doxygen/Math_8hh_source.html

#ifndef MATH_HH

#define MATH_HH


#include "likely.hh"

#include <cassert>

#include <cmath>

#include <cstdint>


#ifdef _MSC_VER

#include <intrin.h>

#pragma intrinsic(_BitScanForward)

#endif


// These constants are very common extensions, but not guaranteed to be defined

// by <cmath> when compiling in a strict standards compliant mode. Also e.g.

// visual studio does not provide them.

#ifndef M_E

#define M_E    2.7182818284590452354

#endif

#ifndef M_LN2

#define M_LN2  0.69314718055994530942 // log_e 2

#endif

#ifndef M_LN10

#define M_LN10 2.30258509299404568402 // log_e 10

#endif

#ifndef M_PI

#define M_PI   3.14159265358979323846

#endif


namespace Math {


template<typename T>

[[nodiscard]] constexpr T log2p1(T x) noexcept

{

        T result = 0;

        while (x) {

                ++result;

                x >>= 1;

        }

        return result;

}


template<typename T>

[[nodiscard]] constexpr bool ispow2(T x) noexcept

{

        return x && ((x & (x - 1)) == 0);

}


template<typename T>

[[nodiscard]] constexpr T floodRight(T x) noexcept

{

        x |= x >> 1;

        x |= x >> 2;

        x |= x >> 4;

        x |= x >> ((sizeof(x) >= 2) ?  8 : 0); // Written in a weird way to

        x |= x >> ((sizeof(x) >= 4) ? 16 : 0); // suppress compiler warnings.

        x |= x >> ((sizeof(x) >= 8) ? 32 : 0); // Generates equally efficient

        return x;                              // code.

}


template<typename T>

[[nodiscard]] constexpr T ceil2(T x) noexcept

{

        // classical implementation:

        //   unsigned res = 1;

        //   while (x > res) res <<= 1;

        //   return res;


        // optimized version

        x += (x == 0); // can be removed if argument is never zero

        return floodRight(x - 1) + 1;

}


[[nodiscard]] inline int16_t clipIntToShort(int x)

{

        static_assert((-1 >> 1) == -1, "right-shift must preserve sign");

        return likely(int16_t(x) == x) ? x : (0x7FFF - (x >> 31));

}


[[nodiscard]] inline uint8_t clipIntToByte(int x)

{

        static_assert((-1 >> 1) == -1, "right-shift must preserve sign");

        return likely(uint8_t(x) == x) ? x : ~(x >> 31);

}


[[nodiscard]] inline unsigned reverseNBits(unsigned x, unsigned bits)

{

        unsigned ret = 0;

        while (bits--) {

                ret = (ret << 1) | (x & 1);

                x >>= 1;

        }

        return ret;


        /* Just for fun I tried the asm version below (the carry-flag trick

         * cannot be described in plain C). It's correct and generates shorter

         * code (both less instructions and less bytes). But it doesn't

         * actually run faster on the machine I tested on, or only a tiny bit

         * (possibly because of dependency chains and processor stalls???).

         * However a big disadvantage of this asm version is that when called

         * with compile-time constant arguments, this version performs exactly

         * the same, while the version above can be further optimized by the

         * compiler (constant-propagation, loop unrolling, ...).

        unsigned ret = 0;

        if (bits) {

                asm (

                "1:     shr     %[VAL]\n"

                "       adc     %[RET],%[RET]\n"

                "       dec     %[BITS]\n"

                "       jne     1b\n"

                        : [VAL]  "+r" (val)

                        , [BITS] "+r" (bits)

                        , [RET]  "+r" (ret)

                );

        }

        return ret;

        */


        /* Maarten suggested the following approach with O(lg(N)) time

         * complexity (the version above is O(N)).

         *  - reverse full (32-bit) word: O(lg(N))

         *  - shift right over 32-N bits: O(1)

         * Note: In some lower end CPU the shift-over-N-bits instruction itself

         *       is O(N), in that case this whole algorithm is O(N)

         * Note2: Instead of '32' it's also possible to use a lower power of 2,

         *        as long as it's bigger than or equal to N.

         * This algorithm may or may not be faster than the version above, I

         * didn't try it yet. Also because this routine is _NOT_ performance

         * critical _AT_ALL_ currently.

         */

}


[[nodiscard]] inline uint8_t reverseByte(uint8_t a)

{

        // Classical implementation (can be extended to 16 and 32 bits)

        //   a = ((a & 0xF0) >> 4) | ((a & 0x0F) << 4);

        //   a = ((a & 0xCC) >> 2) | ((a & 0x33) << 2);

        //   a = ((a & 0xAA) >> 1) | ((a & 0x55) << 1);

        //   return a;


        // The versions below are specific to reverse a single byte (can't

        // easily be extended to wider types). Found these tricks on:

        //    http://graphics.stanford.edu/~seander/bithacks.html

#ifdef __x86_64

        // on 64-bit systems this is slightly faster

        return (((a * 0x80200802ULL) & 0x0884422110ULL) * 0x0101010101ULL) >> 32;

#else

        // on 32-bit systems this is faster

        return (((a * 0x0802 & 0x22110) | (a * 0x8020 & 0x88440)) * 0x10101) >> 16;

#endif

}


[[nodiscard]] inline unsigned countLeadingZeros(unsigned x)

{

#ifdef __GNUC__

        // actually this only exists starting from gcc-3.4.x

        return __builtin_clz(x); // undefined when x==0

#else

        // gives incorrect result for x==0, but that doesn't matter here

        unsigned lz = 0;

        if (x <= 0x0000ffff) { lz += 16; x <<= 16; }

        if (x <= 0x00ffffff) { lz +=  8; x <<=  8; }

        if (x <= 0x0fffffff) { lz +=  4; x <<=  4; }

        lz += (0x55ac >> ((x >> 27) & 0x1e)) & 0x3;

        return lz;

#endif

}


[[nodiscard]] inline unsigned findFirstSet(unsigned x)

{

#if defined(__GNUC__)

        return __builtin_ffs(x);

#elif defined(_MSC_VER)

        unsigned long index;

        return _BitScanForward(&index, x) ? index + 1 : 0;

#else

        if (x == 0) return 0;

        int pos = 0;

        if ((x & 0xffff) == 0) { pos += 16; x >>= 16; }

        if ((x & 0x00ff) == 0) { pos +=  8; x >>=  8; }

        if ((x & 0x000f) == 0) { pos +=  4; x >>=  4; }

        if ((x & 0x0003) == 0) { pos +=  2; x >>=  2; }

        if ((x & 0x0001) == 0) { pos +=  1; }

        return pos + 1;

#endif

}


// Cubic Hermite Interpolation:

//   Given 4 points: (-1, y[-1]), (0, y[0]), (1, y[1]), (2, y[2])

//   Fit a polynomial:  f(x) = a*x^3 + b*x^2 + c*x + d

//     which passes through the given points at x=0 and x=1

//       f(0) = y[0]

//       f(1) = y[1]

//     and which has specific derivatives at x=0 and x=1

//       f'(0) = (y[1] - y[-1]) / 2

//       f'(1) = (y[2] - y[ 0]) / 2

//   Then evaluate this polynomial at the given x-position (x in [0, 1]).

// For more details see:

//   https://en.wikipedia.org/wiki/Cubic_Hermite_spline

//   https://www.paulinternet.nl/?page=bicubic

[[nodiscard]] inline float cubicHermite(const float* y, float x)

{

        assert(0.0f <= x); assert(x <= 1.0f);

        float a = -0.5f*y[-1] + 1.5f*y[0] - 1.5f*y[1] + 0.5f*y[2];

        float b =       y[-1] - 2.5f*y[0] + 2.0f*y[1] - 0.5f*y[2];

        float c = -0.5f*y[-1]             + 0.5f*y[1];

        float d =                    y[0];

        float x2 = x * x;

        float x3 = x * x2;

        return a*x3 + b*x2 + c*x + d;

}


} // namespace Math


#endif // MATH_HH