1 files changed, 199 insertions, 0 deletions
diff --git a/libraries/ode-0.9\/contrib/dRay/dRay_CCylinder.cpp b/libraries/ode-0.9\/contrib/dRay/dRay_CCylinder.cpp
new file mode 100755
index 0000000..b9ea0c0
--- /dev/null
+++ b/libraries/ode-0.9\/contrib/dRay/dRay_CCylinder.cpp
@@ -0,0 +1,199 @@
+// Ripped from Magic Software
+#include "Include\dRay.h"
+#include "dxRay.h"
+int Find(const dVector3 Origin, dVector3 Direction, dReal Length, const dVector3 CCPos, const dMatrix3 CCRot, dReal CCRadius, dReal CCLength, dReal T[2]){
+        dVector3 U, V, W;
+        Decompose(CCRot, U, V, W);
+        dVector3 CCOrigin;
+        CCOrigin[0] = CCPos[0] - (W[0] * CCLength / 2);
+        CCOrigin[1] = CCPos[1] - (W[1] * CCLength / 2);
+        CCOrigin[2] = CCPos[2] - (W[2] * CCLength / 2);
+        CCOrigin[3] = CCPos[3] - (W[3] * CCLength / 2);
+        
+        dVector3 D;
+        D[0] = dDOT(U, Direction);
+        D[1] = dDOT(V, Direction);
+        D[2] = dDOT(W, Direction);
+        dReal DMag = Length;
+        dReal InvDMag = REAL(1.0) / DMag;
+        dVector3 Diff;
+        Diff[0] = Origin[0] - CCOrigin[0];
+        Diff[1] = Origin[1] - CCOrigin[1];
+        Diff[2] = Origin[2] - CCOrigin[2];
+        Diff[3] = Origin[3] - CCOrigin[3];
+        dVector3 P;
+        P[0] = dDOT(U, Diff);
+        P[1] = dDOT(V, Diff);
+        P[2] = dDOT(W, Diff);
+        dReal CCRadiusSq = CCRadius * CCRadius;
+        dReal Epsilon = 1e-12f;
+        if (dFabs(D[2]) >= REAL(1.0) - Epsilon){        // line is parallel to capsule axis
+                dReal Discr =  CCRadiusSq - P[0] * P[0] - P[1] * P[1];
+                if (Discr >= REAL(0.0)){
+            dReal Root = dSqrt(Discr);
+            T[0] = (-P[2] + Root) * InvDMag;
+            T[1] = (CCLength - P[2] + Root) * InvDMag;
+            return 2;
+        }
+        else return 0;
+        }
+        // test intersection with infinite cylinder
+    dReal A = D[0] * D[0] + D[1] * D[1];
+    dReal B = P[0] * D[0] + P[1] * D[1];
+    dReal C = P[0] * P[0] + P[1] * P[1] - CCRadiusSq;
+    dReal Discr = B * B - A * C;
+    if (Discr < REAL(0.0)){     // line does not intersect infinite cylinder
+        return 0;
+    }
+        int Count = 0;
+    if (Discr > REAL(0.0)){     // line intersects infinite cylinder in two places
+        dReal Root = dSqrt(Discr);
+        dReal Inv = REAL(1.0) / A;
+                dReal TTemp = (-B - Root) * Inv;
+        dReal Tmp = P[2] + TTemp * D[2];
+        if (REAL(0.0) <= Tmp && Tmp <= CCLength){
+                        T[Count++] = TTemp * InvDMag;
+                }
+                
+                
+        TTemp = (-B + Root) * Inv;
+        Tmp = P[2] + TTemp * D[2];
+        if (REAL(0.0) <= Tmp && Tmp <= CCLength){
+                        T[Count++] = TTemp * InvDMag;
+                }
+        if (Count == 2){        // line intersects capsule wall in two places
+            return 2;
+        }
+    }
+        else{   // line is tangent to infinite cylinder
+        dReal TTemp = -B / A;
+        dReal Tmp = P[2] + TTemp * D[2];
+        if (REAL(0.0) <= Tmp && Tmp <= CCLength){
+            T[0] = TTemp * InvDMag;
+            return 1;
+        }
+    }
+        // test intersection with bottom hemisphere
+    // fA = 1
+    B += P[2] * D[2];
+    C += P[2] * P[2];
+    Discr = B * B - C;
+    if (Discr > REAL(0.0)){
+        dReal Root = dSqrt(Discr);
+        dReal TTemp = -B - Root;
+        dReal Tmp = P[2] + TTemp * D[2];
+        if (Tmp <= REAL(0.0)){
+            T[Count++] = TTemp * InvDMag;
+            if (Count == 2){
+                return 2;
+                        }
+        }
+        TTemp = -B + Root;
+        Tmp = P[2] + TTemp * D[2];
+        if (Tmp <= REAL(0.0)){
+            T[Count++] = TTemp * InvDMag;
+            if (Count == 2){
+                return 2;
+                        }
+        }
+    }
+    else if (Discr == REAL(0.0)){
+        dReal TTemp = -B;
+        dReal Tmp = P[2] + TTemp * D[2];
+        if (Tmp <= REAL(0.0)){
+            T[Count++] = TTemp * InvDMag;
+            if (Count == 2){
+                return 2;
+                        }
+        }
+    }
+        // test intersection with top hemisphere
+    // fA = 1
+    B -= D[2] * CCLength;
+    C += CCLength * (CCLength - REAL(2.0) * P[2]);
+    Discr = B * B - C;
+    if (Discr > REAL(0.0)){
+        dReal Root = dSqrt(Discr);
+        dReal TTemp = -B - Root;
+        dReal Tmp = P[2] + TTemp * D[2];
+        if (Tmp >= CCLength){
+            T[Count++] = TTemp * InvDMag;
+            if (Count == 2){
+                return 2;
+                        }
+        }
+        TTemp = -B + Root;
+        Tmp = P[2] + TTemp * D[2];
+        if (Tmp >= CCLength){
+            T[Count++] = TTemp * InvDMag;
+            if (Count == 2){
+                return 2;
+                        }
+        }
+    }
+    else if (Discr == REAL(0.0)){
+        dReal TTemp = -B;
+        dReal Tmp = P[2] + TTemp * D[2];
+        if (Tmp >= CCLength){
+            T[Count++] = TTemp * InvDMag;
+            if (Count == 2){
+                return 2;
+                        }
+        }
+    }
+        return Count;
+}
+int dCollideCCR(dxGeom* RayGeom, dxGeom* CCGeom, int Flags, dContactGeom* Contacts, int Stride){
+        const dVector3& CCPos = *(const dVector3*)dGeomGetPosition(CCGeom);
+        const dMatrix3& CCRot = *(const dMatrix3*)dGeomGetRotation(CCGeom);
+        dReal CCRadius, CCLength;
+        dGeomCCylinderGetParams(CCGeom, &CCRadius, &CCLength);
+        dVector3 Origin, Direction;
+        dGeomRayGet(RayGeom, Origin, Direction);
+        dReal Length = dGeomRayGetLength(RayGeom);
+        dReal T[2];
+    int Count = Find(Origin, Direction, Length, CCPos, CCRot, CCRadius, CCLength, T);
+        int ContactCount = 0;
+        for (int i = 0; i < Count; i++){
+                if (T[i] >= 0.0){
+                        dContactGeom* Contact = CONTACT(Flags, Contacts, ContactCount, Stride);
+                        Contact->pos[0] = Origin[0] + T[i] * Direction[0] * Length;
+                        Contact->pos[1] = Origin[1] + T[i] * Direction[1] * Length;
+                        Contact->pos[2] = Origin[2] + T[i] * Direction[2] * Length;
+                        Contact->pos[3] = Origin[3] + T[i] * Direction[3] * Length;
+                        //Contact->normal = 0;
+                        Contact->depth = 0.0f;
+                        Contact->g1 = RayGeom;
+                        Contact->g2 = CCGeom;
+                        ContactCount++;
+                }
+        }
+    return ContactCount;
+}
+\ No newline at end of file

diff --git a/libraries/ode-0.9\/contrib/dRay/dRay_CCylinder.cpp b/libraries/ode-0.9\/contrib/dRay/dRay_CCylinder.cpp new file mode 100755 index 0000000..b9ea0c0 --- /dev/null +++ b/libraries/ode-0.9\/contrib/dRay/dRay_CCylinder.cpp
@@ -0,0 +1,199 @@
	1	// Ripped from Magic Software
	2
	3	#include "Include\dRay.h"
	4	#include "dxRay.h"
	5
	6	int Find(const dVector3 Origin, dVector3 Direction, dReal Length, const dVector3 CCPos, const dMatrix3 CCRot, dReal CCRadius, dReal CCLength, dReal T[2]){
	7	dVector3 U, V, W;
	8	Decompose(CCRot, U, V, W);
	9
	10	dVector3 CCOrigin;
	11	CCOrigin[0] = CCPos[0] - (W[0] * CCLength / 2);
	12	CCOrigin[1] = CCPos[1] - (W[1] * CCLength / 2);
	13	CCOrigin[2] = CCPos[2] - (W[2] * CCLength / 2);
	14	CCOrigin[3] = CCPos[3] - (W[3] * CCLength / 2);
	15
	16	dVector3 D;
	17	D[0] = dDOT(U, Direction);
	18	D[1] = dDOT(V, Direction);
	19	D[2] = dDOT(W, Direction);
	20
	21	dReal DMag = Length;
	22	dReal InvDMag = REAL(1.0) / DMag;
	23
	24	dVector3 Diff;
	25	Diff[0] = Origin[0] - CCOrigin[0];
	26	Diff[1] = Origin[1] - CCOrigin[1];
	27	Diff[2] = Origin[2] - CCOrigin[2];
	28	Diff[3] = Origin[3] - CCOrigin[3];
	29
	30	dVector3 P;
	31	P[0] = dDOT(U, Diff);
	32	P[1] = dDOT(V, Diff);
	33	P[2] = dDOT(W, Diff);
	34
	35	dReal CCRadiusSq = CCRadius * CCRadius;
	36
	37	dReal Epsilon = 1e-12f;
	38
	39	if (dFabs(D[2]) >= REAL(1.0) - Epsilon){ // line is parallel to capsule axis
	40	dReal Discr = CCRadiusSq - P[0] * P[0] - P[1] * P[1];
	41
	42	if (Discr >= REAL(0.0)){
	43	dReal Root = dSqrt(Discr);
	44	T[0] = (-P[2] + Root) * InvDMag;
	45	T[1] = (CCLength - P[2] + Root) * InvDMag;
	46	return 2;
	47	}
	48	else return 0;
	49	}
	50
	51	// test intersection with infinite cylinder
	52	dReal A = D[0] * D[0] + D[1] * D[1];
	53	dReal B = P[0] * D[0] + P[1] * D[1];
	54	dReal C = P[0] * P[0] + P[1] * P[1] - CCRadiusSq;
	55	dReal Discr = B * B - A * C;
	56	if (Discr < REAL(0.0)){ // line does not intersect infinite cylinder
	57	return 0;
	58	}
	59
	60	int Count = 0;
	61
	62	if (Discr > REAL(0.0)){ // line intersects infinite cylinder in two places
	63	dReal Root = dSqrt(Discr);
	64	dReal Inv = REAL(1.0) / A;
	65
	66	dReal TTemp = (-B - Root) * Inv;
	67
	68	dReal Tmp = P[2] + TTemp * D[2];
	69	if (REAL(0.0) <= Tmp && Tmp <= CCLength){
	70	T[Count++] = TTemp * InvDMag;
	71	}
	72
	73
	74	TTemp = (-B + Root) * Inv;
	75	Tmp = P[2] + TTemp * D[2];
	76	if (REAL(0.0) <= Tmp && Tmp <= CCLength){
	77	T[Count++] = TTemp * InvDMag;
	78	}
	79
	80	if (Count == 2){ // line intersects capsule wall in two places
	81	return 2;
	82	}
	83	}
	84	else{ // line is tangent to infinite cylinder
	85	dReal TTemp = -B / A;
	86	dReal Tmp = P[2] + TTemp * D[2];
	87	if (REAL(0.0) <= Tmp && Tmp <= CCLength){
	88	T[0] = TTemp * InvDMag;
	89	return 1;
	90	}
	91	}
	92
	93	// test intersection with bottom hemisphere
	94	// fA = 1
	95	B += P[2] * D[2];
	96	C += P[2] * P[2];
	97	Discr = B * B - C;
	98	if (Discr > REAL(0.0)){
	99	dReal Root = dSqrt(Discr);
	100	dReal TTemp = -B - Root;
	101	dReal Tmp = P[2] + TTemp * D[2];
	102	if (Tmp <= REAL(0.0)){
	103	T[Count++] = TTemp * InvDMag;
	104	if (Count == 2){
	105	return 2;
	106	}
	107	}
	108
	109	TTemp = -B + Root;
	110	Tmp = P[2] + TTemp * D[2];
	111	if (Tmp <= REAL(0.0)){
	112	T[Count++] = TTemp * InvDMag;
	113	if (Count == 2){
	114	return 2;
	115	}
	116	}
	117	}
	118	else if (Discr == REAL(0.0)){
	119	dReal TTemp = -B;
	120	dReal Tmp = P[2] + TTemp * D[2];
	121	if (Tmp <= REAL(0.0)){
	122	T[Count++] = TTemp * InvDMag;
	123	if (Count == 2){
	124	return 2;
	125	}
	126	}
	127	}
	128
	129	// test intersection with top hemisphere
	130	// fA = 1
	131	B -= D[2] * CCLength;
	132	C += CCLength * (CCLength - REAL(2.0) * P[2]);
	133
	134	Discr = B * B - C;
	135	if (Discr > REAL(0.0)){
	136	dReal Root = dSqrt(Discr);
	137	dReal TTemp = -B - Root;
	138	dReal Tmp = P[2] + TTemp * D[2];
	139	if (Tmp >= CCLength){
	140
	141	T[Count++] = TTemp * InvDMag;
	142	if (Count == 2){
	143	return 2;
	144	}
	145	}
	146
	147	TTemp = -B + Root;
	148	Tmp = P[2] + TTemp * D[2];
	149	if (Tmp >= CCLength){
	150	T[Count++] = TTemp * InvDMag;
	151	if (Count == 2){
	152	return 2;
	153	}
	154	}
	155	}
	156	else if (Discr == REAL(0.0)){
	157	dReal TTemp = -B;
	158	dReal Tmp = P[2] + TTemp * D[2];
	159	if (Tmp >= CCLength){
	160	T[Count++] = TTemp * InvDMag;
	161	if (Count == 2){
	162	return 2;
	163	}
	164	}
	165	}
	166	return Count;
	167	}
	168
	169	int dCollideCCR(dxGeom* RayGeom, dxGeom* CCGeom, int Flags, dContactGeom* Contacts, int Stride){
	170	const dVector3& CCPos = (const dVector3)dGeomGetPosition(CCGeom);
	171	const dMatrix3& CCRot = (const dMatrix3)dGeomGetRotation(CCGeom);
	172
	173	dReal CCRadius, CCLength;
	174	dGeomCCylinderGetParams(CCGeom, &CCRadius, &CCLength);
	175
	176	dVector3 Origin, Direction;
	177	dGeomRayGet(RayGeom, Origin, Direction);
	178	dReal Length = dGeomRayGetLength(RayGeom);
	179
	180	dReal T[2];
	181	int Count = Find(Origin, Direction, Length, CCPos, CCRot, CCRadius, CCLength, T);
	182	int ContactCount = 0;
	183	for (int i = 0; i < Count; i++){
	184	if (T[i] >= 0.0){
	185	dContactGeom* Contact = CONTACT(Flags, Contacts, ContactCount, Stride);
	186	Contact->pos[0] = Origin[0] + T[i] * Direction[0] * Length;
	187	Contact->pos[1] = Origin[1] + T[i] * Direction[1] * Length;
	188	Contact->pos[2] = Origin[2] + T[i] * Direction[2] * Length;
	189	Contact->pos[3] = Origin[3] + T[i] * Direction[3] * Length;
	190	//Contact->normal = 0;
	191	Contact->depth = 0.0f;
	192	Contact->g1 = RayGeom;
	193	Contact->g2 = CCGeom;
	194
	195	ContactCount++;
	196	}
	197	}
	198	return ContactCount;
	199	} \ No newline at end of file