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A smoothly reparameterizing Bezier spline that also interpolates orientations

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TwistSpline

A smoothly reparameterizing Bezier spline that also interpolates orientations.

The idea here is to build a header-only C++ template library for the spline, and a reference implementation (maya plugin). Internal testing hasn't found any more major bugs, so this is now a BETA release, and is ready to be tested in production.

Demos

This gif demonstrates the smoothly interpolating pin values for this test setup. Any control can be pinned with an arbitrary value at any time. Not shown: You can unpin both ends as long as at least one control has weight. Stretching Demo

This gif deomonstrates the smoothly interpolating twist values (and their interaction with position pinning) Again, any control can pin its twist value, and twist solves smoothly through length preservation Twisting Demo

Not Shown: The Rider node can constrain between multiple splines. This means that a tool could easily be written to build and switch to another spline. For an artist, this would give the ability to add or remove spline controls on the fly in-scene.

Compiling

Hopefully compiling should be easy using Cmake. There are no dependencies other than Maya and the STL. I only have access to Maya on Windows, so I can't really test on Linux or OSX, but I'm fairly certain everything is cross-platform. If anybody wants to set those up, please feel free, and send a PR. If you are compiling for Windows, there's a mayaConfigure.bat file that should give an easy way to build a Visual Studio solution, or compile. You may have to edit it a bit to suit your needs, but it should be pretty straightforward.

Usage

Currently, the easiest way to handle building a spline and all of its required connections is to use twistSplineBuilder.py and run the makeTwistSpline function inside. You will probably have to edit this file to fit in your pipeline.

makeTwistSpline(prefix, numCVs, numRiders, spread=1, maxParam=None)

prefix is the naming prefix for all the DAG objects. numCVs is the total number of CVs numRiders is the number of evenly spaced locators riding the spline. Locators are used because joints don't show orientation. spread is the amount of space between each controller (cv and tangent). So a spread of 1 makes the CVs 3 apart. maxParam is the parameter value of the last CV. It defaults to (3 * spread * (numCVs - 1))

Node Documentation

TwistSpline Node

This node implements the TwistSpline, which is a dynamically re-parameterizing bezier spline that interpolates twist along its length.

This TwistSpline can have any number of Control Vertices, and each control vertex has an incoming and outgoing tangent. The incoming tangent is ignored for the first CV, and the outgoing tangent is ignored for the last CV.

The OutputSpline plug is a custom type specific to this set of nodes.

The per-CV plugs control how the spline behaves and reparameterizes. The ControlVertex plug recieves the worldpace position and orientation of the CV itself. The InTangent and OutTangent are world matrices that define the bezier tangent positions and orientations for this CV. ParamValue and ParamWeight are used as a pair. ParamValue is the parameter that the currentCV will have when ParamWeight is 1.0. If ParamWeight is 0.0, then the parameter of this CV will float between it's neighbor's parameters (as a percentage of the lengths of its neighboring bezier spline segments). The parameterization algorithm works as long as any paramWeight is greater than 0.

TwistValue and TwistWeight work in a similar way. Twists are interpolated between values that have weight, and skip those that don't. Because this is handled as an interpolated float value, twist behavior allows for arbitrary values, and can twist past 360deg multiple times along the spline.

UseOrient is the "weight" of the ControlVertex worldspace orientation as part of the twist. Because of the limitations of Matrices and Quaternions, you can never get more than a 180 degree twist using orient behavior and popping can occur if you're not careful.

DebugDisplay and DebugScale show the orientation frames calculated along the spline and control their size.

Long Name (short name) Type Default
outputSpline (os) TwistSpline n/a
    The custom spline data output
splineLength (sl) double 0.0
    The total length of the spline
debugDisplay (dd) bool False
    Whether to show the debug axes
debugScale (ds) double 1.0
    The size of the debug axes
vertexData (vd) compound n/a
    Inputs for all of the per-cv data
    inTangent (int) matrix Identity
        The bezier tangent pointing towards the start of the spline
    outTangent (ot) matrix Identity
        The bezier tangent pointing towards the end of the spline
    controlVertex (cv) matrix Identity
        The control vertex
    paramValue (pv) double 0.0
        The parameter value of this CV
    paramWeight (pw) double 0.0
        Whether to use the paramValue, or float
    twistValue (tv) double 0.0
        The twist value of this CV
    twistWeight (tw) double 0.0
        Whether to use the twist value, or interpolate
    useOrient (uo) double 0.0
        Whether to use the orientation of this CV as part of the twist

TwistTangent Node

This node Controls the behavior of a single bezier tangent control.

This node assumes the tangent being controlled is an outgoing tangent. So for incoming tangents, the "previous" and "next" cvs are swapped.

These nodes usually come in pairs. One for each twist spline segment. The in/out linear targets are connected in a cycle between them. Don't worry, it's not an actual cycle as the plugs aren't connected that way internally to the node.

Long Name (short name) Type Default
out (out) double3 n/a
    The final output from this node. Usually connected to a tangent input on a TwistSpline node
    outX (ox) double 0.0
        The output X component
    outY (oy) double 0.0
        The output Y component
    outZ (oz) double 0.0
        The output Z component
smoothTan (st) double3 n/a
    The pure smooth tangent in un-oriented CV space. Not affected by weight or auto
    smoothTanX (stx) double 0.0
        The smoothTangent X component
    smoothTanY (sty) double 0.0
        The smoothTangent Y component
    smoothTanZ (stz) double 0.0
        The smoothTangent Z component
outLinearTarget (lt) double3 n/a
    The target for next linear tangent
    outLinearTargetX (ltx) double 0.0
        The linearTarget X component
    outLinearTargetY (lty) double 0.0
        The linearTarget Y component
    outLinearTargetZ (ltz) double 0.0
        The linearTarget Z component
parentInverseMatrix (pim) matrix Identity
    The parent inverse matrix from the object connected to the output
inTangent (it) matrix Identity
    The user defined floating tangent matrix
previousVertex (pv) matrix Identity
    The CV that is on the opposite side of the current vertex
currentVertex (cv) matrix Identity
    The CV that this tangent is connect to
nextVertex (nv) matrix Identity
    The CV that this tangent points towards
inLinearTarget (nlt) double3 n/a
    Connect the outLinearTarget from another TwistTangent node controlling the same bezier segment here
    inLinearTargetX (nltx) double 0.0
        The linearTarget X component
    inLinearTargetY (nlty) double 0.0
        The linearTarget Y component
    inLinearTargetZ (nltz) double 0.0
        The linearTarget Z component
auto (a) double 1.0
    Whether or not the output is controlled automatically by the CVs
smooth (s) double 1.0
    Whether an automatic output is smooth or linear
weight (w) double 1.0
    The Length of the auto tangent. A weight of 1 is 1/3 of the distance between the current and next CVs

RiderConstraint Node

A node that gets transformations at a given parameters along the spline. Generally, you will make many rider objects, and skin your geometry to those riders.

This node contains many convenience options. Normalization allows easy 0 to 1 parameterization no matter the length of the spline (as a spline that is unpinned will default to parameterizing by length). The globalOffset and globalSpread parameters are common sliding options. And useCycle allows you to constrain in loops so any rider that goes past the end parameter will loop back to the beginning, and vice-versa.

The multiple spline inputs allows you to switch between controlling splines. For instance, you could build a second spline with extra controls as the need arose, and swap control of the riders to that new spline.

Note: Despite its name, this isn't actually implemented as a constraint, but it behaves similarly.

Long Name (short name) Type Default
rotateOrder (ro) enum XYZ
    Enum of the rotation order standard to Maya
globalOffset (go) double 0.0
    A value added to all input parameters. This shifts everything connected to this constraint along the spline.
globalSpread (gs) double 1.0
    A value multiplied by all input parameters. This spreads everything out (happens before the offset)
useCycle (uc) false
    Whether or not to cycle the parameters once they go past the end. If not, they extrapolate linearly.
normalize (n) boolen True
    If true, then the input parameters are remapped so that (0, normValue) maps to (0, restLength) of the spline
normValue (nv) double 1.0
    The remapped maximum value when normalizing
inputSplines (is) compound n/a
    The group that is a spline and its corresponding weight.
    spline (s)
        An input spline
    weight (w) double 1.0
        The constraint weight of that spline
params (ps)
    The parameters for the constraints, and their parent inverse matrices
    param (p) double 0.0
        The parameter where an object will stick to the spline.
    parentInverseMatrix (pim) matrix identity
        The parentInverseMatrix of the object sticking to the spline
outputs (out)
    translate (t) double3 n/a
        The output translation
        translateX (tx) double 0.0
            The output translation X Component
        translateY (ty) double 0.0
            The output translation Y Component
        translateZ (tz) double 0.0
            The output translation Z Component
    rotate (rot) double3 n/a
        The output rotation
        rotateX (rotx) angle 0.0
            The output rotation X Component
        rotateY (roty) angle 0.0
            The output rotation Y Component
        rotateZ (rotz) angle 0.0
            The output rotation Z Component
    scale (scl) double3 n/a
        The output scale
        scaleX (sclx) double 0.0
            The output scale X Component
        scaleY (scly) double 0.0
            The output scale Y Component
        scaleZ (sclz) double 0.0
            The output scale Z Component

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