sqwarmed/sdk_src/public/collisionutils.cpp

3407 lines
117 KiB
C++

//========= Copyright © 1996-2005, Valve Corporation, All rights reserved. ============//
//
// Purpose: Common collision utility methods
//
// $Header: $
// $NoKeywords: $
//=============================================================================//
#if !defined(_STATIC_LINKED) || defined(_SHARED_LIB)
#include "collisionutils.h"
#include "cmodel.h"
#include "mathlib/mathlib.h"
#include "mathlib/vector.h"
#include "tier0/dbg.h"
#include <float.h>
#include "mathlib/vector4d.h"
#include "trace.h"
// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"
#define UNINIT -99999.0
//-----------------------------------------------------------------------------
// Clears the trace
//-----------------------------------------------------------------------------
static void Collision_ClearTrace( const Vector &vecRayStart, const Vector &vecRayDelta, CBaseTrace *pTrace )
{
pTrace->startpos = vecRayStart;
pTrace->endpos = vecRayStart;
pTrace->endpos += vecRayDelta;
pTrace->startsolid = false;
pTrace->allsolid = false;
pTrace->fraction = 1.0f;
pTrace->contents = 0;
}
//-----------------------------------------------------------------------------
// Compute the offset in t along the ray that we'll use for the collision
//-----------------------------------------------------------------------------
static float ComputeBoxOffset( const Ray_t& ray )
{
if (ray.m_IsRay)
return 1e-3f;
// Find the projection of the box diagonal along the ray...
float offset = FloatMakePositive(ray.m_Extents[0] * ray.m_Delta[0]) +
FloatMakePositive(ray.m_Extents[1] * ray.m_Delta[1]) +
FloatMakePositive(ray.m_Extents[2] * ray.m_Delta[2]);
// We need to divide twice: Once to normalize the computation above
// so we get something in units of extents, and the second to normalize
// that with respect to the entire raycast.
offset *= InvRSquared( ray.m_Delta );
// 1e-3 is an epsilon
return offset + 1e-3;
}
//-----------------------------------------------------------------------------
// Intersects a swept box against a triangle
//-----------------------------------------------------------------------------
float IntersectRayWithTriangle( const Ray_t& ray,
const Vector& v1, const Vector& v2, const Vector& v3, bool oneSided )
{
// This is cute: Use barycentric coordinates to represent the triangle
// Vo(1-u-v) + V1u + V2v and intersect that with a line Po + Dt
// This gives us 3 equations + 3 unknowns, which we can solve with
// Cramer's rule...
// E1x u + E2x v - Dx t = Pox - Vox
// There's a couple of other optimizations, Cramer's rule involves
// computing the determinant of a matrix which has been constructed
// by three vectors. It turns out that
// det | A B C | = -( A x C ) dot B or -(C x B) dot A
// which we'll use below..
Vector edge1, edge2, org;
VectorSubtract( v2, v1, edge1 );
VectorSubtract( v3, v1, edge2 );
// Cull out one-sided stuff
if (oneSided)
{
Vector normal;
CrossProduct( edge1, edge2, normal );
if (DotProduct( normal, ray.m_Delta ) >= 0.0f)
return -1.0f;
}
// FIXME: This is inaccurate, but fast for boxes
// We want to do a fast separating axis implementation here
// with a swept triangle along the reverse direction of the ray.
// Compute some intermediary terms
Vector dirCrossEdge2, orgCrossEdge1;
CrossProduct( ray.m_Delta, edge2, dirCrossEdge2 );
// Compute the denominator of Cramer's rule:
// | -Dx E1x E2x |
// det | -Dy E1y E2y | = (D x E2) dot E1
// | -Dz E1z E2z |
float denom = DotProduct( dirCrossEdge2, edge1 );
if( FloatMakePositive( denom ) < 1e-6 )
return -1.0f;
denom = 1.0f / denom;
// Compute u. It's gotta lie in the range of 0 to 1.
// | -Dx orgx E2x |
// u = denom * det | -Dy orgy E2y | = (D x E2) dot org
// | -Dz orgz E2z |
VectorSubtract( ray.m_Start, v1, org );
float u = DotProduct( dirCrossEdge2, org ) * denom;
if ((u < 0.0f) || (u > 1.0f))
return -1.0f;
// Compute t and v the same way...
// In barycentric coords, u + v < 1
CrossProduct( org, edge1, orgCrossEdge1 );
float v = DotProduct( orgCrossEdge1, ray.m_Delta ) * denom;
if ((v < 0.0f) || (v + u > 1.0f))
return -1.0f;
// Compute the distance along the ray direction that we need to fudge
// when using swept boxes
float boxt = ComputeBoxOffset( ray );
float t = DotProduct( orgCrossEdge1, edge2 ) * denom;
if ((t < -boxt) || (t > 1.0f + boxt))
return -1.0f;
return clamp( t, 0, 1 );
}
//-----------------------------------------------------------------------------
// computes the barycentric coordinates of an intersection
//-----------------------------------------------------------------------------
bool ComputeIntersectionBarycentricCoordinates( const Ray_t& ray,
const Vector& v1, const Vector& v2, const Vector& v3, float& u, float& v,
float *t )
{
Vector edge1, edge2, org;
VectorSubtract( v2, v1, edge1 );
VectorSubtract( v3, v1, edge2 );
// Compute some intermediary terms
Vector dirCrossEdge2, orgCrossEdge1;
CrossProduct( ray.m_Delta, edge2, dirCrossEdge2 );
// Compute the denominator of Cramer's rule:
// | -Dx E1x E2x |
// det | -Dy E1y E2y | = (D x E2) dot E1
// | -Dz E1z E2z |
float denom = DotProduct( dirCrossEdge2, edge1 );
if( FloatMakePositive( denom ) < 1e-6 )
return false;
denom = 1.0f / denom;
// Compute u. It's gotta lie in the range of 0 to 1.
// | -Dx orgx E2x |
// u = denom * det | -Dy orgy E2y | = (D x E2) dot org
// | -Dz orgz E2z |
VectorSubtract( ray.m_Start, v1, org );
u = DotProduct( dirCrossEdge2, org ) * denom;
// Compute t and v the same way...
// In barycentric coords, u + v < 1
CrossProduct( org, edge1, orgCrossEdge1 );
v = DotProduct( orgCrossEdge1, ray.m_Delta ) * denom;
// Compute the distance along the ray direction that we need to fudge
// when using swept boxes
if( t )
{
float boxt = ComputeBoxOffset( ray );
*t = DotProduct( orgCrossEdge1, edge2 ) * denom;
if( ( *t < -boxt ) || ( *t > 1.0f + boxt ) )
return false;
}
return true;
}
//-----------------------------------------------------------------------------
// Intersects a plane with a triangle (requires barycentric definition)
//-----------------------------------------------------------------------------
int IntersectTriangleWithPlaneBarycentric( const Vector& org, const Vector& edgeU,
const Vector& edgeV, const Vector4D& plane, Vector2D* pIntersection )
{
// This uses a barycentric method, since we need that to determine
// interpolated points, alphas, and normals
// Given the plane equation P dot N + d = 0
// and the barycentric coodinate equation P = Org + EdgeU * u + EdgeV * v
// Plug em in. Intersection occurs at u = 0 or v = 0 or u + v = 1
float orgDotNormal = DotProduct( org, plane.AsVector3D() );
float edgeUDotNormal = DotProduct( edgeU, plane.AsVector3D() );
float edgeVDotNormal = DotProduct( edgeV, plane.AsVector3D() );
int ptIdx = 0;
// u = 0
if ( edgeVDotNormal != 0.0f )
{
pIntersection[ptIdx].x = 0.0f;
pIntersection[ptIdx].y = - ( orgDotNormal - plane.w ) / edgeVDotNormal;
if ((pIntersection[ptIdx].y >= 0.0f) && (pIntersection[ptIdx].y <= 1.0f))
++ptIdx;
}
// v = 0
if ( edgeUDotNormal != 0.0f )
{
pIntersection[ptIdx].x = - ( orgDotNormal - plane.w ) / edgeUDotNormal;
pIntersection[ptIdx].y = 0.0f;
if ((pIntersection[ptIdx].x >= 0.0f) && (pIntersection[ptIdx].x <= 1.0f))
++ptIdx;
}
// u + v = 1
if (ptIdx == 2)
return ptIdx;
if ( edgeVDotNormal != edgeUDotNormal )
{
pIntersection[ptIdx].x = - ( orgDotNormal - plane.w + edgeVDotNormal) /
( edgeUDotNormal - edgeVDotNormal);
pIntersection[ptIdx].y = 1.0f - pIntersection[ptIdx].x;;
if ((pIntersection[ptIdx].x >= 0.0f) && (pIntersection[ptIdx].x <= 1.0f) &&
(pIntersection[ptIdx].y >= 0.0f) && (pIntersection[ptIdx].y <= 1.0f))
++ptIdx;
}
Assert( ptIdx < 3 );
return ptIdx;
}
//-----------------------------------------------------------------------------
// Returns true if a box intersects with a sphere
//-----------------------------------------------------------------------------
bool IsSphereIntersectingSphere( const Vector& center1, float radius1,
const Vector& center2, float radius2 )
{
Vector delta;
VectorSubtract( center2, center1, delta );
float distSq = delta.LengthSqr();
float radiusSum = radius1 + radius2;
return (distSq <= (radiusSum * radiusSum));
}
//-----------------------------------------------------------------------------
// Returns true if a box intersects with a sphere
//-----------------------------------------------------------------------------
bool IsBoxIntersectingSphere( const Vector& boxMin, const Vector& boxMax,
const Vector& center, float radius )
{
// See Graphics Gems, box-sphere intersection
float dmin = 0.0f;
float flDelta;
// Unrolled the loop.. this is a big cycle stealer...
if (center[0] < boxMin[0])
{
flDelta = center[0] - boxMin[0];
dmin += flDelta * flDelta;
}
else if (center[0] > boxMax[0])
{
flDelta = boxMax[0] - center[0];
dmin += flDelta * flDelta;
}
if (center[1] < boxMin[1])
{
flDelta = center[1] - boxMin[1];
dmin += flDelta * flDelta;
}
else if (center[1] > boxMax[1])
{
flDelta = boxMax[1] - center[1];
dmin += flDelta * flDelta;
}
if (center[2] < boxMin[2])
{
flDelta = center[2] - boxMin[2];
dmin += flDelta * flDelta;
}
else if (center[2] > boxMax[2])
{
flDelta = boxMax[2] - center[2];
dmin += flDelta * flDelta;
}
return dmin < radius * radius;
}
bool IsBoxIntersectingSphereExtents( const Vector& boxCenter, const Vector& boxHalfDiag,
const Vector& center, float radius )
{
// See Graphics Gems, box-sphere intersection
float dmin = 0.0f;
float flDelta, flDiff;
// Unrolled the loop.. this is a big cycle stealer...
flDiff = FloatMakePositive( center.x - boxCenter.x );
if (flDiff > boxHalfDiag.x)
{
flDelta = flDiff - boxHalfDiag.x;
dmin += flDelta * flDelta;
}
flDiff = FloatMakePositive( center.y - boxCenter.y );
if (flDiff > boxHalfDiag.y)
{
flDelta = flDiff - boxHalfDiag.y;
dmin += flDelta * flDelta;
}
flDiff = FloatMakePositive( center.z - boxCenter.z );
if (flDiff > boxHalfDiag.z)
{
flDelta = flDiff - boxHalfDiag.z;
dmin += flDelta * flDelta;
}
return dmin < radius * radius;
}
//-----------------------------------------------------------------------------
// Returns true if a rectangle intersects with a circle
//-----------------------------------------------------------------------------
bool IsCircleIntersectingRectangle( const Vector2D& boxMin, const Vector2D& boxMax,
const Vector2D& center, float radius )
{
// See Graphics Gems, box-sphere intersection
float dmin = 0.0f;
float flDelta;
if (center[0] < boxMin[0])
{
flDelta = center[0] - boxMin[0];
dmin += flDelta * flDelta;
}
else if (center[0] > boxMax[0])
{
flDelta = boxMax[0] - center[0];
dmin += flDelta * flDelta;
}
if (center[1] < boxMin[1])
{
flDelta = center[1] - boxMin[1];
dmin += flDelta * flDelta;
}
else if (center[1] > boxMax[1])
{
flDelta = boxMax[1] - center[1];
dmin += flDelta * flDelta;
}
return dmin < radius * radius;
}
//-----------------------------------------------------------------------------
// returns true if there's an intersection between ray and sphere
//-----------------------------------------------------------------------------
bool IsRayIntersectingSphere( const Vector &vecRayOrigin, const Vector &vecRayDelta,
const Vector& vecCenter, float flRadius, float flTolerance )
{
// For this algorithm, find a point on the ray which is closest to the sphere origin
// Do this by making a plane passing through the sphere origin
// whose normal is parallel to the ray. Intersect that plane with the ray.
// Plane: N dot P = I, N = D (ray direction), I = C dot N = C dot D
// Ray: P = O + D * t
// D dot ( O + D * t ) = C dot D
// D dot O + D dot D * t = C dot D
// t = (C - O) dot D / D dot D
// Clamp t to (0,1)
// Find distance of the point on the ray to the sphere center.
Assert( flTolerance >= 0.0f );
flRadius += flTolerance;
Vector vecRayToSphere;
VectorSubtract( vecCenter, vecRayOrigin, vecRayToSphere );
float flNumerator = DotProduct( vecRayToSphere, vecRayDelta );
float t;
if (flNumerator <= 0.0f)
{
t = 0.0f;
}
else
{
float flDenominator = DotProduct( vecRayDelta, vecRayDelta );
if ( flNumerator > flDenominator )
t = 1.0f;
else
t = flNumerator / flDenominator;
}
Vector vecClosestPoint;
VectorMA( vecRayOrigin, t, vecRayDelta, vecClosestPoint );
return ( vecClosestPoint.DistToSqr( vecCenter ) <= flRadius * flRadius );
// NOTE: This in an alternate algorithm which I didn't use because I'd have to use a sqrt
// So it's probably faster to do this other algorithm. I'll leave the comments here
// for how to go back if we want to
// Solve using the ray equation + the sphere equation
// P = o + dt
// (x - xc)^2 + (y - yc)^2 + (z - zc)^2 = r^2
// (ox + dx * t - xc)^2 + (oy + dy * t - yc)^2 + (oz + dz * t - zc)^2 = r^2
// (ox - xc)^2 + 2 * (ox-xc) * dx * t + dx^2 * t^2 +
// (oy - yc)^2 + 2 * (oy-yc) * dy * t + dy^2 * t^2 +
// (oz - zc)^2 + 2 * (oz-zc) * dz * t + dz^2 * t^2 = r^2
// (dx^2 + dy^2 + dz^2) * t^2 + 2 * ((ox-xc)dx + (oy-yc)dy + (oz-zc)dz) t +
// (ox-xc)^2 + (oy-yc)^2 + (oz-zc)^2 - r^2 = 0
// or, t = (-b +/- sqrt( b^2 - 4ac)) / 2a
// a = DotProduct( vecRayDelta, vecRayDelta );
// b = 2 * DotProduct( vecRayOrigin - vecCenter, vecRayDelta )
// c = DotProduct(vecRayOrigin - vecCenter, vecRayOrigin - vecCenter) - flRadius * flRadius;
// Valid solutions are possible only if b^2 - 4ac >= 0
// Therefore, compute that value + see if we got it
}
//-----------------------------------------------------------------------------
//
// IntersectInfiniteRayWithSphere
//
// Returns whether or not there was an intersection.
// Returns the two intersection points
//
//-----------------------------------------------------------------------------
bool IntersectInfiniteRayWithSphere( const Vector &vecRayOrigin, const Vector &vecRayDelta,
const Vector &vecSphereCenter, float flRadius, float *pT1, float *pT2 )
{
// Solve using the ray equation + the sphere equation
// P = o + dt
// (x - xc)^2 + (y - yc)^2 + (z - zc)^2 = r^2
// (ox + dx * t - xc)^2 + (oy + dy * t - yc)^2 + (oz + dz * t - zc)^2 = r^2
// (ox - xc)^2 + 2 * (ox-xc) * dx * t + dx^2 * t^2 +
// (oy - yc)^2 + 2 * (oy-yc) * dy * t + dy^2 * t^2 +
// (oz - zc)^2 + 2 * (oz-zc) * dz * t + dz^2 * t^2 = r^2
// (dx^2 + dy^2 + dz^2) * t^2 + 2 * ((ox-xc)dx + (oy-yc)dy + (oz-zc)dz) t +
// (ox-xc)^2 + (oy-yc)^2 + (oz-zc)^2 - r^2 = 0
// or, t = (-b +/- sqrt( b^2 - 4ac)) / 2a
// a = DotProduct( vecRayDelta, vecRayDelta );
// b = 2 * DotProduct( vecRayOrigin - vecCenter, vecRayDelta )
// c = DotProduct(vecRayOrigin - vecCenter, vecRayOrigin - vecCenter) - flRadius * flRadius;
Vector vecSphereToRay;
VectorSubtract( vecRayOrigin, vecSphereCenter, vecSphereToRay );
float a = DotProduct( vecRayDelta, vecRayDelta );
// This would occur in the case of a zero-length ray
if ( a == 0.0f )
{
*pT1 = *pT2 = 0.0f;
return vecSphereToRay.LengthSqr() <= flRadius * flRadius;
}
float b = 2 * DotProduct( vecSphereToRay, vecRayDelta );
float c = DotProduct( vecSphereToRay, vecSphereToRay ) - flRadius * flRadius;
float flDiscrim = b * b - 4 * a * c;
if ( flDiscrim < 0.0f )
return false;
flDiscrim = sqrt( flDiscrim );
float oo2a = 0.5f / a;
*pT1 = ( - b - flDiscrim ) * oo2a;
*pT2 = ( - b + flDiscrim ) * oo2a;
return true;
}
//-----------------------------------------------------------------------------
//
// IntersectRayWithSphere
//
// Returns whether or not there was an intersection.
// Returns the two intersection points, clamped to (0,1)
//
//-----------------------------------------------------------------------------
bool IntersectRayWithSphere( const Vector &vecRayOrigin, const Vector &vecRayDelta,
const Vector &vecSphereCenter, float flRadius, float *pT1, float *pT2 )
{
if ( !IntersectInfiniteRayWithSphere( vecRayOrigin, vecRayDelta, vecSphereCenter, flRadius, pT1, pT2 ) )
return false;
if (( *pT1 > 1.0f ) || ( *pT2 < 0.0f ))
return false;
// Clamp it!
if ( *pT1 < 0.0f )
*pT1 = 0.0f;
if ( *pT2 > 1.0f )
*pT2 = 1.0f;
return true;
}
// returns true if the sphere and cone intersect
// NOTE: cone sine/cosine are the half angle of the cone
bool IsSphereIntersectingCone( const Vector &sphereCenter, float sphereRadius, const Vector &coneOrigin, const Vector &coneNormal, float coneSine, float coneCosine )
{
Vector backCenter = coneOrigin - (sphereRadius / coneSine) * coneNormal;
Vector delta = sphereCenter - backCenter;
float deltaLen = delta.Length();
if ( DotProduct(coneNormal, delta) >= deltaLen*coneCosine )
{
delta = sphereCenter - coneOrigin;
deltaLen = delta.Length();
if ( -DotProduct(coneNormal, delta) >= deltaLen * coneSine )
{
return ( deltaLen <= sphereRadius ) ? true : false;
}
return true;
}
return false;
}
//-----------------------------------------------------------------------------
// returns true if the point is in the box
//-----------------------------------------------------------------------------
bool IsPointInBox( const Vector& pt, const Vector& boxMin, const Vector& boxMax )
{
Assert( boxMin[0] <= boxMax[0] );
Assert( boxMin[1] <= boxMax[1] );
Assert( boxMin[2] <= boxMax[2] );
// on x360, force use of SIMD version.
if (IsX360())
{
return IsPointInBox( LoadUnaligned3SIMD(pt.Base()), LoadUnaligned3SIMD(boxMin.Base()), LoadUnaligned3SIMD(boxMax.Base()) ) ;
}
if ( (pt[0] > boxMax[0]) || (pt[0] < boxMin[0]) )
return false;
if ( (pt[1] > boxMax[1]) || (pt[1] < boxMin[1]) )
return false;
if ( (pt[2] > boxMax[2]) || (pt[2] < boxMin[2]) )
return false;
return true;
}
bool IsPointInCone( const Vector &pt, const Vector &origin, const Vector &axis, float cosAngle, float length )
{
Vector delta = pt - origin;
float dist = VectorNormalize( delta );
float dot = DotProduct( delta, axis );
if ( dot < cosAngle )
return false;
if ( dist * dot > length )
return false;
return true;
}
//-----------------------------------------------------------------------------
// returns true if there's an intersection between two boxes
//-----------------------------------------------------------------------------
bool IsBoxIntersectingBox( const Vector& boxMin1, const Vector& boxMax1,
const Vector& boxMin2, const Vector& boxMax2 )
{
Assert( boxMin1[0] <= boxMax1[0] );
Assert( boxMin1[1] <= boxMax1[1] );
Assert( boxMin1[2] <= boxMax1[2] );
Assert( boxMin2[0] <= boxMax2[0] );
Assert( boxMin2[1] <= boxMax2[1] );
Assert( boxMin2[2] <= boxMax2[2] );
if ( (boxMin1[0] > boxMax2[0]) || (boxMax1[0] < boxMin2[0]) )
return false;
if ( (boxMin1[1] > boxMax2[1]) || (boxMax1[1] < boxMin2[1]) )
return false;
if ( (boxMin1[2] > boxMax2[2]) || (boxMax1[2] < boxMin2[2]) )
return false;
return true;
}
bool IsBoxIntersectingBoxExtents( const Vector& boxCenter1, const Vector& boxHalfDiagonal1,
const Vector& boxCenter2, const Vector& boxHalfDiagonal2 )
{
Vector vecDelta, vecSize;
VectorSubtract( boxCenter1, boxCenter2, vecDelta );
VectorAdd( boxHalfDiagonal1, boxHalfDiagonal2, vecSize );
return ( FloatMakePositive( vecDelta.x ) <= vecSize.x ) &&
( FloatMakePositive( vecDelta.y ) <= vecSize.y ) &&
( FloatMakePositive( vecDelta.z ) <= vecSize.z );
}
//-----------------------------------------------------------------------------
//
// IsOBBIntersectingOBB
//
// returns true if there's an intersection between two OBBs
//
//-----------------------------------------------------------------------------
bool IsOBBIntersectingOBB( const Vector &vecOrigin1, const QAngle &vecAngles1, const Vector& boxMin1, const Vector& boxMax1,
const Vector &vecOrigin2, const QAngle &vecAngles2, const Vector& boxMin2, const Vector& boxMax2, float flTolerance )
{
// FIXME: Simple case AABB check doesn't work because the min and max extents are not oriented based on the angle
// this fast check would only be good for cubes.
/*if ( vecAngles1 == vecAngles2 )
{
const Vector &vecDelta = vecOrigin2 - vecOrigin1;
Vector vecOtherMins, vecOtherMaxs;
VectorAdd( boxMin2, vecDelta, vecOtherMins );
VectorAdd( boxMax2, vecDelta, vecOtherMaxs );
return IsBoxIntersectingBox( boxMin1, boxMax1, vecOtherMins, vecOtherMaxs );
}*/
// OBB test...
cplane_t plane;
bool bFoundPlane = ComputeSeparatingPlane( vecOrigin1, vecAngles1, boxMin1, boxMax1,
vecOrigin2, vecAngles2, boxMin2, boxMax2, flTolerance, &plane );
return (bFoundPlane == false);
}
// NOTE: This is only very slightly faster on high end PCs and x360
#define USE_SIMD_RAY_CHECKS 1
//-----------------------------------------------------------------------------
// returns true if there's an intersection between box and ray
//-----------------------------------------------------------------------------
bool FASTCALL IsBoxIntersectingRay( const Vector& boxMin, const Vector& boxMax,
const Vector& origin, const Vector& vecDelta, float flTolerance )
{
#if USE_SIMD_RAY_CHECKS
// Load the unaligned ray/box parameters into SIMD registers
fltx4 start = LoadUnaligned3SIMD(origin.Base());
fltx4 delta = LoadUnaligned3SIMD(vecDelta.Base());
fltx4 boxMins = LoadUnaligned3SIMD( boxMin.Base() );
fltx4 boxMaxs = LoadUnaligned3SIMD( boxMax.Base() );
fltx4 epsilon = ReplicateX4(flTolerance);
// compute the mins/maxs of the box expanded by the ray extents
// relocate the problem so that the ray start is at the origin.
fltx4 offsetMins = SubSIMD(boxMins, start);
fltx4 offsetMaxs = SubSIMD(boxMaxs, start);
fltx4 offsetMinsExpanded = SubSIMD(offsetMins, epsilon);
fltx4 offsetMaxsExpanded = AddSIMD(offsetMaxs, epsilon);
// Check to see if both the origin (start point) and the end point (delta) are on the front side
// of any of the box sides - if so there can be no intersection
fltx4 startOutMins = CmpLtSIMD(Four_Zeros, offsetMinsExpanded);
fltx4 endOutMins = CmpLtSIMD(delta,offsetMinsExpanded);
fltx4 minsMask = AndSIMD( startOutMins, endOutMins );
fltx4 startOutMaxs = CmpGtSIMD(Four_Zeros, offsetMaxsExpanded);
fltx4 endOutMaxs = CmpGtSIMD(delta,offsetMaxsExpanded);
fltx4 maxsMask = AndSIMD( startOutMaxs, endOutMaxs );
if ( IsAnyNegative(SetWToZeroSIMD(OrSIMD(minsMask,maxsMask))))
return false;
// now build the per-axis interval of t for intersections
fltx4 invDelta = ReciprocalSaturateSIMD(delta);
fltx4 tmins = MulSIMD( offsetMinsExpanded, invDelta );
fltx4 tmaxs = MulSIMD( offsetMaxsExpanded, invDelta );
fltx4 crossPlane = OrSIMD(XorSIMD(startOutMins,endOutMins), XorSIMD(startOutMaxs,endOutMaxs));
// only consider axes where we crossed a plane
tmins = MaskedAssign( crossPlane, tmins, Four_Negative_FLT_MAX );
tmaxs = MaskedAssign( crossPlane, tmaxs, Four_FLT_MAX );
// now sort the interval per axis
fltx4 mint = MinSIMD( tmins, tmaxs );
fltx4 maxt = MaxSIMD( tmins, tmaxs );
// now find the intersection of the intervals on all axes
fltx4 firstOut = FindLowestSIMD3(maxt);
fltx4 lastIn = FindHighestSIMD3(mint);
// NOTE: This is really a scalar quantity now [t0,t1] == [lastIn,firstOut]
firstOut = MinSIMD(firstOut, Four_Ones);
lastIn = MaxSIMD(lastIn, Four_Zeros);
// If the final interval is valid lastIn<firstOut, check for separation
fltx4 separation = CmpGtSIMD(lastIn, firstOut);
return IsAllZeros(separation);
#else
// On the x360, we force use of the SIMD functions.
#if defined(_X360)
if (IsX360())
{
fltx4 delta = LoadUnaligned3SIMD(vecDelta.Base());
return IsBoxIntersectingRay(
LoadUnaligned3SIMD(boxMin.Base()), LoadUnaligned3SIMD(boxMax.Base()),
LoadUnaligned3SIMD(origin.Base()), delta, ReciprocalSIMD(delta), // ray parameters
ReplicateX4(flTolerance) ///< eg from ReplicateX4(flTolerance)
);
}
#endif
Assert( boxMin[0] <= boxMax[0] );
Assert( boxMin[1] <= boxMax[1] );
Assert( boxMin[2] <= boxMax[2] );
// FIXME: Surely there's a faster way
float tmin = -FLT_MAX;
float tmax = FLT_MAX;
for (int i = 0; i < 3; ++i)
{
// Parallel case...
if (FloatMakePositive(vecDelta[i]) < 1e-8)
{
// Check that origin is in the box
// if not, then it doesn't intersect..
if ( (origin[i] < boxMin[i] - flTolerance) || (origin[i] > boxMax[i] + flTolerance) )
return false;
continue;
}
// non-parallel case
// Find the t's corresponding to the entry and exit of
// the ray along x, y, and z. The find the furthest entry
// point, and the closest exit point. Once that is done,
// we know we don't collide if the closest exit point
// is behind the starting location. We also don't collide if
// the closest exit point is in front of the furthest entry point
float invDelta = 1.0f / vecDelta[i];
float t1 = (boxMin[i] - flTolerance - origin[i]) * invDelta;
float t2 = (boxMax[i] + flTolerance - origin[i]) * invDelta;
if (t1 > t2)
{
float temp = t1;
t1 = t2;
t2 = temp;
}
if (t1 > tmin)
tmin = t1;
if (t2 < tmax)
tmax = t2;
if (tmin > tmax)
return false;
if (tmax < 0)
return false;
if (tmin > 1)
return false;
}
return true;
#endif
}
//-----------------------------------------------------------------------------
// returns true if there's an intersection between box and ray
//-----------------------------------------------------------------------------
bool FASTCALL IsBoxIntersectingRay( const Vector& boxMin, const Vector& boxMax,
const Vector& origin, const Vector& vecDelta,
const Vector& vecInvDelta, float flTolerance )
{
#if USE_SIMD_RAY_CHECKS
// Load the unaligned ray/box parameters into SIMD registers
fltx4 start = LoadUnaligned3SIMD(origin.Base());
fltx4 delta = LoadUnaligned3SIMD(vecDelta.Base());
fltx4 boxMins = LoadUnaligned3SIMD( boxMin.Base() );
fltx4 boxMaxs = LoadUnaligned3SIMD( boxMax.Base() );
// compute the mins/maxs of the box expanded by the ray extents
// relocate the problem so that the ray start is at the origin.
boxMins = SubSIMD(boxMins, start);
boxMaxs = SubSIMD(boxMaxs, start);
// Check to see if both the origin (start point) and the end point (delta) are on the front side
// of any of the box sides - if so there can be no intersection
fltx4 startOutMins = CmpLtSIMD(Four_Zeros, boxMins);
fltx4 endOutMins = CmpLtSIMD(delta,boxMins);
fltx4 minsMask = AndSIMD( startOutMins, endOutMins );
fltx4 startOutMaxs = CmpGtSIMD(Four_Zeros, boxMaxs);
fltx4 endOutMaxs = CmpGtSIMD(delta,boxMaxs);
fltx4 maxsMask = AndSIMD( startOutMaxs, endOutMaxs );
if ( IsAnyNegative(SetWToZeroSIMD(OrSIMD(minsMask,maxsMask))))
return false;
// now build the per-axis interval of t for intersections
fltx4 epsilon = ReplicateX4(flTolerance);
fltx4 invDelta = LoadUnaligned3SIMD(vecInvDelta.Base());
boxMins = SubSIMD(boxMins, epsilon);
boxMaxs = AddSIMD(boxMaxs, epsilon);
boxMins = MulSIMD( boxMins, invDelta );
boxMaxs = MulSIMD( boxMaxs, invDelta );
fltx4 crossPlane = OrSIMD(XorSIMD(startOutMins,endOutMins), XorSIMD(startOutMaxs,endOutMaxs));
// only consider axes where we crossed a plane
boxMins = MaskedAssign( crossPlane, boxMins, Four_Negative_FLT_MAX );
boxMaxs = MaskedAssign( crossPlane, boxMaxs, Four_FLT_MAX );
// now sort the interval per axis
fltx4 mint = MinSIMD( boxMins, boxMaxs );
fltx4 maxt = MaxSIMD( boxMins, boxMaxs );
// now find the intersection of the intervals on all axes
fltx4 firstOut = FindLowestSIMD3(maxt);
fltx4 lastIn = FindHighestSIMD3(mint);
// NOTE: This is really a scalar quantity now [t0,t1] == [lastIn,firstOut]
firstOut = MinSIMD(firstOut, Four_Ones);
lastIn = MaxSIMD(lastIn, Four_Zeros);
// If the final interval is valid lastIn<firstOut, check for separation
fltx4 separation = CmpGtSIMD(lastIn, firstOut);
return IsAllZeros(separation);
#else
// On the x360, we force use of the SIMD functions.
#if defined(_X360) && !defined(PARANOID_SIMD_ASSERTING)
if (IsX360())
{
return IsBoxIntersectingRay(
LoadUnaligned3SIMD(boxMin.Base()), LoadUnaligned3SIMD(boxMax.Base()),
LoadUnaligned3SIMD(origin.Base()), LoadUnaligned3SIMD(vecDelta.Base()), LoadUnaligned3SIMD(vecInvDelta.Base()), // ray parameters
ReplicateX4(flTolerance) ///< eg from ReplicateX4(flTolerance)
);
}
#endif
Assert( boxMin[0] <= boxMax[0] );
Assert( boxMin[1] <= boxMax[1] );
Assert( boxMin[2] <= boxMax[2] );
// FIXME: Surely there's a faster way
float tmin = -FLT_MAX;
float tmax = FLT_MAX;
for ( int i = 0; i < 3; ++i )
{
// Parallel case...
if ( FloatMakePositive( vecDelta[i] ) < 1e-8 )
{
// Check that origin is in the box, if not, then it doesn't intersect..
if ( ( origin[i] < boxMin[i] - flTolerance ) || ( origin[i] > boxMax[i] + flTolerance ) )
return false;
continue;
}
// Non-parallel case
// Find the t's corresponding to the entry and exit of
// the ray along x, y, and z. The find the furthest entry
// point, and the closest exit point. Once that is done,
// we know we don't collide if the closest exit point
// is behind the starting location. We also don't collide if
// the closest exit point is in front of the furthest entry point
float t1 = ( boxMin[i] - flTolerance - origin[i] ) * vecInvDelta[i];
float t2 = ( boxMax[i] + flTolerance - origin[i] ) * vecInvDelta[i];
if ( t1 > t2 )
{
float temp = t1;
t1 = t2;
t2 = temp;
}
if (t1 > tmin)
tmin = t1;
if (t2 < tmax)
tmax = t2;
if (tmin > tmax)
return false;
if (tmax < 0)
return false;
if (tmin > 1)
return false;
}
return true;
#endif
}
//-----------------------------------------------------------------------------
// Intersects a ray with a aabb, return true if they intersect
//-----------------------------------------------------------------------------
bool FASTCALL IsBoxIntersectingRay( const Vector& vecBoxMin, const Vector& vecBoxMax, const Ray_t& ray, float flTolerance )
{
// On the x360, we force use of the SIMD functions.
#if defined(_X360)
if (IsX360())
{
return IsBoxIntersectingRay(
LoadUnaligned3SIMD(vecBoxMin.Base()), LoadUnaligned3SIMD(vecBoxMax.Base()),
ray, flTolerance);
}
#endif
if ( !ray.m_IsSwept )
{
Vector rayMins, rayMaxs;
VectorSubtract( ray.m_Start, ray.m_Extents, rayMins );
VectorAdd( ray.m_Start, ray.m_Extents, rayMaxs );
if ( flTolerance != 0.0f )
{
rayMins.x -= flTolerance; rayMins.y -= flTolerance; rayMins.z -= flTolerance;
rayMaxs.x += flTolerance; rayMaxs.y += flTolerance; rayMaxs.z += flTolerance;
}
return IsBoxIntersectingBox( vecBoxMin, vecBoxMax, rayMins, rayMaxs );
}
Vector vecExpandedBoxMin, vecExpandedBoxMax;
VectorSubtract( vecBoxMin, ray.m_Extents, vecExpandedBoxMin );
VectorAdd( vecBoxMax, ray.m_Extents, vecExpandedBoxMax );
return IsBoxIntersectingRay( vecExpandedBoxMin, vecExpandedBoxMax, ray.m_Start, ray.m_Delta, flTolerance );
}
//-----------------------------------------------------------------------------
// returns true if there's an intersection between box and ray (SIMD version)
//-----------------------------------------------------------------------------
#ifdef _X360
bool FASTCALL IsBoxIntersectingRay( fltx4 boxMin, fltx4 boxMax,
fltx4 origin, fltx4 delta, fltx4 invDelta, // ray parameters
fltx4 vTolerance ///< eg from ReplicateX4(flTolerance)
)
#else
bool FASTCALL IsBoxIntersectingRay( const fltx4 &inBoxMin, const fltx4 & inBoxMax,
const fltx4 & origin, const fltx4 & delta, const fltx4 & invDelta, // ray parameters
const fltx4 & vTolerance ///< eg from ReplicateX4(flTolerance)
)
#endif
{
// Load the unaligned ray/box parameters into SIMD registers
// compute the mins/maxs of the box expanded by the ray extents
// relocate the problem so that the ray start is at the origin.
#ifdef _X360
boxMin = SubSIMD(boxMin, origin);
boxMax = SubSIMD(boxMax, origin);
#else
fltx4 boxMin = SubSIMD(inBoxMin, origin);
fltx4 boxMax = SubSIMD(inBoxMax, origin);
#endif
// Check to see if the origin (start point) and the end point (delta) are on the same side
// of any of the box sides - if so there can be no intersection
fltx4 startOutMins = AndSIMD( CmpLtSIMD(Four_Zeros, boxMin), CmpLtSIMD(delta,boxMin) );
fltx4 startOutMaxs = AndSIMD( CmpGtSIMD(Four_Zeros, boxMax), CmpGtSIMD(delta,boxMax) );
if ( IsAnyNegative(SetWToZeroSIMD(OrSIMD(startOutMaxs,startOutMins))))
return false;
// now build the per-axis interval of t for intersections
boxMin = SubSIMD(boxMin, vTolerance);
boxMax = AddSIMD(boxMax, vTolerance);
boxMin = MulSIMD( boxMin, invDelta );
boxMax = MulSIMD( boxMax, invDelta );
// now sort the interval per axis
fltx4 mint = MinSIMD( boxMin, boxMax );
fltx4 maxt = MaxSIMD( boxMin, boxMax );
// now find the intersection of the intervals on all axes
fltx4 firstOut = FindLowestSIMD3(maxt);
fltx4 lastIn = FindHighestSIMD3(mint);
// NOTE: This is really a scalar quantity now [t0,t1] == [lastIn,firstOut]
firstOut = MinSIMD(firstOut, Four_Ones);
lastIn = MaxSIMD(lastIn, Four_Zeros);
// If the final interval is valid lastIn<firstOut, check for separation
fltx4 separation = CmpGtSIMD(lastIn, firstOut);
return IsAllZeros(separation);
}
bool FASTCALL IsBoxIntersectingRay( const fltx4& boxMin, const fltx4& boxMax,
const Ray_t& ray, float flTolerance )
{
fltx4 vTolerance = ReplicateX4(flTolerance);
fltx4 rayStart = LoadAlignedSIMD(ray.m_Start);
fltx4 rayExtents = LoadAlignedSIMD(ray.m_Extents);
if ( !ray.m_IsSwept )
{
fltx4 rayMins, rayMaxs;
rayMins = SubSIMD(rayStart, rayExtents);
rayMaxs = AddSIMD(rayStart, rayExtents);
rayMins = AddSIMD(rayMins, vTolerance);
rayMaxs = AddSIMD(rayMaxs, vTolerance);
VectorAligned vecBoxMin, vecBoxMax, vecRayMins, vecRayMaxs;
StoreAlignedSIMD( vecBoxMin.Base(), boxMin );
StoreAlignedSIMD( vecBoxMax.Base(), boxMax );
StoreAlignedSIMD( vecRayMins.Base(), rayMins );
StoreAlignedSIMD( vecRayMaxs.Base(), rayMaxs );
return IsBoxIntersectingBox( vecBoxMin, vecBoxMax, vecRayMins, vecRayMaxs );
}
fltx4 rayDelta = LoadAlignedSIMD(ray.m_Delta);
fltx4 vecExpandedBoxMin, vecExpandedBoxMax;
vecExpandedBoxMin = SubSIMD( boxMin, rayExtents );
vecExpandedBoxMax = AddSIMD( boxMax, rayExtents );
return IsBoxIntersectingRay( vecExpandedBoxMin, vecExpandedBoxMax, rayStart, rayDelta, ReciprocalSIMD(rayDelta), ReplicateX4(flTolerance) );
}
//-----------------------------------------------------------------------------
// Intersects a ray with a ray, return true if they intersect
// t, s = parameters of closest approach (if not intersecting!)
//-----------------------------------------------------------------------------
bool IntersectRayWithRay( const Ray_t &ray0, const Ray_t &ray1, float &t, float &s )
{
Assert( ray0.m_IsRay && ray1.m_IsRay );
//
// r0 = p0 + v0t
// r1 = p1 + v1s
//
// intersection : r0 = r1 :: p0 + v0t = p1 + v1s
// NOTE: v(0,1) are unit direction vectors
//
// subtract p0 from both sides and cross with v1 (NOTE: v1 x v1 = 0)
// (v0 x v1)t = ((p1 - p0 ) x v1)
//
// dotting with (v0 x v1) and dividing by |v0 x v1|^2
// t = Det | (p1 - p0) , v1 , (v0 x v1) | / |v0 x v1|^2
// s = Det | (p1 - p0) , v0 , (v0 x v1) | / |v0 x v1|^2
//
// Det | A B C | = -( A x C ) dot B or -( C x B ) dot A
//
// NOTE: if |v0 x v1|^2 = 0, then the lines are parallel
//
Vector v0( ray0.m_Delta );
Vector v1( ray1.m_Delta );
VectorNormalize( v0 );
VectorNormalize( v1 );
Vector v0xv1 = v0.Cross( v1 );
float lengthSq = v0xv1.LengthSqr();
if( lengthSq == 0.0f )
{
t = 0; s = 0;
return false; // parallel
}
Vector p1p0 = ray1.m_Start - ray0.m_Start;
Vector AxC = p1p0.Cross( v0xv1 );
AxC.Negate();
float detT = AxC.Dot( v1 );
AxC = p1p0.Cross( v0xv1 );
AxC.Negate();
float detS = AxC.Dot( v0 );
t = detT / lengthSq;
s = detS / lengthSq;
// intersection????
Vector i0, i1;
i0 = v0 * t;
i1 = v1 * s;
i0 += ray0.m_Start;
i1 += ray1.m_Start;
if( i0.x == i1.x && i0.y == i1.y && i0.z == i1.z )
return true;
return false;
}
//-----------------------------------------------------------------------------
// Intersects a ray with a plane, returns distance t along ray.
//-----------------------------------------------------------------------------
float IntersectRayWithPlane( const Ray_t& ray, const cplane_t& plane )
{
float denom = DotProduct( ray.m_Delta, plane.normal );
if (denom == 0.0f)
return 0.0f;
denom = 1.0f / denom;
return (plane.dist - DotProduct( ray.m_Start, plane.normal )) * denom;
}
float IntersectRayWithPlane( const Vector& org, const Vector& dir, const cplane_t& plane )
{
float denom = DotProduct( dir, plane.normal );
if (denom == 0.0f)
return 0.0f;
denom = 1.0f / denom;
return (plane.dist - DotProduct( org, plane.normal )) * denom;
}
float IntersectRayWithPlane( const Vector& org, const Vector& dir, const Vector& normal, float dist )
{
float denom = DotProduct( dir, normal );
if (denom == 0.0f)
return 0.0f;
denom = 1.0f / denom;
return (dist - DotProduct( org, normal )) * denom;
}
float IntersectRayWithAAPlane( const Vector& vecStart, const Vector& vecEnd, int nAxis, float flSign, float flDist )
{
float denom = flSign * (vecEnd[nAxis] - vecStart[nAxis]);
if (denom == 0.0f)
return 0.0f;
denom = 1.0f / denom;
return (flDist - flSign * vecStart[nAxis]) * denom;
}
//-----------------------------------------------------------------------------
// Intersects a ray against a box
//-----------------------------------------------------------------------------
bool IntersectRayWithBox( const Vector &vecRayStart, const Vector &vecRayDelta,
const Vector &boxMins, const Vector &boxMaxs, float flTolerance, BoxTraceInfo_t *pTrace )
{
int i;
float d1, d2;
float f;
pTrace->t1 = -1.0f;
pTrace->t2 = 1.0f;
pTrace->hitside = -1;
// UNDONE: This makes this code a little messy
pTrace->startsolid = true;
for ( i = 0; i < 6; ++i )
{
if ( i >= 3 )
{
d1 = vecRayStart[i-3] - boxMaxs[i-3];
d2 = d1 + vecRayDelta[i-3];
}
else
{
d1 = -vecRayStart[i] + boxMins[i];
d2 = d1 - vecRayDelta[i];
}
// if completely in front of face, no intersection
if (d1 > 0 && d2 > 0)
{
// UNDONE: Have to revert this in case it's still set
// UNDONE: Refactor to have only 2 return points (true/false) from this function
pTrace->startsolid = false;
return false;
}
// completely inside, check next face
if (d1 <= 0 && d2 <= 0)
continue;
if (d1 > 0)
{
pTrace->startsolid = false;
}
// crosses face
if (d1 > d2)
{
f = d1 - flTolerance;
if ( f < 0 )
{
f = 0;
}
f = f / (d1-d2);
if (f > pTrace->t1)
{
pTrace->t1 = f;
pTrace->hitside = i;
}
}
else
{
// leave
f = (d1 + flTolerance) / (d1-d2);
if (f < pTrace->t2)
{
pTrace->t2 = f;
}
}
}
return pTrace->startsolid || (pTrace->t1 < pTrace->t2 && pTrace->t1 >= 0.0f);
}
//-----------------------------------------------------------------------------
// Intersects a ray against a box
//-----------------------------------------------------------------------------
bool IntersectRayWithBox( const Vector &vecRayStart, const Vector &vecRayDelta,
const Vector &boxMins, const Vector &boxMaxs, float flTolerance, CBaseTrace *pTrace, float *pFractionLeftSolid )
{
Collision_ClearTrace( vecRayStart, vecRayDelta, pTrace );
BoxTraceInfo_t trace;
if ( IntersectRayWithBox( vecRayStart, vecRayDelta, boxMins, boxMaxs, flTolerance, &trace ) )
{
pTrace->startsolid = trace.startsolid;
if (trace.t1 < trace.t2 && trace.t1 >= 0.0f)
{
pTrace->fraction = trace.t1;
VectorMA( pTrace->startpos, trace.t1, vecRayDelta, pTrace->endpos );
pTrace->contents = CONTENTS_SOLID;
pTrace->plane.normal = vec3_origin;
if ( trace.hitside >= 3 )
{
trace.hitside -= 3;
pTrace->plane.dist = boxMaxs[trace.hitside];
pTrace->plane.normal[trace.hitside] = 1.0f;
pTrace->plane.type = trace.hitside;
}
else
{
pTrace->plane.dist = -boxMins[trace.hitside];
pTrace->plane.normal[trace.hitside] = -1.0f;
pTrace->plane.type = trace.hitside;
}
return true;
}
if ( pTrace->startsolid )
{
pTrace->allsolid = (trace.t2 <= 0.0f) || (trace.t2 >= 1.0f);
pTrace->fraction = 0;
if ( pFractionLeftSolid )
{
*pFractionLeftSolid = trace.t2;
}
pTrace->endpos = pTrace->startpos;
pTrace->contents = CONTENTS_SOLID;
pTrace->plane.dist = pTrace->startpos[0];
pTrace->plane.normal.Init( 1.0f, 0.0f, 0.0f );
pTrace->plane.type = 0;
pTrace->startpos = vecRayStart + (trace.t2 * vecRayDelta);
return true;
}
}
return false;
}
//-----------------------------------------------------------------------------
// Intersects a ray against a box
//-----------------------------------------------------------------------------
bool IntersectRayWithBox( const Ray_t &ray, const Vector &boxMins, const Vector &boxMaxs,
float flTolerance, CBaseTrace *pTrace, float *pFractionLeftSolid )
{
if ( !ray.m_IsRay )
{
Vector vecExpandedMins = boxMins - ray.m_Extents;
Vector vecExpandedMaxs = boxMaxs + ray.m_Extents;
bool bIntersects = IntersectRayWithBox( ray.m_Start, ray.m_Delta, vecExpandedMins, vecExpandedMaxs, flTolerance, pTrace, pFractionLeftSolid );
pTrace->startpos += ray.m_StartOffset;
pTrace->endpos += ray.m_StartOffset;
return bIntersects;
}
return IntersectRayWithBox( ray.m_Start, ray.m_Delta, boxMins, boxMaxs, flTolerance, pTrace, pFractionLeftSolid );
}
//-----------------------------------------------------------------------------
// Intersects a ray against an OBB, returns t1 and t2
//-----------------------------------------------------------------------------
bool IntersectRayWithOBB( const Vector &vecRayStart, const Vector &vecRayDelta,
const matrix3x4_t &matOBBToWorld, const Vector &vecOBBMins, const Vector &vecOBBMaxs,
float flTolerance, BoxTraceInfo_t *pTrace )
{
// FIXME: Two transforms is pretty expensive. Should we optimize this?
Vector start, delta;
VectorITransform( vecRayStart, matOBBToWorld, start );
VectorIRotate( vecRayDelta, matOBBToWorld, delta );
return IntersectRayWithBox( start, delta, vecOBBMins, vecOBBMaxs, flTolerance, pTrace );
}
//-----------------------------------------------------------------------------
// Intersects a ray against an OBB
//-----------------------------------------------------------------------------
bool IntersectRayWithOBB( const Vector &vecRayStart, const Vector &vecRayDelta,
const matrix3x4_t &matOBBToWorld, const Vector &vecOBBMins, const Vector &vecOBBMaxs,
float flTolerance, CBaseTrace *pTrace )
{
Collision_ClearTrace( vecRayStart, vecRayDelta, pTrace );
// FIXME: Make it work with tolerance
Assert( flTolerance == 0.0f );
// OPTIMIZE: Store this in the box instead of computing it here
// compute center in local space
Vector vecBoxExtents = (vecOBBMins + vecOBBMaxs) * 0.5;
Vector vecBoxCenter;
// transform to world space
VectorTransform( vecBoxExtents, matOBBToWorld, vecBoxCenter );
// calc extents from local center
vecBoxExtents = vecOBBMaxs - vecBoxExtents;
// OPTIMIZE: This is optimized for world space. If the transform is fast enough, it may make more
// sense to just xform and call UTIL_ClipToBox() instead. MEASURE THIS.
// save the extents of the ray along
Vector extent, uextent;
Vector segmentCenter = vecRayStart + vecRayDelta - vecBoxCenter;
extent.Init();
// check box axes for separation
for ( int j = 0; j < 3; j++ )
{
extent[j] = vecRayDelta.x * matOBBToWorld[0][j] + vecRayDelta.y * matOBBToWorld[1][j] + vecRayDelta.z * matOBBToWorld[2][j];
uextent[j] = fabsf(extent[j]);
float coord = segmentCenter.x * matOBBToWorld[0][j] + segmentCenter.y * matOBBToWorld[1][j] + segmentCenter.z * matOBBToWorld[2][j];
coord = fabsf(coord);
if ( coord > (vecBoxExtents[j] + uextent[j]) )
return false;
}
// now check cross axes for separation
float tmp, cextent;
Vector cross = vecRayDelta.Cross( segmentCenter );
cextent = cross.x * matOBBToWorld[0][0] + cross.y * matOBBToWorld[1][0] + cross.z * matOBBToWorld[2][0];
cextent = fabsf(cextent);
tmp = vecBoxExtents[1]*uextent[2] + vecBoxExtents[2]*uextent[1];
if ( cextent > tmp )
return false;
cextent = cross.x * matOBBToWorld[0][1] + cross.y * matOBBToWorld[1][1] + cross.z * matOBBToWorld[2][1];
cextent = fabsf(cextent);
tmp = vecBoxExtents[0]*uextent[2] + vecBoxExtents[2]*uextent[0];
if ( cextent > tmp )
return false;
cextent = cross.x * matOBBToWorld[0][2] + cross.y * matOBBToWorld[1][2] + cross.z * matOBBToWorld[2][2];
cextent = fabsf(cextent);
tmp = vecBoxExtents[0]*uextent[1] + vecBoxExtents[1]*uextent[0];
if ( cextent > tmp )
return false;
// !!! We hit this box !!! compute intersection point and return
// Compute ray start in bone space
Vector start;
VectorITransform( vecRayStart, matOBBToWorld, start );
// extent is ray.m_Delta in bone space, recompute delta in bone space
extent *= 2.0f;
// delta was prescaled by the current t, so no need to see if this intersection
// is closer
trace_t boxTrace;
if ( !IntersectRayWithBox( start, extent, vecOBBMins, vecOBBMaxs, flTolerance, pTrace ) )
return false;
// Fix up the start/end pos and fraction
Vector vecTemp;
VectorTransform( pTrace->endpos, matOBBToWorld, vecTemp );
pTrace->endpos = vecTemp;
pTrace->startpos = vecRayStart;
pTrace->fraction *= 2.0f;
// Fix up the plane information
float flSign = pTrace->plane.normal[ pTrace->plane.type ];
pTrace->plane.normal[0] = flSign * matOBBToWorld[0][pTrace->plane.type];
pTrace->plane.normal[1] = flSign * matOBBToWorld[1][pTrace->plane.type];
pTrace->plane.normal[2] = flSign * matOBBToWorld[2][pTrace->plane.type];
pTrace->plane.dist = DotProduct( pTrace->endpos, pTrace->plane.normal );
pTrace->plane.type = 3;
return true;
}
//-----------------------------------------------------------------------------
// Intersects a ray against an OBB
//-----------------------------------------------------------------------------
bool IntersectRayWithOBB( const Vector &vecRayOrigin, const Vector &vecRayDelta,
const Vector &vecBoxOrigin, const QAngle &angBoxRotation,
const Vector &vecOBBMins, const Vector &vecOBBMaxs, float flTolerance, CBaseTrace *pTrace )
{
if (angBoxRotation == vec3_angle)
{
Vector vecAbsMins, vecAbsMaxs;
VectorAdd( vecBoxOrigin, vecOBBMins, vecAbsMins );
VectorAdd( vecBoxOrigin, vecOBBMaxs, vecAbsMaxs );
return IntersectRayWithBox( vecRayOrigin, vecRayDelta, vecAbsMins, vecAbsMaxs, flTolerance, pTrace );
}
matrix3x4_t obbToWorld;
AngleMatrix( angBoxRotation, vecBoxOrigin, obbToWorld );
return IntersectRayWithOBB( vecRayOrigin, vecRayDelta, obbToWorld, vecOBBMins, vecOBBMaxs, flTolerance, pTrace );
}
//-----------------------------------------------------------------------------
// Box support map
//-----------------------------------------------------------------------------
inline void ComputeSupportMap( const Vector &vecDirection, const Vector &vecBoxMins,
const Vector &vecBoxMaxs, float pDist[2] )
{
int nIndex = (vecDirection.x > 0.0f);
pDist[nIndex] = vecBoxMaxs.x * vecDirection.x;
pDist[1 - nIndex] = vecBoxMins.x * vecDirection.x;
nIndex = (vecDirection.y > 0.0f);
pDist[nIndex] += vecBoxMaxs.y * vecDirection.y;
pDist[1 - nIndex] += vecBoxMins.y * vecDirection.y;
nIndex = (vecDirection.z > 0.0f);
pDist[nIndex] += vecBoxMaxs.z * vecDirection.z;
pDist[1 - nIndex] += vecBoxMins.z * vecDirection.z;
}
inline void ComputeSupportMap( const Vector &vecDirection, int i1, int i2,
const Vector &vecBoxMins, const Vector &vecBoxMaxs, float pDist[2] )
{
int nIndex = (vecDirection[i1] > 0.0f);
pDist[nIndex] = vecBoxMaxs[i1] * vecDirection[i1];
pDist[1 - nIndex] = vecBoxMins[i1] * vecDirection[i1];
nIndex = (vecDirection[i2] > 0.0f);
pDist[nIndex] += vecBoxMaxs[i2] * vecDirection[i2];
pDist[1 - nIndex] += vecBoxMins[i2] * vecDirection[i2];
}
//-----------------------------------------------------------------------------
// Intersects a ray against an OBB
//-----------------------------------------------------------------------------
static int s_ExtIndices[3][2] =
{
{ 2, 1 },
{ 0, 2 },
{ 0, 1 },
};
static int s_MatIndices[3][2] =
{
{ 1, 2 },
{ 2, 0 },
{ 1, 0 },
};
bool IntersectRayWithOBB( const Ray_t &ray, const matrix3x4_t &matOBBToWorld,
const Vector &vecOBBMins, const Vector &vecOBBMaxs, float flTolerance, CBaseTrace *pTrace )
{
if ( ray.m_IsRay )
{
return IntersectRayWithOBB( ray.m_Start, ray.m_Delta, matOBBToWorld,
vecOBBMins, vecOBBMaxs, flTolerance, pTrace );
}
Collision_ClearTrace( ray.m_Start + ray.m_StartOffset, ray.m_Delta, pTrace );
// Compute a bounding sphere around the bloated OBB
Vector vecOBBCenter;
VectorAdd( vecOBBMins, vecOBBMaxs, vecOBBCenter );
vecOBBCenter *= 0.5f;
vecOBBCenter.x += matOBBToWorld[0][3];
vecOBBCenter.y += matOBBToWorld[1][3];
vecOBBCenter.z += matOBBToWorld[2][3];
Vector vecOBBHalfDiagonal;
VectorSubtract( vecOBBMaxs, vecOBBMins, vecOBBHalfDiagonal );
vecOBBHalfDiagonal *= 0.5f;
float flRadius = vecOBBHalfDiagonal.Length() + ray.m_Extents.Length();
if ( !IsRayIntersectingSphere( ray.m_Start, ray.m_Delta, vecOBBCenter, flRadius, flTolerance ) )
return false;
// Ok, we passed the trivial reject, so lets do the dirty deed.
// Basically we're going to do the GJK thing explicitly. We'll shrink the ray down
// to a point, and bloat the OBB by the ray's extents. This will generate facet
// planes which are perpendicular to all of the separating axes typically seen in
// a standard seperating axis implementation.
// We're going to create a number of planes through various vertices in the OBB
// which represent all of the separating planes. Then we're going to bloat the planes
// by the ray extents.
// We're going to do all work in OBB-space because it's easier to do the
// support-map in this case
// First, transform the ray into the space of the OBB
Vector vecLocalRayOrigin, vecLocalRayDirection;
VectorITransform( ray.m_Start, matOBBToWorld, vecLocalRayOrigin );
VectorIRotate( ray.m_Delta, matOBBToWorld, vecLocalRayDirection );
// Next compute all separating planes
Vector pPlaneNormal[15];
float ppPlaneDist[15][2];
int i;
for ( i = 0; i < 3; ++i )
{
// Each plane needs to be bloated an amount = to the abs dot product of
// the ray extents with the plane normal
// For the OBB planes, do it in world space;
// and use the direction of the OBB (the ith column of matOBBToWorld) in world space vs extents
pPlaneNormal[i].Init( );
pPlaneNormal[i][i] = 1.0f;
float flExtentDotNormal =
FloatMakePositive( matOBBToWorld[0][i] * ray.m_Extents.x ) +
FloatMakePositive( matOBBToWorld[1][i] * ray.m_Extents.y ) +
FloatMakePositive( matOBBToWorld[2][i] * ray.m_Extents.z );
ppPlaneDist[i][0] = vecOBBMins[i] - flExtentDotNormal;
ppPlaneDist[i][1] = vecOBBMaxs[i] + flExtentDotNormal;
// For the ray-extents planes, they are bloated by the extents
// Use the support map to determine which
VectorCopy( matOBBToWorld[i], pPlaneNormal[i+3].Base() );
ComputeSupportMap( pPlaneNormal[i+3], vecOBBMins, vecOBBMaxs, ppPlaneDist[i+3] );
ppPlaneDist[i+3][0] -= ray.m_Extents[i];
ppPlaneDist[i+3][1] += ray.m_Extents[i];
// Now the edge cases... (take the cross product of x,y,z axis w/ ray extent axes
// given by the rows of the obb to world matrix.
// Compute the ray extent bloat in world space because it's easier...
// These are necessary to compute the world-space versions of
// the edges so we can compute the extent dot products
float flRayExtent0 = ray.m_Extents[s_ExtIndices[i][0]];
float flRayExtent1 = ray.m_Extents[s_ExtIndices[i][1]];
const float *pMatRow0 = matOBBToWorld[s_MatIndices[i][0]];
const float *pMatRow1 = matOBBToWorld[s_MatIndices[i][1]];
// x axis of the OBB + world ith axis
pPlaneNormal[i+6].Init( 0.0f, -matOBBToWorld[i][2], matOBBToWorld[i][1] );
ComputeSupportMap( pPlaneNormal[i+6], 1, 2, vecOBBMins, vecOBBMaxs, ppPlaneDist[i+6] );
flExtentDotNormal =
FloatMakePositive( pMatRow0[0] ) * flRayExtent0 +
FloatMakePositive( pMatRow1[0] ) * flRayExtent1;
ppPlaneDist[i+6][0] -= flExtentDotNormal;
ppPlaneDist[i+6][1] += flExtentDotNormal;
// y axis of the OBB + world ith axis
pPlaneNormal[i+9].Init( matOBBToWorld[i][2], 0.0f, -matOBBToWorld[i][0] );
ComputeSupportMap( pPlaneNormal[i+9], 0, 2, vecOBBMins, vecOBBMaxs, ppPlaneDist[i+9] );
flExtentDotNormal =
FloatMakePositive( pMatRow0[1] ) * flRayExtent0 +
FloatMakePositive( pMatRow1[1] ) * flRayExtent1;
ppPlaneDist[i+9][0] -= flExtentDotNormal;
ppPlaneDist[i+9][1] += flExtentDotNormal;
// z axis of the OBB + world ith axis
pPlaneNormal[i+12].Init( -matOBBToWorld[i][1], matOBBToWorld[i][0], 0.0f );
ComputeSupportMap( pPlaneNormal[i+12], 0, 1, vecOBBMins, vecOBBMaxs, ppPlaneDist[i+12] );
flExtentDotNormal =
FloatMakePositive( pMatRow0[2] ) * flRayExtent0 +
FloatMakePositive( pMatRow1[2] ) * flRayExtent1;
ppPlaneDist[i+12][0] -= flExtentDotNormal;
ppPlaneDist[i+12][1] += flExtentDotNormal;
}
float enterfrac, leavefrac;
float d1[2], d2[2];
float f;
int hitplane = -1;
int hitside = -1;
enterfrac = -1.0f;
leavefrac = 1.0f;
pTrace->startsolid = true;
Vector vecLocalRayEnd;
VectorAdd( vecLocalRayOrigin, vecLocalRayDirection, vecLocalRayEnd );
for ( i = 0; i < 15; ++i )
{
// FIXME: Not particularly optimal since there's a lot of 0's in the plane normals
float flStartDot = DotProduct( pPlaneNormal[i], vecLocalRayOrigin );
float flEndDot = DotProduct( pPlaneNormal[i], vecLocalRayEnd );
// NOTE: Negative here is because the plane normal + dist
// are defined in negative terms for the far plane (plane dist index 0)
d1[0] = -(flStartDot - ppPlaneDist[i][0]);
d2[0] = -(flEndDot - ppPlaneDist[i][0]);
d1[1] = flStartDot - ppPlaneDist[i][1];
d2[1] = flEndDot - ppPlaneDist[i][1];
int j;
for ( j = 0; j < 2; ++j )
{
// if completely in front near plane or behind far plane no intersection
if (d1[j] > 0 && d2[j] > 0)
return false;
// completely inside, check next plane set
if (d1[j] <= 0 && d2[j] <= 0)
continue;
if (d1[j] > 0)
{
pTrace->startsolid = false;
}
// crosses face
float flDenom = 1.0f / (d1[j] - d2[j]);
if (d1[j] > d2[j])
{
f = d1[j] - flTolerance;
if ( f < 0 )
{
f = 0;
}
f *= flDenom;
if (f > enterfrac)
{
enterfrac = f;
hitplane = i;
hitside = j;
}
}
else
{
// leave
f = (d1[j] + flTolerance) * flDenom;
if (f < leavefrac)
{
leavefrac = f;
}
}
}
}
if (enterfrac < leavefrac && enterfrac >= 0.0f)
{
pTrace->fraction = enterfrac;
VectorMA( pTrace->startpos, enterfrac, ray.m_Delta, pTrace->endpos );
pTrace->contents = CONTENTS_SOLID;
// Need to transform the plane into world space...
cplane_t temp;
temp.normal = pPlaneNormal[hitplane];
temp.dist = ppPlaneDist[hitplane][hitside];
if (hitside == 0)
{
temp.normal *= -1.0f;
temp.dist *= -1.0f;
}
temp.type = 3;
MatrixITransformPlane( matOBBToWorld, temp, pTrace->plane );
return true;
}
if ( pTrace->startsolid )
{
pTrace->allsolid = (leavefrac <= 0.0f) || (leavefrac >= 1.0f);
pTrace->fraction = 0;
pTrace->endpos = pTrace->startpos;
pTrace->contents = CONTENTS_SOLID;
pTrace->plane.dist = pTrace->startpos[0];
pTrace->plane.normal.Init( 1.0f, 0.0f, 0.0f );
pTrace->plane.type = 0;
return true;
}
return false;
}
//-----------------------------------------------------------------------------
// Intersects a ray against an OBB
//-----------------------------------------------------------------------------
bool IntersectRayWithOBB( const Ray_t &ray, const Vector &vecBoxOrigin, const QAngle &angBoxRotation,
const Vector &vecOBBMins, const Vector &vecOBBMaxs, float flTolerance, CBaseTrace *pTrace )
{
if ( angBoxRotation == vec3_angle )
{
Vector vecWorldMins, vecWorldMaxs;
VectorAdd( vecBoxOrigin, vecOBBMins, vecWorldMins );
VectorAdd( vecBoxOrigin, vecOBBMaxs, vecWorldMaxs );
return IntersectRayWithBox( ray, vecWorldMins, vecWorldMaxs, flTolerance, pTrace );
}
if ( ray.m_IsRay )
{
return IntersectRayWithOBB( ray.m_Start, ray.m_Delta, vecBoxOrigin, angBoxRotation, vecOBBMins, vecOBBMaxs, flTolerance, pTrace );
}
matrix3x4_t matOBBToWorld;
AngleMatrix( angBoxRotation, vecBoxOrigin, matOBBToWorld );
return IntersectRayWithOBB( ray, matOBBToWorld, vecOBBMins, vecOBBMaxs, flTolerance, pTrace );
}
//-----------------------------------------------------------------------------
//
//-----------------------------------------------------------------------------
void GetNonMajorAxes( const Vector &vNormal, Vector2D &axes )
{
axes[0] = 0;
axes[1] = 1;
if( FloatMakePositive( vNormal.x ) > FloatMakePositive( vNormal.y ) )
{
if( FloatMakePositive( vNormal.x ) > FloatMakePositive( vNormal.z ) )
{
axes[0] = 1;
axes[1] = 2;
}
}
else
{
if( FloatMakePositive( vNormal.y ) > FloatMakePositive( vNormal.z ) )
{
axes[0] = 0;
axes[1] = 2;
}
}
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
QuadBarycentricRetval_t QuadWithParallelEdges( const Vector &vecOrigin,
const Vector &vecU, float lengthU, const Vector &vecV, float lengthV,
const Vector &pt, Vector2D &vecUV )
{
Ray_t rayAxis;
Ray_t rayPt;
//
// handle the u axis
//
rayAxis.m_Start = vecOrigin;
rayAxis.m_Delta = vecU;
rayAxis.m_IsRay = true;
rayPt.m_Start = pt;
rayPt.m_Delta = vecV * -( lengthV * 10.0f );
rayPt.m_IsRay = true;
float s, t;
IntersectRayWithRay( rayAxis, rayPt, t, s );
vecUV[0] = t / lengthU;
//
// handle the v axis
//
rayAxis.m_Delta = vecV;
rayPt.m_Delta = vecU * -( lengthU * 10.0f );
IntersectRayWithRay( rayAxis, rayPt, t, s );
vecUV[1] = t / lengthV;
// inside of the quad??
if( ( vecUV[0] < 0.0f ) || ( vecUV[0] > 1.0f ) ||
( vecUV[1] < 0.0f ) || ( vecUV[1] > 1.0f ) )
return BARY_QUADRATIC_FALSE;
return BARY_QUADRATIC_TRUE;
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
void ResolveQuadratic( double tPlus, double tMinus,
const Vector axisU0, const Vector axisU1,
const Vector axisV0, const Vector axisV1,
const Vector axisOrigin, const Vector pt,
int projU, double &s, double &t )
{
// calculate the sPlus, sMinus pair(s)
double sDenomPlus = ( axisU0[projU] * ( 1 - tPlus ) ) + ( axisU1[projU] * tPlus );
double sDenomMinus = ( axisU0[projU] * ( 1 - tMinus ) ) + ( axisU1[projU] * tMinus );
double sPlus = UNINIT, sMinus = UNINIT;
if( FloatMakePositive( sDenomPlus ) >= 1e-5 )
{
sPlus = ( pt[projU] - axisOrigin[projU] - ( axisV0[projU] * tPlus ) ) / sDenomPlus;
}
if( FloatMakePositive( sDenomMinus ) >= 1e-5 )
{
sMinus = ( pt[projU] - axisOrigin[projU] - ( axisV0[projU] * tMinus ) ) / sDenomMinus;
}
if( ( tPlus >= 0.0 ) && ( tPlus <= 1.0 ) && ( sPlus >= 0.0 ) && ( sPlus <= 1.0 ) )
{
s = sPlus;
t = tPlus;
return;
}
if( ( tMinus >= 0.0 ) && ( tMinus <= 1.0 ) && ( sMinus >= 0.0 ) && ( sMinus <= 1.0 ) )
{
s = sMinus;
t = tMinus;
return;
}
double s0, t0, s1, t1;
s0 = sPlus;
t0 = tPlus;
if( s0 >= 1.0 ) { s0 -= 1.0; }
if( t0 >= 1.0 ) { t0 -= 1.0; }
s1 = sMinus;
t1 = tMinus;
if( s1 >= 1.0 ) { s1 -= 1.0; }
if( t1 >= 1.0 ) { t1 -= 1.0; }
s0 = FloatMakePositive( s0 );
t0 = FloatMakePositive( t0 );
s1 = FloatMakePositive( s1 );
t1 = FloatMakePositive( t1 );
double max0, max1;
max0 = s0;
if( t0 > max0 ) { max0 = t0; }
max1 = s1;
if( t1 > max1 ) { max1 = t1; }
if( max0 > max1 )
{
s = sMinus;
t = tMinus;
}
else
{
s = sPlus;
t = tPlus;
}
}
//-----------------------------------------------------------------------------
//
//-----------------------------------------------------------------------------
QuadBarycentricRetval_t PointInQuadToBarycentric( const Vector &v1, const Vector &v2,
const Vector &v3, const Vector &v4, const Vector &point, Vector2D &uv )
{
#define PIQ_TEXTURE_EPSILON 0.001
#define PIQ_PLANE_EPSILON 0.1
#define PIQ_DOT_EPSILON 0.99f
//
// Think of a quad with points v1, v2, v3, v4 and u, v line segments
// u0 = v2 - v1
// u1 = v3 - v4
// v0 = v4 - v1
// v1 = v3 - v2
//
Vector axisU[2], axisV[2];
Vector axisUNorm[2], axisVNorm[2];
axisU[0] = axisUNorm[0] = v2 - v1;
axisU[1] = axisUNorm[1] = v3 - v4;
axisV[0] = axisVNorm[0] = v4 - v1;
axisV[1] = axisVNorm[1] = v3 - v2;
float lengthU[2], lengthV[2];
lengthU[0] = VectorNormalize( axisUNorm[0] );
lengthU[1] = VectorNormalize( axisUNorm[1] );
lengthV[0] = VectorNormalize( axisVNorm[0] );
lengthV[1] = VectorNormalize( axisVNorm[1] );
//
// check for an early out - parallel opposite edges!
// NOTE: quad property if 1 set of opposite edges is parallel and equal
// in length, then the other set of edges is as well
//
if( axisUNorm[0].Dot( axisUNorm[1] ) > PIQ_DOT_EPSILON )
{
if( FloatMakePositive( lengthU[0] - lengthU[1] ) < PIQ_PLANE_EPSILON )
{
return QuadWithParallelEdges( v1, axisUNorm[0], lengthU[0], axisVNorm[0], lengthV[0], point, uv );
}
}
//
// since we are solving for s in our equations below we need to ensure that
// the v axes are non-parallel
//
bool bFlipped = false;
if( axisVNorm[0].Dot( axisVNorm[1] ) > PIQ_DOT_EPSILON )
{
Vector tmp[2];
tmp[0] = axisV[0];
tmp[1] = axisV[1];
axisV[0] = axisU[0];
axisV[1] = axisU[1];
axisU[0] = tmp[0];
axisU[1] = tmp[1];
bFlipped = true;
}
//
// get the "projection" axes
//
Vector2D projAxes;
Vector vNormal = axisU[0].Cross( axisV[0] );
GetNonMajorAxes( vNormal, projAxes );
//
// NOTE: axisU[0][projAxes[0]] < axisU[0][projAxes[1]],
// this is done to decrease error when dividing later
//
if( FloatMakePositive( axisU[0][projAxes[0]] ) < FloatMakePositive( axisU[0][projAxes[1]] ) )
{
int tmp = projAxes[0];
projAxes[0] = projAxes[1];
projAxes[1] = tmp;
}
// Here's how we got these equations:
//
// Given the points and u,v line segments above...
//
// Then:
//
// (1.0) PT = P0 + U0 * s + V * t
//
// where
//
// (1.1) V = V0 + s * (V1 - V0)
// (1.2) U = U0 + t * (U1 - U0)
//
// Therefore (from 1.1 + 1.0):
// PT - P0 = U0 * s + (V0 + s * (V1-V0)) * t
// Group s's:
// PT - P0 - t * V0 = s * (U0 + t * (V1-V0))
// Two equations and two unknowns in x and y get you the following quadratic:
//
// solve the quadratic
//
double s = 0.0, t = 0.0;
double A, negB, C;
A = ( axisU[0][projAxes[1]] * axisV[0][projAxes[0]] ) -
( axisU[0][projAxes[0]] * axisV[0][projAxes[1]] ) -
( axisU[1][projAxes[1]] * axisV[0][projAxes[0]] ) +
( axisU[1][projAxes[0]] * axisV[0][projAxes[1]] );
C = ( v1[projAxes[1]] * axisU[0][projAxes[0]] ) -
( point[projAxes[1]] * axisU[0][projAxes[0]] ) -
( v1[projAxes[0]] * axisU[0][projAxes[1]] ) +
( point[projAxes[0]] * axisU[0][projAxes[1]] );
negB = C -
( v1[projAxes[1]] * axisU[1][projAxes[0]] ) +
( point[projAxes[1]] * axisU[1][projAxes[0]] ) +
( v1[projAxes[0]] * axisU[1][projAxes[1]] ) -
( point[projAxes[0]] * axisU[1][projAxes[1]] ) +
( axisU[0][projAxes[1]] * axisV[0][projAxes[0]] ) -
( axisU[0][projAxes[0]] * axisV[0][projAxes[1]] );
if( ( A > -PIQ_PLANE_EPSILON ) && ( A < PIQ_PLANE_EPSILON ) )
{
// shouldn't be here -- this should have been take care of in the "early out"
// Assert( 0 );
Vector vecUAvg, vecVAvg;
vecUAvg = ( axisUNorm[0] + axisUNorm[1] ) * 0.5f;
vecVAvg = ( axisVNorm[0] + axisVNorm[1] ) * 0.5f;
float fLengthUAvg = ( lengthU[0] + lengthU[1] ) * 0.5f;
float fLengthVAvg = ( lengthV[0] + lengthV[1] ) * 0.5f;
return QuadWithParallelEdges( v1, vecUAvg, fLengthUAvg, vecVAvg, fLengthVAvg, point, uv );
#if 0
// legacy code -- kept here for completeness!
// not a quadratic -- solve linearly
t = C / negB;
// See (1.2) above
float ui = axisU[0][projAxes[0]] + t * ( axisU[1][projAxes[0]] - axisU[0][projAxes[0]] );
if( FloatMakePositive( ui ) >= 1e-5 )
{
// See (1.0) above
s = ( point[projAxes[0]] - v1[projAxes[0]] - axisV[0][projAxes[0]] * t ) / ui;
}
#endif
}
else
{
// (-b +/- sqrt( b^2 - 4ac )) / 2a
double discriminant = (negB*negB) - (4.0f * A * C);
if( discriminant < 0.0f )
{
uv[0] = -99999.0f;
uv[1] = -99999.0f;
return BARY_QUADRATIC_NEGATIVE_DISCRIMINANT;
}
double quad = sqrt( discriminant );
double QPlus = ( negB + quad ) / ( 2.0f * A );
double QMinus = ( negB - quad ) / ( 2.0f * A );
ResolveQuadratic( QPlus, QMinus, axisU[0], axisU[1], axisV[0], axisV[1], v1, point, projAxes[0], s, t );
}
if( !bFlipped )
{
uv[0] = ( float )s;
uv[1] = ( float )t;
}
else
{
uv[0] = ( float )t;
uv[1] = ( float )s;
}
// inside of the quad??
if( ( uv[0] < 0.0f ) || ( uv[0] > 1.0f ) || ( uv[1] < 0.0f ) || ( uv[1] > 1.0f ) )
return BARY_QUADRATIC_FALSE;
return BARY_QUADRATIC_TRUE;
#undef PIQ_TEXTURE_EPSILON
#undef PIQ_PLANE_EPSILON
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
void PointInQuadFromBarycentric( const Vector &v1, const Vector &v2, const Vector &v3, const Vector &v4,
const Vector2D &uv, Vector &point )
{
//
// Think of a quad with points v1, v2, v3, v4 and u, v line segments
// find the ray from v0 edge to v1 edge at v
//
Vector vPts[2];
VectorLerp( v1, v4, uv[1], vPts[0] );
VectorLerp( v2, v3, uv[1], vPts[1] );
VectorLerp( vPts[0], vPts[1], uv[0], point );
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
void TexCoordInQuadFromBarycentric( const Vector2D &v1, const Vector2D &v2, const Vector2D &v3, const Vector2D &v4,
const Vector2D &uv, Vector2D &texCoord )
{
//
// Think of a quad with points v1, v2, v3, v4 and u, v line segments
// find the ray from v0 edge to v1 edge at v
//
Vector2D vCoords[2];
Vector2DLerp( v1, v4, uv[1], vCoords[0] );
Vector2DLerp( v2, v3, uv[1], vCoords[1] );
Vector2DLerp( vCoords[0], vCoords[1], uv[0], texCoord );
}
//-----------------------------------------------------------------------------
// Compute point from barycentric specification
// Edge u goes from v0 to v1, edge v goes from v0 to v2
//-----------------------------------------------------------------------------
void ComputePointFromBarycentric( const Vector& v0, const Vector& v1, const Vector& v2,
float u, float v, Vector& pt )
{
Vector edgeU, edgeV;
VectorSubtract( v1, v0, edgeU );
VectorSubtract( v2, v0, edgeV );
VectorMA( v0, u, edgeU, pt );
VectorMA( pt, v, edgeV, pt );
}
void ComputePointFromBarycentric( const Vector2D& v0, const Vector2D& v1, const Vector2D& v2,
float u, float v, Vector2D& pt )
{
Vector2D edgeU, edgeV;
Vector2DSubtract( v1, v0, edgeU );
Vector2DSubtract( v2, v0, edgeV );
Vector2DMA( v0, u, edgeU, pt );
Vector2DMA( pt, v, edgeV, pt );
}
//-----------------------------------------------------------------------------
// Compute a matrix that has the correct orientation but which has an origin at
// the center of the bounds
//-----------------------------------------------------------------------------
static void ComputeCenterMatrix( const Vector& origin, const QAngle& angles,
const Vector& mins, const Vector& maxs, matrix3x4_t& matrix )
{
Vector centroid;
VectorAdd( mins, maxs, centroid );
centroid *= 0.5f;
AngleMatrix( angles, matrix );
Vector worldCentroid;
VectorRotate( centroid, matrix, worldCentroid );
worldCentroid += origin;
MatrixSetColumn( worldCentroid, 3, matrix );
}
static void ComputeCenterIMatrix( const Vector& origin, const QAngle& angles,
const Vector& mins, const Vector& maxs, matrix3x4_t& matrix )
{
Vector centroid;
VectorAdd( mins, maxs, centroid );
centroid *= -0.5f;
AngleIMatrix( angles, matrix );
// For the translational component here, note that the origin in world space
// is T = R * C + O, (R = rotation matrix, C = centroid in local space, O = origin in world space)
// The IMatrix translation = - transpose(R) * T = -C - transpose(R) * 0
Vector localOrigin;
VectorRotate( origin, matrix, localOrigin );
centroid -= localOrigin;
MatrixSetColumn( centroid, 3, matrix );
}
//-----------------------------------------------------------------------------
// Compute a matrix which is the absolute value of another
//-----------------------------------------------------------------------------
static inline void ComputeAbsMatrix( const matrix3x4_t& in, matrix3x4_t& out )
{
FloatBits(out[0][0]) = FloatAbsBits(in[0][0]);
FloatBits(out[0][1]) = FloatAbsBits(in[0][1]);
FloatBits(out[0][2]) = FloatAbsBits(in[0][2]);
FloatBits(out[1][0]) = FloatAbsBits(in[1][0]);
FloatBits(out[1][1]) = FloatAbsBits(in[1][1]);
FloatBits(out[1][2]) = FloatAbsBits(in[1][2]);
FloatBits(out[2][0]) = FloatAbsBits(in[2][0]);
FloatBits(out[2][1]) = FloatAbsBits(in[2][1]);
FloatBits(out[2][2]) = FloatAbsBits(in[2][2]);
}
//-----------------------------------------------------------------------------
// Compute a separating plane between two boxes (expensive!)
// Returns false if no separating plane exists
//-----------------------------------------------------------------------------
static bool ComputeSeparatingPlane( const matrix3x4_t &worldToBox1, const matrix3x4_t &box2ToWorld,
const Vector& box1Size, const Vector& box2Size, float tolerance, cplane_t* pPlane )
{
// The various separating planes can be either
// 1) A plane parallel to one of the box face planes
// 2) A plane parallel to the cross-product of an edge from each box
// First, compute the basis of second box in the space of the first box
// NOTE: These basis place the origin at the centroid of each box!
matrix3x4_t box2ToBox1;
ConcatTransforms( worldToBox1, box2ToWorld, box2ToBox1 );
// We're going to be using the origin of box2 in the space of box1 alot,
// lets extract it from the matrix....
Vector box2Origin;
MatrixGetColumn( box2ToBox1, 3, box2Origin );
// Next get the absolute values of these entries and store in absbox2ToBox1.
matrix3x4_t absBox2ToBox1;
ComputeAbsMatrix( box2ToBox1, absBox2ToBox1 );
// There are 15 tests to make. The first 3 involve trying planes parallel
// to the faces of the first box.
// NOTE: The algorithm here involves finding the projections of the two boxes
// onto a particular line. If the projections on the line do not overlap,
// that means that there's a plane perpendicular to the line which separates
// the two boxes; and we've therefore found a separating plane.
// The way we check for overlay is we find the projections of the two boxes
// onto the line, and add them up. We compare the sum with the projection
// of the relative center of box2 onto the same line.
Vector tmp;
float boxProjectionSum;
float originProjection;
// NOTE: For these guys, we're taking advantage of the fact that the ith
// row of the box2ToBox1 is the direction of the box1 (x,y,z)-axis
// transformed into the space of box2.
// First side of box 1
boxProjectionSum = box1Size.x + MatrixRowDotProduct( absBox2ToBox1, 0, box2Size );
originProjection = FloatMakePositive( box2Origin.x ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
VectorCopy( worldToBox1[0], pPlane->normal.Base() );
return true;
}
// Second side of box 1
boxProjectionSum = box1Size.y + MatrixRowDotProduct( absBox2ToBox1, 1, box2Size );
originProjection = FloatMakePositive( box2Origin.y ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
VectorCopy( worldToBox1[1], pPlane->normal.Base() );
return true;
}
// Third side of box 1
boxProjectionSum = box1Size.z + MatrixRowDotProduct( absBox2ToBox1, 2, box2Size );
originProjection = FloatMakePositive( box2Origin.z ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
VectorCopy( worldToBox1[2], pPlane->normal.Base() );
return true;
}
// The next three involve checking splitting planes parallel to the
// faces of the second box.
// NOTE: For these guys, we're taking advantage of the fact that the 0th
// column of the box2ToBox1 is the direction of the box2 x-axis
// transformed into the space of box1.
// Here, we're determining the distance of box2's center from box1's center
// by projecting it onto a line parallel to box2's axis
// First side of box 2
boxProjectionSum = box2Size.x + MatrixColumnDotProduct( absBox2ToBox1, 0, box1Size );
originProjection = FloatMakePositive( MatrixColumnDotProduct( box2ToBox1, 0, box2Origin ) ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 0, pPlane->normal );
return true;
}
// Second side of box 2
boxProjectionSum = box2Size.y + MatrixColumnDotProduct( absBox2ToBox1, 1, box1Size );
originProjection = FloatMakePositive( MatrixColumnDotProduct( box2ToBox1, 1, box2Origin ) ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 1, pPlane->normal );
return true;
}
// Third side of box 2
boxProjectionSum = box2Size.z + MatrixColumnDotProduct( absBox2ToBox1, 2, box1Size );
originProjection = FloatMakePositive( MatrixColumnDotProduct( box2ToBox1, 2, box2Origin ) ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 2, pPlane->normal );
return true;
}
// Next check the splitting planes which are orthogonal to the pairs
// of edges, one from box1 and one from box2. As only direction matters,
// there are 9 pairs since each box has 3 distinct edge directions.
// Here, we take advantage of the fact that the edges from box 1 are all
// axis aligned; therefore the crossproducts are simplified. Let's walk through
// the example of b1e1 x b2e1:
// In this example, the line to check is perpendicular to b1e1 + b2e2
// we can compute this line by taking the cross-product:
//
// [ i j k ]
// [ 1 0 0 ] = - ez j + ey k = l1
// [ ex ey ez ]
// Where ex, ey, ez is the components of box2's x axis in the space of box 1,
// which is == to the 0th column of of box2toBox1
// The projection of box1 onto this line = the absolute dot product of the box size
// against the line, which =
// AbsDot( box1Size, l1 ) = abs( -ez * box1.y ) + abs( ey * box1.z )
// To compute the projection of box2 onto this line, we'll do it in the space of box 2
//
// [ i j k ]
// [ fx fy fz ] = fz j - fy k = l2
// [ 1 0 0 ]
// Where fx, fy, fz is the components of box1's x axis in the space of box 2,
// which is == to the 0th row of of box2toBox1
// The projection of box2 onto this line = the absolute dot product of the box size
// against the line, which =
// AbsDot( box2Size, l2 ) = abs( fz * box2.y ) + abs ( fy * box2.z )
// The projection of the relative origin position on this line is done in the
// space of box 1:
//
// originProjection = DotProduct( <-ez j + ey k>, box2Origin ) =
// -ez * box2Origin.y + ey * box2Origin.z
// NOTE: These checks can be bogus if both edges are parallel. The if
// checks at the beginning of each block are designed to catch that case
// b1e1 x b2e1
if ( absBox2ToBox1[0][0] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.y * absBox2ToBox1[2][0] + box1Size.z * absBox2ToBox1[1][0] +
box2Size.y * absBox2ToBox1[0][2] + box2Size.z * absBox2ToBox1[0][1];
originProjection = FloatMakePositive( -box2Origin.y * box2ToBox1[2][0] + box2Origin.z * box2ToBox1[1][0] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 0, tmp );
CrossProduct( worldToBox1[0], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e1 x b2e2
if ( absBox2ToBox1[0][1] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.y * absBox2ToBox1[2][1] + box1Size.z * absBox2ToBox1[1][1] +
box2Size.x * absBox2ToBox1[0][2] + box2Size.z * absBox2ToBox1[0][0];
originProjection = FloatMakePositive( -box2Origin.y * box2ToBox1[2][1] + box2Origin.z * box2ToBox1[1][1] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 1, tmp );
CrossProduct( worldToBox1[0], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e1 x b2e3
if ( absBox2ToBox1[0][2] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.y * absBox2ToBox1[2][2] + box1Size.z * absBox2ToBox1[1][2] +
box2Size.x * absBox2ToBox1[0][1] + box2Size.y * absBox2ToBox1[0][0];
originProjection = FloatMakePositive( -box2Origin.y * box2ToBox1[2][2] + box2Origin.z * box2ToBox1[1][2] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 2, tmp );
CrossProduct( worldToBox1[0], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e2 x b2e1
if ( absBox2ToBox1[1][0] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.x * absBox2ToBox1[2][0] + box1Size.z * absBox2ToBox1[0][0] +
box2Size.y * absBox2ToBox1[1][2] + box2Size.z * absBox2ToBox1[1][1];
originProjection = FloatMakePositive( box2Origin.x * box2ToBox1[2][0] - box2Origin.z * box2ToBox1[0][0] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 0, tmp );
CrossProduct( worldToBox1[1], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e2 x b2e2
if ( absBox2ToBox1[1][1] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.x * absBox2ToBox1[2][1] + box1Size.z * absBox2ToBox1[0][1] +
box2Size.x * absBox2ToBox1[1][2] + box2Size.z * absBox2ToBox1[1][0];
originProjection = FloatMakePositive( box2Origin.x * box2ToBox1[2][1] - box2Origin.z * box2ToBox1[0][1] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 1, tmp );
CrossProduct( worldToBox1[1], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e2 x b2e3
if ( absBox2ToBox1[1][2] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.x * absBox2ToBox1[2][2] + box1Size.z * absBox2ToBox1[0][2] +
box2Size.x * absBox2ToBox1[1][1] + box2Size.y * absBox2ToBox1[1][0];
originProjection = FloatMakePositive( box2Origin.x * box2ToBox1[2][2] - box2Origin.z * box2ToBox1[0][2] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 2, tmp );
CrossProduct( worldToBox1[1], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e3 x b2e1
if ( absBox2ToBox1[2][0] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.x * absBox2ToBox1[1][0] + box1Size.y * absBox2ToBox1[0][0] +
box2Size.y * absBox2ToBox1[2][2] + box2Size.z * absBox2ToBox1[2][1];
originProjection = FloatMakePositive( -box2Origin.x * box2ToBox1[1][0] + box2Origin.y * box2ToBox1[0][0] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 0, tmp );
CrossProduct( worldToBox1[2], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e3 x b2e2
if ( absBox2ToBox1[2][1] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.x * absBox2ToBox1[1][1] + box1Size.y * absBox2ToBox1[0][1] +
box2Size.x * absBox2ToBox1[2][2] + box2Size.z * absBox2ToBox1[2][0];
originProjection = FloatMakePositive( -box2Origin.x * box2ToBox1[1][1] + box2Origin.y * box2ToBox1[0][1] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 1, tmp );
CrossProduct( worldToBox1[2], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
// b1e3 x b2e3
if ( absBox2ToBox1[2][2] < 1.0f - 1e-3f )
{
boxProjectionSum =
box1Size.x * absBox2ToBox1[1][2] + box1Size.y * absBox2ToBox1[0][2] +
box2Size.x * absBox2ToBox1[2][1] + box2Size.y * absBox2ToBox1[2][0];
originProjection = FloatMakePositive( -box2Origin.x * box2ToBox1[1][2] + box2Origin.y * box2ToBox1[0][2] ) + tolerance;
if ( FloatBits(originProjection) > FloatBits(boxProjectionSum) )
{
MatrixGetColumn( box2ToWorld, 2, tmp );
CrossProduct( worldToBox1[2], tmp.Base(), pPlane->normal.Base() );
return true;
}
}
return false;
}
//-----------------------------------------------------------------------------
// Compute a separating plane between two boxes (expensive!)
// Returns false if no separating plane exists
//-----------------------------------------------------------------------------
bool ComputeSeparatingPlane( const Vector& org1, const QAngle& angles1, const Vector& min1, const Vector& max1,
const Vector& org2, const QAngle& angles2, const Vector& min2, const Vector& max2,
float tolerance, cplane_t* pPlane )
{
matrix3x4_t worldToBox1, box2ToWorld;
ComputeCenterIMatrix( org1, angles1, min1, max1, worldToBox1 );
ComputeCenterMatrix( org2, angles2, min2, max2, box2ToWorld );
// Then compute the size of the two boxes
Vector box1Size, box2Size;
VectorSubtract( max1, min1, box1Size );
VectorSubtract( max2, min2, box2Size );
box1Size *= 0.5f;
box2Size *= 0.5f;
return ComputeSeparatingPlane( worldToBox1, box2ToWorld, box1Size, box2Size, tolerance, pPlane );
}
//-----------------------------------------------------------------------------
// Swept OBB test
//-----------------------------------------------------------------------------
bool IsRayIntersectingOBB( const Ray_t &ray, const Vector& org, const QAngle& angles,
const Vector& mins, const Vector& maxs )
{
if ( angles == vec3_angle )
{
Vector vecWorldMins, vecWorldMaxs;
VectorAdd( org, mins, vecWorldMins );
VectorAdd( org, maxs, vecWorldMaxs );
return IsBoxIntersectingRay( vecWorldMins, vecWorldMaxs, ray );
}
if ( ray.m_IsRay )
{
matrix3x4_t worldToBox;
AngleIMatrix( angles, org, worldToBox );
Ray_t rotatedRay;
VectorTransform( ray.m_Start, worldToBox, rotatedRay.m_Start );
VectorRotate( ray.m_Delta, worldToBox, rotatedRay.m_Delta );
rotatedRay.m_StartOffset = vec3_origin;
rotatedRay.m_Extents = vec3_origin;
rotatedRay.m_IsRay = ray.m_IsRay;
rotatedRay.m_IsSwept = ray.m_IsSwept;
return IsBoxIntersectingRay( mins, maxs, rotatedRay );
}
if ( !ray.m_IsSwept )
{
cplane_t plane;
return ComputeSeparatingPlane( ray.m_Start, vec3_angle, -ray.m_Extents, ray.m_Extents,
org, angles, mins, maxs, 0.0f, &plane ) == false;
}
// NOTE: See the comments in ComputeSeparatingPlane to understand this math
// First, compute the basis of box in the space of the ray
// NOTE: These basis place the origin at the centroid of each box!
matrix3x4_t worldToBox1, box2ToWorld;
ComputeCenterMatrix( org, angles, mins, maxs, box2ToWorld );
// Find the center + extents of an AABB surrounding the ray
Vector vecRayCenter;
VectorMA( ray.m_Start, 0.5, ray.m_Delta, vecRayCenter );
vecRayCenter *= -1.0f;
SetIdentityMatrix( worldToBox1 );
MatrixSetColumn( vecRayCenter, 3, worldToBox1 );
Vector box1Size;
box1Size.x = ray.m_Extents.x + FloatMakePositive( ray.m_Delta.x ) * 0.5f;
box1Size.y = ray.m_Extents.y + FloatMakePositive( ray.m_Delta.y ) * 0.5f;
box1Size.z = ray.m_Extents.z + FloatMakePositive( ray.m_Delta.z ) * 0.5f;
// Then compute the size of the box
Vector box2Size;
VectorSubtract( maxs, mins, box2Size );
box2Size *= 0.5f;
// Do an OBB test of the box with the AABB surrounding the ray
cplane_t plane;
if ( ComputeSeparatingPlane( worldToBox1, box2ToWorld, box1Size, box2Size, 0.0f, &plane ) )
return false;
// Now deal with the planes which are the cross products of the ray sweep direction vs box edges
Vector vecRayDirection = ray.m_Delta;
VectorNormalize( vecRayDirection );
// Need a vector between ray center vs box center measured in the space of the ray (world)
Vector vecCenterDelta;
vecCenterDelta.x = box2ToWorld[0][3] - ray.m_Start.x;
vecCenterDelta.y = box2ToWorld[1][3] - ray.m_Start.y;
vecCenterDelta.z = box2ToWorld[2][3] - ray.m_Start.z;
// Rotate the ray direction into the space of the OBB
Vector vecAbsRayDirBox2;
VectorIRotate( vecRayDirection, box2ToWorld, vecAbsRayDirBox2 );
// Make abs versions of the ray in world space + ray in box2 space
VectorAbs( vecAbsRayDirBox2, vecAbsRayDirBox2 );
// Now do the work for the planes which are perpendicular to the edges of the AABB
// and the sweep direction edges...
// In this example, the line to check is perpendicular to box edge x + ray delta
// we can compute this line by taking the cross-product:
//
// [ i j k ]
// [ 1 0 0 ] = - dz j + dy k = l1
// [ dx dy dz ]
// Where dx, dy, dz is the ray delta (normalized)
// The projection of the box onto this line = the absolute dot product of the box size
// against the line, which =
// AbsDot( vecBoxHalfDiagonal, l1 ) = abs( -dz * vecBoxHalfDiagonal.y ) + abs( dy * vecBoxHalfDiagonal.z )
// Because the plane contains the sweep direction, the sweep will produce
// no extra projection onto the line normal to the plane.
// Therefore all we need to do is project the ray extents onto this line also:
// AbsDot( ray.m_Extents, l1 ) = abs( -dz * ray.m_Extents.y ) + abs( dy * ray.m_Extents.z )
Vector vecPlaneNormal;
// box x x ray delta
CrossProduct( vecRayDirection, Vector( box2ToWorld[0][0], box2ToWorld[1][0], box2ToWorld[2][0] ), vecPlaneNormal );
float flCenterDeltaProjection = FloatMakePositive( DotProduct( vecPlaneNormal, vecCenterDelta ) );
float flBoxProjectionSum =
vecAbsRayDirBox2.z * box2Size.y + vecAbsRayDirBox2.y * box2Size.z +
DotProductAbs( vecPlaneNormal, ray.m_Extents );
if ( FloatBits(flCenterDeltaProjection) > FloatBits(flBoxProjectionSum) )
return false;
// box y x ray delta
CrossProduct( vecRayDirection, Vector( box2ToWorld[0][1], box2ToWorld[1][1], box2ToWorld[2][1] ), vecPlaneNormal );
flCenterDeltaProjection = FloatMakePositive( DotProduct( vecPlaneNormal, vecCenterDelta ) );
flBoxProjectionSum =
vecAbsRayDirBox2.z * box2Size.x + vecAbsRayDirBox2.x * box2Size.z +
DotProductAbs( vecPlaneNormal, ray.m_Extents );
if ( FloatBits(flCenterDeltaProjection) > FloatBits(flBoxProjectionSum) )
return false;
// box z x ray delta
CrossProduct( vecRayDirection, Vector( box2ToWorld[0][2], box2ToWorld[1][2], box2ToWorld[2][2] ), vecPlaneNormal );
flCenterDeltaProjection = FloatMakePositive( DotProduct( vecPlaneNormal, vecCenterDelta ) );
flBoxProjectionSum =
vecAbsRayDirBox2.y * box2Size.x + vecAbsRayDirBox2.x * box2Size.y +
DotProductAbs( vecPlaneNormal, ray.m_Extents );
if ( FloatBits(flCenterDeltaProjection) > FloatBits(flBoxProjectionSum) )
return false;
return true;
}
//--------------------------------------------------------------------------
// Purpose:
//
// NOTE:
// triangle points are given in clockwise order (aabb-triangle test)
//
// 1 edge0 = 1 - 0
// | \ edge1 = 2 - 1
// | \ edge2 = 0 - 2
// | \ .
// | \ .
// 0-----2 .
//
//--------------------------------------------------------------------------
//-----------------------------------------------------------------------------
// Purpose: find the minima and maxima of the 3 given values
//-----------------------------------------------------------------------------
inline void FindMinMax( float v1, float v2, float v3, float &min, float &max )
{
min = max = v1;
if ( v2 < min ) { min = v2; }
if ( v2 > max ) { max = v2; }
if ( v3 < min ) { min = v3; }
if ( v3 > max ) { max = v3; }
}
//-----------------------------------------------------------------------------
// Purpose:
//-----------------------------------------------------------------------------
inline bool AxisTestEdgeCrossX2( float flEdgeZ, float flEdgeY, float flAbsEdgeZ, float flAbsEdgeY,
const Vector &p1, const Vector &p3, const Vector &vecExtents,
float flTolerance )
{
// Cross Product( axialX(1,0,0) x edge ): x = 0.0f, y = edge.z, z = -edge.y
// Triangle Point Distances: dist(x) = normal.y * pt(x).y + normal.z * pt(x).z
float flDist1 = flEdgeZ * p1.y - flEdgeY * p1.z;
float flDist3 = flEdgeZ * p3.y - flEdgeY * p3.z;
// Extents are symmetric: dist = abs( normal.y ) * extents.y + abs( normal.z ) * extents.z
float flDistBox = flAbsEdgeZ * vecExtents.y + flAbsEdgeY * vecExtents.z;
// Either dist1, dist3 is the closest point to the box, determine which and test of overlap with box(AABB).
if ( flDist1 < flDist3 )
{
if ( ( flDist1 > ( flDistBox + flTolerance ) ) || ( flDist3 < -( flDistBox + flTolerance ) ) )
return false;
}
else
{
if ( ( flDist3 > ( flDistBox + flTolerance ) ) || ( flDist1 < -( flDistBox + flTolerance ) ) )
return false;
}
return true;
}
//--------------------------------------------------------------------------
// Purpose:
//--------------------------------------------------------------------------
inline bool AxisTestEdgeCrossX3( float flEdgeZ, float flEdgeY, float flAbsEdgeZ, float flAbsEdgeY,
const Vector &p1, const Vector &p2, const Vector &vecExtents,
float flTolerance )
{
// Cross Product( axialX(1,0,0) x edge ): x = 0.0f, y = edge.z, z = -edge.y
// Triangle Point Distances: dist(x) = normal.y * pt(x).y + normal.z * pt(x).z
float flDist1 = flEdgeZ * p1.y - flEdgeY * p1.z;
float flDist2 = flEdgeZ * p2.y - flEdgeY * p2.z;
// Extents are symmetric: dist = abs( normal.y ) * extents.y + abs( normal.z ) * extents.z
float flDistBox = flAbsEdgeZ * vecExtents.y + flAbsEdgeY * vecExtents.z;
// Either dist1, dist2 is the closest point to the box, determine which and test of overlap with box(AABB).
if ( flDist1 < flDist2 )
{
if ( ( flDist1 > ( flDistBox + flTolerance ) ) || ( flDist2 < -( flDistBox + flTolerance ) ) )
return false;
}
else
{
if ( ( flDist2 > ( flDistBox + flTolerance ) ) || ( flDist1 < -( flDistBox + flTolerance ) ) )
return false;
}
return true;
}
//--------------------------------------------------------------------------
//--------------------------------------------------------------------------
inline bool AxisTestEdgeCrossY2( float flEdgeZ, float flEdgeX, float flAbsEdgeZ, float flAbsEdgeX,
const Vector &p1, const Vector &p3, const Vector &vecExtents,
float flTolerance )
{
// Cross Product( axialY(0,1,0) x edge ): x = -edge.z, y = 0.0f, z = edge.x
// Triangle Point Distances: dist(x) = normal.x * pt(x).x + normal.z * pt(x).z
float flDist1 = -flEdgeZ * p1.x + flEdgeX * p1.z;
float flDist3 = -flEdgeZ * p3.x + flEdgeX * p3.z;
// Extents are symmetric: dist = abs( normal.x ) * extents.x + abs( normal.z ) * extents.z
float flDistBox = flAbsEdgeZ * vecExtents.x + flAbsEdgeX * vecExtents.z;
// Either dist1, dist3 is the closest point to the box, determine which and test of overlap with box(AABB).
if ( flDist1 < flDist3 )
{
if ( ( flDist1 > ( flDistBox + flTolerance ) ) || ( flDist3 < -( flDistBox + flTolerance ) ) )
return false;
}
else
{
if ( ( flDist3 > ( flDistBox + flTolerance ) ) || ( flDist1 < -( flDistBox + flTolerance ) ) )
return false;
}
return true;
}
//--------------------------------------------------------------------------
//--------------------------------------------------------------------------
inline bool AxisTestEdgeCrossY3( float flEdgeZ, float flEdgeX, float flAbsEdgeZ, float flAbsEdgeX,
const Vector &p1, const Vector &p2, const Vector &vecExtents,
float flTolerance )
{
// Cross Product( axialY(0,1,0) x edge ): x = -edge.z, y = 0.0f, z = edge.x
// Triangle Point Distances: dist(x) = normal.x * pt(x).x + normal.z * pt(x).z
float flDist1 = -flEdgeZ * p1.x + flEdgeX * p1.z;
float flDist2 = -flEdgeZ * p2.x + flEdgeX * p2.z;
// Extents are symmetric: dist = abs( normal.x ) * extents.x + abs( normal.z ) * extents.z
float flDistBox = flAbsEdgeZ * vecExtents.x + flAbsEdgeX * vecExtents.z;
// Either dist1, dist2 is the closest point to the box, determine which and test of overlap with box(AABB).
if ( flDist1 < flDist2 )
{
if ( ( flDist1 > ( flDistBox + flTolerance ) ) || ( flDist2 < -( flDistBox + flTolerance ) ) )
return false;
}
else
{
if ( ( flDist2 > ( flDistBox + flTolerance ) ) || ( flDist1 < -( flDistBox + flTolerance ) ) )
return false;
}
return true;
}
//--------------------------------------------------------------------------
//--------------------------------------------------------------------------
inline bool AxisTestEdgeCrossZ1( float flEdgeY, float flEdgeX, float flAbsEdgeY, float flAbsEdgeX,
const Vector &p2, const Vector &p3, const Vector &vecExtents,
float flTolerance )
{
// Cross Product( axialZ(0,0,1) x edge ): x = edge.y, y = -edge.x, z = 0.0f
// Triangle Point Distances: dist(x) = normal.x * pt(x).x + normal.y * pt(x).y
float flDist2 = flEdgeY * p2.x - flEdgeX * p2.y;
float flDist3 = flEdgeY * p3.x - flEdgeX * p3.y;
// Extents are symmetric: dist = abs( normal.x ) * extents.x + abs( normal.y ) * extents.y
float flDistBox = flAbsEdgeY * vecExtents.x + flAbsEdgeX * vecExtents.y;
// Either dist2, dist3 is the closest point to the box, determine which and test of overlap with box(AABB).
if ( flDist3 < flDist2 )
{
if ( ( flDist3 > ( flDistBox + flTolerance ) ) || ( flDist2 < -( flDistBox + flTolerance ) ) )
return false;
}
else
{
if ( ( flDist2 > ( flDistBox + flTolerance ) ) || ( flDist3 < -( flDistBox + flTolerance ) ) )
return false;
}
return true;
}
//--------------------------------------------------------------------------
//--------------------------------------------------------------------------
inline bool AxisTestEdgeCrossZ2( float flEdgeY, float flEdgeX, float flAbsEdgeY, float flAbsEdgeX,
const Vector &p1, const Vector &p3, const Vector &vecExtents,
float flTolerance )
{
// Cross Product( axialZ(0,0,1) x edge ): x = edge.y, y = -edge.x, z = 0.0f
// Triangle Point Distances: dist(x) = normal.x * pt(x).x + normal.y * pt(x).y
float flDist1 = flEdgeY * p1.x - flEdgeX * p1.y;
float flDist3 = flEdgeY * p3.x - flEdgeX * p3.y;
// Extents are symmetric: dist = abs( normal.x ) * extents.x + abs( normal.y ) * extents.y
float flDistBox = flAbsEdgeY * vecExtents.x + flAbsEdgeX * vecExtents.y;
// Either dist1, dist3 is the closest point to the box, determine which and test of overlap with box(AABB).
if ( flDist1 < flDist3 )
{
if ( ( flDist1 > ( flDistBox + flTolerance ) ) || ( flDist3 < -( flDistBox + flTolerance ) ) )
return false;
}
else
{
if ( ( flDist3 > ( flDistBox + flTolerance ) ) || ( flDist1 < -( flDistBox + flTolerance ) ) )
return false;
}
return true;
}
//-----------------------------------------------------------------------------
// Purpose: Test for an intersection (overlap) between an axial-aligned bounding
// box (AABB) and a triangle.
//
// Using the "Separating-Axis Theorem" to test for intersections between
// a triangle and an axial-aligned bounding box (AABB).
// 1. 3 Axis Planes - x, y, z
// 2. 9 Edge Planes Tests - the 3 edges of the triangle crossed with all 3 axial
// planes (x, y, z)
// 3. 1 Face Plane - the triangle plane (cplane_t plane below)
// Output: false = separating axis (no intersection)
// true = intersection
//-----------------------------------------------------------------------------
bool IsBoxIntersectingTriangle( const Vector &vecBoxCenter, const Vector &vecBoxExtents,
const Vector &v1, const Vector &v2, const Vector &v3,
const cplane_t &plane, float flTolerance )
{
// Test the axial planes (x,y,z) against the min, max of the triangle.
float flMin, flMax;
Vector p1, p2, p3;
// x plane
p1.x = v1.x - vecBoxCenter.x;
p2.x = v2.x - vecBoxCenter.x;
p3.x = v3.x - vecBoxCenter.x;
FindMinMax( p1.x, p2.x, p3.x, flMin, flMax );
if ( ( flMin > ( vecBoxExtents.x + flTolerance ) ) || ( flMax < -( vecBoxExtents.x + flTolerance ) ) )
return false;
// y plane
p1.y = v1.y - vecBoxCenter.y;
p2.y = v2.y - vecBoxCenter.y;
p3.y = v3.y - vecBoxCenter.y;
FindMinMax( p1.y, p2.y, p3.y, flMin, flMax );
if ( ( flMin > ( vecBoxExtents.y + flTolerance ) ) || ( flMax < -( vecBoxExtents.y + flTolerance ) ) )
return false;
// z plane
p1.z = v1.z - vecBoxCenter.z;
p2.z = v2.z - vecBoxCenter.z;
p3.z = v3.z - vecBoxCenter.z;
FindMinMax( p1.z, p2.z, p3.z, flMin, flMax );
if ( ( flMin > ( vecBoxExtents.z + flTolerance ) ) || ( flMax < -( vecBoxExtents.z + flTolerance ) ) )
return false;
// Test the 9 edge cases.
Vector vecEdge, vecAbsEdge;
// edge 0 (cross x,y,z)
vecEdge = p2 - p1;
vecAbsEdge.y = FloatMakePositive( vecEdge.y );
vecAbsEdge.z = FloatMakePositive( vecEdge.z );
if ( !AxisTestEdgeCrossX2( vecEdge.z, vecEdge.y, vecAbsEdge.z, vecAbsEdge.y, p1, p3, vecBoxExtents, flTolerance ) )
return false;
vecAbsEdge.x = FloatMakePositive( vecEdge.x );
if ( !AxisTestEdgeCrossY2( vecEdge.z, vecEdge.x, vecAbsEdge.z, vecAbsEdge.x, p1, p3, vecBoxExtents, flTolerance ) )
return false;
if ( !AxisTestEdgeCrossZ1( vecEdge.y, vecEdge.x, vecAbsEdge.y, vecAbsEdge.x, p2, p3, vecBoxExtents, flTolerance ) )
return false;
// edge 1 (cross x,y,z)
vecEdge = p3 - p2;
vecAbsEdge.y = FloatMakePositive( vecEdge.y );
vecAbsEdge.z = FloatMakePositive( vecEdge.z );
if ( !AxisTestEdgeCrossX2( vecEdge.z, vecEdge.y, vecAbsEdge.z, vecAbsEdge.y, p1, p2, vecBoxExtents, flTolerance ) )
return false;
vecAbsEdge.x = FloatMakePositive( vecEdge.x );
if ( !AxisTestEdgeCrossY2( vecEdge.z, vecEdge.x, vecAbsEdge.z, vecAbsEdge.x, p1, p2, vecBoxExtents, flTolerance ) )
return false;
if ( !AxisTestEdgeCrossZ2( vecEdge.y, vecEdge.x, vecAbsEdge.y, vecAbsEdge.x, p1, p3, vecBoxExtents, flTolerance ) )
return false;
// edge 2 (cross x,y,z)
vecEdge = p1 - p3;
vecAbsEdge.y = FloatMakePositive( vecEdge.y );
vecAbsEdge.z = FloatMakePositive( vecEdge.z );
if ( !AxisTestEdgeCrossX3( vecEdge.z, vecEdge.y, vecAbsEdge.z, vecAbsEdge.y, p1, p2, vecBoxExtents, flTolerance ) )
return false;
vecAbsEdge.x = FloatMakePositive( vecEdge.x );
if ( !AxisTestEdgeCrossY3( vecEdge.z, vecEdge.x, vecAbsEdge.z, vecAbsEdge.x, p1, p2, vecBoxExtents, flTolerance ) )
return false;
if ( !AxisTestEdgeCrossZ1( vecEdge.y, vecEdge.x, vecAbsEdge.y, vecAbsEdge.x, p2, p3, vecBoxExtents, flTolerance ) )
return false;
// Test against the triangle face plane.
Vector vecMin, vecMax;
VectorSubtract( vecBoxCenter, vecBoxExtents, vecMin );
VectorAdd( vecBoxCenter, vecBoxExtents, vecMax );
if ( BoxOnPlaneSide( vecMin, vecMax, &plane ) != 3 )
return false;
return true;
}
// NOTE: JAY: This is untested code based on Real-time Collision Detection by Ericson
#if 0
Vector CalcClosestPointOnTriangle( const Vector &P, const Vector &v0, const Vector &v1, const Vector &v2 )
{
Vector e0 = v1 - v0;
Vector e1 = v2 - v0;
Vector p0 = P - v0;
// voronoi region of v0
float d1 = DotProduct( e0, p0 );
float d2 = DotProduct( e1, p0 );
if (d1 <= 0.0f && d2 <= 0.0f)
return v0;
// voronoi region of v1
Vector p1 = P - v1;
float d3 = DotProduct( e0, p1 );
float d4 = DotProduct( e1, p1 );
if (d3 >=0.0f && d4 <= d3)
return v1;
// voronoi region of e0 (v0-v1)
float ve2 = d1*d4 - d3*d2;
if ( ve2 <= 0.0f && d1 >= 0.0f && d3 <= 0.0f )
{
float v = d1 / (d1-d3);
return v0 + v * e0;
}
// voronoi region of v2
Vector p2 = P - v2;
float d5 = DotProduct( e0, p2 );
float d6 = DotProduct( e1, p2 );
if (d6 >= 0.0f && d5 <= d6)
return v2;
// voronoi region of e1
float ve1 = d5*d2 - d1*d6;
if (ve1 <= 0.0f && d2 >= 0.0f && d6 >= 0.0f)
{
float w = d2 / (d2-d6);
return v0 + w * e1;
}
// voronoi region on e2
float ve0 = d3*d6 - d5*d4;
if ( ve0 <= 0.0f && (d4-d3) >= 0.0f && (d5-d6) >= 0.0f )
{
float w = (d4-d3)/((d4-d3) + (d5-d6));
return v1 + w * (v2-v1);
}
// voronoi region of v0v1v2 triangle
float denom = 1.0f / (ve0+ve1+ve2);
float v = ve1*denom;
float w = ve2 * denom;
return v0 + e0 * v + e1 * w;
}
#endif
bool OBBHasFullyContainedIntersectionWithQuad( const Vector &vOBBExtent1_Scaled, const Vector &vOBBExtent2_Scaled, const Vector &vOBBExtent3_Scaled, const Vector &ptOBBCenter,
const Vector &vQuadNormal, float fQuadPlaneDist, const Vector &ptQuadCenter,
const Vector &vQuadExtent1_Normalized, float fQuadExtent1Length,
const Vector &vQuadExtent2_Normalized, float fQuadExtent2Length )
{
Vector ptOBB[8]; //this specific ordering helps us web out from a point to its 3 connecting points with some bit math (most importantly, no if's)
ptOBB[0] = ptOBBCenter - vOBBExtent1_Scaled - vOBBExtent2_Scaled - vOBBExtent3_Scaled;
ptOBB[1] = ptOBBCenter - vOBBExtent1_Scaled - vOBBExtent2_Scaled + vOBBExtent3_Scaled;
ptOBB[2] = ptOBBCenter - vOBBExtent1_Scaled + vOBBExtent2_Scaled + vOBBExtent3_Scaled;
ptOBB[3] = ptOBBCenter - vOBBExtent1_Scaled + vOBBExtent2_Scaled - vOBBExtent3_Scaled;
ptOBB[4] = ptOBBCenter + vOBBExtent1_Scaled - vOBBExtent2_Scaled - vOBBExtent3_Scaled;
ptOBB[5] = ptOBBCenter + vOBBExtent1_Scaled - vOBBExtent2_Scaled + vOBBExtent3_Scaled;
ptOBB[6] = ptOBBCenter + vOBBExtent1_Scaled + vOBBExtent2_Scaled + vOBBExtent3_Scaled;
ptOBB[7] = ptOBBCenter + vOBBExtent1_Scaled + vOBBExtent2_Scaled - vOBBExtent3_Scaled;
float fDists[8];
for( int i = 0; i != 8; ++i )
fDists[i] = vQuadNormal.Dot( ptOBB[i] ) - fQuadPlaneDist;
int iSides[8];
int iSideMask = 0;
for( int i = 0; i != 8; ++i )
{
if( fDists[i] > 0.0f )
{
iSides[i] = 1;
iSideMask |= 1;
}
else
{
iSides[i] = 2;
iSideMask |= 2;
}
}
if( iSideMask != 3 ) //points reside entirely on one side of the quad's plane
return false;
Vector ptPlaneIntersections[12]; //only have 12 lines, can only possibly generate 12 split points
int iPlaneIntersectionsCount = 0;
for( int i = 0; i != 8; ++i )
{
if( iSides[i] == 2 ) //point behind the plane
{
int iAxisCrossings[3];
iAxisCrossings[0] = i ^ 4; //upper 4 vs lower 4 crosses vOBBExtent1 axis
iAxisCrossings[1] = ((i + 1) & 3) + (i & 4); //cycle to the next element while staying within the upper 4 or lower 4, this will cross either vOBBExtent2 or vOBBExtent3 axis, we don't care which
iAxisCrossings[2] = ((i - 1) & 3) + (i & 4); //cylce to the previous element while staying within the upper 4 or lower 4, this will cross the axis iAxisCrossings[1] didn't cross
for( int j = 0; j != 3; ++j )
{
if( iSides[iAxisCrossings[j]] == 1 ) //point in front of the plane
{
//line between ptOBB[i] and ptOBB[iAxisCrossings[j]] intersects the plane, generate a point at the intersection for further testing
float fTotalDist = fDists[iAxisCrossings[j]] - fDists[i]; //remember that fDists[i] is a negative value
ptPlaneIntersections[iPlaneIntersectionsCount] = (ptOBB[iAxisCrossings[j]] * (-fDists[i]/fTotalDist)) + (ptOBB[i] * (fDists[iAxisCrossings[j]]/fTotalDist));
Assert( fabs( ptPlaneIntersections[iPlaneIntersectionsCount].Dot( vQuadNormal ) - fQuadPlaneDist ) < 0.1f ); //intersection point is on plane
++iPlaneIntersectionsCount;
}
}
}
}
Assert( iPlaneIntersectionsCount != 0 );
for( int i = 0; i != iPlaneIntersectionsCount; ++i )
{
//these points are guaranteed to be on the plane, now just check to see if they're within the quad's extents
Vector vToPointFromQuadCenter = ptPlaneIntersections[i] - ptQuadCenter;
float fExt1Dist = vQuadExtent1_Normalized.Dot( vToPointFromQuadCenter );
if( fabs( fExt1Dist ) > fQuadExtent1Length )
return false; //point is outside boundaries
//vToPointFromQuadCenter -= vQuadExtent1_Normalized * fExt1Dist; //to handle diamond shaped quads
float fExt2Dist = vQuadExtent2_Normalized.Dot( vToPointFromQuadCenter );
if( fabs( fExt2Dist ) > fQuadExtent2Length )
return false; //point is outside boundaries
}
return true; //there were lines crossing the quad plane, and every line crossing that plane had its intersection with the plane within the quad's boundaries
}
//-----------------------------------------------------------------------------
// Compute if the Ray intersects the quad plane, and whether the entire
// Ray/Quad intersection is contained within the quad itself
//
// False if no intersection exists, or if part of the intersection is
// outside the quad's extents
//-----------------------------------------------------------------------------
bool RayHasFullyContainedIntersectionWithQuad( const Ray_t &ray,
const Vector &vQuadNormal, float fQuadPlaneDist, const Vector &ptQuadCenter,
const Vector &vQuadExtent1_Normalized, float fQuadExtent1Length,
const Vector &vQuadExtent2_Normalized, float fQuadExtent2Length )
{
Vector ptPlaneIntersections[(12 + 12 + 8)]; //absolute max possible: 12 lines to connect the start box, 12 more to connect the end box, 8 to connect the boxes to eachother
//8 points to make an AABB, 8 lines to connect each point from it's start to end point along the ray, 8 possible intersections
int iPlaneIntersectionsCount = 0;
if( ray.m_IsRay )
{
//just 1 line
if( ray.m_IsSwept )
{
Vector ptEndPoints[2];
ptEndPoints[0] = ray.m_Start;
ptEndPoints[1] = ptEndPoints[0] + ray.m_Delta;
int i;
float fDists[2];
for( i = 0; i != 2; ++i )
fDists[i] = vQuadNormal.Dot( ptEndPoints[i] ) - fQuadPlaneDist;
for( i = 0; i != 2; ++i )
{
if( fDists[i] <= 0.0f )
{
int j = 1-i;
if( fDists[j] >= 0.0f )
{
float fInvTotalDist = 1.0f / (fDists[j] - fDists[i]); //fDists[i] <= 0, ray is swept so no chance that the denom was 0
ptPlaneIntersections[0] = (ptEndPoints[i] * (fDists[j] * fInvTotalDist)) - (ptEndPoints[j] * (fDists[i] * fInvTotalDist)); //fDists[i] <= 0
Assert( fabs( ptPlaneIntersections[iPlaneIntersectionsCount].Dot( vQuadNormal ) - fQuadPlaneDist ) < 0.1f ); //intersection point is on plane
iPlaneIntersectionsCount = 1;
}
else
{
return false;
}
break;
}
}
if( i == 2 )
return false;
}
else //not swept, so this is actually a point on quad question
{
if( fabs( vQuadNormal.Dot( ray.m_Start ) - fQuadPlaneDist ) < 1e-6 )
{
ptPlaneIntersections[0] = ray.m_Start;
iPlaneIntersectionsCount = 1;
}
else
{
return false;
}
}
}
else
{
Vector ptEndPoints[2][8];
//this specific ordering helps us web out from a point to its 3 connecting points with some bit math (most importantly, no if's)
ptEndPoints[0][0] = ray.m_Start; ptEndPoints[0][0].x -= ray.m_Extents.x; ptEndPoints[0][0].y -= ray.m_Extents.y; ptEndPoints[0][0].z -= ray.m_Extents.z;
ptEndPoints[0][1] = ray.m_Start; ptEndPoints[0][1].x -= ray.m_Extents.x; ptEndPoints[0][1].y -= ray.m_Extents.y; ptEndPoints[0][1].z += ray.m_Extents.z;
ptEndPoints[0][2] = ray.m_Start; ptEndPoints[0][2].x -= ray.m_Extents.x; ptEndPoints[0][2].y += ray.m_Extents.y; ptEndPoints[0][2].z += ray.m_Extents.z;
ptEndPoints[0][3] = ray.m_Start; ptEndPoints[0][3].x -= ray.m_Extents.x; ptEndPoints[0][3].y += ray.m_Extents.y; ptEndPoints[0][3].z -= ray.m_Extents.z;
ptEndPoints[0][4] = ray.m_Start; ptEndPoints[0][4].x += ray.m_Extents.x; ptEndPoints[0][4].y -= ray.m_Extents.y; ptEndPoints[0][4].z -= ray.m_Extents.z;
ptEndPoints[0][5] = ray.m_Start; ptEndPoints[0][5].x += ray.m_Extents.x; ptEndPoints[0][5].y -= ray.m_Extents.y; ptEndPoints[0][5].z += ray.m_Extents.z;
ptEndPoints[0][6] = ray.m_Start; ptEndPoints[0][6].x += ray.m_Extents.x; ptEndPoints[0][6].y += ray.m_Extents.y; ptEndPoints[0][6].z += ray.m_Extents.z;
ptEndPoints[0][7] = ray.m_Start; ptEndPoints[0][7].x += ray.m_Extents.x; ptEndPoints[0][7].y += ray.m_Extents.y; ptEndPoints[0][7].z -= ray.m_Extents.z;
float fDists[2][8];
int iSides[2][8];
int iSideMask[2] = { 0, 0 };
for( int i = 0; i != 8; ++i )
{
fDists[0][i] = vQuadNormal.Dot( ptEndPoints[0][i] ) - fQuadPlaneDist;
if( fDists[0][i] > 0.0f )
{
iSides[0][i] = 1;
iSideMask[0] |= 1;
}
else
{
iSides[0][i] = 2;
iSideMask[0] |= 2;
}
}
if( ray.m_IsSwept )
{
for( int i = 0; i != 8; ++i )
ptEndPoints[1][i] = ptEndPoints[0][i] + ray.m_Delta;
for( int i = 0; i != 8; ++i )
{
fDists[1][i] = vQuadNormal.Dot( ptEndPoints[1][i] ) - fQuadPlaneDist;
if( fDists[1][i] > 0.0f )
{
iSides[1][i] = 1;
iSideMask[1] |= 1;
}
else
{
iSides[1][i] = 2;
iSideMask[1] |= 2;
}
}
}
if( (iSideMask[0] | iSideMask[1]) != 3 )
{
//Assert( (iSideMask[0] | iSideMask[1]) != 2 );
return false; //all points resides entirely on one side of the quad
}
//generate intersections for boxes split by the plane at either end of the ray
for( int k = 0; k != 2; ++k )
{
if( iSideMask[k] == 3 ) //box is split by the plane
{
for( int i = 0; i != 8; ++i )
{
if( iSides[k][i] == 2 ) //point behind the plane
{
int iAxisCrossings[3];
iAxisCrossings[0] = i ^ 4; //upper 4 vs lower 4 crosses X axis
iAxisCrossings[1] = ((i + 1) & 3) + (i & 4); //cycle to the next element while staying within the upper 4 or lower 4, this will cross either Y or Z axis, we don't care which
iAxisCrossings[2] = ((i - 1) & 3) + (i & 4); //cylce to the previous element while staying within the upper 4 or lower 4, this will cross the axis iAxisCrossings[1] didn't cross
for( int j = 0; j != 3; ++j )
{
if( iSides[k][iAxisCrossings[j]] == 1 ) //point in front of the plane
{
//line between ptEndPoints[i] and ptEndPoints[iAxisCrossings[j]] intersects the plane, generate a point at the intersection for further testing
float fInvTotalDist = 1.0f / (fDists[k][iAxisCrossings[j]] - fDists[k][i]); //remember that fDists[k][i] is a negative value
ptPlaneIntersections[iPlaneIntersectionsCount] = (ptEndPoints[k][iAxisCrossings[j]] * (-fDists[k][i] * fInvTotalDist)) + (ptEndPoints[k][i] * (fDists[k][iAxisCrossings[j]] * fInvTotalDist));
Assert( fabs( ptPlaneIntersections[iPlaneIntersectionsCount].Dot( vQuadNormal ) - fQuadPlaneDist ) < 0.1f ); //intersection point is on plane
++iPlaneIntersectionsCount;
}
}
}
}
}
}
if( ray.m_IsSwept )
{
for( int i = 0; i != 8; ++i )
{
if( iSides[0][i] != iSides[1][i] )
{
int iPosSide, iNegSide;
if( iSides[0][i] == 1 )
{
iPosSide = 0;
iNegSide = 1;
}
else
{
iPosSide = 1;
iNegSide = 0;
}
Assert( (fDists[iPosSide][i] >= 0.0f) && (fDists[iNegSide][i] <= 0.0f) );
float fInvTotalDist = 1.0f / (fDists[iPosSide][i] - fDists[iNegSide][i]); //remember that fDists[iNegSide][i] is a negative value
ptPlaneIntersections[iPlaneIntersectionsCount] = (ptEndPoints[iPosSide][i] * (-fDists[iNegSide][i] * fInvTotalDist)) + (ptEndPoints[iNegSide][i] * (fDists[iPosSide][i] * fInvTotalDist));
Assert( fabs( ptPlaneIntersections[iPlaneIntersectionsCount].Dot( vQuadNormal ) - fQuadPlaneDist ) < 0.1f ); //intersection point is on plane
++iPlaneIntersectionsCount;
}
}
}
}
//down here, we should simply have a collection of plane intersections, now we see if they reside within the quad
Assert( iPlaneIntersectionsCount != 0 );
for( int i = 0; i != iPlaneIntersectionsCount; ++i )
{
//these points are guaranteed to be on the plane, now just check to see if they're within the quad's extents
Vector vToPointFromQuadCenter = ptPlaneIntersections[i] - ptQuadCenter;
float fExt1Dist = vQuadExtent1_Normalized.Dot( vToPointFromQuadCenter );
if( fabs( fExt1Dist ) > fQuadExtent1Length )
return false; //point is outside boundaries
//vToPointFromQuadCenter -= vQuadExtent1_Normalized * fExt1Dist; //to handle diamond shaped quads
float fExt2Dist = vQuadExtent2_Normalized.Dot( vToPointFromQuadCenter );
if( fabs( fExt2Dist ) > fQuadExtent2Length )
return false; //point is outside boundaries
}
return true; //there were lines crossing the quad plane, and every line crossing that plane had its intersection with the plane within the quad's boundaries
}
//-----------------------------------------------------------------------------
// Purpose: override how single player rays hit the player
//-----------------------------------------------------------------------------
bool LineCircleIntersection(const Vector2D &center,
const float radius,
const Vector2D &vLinePt,
const Vector2D &vLineDir,
float *fIntersection1,
float *fIntersection2)
{
// Line = P + Vt
// Sphere = r (assume we've translated to origin)
// (P + Vt)^2 = r^2
// VVt^2 + 2PVt + (PP - r^2)
// Solve as quadratic: (-b +/- sqrt(b^2 - 4ac)) / 2a
// If (b^2 - 4ac) is < 0 there is no solution.
// If (b^2 - 4ac) is = 0 there is one solution
// If (b^2 - 4ac) is > 0 there are two solutions.
// Translate circle to origin.
const Vector2D P( vLinePt - center );
const float a = vLineDir.Dot(vLineDir);
const float b = 2.0f * P.Dot(vLineDir);
const float c = P.Dot(P) - (radius * radius);
const float insideSqr = b*b - 4*a*c;
// No solution - (b^2 - 4ac) is < 0
if( insideSqr < -1.0e-6f )
{
return false;
}
else
{
const float sqr = (float)FastSqrt(insideSqr);
const float denom = 1.0 / (2.0f * a);
const float t0 = (-b - sqr) * denom;
const float t1 = (-b + sqr) * denom;
// One solution - (b^2 - 4ac) is = 0
if( insideSqr < 1.0e-6f )
{
// a = 0 if the line direction is the zero vector, in which case,
// the line starts inside the circle but will never exit. We fudge
// it for this case and say it intersects at the origin of the line.
// Otherwise, the result is the smallest positive result
*fIntersection1 = *fIntersection2 = ( a == 0.0f ) ? 0.0f : ( t0 < 0 ? t1 : t0 );
Assert( !IS_NAN(*fIntersection1) );
// Started inside of the sphere (the only way we get one solution, unless
// the ray direction is the zero vector)
return c < 0;
}
// Two solutions - (b^2 - 4ac) is > 0
else
{
*fIntersection1 = t0;
*fIntersection2 = t1;
}
return true;
}
}
bool IntersectRayWithAACylinder( const Ray_t &ray,
const Vector &center, float radius, float height, CBaseTrace *pTrace )
{
Assert( ray.m_IsRay );
Collision_ClearTrace( ray.m_Start, ray.m_Delta, pTrace );
// First intersect the ray with the top + bottom planes
float halfHeight = height * 0.5;
// Handle parallel case
Vector vStart = ray.m_Start - center;
Vector vEnd = vStart + ray.m_Delta;
float flEnterFrac, flLeaveFrac;
if (FloatMakePositive(ray.m_Delta.z) < 1e-8)
{
if ( (vStart.z < -halfHeight) || (vStart.z > halfHeight) )
{
return false; // no hit
}
flEnterFrac = 0.0f; flLeaveFrac = 1.0f;
}
else
{
// Clip the ray to the top and bottom of box
flEnterFrac = IntersectRayWithAAPlane( vStart, vEnd, 2, 1, halfHeight);
flLeaveFrac = IntersectRayWithAAPlane( vStart, vEnd, 2, 1, -halfHeight);
if ( flLeaveFrac < flEnterFrac )
{
float temp = flLeaveFrac;
flLeaveFrac = flEnterFrac;
flEnterFrac = temp;
}
if ( flLeaveFrac < 0 || flEnterFrac > 1)
{
return false;
}
}
// Intersect with circle
float flCircleEnterFrac, flCircleLeaveFrac;
if ( !LineCircleIntersection( vec3_origin.AsVector2D(), radius,
vStart.AsVector2D(), ray.m_Delta.AsVector2D(), &flCircleEnterFrac, &flCircleLeaveFrac ) )
{
return false; // no hit
}
Assert( flCircleEnterFrac <= flCircleLeaveFrac );
if ( flCircleLeaveFrac < 0 || flCircleEnterFrac > 1)
{
return false;
}
if ( flEnterFrac < flCircleEnterFrac )
flEnterFrac = flCircleEnterFrac;
if ( flLeaveFrac > flCircleLeaveFrac )
flLeaveFrac = flCircleLeaveFrac;
if ( flLeaveFrac < flEnterFrac )
return false;
VectorMA( ray.m_Start, flEnterFrac , ray.m_Delta, pTrace->endpos );
pTrace->fraction = flEnterFrac;
pTrace->contents = CONTENTS_SOLID;
// Calculate the point on our center line where we're nearest the intersection point
Vector collisionCenter;
CalcClosestPointOnLineSegment( pTrace->endpos, center + Vector( 0, 0, halfHeight ), center - Vector( 0, 0, halfHeight ), collisionCenter );
// Our normal is the direction from that center point to the intersection point
pTrace->plane.normal = pTrace->endpos - collisionCenter;
VectorNormalize( pTrace->plane.normal );
return true;
}
#endif // !_STATIC_LINKED || _SHARED_LIB