/usr/include/openvdb/tools/MeshToVolume.h is in libopenvdb-dev 3.1.0-2.
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//
// Copyright (c) 2012-2015 DreamWorks Animation LLC
//
// All rights reserved. This software is distributed under the
// Mozilla Public License 2.0 ( http://www.mozilla.org/MPL/2.0/ )
//
// Redistributions of source code must retain the above copyright
// and license notice and the following restrictions and disclaimer.
//
// * Neither the name of DreamWorks Animation nor the names of
// its contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// IN NO EVENT SHALL THE COPYRIGHT HOLDERS' AND CONTRIBUTORS' AGGREGATE
// LIABILITY FOR ALL CLAIMS REGARDLESS OF THEIR BASIS EXCEED US$250.00.
//
///////////////////////////////////////////////////////////////////////////
//
/// @file MeshToVolume.h
///
/// @brief Convert polygonal meshes that consist of quads and/or triangles
/// into signed or unsigned distance field volumes.
///
/// @note The signed distance field conversion requires a closed surface
/// but not necessarily a manifold surface. Supports surfaces with
/// self intersections and degenerate faces and is independent of
/// mesh surface normals / polygon orientation.
///
/// @author Mihai Alden
#ifndef OPENVDB_TOOLS_MESH_TO_VOLUME_HAS_BEEN_INCLUDED
#define OPENVDB_TOOLS_MESH_TO_VOLUME_HAS_BEEN_INCLUDED
#include <openvdb/Types.h>
#include <openvdb/math/FiniteDifference.h> // for GudonovsNormSqrd
#include <openvdb/math/Proximity.h> // for closestPointOnTriangleToPoint()
#include <openvdb/util/NullInterrupter.h>
#include <openvdb/util/Util.h>
#include "ChangeBackground.h"
#include "Prune.h" // for pruneInactive and pruneLevelSet
#include "SignedFloodFill.h" // for signedFloodFillWithValues
#include <tbb/blocked_range.h>
#include <tbb/enumerable_thread_specific.h>
#include <tbb/parallel_for.h>
#include <tbb/parallel_reduce.h>
#include <tbb/partitioner.h>
#include <tbb/task_group.h>
#include <tbb/task_scheduler_init.h>
#include <tbb/tick_count.h>
#include <boost/integer_traits.hpp> // const_max
#include <boost/math/special_functions/fpclassify.hpp> // for isfinite()
#include <boost/scoped_array.hpp>
#include <deque>
#include <limits>
#include <sstream>
namespace openvdb {
OPENVDB_USE_VERSION_NAMESPACE
namespace OPENVDB_VERSION_NAME {
namespace tools {
////////////////////////////////////////
/// @brief Mesh to volume conversion flags
enum MeshToVolumeFlags {
/// Switch from the default signed distance field conversion that classifies
/// regions as either inside or outside the mesh boundary to a unsigned distance
/// field conversion that only computes distance values. This conversion type
/// does not require a closed watertight mesh.
UNSIGNED_DISTANCE_FIELD = 0x1,
/// Disable the cleanup step that removes voxels created by self intersecting
/// portions of the mesh.
DISABLE_INTERSECTING_VOXEL_REMOVAL = 0x2,
/// Disable the distance renormalization step that smooths out bumps caused
/// by self intersecting or overlapping portions of the mesh
DISABLE_RENORMALIZATION = 0x4,
/// Disable the cleanup step that removes active voxels that exceed the
/// narrow band limits. (Only relevant for small limits)
DISABLE_NARROW_BAND_TRIMMING = 0x8
};
/// @brief Convert polygonal meshes that consist of quads and/or triangles into
/// signed or unsigned distance field volumes.
///
/// @note Requires a closed surface but not necessarily a manifold surface.
/// Supports surfaces with self intersections and degenerate faces
/// and is independent of mesh surface normals.
///
/// @interface MeshDataAdapter
/// Expected interface for the MeshDataAdapter class
/// @code
/// struct MeshDataAdapter {
/// size_t polygonCount() const; // Total number of polygons
/// size_t pointCount() const; // Total number of points
/// size_t vertexCount(size_t n) const; // Vertex count for polygon n
///
/// // Return position pos in local grid index space for polygon n and vertex v
/// void getIndexSpacePoint(size_t n, size_t v, openvdb::Vec3d& pos) const;
/// };
/// @endcode
///
/// @param mesh mesh data access class that conforms to the MeshDataAdapter
/// interface
/// @param transform world-to-index-space transform
/// @param exteriorBandWidth exterior narrow band width in voxel units
/// @param interiorBandWidth interior narrow band width in voxel units
/// (set to std::numeric_limits<float>::max() to fill object
/// interior with distance values)
/// @param flags optional conversion flags defined in @c MeshToVolumeFlags
/// @param polygonIndexGrid optional grid output that will contain the closest-polygon
/// index for each voxel in the narrow band region
template <typename GridType, typename MeshDataAdapter>
inline typename GridType::Ptr
meshToVolume(
const MeshDataAdapter& mesh,
const math::Transform& transform,
float exteriorBandWidth = 3.0f,
float interiorBandWidth = 3.0f,
int flags = 0,
typename GridType::template ValueConverter<Int32>::Type * polygonIndexGrid = NULL);
/// @brief Convert polygonal meshes that consist of quads and/or triangles into
/// signed or unsigned distance field volumes.
///
/// @param interrupter a callback to interrupt the conversion process that conforms
/// to the util::NullInterrupter interface
/// @param mesh mesh data access class that conforms to the MeshDataAdapter
/// interface
/// @param transform world-to-index-space transform
/// @param exteriorBandWidth exterior narrow band width in voxel units
/// @param interiorBandWidth interior narrow band width in voxel units (set this value to
/// std::numeric_limits<float>::max() to fill interior regions
/// with distance values)
/// @param flags optional conversion flags defined in @c MeshToVolumeFlags
/// @param polygonIndexGrid optional grid output that will contain the closest-polygon
/// index for each voxel in the active narrow band region
template <typename GridType, typename MeshDataAdapter, typename Interrupter>
inline typename GridType::Ptr
meshToVolume(
Interrupter& interrupter,
const MeshDataAdapter& mesh,
const math::Transform& transform,
float exteriorBandWidth = 3.0f,
float interiorBandWidth = 3.0f,
int flags = 0,
typename GridType::template ValueConverter<Int32>::Type * polygonIndexGrid = NULL);
////////////////////////////////////////
/// @brief Contiguous quad and triangle data adapter class
///
/// @details PointType and PolygonType must provide element access
/// through the square brackets operator.
/// @details Points are assumed to be in local grid index space.
/// @details The PolygonType tuple can have either three or four components
/// this property must be specified in a static member variable
/// named @c size, similar to the math::Tuple class.
/// @details A four component tuple can represent a quads or a triangle
/// if the fourth component set to @c util::INVALID_INDEX
template<typename PointType, typename PolygonType>
struct QuadAndTriangleDataAdapter {
QuadAndTriangleDataAdapter(const std::vector<PointType>& points,
const std::vector<PolygonType>& polygons)
: mPointArray(points.empty() ? NULL : &points[0])
, mPointArraySize(points.size())
, mPolygonArray(polygons.empty() ? NULL : &polygons[0])
, mPolygonArraySize(polygons.size())
{
}
QuadAndTriangleDataAdapter(const PointType * pointArray, size_t pointArraySize,
const PolygonType* polygonArray, size_t polygonArraySize)
: mPointArray(pointArray)
, mPointArraySize(pointArraySize)
, mPolygonArray(polygonArray)
, mPolygonArraySize(polygonArraySize)
{
}
size_t polygonCount() const { return mPolygonArraySize; }
size_t pointCount() const { return mPointArraySize; }
/// @brief Vertex count for polygon @a n
size_t vertexCount(size_t n) const {
return (PolygonType::size == 3 || mPolygonArray[n][3] == util::INVALID_IDX) ? 3 : 4;
}
/// @brief Returns position @a pos in local grid index space
/// for polygon @a n and vertex @a v
void getIndexSpacePoint(size_t n, size_t v, Vec3d& pos) const {
const PointType& p = mPointArray[mPolygonArray[n][int(v)]];
pos[0] = double(p[0]);
pos[1] = double(p[1]);
pos[2] = double(p[2]);
}
private:
PointType const * const mPointArray;
size_t const mPointArraySize;
PolygonType const * const mPolygonArray;
size_t const mPolygonArraySize;
}; // struct QuadAndTriangleDataAdapter
////////////////////////////////////////
// Wrapper functions for the mesh to volume converter
/// @brief Convert a triangle mesh to a level set volume.
///
/// @return a grid of type @c GridType containing a narrow-band level set
/// representation of the input mesh.
///
/// @throw TypeError if @c GridType is not scalar or not floating-point
///
/// @note Requires a closed surface but not necessarily a manifold surface.
/// Supports surfaces with self intersections and degenerate faces
/// and is independent of mesh surface normals.
///
/// @param xform transform for the output grid
/// @param points list of world space point positions
/// @param triangles triangle index list
/// @param halfWidth half the width of the narrow band, in voxel units
template<typename GridType>
inline typename GridType::Ptr
meshToLevelSet(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
float halfWidth = float(LEVEL_SET_HALF_WIDTH));
/// @brief Convert a quad mesh to a level set volume.
///
/// @return a grid of type @c GridType containing a narrow-band level set
/// representation of the input mesh.
///
/// @throw TypeError if @c GridType is not scalar or not floating-point
///
/// @note Requires a closed surface but not necessarily a manifold surface.
/// Supports surfaces with self intersections and degenerate faces
/// and is independent of mesh surface normals.
///
/// @param xform transform for the output grid
/// @param points list of world space point positions
/// @param quads quad index list
/// @param halfWidth half the width of the narrow band, in voxel units
template<typename GridType>
inline typename GridType::Ptr
meshToLevelSet(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec4I>& quads,
float halfWidth = float(LEVEL_SET_HALF_WIDTH));
/// @brief Convert a triangle and quad mesh to a level set volume.
///
/// @return a grid of type @c GridType containing a narrow-band level set
/// representation of the input mesh.
///
/// @throw TypeError if @c GridType is not scalar or not floating-point
///
/// @note Requires a closed surface but not necessarily a manifold surface.
/// Supports surfaces with self intersections and degenerate faces
/// and is independent of mesh surface normals.
///
/// @param xform transform for the output grid
/// @param points list of world space point positions
/// @param triangles triangle index list
/// @param quads quad index list
/// @param halfWidth half the width of the narrow band, in voxel units
template<typename GridType>
inline typename GridType::Ptr
meshToLevelSet(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float halfWidth = float(LEVEL_SET_HALF_WIDTH));
/// @brief Convert a triangle and quad mesh to a signed distance field
/// with an asymmetrical narrow band.
///
/// @return a grid of type @c GridType containing a narrow-band signed
/// distance field representation of the input mesh.
///
/// @throw TypeError if @c GridType is not scalar or not floating-point
///
/// @note Requires a closed surface but not necessarily a manifold surface.
/// Supports surfaces with self intersections and degenerate faces
/// and is independent of mesh surface normals.
///
/// @param xform transform for the output grid
/// @param points list of world space point positions
/// @param triangles triangle index list
/// @param quads quad index list
/// @param exBandWidth the exterior narrow-band width in voxel units
/// @param inBandWidth the interior narrow-band width in voxel units
template<typename GridType>
inline typename GridType::Ptr
meshToSignedDistanceField(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float exBandWidth,
float inBandWidth);
/// @brief Convert a triangle and quad mesh to an unsigned distance field.
///
/// @return a grid of type @c GridType containing a narrow-band unsigned
/// distance field representation of the input mesh.
///
/// @throw TypeError if @c GridType is not scalar or not floating-point
///
/// @note Does not requires a closed surface.
///
/// @param xform transform for the output grid
/// @param points list of world space point positions
/// @param triangles triangle index list
/// @param quads quad index list
/// @param bandWidth the width of the narrow band, in voxel units
template<typename GridType>
inline typename GridType::Ptr
meshToUnsignedDistanceField(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float bandWidth);
////////////////////////////////////////
/// @brief Return a grid of type @c GridType containing a narrow-band level set
/// representation of a box.
///
/// @param bbox a bounding box in world units
/// @param xform world-to-index-space transform
/// @param halfWidth half the width of the narrow band, in voxel units
template<typename GridType, typename VecType>
inline typename GridType::Ptr
createLevelSetBox(const math::BBox<VecType>& bbox,
const openvdb::math::Transform& xform,
typename VecType::ValueType halfWidth = LEVEL_SET_HALF_WIDTH);
////////////////////////////////////////
/// @brief Traces the exterior voxel boundary of closed objects in the input
/// volume @a tree. Exterior voxels are marked with a negative sign,
/// voxels with a value below @c 0.75 are left unchanged and act as
/// the boundary layer.
///
/// @note Does not propagate sign information into tile regions.
template <typename FloatTreeT>
inline void
traceExteriorBoundaries(FloatTreeT& tree);
////////////////////////////////////////
/// @brief Extracts and stores voxel edge intersection data from a mesh.
class MeshToVoxelEdgeData
{
public:
//////////
///@brief Internal edge data type.
struct EdgeData {
EdgeData(float dist = 1.0)
: mXDist(dist), mYDist(dist), mZDist(dist)
, mXPrim(util::INVALID_IDX)
, mYPrim(util::INVALID_IDX)
, mZPrim(util::INVALID_IDX)
{
}
//@{
/// Required by several of the tree nodes
/// @note These methods don't perform meaningful operations.
bool operator< (const EdgeData&) const { return false; }
bool operator> (const EdgeData&) const { return false; }
template<class T> EdgeData operator+(const T&) const { return *this; }
template<class T> EdgeData operator-(const T&) const { return *this; }
EdgeData operator-() const { return *this; }
//@}
bool operator==(const EdgeData& rhs) const
{
return mXPrim == rhs.mXPrim && mYPrim == rhs.mYPrim && mZPrim == rhs.mZPrim;
}
float mXDist, mYDist, mZDist;
Index32 mXPrim, mYPrim, mZPrim;
};
typedef tree::Tree4<EdgeData, 5, 4, 3>::Type TreeType;
typedef tree::ValueAccessor<TreeType> Accessor;
//////////
MeshToVoxelEdgeData();
/// @brief Threaded method to extract voxel edge data, the closest
/// intersection point and corresponding primitive index,
/// from the given mesh.
///
/// @param pointList List of points in grid index space, preferably unique
/// and shared by different polygons.
/// @param polygonList List of triangles and/or quads.
void convert(const std::vector<Vec3s>& pointList, const std::vector<Vec4I>& polygonList);
/// @brief Returns intersection points with corresponding primitive
/// indices for the given @c ijk voxel.
void getEdgeData(Accessor& acc, const Coord& ijk,
std::vector<Vec3d>& points, std::vector<Index32>& primitives);
/// @return An accessor of @c MeshToVoxelEdgeData::Accessor type that
/// provides random read access to the internal tree.
Accessor getAccessor() { return Accessor(mTree); }
private:
void operator=(const MeshToVoxelEdgeData&) {}
TreeType mTree;
class GenEdgeData;
};
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
// Internal utility objects and implementation details
namespace mesh_to_volume_internal {
template<typename PointType>
struct TransformPoints {
TransformPoints(const PointType* pointsIn, PointType* pointsOut,
const math::Transform& xform)
: mPointsIn(pointsIn), mPointsOut(pointsOut), mXform(&xform)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
Vec3d pos;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
const PointType& wsP = mPointsIn[n];
pos[0] = double(wsP[0]);
pos[1] = double(wsP[1]);
pos[2] = double(wsP[2]);
pos = mXform->worldToIndex(pos);
PointType& isP = mPointsOut[n];
isP[0] = typename PointType::value_type(pos[0]);
isP[1] = typename PointType::value_type(pos[1]);
isP[2] = typename PointType::value_type(pos[2]);
}
}
PointType const * const mPointsIn;
PointType * const mPointsOut;
math::Transform const * const mXform;
}; // TransformPoints
template<typename ValueType>
struct Tolerance
{
static ValueType epsilon() { return ValueType(1e-7); }
static ValueType minNarrowBandWidth() { return ValueType(1.0 + 1e-6); }
};
////////////////////////////////////////
template<typename TreeType>
class CombineLeafNodes
{
public:
typedef typename TreeType::template ValueConverter<Int32>::Type Int32TreeType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename Int32TreeType::LeafNodeType Int32LeafNodeType;
CombineLeafNodes(TreeType& lhsDistTree, Int32TreeType& lhsIdxTree,
LeafNodeType ** rhsDistNodes, Int32LeafNodeType ** rhsIdxNodes)
: mDistTree(&lhsDistTree)
, mIdxTree(&lhsIdxTree)
, mRhsDistNodes(rhsDistNodes)
, mRhsIdxNodes(rhsIdxNodes)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
tree::ValueAccessor<TreeType> distAcc(*mDistTree);
tree::ValueAccessor<Int32TreeType> idxAcc(*mIdxTree);
typedef typename LeafNodeType::ValueType DistValueType;
typedef typename Int32LeafNodeType::ValueType IndexValueType;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
const Coord& origin = mRhsDistNodes[n]->origin();
LeafNodeType* lhsDistNode = distAcc.probeLeaf(origin);
Int32LeafNodeType* lhsIdxNode = idxAcc.probeLeaf(origin);
DistValueType* lhsDistData = lhsDistNode->buffer().data();
IndexValueType* lhsIdxData = lhsIdxNode->buffer().data();
const DistValueType* rhsDistData = mRhsDistNodes[n]->buffer().data();
const IndexValueType* rhsIdxData = mRhsIdxNodes[n]->buffer().data();
for (Index32 offset = 0; offset < LeafNodeType::SIZE; ++offset) {
if (rhsIdxData[offset] != Int32(util::INVALID_IDX)) {
const DistValueType& lhsValue = lhsDistData[offset];
const DistValueType& rhsValue = rhsDistData[offset];
if (rhsValue < lhsValue) {
lhsDistNode->setValueOn(offset, rhsValue);
lhsIdxNode->setValueOn(offset, rhsIdxData[offset]);
} else if (math::isExactlyEqual(rhsValue, lhsValue)) {
lhsIdxNode->setValueOn(offset,
std::min(lhsIdxData[offset], rhsIdxData[offset]));
}
}
}
delete mRhsDistNodes[n];
delete mRhsIdxNodes[n];
}
}
private:
TreeType * const mDistTree;
Int32TreeType * const mIdxTree;
LeafNodeType ** const mRhsDistNodes;
Int32LeafNodeType ** const mRhsIdxNodes;
}; // class CombineLeafNodes
////////////////////////////////////////
template<typename TreeType>
struct StashOriginAndStoreOffset
{
typedef typename TreeType::LeafNodeType LeafNodeType;
StashOriginAndStoreOffset(std::vector<LeafNodeType*>& nodes, Coord* coordinates)
: mNodes(nodes.empty() ? NULL : &nodes[0]), mCoordinates(coordinates)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
Coord& origin = const_cast<Coord&>(mNodes[n]->origin());
mCoordinates[n] = origin;
origin[0] = static_cast<int>(n);
}
}
LeafNodeType ** const mNodes;
Coord * const mCoordinates;
};
template<typename TreeType>
struct RestoreOrigin
{
typedef typename TreeType::LeafNodeType LeafNodeType;
RestoreOrigin(std::vector<LeafNodeType*>& nodes, const Coord* coordinates)
: mNodes(nodes.empty() ? NULL : &nodes[0]), mCoordinates(coordinates)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
Coord& origin = const_cast<Coord&>(mNodes[n]->origin());
origin[0] = mCoordinates[n][0];
}
}
LeafNodeType ** const mNodes;
Coord const * const mCoordinates;
};
template<typename TreeType>
class ComputeNodeConnectivity
{
public:
typedef typename TreeType::LeafNodeType LeafNodeType;
ComputeNodeConnectivity(const TreeType& tree, const Coord* coordinates,
size_t* offsets, size_t numNodes, const CoordBBox& bbox)
: mTree(&tree)
, mCoordinates(coordinates)
, mOffsets(offsets)
, mNumNodes(numNodes)
, mBBox(bbox)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
size_t* offsetsNextX = mOffsets;
size_t* offsetsPrevX = mOffsets + mNumNodes;
size_t* offsetsNextY = mOffsets + mNumNodes * 2;
size_t* offsetsPrevY = mOffsets + mNumNodes * 3;
size_t* offsetsNextZ = mOffsets + mNumNodes * 4;
size_t* offsetsPrevZ = mOffsets + mNumNodes * 5;
tree::ValueAccessor<const TreeType> acc(*mTree);
Coord ijk;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
const Coord& origin = mCoordinates[n];
offsetsNextX[n] = findNeighbourNode(acc, origin, Coord(LeafNodeType::DIM, 0, 0));
offsetsPrevX[n] = findNeighbourNode(acc, origin, Coord(-LeafNodeType::DIM, 0, 0));
offsetsNextY[n] = findNeighbourNode(acc, origin, Coord(0, LeafNodeType::DIM, 0));
offsetsPrevY[n] = findNeighbourNode(acc, origin, Coord(0, -LeafNodeType::DIM, 0));
offsetsNextZ[n] = findNeighbourNode(acc, origin, Coord(0, 0, LeafNodeType::DIM));
offsetsPrevZ[n] = findNeighbourNode(acc, origin, Coord(0, 0, -LeafNodeType::DIM));
}
}
size_t findNeighbourNode(tree::ValueAccessor<const TreeType>& acc, const Coord& start, const Coord& step) const {
Coord ijk = start + step;
CoordBBox bbox(mBBox);
while (bbox.isInside(ijk)) {
const LeafNodeType* node = acc.probeConstLeaf(ijk);
if (node) return static_cast<size_t>(node->origin()[0]);
ijk += step;
}
return boost::integer_traits<size_t>::const_max;
}
private:
// Disallow assignment
ComputeNodeConnectivity& operator=(const ComputeNodeConnectivity&);
TreeType const * const mTree;
Coord const * const mCoordinates;
size_t * const mOffsets;
const size_t mNumNodes;
const CoordBBox mBBox;
}; // class ComputeNodeConnectivity
template<typename TreeType>
struct LeafNodeConnectivityTable {
enum { INVALID_OFFSET = boost::integer_traits<size_t>::const_max };
typedef typename TreeType::LeafNodeType LeafNodeType;
LeafNodeConnectivityTable(TreeType& tree)
: mLeafNodes()
, mOffsets(NULL)
{
mLeafNodes.reserve(tree.leafCount());
tree.getNodes(mLeafNodes);
if (mLeafNodes.empty()) return;
CoordBBox bbox;
tree.evalLeafBoundingBox(bbox);
const tbb::blocked_range<size_t> range(0, mLeafNodes.size());
// stash the leafnode origin coordinate and temporarily store the
// linear offset in the origin.x variable.
boost::scoped_array<Coord> coordinates(new Coord[mLeafNodes.size()]);
tbb::parallel_for(range, StashOriginAndStoreOffset<TreeType>(mLeafNodes, coordinates.get()));
// build the leafnode offset table
mOffsets.reset(new size_t[mLeafNodes.size() * 6]);
tbb::parallel_for(range,
ComputeNodeConnectivity<TreeType>(tree, coordinates.get(), mOffsets.get(), mLeafNodes.size(), bbox));
// restore the leafnode origin coordinate
tbb::parallel_for(range, RestoreOrigin<TreeType>(mLeafNodes, coordinates.get()));
}
size_t size() const { return mLeafNodes.size(); }
std::vector<LeafNodeType*>& nodes() { return mLeafNodes; }
const std::vector<LeafNodeType*>& nodes() const { return mLeafNodes; }
const size_t* offsetsNextX() const { return mOffsets.get(); }
const size_t* offsetsPrevX() const { return mOffsets.get() + mLeafNodes.size(); }
const size_t* offsetsNextY() const { return mOffsets.get() + mLeafNodes.size() * 2; }
const size_t* offsetsPrevY() const { return mOffsets.get() + mLeafNodes.size() * 3; }
const size_t* offsetsNextZ() const { return mOffsets.get() + mLeafNodes.size() * 4; }
const size_t* offsetsPrevZ() const { return mOffsets.get() + mLeafNodes.size() * 5; }
private:
std::vector<LeafNodeType*> mLeafNodes;
boost::scoped_array<size_t> mOffsets;
}; // struct LeafNodeConnectivityTable
template<typename TreeType>
class SweepExteriorSign
{
public:
enum Axis { X_AXIS = 0, Y_AXIS = 1, Z_AXIS = 2 };
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef LeafNodeConnectivityTable<TreeType> ConnectivityTable;
SweepExteriorSign(Axis axis, const std::vector<size_t>& startNodeIndices, ConnectivityTable& connectivity)
: mStartNodeIndices(startNodeIndices.empty() ? NULL : &startNodeIndices[0])
, mConnectivity(&connectivity)
, mAxis(axis)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
std::vector<LeafNodeType*>& nodes = mConnectivity->nodes();
// Z Axis
size_t idxA = 0, idxB = 1;
Index step = 1;
const size_t* nextOffsets = mConnectivity->offsetsNextZ();
const size_t* prevOffsets = mConnectivity->offsetsPrevZ();
if (mAxis == Y_AXIS) {
idxA = 0;
idxB = 2;
step = LeafNodeType::DIM;
nextOffsets = mConnectivity->offsetsNextY();
prevOffsets = mConnectivity->offsetsPrevY();
} else if (mAxis == X_AXIS) {
idxA = 1;
idxB = 2;
step = LeafNodeType::DIM * LeafNodeType::DIM;
nextOffsets = mConnectivity->offsetsNextX();
prevOffsets = mConnectivity->offsetsPrevX();
}
Coord ijk(0, 0, 0);
int& a = ijk[idxA];
int& b = ijk[idxB];
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
size_t startOffset = mStartNodeIndices[n];
size_t lastOffset = startOffset;
Index pos(0);
for (a = 0; a < int(LeafNodeType::DIM); ++a) {
for (b = 0; b < int(LeafNodeType::DIM); ++b) {
pos = LeafNodeType::coordToOffset(ijk);
size_t offset = startOffset;
// sweep in +axis direction until a boundary voxel is hit.
while ( offset != ConnectivityTable::INVALID_OFFSET &&
traceVoxelLine(*nodes[offset], pos, step) ) {
lastOffset = offset;
offset = nextOffsets[offset];
}
// find last leafnode in +axis direction
offset = lastOffset;
while (offset != ConnectivityTable::INVALID_OFFSET) {
lastOffset = offset;
offset = nextOffsets[offset];
}
// sweep in -axis direction until a boundary voxel is hit.
offset = lastOffset;
pos += step * (LeafNodeType::DIM - 1);
while ( offset != ConnectivityTable::INVALID_OFFSET &&
traceVoxelLine(*nodes[offset], pos, -step)) {
offset = prevOffsets[offset];
}
}
}
}
}
bool traceVoxelLine(LeafNodeType& node, Index pos, Index step) const {
ValueType* data = node.buffer().data();
bool isOutside = true;
for (Index i = 0; i < LeafNodeType::DIM; ++i) {
ValueType& dist = data[pos];
if (dist < ValueType(0.0)) {
isOutside = true;
} else {
// Boundary voxel check. (Voxel that intersects the surface)
if (!(dist > ValueType(0.75))) isOutside = false;
if (isOutside) dist = ValueType(-dist);
}
pos += step;
}
return isOutside;
}
private:
size_t const * const mStartNodeIndices;
ConnectivityTable * const mConnectivity;
const Axis mAxis;
}; // class SweepExteriorSign
template<typename LeafNodeType>
inline void
seedFill(LeafNodeType& node)
{
typedef typename LeafNodeType::ValueType ValueType;
typedef std::deque<Index> Queue;
ValueType* data = node.buffer().data();
// find seed points
Queue seedPoints;
for (Index pos = 0; pos < LeafNodeType::SIZE; ++pos) {
if (data[pos] < 0.0) seedPoints.push_back(pos);
}
if (seedPoints.empty()) return;
// clear sign information
for (Queue::iterator it = seedPoints.begin(); it != seedPoints.end(); ++it) {
ValueType& dist = data[*it];
dist = -dist;
}
// flood fill
Coord ijk(0, 0, 0);
Index pos(0), nextPos(0);
while (!seedPoints.empty()) {
pos = seedPoints.back();
seedPoints.pop_back();
ValueType& dist = data[pos];
if (!(dist < ValueType(0.0))) {
dist = -dist; // flip sign
ijk = LeafNodeType::offsetToLocalCoord(pos);
if (ijk[0] != 0) { // i - 1, j, k
nextPos = pos - LeafNodeType::DIM * LeafNodeType::DIM;
if (data[nextPos] > ValueType(0.75)) seedPoints.push_back(nextPos);
}
if (ijk[0] != (LeafNodeType::DIM - 1)) { // i + 1, j, k
nextPos = pos + LeafNodeType::DIM * LeafNodeType::DIM;
if (data[nextPos] > ValueType(0.75)) seedPoints.push_back(nextPos);
}
if (ijk[1] != 0) { // i, j - 1, k
nextPos = pos - LeafNodeType::DIM;
if (data[nextPos] > ValueType(0.75)) seedPoints.push_back(nextPos);
}
if (ijk[1] != (LeafNodeType::DIM - 1)) { // i, j + 1, k
nextPos = pos + LeafNodeType::DIM;
if (data[nextPos] > ValueType(0.75)) seedPoints.push_back(nextPos);
}
if (ijk[2] != 0) { // i, j, k - 1
nextPos = pos - 1;
if (data[nextPos] > ValueType(0.75)) seedPoints.push_back(nextPos);
}
if (ijk[2] != (LeafNodeType::DIM - 1)) { // i, j, k + 1
nextPos = pos + 1;
if (data[nextPos] > ValueType(0.75)) seedPoints.push_back(nextPos);
}
}
}
} // seedFill()
template<typename LeafNodeType>
inline bool
scanFill(LeafNodeType& node)
{
bool updatedNode = false;
typedef typename LeafNodeType::ValueType ValueType;
ValueType* data = node.buffer().data();
Coord ijk(0, 0, 0);
bool updatedSign = true;
while (updatedSign) {
updatedSign = false;
for (Index pos = 0; pos < LeafNodeType::SIZE; ++pos) {
ValueType& dist = data[pos];
if (!(dist < ValueType(0.0)) && dist > ValueType(0.75)) {
ijk = LeafNodeType::offsetToLocalCoord(pos);
// i, j, k - 1
if (ijk[2] != 0 && data[pos - 1] < ValueType(0.0)) {
updatedSign = true;
dist = ValueType(-dist);
// i, j, k + 1
} else if (ijk[2] != (LeafNodeType::DIM - 1) && data[pos + 1] < ValueType(0.0)) {
updatedSign = true;
dist = ValueType(-dist);
// i, j - 1, k
} else if (ijk[1] != 0 && data[pos - LeafNodeType::DIM] < ValueType(0.0)) {
updatedSign = true;
dist = ValueType(-dist);
// i, j + 1, k
} else if (ijk[1] != (LeafNodeType::DIM - 1) && data[pos + LeafNodeType::DIM] < ValueType(0.0)) {
updatedSign = true;
dist = ValueType(-dist);
// i - 1, j, k
} else if (ijk[0] != 0 && data[pos - LeafNodeType::DIM * LeafNodeType::DIM] < ValueType(0.0)) {
updatedSign = true;
dist = ValueType(-dist);
// i + 1, j, k
} else if (ijk[0] != (LeafNodeType::DIM - 1) && data[pos + LeafNodeType::DIM * LeafNodeType::DIM] < ValueType(0.0)) {
updatedSign = true;
dist = ValueType(-dist);
}
}
} // end value loop
updatedNode |= updatedSign;
} // end update loop
return updatedNode;
} // scanFill()
template<typename TreeType>
class SeedFillExteriorSign
{
public:
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
SeedFillExteriorSign(std::vector<LeafNodeType*>& nodes, bool* changedNodeMask)
: mNodes(nodes.empty() ? NULL : &nodes[0])
, mChangedNodeMask(changedNodeMask)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
if (mChangedNodeMask[n]) {
//seedFill(*mNodes[n]);
mChangedNodeMask[n] = scanFill(*mNodes[n]);
}
}
}
LeafNodeType ** const mNodes;
bool * const mChangedNodeMask;
};
template<typename ValueType>
struct FillArray
{
FillArray(ValueType* array, const ValueType v) : mArray(array), mValue(v) { }
void operator()(const tbb::blocked_range<size_t>& range) const {
const ValueType v = mValue;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
mArray[n] = v;
}
}
ValueType * const mArray;
const ValueType mValue;
};
template<typename ValueType>
inline void
fillArray(ValueType* array, const ValueType val, const size_t length)
{
const size_t grainSize = length / tbb::task_scheduler_init::default_num_threads();
const tbb::blocked_range<size_t> range(0, length, grainSize);
tbb::parallel_for(range, FillArray<ValueType>(array, val), tbb::simple_partitioner());
}
template<typename TreeType>
class SyncVoxelMask
{
public:
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
SyncVoxelMask(std::vector<LeafNodeType*>& nodes, const bool* changedNodeMask, bool* changedVoxelMask)
: mNodes(nodes.empty() ? NULL : &nodes[0])
, mChangedNodeMask(changedNodeMask)
, mChangedVoxelMask(changedVoxelMask)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
if (mChangedNodeMask[n]) {
bool* mask = &mChangedVoxelMask[n * LeafNodeType::SIZE];
ValueType* data = mNodes[n]->buffer().data();
for (Index pos = 0; pos < LeafNodeType::SIZE; ++pos) {
if (mask[pos]) {
data[pos] = ValueType(-data[pos]);
mask[pos] = false;
}
}
}
}
}
LeafNodeType ** const mNodes;
bool const * const mChangedNodeMask;
bool * const mChangedVoxelMask;
};
template<typename TreeType>
class SeedPoints
{
public:
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef LeafNodeConnectivityTable<TreeType> ConnectivityTable;
SeedPoints(ConnectivityTable& connectivity, bool* changedNodeMask, bool* nodeMask, bool* changedVoxelMask)
: mConnectivity(&connectivity)
, mChangedNodeMask(changedNodeMask)
, mNodeMask(nodeMask)
, mChangedVoxelMask(changedVoxelMask)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
if (!mChangedNodeMask[n]) {
bool changedValue = false;
changedValue |= processZ(n, /*firstFace=*/true);
changedValue |= processZ(n, /*firstFace=*/false);
changedValue |= processY(n, /*firstFace=*/true);
changedValue |= processY(n, /*firstFace=*/false);
changedValue |= processX(n, /*firstFace=*/true);
changedValue |= processX(n, /*firstFace=*/false);
mNodeMask[n] = changedValue;
}
}
}
bool processZ(const size_t n, bool firstFace) const
{
const size_t offset = firstFace ? mConnectivity->offsetsPrevZ()[n] : mConnectivity->offsetsNextZ()[n];
if (offset != ConnectivityTable::INVALID_OFFSET && mChangedNodeMask[offset]) {
bool* mask = &mChangedVoxelMask[n * LeafNodeType::SIZE];
const ValueType* lhsData = mConnectivity->nodes()[n]->buffer().data();
const ValueType* rhsData = mConnectivity->nodes()[offset]->buffer().data();
const Index lastOffset = LeafNodeType::DIM - 1;
const Index lhsOffset = firstFace ? 0 : lastOffset, rhsOffset = firstFace ? lastOffset : 0;
Index tmpPos(0), pos(0);
bool changedValue = false;
for (Index x = 0; x < LeafNodeType::DIM; ++x) {
tmpPos = x << (2 * LeafNodeType::LOG2DIM);
for (Index y = 0; y < LeafNodeType::DIM; ++y) {
pos = tmpPos + (y << LeafNodeType::LOG2DIM);
if (lhsData[pos + lhsOffset] > ValueType(0.75)) {
if (rhsData[pos + rhsOffset] < ValueType(0.0)) {
changedValue = true;
mask[pos + lhsOffset] = true;
}
}
}
}
return changedValue;
}
return false;
}
bool processY(const size_t n, bool firstFace) const
{
const size_t offset = firstFace ? mConnectivity->offsetsPrevY()[n] : mConnectivity->offsetsNextY()[n];
if (offset != ConnectivityTable::INVALID_OFFSET && mChangedNodeMask[offset]) {
bool* mask = &mChangedVoxelMask[n * LeafNodeType::SIZE];
const ValueType* lhsData = mConnectivity->nodes()[n]->buffer().data();
const ValueType* rhsData = mConnectivity->nodes()[offset]->buffer().data();
const Index lastOffset = LeafNodeType::DIM * (LeafNodeType::DIM - 1);
const Index lhsOffset = firstFace ? 0 : lastOffset, rhsOffset = firstFace ? lastOffset : 0;
Index tmpPos(0), pos(0);
bool changedValue = false;
for (Index x = 0; x < LeafNodeType::DIM; ++x) {
tmpPos = x << (2 * LeafNodeType::LOG2DIM);
for (Index z = 0; z < LeafNodeType::DIM; ++z) {
pos = tmpPos + z;
if (lhsData[pos + lhsOffset] > ValueType(0.75)) {
if (rhsData[pos + rhsOffset] < ValueType(0.0)) {
changedValue = true;
mask[pos + lhsOffset] = true;
}
}
}
}
return changedValue;
}
return false;
}
bool processX(const size_t n, bool firstFace) const
{
const size_t offset = firstFace ? mConnectivity->offsetsPrevX()[n] : mConnectivity->offsetsNextX()[n];
if (offset != ConnectivityTable::INVALID_OFFSET && mChangedNodeMask[offset]) {
bool* mask = &mChangedVoxelMask[n * LeafNodeType::SIZE];
const ValueType* lhsData = mConnectivity->nodes()[n]->buffer().data();
const ValueType* rhsData = mConnectivity->nodes()[offset]->buffer().data();
const Index lastOffset = LeafNodeType::DIM * LeafNodeType::DIM * (LeafNodeType::DIM - 1);
const Index lhsOffset = firstFace ? 0 : lastOffset, rhsOffset = firstFace ? lastOffset : 0;
Index tmpPos(0), pos(0);
bool changedValue = false;
for (Index y = 0; y < LeafNodeType::DIM; ++y) {
tmpPos = y << LeafNodeType::LOG2DIM;
for (Index z = 0; z < LeafNodeType::DIM; ++z) {
pos = tmpPos + z;
if (lhsData[pos + lhsOffset] > ValueType(0.75)) {
if (rhsData[pos + rhsOffset] < ValueType(0.0)) {
changedValue = true;
mask[pos + lhsOffset] = true;
}
}
}
}
return changedValue;
}
return false;
}
ConnectivityTable * const mConnectivity;
bool * const mChangedNodeMask;
bool * const mNodeMask;
bool * const mChangedVoxelMask;
};
////////////////////////////////////////
template<typename TreeType, typename MeshDataAdapter>
struct ComputeIntersectingVoxelSign
{
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::template ValueConverter<Int32>::Type Int32TreeType;
typedef typename Int32TreeType::LeafNodeType Int32LeafNodeType;
typedef std::pair<boost::shared_array<Vec3d>, boost::shared_array<bool> > LocalData;
typedef tbb::enumerable_thread_specific<LocalData> LocalDataTable;
ComputeIntersectingVoxelSign(
std::vector<LeafNodeType*>& distNodes,
const TreeType& distTree,
const Int32TreeType& indexTree,
const MeshDataAdapter& mesh)
: mDistNodes(distNodes.empty() ? NULL : &distNodes[0])
, mDistTree(&distTree)
, mIndexTree(&indexTree)
, mMesh(&mesh)
, mLocalDataTable(new LocalDataTable())
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
tree::ValueAccessor<const TreeType> distAcc(*mDistTree);
tree::ValueAccessor<const Int32TreeType> idxAcc(*mIndexTree);
ValueType nval;
CoordBBox bbox;
Index xPos(0), yPos(0);
Coord ijk, nijk, nodeMin, nodeMax;
Vec3d cp, xyz, nxyz, dir1, dir2;
LocalData& localData = mLocalDataTable->local();
boost::shared_array<Vec3d>& points = localData.first;
if (!points) points.reset(new Vec3d[LeafNodeType::SIZE * 2]);
boost::shared_array<bool>& mask = localData.second;
if (!mask) mask.reset(new bool[LeafNodeType::SIZE]);
typename LeafNodeType::ValueOnCIter it;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
LeafNodeType& node = *mDistNodes[n];
ValueType* data = node.buffer().data();
const Int32LeafNodeType* idxNode = idxAcc.probeConstLeaf(node.origin());
const Int32* idxData = idxNode->buffer().data();
nodeMin = node.origin();
nodeMax = nodeMin.offsetBy(LeafNodeType::DIM - 1);
// reset computed voxel mask.
memset(mask.get(), 0, sizeof(bool) * LeafNodeType::SIZE);
for (it = node.cbeginValueOn(); it; ++it) {
Index pos = it.pos();
ValueType& dist = data[pos];
if (dist < 0.0 || dist > 0.75) continue;
ijk = node.offsetToGlobalCoord(pos);
xyz[0] = double(ijk[0]);
xyz[1] = double(ijk[1]);
xyz[2] = double(ijk[2]);
bbox.min() = Coord::maxComponent(ijk.offsetBy(-1), nodeMin);
bbox.max() = Coord::minComponent(ijk.offsetBy(1), nodeMax);
bool flipSign = false;
for (nijk[0] = bbox.min()[0]; nijk[0] <= bbox.max()[0] && !flipSign; ++nijk[0]) {
xPos = (nijk[0] & (LeafNodeType::DIM - 1u)) << (2 * LeafNodeType::LOG2DIM);
for (nijk[1] = bbox.min()[1]; nijk[1] <= bbox.max()[1] && !flipSign; ++nijk[1]) {
yPos = xPos + ((nijk[1] & (LeafNodeType::DIM - 1u)) << LeafNodeType::LOG2DIM);
for (nijk[2] = bbox.min()[2]; nijk[2] <= bbox.max()[2]; ++nijk[2]) {
pos = yPos + (nijk[2] & (LeafNodeType::DIM - 1u));
const Int32& polyIdx = idxData[pos];
if (polyIdx == Int32(util::INVALID_IDX) || !(data[pos] < -0.75)) continue;
const Index pointIndex = pos * 2;
if (!mask[pos]) {
mask[pos] = true;
nxyz[0] = double(nijk[0]);
nxyz[1] = double(nijk[1]);
nxyz[2] = double(nijk[2]);
Vec3d& point = points[pointIndex];
point = closestPoint(nxyz, polyIdx);
Vec3d& direction = points[pointIndex + 1];
direction = nxyz - point;
direction.normalize();
}
dir1 = xyz - points[pointIndex];
dir1.normalize();
if (points[pointIndex + 1].dot(dir1) > 0.0) {
flipSign = true;
break;
}
}
}
}
if (flipSign) {
dist = -dist;
} else {
for (Int32 m = 0; m < 26; ++m) {
nijk = ijk + util::COORD_OFFSETS[m];
if (!bbox.isInside(nijk) && distAcc.probeValue(nijk, nval) && nval < -0.75) {
nxyz[0] = double(nijk[0]);
nxyz[1] = double(nijk[1]);
nxyz[2] = double(nijk[2]);
cp = closestPoint(nxyz, idxAcc.getValue(nijk));
dir1 = xyz - cp;
dir1.normalize();
dir2 = nxyz - cp;
dir2.normalize();
if (dir2.dot(dir1) > 0.0) {
dist = -dist;
break;
}
}
}
}
} // active voxel loop
} // leaf node loop
}
private:
Vec3d closestPoint(const Vec3d& center, Int32 polyIdx) const
{
Vec3d a, b, c, cp, uvw;
const size_t polygon = size_t(polyIdx);
mMesh->getIndexSpacePoint(polygon, 0, a);
mMesh->getIndexSpacePoint(polygon, 1, b);
mMesh->getIndexSpacePoint(polygon, 2, c);
cp = closestPointOnTriangleToPoint(a, c, b, center, uvw);
if (4 == mMesh->vertexCount(polygon)) {
mMesh->getIndexSpacePoint(polygon, 3, b);
c = closestPointOnTriangleToPoint(a, b, c, center, uvw);
if ((center - c).lengthSqr() < (center - cp).lengthSqr()) {
cp = c;
}
}
return cp;
}
LeafNodeType ** const mDistNodes;
TreeType const * const mDistTree;
Int32TreeType const * const mIndexTree;
MeshDataAdapter const * const mMesh;
boost::shared_ptr<LocalDataTable> mLocalDataTable;
}; // ComputeIntersectingVoxelSign
////////////////////////////////////////
template<typename LeafNodeType>
inline void
maskNodeInternalNeighbours(const Index pos, bool (&mask)[26])
{
typedef LeafNodeType NodeT;
const Coord ijk = NodeT::offsetToLocalCoord(pos);
// Face adjacent neighbours
// i+1, j, k
mask[0] = ijk[0] != (NodeT::DIM - 1);
// i-1, j, k
mask[1] = ijk[0] != 0;
// i, j+1, k
mask[2] = ijk[1] != (NodeT::DIM - 1);
// i, j-1, k
mask[3] = ijk[1] != 0;
// i, j, k+1
mask[4] = ijk[2] != (NodeT::DIM - 1);
// i, j, k-1
mask[5] = ijk[2] != 0;
// Edge adjacent neighbour
// i+1, j, k-1
mask[6] = mask[0] && mask[5];
// i-1, j, k-1
mask[7] = mask[1] && mask[5];
// i+1, j, k+1
mask[8] = mask[0] && mask[4];
// i-1, j, k+1
mask[9] = mask[1] && mask[4];
// i+1, j+1, k
mask[10] = mask[0] && mask[2];
// i-1, j+1, k
mask[11] = mask[1] && mask[2];
// i+1, j-1, k
mask[12] = mask[0] && mask[3];
// i-1, j-1, k
mask[13] = mask[1] && mask[3];
// i, j-1, k+1
mask[14] = mask[3] && mask[4];
// i, j-1, k-1
mask[15] = mask[3] && mask[5];
// i, j+1, k+1
mask[16] = mask[2] && mask[4];
// i, j+1, k-1
mask[17] = mask[2] && mask[5];
// Corner adjacent neighbours
// i-1, j-1, k-1
mask[18] = mask[1] && mask[3] && mask[5];
// i-1, j-1, k+1
mask[19] = mask[1] && mask[3] && mask[4];
// i+1, j-1, k+1
mask[20] = mask[0] && mask[3] && mask[4];
// i+1, j-1, k-1
mask[21] = mask[0] && mask[3] && mask[5];
// i-1, j+1, k-1
mask[22] = mask[1] && mask[2] && mask[5];
// i-1, j+1, k+1
mask[23] = mask[1] && mask[2] && mask[4];
// i+1, j+1, k+1
mask[24] = mask[0] && mask[2] && mask[4];
// i+1, j+1, k-1
mask[25] = mask[0] && mask[2] && mask[5];
}
template<typename Compare, typename LeafNodeType>
inline bool
checkNeighbours(const Index pos, const typename LeafNodeType::ValueType * data, bool (&mask)[26])
{
typedef LeafNodeType NodeT;
// i, j, k - 1
if (mask[5] && Compare::check(data[pos - 1])) return true;
// i, j, k + 1
if (mask[4] && Compare::check(data[pos + 1])) return true;
// i, j - 1, k
if (mask[3] && Compare::check(data[pos - NodeT::DIM])) return true;
// i, j + 1, k
if (mask[2] && Compare::check(data[pos + NodeT::DIM])) return true;
// i - 1, j, k
if (mask[1] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM])) return true;
// i + 1, j, k
if (mask[0] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM])) return true;
// i+1, j, k-1
if (mask[6] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM])) return true;
// i-1, j, k-1
if (mask[7] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM - 1])) return true;
// i+1, j, k+1
if (mask[8] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM + 1])) return true;
// i-1, j, k+1
if (mask[9] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM + 1])) return true;
// i+1, j+1, k
if (mask[10] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM + NodeT::DIM])) return true;
// i-1, j+1, k
if (mask[11] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM + NodeT::DIM])) return true;
// i+1, j-1, k
if (mask[12] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM - NodeT::DIM])) return true;
// i-1, j-1, k
if (mask[13] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM - NodeT::DIM])) return true;
// i, j-1, k+1
if (mask[14] && Compare::check(data[pos - NodeT::DIM + 1])) return true;
// i, j-1, k-1
if (mask[15] && Compare::check(data[pos - NodeT::DIM - 1])) return true;
// i, j+1, k+1
if (mask[16] && Compare::check(data[pos + NodeT::DIM + 1])) return true;
// i, j+1, k-1
if (mask[17] && Compare::check(data[pos + NodeT::DIM - 1])) return true;
// i-1, j-1, k-1
if (mask[18] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM - NodeT::DIM - 1])) return true;
// i-1, j-1, k+1
if (mask[19] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM - NodeT::DIM + 1])) return true;
// i+1, j-1, k+1
if (mask[20] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM - NodeT::DIM + 1])) return true;
// i+1, j-1, k-1
if (mask[21] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM - NodeT::DIM - 1])) return true;
// i-1, j+1, k-1
if (mask[22] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM + NodeT::DIM - 1])) return true;
// i-1, j+1, k+1
if (mask[23] && Compare::check(data[pos - NodeT::DIM * NodeT::DIM + NodeT::DIM + 1])) return true;
// i+1, j+1, k+1
if (mask[24] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM + NodeT::DIM + 1])) return true;
// i+1, j+1, k-1
if (mask[25] && Compare::check(data[pos + NodeT::DIM * NodeT::DIM + NodeT::DIM - 1])) return true;
return false;
}
template<typename Compare, typename AccessorType>
inline bool
checkNeighbours(const Coord& ijk, AccessorType& acc, bool (&mask)[26])
{
for (Int32 m = 0; m < 26; ++m) {
if (!mask[m] && Compare::check(acc.getValue(ijk + util::COORD_OFFSETS[m]))) {
return true;
}
}
return false;
}
template<typename TreeType>
struct ValidateIntersectingVoxels
{
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
struct IsNegative { static bool check(const ValueType v) { return v < ValueType(0.0); } };
ValidateIntersectingVoxels(TreeType& tree, std::vector<LeafNodeType*>& nodes)
: mTree(&tree)
, mNodes(nodes.empty() ? NULL : &nodes[0])
{
}
void operator()(const tbb::blocked_range<size_t>& range) const
{
tree::ValueAccessor<const TreeType> acc(*mTree);
bool neighbourMask[26];
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
LeafNodeType& node = *mNodes[n];
ValueType* data = node.buffer().data();
typename LeafNodeType::ValueOnCIter it;
for (it = node.cbeginValueOn(); it; ++it) {
const Index pos = it.pos();
ValueType& dist = data[pos];
if (dist < 0.0 || dist > 0.75) continue;
// Mask node internal neighbours
maskNodeInternalNeighbours<LeafNodeType>(pos, neighbourMask);
const bool hasNegativeNeighbour =
checkNeighbours<IsNegative, LeafNodeType>(pos, data, neighbourMask) ||
checkNeighbours<IsNegative>(node.offsetToGlobalCoord(pos), acc, neighbourMask);
if (!hasNegativeNeighbour) {
// push over boundary voxel distance
dist = ValueType(0.75) + Tolerance<ValueType>::epsilon();
}
}
}
}
TreeType * const mTree;
LeafNodeType ** const mNodes;
}; // ValidateIntersectingVoxels
template<typename TreeType>
struct RemoveSelfIntersectingSurface
{
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::template ValueConverter<Int32>::Type Int32TreeType;
struct Comp { static bool check(const ValueType v) { return !(v > ValueType(0.75)); } };
RemoveSelfIntersectingSurface(std::vector<LeafNodeType*>& nodes,
TreeType& distTree, Int32TreeType& indexTree)
: mNodes(nodes.empty() ? NULL : &nodes[0])
, mDistTree(&distTree)
, mIndexTree(&indexTree)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const
{
tree::ValueAccessor<const TreeType> distAcc(*mDistTree);
tree::ValueAccessor<Int32TreeType> idxAcc(*mIndexTree);
bool neighbourMask[26];
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
LeafNodeType& distNode = *mNodes[n];
ValueType* data = distNode.buffer().data();
typename Int32TreeType::LeafNodeType* idxNode =
idxAcc.probeLeaf(distNode.origin());
typename LeafNodeType::ValueOnCIter it;
for (it = distNode.cbeginValueOn(); it; ++it) {
const Index pos = it.pos();
if (!(data[pos] > 0.75)) continue;
// Mask node internal neighbours
maskNodeInternalNeighbours<LeafNodeType>(pos, neighbourMask);
const bool hasBoundaryNeighbour =
checkNeighbours<Comp, LeafNodeType>(pos, data, neighbourMask) ||
checkNeighbours<Comp>(distNode.offsetToGlobalCoord(pos), distAcc, neighbourMask);
if (!hasBoundaryNeighbour) {
distNode.setValueOff(pos);
idxNode->setValueOff(pos);
}
}
}
}
LeafNodeType * * const mNodes;
TreeType * const mDistTree;
Int32TreeType * const mIndexTree;
}; // RemoveSelfIntersectingSurface
////////////////////////////////////////
template<typename NodeType>
struct ReleaseChildNodes
{
ReleaseChildNodes(NodeType ** nodes) : mNodes(nodes) {}
void operator()(const tbb::blocked_range<size_t>& range) const {
typedef typename NodeType::NodeMaskType NodeMaskType;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
const_cast<NodeMaskType&>(mNodes[n]->getChildMask()).setOff();
}
}
NodeType ** const mNodes;
};
template<typename TreeType>
inline void
releaseLeafNodes(TreeType& tree)
{
typedef typename TreeType::RootNodeType RootNodeType;
typedef typename RootNodeType::NodeChainType NodeChainType;
typedef typename boost::mpl::at<NodeChainType, boost::mpl::int_<1> >::type InternalNodeType;
std::vector<InternalNodeType*> nodes;
tree.getNodes(nodes);
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
ReleaseChildNodes<InternalNodeType>(nodes.empty() ? NULL : &nodes[0]));
}
template<typename TreeType>
struct StealUniqueLeafNodes
{
typedef typename TreeType::LeafNodeType LeafNodeType;
StealUniqueLeafNodes(TreeType& lhsTree, TreeType& rhsTree,
std::vector<LeafNodeType*>& overlappingNodes)
: mLhsTree(&lhsTree)
, mRhsTree(&rhsTree)
, mNodes(&overlappingNodes)
{
}
void operator()() const {
std::vector<LeafNodeType*> rhsLeafNodes;
rhsLeafNodes.reserve(mRhsTree->leafCount());
//mRhsTree->getNodes(rhsLeafNodes);
//releaseLeafNodes(*mRhsTree);
mRhsTree->stealNodes(rhsLeafNodes);
tree::ValueAccessor<TreeType> acc(*mLhsTree);
for (size_t n = 0, N = rhsLeafNodes.size(); n < N; ++n) {
if (!acc.probeLeaf(rhsLeafNodes[n]->origin())) {
acc.addLeaf(rhsLeafNodes[n]);
} else {
mNodes->push_back(rhsLeafNodes[n]);
}
}
}
private:
TreeType * const mLhsTree;
TreeType * const mRhsTree;
std::vector<LeafNodeType*> * const mNodes;
};
template<typename DistTreeType, typename IndexTreeType>
inline void
combineData(DistTreeType& lhsDist, IndexTreeType& lhsIdx,
DistTreeType& rhsDist, IndexTreeType& rhsIdx)
{
typedef typename DistTreeType::LeafNodeType DistLeafNodeType;
typedef typename IndexTreeType::LeafNodeType IndexLeafNodeType;
std::vector<DistLeafNodeType*> overlappingDistNodes;
std::vector<IndexLeafNodeType*> overlappingIdxNodes;
// Steal unique leafnodes
tbb::task_group tasks;
tasks.run(StealUniqueLeafNodes<DistTreeType>(lhsDist, rhsDist, overlappingDistNodes));
tasks.run(StealUniqueLeafNodes<IndexTreeType>(lhsIdx, rhsIdx, overlappingIdxNodes));
tasks.wait();
// Combine overlapping leaf nodes
if (!overlappingDistNodes.empty() && !overlappingIdxNodes.empty()) {
tbb::parallel_for(tbb::blocked_range<size_t>(0, overlappingDistNodes.size()),
CombineLeafNodes<DistTreeType>(lhsDist, lhsIdx, &overlappingDistNodes[0], &overlappingIdxNodes[0]));
}
}
/// @brief TBB body object to voxelize a mesh of triangles and/or quads into a collection
/// of VDB grids, namely a squared distance grid, a closest primitive grid and an
/// intersecting voxels grid (masks the mesh intersecting voxels)
/// @note Only the leaf nodes that intersect the mesh are allocated, and only voxels in
/// a narrow band (of two to three voxels in proximity to the mesh's surface) are activated.
/// They are populated with distance values and primitive indices.
template<typename TreeType>
struct VoxelizationData {
typedef boost::scoped_ptr<VoxelizationData> Ptr;
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::template ValueConverter<Int32>::Type Int32TreeType;
typedef typename TreeType::template ValueConverter<unsigned char>::Type UCharTreeType;
typedef tree::ValueAccessor<TreeType> FloatTreeAcc;
typedef tree::ValueAccessor<Int32TreeType> Int32TreeAcc;
typedef tree::ValueAccessor<UCharTreeType> UCharTreeAcc;
VoxelizationData()
: distTree(std::numeric_limits<ValueType>::max())
, distAcc(distTree)
, indexTree(Int32(util::INVALID_IDX))
, indexAcc(indexTree)
, primIdTree(MaxPrimId)
, primIdAcc(primIdTree)
, mPrimCount(0)
{
}
TreeType distTree;
FloatTreeAcc distAcc;
Int32TreeType indexTree;
Int32TreeAcc indexAcc;
UCharTreeType primIdTree;
UCharTreeAcc primIdAcc;
unsigned char getNewPrimId() {
if (mPrimCount == MaxPrimId || primIdTree.leafCount() > 1000) {
mPrimCount = 0;
primIdTree.clear();
}
return mPrimCount++;
}
private:
enum { MaxPrimId = 100 };
unsigned char mPrimCount;
};
template<typename TreeType, typename MeshDataAdapter, typename Interrupter = util::NullInterrupter>
class VoxelizePolygons
{
public:
typedef VoxelizationData<TreeType> VoxelizationDataType;
typedef tbb::enumerable_thread_specific<typename VoxelizationDataType::Ptr> DataTable;
VoxelizePolygons(DataTable& dataTable,
const MeshDataAdapter& mesh,
Interrupter* interrupter = NULL)
: mDataTable(&dataTable)
, mMesh(&mesh)
, mInterrupter(interrupter)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
typename VoxelizationDataType::Ptr& dataPtr = mDataTable->local();
if (!dataPtr) dataPtr.reset(new VoxelizationDataType());
Triangle prim;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
if (this->wasInterrupted()) {
tbb::task::self().cancel_group_execution();
break;
}
const size_t numVerts = mMesh->vertexCount(n);
// rasterize triangles and quads.
if (numVerts == 3 || numVerts == 4) {
prim.index = Int32(n);
mMesh->getIndexSpacePoint(n, 0, prim.a);
mMesh->getIndexSpacePoint(n, 1, prim.b);
mMesh->getIndexSpacePoint(n, 2, prim.c);
evalTriangle(prim, *dataPtr);
if (numVerts == 4) {
mMesh->getIndexSpacePoint(n, 3, prim.b);
evalTriangle(prim, *dataPtr);
}
}
}
}
private:
bool wasInterrupted() const { return mInterrupter && mInterrupter->wasInterrupted(); }
struct Triangle { Vec3d a, b, c; Int32 index; };
struct SubTask
{
SubTask(const Triangle& prim, DataTable& dataTable, size_t polygonCount)
: mLocalDataTable(&dataTable)
, mPrim(prim)
, mPolygonCount(polygonCount)
{
}
void operator()() const
{
const size_t minNumTask = size_t(tbb::task_scheduler_init::default_num_threads() * 10);
if (mPolygonCount > minNumTask) {
typename VoxelizationDataType::Ptr& dataPtr = mLocalDataTable->local();
if (!dataPtr) dataPtr.reset(new VoxelizationDataType());
voxelizeTriangle(mPrim, *dataPtr);
} else {
spawnTasks(mPrim, *mLocalDataTable, mPolygonCount);
}
}
DataTable * const mLocalDataTable;
const Triangle mPrim;
const size_t mPolygonCount;
};
void evalTriangle(const Triangle& prim, VoxelizationDataType& data) const
{
const size_t minNumTask = size_t(tbb::task_scheduler_init::default_num_threads() * 10);
if (mMesh->polygonCount() > minNumTask) {
voxelizeTriangle(prim, data);
} else {
spawnTasks(prim, *mDataTable, mMesh->polygonCount());
}
}
static void spawnTasks(const Triangle& mainPrim, DataTable& dataTable, size_t primCount)
{
const size_t newPrimCount = primCount * 4;
tbb::task_group tasks;
const Vec3d ac = (mainPrim.a + mainPrim.c) * 0.5;
const Vec3d bc = (mainPrim.b + mainPrim.c) * 0.5;
const Vec3d ab = (mainPrim.a + mainPrim.b) * 0.5;
Triangle prim;
prim.index = mainPrim.index;
prim.a = mainPrim.a;
prim.b = ab;
prim.c = ac;
tasks.run(SubTask(prim, dataTable, newPrimCount));
prim.a = ab;
prim.b = bc;
prim.c = ac;
tasks.run(SubTask(prim, dataTable, newPrimCount));
prim.a = ab;
prim.b = mainPrim.b;
prim.c = bc;
tasks.run(SubTask(prim, dataTable, newPrimCount));
prim.a = ac;
prim.b = bc;
prim.c = mainPrim.c;
tasks.run(SubTask(prim, dataTable, newPrimCount));
tasks.wait();
}
static void voxelizeTriangle(const Triangle& prim, VoxelizationDataType& data)
{
std::deque<Coord> coordList;
Coord ijk, nijk;
ijk = Coord::floor(prim.a);
coordList.push_back(ijk);
computeDistance(ijk, prim, data);
unsigned char primId = data.getNewPrimId();
data.primIdAcc.setValueOnly(ijk, primId);
while (!coordList.empty()) {
ijk = coordList.back();
coordList.pop_back();
for (Int32 i = 0; i < 26; ++i) {
nijk = ijk + util::COORD_OFFSETS[i];
if (primId != data.primIdAcc.getValue(nijk)) {
data.primIdAcc.setValueOnly(nijk, primId);
if(computeDistance(nijk, prim, data)) coordList.push_back(nijk);
}
}
}
}
static bool computeDistance(const Coord& ijk, const Triangle& prim, VoxelizationDataType& data)
{
Vec3d uvw, voxelCenter(ijk[0], ijk[1], ijk[2]);
typedef typename TreeType::ValueType ValueType;
const ValueType dist = ValueType((voxelCenter -
closestPointOnTriangleToPoint(prim.a, prim.c, prim.b, voxelCenter, uvw)).lengthSqr());
const ValueType oldDist = data.distAcc.getValue(ijk);
if (dist < oldDist) {
data.distAcc.setValue(ijk, dist);
data.indexAcc.setValue(ijk, prim.index);
} else if (math::isExactlyEqual(dist, oldDist)) {
// makes reduction deterministic when different polygons
// produce the same distance value.
data.indexAcc.setValueOnly(ijk, std::min(prim.index, data.indexAcc.getValue(ijk)));
}
return !(dist > 0.75); // true if the primitive intersects the voxel.
}
DataTable * const mDataTable;
MeshDataAdapter const * const mMesh;
Interrupter * const mInterrupter;
}; // VoxelizePolygons
////////////////////////////////////////
template<typename TreeType>
struct DiffLeafNodeMask
{
typedef typename tree::ValueAccessor<TreeType> AccessorType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::template ValueConverter<bool>::Type BoolTreeType;
typedef typename BoolTreeType::LeafNodeType BoolLeafNodeType;
DiffLeafNodeMask(const TreeType& rhsTree,
std::vector<BoolLeafNodeType*>& lhsNodes)
: mRhsTree(&rhsTree), mLhsNodes(lhsNodes.empty() ? NULL : &lhsNodes[0])
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
tree::ValueAccessor<const TreeType> acc(*mRhsTree);
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
BoolLeafNodeType* lhsNode = mLhsNodes[n];
const LeafNodeType* rhsNode = acc.probeConstLeaf(lhsNode->origin());
if (rhsNode) lhsNode->topologyDifference(*rhsNode, false);
}
}
private:
TreeType const * const mRhsTree;
BoolLeafNodeType ** const mLhsNodes;
};
template<typename LeafNodeTypeA, typename LeafNodeTypeB>
struct UnionValueMasks
{
UnionValueMasks(std::vector<LeafNodeTypeA*>& nodesA, std::vector<LeafNodeTypeB*>& nodesB)
: mNodesA(nodesA.empty() ? NULL : &nodesA[0])
, mNodesB(nodesB.empty() ? NULL : &nodesB[0])
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
mNodesA[n]->topologyUnion(*mNodesB[n]);
}
}
private:
LeafNodeTypeA ** const mNodesA;
LeafNodeTypeB ** const mNodesB;
};
template<typename TreeType>
struct ConstructVoxelMask
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::template ValueConverter<bool>::Type BoolTreeType;
typedef typename BoolTreeType::LeafNodeType BoolLeafNodeType;
ConstructVoxelMask(BoolTreeType& maskTree, const TreeType& tree, std::vector<LeafNodeType*>& nodes)
: mTree(&tree)
, mNodes(nodes.empty() ? NULL : &nodes[0])
, mLocalMaskTree(false)
, mMaskTree(&maskTree)
{
}
ConstructVoxelMask(ConstructVoxelMask& rhs, tbb::split)
: mTree(rhs.mTree)
, mNodes(rhs.mNodes)
, mLocalMaskTree(false)
, mMaskTree(&mLocalMaskTree)
{
}
void operator()(const tbb::blocked_range<size_t>& range)
{
typedef typename LeafNodeType::ValueOnCIter Iterator;
tree::ValueAccessor<const TreeType> acc(*mTree);
tree::ValueAccessor<BoolTreeType> maskAcc(*mMaskTree);
Coord ijk, nijk, localCorod;
Index pos, npos;
for (size_t n = range.begin(); n != range.end(); ++n) {
LeafNodeType& node = *mNodes[n];
CoordBBox bbox = node.getNodeBoundingBox();
bbox.expand(-1);
BoolLeafNodeType& maskNode = *maskAcc.touchLeaf(node.origin());
for (Iterator it = node.cbeginValueOn(); it; ++it) {
ijk = it.getCoord();
pos = it.pos();
localCorod = LeafNodeType::offsetToLocalCoord(pos);
if (localCorod[2] < int(LeafNodeType::DIM - 1)) {
npos = pos + 1;
if (!node.isValueOn(npos)) maskNode.setValueOn(npos);
} else {
nijk = ijk.offsetBy(0, 0, 1);
if (!acc.isValueOn(nijk)) maskAcc.setValueOn(nijk);
}
if (localCorod[2] > 0) {
npos = pos - 1;
if (!node.isValueOn(npos)) maskNode.setValueOn(npos);
} else {
nijk = ijk.offsetBy(0, 0, -1);
if (!acc.isValueOn(nijk)) maskAcc.setValueOn(nijk);
}
if (localCorod[1] < int(LeafNodeType::DIM - 1)) {
npos = pos + LeafNodeType::DIM;
if (!node.isValueOn(npos)) maskNode.setValueOn(npos);
} else {
nijk = ijk.offsetBy(0, 1, 0);
if (!acc.isValueOn(nijk)) maskAcc.setValueOn(nijk);
}
if (localCorod[1] > 0) {
npos = pos - LeafNodeType::DIM;
if (!node.isValueOn(npos)) maskNode.setValueOn(npos);
} else {
nijk = ijk.offsetBy(0, -1, 0);
if (!acc.isValueOn(nijk)) maskAcc.setValueOn(nijk);
}
if (localCorod[0] < int(LeafNodeType::DIM - 1)) {
npos = pos + LeafNodeType::DIM * LeafNodeType::DIM;
if (!node.isValueOn(npos)) maskNode.setValueOn(npos);
} else {
nijk = ijk.offsetBy(1, 0, 0);
if (!acc.isValueOn(nijk)) maskAcc.setValueOn(nijk);
}
if (localCorod[0] > 0) {
npos = pos - LeafNodeType::DIM * LeafNodeType::DIM;
if (!node.isValueOn(npos)) maskNode.setValueOn(npos);
} else {
nijk = ijk.offsetBy(-1, 0, 0);
if (!acc.isValueOn(nijk)) maskAcc.setValueOn(nijk);
}
}
}
}
void join(ConstructVoxelMask& rhs) { mMaskTree->merge(*rhs.mMaskTree); }
private:
TreeType const * const mTree;
LeafNodeType ** const mNodes;
BoolTreeType mLocalMaskTree;
BoolTreeType * const mMaskTree;
};
/// @note The interior and exterior widths should be in world space units and squared.
template<typename TreeType, typename MeshDataAdapter>
struct ExpandNarrowband
{
typedef typename TreeType::ValueType ValueType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::template ValueConverter<Int32>::Type Int32TreeType;
typedef typename Int32TreeType::LeafNodeType Int32LeafNodeType;
typedef typename TreeType::template ValueConverter<bool>::Type BoolTreeType;
typedef typename BoolTreeType::LeafNodeType BoolLeafNodeType;
ExpandNarrowband(
std::vector<BoolLeafNodeType*>& maskNodes,
BoolTreeType& maskTree,
TreeType& distTree,
Int32TreeType& indexTree,
const MeshDataAdapter& mesh,
ValueType exteriorBandWidth,
ValueType interiorBandWidth,
ValueType voxelSize)
: mMaskNodes(maskNodes.empty() ? NULL : &maskNodes[0])
, mMaskTree(&maskTree)
, mDistTree(&distTree)
, mIndexTree(&indexTree)
, mMesh(&mesh)
, mNewMaskTree(false)
, mDistNodes()
, mUpdatedDistNodes()
, mIndexNodes()
, mUpdatedIndexNodes()
, mExteriorBandWidth(exteriorBandWidth)
, mInteriorBandWidth(interiorBandWidth)
, mVoxelSize(voxelSize)
{
}
ExpandNarrowband(const ExpandNarrowband& rhs, tbb::split)
: mMaskNodes(rhs.mMaskNodes)
, mMaskTree(rhs.mMaskTree)
, mDistTree(rhs.mDistTree)
, mIndexTree(rhs.mIndexTree)
, mMesh(rhs.mMesh)
, mNewMaskTree(false)
, mDistNodes()
, mUpdatedDistNodes()
, mIndexNodes()
, mUpdatedIndexNodes()
, mExteriorBandWidth(rhs.mExteriorBandWidth)
, mInteriorBandWidth(rhs.mInteriorBandWidth)
, mVoxelSize(rhs.mVoxelSize)
{
}
void join(ExpandNarrowband& rhs) {
mDistNodes.insert(mDistNodes.end(), rhs.mDistNodes.begin(), rhs.mDistNodes.end());
mIndexNodes.insert(mIndexNodes.end(), rhs.mIndexNodes.begin(), rhs.mIndexNodes.end());
mUpdatedDistNodes.insert(mUpdatedDistNodes.end(), rhs.mUpdatedDistNodes.begin(), rhs.mUpdatedDistNodes.end());
mUpdatedIndexNodes.insert(mUpdatedIndexNodes.end(), rhs.mUpdatedIndexNodes.begin(), rhs.mUpdatedIndexNodes.end());
mNewMaskTree.merge(rhs.mNewMaskTree);
}
void operator()(const tbb::blocked_range<size_t>& range) {
tree::ValueAccessor<BoolTreeType> newMaskAcc(mNewMaskTree);
tree::ValueAccessor<TreeType> distAcc(*mDistTree);
tree::ValueAccessor<Int32TreeType> indexAcc(*mIndexTree);
std::vector<Int32> primitives;
primitives.reserve(26);
LeafNodeType * newDistNodePt = NULL;
Int32LeafNodeType * newIndexNodePt = NULL;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
BoolLeafNodeType& maskNode = *mMaskNodes[n];
if (maskNode.isEmpty()) continue;
Coord ijk = maskNode.origin();
bool usingNewNodes = false;
LeafNodeType * distNodePt = distAcc.probeLeaf(ijk);
Int32LeafNodeType * indexNodePt = indexAcc.probeLeaf(ijk);
assert(!distNodePt == !indexNodePt);
if (!distNodePt && !indexNodePt) {
const ValueType backgroundDist = distAcc.getValue(ijk);
if (!newDistNodePt && !newIndexNodePt) {
newDistNodePt = new LeafNodeType(ijk, backgroundDist);
newIndexNodePt = new Int32LeafNodeType(ijk, indexAcc.getValue(ijk));
} else {
if ((backgroundDist < ValueType(0.0)) != (newDistNodePt->getValue(0) < ValueType(0.0))) {
newDistNodePt->buffer().fill(backgroundDist);
}
newDistNodePt->setOrigin(ijk);
newIndexNodePt->setOrigin(ijk);
}
distNodePt = newDistNodePt;
indexNodePt = newIndexNodePt;
usingNewNodes = true;
}
bool updatedValues = false;
for (typename BoolLeafNodeType::ValueOnIter it = maskNode.beginValueOn(); it; ++it) {
ijk = it.getCoord();
const Index pos = it.pos();
Int32 closestPrimIdx = 0;
const ValueType distance =
computeDistance(ijk, distAcc, indexAcc, primitives, closestPrimIdx);
const bool inside = distNodePt->getValue(pos) < ValueType(0.0);
if (!inside && distance < mExteriorBandWidth) {
distNodePt->setValueOnly(pos, distance);
indexNodePt->setValueOn(pos, closestPrimIdx);
} else if (inside && distance < mInteriorBandWidth) {
distNodePt->setValueOnly(pos, -distance);
indexNodePt->setValueOn(pos, closestPrimIdx);
} else {
continue;
}
for (Int32 i = 0; i < 6; ++i) {
newMaskAcc.setValueOn(ijk + util::COORD_OFFSETS[i]);
}
updatedValues = true;
}
if (updatedValues && usingNewNodes) {
distNodePt->topologyUnion(*indexNodePt);
mDistNodes.push_back(distNodePt);
mIndexNodes.push_back(indexNodePt);
newDistNodePt = NULL;
newIndexNodePt = NULL;
} else if (updatedValues) {
mUpdatedDistNodes.push_back(distNodePt);
mUpdatedIndexNodes.push_back(indexNodePt);
}
}
}
//////////
BoolTreeType& newMaskTree() { return mNewMaskTree; }
std::vector<LeafNodeType*>& newDistNodes() { return mDistNodes; }
std::vector<LeafNodeType*>& updatedDistNodes() { return mUpdatedDistNodes; }
std::vector<Int32LeafNodeType*>& newIndexNodes() { return mIndexNodes; }
std::vector<Int32LeafNodeType*>& updatedIndexNodes() { return mUpdatedIndexNodes; }
private:
ValueType
computeDistance(const Coord& ijk,
tree::ValueAccessor<TreeType>& distAcc, tree::ValueAccessor<Int32TreeType>& idxAcc,
std::vector<Int32>& primitives, Int32& closestPrimIdx) const
{
ValueType minDist = std::numeric_limits<ValueType>::max();
primitives.clear();
const Coord ijkMin = ijk.offsetBy(-1);
const Coord ijkMax = ijk.offsetBy(1);
const Coord nodeMin = ijkMin & ~(LeafNodeType::DIM - 1);
const Coord nodeMax = ijkMax & ~(LeafNodeType::DIM - 1);
CoordBBox bbox;
Coord nijk;
for (nijk[0] = nodeMin[0]; nijk[0] <= nodeMax[0]; nijk[0] += LeafNodeType::DIM) {
for (nijk[1] = nodeMin[1]; nijk[1] <= nodeMax[1]; nijk[1] += LeafNodeType::DIM) {
for (nijk[2] = nodeMin[2]; nijk[2] <= nodeMax[2]; nijk[2] += LeafNodeType::DIM) {
if (LeafNodeType* distleaf = distAcc.probeLeaf(nijk)) {
bbox.min() = Coord::maxComponent(ijkMin, nijk);
bbox.max() = Coord::minComponent(ijkMax, nijk.offsetBy(LeafNodeType::DIM - 1));
evalLeafNode(bbox, *distleaf, *idxAcc.probeLeaf(nijk), primitives, minDist);
}
}
}
}
const ValueType tmpDist = evalPrimitives(ijk, primitives, closestPrimIdx);
return tmpDist > minDist ? tmpDist : minDist + mVoxelSize;
}
void
evalLeafNode(const CoordBBox& bbox, LeafNodeType& distLeaf,
Int32LeafNodeType& idxLeaf, std::vector<Int32>& primitives, ValueType& minNeighbourDist) const
{
ValueType tmpDist;
Index xPos(0), yPos(0), pos(0);
for (int x = bbox.min()[0]; x <= bbox.max()[0]; ++x) {
xPos = (x & (LeafNodeType::DIM - 1u)) << (2 * LeafNodeType::LOG2DIM);
for (int y = bbox.min()[1]; y <= bbox.max()[1]; ++y) {
yPos = xPos + ((y & (LeafNodeType::DIM - 1u)) << LeafNodeType::LOG2DIM);
for (int z = bbox.min()[2]; z <= bbox.max()[2]; ++z) {
pos = yPos + (z & (LeafNodeType::DIM - 1u));
if (distLeaf.probeValue(pos, tmpDist)) {
primitives.push_back(idxLeaf.getValue(pos));
minNeighbourDist = std::min(std::abs(tmpDist), minNeighbourDist);
}
}
}
}
}
ValueType
evalPrimitives(const Coord& ijk, std::vector<Int32>& primitives, Int32& closestPrimIdx) const
{
std::sort(primitives.begin(), primitives.end());
Int32 lastPrim = -1;
Vec3d a, b, c, uvw, voxelCenter(ijk[0], ijk[1], ijk[2]);
double primDist, tmpDist, dist = std::numeric_limits<double>::max();
for (size_t n = 0, N = primitives.size(); n < N; ++n) {
if (primitives[n] == lastPrim) continue;
lastPrim = primitives[n];
const size_t polygon = size_t(lastPrim);
mMesh->getIndexSpacePoint(polygon, 0, a);
mMesh->getIndexSpacePoint(polygon, 1, b);
mMesh->getIndexSpacePoint(polygon, 2, c);
primDist = (voxelCenter -
closestPointOnTriangleToPoint(a, c, b, voxelCenter, uvw)).lengthSqr();
// Split-up quad into a second triangle
if (4 == mMesh->vertexCount(polygon)) {
mMesh->getIndexSpacePoint(polygon, 3, b);
tmpDist = (voxelCenter - closestPointOnTriangleToPoint(
a, b, c, voxelCenter, uvw)).lengthSqr();
if (tmpDist < primDist) primDist = tmpDist;
}
if (primDist < dist) {
dist = primDist;
closestPrimIdx = lastPrim;
}
}
return ValueType(std::sqrt(dist)) * mVoxelSize;
}
//////////
BoolLeafNodeType ** const mMaskNodes;
BoolTreeType * const mMaskTree;
TreeType * const mDistTree;
Int32TreeType * const mIndexTree;
MeshDataAdapter const * const mMesh;
BoolTreeType mNewMaskTree;
std::vector<LeafNodeType*> mDistNodes, mUpdatedDistNodes;
std::vector<Int32LeafNodeType*> mIndexNodes, mUpdatedIndexNodes;
const ValueType mExteriorBandWidth, mInteriorBandWidth, mVoxelSize;
}; // ExpandNarrowband
template<typename TreeType, typename Int32TreeType, typename BoolTreeType, typename MeshDataAdapter>
inline void
expandNarrowband(
TreeType& distTree,
Int32TreeType& indexTree,
BoolTreeType& maskTree,
std::vector<typename BoolTreeType::LeafNodeType*>& maskNodes,
const MeshDataAdapter& mesh,
typename TreeType::ValueType exteriorBandWidth,
typename TreeType::ValueType interiorBandWidth,
typename TreeType::ValueType voxelSize)
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename Int32TreeType::LeafNodeType Int32LeafNodeType;
ExpandNarrowband<TreeType, MeshDataAdapter>
expandOp(maskNodes, maskTree, distTree, indexTree,
mesh, exteriorBandWidth, interiorBandWidth, voxelSize);
tbb::parallel_reduce(tbb::blocked_range<size_t>(0, maskNodes.size()), expandOp);
{
tree::ValueAccessor<TreeType> acc(distTree);
typedef typename std::vector<LeafNodeType*> LeafNodePtVec;
LeafNodePtVec& nodes = expandOp.newDistNodes();
for (typename LeafNodePtVec::iterator it = nodes.begin(), end = nodes.end(); it != end; ++it) {
acc.addLeaf(*it);
}
}
{
tree::ValueAccessor<Int32TreeType> acc(indexTree);
typedef typename std::vector<Int32LeafNodeType*> LeafNodePtVec;
LeafNodePtVec& nodes = expandOp.newIndexNodes();
for (typename LeafNodePtVec::iterator it = nodes.begin(), end = nodes.end(); it != end; ++it) {
acc.addLeaf(*it);
}
}
tbb::parallel_for(tbb::blocked_range<size_t>(0, expandOp.updatedIndexNodes().size()),
UnionValueMasks<LeafNodeType, Int32LeafNodeType>(expandOp.updatedDistNodes(), expandOp.updatedIndexNodes()));
maskTree.clear();
maskTree.merge(expandOp.newMaskTree());
}
////////////////////////////////////////
// Transform values (sqrt, world space scaling and sign flip if sdf)
template<typename TreeType>
struct TransformValues
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::ValueType ValueType;
TransformValues(std::vector<LeafNodeType*>& nodes,
ValueType voxelSize, bool unsignedDist)
: mNodes(&nodes[0])
, mVoxelSize(voxelSize)
, mUnsigned(unsignedDist)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
typename LeafNodeType::ValueOnIter iter;
const bool udf = mUnsigned;
const ValueType w[2] = { -mVoxelSize, mVoxelSize };
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
for (iter = mNodes[n]->beginValueOn(); iter; ++iter) {
ValueType& val = const_cast<ValueType&>(iter.getValue());
val = w[udf || (val < ValueType(0.0))] * std::sqrt(std::abs(val));
}
}
}
private:
LeafNodeType * * const mNodes;
const ValueType mVoxelSize;
const bool mUnsigned;
};
// Inactivate values outside the (exBandWidth, inBandWidth) range.
template<typename TreeType>
struct InactivateValues
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::ValueType ValueType;
InactivateValues(std::vector<LeafNodeType*>& nodes,
ValueType exBandWidth, ValueType inBandWidth)
: mNodes(nodes.empty() ? NULL : &nodes[0])
, mExBandWidth(exBandWidth)
, mInBandWidth(inBandWidth)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
typename LeafNodeType::ValueOnIter iter;
const ValueType exVal = mExBandWidth;
const ValueType inVal = -mInBandWidth;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
for (iter = mNodes[n]->beginValueOn(); iter; ++iter) {
ValueType& val = const_cast<ValueType&>(iter.getValue());
const bool inside = val < ValueType(0.0);
if (inside && !(val > inVal)) {
val = inVal;
iter.setValueOff();
} else if (!inside && !(val < exVal)) {
val = exVal;
iter.setValueOff();
}
}
}
}
private:
LeafNodeType * * const mNodes;
const ValueType mExBandWidth, mInBandWidth;
};
template<typename TreeType>
struct OffsetValues
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::ValueType ValueType;
OffsetValues(std::vector<LeafNodeType*>& nodes, ValueType offset)
: mNodes(nodes.empty() ? NULL : &nodes[0]), mOffset(offset)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
const ValueType offset = mOffset;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
typename LeafNodeType::ValueOnIter iter = mNodes[n]->beginValueOn();
for (; iter; ++iter) {
ValueType& val = const_cast<ValueType&>(iter.getValue());
val += offset;
}
}
}
private:
LeafNodeType * * const mNodes;
const ValueType mOffset;
};
template<typename TreeType>
struct Renormalize
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::ValueType ValueType;
Renormalize(const TreeType& tree, const std::vector<LeafNodeType*>& nodes, ValueType* buffer, ValueType voxelSize)
: mTree(&tree)
, mNodes(nodes.empty() ? NULL : &nodes[0])
, mBuffer(buffer)
, mVoxelSize(voxelSize)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const
{
typedef math::Vec3<ValueType> Vec3Type;
tree::ValueAccessor<const TreeType> acc(*mTree);
Coord ijk;
Vec3Type up, down;
const ValueType dx = mVoxelSize, invDx = ValueType(1.0) / mVoxelSize;
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
ValueType* bufferData = &mBuffer[n * LeafNodeType::SIZE];
typename LeafNodeType::ValueOnCIter iter = mNodes[n]->cbeginValueOn();
for (; iter; ++iter) {
const ValueType phi0 = *iter;
ijk = iter.getCoord();
up[0] = acc.getValue(ijk.offsetBy(1, 0, 0)) - phi0;
up[1] = acc.getValue(ijk.offsetBy(0, 1, 0)) - phi0;
up[2] = acc.getValue(ijk.offsetBy(0, 0, 1)) - phi0;
down[0] = phi0 - acc.getValue(ijk.offsetBy(-1, 0, 0));
down[1] = phi0 - acc.getValue(ijk.offsetBy(0, -1, 0));
down[2] = phi0 - acc.getValue(ijk.offsetBy(0, 0, -1));
const ValueType normSqGradPhi = math::GudonovsNormSqrd(phi0 > 0.0, down, up);
const ValueType diff = math::Sqrt(normSqGradPhi) * invDx - ValueType(1.0);
const ValueType S = phi0 / (math::Sqrt(math::Pow2(phi0) + normSqGradPhi));
bufferData[iter.pos()] = phi0 - dx * S * diff;
}
}
}
private:
TreeType const * const mTree;
LeafNodeType const * const * const mNodes;
ValueType * const mBuffer;
const ValueType mVoxelSize;
};
template<typename TreeType>
struct MinCombine
{
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename TreeType::ValueType ValueType;
MinCombine(std::vector<LeafNodeType*>& nodes, const ValueType* buffer)
: mNodes(nodes.empty() ? NULL : &nodes[0]), mBuffer(buffer)
{
}
void operator()(const tbb::blocked_range<size_t>& range) const {
for (size_t n = range.begin(), N = range.end(); n < N; ++n) {
const ValueType* bufferData = &mBuffer[n * LeafNodeType::SIZE];
typename LeafNodeType::ValueOnIter iter = mNodes[n]->beginValueOn();
for (; iter; ++iter) {
ValueType& val = const_cast<ValueType&>(iter.getValue());
val = std::min(val, bufferData[iter.pos()]);
}
}
}
private:
LeafNodeType * * const mNodes;
ValueType const * const mBuffer;
};
} // mesh_to_volume_internal namespace
////////////////////////////////////////
// Utility method implementation
template <typename FloatTreeT>
inline void
traceExteriorBoundaries(FloatTreeT& tree)
{
typedef mesh_to_volume_internal::LeafNodeConnectivityTable<FloatTreeT> ConnectivityTable;
ConnectivityTable nodeConnectivity(tree);
std::vector<size_t> zStartNodes, yStartNodes, xStartNodes;
for (size_t n = 0; n < nodeConnectivity.size(); ++n) {
if (ConnectivityTable::INVALID_OFFSET == nodeConnectivity.offsetsPrevX()[n]) {
xStartNodes.push_back(n);
}
if (ConnectivityTable::INVALID_OFFSET == nodeConnectivity.offsetsPrevY()[n]) {
yStartNodes.push_back(n);
}
if (ConnectivityTable::INVALID_OFFSET == nodeConnectivity.offsetsPrevZ()[n]) {
zStartNodes.push_back(n);
}
}
typedef mesh_to_volume_internal::SweepExteriorSign<FloatTreeT> SweepingOp;
tbb::parallel_for(tbb::blocked_range<size_t>(0, zStartNodes.size()),
SweepingOp(SweepingOp::Z_AXIS, zStartNodes, nodeConnectivity));
tbb::parallel_for(tbb::blocked_range<size_t>(0, yStartNodes.size()),
SweepingOp(SweepingOp::Y_AXIS, yStartNodes, nodeConnectivity));
tbb::parallel_for(tbb::blocked_range<size_t>(0, xStartNodes.size()),
SweepingOp(SweepingOp::X_AXIS, xStartNodes, nodeConnectivity));
const size_t numLeafNodes = nodeConnectivity.size();
const size_t numVoxels = numLeafNodes * FloatTreeT::LeafNodeType::SIZE;
boost::scoped_array<bool> changedNodeMaskA(new bool[numLeafNodes]);
boost::scoped_array<bool> changedNodeMaskB(new bool[numLeafNodes]);
boost::scoped_array<bool> changedVoxelMask(new bool[numVoxels]);
memset(changedNodeMaskA.get(), 1, sizeof(bool) * numLeafNodes);
mesh_to_volume_internal::fillArray(changedVoxelMask.get(), false, numVoxels);
const tbb::blocked_range<size_t> nodeRange(0, numLeafNodes);
bool nodesUpdated = false;
do {
tbb::parallel_for(nodeRange, mesh_to_volume_internal::SeedFillExteriorSign<FloatTreeT>(
nodeConnectivity.nodes(), changedNodeMaskA.get()));
tbb::parallel_for(nodeRange, mesh_to_volume_internal::SeedPoints<FloatTreeT>(nodeConnectivity,
changedNodeMaskA.get(), changedNodeMaskB.get(), changedVoxelMask.get()));
changedNodeMaskA.swap(changedNodeMaskB);
nodesUpdated = false;
for (size_t n = 0; n < numLeafNodes; ++n) {
nodesUpdated |= changedNodeMaskA[n];
if (nodesUpdated) break;
}
if (nodesUpdated) {
tbb::parallel_for(nodeRange, mesh_to_volume_internal::SyncVoxelMask<FloatTreeT>(
nodeConnectivity.nodes(), changedNodeMaskA.get(), changedVoxelMask.get()));
}
} while (nodesUpdated);
} // void traceExteriorBoundaries()
////////////////////////////////////////
template <typename GridType, typename MeshDataAdapter, typename Interrupter>
inline typename GridType::Ptr
meshToVolume(
Interrupter& interrupter,
const MeshDataAdapter& mesh,
const math::Transform& transform,
float exteriorBandWidth,
float interiorBandWidth,
int flags,
typename GridType::template ValueConverter<Int32>::Type * polygonIndexGrid)
{
typedef typename GridType::Ptr GridTypePtr;
typedef typename GridType::TreeType TreeType;
typedef typename TreeType::LeafNodeType LeafNodeType;
typedef typename GridType::ValueType ValueType;
typedef typename GridType::template ValueConverter<Int32>::Type Int32GridType;
typedef typename Int32GridType::TreeType Int32TreeType;
typedef typename TreeType::template ValueConverter<bool>::Type BoolTreeType;
//////////
// Setup
GridTypePtr distGrid(new GridType(std::numeric_limits<ValueType>::max()));
distGrid->setTransform(transform.copy());
ValueType exteriorWidth = ValueType(exteriorBandWidth);
ValueType interiorWidth = ValueType(interiorBandWidth);
// inf interior width is all right, this value makes the converter fill
// interior regions with distance values.
if (!boost::math::isfinite(exteriorWidth) || boost::math::isnan(interiorWidth)) {
std::stringstream msg;
msg << "Illegal narrow band width: exterior = " << exteriorWidth
<< ", interior = " << interiorWidth;
OPENVDB_LOG_DEBUG(msg.str());
return distGrid;
}
const ValueType voxelSize = ValueType(transform.voxelSize()[0]);
if (!boost::math::isfinite(voxelSize) || math::isZero(voxelSize)) {
std::stringstream msg;
msg << "Illegal transform, voxel size = " << voxelSize;
OPENVDB_LOG_DEBUG(msg.str());
return distGrid;
}
// convert narrow band width from voxel units to world space units.
exteriorWidth *= voxelSize;
// avoid the unit conversion if the interior band width is set to
// inf or std::numeric_limits<float>::max()
if (interiorWidth < std::numeric_limits<ValueType>::max()) {
interiorWidth *= voxelSize;
}
const bool computeSignedDistanceField = (flags & UNSIGNED_DISTANCE_FIELD) == 0;
const bool removeIntersectingVoxels = (flags & DISABLE_INTERSECTING_VOXEL_REMOVAL) == 0;
const bool renormalizeValues = (flags & DISABLE_RENORMALIZATION) == 0;
const bool trimNarrowBand = (flags & DISABLE_NARROW_BAND_TRIMMING) == 0;
Int32GridType* indexGrid = NULL;
typename Int32GridType::Ptr temporaryIndexGrid;
if (polygonIndexGrid) {
indexGrid = polygonIndexGrid;
} else {
temporaryIndexGrid.reset(new Int32GridType(Int32(util::INVALID_IDX)));
indexGrid = temporaryIndexGrid.get();
}
indexGrid->newTree();
indexGrid->setTransform(transform.copy());
if (computeSignedDistanceField) {
distGrid->setGridClass(GRID_LEVEL_SET);
} else {
distGrid->setGridClass(GRID_UNKNOWN);
interiorWidth = ValueType(0.0);
}
TreeType& distTree = distGrid->tree();
Int32TreeType& indexTree = indexGrid->tree();
//////////
// Voxelize mesh
{
typedef mesh_to_volume_internal::VoxelizationData<TreeType> VoxelizationDataType;
typedef tbb::enumerable_thread_specific<typename VoxelizationDataType::Ptr> DataTable;
DataTable data;
typedef mesh_to_volume_internal::VoxelizePolygons<TreeType, MeshDataAdapter, Interrupter> Voxelizer;
const tbb::blocked_range<size_t> polygonRange(0, mesh.polygonCount());
tbb::parallel_for(polygonRange, Voxelizer(data, mesh, &interrupter));
for (typename DataTable::iterator i = data.begin(); i != data.end(); ++i) {
VoxelizationDataType& dataItem = **i;
mesh_to_volume_internal::combineData(distTree, indexTree, dataItem.distTree, dataItem.indexTree);
}
}
// the progress estimates are based on the observed average time for a few different
// test cases and is only intended to provide some rough progression feedback to the user.
if (interrupter.wasInterrupted(30)) return distGrid;
//////////
// Classify interior and exterior regions
if (computeSignedDistanceField) {
// determines the inside/outside state for the narrow band of voxels.
traceExteriorBoundaries(distTree);
std::vector<LeafNodeType*> nodes;
nodes.reserve(distTree.leafCount());
distTree.getNodes(nodes);
const tbb::blocked_range<size_t> nodeRange(0, nodes.size());
typedef mesh_to_volume_internal::ComputeIntersectingVoxelSign<TreeType, MeshDataAdapter> SignOp;
tbb::parallel_for(nodeRange, SignOp(nodes, distTree, indexTree, mesh));
if (interrupter.wasInterrupted(45)) return distGrid;
// remove voxels created by self intersecting portions of the mesh
if (removeIntersectingVoxels) {
tbb::parallel_for(nodeRange,
mesh_to_volume_internal::ValidateIntersectingVoxels<TreeType>(distTree, nodes));
tbb::parallel_for(nodeRange,
mesh_to_volume_internal::RemoveSelfIntersectingSurface<TreeType>(nodes, distTree, indexTree));
tools::pruneInactive(distTree, /*threading=*/true);
tools::pruneInactive(indexTree, /*threading=*/true);
}
}
if (interrupter.wasInterrupted(50)) return distGrid;
if (distTree.activeVoxelCount() == 0) {
distGrid.reset((new GridType(ValueType(0.0))));
return distGrid;
}
// transform values (world space scaling etc.)
{
std::vector<LeafNodeType*> nodes;
nodes.reserve(distTree.leafCount());
distTree.getNodes(nodes);
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
mesh_to_volume_internal::TransformValues<TreeType>(nodes, voxelSize, !computeSignedDistanceField));
}
// propagate sign information into tile regions
if (computeSignedDistanceField) {
distTree.root().setBackground(exteriorWidth, /*updateChildNodes=*/false);
tools::signedFloodFillWithValues(distTree, exteriorWidth, -interiorWidth);
} else {
tools::changeBackground(distTree, exteriorWidth);
}
if (interrupter.wasInterrupted(54)) return distGrid;
//////////
// Expand the narrow band region
const ValueType minBandWidth = voxelSize * ValueType(2.0);
if (interiorWidth > minBandWidth || exteriorWidth > minBandWidth) {
// create the initial voxel mask.
BoolTreeType maskTree(false);
{
std::vector<LeafNodeType*> nodes;
nodes.reserve(distTree.leafCount());
distTree.getNodes(nodes);
mesh_to_volume_internal::ConstructVoxelMask<TreeType> op(maskTree, distTree, nodes);
tbb::parallel_reduce(tbb::blocked_range<size_t>(0, nodes.size()), op);
}
// progress estimation
unsigned maxIterations = std::numeric_limits<unsigned>::max();
float progress = 54.0f, step = 0.0f;
double estimated =
2.0 * std::ceil((std::max(interiorWidth, exteriorWidth) - minBandWidth) / voxelSize);
if (estimated < double(maxIterations)) {
maxIterations = unsigned(estimated);
step = 40.0f / float(maxIterations);
}
std::vector<typename BoolTreeType::LeafNodeType*> maskNodes;
// expand
unsigned count = 0;
while (true) {
if (interrupter.wasInterrupted(int(progress))) return distGrid;
const size_t maskNodeCount = maskTree.leafCount();
if (maskNodeCount == 0) break;
maskNodes.clear();
maskNodes.reserve(maskNodeCount);
maskTree.getNodes(maskNodes);
const tbb::blocked_range<size_t> range(0, maskNodes.size());
tbb::parallel_for(range,
mesh_to_volume_internal::DiffLeafNodeMask<TreeType>(distTree, maskNodes));
mesh_to_volume_internal::expandNarrowband(distTree, indexTree, maskTree, maskNodes,
mesh, exteriorWidth, interiorWidth, voxelSize);
if ((++count) >= maxIterations) break;
progress += step;
}
}
if (interrupter.wasInterrupted(94)) return distGrid;
if (!polygonIndexGrid) indexGrid->clear();
/////////
// Renormalize distances to smooth out bumps caused by self intersecting
// and overlapping portions of the mesh and renormalize the level set.
if (computeSignedDistanceField && renormalizeValues) {
std::vector<LeafNodeType*> nodes;
nodes.reserve(distTree.leafCount());
distTree.getNodes(nodes);
boost::scoped_array<ValueType> buffer(new ValueType[LeafNodeType::SIZE * nodes.size()]);
const ValueType offset = ValueType(0.8 * voxelSize);
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
mesh_to_volume_internal::OffsetValues<TreeType>(nodes, -offset));
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
mesh_to_volume_internal::Renormalize<TreeType>(distTree, nodes, buffer.get(), voxelSize));
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
mesh_to_volume_internal::MinCombine<TreeType>(nodes, buffer.get()));
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
mesh_to_volume_internal::OffsetValues<TreeType>(nodes, offset - mesh_to_volume_internal::Tolerance<ValueType>::epsilon()));
}
if (interrupter.wasInterrupted(99)) return distGrid;
/////////
// Remove active voxels that exceed the narrow band limits
if (trimNarrowBand && std::min(interiorWidth, exteriorWidth) < voxelSize * ValueType(4.0)) {
std::vector<LeafNodeType*> nodes;
nodes.reserve(distTree.leafCount());
distTree.getNodes(nodes);
tbb::parallel_for(tbb::blocked_range<size_t>(0, nodes.size()),
mesh_to_volume_internal::InactivateValues<TreeType>(nodes, exteriorWidth, computeSignedDistanceField ? interiorWidth : exteriorWidth));
tools::pruneLevelSet(distTree, exteriorWidth, computeSignedDistanceField ? -interiorWidth : -exteriorWidth);
}
return distGrid;
}
template <typename GridType, typename MeshDataAdapter>
inline typename GridType::Ptr
meshToVolume(
const MeshDataAdapter& mesh,
const math::Transform& transform,
float exteriorBandWidth,
float interiorBandWidth,
int flags,
typename GridType::template ValueConverter<Int32>::Type * polygonIndexGrid)
{
util::NullInterrupter nullInterrupter;
return meshToVolume<GridType>(nullInterrupter, mesh, transform,
exteriorBandWidth, interiorBandWidth, flags, polygonIndexGrid);
}
////////////////////////////////////////
/// @internal This overload is enabled only for grids with a scalar, floating-point ValueType.
template<typename GridType>
inline typename boost::enable_if<boost::is_floating_point<typename GridType::ValueType>,
typename GridType::Ptr>::type
doMeshConversion(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float exBandWidth,
float inBandWidth,
bool unsignedDistanceField = false)
{
if (points.empty()) {
return typename GridType::Ptr(new GridType(typename GridType::ValueType(exBandWidth)));
}
const size_t numPoints = points.size();
boost::scoped_array<Vec3s> indexSpacePoints(new Vec3s[numPoints]);
// transform points to local grid index space
tbb::parallel_for(tbb::blocked_range<size_t>(0, numPoints),
mesh_to_volume_internal::TransformPoints<Vec3s>(
&points[0], indexSpacePoints.get(), xform));
const int conversionFlags = unsignedDistanceField ? UNSIGNED_DISTANCE_FIELD : 0;
if (quads.empty()) {
QuadAndTriangleDataAdapter<Vec3s, Vec3I>
mesh(indexSpacePoints.get(), numPoints, &triangles[0], triangles.size());
return meshToVolume<GridType>(mesh, xform, exBandWidth, inBandWidth, conversionFlags);
} else if (triangles.empty()) {
QuadAndTriangleDataAdapter<Vec3s, Vec4I>
mesh(indexSpacePoints.get(), numPoints, &quads[0], quads.size());
return meshToVolume<GridType>(mesh, xform, exBandWidth, inBandWidth, conversionFlags);
}
// pack primitives
const size_t numPrimitives = triangles.size() + quads.size();
boost::scoped_array<Vec4I> prims(new Vec4I[numPrimitives]);
for (size_t n = 0, N = triangles.size(); n < N; ++n) {
const Vec3I& triangle = triangles[n];
Vec4I& prim = prims[n];
prim[0] = triangle[0];
prim[1] = triangle[1];
prim[2] = triangle[2];
prim[3] = util::INVALID_IDX;
}
const size_t offset = triangles.size();
for (size_t n = 0, N = quads.size(); n < N; ++n) {
prims[offset + n] = quads[n];
}
QuadAndTriangleDataAdapter<Vec3s, Vec4I>
mesh(indexSpacePoints.get(), numPoints, prims.get(), numPrimitives);
return meshToVolume<GridType>(mesh, xform, exBandWidth, inBandWidth, conversionFlags);
}
/// @internal This overload is enabled only for grids that do not have a scalar,
/// floating-point ValueType.
template<typename GridType>
inline typename boost::disable_if<boost::is_floating_point<typename GridType::ValueType>,
typename GridType::Ptr>::type
doMeshConversion(
const math::Transform& /*xform*/,
const std::vector<Vec3s>& /*points*/,
const std::vector<Vec3I>& /*triangles*/,
const std::vector<Vec4I>& /*quads*/,
float /*exBandWidth*/,
float /*inBandWidth*/,
bool /*unsignedDistanceField*/ = false)
{
OPENVDB_THROW(TypeError,
"mesh to volume conversion is supported only for scalar floating-point grids");
}
////////////////////////////////////////
template<typename GridType>
inline typename GridType::Ptr
meshToLevelSet(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
float halfWidth)
{
std::vector<Vec4I> quads(0);
return doMeshConversion<GridType>(xform, points, triangles, quads,
halfWidth, halfWidth);
}
template<typename GridType>
inline typename GridType::Ptr
meshToLevelSet(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec4I>& quads,
float halfWidth)
{
std::vector<Vec3I> triangles(0);
return doMeshConversion<GridType>(xform, points, triangles, quads,
halfWidth, halfWidth);
}
template<typename GridType>
inline typename GridType::Ptr
meshToLevelSet(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float halfWidth)
{
return doMeshConversion<GridType>(xform, points, triangles, quads,
halfWidth, halfWidth);
}
template<typename GridType>
inline typename GridType::Ptr
meshToSignedDistanceField(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float exBandWidth,
float inBandWidth)
{
return doMeshConversion<GridType>(xform, points, triangles,
quads, exBandWidth, inBandWidth);
}
template<typename GridType>
inline typename GridType::Ptr
meshToUnsignedDistanceField(
const openvdb::math::Transform& xform,
const std::vector<Vec3s>& points,
const std::vector<Vec3I>& triangles,
const std::vector<Vec4I>& quads,
float bandWidth)
{
return doMeshConversion<GridType>(xform, points, triangles, quads,
bandWidth, bandWidth, true);
}
////////////////////////////////////////////////////////////////////////////////
// Required by several of the tree nodes
inline std::ostream&
operator<<(std::ostream& ostr, const MeshToVoxelEdgeData::EdgeData& rhs)
{
ostr << "{[ " << rhs.mXPrim << ", " << rhs.mXDist << "]";
ostr << " [ " << rhs.mYPrim << ", " << rhs.mYDist << "]";
ostr << " [ " << rhs.mZPrim << ", " << rhs.mZDist << "]}";
return ostr;
}
// Required by math::Abs
inline MeshToVoxelEdgeData::EdgeData
Abs(const MeshToVoxelEdgeData::EdgeData& x)
{
return x;
}
////////////////////////////////////////
class MeshToVoxelEdgeData::GenEdgeData
{
public:
GenEdgeData(
const std::vector<Vec3s>& pointList,
const std::vector<Vec4I>& polygonList);
void run(bool threaded = true);
GenEdgeData(GenEdgeData& rhs, tbb::split);
inline void operator() (const tbb::blocked_range<size_t> &range);
inline void join(GenEdgeData& rhs);
inline TreeType& tree() { return mTree; }
private:
void operator=(const GenEdgeData&) {}
struct Primitive { Vec3d a, b, c, d; Int32 index; };
template<bool IsQuad>
inline void voxelize(const Primitive&);
template<bool IsQuad>
inline bool evalPrimitive(const Coord&, const Primitive&);
inline bool rayTriangleIntersection( const Vec3d& origin, const Vec3d& dir,
const Vec3d& a, const Vec3d& b, const Vec3d& c, double& t);
TreeType mTree;
Accessor mAccessor;
const std::vector<Vec3s>& mPointList;
const std::vector<Vec4I>& mPolygonList;
// Used internally for acceleration
typedef TreeType::ValueConverter<Int32>::Type IntTreeT;
IntTreeT mLastPrimTree;
tree::ValueAccessor<IntTreeT> mLastPrimAccessor;
}; // class MeshToVoxelEdgeData::GenEdgeData
inline
MeshToVoxelEdgeData::GenEdgeData::GenEdgeData(
const std::vector<Vec3s>& pointList,
const std::vector<Vec4I>& polygonList)
: mTree(EdgeData())
, mAccessor(mTree)
, mPointList(pointList)
, mPolygonList(polygonList)
, mLastPrimTree(Int32(util::INVALID_IDX))
, mLastPrimAccessor(mLastPrimTree)
{
}
inline
MeshToVoxelEdgeData::GenEdgeData::GenEdgeData(GenEdgeData& rhs, tbb::split)
: mTree(EdgeData())
, mAccessor(mTree)
, mPointList(rhs.mPointList)
, mPolygonList(rhs.mPolygonList)
, mLastPrimTree(Int32(util::INVALID_IDX))
, mLastPrimAccessor(mLastPrimTree)
{
}
inline void
MeshToVoxelEdgeData::GenEdgeData::run(bool threaded)
{
if (threaded) {
tbb::parallel_reduce(tbb::blocked_range<size_t>(0, mPolygonList.size()), *this);
} else {
(*this)(tbb::blocked_range<size_t>(0, mPolygonList.size()));
}
}
inline void
MeshToVoxelEdgeData::GenEdgeData::join(GenEdgeData& rhs)
{
typedef TreeType::RootNodeType RootNodeType;
typedef RootNodeType::NodeChainType NodeChainType;
BOOST_STATIC_ASSERT(boost::mpl::size<NodeChainType>::value > 1);
typedef boost::mpl::at<NodeChainType, boost::mpl::int_<1> >::type InternalNodeType;
Coord ijk;
Index offset;
rhs.mTree.clearAllAccessors();
TreeType::LeafIter leafIt = rhs.mTree.beginLeaf();
for ( ; leafIt; ++leafIt) {
ijk = leafIt->origin();
TreeType::LeafNodeType* lhsLeafPt = mTree.probeLeaf(ijk);
if (!lhsLeafPt) {
mAccessor.addLeaf(rhs.mAccessor.probeLeaf(ijk));
InternalNodeType* node = rhs.mAccessor.getNode<InternalNodeType>();
node->stealNode<TreeType::LeafNodeType>(ijk, EdgeData(), false);
rhs.mAccessor.clear();
} else {
TreeType::LeafNodeType::ValueOnCIter it = leafIt->cbeginValueOn();
for ( ; it; ++it) {
offset = it.pos();
const EdgeData& rhsValue = it.getValue();
if (!lhsLeafPt->isValueOn(offset)) {
lhsLeafPt->setValueOn(offset, rhsValue);
} else {
EdgeData& lhsValue = const_cast<EdgeData&>(lhsLeafPt->getValue(offset));
if (rhsValue.mXDist < lhsValue.mXDist) {
lhsValue.mXDist = rhsValue.mXDist;
lhsValue.mXPrim = rhsValue.mXPrim;
}
if (rhsValue.mYDist < lhsValue.mYDist) {
lhsValue.mYDist = rhsValue.mYDist;
lhsValue.mYPrim = rhsValue.mYPrim;
}
if (rhsValue.mZDist < lhsValue.mZDist) {
lhsValue.mZDist = rhsValue.mZDist;
lhsValue.mZPrim = rhsValue.mZPrim;
}
}
} // end value iteration
}
} // end leaf iteration
}
inline void
MeshToVoxelEdgeData::GenEdgeData::operator()(const tbb::blocked_range<size_t> &range)
{
Primitive prim;
for (size_t n = range.begin(); n < range.end(); ++n) {
const Vec4I& verts = mPolygonList[n];
prim.index = Int32(n);
prim.a = Vec3d(mPointList[verts[0]]);
prim.b = Vec3d(mPointList[verts[1]]);
prim.c = Vec3d(mPointList[verts[2]]);
if (util::INVALID_IDX != verts[3]) {
prim.d = Vec3d(mPointList[verts[3]]);
voxelize<true>(prim);
} else {
voxelize<false>(prim);
}
}
}
template<bool IsQuad>
inline void
MeshToVoxelEdgeData::GenEdgeData::voxelize(const Primitive& prim)
{
std::deque<Coord> coordList;
Coord ijk, nijk;
ijk = Coord::floor(prim.a);
coordList.push_back(ijk);
evalPrimitive<IsQuad>(ijk, prim);
while (!coordList.empty()) {
ijk = coordList.back();
coordList.pop_back();
for (Int32 i = 0; i < 26; ++i) {
nijk = ijk + util::COORD_OFFSETS[i];
if (prim.index != mLastPrimAccessor.getValue(nijk)) {
mLastPrimAccessor.setValue(nijk, prim.index);
if(evalPrimitive<IsQuad>(nijk, prim)) coordList.push_back(nijk);
}
}
}
}
template<bool IsQuad>
inline bool
MeshToVoxelEdgeData::GenEdgeData::evalPrimitive(const Coord& ijk, const Primitive& prim)
{
Vec3d uvw, org(ijk[0], ijk[1], ijk[2]);
bool intersecting = false;
double t;
EdgeData edgeData;
mAccessor.probeValue(ijk, edgeData);
// Evaluate first triangle
double dist = (org -
closestPointOnTriangleToPoint(prim.a, prim.c, prim.b, org, uvw)).lengthSqr();
if (rayTriangleIntersection(org, Vec3d(1.0, 0.0, 0.0), prim.a, prim.c, prim.b, t)) {
if (t < edgeData.mXDist) {
edgeData.mXDist = float(t);
edgeData.mXPrim = prim.index;
intersecting = true;
}
}
if (rayTriangleIntersection(org, Vec3d(0.0, 1.0, 0.0), prim.a, prim.c, prim.b, t)) {
if (t < edgeData.mYDist) {
edgeData.mYDist = float(t);
edgeData.mYPrim = prim.index;
intersecting = true;
}
}
if (rayTriangleIntersection(org, Vec3d(0.0, 0.0, 1.0), prim.a, prim.c, prim.b, t)) {
if (t < edgeData.mZDist) {
edgeData.mZDist = float(t);
edgeData.mZPrim = prim.index;
intersecting = true;
}
}
if (IsQuad) {
// Split quad into a second triangle and calculate distance.
double secondDist = (org -
closestPointOnTriangleToPoint(prim.a, prim.d, prim.c, org, uvw)).lengthSqr();
if (secondDist < dist) dist = secondDist;
if (rayTriangleIntersection(org, Vec3d(1.0, 0.0, 0.0), prim.a, prim.d, prim.c, t)) {
if (t < edgeData.mXDist) {
edgeData.mXDist = float(t);
edgeData.mXPrim = prim.index;
intersecting = true;
}
}
if (rayTriangleIntersection(org, Vec3d(0.0, 1.0, 0.0), prim.a, prim.d, prim.c, t)) {
if (t < edgeData.mYDist) {
edgeData.mYDist = float(t);
edgeData.mYPrim = prim.index;
intersecting = true;
}
}
if (rayTriangleIntersection(org, Vec3d(0.0, 0.0, 1.0), prim.a, prim.d, prim.c, t)) {
if (t < edgeData.mZDist) {
edgeData.mZDist = float(t);
edgeData.mZPrim = prim.index;
intersecting = true;
}
}
}
if (intersecting) mAccessor.setValue(ijk, edgeData);
return (dist < 0.86602540378443861);
}
inline bool
MeshToVoxelEdgeData::GenEdgeData::rayTriangleIntersection(
const Vec3d& origin, const Vec3d& dir,
const Vec3d& a, const Vec3d& b, const Vec3d& c,
double& t)
{
// Check if ray is parallel with triangle
Vec3d e1 = b - a;
Vec3d e2 = c - a;
Vec3d s1 = dir.cross(e2);
double divisor = s1.dot(e1);
if (!(std::abs(divisor) > 0.0)) return false;
// Compute barycentric coordinates
double inv_divisor = 1.0 / divisor;
Vec3d d = origin - a;
double b1 = d.dot(s1) * inv_divisor;
if (b1 < 0.0 || b1 > 1.0) return false;
Vec3d s2 = d.cross(e1);
double b2 = dir.dot(s2) * inv_divisor;
if (b2 < 0.0 || (b1 + b2) > 1.0) return false;
// Compute distance to intersection point
t = e2.dot(s2) * inv_divisor;
return (t < 0.0) ? false : true;
}
////////////////////////////////////////
inline
MeshToVoxelEdgeData::MeshToVoxelEdgeData()
: mTree(EdgeData())
{
}
inline void
MeshToVoxelEdgeData::convert(
const std::vector<Vec3s>& pointList,
const std::vector<Vec4I>& polygonList)
{
GenEdgeData converter(pointList, polygonList);
converter.run();
mTree.clear();
mTree.merge(converter.tree());
}
inline void
MeshToVoxelEdgeData::getEdgeData(
Accessor& acc,
const Coord& ijk,
std::vector<Vec3d>& points,
std::vector<Index32>& primitives)
{
EdgeData data;
Vec3d point;
Coord coord = ijk;
if (acc.probeValue(coord, data)) {
if (data.mXPrim != util::INVALID_IDX) {
point[0] = double(coord[0]) + data.mXDist;
point[1] = double(coord[1]);
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mXPrim);
}
if (data.mYPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]) + data.mYDist;
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mYPrim);
}
if (data.mZPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]);
point[2] = double(coord[2]) + data.mZDist;
points.push_back(point);
primitives.push_back(data.mZPrim);
}
}
coord[0] += 1;
if (acc.probeValue(coord, data)) {
if (data.mYPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]) + data.mYDist;
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mYPrim);
}
if (data.mZPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]);
point[2] = double(coord[2]) + data.mZDist;
points.push_back(point);
primitives.push_back(data.mZPrim);
}
}
coord[2] += 1;
if (acc.probeValue(coord, data)) {
if (data.mYPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]) + data.mYDist;
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mYPrim);
}
}
coord[0] -= 1;
if (acc.probeValue(coord, data)) {
if (data.mXPrim != util::INVALID_IDX) {
point[0] = double(coord[0]) + data.mXDist;
point[1] = double(coord[1]);
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mXPrim);
}
if (data.mYPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]) + data.mYDist;
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mYPrim);
}
}
coord[1] += 1;
if (acc.probeValue(coord, data)) {
if (data.mXPrim != util::INVALID_IDX) {
point[0] = double(coord[0]) + data.mXDist;
point[1] = double(coord[1]);
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mXPrim);
}
}
coord[2] -= 1;
if (acc.probeValue(coord, data)) {
if (data.mXPrim != util::INVALID_IDX) {
point[0] = double(coord[0]) + data.mXDist;
point[1] = double(coord[1]);
point[2] = double(coord[2]);
points.push_back(point);
primitives.push_back(data.mXPrim);
}
if (data.mZPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]);
point[2] = double(coord[2]) + data.mZDist;
points.push_back(point);
primitives.push_back(data.mZPrim);
}
}
coord[0] += 1;
if (acc.probeValue(coord, data)) {
if (data.mZPrim != util::INVALID_IDX) {
point[0] = double(coord[0]);
point[1] = double(coord[1]);
point[2] = double(coord[2]) + data.mZDist;
points.push_back(point);
primitives.push_back(data.mZPrim);
}
}
}
template<typename GridType, typename VecType>
inline typename GridType::Ptr
createLevelSetBox(const math::BBox<VecType>& bbox,
const openvdb::math::Transform& xform,
typename VecType::ValueType halfWidth)
{
const Vec3s pmin = Vec3s(xform.worldToIndex(bbox.min()));
const Vec3s pmax = Vec3s(xform.worldToIndex(bbox.max()));
Vec3s points[8];
points[0] = Vec3s(pmin[0], pmin[1], pmin[2]);
points[1] = Vec3s(pmin[0], pmin[1], pmax[2]);
points[2] = Vec3s(pmax[0], pmin[1], pmax[2]);
points[3] = Vec3s(pmax[0], pmin[1], pmin[2]);
points[4] = Vec3s(pmin[0], pmax[1], pmin[2]);
points[5] = Vec3s(pmin[0], pmax[1], pmax[2]);
points[6] = Vec3s(pmax[0], pmax[1], pmax[2]);
points[7] = Vec3s(pmax[0], pmax[1], pmin[2]);
Vec4I faces[6];
faces[0] = Vec4I(0, 1, 2, 3); // bottom
faces[1] = Vec4I(7, 6, 5, 4); // top
faces[2] = Vec4I(4, 5, 1, 0); // front
faces[3] = Vec4I(6, 7, 3, 2); // back
faces[4] = Vec4I(0, 3, 7, 4); // left
faces[5] = Vec4I(1, 5, 6, 2); // right
QuadAndTriangleDataAdapter<Vec3s, Vec4I> mesh(points, 8, faces, 6);
return meshToVolume<GridType>(mesh, xform, halfWidth, halfWidth);
}
} // namespace tools
} // namespace OPENVDB_VERSION_NAME
} // namespace openvdb
#endif // OPENVDB_TOOLS_MESH_TO_VOLUME_HAS_BEEN_INCLUDED
// Copyright (c) 2012-2015 DreamWorks Animation LLC
// All rights reserved. This software is distributed under the
// Mozilla Public License 2.0 ( http://www.mozilla.org/MPL/2.0/ )
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