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Copyright 2015 Pixar
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Licensed under the Apache License, Version 2.0 (the "Apache License")
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with the following modification; you may not use this file except in
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compliance with the Apache License and the following modification to it:
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Section 6. Trademarks. is deleted and replaced with:
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6. Trademarks. This License does not grant permission to use the trade
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names, trademarks, service marks, or product names of the Licensor
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and its affiliates, except as required to comply with Section 4(c) of
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the License and to reproduce the content of the NOTICE file.
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You may obtain a copy of the Apache License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the Apache License with the above modification is
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distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
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KIND, either express or implied. See the Apache License for the specific
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language governing permissions and limitations under the Apache License.
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Subdivision Compatibility
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-------------------------
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.. contents::
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:local:
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:backlinks: none
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Subdivision Compatibility
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=========================
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This document highlights areas of compatibility with other software that makes
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use of subdivision surfaces, including previous versions of OpenSubdiv.
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The "compatibility" here refers to the choice of subdivision rules that define
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the shape of the resulting surfaces. Different subdivision rules will lead to
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different shapes. Choices affecting shape include:
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* the types of subdivision schemes supported (e.g. Catmull-Clark, Loop, etc.)
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* the basic rules applied for these schemes
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* any extended rules to affect sharpness or creasing
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* rules applied separately to face-varying data
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Ensuring all of these rules are consistent provides the basis for consistent
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shapes, but further approximations to the limit surface create the potential
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for subtle deviations. Even within OpenSubdiv, multiple approximations are
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possible and vary. For now we focus on the compatibility of subdivision rules
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and deal with the limit approximations only when noteworthy.
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Compatibility with OpenSubdiv 2.x
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=================================
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The refactoring of OpenSubdiv 3.0 data representations presented a unique
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opportunity to revisit some corners of the subdivision specification and
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remove or update some legacy features.
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**Face-varying Interpolation Options**
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Face-varying interpolation options have been consolidated into a single enum
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with one additional choice new to 3.0. No functionality from 2.x has been
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removed -- just re-expressed in a simpler and more comprehensible form.
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Face-varying interpolation was previously defined by a "boundary interpolation"
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enum with four modes and an additional boolean "propagate corners" option,
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which was little understood, i.e.:
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* void HbrMesh::SetFVarInterpolateBoundarMethod(InterpolateBoundaryMethod) const;
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* void HbrMesh::SetFVarPropagateCorners(bool) const;
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The latter was only used in conjunction with one
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of the four modes ("edge and corner"), so it was effectively a unique fifth
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choice. Closer inspection of all of these modes also revealed some unexpected
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and undesirable behavior in some common cases -- to an extent that could not
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simply be changed -- and so an additional mode was added to avoid such behavior.
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All choices are now provided through a single "linear interpolation" enum,
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described and illustrated in more detail in the overview of
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`Face-Varying Interpolation <subdivision_surfaces.html#face-varying-interpolation-rules>`__.
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The use of "boundary" in the name of the enum was intentionally removed
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as the choice also affects interior interpolation. The new use of "linear"
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is now intended to reflect the fact that interpolation is constrained to be
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linear where specified by the choice applied.
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All five of Hbr's original modes of face-varying interpolation are supported
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(with minor modifications where Hbr was found to be incorrect in the presence
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of semi-sharp creasing). An additional mode ("corners only") has also been
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added to avoid some of the undesired side-effects of some existing modes
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(illustrated below).
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The new values for the *"Sdc::Options::FVarLinearInterpolation"* enum and its
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equivalents for HbrMesh's InterpolateBoundaryMethod and PropagateCorners flag
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are as follows (ordered such that the set of linear constraints applied is
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always increasing -- from completely smooth to completely linear):
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============================ ================================== =========================
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Sdc FVarLinearInterpolation Hbr FVarInterpolateBoundaryMethod Hbr FVarPropogateCorners
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============================ ================================== =========================
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FVAR_LINEAR_NONE k_InterpolateBoundaryEdgeOnly N/A (ignored)
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FVAR_LINEAR_CORNERS_ONLY N/A N/A
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FVAR_LINEAR_CORNERS_PLUS1 k_InterpolateBoundaryEdgeAndCorner false
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FVAR_LINEAR_CORNERS_PLUS2 k_InterpolateBoundaryEdgeAndCorner true
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FVAR_LINEAR_BOUNDARIES k_InterpolateBoundaryAlwaysSharp N/A (ignored)
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FVAR_LINEAR_ALL k_InterpolateBoundaryNone N/A (ignored)
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============================ ================================== =========================
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Aside from the two "corners plus" modes that preserve Hbr behavior, all other
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modes are designed so that the interpolation of a disjoint face-varying region
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is not affected by changes to other regions that may share the same vertex. So
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the behavior of a disjoint region should be well understood and predictable
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when looking at it in isolation (e.g. with "corners only" one would expect to
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see linear constraints applied where there are topological corners or infinitely
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sharp creasing applied within the region, and nowhere else).
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This is not true of the "plus" modes, and they are named to reflect the fact
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that more is taken into account where disjoint regions meet.
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The following example illustrates some undesired effects of the "plus" modes,
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which in part motivated the addition of the new "corners only" mode. The
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example uses the "catmark_fvar_bound0" and "catmark_fvar_bound1" shapes from
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the suite of regression shapes. Both shapes are a simple regular 4x4 grid of
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quads with face-varying UV data partitioned into multiple disjoint regions.
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The "bound0" shape has two disjoint UV regions -- an upper and lower region --
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while the "bound1" shape further splits the lower region in two.
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This first figure illustrates the effect of the original "plus1" mode (which
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is also the same for "plus2"):
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.. image:: images/fvar_corners_plus1.png
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:align: center
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:width: 60%
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:target: images/fvar_corners_plus1.png
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Note that the effect of splitting the lower UV region in two has the undesired
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side effect of sharpening the boundary of the upper region. This is the result
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of the "plus1" mode making collective decisions about the sharpness of all
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face-varying boundaries at the vertex rather than decisions local to each
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region. In both the "plus1" and "plus2" cases, all face-varying boundaries
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sharing a vertex will be sharpened if there are more than two regions meeting
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at that vertex.
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The second figure illustrates the effect of the new "corners only" mode:
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.. image:: images/fvar_corners_only.png
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:align: center
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:width: 60%
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:target: images/fvar_corners_only.png
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As expected, the splitting of the lower region does not impact the upper
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region. In this case the decision to sharpen a face-varying boundary is made
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based on the local topology of each region.
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**Vertex Interpolation Options**
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Since the various options are now presented through a new API (Sdc rather than
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Hbr), based on the history of some of these options and input from interested
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parties, the following changes have been implemented:
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* The naming of the standard creasing method has been changed from *Normal*
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to *Uniform*. Values for *"Sdc::Options::CreasingMethod"* are now:
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============== ====================================
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CREASE_UNIFORM standard integer subtraction per level (default)
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CREASE_CHAIKIN Chaikin (non-uniform) averaging around vertices
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============== ====================================
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* Legacy modes of the *"smoothtriangle"* rule have been removed (as they
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were never actually enabled in the code). Values for
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*"Sdc::Options::TriangleSubdivision"* are now:
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=============== =================
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TRI_SUB_CATMARK Catmull-Clark weights (default)
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TRI_SUB_SMOOTH "smooth triangle" weights
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=============== =================
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These should have little impact since one is a simple change in terminology
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as part of a new API while the other was removal of an option that was never
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used.
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**Change to Chaikin creasing method**
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In the process of re-implementing the Chaikin creasing method, observations
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lead to a conscious choice to change the behavior of Chaikin creasing in the
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presence of infinitely sharp edges (most noticeable at boundaries).
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Previously, the inclusion of infinite sharpness values in the Chaikin method's
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computation of edge sharpness around a vertex would prevent a
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semi-sharp edge from decaying to zero. Infinitely sharp edges are now
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excluded from the Chaikin (non-uniform) averaging yielding a much more
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predictable and desirable result. For example, where the sharpness assignment
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is actually uniform at such a vertex, the result will now behave the same as
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the Uniform method.
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Since this feature has received little use (only recently activated in
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RenderMan), now seemed the best time to make the change before more widespread
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adoption.
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**Hierarchical Edits**
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While extremely powerful, Hierarchical Edits come with additional maintenance
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and implementation complexity. Support for them in popular interchange formats
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and major DCC applications has either been dropped or was never implemented.
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As a result, the need for Hierarchical Edits is too limited to justify the cost
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and support for them, and they have therefore been removed from the 3.0 release
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of OpenSubdiv. Dropping support for Hierarchical Edits allows for significant
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simplifications of many areas of the subdivision algorithms.
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While the 3.0 release does not offer direct support for Hierarchical Edits,
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the architectural changes and direction of 3.0 still facilitate the application
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of the most common value edits for those wishing to use them -- though not
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always in the same optimized context. Of course, support for Hierarchical
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Edits in the future will be considered based on demand and resources.
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**Non-Manifold Topology**
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OpenSubdiv 2.x and earlier was limited to dealing with meshes whose topology
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was manifold -- a limitation imposed by the use of Hbr. With 3.0 no longer
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using Hbr, the manifold restriction has also been removed.
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OpenSubdiv 3.0, therefore, supports a superset of the meshes supported by 2.x
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and earlier versions (with one known exception noted below).
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Non-manifold meshes that are acceptable to 3.0 however will likely not work
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with 2.x or earlier.
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The one known case that 3.0 will not represent the same as 2.x is ironically
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a case that is non-manifold, and for which Hbr did make special accommodation.
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That case occurs at a non-manifold vertex where two or more faces meet
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at a common vertex, but do not share a common edge, *and* when the boundary
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interpolation mode is set for smooth corners (i.e. "edge only"), as
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illustrated below:
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.. image:: images/bowtie_vertex.png
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:align: center
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:width: 80%
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:target: images/bowtie_vertex.png
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The cage is on the left and is refined to level 2 on the right. On the immediate
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right, boundary interpolation is set to sharp corners and the results appear
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the same for 2.x and 3.0. The center and far right illustrate the affects of
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setting boundary interpolation to smooth corners with 2.x and 3.0 respectively.
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Note that the 2.x result allows the refined mesh (and so the limit surface) to
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split into two while the 3.0 result keeps it connected.
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When Hbr encounters such vertices, regardless of the boundary mode it "splits"
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the vertex -- creating a separate instance of it for each face. So when
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building an HbrMesh, after "finalizing" the mesh, it will result in having
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more vertices than were originally defined (termed "split vertices").
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OpenSubdiv 2.x (and earlier) successfully hid the presence of these extra
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vertices from users.
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This case behaves in such a way that violates certain properties of the
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surface that 3.0 has attempted to emphasize. One of these relates to the
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nature of the limit surface (and becomes more significant in the context of
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face varying): if the cage is connected then so too is its limit surface,
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or similarly, if the cage consists of *N* connected regions then the limit
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surface similarly consists of *N* connected regions. Another undesirable
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property here is that the vertex *V* at which these faces meet must have
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more than one child vertex *V'*. This makes it difficult to "hide" split
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vertices -- OpenSubdiv 2.x tables had an extra level of indirection that
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made it possible to do this relatively easily, but 3.0 has dispensed with
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such indirection where possible to streamline performance.
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Compatibility with RenderMan
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============================
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Since RenderMan and OpenSubdiv versions prior to 3.0 share a common library
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(Hbr), most differences between RenderMan and OpenSubdiv 3.0 are covered in the
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preceding section of compatibility with OpenSubdiv 2.x.
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In addition to some features between RenderMan and OpenSubdiv that are not
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compatible, there are also other differences that may be present due to
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differences in the implementations of similar features.
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For most use cases, OpenSubdiv 3.0 is largely compatible with RenderMan. There
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are however some cases where some differences can be expected. These are
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highlighted below for completeness.
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Incompatibilities
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+++++++++++++++++
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OpenSubdiv and RenderMan will be incompatible when certain features are used
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that are not common to both. They are fully described in the 2.x compatibility
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section and are listed briefly here.
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**OpenSubdiv 3.0 Features Not Supported by RenderMan**
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* Non-manifold meshes
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* Choice of the "corners only" face varying interpolation option
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**RenderMan Features Not Supported by OpenSubdiv 3.0**
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* Hierarchical Edits
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Other Differences
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+++++++++++++++++
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Some differences can occur due to the differing implementations of the
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feature sets. Additionally, OpenSubdiv 3.0's implementation fixes some
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issues discovered in Hbr.
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**Smooth Face-Varying Interpolation with Creasing**
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There have been two discrepancies noted in the way that face-varying data is
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interpolated smoothly in the presence of creases. Smooth face-varying
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interpolation is expected to match vertex interpolation in the interior and
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only differ along the boundaries or discontinuities where the face-varying
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topology is intentionally made to differ from the vertex topology.
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A simple and effective way to identify discrepancies is to use the X and Y
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coordinates of vertex positions as the U and V of texture coordinates. If
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these U and V coordinates are assigned to a face-varying channel, smooth
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interpolation of U and V is expected to exactly match interpolation of X
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and Y, regardless of the presence of any sharpness and creasing.
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Two discrepancies can be seen with Hbr when superimposing the XY vertex
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interpolation with the "projected" UV face-varying interpolation.
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The first discrepancy occurs with interpolation around dart vertices:
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.. image:: images/fvar_hbr_dart.png
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:align: center
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:width: 80%
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:target: images/fvar_hbr_dart.png
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This example shows a simple regular XY grid on the left with an interior sharp
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edge creating a dart vertex in the center. With no asymmetry in the vertices,
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the sharpness has no asymmetric affect and the XY vertex interpolation on
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the immediate right shows the regular grid expected from refinement. On the
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far right is the UV interpolation from Hbr, which exhibits distortion around
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the center dart vertex.
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The second discrepancy occurs with interpolation involving any fractional
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sharpness values. Hbr effectively ignores any fractional sharpness value
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in its face-varying interpolation. So edges of vertices with sharpness of
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say 2.5, will be treated as though their sharpness is 2.0 when face-varying
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values are interpolated. Similarly, any non-zero sharpness value less than
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1.0 is treated as zero by truncation and so is essentially ignored.
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.. image:: images/fvar_hbr_integer.png
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:align: center
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:width: 80%
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:target: images/fvar_hbr_integer.png
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This example shows an asymmetric 2x2 grid of quads on the left with the center
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vertex progressively sharpened from 0.5 to 1.0. The three cases of the vertex
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smooth and sharpened are superimposed on the immediate right to display the
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three distinct interpolation results. On the far right the interpolation from
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Hbr displays the same three cases, but only two are visibly distinct -- the
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sharpness of 0.5 being treated the same as if it were 0.0.
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Both of these cases are corrected in OpenSubdiv 3.0. Smooth face-varying
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interpolation in the presence of creasing should match the expected behavior
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of the vertex interpolation, except where the face-varying topology is
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explicitly made to differ.
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**The Chaikin Creasing Method**
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At least two discrepancies are know to exist between the implementations of
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Hbr in RenderMan and OpenSubdiv 3.0:
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* Use of Chaikin creasing with boundaries or infinitely sharp edges
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* Subtle shape differences due to Hbr's use of "predictive sharpness"
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Fortunately, this feature was only recently added to Hbr and RenderMan and is
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little used, so it is expected these differences will have little impact.
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The first discrepancy is mentioned briefly in the previous section on
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compatibility between OpenSubdiv 2.x and 3.0. A conscious decision was
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made to change the averaging of sharpness values involving infinitely
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sharp edges in order to make results more predictable and favorable.
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The effects can be seen comparing the regression shape "catmark_chaikin2".
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The second is more subtle and results from an oversight within Hbr's
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implementation that is not easily corrected.
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When determining what subdivision rule to apply from one level to the
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next, the sharpness values at the next level must be known in order to
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determine whether or not a transition between differing rules is required.
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If the rule at the next level differs from the previous, a combination of
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the two is applied. Such a change results from the sharpness values of
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one or more edges (or the vertex itself) decaying to zero.
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Rather than compute the sharpness values at the next level accurately,
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Hbr "predicts" it by simply subtracting 1.0 from it, as is done with the
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uniform creasing method, and it bases decisions on that predicted result.
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This does not work for Chaikin though. A sharpness value less than 1.0
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may not decay to 0 if it is averaged with neighboring sharpness values
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greater than 1.0, so this sharpness prediction can result in the wrong
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rule being chosen for the next level.
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A typical case would have the subdivision rules for Chaikin creasing
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transition from Corner to Crease at one level, then from Crease to
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Smooth at the next. Hbr's predictive creasing might mistakenly detect
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the transition as Corner to Smooth at one level, then after properly
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computing the sharpness values for the next level later, from Crease to
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Smooth for the next. One of the regression shapes ("catmark_chakin1")
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was disabled from the regression suite because of this effect. The
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differences in shape that trigger its regression failure were
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investigated and determined to be the result of this issue.
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From observations thus far these differences are subtle but can be
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noticeable.
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**Numerical Precision**
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Since its inception, OpenSubdiv has sought to produce results that were
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numerically consistent to RenderMan. A regression suite to ensure a
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certain level of accuracy was provided to detect any substantial deviation.
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At some point in the development of OpenSubdiv, the point was made that
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numerical accuracy of Hbr could be improved by changing the order of
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operations and combining the vertex with the lowest coefficient first in
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one of the subdivision rules. This was applied more thoroughly in the
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independent implementation of 3.0 (there seemed no reason not to). In
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most cases the relative magnitudes of the coefficients of subdivision and
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limit masks is clear so no overhead was necessary to detect them.
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At a certain point though, this greater accuracy came in conflict with the
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regression suite. It turned out that high-valence vertices could not be
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computed to within the desired tolerances set within the suite. The
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summation of many small coefficients for the adjacent vertices first, before
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the addition of the much larger coefficient for the primary vertex, allowed
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for the accumulation of precision that was being truncated by adding the
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much larger coefficient first in the Hbr implementation. With extremely
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high valence vertices, a difference in magnitude between the most and least
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significant coefficients of several orders of magnitude is likely, and that
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has a significant impact on the single-precision floating point computations.
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The improved accuracy of OpenSubdiv 3.0 can reach a magnitude that will
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not go undetected. Whether or not this can lead to visual artifacts is
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unclear.
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