antkeeper
/
superbuild


								#ifndef AL_NUMERIC_H

								#define AL_NUMERIC_H


								#include <algorithm>

								#include <cmath>

								#include <cstddef>

								#include <cstdint>

								#ifdef HAVE_INTRIN_H

								#include <intrin.h>

								#endif

								#ifdef HAVE_SSE_INTRINSICS

								#include <xmmintrin.h>

								#endif


								#include "opthelpers.h"


								inline constexpr int64_t operator "" _i64(unsigned long long int n) noexcept { return static_cast<int64_t>(n); }

								inline constexpr uint64_t operator "" _u64(unsigned long long int n) noexcept { return static_cast<uint64_t>(n); }


								constexpr inline float minf(float a, float b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline float maxf(float a, float b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline float clampf(float val, float min, float max) noexcept

								{ return minf(max, maxf(min, val)); }


								constexpr inline double mind(double a, double b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline double maxd(double a, double b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline double clampd(double val, double min, double max) noexcept

								{ return mind(max, maxd(min, val)); }


								constexpr inline unsigned int minu(unsigned int a, unsigned int b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline unsigned int maxu(unsigned int a, unsigned int b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline unsigned int clampu(unsigned int val, unsigned int min, unsigned int max) noexcept

								{ return minu(max, maxu(min, val)); }


								constexpr inline int mini(int a, int b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline int maxi(int a, int b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline int clampi(int val, int min, int max) noexcept

								{ return mini(max, maxi(min, val)); }


								constexpr inline int64_t mini64(int64_t a, int64_t b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline int64_t maxi64(int64_t a, int64_t b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline int64_t clampi64(int64_t val, int64_t min, int64_t max) noexcept

								{ return mini64(max, maxi64(min, val)); }


								constexpr inline uint64_t minu64(uint64_t a, uint64_t b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline uint64_t maxu64(uint64_t a, uint64_t b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline uint64_t clampu64(uint64_t val, uint64_t min, uint64_t max) noexcept

								{ return minu64(max, maxu64(min, val)); }


								constexpr inline size_t minz(size_t a, size_t b) noexcept

								{ return ((a > b) ? b : a); }

								constexpr inline size_t maxz(size_t a, size_t b) noexcept

								{ return ((a > b) ? a : b); }

								constexpr inline size_t clampz(size_t val, size_t min, size_t max) noexcept

								{ return minz(max, maxz(min, val)); }


								constexpr inline float lerpf(float val1, float val2, float mu) noexcept

								{ return val1 + (val2-val1)*mu; }

								constexpr inline float cubic(float val1, float val2, float val3, float val4, float mu) noexcept

								{

								    const float mu2{mu*mu}, mu3{mu2*mu};

								    const float a0{-0.5f*mu3 +       mu2 + -0.5f*mu};

								    const float a1{ 1.5f*mu3 + -2.5f*mu2            + 1.0f};

								    const float a2{-1.5f*mu3 +  2.0f*mu2 +  0.5f*mu};

								    const float a3{ 0.5f*mu3 + -0.5f*mu2};

								    return val1*a0 + val2*a1 + val3*a2 + val4*a3;

								}


								/** Find the next power-of-2 for non-power-of-2 numbers. */

								inline uint32_t NextPowerOf2(uint32_t value) noexcept

								{

								    if(value > 0)

								    {

								        value--;

								        value |= value>>1;

								        value |= value>>2;

								        value |= value>>4;

								        value |= value>>8;

								        value |= value>>16;

								    }

								    return value+1;

								}


								/** Round up a value to the next multiple. */

								inline size_t RoundUp(size_t value, size_t r) noexcept

								{

								    value += r-1;

								    return value - (value%r);

								}


								/**

								 * Fast float-to-int conversion. No particular rounding mode is assumed; the

								 * IEEE-754 default is round-to-nearest with ties-to-even, though an app could

								 * change it on its own threads. On some systems, a truncating conversion may

								 * always be the fastest method.

								 */

								inline int fastf2i(float f) noexcept

								{

								#if defined(HAVE_SSE_INTRINSICS)

								    return _mm_cvt_ss2si(_mm_set_ss(f));


								#elif defined(_MSC_VER) && defined(_M_IX86_FP)


								    int i;

								    __asm fld f

								    __asm fistp i

								    return i;


								#elif (defined(__GNUC__) || defined(__clang__)) && (defined(__i386__) || defined(__x86_64__))


								    int i;

								#ifdef __SSE_MATH__

								    __asm__("cvtss2si %1, %0" : "=r"(i) : "x"(f));

								#else

								    __asm__ __volatile__("fistpl %0" : "=m"(i) : "t"(f) : "st");

								#endif

								    return i;


								#else


								    return static_cast<int>(f);

								#endif

								}

								inline unsigned int fastf2u(float f) noexcept

								{ return static_cast<unsigned int>(fastf2i(f)); }


								/** Converts float-to-int using standard behavior (truncation). */

								inline int float2int(float f) noexcept

								{

								#if defined(HAVE_SSE_INTRINSICS)

								    return _mm_cvtt_ss2si(_mm_set_ss(f));


								#elif (defined(_MSC_VER) && defined(_M_IX86_FP) && _M_IX86_FP == 0) \

								    || ((defined(__GNUC__) || defined(__clang__)) && (defined(__i386__) || defined(__x86_64__)) \

								        && !defined(__SSE_MATH__))

								    int sign, shift, mant;

								    union {

								        float f;

								        int i;

								    } conv;


								    conv.f = f;

								    sign = (conv.i>>31) | 1;

								    shift = ((conv.i>>23)&0xff) - (127+23);


								    /* Over/underflow */

								    if UNLIKELY(shift >= 31 || shift < -23)

								        return 0;


								    mant = (conv.i&0x7fffff) | 0x800000;

								    if LIKELY(shift < 0)

								        return (mant >> -shift) * sign;

								    return (mant << shift) * sign;


								#else


								    return static_cast<int>(f);

								#endif

								}

								inline unsigned int float2uint(float f) noexcept

								{ return static_cast<unsigned int>(float2int(f)); }


								/** Converts double-to-int using standard behavior (truncation). */

								inline int double2int(double d) noexcept

								{

								#if defined(HAVE_SSE_INTRINSICS)

								    return _mm_cvttsd_si32(_mm_set_sd(d));


								#elif (defined(_MSC_VER) && defined(_M_IX86_FP) && _M_IX86_FP < 2) \

								    || ((defined(__GNUC__) || defined(__clang__)) && (defined(__i386__) || defined(__x86_64__)) \

								        && !defined(__SSE2_MATH__))

								    int sign, shift;

								    int64_t mant;

								    union {

								        double d;

								        int64_t i64;

								    } conv;


								    conv.d = d;

								    sign = (conv.i64 >> 63) | 1;

								    shift = ((conv.i64 >> 52) & 0x7ff) - (1023 + 52);


								    /* Over/underflow */

								    if UNLIKELY(shift >= 63 || shift < -52)

								        return 0;


								    mant = (conv.i64 & 0xfffffffffffff_i64) | 0x10000000000000_i64;

								    if LIKELY(shift < 0)

								        return (int)(mant >> -shift) * sign;

								    return (int)(mant << shift) * sign;


								#else


								    return static_cast<int>(d);

								#endif

								}


								/**

								 * Rounds a float to the nearest integral value, according to the current

								 * rounding mode. This is essentially an inlined version of rintf, although

								 * makes fewer promises (e.g. -0 or -0.25 rounded to 0 may result in +0).

								 */

								inline float fast_roundf(float f) noexcept

								{

								#if (defined(__GNUC__) || defined(__clang__)) && (defined(__i386__) || defined(__x86_64__)) \

								    && !defined(__SSE_MATH__)


								    float out;

								    __asm__ __volatile__("frndint" : "=t"(out) : "0"(f));

								    return out;


								#elif (defined(__GNUC__) || defined(__clang__)) && defined(__aarch64__)


								    float out;

								    __asm__ volatile("frintx %s0, %s1" : "=w"(out) : "w"(f));

								    return out;


								#else


								    /* Integral limit, where sub-integral precision is not available for

								     * floats.

								     */

								    static const float ilim[2]{

								         8388608.0f /*  0x1.0p+23 */,

								        -8388608.0f /* -0x1.0p+23 */

								    };

								    unsigned int sign, expo;

								    union {

								        float f;

								        unsigned int i;

								    } conv;


								    conv.f = f;

								    sign = (conv.i>>31)&0x01;

								    expo = (conv.i>>23)&0xff;


								    if UNLIKELY(expo >= 150/*+23*/)

								    {

								        /* An exponent (base-2) of 23 or higher is incapable of sub-integral

								         * precision, so it's already an integral value. We don't need to worry

								         * about infinity or NaN here.

								         */

								        return f;

								    }

								    /* Adding the integral limit to the value (with a matching sign) forces a

								     * result that has no sub-integral precision, and is consequently forced to

								     * round to an integral value. Removing the integral limit then restores

								     * the initial value rounded to the integral. The compiler should not

								     * optimize this out because of non-associative rules on floating-point

								     * math (as long as you don't use -fassociative-math,

								     * -funsafe-math-optimizations, -ffast-math, or -Ofast, in which case this

								     * may break).

								     */

								    f += ilim[sign];

								    return f - ilim[sign];

								#endif

								}


								template<typename T>

								constexpr const T& clamp(const T& value, const T& min_value, const T& max_value) noexcept

								{

								    return std::min(std::max(value, min_value), max_value);

								}


								// Converts level (mB) to gain.

								inline float level_mb_to_gain(float x)

								{

								    if(x <= -10'000.0f)

								        return 0.0f;

								    return std::pow(10.0f, x / 2'000.0f);

								}


								// Converts gain to level (mB).

								inline float gain_to_level_mb(float x)

								{

								    if (x <= 0.0f)

								        return -10'000.0f;

								    return maxf(std::log10(x) * 2'000.0f, -10'000.0f);

								}


								#endif /* AL_NUMERIC_H */