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authorMatt Strapp <matt@mattstrapp.net>2021-09-27 21:44:53 -0500
committerMatt Strapp <matt@mattstrapp.net>2021-09-27 21:44:53 -0500
commitb38e870d6be22a377bf7b0fb5048801886ebaa77 (patch)
tree18e021a36e2f939892eb4895269f420274a341df /dev/MinGfx/src/ray.h
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diff --git a/dev/MinGfx/src/ray.h b/dev/MinGfx/src/ray.h
index d1b41b6..4bc3a8c 100644
--- a/dev/MinGfx/src/ray.h
+++ b/dev/MinGfx/src/ray.h
@@ -1,166 +1,166 @@
-/*
- This file is part of the MinGfx Project.
-
- Copyright (c) 2017,2018 Regents of the University of Minnesota.
- All Rights Reserved.
-
- Original Author(s) of this File:
- Dan Keefe, 2018, University of Minnesota
-
- Author(s) of Significant Updates/Modifications to the File:
- ...
- */
-
-#ifndef SRC_RAY_H_
-#define SRC_RAY_H_
-
-#include <iostream>
-
-#include "aabb.h"
-#include "point3.h"
-#include "vector3.h"
-#include "mesh.h"
-
-
-namespace mingfx {
-
-
-/** Stores the mathematical object of a ray that begins at an origin (a 3D
- point) and points in a direction (a unit 3D vector). Rays can intersect
- a variety of other computer graphics objects, such as planes, triangles,
- spheres, 3D meshes, etc. These intersections can be tested with the
- Intersect...() methods. The Ray can also be transformed by a Matrix4.
- Example:
- ~~~
- // Create a pick ray from the mouse position
- void MyGraphicsApp::OnLeftMouseDown(const Point2 &mouse_in_2d_pixels) {
- Point2 mouse_in_2d_ndc = PixelsToNormalizedDeviceCoords(mouse_in_2d_pixels);
- Point3 mouse_in_3d = GfxMath::ScreenToNearPlane(view_matrix, proj_matrix, mouse_in_2d_ndc);
- Matrix4 camera_matrix = view_matrix.Inverse();
- Point3 eye = camera_matrix.ColumnToPoint3(3);
-
- Ray pick_ray(eye, mouse_in_3d - eye);
-
- // check to see if the ray intersects a sphere
- float t;
- Point3 p;
- if (pick_ray.IntersectSphere(Point3(0,0,0), 2.0, &t, &p)) {
- std::cout << "Mouse pointing at sphere! Intersection point = " << p << std::endl;
- }
- }
- ~~~
- */
-class Ray {
-public:
-
- /// Defaults to a ray at the origin and pointing in the -Z direction
- Ray();
-
- /// Creates a ray from a 3D origin and direction
- Ray(const Point3 &origin, const Vector3 &direction);
-
- /// Ray destructor
- virtual ~Ray();
-
- /// Check for "equality", taking floating point imprecision into account
- bool operator==(const Ray& other) const;
-
- /// Check for "inequality", taking floating point imprecision into account
- bool operator!=(const Ray& other) const;
-
- /// Returns the length of the direction vector
- float Length() const;
-
- /** Checks to see if the ray intersects a plane defined by a point and a normal.
- If there was an intersection, true is returned, iTime is set to the intersection
- time, and iPoint is set to the intersection point. The plane is considered
- to be 1-sided. That is the intersection will only occur if the ray hits the
- plane from its front side as determined by the plane's normal.
- */
- bool IntersectPlane(const Point3 &planePt, const Vector3 &planeNormal,
- float *iTime, Point3 *iPoint) const;
-
- /** Checks to see if the ray intersects a triangle defined by the vertices v1, v2, and v3.
- The vertices must be provided in counter-clockwise order so that the normal of the
- triangle can be determined via the right-hand rule. The intersection will only happen
- if the ray hits the front side of the triangle. If there was an intersection,
- true is returned, iTime is set to the intersection time, and iPoint is set to the intersection point.
- */
- bool IntersectTriangle(const Point3 &v1, const Point3 &v2, const Point3 &v3,
- float *iTime, Point3 *iPoint) const;
-
- /** Checks to see if the ray intersects a quad defined by the vertices v1, v2, v3, and v4.
- The vertices must be provided in counter-clockwise order so that the normal of the
- triangle can be determined via the right-hand rule. The intersection will only happen
- if the ray hits the front side of the triangle. If there was an intersection,
- true is returned, iTime is set to the intersection time, and iPoint is set to the intersection point.
- */
- bool IntersectQuad(const Point3 &v1, const Point3 &v2, const Point3 &v3, const Point3 &v4,
- float *iTime, Point3 *iPoint) const;
-
- /** Checks to see if the ray intersects a sphere defined by a center point and a radius.
- If there was an intersection, true is returned, iTime is set to the intersection time,
- and iPoint is set to the intersection point.
- */
- bool IntersectSphere(const Point3 &center, float radius,
- float *iTime, Point3 *iPoint) const;
-
- /** Checks to see if the ray intersects a triangle mesh. This is a brute-force
- check over each triangle in the mesh. If there was an intersection, true is returned,
- iTime is set to the intersection time, iPoint is set to the intersection point,
- and iTriangleID is set to the ID of the closest intersected triangle along the ray.
- */
- bool IntersectMesh(const Mesh &mesh, float *iTime,
- Point3 *iPoint, int *iTriangleID) const;
-
- /** Checks to see if the ray intersects a triangle mesh. This uses a BVH
- (Bounding Volume Hierarchy) to accelerate the ray-triangle intersection tests.
- Each mesh can optionally store a BVH. If a BVH has already been calculated
- for the mesh (done with Mesh::CalculateBVH()), then this function will be
- much faster than the brute-force IntersectMesh() function. If a BVH has
- not already been calculated for the mesh, the first call to FastIntersectMesh()
- will trigger the mesh to create a BVH (not a fast operation) but then
- subsequent calls to FastIntersectMesh() will be fast.
- */
- bool FastIntersectMesh(Mesh *mesh, float *iTime,
- Point3 *iPoint, int *iTriangleID) const;
-
- /** Checks to see if the ray intersects an AABB (Axis-Aligned Bounding Box).
- Typically, this is the first step of a more detailed intersection test and
- we don't care about the actual point of intersection, just whether it
- intersects or not. So, we don't bother calculating the iPoint. We get the
- iTime for free though, so we do return that. You can calc the iPoint if
- you want using:
- ~~~
- float t;
- if (ray.IntersectAABB(box, &t)) {
- Point3 iPoint = ray.origin() + t*ray.direction();
- }
- ~~~
- */
- bool IntersectAABB(const AABB &box, float *iTime) const;
-
- /// Returns the origin
- Point3 origin() const;
-
- /// Returns the direction
- Vector3 direction() const;
-
- /// Sets a new origin and direction
- void set(Point3 newOrigin, Vector3 newDir);
-
-private:
- Point3 p_;
- Vector3 d_;
-};
-
-
-// --- Stream operators ---
-
-std::ostream & operator<< ( std::ostream &os, const Ray &r);
-std::istream & operator>> ( std::istream &is, Ray &r);
-
-
-} // end namespace
-
-#endif
+/*
+ This file is part of the MinGfx Project.
+
+ Copyright (c) 2017,2018 Regents of the University of Minnesota.
+ All Rights Reserved.
+
+ Original Author(s) of this File:
+ Dan Keefe, 2018, University of Minnesota
+
+ Author(s) of Significant Updates/Modifications to the File:
+ ...
+ */
+
+#ifndef SRC_RAY_H_
+#define SRC_RAY_H_
+
+#include <iostream>
+
+#include "aabb.h"
+#include "point3.h"
+#include "vector3.h"
+#include "mesh.h"
+
+
+namespace mingfx {
+
+
+/** Stores the mathematical object of a ray that begins at an origin (a 3D
+ point) and points in a direction (a unit 3D vector). Rays can intersect
+ a variety of other computer graphics objects, such as planes, triangles,
+ spheres, 3D meshes, etc. These intersections can be tested with the
+ Intersect...() methods. The Ray can also be transformed by a Matrix4.
+ Example:
+ ~~~
+ // Create a pick ray from the mouse position
+ void MyGraphicsApp::OnLeftMouseDown(const Point2 &mouse_in_2d_pixels) {
+ Point2 mouse_in_2d_ndc = PixelsToNormalizedDeviceCoords(mouse_in_2d_pixels);
+ Point3 mouse_in_3d = GfxMath::ScreenToNearPlane(view_matrix, proj_matrix, mouse_in_2d_ndc);
+ Matrix4 camera_matrix = view_matrix.Inverse();
+ Point3 eye = camera_matrix.ColumnToPoint3(3);
+
+ Ray pick_ray(eye, mouse_in_3d - eye);
+
+ // check to see if the ray intersects a sphere
+ float t;
+ Point3 p;
+ if (pick_ray.IntersectSphere(Point3(0,0,0), 2.0, &t, &p)) {
+ std::cout << "Mouse pointing at sphere! Intersection point = " << p << std::endl;
+ }
+ }
+ ~~~
+ */
+class Ray {
+public:
+
+ /// Defaults to a ray at the origin and pointing in the -Z direction
+ Ray();
+
+ /// Creates a ray from a 3D origin and direction
+ Ray(const Point3 &origin, const Vector3 &direction);
+
+ /// Ray destructor
+ virtual ~Ray();
+
+ /// Check for "equality", taking floating point imprecision into account
+ bool operator==(const Ray& other) const;
+
+ /// Check for "inequality", taking floating point imprecision into account
+ bool operator!=(const Ray& other) const;
+
+ /// Returns the length of the direction vector
+ float Length() const;
+
+ /** Checks to see if the ray intersects a plane defined by a point and a normal.
+ If there was an intersection, true is returned, iTime is set to the intersection
+ time, and iPoint is set to the intersection point. The plane is considered
+ to be 1-sided. That is the intersection will only occur if the ray hits the
+ plane from its front side as determined by the plane's normal.
+ */
+ bool IntersectPlane(const Point3 &planePt, const Vector3 &planeNormal,
+ float *iTime, Point3 *iPoint) const;
+
+ /** Checks to see if the ray intersects a triangle defined by the vertices v1, v2, and v3.
+ The vertices must be provided in counter-clockwise order so that the normal of the
+ triangle can be determined via the right-hand rule. The intersection will only happen
+ if the ray hits the front side of the triangle. If there was an intersection,
+ true is returned, iTime is set to the intersection time, and iPoint is set to the intersection point.
+ */
+ bool IntersectTriangle(const Point3 &v1, const Point3 &v2, const Point3 &v3,
+ float *iTime, Point3 *iPoint) const;
+
+ /** Checks to see if the ray intersects a quad defined by the vertices v1, v2, v3, and v4.
+ The vertices must be provided in counter-clockwise order so that the normal of the
+ triangle can be determined via the right-hand rule. The intersection will only happen
+ if the ray hits the front side of the triangle. If there was an intersection,
+ true is returned, iTime is set to the intersection time, and iPoint is set to the intersection point.
+ */
+ bool IntersectQuad(const Point3 &v1, const Point3 &v2, const Point3 &v3, const Point3 &v4,
+ float *iTime, Point3 *iPoint) const;
+
+ /** Checks to see if the ray intersects a sphere defined by a center point and a radius.
+ If there was an intersection, true is returned, iTime is set to the intersection time,
+ and iPoint is set to the intersection point.
+ */
+ bool IntersectSphere(const Point3 &center, float radius,
+ float *iTime, Point3 *iPoint) const;
+
+ /** Checks to see if the ray intersects a triangle mesh. This is a brute-force
+ check over each triangle in the mesh. If there was an intersection, true is returned,
+ iTime is set to the intersection time, iPoint is set to the intersection point,
+ and iTriangleID is set to the ID of the closest intersected triangle along the ray.
+ */
+ bool IntersectMesh(const Mesh &mesh, float *iTime,
+ Point3 *iPoint, int *iTriangleID) const;
+
+ /** Checks to see if the ray intersects a triangle mesh. This uses a BVH
+ (Bounding Volume Hierarchy) to accelerate the ray-triangle intersection tests.
+ Each mesh can optionally store a BVH. If a BVH has already been calculated
+ for the mesh (done with Mesh::CalculateBVH()), then this function will be
+ much faster than the brute-force IntersectMesh() function. If a BVH has
+ not already been calculated for the mesh, the first call to FastIntersectMesh()
+ will trigger the mesh to create a BVH (not a fast operation) but then
+ subsequent calls to FastIntersectMesh() will be fast.
+ */
+ bool FastIntersectMesh(Mesh *mesh, float *iTime,
+ Point3 *iPoint, int *iTriangleID) const;
+
+ /** Checks to see if the ray intersects an AABB (Axis-Aligned Bounding Box).
+ Typically, this is the first step of a more detailed intersection test and
+ we don't care about the actual point of intersection, just whether it
+ intersects or not. So, we don't bother calculating the iPoint. We get the
+ iTime for free though, so we do return that. You can calc the iPoint if
+ you want using:
+ ~~~
+ float t;
+ if (ray.IntersectAABB(box, &t)) {
+ Point3 iPoint = ray.origin() + t*ray.direction();
+ }
+ ~~~
+ */
+ bool IntersectAABB(const AABB &box, float *iTime) const;
+
+ /// Returns the origin
+ Point3 origin() const;
+
+ /// Returns the direction
+ Vector3 direction() const;
+
+ /// Sets a new origin and direction
+ void set(Point3 newOrigin, Vector3 newDir);
+
+private:
+ Point3 p_;
+ Vector3 d_;
+};
+
+
+// --- Stream operators ---
+
+std::ostream & operator<< ( std::ostream &os, const Ray &r);
+std::istream & operator>> ( std::istream &is, Ray &r);
+
+
+} // end namespace
+
+#endif