using System; using System.Runtime.CompilerServices; using Unity.IL2CPP.CompilerServices; using static Unity.Mathematics.math; namespace Unity.Mathematics { /// /// A quaternion type for representing rotations. /// [Il2CppEagerStaticClassConstruction] [Serializable] public partial struct quaternion : System.IEquatable, IFormattable { /// /// The quaternion component values. /// public float4 value; /// A quaternion representing the identity transform. public static readonly quaternion identity = new quaternion(0.0f, 0.0f, 0.0f, 1.0f); /// Constructs a quaternion from four float values. /// The quaternion x component. /// The quaternion y component. /// The quaternion z component. /// The quaternion w component. [MethodImpl(MethodImplOptions.AggressiveInlining)] public quaternion(float x, float y, float z, float w) { value.x = x; value.y = y; value.z = z; value.w = w; } /// Constructs a quaternion from float4 vector. /// The quaternion xyzw component values. [MethodImpl(MethodImplOptions.AggressiveInlining)] public quaternion(float4 value) { this.value = value; } /// Implicitly converts a float4 vector to a quaternion. /// The quaternion xyzw component values. /// The quaternion constructed from a float4 vector. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static implicit operator quaternion(float4 v) { return new quaternion(v); } /// Constructs a unit quaternion from a float3x3 rotation matrix. The matrix must be orthonormal. /// The float3x3 orthonormal rotation matrix. public quaternion(float3x3 m) { float3 u = m.c0; float3 v = m.c1; float3 w = m.c2; uint u_sign = (asuint(u.x) & 0x80000000); float t = v.y + asfloat(asuint(w.z) ^ u_sign); uint4 u_mask = uint4((int)u_sign >> 31); uint4 t_mask = uint4(asint(t) >> 31); float tr = 1.0f + abs(u.x); uint4 sign_flips = uint4(0x00000000, 0x80000000, 0x80000000, 0x80000000) ^ (u_mask & uint4(0x00000000, 0x80000000, 0x00000000, 0x80000000)) ^ (t_mask & uint4(0x80000000, 0x80000000, 0x80000000, 0x00000000)); value = float4(tr, u.y, w.x, v.z) + asfloat(asuint(float4(t, v.x, u.z, w.y)) ^ sign_flips); // +---, +++-, ++-+, +-++ value = asfloat((asuint(value) & ~u_mask) | (asuint(value.zwxy) & u_mask)); value = asfloat((asuint(value.wzyx) & ~t_mask) | (asuint(value) & t_mask)); value = normalize(value); } /// Constructs a unit quaternion from an orthonormal float4x4 matrix. /// The float4x4 orthonormal rotation matrix. public quaternion(float4x4 m) { float4 u = m.c0; float4 v = m.c1; float4 w = m.c2; uint u_sign = (asuint(u.x) & 0x80000000); float t = v.y + asfloat(asuint(w.z) ^ u_sign); uint4 u_mask = uint4((int)u_sign >> 31); uint4 t_mask = uint4(asint(t) >> 31); float tr = 1.0f + abs(u.x); uint4 sign_flips = uint4(0x00000000, 0x80000000, 0x80000000, 0x80000000) ^ (u_mask & uint4(0x00000000, 0x80000000, 0x00000000, 0x80000000)) ^ (t_mask & uint4(0x80000000, 0x80000000, 0x80000000, 0x00000000)); value = float4(tr, u.y, w.x, v.z) + asfloat(asuint(float4(t, v.x, u.z, w.y)) ^ sign_flips); // +---, +++-, ++-+, +-++ value = asfloat((asuint(value) & ~u_mask) | (asuint(value.zwxy) & u_mask)); value = asfloat((asuint(value.wzyx) & ~t_mask) | (asuint(value) & t_mask)); value = normalize(value); } /// /// Returns a quaternion representing a rotation around a unit axis by an angle in radians. /// The rotation direction is clockwise when looking along the rotation axis towards the origin. /// /// The axis of rotation. /// The angle of rotation in radians. /// The quaternion representing a rotation around an axis. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion AxisAngle(float3 axis, float angle) { float sina, cosa; math.sincos(0.5f * angle, out sina, out cosa); return quaternion(float4(axis * sina, cosa)); } /// /// Returns a quaternion constructed by first performing a rotation around the x-axis, then the y-axis and finally the z-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The quaternion representing the Euler angle rotation in x-y-z order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerXYZ(float3 xyz) { // return mul(rotateZ(xyz.z), mul(rotateY(xyz.y), rotateX(xyz.x))); float3 s, c; sincos(0.5f * xyz, out s, out c); return quaternion( // s.x * c.y * c.z - s.y * s.z * c.x, // s.y * c.x * c.z + s.x * s.z * c.y, // s.z * c.x * c.y - s.x * s.y * c.z, // c.x * c.y * c.z + s.y * s.z * s.x float4(s.xyz, c.x) * c.yxxy * c.zzyz + s.yxxy * s.zzyz * float4(c.xyz, s.x) * float4(-1.0f, 1.0f, -1.0f, 1.0f) ); } /// /// Returns a quaternion constructed by first performing a rotation around the x-axis, then the z-axis and finally the y-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The quaternion representing the Euler angle rotation in x-z-y order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerXZY(float3 xyz) { // return mul(rotateY(xyz.y), mul(rotateZ(xyz.z), rotateX(xyz.x))); float3 s, c; sincos(0.5f * xyz, out s, out c); return quaternion( // s.x * c.y * c.z + s.y * s.z * c.x, // s.y * c.x * c.z + s.x * s.z * c.y, // s.z * c.x * c.y - s.x * s.y * c.z, // c.x * c.y * c.z - s.y * s.z * s.x float4(s.xyz, c.x) * c.yxxy * c.zzyz + s.yxxy * s.zzyz * float4(c.xyz, s.x) * float4(1.0f, 1.0f, -1.0f, -1.0f) ); } /// /// Returns a quaternion constructed by first performing a rotation around the y-axis, then the x-axis and finally the z-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The quaternion representing the Euler angle rotation in y-x-z order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerYXZ(float3 xyz) { // return mul(rotateZ(xyz.z), mul(rotateX(xyz.x), rotateY(xyz.y))); float3 s, c; sincos(0.5f * xyz, out s, out c); return quaternion( // s.x * c.y * c.z - s.y * s.z * c.x, // s.y * c.x * c.z + s.x * s.z * c.y, // s.z * c.x * c.y + s.x * s.y * c.z, // c.x * c.y * c.z - s.y * s.z * s.x float4(s.xyz, c.x) * c.yxxy * c.zzyz + s.yxxy * s.zzyz * float4(c.xyz, s.x) * float4(-1.0f, 1.0f, 1.0f, -1.0f) ); } /// /// Returns a quaternion constructed by first performing a rotation around the y-axis, then the z-axis and finally the x-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The quaternion representing the Euler angle rotation in y-z-x order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerYZX(float3 xyz) { // return mul(rotateX(xyz.x), mul(rotateZ(xyz.z), rotateY(xyz.y))); float3 s, c; sincos(0.5f * xyz, out s, out c); return quaternion( // s.x * c.y * c.z - s.y * s.z * c.x, // s.y * c.x * c.z - s.x * s.z * c.y, // s.z * c.x * c.y + s.x * s.y * c.z, // c.x * c.y * c.z + s.y * s.z * s.x float4(s.xyz, c.x) * c.yxxy * c.zzyz + s.yxxy * s.zzyz * float4(c.xyz, s.x) * float4(-1.0f, -1.0f, 1.0f, 1.0f) ); } /// /// Returns a quaternion constructed by first performing a rotation around the z-axis, then the x-axis and finally the y-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// This is the default order rotation order in Unity. /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The quaternion representing the Euler angle rotation in z-x-y order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerZXY(float3 xyz) { // return mul(rotateY(xyz.y), mul(rotateX(xyz.x), rotateZ(xyz.z))); float3 s, c; sincos(0.5f * xyz, out s, out c); return quaternion( // s.x * c.y * c.z + s.y * s.z * c.x, // s.y * c.x * c.z - s.x * s.z * c.y, // s.z * c.x * c.y - s.x * s.y * c.z, // c.x * c.y * c.z + s.y * s.z * s.x float4(s.xyz, c.x) * c.yxxy * c.zzyz + s.yxxy * s.zzyz * float4(c.xyz, s.x) * float4(1.0f, -1.0f, -1.0f, 1.0f) ); } /// /// Returns a quaternion constructed by first performing a rotation around the z-axis, then the y-axis and finally the x-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The quaternion representing the Euler angle rotation in z-y-x order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerZYX(float3 xyz) { // return mul(rotateX(xyz.x), mul(rotateY(xyz.y), rotateZ(xyz.z))); float3 s, c; sincos(0.5f * xyz, out s, out c); return quaternion( // s.x * c.y * c.z + s.y * s.z * c.x, // s.y * c.x * c.z - s.x * s.z * c.y, // s.z * c.x * c.y + s.x * s.y * c.z, // c.x * c.y * c.z - s.y * s.x * s.z float4(s.xyz, c.x) * c.yxxy * c.zzyz + s.yxxy * s.zzyz * float4(c.xyz, s.x) * float4(1.0f, -1.0f, 1.0f, -1.0f) ); } /// /// Returns a quaternion constructed by first performing a rotation around the x-axis, then the y-axis and finally the z-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The quaternion representing the Euler angle rotation in x-y-z order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerXYZ(float x, float y, float z) { return EulerXYZ(float3(x, y, z)); } /// /// Returns a quaternion constructed by first performing a rotation around the x-axis, then the z-axis and finally the y-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The quaternion representing the Euler angle rotation in x-z-y order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerXZY(float x, float y, float z) { return EulerXZY(float3(x, y, z)); } /// /// Returns a quaternion constructed by first performing a rotation around the y-axis, then the x-axis and finally the z-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The quaternion representing the Euler angle rotation in y-x-z order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerYXZ(float x, float y, float z) { return EulerYXZ(float3(x, y, z)); } /// /// Returns a quaternion constructed by first performing a rotation around the y-axis, then the z-axis and finally the x-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The quaternion representing the Euler angle rotation in y-z-x order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerYZX(float x, float y, float z) { return EulerYZX(float3(x, y, z)); } /// /// Returns a quaternion constructed by first performing a rotation around the z-axis, then the x-axis and finally the y-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// This is the default order rotation order in Unity. /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The quaternion representing the Euler angle rotation in z-x-y order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerZXY(float x, float y, float z) { return EulerZXY(float3(x, y, z)); } /// /// Returns a quaternion constructed by first performing a rotation around the z-axis, then the y-axis and finally the x-axis. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The quaternion representing the Euler angle rotation in z-y-x order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion EulerZYX(float x, float y, float z) { return EulerZYX(float3(x, y, z)); } /// /// Returns a quaternion constructed by first performing 3 rotations around the principal axes in a given order. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// When the rotation order is known at compile time, it is recommended for performance reasons to use specific /// Euler rotation constructors such as EulerZXY(...). /// /// A float3 vector containing the rotation angles around the x-, y- and z-axis measures in radians. /// The order in which the rotations are applied. /// The quaternion representing the Euler angle rotation in the specified order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion Euler(float3 xyz, RotationOrder order = RotationOrder.ZXY) { switch (order) { case RotationOrder.XYZ: return EulerXYZ(xyz); case RotationOrder.XZY: return EulerXZY(xyz); case RotationOrder.YXZ: return EulerYXZ(xyz); case RotationOrder.YZX: return EulerYZX(xyz); case RotationOrder.ZXY: return EulerZXY(xyz); case RotationOrder.ZYX: return EulerZYX(xyz); default: return quaternion.identity; } } /// /// Returns a quaternion constructed by first performing 3 rotations around the principal axes in a given order. /// All rotation angles are in radians and clockwise when looking along the rotation axis towards the origin. /// When the rotation order is known at compile time, it is recommended for performance reasons to use specific /// Euler rotation constructors such as EulerZXY(...). /// /// The rotation angle around the x-axis in radians. /// The rotation angle around the y-axis in radians. /// The rotation angle around the z-axis in radians. /// The order in which the rotations are applied. /// The quaternion representing the Euler angle rotation in the specified order. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion Euler(float x, float y, float z, RotationOrder order = RotationOrder.Default) { return Euler(float3(x, y, z), order); } /// Returns a quaternion that rotates around the x-axis by a given number of radians. /// The clockwise rotation angle when looking along the x-axis towards the origin in radians. /// The quaternion representing a rotation around the x-axis. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion RotateX(float angle) { float sina, cosa; math.sincos(0.5f * angle, out sina, out cosa); return quaternion(sina, 0.0f, 0.0f, cosa); } /// Returns a quaternion that rotates around the y-axis by a given number of radians. /// The clockwise rotation angle when looking along the y-axis towards the origin in radians. /// The quaternion representing a rotation around the y-axis. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion RotateY(float angle) { float sina, cosa; math.sincos(0.5f * angle, out sina, out cosa); return quaternion(0.0f, sina, 0.0f, cosa); } /// Returns a quaternion that rotates around the z-axis by a given number of radians. /// The clockwise rotation angle when looking along the z-axis towards the origin in radians. /// The quaternion representing a rotation around the z-axis. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion RotateZ(float angle) { float sina, cosa; math.sincos(0.5f * angle, out sina, out cosa); return quaternion(0.0f, 0.0f, sina, cosa); } /// /// Returns a quaternion view rotation given a unit length forward vector and a unit length up vector. /// The two input vectors are assumed to be unit length and not collinear. /// If these assumptions are not met use float3x3.LookRotationSafe instead. /// /// The view forward direction. /// The view up direction. /// The quaternion view rotation. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion LookRotation(float3 forward, float3 up) { float3 t = normalize(cross(up, forward)); return quaternion(float3x3(t, cross(forward, t), forward)); } /// /// Returns a quaternion view rotation given a forward vector and an up vector. /// The two input vectors are not assumed to be unit length. /// If the magnitude of either of the vectors is so extreme that the calculation cannot be carried out reliably or the vectors are collinear, /// the identity will be returned instead. /// /// The view forward direction. /// The view up direction. /// The quaternion view rotation or the identity quaternion. public static quaternion LookRotationSafe(float3 forward, float3 up) { float forwardLengthSq = dot(forward, forward); float upLengthSq = dot(up, up); forward *= rsqrt(forwardLengthSq); up *= rsqrt(upLengthSq); float3 t = cross(up, forward); float tLengthSq = dot(t, t); t *= rsqrt(tLengthSq); float mn = min(min(forwardLengthSq, upLengthSq), tLengthSq); float mx = max(max(forwardLengthSq, upLengthSq), tLengthSq); bool accept = mn > 1e-35f && mx < 1e35f && isfinite(forwardLengthSq) && isfinite(upLengthSq) && isfinite(tLengthSq); return quaternion(select(float4(0.0f, 0.0f, 0.0f, 1.0f), quaternion(float3x3(t, cross(forward, t),forward)).value, accept)); } /// Returns true if the quaternion is equal to a given quaternion, false otherwise. /// The quaternion to compare with. /// True if the quaternion is equal to the input, false otherwise. [MethodImpl(MethodImplOptions.AggressiveInlining)] public bool Equals(quaternion x) { return value.x == x.value.x && value.y == x.value.y && value.z == x.value.z && value.w == x.value.w; } /// Returns whether true if the quaternion is equal to a given quaternion, false otherwise. /// The object to compare with. /// True if the quaternion is equal to the input, false otherwise. [MethodImpl(MethodImplOptions.AggressiveInlining)] public override bool Equals(object x) { return x is quaternion converted && Equals(converted); } /// Returns a hash code for the quaternion. /// The hash code of the quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public override int GetHashCode() { return (int)math.hash(this); } /// Returns a string representation of the quaternion. /// The string representation of the quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public override string ToString() { return string.Format("quaternion({0}f, {1}f, {2}f, {3}f)", value.x, value.y, value.z, value.w); } /// Returns a string representation of the quaternion using a specified format and culture-specific format information. /// The format string. /// The format provider to use during string formatting. /// The formatted string representation of the quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public string ToString(string format, IFormatProvider formatProvider) { return string.Format("quaternion({0}f, {1}f, {2}f, {3}f)", value.x.ToString(format, formatProvider), value.y.ToString(format, formatProvider), value.z.ToString(format, formatProvider), value.w.ToString(format, formatProvider)); } } public static partial class math { /// Returns a quaternion constructed from four float values. /// The x component of the quaternion. /// The y component of the quaternion. /// The z component of the quaternion. /// The w component of the quaternion. /// The quaternion constructed from individual components. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion quaternion(float x, float y, float z, float w) { return new quaternion(x, y, z, w); } /// Returns a quaternion constructed from a float4 vector. /// The float4 containing the components of the quaternion. /// The quaternion constructed from a float4. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion quaternion(float4 value) { return new quaternion(value); } /// Returns a unit quaternion constructed from a float3x3 rotation matrix. The matrix must be orthonormal. /// The float3x3 rotation matrix. /// The quaternion constructed from a float3x3 matrix. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion quaternion(float3x3 m) { return new quaternion(m); } /// Returns a unit quaternion constructed from a float4x4 matrix. The matrix must be orthonormal. /// The float4x4 matrix (must be orthonormal). /// The quaternion constructed from a float4x4 matrix. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion quaternion(float4x4 m) { return new quaternion(m); } /// Returns the conjugate of a quaternion value. /// The quaternion to conjugate. /// The conjugate of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion conjugate(quaternion q) { return quaternion(q.value * float4(-1.0f, -1.0f, -1.0f, 1.0f)); } /// Returns the inverse of a quaternion value. /// The quaternion to invert. /// The quaternion inverse of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion inverse(quaternion q) { float4 x = q.value; return quaternion(rcp(dot(x, x)) * x * float4(-1.0f, -1.0f, -1.0f, 1.0f)); } /// Returns the dot product of two quaternions. /// The first quaternion. /// The second quaternion. /// The dot product of two quaternions. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static float dot(quaternion a, quaternion b) { return dot(a.value, b.value); } /// Returns the length of a quaternion. /// The input quaternion. /// The length of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static float length(quaternion q) { return sqrt(dot(q.value, q.value)); } /// Returns the squared length of a quaternion. /// The input quaternion. /// The length squared of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static float lengthsq(quaternion q) { return dot(q.value, q.value); } /// Returns a normalized version of a quaternion q by scaling it by 1 / length(q). /// The quaternion to normalize. /// The normalized quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion normalize(quaternion q) { float4 x = q.value; return quaternion(rsqrt(dot(x, x)) * x); } /// /// Returns a safe normalized version of the q by scaling it by 1 / length(q). /// Returns the identity when 1 / length(q) does not produce a finite number. /// /// The quaternion to normalize. /// The normalized quaternion or the identity quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion normalizesafe(quaternion q) { float4 x = q.value; float len = math.dot(x, x); return quaternion(math.select(Mathematics.quaternion.identity.value, x * math.rsqrt(len), len > FLT_MIN_NORMAL)); } /// /// Returns a safe normalized version of the q by scaling it by 1 / length(q). /// Returns the given default value when 1 / length(q) does not produce a finite number. /// /// The quaternion to normalize. /// The default value. /// The normalized quaternion or the default value. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion normalizesafe(quaternion q, quaternion defaultvalue) { float4 x = q.value; float len = math.dot(x, x); return quaternion(math.select(defaultvalue.value, x * math.rsqrt(len), len > FLT_MIN_NORMAL)); } /// Returns the natural exponent of a quaternion. Assumes w is zero. /// The quaternion with w component equal to zero. /// The natural exponent of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion unitexp(quaternion q) { float v_rcp_len = rsqrt(dot(q.value.xyz, q.value.xyz)); float v_len = rcp(v_rcp_len); float sin_v_len, cos_v_len; sincos(v_len, out sin_v_len, out cos_v_len); return quaternion(float4(q.value.xyz * v_rcp_len * sin_v_len, cos_v_len)); } /// Returns the natural exponent of a quaternion. /// The quaternion. /// The natural exponent of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion exp(quaternion q) { float v_rcp_len = rsqrt(dot(q.value.xyz, q.value.xyz)); float v_len = rcp(v_rcp_len); float sin_v_len, cos_v_len; sincos(v_len, out sin_v_len, out cos_v_len); return quaternion(float4(q.value.xyz * v_rcp_len * sin_v_len, cos_v_len) * exp(q.value.w)); } /// Returns the natural logarithm of a unit length quaternion. /// The unit length quaternion. /// The natural logarithm of the unit length quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion unitlog(quaternion q) { float w = clamp(q.value.w, -1.0f, 1.0f); float s = acos(w) * rsqrt(1.0f - w*w); return quaternion(float4(q.value.xyz * s, 0.0f)); } /// Returns the natural logarithm of a quaternion. /// The quaternion. /// The natural logarithm of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion log(quaternion q) { float v_len_sq = dot(q.value.xyz, q.value.xyz); float q_len_sq = v_len_sq + q.value.w*q.value.w; float s = acos(clamp(q.value.w * rsqrt(q_len_sq), -1.0f, 1.0f)) * rsqrt(v_len_sq); return quaternion(float4(q.value.xyz * s, 0.5f * log(q_len_sq))); } /// Returns the result of transforming the quaternion b by the quaternion a. /// The quaternion on the left. /// The quaternion on the right. /// The result of transforming quaternion b by the quaternion a. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion mul(quaternion a, quaternion b) { return quaternion(a.value.wwww * b.value + (a.value.xyzx * b.value.wwwx + a.value.yzxy * b.value.zxyy) * float4(1.0f, 1.0f, 1.0f, -1.0f) - a.value.zxyz * b.value.yzxz); } /// Returns the result of transforming a vector by a quaternion. /// The quaternion transformation. /// The vector to transform. /// The transformation of vector v by quaternion q. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static float3 mul(quaternion q, float3 v) { float3 t = 2 * cross(q.value.xyz, v); return v + q.value.w * t + cross(q.value.xyz, t); } /// Returns the result of rotating a vector by a unit quaternion. /// The quaternion rotation. /// The vector to rotate. /// The rotation of vector v by quaternion q. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static float3 rotate(quaternion q, float3 v) { float3 t = 2 * cross(q.value.xyz, v); return v + q.value.w * t + cross(q.value.xyz, t); } /// Returns the result of a normalized linear interpolation between two quaternions q1 and a2 using an interpolation parameter t. /// /// Prefer to use this over slerp() when you know the distance between q1 and q2 is small. This can be much /// higher performance due to avoiding trigonometric function evaluations that occur in slerp(). /// /// The first quaternion. /// The second quaternion. /// The interpolation parameter. /// The normalized linear interpolation of two quaternions. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion nlerp(quaternion q1, quaternion q2, float t) { float dt = dot(q1, q2); if(dt < 0.0f) { q2.value = -q2.value; } return normalize(quaternion(lerp(q1.value, q2.value, t))); } /// Returns the result of a spherical interpolation between two quaternions q1 and a2 using an interpolation parameter t. /// The first quaternion. /// The second quaternion. /// The interpolation parameter. /// The spherical linear interpolation of two quaternions. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static quaternion slerp(quaternion q1, quaternion q2, float t) { float dt = dot(q1, q2); if (dt < 0.0f) { dt = -dt; q2.value = -q2.value; } if (dt < 0.9995f) { float angle = acos(dt); float s = rsqrt(1.0f - dt * dt); // 1.0f / sin(angle) float w1 = sin(angle * (1.0f - t)) * s; float w2 = sin(angle * t) * s; return quaternion(q1.value * w1 + q2.value * w2); } else { // if the angle is small, use linear interpolation return nlerp(q1, q2, t); } } /// Returns a uint hash code of a quaternion. /// The quaternion to hash. /// The hash code for the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static uint hash(quaternion q) { return hash(q.value); } /// /// Returns a uint4 vector hash code of a quaternion. /// When multiple elements are to be hashes together, it can more efficient to calculate and combine wide hash /// that are only reduced to a narrow uint hash at the very end instead of at every step. /// /// The quaternion to hash. /// The uint4 vector hash code of the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static uint4 hashwide(quaternion q) { return hashwide(q.value); } /// /// Transforms the forward vector by a quaternion. /// /// The quaternion transformation. /// The forward vector transformed by the input quaternion. [MethodImpl(MethodImplOptions.AggressiveInlining)] public static float3 forward(quaternion q) { return mul(q, float3(0, 0, 1)); } // for compatibility } }