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Geometry Functions

Notice
The functions listed below are the members of the Unigine.MathLib namespace.

This class is used to represent a collection of generic 3d math functions such as line plane intersection, closest points on two lines, etc.

Geometry Class

Members


void OrthoBasis ( vec3 v, vec3 tangent, vec3 binormal ) #

Creates an ortho transformation. Output tangent and binormal vectors will be put to corresponding return vectors.

Arguments

  • vec3 v - Input vector.
  • vec3 tangent - Return tangent vector.
  • vec3 binormal - Return binormal vector.

void OrthoBasis ( dvec3 v, dvec3 tangent, dvec3 binormal ) #

Creates an ortho transformation. Output tangent and binormal vectors will be put to corresponding return vectors.

Arguments

  • dvec3 v - Input vector.
  • dvec3 tangent - Return tangent vector.
  • dvec3 binormal - Return binormal vector.

void OrthoTransform ( vec3 v, mat4 transform ) #

Creates an ortho transformation. The transformation will be put to the transformation matrix.

Arguments

  • vec3 v - Input vector.
  • mat4 transform - Transformation matrix (mat4) to be set.

void OrthoTransform ( dvec3 v, dmat4 transform ) #

Creates an ortho transformation. The transformation will be put to the transformation matrix.

Arguments

  • dvec3 v - Input vector.
  • dmat4 transform - Transformation matrix (dmat4) to be set.

quat OrthoTangent ( vec4 t, vec3 n ) #

Creates the ortho triangle tangent space basis.

Arguments

  • vec4 t - Tangent vector.
  • vec3 n - Normal vector.

Return value

Tangent basis.

quat OrthoTangent ( vec3 t, vec3 b, vec3 n ) #

Creates the ortho triangle tangent space basis.

Arguments

  • vec3 t - Tangent vector.
  • vec3 b - Binormal vector.
  • vec3 n - Normal vector.

Return value

Tangent basis.

float TriangleArea ( vec3 v0, vec3 v1, vec3 v2 ) #

Returns the triangle area.

Arguments

  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.

Return value

Triangle area.

double TriangleArea ( dvec3 v0, dvec3 v1, dvec3 v2 ) #

Returns the triangle area.

Arguments

  • dvec3 v0 - The first triangle vertex.
  • dvec3 v1 - The second triangle vertex.
  • dvec3 v2 - The third triangle vertex.

Return value

Triangle area.

vec3 TriangleNormal ( vec3 v0, vec3 v1, vec3 v2 ) #

Returns the triangle normal vector.

Arguments

  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.

Return value

Triangle normal vector.

dvec3 TriangleNormal ( dvec3 v0, dvec3 v1, dvec3 v2 ) #

Returns the triangle normal vector.

Arguments

  • dvec3 v0 - The first triangle vertex.
  • dvec3 v1 - The second triangle vertex.
  • dvec3 v2 - The third triangle vertex.

Return value

Triangle normal vector.

vec4 TrianglePlane ( vec3 v0, vec3 v1, vec3 v2 ) #

Returns the triangle plane.

Arguments

  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.

Return value

Triangle plane.

dvec4 TrianglePlane ( dvec3 v0, dvec3 v1, dvec3 v2 ) #

Returns the triangle plane.

Arguments

  • dvec3 v0 - The first triangle vertex.
  • dvec3 v1 - The second triangle vertex.
  • dvec3 v2 - The third triangle vertex.

Return value

Triangle plane.

vec4 TriangleTangent ( vec3 v0, vec3 v1, vec3 v2 ) #

Returns the triangle tangent space.

Arguments

  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.

Return value

Triangle tangent space vector.

vec4 TriangleTangent ( vec3 v0, vec3 v1, vec3 v2, vec2 t0, vec2 t1, vec2 t2, vec3 normal ) #

Returns the triangle tangent space.

Arguments

  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.
  • vec2 t0 - Tangent vector of the first triangle vertex.
  • vec2 t1 - Tangent vector of the second triangle vertex.
  • vec2 t2 - Tangent vector of the third triangle vertex.
  • vec3 normal - Normal.

Return value

Triangle tangent space vector.

vec4 TriangleTangent ( vec3 v0, vec3 v1, vec3 v2, vec2 t0, vec2 t1, vec2 t2 ) #

Returns the triangle tangent space.

Arguments

  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.
  • vec2 t0 - Tangent vector of the first triangle vertex.
  • vec2 t1 - Tangent vector of the second triangle vertex.
  • vec2 t2 - Tangent vector of the third triangle vertex.

Return value

Triangle tangent space vector.

dvec4 PolygonPlane ( dvec3[] vertex, int[] indices ) #

Returns the polygon plane.

Arguments

  • dvec3[] vertex - Vertex structure.
  • int[] indices - Array of vertex indices.

Return value

Polygon plane.

vec4 PolygonPlane ( vec3[] vertex, int[] indices ) #

Returns the polygon plane.

Arguments

  • vec3[] vertex - Vertex structure.
  • int[] indices - Array of vertex indices.

Return value

Polygon plane.

bool PointTriangleInside ( vec3 point, vec3 v0, vec3 v1, vec3 v2 ) #

Checks if a point is inside a triangle.

Arguments

  • vec3 point - Point to be checked.
  • vec3 v0 - The first vertex of the triangle.
  • vec3 v1 - The second vertex of the triangle.
  • vec3 v2 - The third vertex of the triangle.

Return value

true if the point is inside the given triangle; otherwise, false.

bool PointTriangleInside ( dvec3 point, dvec3 v0, dvec3 v1, dvec3 v2 ) #

Checks if a point is inside a triangle.

Arguments

  • dvec3 point - Point to be checked.
  • dvec3 v0 - The first vertex of the triangle.
  • dvec3 v1 - The second vertex of the triangle.
  • dvec3 v2 - The third vertex of the triangle.

Return value

true if the point is inside the given triangle; otherwise, false.

bool PointTriangleInside ( vec3 point, vec3 v0, vec3 v1, vec3 v2, vec3 normal ) #

Checks if a point is inside a triangle.

Arguments

  • vec3 point - Point to be checked.
  • vec3 v0 - The first vertex of the triangle.
  • vec3 v1 - The second vertex of the triangle.
  • vec3 v2 - The third vertex of the triangle.
  • vec3 normal - Normal to the triangle plane.

Return value

true if the point is inside the given triangle; otherwise, false.

bool PointTriangleInside ( dvec3 point, dvec3 v0, dvec3 v1, dvec3 v2, dvec3 normal ) #

Checks if a point is inside a triangle.

Arguments

  • dvec3 point - Point to be checked.
  • dvec3 v0 - The first vertex of the triangle.
  • dvec3 v1 - The second vertex of the triangle.
  • dvec3 v2 - The third vertex of the triangle.
  • dvec3 normal - Normal to the triangle plane.

Return value

true if the point is inside the given triangle; otherwise, false.

float PointTriangleDistance ( vec3 point, vec3 v0, vec3 v1, vec3 v2, vec4 plane ) #

Returns the closest distance from a point to a triangle.

Arguments

  • vec3 point - Point.
  • vec3 v0 - The first vertex of the triangle.
  • vec3 v1 - The second vertex of the triangle.
  • vec3 v2 - The third vertex of the triangle.
  • vec4 plane - Triangle plane.

Return value

Distance.

double PointTriangleDistance ( dvec3 point, dvec3 v0, dvec3 v1, dvec3 v2, dvec4 plane ) #

Returns the closest distance from a point to a triangle.

Arguments

  • dvec3 point - Point.
  • dvec3 v0 - The first vertex of the triangle.
  • dvec3 v1 - The second vertex of the triangle.
  • dvec3 v2 - The third vertex of the triangle.
  • dvec4 plane - Triangle plane.

Return value

Distance.

void PointTriangleCoordinates ( vec2 point, vec2 v0, vec2 v1, vec2 v2, float a, float b ) #

Calculates barycentric triangle coordinates. The coordinates will be put to corresponding return variables.

Arguments

  • vec2 point - Point.
  • vec2 v0 - The first vertex of the triangle.
  • vec2 v1 - The second vertex of the triangle.
  • vec2 v2 - The third vertex of the triangle.
  • float a - Return variable.
  • float b - Return variable.

void PointTriangleCoordinates ( vec3 point, vec3 v0, vec3 v1, vec3 v2, float a, float b ) #

Calculates barycentric triangle coordinates. The coordinates will be put to corresponding return variables.

Arguments

  • vec3 point - Point.
  • vec3 v0 - The first vertex of the triangle.
  • vec3 v1 - The second vertex of the triangle.
  • vec3 v2 - The third vertex of the triangle.
  • float a - Return variable.
  • float b - Return variable.

void PointTriangleCoordinates ( dvec3 point, dvec3 v0, dvec3 v1, dvec3 v2, double a, double b ) #

Calculates barycentric triangle coordinates. The coordinates will be put to corresponding return variables.

Arguments

  • dvec3 point - Point.
  • dvec3 v0 - The first vertex of the triangle.
  • dvec3 v1 - The second vertex of the triangle.
  • dvec3 v2 - The third vertex of the triangle.
  • double a - Return variable.
  • double b - Return variable.

float PointPolygonDistance ( vec3 point, vec3[] vertex, int[] indices, vec4 plane ) #

Returns the distance from a point to a polygon.

Arguments

  • vec3 point - Point.
  • vec3[] vertex - Vertex structure.
  • int[] indices - Array of vertex indices.
  • vec4 plane - Polygon plane.

Return value

Distance.

double PointPolygonDistance ( dvec3 point, dvec3[] vertex, int[] indices, dvec4 plane ) #

Returns the distance from a point to a polygon.

Arguments

  • dvec3 point - Point.
  • dvec3[] vertex - Vertex structure.
  • int[] indices - Array of vertex indices.
  • dvec4 plane - Polygon plane.

Return value

Distance.

bool RayBoundBoxIntersection ( vec3 point, vec3 direction, vec3 min, vec3 max ) #

Checks if a ray intersects a bounding box. The same function as IRayBoundBoxIntersection(), but the latter has higher performance due to reduction of division operations, as the ray direction is replaced by the pre-calculated inverse of the ray direction.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 direction - Direction of the ray.
  • vec3 min - Min coordinates of the axis-aligned bounding box.
  • vec3 max - Max coordinates of the axis-aligned bounding box.

Return value

true if the given ray intersects the given bounding box; otherwise, false.

bool RayBoundBoxIntersection ( dvec3 point, dvec3 direction, dvec3 min, dvec3 max ) #

Checks if a ray intersects a bounding box. The same function as IRayBoundBoxIntersection(), but the latter has higher performance due to reduction of division operations, as the ray direction is replaced by the pre-calculated inverse of the ray direction.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 direction - Direction of the ray.
  • dvec3 min - Min coordinates of the axis-aligned bounding box.
  • dvec3 max - Max coordinates of the axis-aligned bounding box.

Return value

true if the given ray intersects the given bounding box; otherwise, false.

bool IRayBoundBoxIntersection ( vec3 point, vec3 idirection, vec3 min, vec3 max ) #

Checks if there is an intersection between a ray and a bounding box. The same function as RayBoundBoxIntersection(), but it uses the inverse of the ray direction, which increases performance.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 idirection - Inverse direction of the ray.
  • vec3 min - Min coordinates of the axis-aligned bounding box.
  • vec3 max - Max coordinates of the axis-aligned bounding box.

Return value

true if the given ray intersects the given bounding box; otherwise, false.

bool IRayBoundBoxIntersection ( dvec3 point, dvec3 idirection, dvec3 min, dvec3 max ) #

Checks if there is an intersection between a ray and a bounding box. The same function as RayBoundBoxIntersection(), but it uses the inverse of the ray direction, which increases performance.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 idirection - Inverse direction of the ray.
  • dvec3 min - Min coordinates of the axis-aligned bounding box.
  • dvec3 max - Max coordinates of the axis-aligned bounding box.

Return value

true if the given ray intersects the given bounding box; otherwise, false.

bool RayTriangleIntersection ( vec3 point, vec3 direction, vec3 v0, vec3 v1, vec3 v2 ) #

Checks if a ray intersects a triangle.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 direction - Direction of the ray.
  • vec3 v0 - The first triangle vertex.
  • vec3 v1 - The second triangle vertex.
  • vec3 v2 - The third triangle vertex.

Return value

true if the given ray intersects the given triangle; otherwise, false.

bool RayTriangleIntersection ( dvec3 point, dvec3 direction, dvec3 v0, dvec3 v1, dvec3 v2 ) #

Checks if a ray intersects a triangle.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 direction - Direction of the ray.
  • dvec3 v0 - The first triangle vertex.
  • dvec3 v1 - The second triangle vertex.
  • dvec3 v2 - The third triangle vertex.

Return value

true if the given ray intersects the given triangle; otherwise, false.

bool LinePlaneIntersection ( vec3 p0, vec3 p1, vec4 plane ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • vec3 p0 - Start point of the line.
  • vec3 p1 - End point of the line.
  • vec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( dvec3 p0, dvec3 p1, dvec4 plane ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • dvec3 p0 - Start point of the line.
  • dvec3 p1 - End point of the line.
  • dvec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( vec3 p0, vec3 p1, vec3 plane_point, vec3 plane_normal ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • vec3 p0 - Start point of the line.
  • vec3 p1 - End point of the line.
  • vec3 plane_point - Point of the plane.
  • vec3 plane_normal - Normal to the plane.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( dvec3 p0, dvec3 p1, dvec3 plane_point, dvec3 plane_normal ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • dvec3 p0 - Start point of the line.
  • dvec3 p1 - End point of the line.
  • dvec3 plane_point - Point of the plane.
  • dvec3 plane_normal - Normal to the plane.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( vec3 p0, vec3 p1, vec4 plane, vec3 ret ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • vec3 p0 - Start point of the line.
  • vec3 p1 - End point of the line.
  • vec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.
  • vec3 ret - Return vector.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( dvec3 p0, dvec3 p1, dvec4 plane, dvec3 ret ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • dvec3 p0 - Start point of the line.
  • dvec3 p1 - End point of the line.
  • dvec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.
  • dvec3 ret - Return vector.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( vec3 p0, vec3 p1, vec3 plane_point, vec3 plane_normal, vec3 ret ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • vec3 p0 - Start point of the line.
  • vec3 p1 - End point of the line.
  • vec3 plane_point - Point of the plane.
  • vec3 plane_normal - Normal to the plane.
  • vec3 ret - Return vector.

Return value

true if the given line intersects the given plane; otherwise, false.

bool LinePlaneIntersection ( dvec3 p0, dvec3 p1, dvec3 plane_point, dvec3 plane_normal, dvec3 ret ) #

Checks if there is an intersection between a line and a plane.

Arguments

  • dvec3 p0 - Start point of the line.
  • dvec3 p1 - End point of the line.
  • dvec3 plane_point - Point of the plane.
  • dvec3 plane_normal - Normal to the plane.
  • dvec3 ret - Return vector.

Return value

true if the given line intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( vec3 point, vec3 direction, vec4 plane ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 direction - Direction of the ray.
  • vec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( dvec3 point, dvec3 direction, dvec4 plane ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 direction - Direction of the ray.
  • dvec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( vec3 point, vec3 direction, vec3 plane_point, vec3 plane_normal ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 direction - Direction of the ray.
  • vec3 plane_point - Point on the plane.
  • vec3 plane_normal - Normal to the plane.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( dvec3 point, dvec3 direction, dvec3 plane_point, dvec3 plane_normal ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 direction - Direction of the ray.
  • dvec3 plane_point - Point on the plane.
  • dvec3 plane_normal - Normal to the plane.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( vec3 point, vec3 direction, vec4 plane, vec3 ret ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 direction - Direction of the ray.
  • vec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.
  • vec3 ret - Return vector.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( dvec3 point, dvec3 direction, dvec4 plane, dvec3 ret ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 direction - Direction of the ray.
  • dvec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.
  • dvec3 ret - Return vector.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( vec3 point, vec3 direction, vec3 plane_point, vec3 plane_normal, vec3 ret ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • vec3 point - Starting point of the ray.
  • vec3 direction - Direction of the ray.
  • vec3 plane_point - Point on the plane.
  • vec3 plane_normal - Normal to the plane.
  • vec3 ret - Return vector.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool RayPlaneIntersection ( dvec3 point, dvec3 direction, dvec3 plane_point, dvec3 plane_normal, dvec3 ret ) #

Checks if there is an intersection between a ray and a plane.

Arguments

  • dvec3 point - Starting point of the ray.
  • dvec3 direction - Direction of the ray.
  • dvec3 plane_point - Point on the plane.
  • dvec3 plane_normal - Normal to the plane.
  • dvec3 ret - Return vector.

Return value

true if the given ray intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( vec3 p0, vec3 p1, vec4 plane ) #

Checks if a segment intersects a plane.

Arguments

  • vec3 p0 - Starting point of the line segment.
  • vec3 p1 - End point of the line segment.
  • vec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( dvec3 p0, dvec3 p1, dvec4 plane ) #

Checks if a segment intersects a plane.

Arguments

  • dvec3 p0 - Starting point of the line segment.
  • dvec3 p1 - End point of the line segment.
  • dvec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( vec3 p0, vec3 p1, vec3 plane_point, vec3 plane_normal ) #

Checks if a segment intersects a plane.

Arguments

  • vec3 p0 - Starting point of the line segment.
  • vec3 p1 - End point of the line segment.
  • vec3 plane_point - Point on the plane.
  • vec3 plane_normal - Normal to the plane.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( dvec3 p0, dvec3 p1, dvec3 plane_point, dvec3 plane_normal ) #

Checks if a segment intersects a plane.

Arguments

  • dvec3 p0 - Starting point of the line segment.
  • dvec3 p1 - End point of the line segment.
  • dvec3 plane_point - Point on the plane.
  • dvec3 plane_normal - Normal to the plane.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( vec3 p0, vec3 p1, vec4 plane, vec3 ret ) #

Calculates the intersection of a segment and a plane. If the function returns true, the point of intersection will be put to the return vector.

Arguments

  • vec3 p0 - Starting point of the line segment.
  • vec3 p1 - End point of the line segment.
  • vec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.
  • vec3 ret - Return vector.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( dvec3 p0, dvec3 p1, dvec4 plane, dvec3 ret ) #

Calculates the intersection of a segment and a plane. If the function returns true, the point of intersection will be put to the return vector.

Arguments

  • dvec3 p0 - Starting point of the line segment.
  • dvec3 p1 - End point of the line segment.
  • dvec4 plane - 4D vector (A, B, C, D) representing a plane, where: A,B,C are the components of the normal vector of the plane, and D is the distance of the plane from the origin.
  • dvec3 ret - Return vector.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( vec3 p0, vec3 p1, vec3 plane_point, vec3 plane_normal, vec3 ret ) #

Calculates the intersection of a segment and a plane. If the function returns true, the point of intersection will be put to the return vector.

Arguments

  • vec3 p0 - Starting point of the line segment.
  • vec3 p1 - End point of the line segment.
  • vec3 plane_point - Point on the plane.
  • vec3 plane_normal - Normal to the plane.
  • vec3 ret - Return vector.

Return value

true if the given segment intersects the given plane; otherwise, false.

bool SegmentPlaneIntersection ( dvec3 p0, dvec3 p1, dvec3 plane_point, dvec3 plane_normal, dvec3 ret ) #

Calculates the intersection of a segment and a plane. If the function returns true, the point of intersection will be put to the return vector.

Arguments

  • dvec3 p0 - Starting point of the line segment.
  • dvec3 p1 - End point of the line segment.
  • dvec3 plane_point - Point on the plane.
  • dvec3 plane_normal - Normal to the plane.
  • dvec3 ret - Return vector.

Return value

true if the given segment intersects the given plane; otherwise, false.

vec3 GetClosestPointOnLine ( vec3 point, vec3 p0, vec3 p1 ) #

Scans the specified line segment and returns the point closest to the reference point.

Arguments

  • vec3 point - Reference point.
  • vec3 p0 - Starting point of the line.
  • vec3 p1 - End point of the line.

Return value

Return value.

dvec3 GetClosestPointOnLine ( dvec3 point, dvec3 p0, dvec3 p1 ) #

Scans the specified line segment and returns the point closest to the reference point.

Arguments

  • dvec3 point - Reference point.
  • dvec3 p0 - Starting point of the line.
  • dvec3 p1 - End point of the line.

Return value

Return value.

bool GetClosestPointOnTriangle ( vec3 point, vec3 v0, vec3 v1, vec3 v2, vec3 ret ) #

Scans the specified triangle and searches for the point closest to the reference point. The found point will be put to the return vector.

Arguments

  • vec3 point - Reference point.
  • vec3 v0 - The first vertex of the triangle.
  • vec3 v1 - The second vertex of the triangle.
  • vec3 v2 - The third vertex of the triangle.
  • vec3 ret - Return vector.

Return value

true if the point is inside the triangle; otherwise, false.

bool GetClosestPointOnTriangle ( dvec3 point, dvec3 v0, dvec3 v1, dvec3 v2, dvec3 ret ) #

Scans the specified triangle and searches for the point closest to the reference point. The found point will be put to the return vector.

Arguments

  • dvec3 point - Reference point.
  • dvec3 v0 - The first vertex of the triangle.
  • dvec3 v1 - The second vertex of the triangle.
  • dvec3 v2 - The third vertex of the triangle.
  • dvec3 ret - Return vector.

Return value

true if the point is inside the triangle; otherwise, false.

bool GetClosestPointsOnLines ( vec3 p00, vec3 p01, vec3 p10, vec3 p11, vec3 ret_0, vec3 ret_1 ) #

Scans the two specified lines and searches for the pair of closest points. The closest points of the first and the second lines will be put to the respective return vector.

Arguments

  • vec3 p00 - Starting point of the first line.
  • vec3 p01 - End point of the first line.
  • vec3 p10 - Starting point of the second line.
  • vec3 p11 - End point of the second line.
  • vec3 ret_0 - First return vector.
  • vec3 ret_1 - Second return vector.

Return value

true if the lines cross; otherwise, false.

bool GetClosestPointsOnLines ( dvec3 p00, dvec3 p01, dvec3 p10, dvec3 p11, dvec3 ret_0, dvec3 ret_1 ) #

Scans the two specified lines and searches for the pair of closest points. The closest points of the first and the second lines will be put to the respective return vector.

Arguments

  • dvec3 p00 - Starting point of the first line.
  • dvec3 p01 - End point of the first line.
  • dvec3 p10 - Starting point of the second line.
  • dvec3 p11 - End point of the second line.
  • dvec3 ret_0 - First return vector.
  • dvec3 ret_1 - Second return vector.

Return value

true if the lines cross; otherwise, false.

vec3 ProjectOntoPlane ( vec3 v, vec3 plane_normal ) #

Calculates the projection of a vector onto a given plane.

Arguments

  • vec3 v - Input vector.
  • vec3 plane_normal - Normal to the plane.

Return value

Projection of the input vector onto the plane.

dvec3 ProjectOntoPlane ( dvec3 v, dvec3 plane_normal ) #

Calculates the projection of a vector onto a given plane.

Arguments

  • dvec3 v - Input vector.
  • dvec3 plane_normal - Normal to the plane.

Return value

Projection of the input vector onto the plane.

void TriangleRasterize ( vec2 v0, vec2 v1, vec2 v2, int x0, int y0, int x1, int y1, TriangleRasterizeShader shader ) #

Positions the given triangle within the given screen coordinates, rasterizes it and applies the specified shader to each pixel.

Arguments

  • vec2 v0 - The first vertex of the triangle.
  • vec2 v1 - The second vertex of the triangle.
  • vec2 v2 - The third vertex of the triangle.
  • int x0 - The X coordinate of the top left corner of screen space.
  • int y0 - The Y coordinate of the top left corner of screen space.
  • int x1 - The X coordinate of the bottom right corner of screen space.
  • int y1 - The Y coordinate of the bottom right corner of screen space.
  • TriangleRasterizeShader shader - Shader.
Last update: 13.12.2024
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