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diff --git a/libs/ode-0.16.1/OPCODE/OPC_RayTriOverlap.h b/libs/ode-0.16.1/OPCODE/OPC_RayTriOverlap.h
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+#define LOCAL_EPSILON 0.000001f
+
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+/**
+ * Computes a ray-triangle intersection test.
+ * Original code from Tomas Möller's "Fast Minimum Storage Ray-Triangle Intersection".
+ * It's been optimized a bit with integer code, and modified to return a non-intersection if distance from
+ * ray origin to triangle is negative.
+ *
+ * \param vert0 [in] triangle vertex
+ * \param vert1 [in] triangle vertex
+ * \param vert2 [in] triangle vertex
+ * \return true on overlap. mStabbedFace is filled with relevant info.
+ */
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+inline_ BOOL RayCollider::RayTriOverlap(const Point& vert0, const Point& vert1, const Point& vert2)
+{
+ // Stats
+ mNbRayPrimTests++;
+
+ // Find vectors for two edges sharing vert0
+ Point edge1 = vert1 - vert0;
+ Point edge2 = vert2 - vert0;
+
+ // Begin calculating determinant - also used to calculate U parameter
+ Point pvec = mDir^edge2;
+
+ // If determinant is near zero, ray lies in plane of triangle
+ float det = edge1|pvec;
+
+ if(mCulling)
+ {
+ if(det <= LOCAL_EPSILON * FCMin2(edge1.SquareMagnitude(), edge2.SquareMagnitude())) return FALSE;
+ // From here, det is > 0. So we can use integer cmp.
+
+ // Calculate distance from vert0 to ray origin
+ Point tvec = mOrigin - vert0;
+
+ // Calculate U parameter and test bounds
+ mStabbedFace.mU = tvec|pvec;
+// if(IR(u)&0x80000000 || u>det) return FALSE;
+ if(IS_NEGATIVE_FLOAT(mStabbedFace.mU) || IR(mStabbedFace.mU)>IR(det)) return FALSE;
+
+ // Prepare to test V parameter
+ Point qvec = tvec^edge1;
+
+ // Calculate V parameter and test bounds
+ mStabbedFace.mV = mDir|qvec;
+ if(IS_NEGATIVE_FLOAT(mStabbedFace.mV) || mStabbedFace.mU+mStabbedFace.mV>det) return FALSE;
+
+ // Calculate t, scale parameters, ray intersects triangle
+ mStabbedFace.mDistance = edge2|qvec;
+ // Det > 0 so we can early exit here
+ // Intersection point is valid if distance is positive (else it can just be a face behind the orig point)
+ if(IS_NEGATIVE_FLOAT(mStabbedFace.mDistance)) return FALSE;
+ // Else go on
+ float OneOverDet = 1.0f / det;
+ mStabbedFace.mDistance *= OneOverDet;
+ mStabbedFace.mU *= OneOverDet;
+ mStabbedFace.mV *= OneOverDet;
+ }
+ else
+ {
+ // the non-culling branch
+ if(FastFabs(det) <= LOCAL_EPSILON * FCMin2(edge1.SquareMagnitude(), edge2.SquareMagnitude())) return FALSE;
+ float OneOverDet = 1.0f / det;
+
+ // Calculate distance from vert0 to ray origin
+ Point tvec = mOrigin - vert0;
+
+ // Calculate U parameter and test bounds
+ mStabbedFace.mU = (tvec|pvec) * OneOverDet;
+// if(IR(u)&0x80000000 || u>1.0f) return FALSE;
+ if(IS_NEGATIVE_FLOAT(mStabbedFace.mU) || IR(mStabbedFace.mU)>IEEE_1_0) return FALSE;
+
+ // prepare to test V parameter
+ Point qvec = tvec^edge1;
+
+ // Calculate V parameter and test bounds
+ mStabbedFace.mV = (mDir|qvec) * OneOverDet;
+ if(IS_NEGATIVE_FLOAT(mStabbedFace.mV) || mStabbedFace.mU+mStabbedFace.mV>1.0f) return FALSE;
+
+ // Calculate t, ray intersects triangle
+ mStabbedFace.mDistance = (edge2|qvec) * OneOverDet;
+ // Intersection point is valid if distance is positive (else it can just be a face behind the orig point)
+ if(IS_NEGATIVE_FLOAT(mStabbedFace.mDistance)) return FALSE;
+ }
+ return TRUE;
+}