virtualx-engine/thirdparty/embree-aarch64/kernels/common/accelset.h

// Copyright 2009-2020 Intel Corporation
// SPDX-License-Identifier: Apache-2.0

#pragma once

#include "default.h"
#include "builder.h"
#include "geometry.h"
#include "ray.h"
#include "hit.h"

namespace embree
{
  struct IntersectFunctionNArguments;
  struct OccludedFunctionNArguments;
  
  typedef void (*ReportIntersectionFunc) (IntersectFunctionNArguments* args, const RTCFilterFunctionNArguments* filter_args);
  typedef void (*ReportOcclusionFunc) (OccludedFunctionNArguments* args, const RTCFilterFunctionNArguments* filter_args);
  
  struct IntersectFunctionNArguments : public RTCIntersectFunctionNArguments
  {
    IntersectContext* internal_context;
    Geometry* geometry;
    ReportIntersectionFunc report;
  };

  struct OccludedFunctionNArguments : public RTCOccludedFunctionNArguments
  {
    IntersectContext* internal_context;
    Geometry* geometry;
    ReportOcclusionFunc report;
  };

  /*! Base class for set of acceleration structures. */
  class AccelSet : public Geometry
  {
  public:
    typedef RTCIntersectFunctionN IntersectFuncN;  
    typedef RTCOccludedFunctionN OccludedFuncN;
    typedef void (*ErrorFunc) ();

      struct IntersectorN
      {
        IntersectorN (ErrorFunc error = nullptr) ;
        IntersectorN (IntersectFuncN intersect, OccludedFuncN occluded, const char* name);
        
        operator bool() const { return name; }
        
      public:
        static const char* type;
        IntersectFuncN intersect;
        OccludedFuncN occluded; 
        const char* name;
      };
      
    public:
      
      /*! construction */
      AccelSet (Device* device, Geometry::GType gtype, size_t items, size_t numTimeSteps);
      
      /*! makes the acceleration structure immutable */
      virtual void immutable () {}
      
      /*! build accel */
      virtual void build () = 0;

      /*! check if the i'th primitive is valid between the specified time range */
      __forceinline bool valid(size_t i, const range<size_t>& itime_range) const
      {
        for (size_t itime = itime_range.begin(); itime <= itime_range.end(); itime++)
          if (!isvalid_non_empty(bounds(i,itime))) return false;
        
        return true;
      }

      /*! Calculates the bounds of an item */
      __forceinline BBox3fa bounds(size_t i, size_t itime = 0) const
      {
        BBox3fa box;
        assert(i < size());
        RTCBoundsFunctionArguments args;
        args.geometryUserPtr = userPtr;
        args.primID = (unsigned int)i;
        args.timeStep = (unsigned int)itime;
        args.bounds_o = (RTCBounds*)&box;
        boundsFunc(&args);
        return box;
      }

      /*! calculates the linear bounds of the i'th item at the itime'th time segment */
      __forceinline LBBox3fa linearBounds(size_t i, size_t itime) const
      {
        BBox3fa box[2];
        assert(i < size());
        RTCBoundsFunctionArguments args;
        args.geometryUserPtr = userPtr;
        args.primID = (unsigned int)i;
        args.timeStep = (unsigned int)(itime+0);
        args.bounds_o = (RTCBounds*)&box[0];
        boundsFunc(&args);
        args.timeStep = (unsigned int)(itime+1);
        args.bounds_o = (RTCBounds*)&box[1];
        boundsFunc(&args);
        return LBBox3fa(box[0],box[1]);
      }

      /*! calculates the build bounds of the i'th item, if it's valid */
      __forceinline bool buildBounds(size_t i, BBox3fa* bbox = nullptr) const
      {
        const BBox3fa b = bounds(i);
        if (bbox) *bbox = b;
        return isvalid_non_empty(b);
      }

      /*! calculates the build bounds of the i'th item at the itime'th time segment, if it's valid */
      __forceinline bool buildBounds(size_t i, size_t itime, BBox3fa& bbox) const
      {
        const LBBox3fa bounds = linearBounds(i,itime);
        bbox = bounds.bounds0; // use bounding box of first timestep to build BVH
        return isvalid_non_empty(bounds);
      }

      /*! calculates the linear bounds of the i'th primitive for the specified time range */
      __forceinline LBBox3fa linearBounds(size_t primID, const BBox1f& dt) const {
        return LBBox3fa([&] (size_t itime) { return bounds(primID, itime); }, dt, time_range, fnumTimeSegments);
      }
      
      /*! calculates the linear bounds of the i'th primitive for the specified time range */
      __forceinline bool linearBounds(size_t i, const BBox1f& time_range, LBBox3fa& bbox) const  {
        if (!valid(i, timeSegmentRange(time_range))) return false;
        bbox = linearBounds(i, time_range);
        return true;
      }

      /* gets version info of topology */
      unsigned int getTopologyVersion() const {
        return numPrimitives;
      }
    
      /* returns true if topology changed */
      bool topologyChanged(unsigned int otherVersion) const {
        return numPrimitives != otherVersion;
      }

  public:

      /*! Intersects a single ray with the scene. */
      __forceinline void intersect (RayHit& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportIntersectionFunc report) 
      {
        assert(primID < size());
        assert(intersectorN.intersect);
        
        int mask = -1;
        IntersectFunctionNArguments args;
        args.valid = &mask;
        args.geometryUserPtr = userPtr;
        args.context = context->user;
        args.rayhit = (RTCRayHitN*)&ray;
        args.N = 1;
        args.geomID = geomID;
        args.primID = primID;
        args.internal_context = context;
        args.geometry = this;
        args.report = report;
        
        intersectorN.intersect(&args);
      }

      /*! Tests if single ray is occluded by the scene. */
      __forceinline void occluded (Ray& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportOcclusionFunc report)
      {
        assert(primID < size());
        assert(intersectorN.occluded);
        
        int mask = -1;
        OccludedFunctionNArguments args;
        args.valid = &mask;
        args.geometryUserPtr = userPtr;
        args.context = context->user;
        args.ray = (RTCRayN*)&ray;
        args.N = 1;
        args.geomID = geomID;
        args.primID = primID;
        args.internal_context = context;
        args.geometry = this;
        args.report = report;
        
        intersectorN.occluded(&args);
      }
   
      /*! Intersects a packet of K rays with the scene. */
      template<int K>
        __forceinline void intersect (const vbool<K>& valid, RayHitK<K>& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportIntersectionFunc report) 
      {
        assert(primID < size());
        assert(intersectorN.intersect);
        
        vint<K> mask = valid.mask32();
        IntersectFunctionNArguments args;
        args.valid = (int*)&mask;
        args.geometryUserPtr = userPtr;
        args.context = context->user;
        args.rayhit = (RTCRayHitN*)&ray;
        args.N = K;
        args.geomID = geomID;
        args.primID = primID;
        args.internal_context = context;
        args.geometry = this;
        args.report = report;
         
        intersectorN.intersect(&args);
      }

      /*! Tests if a packet of K rays is occluded by the scene. */
      template<int K>
        __forceinline void occluded (const vbool<K>& valid, RayK<K>& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportOcclusionFunc report)
      {
        assert(primID < size());
        assert(intersectorN.occluded);
        
        vint<K> mask = valid.mask32();
        OccludedFunctionNArguments args;
        args.valid = (int*)&mask;
        args.geometryUserPtr = userPtr;
        args.context = context->user;
        args.ray = (RTCRayN*)&ray;
        args.N = K;
        args.geomID = geomID;
        args.primID = primID;
        args.internal_context = context;
        args.geometry = this;
        args.report = report;
        
        intersectorN.occluded(&args);
      }

    public:
      RTCBoundsFunction boundsFunc;
      IntersectorN intersectorN;
  };
  
#define DEFINE_SET_INTERSECTORN(symbol,intersector)                     \
  AccelSet::IntersectorN symbol() {                                     \
    return AccelSet::IntersectorN(intersector::intersect, \
                                  intersector::occluded, \
                                  TOSTRING(isa) "::" TOSTRING(symbol)); \
  }
}
Add Embree-aarch64 thirdparty library 2021-04-20 18:38:09 +02:00			`// Copyright 2009-2020 Intel Corporation`
			`// SPDX-License-Identifier: Apache-2.0`

			`#pragma once`

			`#include "default.h"`
			`#include "builder.h"`
			`#include "geometry.h"`
			`#include "ray.h"`
			`#include "hit.h"`

			`namespace embree`
			`{`
			`struct IntersectFunctionNArguments;`
			`struct OccludedFunctionNArguments;`

			`typedef void (ReportIntersectionFunc) (IntersectFunctionNArguments args, const RTCFilterFunctionNArguments* filter_args);`
			`typedef void (ReportOcclusionFunc) (OccludedFunctionNArguments args, const RTCFilterFunctionNArguments* filter_args);`

			`struct IntersectFunctionNArguments : public RTCIntersectFunctionNArguments`
			`{`
			`IntersectContext* internal_context;`
			`Geometry* geometry;`
			`ReportIntersectionFunc report;`
			`};`

			`struct OccludedFunctionNArguments : public RTCOccludedFunctionNArguments`
			`{`
			`IntersectContext* internal_context;`
			`Geometry* geometry;`
			`ReportOcclusionFunc report;`
			`};`

			`/! Base class for set of acceleration structures. /`
			`class AccelSet : public Geometry`
			`{`
			`public:`
			`typedef RTCIntersectFunctionN IntersectFuncN;`
			`typedef RTCOccludedFunctionN OccludedFuncN;`
			`typedef void (*ErrorFunc) ();`

			`struct IntersectorN`
			`{`
			`IntersectorN (ErrorFunc error = nullptr) ;`
			`IntersectorN (IntersectFuncN intersect, OccludedFuncN occluded, const char* name);`

			`operator bool() const { return name; }`

			`public:`
			`static const char* type;`
			`IntersectFuncN intersect;`
			`OccludedFuncN occluded;`
			`const char* name;`
			`};`

			`public:`

			`/! construction /`
			`AccelSet (Device* device, Geometry::GType gtype, size_t items, size_t numTimeSteps);`

			`/! makes the acceleration structure immutable /`
			`virtual void immutable () {}`

			`/! build accel /`
			`virtual void build () = 0;`

			`/! check if the i'th primitive is valid between the specified time range /`
			`__forceinline bool valid(size_t i, const range<size_t>& itime_range) const`
			`{`
			`for (size_t itime = itime_range.begin(); itime <= itime_range.end(); itime++)`
			`if (!isvalid_non_empty(bounds(i,itime))) return false;`

			`return true;`
			`}`

			`/! Calculates the bounds of an item /`
			`__forceinline BBox3fa bounds(size_t i, size_t itime = 0) const`
			`{`
			`BBox3fa box;`
			`assert(i < size());`
			`RTCBoundsFunctionArguments args;`
			`args.geometryUserPtr = userPtr;`
			`args.primID = (unsigned int)i;`
			`args.timeStep = (unsigned int)itime;`
			`args.bounds_o = (RTCBounds*)&box;`
			`boundsFunc(&args);`
			`return box;`
			`}`

			`/! calculates the linear bounds of the i'th item at the itime'th time segment /`
			`__forceinline LBBox3fa linearBounds(size_t i, size_t itime) const`
			`{`
			`BBox3fa box[2];`
			`assert(i < size());`
			`RTCBoundsFunctionArguments args;`
			`args.geometryUserPtr = userPtr;`
			`args.primID = (unsigned int)i;`
			`args.timeStep = (unsigned int)(itime+0);`
			`args.bounds_o = (RTCBounds*)&box[0];`
			`boundsFunc(&args);`
			`args.timeStep = (unsigned int)(itime+1);`
			`args.bounds_o = (RTCBounds*)&box[1];`
			`boundsFunc(&args);`
			`return LBBox3fa(box[0],box[1]);`
			`}`

			`/! calculates the build bounds of the i'th item, if it's valid /`
			`__forceinline bool buildBounds(size_t i, BBox3fa* bbox = nullptr) const`
			`{`
			`const BBox3fa b = bounds(i);`
			`if (bbox) *bbox = b;`
			`return isvalid_non_empty(b);`
			`}`

			`/! calculates the build bounds of the i'th item at the itime'th time segment, if it's valid /`
			`__forceinline bool buildBounds(size_t i, size_t itime, BBox3fa& bbox) const`
			`{`
			`const LBBox3fa bounds = linearBounds(i,itime);`
			`bbox = bounds.bounds0; // use bounding box of first timestep to build BVH`
			`return isvalid_non_empty(bounds);`
			`}`

			`/! calculates the linear bounds of the i'th primitive for the specified time range /`
			`__forceinline LBBox3fa linearBounds(size_t primID, const BBox1f& dt) const {`
			`return LBBox3fa([&] (size_t itime) { return bounds(primID, itime); }, dt, time_range, fnumTimeSegments);`
			`}`

			`/! calculates the linear bounds of the i'th primitive for the specified time range /`
			`__forceinline bool linearBounds(size_t i, const BBox1f& time_range, LBBox3fa& bbox) const {`
			`if (!valid(i, timeSegmentRange(time_range))) return false;`
			`bbox = linearBounds(i, time_range);`
			`return true;`
			`}`

			`/* gets version info of topology */`
			`unsigned int getTopologyVersion() const {`
			`return numPrimitives;`
			`}`

			`/* returns true if topology changed */`
			`bool topologyChanged(unsigned int otherVersion) const {`
			`return numPrimitives != otherVersion;`
			`}`

			`public:`

			`/! Intersects a single ray with the scene. /`
			`__forceinline void intersect (RayHit& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportIntersectionFunc report)`
			`{`
			`assert(primID < size());`
			`assert(intersectorN.intersect);`

			`int mask = -1;`
			`IntersectFunctionNArguments args;`
			`args.valid = &mask;`
			`args.geometryUserPtr = userPtr;`
			`args.context = context->user;`
			`args.rayhit = (RTCRayHitN*)&ray;`
			`args.N = 1;`
			`args.geomID = geomID;`
			`args.primID = primID;`
			`args.internal_context = context;`
			`args.geometry = this;`
			`args.report = report;`

			`intersectorN.intersect(&args);`
			`}`

			`/! Tests if single ray is occluded by the scene. /`
			`__forceinline void occluded (Ray& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportOcclusionFunc report)`
			`{`
			`assert(primID < size());`
			`assert(intersectorN.occluded);`

			`int mask = -1;`
			`OccludedFunctionNArguments args;`
			`args.valid = &mask;`
			`args.geometryUserPtr = userPtr;`
			`args.context = context->user;`
			`args.ray = (RTCRayN*)&ray;`
			`args.N = 1;`
			`args.geomID = geomID;`
			`args.primID = primID;`
			`args.internal_context = context;`
			`args.geometry = this;`
			`args.report = report;`

			`intersectorN.occluded(&args);`
			`}`

			`/! Intersects a packet of K rays with the scene. /`
			`template<int K>`
			`__forceinline void intersect (const vbool<K>& valid, RayHitK<K>& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportIntersectionFunc report)`
			`{`
			`assert(primID < size());`
			`assert(intersectorN.intersect);`

			`vint<K> mask = valid.mask32();`
			`IntersectFunctionNArguments args;`
			`args.valid = (int*)&mask;`
			`args.geometryUserPtr = userPtr;`
			`args.context = context->user;`
			`args.rayhit = (RTCRayHitN*)&ray;`
			`args.N = K;`
			`args.geomID = geomID;`
			`args.primID = primID;`
			`args.internal_context = context;`
			`args.geometry = this;`
			`args.report = report;`

			`intersectorN.intersect(&args);`
			`}`

			`/! Tests if a packet of K rays is occluded by the scene. /`
			`template<int K>`
			`__forceinline void occluded (const vbool<K>& valid, RayK<K>& ray, unsigned int geomID, unsigned int primID, IntersectContext* context, ReportOcclusionFunc report)`
			`{`
			`assert(primID < size());`
			`assert(intersectorN.occluded);`

			`vint<K> mask = valid.mask32();`
			`OccludedFunctionNArguments args;`
			`args.valid = (int*)&mask;`
			`args.geometryUserPtr = userPtr;`
			`args.context = context->user;`
			`args.ray = (RTCRayN*)&ray;`
			`args.N = K;`
			`args.geomID = geomID;`
			`args.primID = primID;`
			`args.internal_context = context;`
			`args.geometry = this;`
			`args.report = report;`

			`intersectorN.occluded(&args);`
			`}`

			`public:`
			`RTCBoundsFunction boundsFunc;`
			`IntersectorN intersectorN;`
			`};`

			`#define DEFINE_SET_INTERSECTORN(symbol,intersector) \`
			`AccelSet::IntersectorN symbol() { \`
			`return AccelSet::IntersectorN(intersector::intersect, \`
			`intersector::occluded, \`
			`TOSTRING(isa) "::" TOSTRING(symbol)); \`
			`}`
			`}`