sweptEmitter/sweptEmitter.cpp

sweptEmitter/sweptEmitter.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:
//
// Produces the dependency graph node "sweptEmitter".
//
// This node is an example of a particle emitter that emits in a direction
// from a curve or surface.
//
// The example MEL script "sweptEmitter.mel" shows how to create the node
// and appropriate connections to correctly establish a user defined particle emitter.
//
#include <maya/MIOStream.h>
#include <math.h>
#include <stdlib.h>
#include "sweptEmitter.h"
#include <maya/MDataHandle.h>
#include <maya/MFnDynSweptGeometryData.h>
#include <maya/MDynSweptLine.h>
#include <maya/MDynSweptTriangle.h>
#include <maya/MVectorArray.h>
#include <maya/MDoubleArray.h>
#include <maya/MIntArray.h>
#include <maya/MMatrix.h>
#include <maya/MArrayDataBuilder.h>
#include <maya/MFnDependencyNode.h>
#include <maya/MFnNumericAttribute.h>
#include <maya/MFnUnitAttribute.h>
#include <maya/MFnVectorArrayData.h>
#include <maya/MFnDoubleArrayData.h>
#include <maya/MFnArrayAttrsData.h>
#include <maya/MFnMatrixData.h>
MTypeId sweptEmitter::id( 0x80016 );
sweptEmitter::sweptEmitter()
: lastWorldPoint(0, 0, 0, 1)
{
}
sweptEmitter::~sweptEmitter()
{
}
void *sweptEmitter::creator()
{
return new sweptEmitter;
}
MStatus sweptEmitter::initialize()
//
// Descriptions:
// Initialize the node, create user defined attributes.
//
{
return( MS::kSuccess );
}
MStatus sweptEmitter::compute(const MPlug& plug, MDataBlock& block)
//
// Descriptions:
// Call emit emit method to generate new particles.
//
{
MStatus status;
// Determine if we are requesting the output plug for this emitter node.
//
if( !(plug == mOutput) )
// Get the logical index of the element this plug refers to,
// because the node can be emitting particles into more
// than one particle shape.
//
int multiIndex = plug.logicalIndex( &status );
McheckErr(status, "ERROR in plug.logicalIndex.\n");
// Get output data arrays (position, velocity, or parentId)
// that the particle shape is holding from the previous frame.
//
MArrayDataHandle hOutArray = block.outputArrayValue(mOutput, &status);
McheckErr(status, "ERROR in hOutArray = block.outputArrayValue.\n");
// Create a builder to aid in the array construction efficiently.
//
MArrayDataBuilder bOutArray = hOutArray.builder( &status );
McheckErr(status, "ERROR in bOutArray = hOutArray.builder.\n");
// Get the appropriate data array that is being currently evaluated.
//
MDataHandle hOut = bOutArray.addElement(multiIndex, &status);
McheckErr(status, "ERROR in hOut = bOutArray.addElement.\n");
// Get the data and apply the function set.
//
MObject dOutput = fnOutput.create ( &status );
McheckErr(status, "ERROR in fnOutput.create.\n");
// Check if the particle object has reached it's maximum,
// hence is full. If it is full then just return with zero particles.
//
bool beenFull = isFullValue( multiIndex, block );
if( beenFull )
{
return( MS::kSuccess );
}
// Get deltaTime, currentTime and startTime.
// If deltaTime <= 0.0, or currentTime <= startTime,
// do not emit new pariticles and return.
//
MTime cT = currentTimeValue( block );
MTime sT = startTimeValue( multiIndex, block );
MTime dT = deltaTimeValue( multiIndex, block );
if( (cT <= sT) || (dT <= 0.0) )
{
// We do not emit particles before the start time,
// and do not emit particles when moving backwards in time.
//
// This code is necessary primarily the first time to
// establish the new data arrays allocated, and since we have
// already set the data array to length zero it does
// not generate any new particles.
//
hOut.set( dOutput );
block.setClean( plug );
return( MS::kSuccess );
}
// Get speed, direction vector, and inheritFactor attributes.
//
double speed = speedValue( block );
MVector dirV = directionVector( block );
double inheritFactor = inheritFactorValue( multiIndex, block );
// Get the position and velocity arrays to append new particle data.
//
MVectorArray fnOutPos = fnOutput.vectorArray("position", &status);
MVectorArray fnOutVel = fnOutput.vectorArray("velocity", &status);
// Convert deltaTime into seconds.
//
double dt = dT.as( MTime::kSeconds );
// Apply rotation to the direction vector
MVector rotatedV = useRotation ( dirV );
// position,
MVectorArray inPosAry;
// velocity
MVectorArray inVelAry;
// emission rate
MIntArray emitCountPP;
// Get the swept geometry data
//
MObject thisObj = this->thisMObject();
MPlug sweptPlug( thisObj, mSweptGeometry );
if ( sweptPlug.isConnected() )
{
MDataHandle sweptHandle = block.inputValue( mSweptGeometry );
// MObject sweptData = sweptHandle.asSweptGeometry();
MObject sweptData = sweptHandle.data();
MFnDynSweptGeometryData fnSweptData( sweptData );
// Curve emission
//
if (fnSweptData.lineCount() > 0) {
int numLines = fnSweptData.lineCount();
for ( int i=0; i<numLines; i++ )
{
inPosAry.clear();
inVelAry.clear();
emitCountPP.clear();
MDynSweptLine line = fnSweptData.sweptLine( i );
// ... process current line ...
MVector p1 = line.vertex( 0 );
MVector p2 = line.vertex( 1 );
inPosAry.append( p1 );
inPosAry.append( p2 );
inVelAry.append( MVector( 0,0,0 ) );
inVelAry.append( MVector( 0,0,0 ) );
// emit Rate for two points on line
emitCountPP.clear();
status = emitCountPerPoint( plug, block, 2, emitCountPP );
emit( inPosAry, inVelAry, emitCountPP,
dt, speed, inheritFactor, rotatedV, fnOutPos, fnOutVel );
}
}
// Surface emission (nurb or polygon)
//
if (fnSweptData.triangleCount() > 0) {
int numTriangles = fnSweptData.triangleCount();
for ( int i=0; i<numTriangles; i++ )
{
inPosAry.clear();
inVelAry.clear();
emitCountPP.clear();
MDynSweptTriangle tri = fnSweptData.sweptTriangle( i );
// ... process current triangle ...
MVector p1 = tri.vertex( 0 );
MVector p2 = tri.vertex( 1 );
MVector p3 = tri.vertex( 2 );
MVector center = p1 + p2 + p3;
center /= 3.0;
inPosAry.append( center );
inVelAry.append( MVector( 0,0,0 ) );
// emit Rate for two points on line
emitCountPP.clear();
status = emitCountPerPoint( plug, block, 1, emitCountPP );
emit( inPosAry, inVelAry, emitCountPP,
dt, speed, inheritFactor, rotatedV, fnOutPos, fnOutVel );
}
}
}
// Update the data block with new dOutput and set plug clean.
//
hOut.set( dOutput );
block.setClean( plug );
return( MS::kSuccess );
}
void sweptEmitter::emit
(
const MVectorArray &inPosAry, // points where new particles from
const MVectorArray &inVelAry, // initial velocity of new particles
const MIntArray &emitCountPP, // # of new particles per point
double dt, // elapsed time
double speed, // speed factor
double inheritFactor, // for inherit velocity
MVector dirV, // emit direction
MVectorArray &outPosAry, // holding new particles position
MVectorArray &outVelAry // holding new particles velocity
)
//
// Descriptions:
//
{
// check the length of input arrays.
//
int posLength = inPosAry.length();
int velLength = inVelAry.length();
int countLength = emitCountPP.length();
if( (posLength != velLength) || (posLength != countLength) )
return;
// Compute total emit count.
//
int index;
int totalCount = 0;
for( index = 0; index < countLength; index ++ )
totalCount += emitCountPP[index];
if( totalCount <= 0 )
return;
// Map direction vector into world space and normalize it.
//
dirV.normalize();
// Start emission.
//
int emitCount;
MVector newPos, newVel;
MVector prePos, sPos, sVel;
for( index = 0; index < posLength; index++ )
{
emitCount = emitCountPP[index];
if( emitCount <= 0 )
continue;
sPos = inPosAry[index];
sVel = inVelAry[index];
prePos = sPos - sVel * dt;
for( int i = 0; i < emitCount; i++ )
{
double alpha = ( (double)i + drand48() ) / (double)emitCount;
newPos = (1 - alpha) * prePos + alpha * sPos;
newVel = dirV * speed;
newPos += newVel * ( dt * (1 - alpha) );
newVel += sVel * inheritFactor;
// Add new data into output arrays.
//
outPosAry.append( newPos );
outVelAry.append( newVel );
}
}
}
MVector sweptEmitter::useRotation ( MVector &direction )
{
MStatus status;
MVector rotatedVector;
MObject thisNode = thisMObject();
MFnDependencyNode fnThisNode( thisNode );
// get worldMatrix attribute.
//
MObject worldMatrixAttr = fnThisNode.attribute( "worldMatrix" );
// build worldMatrix plug, and specify which element the plug refers to.
// We use the first element(the first dagPath of this emitter).
//
MPlug matrixPlug( thisNode, worldMatrixAttr );
matrixPlug = matrixPlug.elementByLogicalIndex( 0 );
// Get the value of the 'worldMatrix' attribute
//
MObject matrixObject;
status = matrixPlug.getValue( matrixObject );
if( !status )
{
status.perror("sweptEmitter::useRotation: get matrixObject");
return ( direction );
}
MFnMatrixData worldMatrixData( matrixObject, &status );
if( !status )
{
status.perror("sweptEmitter::useRotation: get worldMatrixData");
return( direction );
}
MMatrix worldMatrix = worldMatrixData.matrix( &status );
if( !status )
{
status.perror("sweptEmitter::useRotation: get worldMatrixData.matrix");
return( direction );
}
rotatedVector = direction * worldMatrix;
return( rotatedVector );
}
MStatus sweptEmitter::emitCountPerPoint
(
const MPlug &plug,
MDataBlock &block,
int length, // length of emitCountPP
MIntArray &emitCountPP // output: emitCount for each point
)
//
// Descriptions:
// Compute emitCount for each point where new particles come from.
//
{
MStatus status;
int plugIndex = plug.logicalIndex( &status );
McheckErr(status, "ERROR in emitCountPerPoint: when plug.logicalIndex.\n");
// Get rate and delta time.
//
double rate = rateValue( block );
MTime dt = deltaTimeValue( plugIndex, block );
// Compute emitCount for each point.
//
double dblCount = rate * dt.as( MTime::kSeconds );
int intCount = (int)dblCount;
for( int i = 0; i < length; i++ )
{
emitCountPP.append( intCount );
}
return( MS::kSuccess );
}
MStatus initializePlugin(MObject obj)
{
MStatus status;
MFnPlugin plugin(obj, PLUGIN_COMPANY, "3.0", "Any");
status = plugin.registerNode( "sweptEmitter", sweptEmitter::id,
&sweptEmitter::creator, &sweptEmitter::initialize,
if (!status) {
status.perror("registerNode");
return status;
}
return status;
}
MStatus uninitializePlugin(MObject obj)
{
MStatus status;
MFnPlugin plugin(obj);
status = plugin.deregisterNode( sweptEmitter::id );
if (!status) {
status.perror("deregisterNode");
return status;
}
return status;
}