mirror of
https://github.com/PixarAnimationStudios/OpenSubdiv
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494 lines
16 KiB
C++
494 lines
16 KiB
C++
//
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// Copyright 2013 Pixar
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//
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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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//
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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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//
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// You may obtain a copy of the Apache License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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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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//
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#include "../far/patchTables.h"
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#include "../far/stencilTables.h"
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#include <cstring>
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namespace OpenSubdiv {
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namespace OPENSUBDIV_VERSION {
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namespace Far {
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static void
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getBeziereWeights(float t, float point[4], float deriv[3]) {
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// The weights for the four uniform cubic Bezier basis functions are:
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// (1 - t)^3
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// 3 * t * (1-t)
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// 3 * t^2 * (1-t)
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// t^3
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float t2 = t*t,
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w0 = 1.0f - t,
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w2 = w0 * w0;
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assert(point);
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point[0] = w0*w2;
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point[1] = 3.0f * t * w2;
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point[2] = 3.0f * t2 * w0;
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point[3] = t * t2;
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// The weights for the three uniform quadratic basis functions are:
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// (1-t)^2
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// 2 * t * (1-t)
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// t^2
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if (deriv) {
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deriv[0] = w2;
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deriv[1] = 2.0f * t * w0;
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deriv[2] = t2;
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}
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}
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static void
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getBSplineWeights(float t, float point[4], float deriv[3]) {
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// The weights for the four uniform cubic B-Spline basis functions are:
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// (1/6)(1 - t)^3
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// (1/6)(3t^3 - 6t^2 + 4)
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// (1/6)(-3t^3 + 3t^2 + 3t + 1)
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// (1/6)t^3
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float t2 = t*t,
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t3 = 3.0f*t2*t,
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w0 = 1.0f-t;
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assert(point);
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point[0] = (w0*w0*w0) / 6.0f;
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point[1] = (t3 - 6.0f*t2 + 4.0f) / 6.0f;
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point[2] = (3.0f*t2 - t3 + 3.0f*t + 1.0f) / 6.0f;
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point[3] = t3 / 18.0f;
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// The weights for the three uniform quadratic basis functions are:
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// (1/2)(1-t)^2
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// (1/2)(1 + 2t - 2t^2)
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// (1/2)t^2
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if (deriv) {
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deriv[0] = 0.5f * w0 * w0;
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deriv[1] = 0.5f + t - t2;
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deriv[2] = 0.5f * t2;
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}
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}
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void
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getBoxSplineWeights(float v, float w, float B[12]) {
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float u = 1.0f - v - w;
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//
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// The 12 basis functions of the quartic box spline (unscaled by their common
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// factor of 1/12 until later, and formatted to make it easy to spot any
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// typing errors):
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//
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// 15 terms for the 3 points above the triangle corners
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// 9 terms for the 3 points on faces opposite the triangle edges
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// 2 terms for the 6 points on faces opposite the triangle corners
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//
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// Powers of each variable for notational convenience:
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float u2 = u*u;
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float u3 = u*u2;
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float u4 = u*u3;
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float v2 = v*v;
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float v3 = v*v2;
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float v4 = v*v3;
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float w2 = w*w;
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float w3 = w*w2;
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float w4 = w*w3;
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// And now the basis functions:
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B[ 0] = u4 + 2.0f*u3*v;
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B[ 1] = u4 + 2.0f*u3*w;
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B[ 8] = w4 + 2.0f*w3*u;
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B[11] = w4 + 2.0f*w3*v;
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B[ 9] = v4 + 2.0f*v3*w;
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B[ 5] = v4 + 2.0f*v3*u;
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B[ 2] = u4 + 2.0f*u3*w + 6.0f*u3*v + 6.0f*u2*v*w + 12.0f*u2*v2 +
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v4 + 2.0f*v3*w + 6.0f*v3*u + 6.0f*v2*u*w;
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B[ 4] = w4 + 2.0f*w3*v + 6.0f*w3*u + 6.0f*w2*u*v + 12.0f*w2*u2 +
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u4 + 2.0f*u3*v + 6.0f*u3*w + 6.0f*u2*v*w;
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B[10] = v4 + 2.0f*v3*u + 6.0f*v3*w + 6.0f*v2*w*u + 12.0f*v2*w2 +
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w4 + 2.0f*w3*u + 6.0f*w3*v + 6.0f*w3*u*v;
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B[ 3] = v4 + 6*v3*w + 8*v3*u + 36*v2*w*u + 24*v2*u2 + 24*v*u3 +
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w4 + 6*w3*v + 8*w3*u + 36*w2*v*u + 24*w2*u2 + 24*w*u3 + 6*u4 + 60*u2*v*w + 12*v2*w2;
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B[ 6] = w4 + 6*w3*u + 8*w3*v + 36*w2*u*v + 24*w2*v2 + 24*w*v3 +
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u4 + 6*u3*w + 8*u3*v + 36*u2*v*w + 24*u2*v2 + 24*u*v3 + 6*v4 + 60*v2*w*u + 12*w2*u2;
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B[ 7] = u4 + 6*u3*v + 8*u3*w + 36*u2*v*w + 24*u2*w2 + 24*u*w3 +
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v4 + 6*v3*u + 8*v3*w + 36*v2*u*w + 24*v2*w2 + 24*v*w3 + 6*w4 + 60*w2*u*v + 12*u2*v2;
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for (int i = 0; i < 12; ++i) {
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B[i] *= 1.0f / 12.0f;
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}
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}
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void
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PatchTables::getBasisWeights(TensorBasis basis, PatchParam::BitField bits,
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float s, float t, float point[16], float deriv1[16], float deriv2[16]) {
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int const rots[4][16] =
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{ { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 },
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{ 12, 8, 4, 0, 13, 9, 5, 1, 14, 10, 6, 2, 15, 11, 7, 3 },
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{ 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0 },
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{ 3, 7, 11, 15, 2, 6, 10, 14, 1, 5, 9, 13, 0, 4, 8, 12 } };
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assert(bits.GetRotation()<4);
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int const * rot = rots[bits.GetRotation()];
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float sWeights[4], tWeights[4], d1Weights[3], d2Weights[3];
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if (basis==BASIS_BSPLINE) {
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getBSplineWeights(s, point ? sWeights : 0, deriv1 ? d1Weights : 0);
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getBSplineWeights(t, point ? tWeights : 0, deriv2 ? d2Weights : 0);
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} else if (basis==BASIS_BEZIER) {
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getBeziereWeights(s, point ? sWeights : 0, deriv1 ? d1Weights : 0);
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getBeziereWeights(t, point ? tWeights : 0, deriv2 ? d2Weights : 0);
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} else {
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assert(0);
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}
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if (point) {
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// Compute the tensor product weight corresponding to each control
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// vertex
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memset(point, 0, 16*sizeof(float));
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for (int i = 0; i < 4; ++i) {
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for (int j = 0; j < 4; ++j) {
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point[rot[4*i+j]] += sWeights[j] * tWeights[i];
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}
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}
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}
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if (deriv1 and deriv2) {
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// Compute the tangent stencil. This is done by taking the tensor
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// product between the quadratic weights computed for s and the cubic
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// weights computed for t. The stencil is constructed using
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// differences between consecutive vertices in each row (i.e.
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// in the s direction).
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memset(deriv1, 0, 16*sizeof(float));
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for (int i = 0, k = 0; i < 4; ++i) {
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float prevWeight = 0.0f;
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for (int j = 0; j < 3; ++j) {
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float weight = d1Weights[j]*tWeights[i];
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deriv1[rot[k++]] += prevWeight - weight;
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prevWeight = weight;
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}
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deriv1[rot[k++]]+=prevWeight;
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}
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memset(deriv2, 0, 16*sizeof(float));
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#define FASTER_TENSOR
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#ifdef FASTER_TENSOR
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// XXXX manuelk this might be slightly more efficient ?
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float dW[4];
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dW[0] = - d2Weights[0];
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dW[1] = d2Weights[0] - d2Weights[1];
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dW[2] = d2Weights[1] - d2Weights[2];
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dW[3] = d2Weights[2];
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for (int i = 0, k = 0; i < 4; ++i) {
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for (int j = 0; j < 4; ++j) {
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deriv2[rot[k++]] = sWeights[j] * dW[i];
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}
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}
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#else
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for (int j = 0; j < 4; ++j) {
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float prevWeight = 0.0f;
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for (int i = 0; i < 3; ++i) {
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float weight = sWeights[j]*d2Weights[i];
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deriv2[rot[4*i+j]]+=prevWeight - weight;
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prevWeight = weight;
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}
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deriv2[rot[12+j]] += prevWeight;
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}
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#endif
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// Scale derivatives up based on level of subdivision
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float scale = float(1 << bits.GetDepth());
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for (int k=0; k<16; ++k) {
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deriv1[k] *= scale;
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deriv2[k] *= scale;
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}
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}
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}
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PatchTables::PatchTables(int maxvalence) :
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_maxValence(maxvalence), _endcapStencilTables(0), _fvarPatchTables(0) { }
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// Copy constructor
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// XXXX manuelk we need to eliminate this constructor (C++11 smart pointers)
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PatchTables::PatchTables(PatchTables const & src) :
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_maxValence(src._maxValence),
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_numPtexFaces(src._numPtexFaces),
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_patchArrays(src._patchArrays),
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_patchVerts(src._patchVerts),
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_paramTable(src._paramTable),
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#ifdef ENDCAP_TOPOPOLGY
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_endcapTopology(src._endcapTopology),
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#endif
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_quadOffsetsTable(src._quadOffsetsTable),
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_vertexValenceTable(src._vertexValenceTable),
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_sharpnessIndices(src._sharpnessIndices),
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_sharpnessValues(src._sharpnessValues) {
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_endcapStencilTables = src._endcapStencilTables ?
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new StencilTables(*src._endcapStencilTables) : 0;
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_fvarPatchTables = src._fvarPatchTables ?
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new FVarPatchTables(*src._fvarPatchTables) : 0;
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}
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PatchTables::~PatchTables() {
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delete _endcapStencilTables;
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delete _fvarPatchTables;
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}
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//
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// PatchArrays
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//
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struct PatchTables::PatchArray {
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PatchArray(PatchDescriptor d, int np, Index v, Index p, Index qo) :
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desc(d), numPatches(np), vertIndex(v),
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patchIndex(p), quadOffsetIndex (qo) { }
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PatchDescriptor desc; // type of patches in the array
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int numPatches; // number of patches in the array
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Index vertIndex, // index to the first control vertex
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patchIndex, // index of the first patch in the array
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quadOffsetIndex; // index of the first quad offset entry
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};
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inline PatchTables::PatchArray &
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PatchTables::getPatchArray(Index arrayIndex) {
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assert(arrayIndex<(Index)GetNumPatchArrays());
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return _patchArrays[arrayIndex];
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}
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inline PatchTables::PatchArray const &
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PatchTables::getPatchArray(Index arrayIndex) const {
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assert(arrayIndex<(Index)GetNumPatchArrays());
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return _patchArrays[arrayIndex];
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}
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void
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PatchTables::reservePatchArrays(int numPatchArrays) {
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_patchArrays.reserve(numPatchArrays);
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}
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inline int
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getPatchSize(PatchDescriptor desc) {
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int size = desc.GetNumControlVertices();
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// XXXX manuelk we do not store the topology for Gregory Basis
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// patch types yet - so point to the 4 corners of the 0-ring
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if (desc.GetType() == PatchDescriptor::GREGORY_BASIS) {
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size = 4;
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}
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return size;
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}
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void
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PatchTables::pushPatchArray(PatchDescriptor desc, int npatches,
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Index * vidx, Index * pidx, Index * qoidx) {
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if (npatches>0) {
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_patchArrays.push_back(PatchArray(
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desc, npatches, *vidx, *pidx, qoidx ? *qoidx : 0));
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int nverts = getPatchSize(desc);
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*vidx += npatches * nverts;
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*pidx += npatches;
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if (qoidx) {
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*qoidx += (desc.GetType() == PatchDescriptor::GREGORY) ?
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npatches*nverts : 0;
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}
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}
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}
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Index *
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PatchTables::getSharpnessIndices(int arrayIndex) {
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return &_sharpnessIndices[getPatchArray(arrayIndex).patchIndex];
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}
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float *
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PatchTables::getSharpnessValues(int arrayIndex) {
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return &_sharpnessValues[getPatchArray(arrayIndex).patchIndex];
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}
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PatchDescriptor
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PatchTables::GetPatchDescriptor(PatchHandle const & handle) const {
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return getPatchArray(handle.arrayIndex).desc;
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}
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PatchDescriptor
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PatchTables::GetPatchArrayDescriptor(int arrayIndex) const {
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return getPatchArray(arrayIndex).desc;
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}
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int
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PatchTables::GetNumPatchArrays() const {
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return (int)_patchArrays.size();
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}
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int
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PatchTables::GetNumPatches(int arrayIndex) const {
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return getPatchArray(arrayIndex).numPatches;
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}
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int
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PatchTables::GetNumControlVertices(int arrayIndex) const {
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PatchArray const & pa = getPatchArray(arrayIndex);
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return pa.numPatches * getPatchSize(pa.desc);
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}
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IndexArray
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PatchTables::getPatchArrayVertices(int arrayIndex) {
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PatchArray const & pa = getPatchArray(arrayIndex);
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int size = getPatchSize(pa.desc);
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assert(pa.vertIndex<(Index)_patchVerts.size());
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return IndexArray(&_patchVerts[pa.vertIndex], pa.numPatches * size);
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}
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IndexArray const
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PatchTables::GetPatchArrayVertices(int arrayIndex) const {
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PatchArray const & pa = getPatchArray(arrayIndex);
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int size = getPatchSize(pa.desc);
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assert(pa.vertIndex<(Index)_patchVerts.size());
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return IndexArray(&_patchVerts[pa.vertIndex], pa.numPatches * size);
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}
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IndexArray const
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PatchTables::GetPatchVertices(PatchHandle const & handle) const {
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PatchArray const & pa = getPatchArray(handle.arrayIndex);
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Index vert = pa.vertIndex;
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// XXXX manuelk we do not store the topology for Gregory Basis
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// patch types yet - so point to the 4 corners of the 0-ring
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vert += (pa.desc.GetType() == PatchDescriptor::GREGORY_BASIS) ?
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handle.vertIndex / 5 : handle.vertIndex;
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assert(vert<(Index)_patchVerts.size());
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return IndexArray(&_patchVerts[vert], getPatchSize(pa.desc));
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}
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IndexArray const
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PatchTables::GetPatchVertices(int arrayIndex, int patchIndex) const {
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PatchArray const & pa = getPatchArray(arrayIndex);
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int size = getPatchSize(pa.desc);
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assert((pa.vertIndex + patchIndex*size)<(Index)_patchVerts.size());
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return IndexArray(&_patchVerts[pa.vertIndex + patchIndex*size], size);
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}
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PatchParam
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PatchTables::GetPatchParam(PatchHandle const & handle) const {
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assert(handle.patchIndex < (Index)_paramTable.size());
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return _paramTable[handle.patchIndex];
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}
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PatchParam
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PatchTables::GetPatchParam(int arrayIndex, int patchIndex) const {
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PatchArray const & pa = getPatchArray(arrayIndex);
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assert((pa.patchIndex + patchIndex) < (int)_paramTable.size());
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return _paramTable[pa.patchIndex + patchIndex];
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}
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PatchParamArray
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PatchTables::getPatchParams(int arrayIndex) {
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PatchArray const & pa = getPatchArray(arrayIndex);
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return PatchParamArray(&_paramTable[pa.patchIndex], pa.numPatches);
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}
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PatchParamArray const
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PatchTables::GetPatchParams(int arrayIndex) const {
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PatchArray const & pa = getPatchArray(arrayIndex);
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return PatchParamArray(&_paramTable[pa.patchIndex], pa.numPatches);
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}
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float
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PatchTables::GetSingleCreasePatchSharpnessValue(PatchHandle const & handle) const {
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assert((handle.patchIndex) < (int)_sharpnessIndices.size());
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Index index = _sharpnessIndices[handle.patchIndex];
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if (index == Vtr::INDEX_INVALID) {
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return 0.0f;
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}
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assert(index < (Index)_sharpnessValues.size());
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return _sharpnessValues[index];
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}
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float
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PatchTables::GetSingleCreasePatchSharpnessValue(int arrayIndex, int patchIndex) const {
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PatchArray const & pa = getPatchArray(arrayIndex);
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assert((pa.patchIndex + patchIndex) < (int)_sharpnessIndices.size());
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Index index = _sharpnessIndices[pa.patchIndex + patchIndex];
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if (index == Vtr::INDEX_INVALID) {
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return 0.0f;
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}
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assert(index < (Index)_sharpnessValues.size());
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return _sharpnessValues[index];
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}
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PatchTables::QuadOffsetsArray const
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PatchTables::GetPatchQuadOffsets(PatchHandle const & handle) const {
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PatchArray const & pa = getPatchArray(handle.arrayIndex);
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return Vtr::Array<unsigned int>(&_quadOffsetsTable[pa.quadOffsetIndex + handle.vertIndex], 4);
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}
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IndexArray
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PatchTables::getFVarVerts(int arrayIndex, int channel) {
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PatchArray const & pa = getPatchArray(arrayIndex);
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assert(_fvarPatchTables and (channel<(int)_fvarPatchTables->_channels.size()));
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|
std::vector<Index> & verts = _fvarPatchTables->_channels[channel].patchVertIndices;
|
|
int ofs = pa.patchIndex * pa.desc.GetNumFVarControlVertices();
|
|
return IndexArray(&verts[ofs],pa.numPatches * pa.desc.GetNumFVarControlVertices());
|
|
}
|
|
|
|
bool
|
|
PatchTables::IsFeatureAdaptive() const {
|
|
|
|
// check for presence of tables only used by adaptive patches
|
|
if (not _vertexValenceTable.empty() or _endcapStencilTables)
|
|
return true;
|
|
|
|
// otherwise, we have to check each patch array
|
|
for (int i=0; i<GetNumPatchArrays(); ++i) {
|
|
PatchDescriptor const & desc = _patchArrays[i].desc;
|
|
if (desc.GetType()>=PatchDescriptor::REGULAR and
|
|
desc.GetType()<=PatchDescriptor::GREGORY_BASIS) {
|
|
return true;
|
|
}
|
|
}
|
|
return false;
|
|
}
|
|
|
|
int
|
|
PatchTables::GetNumPatchesTotal() const {
|
|
// there is one PatchParam record for each patch in the mesh
|
|
return (int)_paramTable.size();
|
|
}
|
|
|
|
// Returns the first array of patches matching the descriptor
|
|
Index
|
|
PatchTables::findPatchArray(PatchDescriptor desc) {
|
|
for (int i=0; i<(int)_patchArrays.size(); ++i) {
|
|
if (_patchArrays[i].desc==desc)
|
|
return i;
|
|
}
|
|
return Vtr::INDEX_INVALID;
|
|
}
|
|
|
|
} // end namespace Far
|
|
|
|
} // end namespace OPENSUBDIV_VERSION
|
|
} // end namespace OpenSubdiv
|