particleAttrNode/particleAttrNode.cpp

particleAttrNode/particleAttrNode.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.
// ==========================================================================
//+
// DESCRIPTION:
//
// This plug-in produces the dependency node "particleAttr".
//
// The "particleAttrNode" is an example node that extends the "MPxParticleAttributeMapperNode" type.
// These nodes allow us to define custom nodes to map per-particle attribute data to a particle shape.
//
// In this particular example, we have defined two operations:
//
// - compute2DTexture()
// - computeMesh()
//
// The compute2DTexture() replicates the behavior of the internal 'arrayMapper' node in Maya at the API level.
// Given an input texture node and a U/V coordinate per particle input, this node will evaluate the texture
// at the given coordinates and map the result back to the "outColorPP" or "outValuePP" attributes.
// See the method description for compute2DTexture() to know how to setup a proper attribute mapping graph.
//
// The computeMesh() is a user-defined operation. It is called when the 'computeNode' attribute is connected
// to a polygonal mesh. Given a particle count, it then maps the object space vertex positions of the mesh
// to a user-defined 'outPositions' vector attribute. This 'outPositions' attribute can then be connected to
// drive one of the vector typed, per-particle attribute in the shape. In the given example, the particle shape's
// 'rampPosition' attribute is being driven. For further details, see the computeMesh() method description
// for information on how to setup this example.
//
#include "particleAttrNode.h"
#include <maya/MStatus.h>
#include <maya/MObject.h>
#include <maya/MDataBlock.h>
#include <maya/MDataHandle.h>
#include <maya/MPlug.h>
#include <maya/MVector.h>
#include <maya/MDoubleArray.h>
#include <maya/MVectorArray.h>
#include <maya/MPlugArray.h>
#include <maya/MPointArray.h>
#include <maya/MFnDoubleArrayData.h>
#include <maya/MFnVectorArrayData.h>
#include <maya/MFnMesh.h>
#include <maya/MFnTypedAttribute.h>
#include <maya/MFnNumericAttribute.h>
#include <maya/MDynamicsUtil.h>
MTypeId particleAttrNode::id = 0x81036;
MObject particleAttrNode::outPositionPP;
MObject particleAttrNode::particleCount;
particleAttrNode::particleAttrNode()
{}
particleAttrNode::~particleAttrNode()
{}
void* particleAttrNode::creator()
{
return new particleAttrNode();
}
MStatus particleAttrNode::initialize()
{
MStatus status = MS::kSuccess;
// In addition to the standard arrayMapper attributes,
// create an additional vector attribute.
//
MFnTypedAttribute typedAttrFn;
MVectorArray defaultVectArray;
MFnVectorArrayData vectArrayDataFn;
vectArrayDataFn.create( defaultVectArray );
typedAttrFn.create( "outPosition",
"opos",
vectArrayDataFn.object(),
&status );
// Transient output attribute. Not writable nor storable.
//
typedAttrFn.setWritable(false);
typedAttrFn.setStorable(false);
outPositionPP = typedAttrFn.object();
addAttribute( outPositionPP );
numAttrFn.create( "particleCount", "pc", MFnNumericData::kInt );
particleCount = numAttrFn.object();
addAttribute( particleCount );
attributeAffects( computeNode, outPositionPP );
attributeAffects( particleCount, outPositionPP );
return status;
}
MStatus particleAttrNode::compute( const MPlug& plug, MDataBlock& block )
{
MStatus status = MS::kUnknownParameter;
if( (plug.attribute() == outColorPP) || (plug.attribute() == outValuePP) )
{
status = compute2DTexture( plug, block );
}
else if( plug.attribute() == outPositionPP )
{
status = computeMesh( plug, block );
}
return status;
}
MStatus particleAttrNode::compute2DTexture( const MPlug& plug, MDataBlock& block )
//
// Description:
//
// This computes an outputValue/Color based on input U and V coordinates.
// The code contained herein replicates the compute code of the internal Maya
// 'arrayMapper' node.
//
// How to use:
//
// 1) Create a ramp
// 2) Create a particleAttr node
// 3) Create an emitter with a particleShape
// 4) Create a per particle color attribute (rgbPP) on the particleShape via the AE.
// 5) connectAttr ramp1.outColor particleAttr1.computeNode
// 6) connectAttr particleShape1.age particleAttr1.vCoordPP
// 7) connectAttr particleAttr1.outColorPP particleShape1.rgbPP
//
{
MStatus status = MS::kSuccess;
//
// We request the computeNodeColor attributes here to make sure that
// they get marked clean as the arrayMapper's output attribute(s) get
// computed.
//
/* MDataHandle hComputeNodeColor = */ block.inputValue( computeNodeColor );
/* MDataHandle hComputeNodeColorR = */ block.inputValue( computeNodeColorR );
/* MDataHandle hComputeNodeColorG = */ block.inputValue( computeNodeColorG );
/* MDataHandle hComputeNodeColorB = */ block.inputValue( computeNodeColorB );
bool doUcoord = false;
bool doVcoord = false;
bool doOutColor = ( plug.attribute() == outColorPP );
bool doOutValue = ( plug.attribute() == outValuePP );
// Get pointers to the source attributes: aUCoordPP, aVCoordPP.
//
MFnDoubleArrayData dataDoubleArrayFn;
MObject uCoordD = block.inputValue( uCoordPP ).data();
status = dataDoubleArrayFn.setObject( uCoordD );
if( status == MS::kSuccess )
{
uAry = dataDoubleArrayFn.array();
if (uAry.length())
{
doUcoord = true;
}
}
status = MS::kSuccess;
MObject vCoordD = block.inputValue( vCoordPP ).data();
status = dataDoubleArrayFn.setObject( vCoordD );
if( status == MS::kSuccess )
{
vAry = dataDoubleArrayFn.array();
if (vAry.length())
{
doVcoord = true;
}
}
// Get pointers to destination attributes: outColorPP, outValuePP.
//
status = MS::kSuccess;
MFnVectorArrayData dataVectorArrayFn;
MVectorArray outColorAry;
if( doOutColor )
{
MObject colorD = block.outputValue( outColorPP ).data();
status = dataVectorArrayFn.setObject( colorD );
if( status == MS::kSuccess )
{
outColorAry = dataVectorArrayFn.array();
}
}
status = MS::kSuccess;
MDoubleArray outValueAry;
if( doOutValue )
{
MObject valueD = block.outputValue( outValuePP ).data();
status = dataDoubleArrayFn.setObject( valueD );
if( status == MS::kSuccess )
{
outValueAry = dataDoubleArrayFn.array();
}
}
// Setup loop counter.
//
unsigned int uCount = ( doUcoord ? uAry.length() : 0 );
unsigned int vCount = ( doVcoord ? vAry.length() : 0 );
unsigned int count = ( (uCount) > (vCount) ? (uCount) : (vCount) );
// Resize the output arrays to match the max size
// of the input arrays.
//
if( doOutColor ) outColorAry.setLength( count );
if( doOutValue ) outValueAry.setLength( count );
// Check for a texture node
//
bool hasTextureNode =
computeNode );
// Call the texture node to compute color values for
// the input u,v coordinate arrays.
//
if( hasTextureNode )
{
computeNode,
uAry,
vAry,
&outColorAry,
&outValueAry );
// Scale the output value and/or color to the min/max range.
//
const double& minValue = block.inputValue( outMinValue ).asDouble();
const double& maxValue = block.inputValue( outMaxValue ).asDouble();
if( (minValue != 0.0) || (maxValue != 1.0) )
{
double r = maxValue - minValue;
if( doOutValue )
{
for( unsigned int i = 0; i < count; i++ )
{
outValueAry[i] = (r * outValueAry[i]) + minValue;
}
}
if( doOutColor )
{
MVector minVector( minValue, minValue, minValue );
for( unsigned int i = 0; i < count; i++ )
{
outColorAry[i] = (r * outColorAry[i]) + minVector;
}
}
}
}
else
{
// Not connected to texture node, so simply set output
// arrays to default values.
//
for( unsigned int i = 0; i < count; i++ )
{
MVector clr( 0.0, 0.0, 0.0 );
if( doOutColor )
{
outColorAry[i] = clr;
}
if( doOutValue )
{
outValueAry[i] = clr.x;
}
}
}
dataVectorArrayFn.set( outColorAry );
dataDoubleArrayFn.set( outValueAry );
return MS::kSuccess;
}
MStatus particleAttrNode::computeMesh( const MPlug& plug, MDataBlock& block )
//
// Description:
//
// To illustrate a custom use of the arrayMapper node, we'll define this
// alternative compute that will map particles to mesh vertex positions. If
// array lengths do not match, we'll wrap around the arrays.
//
// How to use:
//
// 1) Create a poly surface.
// 2) connectAttr polyShape1.outMesh particleAttr1.computeNode
// 3) connectAttr particleShape1.count particleAttr1.particleCount
// 4) connectAttr particleAttr1.outPosition particleShape1.rampPosition (*)
//
// * You may choose to drive any vector based per particle attribute.
// rampPosition was selected here as an example.
//
{
MStatus status = MS::kSuccess;
// Verify that computeNode has a mesh connected to computeNode
//
MPlug compPlug( thisMObject(), computeNode );
MPlugArray conns;
compPlug.connectedTo( conns, true, false, &status );
if( conns.length() <= 0 )
{
return MS::kFailure;
}
MPlug conn = conns[0];
MObject compNode = conn.node();
MFnMesh meshFn( compNode, &status );
if( status != MS::kSuccess )
{
return MS::kFailure;
}
// Retrieve the mesh vertices
//
MPointArray points;
meshFn.getPoints( points );
unsigned int nPoints = points.length();
// Retrieve the current particle count.
//
// NOTE: Due to the order in which the particle system requests
// various pieces of data, some attributes are requested prior
// to the actual emission of particles (eg. rampPosition), whereas
// other attributes are requested after particles have been emitted.
//
// If the driven PP attribute on the particleShape is requested prior
// to the emission of particles, this compute() method will be called
// before any particles have been emitted. As a result, the effect
// will be lagged by one frame.
//
unsigned int nParticles = 0;
int nSignedPart = block.inputValue( particleCount ).asInt();
if( nSignedPart > 0 )
{
nParticles = nSignedPart;
}
// Get pointer to destination attribute: outPositionPP
//
MFnVectorArrayData dataVectorArrayFn;
MVectorArray outPosArray;
MObject posD = block.outputValue( outPositionPP ).data();
//const char* typeStr = posD.apiTypeStr();
status = dataVectorArrayFn.setObject( posD );
if( status == MS::kSuccess )
{
outPosArray = dataVectorArrayFn.array();
}
outPosArray.setLength( nParticles );
for( unsigned int i = 0; i < nParticles; i++ )
{
unsigned int index = i;
if( nParticles > nPoints )
{
index = i % nPoints;
}
MPoint point = points[index];
MVector pos( point.x, point.y, point.z );
outPosArray[i] = pos;
}
dataVectorArrayFn.set( outPosArray );
return MS::kSuccess;
}