.setUniform3f("lightDirectionVC".concat(lightNum), normal[0], normal[1], normal[2]); // camera DOP is 0,0,-1.0 in VC var halfAngle = [-0.5 * normal[0], -0.5 * normal[1], -0.5 * (normal[2] - 1.0)]; program.setUniform3fArray("lightHalfAngleVC".concat(lightNum), halfAngle); lightNum++; } }); // mat3.transpose(keyMats.normalMatrix, keyMats.normalMatrix); } } }; publicAPI.setPropertyShaderParameters = function (cellBO, ren, actor) { var program = cellBO.getProgram(); program.setUniformi('ctexture', model.colorTexture.getTextureUnit()); program.setUniformi('otexture', model.opacityTexture.getTextureUnit()); program.setUniformi('jtexture', model.jitterTexture.getTextureUnit()); var volInfo = model.scalarTexture.getVolumeInfo(); var vprop = actor.getProperty(); // set the component mix when independent var numComp = model.scalarTexture.getComponents(); var iComps = actor.getProperty().getIndependentComponents(); if (iComps && numComp >= 2) { for (var i = 0; i < numComp; i++) { program.setUniformf("mix".concat(i), actor.getProperty().getComponentWeight(i)); } } // three levels of shift scale combined into one // for performance in the fragment shader for (var _i2 = 0; _i2 < numComp; _i2++) { var target = iComps ? _i2 : 0; var sscale = volInfo.scale[_i2]; var ofun = vprop.getScalarOpacity(target); var oRange = ofun.getRange(); var oscale = sscale / (oRange[1] - oRange[0]); var oshift = (volInfo.offset[_i2] - oRange[0]) / (oRange[1] - oRange[0]); program.setUniformf("oshift".concat(_i2), oshift); program.setUniformf("oscale".concat(_i2), oscale); var cfun = vprop.getRGBTransferFunction(target); var cRange = cfun.getRange(); program.setUniformf("cshift".concat(_i2), (volInfo.offset[_i2] - cRange[0]) / (cRange[1] - cRange[0])); program.setUniformf("cscale".concat(_i2), sscale / (cRange[1] - cRange[0])); } if (model.gopacity) { if (iComps) { for (var nc = 0; nc < numComp; ++nc) { var _sscale = volInfo.scale[nc]; var useGO = vprop.getUseGradientOpacity(nc); if (useGO) { var gomin = vprop.getGradientOpacityMinimumOpacity(nc); var gomax = vprop.getGradientOpacityMaximumOpacity(nc); program.setUniformf("gomin".concat(nc), gomin); program.setUniformf("gomax".concat(nc), gomax); var goRange = [vprop.getGradientOpacityMinimumValue(nc), vprop.getGradientOpacityMaximumValue(nc)]; program.setUniformf("goscale".concat(nc), _sscale * (gomax - gomin) / (goRange[1] - goRange[0])); program.setUniformf("goshift".concat(nc), -goRange[0] * (gomax - gomin) / (goRange[1] - goRange[0]) + gomin); } else { program.setUniformf("gomin".concat(nc), 1.0); program.setUniformf("gomax".concat(nc), 1.0); program.setUniformf("goscale".concat(nc), 0.0); program.setUniformf("goshift".concat(nc), 1.0); } } } else { var _sscale2 = volInfo.scale[numComp - 1]; var _gomin = vprop.getGradientOpacityMinimumOpacity(0); var _gomax = vprop.getGradientOpacityMaximumOpacity(0); program.setUniformf('gomin0', _gomin); program.setUniformf('gomax0', _gomax); var _goRange = [vprop.getGradientOpacityMinimumValue(0), vprop.getGradientOpacityMaximumValue(0)]; program.setUniformf('goscale0', _sscale2 * (_gomax - _gomin) / (_goRange[1] - _goRange[0])); program.setUniformf('goshift0', -_goRange[0] * (_gomax - _gomin) / (_goRange[1] - _goRange[0]) + _gomin); } } var vtkImageLabelOutline = actor.getProperty().getUseLabelOutline(); if (vtkImageLabelOutline === true) { var labelOutlineThickness = actor.getProperty().getLabelOutlineThickness(); program.setUniformi('outlineThickness', labelOutlineThickness); } if (model.lastLightComplexity > 0) { program.setUniformf('vAmbient', vprop.getAmbient()); program.setUniformf('vDiffuse', vprop.getDiffuse()); program.setUniformf('vSpecular', vprop.getSpecular()); program.setUniformf('vSpecularPower', vprop.getSpecularPower()); } }; publicAPI.getClippingPlaneShaderParameters = function (cellBO, ren, actor) { if (model.renderable.getClippingPlanes().length > 0) { var keyMats = model.openGLCamera.getKeyMatrices(ren); var clipPlaneNormals = []; var clipPlaneDistances = []; var clipPlanes = model.renderable.getClippingPlanes(); var clipPlaneSize = clipPlanes.length; for (var i = 0; i < clipPlaneSize; ++i) { var clipPlaneNormal = clipPlanes[i].getNormal(); var clipPlanePos = clipPlanes[i].getOrigin(); transformMat3(clipPlaneNormal, clipPlaneNormal, keyMats.normalMatrix); transformMat4(clipPlanePos, clipPlanePos, keyMats.wcvc); var clipPlaneDist = -1.0 * dot(clipPlanePos, clipPlaneNormal); clipPlaneNormals.push(clipPlaneNormal[0]); clipPlaneNormals.push(clipPlaneNormal[1]); clipPlaneNormals.push(clipPlaneNormal[2]); clipPlaneDistances.push(clipPlaneDist); } var program = cellBO.getProgram(); program.setUniform3fv("vClipPlaneNormals", clipPlaneNormals); program.setUniformfv("vClipPlaneDistances", clipPlaneDistances); } }; publicAPI.getRenderTargetSize = function () { if (model.lastXYF > 1.43) { var sz = model.framebuffer.getSize(); return [model.fvp[0] * sz[0], model.fvp[1] * sz[1]]; } return model.openGLRenderWindow.getFramebufferSize(); }; publicAPI.renderPieceStart = function (ren, actor) { if (model.renderable.getAutoAdjustSampleDistances()) { var rwi = ren.getVTKWindow().getInteractor(); var rft = rwi.getLastFrameTime(); // console.log(`last frame time ${Math.floor(1.0 / rft)}`); // frame time is typically for a couple frames prior // which makes it messy, so keep long running averages // of frame times and pixels rendered model.avgFrameTime = 0.97 * model.avgFrameTime + 0.03 * rft; model.avgWindowArea = 0.97 * model.avgWindowArea + 0.03 / (model.lastXYF * model.lastXYF); if (ren.getVTKWindow().getInteractor().isAnimating()) { // compute target xy factor var txyf = Math.sqrt(model.avgFrameTime * rwi.getDesiredUpdateRate() / model.avgWindowArea); // limit subsampling to a factor of 10 if (txyf > 10.0) { txyf = 10.0; } model.targetXYF = txyf; } else { model.targetXYF = Math.sqrt(model.avgFrameTime * rwi.getStillUpdateRate() / model.avgWindowArea); } // have some inertia to change states around 1.43 if (model.targetXYF < 1.53 && model.targetXYF > 1.33) { model.targetXYF = model.lastXYF; } // and add some inertia to change at all if (Math.abs(1.0 - model.targetXYF / model.lastXYF) < 0.1) { model.targetXYF = model.lastXYF; } model.lastXYF = model.targetXYF; } else { model.lastXYF = model.renderable.getImageSampleDistance(); } // only use FBO beyond this value if (model.lastXYF <= 1.43) { model.lastXYF = 1.0; } // console.log(`last target ${model.lastXYF} ${model.targetXYF}`); // console.log(`awin aft ${model.avgWindowArea} ${model.avgFrameTime}`); var xyf = model.lastXYF; var size = model.openGLRenderWindow.getFramebufferSize(); // const newSize = [ // Math.floor((size[0] / xyf) + 0.5), // Math.floor((size[1] / xyf) + 0.5)]; // const diag = vtkBoundingBox.getDiagonalLength(model.currentInput.getBounds()); // // so what is the resulting sample size roughly // console.log(`sam size ${diag / newSize[0]} ${diag / newSize[1]} ${model.renderable.getImageSampleDistance()}`); // // if the sample distance is getting far from the image sample dist // if (2.0 * diag / (newSize[0] + newSize[1]) > 4 * model.renderable.getSampleDistance()) { // model.renderable.setSampleDistance(4.0 * model.renderable.getSampleDistance()); // } // if (2.0 * diag / (newSize[0] + newSize[1]) < 0.25 * model.renderable.getSampleDistance()) { // model.renderable.setSampleDistance(0.25 * model.renderable.getSampleDistance()); // } // create/resize framebuffer if needed if (xyf > 1.43) { model.framebuffer.saveCurrentBindingsAndBuffers(); if (model.framebuffer.getGLFramebuffer() === null) { model.framebuffer.create(Math.floor(size[0] * 0.7), Math.floor(size[1] * 0.7)); model.framebuffer.populateFramebuffer(); } else { var fbSize = model.framebuffer.getSize(); if (fbSize[0] !== Math.floor(size[0] * 0.7) || fbSize[1] !== Math.floor(size[1] * 0.7)) { model.framebuffer.create(Math.floor(size[0] * 0.7), Math.floor(size[1] * 0.7)); model.framebuffer.populateFramebuffer(); } } model.framebuffer.bind(); var gl = model.context; gl.clearColor(0.0, 0.0, 0.0, 0.0); gl.colorMask(true, true, true, true); gl.clear(gl.COLOR_BUFFER_BIT); gl.viewport(0, 0, size[0] / xyf, size[1] / xyf); model.fvp = [Math.floor(size[0] / xyf) / Math.floor(size[0] * 0.7), Math.floor(size[1] / xyf) / Math.floor(size[1] * 0.7)]; } model.context.disable(model.context.DEPTH_TEST); // make sure the BOs are up to date publicAPI.updateBufferObjects(ren, actor); // set interpolation on the texture based on property setting var iType = actor.getProperty().getInterpolationType(); if (iType === InterpolationType.NEAREST) { model.scalarTexture.setMinificationFilter(Filter.NEAREST); model.scalarTexture.setMagnificationFilter(Filter.NEAREST); } else { model.scalarTexture.setMinificationFilter(Filter.LINEAR); model.scalarTexture.setMagnificationFilter(Filter.LINEAR); } // Bind the OpenGL, this is shared between the different primitive/cell types. model.lastBoundBO = null; // if we have a zbuffer texture then activate it if (model.zBufferTexture !== null) { model.zBufferTexture.activate(); } }; publicAPI.renderPieceDraw = function (ren, actor) { var gl = model.context; // render the texture model.scalarTexture.activate(); model.opacityTexture.activate(); model.colorTexture.activate(); model.jitterTexture.activate(); publicAPI.updateShaders(model.tris, ren, actor); // First we do the triangles, update the shader, set uniforms, etc. // for (let i = 0; i < 11; ++i) { // gl.drawArrays(gl.TRIANGLES, 66 * i, 66); // } gl.drawArrays(gl.TRIANGLES, 0, model.tris.getCABO().getElementCount()); model.tris.getVAO().release(); model.scalarTexture.deactivate(); model.colorTexture.deactivate(); model.opacityTexture.deactivate(); model.jitterTexture.deactivate(); }; publicAPI.renderPieceFinish = function (ren, actor) { // if we have a zbuffer texture then deactivate it if (model.zBufferTexture !== null) { model.zBufferTexture.deactivate(); } if (model.lastXYF > 1.43) { // now copy the framebuffer with the volume into the // regular buffer model.framebuffer.restorePreviousBindingsAndBuffers(); if (model.copyShader === null) { model.copyShader = model.openGLRenderWindow.getShaderCache().readyShaderProgramArray(['//VTK::System::Dec', 'attribute vec4 vertexDC;', 'uniform vec2 tfactor;', 'varying vec2 tcoord;', 'void main() { tcoord = vec2(vertexDC.x*0.5 + 0.5, vertexDC.y*0.5 + 0.5) * tfactor; gl_Position = vertexDC; }'].join('\n'), ['//VTK::System::Dec', '//VTK::Output::Dec', 'uniform sampler2D texture1;', 'varying vec2 tcoord;', 'void main() { gl_FragData[0] = texture2D(texture1,tcoord); }'].join('\n'), ''); var program = model.copyShader; model.copyVAO = vtkVertexArrayObject.newInstance(); model.copyVAO.setOpenGLRenderWindow(model.openGLRenderWindow); model.tris.getCABO().bind(); if (!model.copyVAO.addAttributeArray(program, model.tris.getCABO(), 'vertexDC', model.tris.getCABO().getVertexOffset(), model.tris.getCABO().getStride(), model.context.FLOAT, 3, model.context.FALSE)) { vtkErrorMacro('Error setting vertexDC in copy shader VAO.'); } } else { model.openGLRenderWindow.getShaderCache().readyShaderProgram(model.copyShader); } var size = model.openGLRenderWindow.getFramebufferSize(); model.context.viewport(0, 0, size[0], size[1]); // activate texture var tex = model.framebuffer.getColorTexture(); tex.activate(); model.copyShader.setUniformi('texture', tex.getTextureUnit()); model.copyShader.setUniform2f('tfactor', model.fvp[0], model.fvp[1]); var gl = model.context; gl.blendFuncSeparate(gl.ONE, gl.ONE_MINUS_SRC_ALPHA, gl.ONE, gl.ONE_MINUS_SRC_ALPHA); // render quad model.context.drawArrays(model.context.TRIANGLES, 0, model.tris.getCABO().getElementCount()); tex.deactivate(); gl.blendFuncSeparate(gl.SRC_ALPHA, gl.ONE_MINUS_SRC_ALPHA, gl.ONE, gl.ONE_MINUS_SRC_ALPHA); } }; publicAPI.renderPiece = function (ren, actor) { publicAPI.invokeEvent({ type: 'StartEvent' }); model.renderable.update(); model.currentInput = model.renderable.getInputData(); publicAPI.invokeEvent({ type: 'EndEvent' }); if (!model.currentInput) { vtkErrorMacro('No input!'); return; } publicAPI.renderPieceStart(ren, actor); publicAPI.renderPieceDraw(ren, actor); publicAPI.renderPieceFinish(ren, actor); }; publicAPI.computeBounds = function (ren, actor) { if (!publicAPI.getInput()) { uninitializeBounds(model.Bounds); return; } model.bounds = publicAPI.getInput().getBounds(); }; publicAPI.updateBufferObjects = function (ren, actor) { // Rebuild buffers if needed if (publicAPI.getNeedToRebuildBufferObjects(ren, actor)) { publicAPI.buildBufferObjects(ren, actor); } }; publicAPI.getNeedToRebuildBufferObjects = function (ren, actor) { // first do a coarse check if (model.VBOBuildTime.getMTime() < publicAPI.getMTime() || model.VBOBuildTime.getMTime() < actor.getMTime() || model.VBOBuildTime.getMTime() < model.renderable.getMTime() || model.VBOBuildTime.getMTime() < actor.getProperty().getMTime() || model.VBOBuildTime.getMTime() < model.currentInput.getMTime()) { return true; } return false; }; publicAPI.buildBufferObjects = function (ren, actor) { var image = model.currentInput; if (!image) { return; } var scalars = image.getPointData() && image.getPointData().getScalars(); if (!scalars) { return; } var vprop = actor.getProperty(); if (!model.jitterTexture.getHandle()) { var oTable = new Uint8Array(32 * 32); for (var i = 0; i < 32 * 32; ++i) { oTable[i] = 255.0 * Math.random(); } model.jitterTexture.setMinificationFilter(Filter.LINEAR); model.jitterTexture.setMagnificationFilter(Filter.LINEAR); model.jitterTexture.create2DFromRaw(32, 32, 1, VtkDataTypes.UNSIGNED_CHAR, oTable); } var numComp = scalars.getNumberOfComponents(); var iComps = vprop.getIndependentComponents(); var numIComps = iComps ? numComp : 1; // rebuild opacity tfun? var toString = "".concat(vprop.getMTime()); if (model.opacityTextureString !== toString) { var oWidth = 1024; var oSize = oWidth * 2 * numIComps; var ofTable = new Float32Array(oSize); var tmpTable = new Float32Array(oWidth); for (var c = 0; c < numIComps; ++c) { var ofun = vprop.getScalarOpacity(c); var opacityFactor = model.renderable.getSampleDistance() / vprop.getScalarOpacityUnitDistance(c); var oRange = ofun.getRange(); ofun.getTable(oRange[0], oRange[1], oWidth, tmpTable, 1); // adjust for sample distance etc for (var _i3 = 0; _i3 < oWidth; ++_i3) { ofTable[c * oWidth * 2 + _i3] = 1.0 - Math.pow(1.0 - tmpTable[_i3], opacityFactor); ofTable[c * oWidth * 2 + _i3 + oWidth] = ofTable[c * oWidth * 2 + _i3]; } } model.opacityTexture.releaseGraphicsResources(model.openGLRenderWindow); model.opacityTexture.setMinificationFilter(Filter.LINEAR); model.opacityTexture.setMagnificationFilter(Filter.LINEAR); // use float texture where possible because we really need the resolution // for this table. Errors in low values of opacity accumulate to // visible artifacts. High values of opacity quickly terminate without // artifacts. if (model.openGLRenderWindow.getWebgl2() || model.context.getExtension('OES_texture_float') && model.context.getExtension('OES_texture_float_linear')) { model.opacityTexture.create2DFromRaw(oWidth, 2 * numIComps, 1, VtkDataTypes.FLOAT, ofTable); } else { var _oTable = new Uint8Array(oSize); for (var _i4 = 0; _i4 < oSize; ++_i4) { _oTable[_i4] = 255.0 * ofTable[_i4]; } model.opacityTexture.create2DFromRaw(oWidth, 2 * numIComps, 1, VtkDataTypes.UNSIGNED_CHAR, _oTable); } model.opacityTextureString = toString; } // rebuild color tfun? toString = "".concat(vprop.getMTime()); if (model.colorTextureString !== toString) { var cWidth = 1024; var cSize = cWidth * 2 * numIComps * 3; var cTable = new Uint8Array(cSize); var _tmpTable = new Float32Array(cWidth * 3); for (var _c = 0; _c < numIComps; ++_c) { var cfun = vprop.getRGBTransferFunction(_c); var cRange = cfun.getRange(); cfun.getTable(cRange[0], cRange[1], cWidth, _tmpTable, 1); for (var _i5 = 0; _i5 < cWidth * 3; ++_i5) { cTable[_c * cWidth * 6 + _i5] = 255.0 * _tmpTable[_i5]; cTable[_c * cWidth * 6 + _i5 + cWidth * 3] = 255.0 * _tmpTable[_i5]; } } model.colorTexture.releaseGraphicsResources(model.openGLRenderWindow); model.colorTexture.setMinificationFilter(Filter.LINEAR); model.colorTexture.setMagnificationFilter(Filter.LINEAR); model.colorTexture.create2DFromRaw(cWidth, 2 * numIComps, 3, VtkDataTypes.UNSIGNED_CHAR, cTable); model.colorTextureString = toString; } // rebuild the scalarTexture if the data has changed toString = "".concat(image.getMTime()); if (model.scalarTextureString !== toString) { // Build the textures var dims = image.getDimensions(); model.scalarTexture.releaseGraphicsResources(model.openGLRenderWindow); model.scalarTexture.resetFormatAndType(); model.scalarTexture.create3DFilterableFromRaw(dims[0], dims[1], dims[2], numComp, scalars.getDataType(), scalars.getData()); // console.log(model.scalarTexture.get()); model.scalarTextureString = toString; } if (!model.tris.getCABO().getElementCount()) { // build the CABO var ptsArray = new Float32Array(12); for (var _i6 = 0; _i6 < 4; _i6++) { ptsArray[_i6 * 3] = _i6 % 2 * 2 - 1.0; ptsArray[_i6 * 3 + 1] = _i6 > 1 ? 1.0 : -1.0; ptsArray[_i6 * 3 + 2] = -1.0; } var cellArray = new Uint16Array(8); cellArray[0] = 3; cellArray[1] = 0; cellArray[2] = 1; cellArray[3] = 3; cellArray[4] = 3; cellArray[5] = 0; cellArray[6] = 3; cellArray[7] = 2; // const dim = 12.0; // const ptsArray = new Float32Array(3 * dim * dim); // for (let i = 0; i < dim; i++) { // for (let j = 0; j < dim; j++) { // const offset = ((i * dim) + j) * 3; // ptsArray[offset] = (2.0 * (i / (dim - 1.0))) - 1.0; // ptsArray[offset + 1] = (2.0 * (j / (dim - 1.0))) - 1.0; // ptsArray[offset + 2] = -1.0; // } // } // const cellArray = new Uint16Array(8 * (dim - 1) * (dim - 1)); // for (let i = 0; i < dim - 1; i++) { // for (let j = 0; j < dim - 1; j++) { // const offset = 8 * ((i * (dim - 1)) + j); // cellArray[offset] = 3; // cellArray[offset + 1] = (i * dim) + j; // cellArray[offset + 2] = (i * dim) + 1 + j; // cellArray[offset + 3] = ((i + 1) * dim) + 1 + j; // cellArray[offset + 4] = 3; // cellArray[offset + 5] = (i * dim) + j; // cellArray[offset + 6] = ((i + 1) * dim) + 1 + j; // cellArray[offset + 7] = ((i + 1) * dim) + j; // } // } var points = vtkDataArray.newInstance({ numberOfComponents: 3, values: ptsArray }); points.setName('points'); var cells = vtkDataArray.newInstance({ numberOfComponents: 1, values: cellArray }); model.tris.getCABO().createVBO(cells, 'polys', Representation.SURFACE, { points: points, cellOffset: 0 }); } model.VBOBuildTime.modified(); }; } // ---------------------------------------------------------------------------- // Object factory // ---------------------------------------------------------------------------- var DEFAULT_VALUES = { context: null, VBOBuildTime: null, scalarTexture: null, scalarTextureString: null, opacityTexture: null, opacityTextureString: null, colorTexture: null, colorTextureString: null, jitterTexture: null, tris: null, framebuffer: null, copyShader: null, copyVAO: null, lastXYF: 1.0, targetXYF: 1.0, zBufferTexture: null, lastZBufferTexture: null, lastLightComplexity: 0, fullViewportTime: 1.0, idxToView: null, idxNormalMatrix: null, modelToView: null, projectionToView: null, avgWindowArea: 0.0, avgFrameTime: 0.0 }; // ---------------------------------------------------------------------------- function extend(publicAPI, model) { var initialValues = arguments.length > 2 && arguments[2] !== undefined ? arguments[2] : {}; Object.assign(model, DEFAULT_VALUES, initialValues); // Inheritance vtkViewNode.extend(publicAPI, model, initialValues); model.VBOBuildTime = {}; obj(model.VBOBuildTime, { mtime: 0 }); model.tris = vtkHelper.newInstance(); model.scalarTexture = vtkOpenGLTexture.newInstance(); model.opacityTexture = vtkOpenGLTexture.newInstance(); model.colorTexture = vtkOpenGLTexture.newInstance(); model.jitterTexture = vtkOpenGLTexture.newInstance(); model.jitterTexture.setWrapS(Wrap.REPEAT); model.jitterTexture.setWrapT(Wrap.REPEAT); model.framebuffer = vtkOpenGLFramebuffer.newInstance(); model.idxToView = identity(new Float64Array(16)); model.idxNormalMatrix = identity$1(new Float64Array(9)); model.modelToView = identity(new Float64Array(16)); model.projectionToView = identity(new Float64Array(16)); model.projectionToWorld = identity(new Float64Array(16)); // Build VTK API setGet(publicAPI, model, ['context']); // Object methods vtkOpenGLVolumeMapper(publicAPI, model); } // ---------------------------------------------------------------------------- var newInstance = newInstance$1(extend, 'vtkOpenGLVolumeMapper'); // ---------------------------------------------------------------------------- var vtkVolumeMapper = { newInstance: newInstance, extend: extend }; // Register ourself to OpenGL backend if imported registerOverride('vtkVolumeMapper', newInstance); export default vtkVolumeMapper; export { extend, newInstance };