#include "Quaternion.h" #include "2d/ccMacros.h" NS_CC_MATH_BEGIN Quaternion::Quaternion() : x(0.0f), y(0.0f), z(0.0f), w(1.0f) { } Quaternion::Quaternion(float xx, float yy, float zz, float ww) : x(xx), y(yy), z(zz), w(ww) { } Quaternion::Quaternion(float* array) { set(array); } Quaternion::Quaternion(const Matrix& m) { set(m); } Quaternion::Quaternion(const Vector3& axis, float angle) { set(axis, angle); } Quaternion::Quaternion(const Quaternion& copy) { set(copy); } Quaternion::~Quaternion() { } const Quaternion& Quaternion::identity() { static Quaternion value(0.0f, 0.0f, 0.0f, 1.0f); return value; } const Quaternion& Quaternion::zero() { static Quaternion value(0.0f, 0.0f, 0.0f, 0.0f); return value; } bool Quaternion::isIdentity() const { return x == 0.0f && y == 0.0f && z == 0.0f && w == 1.0f; } bool Quaternion::isZero() const { return x == 0.0f && y == 0.0f && z == 0.0f && w == 0.0f; } void Quaternion::createFromRotationMatrix(const Matrix& m, Quaternion* dst) { m.getRotation(dst); } void Quaternion::createFromAxisAngle(const Vector3& axis, float angle, Quaternion* dst) { GP_ASSERT(dst); float halfAngle = angle * 0.5f; float sinHalfAngle = sinf(halfAngle); Vector3 normal(axis); normal.normalize(); dst->x = normal.x * sinHalfAngle; dst->y = normal.y * sinHalfAngle; dst->z = normal.z * sinHalfAngle; dst->w = cosf(halfAngle); } void Quaternion::conjugate() { conjugate(this); } void Quaternion::conjugate(Quaternion* dst) const { GP_ASSERT(dst); dst->x = -x; dst->y = -y; dst->z = -z; dst->w = w; } bool Quaternion::inverse() { return inverse(this); } bool Quaternion::inverse(Quaternion* dst) const { GP_ASSERT(dst); float n = x * x + y * y + z * z + w * w; if (n == 1.0f) { dst->x = -x; dst->y = -y; dst->z = -z; dst->w = w; return true; } // Too close to zero. if (n < 0.000001f) return false; n = 1.0f / n; dst->x = -x * n; dst->y = -y * n; dst->z = -z * n; dst->w = w * n; return true; } void Quaternion::multiply(const Quaternion& q) { multiply(*this, q, this); } void Quaternion::multiply(const Quaternion& q1, const Quaternion& q2, Quaternion* dst) { GP_ASSERT(dst); float x = q1.w * q2.x + q1.x * q2.w + q1.y * q2.z - q1.z * q2.y; float y = q1.w * q2.y - q1.x * q2.z + q1.y * q2.w + q1.z * q2.x; float z = q1.w * q2.z + q1.x * q2.y - q1.y * q2.x + q1.z * q2.w; float w = q1.w * q2.w - q1.x * q2.x - q1.y * q2.y - q1.z * q2.z; dst->x = x; dst->y = y; dst->z = z; dst->w = w; } void Quaternion::normalize() { normalize(this); } void Quaternion::normalize(Quaternion* dst) const { GP_ASSERT(dst); if (this != dst) { dst->x = x; dst->y = y; dst->z = z; dst->w = w; } float n = x * x + y * y + z * z + w * w; // Already normalized. if (n == 1.0f) return; n = sqrt(n); // Too close to zero. if (n < 0.000001f) return; n = 1.0f / n; dst->x *= n; dst->y *= n; dst->z *= n; dst->w *= n; } void Quaternion::set(float xx, float yy, float zz, float ww) { this->x = xx; this->y = yy; this->z = zz; this->w = ww; } void Quaternion::set(float* array) { GP_ASSERT(array); x = array[0]; y = array[1]; z = array[2]; w = array[3]; } void Quaternion::set(const Matrix& m) { Quaternion::createFromRotationMatrix(m, this); } void Quaternion::set(const Vector3& axis, float angle) { Quaternion::createFromAxisAngle(axis, angle, this); } void Quaternion::set(const Quaternion& q) { this->x = q.x; this->y = q.y; this->z = q.z; this->w = q.w; } void Quaternion::setIdentity() { x = 0.0f; y = 0.0f; z = 0.0f; w = 1.0f; } float Quaternion::toAxisAngle(Vector3* axis) const { GP_ASSERT(axis); Quaternion q(x, y, z, w); q.normalize(); axis->x = q.x; axis->y = q.y; axis->z = q.z; axis->normalize(); return (2.0f * acos(q.w)); } void Quaternion::lerp(const Quaternion& q1, const Quaternion& q2, float t, Quaternion* dst) { GP_ASSERT(dst); GP_ASSERT(!(t < 0.0f || t > 1.0f)); if (t == 0.0f) { memcpy(dst, &q1, sizeof(float) * 4); return; } else if (t == 1.0f) { memcpy(dst, &q2, sizeof(float) * 4); return; } float t1 = 1.0f - t; dst->x = t1 * q1.x + t * q2.x; dst->y = t1 * q1.y + t * q2.y; dst->z = t1 * q1.z + t * q2.z; dst->w = t1 * q1.w + t * q2.w; } void Quaternion::slerp(const Quaternion& q1, const Quaternion& q2, float t, Quaternion* dst) { GP_ASSERT(dst); slerp(q1.x, q1.y, q1.z, q1.w, q2.x, q2.y, q2.z, q2.w, t, &dst->x, &dst->y, &dst->z, &dst->w); } void Quaternion::squad(const Quaternion& q1, const Quaternion& q2, const Quaternion& s1, const Quaternion& s2, float t, Quaternion* dst) { GP_ASSERT(!(t < 0.0f || t > 1.0f)); Quaternion dstQ(0.0f, 0.0f, 0.0f, 1.0f); Quaternion dstS(0.0f, 0.0f, 0.0f, 1.0f); slerpForSquad(q1, q2, t, &dstQ); slerpForSquad(s1, s2, t, &dstS); slerpForSquad(dstQ, dstS, 2.0f * t * (1.0f - t), dst); } void Quaternion::slerp(float q1x, float q1y, float q1z, float q1w, float q2x, float q2y, float q2z, float q2w, float t, float* dstx, float* dsty, float* dstz, float* dstw) { // Fast slerp implementation by kwhatmough: // It contains no division operations, no trig, no inverse trig // and no sqrt. Not only does this code tolerate small constraint // errors in the input quaternions, it actually corrects for them. GP_ASSERT(dstx && dsty && dstz && dstw); GP_ASSERT(!(t < 0.0f || t > 1.0f)); if (t == 0.0f) { *dstx = q1x; *dsty = q1y; *dstz = q1z; *dstw = q1w; return; } else if (t == 1.0f) { *dstx = q2x; *dsty = q2y; *dstz = q2z; *dstw = q2w; return; } if (q1x == q2x && q1y == q2y && q1z == q2z && q1w == q2w) { *dstx = q1x; *dsty = q1y; *dstz = q1z; *dstw = q1w; return; } float halfY, alpha, beta; float u, f1, f2a, f2b; float ratio1, ratio2; float halfSecHalfTheta, versHalfTheta; float sqNotU, sqU; float cosTheta = q1w * q2w + q1x * q2x + q1y * q2y + q1z * q2z; // As usual in all slerp implementations, we fold theta. alpha = cosTheta >= 0 ? 1.0f : -1.0f; halfY = 1.0f + alpha * cosTheta; // Here we bisect the interval, so we need to fold t as well. f2b = t - 0.5f; u = f2b >= 0 ? f2b : -f2b; f2a = u - f2b; f2b += u; u += u; f1 = 1.0f - u; // One iteration of Newton to get 1-cos(theta / 2) to good accuracy. halfSecHalfTheta = 1.09f - (0.476537f - 0.0903321f * halfY) * halfY; halfSecHalfTheta *= 1.5f - halfY * halfSecHalfTheta * halfSecHalfTheta; versHalfTheta = 1.0f - halfY * halfSecHalfTheta; // Evaluate series expansions of the coefficients. sqNotU = f1 * f1; ratio2 = 0.0000440917108f * versHalfTheta; ratio1 = -0.00158730159f + (sqNotU - 16.0f) * ratio2; ratio1 = 0.0333333333f + ratio1 * (sqNotU - 9.0f) * versHalfTheta; ratio1 = -0.333333333f + ratio1 * (sqNotU - 4.0f) * versHalfTheta; ratio1 = 1.0f + ratio1 * (sqNotU - 1.0f) * versHalfTheta; sqU = u * u; ratio2 = -0.00158730159f + (sqU - 16.0f) * ratio2; ratio2 = 0.0333333333f + ratio2 * (sqU - 9.0f) * versHalfTheta; ratio2 = -0.333333333f + ratio2 * (sqU - 4.0f) * versHalfTheta; ratio2 = 1.0f + ratio2 * (sqU - 1.0f) * versHalfTheta; // Perform the bisection and resolve the folding done earlier. f1 *= ratio1 * halfSecHalfTheta; f2a *= ratio2; f2b *= ratio2; alpha *= f1 + f2a; beta = f1 + f2b; // Apply final coefficients to a and b as usual. float w = alpha * q1w + beta * q2w; float x = alpha * q1x + beta * q2x; float y = alpha * q1y + beta * q2y; float z = alpha * q1z + beta * q2z; // This final adjustment to the quaternion's length corrects for // any small constraint error in the inputs q1 and q2 But as you // can see, it comes at the cost of 9 additional multiplication // operations. If this error-correcting feature is not required, // the following code may be removed. f1 = 1.5f - 0.5f * (w * w + x * x + y * y + z * z); *dstw = w * f1; *dstx = x * f1; *dsty = y * f1; *dstz = z * f1; } void Quaternion::slerpForSquad(const Quaternion& q1, const Quaternion& q2, float t, Quaternion* dst) { GP_ASSERT(dst); // cos(omega) = q1 * q2; // slerp(q1, q2, t) = (q1*sin((1-t)*omega) + q2*sin(t*omega))/sin(omega); // q1 = +- q2, slerp(q1,q2,t) = q1. // This is a straight-forward implementation of the formula of slerp. It does not do any sign switching. float c = q1.x * q2.x + q1.y * q2.y + q1.z * q2.z + q1.w * q2.w; if (fabs(c) >= 1.0f) { dst->x = q1.x; dst->y = q1.y; dst->z = q1.z; dst->w = q1.w; return; } float omega = acos(c); float s = sqrt(1.0f - c * c); if (fabs(s) <= 0.00001f) { dst->x = q1.x; dst->y = q1.y; dst->z = q1.z; dst->w = q1.w; return; } float r1 = sin((1 - t) * omega) / s; float r2 = sin(t * omega) / s; dst->x = (q1.x * r1 + q2.x * r2); dst->y = (q1.y * r1 + q2.y * r2); dst->z = (q1.z * r1 + q2.z * r2); dst->w = (q1.w * r1 + q2.w * r2); } NS_CC_MATH_END