* Applying Xantor's patch 0001089 - Added llRot2Angle, llRot2Axis,llAxisAngle2Rot. Re-implemented llRot2Euler, llEuler2Rot
Teravus Ovares
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80ea0b94b9
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2ae933a88b
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@ -53,6 +53,7 @@ Patches
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* lulurun
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* Melanie Thielker
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* John R Sohn(XenReborn)
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* Xantor
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LSL Devs
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@ -1044,9 +1044,9 @@ namespace OpenSim.Region.ScriptEngine.Common
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return m_LSL_Functions.llRot2Axis(rot);
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}
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public void llRot2Angle()
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public double llRot2Angle(LSL_Types.Quaternion rot)
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{
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m_LSL_Functions.llRot2Angle();
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return m_LSL_Functions.llRot2Angle(rot);
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}
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public double llAcos(double val)
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@ -283,6 +283,41 @@ namespace OpenSim.Region.ScriptEngine.Common
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}
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//Now we start getting into quaternions which means sin/cos, matrices and vectors. ckrinke
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// Xantor's new llRot2Euler
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public LSL_Types.Vector3 llRot2Euler(LSL_Types.Quaternion r)
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{
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m_host.AddScriptLPS(1);
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double x, y, z;
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double sqw = r.s*r.s;
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double sqx = r.x*r.x;
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double sqy = r.y*r.y;
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double sqz = r.z*r.z;
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double unit = sqx + sqy + sqz + sqw; // if normalised is one, otherwise is correction factor
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double test = r.x*r.y + r.z*r.s;
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if (test > 0.499 * unit) // singularity at north pole
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{
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x = 0;
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y = 2 * Math.Atan2(r.x, r.s);
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z = Math.PI/2;
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return new LSL_Types.Vector3(x, y, z);
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}
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if (test < -0.499 * unit) // singularity at south pole
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{
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x = 0;
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y = -2 * Math.Atan2(r.x,r.s);
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z = -Math.PI/2;
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return new LSL_Types.Vector3(x, y, z);
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}
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x = Math.Atan2(2 * r.x * r.s - 2 * r.y * r.z, -sqx + sqy - sqz + sqw);
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y = Math.Atan2(2*r.y*r.s-2*r.x*r.z , sqx - sqy - sqz + sqw);
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z = Math.Asin(2*test/unit);
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return new LSL_Types.Vector3(x, y, z);
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}
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// Old implementation of llRot2Euler
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/*
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public LSL_Types.Vector3 llRot2Euler(LSL_Types.Quaternion r)
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{
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m_host.AddScriptLPS(1);
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@ -301,7 +336,42 @@ namespace OpenSim.Region.ScriptEngine.Common
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else
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return new LSL_Types.Vector3(0.0, -Math.PI / 2, Math.Atan2((r.z * r.s + r.x * r.y), 0.5 - t.x - t.z));
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}
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*/
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// Xantor's new llEuler2Rot()
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/* From wiki:
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The Euler angle vector (in radians) is converted to a rotation by doing the rotations around the 3 axes
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in Z, Y, X order. So llEuler2Rot(<1.0, 2.0, 3.0> * DEG_TO_RAD) generates a rotation by taking the zero rotation,
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a vector pointing along the X axis, first rotating it 3 degrees around the global Z axis, then rotating the resulting
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vector 2 degrees around the global Y axis, and finally rotating that 1 degree around the global X axis.
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*/
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public LSL_Types.Quaternion llEuler2Rot(LSL_Types.Vector3 v)
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{
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m_host.AddScriptLPS(1);
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double x,y,z,s;
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double c1 = Math.Cos(v.y / 2);
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double s1 = Math.Sin(v.y / 2 );
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double c2 = Math.Cos(v.z / 2 );
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double s2 = Math.Sin(v.z / 2 );
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double c3 = Math.Cos(v.x / 2 );
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double s3 = Math.Sin(v.x / 2 );
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double c1c2 = c1 * c2;
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double s1s2 = s1 * s2;
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s = c1c2 * c3 - s1s2 * s3;
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x = c1c2 * s3 + s1s2 * c3;
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y = s1 * c2 * c3 + c1 * s2 * s3;
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z = c1 * s2 * c3 - s1 * c2 * s3;
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return new LSL_Types.Quaternion(x, y, z, s);
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}
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/*
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// Old implementation
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public LSL_Types.Quaternion llEuler2Rot(LSL_Types.Vector3 v)
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{
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m_host.AddScriptLPS(1);
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@ -338,6 +408,9 @@ namespace OpenSim.Region.ScriptEngine.Common
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return a;
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}
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*/
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public LSL_Types.Quaternion llAxes2Rot(LSL_Types.Vector3 fwd, LSL_Types.Vector3 left, LSL_Types.Vector3 up)
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{
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m_host.AddScriptLPS(1);
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@ -2721,24 +2794,115 @@ namespace OpenSim.Region.ScriptEngine.Common
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return 0;
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}
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/* The new / changed functions were tested with the following LSL script:
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default
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{
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state_entry()
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{
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rotation rot = llEuler2Rot(<0,70,0> * DEG_TO_RAD);
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llOwnerSay("to get here, we rotate over: "+ (string) llRot2Axis(rot) );
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llOwnerSay("and we rotate for: "+ (llRot2Angle(rot) * RAD_TO_DEG));
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// convert back and forth between quaternion <-> vector and angle
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rotation newrot = llAxisAngle2Rot(llRot2Axis(rot),llRot2Angle(rot));
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llOwnerSay("Old rotation was: "+(string) rot);
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llOwnerSay("re-converted rotation is: "+(string) newrot);
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llSetRot(rot); // to check the parameters in the prim
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}
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}
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*/
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// Xantor 29/apr/2008
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// Returns rotation described by rotating angle radians about axis.
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// q = cos(a/2) + i ( x * sin(a/2)) + j (y * sin(a/2)) + k ( z * sin(a/2))
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public LSL_Types.Quaternion llAxisAngle2Rot(LSL_Types.Vector3 axis, double angle)
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{
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m_host.AddScriptLPS(1);
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NotImplemented("llAxisAngle2Rot");
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return new LSL_Types.Quaternion();
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double x, y, z, s, t;
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s = Math.Cos(angle / 2);
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t = Math.Sin(angle / 2); // temp value to avoid 2 more sin() calcs
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x = axis.x * t;
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y = axis.y * t;
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z = axis.z * t;
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return new LSL_Types.Quaternion(x,y,z,s);
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// NotImplemented("llAxisAngle2Rot");
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}
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// Xantor 29/apr/2008
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// converts a Quaternion to X,Y,Z axis rotations
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public LSL_Types.Vector3 llRot2Axis(LSL_Types.Quaternion rot)
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{
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m_host.AddScriptLPS(1);
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NotImplemented("llRot2Axis");
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return new LSL_Types.Vector3();
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double x,y,z;
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if (rot.s > 1) // normalization needed
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{
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double length = Math.Sqrt(rot.x * rot.x + rot.y * rot.y +
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rot.z * rot.z + rot.s * rot.s);
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rot.x /= length;
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rot.y /= length;
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rot.z /= length;
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rot.s /= length;
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}
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double angle = 2 * Math.Acos(rot.s);
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double s = Math.Sqrt(1 - rot.s * rot.s);
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if (s < 0.001)
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{
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x = 1;
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y = z = 0;
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}
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else
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{
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x = rot.x / s; // normalise axis
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y = rot.y / s;
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z = rot.z / s;
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}
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return new LSL_Types.Vector3(x,y,z);
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// NotImplemented("llRot2Axis");
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}
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public void llRot2Angle()
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// Returns the angle of a quaternion (see llRot2Axis for the axis)
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public double llRot2Angle(LSL_Types.Quaternion rot)
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{
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m_host.AddScriptLPS(1);
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NotImplemented("llRot2Angle");
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if (rot.s > 1) // normalization needed
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{
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double length = Math.Sqrt(rot.x * rot.x + rot.y * rot.y +
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rot.z * rot.z + rot.s * rot.s);
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rot.x /= length;
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rot.y /= length;
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rot.z /= length;
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rot.s /= length;
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}
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double angle = 2 * Math.Acos(rot.s);
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return angle;
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// NotImplemented("llRot2Angle");
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}
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public double llAcos(double val)
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@ -323,7 +323,8 @@ namespace OpenSim.Region.ScriptEngine.Common
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LSL_Types.Quaternion llAxisAngle2Rot(LSL_Types.Vector3 axis, double angle);
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//wiki: vector llRot2Axis(rotation rot)
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LSL_Types.Vector3 llRot2Axis(LSL_Types.Quaternion rot);
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void llRot2Angle();
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//wiki: double llRot2Angle(rotation rot);
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double llRot2Angle(LSL_Types.Quaternion rot);
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//wiki: double llAcos(double val)
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double llAcos(double val);
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//wiki: double llAsin(double val)
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