C++ API Reference
gpuCache/gpuCacheMaterialBakers.cpp
//-
//**************************************************************************/
// Copyright 2015 Autodesk, Inc. All rights reserved.
//
// Use of this software is subject to the terms of the Autodesk
// license agreement provided at the time of installation or download,
// or which otherwise accompanies this software in either electronic
// or hard copy form.
//**************************************************************************/
//+
#include "gpuCacheMaterialBakers.h"
#include "gpuCacheMaterialNodes.h"
#include "gpuCacheShapeNode.h"
#include "gpuCacheUtil.h"
#include <set>
#include <functional>
#include <maya/MFnDagNode.h>
#include <maya/MFnNumericData.h>
#include <maya/MPlugArray.h>
namespace GPUCache {
// Bakers for concrete materials.
//
namespace MaterialBakers {
// This class is the base class for all shading node bakers.
class BaseMaterialNodeBaker
{
public:
typedef std::shared_ptr<BaseMaterialNodeBaker> Ptr;
// Create a material baker for the given DG node.
static BaseMaterialNodeBaker::Ptr create(
const MObject& node,
std::set<std::string>* traversedNodes);
BaseMaterialNodeBaker(const MObject& node)
: fNode(node), fTraversedNodes(NULL)
{}
virtual ~BaseMaterialNodeBaker()
{}
BaseMaterialNodeBaker(const BaseMaterialNodeBaker&) = delete;
BaseMaterialNodeBaker& operator=(const BaseMaterialNodeBaker&) = delete;
// Create the baked material node and collect the
// properties and plugs for sampling.
void setupNetwork()
{
// There are virtual function calls so we can't do this in c'tor.
fBakedNode = createNode(fNode.name());
assert(fBakedNode);
collectPlugsAndProperties();
}
// Sample the shading node at the given time.
void sample(const MTime& time)
{
assert(fBakedNode);
// Loop over all channels.
for(Channel& channel : fChannels) {
// Sample the plug and add the sample to the property
switch (channel.prop()->type()) {
case MaterialProperty::kBool:
sampleBoolPlug(time, channel.plug(), channel.prop());
break;
case MaterialProperty::kInt32:
sampleInt32Plug(time, channel.plug(), channel.prop());
break;
case MaterialProperty::kFloat:
sampleFloatPlug(time, channel.plug(), channel.prop());
break;
case MaterialProperty::kFloat2:
sampleFloat2Plug(time, channel.plug(), channel.prop());
break;
case MaterialProperty::kFloat3:
sampleFloat3Plug(time, channel.plug(), channel.prop());
break;
case MaterialProperty::kRGB:
sampleFloat3PlugAsColor(time, channel.plug(), channel.prop());
break;
case MaterialProperty::kString:
sampleStringPlug(time, channel.plug(), channel.prop());
break;
default:
assert(0); // the data type is not implemented!
break;
}
// Recursively sample source nodes.
BaseMaterialNodeBaker::Ptr& srcBaker = channel.srcBaker();
if (srcBaker) {
srcBaker->sample(time);
}
}
}
// Add the shading node to the graph.
// The graph will have the ownership of all the shading nodes.
void addToGraph(MaterialGraph::MPtr& graph)
{
assert(fBakedNode); // created by derived classes
if (fBakedNode) {
graph->addNode(fBakedNode);
}
// Recursively add the connected shading nodes
for(Channel& channel : fChannels) {
BaseMaterialNodeBaker::Ptr& srcBaker = channel.srcBaker();
if (srcBaker) {
srcBaker->addToGraph(graph);
}
}
}
// Connect the shading nodes.
void connect()
{
// Loop over all the channels and connect to its source node.
for(Channel& channel : fChannels) {
MaterialProperty::MPtr dstProp = channel.prop();
BaseMaterialNodeBaker::Ptr srcBaker = channel.srcBaker();
MaterialProperty::MPtr srcProp = channel.srcProp();
// Connect to srcNode.srcProp
if (dstProp && srcBaker && srcProp) {
MaterialNode::Ptr srcNode = srcBaker->bakedNode();
if (srcNode) {
dstProp->connect(srcNode, srcProp);
}
}
}
}
// Return the baked material node.
MaterialNode::MPtr bakedNode()
{ assert(fBakedNode); return fBakedNode; }
protected:
// Override by derived classes.
virtual MaterialNode::MPtr createNode(const MString& name) = 0;
virtual void collectPlugsAndProperties() = 0;
// Sample a Maya bool plug
void sampleBoolPlug(const MTime& time, const MPlug& plug, MaterialProperty::MPtr& prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
bool value = plug.asBool();
if (prop->isDefault() || prop->asBool(timeInSeconds) != value) {
prop->setBool(timeInSeconds, value);
}
}
// Sample a Maya int plug
void sampleInt32Plug(const MTime& time, const MPlug& plug, MaterialProperty::MPtr& prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
int value = plug.asInt();
if (prop->isDefault() || prop->asInt32(timeInSeconds) != value) {
prop->setInt32(timeInSeconds, value);
}
}
// Sample a Maya float plug
void sampleFloatPlug(const MTime& time, const MPlug& plug, MaterialProperty::MPtr& prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
float value = plug.asFloat();
if (prop->isDefault() || prop->asFloat(timeInSeconds) != value) {
prop->setFloat(timeInSeconds, value);
}
}
// Sample a Maya (float,float) plug
void sampleFloat2Plug(const MTime& time, const MPlug& plug, MaterialProperty::MPtr& prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
MObject data = plug.asMObject();
assert(data.hasFn(MFn::kNumericData));
float value[2], prev[2];
MFnNumericData(data).getData2Float(value[0], value[1]);
prop->asFloat2(timeInSeconds, prev[0], prev[1]);
if (prop->isDefault() || value[0] != prev[0] || value[1] != prev[1]) {
prop->setFloat2(timeInSeconds, value[0], value[1]);
}
}
// Sample a Maya (float,float,float) plug
void sampleFloat3Plug(const MTime& time, const MPlug& plug, MaterialProperty::MPtr& prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
MObject data = plug.asMObject();
assert(data.hasFn(MFn::kNumericData));
float value[3], prev[3];
MFnNumericData(data).getData3Float(value[0], value[1], value[2]);
prop->asFloat3(timeInSeconds, prev[0], prev[1], prev[2]);
if (prop->isDefault() || value[0] != prev[0] || value[1] != prev[1] || value[2] != prev[2]) {
prop->setFloat3(timeInSeconds, value[0], value[1], value[2]);
}
}
// Sample a Maya (float,float,float) plug as MColor
void sampleFloat3PlugAsColor(const MTime& time, const MPlug& plug, MaterialProperty::MPtr prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
MObject data = plug.asMObject();
assert(data.hasFn(MFn::kNumericData));
MColor value;
MFnNumericData(data).getData3Float(value.r, value.g, value.b);
if (prop->isDefault() || value != prop->asColor(timeInSeconds)) {
prop->setColor(timeInSeconds, value);
}
}
// Sample a Maya MString plug
void sampleStringPlug(const MTime& time, const MPlug& plug, MaterialProperty::MPtr& prop)
{
double timeInSeconds = time.as(MTime::kSeconds);
MString value = plug.asString();
if (prop->isDefault() || value != prop->asString(timeInSeconds)) {
prop->setString(timeInSeconds, value);
}
}
// Register the plug and its source plugs for sampling.
void sampleChannel(const MString& name, MaterialProperty::MPtr& prop)
{
// Find the plug by its name
MPlug plug = fNode.findPlug(name, false);
assert(!plug.isNull());
assert(prop);
if (!plug.isNull() && prop) {
// Track the connection to the source node.
BaseMaterialNodeBaker::Ptr srcBaker;
MaterialProperty::MPtr srcProp;
if (plug.isDestination()) {
// Find the source node.
MPlugArray plugArray;
plug.connectedTo(plugArray, true, false);
assert(plugArray.length() == 1);
if (plugArray.length() > 0) {
MPlug srcPlug = plugArray[0];
assert(!srcPlug.isNull());
MObject srcNode = srcPlug.node();
assert(!srcNode.isNull());
// If there is a circular connection, we stop tracking the
// connection to the source node. Instead, we sample the
// plug value directly.
if (!isTraversed(srcNode)) {
// Create the baker for the source node.
srcBaker = BaseMaterialNodeBaker::create(srcNode, fTraversedNodes);
if (srcBaker) {
// We recognize the node. Find the source property.
for(Channel& channel : srcBaker->fChannels) {
if (channel.plug() == srcPlug) {
srcProp = channel.prop();
break;
}
}
// Can't find a source property.. give up.
if (!srcProp) {
srcBaker.reset();
}
}
}
}
}
// Add this channel to the list (with optional source baker)
fChannels.push_back(Channel(plug, prop, srcBaker, srcProp));
}
}
// Set the traversed nodes to prevent infinite recursive.
void setTraversedNodes(std::set<std::string>* traversedNodes)
{
fTraversedNodes = traversedNodes;
}
// Query if the node has been traversed.
bool isTraversed(const MObject& node)
{
std::string name = MFnDependencyNode(node).name().asChar();
assert(!name.empty());
if (fTraversedNodes && (*fTraversedNodes).find(name) != (*fTraversedNodes).end()) {
return true;
}
return false;
}
// Set the traversed state of the node.
void setTraversed(const MObject& node)
{
std::string name = MFnDependencyNode(node).name().asChar();
assert(!name.empty());
if (fTraversedNodes) {
(*fTraversedNodes).insert(name);
}
}
private:
class Channel
{
public:
Channel(const MPlug& plug,
MaterialProperty::MPtr& prop,
BaseMaterialNodeBaker::Ptr& srcBaker,
MaterialProperty::MPtr& srcProp)
: fPlug(plug),
fProp(prop),
fSrcBaker(srcBaker),
fSrcProp(srcProp)
{}
~Channel() {}
const MPlug& plug() { return fPlug; }
MaterialProperty::MPtr& prop() { return fProp; }
BaseMaterialNodeBaker::Ptr& srcBaker() { return fSrcBaker; }
MaterialProperty::MPtr& srcProp() { return fSrcProp; }
private:
MPlug fPlug;
MaterialProperty::MPtr fProp;
BaseMaterialNodeBaker::Ptr fSrcBaker;
MaterialProperty::MPtr fSrcProp;
};
std::vector<Channel> fChannels;
private:
MFnDependencyNode fNode;
MaterialNode::MPtr fBakedNode;
std::set<std::string>* fTraversedNodes;
};
class SurfaceMaterialBaker : public BaseMaterialNodeBaker
{
public:
SurfaceMaterialBaker(const MObject& node)
: BaseMaterialNodeBaker(node) {}
MaterialNode::MPtr createNode(const MString& name) override
{
return std::make_shared<SurfaceMaterial>(name);
}
void collectPlugsAndProperties() override
{
std::shared_ptr<SurfaceMaterial> surfaceMaterial =
std::dynamic_pointer_cast<SurfaceMaterial>(bakedNode());
sampleChannel("outColor", surfaceMaterial->OutColor);
sampleChannel("outTransparency", surfaceMaterial->OutTransparency);
}
};
class LambertBaker : public SurfaceMaterialBaker
{
public:
LambertBaker(const MObject& node)
: SurfaceMaterialBaker(node) {}
MaterialNode::MPtr createNode(const MString& name) override
{
return std::make_shared<LambertMaterial>(name);
}
void collectPlugsAndProperties() override
{
SurfaceMaterialBaker::collectPlugsAndProperties();
std::shared_ptr<LambertMaterial> lambert =
std::dynamic_pointer_cast<LambertMaterial>(bakedNode());
sampleChannel("color", lambert->Color);
sampleChannel("transparency", lambert->Transparency);
sampleChannel("ambientColor", lambert->AmbientColor);
sampleChannel("incandescence", lambert->Incandescence);
sampleChannel("diffuse", lambert->Diffuse);
sampleChannel("translucence", lambert->Translucence);
sampleChannel("translucenceDepth", lambert->TranslucenceDepth);
sampleChannel("translucenceFocus", lambert->TranslucenceFocus);
sampleChannel("hideSource", lambert->HideSource);
sampleChannel("glowIntensity", lambert->GlowIntensity);
}
};
class PhongBaker : public LambertBaker
{
public:
PhongBaker(const MObject& node)
: LambertBaker(node) {}
MaterialNode::MPtr createNode(const MString& name) override
{
return std::make_shared<PhongMaterial>(name);
}
void collectPlugsAndProperties() override
{
LambertBaker::collectPlugsAndProperties();
std::shared_ptr<PhongMaterial> phong =
std::dynamic_pointer_cast<PhongMaterial>(bakedNode());
sampleChannel("cosinePower", phong->CosinePower);
sampleChannel("specularColor", phong->SpecularColor);
sampleChannel("reflectivity", phong->Reflectivity);
sampleChannel("reflectedColor", phong->ReflectedColor);
}
};
class BlinnBaker : public LambertBaker
{
public:
BlinnBaker(const MObject& node)
: LambertBaker(node) {}
MaterialNode::MPtr createNode(const MString& name) override
{
return std::make_shared<BlinnMaterial>(name);
}
void collectPlugsAndProperties() override
{
LambertBaker::collectPlugsAndProperties();
std::shared_ptr<BlinnMaterial> phong =
std::dynamic_pointer_cast<BlinnMaterial>(bakedNode());
sampleChannel("eccentricity", phong->Eccentricity);
sampleChannel("specularRollOff",phong->SpecularRollOff);
sampleChannel("specularColor", phong->SpecularColor);
sampleChannel("reflectivity", phong->Reflectivity);
sampleChannel("reflectedColor", phong->ReflectedColor);
}
};
class Texture2dBaker : public BaseMaterialNodeBaker
{
public:
Texture2dBaker(const MObject& node)
: BaseMaterialNodeBaker(node) {}
MaterialNode::MPtr createNode(const MString& name) override = 0;
void collectPlugsAndProperties() override
{
std::shared_ptr<Texture2d> texture2d =
std::dynamic_pointer_cast<Texture2d>(bakedNode());
sampleChannel("defaultColor", texture2d->DefaultColor);
sampleChannel("outColor", texture2d->OutColor);
sampleChannel("outAlpha", texture2d->OutAlpha);
}
};
class FileTextureBaker : public Texture2dBaker
{
public:
FileTextureBaker(const MObject& node)
: Texture2dBaker(node)
{
}
MaterialNode::MPtr createNode(const MString& name) override
{
return std::make_shared<FileTexture>(name);
}
void collectPlugsAndProperties() override
{
Texture2dBaker::collectPlugsAndProperties();
std::shared_ptr<FileTexture> file =
std::dynamic_pointer_cast<FileTexture>(bakedNode());
sampleChannel("outTransparency", file->OutTransparency);
sampleChannel("fileTextureName", file->FileTextureName);
}
};
class UnknownTexture2dBaker : public Texture2dBaker
{
public:
UnknownTexture2dBaker(const MObject& node)
: Texture2dBaker(node) {}
MaterialNode::MPtr createNode(const MString& name) override
{
return std::make_shared<UnknownTexture2d>(name);
}
void collectPlugsAndProperties() override
{
Texture2dBaker::collectPlugsAndProperties();
}
};
BaseMaterialNodeBaker::Ptr BaseMaterialNodeBaker::create(
const MObject& node,
std::set<std::string>* traversedNodes)
{
BaseMaterialNodeBaker::Ptr baker;
if (node.hasFn(MFn::kPhong)) {
baker = std::make_shared<PhongBaker>(std::ref(node));
}
else if (node.hasFn(MFn::kBlinn)) {
baker = std::make_shared<BlinnBaker>(std::ref(node));
}
else if (node.hasFn(MFn::kLambert)) {
baker = std::make_shared<LambertBaker>(std::ref(node));
}
else if (node.hasFn(MFn::kFileTexture)) {
baker = std::make_shared<FileTextureBaker>(std::ref(node));
}
else if (node.hasFn(MFn::kTexture2d)) {
baker = std::make_shared<UnknownTexture2dBaker>(std::ref(node));
}
// Recursively create connected bakers.
if (baker) {
baker->setTraversedNodes(traversedNodes);
baker->setTraversed(node);
baker->setupNetwork();
}
return baker;
}
}
using namespace MaterialBakers;
/*==============================================================================
* CLASS MaterialBaker
*============================================================================*/
// This class bakes a material graph that has a surface material as its root.
class MaterialBaker::MaterialGraphBaker
{
public:
MaterialGraphBaker(const MObject& node)
{
fRootBaker = BaseMaterialNodeBaker::create(node, &fTraversedNodes);
}
~MaterialGraphBaker() {}
MaterialGraphBaker(const MaterialGraphBaker&) = delete;
MaterialGraphBaker& operator=(const MaterialGraphBaker&) = delete;
void sample(const MTime& time)
{
if (fRootBaker) {
fRootBaker->sample(time);
}
}
void buildGraph()
{
if (fRootBaker) {
MaterialNode::Ptr rootNode = fRootBaker->bakedNode();
if (rootNode) {
// Create the material graph.
MaterialGraph::MPtr graph = std::make_shared<MaterialGraph>(rootNode->name());
// Add all shading nodes to the graph
fRootBaker->addToGraph(graph);
// Connect the shading nodes
fRootBaker->connect();
// Set the root node of the graph
graph->setRootNode(rootNode);
fGraph = graph;
}
// We are done with the bakers
fRootBaker.reset();
}
}
MaterialGraph::Ptr get() const
{
return fGraph;
}
private:
BaseMaterialNodeBaker::Ptr fRootBaker;
MaterialGraph::MPtr fGraph;
std::set<std::string> fTraversedNodes;
};
MaterialBaker::MaterialBaker()
{}
MaterialBaker::~MaterialBaker()
{}
MStatus MaterialBaker::addShapePath(const MDagPath& dagPath)
{
// Must be a shape.
if (!dagPath.node().hasFn(MFn::kShape)) {
return MS::kFailure;
}
// Check if we are recursively baking gpuCache nodes
MFnDagNode dagNode(dagPath);
if (dagNode.typeId() == ShapeNode::id) {
const ShapeNode* node = (const ShapeNode*)dagNode.userNode();
if (node) {
const MaterialGraphMap::Ptr materials = node->getCachedMaterial();
if (materials) {
// Grab the existing materials.
const MaterialGraphMap::NamedMap& graphs = materials->getGraphs();
if (!graphs.empty()) {
fExistingGraphs.insert(graphs.cbegin(), graphs.cend());
}
}
}
return MS::kSuccess;
}
// Find all connected materials.
InstanceMaterialLookup lookup(dagPath);
if (lookup.hasWholeObjectMaterial()) {
// Single material applied to the whole object.
MObject surfaceMaterial = lookup.findWholeObjectSurfaceMaterial();
// No material, silently ignored.
if (surfaceMaterial.isNull()) {
return MS::kSuccess;
}
// Get the name of the surface material
MFnDependencyNode dgNode(surfaceMaterial);
MString name = dgNode.name();
// Create a new material baker
MaterialGraphBakers::iterator iter = fMaterialGraphBakers.find(name);
if (iter == fMaterialGraphBakers.end()) {
MaterialGraphBakerPtr baker =
std::make_shared<MaterialGraphBaker>(surfaceMaterial);
fMaterialGraphBakers.insert(std::make_pair(name, baker));
}
}
else if (lookup.hasComponentMaterials()) {
// Multiple materials applied to components.
std::vector<MObject> surfaceMaterials;
lookup.findSurfaceMaterials(surfaceMaterials);
for(const MObject& surfaceMaterial : surfaceMaterials) {
if (surfaceMaterial.isNull()) continue;
// Get the name of the surface material
MFnDependencyNode dgNode(surfaceMaterial);
MString name = dgNode.name();
// Create a new material baker
MaterialGraphBakers::iterator iter = fMaterialGraphBakers.find(name);
if (iter == fMaterialGraphBakers.end()) {
MaterialGraphBakerPtr baker =
std::make_shared<MaterialGraphBaker>(surfaceMaterial);
fMaterialGraphBakers.insert(std::make_pair(name, baker));
}
}
}
return MS::kSuccess;
}
MStatus MaterialBaker::sample(const MTime& time)
{
for(MaterialGraphBakers::value_type& val : fMaterialGraphBakers) {
val.second->sample(time);
}
return MS::kSuccess;
}
MStatus MaterialBaker::buildGraph()
{
for(MaterialGraphBakers::value_type& val : fMaterialGraphBakers) {
val.second->buildGraph();
}
return MS::kSuccess;
}
MaterialGraphMap::Ptr MaterialBaker::get()
{
MaterialGraphMap::MPtr graphMap = std::make_shared<MaterialGraphMap>();
// Add baked materials.
for(const MaterialGraphBakers::value_type& val : fMaterialGraphBakers) {
MaterialGraph::Ptr graph = val.second->get();
if (graph) {
graphMap->addMaterialGraph(graph);
}
}
// Add existing materials
for(const NamedMaterialGraphs::value_type& val : fExistingGraphs) {
if (val.second && !graphMap->find(val.first)) {
graphMap->addMaterialGraph(val.second);
}
}
return !graphMap->getGraphs().empty() ? graphMap : MaterialGraphMap::Ptr();
}
} // namespace GPUCache