#ifndef COMMON_VECMAT_H #define COMMON_VECMAT_H #include #include #include #include #include "alspan.h" namespace alu { template class VectorR { static_assert(std::is_floating_point::value, "Must use floating-point types"); alignas(16) std::array mVals; public: constexpr VectorR() noexcept = default; constexpr VectorR(const VectorR&) noexcept = default; constexpr VectorR(T a, T b, T c, T d) noexcept : mVals{{a, b, c, d}} { } constexpr VectorR& operator=(const VectorR&) noexcept = default; T& operator[](size_t idx) noexcept { return mVals[idx]; } constexpr const T& operator[](size_t idx) const noexcept { return mVals[idx]; } VectorR& operator+=(const VectorR &rhs) noexcept { mVals[0] += rhs.mVals[0]; mVals[1] += rhs.mVals[1]; mVals[2] += rhs.mVals[2]; mVals[3] += rhs.mVals[3]; return *this; } T normalize() { const T length{std::sqrt(mVals[0]*mVals[0] + mVals[1]*mVals[1] + mVals[2]*mVals[2])}; if(length > std::numeric_limits::epsilon()) { T inv_length{T{1}/length}; mVals[0] *= inv_length; mVals[1] *= inv_length; mVals[2] *= inv_length; return length; } mVals[0] = mVals[1] = mVals[2] = T{0}; return T{0}; } constexpr VectorR cross_product(const alu::VectorR &rhs) const { return VectorR{ (*this)[1]*rhs[2] - (*this)[2]*rhs[1], (*this)[2]*rhs[0] - (*this)[0]*rhs[2], (*this)[0]*rhs[1] - (*this)[1]*rhs[0], T{0}}; } constexpr T dot_product(const alu::VectorR &rhs) const { return (*this)[0]*rhs[0] + (*this)[1]*rhs[1] + (*this)[2]*rhs[2]; } }; using Vector = VectorR; template class MatrixR { static_assert(std::is_floating_point::value, "Must use floating-point types"); alignas(16) std::array mVals; public: constexpr MatrixR() noexcept = default; constexpr MatrixR(const MatrixR&) noexcept = default; constexpr MatrixR(T aa, T ab, T ac, T ad, T ba, T bb, T bc, T bd, T ca, T cb, T cc, T cd, T da, T db, T dc, T dd) noexcept : mVals{{aa,ab,ac,ad, ba,bb,bc,bd, ca,cb,cc,cd, da,db,dc,dd}} { } constexpr MatrixR& operator=(const MatrixR&) noexcept = default; auto operator[](size_t idx) noexcept { return al::span{&mVals[idx*4], 4}; } constexpr auto operator[](size_t idx) const noexcept { return al::span{&mVals[idx*4], 4}; } static constexpr MatrixR Identity() noexcept { return MatrixR{ T{1}, T{0}, T{0}, T{0}, T{0}, T{1}, T{0}, T{0}, T{0}, T{0}, T{1}, T{0}, T{0}, T{0}, T{0}, T{1}}; } }; using Matrix = MatrixR; template inline VectorR operator*(const MatrixR &mtx, const VectorR &vec) noexcept { return VectorR{ vec[0]*mtx[0][0] + vec[1]*mtx[1][0] + vec[2]*mtx[2][0] + vec[3]*mtx[3][0], vec[0]*mtx[0][1] + vec[1]*mtx[1][1] + vec[2]*mtx[2][1] + vec[3]*mtx[3][1], vec[0]*mtx[0][2] + vec[1]*mtx[1][2] + vec[2]*mtx[2][2] + vec[3]*mtx[3][2], vec[0]*mtx[0][3] + vec[1]*mtx[1][3] + vec[2]*mtx[2][3] + vec[3]*mtx[3][3]}; } template inline VectorR cast_to(const VectorR &vec) noexcept { return VectorR{static_cast(vec[0]), static_cast(vec[1]), static_cast(vec[2]), static_cast(vec[3])}; } } // namespace alu #endif /* COMMON_VECMAT_H */